pmid termid comment
PMID:10022828 GO:0110085 establishment, but not maintenance, of ring localization requires F-actin (assayed using latrunculin A)
PMID:10022828 GO:0110085 establishment, but not maintenance, of ring localization requires F-actin (assayed using latrunculin A)
PMID:10022921 FYPO:0003775 assayed using Tf1 transposon plasmid construct
PMID:10022921 FYPO:0000593 assayed using Tf1 transposon plasmid construct
PMID:10022921 FYPO:0003772 assayed using Tf1 transposon
PMID:10022921 FYPO:0003773 assayed using Tf1 transposon Gag and IN
PMID:10022921 FYPO:0003774 assayed using Tf1 transposon
PMID:10087262 GO:0032178 combined localization and membrane fraction
PMID:10087262 FYPO:0002061 . mok1-664pck2 was synthetically lethal at 30C, a temperature at which either single mutant could grew (Fig. 10b)
PMID:10087262 FYPO:0002060 . Synthetic lethality was not observed between mok1- 664 and pck1, consistent with our previous result showing that pck2 plays the major role (Toda et al., 1993)
PMID:10087262 FYPO:0006802 Fig. 1 a, 'delocalized actin'
PMID:10087262 PBO:0099872 Fig. 1 c
PMID:10087262 FYPO:0002060 pck2delta rescues ags1 ox defect
PMID:10087262 FYPO:0007293 . mok1-664pck2 was synthetically lethal at 30C, a temperature at which either single mutant could grew (Fig. 10b)
PMID:10087262 PBO:0093772 data not shown
PMID:10087262 PBO:0105978 The other was observed as pairs of di- vided cells associated side-by-side (12%), the cell wall of which appeared fragile and often lysed upon division.
PMID:10087262 PBO:0105979 translocation of actin from one end t the other (also fig7)
PMID:10087262 PBO:0105980 more than threefold over compared with wild-type cells (344%)
PMID:10087262 GO:0016020 These results suggested that Mok1 is an stable integral membrane pro- tein, which is consistent with the presence of several trans- membrane domains (Fig. 2 a).
PMID:10087262 GO:0031520 combined localization and membrane fraction
PMID:10091325 GO:0004371 activated_by CHEBI:29108 | activated_by CHEBI:18420 | inhibited_by CHEBI:16761
PMID:10207075 FYPO:0003606 In contrast to the point mutation, the rec8::ura4 strain showed no shortening of prophase in three independent time courses (data not shown). Shortening of the prophase in the point mutation strain may indicate a role of Rec8p in meiosis regulation. Alternative explanations, like shortening of prophase by an additional mutation, were not excluded.
PMID:10226032 PBO:0098012 Surprisingly, Csk1 also activated Cdc2 in complexes with either Cdc13 or Cig2 cyclins.
PMID:10226032 PBO:0098010 mcs6 requires mcs2 for CTD kinase activity but not cyclin-dependent kinase activating kinase activity. mcs2 does not cycle throughout the cell cycle.
PMID:10226032 PBO:0098011 Csk1 activated both the monomeric and the Mcs2-bound forms of Mcs6.
PMID:10364209 MOD:00046 Fig. 1B
PMID:10364209 PBO:0096439 The same level of Myo2p co-immunoprecipitated with mutant Cdc4p as with wild-type Cdc4p (Fig. 5A).
PMID:10364209 FYPO:0001357 DNS
PMID:10364209 MOD:00046 Fig. 1B
PMID:10364209 FYPO:0001357 DNS
PMID:10365961 PBO:0101225 tyrosine, possibly Y188 (but not determined experimentally)
PMID:10365961 PBO:0095167 tyrosine, possibly Y188 (but not determined experimentally)
PMID:10365961 PBO:0095167 tyrosine, possibly Y188 (but not determined experimentally)
PMID:10366596 FYPO:0004086 in zygotic nucleus
PMID:10366596 FYPO:0001976 astral
PMID:10366596 FYPO:0004159 The ~14-fold increase of the disomic spores indicated that chromosome missegregation increased during meiosis I
PMID:10366596 FYPO:0004086 in zygotic nucleus
PMID:10381387 PBO:0094917 it doesn't say old, but it is...
PMID:10381387 PBO:0094917 it doesn't say old, but it is...
PMID:10388806 FYPO:0001430 cdc18delta::p[nmt*.cdc18+-LEU2]
PMID:10388806 PBO:0026408 Val: moved down from FYPO:0001429, its a fully penetrant inviable phenotype (anucleate)
PMID:10388806 FYPO:0001428 cdc18delta::p[nmt*.cdc18+-LEU2]
PMID:10392445 FYPO:0000474 conditions under which pat1-114 alone induces meiosis & sporulation
PMID:10398679 GO:0038066 is response to heat a real process or should be resposne to denatured proteins or whatever?
PMID:10398680 FYPO:0001042 figue 4
PMID:10398680 FYPO:0006174 figure 3
PMID:10398680 FYPO:0007304 figure3
PMID:10398680 FYPO:0003788 fig 1a
PMID:10398680 FYPO:0003241 Figure 1F & 7B (second mitosis)
PMID:10398680 FYPO:0006190 Figure 1, A and B All of these required passage through G1 (second mitosis)
PMID:10398680 FYPO:0007914 suggesting that sister centromeres were separated in the metaphase-arrested cells.
PMID:10398680 FYPO:0002060 figure 8a
PMID:10398680 FYPO:0006715 Figure 1, A and B All of these required passage through G1 (second mitosis)
PMID:10398680 FYPO:0004308 (Fig. 6D): Mis12 is thus required for maintaining the inner centromere structure.
PMID:10398680 FYPO:0002061 figure 8a
PMID:10398680 PBO:0103286 figure 6 Conversely, the mis6-302 strain integrated with the Mis12–HA gene was used.
PMID:10398680 FYPO:0002061 figure 8a
PMID:10398680 PBO:0103285 figure 6 Hence, mis6–HA could interact with the centromere in the absence of functional Mis12.
PMID:10398680 FYPO:0007914 figure 3 (before phase 3 extension)
PMID:10398680 FYPO:0006190 Figure 2
PMID:10398680 GO:0000939 These results showed that Mis12 was localized at centromeres throughout the cell cycle
PMID:10428959 PBO:0096485 (vw: sty1-atf1 pathway)
PMID:10428959 GO:0038066 table 2
PMID:10428959 PBO:0096482 Figure 3 (vw: severity 20.2 micron)
PMID:10428959 PBO:0096482 Figure 3 (vw severity 23.4 micron)
PMID:10428959 FYPO:0002060 DNS
PMID:10428959 PBO:0022884 figure 2C (vw: not by sty1)
PMID:10428959 GO:0005515 Figure1/2
PMID:10428959 GO:0010971 figure 3
PMID:10428959 GO:0010971 figure 3
PMID:10428959 PBO:0096492 figure 7
PMID:10428959 PBO:0096491 figure 7
PMID:10428959 GO:0005515 Figure 1/2
PMID:10428959 FYPO:0004481 figure 3b
PMID:10428959 FYPO:0001214 figure 3b
PMID:10428959 GO:0031139 table 2
PMID:10428959 PBO:0096490 figure 7
PMID:10428959 PBO:0096489 Figure 6B
PMID:10428959 PBO:0096488 Figure 6
PMID:10428959 PBO:0096487 Figure 5
PMID:10428959 PBO:0096486 Figure 5
PMID:10428959 PBO:0096484 (vw: sty1-atf1 pathway)
PMID:10430583 PBO:0093619 same as rad51delta alone
PMID:10430583 PBO:0093619 same as rad51delta alone
PMID:10459013 GO:0044732 present throughout mitotic cell cycle
PMID:10462529 FYPO:0001490 fig2
PMID:10462529 FYPO:0006036 fig1
PMID:10462529 FYPO:0006037 fig1
PMID:10462529 GO:0002183 fig2
PMID:10462529 FYPO:0002061 fig2
PMID:10462529 FYPO:0002061 Fig. 3
PMID:10462529 FYPO:0002085 Fig. 3
PMID:10462529 FYPO:0006038 4a
PMID:10462529 FYPO:0002085 fig5
PMID:10462529 FYPO:0003503 fig5
PMID:10462529 FYPO:0003503 fig5
PMID:10462529 PBO:0101463 fig 6
PMID:10462529 PBO:0101462 fig5
PMID:10462529 FYPO:0006038 fig3
PMID:10462529 FYPO:0002061 fig2
PMID:10462529 FYPO:0006822 fig7
PMID:10462529 FYPO:0000951 fig 7
PMID:10462529 PBO:0094621 extension, of cdc25 7b
PMID:10462529 FYPO:0001122 fig6
PMID:10462529 PBO:0101461 fig 6
PMID:10473641 FYPO:0004539 broken
PMID:10521402 FYPO:0006763 Fig1B cds1 is required for meiotic DNA replication checkpoint
PMID:10521402 PBO:0096550 Fig 1A rad1 is required for meiotic DNA replication checkpoint
PMID:10521402 PBO:0096550 Fig 1B double cds1delta chk1 delta has same phenotype as single cds1delta/cds1 delta
PMID:10521402 PBO:0096551 Fig1B
PMID:10521402 PBO:0096551 Fig1B
PMID:10521402 PBO:0021428 Fig3B data not shown
PMID:10521402 PBO:0021428 Fig3B data not shown
PMID:10521402 PBO:0096553 Data not shown prophase arrest with horsetail nuclear morphology see fig3A for pat1ts control
PMID:10521402 PBO:0096553 Data not shown prophase arrest with horsetail nuclear morphology see fig3A for pat1ts control
PMID:10521402 PBO:0096552 Data not shown. kinetics same as pat1ts rad1delta diploid
PMID:10521402 PBO:0096552 Data not shown. kinetics same as pat1ts rad1delta diploid
PMID:10521402 PBO:0096552 Data not shown. kinetics same as pat1ts rad1delta diploid
PMID:10521402 PBO:0096552 Fig 2 A,B
PMID:10521402 PBO:0096558 Fig6C
PMID:10521402 PBO:0096557 Fig 5A see Fig4A for control
PMID:10521402 PBO:0096557 Fig 5A see Fig4A for control
PMID:10521402 PBO:0096555 Fig5A see control in Fig4A
PMID:10521402 PBO:0096556 Fig5B see Fig4B for control
PMID:10521402 PBO:0096555 Fig5A see control in Fig4A
PMID:10521402 PBO:0096554 Fig4 present during meiotic DNA replication checkpoint arrest
PMID:10521402 PBO:0096559 Fig6A,D; meiotic cells unable to inhibit CDK1 activity in response to activation of the meiotic DNA replication checkpoint, arrest at metaphase of Meiosis I and do not undergo nuclear division
PMID:10521402 FYPO:0000734 Fig3 B
PMID:10521402 FYPO:0004929 Fig3 B
PMID:10521402 PBO:0096550 Data not shown when rad1 is deleted checkpoint is not activated and cells attempt meiotic nuclear divisions see also Fig1, 2, 3B
PMID:10521402 GO:0072441 Fig 4
PMID:10521402 FYPO:0001733 Fig3B
PMID:10521402 PBO:0096552 Fig 2 A,B
PMID:10523629 PBO:0100802 Fig 5 C
PMID:10523629 PBO:0095532 Figure 1 a
PMID:10523629 PBO:0100801 Fig 5 J
PMID:10523629 PBO:0038186 fig 4
PMID:10523629 PBO:0095532 Figure 1 a
PMID:10523629 PBO:0100796 Figure 1 a
PMID:10523629 PBO:0095532 Figure 1 a
PMID:10523629 PBO:0095532 Figure 1 a
PMID:10523629 PBO:0100796 Figure 1 a
PMID:10523629 PBO:0095532 Figure 1 a
PMID:10523629 PBO:0095532 Figure 1 a
PMID:10523629 PBO:0093616 fig 4
PMID:10523629 PBO:0095532 Figure 1 a
PMID:10523629 PBO:0100796 Figure 1 a
PMID:10523629 PBO:0095532 Figure 1 a
PMID:10523629 PBO:0100798 fig 2a
PMID:10523629 PBO:0094734 fig 2a
PMID:10523629 PBO:0095532 Figure 1 a
PMID:10523629 PBO:0100799 fig 3 C
PMID:10523629 PBO:0100803 Fig 5 G
PMID:10523629 PBO:0095532 Figure 1 a
PMID:10523629 PBO:0100796 Figure 1 a
PMID:10526233 FYPO:0003166 (it basically the same as cut except the nucleus is not bisected)
PMID:10526233 FYPO:0003166 (it basically the same as cut except the nucleus is not bisected)
PMID:10545452 FYPO:0001234 The drc1-191 rng2-D5 and drc1-191 cdc4-8 double mutants grew extremely poorly a
PMID:10545452 FYPO:0001368 i.e next round of replication
PMID:10545452 PBO:0109008 Interestingly, unlike the drc1-191 mutant, drc1::ura4 underwent multiple nuclear division cycles causing arrested cells to accumulate up to 32 nuclei.
PMID:10545452 FYPO:0004691 Germinated drc1::ura4 spores were capable of po- larity establishment (shown with arrows in Figure 6C), but appeared to be incapable of polarity maintenance, causing them to become spherical and highly enlarged (Figure 6C).
PMID:10545452 FYPO:0001495 The drc1-191 rng2-D5 and drc1-191 cdc4-8 double mutants grew extremely poorly and showed cyto- kinesis defects at 24, a temperature at which rng2-D5 and cdc4-8 single mutants grew healthily and resembled wild-type cells in morphology (Figure 7).
PMID:10545452 PBO:0094638 Upon prolonged incubation at the restrictive temperature (Figure 2, 8 hr), cells assumed a variety of shapes and 20% of cells were found to contain four nuclei with actomyosin rings, whereas the rest of the cells (80%) still contained only two interphase nuclei and detectable
PMID:10545452 FYPO:0007541 The drc1-191 rng2-D5 and drc1-191 cdc4-8 double mutants grew extremely poorly and showed cyto- kinesis defects at 24, a temperature at which rng2-D5 and cdc4-8 single mutants grew healthily and resembled wild-type cells in morphology (Figure 7). In both double mutant combinations (drc1-191 cdc4-8 and drc1-191 rng2- D5) highly elongated cells with multiple nuclei were seen frequently.
PMID:10545452 PBO:0094639 Upon prolonged incubation at the restrictive temperature (Figure 2, 8 hr), cells assumed a variety of shapes and 20% of cells were found to contain four nuclei with actomyosin rings, whereas the rest of the cells (80%) still contained only two interphase nuclei and detectable
PMID:10545452 PBO:0094640 Upon prolonged incubation at the restrictive temperature (Figure 2, 8 hr), cells assumed a variety of shapes and 20% of cells were found to contain four nuclei with actomyosin rings, whereas the rest of the cells (80%) still contained only two interphase nuclei and detectable
PMID:10545452 PBO:0094641 Upon prolonged incubation at the restrictive temperature (Figure 2, 8 hr), cells assumed a variety of shapes and 20% of cells were found to contain four nuclei with actomyosin rings, whereas the rest of the cells (80%) still contained only two interphase nuclei and detectable
PMID:10545452 FYPO:0004629 i.e next round of replication
PMID:10545452 FYPO:0002060 The drc1-191 mutation was found to be recessive, since cells of the genotype drc1/drc1- 191 resembled wild-type cells and were capable of colony formation under conditions in which the drc1-191 mu- tant was unable to form colonies (data not shown).
PMID:10545452 FYPO:0002061 The drc1-191 mutation was found to be recessive, since cells of the genotype drc1/drc1- 191 resembled wild-type cells and were capable of colony formation under conditions in which the drc1-191 mu- tant was unable to form colonies (data not shown).
PMID:10545452 FYPO:0003931 Figure 1, 4 hr
PMID:10545452 FYPO:0001006 Figure 1, 8 hr
PMID:10545452 FYPO:0003710 Figure 1, 0 hr
PMID:10545452 PBO:0109007 At the drc1-191 arrest point all binucleate cells were found to have Cdc7p staining localized at one SPB. Merged images of chromosomal staining with DAPI and Cdc7p staining with HA antibodies is shown in Figure 4. The drc1-191 mutant, therefore, arrests at a point in the cell cycle where the septum-promoting Cdc7p is located on one SPB.
PMID:10545452 FYPO:0000579 capable of germination and establishing polarized growth, but were incapable of performing cytokinesis and did not maintain polarity (Figure 6B).
PMID:10545452 FYPO:0000026 capable of germination and establishing polarized growth, but were incapable of performing cytokinesis and did not maintain polarity (Figure 6B).
PMID:10545452 PBO:0094637 Microtubule staining confirmed that the drc1-191 cells were arrested in interphase since cells blocked predominantly either with interphase arrays of microtubules or with a postana- phase array of microtubules (Figure 3A, 4 hr).
PMID:10545452 FYPO:0001234 The drc1-191 rng2-D5 and drc1-191 cdc4-8 double mutants grew extremely poorly a
PMID:10545452 FYPO:0000272 capable of germination and establishing polarized growth, but were incapable of performing cytokinesis and did not maintain polarity (Figure 6B).
PMID:10545452 FYPO:0002061 The drc1-191 myo2-E1 double mutant was unable to form colonies at 24, a temperature at which both parental strains were capable of colony formation (data not shown).
PMID:10545452 FYPO:0002061 The drc1-191 myo2-E1 double mutant was unable to form colonies at 24, a temperature at which both parental strains were capable of colony formation (data not shown).
PMID:10547441 FYPO:0003889 this should be decreased thickness at old end during veg growth
PMID:10567589 FYPO:0001929 3c
PMID:10567589 FYPO:0001122 The profile of pmt3 cells showed a decrease of the number of cells with 2C DNA content and an increase in the number of cells with a DNA content greater or less than 2C DNA content (at times 2 and 0 h in Fig. 3C)
PMID:10567589 FYPO:0003241 The profile of pmt3 cells showed a decrease of the number of cells with 2C DNA content and an increase in the number of cells with a DNA content greater or less than 2C DNA content (at times 2 and 0 h in Fig. 3C)
PMID:10567589 PBO:0096816 fig2d - number 7 and 8
PMID:10567589 PBO:0093769 fig2d - number 7 and 8
PMID:10574765 PBO:0096824 Figure 3 normal at non-growing end
PMID:10574765 PBO:0096824 Figure 3 normal at non-growing end
PMID:10574765 PBO:0096817 Figure 2b Boundary of non growing cell end maintained
PMID:10574765 PBO:0096819 Figure 3 F actin is absent from non growing end
PMID:10574765 PBO:0096818 Figure 2c Boundary of the non growing cell end not maintained
PMID:10574765 PBO:0096820 Figure 4 Ral3/cor-CGFP fusion is expressed from pMral3/cor-C
PMID:10574765 PBO:0096821 Figure 4 Ral3/cor-CGFP fusion is expressed from pMral3/cor-C
PMID:10574765 PBO:0109946 "vw: jacky suggested ""protein localisation to the lateral plasma membrane""but will keep as parent Figures 1, S1 and S2. Cor-C GFP is probably episomal but it is not clear"
PMID:10574765 PBO:0096822 Figure 4 Ral3/cor-CGFP fusion is expressed from pMral3/cor-C
PMID:10574765 PBO:0096817 Figure 2a Boundary of non growing cell end maintained
PMID:10581266 FYPO:0002061 fig9 high overexpression is lethal
PMID:10581266 FYPO:0001493 fig9
PMID:10581266 FYPO:0002729 fig6
PMID:10581266 FYPO:0002025 fig6
PMID:10581266 FYPO:0002177 fig6
PMID:10581266 FYPO:0003439 fig4
PMID:10588638 FYPO:0004372 inferred from Chk1 phosphorylation phenotypes
PMID:10588653 FYPO:0002060 Fig3 synthetic rescue of cdc3
PMID:10588653 PBO:0097633 Figure 8 The most striking difference between wild-type Arp2p and Arp2-E316K was the failure to coimmunoprecipitate labeled Arp3p with Arp2-E316K
PMID:10588653 FYPO:0001324 8B & C These results clearly establish that the mutant Arp2-E316K protein turns over more rapidly than wild-type Arp2 protein
PMID:10588653 PBO:0097632 (Figure 8A). Arp2-E316K mutant protein had a reduced affinity for ATP compared with wild type Arp2p
PMID:10588653 PBO:0097632 (Figure 8A). T12A protein was also labeled by the ATP analogue, but to a much lesser degree than wild-type Arp2p
PMID:10588653 GO:0005524 Fig 8 A After UV irradiation, we found that both wild-type Arp2p and Arp3p were labeled by 8-azido-[a-32P]ATP, indicating that these actin-related proteins bind ATP as predicted
PMID:10588653 GO:0005524 Fig 8 A After UV irradiation, we found that both wild-type Arp2p and Arp3p were labeled by 8-azido-[a-32P]ATP, indicating that these actin-related proteins bind ATP as predicted
PMID:10588653 PBO:0097631 figure (Figure 6D)
PMID:10588653 PBO:0097630 figure (Figure 6)
PMID:10588653 GO:0005885 Fig6
PMID:10588653 GO:0005885 Fig6
PMID:10588653 FYPO:0001324 figure suggesting that the mutant protein is likely less stable than the wild-type Arp2 protein (Figure 6B), a hypothesis confirmed below (see Figure 8C).
PMID:10588653 GO:0005885 Fig6
PMID:10588653 GO:0005885 Fig6
PMID:10588653 GO:0005885 Fig6
PMID:10588653 FYPO:0006116 figure 4 In arp2-1 mutant cells grown at the restrictive temperature, the protein was not detected in patches. Rather, it appeared to be diffusely distributed throughout the cytoplasm (Figure 4C).
PMID:10588653 PBO:0097629 figure4
PMID:10588653 PBO:0018339 figure4
PMID:10588653 GO:0030479 figure4
PMID:10588653 FYPO:0002061 Fig3
PMID:10588653 FYPO:0002061 Fig3
PMID:10588653 FYPO:0002061 DNS In all tetrads, the viable colonies were Arp21 Ura2, indicating that arp21 is an essential gen
PMID:10588653 PBO:0095676 figure 1c
PMID:10588653 PBO:0035605 figure 1, after 8 hours, medial region of the cells continued to accumulate excess cell wall material
PMID:10588653 FYPO:0000650 figure 1, after 5 hours
PMID:10588653 PBO:0035615 DNS after 5 hours
PMID:10588653 FYPO:0001367 DNS
PMID:10588653 FYPO:0001357 DNS
PMID:10591634 PBO:0101467 IPI and IMP evidence
PMID:10593886 GO:0004674 only in vitro data evidence
PMID:10641037 FYPO:0007912 figure 3b
PMID:10641037 FYPO:0002060 DNS
PMID:10641037 FYPO:0002060 figure 2
PMID:10651902 PBO:0105063 Rho1 appears to have a dual role in stabilizing and localizing Pck proteins
PMID:10651902 PBO:0105062 appeared thicker
PMID:10651902 PBO:0099872 fig6
PMID:10651902 GO:0005515 Rho1 GTP bound form pck2 HR1 domain
PMID:10651902 FYPO:0004104 normal volume?
PMID:10651902 PBO:0019176 fig6
PMID:10683155 FYPO:0000229 cut if exposed to radiation during S phase, but not if exposed during G2
PMID:10683155 GO:0000785 constant level throughout cell cycle
PMID:10698951 FYPO:0002060 temperature restrictive for cdc27-P11 alone
PMID:10698951 FYPO:0002061 temperature restrictive for cdc27-P11 alone
PMID:10712506 PBO:0104977 from materials and methods
PMID:10712506 PBO:0095855 from materials and methods
PMID:10712506 PBO:0104977 from materials and methods
PMID:10712506 FYPO:0001719 from materials and methods
PMID:10718196 FYPO:0000337 DNS
PMID:10725227 PBO:0107283 Fig6 total protein translation not affected
PMID:10725227 PBO:0107277 Fig 1B there is a small G1 peak which get slightly bigger but they also cells arrested in G1 by -N, when refed and shifted to the restrictive temp cannot enter S phase but this is data not shown
PMID:10725227 PBO:0097954 Fig 1B
PMID:10725227 PBO:0097954 Fig 1B G1 arrest of ded1-1D5 is dependent on rum1+
PMID:10725227 FYPO:0002060 Table 2
PMID:10725227 FYPO:0002060 Table 2
PMID:10725227 FYPO:0002060 Table 2
PMID:10725227 PBO:0107289 Fig9
PMID:10725227 PBO:0107288 Fig10B
PMID:10725227 PBO:0107287 Fig10A
PMID:10725227 PBO:0107286 Fig9
PMID:10725227 PBO:0107285 Fig8. The labelling looks wrong in this figure, not sure whether to annotate it or not
PMID:10725227 PBO:0107285 Fig8. The labelling looks wrong in this figure, not sure whether to annotate it or not
PMID:10725227 FYPO:0001355 Fig7 B over expression of cig2+ cDNAI partially suppresses the rescue of cdc21-M68 by ded1-1D5
PMID:10725227 FYPO:0002061 Fig7 B over expression of cig2+ cDNAII suppresses the rescue of cdc21-M68 by ded1-1D5
PMID:10725227 FYPO:0002061 Fig7 B over expression of cig2+ cDNAIII suppresses the rescue of cdc21-M68 by ded1-1D5
PMID:10725227 PBO:0107284 Fig7C, D The protein and mRNA levels are compared to cDNA-I which is also expressed from medium strength nmt1 promoter ON
PMID:10725227 FYPO:0002060 Fig2B
PMID:10725227 PBO:0107282 Fig6 total protein translation not affect
PMID:10725227 PBO:0107281 Fig 5B 35S Methionine pulse, measured incorporation
PMID:10725227 PBO:0105174 Fig 5B 35S Methionine pulse, measured incorporation
PMID:10725227 PBO:0107280 Fig 5A 35S Methionine pulse measured incorporation
PMID:10725227 GO:0005737 Fig4B
PMID:10725227 PBO:0107279 Fig3B cdc13 protein presence in nuc2-663 alone
PMID:10725227 PBO:0107278 Fig3B cig2 protein presence in nuc2-663 alone
PMID:10725227 PBO:0107279 Fig3A
PMID:10725227 PBO:0107278 Fig3A
PMID:10725227 FYPO:0002060 Fig2D the semi permissive temperature 34.5C for ded1-D5 allows it to suppress cdc19-P1 (mcm2)
PMID:10725227 FYPO:0002060 Fig2B
PMID:10725227 FYPO:0002060 Fig2B
PMID:10725227 FYPO:0002060 Fig2B
PMID:10725227 FYPO:0002061 Fig2C ded1-78 is a cold sensitive mutant
PMID:10725227 FYPO:0002061 Fig2C ded1-61 is a cold sensitive mutant
PMID:10733588 FYPO:0001420 Fig. 3D and data not shown
PMID:10733588 FYPO:0001840 Table2
PMID:10733588 FYPO:0001840 Table2
PMID:10748059 GO:0044750 inhibited_by(CHEBI:48828)
PMID:10749926 FYPO:0000228 figure 4
PMID:10749926 PBO:0106371 Fig 6
PMID:10749926 FYPO:0002061 figure 1B
PMID:10749926 FYPO:0000229 figure 4 (spindle is still present, normally disaaembld by cytokinesis)
PMID:10749926 FYPO:0000620 figure 1B
PMID:10749926 PBO:0106370 Fig 6
PMID:10757807 PBO:0093580 same as cds1delta alone
PMID:10757807 PBO:0093580 same as rqh1delta alone
PMID:10757807 PBO:0093580 same as cdc27-P11 alone
PMID:10766248 PBO:0095955 severity correlates positively with overexpression level, and different isolates with same construct integrated show different Cdc18 levels
PMID:10766248 PBO:0095955 cdc18+ low level overexpression
PMID:10766248 PBO:0095955 severity correlates positively with overexpression level
PMID:10769212 FYPO:0002061 inviable at 34 or 37 degrees
PMID:10769212 FYPO:0002060 temperature restrictive for cdc4-8 alone
PMID:10769212 FYPO:0004652 temperature restrictive for cdc4-8 alone
PMID:10769212 PBO:0094469 temperature restrictive for cdc4-8 alone
PMID:10769212 FYPO:0002061 inviable at 37 degrees; some growth at 34 degrees
PMID:10769212 GO:0110085 dependent on F-actin (assayed using Latrunculin A)
PMID:10769212 PBO:0023726 early mitosis; independent of F-actin (assayed using Latrunculin A)
PMID:10769212 FYPO:0003389 temperature restrictive for cdc4-8 alone
PMID:10769212 FYPO:0002061 inviable at 37 degrees; some growth at 34 degrees
PMID:10770926 GO:0003697 activated by ATP
PMID:10770926 GO:0003697 activated by ATP
PMID:10770926 GO:0003697 activated by ATP
PMID:10775265 PBO:0097839 Figure4;TableI;datanotshown
PMID:10775265 PBO:0097839 Figure4;TableI;datanotshown
PMID:10775265 PBO:0097839 Figure4;TableI;datanotshown
PMID:10775265 PBO:0097839 Figure4;TableI;datanotshown
PMID:10775265 PBO:0095730 Figure4;TableI;datanotshown
PMID:10775265 PBO:0095731 Cdc7p cannot localize to the SPB(s) in cdc11 (Figure 4; Table I)
PMID:10775265 PBO:0097834 I inferred new because it's asymmetric and we know sin is new
PMID:10775265 PBO:0097839 Figure4;TableI;datanotshown
PMID:10775265 FYPO:0005055 After shift to restrictive temperature, cdc16-116 cells display two phenotypes termed type I and type II cells (Minet et al., 1979; Cerutti and Simanis, 1999). Type I cells have two nuclei and make multiple septa. Type II cells have a single nucleus and a septa. It has been proposed that the type II cells immediately septate again after division because they inherit the SPB that contains active Spg1p (Cerutti and Simanis, 1999). In support of this hypothesis, Sid1p was present at the SPB in type II cells (Figure 3A; see arrow).
PMID:10775265 FYPO:0003501 After shift to restrictive temperature, cdc16-116 cells display two phenotypes termed type I and type II cells (Minet et al., 1979; Cerutti and Simanis, 1999). Type I cells have two nuclei and make multiple septa. Type II cells have a single nucleus and a septa. It has been proposed that the type II cells immediately septate again after division because they inherit the SPB that contains active Spg1p (Cerutti and Simanis, 1999). In support of this hypothesis, Sid1p was present at the SPB in type II cells (Figure 3A; see arrow).
PMID:10775265 PBO:0097835 fig 3c
PMID:10775265 PBO:0097836 fig 3d
PMID:10775265 PBO:0095730 Figure4;TableI;datanotshown
PMID:10775265 PBO:0095730 Figure4;TableI;datanotshown
PMID:10775265 FYPO:0001493 dns
PMID:10775265 PBO:0095730 Figure4;TableI;datanotshown
PMID:10775265 PBO:0095730 Figure4;TableI;datanotshown
PMID:10775265 PBO:0097834 I inferred new because it's asymmetric and we know sin is new
PMID:10775265 PBO:0095730 Figure4;TableI;datanotshown
PMID:10775265 PBO:0021078 I inferred new because it's asymmetric and we know sin is new
PMID:10775265 PBO:0097843 Afterashifttorestrictivetemperaturefor50min to inactivate Cdc2p, cells could now be observed that were septating without undergoing anaphase (Figure 7E and F, see arrows). At this point, 96% (68/71) of cells displaying Sid1p signal at the SPB were septating without having undergone anaphase (Figure 7E and F, see arrows
PMID:10775265 PBO:0095730 GFP±Sid1p signal was not observed at SPBs in these cells although faint nuclear signal was observed (Figure 7A). This suggests that some aspect of completion of mitosis is required in order for Sid1p to localize.
PMID:10779336 FYPO:0001689 3B
PMID:10779336 FYPO:0000095 3B
PMID:10779336 FYPO:0001490 1A increased size?
PMID:10779336 FYPO:0002061 fig8
PMID:10779336 FYPO:0000089 3B
PMID:10779336 FYPO:0000089 3B
PMID:10779336 FYPO:0000141 2
PMID:10779336 FYPO:0000620 2B
PMID:10779336 FYPO:0000268 3A
PMID:10779336 FYPO:0002553 3B
PMID:10779336 FYPO:0000158 1B
PMID:10779336 FYPO:0001387 1A
PMID:10779336 FYPO:0003165 2B
PMID:10779336 FYPO:0002060 2B
PMID:10779336 FYPO:0000141 2B
PMID:10779336 FYPO:0001128 5.6%
PMID:10779336 FYPO:0002092 4C
PMID:10792724 GO:0004185 residue=S200
PMID:10799520 PBO:0104247 As expected, most sid3–106 mutant cells (71%) contained four or more nuclei showing that there was insufficient Spg1 function in these cells for septation.
PMID:10799520 PBO:0023023 Cdc7-HA was not localized to SPBs during interphase (Fig. 1C, 1),, localized to both SPBs in metaphase and early anaphase cells (Fig. 1C, 2 and 3), and localized to one SPB in late mitotic cells (Fig. 1C, 4 – 6) (8).
PMID:10799520 PBO:0022584 Cdc7-HA was not localized to SPBs during interphase (Fig. 1C, 1),
PMID:10799520 PBO:0018634 Spg1-HAH localized to SPBs throughout the cell cycle (Fig. 1B, second column) (8). Byr4 colocalized with Spg1-HAH during interphase (Fig. 1B, 1), but was absent from SPBs in metaphase (Fig. 1B, 2) and early anaphase
PMID:10799520 PBO:0019671 Later in anaphase, Byr4 colocalized with one SPB (Fig. 1B, 4). Byr4 colocalized with one or both SPBs in binucleate cells with septa (Fig. 1B, 5 and 6). In the vast majority of cells, Byr4 localized to SPBs that did not contain Cdc7 (Fig. 1C, 1, 4, and 5).
PMID:10799520 PBO:0104241 is this the right term?
PMID:10799520 FYPO:0001222 combine, other binucleates should unde new term
PMID:10799520 PBO:0104243 This analysis of microtubule structures confirmed that mononucleate cells with Cdc7 local- ized to SPBs were in interphase and suggested that Byr4 was required to prevent septation during interphase.
PMID:10799520 PBO:0104244 Figure 2E. These results show that Byr4 is re- quired to prevent septation in G1 cells.
PMID:10799520 PBO:0104249 Western analysis showed that this decrease was not due to reduced Byr4 amounts
PMID:10799520 PBO:0104248 Examination of these cells following 12 h of growth in thiamine-containing medium also showed that most cells (59%) contained Byr4 at all SPBs (Table II). In contrast to sid3–106 mutants, though, the amount of Byr4 localized to SPBs in cells depleted of Spg1 using the conditional promoter was greatly reduced (data not shown)
PMID:10799520 PBO:0104249 Western analysis showed that the reduction in Byr4 localization to SPBs in cells depleted of Spg1 was not due to reduced Byr4 protein amounts (data not shown).
PMID:10799520 PBO:0104248 Examination of these cells following 12 h of growth in thiamine-containing medium also showed that most cells (59%) contained Byr4 at all SPBs (Table II). In contrast to sid3–106 mutants, though, the amount of Byr4 localized to SPBs in cells depleted of Spg1 using the conditional promoter was greatly reduced (data not shown)
PMID:10799520 PBO:0104245 A corresponding decrease in the fraction of cells with Spg1 localized to SPBs occurred and reached 7% at 16 h (Fig. 3)
PMID:10805744 PBO:0094458 not sown it is ser/thr kinase activity
PMID:10805744 PBO:0093825 same as cdc2delta alone
PMID:10805785 PBO:0095723 fig 1c
PMID:10805785 PBO:0095723 fig 1c
PMID:10805785 PBO:0095723 fig 1c
PMID:10805785 PBO:0095723 fig 1c
PMID:10805785 PBO:0095723 fig 1c
PMID:10805785 PBO:0095723 fig 1c
PMID:10805785 PBO:0094918 fig2
PMID:10805785 PBO:0095723 fig 1c
PMID:10805785 PBO:0095723 fig 1c
PMID:10850973 GO:0008441 activated_by(CHEBI:18420)| activated_by(CHEBI:29103)| inhibited_by(CHEBI:48607)| inhibited_by(CHEBI:26710)
PMID:10852821 PBO:0094467 fig 7A (depends on actin)
PMID:10852821 FYPO:0000161 Fig. 3B
PMID:10852821 PBO:0094466 fig 7A
PMID:10852821 PBO:0094468 fig8 myo2 clumped in nodes instead of ring
PMID:10852821 FYPO:0007127 fig9
PMID:10852821 PBO:0094464 Fig 6
PMID:10852821 PBO:0094465 Fig 6
PMID:10852821 PBO:0094464 Fig 6
PMID:10852821 PBO:0094464 Fig 6
PMID:10852821 PBO:0094465 Fig 6
PMID:10852821 PBO:0094469 fig8
PMID:10852821 FYPO:0001368 fig8
PMID:10852821 FYPO:0001368 fig8
PMID:10852821 PBO:0094468 fig8 myo2 clumped in nodes instead of ring
PMID:10852821 PBO:0094469 fig8
PMID:10852821 FYPO:0000161 Fig. 3B
PMID:10852821 FYPO:0002050 Fig. 3B
PMID:10852821 FYPO:0002050 Fig. 3B
PMID:10852821 FYPO:0004736 fig9 maintenance
PMID:10852821 PBO:0094464 Fig 6
PMID:10864871 FYPO:0000284 2nd division
PMID:10871341 FYPO:0000474 diploid; ran1 allele pat1-114 in background
PMID:10871341 FYPO:0002044 diploid; ran1 allele pat1-114 in background
PMID:10871341 FYPO:0002044 diploid; ran1 allele pat1-114 in background
PMID:10871341 PBO:0095590 diploid; ran1 allele pat1-114 in background
PMID:10879493 FYPO:0000081 2M glucose = 36% w/v = A LOT, so it is osmolarity rather than glucose itself I guess
PMID:10879493 FYPO:0000081 2M glucose = 36% w/v = A LOT, so it is osmolarity rather than glucose itself I guess
PMID:10886372 FYPO:0002059 don't know veg or spore
PMID:10905343 PBO:0098815 total alpha tubulin level reduced but not known whether from nda3 or atb2 or both
PMID:10905343 PBO:0098816 total alpha tubulin level reduced but not known whether from nda2 or atb2 or both
PMID:10921876 PBO:0105405 fig3 cdc25-22 block and release
PMID:10921876 PBO:0105404 fig3 cdc25-22 block and release
PMID:10921876 PBO:0105404 fig 3 cdc25-22 block and release
PMID:10921876 PBO:0105405 fig 3 cdc25-22 block and release
PMID:10921876 FYPO:0001425 fig1 b
PMID:10921876 PBO:0100981 fig1a
PMID:10921876 PBO:0105409 fig1a
PMID:10921876 GO:1905785 APC-SLP1
PMID:10921876 PBO:0096939 fig3 cdc25-22 block and release
PMID:10921876 PBO:0105406 fig3 cdc25-22 block and release
PMID:10921876 PBO:0105402 APC-Ste9 dependent protein destruction/11365/) I didn't do a phenotype for this becase they don't whow a WT scanario.I used the ubiquitin-dependent term becasuethis is whet they were testing as we already know that this decgradation is APC/protiesome dependnet. I know its a bit of a stretch...
PMID:10921876 PBO:0105403 APC-Ste9 dependent protein destruction/11365/) I didn't do a phenotype for this becase they don't whow a WT scanario.I used the ubiquitin-dependent term becasuethis is whet they were testing as we already know that this decgradation is APC/protiesome dependnet. I know its a bit of a stretch...
PMID:10921878 PBO:0103561 during mitotic G2 arrest
PMID:10930468 PBO:0109148 DNES1-mid1p had a clear defect in nuclear export– in contrast to wild-type mid1p, which exits the nucleus during mitosis, it remained in the nucleus throughout the cell cycle, although some faint rings were occasionally seen (Figure 6, A-B).
PMID:10930468 FYPO:0001234 and the generation time of the population was increased approximately two-fold (Figure 1C top).
PMID:10930468 PBO:0104479 Cells carrying pREP41Xmid1 exhibited a striking phenotype: they formed bulges near the cell center (Figure 1B). Medial bulges were exhibited in 40% of the cells 20 h after removal of thiamine (Figure 1C middle). Cells were longer than normal, suggestive of a cell cycle delay in interphase (Figure 1B)
PMID:10930468 PBO:0104483 inferred from Nuclear export of mid1p was sensitive to leptomycin B (LMB), a drug that blocks the nuclear export factor crm1p (see Figure 8; Nishi et al., 1994; Kudo et al.; 1999), showing that the nuclear export of mid1p is crm1 dependent.
PMID:10930468 PBO:0104484 no NLS*-mid1p was detectable in the nucleus when expressed under the control of mid1 promoter (
PMID:10930468 FYPO:0008074 noNLS*-mid1p was detectable in the nucleus when expressed under the control of mid1 promoter (
PMID:10930468 PBO:0104485 localized in an identical manner to wild-type mid1p (Figure 9A) and was fully functional (Figure 7 and Table 2).
PMID:10930468 PBO:0104486 DNES1-mid1p had a clear defect in nuclear export– in contrast to wild-type mid1p, which exits the nucleus during mitosis, it remained in the nucleus throughout the cell cycle, although some faint rings were occasionally seen (Figure 6, A-B).
PMID:10930468 PBO:0104487 diffuse cytoplsmic throughout the cell cycle
PMID:10930468 FYPO:0006638 diffuse cytoplsmic throughout the cell cycle
PMID:10930468 PBO:0104482 DNES1-mid1p had a clear defect in nuclear export– in contrast to wild-type mid1p, which exits the nucleus during mitosis, it remained in the nucleus throughout the cell cycle, although some faint rings were occasionally seen (Figure 6, A-B).
PMID:10930468 PBO:0104481 DNES1-mid1p had a clear defect in nuclear export– in contrast to wild-type mid1p, which exits the nucleus during mitosis, it remained in the nucleus throughout the cell cycle, although some faint rings were occasionally seen (Figure 6, A-B).
PMID:10930468 PBO:0109150 DNES2-mid1p had a weaker, but demonstrable nuclear export defect: it retained some weak cortical staining and weak rings in addition to nuclear staining (Figure 6C), but
PMID:10930468 PBO:0104480 DNES2-mid1p had a weaker, but demonstrable nuclear export defect: it retained some weak cortical staining and weak rings in addition to nuclear staining (Figure 6C), but
PMID:10930468 PBO:0109149 DNES1-mid1p had a clear defect in nuclear export– in contrast to wild-type mid1p, which exits the nucleus during mitosis, it remained in the nucleus throughout the cell cycle, although some faint rings were occasionally seen (Figure 6, A-B).
PMID:10930468 FYPO:0002070 No defects in nuclear positioning were apparent, as nuclei were positioned properly at the middle of the cell or in the bulge region (see Figure 2). Mid1p localization in these
PMID:10947840 FYPO:0002060 We found, on the other hand, that the ts phenotype of mis3-224 was suppressed by dis2-11, a cs mutation with greatly reduced type 1 protein phosphatase (PP1) activity and the inability to exit from mitosis (Ohkura et al. 1989).
PMID:10947840 FYPO:0004481 they ceased to increase in number after two divisions (Fig. 1A, open triangles). The growth arrest phenotype of mis3-224 (Fig. 1C) was distinct from that of typical cdc mutants, as its cell length increase was insigni®cant (1.3-fold) after 8h at 36 8C. mis3-224 at 36 8C was unable to increase in cell length because the levels of protein and RNA ceased to increase (B, ®lled and open triangles, respectively).
PMID:10947840 FYPO:0007136 they ceased to increase in number after two divisions (Fig. 1A, open triangles). The growth arrest phenotype of mis3-224 (Fig. 1C) was distinct from that of typical cdc mutants, as its cell length increase was insigni®cant (1.3-fold) after 8h at 36 8C. mis3-224 at 36 8C was unable to increase in cell length because the levels of protein and RNA ceased to increase (B, ®lled and open triangles, respectively).
PMID:10947840 FYPO:0008218 These results showed that cells lacking functional Mis3 could not promote cell growth upon the release to complete medium and remained in the G1/S phase.
PMID:10947840 FYPO:0000088 it was moderately sensitive at 308C (Fig. 5A, top): mutant failed to produce colonies in the presence of 8 mM HU at 30 8C, a semi-restrictive temperature.
PMID:10947840 PBO:0112273 At 36 8C in mis3-224, the level of Mik1 increased to a peak after 4h, but then strikingly decreased to a low level (E).
PMID:10947840 PBO:0112789 At 36 8C in mis3-224, the level of Mik1 increased to a peak after 4h, but then strikingly decreased to a low level (E).
PMID:10947840 FYPO:0002061 Tetrad dissection indicated that the mis3-224 dsk1 null double mutant failed to grow at any temperature.
PMID:10947840 FYPO:0002061 Tetrad dissection indicated that the mis3-224 dsk1 null double mutant failed to grow at any temperature.
PMID:10947840 FYPO:0002061 In addition to the interaction between Mis3 and Wee1, it was found that the double mutants mis3 cdc25 and mis3 cdc13 were able to form colonies at 268C, but not at 308C (Fig. 6A).
PMID:10947840 FYPO:0002061 In addition to the interaction between Mis3 and Wee1, it was found that the double mutants mis3 cdc25 and mis3 cdc13 were able to form colonies at 268C, but not at 308C (Fig. 6A).
PMID:10947840 FYPO:0002061 In addition to the interaction between Mis3 and Wee1, it was found that the double mutants mis3 cdc25 and mis3 cdc13 were able to form colonies at 268C, but not at 308C (Fig. 6A).
PMID:10947840 FYPO:0002061 In addition to the interaction between Mis3 and Wee1, it was found that the double mutants mis3 cdc25 and mis3 cdc13 were able to form colonies at 268C, but not at 308C (Fig. 6A).
PMID:10947840 FYPO:0002060 We found, on the other hand, that the ts phenotype of mis3-224 was suppressed by dis2-11, a cs mutation with greatly reduced type 1 protein phosphatase (PP1) activity and the inability to exit from mitosis (Ohkura et al. 1989).
PMID:10950958 PBO:0095430 As shown in Fig. 9B, the GFP-Its3-1 mutant protein (GFP-mIts3) was no longer localized to the plasma membrane and instead...
PMID:10950958 GO:0032153 GFP-Its3 localized to the plasma membrane at all stages of the cell cycle (Fig. 9A).
PMID:10950958 GO:0005886 GFP-Its3 localized to the plasma membrane at all stages of the cell cycle (Fig. 9A).
PMID:10950958 FYPO:0000650 In addition, its3-1 mutant had a septation index approximately twice that seen in wild-type cells at the permissive temperature.
PMID:10950958 FYPO:0001406 Micro- scopic observation revealed that some mutant cells have a thick septum that was brightly stained with Calcofluor and was hardly seen in wild-type cells (Fig. 8A).
PMID:10950958 FYPO:0008042 On the other hand, in the its3-1 mutant cells, actin patches were partially polarized at 27 °C, and the polarization was completely lost upon temperature upshift or FK506 treatment (Fig. 7A).
PMID:10950958 FYPO:0000790 In wild-type cells, a shift from 27 to 33 °C caused a transient heat-induced disorganization of actin patches,
PMID:10950958 FYPO:0006626 NOT PM
PMID:10950958 FYPO:0000994 nterestingly, the level of PI(4)P was significantly higher than that of the wild-type cells.
PMID:10950958 FYPO:0006625 NOT PLASMA MEMBRANE As shown in Fig. 5B, its3-1 mutant cells contained about 10% of the amount of PI(4,5)P2 found in wild- type cells, indicating that the mutation caused a significant decrease in PI(4)P5K activity of Its3.
PMID:10950958 FYPO:0002061 Tetrad analysis of the heterozygous diploid showed two viable (Ura) and two inviable spores (Fig. 3D), indicating that the its3 gene is essential for cell growth.
PMID:10950958 FYPO:0002061 ppb1 (CN in Fig. 2) mutant. As expected, no double mutant was obtained, indicating that its3 mutation and calcineurin deletion was synthetically lethal.
PMID:10950958 FYPO:0002061 ppb1 (CN in Fig. 2) mutant. As expected, no double mutant was obtained, indicating that its3 mutation and calcineurin deletion was synthetically lethal.
PMID:10950958 PBO:0095429 Purified GST fusion pro- teins were subjected to in vitro kinase reaction as described under “Experimental Procedures.” Fig. 6 shows that mutant Its3 tagged with GST had detectable but reduced PI(4)5K ac- tivity compared with the wild-type.
PMID:10950958 PBO:0109009 PI(4)5K activity kinase: As shown in Fig. 1A, its3-1 mutant cells could not grow at 33 °C, 36 °C, or in the YPD plate containing FK506, whereas wild-type cells grew normally.
PMID:10950958 FYPO:0000086 As shown in Fig. 1A, its3-1 mutant cells could not grow at 33 °C, 36 °C, or in the YPD plate containing FK506, whereas wild-type cells grew normally.
PMID:10950958 FYPO:0002061 As shown in Fig. 1A, its3-1 mutant cells could not grow at 33 °C, 36 °C, or in the YPD plate containing FK506, whereas wild-type cells grew normally.
PMID:10954610 PBO:0099391 transcription run-on assay
PMID:10954610 PBO:0099392 steady-state labeling assay; stability increases in wt but not sty1delta upon UV exposure
PMID:10954610 PBO:0099392 steady-state labeling assay; stability increases in wt but not mutant upon UV exposure
PMID:10954610 PBO:0099391 transcription run-on assay
PMID:10970777 GO:0004081 there is another unknown gene with this activity
PMID:10970777 PBO:0096414 decreased
PMID:10978278 PBO:0097277 beta tubulin specific pathway
PMID:11007487 PBO:0098917 Fig 4
PMID:11007487 PBO:0098918 Fig 6 (live cell imaging) GFP-tubulin expressed from nmt1 promoter on multi copy plasmid
PMID:11007487 FYPO:0001399 data not shown
PMID:11007487 FYPO:0001018 Fig 1 B
PMID:11007487 PBO:0098921 (Figure 4I) I'm not sure if we knew it was the plus end then, but we do now ;)
PMID:11007487 PBO:0098922 (Figure 4I)
PMID:11007487 PBO:0037211 Figures 4C and 4G
PMID:11007487 PBO:0018345 Fig 4A & fig 3 G
PMID:11007487 PBO:0038056 Fig 3F (methanol fixation)
PMID:11007487 PBO:0098920 Fig 3 C
PMID:11007487 GO:0031122 """We conclude that tip1p is required for the correct organization of the microtubule cytoskeleton and for the proper localization of the tea1p marker to the cell ends"""
PMID:11007487 GO:0030010 """These phenotypes establish that tip1p is required to properly position the growth zones at the antipodes of the cells."""
PMID:11007487 FYPO:0000224 Fig 1 tip1 expressed from pREP3X
PMID:11007487 FYPO:0004700 Fig 1 tip1 expressed from pREP3X
PMID:11007487 FYPO:0000015 Fig 1 tip1 expressed from pREP3X
PMID:11007487 FYPO:0000014 Fig 1 tip1 expressed from pREP3X. I've used this term as it is the nearest to schmoozing which is the term they use in the paper. To be honest I think tapered is better as they don't know that the cells are shmooing
PMID:11007487 PBO:0038053 Fig 3B
PMID:11007487 PBO:0098915 Fig 3 H (methanol fixation)
PMID:11007487 FYPO:0005799 Fig 6 (live cell imaging) GFP-tubulin expressed from nmt1 promoter on multi copy plasmid
PMID:11007487 PBO:0098919 Fig 3 (methanol fixation)
PMID:11007487 PBO:0038059 Fig 4F However, tip1p was observed at the tips of the astral microtubules that ema- nated from the cytoplasmic face of the nuclear-located spindle pole body during anaphase and at the tips of the microtubules generated from the central region of postmitotic cells (Figures 4F).
PMID:11007487 FYPO:0001366 Fig 3I (Formaldehyde fixation)
PMID:11007487 PBO:0037218 Fig3I
PMID:11007487 PBO:0098915 Fig 3 K (methanol fixation)
PMID:11007487 PBO:0038055 Fig 3D
PMID:11007487 FYPO:0001400 Fig 3 K (methanol fixation)
PMID:11007487 PBO:0098916 ( data for these cells not shown)
PMID:11007487 GO:0008017 figure 4H in vitro
PMID:11014802 GO:0010515 maybe not shown strongly in this paper but I'm trying to get the git genes annotated to this term because pka1 phosphorylates rst2 which excludes rst2 from the nucleus. rst2 when in the nucleus activates ste11 transcription.
PMID:11014802 GO:0010515 maybe not shown strongly in this paper but I'm trying to get the git genes annotated to this term because pka1 phosphorylates rst2 which excludes rst2 from the nucleus. rst2 when in the nucleus activates ste11 transcription.
PMID:11017199 PBO:0099479 structure
PMID:11018050 FYPO:0002060 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media.
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media.
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 PBO:0037206 Fig 2B
PMID:11018050 FYPO:0002760 Fig 3
PMID:11018050 PBO:0098938 Fig 2D
PMID:11018050 FYPO:0005809 Data was not shown.
PMID:11018050 PBO:0037208 Fig 4
PMID:11018050 PBO:0037209 Fig 2
PMID:11018050 PBO:0095634 forms microcolonies
PMID:11018050 PBO:0037209 Fig 2G
PMID:11018050 PBO:0022298 Fig 5
PMID:11018050 PBO:0037211 Fig 5
PMID:11018050 PBO:0037212 Fig 6 cell tip localisation increased compared to exponentially growing cells
PMID:11018050 PBO:0098939 Fig 8 and Fig 5 Tea2 is not completely delocalised but is has a more extended distribution along the microtubules
PMID:11018050 PBO:0098940 Fig 8 (vw: I made this 'along micriotubule because we know its microtubule dept)
PMID:11018050 PBO:0018421 Fig 6
PMID:11018050 FYPO:0002060 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002060 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002060 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media.
PMID:11018050 PBO:0098941 fig 8 c
PMID:11018050 FYPO:0002060 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002060 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002060 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002060 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002060 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11018050 FYPO:0002058 growth assayed on agar plates at different temperature and media
PMID:11027257 FYPO:0002061 temp semi-permissive for spp2-8 alone
PMID:11027257 FYPO:0002061 temp semi-permissive for spp2-9 alone
PMID:11027257 FYPO:0002061 temp semi-permissive for spp2-9 alone
PMID:11027257 FYPO:0002061 temp semi-permissive for spp2-8 alone
PMID:11027257 FYPO:0002061 temp semi-permissive for spp2-8 alone
PMID:11027257 FYPO:0002061 temp semi-permissive for spp2-8 alone
PMID:11027257 FYPO:0002061 temp semi-permissive for spp2-8 alone
PMID:11027257 FYPO:0002061 temp semi-permissive for spp2-8 alone
PMID:11027257 FYPO:0002061 temp semi-permissive for spp2-9 alone
PMID:11027257 FYPO:0002061 temp semi-permissive for spp2-8 alone
PMID:11027257 FYPO:0002061 temp semi-permissive for spp2-9 alone
PMID:11027257 FYPO:0000062 higher temp, restrictive for spp2-8 alone
PMID:11027257 FYPO:0006822 higher temp, restrictive for spp2-9 alone
PMID:11027257 FYPO:0000062 higher temp, restrictive for spp2-9 alone
PMID:11027257 FYPO:0002061 temp semi-permissive for spp2-9 alone
PMID:11027257 FYPO:0002061 temp semi-permissive for spp2-9 alone
PMID:11027257 FYPO:0002061 higher temp, restrictive for spp2-9 alone
PMID:11027257 FYPO:0006822 higher temp, restrictive for spp2-8 alone
PMID:11027257 FYPO:0002061 higher temp, restrictive for spp2-8 alone
PMID:11027257 FYPO:0002060 temp semi-permissive for spp2-8 alone
PMID:11027257 FYPO:0002061 temp semi-permissive for spp2-8 alone
PMID:11027257 PBO:0023027 mixed population
PMID:11027257 PBO:0019630 mixed population
PMID:11027257 FYPO:0002061 temp semi-permissive for spp2-9 alone
PMID:11027257 FYPO:0002060 temp semi-permissive for spp2-9 alone
PMID:11027257 FYPO:0002061 temp semi-permissive for spp2-9 alone
PMID:11027263 FYPO:0004672 same as hsk1-1312 alone
PMID:11027263 FYPO:0001355 temp. restrictive for hsk1-1312 alone; fudged a bit because assayed at 32
PMID:11069657 FYPO:0000175 they form parts that fail to mature
PMID:11069779 FYPO:0002061 **SYNTHETIC LETHAL
PMID:11069779 FYPO:0001524 toxic aa-analog
PMID:11071923 FYPO:0007317 global translation, not a specific gene
PMID:11076964 GO:0030479 dependent on F-actin (assayed using Latrunculin A)
PMID:11080156 PBO:0033364 with cut at second division
PMID:11080156 FYPO:0004537 SAC- fypo/issues/2310
PMID:11080156 PBO:0033364 with cut
PMID:11080156 FYPO:0003165 after passage through G1
PMID:11084332 PBO:0102587 total protein in proteasome mutant
PMID:11084332 PBO:0102589 during G1 arrest fig4 C right hand panel
PMID:11084332 FYPO:0000833 total ubiquitinated
PMID:11084332 PBO:0102590 ubiquitinated
PMID:11084332 PBO:0097048 ubiquitinated
PMID:11084332 PBO:0102586 delayed during anaphase
PMID:11084332 PBO:0102587 total protein in proteasome mutant
PMID:11084332 PBO:0102585 during anaphase
PMID:11084332 PBO:0102588 during G1 arrest fig4 C right hand panel
PMID:11102508 PBO:0033981 WT 0.5%
PMID:11134033 PBO:0037397 figure 1 b (I)
PMID:11134033 PBO:0037400 indicated by decreased polysome to monosome ratio
PMID:11134033 GO:0005737 Fig. 2
PMID:11134033 PBO:0037399 figure 1 C
PMID:11134033 FYPO:0000337 figure 1 b
PMID:11134033 FYPO:0003302 figure 1 b
PMID:11134033 FYPO:0002946 figure 1 a
PMID:11134033 FYPO:0002060 (data not shown)
PMID:11134033 PBO:0096454 figure 1 b (I)
PMID:11160827 PBO:0092751 present throughout mitotic cell cycle
PMID:11179424 PBO:0103795 residue not determined experimentally, but probably Y173
PMID:11226171 FYPO:0005370 sequencing
PMID:11226171 FYPO:0000267 same sensitivity as rhp54delta alone
PMID:11226171 FYPO:0000267 same sensitivity as rhp54delta alone
PMID:11226171 FYPO:0005370 sequencing
PMID:11231017 FYPO:0001234 fig1
PMID:11231017 FYPO:0000106 fig1
PMID:11231572 GO:0030479 dependent on F-actin (assayed using Latrunculin A)
PMID:11231572 GO:0110085 dependent on F-actin (assayed using Latrunculin A)
PMID:11238401 GO:0010515 maybe not shown strongly in this paper but I'm trying to get the git genes annotated to this term because pka1 phosphorylates rst2 which excludes rst2 from the nucleus. rst2 when in the nucleus activates ste11 transcription.
PMID:11238401 GO:0010515 maybe not shown strongly in this paper but I'm trying to get the git genes annotated to this term because pka1 phosphorylates rst2 which excludes rst2 from the nucleus. rst2 when in the nucleus activates ste11 transcription.
PMID:11242054 FYPO:0007334 oss of association of Swi6 with centromeres should result in expression of a normally silent marker gene embedded in centro- meric chromatin. Figure 4e shows that this is indeed the case. On indicator plates, wild-type strains silence the centromeric ade6+ marker, which results in red, repressed colonies13; however, in strains lacking Clr4 (D) or strains defective in Clr4 methylase activity (G341D), this ade6+ gene is clearly expressed, resulting in the formation of white colonies.
PMID:11242054 PBO:0111582 The ®ssion yeast S. pombe has an HP1 homologue Swi6, which contains a chromo domain that is closely related to those of HP1 family members1. Figure 4a shows that the Swi6 chromo domain is able to bind H3 peptide methylated at Lys 9, whereas its chromo- shadow domain has no methyl-binding activity.
PMID:11242054 PBO:0111086 whereas the Clr4-G341D strain shows loss of localiza- tion from the nuclear periphery and accumulation of more diffuse staining over the nucleolus (Fig. 4c).
PMID:11242054 FYPO:0007334 oss of association of Swi6 with centromeres should result in expression of a normally silent marker gene embedded in centro- meric chromatin. Figure 4e shows that this is indeed the case. On indicator plates, wild-type strains silence the centromeric ade6+ marker, which results in red, repressed colonies13; however, in strains lacking Clr4 (D) or strains defective in Clr4 methylase activity (G341D), this ade6+ gene is clearly expressed, resulting in the formation of white colonies.
PMID:11248251 GO:0005759 These results further indicate that the C-terminal end of Cox15p, together with Yah1p, is located in the matrix com- partment. Yah1p fused to Cox15p is therefore in the same compartment as the native protein (Fig. 5B).
PMID:11248251 PBO:0110542 We propose that the two proteins are part of a mitochondrial (prokaryotic) type monooxygenase that hydroxylates the methyl group of heme O. Accordingly, the third component of this pathway is ferredoxin (adrenodoxin) dehydrogenase encoded by ARH1 which has been localized in mitochondria of S. cerevisiae [13]. As depicted in Fig. 3, the function of Cox15p would be analogous to that of P450 in other three component monooxygenases [14].
PMID:11248251 FYPO:0008143 The two exceptions were the cox10 and cox15 mutants, both of which lacked heme A. In agreement with earlier results the cox10 mutant also had no heme O [4].
PMID:11248251 FYPO:0008143 The two exceptions were the cox10 and cox15 mutants, both of which lacked heme A. In agreement with earlier results the cox10 mutant also had no heme O [4]. This was not true of the cox15 mutant which had a very low but detectable amount of heme O (Fig. 1).
PMID:11248251 FYPO:0008144 In agreement with earlier results the cox10 mutant also had no heme O [4]. This was not true of the cox15 mutant which had a very low but detectable amount of heme O (Fig. 1).
PMID:11248251 PBO:0110543 This was not true of the cox15 mutant which had a very low but detectable amount of heme O (Fig. 1).
PMID:11250892 GO:0072686 Figure 1 C
PMID:11250892 PBO:0108092 figure 3
PMID:11250892 PBO:0108091 Fig 1
PMID:11250892 PBO:0108093 fig 7
PMID:11252721 FYPO:0002061 facs and author comment about growth
PMID:11260263 FYPO:0000708 Fig 2 B
PMID:11260263 FYPO:0002061 0.75 M
PMID:11260263 PBO:0093595 0.75 M
PMID:11260263 FYPO:0002021 Fig 2 B
PMID:11263963 FYPO:0002459 Fig. 3A
PMID:11263963 FYPO:0001357 Fig. 3B and D
PMID:11263963 PBO:0112460 Fig. 4
PMID:11263963 PBO:0112460 Fig. 4
PMID:11263963 GO:0032956 This hypersensitivity to LatB of mutants of either Drkp1 or Dpck2 indicates that both Rkp1 and Pck2 are required for stable filamentous actin network.
PMID:11263963 GO:0032956 This hypersensitivity to LatB of mutants of either Drkp1 or Dpck2 indicates that both Rkp1 and Pck2 are required for stable filamentous actin network.
PMID:11263963 PBO:0112461 As shown in Fig. 5, growth of the cells expressing human RACK1 was not seriously affected by the presence of LatB indicating human RACK1 is a functional homolog of Rkp1.
PMID:11263963 FYPO:0001357 Fig. 3B and D
PMID:11263963 FYPO:0001355 Fig. 3B and D
PMID:11263963 GO:0005886 Fig. 1B
PMID:11263963 FYPO:0000961 Fig. 3D
PMID:11263963 FYPO:0001492 Fig. 3A
PMID:11263963 FYPO:0000961 Fig. 3D
PMID:11263963 PBO:0093596 Fig. 3D
PMID:11263963 PBO:0093596 Fig. 3D
PMID:11263963 PBO:0094278 Fig. 3D
PMID:11263963 PBO:0094279 Fig. 3D
PMID:11263963 PBO:0094276 Fig. 3D
PMID:11263963 PBO:0112429 Fig. 4
PMID:11263963 FYPO:0000648 Fig. 3A
PMID:11263963 FYPO:0002459 Fig. 3A
PMID:11271422 PBO:0097505 Fig. 2B
PMID:11271422 FYPO:0001315 Fig. 2B
PMID:11271422 PBO:0097505 Fig. 2B
PMID:11271422 PBO:0112775 Fig. 1A
PMID:11271422 FYPO:0005369 Fig. 3A
PMID:11271422 FYPO:0002060 Fig. 3A
PMID:11271422 FYPO:0002060 Fig. 3A
PMID:11271422 PBO:0112773 Fig. 1A
PMID:11271422 PBO:0104247 Fig. 1A
PMID:11271422 PBO:0097505 Fig. 2A
PMID:11271422 PBO:0112774 Microscopy revealed occasional cells with an aberrant septum or with multiple nuclei. Fig. 2A
PMID:11271422 PBO:0107432 Fig. 2A
PMID:11271422 PBO:0038207 Fig. 2A
PMID:11271422 FYPO:0002049 Fig. 2B
PMID:11279037 FYPO:0002061 taf73 does not substitute for taf5
PMID:11290708 GO:0005634 qualifier=predominantly
PMID:11294895 PBO:0100352 localization requires F-actin (assayed using latrunculin A)
PMID:11294895 PBO:0019716 localization requires F-actin (assayed using latrunculin A)
PMID:11294895 PBO:0018421 localization requires F-actin (assayed using latrunculin A)
PMID:11294907 PBO:0018972 dependent on actin cytoskeleton (assayed using Latrunculin A)
PMID:11294907 PBO:0095174 dependent on actin cytoskeleton (assayed using Latrunculin A)
PMID:11294907 PBO:0095173 dependent on actin cytoskeleton (assayed using Latrunculin A)
PMID:11294907 GO:0110085 dependent on actin cytoskeleton (assayed using Latrunculin A)
PMID:11313455 GO:0003682 chromatin fractionation assay; increased during response to DNA damage by MMS or ionizing radiation; dissociates during response to HU
PMID:11313455 GO:0003682 chromatin fractionation assay
PMID:11313455 GO:0003682 chromatin fractionation assay
PMID:11313465 PBO:0106865 Rad3 phosphorylates T11 in response to hydroxyurea treatment
PMID:11313465 PBO:0106866 cellular response to hydroxyurea
PMID:11313465 PBO:0106867 phosphorylates Cds1
PMID:11331883 PBO:0109722 table1 Interestingly, sister chromatids do not segregate randomly in the absence of Rec8 but rather segregate equationally10 (Table 1), implying that cohesion must be preserved between sister centromeres to give them a mitotic-like, back-to-back orientation
PMID:11331883 PBO:0098558 In contrast, Rec8 disappeared completely in Dbub1 anaphase I cells. Rec8 was not observed in any of the >100 late-anaphase cells examined and was obviously never detected in early MII cells
PMID:11331883 PBO:0098557 In contrast, Rec8 disappeared completely in Dbub1 anaphase I cells. Rec8 was not observed in any of the >100 late-anaphase cells examined and was obviously never detected in early MII cells
PMID:11331883 PBO:0109721 table1
PMID:11331883 GO:1990813 The most straightforward interpretation is that Bub1 is required to maintain sister-chromatid cohesion at anaphase I by preventing the removal of Rec8 from centromeric regions.
PMID:11331883 FYPO:0005648 Fig. 2c and Table 1),
PMID:11331883 PBO:0098556 Consistently, Rec8 localization was indistinguishable from wildtype from early meiosis and until metaphase I (Fig. 3). Rec8 first appeared in the centromeric regions of cells before conjugation (Fig. 3, G1 cells) and its distribution was further extended throughout chromatin during the horse-tail stage and until metaphase I. Therefore, Rec8 is properly localized and co-orientation still occurs in the absence of Bub1, indicating that the occurrence of equational segregation in Dbub1 cells may be due to a defect in functional fusion of sister kinetochores rather than to defective co-orientation of sister centromeres.
PMID:11331883 PBO:0109723 table1 Together, these results rule out the possibility that equational segregation in the absence of Bub1 is due to loss of sister-chromatid cohesion before attachment of kinetochores to microtubules.
PMID:11350031 PBO:0098377 all taf1 introns affected
PMID:11359920 FYPO:0001933 30 degrees
PMID:11359920 PBO:0032994 30 degrees
PMID:11359920 PBO:0032997 30 degrees
PMID:11359920 PBO:0032998 30 degrees
PMID:11359920 PBO:0097500 30 degrees
PMID:11359920 PBO:0032993 30 degrees
PMID:11359920 PBO:0094206 30 degrees
PMID:11359920 PBO:0097499 30 degrees
PMID:11359920 PBO:0097498 30 degrees
PMID:11359920 FYPO:0001430 30 degrees
PMID:11359928 PBO:0019203 fig 2 c
PMID:11359928 PBO:0106453 Figure 4A
PMID:11359928 PBO:0095312 fig 3a
PMID:11359928 PBO:0106452 fig 2 c
PMID:11359928 PBO:0019203 fig 8
PMID:11359928 PBO:0106454 Figure 4A
PMID:11369198 PBO:0036768 Figure 5b
PMID:11369198 PBO:0022298 movie 1A
PMID:11369198 PBO:0023853 fig 2B
PMID:11369198 PBO:0018845 fig 2 B
PMID:11369198 PBO:0097445 Figure 5b
PMID:11369198 FYPO:0004236 Figure 5b
PMID:11369198 FYPO:0002061 data not shown
PMID:11384993 PBO:0101549 a significant reduction in kinase activity (40% of Sid1)
PMID:11384993 PBO:0101548 barely above background for vector alone and Sid1C (Fig. 2B)
PMID:11387218 PBO:0095886 punctate in wild type, diffuse throughout nucleus in mutant
PMID:11387325 PBO:0111636 The key findings were that the S. pombe guany- lyltransferase bound equally well to the CTD Ser5-PO4 peptide and the Ser2-PO4/Ser5-PO4 peptide. Slightly less than one-fifth of the input protein was retained on the beads in both cases
PMID:11387325 PBO:0111613 To gauge the role of the non-reiterated protein segment, we constructed an AD-Rpb1(1516 –1752) fusion clone and tested it in a directed two-hybrid assay paired with BD-Pce1 and BD- Pct1. We found that the Rpb1 interaction with both capping enzymes persisted when the AD fusion contained little more than the CTD repeats per se.
PMID:11387325 PBO:0111635 The novel finding was that the recombinant S. pombe RNA triphosphatase by itself bound specifically to CTD peptides phosphorylated on Ser-5 and not to the unphosphorylated pep- tide or the Ser2-PO4 peptide (Fig. 3B).
PMID:11387325 PBO:0111636 The key findings were that the S. pombe guany- lyltransferase bound equally well to the CTD Ser5-PO4 peptide and the Ser2-PO4/Ser5-PO4 peptide. Slightly less than one-fifth of the input protein was retained on the beads in both cases
PMID:11387325 PBO:0111612 To gauge the role of the non-reiterated protein segment, we constructed an AD-Rpb1(1516 –1752) fusion clone and tested it in a directed two-hybrid assay paired with BD-Pce1 and BD- Pct1. We found that the Rpb1 interaction with both capping enzymes persisted when the AD fusion contained little more than the CTD repeats per se.
PMID:11405625 PBO:0019133 high penetrance = large fraction of cells
PMID:11414703 FYPO:0002059 One of the diploid clones (C1) was allowed to sporulate and ;100 of the haploids obtained were tested for resistance to G418. We found no resis- tants, which implicates that spSNW1 is an essential gene in S. pombe.
PMID:11432827 FYPO:0000324 3f
PMID:11432827 FYPO:0003165 Fig 3B
PMID:11432827 FYPO:0002061 Figure 3A, rapid loss of viability
PMID:11432827 FYPO:0002061 Table 1
PMID:11432827 FYPO:0000276 Figure 1 C
PMID:11432827 FYPO:0001734 Figure 1 C
PMID:11432827 FYPO:0006196 Figure 1 C
PMID:11432827 FYPO:0004317 1A
PMID:11432827 FYPO:0001491 2C
PMID:11432827 FYPO:0000141 Figure 1 A
PMID:11432827 FYPO:0002638 ind mad2 mutant loses viability
PMID:11432827 PBO:0093562 figure 4A
PMID:11432827 FYPO:0001574 Figure 1 A
PMID:11432827 PBO:0033178 figure 4B
PMID:11432827 GO:0000940 dependent on mitotic spindle (GO:0072686)
PMID:11432827 FYPO:0004318 Question could be required for, or upstream spindle checkpoint, but it could cause a problem which preceds the point where it is possible to activate the checkpoint?BUT...alp14 and mad2 in same pathway and overexpression of mad2 cannot resuce defect of double/single mutant
PMID:11432827 FYPO:0000416 cut2 levels were reduced in alp14 mutant
PMID:11432827 FYPO:0002060 2C
PMID:11432827 FYPO:0000131 1A
PMID:11448769 PBO:0019801 (vw: sid2 phenotype indicates that Clp1 localization is independent of SIN)
PMID:11460168 PBO:0112764 Fig. 4B
PMID:11460168 PBO:0112425 Fig. 2B
PMID:11460168 PBO:0112762 Fig. 3B
PMID:11460168 PBO:0112426 Fig. 2C
PMID:11460168 PBO:0112762 Fig. 3B
PMID:11460168 PBO:0112427 We found that a rad21-45 mutant was unable to arrest in the presence of Lat B. Fig. 2B and C
PMID:11460168 FYPO:0009019 Fig. 2D
PMID:11460168 FYPO:0000620 Cells that lack Mad2 arrest in metaphase in the presence of Lat B (Fig. 3a)
PMID:11460168 PBO:0112763 Fig. 3B
PMID:11460168 FYPO:0006660 Fig. 4E
PMID:11460168 PBO:0112429 Fig. 4A
PMID:11460168 FYPO:0001357 Fig. 4A
PMID:11460168 FYPO:0009019 Fig. 4D
PMID:11460168 PBO:0112427 Importantly, we found that synchronized Datf1 cells completely failed to arrest nuclear division in the presence of Lat B (Fig. 4d)
PMID:11460168 PBO:0112765 Fig. 4B
PMID:11460168 PBO:0112430 Fig. 4F
PMID:11460168 PBO:0112424 Fig. 1E and F
PMID:11493649 GO:0051446 positive regulation of meiotic cell cycle exit
PMID:11493649 GO:0051447 negative regulation of meiotic exit
PMID:11514435 PBO:0098113 figure 1 & Figure 3B and Table 2
PMID:11514435 FYPO:0002627 figure 1
PMID:11514435 FYPO:0002061 figure 2a
PMID:11514435 GO:0052712 (Figure 7b) heterologous complementation
PMID:11514435 FYPO:0002061 figure 2a
PMID:11514435 FYPO:0001489 figure 2a
PMID:11514435 PBO:0098114 figure 1 Figure 3B and Table 2
PMID:11514435 GO:0016020 Figure 4D, lane 3
PMID:11514435 PBO:0098116 Figure 5 E to membrane
PMID:11514435 PBO:0098118 fig 6
PMID:11514435 PBO:0098117 fig 6
PMID:11514435 FYPO:0005485 figure 7b
PMID:11514435 GO:0052714 (Figure 7D) assayed reaction products
PMID:11514435 FYPO:0005485 figure 7b
PMID:11514435 GO:0046513 from MF
PMID:11514435 GO:0046521 from MF
PMID:11514435 GO:0071944 Figure 5
PMID:11514435 PBO:0098115 Figure 5D
PMID:11514435 GO:0005886 Figure 4D, lane 3 + figure 5
PMID:11514435 PBO:0098115 Figure 5 E
PMID:11514436 PBO:0105022 dns
PMID:11514436 FYPO:0002151 Thefact that out of almost 200 tetrads analyzed, not a single ura spore survived confirmed that spg1 is essential for vegetative growth, and this essential function cannot be bypassed by inactivating par1 and par2 by deletion.
PMID:11514436 PBO:0094971 asymetric localization is normal
PMID:11514436 PBO:0105023 figure 4a
PMID:11514436 FYPO:0002024 table 2, par1/2 does not supress sin phenotype
PMID:11514436 FYPO:0002024 table 2, par1/2 does not supress sin phenotype
PMID:11514436 FYPO:0002024 table 2, par1/2 does not supress sin phenotype
PMID:11514436 FYPO:0002024 table 2, par1/2 does not supress sin phenotype
PMID:11514436 FYPO:0001357 (Figure 1C, lane 8
PMID:11514436 FYPO:0002061 (Figure 2A).
PMID:11514436 FYPO:0002024 SID PHENOTYPE (Figure 2B).
PMID:11514436 FYPO:0006023 figure 2b
PMID:11514436 FYPO:0002024 figure 3biv
PMID:11514436 FYPO:0002061 figure 3a
PMID:11514436 FYPO:0002061 figure 3a
PMID:11514436 FYPO:0002061 figure 3a
PMID:11514436 FYPO:0002024 figure 3biv
PMID:11514436 FYPO:0002024 table 2, par1/2 does not supress sin phenotype
PMID:11514436 FYPO:0002024 table 2, par1/2 does not supress sin phenotype
PMID:11514436 FYPO:0002024 table 2, par1/2 does not supress sin phenotype
PMID:11514436 FYPO:0002024 table 2, par1/2 does not supress sin phenotype
PMID:11514436 FYPO:0002024 table 2, par1/2 does not supress sin phenotype
PMID:11514436 FYPO:0002024 table 2, par1/2 does not supress sin phenotype
PMID:11514436 FYPO:0002024 table 2, par1/2 does not supress sin phenotype
PMID:11514436 FYPO:0002024 table 2, par1/2 does not supress sin phenotype
PMID:11514436 FYPO:0001120 figure 4a
PMID:11532929 PBO:0098207 cdc25-22 background
PMID:11532929 PBO:0098207 cdc25-22 background
PMID:11532929 PBO:0098208 cdc25-22 background
PMID:11553781 PBO:0103157 Rad3 phosphorylates S345 in response to DNA damage caused by ionizing radiation
PMID:11553781 PBO:0103159 vw: changed from response to chemical to part of DNA damage checkpoint signalling
PMID:11554922 FYPO:0000188 evidence: immunoblot using antibody that recognizes thymine dimers
PMID:11598020 GO:0005721 fig 4a
PMID:11598020 GO:0005721 fig 4a
PMID:11598020 GO:0005634 fig 4a
PMID:11598020 PBO:0106460 fig 4a
PMID:11598020 PBO:0106461 fig 4a
PMID:11600706 PBO:0111727 (vw: in vitro purification system)
PMID:11600706 PBO:0111728 (vw: in vitro purification system)
PMID:11600706 PBO:0111729 (vw: in vitro purification system)
PMID:11600706 FYPO:0002778 figure 1C
PMID:11600706 FYPO:0005934 figure 1C
PMID:11600706 MOD:01149 Figure 3B
PMID:11600706 GO:0005515 fig 2B
PMID:11600706 GO:0005515 fig 2B
PMID:11606752 PBO:0098344 level of mutant cdc18deltaCDK1-5 protein
PMID:1165770 PBO:0102252 Table 1
PMID:1165770 PBO:0093712 Table 1
PMID:1165770 PBO:0102251 Figure 3
PMID:1165770 PBO:0102253 Table 1
PMID:1165770 PBO:0093712 cdc9-50 is the original name for wee1-50 allele. It was changed in subsequent publications to wee1 because of its phenotype and there is now no cdc9 gene
PMID:1165770 PBO:0102250 Table 1, Figure 2
PMID:11676915 PBO:0095721 figure 6
PMID:11676915 PBO:0095728 figure 6
PMID:11676915 PBO:0095729 figure 6
PMID:11676915 PBO:0095730 figure 6
PMID:11676915 PBO:0095731 figure 6
PMID:11676915 PBO:0094918 figure 6
PMID:11676915 PBO:0095732 figure 6
PMID:11676915 PBO:0095733 figure 6
PMID:11676915 PBO:0018346 figure 3 b
PMID:11676915 PBO:0094089 fig 5c
PMID:11676915 FYPO:0000941 dns
PMID:11676915 PBO:0095724 scaffold, platform
PMID:11676915 PBO:0095725 scaffold, platform
PMID:11676915 PBO:0095726 scaffold, platform
PMID:11676915 PBO:0095727 scaffold, platform
PMID:11676915 PBO:0018634 figure 3 b
PMID:11676915 PBO:0095723 fig 5a
PMID:11676915 FYPO:0002912 fig 1 a
PMID:11676915 FYPO:0001368 fig 1 a
PMID:11676915 PBO:0095718 fig 1 a
PMID:11676924 GO:0000723 qualifier=same_pathway
PMID:11676924 GO:0140445 colocalizes with this region and taz1, abnormal localization in taz1-delta, and physically associates with taz1
PMID:11683390 PBO:0037411 Fig 2A, Fig3 Fig5D pREP5cdc2YFP integrant grown in YE+supplements (i.e. promoter OFF).
PMID:11683390 PBO:0106307 Fig 7
PMID:11683390 PBO:0106306 Fig 7
PMID:11683390 PBO:0037426 Fig 7
PMID:11683390 PBO:0037423 Fig 8
PMID:11683390 GO:0000776 cdc2 is localised at the centromeres during horse tail movement. Fig 9 shows that cdc2YFP is associated with cen1GFP
PMID:11683390 PBO:0037421 Fig 7 do not actually say it is associated with SPB just SPB region, i.e. telomere-SPB- centromere bouquet cluster
PMID:11683390 PBO:0037404 Fig2A, B, Fig 4C, pREP5cdc2YFP integrant grown in YE+supplements (i.e. promoter OFF) Proportion of total of Cdc2YFP in nucleus and cytoplasm varies across cell cycle. Lowest in nucleus during late mitosis (~ 10% of total), highest in nucleus in late G2 (~30-40%) of total
PMID:11683390 PBO:0037405 Fig2A, B, Fig 4C, pREP5cdc2YFP integrant grown in YE+supplements (i.e. promoter OFF) Proportion of total of Cdc2YFP in nucleus and cytoplasm varies across cell cycle. Lowest in nucleus during late mitosis (~ 10% of total), highest in nucleus in late G2 (~30-40%) of total
PMID:11683390 PBO:0018712 Fig2A, B, Fig 4C, pREP5cdc2YFP integrant grown in YE+supplements (i.e. promoter OFF) Proportion of total of Cdc2YFP in nucleus and cytoplasm varies across cell cycle. Lowest in nucleus during late mitosis (~ 10% of total), highest in nucleus in late G2 (~30-40%) of total
PMID:11683390 PBO:0037406 Fig2A, B, Fig 4C, pREP5cdc2YFP integrant grown in YE+supplements (i.e. promoter OFF) Proportion of total of Cdc2YFP in nucleus and cytoplasm varies across cell cycle. Lowest in nucleus during late mitosis (~ 10% of total), highest in nucleus in late G2 (~30-40%) of total
PMID:11683390 PBO:0106305 Fig 6 Cdc13YFP and Cdc2YFP remain associated with spindle, SPB. Cdc13 is not degraded by defective proteasome. Rpt1 is called Mts2 in this paper
PMID:11683390 PBO:0106305 Fig 6 Cdc13YFP and Cdc2YFP remain associated with spindle, SPB. Cdc13 is not recognised by defective APC
PMID:11683390 PBO:0021746 Fig2A, B, Fig 4C, pREP5cdc2YFP integrant grown in YE+supplements (i.e. promoter OFF) Proportion of total of Cdc2YFP in nucleus and cytoplasm varies across cell cycle. Lowest in nucleus during late mitosis (~ 10% of total), highest in nucleus in late G2 (~30-40%) of total
PMID:11683390 PBO:0021499 Fig2A, B, Fig 4C, pREP5cdc2YFP integrant grown in YE+supplements (i.e. promoter OFF) Proportion of total of Cdc2YFP in nucleus and cytoplasm varies across cell cycle. Lowest in nucleus during late mitosis (~ 10% of total), highest in nucleus in late G2 (~30-40%) of total
PMID:11683390 PBO:0037407 Fig2A, B, Fig 4C, pREP5cdc2YFP integrant grown in YE+supplements (i.e. promoter OFF) Proportion of total of Cdc2YFP in nucleus and cytoplasm varies across cell cycle. Lowest in nucleus during late mitosis (~ 10% of total), highest in nucleus in late G2 (~30-40%) of total
PMID:11683390 PBO:0019070 Fig2A pREP5cdc13-YFP integrant grown in YE+supplements (i.e. promoter OFF)
PMID:11683390 PBO:0022133 Fig2A pREP5cdc13-YFP integrant grown in YE+supplements (i.e. promoter OFF)
PMID:11683390 PBO:0018999 Fig2A pREP5cdc13-YFP integrant grown in YE+supplements (i.e. promoter OFF)
PMID:11683390 PBO:0018677 Fig2A pREP5cdc13-YFP integrant grown in YE+supplements (i.e. promoter OFF)
PMID:11683390 PBO:0037148 Fig 2A b-c, Fig5D pREP5cdc13YFP integrant grown in YE+supplements (i.e. promoter OFF).
PMID:11683390 PBO:0023023 Fig 2A b-c, Fig5D pREP5cdc13YFP integrant grown in YE+supplements (i.e. promoter OFF).
PMID:11683390 PBO:0018634 Fig 2A b-c, Fig5D pREP5cdc13YFP integrant grown in YE+supplements (i.e. promoter OFF).
PMID:11683390 PBO:0037408 Fig 2A b-c, Fig5 pREP5cdc2YFP integrant grown in YE+supplements (i.e. promoter OFF).
PMID:11683390 PBO:0106305 Fig 6 Cdc2YFP and non-degradable Cdc13YFP remain associated with spindle, SPB.Cdc13 degradation is abolished rather than delayed
PMID:11683390 PBO:0037148 Fig 2A b-c, Fig5 pREP5cdc2YFP integrant grown in YE+supplements (i.e. promoter OFF).
PMID:11683390 PBO:0037419 Fig 6
PMID:11683390 PBO:0106300 Figure 4A. Cdc13YFP expressed from integrated pREP45. Decreased nuclear import of cdc2YFP compared to cdc13delta cig1delta mutant
PMID:11683390 PBO:0106301 Figure 4B. Cdc13YFP expressed from integrated pREP45
PMID:11683390 PBO:0106304 Data not shown. Cdc2 does not go prematurely to the SPB in a cut12 mutant (this is the stf1-1 mutant)
PMID:11683390 PBO:0106301 Figure 4A. Cdc13YFP expressed from integrated pREP45.
PMID:11683390 PBO:0106300 Figure 4A. Cdc13YFP expressed from integrated pREP45
PMID:11683390 PBO:0106299 Figure 4A
PMID:11683390 PBO:0037412 Fig 2C, pREP5cdc13YFP integrant grown in YE+supplements (i.e. promoter OFF).
PMID:11683390 PBO:0023023 Fig 2A b-c, Fig5 pREP5cdc2YFP integrant grown in YE+supplements (i.e. promoter OFF).
PMID:11683390 PBO:0037409 Fig 2A b-c, Fig5 pREP5cdc2YFP integrant grown in YE+supplements (i.e. promoter OFF).
PMID:11683390 PBO:0024116 Fig2A, B pREP5cdc2YFP integrant grown in YE+supplements (i.e. promoter OFF). Proportion of total of Cdc2YFP in nucleus and cytoplasm varies across cell cycle. Lowest in nucleus during late mitosis (~ 10% of total), highest in nucleus in late G2 (~30-40%) of total
PMID:11683390 PBO:0019070 Fig2A, B pREP5cdc2YFP integrant grown in YE+supplements (i.e. promoter OFF). Proportion of total of Cdc2YFP in nucleus and cytoplasm varies across cell cycle. Lowest in nucleus during late mitosis (~ 10% of total), highest in nucleus in late G2 (~30-40%) of total
PMID:11683390 PBO:0022133 Fig2A, B pREP5cdc2YFP integrant grown in YE+supplements (i.e. promoter OFF). Proportion of total of Cdc2YFP in nucleus and cytoplasm varies across cell cycle. Lowest in nucleus during late mitosis (~ 10% of total), highest in nucleus in late G2 (~30-40%) of total
PMID:11683390 PBO:0021007 Fig 2A, Fig3 Fig5D pREP5cdc2YFP integrant grown in YE+supplements (i.e. promoter OFF).
PMID:11683390 PBO:0018999 Fig2A, B pREP5cdc2YFP integrant grown in YE+supplements (i.e. promoter OFF). Proportion of total of Cdc2YFP in nucleus and cytoplasm varies across cell cycle. Lowest in nucleus during late mitosis (~ 10% of total), highest in nucleus in late G2 (~30-40%) of total
PMID:11683390 PBO:0037410 Fig2A, B pREP5cdc2YFP integrant grown in YE+supplements (i.e. promoter OFF). Proportion of total of Cdc2YFP in nucleus and cytoplasm varies across cell cycle. Lowest in nucleus during late mitosis (~ 10% of total), highest in nucleus in late G2 (~30-40%) of total
PMID:11683390 PBO:0021770 Fig2A, B pREP5cdc2YFP integrant grown in YE+supplements (i.e. promoter OFF). Proportion of total of Cdc2YFP in nucleus and cytoplasm varies across cell cycle. Lowest in nucleus during late mitosis (~ 10% of total), highest in nucleus in late G2 (~30-40%) of total
PMID:11683390 PBO:0037411 Fig 2A, Fig 3, Fig5D pREP5cdc13YFP integrant grown in YE+supplements (i.e. promoter OFF).
PMID:11683390 PBO:0021007 Fig 2A, Fig 3, Fig5D pREP5cdc13YFP integrant grown in YE+supplements (i.e. promoter OFF).
PMID:11685532 GO:0000776 mitotic, in meiosis it is only n the kinetochore during meitoic division(metaphase/anaphase) not during prophase
PMID:11694585 FYPO:0004257 27 degrees C
PMID:11694585 FYPO:0002061 30 degrees C
PMID:11694585 FYPO:0002023 27 degrees C
PMID:11694585 FYPO:0004257 27 degrees C
PMID:11694585 FYPO:0002061 30 degrees C
PMID:11694585 PBO:0019147 various abnormal shapes
PMID:11694585 PBO:0019147 various abnormal shapes
PMID:11694585 FYPO:0003315 temperature restrictive for cdc4-8
PMID:11694585 FYPO:0002437 temperature permissive for cdc4-8
PMID:11694585 GO:0051015 assayed using purified rabbit skeletal muscle F-actin
PMID:11694585 GO:0051017 in vitro bundling, detected by microscopy; Figure 2
PMID:11694585 GO:0032153 dependent on actin cytoskeleton (assayed using Latrunculin A)
PMID:11694585 GO:0030479 dependent on actin cytoskeleton (assayed using Latrunculin A)
PMID:11696322 PBO:0022665 figure 5bc
PMID:11696322 PBO:0104463 figure 5e
PMID:11696322 FYPO:0001367 Figure 3fg
PMID:11696322 FYPO:0001368 Figure 3fg
PMID:11696322 FYPO:0003193 table1
PMID:11696322 PBO:0104462 igure 3b–g,i)
PMID:11696322 FYPO:0002021 figure 3b–g,i)
PMID:11696322 FYPO:0003315 figure 3b-g
PMID:11696322 FYPO:0000016 figure 3
PMID:11696322 FYPO:0001234 data not shown
PMID:11696322 PBO:0018345 figure 5a
PMID:11696322 FYPO:0003225 table1
PMID:11696322 FYPO:0002401 Figure 4, table1
PMID:11717425 FYPO:0001095 filter binding assay
PMID:11719193 GO:0008821 magneisum activated_by(CHEBI:18420)
PMID:11737264 FYPO:0005103 population is viable but sick; can't tell which individual cells are viable
PMID:11737264 FYPO:0000021 population is viable but sick; can't tell which individual cells are viable
PMID:11737264 FYPO:0000647 population is viable but sick; can't tell which individual cells are viable, but very small cells look lysed
PMID:11737264 FYPO:0007436 population is viable but sick, and the elongated multiseptate cells are probably dead
PMID:11737264 PBO:0019176 population is viable, but very small cells look lysed
PMID:11737264 PBO:0019176 population grows well, but very small cells look lysed
PMID:11739790 FYPO:0004511 Figure 4, B&D
PMID:11739790 PBO:0105588 arrested
PMID:11739790 PBO:0105588 arrested
PMID:11739790 PBO:0105588 arrested
PMID:11739790 FYPO:0002060 Figure 2 and Table 2
PMID:11739790 FYPO:0004511 Figure 4, B&D
PMID:11777938 FYPO:0005322 figure 2
PMID:11777938 FYPO:0000620 NORMAL LENGTH
PMID:11780129 PBO:0112308 (Fig. 3b, data not shown)
PMID:11780129 PBO:0112302 Psc3 localization was strikingly disrupted in the swi6∆ strain at both loci (Fig. 1b).
PMID:11780129 FYPO:0002336 We consistently observed that psc3-4T and the other psc3 mutant alleles had no detectable effect on the silencing of a marker gene inserted at either centromeric (otr1R::ura4+) repeats or in the silent mating-type (Kint2::ura4+) region (see Supplementary Information).
PMID:11780129 GO:0005721 Interestingly, we found that Psc3 is enriched at the heterochromatic locations containing Swi6, such as the silent mating-type locus and the centromeric repeats (Fig. 1b, c, wild type).
PMID:11780129 FYPO:0002360 We consistently observed that psc3-4T and the other psc3 mutant alleles had no detectable effect on the silencing of a marker gene inserted at either centromeric (otr1R::ura4+) repeats or in the silent mating-type (Kint2::ura4+) region (see Supplementary Information).
PMID:11780129 PBO:0110924 However, this mutation did not affect Swi6 localization at otr and KR (Fig. 1e).
PMID:11780129 PBO:0112300 shown), and the association with otr and KR was much reduced (Fig. 1d).
PMID:11780129 PBO:0112301 Psc3 localization was strikingly disrupted in the swi6∆ strain at both loci (Fig. 1b).
PMID:11780129 PBO:0112301 Psc3 localization was strikingly disrupted in the swi6∆ strain at both loci (Fig. 1b).
PMID:11780129 PBO:0112307 we found that cohesin mutants (psc3-1T, psc3-2T, psc3-4T and rad21-K1) pro- duced switching-defective colonies at a rate nearly 100-fold that of the wild type (Fig.3a,b).
PMID:11780129 PBO:0112307 we found that cohesin mutants (psc3-1T, psc3-2T, psc3-4T and rad21-K1) pro- duced switching-defective colonies at a rate nearly 100-fold that of the wild type (Fig.3a,b).
PMID:11780129 PBO:0112307 we found that cohesin mutants (psc3-1T, psc3-2T, psc3-4T and rad21-K1) pro- duced switching-defective colonies at a rate nearly 100-fold that of the wild type (Fig.3a,b).
PMID:11780129 FYPO:0000228 Moreover, the psc3+–GFP swi6∆ cells showed increased mini-chromosome loss and exhibited a high incidence of lagging chromosome and other chromosome segregation abnormalities (Fig. 2c)
PMID:11780129 FYPO:0000228 Figure 2b
PMID:11780129 PBO:0112306 (Fig. 2a, b).
PMID:11780129 PBO:0112305 (Fig. 2a, b).
PMID:11780129 PBO:0112559 psc3-1T also displays the lagging- chromosome phenotype and mis-segregated the mini-chromosome Ch16 (ref. 17) at a higher rate than the wild type, mimicking the swi6∆ phenotype (Fig. 2a, b).
PMID:11780129 PBO:0112558 psc3-1T also displays the lagging- chromosome phenotype and mis-segregated the mini-chromosome Ch16 (ref. 17) at a higher rate than the wild type, mimicking the swi6∆ phenotype (Fig. 2a, b).
PMID:11780129 GO:0031934 Interestingly, we found that Psc3 is enriched at the heterochromatic locations containing Swi6, such as the silent mating-type locus and the centromeric repeats (Fig. 1b, c, wild type).
PMID:11780129 GO:0031934 Interestingly, we found that Psc3 is enriched at the heterochromatic locations containing Swi6, such as the silent mating-type locus and the centromeric repeats (Fig. 1b, c, wild type).
PMID:11780129 PBO:0112302 Psc3 localization was strikingly disrupted in the swi6∆ strain at both loci (Fig. 1b).
PMID:11780129 GO:0005721 Interestingly, we found that Psc3 is enriched at the heterochromatic locations containing Swi6, such as the silent mating-type locus and the centromeric repeats (Fig. 1b, c, wild type).
PMID:11780129 PBO:0112307 we found that cohesin mutants (psc3-1T, psc3-2T, psc3-4T and rad21-K1) pro- duced switching-defective colonies at a rate nearly 100-fold that of the wild type (Fig.3a,b).
PMID:11781565 PBO:0106287 Fig1C no increase in presence of HU compared to no HU when all MCB elements are removed. res1 and lacZ fusion on episomal plasmids
PMID:11781565 PBO:0106288 Fig2B
PMID:11781565 PBO:0106289 Fig2B
PMID:11781565 PBO:0106290 Fig2B
PMID:11781565 PBO:0106291 Fig2B
PMID:11781565 PBO:0106292 Fig3A
PMID:11781565 PBO:0106292 Fig3B
PMID:11781565 PBO:0106292 Fig3B
PMID:11781565 PBO:0106293 Fig4D
PMID:11781565 PBO:0106293 Fig4D
PMID:11781565 PBO:0106293 Fig4D
PMID:11781565 PBO:0106294 FIg4E
PMID:11781565 FYPO:0002060 Fig 5 res1-S130A can rescue the pat1-114 mutant at low levels of over expression
PMID:11781565 FYPO:0002061 Fig5 res1+ is unable to rescue the pat1-114 mutant at low levels of over expression
PMID:11781565 PBO:0105915 Fig6
PMID:11781565 PBO:0098713 Fig7B res1S130A prevents the normal down regulation of MBF dependent transcription by res1+
PMID:11781565 PBO:0096409 Fig7B res1S130A prevents the normal down regulation of MBF dependent transcription by res1+
PMID:11781565 PBO:0096413 Fig7B res1S130A prevents the normal down regulation of MBF dependent transcription by res1+
PMID:11781565 PBO:0109006 Fig2B
PMID:11781565 FYPO:0006762 Fig2B
PMID:11781565 PBO:0106277 Fig1B
PMID:11781565 PBO:0106278 Fig1B
PMID:11781565 PBO:0106279 Fig1B
PMID:11781565 PBO:0106280 Fig1B
PMID:11781565 PBO:0106281 Fig1B
PMID:11781565 PBO:0106278 Fig1B
PMID:11781565 PBO:0106282 Fig1B
PMID:11781565 PBO:0106283 Fig1B
PMID:11781565 PBO:0106284 data not shown 8 fold increase in response to res1 oe. res1 and lacZ fusion on episomal plasmids
PMID:11781565 PBO:0106285 Data not shown 20 fold increase in response to res1 oe. res1 and lacZ fusion on episomal plasmids
PMID:11781565 PBO:0106286 Fig1C Shows 5 fold increase in presence of HU compared to no HU. res1 and lacZ fusion on episomal plasmids
PMID:11781565 PBO:0106286 Fig1C 5 fold increase in HU compared to no HU. res1 and lacZ fusion on episomal plasmids
PMID:11792803 FYPO:0003758 figure 2 a ( stretched chromaitn along elongating spindle at anaphase B)
PMID:11792803 FYPO:0005739 figure 2 b
PMID:11792803 FYPO:0000276 figure 2 b chromsome detached from spindle
PMID:11792803 FYPO:0004255 figure 2 b
PMID:11792803 FYPO:0005738 figure 2 b
PMID:11792803 PBO:0093462 fig6
PMID:11792803 PBO:0093462 fig6
PMID:11792803 PBO:0093462 fig6
PMID:11792803 PBO:0033839 fig8
PMID:11792803 PBO:0092680 fig8
PMID:11792803 PBO:0023853 fig8
PMID:11818066 FYPO:0002060 does not undergo meiosis under conditions where pat1-114 single mutant does
PMID:11818066 FYPO:0002052 not really sure freq is normal, because wt not shown, but text suggests it's close
PMID:11818066 PBO:0111616 Rad24 sequesters phosphorylated Mei2, preventing Mei2 binding to meiRNA (sme2)
PMID:11839792 PBO:0110539 56% of sar1-1, 68% of sec31-1, and 50% of pmm1-1 cells had accumulated ER membranes and dilated nuclear and ER lumens (Table 1).
PMID:11839792 PBO:0110535 Pap1p was localized predominantly to the cytoplasm in wild- type cells (Fig. 5A) as well as in the sar1-1, sec31-1 and pmm1- 1 mutants grown at the restrictive temperature, suggesting that nuclear protein export was not adversely affected in these cells (Fig. 5C,E,G).
PMID:11839792 PBO:0110535 Pap1p was localized predominantly to the cytoplasm in wild- type cells (Fig. 5A) as well as in the sar1-1, sec31-1 and pmm1- 1 mutants grown at the restrictive temperature, suggesting that nuclear protein export was not adversely affected in these cells (Fig. 5C,E,G).
PMID:11839792 PBO:0110536 Pap1p was localized predominantly to the cytoplasm in wild- type cells (Fig. 5A) as well as in the sar1-1, sec31-1 and pmm1- 1 mutants grown at the restrictive temperature, suggesting that nuclear protein export was not adversely affected in these cells (Fig. 5C,E,G).
PMID:11839792 PBO:0110536 Pap1p was localized predominantly to the cytoplasm in wild- type cells (Fig. 5A) as well as in the sar1-1, sec31-1 and pmm1- 1 mutants grown at the restrictive temperature, suggesting that nuclear protein export was not adversely affected in these cells (Fig. 5C,E,G).
PMID:11839792 PBO:0110540 56% of sar1-1, 68% of sec31-1, and 50% of pmm1-1 cells had accumulated ER membranes and dilated nuclear and ER lumens (Table 1).
PMID:11839792 FYPO:0003935 In sar1-1 cells, acid phosphatase accumulated in its 72 kDa core glycosylated form (arrow) even at 25°C (Fig. 2A, lane 5), and this form increased in abundance upon incubation at 36°C (Fig. 2A, lanes 6-8), indicating a block in its secretion from the ER
PMID:11839792 FYPO:0003935 The glycosylation profile of acid phosphatase in sec31-1 cells also revealed a block in secretion from the ER (Fig. 2B). In sec31-1 cells at 25°C (Fig. 2B, lane 3), a low level of the 72 kDa form of acid phosphatase (arrow) and high molecular weight smears indicated normal protein secretion. However, sec31-1 cells incubated at 36°C for 4 hours, accumulated a high level of the 72 kDa ER form of acid phosphatase (Fig. 2B, lane 4), indicating that protein secretion from the ER is inhibited
PMID:11839792 FYPO:0002061 sar1, sec31 and pmm1 are essential genes
PMID:11839792 FYPO:0002061 sar1, sec31 and pmm1 are essential genes
PMID:11839792 FYPO:0002061 sar1, sec31 and pmm1 are essential genes
PMID:11839792 PBO:0110526 sar1, sec31 and pmm1 are essential genes vw:2c binucleate? should this be WT knockdown?
PMID:11839792 FYPO:0002280 These data confirm that pmm1 is an essential gene. Microscopic examination of the tetrad dissection plates revealed that, of 54 pmm1 null spores examined, 98% germinated. Of these, 52% formed single, rounded cells and 47% arrested as single, septated cells.
PMID:11839792 PBO:0110537 56% of sar1-1, 68% of sec31-1, and 50% of pmm1-1 cells had accumulated ER membranes and dilated nuclear and ER lumens (Table 1).
PMID:11839792 PBO:0110528 19% were septated, binucleated cells with condensed chromosomes. (vw:2c binucleate? should this be WT knockdown?)
PMID:11839792 PBO:0110529 56% of sar1-1, 68% of sec31-1, and 50% of pmm1-1 cells had accumulated ER membranes and dilated nuclear and ER lumens (Table 1).
PMID:11839792 PBO:0110530 56% of sar1-1, 68% of sec31-1, and 50% of pmm1-1 cells had accumulated ER membranes and dilated nuclear and ER lumens (Table 1).
PMID:11839792 PBO:0110531 56% of sar1-1, 68% of sec31-1, and 50% of pmm1-1 cells had accumulated ER membranes and dilated nuclear and ER lumens (Table 1).
PMID:11839792 PBO:0110538 56% of sar1-1, 68% of sec31-1, and 50% of pmm1-1 cells had accumulated ER membranes and dilated nuclear and ER lumens (Table 1).
PMID:11839792 PBO:0110532 56% of sar1-1, 68% of sec31-1, and 50% of pmm1-1 cells had accumulated ER membranes and dilated nuclear and ER lumens (Table 1).
PMID:11839792 PBO:0110533 56% of sar1-1, 68% of sec31-1, and 50% of pmm1-1 cells had accumulated ER membranes and dilated nuclear and ER lumens (Table 1).
PMID:11839792 PBO:0110534 Pap1p was localized predominantly to the cytoplasm in wild- type cells (Fig. 5A) as well as in the sar1-1, sec31-1 and pmm1- 1 mutants grown at the restrictive temperature, suggesting that nuclear protein export was not adversely affected in these cells (Fig. 5C,E,G).
PMID:11839792 PBO:0110535 Pap1p was localized predominantly to the cytoplasm in wild- type cells (Fig. 5A) as well as in the sar1-1, sec31-1 and pmm1- 1 mutants grown at the restrictive temperature, suggesting that nuclear protein export was not adversely affected in these cells (Fig. 5C,E,G).
PMID:11854402 PBO:0101937 during premeiotic DNA replication
PMID:11854402 PBO:0101936 during premeiotic DNA replication
PMID:11854402 PBO:0101936 during premeiotic DNA replication
PMID:11854402 PBO:0101936 during premeiotic DNA replication
PMID:11854402 PBO:0099076 during premeiotic DNA replication
PMID:11854409 PBO:0097222 fig 1A inviable
PMID:11854409 GO:0005515 Figure 5B
PMID:11854409 GO:0005515 Figure 5A
PMID:11854409 FYPO:0003440 fig 2, 3
PMID:11854409 FYPO:0006558 fig 2, 3
PMID:11854409 GO:0005515 UPR
PMID:11854409 GO:0005515 UPR
PMID:11854409 GO:0005515 UPR
PMID:11854409 GO:0005515 Figure 5C
PMID:11861551 PBO:0023853 fig 1a
PMID:11861551 PBO:0022963 fig 1
PMID:11861551 GO:0005634 fig 1a
PMID:11861551 FYPO:0002061 fig 7a
PMID:11861551 FYPO:0000229 fig 7a
PMID:11861551 GO:0000776 igure 7
PMID:11861551 PBO:0112057 fig 7
PMID:11861551 GO:1990023 igure 7
PMID:11861551 FYPO:0000131 4
PMID:11861551 FYPO:0004101 4
PMID:11861551 FYPO:0004101 4
PMID:11861551 FYPO:0003286 4c
PMID:11861551 PBO:0097993 fig 3
PMID:11861551 PBO:0035224 fig 3
PMID:11861765 FYPO:0002061 fig 3B
PMID:11861765 PBO:0096828 fig 4A
PMID:11861765 FYPO:0000141 fig 4 D
PMID:11861765 FYPO:0001779 fig 3D
PMID:11861765 PBO:0033209 fig 4B,C
PMID:11861765 FYPO:0002060 fig 1
PMID:11861765 PBO:0093562 fig 3A
PMID:11861765 PBO:0093629 fig 2
PMID:11861765 FYPO:0000581 fig 5B
PMID:11861765 PBO:0033665 fig 3C
PMID:11861765 FYPO:0003165 fig 3C
PMID:11861765 FYPO:0001513 fig 3C
PMID:11861765 FYPO:0000925 fig 5A
PMID:11861765 PBO:0105969 fig 2 A
PMID:11861765 FYPO:0001779 fig 3D
PMID:11861765 PBO:0093617 fig 2 B
PMID:11861765 PBO:0093586 fig 2 B
PMID:11861765 FYPO:0002578 fig 2 B
PMID:11861765 FYPO:0003241 fig 4B
PMID:11861765 PBO:0035685 fig 4B,C
PMID:11861765 FYPO:0004507 fig 3C
PMID:11861765 FYPO:0001234 fig 4 D
PMID:11861765 PBO:0035688 fig 8A
PMID:11861765 FYPO:0002061 fig 8B
PMID:11861765 FYPO:0001234 fig 8B
PMID:11861765 FYPO:0000839 fig 8C
PMID:11861765 FYPO:0000141 fig 8C
PMID:11861765 PBO:0105971 fig 7C
PMID:11861765 PBO:0105970 fig 7B
PMID:11861905 PBO:0092337 figure 1a
PMID:11861905 PBO:0092180 figure 1a
PMID:11861905 FYPO:0007627 The 210-nt region resides downstream of the distal poly(A) site and it is not included in the mature rrg1+ mRNA, in contrast to other regulatory elements for post-transcriptional control. However, some recent studies on S.pombe have shown that RNA pol II transcription proceeds beyond the poly(A) site and that the downstream sequences located in the 3′ noncoding region are responsible for transcription termination and mRNA 3′-end formation, which are closely coupled to efficient gene expression
PMID:11870212 PBO:0033837 Fig. 3B
PMID:11870212 PBO:0033837 Fig. 3B
PMID:11870212 PBO:0023853 Fig. 3B
PMID:11870212 PBO:0108184 Fig. 3B
PMID:11870212 FYPO:0000141 movement in anap[hase A
PMID:11870212 PBO:0023853 Fig. 3B
PMID:11870212 PBO:0108184 Fig. 3B
PMID:11882285 PBO:0023558 fig4
PMID:11882285 PBO:0102358 fig 1C
PMID:11882285 FYPO:0000639 fig 1
PMID:11882285 FYPO:0003307 fig 1
PMID:11882285 FYPO:0000274 fig 1
PMID:11882285 FYPO:0001532 fig 1
PMID:11882285 PBO:0102360 fig 5a
PMID:11882285 PBO:0102361 fig 5a ie wt like
PMID:11882285 PBO:0102359 S1
PMID:11882285 PBO:0102359 S1
PMID:11882285 PBO:0102359 S1
PMID:11882285 PBO:0092680 figure 3
PMID:11882285 FYPO:0000091 fig 2D
PMID:11882285 FYPO:0000091 fig 2D
PMID:11882285 PBO:0094474 fig 1 (3-4um normal metaphese lenght 2-2.5 um
PMID:11882285 PBO:0102359 S1
PMID:11884512 PBO:0095634 data not shown
PMID:11884512 FYPO:0000268 Figure 3 C
PMID:11884512 PBO:0093629 same as rad17 single mutant, epistatic
PMID:11884512 FYPO:0000097 data not shown
PMID:11884512 FYPO:0001253 3B
PMID:11884512 PBO:0098732 NEM, which inhibit the Pmt3-processing activity of Ulp1, and the serine protease inhibitor PMSF, have no effect on Pmt3 deconjugating activity
PMID:11884512 PBO:0099111 Of the inhibitors we tested, only iodoacetamide (10 mM) and NEM (10 mM) inhibited Ulp1 activity
PMID:11884604 PBO:0111656 broad specificity; actually inferred from combination of phenotype and sequence similarity
PMID:11884604 PBO:0098977 not much evidence of specificity for H3 vs. H4 or position
PMID:11884604 GO:0004407 actually inferred from combination of phenotype and sequence similarity
PMID:11884604 GO:0000785 not (coincident_with(SO:0001789) | coincident_with(SO:0001795))
PMID:11884604 PBO:0111654 actually inferred from combination of phenotype and sequence similarity
PMID:11884604 PBO:0111655 actually inferred from combination of phenotype and sequence similarity
PMID:11884604 PBO:0111656 actually inferred from combination of phenotype and sequence similarity
PMID:11884604 PBO:0111654 broad specificity; actually inferred from combination of phenotype and sequence similarity
PMID:11884604 PBO:0111655 broad specificity; actually inferred from combination of phenotype and sequence similarity
PMID:11884604 PBO:0111657 broad specificity; actually inferred from combination of phenotype and sequence similarity
PMID:11884604 PBO:0111658 broad specificity; actually inferred from combination of phenotype and sequence similarity
PMID:11884604 PBO:0111659 broad specificity; actually inferred from combination of phenotype and sequence similarity
PMID:11884604 PBO:0111660 broad specificity; actually inferred from combination of phenotype and sequence similarity
PMID:11884604 PBO:0111661 broad specificity; actually inferred from combination of phenotype and sequence similarity
PMID:11884604 PBO:0111662 broad specificity; actually inferred from combination of phenotype and sequence similarity
PMID:11886869 PBO:0111429 To determine whether the main pathway for Cd2� de- toxification in S. pombe, the formation of phytochelatins, is required for the �zhf-dependent protection, the zhf gene was disrupted in the �pcs strain Sp27 (20). Toxicity assays showed that the protective effect was even more pronounced in this genetic background.
PMID:11886869 PBO:0093559 �zhf strain were viable and showed only a minor reduction in growth rate under control conditions without any added heavy metal salts.
PMID:11886869 PBO:0110448 In the presence of elevated Zn2� levels, however, they were severely growth-inhibited (Fig. 1, A and B).
PMID:11886869 GO:0140209 storage
PMID:11886869 FYPO:0001245 Similarly, the absence of a functional Zhf protein rendered the S. pombe cells Co2�-hypersensitive (Fig. 1C). At 1 mM Co2� in EMM, wild-type cells showed 94% (�11%) of the optical density of untreated control cells, whereas �zhf cells reached only 36% (�3.5%).
PMID:11886869 FYPO:0000763 In contrast to that, the zhf disruption was found to significantly protect cells from toxicity of Cd2� ions, the third known substrate of CDF proteins. At the IC50 con- centration for wild-type cells of 100 �M, �zhf cells were inhib- ited by only 4% (�3%) (Fig. 1D).
PMID:11886869 FYPO:0002588 a pronounced protective effect of the Zhf inactivation could be detected also for Ni2�
PMID:11907273 FYPO:0000172 using chromosome III
PMID:11907273 GO:0005515 2-hybrid
PMID:11909965 PBO:0096197 figure 3a DECREASDED cell cycle arrest in mitotic anaphase
PMID:11909965 FYPO:0003762 figure 3a cell cycle arrest in mitotic ametaphase
PMID:11909965 FYPO:0003762 figure 3a cell cycle arrest in mitotic metaphase
PMID:11909965 FYPO:0004318 figure2C
PMID:11909965 FYPO:0004318 figure2C
PMID:11909965 PBO:0033937 2B
PMID:11909965 FYPO:0000069 Fig 2A
PMID:11909965 PBO:0096195 2B
PMID:11909965 PBO:0096196 2B
PMID:11909965 PBO:0096196 2B
PMID:11909965 PBO:0023853 figure 5A
PMID:11909965 GO:0005515 figure 5
PMID:11927555 GO:0006998 suggesting the lethal synthetic interaction between ®n1D and cut11 might relate of the nuclear envelope rather than SPB anchoring during mitosis
PMID:11927555 FYPO:0007566 These data show that Fin1p- mediated compaction of the chromosomes is not func- tionally related to mitotic chromosome condensation and the mechanism by which it occurs remains obscure.
PMID:11927555 FYPO:0007566 These data show that Fin1p- mediated compaction of the chromosomes is not func- tionally related to mitotic chromosome condensation and the mechanism by which it occurs remains obscure.
PMID:11927555 FYPO:0007566 These data show that Fin1p- mediated compaction of the chromosomes is not func- tionally related to mitotic chromosome condensation and the mechanism by which it occurs remains obscure.
PMID:11927555 PBO:0037408 Figure 5
PMID:11927555 PBO:0018346 Figure 5
PMID:11927555 PBO:0101164 Figure 5
PMID:11927555 PBO:0093564 Figure 6
PMID:11927555 FYPO:0000620 fig 6 resulted in a synthetic arrest at metaphase of mitosis. This contrasts with the G1 cell cycle arrest of pim1-d1 single mutant cells (Krien et al., 1998).
PMID:11927555 PBO:0093562 fig6
PMID:11927555 PBO:0093564 Figure 6
PMID:11927555 FYPO:0000276 Figure 6
PMID:11927555 PBO:0101165 Figure 6 which was enhanced by the presence of the pim1-d1 mutation at 36°C to include all mitotic cells (arrowed
PMID:11927555 FYPO:0003738 fig6
PMID:11927555 FYPO:0000338 fig6
PMID:11927555 FYPO:0001489 fig6
PMID:11927555 FYPO:0006821 The double ®n1Dbub1D mutants were viable, though substantially retarded in colony formation and showed extensive chromosome segregation defects (Figure 7A).
PMID:11927555 FYPO:0000141 The double ®n1Dbub1D mutants were viable, though substantially retarded in colony formation and showed extensive chromosome segregation defects (Figure 7A).
PMID:11927555 FYPO:0002061 Double mutants between ®n1D and the temperature-sensitive allele rad21-K1 (Tatebayashi et al., 1998) were synthetically lethal at all temperatures
PMID:11927555 PBO:0101166 (in. non mitotic cells)
PMID:11927555 FYPO:0007566 These data show that Fin1p- mediated compaction of the chromosomes is not func- tionally related to mitotic chromosome condensation and the mechanism by which it occurs remains obscure.
PMID:11950879 FYPO:0003570 "indicated by ""majority of the Mad2-GFP was localized to the spindle"""
PMID:11950879 PBO:0092680 (vw: nda3 tubulin mutant does not assemble spindle and shows Mad2 is localized to unattached kinetochores)
PMID:11950879 FYPO:0003570 "indicated by ""majority of the Mad2-GFP was localized to the spindle"""
PMID:11950879 FYPO:0002638 "indicated by ""majority of the Mad2-GFP was localized to the spindle"""
PMID:11950884 FYPO:0006772 Fig8D,E pom1 has a role in the relocalisation of actin to the shmooing cell tip
PMID:11950884 FYPO:0000761 Fig6C
PMID:11950884 FYPO:0000761 Fig6C
PMID:11950884 PBO:0102927 location is abolished during mating Fig4Dc and Fig4Ec
PMID:11950884 PBO:0102926 Fig6C
PMID:11950884 PBO:0102925 Fig6A
PMID:11950884 FYPO:0007563 Fig6B
PMID:11950884 FYPO:0007563 Fig6B
PMID:11950884 PBO:0102928 regulation of
PMID:11950884 PBO:0102921 Fig1
PMID:11950884 PBO:0102925 Fig6A
PMID:11950884 PBO:0102925 Fig6A
PMID:11950884 FYPO:0007810 Fig 5, Table 3,4
PMID:11950884 FYPO:0007810 Fig5 Table 3,4
PMID:11950884 FYPO:0007810 Fig5 Table 4
PMID:11950884 PBO:0102924 Fig2A
PMID:11950884 PBO:0102923 Fig2A
PMID:11950884 PBO:0102922 Fig2A
PMID:11950884 PBO:0102927 FIg 4 F location alkso exists during mating
PMID:11950884 GO:0043332 After pheromone addition, Tea1GFP became mostly lost from the growing end and was redistributed along the cell periphery at the nongrowing larger end (Fig. 3E). After pheromone addition, Tea2GFP and Tip1YFP were also reduced at the growing end, accumulating at the non-growing end and in the cytoplasm, often as dots in a row (Fig. 3E). The same relocalisation was observed for Tea2GFP during an h90 mating. In conjugating cells, Tea2GFP was found to localise to the nongrowing ends with some dots in the..
PMID:11950884 GO:0043332 After pheromone addition, Tea1GFP became mostly lost from the growing end and was redistributed along the cell periphery at the nongrowing larger end (Fig. 3E). After pheromone addition, Tea2GFP and Tip1YFP were also reduced at the growing end, accumulating at the non-growing end and in the cytoplasm, often as dots in a row (Fig. 3E). The same relocalisation was observed for Tea2GFP during an h90 mating. In conjugating cells, Tea2GFP was found to localise to the nongrowing ends with some dots in the..
PMID:11950884 GO:0043332 After pheromone addition, Tea1GFP became mostly lost from the growing end and was redistributed along the cell periphery at the nongrowing larger end (Fig. 3E). After pheromone addition, Tea2GFP and Tip1YFP were also reduced at the growing end, accumulating at the non-growing end and in the cytoplasm, often as dots in a row (Fig. 3E). The same relocalisation was observed for Tea2GFP during an h90 mating. In conjugating cells, Tea2GFP was found to localise to the nongrowing ends with some dots in the..
PMID:11950884 FYPO:0007563 Fig6B All three mutants were able to detect and respond to pheromone by arresting in G1, as shown by FACS analysis (Fig. 6B),
PMID:11950927 FYPO:0003165 Figure 1C
PMID:11950927 FYPO:0001575 dominent negative effect
PMID:11950927 FYPO:0001575 dominent negative effect
PMID:11950927 FYPO:0001234 Figure 6A)
PMID:11950927 FYPO:0000134 Figure 6A)
PMID:11950927 PBO:0098340 Pic1– 765-924, which lacks the IN box, failed to bind Ark1p,
PMID:11950927 PBO:0098338 Figure2
PMID:11950927 FYPO:0000134 fig 3c
PMID:11950927 FYPO:0001513 fig 3c
PMID:11950927 FYPO:0001357 fig4
PMID:11950927 FYPO:0001575 dominent negative effect
PMID:11950932 PBO:0110444 How- ever, its localization to the SPB was lost in the sid4-SA1 mutant at restrictive temperature (Figure 3).
PMID:11950932 PBO:0110443 The CAA20785 GFP fusion protein localized normally in cdc16-116, spg1-106, cdc7-24, and sid2-250 temperature-sensitive mutants...(figure 3)
PMID:11950932 PBO:0110443 The CAA20785 GFP fusion protein localized normally in cdc16-116, spg1-106, cdc7-24, and sid2-250 temperature-sensitive mutants...(figure 3)
PMID:11950932 PBO:0110443 The CAA20785 GFP fusion protein localized normally in cdc16-116, spg1-106, cdc7-24, and sid2-250 temperature-sensitive mutants...(figure 3)
PMID:11950932 PBO:0110443 The CAA20785 GFP fusion protein localized normally in cdc16-116, spg1-106, cdc7-24, and sid2-250 temperature-sensitive mutants...(figure 3)
PMID:11950932 PBO:0018346 The single and merged images indicate that CAA20785 colocalizes with Sid4p to SPBs throughout the cell cycle (Figure 2B).
PMID:11950932 PBO:0018634 The single and merged images indicate that CAA20785 colocalizes with Sid4p to SPBs throughout the cell cycle (Figure 2B).
PMID:11950932 PBO:0110445 At 36°C, Spg1p-GFP was detected at SPBs in wild-type cells but was absent from SPBs in the cdc11 mutant strains (Figure 4B).
PMID:11950932 PBO:0110447 Overproduction of Cdc11p(631–1045) had no effect on the localization of Sid4p-GFP but caused the loss of Cdc11p-GFP and Spg1p-GFP from SPBs (Figure 5B).
PMID:11950932 PBO:0110446 Overproduction of Cdc11p(631–1045) had no effect on the localization of Sid4p-GFP but caused the loss of Cdc11p-GFP and Spg1p-GFP from SPBs (Figure 5B). This is consistent with the with the idea that Cdc11p(631–1045) saturates the SPB bind- ing site for Cdc11p, thus eliminating the opportunity for the full-length protein to localize to the SPB.
PMID:11950932 FYPO:0007569 nterestingly, we found that overproduction of GFP-Cdc11p(631–1045) gener-ated a sid phenotype (Figure 5A).
PMID:11950932 PBO:0110443 GFP- Cdc11p(1– 630) was distributed throughout the cytoplasm (our unpublished results), but GFP-Cdc11p(631–1045) local- ized to SPBs (Figure 5A).
PMID:11950932 PBO:0110444 GFP- Cdc11p(1– 630) was distributed throughout the cytoplasm (our unpublished results), but GFP-Cdc11p(631–1045) local- ized to SPBs (Figure 5A).
PMID:11950932 PBO:0110445 At 36°C, Spg1p-GFP was detected at SPBs in wild-type cells but was absent from SPBs in the cdc11 mutant strains (Figure 4B).
PMID:11952833 PBO:0106480 even though cdc13 is present
PMID:11952833 FYPO:0004537 premature SIN
PMID:11952833 PBO:0101805 even though cdc13 is present
PMID:11955632 FYPO:0003655 tRNA
PMID:11967147 FYPO:0000670 Figure 5B
PMID:11967147 FYPO:0003969 Figure 5B
PMID:11967147 FYPO:0003969 Figure 5B
PMID:11967147 FYPO:0002638 Figure 5D
PMID:11967147 FYPO:0002638 Figure 5D
PMID:11967147 FYPO:0005343 Figure 5D
PMID:11967147 FYPO:0006171 Figure 5D abolished pausing
PMID:11967147 PBO:0103981 Fig 1D
PMID:11967147 PBO:0103981 Fig 1D
PMID:11967147 PBO:0020141 fig2b
PMID:11967147 FYPO:0000670 Figure 5B
PMID:11967147 PBO:0093767 figure S1
PMID:11967147 PBO:0020141 fig2b
PMID:11967147 FYPO:0002060 figure S1 (20% longer)
PMID:11967147 FYPO:0002060 figure S1 (20% longer)
PMID:11967147 PBO:0103980 Fig 1A
PMID:11967147 PBO:0103980 Fig 1A
PMID:11967147 FYPO:0000274 Fig 1A
PMID:11967147 FYPO:0000274 Fig 1A
PMID:11967147 FYPO:0002060 figure S1
PMID:11967147 FYPO:0001840 Fig 1C
PMID:11967147 FYPO:0002060 figure S1 (20% longer)
PMID:11967147 PBO:0024749 fig2d
PMID:11967147 PBO:0024749 fig2d
PMID:11967147 FYPO:0002060 figure S1
PMID:11967147 FYPO:0001840 DNs
PMID:11967147 FYPO:0001840 DNS
PMID:11967147 FYPO:0002061 fig 5A
PMID:11967147 FYPO:0002061 fig 5A
PMID:11967147 FYPO:0002061 fig 5A
PMID:11967147 FYPO:0000141 Figure 5B
PMID:11967147 PBO:0103982 fig2a
PMID:11967147 PBO:0103982 fig2a
PMID:11972332 PBO:0109322 Figure 1A
PMID:11973289 FYPO:0002061 "Alleles with ""not specified"" expression were under nmt promoter, I think not induced (but I'm not sure how the resulting exp level compares with endogenous)."
PMID:11973289 FYPO:0002061 "Alleles with ""not specified"" expression were under nmt promoter, I think not induced (but I'm not sure how the resulting exp level compares with endogenous)."
PMID:11973289 FYPO:0002061 "Alleles with ""not specified"" expression were under nmt promoter, I think not induced (but I'm not sure how the resulting exp level compares with endogenous)."
PMID:11973289 FYPO:0001276 "Alleles with ""not specified"" expression were under nmt promoter, I think not induced (but I'm not sure how the resulting exp level compares with endogenous)."
PMID:11973289 FYPO:0001276 "Alleles with ""not specified"" expression were under nmt promoter, I think not induced (but I'm not sure how the resulting exp level compares with endogenous)."
PMID:11973289 FYPO:0002061 "Alleles with ""not specified"" expression were under nmt promoter, I think not induced (but I'm not sure how the resulting exp level compares with endogenous)."
PMID:11973289 FYPO:0001278 "Alleles with ""not specified"" expression were under nmt promoter, I think not induced (but I'm not sure how the resulting exp level compares with endogenous)."
PMID:12000964 FYPO:0004588 (vw: delayed)
PMID:12000964 FYPO:0003438 (vw: I added this as an inference, because the checkpoint is never satisfied)
PMID:12000964 FYPO:0003545 (vw: I added this as an inference, because the checkpoint is never satisfied)
PMID:12000964 FYPO:0000611 (vw: DNA checkpoint dept)
PMID:12006645 FYPO:0002059 tetrads only
PMID:12006658 GO:0005737 "can't capture punctate cytoplasmic localization during heat or osmotic stress, because there isn't a suitable GO CC term, and they wouldn't add something as vague as ""cytoplasmic focus"""
PMID:12006658 FYPO:0003125 polysome profiling
PMID:12006658 PBO:0105175 assayed by incorporation of labeled methionine
PMID:12006658 PBO:0105174 assayed by incorporation of labeled methionine
PMID:12006658 GO:0002183 taking authors' word that ribosome profiling phenotype is specific enough to infer role in translation initiation
PMID:12007420 PBO:0099942 Fig1
PMID:12007420 PBO:0103187 Fig2A
PMID:12007420 PBO:0103188 Fig2D (jvh: no tea3GFP staining cell middle in nda3 block)
PMID:12007420 PBO:0103189 Fig2D (jvh: tea3GFP staining cell middle after nda3 block and release)
PMID:12007420 PBO:0103190 Fig3C
PMID:12007420 PBO:0103191 Fig 3D
PMID:12007420 FYPO:0002061 Fig3B
PMID:12007420 PBO:0103192 Fig4A
PMID:12007420 PBO:0103192 Fig4C
PMID:12007420 PBO:0097442 Fig4B
PMID:12007420 PBO:0019143 Fig4D (jvh: tea3 does not affect polarity and the elongated cells do not branch. This is different to pom1 where cdc11-119 cells form branches)
PMID:12007420 FYPO:0001406 Fig3B
PMID:12007420 FYPO:0002452 Fig3B
PMID:12007420 FYPO:0002060 Fig3B
PMID:12007420 FYPO:0002060 Fig3B
PMID:12007420 FYPO:0002060 Fig3B
PMID:12007420 PBO:0103185 Fig1 C
PMID:12007420 PBO:0101140 Fig1D
PMID:12007420 PBO:0103186 localisation of tea3 is a late event in septation
PMID:12007420 GO:0051285 localises at both ends, slightly enriched at non growing end
PMID:12007420 PBO:0101140 Fig1D
PMID:12007420 PBO:0103185 Fig1 C
PMID:12007420 FYPO:0003150 Fig1B
PMID:12019258 FYPO:0005431 assayed using 160-bp palindromic sequence inserted into ade6 locus
PMID:12019258 GO:0042138 assayed using 160-bp palindromic sequence inserted into ade6 locus
PMID:12019258 FYPO:0005431 assayed using 160-bp palindromic sequence inserted into ade6 locus
PMID:12019258 FYPO:0005432 assayed using 160-bp palindromic sequence inserted into ade6 locus
PMID:12019258 FYPO:0005431 assayed using 160-bp palindromic sequence inserted into ade6 locus
PMID:12019258 FYPO:0005433 assayed using 160-bp palindromic sequence inserted into ade6 locus
PMID:12023299 PBO:0093620 (mah: same as rqh1delta alone)
PMID:12023299 PBO:0093619 (mah: same as rad51delta alone)
PMID:12023299 PBO:0093619 (mah: same as rad51delta alone)
PMID:12023299 PBO:0093619 (mah: same as rad51delta alone)
PMID:12023299 PBO:0093629 (mah: same as rad51delta alone)
PMID:12023299 PBO:0093629 (mah: same as rad51delta alone)
PMID:12023299 PBO:0093619 (mah: same as rad51delta alone)
PMID:12023299 PBO:0101530 (mah: same as rad51delta alone)
PMID:12023299 PBO:0100481 (mah: slighly more severe than rad50delta alone)
PMID:12023299 PBO:0101530 (mah: same as rad51delta alone)
PMID:12023299 PBO:0101526 (mah: residue=T215)
PMID:12023299 PBO:0096052 (mah: assayed substrate: exogenous histone H1)
PMID:12023299 GO:0000724 (mah: localization to DSB sites also contributes to inference)
PMID:12023299 PBO:0093620 (mah: sensitivity depends on how highly overexpressed top3+ is; more top3+ -> lower sensitivity)
PMID:12034771 PBO:0103836 Fig3C, Fig5A STILL TO ADD curved around cell end during mitotic interphase
PMID:12034771 PBO:0037574 Fig5B
PMID:12034771 PBO:0018421 used endogenous tea2 gene tagged at C term with GFP. Fig1A
PMID:12034771 PBO:0037211 used endogenous tea1 gene tagged at C term with YFP and tubulin CFP for live cell imaging of tea1 on microtubules Fig1C
PMID:12034771 PBO:0103829 used endogenous tea2 gene tagged at C term with GFP. Fig1A
PMID:12034771 PBO:0103830 Figure 2A
PMID:12034771 PBO:0103831 Fig2C OUTSTANDING Q IS IT ALONG OR ON?
PMID:12034771 PBO:0103837 Fig6
PMID:12034771 PBO:0103838 Fig6
PMID:12034771 PBO:0103839 Fig6
PMID:12034771 PBO:0103834 Fig3C
PMID:12034771 PBO:0103832 Fig3C
PMID:12034771 PBO:0103833 Fig3C
PMID:12034771 PBO:0037573 Fig5B
PMID:12034771 FYPO:0003702 Fig5A
PMID:12034771 FYPO:0003702 Fig5A
PMID:12034771 PBO:0037573 Fig5B
PMID:12034771 PBO:0103835 Fig4B
PMID:12034771 PBO:0100778 Fig4B. I know that the protein is localising to the plus end but they did not say this in this paper although they do say it is on the tips of polymerizing microtubules so it could be FYPO 0004731
PMID:12034771 PBO:0103831 Fig4A
PMID:12034771 PBO:0103834 Fig3C
PMID:12034771 PBO:0103834 Fig3C
PMID:12050156 FYPO:0000116 The growth of the resulting zym1� showed only a small but reproducible impairment in rich me- dium (YE5S) supplemented with 10 –100 �M zinc (Fig. 5A).
PMID:12050156 PBO:0111362 Zinc caused the accumulation of zym1 transcripts with up to 10 –20-fold increase 30 min after the addition of ZnSO4 (Fig. 3, A and C).
PMID:12050156 PBO:0110448 Most importantly, the zhf� strain was hypersensitive to zinc showing impaired growth on rich medium (YE5S) compared with the equivalent control strain and was unable to grow in medium supplemented with 20 �M ZnSO4 (Fig. 1C).
PMID:12050156 PBO:0110450 Both the basal and zinc-induced levels of zym1 transcripts were severely reduced in wis1� (Fig. 3C).
PMID:12050156 PBO:0110448 FIG. 1. Zhf is required for growth on high and low zinc
PMID:12050156 PBO:0110449 FIG. 1. Zhf is required for growth on high and low zinc
PMID:12050156 PBO:0110449 Zhf Is Required for Growth on Low Zinc
PMID:12050156 PBO:0093530 Cadmium increased the proportion of longer zym1 transcripts as observed previously following the exposure to copper (Fig. 6B).
PMID:12050156 PBO:0110451 but this pathway is not obligatory for zinc perception because zinc induction was retained in Wis1 mutants albeit at reduced magnitude.
PMID:12050156 PBO:0110451 The abundance of zym1 transcripts was also re- duced in cells lacking Pcr1, a bZIP transcription factor that in conjunction with Atf1 functions downstream of Sty1 (41, 42) (Fig. 3C).
PMID:12058079 GO:0043139 activated_by(CHEBI:18420)
PMID:12062100 PBO:0092132 longer transcript
PMID:12062100 PBO:0097585 longer transcript
PMID:12062100 PBO:0097586 longer transcript
PMID:12065422 FYPO:0000620 Figure 2B and C
PMID:12065422 FYPO:0002061 Introduction of either ®n1.ts1 or ®n1.D to a cut12.s11 cdc25.22 mutant background abolished the growth of cdc25.22 above 30°C that had been conferred by the cut12.s11 mutation (Figure 6C).
PMID:12065422 PBO:0095089 25 degrees figure 7
PMID:12065422 PBO:0095088 25 degrees figure 7
PMID:12065422 PBO:0095087 25 degrees figure5d
PMID:12065422 PBO:0095086 figure 5d
PMID:12065422 FYPO:0002061 DNS
PMID:12065422 FYPO:0002061 DNS
PMID:12065422 FYPO:0003481 Table II
PMID:12065422 FYPO:0001124 Table II
PMID:12065422 FYPO:0001124 recessive, loss- of-function mutation
PMID:12065422 FYPO:0003481 Figure 2A; Table II
PMID:12065422 FYPO:0001399 recessive, loss- of-function mutation
PMID:12065422 PBO:0095085 Figures 1C and 2C
PMID:12065422 PBO:0095083 Figure 1A. We concluded that the severe phenotype of a ®n1.ts1 mutant is a transitory response to loss of Fin1 function. This implied that ®n1.D haploids adapted to loss of Fin1 after the ®rst division of a germinating spore.
PMID:12065422 PBO:0095084 Figure 1B
PMID:12065422 PBO:0095084 Figure 1C
PMID:12065422 PBO:0095084 Figure 1C
PMID:12074602 PBO:0111133 binds to 54-bp element at 1186-1239
PMID:12093738 PBO:0100979 Fig1C
PMID:12093738 FYPO:0003449 Fig5A lower panel
PMID:12093738 PBO:0100986 Fig 4A cells block normally with 1C DNA content even when cig2 is over expressed
PMID:12093738 PBO:0024304 Fig1A
PMID:12093738 PBO:0100985 Fig5B
PMID:12093738 FYPO:0000017 Fig5A lower panel used forward scatter to measure cell size
PMID:12093738 PBO:0100990 Fig1D
PMID:12093738 PBO:0100989 Fig1D The protein cdc2 protein assayed is in complex with cig2 as there is no cdc2-cdc13 complex present
PMID:12093738 PBO:0099888 Fig2C the cdc2-cig2 and cdc2-cdc13 complexes have increased kinase activity
PMID:12093738 PBO:0100980 Fig2C the cdc2-cig2 and cdc2-cdc13 complexe have no tyrosine 15 phosphorylation
PMID:12093738 PBO:0100981 Fig 4B cig2 over expression also occurs when cells blocked with HU
PMID:12093738 PBO:0099234 Fig 3A, D
PMID:12093738 PBO:0100981 Fig 3C cig2 over expression from ~10hours after thiamine removal
PMID:12093738 PBO:0100982 Fig 3B no G1 peak is observed showing that S phase onset is not delayed
PMID:12093738 PBO:0100983 Fig5A small peak of less that 1C DNA content
PMID:12093738 PBO:0019210 Fig 3 data not shown cell viability is reduced at late time points
PMID:12093738 PBO:0100984 Fig5A used forward scatter to measure cell size small peak of short cells
PMID:12093738 PBO:0100978 Fig1C
PMID:12093738 PBO:0100988 fypo/issues/3165 Fig5C
PMID:12093738 PBO:0100977 Fig1C
PMID:12093738 PBO:0100987 Fig5C
PMID:12093738 PBO:0093769 fypo/issues/3165 Fig5B in the absence of cig2 there is a delay in the appearance of cut cells
PMID:12112233 FYPO:0003027 Figure 1
PMID:12112233 FYPO:0001357 Figure 1
PMID:12112233 FYPO:0002522 actually accumulation
PMID:12181326 FYPO:0006661 data not shown
PMID:12181336 PBO:0107186 Fig 4
PMID:12181336 PBO:0107193 fig7
PMID:12181336 PBO:0107192 fig7
PMID:12181336 PBO:0107189 fig has 6
PMID:12181336 PBO:0107191 small amount
PMID:12181336 PBO:0107189 fig 5
PMID:12181336 PBO:0107189 fig 5
PMID:12181336 PBO:0107189 fig 5
PMID:12181336 GO:0005737 fig 5 Consistent with previous immunolocalization studies (Gaits et al., 1998), wild-type Wis1-GFP showed solely cytoplasmic localization and little GFP signal was seen in the nuclear region (Figure 5A).
PMID:12181336 PBO:0107188 Fig 4
PMID:12181336 PBO:0107187 Fig 4
PMID:12181336 PBO:0107182 2 B
PMID:12181336 PBO:0107185 Fig 3
PMID:12181336 PBO:0107182 2 B
PMID:12181336 PBO:0107184 Fig 3
PMID:12181336 PBO:0107184 Fig 3
PMID:12181336 PBO:0107183 Fig 3
PMID:12181336 PBO:0107183 Fig 3
PMID:12181336 PBO:0107181 2B
PMID:12185500 FYPO:0002061 27 degrees C
PMID:12185500 FYPO:0002060 25 degrees C
PMID:12185500 FYPO:0002061 25 degrees C
PMID:12185500 FYPO:0002061 25 degrees C
PMID:12185500 FYPO:0002061 27 degrees C
PMID:12185500 FYPO:0002061 29 degrees C
PMID:12185500 FYPO:0002061 29 degrees C
PMID:12185500 FYPO:0000082 restrictive temp 36
PMID:12185500 FYPO:0000082 restrictive temp 32
PMID:12185840 GO:0005739 fig 2 C
PMID:12185840 PBO:0101611 Figure 2C
PMID:12186944 GO:0032153 localization requires microtubules (assayed using thiabendazole or carbendazim) but not F-actin (assayed using latrunculin A)
PMID:12186947 PBO:0021453 penetrance low if cells exposed to UV
PMID:12193640 PBO:0107146 As expected, Swi6, which depends on histone modification for chromatin binding, was de- localized from the ura4� transgenes (Fig. 3C).
PMID:12193640 PBO:0107146 As expected, Swi6, which depends on histone modification for chromatin binding, was de- localized from the ura4� transgenes (Fig. 3C).
PMID:12193640 FYPO:0003412 Two transgenes located centromere distal to the tRNA genes were de-repressed in ago1– , dcr1– , and rdp1– , but a transgene located within the central region remained silent. Similar results were obtained in all three mutant strains, as assayed by growth on me- dium lacking uracil and by Northern blots (Fig. 1, B) (21).
PMID:12193640 FYPO:0004331 Two transgenes located centromere distal to the tRNA genes were de-repressed in ago1– , dcr1– , and rdp1– , but a transgene located within the central region remained silent. Similar results were obtained in all three mutant strains, as assayed by growth on me- dium lacking uracil and by Northern blots (Fig. 1, B) (21).
PMID:12193640 FYPO:0003096 . In contrast, levels of K9 were greatly reduced.
PMID:12193640 FYPO:0003412 Two transgenes located centromere distal to the tRNA genes were de-repressed in ago1– , dcr1– , and rdp1– , but a transgene located within the central region remained silent. Similar results were obtained in all three mutant strains, as assayed by growth on me- dium lacking uracil and by Northern blots (Fig. 1, B) (21).
PMID:12193640 FYPO:0003412 Two transgenes located centromere distal to the tRNA genes were de-repressed in ago1– , dcr1– , and rdp1– , but a transgene located within the central region remained silent. Similar results were obtained in all three mutant strains, as assayed by growth on me- dium lacking uracil and by Northern blots (Fig. 1, B) (21).
PMID:12193640 FYPO:0007337 dcr1– , rdp1– , and ago1– cells had increased levels of K4 in the centromeric region in comparison to actin controls (Fig. 3B).
PMID:12193640 PBO:0107146 As expected, Swi6, which depends on histone modification for chromatin binding, was de- localized from the ura4� transgenes (Fig. 3C).
PMID:12193640 PBO:0094684 However, three major transcripts that hybridized to the repeats were found to accumulate at high levels in each of the RNAi mutants (Fig. 1C).
PMID:12193640 FYPO:0003096 . In contrast, levels of K9 were greatly reduced.
PMID:12193640 FYPO:0003096 . In contrast, levels of K9 were greatly reduced.
PMID:12193640 PBO:0097227 These transcripts were also found in swi6– (Fig. 1D) but at a much lower lev
PMID:12193640 FYPO:0004331 Two transgenes located centromere distal to the tRNA genes were de-repressed in ago1– , dcr1– , and rdp1– , but a transgene located within the central region remained silent. Similar results were obtained in all three mutant strains, as assayed by growth on me- dium lacking uracil and by Northern blots (Fig. 1, B) (21).
PMID:12193640 FYPO:0004331 Two transgenes located centromere distal to the tRNA genes were de-repressed in ago1– , dcr1– , and rdp1– , but a transgene located within the central region remained silent. Similar results were obtained in all three mutant strains, as assayed by growth on me- dium lacking uracil and by Northern blots (Fig. 1, B) (21).
PMID:12193640 PBO:0094684 However, three major transcripts that hybridized to the repeats were found to accumulate at high levels in each of the RNAi mutants (Fig. 1C).
PMID:12193640 PBO:0094684 However, three major transcripts that hybridized to the repeats were found to accumulate at high levels in each of the RNAi mutants (Fig. 1C).
PMID:12193640 FYPO:0007337 dcr1– , rdp1– , and ago1– cells had increased levels of K4 in the centromeric region in comparison to actin controls (Fig. 3B).
PMID:12193640 FYPO:0007337 dcr1– , rdp1– , and ago1– cells had increased levels of K4 in the centromeric region in comparison to actin controls (Fig. 3B).
PMID:12196391 PBO:0093637 same as rad3delta alone
PMID:12196391 PBO:0093637 same as rad3delta alone
PMID:12196391 PBO:0093637 same as rad26delta alone
PMID:12196391 PBO:0093633 same as either single mutant
PMID:12196391 PBO:0093637 same as rad3delta alone
PMID:12196391 PBO:0093633 same as either single mutant
PMID:12196391 PBO:0093637 same as rad3delta alone
PMID:12207036 FYPO:0002060 Fig 6
PMID:12207036 FYPO:0002060 Fig 6
PMID:12207036 FYPO:0002060 Fig 6
PMID:12242222 FYPO:0002946 fig 4 e
PMID:12242222 FYPO:0000647 fig 4
PMID:12242222 FYPO:0005870 fig 4
PMID:12242294 FYPO:0002638 fig 8a
PMID:12242294 PBO:0099328 data not shown
PMID:12242294 FYPO:0004085 fig 8a
PMID:12242294 FYPO:0001355 fig 8a
PMID:12242294 PBO:0095634 fig8d
PMID:12242294 FYPO:0002061 fig8d
PMID:12242294 PBO:0103973 data not shown
PMID:12242294 PBO:0103974 data not shown
PMID:12242294 FYPO:0001355 fig 8b
PMID:12242294 FYPO:0002638 fig 8a
PMID:12242294 FYPO:0001355 fig 8b
PMID:12242294 FYPO:0000324 fig 1a
PMID:12242294 PBO:0034020 figure 9
PMID:12242294 FYPO:0002390 fig 1a (maintenence of)
PMID:12242294 PBO:0103972 data not shown
PMID:12354095 PBO:0093558 Fig. 1
PMID:12354095 PBO:0093558 Fig. 5B
PMID:12354095 PBO:0095096 Fig. 5C and D
PMID:12354095 FYPO:0001406 Fig. 6
PMID:12354095 PBO:0101760 Fig. 1
PMID:12354095 FYPO:0005970 Fig. 1
PMID:12354095 PBO:0093558 Fig. 1
PMID:12354095 FYPO:0000118 Fig. 2B
PMID:12354095 FYPO:0001315 Fig. 2B
PMID:12354095 FYPO:0001315 Fig. 2B
PMID:12354095 FYPO:0001315 Fig. 2B
PMID:12354095 FYPO:0001315 Fig. 2B
PMID:12354095 FYPO:0001315 Fig. 2B
PMID:12354095 PBO:0094642 Fig. 2B
PMID:12354095 PBO:0104246 Fig. 2B
PMID:12354095 PBO:0112776 Fig. 2B
PMID:12354095 FYPO:0000674 Fig. 2C
PMID:12354095 FYPO:0000674 Fig. 2C
PMID:12354095 PBO:0112777 Fig. 3A and D
PMID:12354095 PBO:0112778 Fig. 3B and D
PMID:12354095 PBO:0112779 Fig. 3C and D
PMID:12354095 PBO:0112780 Fig. 3B and D
PMID:12354095 PBO:0112781 Fig. 3C and D
PMID:12354095 PBO:0110822 Fig. 3A and D
PMID:12354095 PBO:0112782 Fig. 3B and D
PMID:12354095 PBO:0112783 Fig. 3C and D
PMID:12354095 PBO:0112784 Fig. 3B and D
PMID:12354095 FYPO:0001357 Fig. 1
PMID:12354095 FYPO:0001357 Fig. 1
PMID:12354095 PBO:0093641 Fig. 1
PMID:12354095 PBO:0093641 Fig. 1
PMID:12354095 PBO:0101752 Fig. 1
PMID:12354095 PBO:0101752 Fig. 1
PMID:12354095 PBO:0112785 Fig. 3C and D
PMID:12354095 PBO:0093641 Fig. 4A
PMID:12354095 PBO:0093558 Fig. 4A
PMID:12354095 PBO:0093641 Fig. 4B
PMID:12354095 PBO:0093641 Fig. 4B
PMID:12354095 PBO:0093641 Fig. 4B
PMID:12354095 FYPO:0001470 Fig. 4B
PMID:12354095 FYPO:0001470 Fig. 4A
PMID:12354095 PBO:0093558 Fig. 4A
PMID:12354095 PBO:0093558 Fig. 4B
PMID:12354095 PBO:0093558 Fig. 4B
PMID:12354095 PBO:0093558 Fig. 4B
PMID:12354095 PBO:0093558 Fig. 4B
PMID:12354095 PBO:0093557 Fig. 5A
PMID:12354095 PBO:0093557 Fig. 5A
PMID:12354095 PBO:0093557 Fig. 5A
PMID:12354095 PBO:0093558 Fig. 5A
PMID:12354095 PBO:0093557 Fig. 5B
PMID:12354095 PBO:0093557 Fig. 5B
PMID:12354095 PBO:0093558 Fig. 5B
PMID:12390246 FYPO:0005349 fig 4a b
PMID:12390246 PBO:0034014 penetrance is mentioned in EXP accompanying fig 6A
PMID:12390246 PBO:0034015 penetrance is mentioned in EXP accompanying fig 6A
PMID:12390246 PBO:0034018 penetrance is mentioned in EXP accompanying fig 6A
PMID:12390246 PBO:0034017 penetrance is mentioned in EXP accompanying fig 6A
PMID:12390246 PBO:0034016 penetrance is mentioned in EXP accompanying fig 6A
PMID:12390246 PBO:0034015 Fig 6A
PMID:12399381 GO:0005737 fig 5A
PMID:12399381 GO:0034399 fig 5A
PMID:12399381 PBO:0037055 figure 5 CD
PMID:12399381 PBO:0107302 figure 4 cdr phenotype
PMID:12399381 PBO:0107304 figure 4 cdr phenotype
PMID:12399381 PBO:0107304 figure 4 cdr phenotype
PMID:12399381 PBO:0107304 figure 4 cdr phenotype
PMID:12399381 PBO:0107304 figure 4 cdr phenotype
PMID:12399381 PBO:0107305 fig5
PMID:12399381 GO:0005634 fig 5A
PMID:12399381 FYPO:0000590 fig 5 CD
PMID:12399381 PBO:0094730 figure 6A
PMID:12399381 PBO:0094966 semi wee
PMID:12399381 PBO:0107308 figure 6 b during x phase?
PMID:12399381 FYPO:0006822 table4
PMID:12399381 PBO:0107305 fig5
PMID:12399381 PBO:0107305 fig5
PMID:12399381 PBO:0107309 figure1 cdr phenotype
PMID:12399381 PBO:0037050 figure1
PMID:12399381 PBO:0107302 figure1 cdr phenotype
PMID:12399381 PBO:0095634 figure1
PMID:12399381 PBO:0095685 figure1
PMID:12399381 PBO:0037050 figure2a
PMID:12399381 PBO:0095634 figure2a
PMID:12399381 PBO:0107303 figure 2C/D
PMID:12399381 FYPO:0001490 figure 3
PMID:12399381 PBO:0107302 figure 4 cdr phenotype
PMID:12399381 PBO:0107302 figure 4 cdr phenotype
PMID:12399381 PBO:0107302 figure 4 cdr phenotype
PMID:12411492 PBO:0107489 same as plo1-ts35 alone
PMID:12411492 PBO:0107491 same as plo1-ts35 alone
PMID:12411492 PBO:0107490 same as plo1-ts35 alone
PMID:12419251 PBO:0100913 actually ectopic expression, throughout cell cycle
PMID:12419251 PBO:0105826 normal binding periodicity over cell cycle
PMID:12419251 PBO:0105826 normal binding periodicity over cell cycle
PMID:12419251 PBO:0097194 normal binding periodicity over cell cycle
PMID:12419251 FYPO:0000333 actually ectopic expression, throughout cell cycle
PMID:12426374 FYPO:0000141 figure 1 B
PMID:12426374 FYPO:0006179 Figure 1B rows 4±6
PMID:12426374 PBO:0092680 Figure 1A and C
PMID:12426374 FYPO:0006179 (see rows 4±6 in Figure 1B)
PMID:12426374 FYPO:0006179 (see rows 4±6 in Figure 1B)
PMID:12426374 PBO:0092680 Figure 1A and C
PMID:12426374 FYPO:0002638 (vw: assayed by increased mad2 at kinetochore - checkpoint active)
PMID:12426374 FYPO:0006190 (vw: assayed by increased mad2 at kinetochore - checkpoint active)
PMID:12427731 GO:0004672 assayed using myelin basic protein; doesn't rule out tyrosine phosphorylation
PMID:12427731 GO:0007163 based just on this paper, candidate for involved_in_or_regulates qualifier
PMID:12427731 PBO:0097508 substrate myelin basic protein
PMID:12442907 FYPO:0003481 (Figs. 3A and 3B). there were cells that initiated and completed the mitosis in a small portion (Table 1), which eventually led to cell proliferation until the stationary phase (Fig. 2A).
PMID:12442907 FYPO:0000636 fig 1b The estimated doubling time of the mutant was 110 min in a rich (YE) medium, while that of the wild-type cells was 150 min.
PMID:12442907 FYPO:0001234 As shown in Fig. 2A, the rate of cell proliferation was immediately reduced after the amount of Rrg1 was increased.
PMID:12442907 FYPO:0003306 Table 1
PMID:12442907 FYPO:0007628 (Figs. 3A and 3B).
PMID:12442907 FYPO:0001406 a considerable portion of the Rrg1-overproduced cells that undergo mitosis showed an abnormal accumulation of septum material (Figs. 3F, 3G, and 3H).
PMID:12442907 FYPO:0006822 small daughter at g1 Fig 1c The mutant produced daughter cells with an average length of 6 μm; whereas, the wild-type cells averaged 7.5 μm
PMID:12442907 FYPO:0001046 Fig 1c The mutant produced daughter cells with an average length of 6 μm; whereas, the wild-type cells averaged 7.5 μm
PMID:12455694 FYPO:0002061 32 degrees; mcl1-1 semi-permissive
PMID:12455694 FYPO:0002061 32 degrees; mcl1-1 semi-permissive
PMID:12455993 GO:0031533 Surprisingly, the S. pombe capping enzyme subunits do not interact with each other.
PMID:12455993 GO:0031533 Surprisingly, the S. pombe capping enzyme subunits do not interact with each other.
PMID:12479804 FYPO:0005781 Table1
PMID:12479804 FYPO:0005781 Table1
PMID:12479804 PBO:0095090 fig 5
PMID:12479804 FYPO:0005781 Table1
PMID:12479804 FYPO:0005781 Table1
PMID:12479804 PBO:0096053 fig6
PMID:12479804 FYPO:0004106 Figure 2
PMID:12479804 FYPO:0005781 Table1
PMID:12479804 PBO:0022584 Figure 3A, panel 3
PMID:12479804 PBO:0105158 Figures 3E and 3F
PMID:12479804 PBO:0105155 Figure 2A, panels 11 and 14
PMID:12479804 PBO:0105154 fig 1B
PMID:12479804 GO:0031030 The observation that Clp1p/Flp1p is required for sep- tation in dma1 mutants is consistent with a model where Dma1p inhibits SIN activation
PMID:12479804 FYPO:0003762 fig 1A I'm modelling this as normal becasue nda3 is providing microtubule damage. Checkpoint would be expected to be o in WT in this scenario. cells failed to maintain the microtubule damage-induced checkpoint arrest and began to aberrantly form septa
PMID:12479804 FYPO:0005781 fig 1A I'm modelling this as decreased because nda3 is providing microtubule damage. Checkpoint would be expected to be o in WT in this scenario. cells failed to maintain the microtubule damage-induced checkpoint arrest and began to aberrantly form septa
PMID:12479804 PBO:0105163 Figure 4A
PMID:12479804 PBO:0105160 Figure 4B)
PMID:12479804 PBO:0105164 igure 4C, bottom
PMID:12479804 PBO:0105165 igure 4C, bottom
PMID:12479804 GO:0005515 Fig4
PMID:12479804 PBO:0094087 Figure 5
PMID:12479804 PBO:0105159 Figures 3E and 3F
PMID:12479804 PBO:0096052 fig6
PMID:12479804 PBO:0101132 Figure 5
PMID:12479804 PBO:0096153 Figures 3E and 3F)
PMID:12479804 PBO:0105160 Figures 3E and 3F)
PMID:12479804 PBO:0105161 Figures 3E and 3F)
PMID:12479804 PBO:0105160 Figures 3E and 3F)
PMID:12479804 PBO:0105160 Figures 3E and 3F)
PMID:12479804 PBO:0105156 Figure 2A, panels 11 and 14
PMID:12479804 PBO:0100276 Figure 2D
PMID:12479804 PBO:0024374 (faintly) Figure 3A, panel 2, arrowhead
PMID:12479804 PBO:0105157 Figure 3A, panel 3
PMID:12479804 PBO:0105161 Figures 3E and 3F)
PMID:12479804 PBO:0105161 Figures 3E and 3F)
PMID:12479804 PBO:0105162 Figure 4A 10% (2/20) of anaphase cells displayed Dma1p-GFP SPB signal
PMID:12482946 PBO:0098309 Fig. 2B
PMID:12482946 FYPO:0002834 Fig. 2B
PMID:12482946 PBO:0098308 Fig. 2A
PMID:12482946 FYPO:0000091 Fig. 1D
PMID:12482946 PBO:0098310 Fig. 2B
PMID:12482946 FYPO:0000220 Fig. 2B
PMID:12526748 PBO:0106600 figure1e
PMID:12526748 PBO:0106599 figure1e
PMID:12526748 PBO:0106598 figure1e
PMID:12526748 PBO:0106594 Figure S1
PMID:12526748 PBO:0106607 fig3
PMID:12526748 PBO:0106606 fig3
PMID:12526748 PBO:0093562 fig1
PMID:12526748 PBO:0093562 fig1
PMID:12526748 FYPO:0006993 fig1b
PMID:12526748 PBO:0106605 fig3
PMID:12526748 PBO:0096191 Figure S1
PMID:12526748 PBO:0096039 D.N.S?
PMID:12526748 PBO:0106603 Pst1p colocalizes with the otr/imr region in a cell cycle-specific manner.
PMID:12526748 PBO:0106604 fig3
PMID:12526748 PBO:0106605 fig3
PMID:12526748 PBO:0106602 D.N.S?
PMID:12526748 PBO:0093562 fig1
PMID:12526748 FYPO:0002827 Figure S1
PMID:12526748 FYPO:0003411 Figure S1
PMID:12526748 PBO:0106607 fig3
PMID:12526748 PBO:0106606 fig3
PMID:12526748 PBO:0096770 fig1
PMID:12526748 PBO:0106604 fig3
PMID:12526748 PBO:0096785 D.N.S?
PMID:12526748 PBO:0106597 figure1e
PMID:12526748 PBO:0106596 figure1e
PMID:12526748 PBO:0106595 Figure 1C
PMID:12546793 FYPO:0007890 (Figure 2B). Immunofluorescence showed that byr4p was also present on the SPB in the arrested cells
PMID:12546793 GO:0032991 SIN signalling complex
PMID:12546793 PBO:0094976 Less than 10% of these cells had cdc7p on the spindle pole body, consistent with previous studies [25].
PMID:12546793 PBO:0094973 (Figure 3B). However, at 36C, when cdc11p is no longer associated with the SPB [3, 4], most of the cdc11p was hypophosphory- lated (form 1)
PMID:12546793 PBO:0094968 (Figure 1A) In a mob1-R4 byr4::ura4 mutant, and also in cdc16-116 grown for 5 hr at 36C, cdc11p accumulated in the hyperphosphorylated (3) form
PMID:12546793 PBO:0094968 (Figure 1A) In a mob1-R4 byr4::ura4 mutant, and also in cdc16-116 grown for 5 hr at 36C, cdc11p accumulated in the hyperphosphorylated (3) form. Later: in mutants such as cdc16-116 or byr4::ura4, in which cdc7p is present on both spindle pole bodies, the hyperphosphorylated form (3) of cdc11p is more abundant.
PMID:12546793 PBO:0094969 (Figure 1B) n G2-arrested cdc2-17 cells overexpressing spg1p, cdc11p was predominantly in the hyperphosphorylated form
PMID:12546793 GO:0031028 HYPERPHOSPHORYLATD FORM Together, these data demonstrate, first, that mitotic cdc2p activity is not required for hyperphosphorylation of cdc11p and, second, that activation of the SIN correlates with accu- mulation of hyperphosphorylated cdc11p.
PMID:12546793 PBO:0094970 HYPERPHOSPHORYLATION (Figure 1C) In the mutant plo1-ts4, which is defective in SIN signaling but not spindle formation [10], hyperphosphorylated cdc11p was observed during mi- tosis, even though the cells were not septating .
PMID:12546793 PBO:0094971 (Figure 1C, and data not shown) Immunofluorescence indicated that both byr4p and cdc7p showed a normal, asymmetric distribution during mitosis
PMID:12546793 PBO:0094972 (Figure 1C, and data not shown) Immunofluorescence indicated that both byr4p and cdc7p showed a normal, asymmetric distribution during mitosis
PMID:12546793 PBO:0094970 (see the Supplementary) Additional experiments indicated that neither mph1p nor fin1p regulate the phosphorylation of cdc11p
PMID:12546793 PBO:0094970 (see the Supplementary) Additional experiments indicated that neither mph1p nor fin1p regulate the phosphorylation of cdc11p
PMID:12546793 PBO:0094970 (see the Supplementary) Additional experiments indicated that neither mph1p nor fin1p regulate the phosphorylation of cdc11p
PMID:12546793 PBO:0094970 (Figure 1D) The hyperphosphorylated form (3) of cdc11p was observed during mitosis in both sid2-250 and sid1- 239 mutants
PMID:12546793 PBO:0094970 (Figure 1D) The hyperphosphorylated form (3) of cdc11p was observed during mitosis in both sid2-250 and sid1- 239 mutants
PMID:12546793 PBO:0094970 (Figure 1D) The hyperphosphorylated form (3) of cdc11p was observed during mitosis in both sid2-250 and sid1- 239 mutants
PMID:12546793 PBO:0094973 (Figure 1E) In contrast, in cdc7-24, the hyperphosphorylated form of cdc11p (3) was greatly reduced, and the intensity of the hypophos- phorylated forms (1 and 2) increased
PMID:12546793 PBO:0094973 (DNS)
PMID:12546793 PBO:0094973 (Figure 1G) No significant hyperphosphorylation of cdc11p occurred at 36C.
PMID:12546793 PBO:0108961 In contrast, in cdc7-24, the hyperphosphorylated form of cdc11p (3) was greatly reduced, and the intensity of the hypophos- phorylated forms (1 and 2) increased (Figure 1E). A simi- lar result was observed in cdc7-A20 (data not shown). Furthermore, no mitotic hyperphosphorylation of cdc11p was seen in spg1-B8 at the nonpermissive temperature (Figure 1E), when cdc7p does not localize to the SPB [13]. Finally, when cdc7 was expressed ectopically in G2-arrested cells, cdc11p accumulated in the hyper- phosphorylated form (3) (Figure 1F).
PMID:12546793 PBO:0094973 (Figure 1G) No significant hyperphosphorylation of cdc11p occurred at 36C .
PMID:12546793 GO:0032991 SIN signalling complex
PMID:12565823 FYPO:0001035 Fig 4a
PMID:12565827 PBO:0018339 Fig. 2C
PMID:12565827 PBO:0018345 Fig. 2C
PMID:12589755 FYPO:0000268 same as crb2delta alone
PMID:12604790 GO:1904931 assayed with other MCM subunits present
PMID:12606573 FYPO:0005634 figure 7A
PMID:12606573 FYPO:0005634 figure 7A
PMID:12606573 FYPO:0005634 Figure 4E
PMID:12606573 PBO:0035223 In zygotes undergoing meiotic divisions, WT Bub1±GFPp became associated with the centromeres after meiotic prophase and remained associated until anaphase I, con®rming previous reports using ®xed cells (Bernard et al., 2001; Figure 7B, WT, f±h).
PMID:12606573 PBO:0099173 decreased rate of spindle phase I elongation (70 mins. vs 40 wt)
PMID:12606573 FYPO:0000091 Figure 3A during spindle checkpoint
PMID:12606573 PBO:0099170 In zygotes undergoing meiotic divisions, WT Bub1±GFPp became associated with the centromeres after meiotic prophase and remained associated until anaphase I, con®rming previous reports using ®xed cells (Bernard et al., 2001; Figure 7B, WT, f±h).
PMID:12606573 PBO:0099171 figure 7B
PMID:12606573 PBO:0099171 figure 7B
PMID:12606573 FYPO:0005634 figure 7A
PMID:12606573 PBO:0111078 in vitro assay for activity, phenotype for process
PMID:12606573 PBO:0099173 normal rate of spindle phase I elongation. MI spindle elongation time is reduced to 40 min in rec7-146 bub1D cells (Figure 8Ad, upper panel)
PMID:12606573 PBO:0099172 Figure 7Ca
PMID:12606573 PBO:0099167 Figure 7A
PMID:12646585 GO:0071472 kinase activity increases in presence of salt
PMID:12653962 PBO:0035689 fig 6B
PMID:12653962 PBO:0106919 fig 6B
PMID:12653962 PBO:0035689 fig 6B
PMID:12653962 PBO:0106919 fig 6B
PMID:12654901 FYPO:0004097 fig 3
PMID:12654901 PBO:0101313 fig 8
PMID:12654901 FYPO:0004652 """exhibited well- defined, normal actin rings"""
PMID:12654901 FYPO:0001037 not shown
PMID:12654901 FYPO:0000674 not shown
PMID:12654901 FYPO:0001420 not shown
PMID:12654901 FYPO:0001971 fig7b
PMID:12654901 PBO:0101312 fig 7
PMID:12654901 PBO:0101311 fig7a
PMID:12654901 FYPO:0002141 not shown
PMID:12654901 FYPO:0001022 not shown
PMID:12654901 GO:0036391 Fig 6
PMID:12654901 GO:0032176 Fig 6
PMID:12654901 GO:0036391 Fig 6
PMID:12654901 PBO:0101309 fig2 maximum 3 septa
PMID:12654901 FYPO:0001971 fig2
PMID:12654901 PBO:0098144 fig 8
PMID:12654901 PBO:0101311 fig7c
PMID:12654901 FYPO:0001971 fig2
PMID:12654901 PBO:0101310 fig2 maximum 3 septa
PMID:12654901 FYPO:0001971 data not shown
PMID:12654901 FYPO:0006399 Fig. 4, B and C)I
PMID:12654901 GO:0032176 Fig 6
PMID:12668659 PBO:0101311 fig5
PMID:12668659 PBO:0098144 Fig. 7 D
PMID:12668659 GO:0036391 fig2a colocalizes with sep3
PMID:12668659 FYPO:0001234 Fig8
PMID:12668659 PBO:0106208 fig4
PMID:12668659 FYPO:0001971 fig1
PMID:12668659 FYPO:0001971 fig5
PMID:12668659 FYPO:0001971 fig5
PMID:12668659 FYPO:0000132 Fig8
PMID:12668659 FYPO:0001971 fig5
PMID:12668659 FYPO:0002060 fig1
PMID:12668659 FYPO:0001971 fig5
PMID:12668659 PBO:0106209 fig5
PMID:12668659 FYPO:0001971 fig5
PMID:12668659 PBO:0106209 fig5
PMID:12668659 PBO:0106202 Fig. 3 C
PMID:12668659 PBO:0106202 Fig. 3 C
PMID:12668659 PBO:0106207 Fig3
PMID:12668659 PBO:0106206 Fig3
PMID:12668659 PBO:0102770 fig4
PMID:12668659 FYPO:0001492 Fig8
PMID:12668659 FYPO:0006821 Fig8
PMID:12668659 PBO:0106205 Fig3
PMID:12668659 PBO:0106204 Fig3
PMID:12668659 PBO:0106203 Fig. 3 A, lanes 1 and 7 (control)
PMID:12668659 PBO:0106202 Fig. 3 A, lanes 1 and 7
PMID:12668659 GO:0031097 fig2a
PMID:12668659 PBO:0106201 unpublished obsevation
PMID:12668659 PBO:0106201 unpublished obsevation
PMID:12668659 FYPO:0000339 fig1
PMID:12668659 FYPO:0000021 Fig8
PMID:12668659 PBO:0094588 fig5
PMID:12668659 PBO:0106209 fig5
PMID:12676088 PBO:0099284 telomerase regulator
PMID:12697806 FYPO:0002687 after 100 generations
PMID:12715160 FYPO:0001490 salt stress
PMID:12715160 PBO:0020891 salt stress
PMID:12719471 FYPO:0000732 at anaphase?
PMID:12719471 FYPO:0003217 abolished
PMID:12719471 FYPO:0000732 at anaphase?
PMID:12759375 FYPO:0000737 meiosis II
PMID:12764130 PBO:0038196 Fig 4B
PMID:12764130 PBO:0103984 Fig 1B,C demonstrates in vitro kinase activity. 2A in vivo
PMID:12764130 PBO:0098304 Fig1 GST tea1 directly phosphorylated by Shk1 in vitro Fig2A GST-tea1 is phosphorylated in vivo in a Shk1 dependent manner
PMID:12764130 PBO:0102652 Fig2B. shk1 K415R mutant is expressed from a weak allele of nmt1 promoter ON but does not say whether it is expressed at wild type levels. pREP4XGST-tea1 is a multi copy plasmid promoter ON
PMID:12764130 PBO:0038194 Fig3A tea1 delta is a temperature dependent suppressor of loss of skb15
PMID:12764130 PBO:0103985 Fig 4B
PMID:12764130 PBO:0099010 Fig4C,D Cells shown a normal tea1 delta actin morphology
PMID:12764130 PBO:0103986 Fig 4E
PMID:12764130 PBO:0093701 Fig3Biii Cells shown a normal tea1 delta morphology
PMID:12764130 PBO:0038205 Fig 7B,C Penetrance refers to the penetrance of the NTR old-new end growth pattern
PMID:12764130 PBO:0038206 Fig8. pREP3X tea1 is a multi copy plasmid and is over expressed from the nmt1 promoter
PMID:12764130 PBO:0038207 Data not shown. pREP3X tea1 is a multi copy plasmid and is over expressed from the nmt1 promoter
PMID:12764130 PBO:0101140 Fig 7A
PMID:12764130 PBO:0038199 Fig4F Cells have a similar defect to a tea1 delta cell wall defect
PMID:12764130 PBO:0038200 Fig 5B
PMID:12764130 PBO:0038203 Fig6D
PMID:12764130 PBO:0038201 Fig 5C,D
PMID:12764130 PBO:0038202 Data not shown
PMID:12764130 PBO:0035685 Fig5D
PMID:12764130 PBO:0033269 Fig 6B,C
PMID:12764130 PBO:0038195 Fig3B ii
PMID:12773390 PBO:0099328 fig 4 a
PMID:12773390 GO:1905560 Figure 4A and B
PMID:12773390 GO:0000785 Figure 5B
PMID:12773390 FYPO:0002060 Fig 6 a
PMID:12773390 FYPO:0000113 figure 1 E
PMID:12773390 MOD:00046 Figure 7A and B
PMID:12773390 MOD:00047 Figure 7A and B
PMID:12773390 FYPO:0002061 figure 1 a
PMID:12773390 MOD:00046 Figure 7A and B
PMID:12773390 FYPO:0002060 figure 1 a
PMID:12773390 FYPO:0002106 figure 1 b (is described as a pair, but is cylindrical short and wide....
PMID:12773390 PBO:0092730 Fig 2
PMID:12773390 PBO:0112007 Figure 4A and B
PMID:12773390 PBO:0025603 Fig 2
PMID:12773390 FYPO:0002061 figure 1 a
PMID:12773390 PBO:0093562 fig 3 a
PMID:12773390 FYPO:0002061 Fig 6 a
PMID:12773390 GO:0005515 figure 1 F
PMID:12773390 FYPO:0000113 figure 1 E
PMID:12773390 FYPO:0000113 figure 1 E
PMID:12773390 GO:0005515 figure 1 F
PMID:12773390 FYPO:0002061 Fig 1 a
PMID:12773390 FYPO:0002060 Fig 1 a
PMID:12773390 FYPO:0000113 figure 1 E
PMID:12773390 FYPO:0002060 Fig 1 a
PMID:12773390 PBO:0093562 fig 3 a
PMID:12773390 PBO:0093562 fig 3 a
PMID:12773390 FYPO:0000964 fig 3 a
PMID:12773390 FYPO:0000964 fig 3 a
PMID:12773390 PBO:0093562 fig 3 a
PMID:12773390 PBO:0106635 fig 3 b (WT 11%)
PMID:12773390 PBO:0106636 fig 3 b (WT 11%)
PMID:12773390 PBO:0100335 fig 4 a
PMID:12773392 GO:0005634 Our analyses showed that all four proteins were localized predominantly in the nucleus on chromatin but excluded from the nucleolus (Figure 4A and B).
PMID:12773392 GO:0005634 Our analyses showed that all four proteins were localized predominantly in the nucleus on chromatin but excluded from the nucleolus (Figure 4A and B).
PMID:12773392 GO:0005730 Our analyses showed that all four proteins were localized predominantly in the nucleus on chromatin but excluded from the nucleolus (Figure 4A and B).
PMID:12773392 GO:0005730 Our analyses showed that all four proteins were localized predominantly in the nucleus on chromatin but excluded from the nucleolus (Figure 4A and B).
PMID:12773392 GO:0005730 Our analyses showed that all four proteins were localized predominantly in the nucleus on chromatin but excluded from the nucleolus (Figure 4A and B).
PMID:12773392 GO:0005730 Our analyses showed that all four proteins were localized predominantly in the nucleus on chromatin but excluded from the nucleolus (Figure 4A and B).
PMID:12773392 PBO:0093616 sensitivity to DNA-damaging agents [such as UV, methyl methane- sulfonate (MMS) and bleomycin] (Figure 5B±D)
PMID:12773392 PBO:0093587 sensitivity to DNA-damaging agents [such as UV, methyl methane- sulfonate (MMS) and bleomycin] (Figure 5B±D)
PMID:12773392 FYPO:0000082 and irreversible tem- perature-sensitive (Ts±) growth defects (Figure 5B±D).
PMID:12773392 PBO:0093616 sensitivity to DNA-damaging agents [such as UV, methyl methane- sulfonate (MMS) and bleomycin] (Figure 5B±D)
PMID:12773392 PBO:0093616 sensitivity to DNA-damaging agents [such as UV, methyl methane- sulfonate (MMS) and bleomycin] (Figure 5B±D)
PMID:12773392 PBO:0093587 sensitivity to DNA-damaging agents [such as UV, methyl methane- sulfonate (MMS) and bleomycin] (Figure 5B±D)
PMID:12773392 PBO:0093587 sensitivity to DNA-damaging agents [such as UV, methyl methane- sulfonate (MMS) and bleomycin] (Figure 5B±D)
PMID:12773392 FYPO:0000082 and irreversible tem- perature-sensitive (Ts±) growth defects (Figure 5B±D).
PMID:12773392 FYPO:0000082 and irreversible tem- perature-sensitive (Ts±) growth defects (Figure 5B±D).
PMID:12773392 FYPO:0000082 and irreversible tem- perature-sensitive (Ts±) growth defects (Figure 5B±D).
PMID:12773392 PBO:0093586 sensitivity to DNA-damaging agents [such as UV, methyl methane- sulfonate (MMS) and bleomycin] (Figure 5B±D)
PMID:12773392 PBO:0093616 sensitivity to DNA-damaging agents [such as UV, methyl methane- sulfonate (MMS) and bleomycin] (Figure 5B±D)
PMID:12773392 PBO:0093629 sensitivity to DNA-damaging agents [such as UV, methyl methane- sulfonate (MMS) and bleomycin] (Figure 5B±D)
PMID:12773392 PBO:0093629 sensitivity to DNA-damaging agents [such as UV, methyl methane- sulfonate (MMS) and bleomycin] (Figure 5B±D)
PMID:12773392 PBO:0093629 sensitivity to DNA-damaging agents [such as UV, methyl methane- sulfonate (MMS) and bleomycin] (Figure 5B±D)
PMID:12773392 PBO:0093629 sensitivity to DNA-damaging agents [such as UV, methyl methane- sulfonate (MMS) and bleomycin] (Figure 5B±D)
PMID:12773392 FYPO:0005310 Moreover, Dprw1 cells showed an increase in acetylation of H3 Lys9 and Lys14.
PMID:12773392 FYPO:0005310 Cells carrying Dalp13 were speci®cally defective in the removal of acetyl groups present on H3 Lys9 and Lys14, as well as H4 Lys5 and Lys8.
PMID:12773392 FYPO:0002363 The results presented in Figure 5E demonstrate that mutant strains show a signi®cant increase in histone acetylation levels compared with the wild-type control. Mutation in clr6 results in elevated acetylation levels at all residues tested on the histone H3 and H4 tails.
PMID:12773392 FYPO:0000892 The Dpst2 cells showed a signi®cant increase in acetylation of most lysine residues on H3 and H4 tails, except H4 Lys8.
PMID:12773392 FYPO:0007631 The Dpst2 cells showed a signi®cant increase in acetylation of most lysine residues on H3 and H4 tails, except H4 Lys8.
PMID:12773392 FYPO:0002365 The results presented in Figure 5E demonstrate that mutant strains show a signi®cant increase in histone acetylation levels compared with the wild-type control. Mutation in clr6 results in elevated acetylation levels at all residues tested on the histone H3 and H4 tails.
PMID:12773392 FYPO:0005309 Cells carrying Dalp13 were speci®cally defective in the removal of acetyl groups present on H3 Lys9 and Lys14, as well as H4 Lys5 and Lys8.
PMID:12773392 FYPO:0007631 Interestingly, we noticed that Dprw1 causes an increase in the acetylation of H4 Lys5 and Lys12, a pattern of acetylation known to be associated with newly synthesized histones (Sobel et al., 1995).
PMID:12773392 FYPO:0005309 Interestingly, we noticed that Dprw1 causes an increase in the acetylation of H4 Lys5 and Lys12, a pattern of acetylation known to be associated with newly synthesized histones (Sobel et al., 1995).
PMID:12773392 FYPO:0000892 Moreover, Dprw1 cells showed an increase in acetylation of H3 Lys9 and Lys14.
PMID:12773392 FYPO:0000892 Cells carrying Dalp13 were speci®cally defective in the removal of acetyl groups present on H3 Lys9 and Lys14, as well as H4 Lys5 and Lys8.
PMID:12773392 FYPO:0005308 Cells carrying Dalp13 were speci®cally defective in the removal of acetyl groups present on H3 Lys9 and Lys14, as well as H4 Lys5 and Lys8.
PMID:12773392 FYPO:0005310 The Dpst2 cells showed a signi®cant increase in acetylation of most lysine residues on H3 and H4 tails, except H4 Lys8.
PMID:12773392 FYPO:0007632 The Dpst2 cells showed a signi®cant increase in acetylation of most lysine residues on H3 and H4 tails, except H4 Lys8.
PMID:12773392 GO:0032129 These data suggest that Clr6 and its associated factors are involved in the deacetylation of histones in vivo.
PMID:12773392 GO:0031078 These data suggest that Clr6 and its associated factors are involved in the deacetylation of histones in vivo.
PMID:12773392 GO:0034739 These data suggest that Clr6 and its associated factors are involved in the deacetylation of histones in vivo.
PMID:12773392 GO:0140937 These data suggest that Clr6 and its associated factors are involved in the deacetylation of histones in vivo.
PMID:12773392 PBO:0103767 Our analysis revealed that mutant strains display defects in the segregation, resolution and/or condensation of chromosomes during mitosis (Figure 6A), and mis-segre- gated the mini-chromosome Ch16 (a 530 kb derivative of chromosome 3; Niwa et al., 1986) at a signi®cantly higher rate than wild-type cells (Figure 6C).
PMID:12773392 PBO:0103767 Our analysis revealed that mutant strains display defects in the segregation, resolution and/or condensation of chromosomes during mitosis (Figure 6A), and mis-segre- gated the mini-chromosome Ch16 (a 530 kb derivative of chromosome 3; Niwa et al., 1986) at a signi®cantly higher rate than wild-type cells (Figure 6C).
PMID:12773392 PBO:0103767 Our analysis revealed that mutant strains display defects in the segregation, resolution and/or condensation of chromosomes during mitosis (Figure 6A), and mis-segre- gated the mini-chromosome Ch16 (a 530 kb derivative of chromosome 3; Niwa et al., 1986) at a signi®cantly higher rate than wild-type cells (Figure 6C).
PMID:12773392 PBO:0111994 Our analysis revealed that mutant strains display defects in the segregation, resolution and/or condensation of chromosomes during mitosis (Figure 6A), and mis-segre- gated the mini-chromosome Ch16 (a 530 kb derivative of chromosome 3; Niwa et al., 1986) at a signi®cantly higher rate than wild-type cells (Figure 6C).
PMID:12773392 FYPO:0008183 We found that H3 Ser10 phosphorylation levels were considerably reduced in alp13, pst2 and clr6 mutant cells, except at 2±3 foci near the nuclear periphery, presumably representing heterochromatic loci (Figure 7)
PMID:12773392 FYPO:0008183 We found that H3 Ser10 phosphorylation levels were considerably reduced in alp13, pst2 and clr6 mutant cells, except at 2±3 foci near the nuclear periphery, presumably representing heterochromatic loci (Figure 7)
PMID:12773392 GO:0032221 Identi®cation of Clr6-associated proteins, (Figure 1B) /Alp13, Prw1 and Pst2 are stably associated with Clr6 in vivo (Figure 3A)
PMID:12773392 GO:0032221 Identi®cation of Clr6-associated proteins, (Figure 1B)/Alp13, Prw1 and Pst2 are stably associated with Clr6 in vivo (Figure 3A)
PMID:12773392 GO:0032221 Identi®cation of Clr6-associated proteins, (Figure 1B)/Alp13, Prw1 and Pst2 are stably associated with Clr6 in vivo (Figure 3A)
PMID:12773392 GO:0032221 Identi®cation of Clr6-associated proteins, (Figure 1B)/ Alp13, Prw1 and Pst2 are stably associated with Clr6 in vivo (Figure 3A)
PMID:12773392 GO:0004407 Af®nity-puri®ed Clr6-HA and control wild-type fractions were incubated with [3H]acetyl- labelled histones. Quantitation of released [3H]acetyl groups revealed that the Clr6-HA fraction possesses deacetylase activity and that this activity is sensitive to trichostatin A (TSA), a speci®c inhibitor of HDACs (Figure 1C).
PMID:12773392 GO:0005634 Our analyses showed that all four proteins were localized predominantly in the nucleus on chromatin but excluded from the nucleolus (Figure 4A and B).
PMID:12773392 GO:0005634 Our analyses showed that all four proteins were localized predominantly in the nucleus on chromatin but excluded from the nucleolus (Figure 4A and B).
PMID:12773576 FYPO:0000892 Figure 6C
PMID:12773576 PBO:0104706 increased spatial extent of heterochromatin assembly (JUST)
PMID:12773576 PBO:0104706 increased spatial extent of heterochromatin assembly (JUST, not at prpote4in coding gene!)
PMID:12773576 FYPO:0002827 Figure 6A, 6B
PMID:12773576 PBO:0104708 normal spatial extent of heterochromatin assembly (JUST)
PMID:12773576 FYPO:0005310 Figure 6C
PMID:12773576 FYPO:0001859 Figure 6C
PMID:12773576 PBO:0104707 outer repeats
PMID:12773576 FYPO:0004238 Figure 6C
PMID:12786945 PBO:0112181 This comes from point mutation in FLEX moitf abolished transcription. Phenotype is not captured because the precise mutant could not be established.
PMID:12789340 PBO:0097160 inferred from combination of FYPO:0005798 and FYPO:0005828
PMID:12791993 FYPO:0006004 data not shown
PMID:12791993 FYPO:0005689 Fig 1B cell cycle arrest with post anaphase microtubule array
PMID:12791993 FYPO:0006004 Fig1A
PMID:12791993 FYPO:0003126 Fig 1A
PMID:12791993 FYPO:0003838 Fig 1B, C Cells arrest with a stable actinomyosin ring and fail to undergo cytokinesis
PMID:12791993 FYPO:0003126 Fig2 E,F
PMID:12791993 PBO:0095628 Fig 3A
PMID:12791993 PBO:0095629 Fig 3C
PMID:12791993 PBO:0095631 Fig 3E, F.
PMID:12791993 PBO:0094421 Fig 3E
PMID:12791993 PBO:0095632 Fig 3E
PMID:12791993 FYPO:0001400 Fig2 E,F
PMID:12791993 FYPO:0006005 Fig 4C (displacemetn is supressed by inhibiting membrane trafficking
PMID:12791993 FYPO:0002026 Fig 4D
PMID:12791993 FYPO:0003303 Fig 4D, E, F
PMID:12791993 FYPO:0003245 Fig 4D, E, F
PMID:12791993 FYPO:0003126 data not shown
PMID:12791993 FYPO:0006004 data not shown
PMID:12791993 FYPO:0003126 data not shown
PMID:12791993 PBO:0094469 Fig 3C
PMID:12791993 PBO:0095630 Fig 3C
PMID:12791993 PBO:0095196 Fig 3C
PMID:12796476 FYPO:0002021 figure 1D but lacked both actin con- tractile rings and polarized actin patches (Fig. 1 D)
PMID:12796476 FYPO:0003210 abnormal (partial, broad, and misoriented) septa (Fig. 1 G)
PMID:12796476 FYPO:0002061 Thus, Cdc12(FH1FH2)p can replace the essential functions of Cdc12p in vivo when Cdc12p is nonfunctional, but is toxic when overexpressed in the pres- ence of functional Cdc12p.
PMID:12796476 FYPO:0001357 control, functional fragment
PMID:12796476 GO:0030041 fission yeast Cdc12 (FH1FH2)p purified from bacteria (Fig. 1 B) stimulated ac- tin polymerization, as detailed below (see Fig. 4). This is consistent with Cdc12(FH1FH2)p and MmCPcapping the barbed (fast depolymerizing) ends of the fila- ments with high affinity (Kd 0.1 M), allowing dissocia- tion only from the slowly depolymerizing (Pollard, 1986) pointed ends (Caldwell et al., 1989)
PMID:12796476 GO:0051016 MF?
PMID:12796476 GO:0051015 barbed end actin capping
PMID:12796476 FYPO:0005853 figure 1D impressive enrichment of actin filaments in ab- errant thick cables and aster-like accumulations
PMID:12796476 FYPO:0002437 figure 1D impressive enrichment of actin filaments in ab- errant thick cables and aster-like accumulations
PMID:12796476 FYPO:0001493 figure 1D arrested after 24 h (Fig. 1 E)
PMID:12796476 PBO:0106850 actin binding inhibitor pointed end
PMID:12796476 PBO:0024260 figure 1D but lacked both actin con- tractile rings and polarized actin patches (Fig. 1 D)
PMID:12805221 MOD:00046 referred to in PMID:33137119
PMID:12808043 PBO:0023748 dependent on sme2 expression
PMID:12810074 GO:0005737 Comparison of mitochondria staining with GFP–Ung1 showed no detectable co-localization of Ung1 and mitochondria (Fig. 1B, right). Thus, these cellular localization studies indicate that fission yeast Ung1 is more similar to the nuclear form of human UNG as they both localized predominantly in the nucleus
PMID:12815070 FYPO:0002061 ability to form colonies o nrich medium at 36°C was indistin- guishable from that of wild-typec ells
PMID:12815070 FYPO:0002061 This established that mutating plo1 in a way that did not affect cell viability compromised the ability of cut12.s11 to suppress cdc25.22. Fig 9A. cdc25.22 and cdc25.22 plo1.ts19 cells, on the other hand, could not form colo- nies on this medium at this temperature, but cdc25.22 cut12.s11 cells could
PMID:12815070 FYPO:0002061 triple cut12.s11 cdc25.22 plo1.ts19 cells were unable to grow (Fig. 9A).
PMID:12815070 FYPO:0000400 Whereas single plo1.ts2 and plo1.ts19 mutant and double cut12.s11 cdc25.22 mutant cells all entered mitosis (Fig. 9B,C), the single cdc25.22 mutant and both double cdc25.22 plo1.ts and triple cut12.s11 cdc25.22 plo1.ts mutants did not.
PMID:12815070 PBO:0101128 Fig. 2A;
PMID:12815070 PBO:0101128 Fig. 2A;
PMID:12815070 PBO:0101128 Fig. 2A;
PMID:12815070 PBO:0101128 Fig. 2B
PMID:12815070 PBO:0101129 his suggested that the inability to promote mitotic Plo1-associated kinase activity in cut12.1 cells was not a simple consequence of an inability to assemble a bipolar spindle,or an inability to commit to mitosis.Rather,the data indicate that Cut12 function was required for full activationof Plo1-associated kinase activity during mitotic commitment. Alspp Fig. 6B
PMID:12815070 PBO:0100189 Figs.1A,4C)
PMID:12815070 PBO:0101130 Plo1-associatedkinaseactivityofextractsfromarrested cdc2.33cut12.s11cellswas2.4-fold(±0.35;n=6)higher than that of the control cdc2.33 cut12+ cells (Fig. 4D). This established that cut12.s11 increased Plo1 activity ininterphase.
PMID:12815070 PBO:0101131 Kinase assays of these mitotic samples indicated that the cut12.s11 mutation promoted a 1.6 (±0.18; n = 5) in-creaseinPlo1-specificactivityduringmitosis(Fig.4D).
PMID:12815070 FYPO:0002061 Both plo1.ts2 and plo1.ts19 conferred temperature sensitivity for growth on minimal medium
PMID:12815070 FYPO:0002061 Both plo1.ts2 and plo1.ts19 conferred temperature sensitivity for growth on minimal medium
PMID:12815070 FYPO:0002061 Fig 9A. cdc25.22 and cdc25.22 plo1.ts19 cells, on the other hand, could not form colo- nies on this medium at this temperature, but cdc25.22 cut12.s11 cells could
PMID:12815070 PBO:0101137 Plo1.K65R,the“kinasedead”mutantprotein,onlyas- sociatedwithmitoticbutnotwithinterphaseSPBs(data not shown).
PMID:12815070 PBO:0101136 The extended and more random size of plo1.ts2cellsatdivisionsuggestedthatthismaybethe case. Despite the fact that these cells are able to enter mitosis,theyappeartobedoingsoinalessefficient,or more random manner (Fig. 8B).
PMID:12815070 PBO:0101135 Whereas cells in which the expres- sionoftheconstitutivelyactivemutantremainedre- pressed arrested cell cycle progression in interphase, 11% of those in which it had been expressed entered mitosis.This degree of suppression is very similar to the level of suppression of cdc25.22 arising from the pres- ence of the cut12.s11 mutation (Fig. 9B) and established that activation of Plo1 is sufficient to suppress the deficiency in Cdc25 function in cdc25.22 cells.
PMID:12815070 PBO:0101133 full-lengthproteinappearedtobelargely absent from plo1.ts19 on either minimal or rich medium at either 25°C or 36°C (Fig. 7B)
PMID:12815070 PBO:0101134 We concluded thatthePlo1-dependentkinaseactivityofbothplo1.ts2 andplo1.ts19wasgreatlyreduced.
PMID:12815070 PBO:0101134 We concluded thatthePlo1-dependentkinaseactivityofbothplo1.ts2 andplo1.ts19wasgreatlyreduced.
PMID:12815070 FYPO:0001683 plo1.ts2 strains entered mitosis but did not form spindles
PMID:12815070 FYPO:0000276 plo1.ts2 strains entered mitosis but did not form spindles
PMID:12815070 FYPO:0000620 Unlike classic “cut” mutants (Hirano et al. 1986), septation did not always follow on from the mi- toticarrest.
PMID:12815070 FYPO:0000400 Whereas single plo1.ts2 and plo1.ts19 mutant and double cut12.s11 cdc25.22 mutant cells all entered mitosis (Fig. 9B,C), the single cdc25.22 mutant and both double cdc25.22 plo1.ts and triple cut12.s11 cdc25.22 plo1.ts mutants did not.
PMID:12815070 FYPO:0002060 ability to form colonies o nrich medium at 36°C was indistin- guishable from that of wild-typec ells
PMID:12815070 PBO:0101132 Western blot analysis showed that Plo1 levels in plo1.ts2cellswerenotradicallydifferentfromwildtype,
PMID:12815070 PBO:0101133 full-lengthproteinappearedtobelargely absent from plo1.ts19 on either minimal or rich medium at either 25°C or 36°C (Fig. 7B)
PMID:12840005 PBO:0100889 assayed using RTS1 mut2 or mut8 on plasmid
PMID:12840005 FYPO:0003084 assayed using RTS1 mut2 or mut8 on plasmid
PMID:12840005 FYPO:0003084 assayed using RTS1 mut2 or mut8 on plasmid
PMID:12840005 PBO:0100890 assayed using RTS1 mut2 or mut8 on plasmid
PMID:12840005 FYPO:0005356 assayed using RTS1 mut2 or mut8 on plasmid
PMID:12840005 FYPO:0005356 assayed using RTS1 mut2 or mut8 on plasmid
PMID:12857865 FYPO:0003738 Fig4
PMID:12857865 FYPO:0002061 data not shown
PMID:12857865 FYPO:0002061 data not shown
PMID:12857865 FYPO:0002061 Figure 6A
PMID:12857865 GO:0061496 Fig 2/3
PMID:12857865 FYPO:0002061 Fig4
PMID:12857865 FYPO:0000276 Fig4
PMID:12857865 FYPO:0005023 Figure 7 (this protrusion is opposite side of nucleus to the SPB)
PMID:12857865 FYPO:0003788 Figure 7 (this protrusion is opposite side of nucleus to the SPB)
PMID:12857865 FYPO:0000608 Figure 7
PMID:12857865 FYPO:0003165 Figure 6A
PMID:12861005 FYPO:0005402 same as taz1d alone
PMID:12861005 FYPO:0005402 same as taz1d alone
PMID:12861005 FYPO:0005402 same as taz1d alone
PMID:12861005 FYPO:0005402 same as taz1d alone
PMID:12861005 FYPO:0005402 same as taz1d alone
PMID:12861005 PBO:0093616 same as rad51d alone
PMID:12861005 FYPO:0005402 same as taz1d alone
PMID:12861005 FYPO:0005402 same as taz1d alone
PMID:12867036 PBO:0111282 Moreover, the level of Swi6 associated with imr1R::ura4� and otr1R::ura4� report- ers was reduced 8- and 3-fold, respectively, in sir2� compared to wild-type cells (Figure 3B).
PMID:12867036 PBO:0097399 Histone H3-K9 methylation levels at Kint2::ura4� and imr1R::ura4� were strongly reduced in sir2� com- pared to sir2� cells (32- and 13-fold, respectively) (Figure 3B).
PMID:12867036 PBO:0112507 Consistent with its weaker effect on silencing of otr1R::ura4�, deletion of sir2� had only a weak effect on methylation of this ura4� reporter (Figure 3B).
PMID:12867036 PBO:0096189 Deletion of sir2� caused derepression of ura4� at both loci (Figure 2D). However, this effect was much stronger at the imr repeats than at the otr repeats. While sir2� cells carrying imr1R::ura4� did not form colonies on FOA-containing plates, mutant cells carrying otr1R::ura4� showed ap- preciable growth on FOA plates (Figure 2D). These re- sults indicated that Sir2 was required for silencing at the S. pombe centromeric DNA regions.
PMID:12867036 FYPO:0004690 Compared to wild-type cells, in sir2� cells, acetylation of K9 was increased by 16-, 11-, and 7-fold at the ura4� reporter inserted in the mating locus (Kint2::ura4�), the inner (imr1R::ura4�), and the outer centromeric repeats (otr1R::ura4�), respectively (Figure 3A).
PMID:12867036 FYPO:0006681 Compared to wild-type cells, in sir2� cells, acetylation of K9 was increased by 16-, 11-, and 7-fold at the ura4� reporter inserted in the mating locus (Kint2::ura4�), the inner (imr1R::ura4�), and the outer centromeric repeats (otr1R::ura4�), respectively (Figure 3A).
PMID:12867036 PBO:0096301 Compared to wild-type cells, in sir2� cells, acetylation of K9 was increased by 16-, 11-, and 7-fold at the ura4� reporter inserted in the mating locus (Kint2::ura4�), the inner (imr1R::ura4�), and the outer centromeric repeats (otr1R::ura4�), respectively (Figure 3A).
PMID:12867036 FYPO:0007633 Compared to wild-type cells, in sir2� cells, acetylation of K9 was increased by 16-, 11-, and 7-fold at the ura4� reporter inserted in the mating locus (Kint2::ura4�), the inner (imr1R::ura4�), and the outer centromeric repeats (otr1R::ura4�), respectively (Figure 3A).
PMID:12867036 FYPO:0006815 Compared to wild-type cells, in sir2� cells, acetylation of K9 was increased by 16-, 11-, and 7-fold at the ura4� reporter inserted in the mating locus (Kint2::ura4�), the inner (imr1R::ura4�), and the outer centromeric repeats (otr1R::ura4�), respectively (Figure 3A).
PMID:12867036 PBO:0111016 ChIP analy- sis showed that the level of Swi6 associated with Kint2::ura4� was reduced 47-fold in sir2� compared to wild-type cells (Figure 3B).
PMID:12867036 PBO:0104873 Moreover, the level of Swi6 associated with imr1R::ura4� and otr1R::ura4� report- ers was reduced 8- and 3-fold, respectively, in sir2� compared to wild-type cells (Figure 3B).
PMID:12867036 FYPO:0006670 We combined the sir2� mutant with REII� and found that the sir2� REII� double mutant had a strong haploid meiosis phenotype (Figure 2E).
PMID:12867036 FYPO:0000470 We observed a strong reduction in staining of sir2� compared to sir2� cells, which indicated a reduced rate of switching to the opposite mating type in sir2� cells (Figure 2E, column 1).
PMID:12867036 FYPO:0007336 In contrast, sir2� L(BglII)::ade6� cells formed white colonies, indicating loss of silencing of the reporter gene (Figure 2C).
PMID:12867036 GO:0046969 spSir2 efficiently deacetylated an H4 peptide with acetyl-lysine at position 16 (AcK16) and an H3 peptide with acetyl-lysine at posi- tion 9 (AcK9), compared to H4 peptides with acetyl- lysine at positions 5 (AcK5), 8 (AcK8), and 12 (AcK12) (Figure 1B).
PMID:12867036 GO:0046970 spSir2 efficiently deacetylated an H4 peptide with acetyl-lysine at position 16 (AcK16) and an H3 peptide with acetyl-lysine at posi- tion 9 (AcK9), compared to H4 peptides with acetyl- lysine at positions 5 (AcK5), 8 (AcK8), and 12 (AcK12) (Figure 1B).
PMID:12867036 PBO:0108388 Consistent with its weaker effect on silencing of otr1R::ura4�, deletion of sir2� had only a weak effect on methylation of this ura4� reporter (Figure 3B).
PMID:12867036 PBO:0094282 Deletion of sir2� caused derepression of ura4� at both loci (Figure 2D). However, this effect was much stronger at the imr repeats than at the otr repeats. While sir2� cells carrying imr1R::ura4� did not form colonies on FOA-containing plates, mutant cells carrying otr1R::ura4� showed ap- preciable growth on FOA plates (Figure 2D). These re- sults indicated that Sir2 was required for silencing at the S. pombe centromeric DNA regions.
PMID:12868054 FYPO:0007286 fig 7 prevacuolar compartment membrane
PMID:12868054 FYPO:0003656 4 mM
PMID:12868054 FYPO:0000583 fig 5
PMID:12868054 FYPO:0005547 fig 6
PMID:12868054 PBO:0095634 n liquid YES medium at 27 ◦ C, the cells had a doubling time of ∼8 h, in contrast to 2 h 30 min for wild-type cells.
PMID:12868054 FYPO:0002061 While both wild- type and vps33 cells grew at 26 ◦ C, vps33 cells exhibited a temperature-sensitive growth at 37 ◦C (Figure 2A).
PMID:12868054 FYPO:0000369 2b
PMID:12868054 FYPO:0004483 Fig3
PMID:12868054 PBO:0096587 strong sensitiv- ity to 100 mM CaCl2 (Figure 4A)
PMID:12868054 FYPO:0000076 at 5 μg/ml
PMID:12868054 FYPO:0000096 fig 7a
PMID:12871901 FYPO:0000583 homozygous diploid
PMID:12871901 FYPO:0002044 homozygous diploid
PMID:12871901 PBO:0096410 Northern blot
PMID:12871901 FYPO:0000611 permissive for cdc25-22; restrictive for cdt2-M1
PMID:12888492 GO:0033214 IGI with cerevisiae
PMID:12893961 FYPO:0002060 fig3
PMID:12893961 FYPO:0004009 fig5
PMID:12893961 FYPO:0002060 fig4
PMID:12893961 FYPO:0002060 fig4
PMID:12893961 FYPO:0002061 fig4
PMID:12893961 FYPO:0001234 fig3
PMID:12893961 FYPO:0002061 fig4
PMID:12894167 PBO:0102431 LOCALIZES OK, IS NOT RETAINED
PMID:12894167 PBO:0102429 """These results indicate that Mal3 is required for the proper association of Tea2 with microtubules and sug- gest that Mal3 stabilizes the kinesin–microtubule interaction"""
PMID:12925774 PBO:0097003 during mitotic DNA replication initiation
PMID:12930956 PBO:0105456 assayed in pku80d haploid derived from pku80d pku+ heterozygous diploid
PMID:12951601 PBO:0104346 Fig. 1c, cells 1 and 3 Furthermore, multiple Mad2 dots, which have never been seen in wild type cells
PMID:12951601 FYPO:0006346 fig 1a thinner discontinuous spindles fypo/issues/3208
PMID:12951601 FYPO:0002061 Fig 1d
PMID:12951601 FYPO:0003165 Fig 1e
PMID:12951601 FYPO:0002061 Fig 1d
PMID:12951601 FYPO:0002061 Fig 1d
PMID:12951601 FYPO:0002061 Fig 1d
PMID:12966087 GO:0000724 epistasis with Rhp51
PMID:12966087 GO:0000724 epistasis with Rhp51
PMID:12972434 PBO:0099028 These data indicate that the decrease in ribosomal protein L25-A observed in cpc2::ura4 cells is probably due to a defect in recruitment of its mRNA to polyribosomes. The decreased amounts of both sam1 and thi2 RNAs are sufficient to account for the lowered protein abundance of each in cpc2::ura4 cells. In contrast, the decline in the level of ribosomal protein Rpl25 in cpc2::ura4 cells is not likely to be caused by an inability to accumulate its mRNA transcript.
PMID:12972434 PBO:0099027 These data indicate that the decrease in ribosomal protein L25-A observed in cpc2::ura4 cells is probably due to a defect in recruitment of its mRNA to polyribosomes. The decreased amounts of both sam1 and thi2 RNAs are sufficient to account for the lowered protein abundance of each in cpc2::ura4 cells. In contrast, the decline in the level of ribosomal protein Rpl25 in cpc2::ura4 cells is not likely to be caused by an inability to accumulate its mRNA transcript.
PMID:12972434 GO:2000765 e pyruvate kinase, thiazole biosynthetic enzyme, and ribosomal protein L25-A
PMID:12972571 PBO:0100551 mcm4ts-td phenotype indicates that Cdc23 chromatin localization is independent of Mcm4
PMID:12972571 PBO:0104571 late anaphase
PMID:12972571 PBO:0101303 late anaphase
PMID:1314171 GO:0015385 inhibited by CCCP
PMID:1316996 FYPO:0002060 cdc2-E8 suppresses mitotic catastrophe at high temperature
PMID:1316996 FYPO:0001382 Hi used as substrate
PMID:1316996 PBO:0096052 HI used as substrate
PMID:1316996 FYPO:0002060 cdc2-A21 suppresses mitotic catastrophe at high temperature
PMID:1316996 PBO:0096052 HI used as substrate
PMID:1316996 FYPO:0000839 cells inviable at all temperatures in presence of wee1+
PMID:1316996 FYPO:0000839 G2 arrest shown by FACS analysis.
PMID:1316996 FYPO:0000839 crosses with this mutant generate a high level of diploids.
PMID:1316996 FYPO:0001382 Hi used as substrate
PMID:1316996 FYPO:0004922 G2 arrest shown by FACS analysis.
PMID:1316996 FYPO:0002060 cdc2-E9 suppresses mitotic catastrophe at high temperature
PMID:1324908 GO:0003882 regulated by inositol
PMID:1324908 GO:0008444 regulated by inositol
PMID:1324908 FYPO:0000663 GO:0008444 CDP-DG synthase and GO:0003882 PS synthase
PMID:1332977 MOD:00046 3 sites in N-terminus (1-75) and 7 in C-terminus (1221-1485), but positions not determined
PMID:1332977 GO:0003918 phosphorylated and dephosphorylated forms both active; no PR col 17 because no evidence that dephosphorylated form is physiologically relevant (dephosphorylated in vitro)
PMID:1372994 PBO:0107331 val: I used this to link to process term even though it isn't shown directly in this paper
PMID:1372994 GO:0010972 AL added as BP since Val had added it involved_in on MF
PMID:1396704 PBO:0094498 activated_by(CHEBI:17234)
PMID:1427071 PBO:0019031 hydroxyurea absent
PMID:14519123 FYPO:0000103 fig4
PMID:14519123 FYPO:0000087 fig4
PMID:14519123 FYPO:0003270 fig4
PMID:14519123 FYPO:0000037 fig3
PMID:14519123 FYPO:0001712 fig3
PMID:14519123 PBO:0110915 https://github.com/geneontology/go-ontology/issues/26833
PMID:14528010 GO:0008821 is not a resolvase - makes symmetric cuts on opposed strands across the junction but does not convert products to linear DNA molecules
PMID:14528010 GO:1990238 specific for dsDNA at ds/ssDNA junction
PMID:14532136 GO:0007129 there is good evidence for this, but not bullet proof
PMID:14585996 GO:0000785 phenotype indicates that mrc1/Phos:S604 has higher affinity for chromatin than Unphos:S604
PMID:14585996 PBO:0103276 in presence of hydroxyurea
PMID:14585996 PBO:0103275 in presence of hydroxyurea
PMID:14585996 PBO:0094250 residue S604
PMID:14585996 PBO:0094250 residue S604
PMID:14599746 GO:0070914 inferred from increased mutation rate upon UV exposure in mutant
PMID:14599746 GO:0006284 rationale: increased transversion frequency indicates that 8-oxoG persists more in mutant, but normal indel frequency suggests not NER
PMID:14602073 GO:0110085 independent of F-actin (assayed using Latrunculin A)
PMID:14602073 GO:0110085 dependent on F-actin (assayed using Latrunculin A)
PMID:14602073 GO:0110085 dependent on F-actin (assayed using Latrunculin A)
PMID:14602073 GO:0110085 dependent on F-actin (assayed using Latrunculin A)
PMID:14602073 GO:0110085 dependent on F-actin (assayed using Latrunculin A)
PMID:14602073 GO:0110085 dependent on F-actin (assayed using Latruncilin A)
PMID:14602073 PBO:0024047 late interphase; independent of F-actin (assayed using Latrunculin A)
PMID:14602073 PBO:0024047 late interphase; independent of F-actin (assayed using Latrunculin A)
PMID:14602073 PBO:0024047 late interphase; independent of F-actin (assayed using Latrunculin A)
PMID:14602073 PBO:0024047 late interphase; independent of F-actin (assayed using Latrunculin A)
PMID:14602073 PBO:0024047 late interphase; independent of F-actin (assayed using Latrunculin A)
PMID:14602073 PBO:0018470 late interphase; independent of F-actin (assayed using Latrunculin A)
PMID:14602073 PBO:0018677 before late interphase
PMID:14602073 PBO:0018470 late interphase; independent of F-actin (assayed using Latrunculin A)
PMID:14602073 GO:0110085 dependent on F-actin (assayed using Latrunculin A)
PMID:14602073 PBO:0018470 late interphase; independent of F-actin (assayed using Latrunculin A)
PMID:14602073 PBO:0018844 late interphase; independent of F-actin (assayed using Latrunculin A)
PMID:14602073 GO:0110085 dependent on F-actin (assayed using Latrunculin A)
PMID:14602073 PBO:0018470 late interphase; independent of F-actin (assayed using Latrunculin A)
PMID:14612233 GO:0004382 activated_by(CHEBI:29108)| activated_by(CHEBI:29035)
PMID:14633985 PBO:0093578 fig1c
PMID:14633985 PBO:0094759 This decrease correlated with a large drop in the amount of Atf1 protein (Figure 4C).
PMID:14633985 PBO:0094760 The H2O2-induced increase in expression of pcr1+ mRNA, which encodes a binding partner of Atf1, was similarly eliminated in csx1D cells (Figure 4A
PMID:14633985 PBO:0094761 mRNA expression levels of two other transcription factor genes involved in oxidative stress, pap1+ and prr1+, were unaffected by the csx1D mutation (Figure 4A).
PMID:14633985 PBO:0094762 mRNA expression levels of two other transcription factor genes involved in oxidative stress, pap1+ and prr1+, were unaffected by the csx1D mutation (Figure 4A).
PMID:14633985 FYPO:0005947 fig1
PMID:14633985 PBO:0093578 fig1
PMID:14633985 PBO:0093578 fig1c
PMID:14633985 PBO:0093612 fig1c
PMID:14633985 PBO:0094387 fig1c
PMID:14633985 PBO:0094756 As shown in Figure 2C, H2O2 induced robust phosphorylation of Spc1 in csx1D cells..... Csx1 is not necessary for Spc1 activation.
PMID:14633985 PBO:0093577 fig1
PMID:14633985 PBO:0093578 fig1
PMID:14633985 FYPO:0002061 The csx1D single mutant was less sensitive to H2O2 than the spc1D mutant, whereas the csx1D spc1D double mutant was more sensitive than the spc1D strain. These ®ndings were consistent with the idea that Csx1 and Spc1 have independent functions in oxidative stress tolerance.
PMID:14633985 PBO:0094758 the large increase in atf1+ mRNA that is induced by H2O2 in wildtype cells was abolished in csx1D cells.
PMID:14633985 PBO:0094763 mRNA expression levels of two other transcription factor genes involved in oxidative stress, pap1+ and prr1+, were unaffected by the csx1D mutation (Figure 4A).
PMID:14633985 PBO:0094764 Figure 4E).
PMID:14633985 GO:0005737 Figure 6A, Csx1±GFP was detected in the cytoplasm and appeared to be excluded from the nucleus. This pattern of Csx1±GFP localization was unaffected by oxidative stress.
PMID:14633985 GO:0005634 Figure 6A, Csx1±GFP was detected in the cytoplasm and appeared to be excluded from the nucleus. This pattern of Csx1±GFP localization was unaffected by oxidative stress.
PMID:14633985 PBO:0094765 (Figure 6B). decreased stability in response to oxidative stress
PMID:14633985 PBO:0094765 decreased stability in response to oxidative stress (Figure 6B)
PMID:14633985 PBO:0094766 (Figure 6B) decreased stability in response to oxidative stress
PMID:14633985 PBO:0094766 (Figure 6B) decreased stability in response to oxidative stress
PMID:14633985 PBO:0094767 Figure 7A
PMID:14633985 PBO:0094770 from genetics and Sty1 consensus. Later papers say Activated Sty1 also phosphorylates Csx1
PMID:14648198 PBO:0094377 actually inferred from combination of phenotypes, prior knowledge about MBF proteins, and MCBs in promoters, but just using IMP is simpler
PMID:14648198 PBO:0094372 actually inferred from combination of phenotypes, prior knowledge about MBF proteins, and MCBs in promoters, but just using IMP is simpler
PMID:14648198 PBO:0094375 actually inferred from combination of phenotypes, prior knowledge about MBF proteins, and MCBs in promoters, but just using IMP is simpler
PMID:14648198 PBO:0094376 actually inferred from combination of phenotypes, prior knowledge about MBF proteins, and MCBs in promoters, but just using IMP is simpler
PMID:14648198 PBO:0094374 actually inferred from combination of phenotypes, prior knowledge about MBF proteins, and MCBs in promoters, but just using IMP is simpler
PMID:14648198 PBO:0094373 actually inferred from combination of phenotypes, prior knowledge about MBF proteins, and MCBs in promoters, but just using IMP is simpler
PMID:14648198 PBO:0094372 actually inferred from combination of phenotypes, prior knowledge about MBF proteins, and MCBs in promoters, but just using IMP is simpler
PMID:14648198 PBO:0094374 actually inferred from combination of phenotypes, prior knowledge about MBF proteins, and MCBs in promoters, but just using IMP is simpler
PMID:14648198 PBO:0094373 actually inferred from combination of phenotypes, prior knowledge about MBF proteins, and MCBs in promoters, but just using IMP is simpler
PMID:14654689 FYPO:0002239 same as rad11-D223Y alone
PMID:14654689 GO:0000723 also inferred from localization to telomere
PMID:14654689 PBO:0093621 same as rad11-D223Y alone
PMID:14654689 PBO:0093620 same as rad50delta alone
PMID:14663827 PBO:0110137 figure5
PMID:14663827 PBO:0110137 figure5
PMID:14663827 PBO:0110137 figure5
PMID:14663827 PBO:0106644 figure5
PMID:14663827 PBO:0110136 figure5
PMID:14663827 PBO:0037207 figure5
PMID:14663827 PBO:0110136 figure5
PMID:14663827 PBO:0110135 Figure 4
PMID:14663827 PBO:0110135 Figure 4
PMID:14663827 PBO:0110134 Figure 4
PMID:14663827 PBO:0110134 Figure 4
PMID:14663827 PBO:0110133 Figure 4
PMID:14663827 PBO:0110132 Figure 4 shows that tea1 cells at high temperatures displayed microtubules bending round the cell ends, in accordance with previously published results (Mata and Nurse, 1997).
PMID:14663827 PBO:0110129 Figure 3
PMID:14663827 PBO:0110128 Figure 3
PMID:14663827 PBO:0110127 Figure 3
PMID:14663827 PBO:0110127 Figure 3
PMID:14663827 PBO:0110126 Figure 3
PMID:14663827 PBO:0099081 Figure 3
PMID:14663827 PBO:0110125 Figure 3
PMID:14663827 PBO:0100628 Figure 3 Our tea1 result differs from that of Rupes et al. (1999), who found that tea1 cells did not switch to bipolar growth after a LatA pulse. This may be due to differences in scoring or temperature between the experiments.
PMID:14663827 FYPO:0008131 Figure 1 Tea3 cells resumed growth from their old end after division, indicating that the cell inheriting a growing end had no difficulty in reidentifying it as the appropriate site for growth after division (Figure 1).
PMID:14663827 PBO:0110124 Figure 1 about 60% from old end
PMID:14663827 PBO:0110124 Figure 1 about 60% from old end
PMID:14663827 PBO:0110123 Figure 1 about 30% from old end
PMID:14663827 PBO:0110123 Figure 1 about 30% from new end. In contrast, 14% of tea1 cells and 30% of pom1 cells failed to resume growth from a previously growing end (Figure 1).
PMID:14663827 PBO:0110122 Figure 1 about 14% from new end In contrast, 14% of tea1 cells and 30% of pom1 cells failed to resume growth from a previously growing end (Figure 1).
PMID:14663827 FYPO:0003150 Figure 2
PMID:14704433 PBO:0110923 Deletion of tas3+ abolished the association of Chp1-Flag with otr1::ura4+, as well as with native cen sequences (Fig. 4C).
PMID:14704433 PBO:0110922 Furthermore, deletion of ago1+, dcr1+, or rdp1+ abolished the association of Chp1-Flag and Tas3-TAP with otr1::ura4+, as well as with centromeric repeat sequences (Fig. 4, A and B).
PMID:14704433 PBO:0110922 Furthermore, deletion of ago1+, dcr1+, or rdp1+ abolished the association of Chp1-Flag and Tas3-TAP with otr1::ura4+, as well as with centromeric repeat sequences (Fig. 4, A and B).
PMID:14704433 FYPO:0002834 A tas3 deletion strain carrying the ura4+ reporter gene inserted at innermost (imr) or outermost (otr) centromeric repeats of chromosome 1 (imr1R::ura4+ and otr1R::ura4+, respectively) displayed a loss of silencing of both reporter genes (Fig. 2D) to an extent similar to that of the deletion of sir2, chp1, or ago1 (Fig. 2D)
PMID:14704433 PBO:0110922 Furthermore, deletion of ago1+, dcr1+, or rdp1+ abolished the association of Chp1-Flag and Tas3-TAP with otr1::ura4+, as well as with centromeric repeat sequences (Fig. 4, A and B).
PMID:14704433 FYPO:0002566 Further, chromatin immunoprecipitation (ChIP) showed that Tas3 was required for H3-K9 methylation and Swi6 localization of a ura4+ reporter gene inserted at each of the above loci (Fig. 2E).
PMID:14704433 FYPO:0002834 A tas3 deletion strain carrying the ura4+ reporter gene inserted at innermost (imr) or outermost (otr) centromeric repeats of chromosome 1 (imr1R::ura4+ and otr1R::ura4+, respectively) displayed a loss of silencing of both reporter genes (Fig. 2D) to an extent similar to that of the deletion of sir2, chp1, or ago1 (Fig. 2D)
PMID:14704433 FYPO:0002834 A tas3 deletion strain carrying the ura4+ reporter gene inserted at innermost (imr) or outermost (otr) centromeric repeats of chromosome 1 (imr1R::ura4+ and otr1R::ura4+, respectively) displayed a loss of silencing of both reporter genes (Fig. 2D) to an extent similar to that of the deletion of sir2, chp1, or ago1 (Fig. 2D)
PMID:14704433 FYPO:0002834 A tas3 deletion strain carrying the ura4+ reporter gene inserted at innermost (imr) or outermost (otr) centromeric repeats of chromosome 1 (imr1R::ura4+ and otr1R::ura4+, respectively) displayed a loss of silencing of both reporter genes (Fig. 2D) to an extent similar to that of the deletion of sir2, chp1, or ago1 (Fig. 2D)
PMID:14730319 FYPO:0005648 Fig. 2c
PMID:14730319 PBO:0104842 Fig. 2c
PMID:14730319 PBO:0104845 fig 2 and 3d
PMID:14730319 FYPO:0000091 Fig. 4a)
PMID:14730319 PBO:0104847 Fig. 4c)
PMID:14730319 PBO:0104848 Fig. 4d, e)
PMID:14730319 PBO:0104849 Fig. 4c)
PMID:14730319 PBO:0096804 Fig. 4c)
PMID:14730319 PBO:0104851 Fig. 4d
PMID:14730319 FYPO:0002219 fig 2a
PMID:14730319 PBO:0112496 fig 2a
PMID:14730319 PBO:0104843 Fig. 2c
PMID:14730319 FYPO:0002060 Fig. 4a)
PMID:14739927 GO:0005515 proteins dissociate during cellular response to UV
PMID:14739927 GO:0005515 interaction increases during cellular response to UV
PMID:14742702 GO:0070850 Figure 5A, lane 4
PMID:14742702 PBO:0018346 Figure 2A
PMID:14742702 PBO:0100541 Figure 3B
PMID:14742702 PBO:0100542 Figure 3B
PMID:14742702 PBO:0100539 Figure 4A
PMID:14742702 PBO:0100543 Figure 3B
PMID:14742702 PBO:0100544 Figure 3B
PMID:14742702 PBO:0100545 Figure 4D
PMID:14742702 PBO:0100546 Figure 4D
PMID:14742702 PBO:0100547 Figure 4E
PMID:14742702 PBO:0094141 Figure 4F
PMID:14742702 PBO:0100538 Figure 1D
PMID:14742702 GO:0070850 Figure 5A, lane 4
PMID:14742702 GO:0005515 Figure 6A
PMID:14742702 GO:0005515 Figure 6A
PMID:14742702 PBO:0100548 Figure 6B
PMID:14742702 PBO:0100544 8C
PMID:14742702 FYPO:0001978 Figure 8E
PMID:14742702 FYPO:0001733 Figure 8E
PMID:14742702 FYPO:0001355 Figure 8E
PMID:14742702 FYPO:0002400 Figure 8E
PMID:14742702 FYPO:0006195 Figure 8E
PMID:14742702 FYPO:0000274 Figure 1A
PMID:14742702 FYPO:0002638 Figure 1A inferred from increased duration of mitosis
PMID:14742702 FYPO:0006173 Figure 1B
PMID:14742702 FYPO:0005343 Figure 1B
PMID:14742702 FYPO:0000141 Figure 1C
PMID:14742702 FYPO:0006048 Figure 1C rows 2 and 3, note chromosome missegregation in the cell of row 3, and see Supplementary Figure S1 for quantifica- tion of spindle intensity
PMID:14742702 FYPO:0000177 Figure 1C
PMID:14742702 PBO:0022298 Figure 1D
PMID:14742702 PBO:0100538 Figure 1D
PMID:14742702 PBO:0018346 Figure 2A
PMID:14742702 PBO:0100539 On temperature shift down to 20°C, Alp7-YFP localized only to the SPB (Figure 2B). This also indicates that Alp7 does not require a microtubule cytoskeleton to localize to the SPB.
PMID:14742702 PBO:0100540 Figure 2D
PMID:1475195 FYPO:0000470 other evidence = iodine staining
PMID:14766746 PBO:0097029 filter binding assay
PMID:14766746 FYPO:0004386 filter binding assay
PMID:14766746 PBO:0097028 filter binding assay
PMID:14766746 FYPO:0004384 filter binding assay
PMID:14972679 PBO:0106725 Figures 1A and 2
PMID:14972679 PBO:0022058 By metaphase I, 100% of cells (n 100) contained a strong nuclear signal. Sgo1-GFP was concentrated in distinct foci in about half of these metaphase I cells (Figure 3A-2).
PMID:14972679 FYPO:0005509 Figures 1A and 2
PMID:14972679 PBO:0106731 Furthermore, no Rec8-specific fluorescence at all could be detected in 10% of the mutant binucleates. In contrast, the distribution of Rec8- GFP fluorescence in sgo2 mutant binucleates was in- distinguishable from wild-type.
PMID:14972679 PBO:0106724 Figures 1A and 2
PMID:14972679 PBO:0106723 Figures 1B
PMID:14972679 PBO:0106722 Figures 1B
PMID:14972679 PBO:0106721 Figures 1B
PMID:14972679 FYPO:0004159 Figures 1A and 2
PMID:15004232 FYPO:0004766 Figure 5F
PMID:15040954 GO:0004022 qualifier=major
PMID:15047861 PBO:0093595 fig1
PMID:15047861 FYPO:0003279 Figure 3B, a–c
PMID:15047861 FYPO:0000349 Figure 3B, a–c accumulation of presumptive post-Golgi secretory vesicles and abnormal Golgi-like structures were also characteristic of the ypt3-i5 mutants that we reported previously (Cheng et al., 2002).
PMID:15047861 FYPO:0002061 fig1
PMID:15047861 FYPO:0000650 fig6
PMID:15047861 FYPO:0002258 When the cells were labeled with FM4-64 for 60 min, the apm1 cells were highly frag- mented compared with wild-type cells, consistent with the findings obtained by electron microscopy (Figure 7B)
PMID:15047861 PBO:0093595 fig1
PMID:15047861 PBO:0093641 fig1
PMID:15047861 FYPO:0002061 fig1
PMID:15047861 FYPO:0002060 fig1
PMID:15047861 FYPO:0002061 fig8c
PMID:15047861 FYPO:0000426 When the cells were labeled with FM4-64 for 60 min, the apm1 cells were highly frag- mented compared with wild-type cells, consistent with the findings obtained by electron microscopy (Figure 7B)
PMID:15047861 FYPO:0002060 DNS
PMID:15047861 FYPO:0002061 fig1
PMID:15047861 PBO:0093641 fig1
PMID:15052323 GO:0036374 Mix of IMP evidence & a proxy assay for hydrolase function
PMID:15062095 FYPO:0000901 the variant caused abnormal microtubule behavior in cell-end regions, which is likely to be the cause of the previously reported shape abnormalities
PMID:15068790 PBO:0104123 Fig. 1
PMID:15068790 FYPO:0000339 Fig. 1
PMID:15068790 PBO:0104122 Fig. 1
PMID:15068790 PBO:0104124 Fig. 1
PMID:15068790 PBO:0104125 Fig. 1
PMID:15068790 FYPO:0007983 Fig. 1
PMID:15068790 FYPO:0007114 Fig. 1
PMID:15068790 PBO:0104126 Fig. 1
PMID:15068790 PBO:0104127 Fig. 1
PMID:15068790 PBO:0104128 Fig. 2
PMID:15068790 PBO:0104129 Fig. 2
PMID:15068790 FYPO:0007985 Fig. 2
PMID:15068790 PBO:0104130 Fig. 2
PMID:15068790 PBO:0104131 Fig. 6
PMID:15068790 PBO:0104131 Fig. 6
PMID:15068790 PBO:0104132 Fig. 7
PMID:15068790 PBO:0104133 Fig. 7
PMID:15068790 FYPO:0002818 Fig. 7
PMID:15068790 PBO:0104134 Fig. 7
PMID:15121844 FYPO:0002134 three-hybrid assay involving Uaf2, Prp2, and an RNA fragment containing the heterologous beta-globin 3′ splice site
PMID:15121844 FYPO:0002134 three-hybrid assay involving Uaf2, Prp2, and an RNA fragment containing the heterologous beta-globin 3′ splice site
PMID:15121844 FYPO:0002134 three-hybrid assay involving Uaf2, Prp2, and an RNA fragment containing the heterologous beta-globin 3′ splice site
PMID:15121844 FYPO:0002134 three-hybrid assay involving Uaf2, Prp2, and an RNA fragment containing the heterologous beta-globin 3′ splice site
PMID:15121844 FYPO:0002357 three-hybrid assay involving Uaf2, Prp2, and an RNA fragment containing the heterologous beta-globin 3′ splice site
PMID:15132994 PBO:0107121 We draw two conclu- sions from these data; first, association of Fin1 with the SPB requires activation of the SIN; second, recruitment of Fin1 to the SPB requires the SIN inhibitor Byr4, with which it interacts.
PMID:15132994 FYPO:0006917 is this the correct term?
PMID:15132994 PBO:0107120 Fin1 binds Byr4. (A) Fin1 failed to associate withSPBs when the SIN was either inactive or hyperactive. Fin1 failed to bind to the SPB when byr4+ was deleted (Table 1).
PMID:15132994 PBO:0107120 Fin1 binds Byr4. (A) Fin1 failed to associate with SPBs when the SIN was either inactive or hyperactive.
PMID:15132994 PBO:0033837 fig 1 c
PMID:15132994 PBO:0018346 fig 1 c
PMID:15132994 PBO:0107120 Fin1 failed to bind to the SPB when byr4+ was deleted (Table 1).
PMID:15147872 FYPO:0005342 fig 3a
PMID:15147872 PBO:0096456 fig 2
PMID:15147872 PBO:0096455 table1
PMID:15147872 PBO:0096454 table1
PMID:15147872 PBO:0096453 table1
PMID:15147872 PBO:0037885 fig 1 c. figure 2
PMID:15147872 PBO:0037884 fig 1 a b
PMID:15147872 PBO:0096452 fig 1 a b
PMID:15147872 PBO:0037889 fig 4 abnormally segregating nuclear membrane #2863 PENDING
PMID:15155581 PBO:0093579 Fig 3
PMID:15155581 PBO:0103071 basal phosphorylation on T412 & S423
PMID:15155581 FYPO:0003489 Fig 3
PMID:15155581 PBO:0094252 Fig 1
PMID:15155581 PBO:0103061 Fig 1
PMID:15155581 PBO:0094252 Fig 1
PMID:15155581 PBO:0103061 Fig 1
PMID:15155581 PBO:0093580 Fig 3
PMID:15155581 PBO:0093579 Fig 3
PMID:15155581 PBO:0097512 Fig 3
PMID:15155581 PBO:0096806 Fig 3
PMID:15155581 PBO:0093581 Fig 3
PMID:15155581 FYPO:0000267 Fig 3; same as either single mutant
PMID:15155581 PBO:0100925 Fig 2
PMID:15155581 PBO:0103061 Fig 2
PMID:15155581 PBO:0103062 Fig 2
PMID:15155581 PBO:0103064 Fig 2
PMID:15155581 PBO:0103064 Fig 2
PMID:15155581 PBO:0093579 Fig 3
PMID:15155581 PBO:0103065 Fig 4
PMID:15155581 PBO:0103065 Fig 4
PMID:15155581 FYPO:0000267 Fig 3
PMID:15155581 PBO:0103063 Fig 4
PMID:15155581 PBO:0093579 Fig 3
PMID:15155581 FYPO:0003489 Fig 3
PMID:15155581 FYPO:0000267 Fig 3
PMID:15155581 PBO:0103062 Fig 1
PMID:15155581 FYPO:0000267 Fig 3
PMID:15155581 PBO:0096806 Fig 3
PMID:15155581 PBO:0100925 Fig 1
PMID:15155581 PBO:0103062 Fig 1
PMID:15155581 PBO:0094252 Fig 1
PMID:15155581 PBO:0103061 Fig 1
PMID:15155581 PBO:0094252 Fig 1
PMID:15155581 PBO:0103061 Fig 1
PMID:15155581 PBO:0103065 Fig 4
PMID:15155581 PBO:0100317 Fig 5
PMID:15155581 PBO:0100318 Fig 5
PMID:15155581 PBO:0103063 Fig 4
PMID:15155581 PBO:0103066 Fig 5
PMID:15155581 PBO:0100317 Fig 5
PMID:15155581 PBO:0103066 Fig 5
PMID:15155581 PBO:0100318 Fig 5
PMID:15161942 FYPO:0004418 a reminder why we compounded these phenotypes: nuclear accumulation of poly(A)+ RNA was observed only in cells with the cut phenotype in ptr11-1. No nuclear accumulation was observed in cells without the cut phenotype indicating a possible relationship between the cut phenotype and the nuclear accumulation of poly(A)+ RNA in this mutant.
PMID:15161942 FYPO:0004418 a reminder why we compounded these phenotypes: nuclear accumulation of poly(A)+ RNA was observed only in cells with the cut phenotype in ptr11-1. No nuclear accumulation was observed in cells without the cut phenotype indicating a possible relationship between the cut phenotype and the nuclear accumulation of poly(A)+ RNA in this mutant.
PMID:15161942 FYPO:0004418 a reminder why we compounded these phenotypes: nuclear accumulation of poly(A)+ RNA was observed only in cells with the cut phenotype in ptr11-1. No nuclear accumulation was observed in cells without the cut phenotype indicating a possible relationship between the cut phenotype and the nuclear accumulation of poly(A)+ RNA in this mutant.
PMID:15161942 FYPO:0004121 a reminder why we compounded these phenotypes: nuclear accumulation of poly(A)+ RNA was observed only in cells with the cut phenotype in ptr11-1. No nuclear accumulation was observed in cells without the cut phenotype indicating a possible relationship between the cut phenotype and the nuclear accumulation of poly(A)+ RNA in this mutant.
PMID:15161942 FYPO:0004418 a reminder why we compounded these phenotypes: nuclear accumulation of poly(A)+ RNA was observed only in cells with the cut phenotype in ptr11-1. No nuclear accumulation was observed in cells without the cut phenotype indicating a possible relationship between the cut phenotype and the nuclear accumulation of poly(A)+ RNA in this mutant.
PMID:15161942 FYPO:0004418 a reminder why we compounded these phenotypes: nuclear accumulation of poly(A)+ RNA was observed only in cells with the cut phenotype in ptr11-1. No nuclear accumulation was observed in cells without the cut phenotype indicating a possible relationship between the cut phenotype and the nuclear accumulation of poly(A)+ RNA in this mutant.
PMID:15161942 FYPO:0004418 a reminder why we compounded these phenotypes: nuclear accumulation of poly(A)+ RNA was observed only in cells with the cut phenotype in ptr11-1. No nuclear accumulation was observed in cells without the cut phenotype indicating a possible relationship between the cut phenotype and the nuclear accumulation of poly(A)+ RNA in this mutant.
PMID:15161942 FYPO:0004418 a reminder why we compounded these phenotypes: nuclear accumulation of poly(A)+ RNA was observed only in cells with the cut phenotype in ptr11-1. No nuclear accumulation was observed in cells without the cut phenotype indicating a possible relationship between the cut phenotype and the nuclear accumulation of poly(A)+ RNA in this mutant.
PMID:15161942 FYPO:0004418 a reminder why we compounded these phenotypes: nuclear accumulation of poly(A)+ RNA was observed only in cells with the cut phenotype in ptr11-1. No nuclear accumulation was observed in cells without the cut phenotype indicating a possible relationship between the cut phenotype and the nuclear accumulation of poly(A)+ RNA in this mutant.
PMID:15161942 FYPO:0004418 a reminder why we compounded these phenotypes: nuclear accumulation of poly(A)+ RNA was observed only in cells with the cut phenotype in ptr11-1. No nuclear accumulation was observed in cells without the cut phenotype indicating a possible relationship between the cut phenotype and the nuclear accumulation of poly(A)+ RNA in this mutant.
PMID:15161942 FYPO:0004418 a reminder why we compounded these phenotypes: nuclear accumulation of poly(A)+ RNA was observed only in cells with the cut phenotype in ptr11-1. No nuclear accumulation was observed in cells without the cut phenotype indicating a possible relationship between the cut phenotype and the nuclear accumulation of poly(A)+ RNA in this mutant.
PMID:15161942 FYPO:0004418 a reminder why we compounded these phenotypes: nuclear accumulation of poly(A)+ RNA was observed only in cells with the cut phenotype in ptr11-1. No nuclear accumulation was observed in cells without the cut phenotype indicating a possible relationship between the cut phenotype and the nuclear accumulation of poly(A)+ RNA in this mutant.
PMID:15161942 FYPO:0004418 a reminder why we compounded these phenotypes: nuclear accumulation of poly(A)+ RNA was observed only in cells with the cut phenotype in ptr11-1. No nuclear accumulation was observed in cells without the cut phenotype indicating a possible relationship between the cut phenotype and the nuclear accumulation of poly(A)+ RNA in this mutant.
PMID:15161942 FYPO:0004418 a reminder why we compounded these phenotypes: nuclear accumulation of poly(A)+ RNA was observed only in cells with the cut phenotype in ptr11-1. No nuclear accumulation was observed in cells without the cut phenotype indicating a possible relationship between the cut phenotype and the nuclear accumulation of poly(A)+ RNA in this mutant.
PMID:15161942 FYPO:0004397 a reminder why we compounded these phenotypes: nuclear accumulation of poly(A)+ RNA was observed only in cells with the cut phenotype in ptr11-1. No nuclear accumulation was observed in cells without the cut phenotype indicating a possible relationship between the cut phenotype and the nuclear accumulation of poly(A)+ RNA in this mutant.
PMID:15161942 FYPO:0004418 a reminder why we compounded these phenotypes: nuclear accumulation of poly(A)+ RNA was observed only in cells with the cut phenotype in ptr11-1. No nuclear accumulation was observed in cells without the cut phenotype indicating a possible relationship between the cut phenotype and the nuclear accumulation of poly(A)+ RNA in this mutant.
PMID:15173168 PBO:0094255 residue T11
PMID:15173168 PBO:0102382 residue T11
PMID:15173168 PBO:0109147 inferred from phenotypes of mrc1delta, rad3delta, Cds1-Rad26 fusion, other cds1 alleles, and combinations thereof
PMID:15173168 PBO:0094255 residue T11
PMID:15173168 PBO:0094255 residue T11
PMID:15173168 PBO:0094255 residue T11
PMID:15173168 PBO:0094255 residue T11
PMID:15173168 PBO:0094255 residue T11
PMID:15173168 PBO:0094255 residue T11
PMID:15173168 PBO:0094255 residue T11
PMID:15173168 PBO:0094255 residue T11
PMID:15173168 PBO:0094254 residue T11
PMID:15173383 FYPO:0000444 TEV protease present; Cdc6 truncated
PMID:15173383 FYPO:0002061 TEV protease present; Cdc6 truncated
PMID:15175657 FYPO:0002060 dns
PMID:15177031 PBO:0108155 Fig6 E
PMID:15177031 PBO:0102694 Fig 6A,B GFPmal3 is mildly overexpressed from the repressed nmt1 promoter
PMID:15177031 PBO:0108159 Fig 6C,D GFPmal3 is mildly overexpressed from the repressed nmt1 promoter
PMID:15177031 PBO:0108158 (plus end directed)
PMID:15177031 PBO:0108157 Fig 5E,F tea2-GFP is mildly overexpressed from the repressed integrated nmt1 promoter
PMID:15177031 FYPO:0002760 Fig 5E,F tea2-GFP is mildly overexpressed from the repressed integrated nmt1 promoter
PMID:15177031 PBO:0108156 Fig 5A,B Endogenous tea2 tagged with GFP
PMID:15177031 PBO:0103838 Fig 5A,B Endogenous tea2 tagged with GFP
PMID:15177031 PBO:0108155 Fig 5A,B Endogenous tea2 tagged with GFP
PMID:15177031 PBO:0108154 Fig 5C
PMID:15177031 PBO:0108153 Fig 4I
PMID:15177031 PBO:0102425 Fig 4E-H
PMID:15177031 PBO:0108152 Fig 4C
PMID:15177031 PBO:0108151 Fig 4C Tip1YFP is expressed from endogenous tip1 gene tagged with YFP
PMID:15177031 PBO:0103837 Fig 4E-H Tip1YFP is expressed from endogenous tip1 gene tagged with YFP
PMID:15177031 PBO:0108151 Fig 4A,B
PMID:15177031 PBO:0103837 Fig 4A,B
PMID:15177031 PBO:0108150 data not shown
PMID:15177031 PBO:0108149 data not shown
PMID:15177031 PBO:0037217 co-localises with tip1
PMID:15177031 PBO:0093701 Fig 2 same phenotype as tea2delta and tip1delta single mutants
PMID:15177031 PBO:0037218 Fig 2 same phenotype as tea2delta and tip1delta single mutants
PMID:15177031 FYPO:0002760 Fig 2 same phenotype as tea2delta and tip1delta single mutants
PMID:15177031 PBO:0037217 Fig 1 live imaging of Tip1YFP and CFP tubulin
PMID:15177031 PBO:0108160 Fig6E
PMID:15177031 PBO:0018345 colocalises with tip1
PMID:15177031 FYPO:0002060 Fig 2 same phenotype as tea2delta and tip1delta single mutants
PMID:15184401 PBO:0097801 fig 6F
PMID:15184401 PBO:0097022 fig 4F
PMID:15184401 PBO:0097022 fig 4F
PMID:15184401 PBO:0097592 Fig. 4 D
PMID:15184401 PBO:0097593 Fig. 4 D
PMID:15184401 PBO:0094424 Fig. 1 C/ Fig3
PMID:15184401 PBO:0097022 fig 4F
PMID:15184401 PBO:0097802 fig 6F
PMID:15184401 PBO:0097593 Fig. 1 C
PMID:15184401 PBO:0094468 Fig. 1 C
PMID:15184401 FYPO:0001122 Fig 1E
PMID:15184401 FYPO:0001122 Fig 1E
PMID:15184401 PBO:0097592 Fig. 1 C
PMID:15184401 PBO:0097022 fig 4F
PMID:15184401 PBO:0097592 Fig. 1 C
PMID:15184401 PBO:0097593 Fig. 1 C
PMID:15184401 PBO:0097799 (G2) Fig. 6 B
PMID:15184401 PBO:0097800 Fig. 6 B (G2)
PMID:15184401 PBO:0097799 Fig. 6 C . (G2)
PMID:15184401 PBO:0097801 fig 6F
PMID:15184402 PBO:0037217 During mitosis, tea1p persists at the cell tips, whereas for3p and bud6p leave the cell tip and accumulate more at the cell division plane.
PMID:15184402 PBO:0100352 During mitosis, tea1p persists at the cell tips, whereas for3p and bud6p leave the cell tip and accumulate more at the cell division plane.
PMID:15189983 FYPO:0006141 figure1
PMID:15189983 PBO:0099908 fig 7
PMID:15189983 PBO:0093784 figure1
PMID:15189983 PBO:0099907 fig 7
PMID:15189983 PBO:0099906 fig 7
PMID:15189983 PBO:0099905 fig 7
PMID:15189983 PBO:0092140 Fig. 7 (lanes 1 and 2), we observed that both cgs1 and pka1 are transcriptionally induced by glucose starvation.
PMID:15189983 PBO:0092140 Fig. 7 (lanes 1 and 2), we observed that both cgs1 and pka1 are transcriptionally induced by glucose starvation.
PMID:15189983 PBO:0099904 table 3
PMID:15189983 PBO:0099904 table 3
PMID:15189983 PBO:0095677 fig 6
PMID:15189983 PBO:0099903 fig 6
PMID:15189983 PBO:0093605 fig 6
PMID:15189983 PBO:0093605 fig 6
PMID:15189983 FYPO:0000245 fig 6
PMID:15189983 PBO:0093824 For cgs1-1 mu- tant cells, pregrowth on YEA medium results in a nearly 100- fold loss of mating efficiency, as expected. More surprisingly, we found that pregrowth of the cgs1-1 strain on PM medium reduces the mating efficiency defect to only fourfold (Table 2).
PMID:15189983 PBO:0093825 For cgs1-1 mu- tant cells, pregrowth on YEA medium results in a nearly 100- fold loss of mating efficiency, as expected. More surprisingly, we found that pregrowth of the cgs1-1 strain on PM medium reduces the mating efficiency defect to only fourfold (Table 2).
PMID:15189983 PBO:0099902 he FWP190 (git2) cells can grow in the pres- ence of 2 M sorbitol, which is lethal to JSP12 (git2 spc1-12) and JSP29 (git2 wis1-29) cells. Therefore, the loss of adenyl- ate cyclase appears to confer a salt-sensitive, but not an os- motically sensitive, growth defect.
PMID:15189983 FYPO:0001214 git2 strains themselves were severely defective for growth on YEA medium containing 1 M KCl (Fig. 1).
PMID:15189983 FYPO:0006141 figure1
PMID:15189983 FYPO:0006141 figure1
PMID:15189983 PBO:0099902 he FWP190 (git2) cells can grow in the pres- ence of 2 M sorbitol, which is lethal to JSP12 (git2 spc1-12) and JSP29 (git2 wis1-29) cells. Therefore, the loss of adenyl- ate cyclase appears to confer a salt-sensitive, but not an os- motically sensitive, growth defect.
PMID:15189983 FYPO:0000961 he FWP190 (git2) cells can grow in the pres- ence of 2 M sorbitol, which is lethal to JSP12 (git2 spc1-12) and JSP29 (git2 wis1-29) cells. Therefore, the loss of adenyl- ate cyclase appears to confer a salt-sensitive, but not an os- motically sensitive, growth defect.
PMID:15189983 FYPO:0000961 he FWP190 (git2) cells can grow in the pres- ence of 2 M sorbitol, which is lethal to JSP12 (git2 spc1-12) and JSP29 (git2 wis1-29) cells. Therefore, the loss of adenyl- ate cyclase appears to confer a salt-sensitive, but not an os- motically sensitive, growth defect.
PMID:15189983 FYPO:0001490 figure2
PMID:15189983 FYPO:0001490 figure2
PMID:15189983 FYPO:0001490 figure2
PMID:15189983 FYPO:0002199 unlike JSP12 (git2 spc1-12) and JSP29 (git2 wis1-29), cells that elongate and die, cells of the parental strain FWP190 (git2) appear to simply arrest growth (Fig. 2)
PMID:15194812 PBO:0097127 Cdc45 reappears quickly after shift from restrictive to permissive temperature
PMID:15194814 FYPO:0004274 homozygous diploid
PMID:15194814 FYPO:0004273 homozygous diploid
PMID:15218150 PBO:0112540 Fig. 2B
PMID:15218150 GO:0141194 Fig. 3
PMID:15218150 GO:0141194 Fig. 3
PMID:15218150 PBO:0112700 Fig. 4B
PMID:15218150 PBO:0112699 Fig. 4B
PMID:15218150 FYPO:0008212 Fig. 2B
PMID:15218150 FYPO:0008212 Fig. 2B
PMID:15218150 FYPO:0008212 Fig. 2B
PMID:15218150 FYPO:0008212 Fig. 2B
PMID:15218150 FYPO:0008212 Fig. 2B
PMID:15218150 FYPO:0008212 Fig. 2B
PMID:15218150 FYPO:0005865 Fig. 2B
PMID:15218150 PBO:0112683 Fig. 2B
PMID:15218150 PBO:0112683 Fig. 2B
PMID:15218150 PBO:0112683 Fig. 2B
PMID:15218150 FYPO:0002336 Fig. 1B
PMID:15218150 FYPO:0002336 Fig. 1B
PMID:15218150 FYPO:0002336 Fig. 1B
PMID:15218150 FYPO:0002336 Fig. 1B
PMID:15218150 PBO:0095653 Fig. 1B
PMID:15218150 PBO:0095653 Fig. 1B
PMID:15218150 PBO:0095651 Fig. 1B
PMID:15218150 PBO:0095651 Fig. 1B
PMID:15218150 PBO:0095653 Fig. 1B
PMID:15218150 PBO:0095653 Fig. 1B
PMID:15218150 FYPO:0002336 Fig. 1C
PMID:15218150 PBO:0095651 Fig. 1C
PMID:15218150 PBO:0095651 Fig. 1C
PMID:15218150 PBO:0095651 Fig. 1C
PMID:15218150 FYPO:0007336 Fig. 1C
PMID:15218150 FYPO:0007336 Fig. 1C
PMID:15218150 FYPO:0007336 Fig. 1C
PMID:15218150 FYPO:0007336 Fig. 1C
PMID:15218150 FYPO:0007336 Fig. 1C
PMID:15218150 FYPO:0007336 Fig. 1C
PMID:15218150 PBO:0110928 Fig. 1B
PMID:15218150 PBO:0110928 Fig. 1B
PMID:15218150 PBO:0110928 Fig. 1B
PMID:15218150 PBO:0112698 Fig. 1B
PMID:15218150 PBO:0112540 Fig. 1B
PMID:15218150 PBO:0112540 Fig. 1B
PMID:15218150 PBO:0112540 Fig. 1B
PMID:15218150 PBO:0112540 Fig. 1B
PMID:15218150 PBO:0112540 Fig. 1B
PMID:15218150 PBO:0112540 Fig. 1B
PMID:15218150 FYPO:0005865 Fig. 1B
PMID:15218150 FYPO:0005865 Fig. 1B
PMID:15218150 FYPO:0005865 Fig. 1B
PMID:15218150 FYPO:0005865 Fig. 1B
PMID:15218150 PBO:0097399 Fig. 1B
PMID:15218150 PBO:0097399 Fig. 1B
PMID:15218150 PBO:0097399 Fig. 1B
PMID:15218150 PBO:0097399 Fig. 1B
PMID:15218150 PBO:0097399 Fig. 1B
PMID:15218150 PBO:0097399 Fig. 1B
PMID:15218150 PBO:0110928 Fig. 1C
PMID:15218150 PBO:0112540 Fig. 1C
PMID:15218150 PBO:0112540 Fig. 1C
PMID:15218150 PBO:0112540 Fig. 1C
PMID:15218150 PBO:0112683 Fig. 1C
PMID:15218150 PBO:0112683 Fig. 1C
PMID:15218150 PBO:0112683 Fig. 1C
PMID:15218150 PBO:0112683 Fig. 1C
PMID:15218150 PBO:0112683 Fig. 1C
PMID:15218150 PBO:0112683 Fig. 1C
PMID:15218150 FYPO:0005865 Fig. 1C
PMID:15218150 PBO:0097399 Fig. 1C
PMID:15218150 PBO:0097399 Fig. 1C
PMID:15218150 PBO:0097399 Fig. 1C
PMID:15218150 FYPO:0008212 Fig. 1C
PMID:15218150 FYPO:0008212 Fig. 1C
PMID:15218150 FYPO:0008212 Fig. 1C
PMID:15218150 FYPO:0008212 Fig. 1C
PMID:15218150 FYPO:0008212 Fig. 1C
PMID:15218150 FYPO:0008212 Fig. 1C
PMID:15218150 FYPO:0002336 Fig. 2A
PMID:15218150 PBO:0095651 Fig. 2A
PMID:15218150 PBO:0095651 Fig. 2A
PMID:15218150 PBO:0095651 Fig. 2A
PMID:15218150 PBO:0095651 Fig. 2A
PMID:15218150 PBO:0095651 Fig. 2A
PMID:15218150 PBO:0095651 Fig. 2A
PMID:15218150 FYPO:0002336 Fig. 2B
PMID:15218150 FYPO:0007336 Fig. 2B
PMID:15218150 FYPO:0007336 Fig. 2B
PMID:15218150 FYPO:0007336 Fig. 2B
PMID:15218150 FYPO:0007336 Fig. 2B
PMID:15218150 FYPO:0007336 Fig. 2B
PMID:15218150 FYPO:0007336 Fig. 2B
PMID:15218150 PBO:0112698 Fig. 2A
PMID:15218150 PBO:0112540 Fig. 2A
PMID:15218150 PBO:0112540 Fig. 2A
PMID:15218150 PBO:0112683 Fig. 2A
PMID:15218150 PBO:0112683 Fig. 2A
PMID:15218150 PBO:0112683 Fig. 2A
PMID:15218150 PBO:0112683 Fig. 2A
PMID:15218150 FYPO:0005865 Fig. 2A
PMID:15218150 PBO:0097399 Fig. 2A
PMID:15218150 PBO:0097399 Fig. 2A
PMID:15218150 PBO:0097399 Fig. 2A
PMID:15218150 PBO:0097399 Fig. 2A
PMID:15218150 PBO:0097399 Fig. 2A
PMID:15218150 PBO:0097399 Fig. 2A
PMID:15219990 GO:0051537 spectra looks the same as Adx
PMID:15226378 FYPO:0003182 homozygous diploid
PMID:15226378 FYPO:0003182 homozygous diploid
PMID:15226405 FYPO:0004602 frequency of different stages of LE development is different though, but morphology is normal
PMID:15226405 FYPO:0004602 frequency of different stages of LE development is different though, but morphology is normal
PMID:15249580 PBO:0103033 mishapen
PMID:15249580 PBO:0109046 (vw fixed from GO:0052812 to GO:0016308 based on e-mail from Pgaudet) The data are consistent with a model in which its3p, like its mammalian homologue, can convert PI(3)P to PI(3,4)P2 and PI(3,4,5)P3.
PMID:15249580 PBO:0103032 The data are consistent with a model in which its3p, like its mammalian homologue, can convert PI(3)P to PI(3,4)P2 and PI(3,4,5)P3.
PMID:15249580 GO:0004439 fig 1c
PMID:15249580 GO:0016314 fig 1c
PMID:15265986 PBO:0096462 in response to cytokinesis after mitosis checkpoint
PMID:15265986 PBO:0096461 in response to cytokinesis after mitosis checkpoint
PMID:15278909 PBO:0019995 during premeiotic DNA replication
PMID:15292231 PBO:0111982 Fig. 2B
PMID:15292231 PBO:0111981 Fig. 2B
PMID:15292231 PBO:0111985 Fig. 2B
PMID:15292231 PBO:0111984 Fig. 2B
PMID:15292231 PBO:0111983 Fig. 2B
PMID:15292231 PBO:0111982 Fig. 2B
PMID:15292231 PBO:0111981 Fig. 2B
PMID:15292231 PBO:0111980 Fig. 2B
PMID:15292231 PBO:0111980 Fig. 2B Furthermore, ChIP analysis showed that the absence of atf1 and pcr1 resulted in a considerable increase in histone H3/H4 acetylation and euchromatic-specific H3 Lys-4 methylation of the selected region
PMID:15292231 PBO:0112046 Fig. 1. An atf1 deletion strain carrying the ade6� reporter gene inserted at the mat3-M locus displayed a loss of silencing of the reporter gene (Fig. 1A).
PMID:15292231 PBO:0111990 Fig. 6B
PMID:15292231 PBO:0111976 Fig. 3 Moreover, the ade6-off to ade6-on conversion in �sty1 and �wis1 mutants was significantly reduced relative to wild- type cells, indicating that sty1 and wis1 deletions enhanced stabilization of the epigenetic inheritance of the silent states (Fig. 3B).
PMID:15292231 PBO:0111976 Fig. 3
PMID:15292231 PBO:0111976 Fig. 3
PMID:15292231 GO:0030466 RNAi-independent mechanism
PMID:15292231 GO:0030466 RNAi-independent mechanism
PMID:15292231 PBO:0111988 Fig. 2C
PMID:15292231 PBO:0111987 Fig. 2C
PMID:15292231 PBO:0111987 Fig. 2C
PMID:15292231 PBO:0111986 Fig. 2B
PMID:15292231 PBO:0111979 Fig. 3
PMID:15292231 PBO:0111984 Fig. 2B
PMID:15292231 PBO:0111983 Fig. 2B
PMID:15292231 PBO:0101106 Fig. 1A In contrast, the atf1 deletion resulted in increased transcriptional repression at both centromeres and telomeres (Fig. 1A).
PMID:15292231 PBO:0111976 Fig. 1 Similar to atf1 mutants, �pcr1 showed reduced silencing, but the effect was weaker than that of �atf1 or �atf1�pcr1 (Fig. 1B).
PMID:15292231 PBO:0111977 Fig. 1B
PMID:15292231 PBO:0111978 Fig. 1
PMID:15292231 GO:0030466 RNAi-independent mechanism
PMID:15292231 GO:0090055 The results presented above suggest that the kinase activity of Wis1 and Sty1/Spc1 is required for proper control of hetero chromatin assembly by Atf1 and Pcr1.
PMID:15292231 GO:0090055 The results presented above suggest that the kinase activity of Wis1 and Sty1/Spc1 is required for proper control of hetero chromatin assembly by Atf1 and Pcr1.
PMID:15292231 PBO:0112047 ATF/CREB-binding
PMID:15292231 PBO:0112047 ATF/CREB-binding
PMID:15292231 PBO:0111992 Fig. 2B
PMID:15292231 PBO:0111991 Fig. 6B
PMID:15292231 PBO:0111981 Fig. 6B
PMID:15292231 PBO:0111989 Fig. 6B
PMID:15292231 PBO:0111975 Fig. 1A In contrast, the atf1 deletion resulted in increased transcriptional repression at both centromeres and telomeres (Fig. 1A).
PMID:15297457 GO:0031573 would it be better/safer to annotate to parent (generic intra-S checkpoint term)?
PMID:15314153 PBO:0093561 25 degrees
PMID:15314153 FYPO:0002061 30 degrees
PMID:15316017 GO:0052658 activated_by(CHEBI:18420)| inhibited_by(CHEBI:29108)
PMID:15329725 FYPO:0005428 Fig. 1f)
PMID:15329725 FYPO:0002102 Fig. 1d and Fig. 1h
PMID:15329725 FYPO:0005429 Fig. 1h
PMID:1533272 PBO:0104192 Fig 2. Cdc2-DL2 over expressed from an integrated pREP1 (pMNS21) plasmid.
PMID:1533272 PBO:0104193 Fig 5. Cdc2-DL2 over expressed from an integrated pREP1 (pMNS21) plasmid. Phosphorylation on threonine, but position(s) not determined.
PMID:1533272 FYPO:0001491 cdc13 expressed from own promoter on multi copy plasmid pUR18
PMID:1533272 PBO:0097954 Fig 3. Cdc2-DL2 over expressed from an integrated pREP1 (pMNS21) plasmid.
PMID:1533272 PBO:0104194 Fig 7 Cdc2-DL2 over expressed from an integrated pREP1 (pMNS21) plasmid. Binds to cdc13 but this is reduced compared to binding of cdc2+ to cdc13
PMID:1533272 PBO:0102314 Fig 4 Histone H1 used as substrate. Cdc2-DL2 over expressed from an integrated pREP1 (pMNS21) plasmid.
PMID:15340008 PBO:0111723 Fig. 1D &2
PMID:15340008 FYPO:0002150 Fig. 5B
PMID:15340008 FYPO:0002150 Fig. 5B
PMID:15340008 PBO:0111726 Fig. 7
PMID:15340008 FYPO:0008162 Fig 1,3, & 4
PMID:15340008 FYPO:0003306 Fig. 1 C
PMID:15340008 FYPO:0002150 Fig. 5A
PMID:15340008 FYPO:0003612 Fig. 5D
PMID:15340008 FYPO:0003612 Fig. 5C
PMID:15340008 PBO:0111725 Fig. 4C
PMID:15340008 PBO:0111724 Fig. 3A
PMID:15340008 PBO:0111724 Fig. 3A
PMID:15340008 PBO:0102116 Fig. 3A
PMID:15340008 PBO:0102116 Fig. 3A
PMID:15340008 PBO:0020742 Fig. 3
PMID:15340008 PBO:0020742 Fig. 3
PMID:15340008 FYPO:0001513 Fig. 3
PMID:15340008 FYPO:0001513 Fig. 3
PMID:15340008 FYPO:0001513 Fig. 2
PMID:15340008 FYPO:0001761 Fig. 2
PMID:15340008 PBO:0111722 Fig. 1
PMID:15340008 FYPO:0002150 Fig. 5A
PMID:15359282 PBO:0096188 Fig. 4C
PMID:15359282 GO:0005634 figure 2
PMID:15359282 PBO:0111730 Fig. 3A
PMID:15359282 PBO:0111731 Fig. 3A
PMID:15359282 PBO:0111732 Fig. 3
PMID:15359282 PBO:0093564 Fig. 4A
PMID:15359282 PBO:0093562 Fig. 4A
PMID:15359282 PBO:0103456 Fig. 4B
PMID:15359282 PBO:0103455 Fig. 4B
PMID:15359282 PBO:0096191 Fig. 4C
PMID:15359282 PBO:0096191 Fig. 4C
PMID:15359282 PBO:0096189 Fig. 4C
PMID:15359282 PBO:0096188 Fig. 4C
PMID:15359282 PBO:0097301 Fig. 6A
PMID:15359282 PBO:0097301 Fig. 6A
PMID:15359282 PBO:0097301 Fig. 6A
PMID:15359282 PBO:0097301 Fig. 6A
PMID:15359282 FYPO:0002150 Fig. 6A
PMID:15359282 FYPO:0002150 Fig. 6A
PMID:15359282 FYPO:0002150 Fig. 6A
PMID:15359282 FYPO:0002150 Fig. 6A
PMID:15359282 PBO:0093634 Fig. 6B
PMID:15359282 PBO:0093632 Fig. 6B
PMID:15359282 PBO:0111735 Figure 3 (E1, activating)
PMID:15359282 PBO:0111734 Figure 3 (E2)
PMID:15359282 PBO:0111733 Figure 3 (E3)
PMID:15359282 FYPO:0002687 Fig. 6B
PMID:15359282 FYPO:0002687 Fig. 6B
PMID:15359282 FYPO:0002687 Fig. 6B
PMID:15367656 PBO:0033073 no hydroxyurea
PMID:15369671 PBO:0101419 fig4
PMID:15369671 PBO:0096686 fig4
PMID:15369671 PBO:0101421 fig4
PMID:15371542 FYPO:0001839 fig 1a
PMID:15371542 FYPO:0000964 fig 1a
PMID:15371542 FYPO:0000091 fig1
PMID:15371542 FYPO:0001840 fig1
PMID:15372076 PBO:0111009 fig 1
PMID:15372076 PBO:0107146 fig 1
PMID:15372076 PBO:0111013 fig 1
PMID:15372076 PBO:0111014 Figure 1
PMID:15372076 PBO:0111015 Figure 1
PMID:15372076 PBO:0111016 Figure 1
PMID:15372076 GO:0031508 Therefore, Chp1 protein was also involved in the production or processing of centromeric RNA transcripts, which might be linked to heterochromatin estab- lishment.
PMID:15372076 GO:0005721 Figure 1
PMID:15372076 GO:0140720 Figure 1
PMID:15372076 GO:0031934 Figure 1
PMID:15372076 GO:0005721 Figure 1
PMID:15372076 GO:0005721 Figure 1
PMID:15372076 GO:0140720 Figure 1
PMID:15372076 GO:0140720 Figure 1
PMID:15372076 GO:0031934 Figure 1
PMID:15372076 GO:0031934 Figure 1
PMID:15372076 PBO:0111008 We found that the association of Chp1-13myc with the three heterochromatic regions (CEN, MAT, and TEL) was not affected in the absence of swi6 þ or chp2 þ (Figure 2A).
PMID:15372076 PBO:0110927 We found that the association of Chp1-13myc with the three heterochromatic regions (CEN, MAT, and TEL) was not affected in the absence of swi6 þ or chp2 þ (Figure 2A).
PMID:15372076 PBO:0097399 We found that H3-K9 methylation at the three heterochromatic regions (CEN- dg223, MAT-K-R, or TEL-E12) was reduced to a level compar- able to that in Dclr4 (Figure 6A),
PMID:15372076 GO:0031508 H3-K9 methylation at the three heterochromatic regions (CEN-dg223,MAT-K-R, or TEL-E12) was reduced to a level comparable to that in Dclr4 (Figure 6A), suggesting that Rik1 has a critical role in H3-K9 methylation at the native heterochromatic regions.
PMID:15372076 GO:0030466 H3-K9 methylation at the three heterochromatic regions (CEN-dg223,MAT-K-R, or TEL-E12) was reduced to a level comparable to that in Dclr4 (Figure 6A), suggesting that Rik1 has a critical role in H3-K9 methylation at the native heterochromatic regions.
PMID:15372076 GO:0031509 H3-K9 methylation at the three heterochromatic regions (CEN-dg223,MAT-K-R, or TEL-E12) was reduced to a level comparable to that in Dclr4 (Figure 6A), suggesting that Rik1 has a critical role in H3-K9 methylation at the native heterochromatic regions.
PMID:15372076 PBO:0108387 We found that H3-K9 methylation at the three heterochromatic regions (CEN- dg223, MAT-K-R, or TEL-E12) was reduced to a level compar- able to that in Dclr4 (Figure 6A),
PMID:15372076 PBO:0097399 We found that H3-K9 methylation at the three heterochromatic regions (CEN- dg223, MAT-K-R, or TEL-E12) was reduced to a level compar- able to that in Dclr4 (Figure 6A),
PMID:15372076 PBO:0111020 We found that H3-K9 methylation at the three heterochromatic regions (CEN- dg223, MAT-K-R, or TEL-E12) was reduced to a level compar- able to that in Dclr4 (Figure 6A),
PMID:15372076 PBO:0108387 We found that H3-K9 methylation at the three heterochromatic regions (CEN- dg223, MAT-K-R, or TEL-E12) was reduced to a level compar- able to that in Dclr4 (Figure 6A),
PMID:15372076 FYPO:0003096 Interestingly, we found that, although deletion of either swi6 þ or chp2 þ did not affect the H3-K9 methylation at MAT (K-R) and TEL (E12) in the Dchp1 background, the methylation level in these regions was severely decreased in the triple-mutant strain (Figure 5D, Dchp1Dchp2Dswi6). Again, these results demonstrate that Swi6 and Chp2 are required for the maintenance of H3-K9 methylation at the three heterochromatic regions, and also indicate that Swi6 and Chp2 have overlapping functions in the maintenance of H3-K9 methylation.
PMID:15372076 FYPO:0003096 nexpectedly, the cen- tromeric H3-K9 methylation was also severely decreased in the Dchp1Dchp2 strain (Figure 5D, Dchp1Dchp2).
PMID:15372076 FYPO:0003097 Interestingly, we found that swi6þ dele- tion caused a loss of the H3-K9 methylation at CEN (dg223) in the Dchp1 background (Figure 5D, Dchp1Dswi6), suggesting that Swi6 is required for the maintenance of centromeric H3- K9 methylation in the Dchp1 strain.
PMID:15372076 FYPO:0003235 Intriguingly, we found that, even in the Dchp1 cells, histone H3 in native centromeric heterochromatin (CEN-dg223 locus) remained methylated at lysine 9 (Figure 4B, Dchp1).
PMID:15372076 FYPO:0003235 n Dswi6 or Dchp2 cells, the three heterochromatic regions were enriched in K9-methylated H3 at the same level as in wild-type cells (Figure 5B).
PMID:15372076 FYPO:0003235 Intriguingly, we found that, even in the Dchp1 cells, histone H3 in native centromeric heterochromatin (CEN-dg223 locus) remained methylated at lysine 9 (Figure 4B, Dchp1).
PMID:15372076 GO:0031509 The present data also demonstrate that Chp1 function is required not only for the centromeres but also for the mating-type region and telomeres.
PMID:15372076 GO:0030466 The present data also demonstrate that Chp1 function is required not only for the centromeres but also for the mating-type region and telomeres.
PMID:15372076 PBO:0111019 Figure 1
PMID:15372076 PBO:0111018 Figure 1
PMID:15372076 PBO:0111017 Figure 1
PMID:15372076 PBO:0110927 We found that the association of Chp1-13myc with the three heterochromatic regions (CEN, MAT, and TEL) was not affected in the absence of swi6 þ or chp2 þ (Figure 2A).
PMID:15372076 PBO:0111008 We found that the association of Chp1-13myc with the three heterochromatic regions (CEN, MAT, and TEL) was not affected in the absence of swi6 þ or chp2 þ (Figure 2A).
PMID:15372076 PBO:0111020 We found that H3-K9 methylation at the three heterochromatic regions (CEN- dg223, MAT-K-R, or TEL-E12) was reduced to a level compar- able to that in Dclr4 (Figure 6A),
PMID:15372076 PBO:0110929 We found that the association of Chp1-13myc with the three heterochromatic regions (CEN, MAT, and TEL) was not affected in the absence of swi6 þ or chp2 þ (Figure 2A).
PMID:15372076 PBO:0110929 We found that the association of Chp1-13myc with the three heterochromatic regions (CEN, MAT, and TEL) was not affected in the absence of swi6 þ or chp2 þ (Figure 2A).
PMID:15372076 PBO:0111009 In contrast, the centromeric localization of Swi6 or Chp2-13myc was specifically de- creased in the Dchp1 cells (Figures 2B and C, Dchp1)
PMID:15372076 PBO:0107146 In contrast, the centromeric localization of Swi6 or Chp2-13myc was specifically de- creased in the Dchp1 cells (Figures 2B and C, Dchp1)
PMID:15372076 PBO:0111010 Interestingly, Swi6 was required for the localization of Chp2 to the mating-type region or telomeres but not to the centromeres (Figure 2B, Dswi6).
PMID:15372076 PBO:0111011 Interestingly, Swi6 was required for the localization of Chp2 to the mating-type region or telomeres but not to the centromeres (Figure 2B, Dswi6).
PMID:15372076 PBO:0111012 Interestingly, Swi6 was required for the localization of Chp2 to the mating-type region or telomeres but not to the centromeres (Figure 2B, Dswi6).
PMID:15385632 PBO:0098863 Figure 6, A, D, and E
PMID:15385632 GO:0005515 Figure 2A,Figure 2, D and E
PMID:15385632 GO:0005515 Figure 2A, Figure 2, D and E
PMID:15385632 GO:0005515 Figure 2A
PMID:15385632 GO:0005515 Figure 2A
PMID:15385632 GO:0005515 Figure 2A Figure 2, B and C)
PMID:15385632 GO:0005515 Figure 2A
PMID:15385632 PBO:0098855 Figure 1H and Table 1
PMID:15385632 PBO:0098856 Figure 1I
PMID:15385632 PBO:0098857 Figure 1J Based on the lower recovery of coimmunoprecipitated proteins, this Spn1p-Spn4p complex appears to be less stable than in the presence of Spn2p or Spn3p.
PMID:15385632 GO:0005515 Figure 2, D and E
PMID:15385632 PBO:0098858 Figure 5 C
PMID:15385632 PBO:0098859 Figure 5
PMID:15385632 PBO:0098860 Figure 5
PMID:15385632 PBO:0098860 Figure 5
PMID:15385632 PBO:0098859 Figure 5
PMID:15385632 PBO:0098861 Figure 5
PMID:15385632 PBO:0098862 Figure 6, A, D, and E
PMID:15385632 PBO:0098864 Figure 6, A, D, and E
PMID:15385632 FYPO:0006062 Figure 6, A, D, and E
PMID:15385632 PBO:0098862 Figure 6, A, D, and E
PMID:15385632 PBO:0098865 Figure 6, A, D, and E
PMID:15385632 PBO:0098864 Figure 6, A, D, and E
PMID:15385632 FYPO:0006062 Figure 6, A, D, and E
PMID:15385632 FYPO:0001972 fig5
PMID:15385632 PBO:0098152 fig5
PMID:15385632 FYPO:0006062 fig 6
PMID:15385632 GO:0000921 Combining this observation with our biochemical data, we conclude that a subcomplex of Spn1p-Spn4p is sufficient for formation of ectopic structures and localizing to the medial cortex, but at least one other septin is required for assembly of a ring structure.
PMID:15385632 GO:0000921 Combining this observation with our biochemical data, we conclude that a subcomplex of Spn1p-Spn4p is sufficient for formation of ectopic structures and localizing to the medial cortex, but at least one other septin is required for assembly of a ring structure.
PMID:15385632 GO:0031106 In this case, Spn3p-GFP was recruited to the medial region before mitosis as before (Figure 8A) and it was now assembled into highly organized ring structures that were easily visualized as split rings once septa had formed (Fig- ure 8, B and C). Virtually no diffuse disk structures were observed (Figure 8, B–D). We conclude from this experiment that Mid2p is solely responsible directly or indirectly for regulating septin ring coalesence in S. pombe.
PMID:15385632 FYPO:0006063 erexpression was the relative persistence of septin rings and the inhibition of mitotic progression, as determined by monitoring the for- mation of binucleates (Figure 8A). This result is consistent with our previous results, indicating that prolonged expres- sion of Mid2p stabilizes septin ring structures and influences cell cycle progression (Tasto et al., 2003). erexpression was the relative persistence of septin rings and the inhibition of mitotic progression, as determined by monitoring the for- mation of binucleates (Figure 8A). This result is consistent with our previous results, indicating that prolonged expres- sion of Mid2p stabilizes septin ring structures and influences cell cycle progression (Tasto et al., 2003).
PMID:1538784 GO:0044732 throughout_cell_cycle
PMID:15466421 FYPO:0002890 homozygous diploid
PMID:15466421 FYPO:0000913 homozygous diploid
PMID:15470240 FYPO:0002903 fig2
PMID:15470240 FYPO:0002903 fig2
PMID:15470240 FYPO:0004256 fig2
PMID:15471884 GO:0003690 low affinity
PMID:15471884 GO:0070337 lower affinity than for Y-form DNA
PMID:15485922 FYPO:0005402 same as taz1delta alone
PMID:15485922 FYPO:0005402 same as taz1delta alone
PMID:15504913 FYPO:0008207 Table 1
PMID:15504913 FYPO:0008207 Table 1
PMID:15504913 PBO:0112669 Table 1
PMID:15504913 PBO:0112669 Table 1
PMID:15504913 PBO:0112669 Table 1
PMID:15504913 PBO:0112669 Table 1
PMID:15504913 PBO:0112668 Table 1
PMID:15504913 FYPO:0001367 Fig. 6C
PMID:15504913 FYPO:0001357 Fig. 6B
PMID:15504913 PBO:0112667 Fig. 6B
PMID:15504913 GO:0110085 Rng3p-GFP3 and Rng3p-YFP3 concentrated in contractile rings from anaphase B through constriction (Fig. 5).
PMID:15504913 PBO:0107510 Rng3p-GFP3 and Rng3p-YFP3 concentrated in contractile rings from anaphase B through constriction (Fig. 5).
PMID:15504913 PBO:0099316 Rng3p-GFP3 and Rng3p-YFP3 concentrated in contractile rings from anaphase B through constriction (Fig. 5).
PMID:15504913 FYPO:0001252 Fig. 4C
PMID:15504913 FYPO:0001252 Fig. 4B
PMID:15504913 FYPO:0001252 Fig. 4A
PMID:15504913 FYPO:0000418 Fig. 4C
PMID:15504913 FYPO:0000161 Fig. 4C
PMID:15504913 FYPO:0000418 Fig. 4B
PMID:15504913 FYPO:0000161 Fig. 4B
PMID:15504913 FYPO:0000418 Fig. 4A
PMID:15504913 FYPO:0000161 Fig. 4A
PMID:15504913 PBO:0112666 Fig. 3B and C
PMID:15504913 GO:0016460 Fig. 1
PMID:15504913 GO:0016460 Fig. 1
PMID:15504913 GO:0033275 Fig. 3
PMID:15504913 FYPO:0001357 Fig. 6B
PMID:15504913 PBO:0112669 Table 1
PMID:15504913 FYPO:0008207 Table 1
PMID:15504913 FYPO:0008207 Table 1
PMID:15504913 PBO:0112668 Table 1
PMID:15504913 PBO:0112670 Table 1
PMID:15504913 PBO:0112670 Table 1
PMID:15504913 FYPO:0008207 Table 1
PMID:15504913 FYPO:0008207 Table 1
PMID:15507118 FYPO:0003763 inviable mononucleate aseptate vegetative cell with cell cycle arrest in mitotic G2 phase
PMID:15509783 PBO:0023853 Figure 2A
PMID:15509783 PBO:0112055 checkpoint
PMID:15509783 FYPO:0000229 Fig. 7D
PMID:15509783 FYPO:0004318 Fig. 7D
PMID:15509783 PBO:0097819 Fig. 7B
PMID:15509783 PBO:0097818 Fig. 7B
PMID:15509783 FYPO:0000229 figure 1B
PMID:15509783 FYPO:0004318 figure 1B
PMID:15509783 PBO:0097815 table2
PMID:15509783 PBO:0097814 table2
PMID:15509783 PBO:0097813 table2
PMID:15509783 PBO:0097812 table2
PMID:15509783 PBO:0097811 table2
PMID:15509865 PBO:0102573 (Table 3) assayed using pairing of his2 loci
PMID:15509865 FYPO:0003179 (Table 2).leu1 and his2 loc, reduced 12 fold
PMID:15509865 FYPO:0004093 data not shown
PMID:15509865 FYPO:0006128 DURATION Fig. 2B,C
PMID:15509865 FYPO:0005383 Fig. 2B,C
PMID:15509865 FYPO:0000927 (Fig. 2A)
PMID:15509865 FYPO:0000927 (Fig. 2A)
PMID:15509865 FYPO:0004764 (Fig. 6B,C). in meiotic cells, shmooing cells
PMID:15509865 FYPO:0004731 (Fig. 6A-C), during meiotic prophase, shmooing
PMID:15509865 FYPO:0006130 meiosis
PMID:15509865 FYPO:0004764 (Fig. 6B,C). in meiotic cells, shmooing cells
PMID:15509865 FYPO:0005814 (Fig. 6B,C). in meiotic cells, shmooing cells
PMID:15509865 FYPO:0005814 (Fig. 6B,C). in meiotic cells, shmooing cells
PMID:15509865 FYPO:0003066 data not shown , phenocopies ssm4 &dhc1
PMID:15509865 FYPO:0000927 data not shown , phenocopies ssm4 &dhc1
PMID:15509865 GO:0005515 Fig. 3C).
PMID:15509865 GO:0005515 Fig. 3B
PMID:15509865 GO:0005515 Fig. 3B
PMID:15509865 PBO:0033208 Table 3
PMID:15509865 PBO:0033208 Table 3
PMID:15509865 PBO:0033208 Table 3
PMID:15509865 FYPO:0000678 Add?
PMID:15525536 GO:0072479 only required when there are problems , possibly involved in repair of monoorientation
PMID:15537393 FYPO:0001190 Figure 3c
PMID:15537393 FYPO:0001082 Figure 3d
PMID:15537393 PBO:0109438 figure 2f
PMID:15537393 PBO:0109437 figure 2e
PMID:15537393 PBO:0109436 figure 2e
PMID:15537393 PBO:0109435 figure 2e
PMID:15537393 PBO:0109434 figure 2e
PMID:15537393 PBO:0096587 figure 2e
PMID:15537393 FYPO:0001355 figure 2d
PMID:15537393 FYPO:0002061 figure 2d
PMID:15537393 FYPO:0002196 figure 2f
PMID:15537393 FYPO:0001327 figure 2g
PMID:15537393 FYPO:0000647 Figure 3b
PMID:15537393 PBO:0109439 figure 2f
PMID:15537393 FYPO:0001082 Figure 3d
PMID:15537393 FYPO:0001190 Figure 3c
PMID:15537393 FYPO:0002050 Figure 3b
PMID:15546915 FYPO:0004892 Figure 4 GI Rho1 OEX rescues echinocandin sensitivity
PMID:15546915 FYPO:0002061 figure4
PMID:15546915 FYPO:0007949 (1-3 beta D) As shown in Fig. 6C, there was an increase in the amount of β-glucan in cells that overexpressed rgf3+ compared with wild-type cells (16% and 10%, respectively),
PMID:15546915 FYPO:0007949 As shown in Fig. 6C, there was an increase in the amount of β-glucan in cells that overexpressed rgf3+ compared with wild-type cells (16% and 10%, respectively),
PMID:15546915 PBO:0101163 replace with cytokinetic phase
PMID:15546915 FYPO:0000647 (Fig. 1A
PMID:15546915 FYPO:0002159 (Fig. 1A
PMID:15546915 FYPO:0002150 Fig. 3A
PMID:15546915 FYPO:0001123 Figure 3B indicates a bypass of cytokinesis checkpoint
PMID:15546915 FYPO:0000951 Figure 3 C shrunken cell
PMID:15546915 PBO:0102105 Figure 5 These results indicate that Rgf3p acts as a specific Rho1p activator in S. pombe.
PMID:15546915 FYPO:0001253 Fig. 6A + DAPI staining revealed that, in most multiseptate cells, each compartment contained one nucleus, indicative of a defect in cell separation after septum assembly (not shown)
PMID:15546915 FYPO:0001968 (Fig. 6B)....an increase in enzymatic activity was detected in cells overexpressing rgf3+ compared with the activity observed in the wild-type strain
PMID:15546915 FYPO:0000951 Figure 3 C shrunken cell
PMID:15548596 FYPO:0002134 three-hybrid assay involving Uaf2, Prp2, and an RNA fragment containing the heterologous beta-globin 3′ splice site
PMID:15550243 FYPO:0004126 Fig. 1
PMID:15550243 FYPO:0000964 Neither loss of Set9 protein, its catalytic activity, nor its H4-K20 substrate rendered cells hypersensitive to TBZ over a range of concentrations (10–30 �g/ml) or temperatures (18�C–36�C) (Figure 2D
PMID:15550243 GO:0010468 Fig. 2B
PMID:15550243 PBO:0112170 Fig. 1, 3 and 4
PMID:15550243 PBO:0112169 Fig. 1, 3 and 4
PMID:15550243 PBO:0112167 figure 1
PMID:15550243 PBO:0112168 figure 1
PMID:15550243 PBO:0112176 figure 1
PMID:15550243 PBO:0112165 Fig. 1, 3 and 4
PMID:15550243 PBO:0112164 Fig. 5 Crb2 phosphorylation is markedly compromised in the absence of Set9, even at low IR doses (Figure 5A).
PMID:15550243 PBO:0097793 Fig. 5 Further, the double mutant displays a checkpoint defect equivalent to that of the crb2� mutant (Figure 5C).
PMID:15550243 PBO:0097793 Fig. 5
PMID:15550243 PBO:0112163 Fig. 5B Clearly, this is not the case, as the sensitivity of the double crb2T215A-set9� mutant is much greater than either single mutant alone and equal to deletion of crb2� (Figure 5B).
PMID:15550243 PBO:0112161 Fig. 5B
PMID:15550243 PBO:0112162 Fig. 5
PMID:15550243 PBO:0112161 Fig. 4D
PMID:15550243 PBO:0112163 Fig. 4D
PMID:15550243 PBO:0112163 Fig. 4D
PMID:15550243 PBO:0112163 Fig. 4D
PMID:15550243 PBO:0112163 Fig. 4D
PMID:15550243 PBO:0112191 Fig. 4D
PMID:15550243 PBO:0112191 Fig. 4D
PMID:15550243 GO:0031508 Fig. 2B Fission yeast centromeric gene silencing was also found not to be dependent upon H4-K20 methylation (Figures 2B and 2C).
PMID:15550243 PBO:0093613 resulted in cells hyper- sensitive to DNA damage induced by ultraviolent (UV) light, ionizing radiation (IR), and the topoisomerase I poison camptothecin (CPT) (Figure 3A).
PMID:15550243 PBO:0093613 Fig. 3
PMID:15550243 PBO:0093613 Fig. 3
PMID:15550243 PBO:0105171 Fig. 3
PMID:15550243 PBO:0105171 Fig. 3
PMID:15550243 PBO:0112160 Fig. 4C
PMID:15550243 PBO:0112191 Fig. 4D
PMID:15550243 PBO:0105171 Fig. 3
PMID:15550243 PBO:0093613 Fig. 3
PMID:15550243 PBO:0105171 Fig. 3
PMID:15550243 GO:0006289 Genetic studies indicated that loss of Set9 protein further increased the UV sensitivity of excision repair mutants (rad13, uvde, and rad13-uvde, data not shown), arguing that Set9 does not function in excision repair.
PMID:15550243 PBO:0097794 set9 cells arrested similar to wt but reentered mitosis markedly faster. Unlike wt, 20%–30% of set9 cells exhibited an abberant or “cut-like” mitotic phenotype. Fig. 4
PMID:15550243 PBO:0112191 Fig. 4D
PMID:15550243 PBO:0112191 Fig. 4D
PMID:15550243 PBO:0112191 Fig. 4D
PMID:15550243 PBO:0112161 Fig. 4D
PMID:15550243 PBO:0112191 Fig. 4D
PMID:15550243 PBO:0112161 Fig. 4D
PMID:15550243 GO:0042393 Fig. 1A
PMID:15550243 FYPO:0004218 Fig. 1 Figure 1D shows that the modification is specifically Set9 dependent, as loss of Set9 but not Set1, Set2, Set6, or Clr4 resulted in essentially undetectable mono-, di-, and trimethylated H4-K20.
PMID:15550243 FYPO:0004217 Fig. 1 Figure 1D shows that the modification is specifically Set9 dependent, as loss of Set9 but not Set1, Set2, Set6, or Clr4 resulted in essentially undetectable mono-, di-, and trimethylated H4-K20.
PMID:15550243 PBO:0112158 Fig. 1
PMID:15550243 FYPO:0004218 Fig. 1 Expression of exogenous wt HA- tagged Set9 but not Set9Y220A was able to rescue H4- K20 methylation in set9� cells (Figure 1E).
PMID:15550243 FYPO:0004217 Fig. 1
PMID:15550243 PBO:0112159 Fig. 1
PMID:15572668 PBO:0112620 Table 2
PMID:15572668 PBO:0112618 Table 2
PMID:15572668 PBO:0112619 Table 2
PMID:15572668 PBO:0112620 Table 2
PMID:15572668 PBO:0112620 Table 2
PMID:15572668 PBO:0112620 Table 2
PMID:15572668 PBO:0112620 Table 2
PMID:15572668 PBO:0112637 Fig. 4A
PMID:15572668 PBO:0112631 Fig. 4A
PMID:15572668 PBO:0112636 Fig. 4A
PMID:15572668 PBO:0112635 Fig. 4A
PMID:15572668 PBO:0112634 Fig. 2D
PMID:15572668 PBO:0112620 Table 2
PMID:15572668 PBO:0112620 Table 2
PMID:15572668 PBO:0112624 Table 2
PMID:15572668 PBO:0112625 Table 2
PMID:15572668 PBO:0112626 Table 2
PMID:15572668 PBO:0112627 Table 2
PMID:15572668 PBO:0112633 Fig. 2D
PMID:15572668 PBO:0112632 When mutations in the helix were combined with mutations in the NLS (Helix* NLS* Cter-GFP), Cter-GFP was found in the cytoplasm. Fig. 2C
PMID:15572668 PBO:0112628 Table 2
PMID:15572668 PBO:0112629 Finally, Cter-GFP remained more con- centrated at the new tip compared to the old tip in short cells after sister cell separation. [...] An association with the cell tips and septum region was never observed for wild-type mid1p and may either result from the truncation of mid1p or from the higher concentration of this construct.
PMID:15572668 PBO:0112620 Table 2
PMID:15572668 PBO:0112630 Cter-GFP was then observed in the region of septum formation (Fig. 1B, 16 to 52 min), where it was probably associated with the ingressing plasma membrane of the cleavage furrow. [...] An association with the cell tips and septum region was never observed for wild-type mid1p and may either result from the truncation of mid1p or from the higher concentration of this construct.
PMID:15572668 PBO:0112631 Cter-GFP mutated in the helix (Helix� Cter-GFP) was concentrated in the nucleus, even during mitosis (arrow in Fig. 2C)
PMID:15572668 PBO:0112638 Fig. 4A
PMID:15572668 PBO:0112621 Table 2
PMID:15572668 PBO:0112639 Fig. 4A
PMID:15572668 PBO:0112620 Table 2
PMID:15572668 PBO:0112620 Table 2
PMID:15572668 PBO:0112620 Table 2
PMID:15572668 PBO:0112623 Table 2
PMID:15572668 PBO:0112620 Table 2
PMID:15572668 PBO:0112617 Table 2
PMID:15572668 PBO:0112640 These observations indicate that Helix� NLS� mid1-mRFP colocalize with myo2-GFP and cdc12-GFP in early mitosis. This suggests that in wild-type cells mid1p mediates anchorage of myo2p and cdc12p to the central cortex in early mitosis.
PMID:15572668 PBO:0112620 Table 2
PMID:15572668 PBO:0112641 These observations indicate that Helix� NLS� mid1-mRFP colocalize with myo2-GFP and cdc12-GFP in early mitosis. This suggests that in wild-type cells mid1p mediates anchorage of myo2p and cdc12p to the central cortex in early mitosis.
PMID:15572668 PBO:0112622 Table 2
PMID:15601865 PBO:0109326 As expected from the two-hybrid results, neither the U-box (His6-Prp19p 1–58) nor the C terminus containing the WD40 repeats (His6-Prp19p 165–503) was able to tetramerize (data not shown).
PMID:15601865 PBO:0109325 As expected from the two-hybrid results, neither the U-box (His6-Prp19p 1–58) nor the C terminus containing the WD40 repeats (His6-Prp19p 165–503) was able to tetramerize (data not shown).
PMID:15601865 PBO:0109324 Fig. 3
PMID:15601865 PBO:0109325 As expected from the two-hybrid results, neither the U-box (His6-Prp19p 1–58) nor the C terminus containing the WD40 repeats (His6-Prp19p 165–503) was able to tetramerize (data not shown).
PMID:15615784 GO:0007163 based just on this paper, candidate for involved_in_or_regulates qualifier
PMID:15615784 GO:0007163 based just on this paper, candidate for involved_in_or_regulates qualifier
PMID:15615784 FYPO:0003000 assayed in vitro
PMID:15615784 FYPO:0003000 assayed in vitro
PMID:15615848 PBO:0104870 Fig. 1B
PMID:15615848 PBO:0104876 (Fig. 5A) Although all three components of RITS (Ago1, Chp1, and Tas3) are found to be dramatically enriched at otr1R::ura4 and centromeric repeats in wild-type cells, these proteins completely fail to localize to these centromeric loci in rdp1D903A cells
PMID:15615848 PBO:0096476 (Fig. 5A) Although all three components of RITS (Ago1, Chp1, and Tas3) are found to be dramatically enriched at otr1R::ura4 and centromeric repeats in wild-type cells, these proteins completely fail to localize to these centromeric loci in rdp1D903A cells
PMID:15615848 PBO:0104875 (Fig. 5A) Although all three components of RITS (Ago1, Chp1, and Tas3) are found to be dramatically enriched at otr1R::ura4 and centromeric repeats in wild-type cells, these proteins completely fail to localize to these centromeric loci in rdp1D903A cells
PMID:15615848 FYPO:0008011 (Fig. 4B). We found that, whereas siRNAs could be readily detected in the affinity-purified fraction of RITS from wild-type cells, there were no detectable RITS- associated siRNAs present in rdp1D903A, rdp1, or dcr1 cells
PMID:15615848 FYPO:0008011 (Fig. 4B). We found that, whereas siRNAs could be readily detected in the affinity-purified fraction of RITS from wild-type cells, there were no detectable RITS- associated siRNAs present in rdp1D903A, rdp1, or dcr1 cells
PMID:15615848 FYPO:0008011 (Fig. 4B). We found that, whereas siRNAs could be readily detected in the affinity-purified fraction of RITS from wild-type cells, there were no detectable RITS- associated siRNAs present in rdp1D903A, rdp1, or dcr1 cells
PMID:15615848 FYPO:0008010 In contrast, a noticeably larger fraction of rdp1D903A cells exhibited an increased number of Swi6 foci, and most of these Swi6 foci still colocalized with Taz1, suggesting a declustering of telomeres even though the localization of telo- meres to the nuclear periphery was unaffected (Fig. 3 C and D)
PMID:15615848 PBO:0110436 herefore, we conclude from these analyses that the RdRP activity of Rdp1 is essential for the generation of RITS-associated siRNAs. plus centrromeric chromatin assays
PMID:15615848 FYPO:0004974 In contrast, a noticeably larger fraction of rdp1D903A cells exhibited an increased number of Swi6 foci, and most of these Swi6 foci still colocalized with Taz1, suggesting a declustering of telomeres even though the localization of telo- meres to the nuclear periphery was unaffected (Fig. 3 C and D)
PMID:15615848 FYPO:0008009 (Fig. 3 C and D) In contrast, a noticeably larger fraction of rdp1D903A cells exhibited an increased number of Swi6 foci, and most of these Swi6 foci still colocalized with Taz1, suggesting a declustering of telomeres even though the localization of telo- meres to the nuclear periphery was unaffected
PMID:15615848 PBO:0032780 . We found that rdp1 mutants have a significantly higher percentage (20%) of cells with lagging chromosomes during late anaphase than in the wild-type strain (1%) (Fig. 3B)
PMID:15615848 PBO:0093562 hypersensitive to TBZ, indicating that chromosome segregation is not robust in these mutant cells (Fig. 3A).
PMID:15615848 PBO:0104873 (Fig. 2D). cells localization of both methylated H3–K9 and Swi6 at centromeric otr1R::ura4 was severely affected in rdp1D903A cells (Fig. 2D).
PMID:15615848 FYPO:0003096 (Fig. 2D). cells localization of both methylated H3–K9 and Swi6 at centromeric otr1R::ura4 was severely affected in rdp1D903A cells (Fig. 2D).
PMID:15615848 FYPO:0007334 (Fig. 2C). (otr1R::ura4) (Fig. 2B) Immunoblotting assay showed that the protein level of the Rdp1 mutant (Rdp1D903A) is comparable to that of wild-type Rdp1, suggesting that the D903A mutation does not affect the stability of the mutant protein
PMID:15615848 PBO:0104872 (Fig. 2B) Immunoblotting assay showed that the protein level of the Rdp1 mutant (Rdp1D903A) is comparable to that of wild-type Rdp1, suggesting that the D903A mutation does not affect the stability of the mutant protein
PMID:15615848 PBO:0108530 Fig. 1B
PMID:15615848 PBO:0104870 Fig. 1B
PMID:15615848 PBO:0104870 Fig. 1B
PMID:15615848 PBO:0104870 Fig. 1B
PMID:15615848 PBO:0104870 Fig. 1B
PMID:15615848 GO:0005721 Fig. 1A CenH
PMID:15615848 GO:0031934 Fig. 1A CenH
PMID:15615848 GO:0140720 Fig. 1A
PMID:15625190 PBO:0100071 three-hybrid assay; also binds exogenous ESEs
PMID:15632064 FYPO:0007326 fig 1 The data sug- gest that the mutants are not deficient in termination effi- ciency.
PMID:15632064 GO:0005666 Mutated Rpc11p subunits associate with Pol III and impair its RNA 3 cleavage activity.
PMID:15632064 FYPO:0007326 fig 1 The data sug- gest that the mutants are not deficient in termination effi- ciency.
PMID:15632064 FYPO:0007008 fig 1 The data sug- gest that the mutants are not deficient in termination effi- ciency.
PMID:15632064 PBO:0108882 trna chaperone
PMID:15643072 FYPO:0001250 assayed in strain with cdc10-129 to synchronize
PMID:15647375 FYPO:0000252 fig 4
PMID:15647375 PBO:0020141 GO:0051329 = mitotic interpase
PMID:15647375 PBO:0020565 GO:0000093 = mitotic telophase
PMID:15647375 FYPO:0002303 fig4
PMID:15647375 FYPO:0000229 fig 4
PMID:15654094 GO:0042138 assayed using 160-bp palindromic sequence inserted into ade6 locus
PMID:15654094 GO:0042138 assayed using 160-bp palindromic sequence inserted into ade6 locus
PMID:15654094 GO:0042138 assayed using 160-bp palindromic sequence inserted into ade6 locus
PMID:15654094 GO:0007131 assayed using 160-bp palindromic sequence inserted into ade6 locus
PMID:15665379 PBO:0103509 fig 2
PMID:15665379 PBO:0103509 fig 2
PMID:15665379 PBO:0103508 fig 2
PMID:15665379 PBO:0103510 fig 3b
PMID:15671491 FYPO:0003934 assayed using reporter based on S. cerevisiae MFA2
PMID:15671491 FYPO:0003932 assayed using reporter based on S. cerevisiae MFA2
PMID:15671491 FYPO:0003932 assayed using reporter based on S. cerevisiae MFA2
PMID:15671491 FYPO:0003933 assayed using reporter based on S. cerevisiae MFA2
PMID:15671491 FYPO:0003933 assayed using reporter based on S. cerevisiae MFA2
PMID:15689489 FYPO:0007304 Fig. 6
PMID:15689489 FYPO:0002401 Fig. 2
PMID:15689489 FYPO:0005558 Fig. 2
PMID:15689489 FYPO:0003302 Fig. 5
PMID:15689489 FYPO:0007981 Fig. 6
PMID:15689489 FYPO:0004395 Fig. 6
PMID:15689489 FYPO:0005722 Fig. 6
PMID:15689489 FYPO:0003840 Fig. 1
PMID:15689489 PBO:0106125 Fig. 1
PMID:15689489 PBO:0106124 Fig. 1
PMID:15689489 FYPO:0003481 Fig. 1
PMID:15689489 PBO:0106123 In metaphase the difference kinds of microtubules cannot be distinguished, but they can be distinguished during anaphase B
PMID:15710398 FYPO:0002061 while cells that expressed cytosolic Msp1pDMIS or CAT died.
PMID:15710398 FYPO:0002061 while cells that expressed cytosolic Msp1pDMIS or CAT died.
PMID:15710398 FYPO:0002061 GTPase (Msp1pK276A) and coiledcoil deleted (Msp1pD25-D50) mutants did not support the function of Msp1p as they failed to complement the msp1+ gene deletion.
PMID:15710398 FYPO:0002061 while cells that expressed cytosolic Msp1pDMIS or CAT died.
PMID:15710398 FYPO:0003810 fragmented: By 27 h, when repression was almost complete, the mitochondrial network fragmented into clusters of small rounded mitochondria. This phenotype is reminiscent of the mitochondrial morphology defect observed in S. cerevisiae deleted for MGM1 [18].
PMID:15710398 FYPO:0003896 while cells that expressed cytosolic Msp1pDMIS or CAT died.
PMID:15710398 FYPO:0003810 On the contrary, even slight overexpression of Msp1pK276A, Msp1pD50 or Msp1pD25 induced mitochondrial fragmentation; in about 60% of the cells the mitochondria appeared as small more or less clustered individual dots.
PMID:15710398 FYPO:0003810 On the contrary, even slight overexpression of Msp1pK276A, Msp1pD50 or Msp1pD25 induced mitochondrial fragmentation; in about 60% of the cells the mitochondria appeared as small more or less clustered individual dots.
PMID:15710398 FYPO:0003810 On the contrary, even slight overexpression of Msp1pK276A, Msp1pD50 or Msp1pD25 induced mitochondrial fragmentation; in about 60% of the cells the mitochondria appeared as small more or less clustered individual dots.
PMID:15710398 FYPO:0000636 Time-course measurements of the doubling times of these cultures showed that at day 5 the growth rate of strains expressing Msp1pK276A, Msp1pD50 and Msp1pD25 was greatly increased... (Fig. 4A).
PMID:15710398 FYPO:0000636 Time-course measurements of the doubling times of these cultures showed that at day 5 the growth rate of strains expressing Msp1pK276A, Msp1pD50 and Msp1pD25 was greatly increased... (Fig. 4A).
PMID:15710398 FYPO:0000636 Time-course measurements of the doubling times of these cultures showed that at day 5 the growth rate of strains expressing Msp1pK276A, Msp1pD50 and Msp1pD25 was greatly increased... (Fig. 4A).
PMID:15710398 FYPO:0000492 (Fig. 4B), Loss of the GTPase function of Msp1p is thus sufficient to affect the maintenance of the mitochondrial genome and the viability of S. pombe cells.
PMID:15710398 PBO:0109717 In Msp1p overexpressing cells, more than 85% of the cells had an aggregated filamentous mitochondrial network.
PMID:15710398 GO:0008053 MEMBRANE
PMID:15710398 FYPO:0000492 Fig. 4B),
PMID:15710398 FYPO:0000492 Fig. 4B),
PMID:15710398 FYPO:0003807 the mitochondrial network appeared as highly interconnected tubules forming net-like structures (Fig. 5A).
PMID:15710398 FYPO:0003896 In the doubledisrupted Dmsp1Ddnm1 strain, the mitochondria formed elongated tubules which resembled those seen in wild-type cells, ...... (Fig. 5E).
PMID:15710398 FYPO:0003896 In the doubledisrupted Dmsp1Ddnm1 strain, the mitochondria formed elongated tubules which resembled those seen in wild-type cells, ...... (Fig. 5E).
PMID:15710398 FYPO:0002060 In the Dmsp1Ddnm1 strain, mtDNA depletion (Fig. 5F) and lethality (not shown) did not occur.
PMID:15710398 FYPO:0002060 In the Dmsp1Ddnm1 strain, mtDNA depletion (Fig. 5F) and lethality (not shown) did not occur.
PMID:15710398 FYPO:0008108 In the Dmsp1Ddnm1 strain, mtDNA depletion (Fig. 5F) and lethality (not shown) did not occur
PMID:15710398 FYPO:0008108 In the Dmsp1Ddnm1 strain, mtDNA depletion (Fig. 5F) and lethality (not shown) did not occur
PMID:15716270 FYPO:0003699 25S rRNA position 1084
PMID:15716270 FYPO:0003699 18S rRNA positions 208, 2341
PMID:15716270 FYPO:0003699 18S rRNA position 1307
PMID:15716270 FYPO:0003699 25S rRNA position 1723
PMID:15716270 FYPO:0003699 25S rRNA positions 2298, 2401
PMID:15716270 FYPO:0003699 25S rRNA position 3069
PMID:15716270 FYPO:0003699 18S rRNA position 1204
PMID:15716270 FYPO:0003699 25S rRNA position 1074
PMID:15716270 FYPO:0003699 25S rRNA position 3017
PMID:15716270 FYPO:0003699 25S rRNA positions 2216, 2220, 2351
PMID:15728720 FYPO:0000209 increased centromere spindle pole body detachment during meiotic prophase fission-yeast-phenotype/2055/
PMID:15731009 GO:0030479 dependent on F-actin (asayed using Latrunculin A); independent of microtubules (assayed using MBC)
PMID:15731009 GO:0110085 dependent on F-actin (asayed using Latrunculin A); independent of microtubules (assayed using MBC)
PMID:15731009 PBO:0107072 same as orb3-167 alone
PMID:15731009 PBO:0107072 same as orb3-167 alone
PMID:15731009 GO:0007163 based just on this paper, candidate for involved_in_or_regulates qualifier
PMID:15731009 GO:0004672 assayed using casein; doesn't quite rule out tyrosine phosphorylation
PMID:15731009 GO:0030950 based just on this paper, candidate for involved_in_or_regulates qualifier
PMID:15743828 PBO:0110927 Surprisingly, however, other foci of Chp1-6xmyc and Tas3- 13xmyc persisted in ago1� cells. Similar results were obtained in cells from which Dicer was deleted (Fig. 5A and B, right panels).
PMID:15743828 FYPO:0002827 Nonetheless, deletion of chp1� or ago1� only slightly alleviated silencing (20, 38), as revealed by the presence of pink colonies compared with the red, fully repressed colonies (Fig. 8A).
PMID:15743828 FYPO:0002827 Nonetheless, deletion of chp1� or ago1� only slightly alleviated silencing (20, 38), as revealed by the presence of pink colonies compared with the red, fully repressed colonies (Fig. 8A).
PMID:15743828 PBO:0111626 Surprisingly, however, other foci of Chp1-6xmyc and Tas3- 13xmyc persisted in ago1� cells. Similar results were obtained in cells from which Dicer was deleted (Fig. 5A and B, right panels).
PMID:15743828 PBO:0110927 Surprisingly, however, other foci of Chp1-6xmyc and Tas3- 13xmyc persisted in ago1� cells. Similar results were obtained in cells from which Dicer was deleted (Fig. 5A and B, right panels).
PMID:15743828 PBO:0111625 in ago1� cells there is a loss of centromere-associated Chp1 and Tas3, as revealed by loss of costaining of Chp1-6xmyc (Fig. 5A) and Tas3-13xmyc (Fig. 5B)
PMID:15743828 PBO:0111013 in ago1� cells there is a loss of centromere-associated Chp1 and Tas3, as revealed by loss of costaining of Chp1-6xmyc (Fig. 5A) and Tas3-13xmyc (Fig. 5B)
PMID:15743828 GO:0031934 Thus, Tas3-13xmyc and Chp1-6xmyc colocalize to the mat2/3 locus, to telomeres, and to centromeres and possibly associate with all sites of heterochromatin.
PMID:15743828 GO:0005721 Thus, Tas3-13xmyc and Chp1-6xmyc colocalize to the mat2/3 locus, to telomeres, and to centromeres and possibly associate with all sites of heterochromatin.
PMID:15743828 GO:0140720 Thus, Tas3-13xmyc and Chp1-6xmyc colocalize to the mat2/3 locus, to telomeres, and to centromeres and possibly associate with all sites of heterochromatin.
PMID:15743828 PBO:0111624 Consistent with this result, immunolocalization of 3xHA- chp11–409 with anti-HA antibody revealed that the truncated protein was diffusely localized throughout the chromatin and nucleolus (Fig. 3D).
PMID:15743828 PBO:0111621 These cells exhibited high levels of chromosome segregation defects (Fig. 3C) and defects in centromeric silencing (Fig. 3B).
PMID:15743828 PBO:0111624 In contrast, �CDchp1-6xmyc exhibited a diffuse faint spotty staining pattern throughout the nucleoplasm and was not as- sociated with chromatin (Fig. 2E). Thus, the chromodomain, but not the RRM, is essential for Chp1 localization to all sites of heterochromatin and for normal Chp1 function at centro- meric sequences.
PMID:15743828 FYPO:0000141 These cells exhibited high levels of chromosome segregation defects (Fig. 3C) and defects in centromeric silencing (Fig. 3B).
PMID:15743828 PBO:0111623 n contrast, cells lacking the RRM domain of Chp1 (�RRMchp1-6xmyc) exhibited no loss of Chp1 function.
PMID:15743828 PBO:0111622 n contrast, cells lacking the RRM domain of Chp1 (�RRMchp1-6xmyc) exhibited no loss of Chp1 function.
PMID:15743828 FYPO:0000141 Importantly, cells lacking only the Chp1 chromodo- main (�CDchp1-6xmyc) behaved similar to the chp1 null strain, with elevated transcription of the centromeric marker gene (Fig. 2C) and numerous mitotic chromosome segregation de- fects (Fig. 2D)
PMID:15743828 PBO:0111621 Importantly, cells lacking only the Chp1 chromodo- main (�CDchp1-6xmyc) behaved similar to the chp1 null strain, with elevated transcription of the centromeric marker gene (Fig. 2C) and numerous mitotic chromosome segregation de- fects (Fig. 2D)
PMID:15743828 PBO:0111627 Tas3-13xmyc protein was essentially lost in chp1� cells, whereas it was present at normal levels in the ago1� cells (Fig. 6B) To address whether loss of Tas3-13xmyc protein in chp1� cells was due to suppression of tas3-13xmyc� transcription, we performed quantitative RT-PCR using RNA prepared from wild-type, chp1�, and ago1� backgrounds. Deletion of chp1� had no effect on tas3-13xmyc� transcript levels (Fig. 6C); therefore, the loss of Tas3 protein in chp1 null cells is a post- transcriptional effect.
PMID:15743828 PBO:0111013 We also assessed the localization of Chp1-6xmyc and Tas3- 13xmyc in cells lacking tas3 and chp1, respectively (Fig. 6A). In cells with tas3 deleted, Chp1 was delocalized, with a cloud of small foci of staining that mainly accumulated over the nucle- olus (Fig. 6A)
PMID:15743828 PBO:0111626 Surprisingly, however, other foci of Chp1-6xmyc and Tas3- 13xmyc persisted in ago1� cells. Similar results were obtained in cells from which Dicer was deleted (Fig. 5A and B, right panels).
PMID:15743909 FYPO:0003066 homozygous cross
PMID:15743909 PBO:0095174 dependent on F-actin (assayed using Latrunculin A)
PMID:15743909 PBO:0095173 dependent on F-actin (assayed using Latrunculin A)
PMID:15743909 FYPO:0003066 homozygous cross
PMID:15743909 FYPO:0003066 homozygous cross
PMID:15772152 FYPO:0000899 normal length
PMID:15797383 PBO:0095815 fig2
PMID:15797383 GO:0032933 fig2,5
PMID:15797383 GO:0032933 fig2,3,4
PMID:15797383 GO:0032936 fig1
PMID:15797383 PBO:0095816 fig2 ln 11-12
PMID:15797383 GO:0032936 fig1
PMID:15797925 GO:0034399 punctate, similar to nuclear pore components; localization not dependent on microtubules
PMID:15797925 FYPO:0004121 assayed using NLS-LacI-GFP construct
PMID:15800064 PBO:0106050 Figure 3 B fypo/issues/2830
PMID:15800064 FYPO:0004766 Figure 4
PMID:15800064 PBO:0106051 fig 5 a
PMID:15800064 PBO:0106051 fig 5 a
PMID:15800064 PBO:0106052 fig 5 b
PMID:15800064 FYPO:0003171 fig 6 B
PMID:15800064 FYPO:0002026 fig 6 c
PMID:15800064 FYPO:0005688 Figure 3A
PMID:15800064 FYPO:0004624 figure 3A c
PMID:15800064 PBO:0037745 figure 3A
PMID:15800064 PBO:0023023 fig 2 a,c 2D
PMID:15800064 PBO:0022298 fig 2 a 2D
PMID:15800064 PBO:0037743 fig 2 a 2D
PMID:15800064 PBO:0037148 fig 2 a,c 2D
PMID:15800064 GO:0005515 fig 1 C
PMID:15800064 FYPO:0003126 figure 3A c
PMID:15800064 PBO:0106048 Figure 3 fypo/issues/2830
PMID:15800064 PBO:0106049 Figure 3 fypo/issues/2830
PMID:15800064 PBO:0037744 figure 3A
PMID:15800064 FYPO:0004611 figure 3A
PMID:15809031 PBO:0097169 inferred from direct physical interactions between tea4,tea1 and tea4,for3, plus tea4delta phenotype
PMID:15827087 FYPO:0001120 Fig1. They describe cells as swollen in their middle region
PMID:15827087 FYPO:0000021 Fig1
PMID:15827087 PBO:0037439 Fig1C Table 2
PMID:15827087 PBO:0037440 Fig1 Table 2
PMID:15827087 PBO:0103535 Table 2 This distribution is only seen in cells with a rod shaped appearance
PMID:15827087 PBO:0103536 Table 2 This distribution is only seen in cells with a rod shaped appearance
PMID:15827087 PBO:0037443 Table 2 This distribution is only seen in cells with a rod shaped appearance
PMID:15827087 PBO:0037444 Table 2
PMID:15827087 PBO:0103538 Fig1B This distribution is only seen in cells with a rod shaped appearance
PMID:15827087 FYPO:0002058 data not shown
PMID:15827087 FYPO:0000224 Fig1. They describe cells as swollen in their middle region
PMID:15827087 FYPO:0000015 Fig1 permissive temperature is 25°C
PMID:15827087 FYPO:0001355 data not shown, permissive temperature 25°C
PMID:15827087 PBO:0094949 data not shown Non permissive temperature is 32°C and above
PMID:15827087 FYPO:0003150 Fig2A,B
PMID:15827087 PBO:0103539 Fig2A,B
PMID:15827087 PBO:0037448 Fig2D
PMID:15827087 FYPO:0000426 data not shown
PMID:15827087 FYPO:0003150 Fig2A and data not shown
PMID:15827087 PBO:0099011 Fig3A,B Deletion of the talin domain suppresses the premature activation of bipolar growth in a cdc10 mutant in latA
PMID:15827087 PBO:0019098 Fig4D
PMID:15827087 PBO:0037449 data for cdc25-22 block not shown but see also Fig4A
PMID:15827087 PBO:0103540 Fig 4B
PMID:15827087 PBO:0103541 data not shown, same as Fig 4C
PMID:15827087 PBO:0103541 Fig 4C
PMID:15827087 PBO:0018339 Fig4B
PMID:15827087 PBO:0103543 Fig2A and data not shown
PMID:15827087 FYPO:0002058 data not shown
PMID:15837798 FYPO:0004700 mto2 deletion strain, which yielded viable but slightly bent cells (Fig. 3 A)
PMID:15837798 PBO:0104131 mto2 deletion strain, which yielded viable but slightly bent cells (Fig. 3 A)
PMID:15837798 FYPO:0005686 The average number of MT bundles in mto2Δ cells (n = 1.3 ± 0.7 SD; Fig. 3 E) was significantly lower than in wild-type cells (3.6 ± 0.9)
PMID:15857958 PBO:0099471 Fig. 5
PMID:15857958 PBO:0099470 Fig. 5
PMID:15857958 PBO:0099470 Fig. 5
PMID:15857958 PBO:0099469 Fig. 5
PMID:15857958 PBO:0099468 Fig. 5
PMID:15857958 PBO:0099467 Fig. 5
PMID:15857958 PBO:0099467 Fig. 5
PMID:15857958 PBO:0099466 Fig. 5 Synthetic phenotype
PMID:15857958 PBO:0037128 Fig. 5 Synthetic phenotype
PMID:15857958 PBO:0099465 Fig. 5 Synthetic phenotype
PMID:15857958 FYPO:0001355 Fig. 5
PMID:15857958 FYPO:0002060 Fig. 5
PMID:15857958 FYPO:0002060 Fig. 5
PMID:15857958 FYPO:0002060 Fig. 5
PMID:15857958 FYPO:0002061 Fig. 5
PMID:15857958 FYPO:0002061 Fig. 5
PMID:15857958 PBO:0099472 Fig. 7
PMID:15857958 PBO:0099473 Fig. 6
PMID:15857958 PBO:0099474 Fig. 6
PMID:15857958 PBO:0099475 Fig. 7
PMID:15857958 PBO:0099476 Fig. 7
PMID:15857958 PBO:0099477 Fig. 7
PMID:15857958 FYPO:0002061 Fig. 7
PMID:15857958 FYPO:0002061 Fig. 7
PMID:15857958 FYPO:0002061 Fig. 7
PMID:15857958 PBO:0023726 Fig. 4
PMID:15857958 PBO:0018346 Fig. 4
PMID:15857958 FYPO:0000729 Fig. 3
PMID:15857958 FYPO:0006917 Fig. 3 rescue of FYPO:0000324
PMID:15857958 PBO:0099464 Fig. 3 - mad2 signal. background: cdc25-22
PMID:15857958 FYPO:0000729 Fig. 3 - background: cdc25-22
PMID:15857958 FYPO:0004087 Fig. 2
PMID:15857958 FYPO:0000324 Fig. 2 and Fig. 3 (cdc13 signal)
PMID:15857958 PBO:0099463 Fig. 2
PMID:15857958 PBO:0099462 Fig. 2
PMID:1588914 PBO:0100671 see Table 2
PMID:1588914 FYPO:0001490 Table 2 pwis4 does not suppress wee1-50 cdc25-22 mcs6-13
PMID:1588914 PBO:0019154 multicopy pwis1 does not suppress cdc2-33 ts phenotype
PMID:1588914 FYPO:0002061 Table 2 pwis4 does not suppress wee1-50 cdc25-22 mcs6-13
PMID:1588914 FYPO:0002060 see Table 2
PMID:1588914 FYPO:0002061 multicopy pwis4 does not suppress cdc25-22 ts phenotype showing that wis4 does not act by by directly reversing cdc25-22 loss of function
PMID:1588914 PBO:0019154 multicopy pwis3 does not suppress cdc25-22 ts phenotype showing that spo12 does not act by by directly reversing cdc25-22 loss of function
PMID:1588914 FYPO:0002061 multicopy pwis2 does not suppress cdc2-33 ts phenotype
PMID:1588914 FYPO:0002061 multicopy pwis2 does not suppress cdc25-22 ts phenotype showing that wis2 does not act by by directly reversing cdc25-22 loss of function
PMID:1588914 FYPO:0001490 See Table 2 multi copy pwis4 does not suppress cdc25-22 wee1-50 mcs4-13
PMID:1588914 FYPO:0002061 see Table 2 multi copy pwis4 does not suppress cdc25-22 wee1-50 mcs4-13
PMID:1588914 PBO:0019154 multicopy pwis1 does not suppress cdc25-22 ts phenotype showing that wis1 does not act by by directly reversing cdc25-22 loss of function
PMID:1588914 FYPO:0002060 the wis1 gene on a multi copy plasmid pwis1 can suppress the lethal phenotype of wee1-50 cdc25-22 win1-1
PMID:1588914 FYPO:0002060 the wis2 gene on a multi copy plasmid pwis2 can suppress the lethal phenotype of wee1-50 cdc25-22 win1-1
PMID:1588914 FYPO:0002060 the spo12 gene on a multi copy plasmid pwis3 can suppress the lethal phenotype of wee1-50 cdc25-22 win1-1
PMID:1588914 FYPO:0002060 the wis4 gene on a multi copy plasmid pwis4 can suppress the lethal phenotype of wee1-50 cdc25-22 win1-1
PMID:1588914 FYPO:0001490 Table 2 pwis1 does not suppress wee1-50 cdc25-22 mcs6-13
PMID:1588914 PBO:0097762 multicopy pwis3 does not suppress cdr2-69 phenotype
PMID:1588914 PBO:0093712 multicopy pwis4 does not suppress cdc2-3w phenotype
PMID:1588914 PBO:0093712 multicopy pwis4 does not suppress cdc2-1w phenotype
PMID:1588914 PBO:0097558 Table 2 the wis1 gene on a multi copy plasmid pwis1 can suppress the lethal phenotype of wee1-50 cdc25-22 win1-1
PMID:1588914 FYPO:0002061 multicopy pwis1 does not suppress cdc13-117 ts phenotype
PMID:1588914 PBO:0100670 the wis2 gene on a multi copy plasmid pwis2 can suppress the lethal phenotype of wee1-50 cdc25-22 win1-1
PMID:1588914 PBO:0019154 multicopy pwis4 does not suppress cdc13-117 ts phenotype
PMID:1588914 PBO:0019154 multicopy pwis4 does not suppress cdc2-33 ts phenotype
PMID:1588914 PBO:0093712 multicopy pwis4 does not suppress wee1-50 ts phenotype
PMID:1588914 PBO:0100671 the spo12 gene on a multi copy plasmid pwis3 can suppress the lethal phenotype of wee1-50 cdc25-22 win1-1
PMID:1588914 PBO:0097762 multicopy pwis4 does not suppress cdr1-34 phenotype
PMID:1588914 PBO:0097762 multicopy pwis3 does not suppress cdr1-34 phenotype
PMID:1588914 PBO:0093712 multicopy pwis3 does not suppress wee1-50 ts phenotype
PMID:1588914 PBO:0093712 multicopy pwis3 does not suppress cdc2-3w phenotype
PMID:1588914 PBO:0093712 multicopy pwis3 does not suppress cdc2-1w phenotype
PMID:1588914 PBO:0019154 multicopy pwis3 does not suppress cdc13-117 ts phenotype
PMID:1588914 PBO:0019154 multicopy pwis3 does not suppress cdc2-33 ts phenotype
PMID:1588914 PBO:0097762 multicopy pwis2 does not suppress cdr2-69 phenotype
PMID:1588914 PBO:0097762 multicopy pwis2 does not suppress cdr1-34 phenotype
PMID:1588914 PBO:0093712 multicopy pwis2 does not suppress wee1-50 ts phenotype
PMID:1588914 PBO:0093712 multicopy pwis2 does not suppress cdc2-3w phenotype
PMID:1588914 PBO:0093712 multicopy pwis2 does not suppress cdc2-1w phenotype
PMID:1588914 PBO:0019154 multicopy pwis2 does not suppress cdc13-117 ts phenotype
PMID:1588914 PBO:0019154 multicopy pwis2 does not suppress cdc2-33 ts phenotype
PMID:1588914 PBO:0097762 multicopy pwis1 does not suppress cdr2-69 phenotype
PMID:1588914 PBO:0097762 multicopy pwis1 does not suppress cdr1-34 phenotype
PMID:1588914 PBO:0093712 multicopy pwis1 does not suppress wee1-50 ts phenotype
PMID:1588914 PBO:0093712 multicopy pwis1 does not suppress cdc2-3w phenotype
PMID:1588914 PBO:0093712 multicopy pwis1 does not suppress cdc2-1w phenotype
PMID:1588914 PBO:0019154 multicopy pwis1 does not suppress cdc13-117 ts phenotype
PMID:1588914 FYPO:0002176 data not shown
PMID:1588914 FYPO:0002176 Table 3 pwis4 surpresses the elongated cell phenotype of win1-1
PMID:1588914 PBO:0097762 multicopy pwis4 does not suppress cdr2-69 phenotype
PMID:1588914 FYPO:0001492 Table 3 cells are 30-50% longer than wild type
PMID:1588914 PBO:0100671 the wis4 gene on a multi copy plasmid pwis4 can suppress the lethal phenotype of wee1-50 cdc25-22 win1-1
PMID:1588914 FYPO:0002061 multicopy pwis3 does not suppress cdc25-22 ts phenotype showing that spo12 does not act by by directly reversing cdc25-22 loss of function
PMID:1588914 FYPO:0002061 multicopy pwis1 does not suppress cdc25-22 ts phenotype showing that wis1 does not act by by directly reversing cdc25-22 loss of function
PMID:1588914 PBO:0097558 see Table 2
PMID:1588914 PBO:0019154 multicopy pwis4 does not suppress cdc25-22 ts phenotype showing that wis4 does not act by by directly reversing cdc25-22 loss of function
PMID:1588914 PBO:0100670 see Table 2
PMID:1588914 PBO:0100671 see Table 2
PMID:1588914 PBO:0019154 multicopy pwis2 does not suppress cdc25-22 ts phenotype showing that wis2 does not act by by directly reversing cdc25-22 loss of function
PMID:1588914 FYPO:0002061 multicopy pwis4 does not suppress cdc13-117 ts phenotype
PMID:1588914 FYPO:0002061 multicopy pwis4 does not suppress cdc2-33 ts phenotype
PMID:1588914 FYPO:0002061 multicopy pwis3 does not suppress cdc13-117 ts phenotype
PMID:1588914 FYPO:0002061 multicopy pwis1 does not suppress cdc2-33 ts phenotype
PMID:1588914 FYPO:0002060 see Table 2
PMID:1588914 FYPO:0002060 see Table 2
PMID:1588914 FYPO:0002060 see Table 2
PMID:1588914 FYPO:0002061 multicopy pwis3 does not suppress cdc2-33 ts phenotype
PMID:1588914 FYPO:0002061 multicopy pwis2 does not suppress cdc13-117 ts phenotype
PMID:1588914 FYPO:0002061 Table 2 pwis1 does not suppress wee1-50 cdc25-22 mcs6-13
PMID:1588914 FYPO:0002060 see Table 2
PMID:1588914 PBO:0100670 see Table 2
PMID:15908586 FYPO:0007313 Figure 3
PMID:15908586 PBO:0033885 Figure 2
PMID:15908586 PBO:0033665 Figure 2
PMID:15908586 PBO:0105929 Figure 2 Further examination of the IF samples revealed that hrp1D single and hrp1D hrp3D double mutants cells showed elevated numbers of asymmetric segregation (large and small nuclei) in late anaphase cells
PMID:15908586 PBO:0105932 dhIII transcripts were detectable in hrp1D dcr1D and dcr1D cells, but not in the wild-type and hrp1D cells (Figure 4E). The dhIII transcripts were more abundant in hrp1D dcr1D cells than in dcr1D cells consistent with the reduced silencing observed at dg-dh in hrp1D (Figure 1E). If transcripts read through in hrp1D from dh-dg into the central core region, then they should be readily detectable in the intervening imrIII region. However, imrIII transcripts were not observed in hrp1D cells. From these results, we concluded that the hrp1D mutant does not cause read through of dg-dh transcripts into the central core region. Hrp1 is present at the centromere in a cell
PMID:15908586 FYPO:0001355 The mis6-302 hrp1D double mutant had a reduced growth at 30 C as compared with the mis6-302 and hrp1D single mutants (Figure 3C).
PMID:15908586 FYPO:0001355 The mis6-302 hrp1D double mutant had a reduced growth at 30 C as compared with the mis6-302 and hrp1D single mutants (Figure 3C).
PMID:15908586 FYPO:0008062 Figure 3 There was a 4- fold reduction of Cnp1 at cnt2 in hrp1D cells,
PMID:15908586 PBO:0105931 Figure 3 There was a 4- fold reduction of Cnp1 at cnt2 in hrp1D cells,
PMID:15908586 FYPO:0007314 Figure 3
PMID:15908586 FYPO:0002827 Figure 1
PMID:15908586 FYPO:0004542 Figure 1
PMID:15908586 FYPO:0003412 Figure 1
PMID:15908586 FYPO:0004331 Figure 1
PMID:15908586 PBO:0093564 Figure 2A In contrast, both of the single mutants were hypersensitive to this concentration of TBZ, showing a 5- to 25-fold growth reduction compared with wt
PMID:15908586 PBO:0093564 Figure 2A In contrast, both of the single mutants were hypersensitive to this concentration of TBZ, showing a 5- to 25-fold growth reduction compared with wt
PMID:15908586 PBO:0093562 Figure 2A In contrast, both of the single mutants were hypersensitive to this concentration of TBZ, showing a 5- to 25-fold growth reduction compared with wt
PMID:15908586 PBO:0093562 Figure 2A In contrast, both of the single mutants were hypersensitive to this concentration of TBZ, showing a 5- to 25-fold growth reduction compared with wt
PMID:15908586 FYPO:0002061 Figure 2A In contrast, both of the single mutants were hypersensitive to this concentration of TBZ, showing a 5- to 25-fold growth reduction compared with wt
PMID:15908586 FYPO:0002061 Figure 2A In contrast, both of the single mutants were hypersensitive to this concentration of TBZ, showing a 5- to 25-fold growth reduction compared with wt
PMID:15908586 FYPO:0003937 Figure 2 In cultures without TSA, the hrp1D cells grew slightly faster than wt cells as reported previously (48).
PMID:15908586 FYPO:0001355 Figure 2
PMID:15908586 FYPO:0001357 Figure 2A In contrast, both of the single mutants were hypersensitive to this concentration of TBZ, showing a 5- to 25-fold growth reduction compared with wt
PMID:15908586 FYPO:0001357 Figure 2A In contrast, both of the single mutants were hypersensitive to this concentration of TBZ, showing a 5- to 25-fold growth reduction compared with wt
PMID:15908586 PBO:0093727 Figure 2A However, growth of the double mutant cells was completely inhibited by TSA.
PMID:15908586 FYPO:0002620 Figure 2
PMID:15908586 FYPO:0002620 Figure 2
PMID:15908586 PBO:0105928 Figure 2
PMID:15915339 PBO:0093616 more sensitive than either single mutant
PMID:15915339 PBO:0093587 more sensitive than either single mutant
PMID:15915339 PBO:0093580 more sensitive than either single mutant
PMID:15915339 PBO:0093629 more sensitive than either single mutant
PMID:15920625 GO:0036374 Proxy assay for hydrolase function used and IMP evidence for catalytic activity
PMID:15925945 PBO:0096148 assayed using AlF4- to mimic GTP-bound Gpa2
PMID:15933715 PBO:0107082 We therefore analysed the localisation of Etd1p-GFP in cdc8-110 mutant cells and found that, at the restrictive temperature of 361C, Etd1p never formed a ring (Figure 3B, upper panels).
PMID:15933715 FYPO:0002816 Spores deleted for etd1 (etd1D) germinated and accumulated multiple nuclei without septation, an identical phenotype to that of etd1-1 mutant cells under restrictive conditions (Figure 1C).
PMID:15933715 FYPO:0002024 Under derepressed conditions ( thiamine), Etd1p overproduction generated elongated and multinucleate cells in both etd1-1 mutant and wild-type backgrounds (Figure 1D and data not shown). Thus, the phenotypic defect caused by an excess of Etd1p was identical to that produced by a deficiency of this protein, suggesting that Etd1p functions in a stoichiometric protein complex.
PMID:15933715 PBO:0018345 In interphase cells, Etd1p-GFP was located at the cell cortex and was more concentrated at the cell tips (Figure 2A, cell 1).
PMID:15933715 MOD:01148 These results indicate that Etd1p is polyubiquitinated and degraded through the ubiquitin-dependent 26S-proteasome pathway.
PMID:15933715 PBO:0109989 Etd1p-GFP, demonstrating that Etd1p interacts physically with Cdc15p. Similarly, Cdc15p was detected in anti-GFP immune complexes (data not shown). Thus, Etd1p may localise to the actomyosin ring by association with Cdc15p. (the anchor is using 2022 knowledge)
PMID:15933715 PBO:0022665 In early anaphase, Etd1p-GFP became concentrated in the medial region of the cell cortex as a broad band (Figure 2A, cell 2)
PMID:15933715 PBO:0107081 In early anaphase, Etd1p-GFP became concentrated in the medial region of the cell cortex as a broad band (Figure 2A, cell 2)
PMID:15933715 PBO:0107086 missing annotation, we dont have that cdc7 is on old SPB in metaphase ... Cdc7p-GFP appeared at both SPBs at the initiation of mitosis and only at one SPB as cells progressed through anaphase until the completion of cell division.
PMID:15933715 FYPO:0001493 Figure 1A and B).
PMID:15933715 PBO:0107085 Etd1p-GFP failed to localise to the medial ring at the restrictive temperature. Instead, these mutant cells accumulated Etd1-GFP in a broad band at the plasma membrane overlying the site of cytokinesis (Figure 6A, upper panel,
PMID:15933715 GO:0031028 suggesting that Etd1p is somehow necessary to maintain Spg1p activity during anaphase until the completion of cytokinesis
PMID:15933715 PBO:0022666 In early anaphase, Etd1p-GFP became concentrated in the medial region of the cell cortex as a broad band (Figure 2A, cell 2)
PMID:15933715 PBO:0107082 We therefore analysed the localisation of Etd1p-GFP in cdc8-110 mutant cells and found that, at the restrictive temperature of 361C, Etd1p never formed a ring (Figure 3B, upper panels).
PMID:15933715 FYPO:0000842 Figure 1A and B).
PMID:15933715 FYPO:0003838 However, in etd1-1 mutant cells, the medial ring marked with Cdc15p-GFP seems to fail constriction. To bette
PMID:15936270 PBO:0097149 The specific localization of Wsh3-GFP was lost in the Δtea1 mutant and the Wsh3-GFP signal was diffused throughout the cytoplasm (Figure 4A)
PMID:15936270 FYPO:0001357 DNS
PMID:15936270 PBO:0037676 (p;enetrance for m 6B) highly bent or branched morphology (Figure 2a)
PMID:15936270 PBO:0106648 We also found that, even under the optimal growth condition, the Δspc1 mutation exacerbates the morphology defects of the Δtea1 mutant; the Δtea1 Δspc1 double mutant grown at 30oC in rich YES medium contain large fractions of significantly bent and branched cells (Figure 6D).
PMID:15936270 PBO:0106649 We also found that, even under the optimal growth condition, the Δspc1 mutation exacerbates the morphology defects of the Δtea1 mutant; the Δtea1 Δspc1 double mutant grown at 30oC in rich YES medium contain large fractions of significantly bent and branched cells (Figure 6D).
PMID:15936270 FYPO:0007379 Cell polarity defects with bent and branched morphology were observed after shifting the Δspc1 mutant from 25oC to 36oC (Figure 6C).
PMID:15936270 FYPO:0001018 2c Δwsh3 cells were found to grow exclusively in a monopolar fashion.
PMID:15936270 FYPO:0001019 Actin patches, which are localized to the growing tips of fission yeast cells [38], were detected mostly in one tip of the Δwsh3 cell (Figure 2C).
PMID:15936270 PBO:0106644 highly bent or branched morphology (Figure 2a)
PMID:15936270 PBO:0106644 (p;enetrance for m 6B) highly bent or branched morphology (Figure 2a)
PMID:15936270 FYPO:0007380 Figure 2B).
PMID:15936270 PBO:0106645 Wsh3-GFP was abrogated by a mutation in β- tubulin, nda3-KM311 [39] even at its permissive temperature, 30oC (Figure 3B, left).
PMID:15936270 PBO:0106644 (penetrance from 6B) nWe found that high osmolarity stress by 0.6 M KCl also promotes appearance of T-shaped cells in the Δtea1 strain, to the levels comparable to the Δwsh3 mutant (Figure 6B).
PMID:15936270 PBO:0106647 Δwsh3 cells, the cell-end localization of Pom1 was lost and Pom1-GFP often accumulated in vesicle-like structures in the cytoplasm (Figure 5D)
PMID:15936270 PBO:0106646 In contrast, most of Δwsh3 cells showed highly concentrated Tea1-GFP signals at one end, while the other end contained significantly less Tea1-GFP dots (Figure 5A, right panel)
PMID:15936270 FYPO:0007398 DNS
PMID:15936270 FYPO:0002104 On the other hand, oxidative stress by hydrogen peroxide, which also induces Spc1 activation [34], did not significantly affect Δwsh3 cells (data not shown).
PMID:15937127 PBO:0107944 fig2
PMID:15937127 FYPO:0006338 DNA at the tips, telophase delay
PMID:15937127 GO:0005634 Figure 3F-3
PMID:15937127 GO:0034399 Figure 3F-3
PMID:15937127 GO:0005634 Figure 3F-3
PMID:15937127 PBO:0107946 fig3 B-2 (1.1% WT)
PMID:15937127 FYPO:0001355 fig3
PMID:15937127 FYPO:0002060 fig3
PMID:15937127 GO:0006606 fig2
PMID:15937127 GO:0034399 Figure 3F-3
PMID:15937127 PBO:0107949 fig 4D
PMID:15937127 PBO:0100894 fig 4D
PMID:15937127 PBO:0107140 fig 4D
PMID:15937127 GO:0006606 fig2
PMID:15937127 PBO:0107945 fig2
PMID:15937127 PBO:0100663 fig 4D
PMID:15937127 PBO:0107944 fig2
PMID:15937127 PBO:0107950 fig 5B
PMID:15937127 PBO:0107950 fig 5B
PMID:15937127 PBO:0107947 fig3 B-2 (never seen in WT)
PMID:15937127 FYPO:0003165 fig 3C
PMID:15941470 FYPO:0002061 Tev protease present; Cdc23 truncated
PMID:15941470 FYPO:0000611 Tev protease present; Cdc23 truncated; cells not synchronized
PMID:15941470 PBO:0101304 Tev protease present; Cdc23 truncated; Cdc23 C-terminal fragment not retained in nucleus
PMID:15941470 PBO:0101305 Tev protease present; Cdc23 truncated; Cdc23 C-terminal fragment not retained in nucleus
PMID:15941470 FYPO:0002060 Tev protease present; Cdc23 truncated
PMID:15941470 FYPO:0001430 Tev protease present; Cdc23 truncated; N starvation/recovery synchronizes cells
PMID:15957215 GO:0006265 from the catenated plasmid experiment (and failure to separate sisters)
PMID:15992541 PBO:0105631 promoter repressed
PMID:15992541 PBO:0105630 thiamine absent; expression level lower than with endogenous promoter but higher than when repressed
PMID:16055437 PBO:0109312 figure 1a
PMID:16079916 FYPO:0005309 assayed in intergenic regions
PMID:16079916 FYPO:0005310 assayed in intergenic regions
PMID:16079916 FYPO:0005310 protein-coding genes and intergenic regions
PMID:16079916 FYPO:0007631 protein-coding genes and intergenic regions
PMID:16079916 FYPO:0007632 protein-coding genes and intergenic regions
PMID:16079916 FYPO:0007631 protein-coding genes and intergenic regions
PMID:16079916 FYPO:0005309 protein-coding genes and intergenic regions
PMID:16079916 FYPO:0005310 protein-coding genes and intergenic regions
PMID:16079916 FYPO:0000892 protein-coding genes and intergenic regions
PMID:16079916 FYPO:0005310 protein-coding genes and intergenic regions
PMID:16079916 FYPO:0007632 assayed in intergenic regions
PMID:16079916 FYPO:0007631 assayed in intergenic regions
PMID:16079916 FYPO:0005309 protein-coding genes and intergenic regions
PMID:16079916 FYPO:0000892 protein-coding genes and intergenic regions
PMID:16079916 FYPO:0007632 protein-coding genes and intergenic regions
PMID:16079916 FYPO:0000892 protein-coding genes and intergenic regions
PMID:16085489 GO:0044878 clp1 cytoplasmic localization not maintained during cytokinetic stress. cdc7 localization to SPB not maintained during cytokinetic stress
PMID:16087707 GO:0071933 specific Arp2/3 complex subunit(s) not identified; authors use Myo1 tail as representative of whole protein
PMID:16087707 GO:0000147 also from timing of localization to patches
PMID:16087707 GO:0000147 also from synthetic lethality with myo1, timing of localization to patches, and vrp1 mutant phenotype
PMID:16087707 GO:0030479 dependent on F-actin (assayed using Latrunculin A)
PMID:16087707 GO:0071933 specific Arp2/3 complex subunit(s) not identified; authors use Myo1 tail as representative of whole protein
PMID:16087707 GO:0000147 also from timing of localization to patches
PMID:16087707 GO:0030479 dependent on F-actin (assayed using Latrunculin A)
PMID:16087707 GO:0030479 dependent on F-actin (assayed using Latrunculin A)
PMID:16087707 GO:0000147 also from timing of localization to patches
PMID:16087749 FYPO:0002060 et2� cells grew nor- mally on rich YEA medium, they showed a strong growth defect in synthetic medium (EMM), which is nutrient depleted compared to YEA (Fig. 4B).
PMID:16087749 FYPO:0002919 As shown in Fig. 4A, dele- tion of set2� resulted in a complete abolishment of K36 meth- ylation (mono-, di-, and trimethylation), but not K4 methyl- ation or H3 K9 acetylation, in bulk histones
PMID:16087749 PBO:0111677 The results revealed that histone H3 was the only histone methylated (Fig. 3B).
PMID:16087749 PBO:0111675 As shown in Fig. Fig.3D,3D, SpSet2 was able to methylate an H3 peptide of residues 27 to 45, but not that of an H3 N-terminal peptide (residues 1 to 20). These data demonstrate that SpSet2 is a robust nucleosome-selective HMT specific for K36 methylation.
PMID:16087749 GO:0140673 . No unmodifiedPol II could be detected in these immunoprecipitates, althoughunmodified Pol II could be readily detected in the input extracts. These data demonstrate that SpSet2 is associated withthe elongating form of Pol II in S. pombe.
PMID:16087749 PBO:0111676 The results revealed that histone H3 was the only histone methylated (Fig. 3B).
PMID:16087749 PBO:0111674 The results revealed that histone H3 was the only histone methylated (Fig. 3B).
PMID:16087749 PBO:0111680 As shown in Fig. Fig.3D,3D, SpSet2 was able to methylate an H3 peptide of residues 27 to 45, but not that of an H3 N-terminal peptide (residues 1 to 20). These data demonstrate that SpSet2 is a robust nucleosome-selective HMT specific for K36 methylation.
PMID:16087749 PBO:0111679 As shown in Fig. Fig.3D,3D, SpSet2 was able to methylate an H3 peptide of residues 27 to 45, but not that of an H3 N-terminal peptide (residues 1 to 20). These data demonstrate that SpSet2 is a robust nucleosome-selective HMT specific for K36 methylation.
PMID:16087749 PBO:0111678 As shown in Fig. Fig.3D,3D, SpSet2 was able to methylate an H3 peptide of residues 27 to 45, but not that of an H3 N-terminal peptide (residues 1 to 20). These data demonstrate that SpSet2 is a robust nucleosome-selective HMT specific for K36 methylation.
PMID:16087749 FYPO:0001355 et2� cells grew nor- mally on rich YEA medium, they showed a strong growth defect in synthetic medium (EMM), which is nutrient depleted compared to YEA (Fig. 4B).
PMID:16096637 PBO:0018346 both SPBs in early mitosis
PMID:16096637 PBO:0102313 Pmo25 formed a complex with Nak1 and was required for both the localization and kinase activity of Nak1.
PMID:16111942 FYPO:0000590 S1D
PMID:16111942 FYPO:0004796 Interestingly, however, azygotic asci arising from diploid hrs1D cells did not show an apparent defect in spore formation (Figure S1D
PMID:16111942 GO:0032118 arious exp, and ectoptic mitotic exprression
PMID:16111942 GO:0030989 arious exp, and ectoptic mitotic exprression
PMID:16111942 PBO:0018718 Fig 1A appeared at theSPB upon conjugation of haploid cells, persisted untilthe onset of meiosis I, and disappeared thereafter
PMID:16120966 GO:0003887 distributive; substrate preference: small gaps with a 5′-phosphate group
PMID:16120966 GO:0003899 can incorporate NTPs or dNTPs; changed from primase activity because not tested with unprimed template
PMID:16127433 PBO:0112653 Fig. 4B
PMID:16127433 PBO:0094283 Fig. S3
PMID:16127433 FYPO:0007334 Fig. S3
PMID:16127433 PBO:0112649 Fig. 2B
PMID:16127433 PBO:0112648 Fig. 2B
PMID:16127433 PBO:0110865 Fig. 5D
PMID:16127433 PBO:0112520 Fig. 5C
PMID:16127433 PBO:0112656 Fig. 5C
PMID:16127433 PBO:0112655 Fig. 5A
PMID:16127433 PBO:0112654 Fig. 5A
PMID:16127433 FYPO:0002331 Fig. 4B
PMID:16127433 FYPO:0002331 Fig. 4B
PMID:16127433 PBO:0094283 Fig. S3
PMID:16127433 PBO:0112653 Fig. 4B
PMID:16127433 FYPO:0004745 Fig. 4B
PMID:16127433 FYPO:0004745 Fig. 4B
PMID:16127433 FYPO:0007334 Fig. 4A
PMID:16127433 PBO:0093561 Fig. 4A
PMID:16127433 PBO:0112817 Fig. 4B
PMID:16127433 FYPO:0000468 Fig. 3C
PMID:16127433 FYPO:0001861 Fig. 3B
PMID:16127433 PBO:0112650 Fig. 2B
PMID:16127433 FYPO:0003412 Fig. S3
PMID:16127433 PBO:0093560 Fig. S3
PMID:16127433 FYPO:0001357 Fig. S3
PMID:16127433 FYPO:0001357 Fig. S3
PMID:16127433 PBO:0095057 Fig. 3A
PMID:16127433 PBO:0112651 Fig. 2B
PMID:16127433 FYPO:0001357 Fig. S3
PMID:16127433 PBO:0112644 Fig. 2B
PMID:16127433 PBO:0098773 Fig. 2B
PMID:16127433 PBO:0094681 Fig. 2A
PMID:16127433 FYPO:0007336 Fig. 2A
PMID:16138082 FYPO:0008059 From these results, we conclude that the F330A mutation significantly reduces the affinity of the Mud1 UBA domain for K48-linked polyUb chains without significantly affecting monoUb binding.
PMID:16138082 FYPO:0008060 From these results, we conclude that the F330A mutation significantly reduces the affinity of the Mud1 UBA domain for K48-linked polyUb chains without significantly affecting monoUb binding.
PMID:16141239 FYPO:0000034 endocytosis restricted to cell end
PMID:16141239 FYPO:0000422 Fig. 5A,B
PMID:16141239 FYPO:0000426 Fig. 5A,B
PMID:16141239 FYPO:0006341 endocytosis restricted to cell end
PMID:16141239 FYPO:0006341 endocytosis restricted to cell end
PMID:16141239 FYPO:0006341 endocytosis restricted to cell end
PMID:16141239 FYPO:0000422 Fig. 5A,B
PMID:16157682 FYPO:0000468 Fig. 1C
PMID:16157682 FYPO:0000468 Fig. 1C
PMID:16157682 PBO:0097950 Fig. 2B
PMID:16157682 PBO:0098583 Fig. 2A
PMID:16157682 PBO:0098583 Fig. 2A
PMID:16157682 FYPO:0005063 Fig. 8C
PMID:16157682 FYPO:0005063 Fig. 8C
PMID:16157682 FYPO:0005063 Fig. 8C
PMID:16157682 FYPO:0006112 Fig. 8B
PMID:16157682 PBO:0112644 Fig. 8B
PMID:16157682 PBO:0112644 Fig. 8B
PMID:16157682 PBO:0094681 Fig. 7
PMID:16157682 PBO:0094681 Fig. 7
PMID:16157682 PBO:0094681 Fig. 7
PMID:16157682 PBO:0098583 Fig. 7
PMID:16157682 PBO:0098583 Fig. 7
PMID:16157682 FYPO:0002336 Fig. 7
PMID:16157682 PBO:0095651 Fig. 7
PMID:16157682 PBO:0112643 Fig. 5
PMID:16157682 PBO:0112643 Fig. 5
PMID:16157682 PBO:0103456 Table 2 and Fig. 4
PMID:16157682 PBO:0103456 Table 2 and Fig. 4
PMID:16157682 FYPO:0007336 Fig. 2C
PMID:16157682 FYPO:0007336 Fig. 2C
PMID:16157682 PBO:0097950 Fig. 2B
PMID:16157682 PBO:0098583 Fig. 7
PMID:16157682 PBO:0095653 Fig. 7
PMID:16169489 FYPO:0002059 knocked out in diploid. Can't tell if it vegetative or spore?
PMID:16169489 FYPO:0000581 27% of spores produce viable colonies
PMID:16169489 FYPO:0002059 knocked out in diploid. Can't tell if it vegetative or spore?
PMID:1617727 GO:0045292 splicing of artificial construct with wt or mutated splice sites assayed in mutants
PMID:16199877 FYPO:0000141 S1B
PMID:16199877 FYPO:0000266 DNS
PMID:16199877 FYPO:0000268 DNS
PMID:16199877 FYPO:0002061 fig 3A
PMID:16199877 FYPO:0000229 fig 3B
PMID:16199877 FYPO:0000091 DNS
PMID:16199877 FYPO:0001234 Fig 1D
PMID:16199877 PBO:0106353 Fig 1B
PMID:16199877 FYPO:0000229 DNS
PMID:16199877 PBO:0106353 Fig 1E
PMID:16199877 PBO:0106359 Fig. S1C
PMID:16199877 FYPO:0001234 Fig 1D
PMID:16199877 FYPO:0002061 Fig 1A
PMID:16199877 FYPO:0001490 fig 3B
PMID:16199877 FYPO:0001494 fig 3B
PMID:16199877 PBO:0023853 Fig. 3C).
PMID:16199877 PBO:0022134 Fig. 3C).
PMID:16199877 FYPO:0008164 Fig 3C
PMID:16199877 PBO:0106355 Fig 3C
PMID:16199877 FYPO:0000316 fig4
PMID:16199877 PBO:0106356 Figur 4B
PMID:16199877 FYPO:0000229 Figur 4B
PMID:16199877 FYPO:0000228 Figur 4B
PMID:16199877 FYPO:0000284 Figur 4B
PMID:16199877 PBO:0022134 Fig. 3C).
PMID:16199877 PBO:0023853 Fig. 3C).
PMID:16199877 PBO:0112051 Fig 5DE
PMID:16199877 FYPO:0000316 S1A
PMID:16199877 PBO:0106358 Fig. S1C
PMID:16246721 GO:0030466 [SPREADING] Subsequently, Clr3 spreads across the entire mat2/3 interval that is dependent upon its own HDAC activity, Swi6 and Sir2 proteins, and possibly other fac- tors, such as Chp2, involved in heterochromatin as- sembly.
PMID:16246721 FYPO:0005845 .....Interestingly, identical modifi- cation patterns were also observed in a swi6 mutant, consistent with Swi6 involvement in Clr3 spreading (Figure 5A).
PMID:16246721 PBO:0111016 We next explored whether loss of Clr3 affects Swi6 binding at the mat locus. Deletion of clr3 resulted in severely reduced Swi6 levels at Kint2::ura4+ even though Swi6 expression was not affected (Figure 5C; Figure S3).
PMID:16246721 FYPO:0007633 deletion of clr3 resulted in an increase in acetylation at H3K14 (H3K14ac) (Figure 6A), a mark of active chromatin that is absent at heterochromatic loci.
PMID:16246721 FYPO:0008158 Furthermore, the levels of H3S10 phosphorylation (H3S10ph), another modification mark associated with active chromatin as well as mitotic chromosomes (Nowak and Corces, 2004), were also increased at the mat locus (Figure 6A).
PMID:16246721 PBO:0111118 Similar changes were observed in the swi6 mutant; however, the effect on H3S10ph was weaker than in the clr3 mutant (Figure 6A).
PMID:16246721 FYPO:0008159 Our analyses revealed that a temper- ature-sensitive mutation in the survivin homolog Cut17/ Bir1 (cut17-275), which is known to bind centromeric repeats and is required for proper localization of fission yeast aurora kinase Ark1 (Morishita et al., 2001), almost completely abolished H3S10ph at the mat locus in clr3D cells (Figure 6C).
PMID:16246721 GO:0031508 We show that Cir3, a fission yeast homolog of mammalian class |I HDACs, acts in a distinct pathway parallel to RNAi-directed heterochromatin nucleation to recruit Cl4 and mediate H3K9 methylation at the silent mating-type region and centromeres.
PMID:16246721 PBO:0111663 At the mat locus, Clr3 is recruited at a specific site through a mechanism involving ATF/CREB family proteins
PMID:16246721 GO:0030466 [SPREADING] Subsequently, Clr3 spreads across the entire mat2/3 interval that is dependent upon its own HDAC activity, Swi6 and Sir2 proteins, and possibly other fac- tors, such as Chp2, involved in heterochromatin as- sembly.
PMID:16246721 FYPO:0008153 Whereas H3K9me levels at Kint2:: ura4+ were not affected in clr3D, dcr1D, or atf1D single mutants compared to wild-type, H3K9me was com- pletely abolished in a clr3D dcr1D double mutant strain (Figure 4A).
PMID:16246721 PBO:0111115 [ vw specifically to REIII/ CAS, nucleation site] In double mutant cells lacking Pcr1 and Swi6, the localization of Clr3 was almost com- pletely abolished from REIII (Figure 3).
PMID:16246721 FYPO:0005845 ..... However, in clr3D cells, H3K9me3 was significantly reduced, while there was a substantial in- crease in H3K9me1. Furthermore, H3K9me2 levels were slightly elevated (Figure 5A).
PMID:16246721 GO:0030466 [SPREADING] Subsequently, Clr3 spreads across the entire mat2/3 interval that is dependent upon its own HDAC activity, Swi6 and Sir2 proteins, and possibly other fac- tors, such as Chp2, involved in heterochromatin as- sembly.
PMID:16246721 GO:0030466 [NUCLEATION/SPREADING] Subsequently, Clr3 spreads across the entire mat2/3 interval that is dependent upon its own HDAC activity, Swi6 and Sir2 proteins, and possibly other fac- tors, such as Chp2, involved in heterochromatin as- sembly. These results suggest that Clr3 operates in a pathway parallel to RNAi to nucleate heterochromatin at the mat locus.
PMID:16246721 PBO:0111116 These data, together with results showing defects in Swi6 localiza- tion at the mat locus in clr3-735 cells (see below; Figure S2),
PMID:16246721 PBO:0109217 Surprisingly, except for a small but reproducible enrichment of Clr3 at the nu- cleation site, Clr3 was virtually absent from the entire mat2/3 region in a sir2D strain (Figure 2A).
PMID:16246721 FYPO:0007891 ChIP analysis revealed that the Clr3 mutant protein was mainly restricted to the nucleation site adjacent to the mat3 locus and the spreading of Clr3 across the mat2/3 region was se- verely affected (Figure 2A).
PMID:16246721 FYPO:0008157 mutant cells are de- fective in histone deacetylation and silencing at the mat2/3 locus (see Figure S1
PMID:16246721 FYPO:0007891 In the absence of Swi6, Clr3 localization was confined to a small region near the mat3 locus (Figure 2A), which is distinct from the cenH element responsi- ble for RNAi-mediated targeting of heterochromatin to this region.
PMID:16246721 GO:0030466 [NUCLEATION]
PMID:16246721 PBO:0111115 Remarkably, loss of Swi6 and Chp2 but not Chp1 completely abolished the localization of Clr3 at Kint2::ura4+ (Figure 1)
PMID:16246721 PBO:0111115 Remarkably, loss of Swi6 and Chp2 but not Chp1 completely abolished the localization of Clr3 at Kint2::ura4+ (Figure 1)
PMID:16246721 PBO:0111115 Remarkably, loss of Swi6 and Chp2 but not Chp1 completely abolished the localization of Clr3 at Kint2::ura4+ (Figure 1)
PMID:16246721 GO:0031934 Our results revealed that Clr3 is indeed enriched through- out the 20 kb heterochromatic domain surrounded by the IR-R and IR-L boundary elements but is absent at the surrounding euchromatic regions (Figure 2A).
PMID:16246721 GO:0030466 [NUCLEATION] Same pathway as clr3
PMID:16246721 FYPO:0003097 Remarkably, whereas clr3D or dcr1D single mutant strains still maintained H3K9 methylation, H3K9me at centromeric repeats was almost completely abolished in clr3Ddcr1D double mutant cells (Figure 4C).
PMID:16246721 PBO:0111117 Remarkably, loss of Swi6 and Chp2 but not Chp1 completely abolished the localization of Clr3 at Kint2::ura4+ (Figure 1)
PMID:16251348 GO:0005730 fig 2c
PMID:16251348 GO:0006364 fig3B
PMID:16252005 PBO:0093618 same as ddb1delta alone
PMID:16252005 PBO:0093613 same as cdt2delta alone
PMID:16252005 PBO:0093613 same as ddb1delta alone
PMID:16252005 PBO:0093615 same as csn1delta alone
PMID:16252005 PBO:0093618 same as pcu4delta alone
PMID:16252005 PBO:0093613 same as pcu4delta alone
PMID:16252005 PBO:0093618 same as cdt2delta alone
PMID:16252005 GO:0006511 (regulation ) can also infer (IC) from GO:0030674
PMID:16262791 PBO:0108887 detectable in mutants that increase bound GTP:GDP ratio, implying that protein-protein interaction is GTP-dependent
PMID:16272747 FYPO:0001234 Therefore, sec9+ is essential for vegetative cell growth and spore germination.
PMID:16272747 PBO:0110455 As shown in Fig. 2A, accumulation of sec9 mRNA was completely abolished in the mei4Δ mutant. Furthermore, ectopic overexpression of mei4+ was found to induce sec9+ mRNA in vegetative cells (Fig. 2C). sec9+ has a consensus recognition sequence for Mei4, GTAAAYA (Horie et al., 1998) in the 5' upstream region. We conclude that transcription of sec9+ during meiosis is strictly regulated by Mei4.
PMID:16272747 FYPO:0002061 In addition to causing a defect in ascospore formation, the sec9-10 mutation compromised vegetative growth. As shown in Fig. 3B, the sec9-10 mutant grew well at 25°C but was unable to form colonies at 37°C.
PMID:16272747 PBO:0104431 In marked contrast, sec9-10 cells exhibited a rather uniform arrest morphology at the restrictive temperature (Fig. 3C). At 12 hr after the shift to 34°C, approximately 43% of the sec9-10 cells had a single septum, and 4% exhibited multiple septa (Table II).
PMID:16272747 FYPO:0000622 In marked contrast, sec9-10 cells exhibited a rather uniform arrest morphology at the restrictive temperature (Fig. 3C). At 12 hr after the shift to 34°C, approximately 43% of the sec9-10 cells had a single septum, and 4% exhibited multiple septa (Table II).
PMID:16272747 FYPO:0001234 Therefore, sec9+ is essential for vegetative cell growth and spore germination.
PMID:16272747 PBO:0112761 As shown in Fig. 2A, accumulation of sec9 mRNA was completely abolished in the mei4Δ mutant. Furthermore, ectopic overexpression of mei4+ was found to induce sec9+ mRNA in vegetative cells (Fig. 2C). sec9+ has a consensus recognition sequence for Mei4, GTAAAYA (Horie et al., 1998) in the 5' upstream region. We conclude that transcription of sec9+ during meiosis is strictly regulated by Mei4.
PMID:16272747 FYPO:0001914 In wild type cells, most haploid nuclei produced by meiotic second divisions were encapsulated by the FSM (Fig. 4A). In sec9-10 mutant cells, FSMs initiated normally at both poles of the meiosis II spindles (Fig. 4A), but extension of the FSMs was soon blocked, resulting in anucleated small prespores (Fig. 4B). These results indicated that the FSM initiated normally, but its subsequent development was abnormal.
PMID:16272747 FYPO:0002061 Therefore, sec9+ is essential for vegetative cell growth and spore germination.
PMID:16272747 PBO:0110453 The level of sec9 mRNA began to increase about 6 hr after induction and peaked at about 9 hr, when cells were in early meiosis II (Fig. 2A, 2B).
PMID:16291723 FYPO:0002061 `SYNTHETIC LETHAL
PMID:16291723 FYPO:0003369 (50 mM)
PMID:16291723 FYPO:0001234 Fig. 1A.
PMID:16291723 PBO:0096390 Fig. 1A. All cells lysed while undergoing division and the daughter cells remained attached to one another.
PMID:16291723 FYPO:0001366 Fig. 1A. All cells lysed while undergoing division and the daughter cells remained attached to one another.
PMID:16291723 FYPO:0000132 with lysis (these are not chained cells) (Fig. 2C).....cells septum degradation appeared to initiate at a single position around the cell circumference and the entire cell wall disappeared from this area
PMID:16291723 GO:0005783 (Fig. 3B). Gyp10 localized to structures reminiscent of the endoplasmic reticulum (Broughton et al., 1997) when expressed from the low strength nmt81 promoter
PMID:16291723 FYPO:0002060 Fig. 3C.
PMID:16291723 FYPO:0001234 (Fig. 3C).
PMID:16291723 PBO:0020891 (Fig. 3C).
PMID:16291723 FYPO:0002061 Fig. 3C
PMID:16291723 FYPO:0002200 Fig. 3C
PMID:16291723 PBO:0096391 Fig. 3C
PMID:16291723 GO:0016192 Consistent with a role in vesicular trafficking, gyp10 showed a strong negative genetic interaction with cells lacking the exocyst subunit, Exo70p (Wang et al., 2002) (Fig. 3C).
PMID:16291723 GO:0000935 Both proteins localized to the division site(Fig. 4B,D). Rgf1p-GFP formed rings (Fig. 4B) late in mitosis as only cells containing segregated DNA masses contained them (data not shown and Fig. 7A)
PMID:16291723 GO:0031097 .By contrast, Rgf3p-GFP was not detected at cell ends, only at the medial region of the cell (Fig. 4D). Furthermore, Rgf3p rings constricted (Fig. 4D, inset). These differences in pattern are illustrated in Fig. 4E
PMID:16291723 GO:0051286 Rgf1p-GFP was also detected at cell ends (Fig. 4B).
PMID:16291723 PBO:0096392 Figue 5C
PMID:16291723 PBO:0096393 Figue 5C
PMID:16291723 PBO:0096394 Figue 5C Interestingly, overexpression of gpt10+ (Fig. 5G), but not rho1+ (data not shown) restored the localization of Rgf3 in lad1-1 cells at 36°C.
PMID:16291723 FYPO:0002061 rgf3+ is essential
PMID:16291723 FYPO:0002060 rgf3+ is essential
PMID:16291723 FYPO:0001367 fig 6
PMID:16291723 PBO:0096395 asked whether Rho1p was able to localize correctly to the medial region of the cell in the lad1-1 strain that we had shown lacks medially placed Rgf3p (Fig. 5C). We found that it did (Fig. 6B).
PMID:16291723 PBO:0096396 Ace2p, we examined whether Rgf3p levels were altered in cells lacking or overproducing Ace2p. Overproduction of Ace2p led to increased Rgf3p levels whereas Rgf3p was less abundant in cells lacking Ace2p (Fig. 7B). However, Rgf3p-Myc13 was clearly detectable in the absence of Ace2p suggesting that other factors cooperate with Ace2p to regulate rgf3+ expression.
PMID:16291723 PBO:0096397 To determine whether Rgf3p production was controlled by Ace2p, we examined whether Rgf3p levels were altered in cells lacking or overproducing Ace2p. Overproduction of Ace2p led to increased Rgf3p levels whereas Rgf3p was less abundant in cells lacking Ace2p (Fig. 7B
PMID:16291723 PBO:0096398 To determine whether Rgf3p production was controlled by Ace2p, we examined whether Rgf3p levels were altered in cells lacking or overproducing Ace2p. Overproduction of Ace2p led to increased Rgf3p levels whereas Rgf3p was less abundant in cells lacking Ace2p (Fig. 7B
PMID:16291723 GO:0140279 Rgf3p appears necessary to stimulate Rho1p-mediated activation of a glucan synthase crucial after septation for proper new cell-end formation.
PMID:16317005 PBO:0101093 activated_by CHEBI:15422 | inhibited_by CHEBI:16284
PMID:16317005 PBO:0101093 activated_by CHEBI:15422 | inhibited_by CHEBI:16284
PMID:16325576 PBO:0109782 Figure 2C
PMID:16325576 PBO:0109780 figure1
PMID:16325576 PBO:0109780 figure1
PMID:16325576 PBO:0109780 figure1
PMID:16325576 PBO:0109780 figure1
PMID:16325576 PBO:0109780 figure1
PMID:16325576 FYPO:0001894 figure2a
PMID:16325576 FYPO:0001894 figure2a
PMID:16325576 PBO:0109676 figure2b
PMID:16325576 PBO:0109781 Figure 2C
PMID:16325576 PBO:0109782 Figure 2C/3b
PMID:16325576 FYPO:0004159 Figure 2C
PMID:16325576 PBO:0109783 S1
PMID:16325576 PBO:0109784 S1
PMID:16325576 PBO:0109785 S1
PMID:16325576 PBO:0109786 S1
PMID:16325576 PBO:0109786 S1
PMID:16325576 PBO:0109786 S1
PMID:16325576 FYPO:0000488 S2
PMID:16325576 FYPO:0005648 Figure 2D. Although deletion of moa1+ thus causes a centro- mere-specific defect, recombination appears to promote re- ductional segregation in moa1D cells because the defect in monopolar attachment is lessened in diploid recombination- proficient meiosis compared to haploid meiosis or diploid
PMID:16325576 FYPO:0004393 Whereas monopolar attachment is obviously impaired in moa1D rec12D meiosis I, the protection of centromere co- hesion also appears defective since almost all sister chroma- tids eventually separate.
PMID:16325576 PBO:0096952 Whereas monopolar attachment is obviously impaired in moa1D rec12D meiosis I, the protection of centromere co- hesion also appears defective since almost all sister chroma- tids eventually separate.
PMID:16325576 PBO:0092319 induced
PMID:16325576 GO:0005515 fig 5A
PMID:16325576 PBO:0096955 Figure 5C However, the ChIP assay demonstrated intact lo- calization of Moa1 in rec8D meiotic cells (Figure 5C). Instead, we discovered that Moa1 localization was abolished in cells lacking CENP-C (Cnp3) (Figure 5C),
PMID:16325576 PBO:0096955 Figure 5C However, the ChIP assay demonstrated intact lo- calization of Moa1 in rec8D meiotic cells (Figure 5C). Instead, we discovered that Moa1 localization was abolished in cells lacking CENP-C (Cnp3) (Figure 5C),
PMID:16325576 PBO:0096957 Surprisingly, moa1D cells displayed slightly stronger signals of Rec8-GFP at the cluster of centromeres (Figure 6A, GFP dots in the nucleus). Subsequent ChIP assays revealed that the association of Rec8 to chromatin increased nearly 2-fold in moa1D cells, particularly at the centromeric central core region (Figure 6B).
PMID:16325576 PBO:0096958 This hypothesis makes the key prediction that the in- crease of Rec8 at the centromeric central core would de- pend on DNA replication. To test this possibility, we blocked DNA replication by adding HU to the synchronized meiotic culture and examined by ChIP the localization pattern of Rec8 (Figure 6C). Levels of central core-associated Rec8 were the same before (+HU) or after DNA replication (-HU) in wild-type cells. Remarkably, HU treatment abolished the increase of central core Rec8 in moa1D cells, and the pattern became similar to that in moa1+ cells (Figure 6C, +HU).
PMID:16325576 FYPO:0004212 (VW, I am not sure that I captured this correctly?) A ChIP assay revealed that the association of Rec8(TEV) with chromatin is partly, but not entirely, impaired only at the centromeric central core region when cen-TEV protease is coexpressed (Figure 7C), suggesting that Rec8(TEV) is cleaved in a region-specific manner. We reasoned that, even if central core Rec8 is cleaved by cen-TEV protease, newly produced or free Rec8 complexes can be reloaded, resulting in the observed association of low levels of Rec8 at the central core. Nevertheless, such ‘‘turnover’’ of cohesin complexes would eventually abolish cohesion because newly associated cohesins do not reestablish cohesion after DNA replication.
PMID:16360688 PBO:0112576 figure 3a Interestingly, no additive effect was seen in the bub11–179 sgo2D double mutant, indicating that Sgo2 and the kinase domain of Bub1 act in the same pathway (Figure 3A).
PMID:16360688 PBO:0112582 figure 1c
PMID:16360688 PBO:0112584 figure 1c
PMID:16360688 PBO:0112577 figure 1a
PMID:16360688 PBO:0112577 figure1a
PMID:16360688 PBO:0112576 figure 1b
PMID:16360688 PBO:0112582 Interestingly, no additive effect was seen in the bub11–179 sgo2D double mutant, indicating that Sgo2 and the kinase domain of Bub1 act in the same pathway (Figure 3A).
PMID:16360688 FYPO:0006315 As reported previously [13], expression of Rec8RDRD in wild-type cells prevented homolog segregation (no bi- nucleate cells), but homolog segregation was restored to a certain extent by the deletion of rec11 (approxi- mately 40% binucleated cells).
PMID:16360688 PBO:0112585 figure 1c
PMID:16360688 PBO:0100757 but homolog segregation was restored to a certain extent by the deletion of rec11 (approxi- mately 40% binucleated cells).
PMID:16360688 PBO:0112578 figure 1a
PMID:16360688 PBO:0112583 figure 1c
PMID:16360688 PBO:0112579 figure1a
PMID:16360688 PBO:0112586 , Sgo1 is seen as nuclear staining with punctate dots of fluores- cence along the spindle (Figure 1D and [2, 9]). This local- ization is abolished in a bub1D background but pre- served in the truncated mutants (Figure 1D), although the signal intensity was variable; in bub11–585, Sgo1 staining was as strong as in the wild-type, but it was weaker in bub11–179 and bub11–826 backgrounds. We conclude that the N terminus of Bub1 is sufficient to pro- mote correct Sgo1 localization and function during MI.
PMID:16360688 PBO:0112587 , Sgo1 is seen as nuclear staining with punctate dots of fluores- cence along the spindle (Figure 1D and [2, 9]). This local- ization is abolished in a bub1D background but pre- served in the truncated mutants (Figure 1D), although the signal intensity was variable; in bub11–585, Sgo1 staining was as strong as in the wild-type, but it was weaker in bub11–179 and bub11–826 backgrounds. We conclude that the N terminus of Bub1 is sufficient to pro- mote correct Sgo1 localization and function during MI.
PMID:16360688 PBO:0112587 , Sgo1 is seen as nuclear staining with punctate dots of fluores- cence along the spindle (Figure 1D and [2, 9]). This local- ization is abolished in a bub1D background but pre- served in the truncated mutants (Figure 1D), although the signal intensity was variable; in bub11–585, Sgo1 staining was as strong as in the wild-type, but it was weaker in bub11–179 and bub11–826 backgrounds. We conclude that the N terminus of Bub1 is sufficient to pro- mote correct Sgo1 localization and function during MI.
PMID:16360688 PBO:0112587 , Sgo1 is seen as nuclear staining with punctate dots of fluores- cence along the spindle (Figure 1D and [2, 9]). This local- ization is abolished in a bub1D background but pre- served in the truncated mutants (Figure 1D), although the signal intensity was variable; in bub11–585, Sgo1 staining was as strong as in the wild-type, but it was weaker in bub11–179 and bub11–826 backgrounds. We conclude that the N terminus of Bub1 is sufficient to pro- mote correct Sgo1 localization and function during MI.
PMID:16360688 PBO:0112576 figure 1c
PMID:16360688 PBO:0112588 figure1c a high frequency of sis- ter-chromatid nondisjunction during MII (Figure 1C), consistent with Sgo1’s being largely nonfunctional in this mutant background.
PMID:16360688 PBO:0112586 Similarly, we found that Sgo1 was mislocalized in a different allele (Figure 1D, K762M [6])
PMID:16360688 PBO:0112589 However, we found that Bub1K762M was properly localized in metaphase I cells and that the amount of protein at centromeres was close to wild-type levels (Figure S1).
PMID:16360688 PBO:0112576 figure 1c
PMID:16360688 PBO:0112582 figure 1c Interestingly, no additive effect was seen in the bub11–179 sgo2D double mutant, indicating that Sgo2 and the kinase domain of Bub1 act in the same pathway (Figure 3A).
PMID:16360688 PBO:0112581 figure1a
PMID:16360688 PBO:0112580 figure1a
PMID:16394105 PBO:0037146 fig 3
PMID:16394105 PBO:0102080 Figure 1 B
PMID:16394105 PBO:0102085 Figure 8 C
PMID:16394105 PBO:0102079 Figure 1 B
PMID:16394105 PBO:0102078 supp data
PMID:16394105 FYPO:0002060 table 4
PMID:16394105 PBO:0102086 Figure 8 D
PMID:16394105 FYPO:0005684 fig 4
PMID:16394105 FYPO:0005684 fig 4
PMID:16394105 PBO:0102086 Figure 8 D
PMID:16394105 FYPO:0005683 fig 4
PMID:16394105 FYPO:0005703 both the growth and shrinkage rates were decreased down to 33 and 60%, respectively,
PMID:16394105 PBO:0102086 Figure 8 D
PMID:16394105 FYPO:0005691 Figure 9
PMID:16394105 FYPO:0000903 both the growth and shrinkage rates were decreased down to 33 and 60%, respectively,
PMID:16394105 FYPO:0002638 Figure 1 B
PMID:16394105 PBO:0102077 Figure 1 B
PMID:16394105 PBO:0102076 Figure 1 B
PMID:16394105 FYPO:0001357 fig 7 a
PMID:16394105 PBO:0102084 Figure 8 AB
PMID:16394105 FYPO:0005706 fig 4
PMID:16394105 FYPO:0005683 fig 4
PMID:16394105 FYPO:0002060 table 4
PMID:16394105 FYPO:0002060 table 4
PMID:16394105 PBO:0037147 fig 3
PMID:16394105 FYPO:0000899 morphology
PMID:16394105 FYPO:0001357 fig 7 a
PMID:16394105 PBO:0037149 Figur 6 B,C
PMID:16394105 PBO:0037150 Figur 6 B,C
PMID:16394105 FYPO:0001234 fig 7 b
PMID:16394105 FYPO:0002061 table 4
PMID:16394105 FYPO:0002061 table 4
PMID:16394105 FYPO:0002060 fig 5 e
PMID:16394105 FYPO:0002061 fig 5 d
PMID:16394105 FYPO:0005706 fig 4
PMID:16407242 PBO:0094176 higher protein level than in absence of HU, in both wild type and mutant
PMID:16407242 PBO:0098225 higher protein level than in absence of HU, in both wild type and mutant
PMID:16421249 FYPO:0001357 Figure 7C,
PMID:16421249 PBO:0094648 (Figure 2A The resulting strain, rgf1, showed a slow growth pattern at 28°C
PMID:16421249 PBO:0099850 Figure 2A
PMID:16421249 PBO:0099851 Figure 2B regardless of the growth temperature 30 –35% of the cells were lysed,
PMID:16421249 PBO:0099851 Figure 2B regardless of the growth temperature 30 –35% of the cells were lysed,
PMID:16421249 PBO:0099852 Figure 2B regardless of the growth temperature 30 –35% of the cells were lysed,
PMID:16421249 GO:0090334 positive regulation
PMID:16421249 PBO:0099853 this being consistent with the idea that rgf1 could act in the same pathway as rho1 (Figure 4A). Figure 5. The amount of active Rho1p increased considerably in the strain overexpressing Rgf1p compared with the wild- type strain. Moreover, only a minor amount of GTP-Rho1p was detected in the strain lacking Rgf1p.
PMID:16421249 FYPO:0001397 Figure 3A, As shown in Figure 3A, the rgf1 mutants showed a defect in actin organization in that they organized actin patches mostly at one end of the cell only
PMID:16421249 FYPO:0001366 Figure 3A at cell division site
PMID:16421249 FYPO:0003535 (Figure 3B) 55% of cdc10-129 cells displayed bipolar growth, whereas only 4% of cdc10-129 rgf1 cells were bipolar
PMID:16421249 GO:0051523 positive regulation
PMID:16421249 PBO:0099854 Figure 2B regardless of the growth temperature 30 –35% of the cells were lysed,
PMID:16421249 GO:0030866 positive regulation
PMID:16421249 FYPO:0005152 Figure 4A, the Csp hypersensitivity of the rgf1delta mutant was suppressed by rho1delta in .... None of the other genes was able to suppress the hypersensitivity of rgf1;
PMID:16421249 FYPO:0000079 Figure 4A, the Csp hypersensitivity of the rgf1delta mutant was suppressed by rho1delta in .... None of the other genes was able to suppress the hypersensitivity of rgf1;
PMID:16421249 FYPO:0000079 Figure 4A, the Csp hypersensitivity of the rgf1delta mutant was suppressed by rho1delta in .... None of the other genes was able to suppress the hypersensitivity of rgf1;
PMID:16421249 FYPO:0000079 Figure 4A, the Csp hypersensitivity of the rgf1delta mutant was suppressed by rho1delta in .... None of the other genes was able to suppress the hypersensitivity of rgf1;
PMID:16421249 FYPO:0000079 Figure 4A, the Csp hypersensitivity of the rgf1delta mutant was suppressed by rho1delta in .... None of the other genes was able to suppress the hypersensitivity of rgf1;
PMID:16421249 FYPO:0000079 Figure 4A, the Csp hypersensitivity of the rgf1delta mutant was suppressed by rho1delta in .... None of the other genes was able to suppress the hypersensitivity of rgf1;
PMID:16421249 FYPO:0007436 Figure 4c Lack of Rga1p produces small colonies and the cells show a swollen, multiseptated or branched shape; a pheno- type similar to that seen in cells in which Rho1p is excessively activated
PMID:16421249 PBO:0095634 (Figure 2A The resulting strain, rgf1, showed a slow growth pattern at 28°C
PMID:16421249 PBO:0094648 rga1 cells were severely impaired for growth, whereas rgf1rga1 exhibited a better growth pat- tern and resembled rgf1 cells.
PMID:16421249 PBO:0099855 rescue of multiseptate, swollen
PMID:16421249 PBO:0099856 increased gtp-bound gtpase (active)
PMID:16421249 PBO:0099857 decreased gtp-bound gtpase (active)
PMID:16421249 PBO:0099851 Figure 2B regardless of the growth temperature 30 –35% of the cells were lysed,
PMID:16421249 FYPO:0001968 (Figure 6B) GS activity increased during rgf1 overex- pression. This activity was fourfold higher than that ob- served in the wild-type strain
PMID:16421249 FYPO:0001357 Figure 7A, only a moderate expres- sion of bgs4 restored growth of an rgf1 mutant in the presence of the antifungal agent
PMID:16421249 FYPO:0001357 Figure 7A,
PMID:16421249 FYPO:0001357 Figure 7A,
PMID:16421249 FYPO:0001357 Figure 7A,
PMID:16421249 FYPO:0002060 DNS
PMID:16421249 GO:0090334 positive regulation
PMID:16421249 PBO:0018345 Figure 8A
PMID:16421249 PBO:0020227 Figure 8A
PMID:16421249 PBO:0098289 Figure 8A
PMID:16421249 GO:0140472 Figure 8A
PMID:16428435 PBO:0093560 Fig. 4
PMID:16428435 FYPO:0005369 Fig. 4
PMID:16428435 FYPO:0005369 Fig. 4
PMID:16428435 FYPO:0005369 Fig. 4
PMID:16428435 PBO:0093554 Fig. 4
PMID:16428435 PBO:0093559 Fig. 4
PMID:16428435 PBO:0112187 Fig. 2D
PMID:16428435 PBO:0112186 Fig. 2D
PMID:16428435 PBO:0112036 Fig. 2C and D
PMID:16428435 PBO:0112035 Fig. 2B
PMID:16428435 PBO:0093560 Fig. 4
PMID:16428435 PBO:0093560 Fig. 4
PMID:16428435 PBO:0093559 Fig. 4
PMID:16428435 PBO:0093561 Fig. 4
PMID:16428435 PBO:0093557 Fig. 4
PMID:16428435 PBO:0112034 Fig. 2
PMID:16428435 PBO:0112037 Fig. 3
PMID:16428435 PBO:0093557 Fig. 4
PMID:16428435 PBO:0093558 Fig. 4
PMID:16428435 PBO:0093558 Fig. 4
PMID:16428435 FYPO:0004481 Fig. 4
PMID:16428435 PBO:0112035 Fig. 3B and C
PMID:16428435 FYPO:0004481 Fig. 4
PMID:16428435 PBO:0093560 Fig. 4
PMID:16428435 PBO:0093560 Fig. 4
PMID:16428435 PBO:0093561 Fig. 4
PMID:16428435 PBO:0093559 Fig. 4
PMID:16428435 FYPO:0002150 Thus, the carboxyl terminus of Cdk9 [...] is required for cell viability. Table 2
PMID:16428435 FYPO:0002061 Tetrad analysis revealed a 2:2 segregation of viability, and all viable progeny were G418 sensitive, indicating that cdk9 + is essential (data not shown).
PMID:16453724 FYPO:0003758 ABOLISHED SEPARATION
PMID:16453724 FYPO:0003758 ABOLISHED SEPARATION
PMID:16453724 FYPO:0000608 with re-replication
PMID:16453733 FYPO:0002085 suppresses cdc2-M26 temperature sensitive phenotype at 32
PMID:16453733 FYPO:0002085 suppresses cdc2-M55 temperature sensitive phenotype at 32
PMID:16453733 FYPO:0002085 suppresses temperature sensitive phenotype of cdc2-33 at 32
PMID:16453733 PBO:0033166 23% 2 spore asci when selfed
PMID:16453733 FYPO:0000681 when selfed produces 76% 2 spore asci at 25 compared to 5% in suc1+ background
PMID:16453733 FYPO:0002085 suppresses cdc2-33 temperature sensitive phenotype at 32
PMID:16453733 FYPO:0002085 suppresses cdc2-56 temperature sensitive phenotype at 35
PMID:16453733 FYPO:0002085 suppresses cdc2-M26 temperature sensitive phenotype at 32
PMID:16453733 FYPO:0000681 increased expression gives increased % 2 spored asci
PMID:16453733 FYPO:0002085 suppresses cdc2-56 temperature sensitive phenotype at 35
PMID:16453733 FYPO:0002085 suppresses cdc2-M55 temperature sensitive phenotype at 32
PMID:16453733 FYPO:0002085 suppresses cdc2-L7 temperature sensitive phenotype at 32 and weakly at 35
PMID:16453733 FYPO:0002085 suppresses cdc2-L7 temperature sensitive phenotype at 32
PMID:1645660 GO:0016791 inhibited_by zinc(2+) activated_by magnesium(2+)
PMID:16467379 GO:0031097 localization dependent on F-actin (assayed using Latrunculin A)
PMID:16481403 FYPO:0006397 from both ends
PMID:16481403 GO:0051415 emtoc
PMID:16481403 FYPO:0005558 from both ends
PMID:16481403 FYPO:0006195 Fig1 D (actually 2 bundles)
PMID:16481403 PBO:0101741 fig1
PMID:16481403 PBO:0020565 igure 5B
PMID:16481403 GO:0008017 fig 1c
PMID:16483313 PBO:0102487 isn't really processing, cleavage
PMID:16489217 GO:0010515 maybe not shown strongly in this paper but I'm trying to get the git genes annotated to this term because pka1 phosphorylates rst2 which excludes rst2 from the nucleus. rst2 when in the nucleus activates ste11 transcription.
PMID:16537923 PBO:0098521 genes specified in extensions assayed in low-throughput Northern blots; additional genes assayed in high-throughput microarrays not listed
PMID:16537923 FYPO:0001357 aerobic conditions
PMID:16537923 PBO:0098522 genes specified in extensions assayed in low-throughput Northern blots; additional genes assayed in high-throughput microarrays not listed
PMID:16537923 PBO:0098520 genes specified in extensions assayed in low-throughput Northern blots; additional genes assayed in high-throughput microarrays not listed
PMID:16541024 GO:0000775 Fig. 4b
PMID:16541024 PBO:0097372 Fig. 2b
PMID:16541024 GO:0000775 Fig. 4b
PMID:16541024 FYPO:0003176 Supplementary Fig. S2a
PMID:16541024 PBO:0097371 Fig. 4
PMID:16541024 PBO:0112500 Fig. 2b
PMID:16541024 GO:0000159 fig.1
PMID:16541024 GO:0000159 fig.1
PMID:16541024 FYPO:0003176 Supplementary Fig. S2a
PMID:16541024 FYPO:0003176 Supplementary Fig. S2a
PMID:16541024 PBO:0097366 Supplementary Fig. S2a
PMID:16541024 PBO:0097016 Supplementary Fig. S2a
PMID:16541024 GO:0000159 fig.1
PMID:16541024 FYPO:0002219 Fig. 2a
PMID:16541024 PBO:0112500 Fig. 2b
PMID:16541024 PBO:0097373 Fig. 4
PMID:16541024 PBO:0109333 this is an inference, but almost certainly true based on the genetics
PMID:16541024 PBO:0112501 Fig. 2b
PMID:16541024 PBO:0112501 Fig. 2b
PMID:16541024 PBO:0097370 Fig. 2b
PMID:16541024 PBO:0097370 Fig. 2b
PMID:16541024 FYPO:0002219 Fig. 2a
PMID:16541024 PBO:0097370 Fig. 2b
PMID:16541024 PBO:0109336 Notably, we detected only a single combination of PP2A subunits associated with SpSgo1, namely SpPaa1A–SpPar1B′–SpPpa2C
PMID:16541024 PBO:0097371 Fig. 4
PMID:16541024 FYPO:0002219 Fig. 2a
PMID:16541024 PBO:0097367 Fig. 2a
PMID:16541024 GO:0000775 Fig. 4b
PMID:16541024 GO:0000775 Fig. 4b
PMID:16541025 FYPO:0003182 (Supplementary Fig. 7)
PMID:16541025 PBO:0109338 Fig. 5a
PMID:16541025 PBO:0102397 Fig. 5b however, it colocalizes with Sgo1 at centromeres during meiosis I
PMID:16541025 PBO:0095117 dns
PMID:16541025 PBO:0102398 (Fig. 5b).
PMID:16541025 PBO:0102399 We found that, like sgo1D cells, par1D cells mostly lost centromeric Rec8 localization at this stage (Fig. 5d)
PMID:16541025 FYPO:0005648 (Supplementary Fig. 7)...both of these mutant cell types showed precocious centromeric dissociation after meiosis I, and random chromosome segregation following meiosis II
PMID:16541025 FYPO:0003182 (Supplementary Fig. 7)
PMID:16541025 FYPO:0005648 (Supplementary Fig. 7).
PMID:16541025 PBO:0109338 Fig. 5a
PMID:1655416 PBO:0033737 LENgth
PMID:1655416 FYPO:0000333 transient
PMID:1655416 FYPO:0000333 is delayed but the delay is reduced compared to the single mutant
PMID:1655416 GO:0005515 ADD MODIFIED FORMS
PMID:1655416 PBO:0033742 figure 10 C
PMID:1655416 PBO:0033741 figure 10 C
PMID:1657594 GO:0030552 fig 6
PMID:1657594 PBO:0099549 fig 6
PMID:16585273 FYPO:0000927 Fig. 4 E
PMID:16611237 PBO:0095920 indicates a G2 delay
PMID:16618806 PBO:0099533 induced dimerization increases Cds1 autophosphorylation without prior phosphorylation on T11
PMID:16618806 PBO:0102097 assayed substrate myelin basic protein
PMID:16618806 PBO:0102097 assayed substrate myelin basic protein
PMID:16618806 PBO:0102097 assayed substrate myelin basic protein
PMID:16618806 PBO:0102098 has output PR:000037300
PMID:16618806 PBO:0102097 assayed substrate myelin basic protein
PMID:16618806 PBO:0102090 residue T11
PMID:16618806 PBO:0098128 assayed substrate myelin basic protein
PMID:16618806 PBO:0098128 assayed substrate myelin basic protein
PMID:16618806 PBO:0093581 cells otherwise haploid
PMID:16618806 PBO:0102091 residue T11
PMID:16618806 PBO:0094255 residue T11
PMID:16618806 PBO:0094206 assayed substrate myelin basic protein
PMID:16618806 PBO:0102093 effect of mutation in substrate Cds1 molecule
PMID:16618806 PBO:0098128 assayed substrate myelin basic protein
PMID:16618806 PBO:0098128 assayed substrate myelin basic protein
PMID:16618806 PBO:0098128 assayed substrate myelin basic protein
PMID:16618806 PBO:0102090 residue T11
PMID:16618806 PBO:0093581 cells otherwise haploid
PMID:16618806 PBO:0093581 cells otherwise haploid
PMID:16618806 PBO:0102092 residue T11
PMID:16618806 PBO:0102090 residue T11
PMID:16618806 PBO:0098128 assayed substrate myelin basic protein
PMID:16618806 PBO:0102094 effect of mutation in substrate Cds1 molecule
PMID:16618806 PBO:0102095 effect of mutation in substrate Cds1 molecule
PMID:16618806 PBO:0102096 abolished dimerization in kinase-dead cds1-D312E
PMID:16624923 FYPO:0007168 cortical location/microtubules did not show a lateral interaction with the cell corte/Ninety-two percent of microtubules in num1D cells underwent catastrophe Figure 3.—Nuclear behavior in wild-type and num1D zy- gotes. Chromosomal DNA in zygotes (JY450 or JV627) was stained with Hoechst 33342 and monitored. The numbers on the left indicate time in minutes. Microtubules were visu- alized simultaneously by GFP-tagged a-tubulin. Stained DNA is shown in red, and GFP fluorescence in green. Bar, 5 mm. within 2 min of contacting the cell cortex (n 1⁄4 59). In contrast, 80% of microtubules that interacted with the cell cortex laterally in wild-type cells remained at the cell ends for .2 min (n 1⁄4 15).
PMID:16624923 PBO:0105249 membrane anchor
PMID:16682348 PBO:0103025 G1 arrested cells
PMID:16682348 PBO:0101859 (G1 arrested cells)
PMID:16687577 PBO:0106114 Figure 6 asymetric during cytokinesis delay
PMID:16687577 PBO:0095630 fig 1
PMID:16687577 PBO:0095630 fig 1
PMID:16687577 PBO:0095630 fig 1
PMID:16687577 PBO:0095196 fig 2
PMID:16687577 PBO:0106115 fig7
PMID:16687577 PBO:0106111 fig 5 (during ectopic SIN activation)
PMID:16687577 PBO:0106106 fig 2
PMID:16687577 PBO:0106112 Figure 5, D and E for maintenance of the actomyosin ring in response to cytokinesis delay upon
PMID:16687577 PBO:0106107 fig 3
PMID:16687577 PBO:0094433 fig 3
PMID:16687577 PBO:0106108 fig4
PMID:16687577 PBO:0106109 fig4
PMID:16687577 FYPO:0002026 fig4
PMID:16687577 GO:1903475 different pathway
PMID:16687577 PBO:0106113 Figure 5, D and E for maintenance of the actomyosin ring in response to cytokinesis delay upon
PMID:16687577 GO:1903475 different pathway
PMID:16687577 PBO:0106110 fig 5
PMID:16687577 PBO:0038073 fig 5
PMID:16738311 PBO:0093560 32 °C
PMID:16738311 FYPO:0001355 32 °C; very slightly worse than without cid12delta
PMID:16738311 FYPO:0002928 centromere outer repeat transcripts
PMID:16738311 PBO:0021902 homozygous diploid
PMID:16738311 FYPO:0001355 32 °C
PMID:16738311 FYPO:0001357 32 °C
PMID:16738311 PBO:0112498 homozygous diploid
PMID:16738311 PBO:0094078 homozygous diploid
PMID:16738311 FYPO:0002061 26 °C
PMID:16738311 FYPO:0002061 26 °C
PMID:16738311 PBO:0093560 32 °C
PMID:16738311 PBO:0093560 32 °C; same as without cid12delta
PMID:16738311 PBO:0094078 homozygous diploid
PMID:16738311 FYPO:0001355 32 °C
PMID:16738311 PBO:0019238 homozygous diploid
PMID:16738311 FYPO:0000460 nda3-KM311 allele also in genotype, but used as assay tool here
PMID:16738311 PBO:0109960 homozygous diploid
PMID:16738311 FYPO:0001355 32 °C; better than without cid12delta
PMID:16738311 FYPO:0001355 32 °C
PMID:16738311 FYPO:0001355 32 °C
PMID:16762840 FYPO:0002335 . We found that loss of Epe1 restores Swi6 localization and silencing in Dago1 and Dclr3 mutants to levels comparable to wild-type cells (Figure 5C and Figure S3),
PMID:16762840 PBO:0111025 Moreover, Epe1 was de- tected at certain meiotic genes, some of which are coated with heterochromatic markers (Figure 2A; [Cam et al., 2005]).
PMID:16762840 PBO:0098232 Moreover, Epe1 was de- tected at certain meiotic genes, some of which are coated with heterochromatic markers (Figure 2A; [Cam et al., 2005]).
PMID:16762840 PBO:0111023 Moreover, Epe1 was de- tected at certain meiotic genes, some of which are coated with heterochromatic markers (Figure 2A; [Cam et al., 2005]).
PMID:16762840 PBO:0111022 Moreover, Epe1 was de- tected at certain meiotic genes, some of which are coated with heterochromatic markers (Figure 2A; [Cam et al., 2005]).
PMID:16762840 PBO:0098231 Moreover, Epe1 was de- tected at certain meiotic genes, some of which are coated with heterochromatic markers (Figure 2A; [Cam et al., 2005]).
PMID:16762840 PBO:0111026 In swi6 mutant background, Epe1-GFP was no longer localized to discrete spots at the nuclear periphery (Figure 3A).
PMID:16762840 GO:0005721 heterochromatic loci, including centromeres, telomeres, and the mat locus (Figure 2A).
PMID:16762840 GO:0140720 heterochromatic loci, including centromeres, telomeres, and the mat locus (Figure 2A).
PMID:16762840 GO:0031934 heterochromatic loci, including centromeres, telomeres, and the mat locus (Figure 2A).
PMID:16762840 PBO:0111021 Moreover, Epe1 was de- tected at certain meiotic genes, some of which are coated with heterochromatic markers (Figure 2A; [Cam et al., 2005]).
PMID:16762840 GO:0000792 Localization of Epe1-GFP re- vealed two to three discrete foci at the nuclear periphery (Figure S1 available in the Supplemental Data with this article online), in a pattern that is similar to those of proteins associated with heterochromatin such as Swi6 (Ekwall et al., 1995).
PMID:16762840 PBO:0111027 Moreover, ChIP analy- sis revealed that mutation in Swi6 or an H3K9-specific methyltransferase Clr4 abolished Epe1 localization at centromeres, telomeres, and the mat locus, concurrent with loss of Swi6 at these loci (Figure 3B)
PMID:16762840 PBO:0111028 Moreover, ChIP analy- sis revealed that mutation in Swi6 or an H3K9-specific methyltransferase Clr4 abolished Epe1 localization at centromeres, telomeres, and the mat locus, concurrent with loss of Swi6 at these loci (Figure 3B)
PMID:16762840 PBO:0111029 Moreover, ChIP analy- sis revealed that mutation in Swi6 or an H3K9-specific methyltransferase Clr4 abolished Epe1 localization at centromeres, telomeres, and the mat locus, concurrent with loss of Swi6 at these loci (Figure 3B)
PMID:16762840 PBO:0110571 a glutathione S-transferase (GST) pull-down assay showed that in vitro-translated Epe1 directly binds to GST-Swi6, but not GST alone (Figure 3D). This inter- action is not affected by a mutation in JmjC domain of Epe1 (Y307A) that impairs Epe1 function. Based on these analyses, Swi6-mediated recruitment of Epe1 might involve direct interaction between these factors. ChIP analysis revealed that muta- tions in swi6 or clr4 resulted in loss of Epe1 from mcp5, mcp7, mei4, and ssm4, and from the LC region (Figures 4A and 4B), suggesting Swi6 facilitated recruit- ment of Epe1 to these loci.
PMID:16762840 PBO:0094684 However, abundant transcripts corresponding to cen- tromeric repeats and cenH are detectable in RNAi- defective Dago1 cells. We found that the levels of tran- scripts in Depe1Dago1 double mutant cells were significantly reduced (Figures 5A and 5B), indicating that Epe1 facilitates transcription of the heterochromatic repeats.
PMID:16762840 PBO:0097227 However, abundant transcripts corresponding to cen- tromeric repeats and cenH are detectable in RNAi- defective Dago1 cells. We found that the levels of tran- scripts in Depe1Dago1 double mutant cells were significantly reduced (Figures 5A and 5B), indicating that Epe1 facilitates transcription of the heterochromatic repeats.
PMID:16762840 PBO:0097227 However, abundant transcripts corresponding to cen- tromeric repeats and cenH are detectable in RNAi- defective Dago1 cells. We found that the levels of tran- scripts in Depe1Dago1 double mutant cells were significantly reduced (Figures 5A and 5B), indicating that Epe1 facilitates transcription of the heterochromatic repeats.
PMID:16762840 PBO:0097227 Our analysis revealed that Epe1 is required for the increase in transcription of repeats in Dclr3 back- ground, as suggested by the dramatic reduction in tran- script levels in Depe1 Dclr3 double mutant compared to Dclr3 single mutant (Figures 5A and 5B).
PMID:16762840 PBO:0097227 Our analysis revealed that Epe1 is required for the increase in transcription of repeats in Dclr3 back- ground, as suggested by the dramatic reduction in tran- script levels in Depe1 Dclr3 double mutant compared to Dclr3 single mutant (Figures 5A and 5B).
PMID:16762840 PBO:0094684 Our analysis revealed that Epe1 is required for the increase in transcription of repeats in Dclr3 back- ground, as suggested by the dramatic reduction in tran- script levels in Depe1 Dclr3 double mutant compared to Dclr3 single mutant (Figures 5A and 5B).
PMID:16762840 FYPO:0002335 . We found that loss of Epe1 restores Swi6 localization and silencing in Dago1 and Dclr3 mutants to levels comparable to wild-type cells (Figure 5C and Figure S3),
PMID:16762840 PBO:0111024 Moreover, Epe1 was de- tected at certain meiotic genes, some of which are coated with heterochromatic markers (Figure 2A; [Cam et al., 2005]).
PMID:16762840 PBO:0094684 Indeed, in a situation wherein heterochromatin has been completely abol- ished, such as in a Dclr4 background, loss of Epe1 had no detectable effect on transcript levels (Figure 5D).
PMID:16762840 PBO:0094684 Indeed, in a situation wherein heterochromatin has been completely abol- ished, such as in a Dclr4 background, loss of Epe1 had no detectable effect on transcript levels (Figure 5D).
PMID:16762840 PBO:0111030 Deletion of clr3 re- sults in a dramatic increase in Pol II occupancy at cenH element within silent mat domain.
PMID:16762840 PBO:0111031 Remarkably, loss of Epe1 resulted in a diminished access of Pol II to cenH in Dclr3 cells, as indicated by substantial reduction in Pol II levels in Depe1 Dclr3 double mutant as compared to Dclr3 single mutant (Figure 5E).
PMID:16762840 FYPO:0000877 Remarkably, loss of Epe1 resulted in a diminished access of Pol II to cenH in Dclr3 cells, as indicated by substantial reduction in Pol II levels in Depe1 Dclr3 double mutant as compared to Dclr3 single mutant (Figure 5E). These results suggest that Epe1 has an important role in promoting access of transcriptional machinery to heterochromatic sequences, thereby facilitating transcription of repeat elements. Therefore, the balance of activities between Clr3 and Epe1, both of which are recruited by Swi6, seems critical in determining the transcriptional state of repeat ele- ments.
PMID:16762840 FYPO:0000862 Indeed, we found that loss of H3K9me2 in cells overexpressing Epe1 is de- pendent upon Swi6 (Figure 6D).
PMID:16762840 FYPO:0006373 We also tested the effect of Epe1 on heterochromatic markers at meiotic genes. Interestingly, loss of Epe1 re- sulted in considerable increase in H3K9me2 and H3K9me3 levels, concomitant with moderate increase in Swi6 binding at the ssm4 gene (Figures 6E and 6F).
PMID:16762840 FYPO:0006373 A similar increase in H3K9me2 levels was also observed in swi6 mutant cells defective in Epe1 recruitment to meiotic genes (Figure 6E).
PMID:16762840 FYPO:0002335 The Y307 mutation abolished the ability of Epe1 to destabilize heterochromatic silencing (Figure 6A).
PMID:16762840 PBO:0110802 ChIP analysis showed that mutant protein is recruited to heterochromatic loci (Figure 6B), consis- tent with data showing that Y307A mutation has no ef- fect on Epe1 interaction with Swi6 in vitro (Figure 3D)
PMID:16762840 PBO:0111032 We next investigated the possible involvement of Epe1 in boundary function of the IRC elements. Remarkably, deletion of epe1 resulted in spreading of Swi6 and H3K9me into euchromatic regions surrounding cen1 (Figure 7D).
PMID:16775007 GO:0005515 Fig 2A
PMID:16775007 GO:0044732 Fig 1A
PMID:16775007 FYPO:0002061 Figure 7A
PMID:16775007 FYPO:0002061 Figure 5, A and B
PMID:16775007 GO:0005515 Figure 4C
PMID:16775007 PBO:0098902 Fig2A
PMID:16775007 PBO:0098905 fig 5D
PMID:16816948 FYPO:0004009 pulse/chase
PMID:16822282 FYPO:0002143 fig3A
PMID:16822282 FYPO:0001309 fig3A
PMID:16822282 FYPO:0004129 caspase
PMID:16822282 FYPO:0002143 fig3A
PMID:16822282 FYPO:0002143 fig3A
PMID:16822282 FYPO:0001310 fig3A
PMID:16822282 FYPO:0004129 caspase
PMID:16822282 PBO:0097358 caspase
PMID:16822282 FYPO:0001310 fig3A
PMID:16822282 FYPO:0001309 fig3A
PMID:16823445 PBO:0094868 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPCP20C8.03) (mah 2014-08-05)
PMID:16823445 FYPO:0000625 assayed in diploid
PMID:16823445 FYPO:0000584 assayed in diploid
PMID:16823445 PBO:0094863 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPCP20C8.03) (mah 2014-08-05)
PMID:16823445 PBO:0094864 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPCP20C8.03) (mah 2014-08-05)
PMID:16823445 PBO:0094865 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPCP20C8.03) (mah 2014-08-05)
PMID:16823445 PBO:0094866 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPCP20C8.03) (mah 2014-08-05)
PMID:16823445 PBO:0094867 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPCP20C8.03) (mah 2014-08-05)
PMID:16823445 PBO:0094869 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPCP20C8.03) (mah 2014-08-05)
PMID:16823445 PBO:0094605 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPCP20C8.03) (mah 2014-08-05)
PMID:16823445 PBO:0094870 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPCP20C8.03) (mah 2014-08-05)
PMID:16823445 PBO:0094871 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPCP20C8.03) (mah 2014-08-05)
PMID:16823445 PBO:0094872 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPCP20C8.03) (mah 2014-08-05)
PMID:16823445 FYPO:0000583 assayed in diploid
PMID:16823445 PBO:0108615 Abstract We propose that Mei2 turns off the DSR-Mmi1 system by sequestering Mmi1 to the dot and thereby secures stable expression of meiosis-specific transcripts.
PMID:16824200 PBO:0022963 requires intact mitotic spindle, as shown by cold-depolymerizing microtubules and nda3 mad2 double mutant phenotype
PMID:16857197 PBO:0105400 might be abolished. Sometimes you see diploidization.
PMID:16914721 PBO:0097313 microarray data shows 111 genes affected
PMID:16914721 PBO:0094384 microarray data shows 111 genes affected
PMID:16914721 GO:0000184 These findings showed that Upf1 is re- quired for degradation of the ade6-M26 mRNA in S. pombe.
PMID:16914721 PBO:0097312 microarray data shows 111 genes affected
PMID:16914721 PBO:0097311 microarray data shows 111 genes affected
PMID:16914721 GO:0000184 These findings showed that Upf1 is re- quired for degradation of the ade6-M26 mRNA in S. pombe.
PMID:16914721 FYPO:0003917 assayed using ade6-M26
PMID:16920624 PBO:0106992 Figure 2C. The loss rate in Dis16E was lower than Dis16A and slightly higher than that in the wild-type. (The Dis16E mutant appears to mimic at least partially the Cdc2-phosphory- lated form of Dis1)
PMID:16920624 PBO:0106993 These results established that phosphorylation of Dis1 by Cdc2 is required for the high-fidelity segregation of a minichromosome. (A little bit of curator licence here)
PMID:16920624 FYPO:0002061 Figure 2D. The double mutant mis12 Dis16A failed to produce colonies at 33
PMID:16920624 FYPO:0001355 Figure 2D. whereas mis12 Dis1N3A and mis12 Dis1C3A showed weak inhibition of colony formation
PMID:16920624 FYPO:0001355 Figure 2D. whereas mis12 Dis1N3A and mis12 Dis1C3A showed weak inhibition of colony formation
PMID:16920624 FYPO:0001357 Figure 2D. However, the double mutant mis12 Dis16E could form colonies at 33C.
PMID:16920624 PBO:0023853 PHOSPHORYLATED. Fig3A The Dis1WT-GFP signals are seen as the kinetochore dots in metaphase. AND 4b
PMID:16920624 PBO:0106994 protein localized to spindle (also a child of mislocalized protein)
PMID:16920624 FYPO:0004310 Measurements of the durations of phase 1 (prophase to metaphase), 2 (metaphase to anaphase), and 3 (ana- phase B) on each of the 30 movies of Dis1WT, Dis16A, and Dis16E strains indicated that the timing of mitosis did not seem to be affected by any mutations because mea- sured differences were within the boundaries of experi- mental error (Figure S1C)
PMID:16920624 FYPO:0004310 Measurements of the durations of phase 1 (prophase to metaphase), 2 (metaphase to anaphase), and 3 (ana- phase B) on each of the 30 movies of Dis1WT, Dis16A, and Dis16E strains indicated that the timing of mitosis did not seem to be affected by any mutations because mea- sured differences were within the boundaries of experi- mental error (Figure S1C)
PMID:16920624 PBO:0106996 Curiously, bent spindles were observed in late anaphase of 53 of 121 Dis16A cells in movies, whereas only 18 of 104 Dis1WT and ten of 127 Dis16E cells examined showed the bent spindle (Figure S1D).
PMID:16920624 PBO:0022134 UNPHOSPHORYLATED. In anaphase, Dis1WT-GFP signals abruptly increased along the spindle and at the SPBs despite being absent from the central zone.
PMID:16920624 PBO:0018845 Because Dis1WT, Dis16A, and Dis16E all associated with anaphase SPBs, this as- sociation was independent of modification of the mole- cule on the Cdc2 phosphorylation sites.
PMID:16920624 FYPO:0000964 fig6
PMID:16920624 FYPO:0002061 In contrast, the Dis16E mutant, which shows the synthetic lethality with Dmtc1, dimin- ished signals along the metaphase spindle. Thus, there is a correlation between the affinity for microtubules of the mutant versions of Dis1 and these mutants’ ability to rescue the Dmtc1 defect.
PMID:16920624 PBO:0106989 figure 1B.
PMID:16920624 PBO:0106989 figure 1B.
PMID:16920624 PBO:0106990 Figure 1C
PMID:16920624 FYPO:0002141 Figure 2A.
PMID:16920624 FYPO:0002141 Figure 2A.
PMID:16920624 PBO:0093564 Figure 2B.
PMID:16920624 PBO:0093563 Figure 2B.
PMID:16920624 PBO:0093562 Figure 2B.
PMID:16920624 FYPO:0000964 Figure 2B. The sensitivities of Dis1N3A and Dis1C3A were similar to that of the wild-type.
PMID:16920624 FYPO:0000964 Figure 2B. The sensitivities of Dis1N3A and Dis1C3A were similar to that of the wild-type.
PMID:16920624 PBO:0106991 Figure 2C. The loss rate of CN2 minichromosome in Dis16A was much higher than that of the wild-type integrant...
PMID:16920624 FYPO:0001839 Figure 2C. .... whereas Dis1N3A and Dis1C3A had loss rates that were comparable to those of the wild- type Dis1 integrant.
PMID:16920624 FYPO:0001839 Figure 2C. .... whereas Dis1N3A and Dis1C3A had loss rates that were comparable to those of the wild- type Dis1 integrant.
PMID:16921379 PBO:0105172 in complex with Sfr1
PMID:16921379 PBO:0105172 in complex with Swi5
PMID:16921379 GO:0005515 sfr1 protein is not stable without swi5. swi5 alone does not bind rad51.
PMID:16921379 GO:0005515 sfr1 protein is not stable without swi5. swi5 alone does not bind rad51.
PMID:16931764 FYPO:0002835 Fig. 1E
PMID:16931764 PBO:0112803 Fig. 2A
PMID:16931764 PBO:0112804 Fig. 2A
PMID:16931764 PBO:0112803 Fig. 2A
PMID:16931764 PBO:0112804 Fig. 2A
PMID:16931764 PBO:0112805 Fig. 2B
PMID:16931764 PBO:0112806 Fig. 2B
PMID:16931764 PBO:0112801 Fig. 1D
PMID:16931764 PBO:0112801 Fig. 1D
PMID:16931764 PBO:0112802 Fig. 1D
PMID:16931764 FYPO:0002835 Fig. 1E
PMID:16931764 PBO:0112807 Fig. 2C
PMID:16931764 PBO:0112807 Fig. 2C
PMID:16931764 PBO:0098772 Fig. 2C
PMID:16931764 PBO:0098772 Fig. 2C
PMID:16931764 PBO:0094684 Fig. 3C
PMID:16931764 PBO:0094684 Fig. 3C
PMID:16931764 PBO:0112800 Fig. 1C
PMID:16931764 PBO:0112800 Fig. 1C
PMID:16931764 PBO:0112802 Fig. 1D
PMID:16931764 PBO:0112801 Fig. 1D
PMID:16931764 PBO:0112802 Fig. 1D
PMID:16931764 PBO:0112799 "Thus, Ago1 from fission yeast has ""slicing"" activity and can direct site-specific cleavage of RNA substrates via siRNA."
PMID:16931764 PBO:0112800 Fig. 1C
PMID:16931764 PBO:0112801 Fig. 1D
PMID:16931764 PBO:0112802 Fig. 1D
PMID:16963626 PBO:0095322 Consistently, mutations in the php3 - and php5 -encoded CCAAT-binding proteins were phenocopies of php2
PMID:16963626 GO:0016602 6b
PMID:16963626 PBO:0095322 Consistently, mutations in the php3 - and php5 -encoded CCAAT-binding proteins were phenocopies of php2
PMID:16963626 GO:0016602 using the cross-linking agent EGS, we found that the Php4 protein associates with the Php2/Php3/Php5 complex
PMID:1699136 PBO:0024124 figure 1c and Double staining using a combination of cdc13- and tubulin- specific antibodies showed that the dots corresponded exactly to the positions of the mitotic spindle poles (Fig. 3a, b)
PMID:1699136 PBO:0096176 figure 1c
PMID:1699136 PBO:0024124 figure 1c and Double staining using a combination of cdc13- and tubulin- specific antibodies showed that the dots corresponded exactly to the positions of the mitotic spindle poles (Fig. 3a, b)
PMID:1699136 PBO:0033573 figure2
PMID:17004072 FYPO:0001861 figure 2a
PMID:17004072 FYPO:0001861 figure 2a
PMID:17004072 FYPO:0002060 figure 5 b
PMID:17004072 FYPO:0002061 table 2
PMID:17005570 PBO:0104000 fig3
PMID:17005570 PBO:0104004 fig 6 B, lane 9
PMID:17005570 PBO:0104004 fig 6 B, lane 3
PMID:17005570 PBO:0104004 fig 6 A, lane 9
PMID:17005570 GO:0005515 fig 1
PMID:17005570 GO:0005515 fig 1
PMID:17005570 PBO:0104003 fig 5 C
PMID:17005570 PBO:0104003 fig 5 A
PMID:17005570 GO:0005515 fig 1
PMID:17005570 GO:0005515 fig 1
PMID:17005570 PBO:0103998 Fig 1c lane 9
PMID:17005570 PBO:0104002 fig3
PMID:17005570 PBO:0104002 fig3
PMID:17005570 PBO:0104002 fig3
PMID:17005570 PBO:0104000 fig3
PMID:17005570 PBO:0104005 fig 7 A
PMID:17005570 PBO:0104000 fig3
PMID:17005570 PBO:0104001 fig 1 f
PMID:17005570 PBO:0104001 fig 1 f
PMID:17005570 GO:0005515 fig 1 F
PMID:17005570 PBO:0104000 fig 1 d
PMID:17005570 PBO:0103999 fig 1 c
PMID:17005570 GO:0005515 fig 1
PMID:17005570 PBO:0103998 fig 1 b
PMID:17005570 PBO:0103999 fig 1 b
PMID:17005570 PBO:0104005 fig 7 A
PMID:17005570 GO:0005515 fig 1
PMID:17005570 GO:0005515 fig 1
PMID:1703321 PBO:0093712 I'm sure this has already been annotated. But previous annotations didn't come up, should they?
PMID:1703321 PBO:0097952 Figure 4D phospho amino acid analysis
PMID:1703321 PBO:0093712 data not shown
PMID:1703321 FYPO:0002060 cdc2-F15 gene is expressed from episomal pIRT2
PMID:1703321 FYPO:0006822 cdc2-F15 gene is expressed from episomal pIRT2
PMID:1703321 PBO:0093712 cdc25 over expressed from the constitutive ADH promoter. Data not shown
PMID:1703321 PBO:0093712 Also think this is previously annotated
PMID:1703321 PBO:0097952 Figure 4D phospho amino acid analysis
PMID:1703321 PBO:0097952 Figure 4 phospho amino acid analysis
PMID:1703321 PBO:0093712 data not shown
PMID:1703321 PBO:0097952 Figure 4D phospho amino acid analysis
PMID:1703321 FYPO:0002060 cdc2-F15 gene is expressed from episomal pIRT2
PMID:1703321 PBO:0093712 cdc2-F15 gene is expressed from episomal pIRT2
PMID:17035632 PBO:0109096 Proteins of the Mis6-like group remained at the centromere throughout meiosis (Figure 2B), whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0109097 Proteins of the Mis6-like group remained at the centromere throughout meiosis (Figure 2B), whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0109097 Proteins of the Mis6-like group remained at the centromere throughout meiosis (Figure 2B), whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0109096 Proteins of the Mis6-like group remained at the centromere throughout meiosis (Figure 2B), whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0109097 Proteins of the Mis6-like group remained at the centromere throughout meiosis (Figure 2B), whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0109097 Proteins of the Mis6-like group remained at the centromere throughout meiosis (Figure 2B), whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0109097 Proteins of the Mis6-like group remained at the centromere throughout meiosis (Figure 2B), whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0109097 whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0109096 Proteins of the Mis6-like group remained at the centromere throughout meiosis (Figure 2B), whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0109096 Proteins of the Mis6-like group remained at the centromere throughout meiosis (Figure 2B), whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0109096 Proteins of the Mis6-like group remained at the centromere throughout meiosis (Figure 2B), whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0109097 Proteins of the Mis6-like group remained at the centromere throughout meiosis (Figure 2B), whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0109096 Proteins of the Mis6-like group remained at the centromere throughout meiosis (Figure 2B), whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0018649 These 4 proteins share homology with the S. cerevisiae DASH com- plex, DAM1, DAD2, ASK1, and SPC34 (Miranda et al., 2005), and the observation that their centromere localization is limited to the M phase has been previously reported in S. pombe (Liu et al., 2005). Thus, we assigned these four proteins to the DASH complex (Table 2)
PMID:17035632 PBO:0018649 These 4 proteins share homology with the S. cerevisiae DASH com- plex, DAM1, DAD2, ASK1, and SPC34 (Miranda et al., 2005), and the observation that their centromere localization is limited to the M phase has been previously reported in S. pombe (Liu et al., 2005). Thus, we assigned these four proteins to the DASH complex (Table 2)
PMID:17035632 PBO:0018649 These 4 proteins share homology with the S. cerevisiae DASH com- plex, DAM1, DAD2, ASK1, and SPC34 (Miranda et al., 2005), and the observation that their centromere localization is limited to the M phase has been previously reported in S. pombe (Liu et al., 2005). Thus, we assigned these four proteins to the DASH complex (Table 2)
PMID:17035632 PBO:0018649 These 4 proteins share homology with the S. cerevisiae DASH com- plex, DAM1, DAD2, ASK1, and SPC34 (Miranda et al., 2005), and the observation that their centromere localization is limited to the M phase has been previously reported in S. pombe (Liu et al., 2005). Thus, we assigned these four proteins to the DASH complex (Table 2)
PMID:17035632 PBO:0103971 In contrast, four proteins (Dam1, Dad2, Ask1, and Spc34) were localized at the centromere only at the M phase (Table 2; group 2).
PMID:17035632 PBO:0103971 In contrast, four proteins (Dam1, Dad2, Ask1, and Spc34) were localized at the centromere only at the M phase (Table 2; group 2).
PMID:17035632 PBO:0103971 In contrast, four proteins (Dam1, Dad2, Ask1, and Spc34) were localized at the centromere only at the M phase (Table 2; group 2).
PMID:17035632 PBO:0109097 whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0109097 whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0109097 whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0109097 whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0103971 In contrast, four proteins (Dam1, Dad2, Ask1, and Spc34) were localized at the centromere only at the M phase (Table 2; group 2).
PMID:17035632 PBO:0109097 whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0109097 The DASH complex proteins (Dam1, Spc34, Dad2, and Ask1) were not detected during meiotic prophase. They reappeared at the centromere shortly before metaphase of meiosis I (Figure 4),
PMID:17035632 PBO:0109097 The DASH complex proteins (Dam1, Spc34, Dad2, and Ask1) were not detected during meiotic prophase. They reappeared at the centromere shortly before metaphase of meiosis I (Figure 4),
PMID:17035632 PBO:0103971 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103971 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103971 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103971 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103971 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103971 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103971 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103971 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103971 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103971 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103971 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103971 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103971 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103971 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103971 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103971 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103971 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103971 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103970 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103970 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103970 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103970 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0109097 The DASH complex proteins (Dam1, Spc34, Dad2, and Ask1) were not detected during meiotic prophase. They reappeared at the centromere shortly before metaphase of meiosis I (Figure 4),
PMID:17035632 PBO:0109097 The DASH complex proteins (Dam1, Spc34, Dad2, and Ask1) were not detected during meiotic prophase. They reappeared at the centromere shortly before metaphase of meiosis I (Figure 4),
PMID:17035632 PBO:0109099 In addition, their centromere localization depended on Mis6: Cnl2 and Fta7 proteins lost their centromere localization in a mis6-302 tem- perature-sensitive mutant at the restricted temperature of 36°C (Figure 1E)
PMID:17035632 PBO:0109098 In addition, their centromere localization depended on Mis6: Cnl2 and Fta7 proteins lost their centromere localization in a mis6-302 tem- perature-sensitive mutant at the restricted temperature of 36°C (Figure 1E)
PMID:17035632 PBO:0109097 whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0109097 whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0103970 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103970 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103970 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103970 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103970 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103970 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103970 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0109097 whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0103970 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103970 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103970 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103970 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103970 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103970 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0103970 18 proteins were localized at the centromere throughout the mitotic cell cycle (Table 2; group 1)
PMID:17035632 PBO:0109097 Sgo1 protein signal intensity increased in two steps (52 and 20 min before the metaphase–anaphase transition of meiosis I) in a way similar to the NMS (Ndc80- Mis12-Spc7) complex proteins (Figure 7B).
PMID:17035632 PBO:0109096 Sgo1 protein signal intensity increased in two steps (52 and 20 min before the metaphase–anaphase transition of meiosis I) in a way similar to the NMS (Ndc80- Mis12-Spc7) complex proteins (Figure 7B).
PMID:17035632 PBO:0109097 Proteins of the Mis6-like group remained at the centromere throughout meiosis (Figure 2B), whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0109097 Proteins of the Mis6-like group remained at the centromere throughout meiosis (Figure 2B), whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0109096 Proteins of the Mis6-like group remained at the centromere throughout meiosis (Figure 2B), whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0109096 Proteins of the Mis6-like group remained at the centromere throughout meiosis (Figure 2B), whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0109097 Proteins of the Mis6-like group remained at the centromere throughout meiosis (Figure 2B), whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17035632 PBO:0109096 Proteins of the Mis6-like group remained at the centromere throughout meiosis (Figure 2B), whereas those of the NMS group disappeared from the centromere or their presence was significantly reduced, dur- ing meiotic prophase (Figure 3).
PMID:17036054 PBO:0101888 figure 1a
PMID:17036054 PBO:0101887 figure 1a
PMID:17036054 FYPO:0005720 fig1b
PMID:17036054 PBO:0101893 fig1b
PMID:17036054 PBO:0101893 fig1b
PMID:17036054 PBO:0101894 fig1b
PMID:17036054 PBO:0101893 fig1b
PMID:17036054 PBO:0101891 Supplement
PMID:17036054 PBO:0101890 figure 1a
PMID:17036054 PBO:0101888 figure 1a
PMID:17036054 PBO:0101888 figure 1a
PMID:17036054 PBO:0101887 figure 1a
PMID:17036054 PBO:0101887 figure 1a
PMID:17036054 PBO:0101889 figure 1a
PMID:17038309 GO:0003677 binds both circular and linear DNA fragments
PMID:17038309 GO:0097680 i) xlf1 deletion is epistatic with lig4 deletion ii) IR sensitivity during spore state and inability to ligate linearised plasmids during vegetative state
PMID:17039252 PBO:0094400 especially during S and G2 phases
PMID:17039252 PBO:0094400 especially during S and G2 phases
PMID:17039252 PBO:0094400 especially during S and G2 phases
PMID:17039252 PBO:0094400 especially during S and G2 phases
PMID:17046992 FYPO:0004481 cells stop growing at high temperature, but remain viable and resume growth and division when returned to standard temperature
PMID:17046992 GO:1900087 TORC1 senses nutrients and pushes cells into the next cell cycle. Removing TORC1 activity, you get a buildup of rum1 and srw1 which inhibit G1/S
PMID:17046992 FYPO:0002060 cells stop growing at high temperature, but remain viable and resume growth and division when returned to standard temperature
PMID:17085965 GO:1902929 localization depends on microtubule cytoskeleton, as determined by treatment with carbendazim (methyl 2-benzimidazolecarbamate; MBC), and on actin cytoskeleton, as determined by treatment with latrunculin B or cytochalasin D
PMID:17112379 PBO:0093561 25 degrees
PMID:17112379 FYPO:0001974 30 degrees
PMID:17112379 FYPO:0002061 30 degrees
PMID:17112379 PBO:0093559 25 degrees
PMID:17112379 PBO:0093561 25 degrees
PMID:17121544 FYPO:0005097 (mimic nitrogen starvation response, When starved for nitrogen, on the other hand, the cells divide twice and then arrest at G1) At 4 h and 8 h after the shift to36 °C, the average cell length was reduced to 6.4 μm and6.2 μm, respectively, which were ∼50% decreases com-pared to wild-type cells (13.0 μm and 12.9 μm). Similar tsresults were obtained for tor2 -19. It is of note that, in contrast to the reduced length, the cell width remained constant in these mutant cells.
PMID:17121544 PBO:0103529 70% of ts the tor2 -13 cells committed sexual development to ts form zygotes and spores (Fig. 3B,C)
PMID:17121544 PBO:0097202 at 30 degrees// Tor1 becomes necessary for cell growth when Tor2 function is compromised.
PMID:17121544 PBO:0103531 at 30 degrees
PMID:17121544 FYPO:0002578 s expected, these double mutants behaved the same as tor1∆rhb1+o/e cells, in which growth was restored under stress conditions (the fourth row).
PMID:17121544 PBO:0103528 (mimic nitrogen starvation response, When starved for nitrogen, on the other hand, the cells divide twice and then arrest at G1) At 4 h and 8 h after the shift to36 °C, the average cell length was reduced to 6.4 μm and6.2 μm, respectively, which were ∼50% decreases com-pared to wild-type cells (13.0 μm and 12.9 μm). Similar tsresults were obtained for tor2 -19. It is of note that, in contrast to the reduced length, the cell width remained constant in these mutant cells.
PMID:17121544 FYPO:0005097 (mimic nitrogen starvation response, When starved for nitrogen, on the other hand, the cells divide twice and then arrest at G1) At 4 h and 8 h after the shift to36 °C, the average cell length was reduced to 6.4 μm and6.2 μm, respectively, which were ∼50% decreases com-pared to wild-type cells (13.0 μm and 12.9 μm). Similar tsresults were obtained for tor2 -19. It is of note that, in contrast to the reduced length, the cell width remained constant in these mutant cells.
PMID:17121544 FYPO:0002061 Figure 1B
PMID:17121544 FYPO:0002061 Figure 1B
PMID:17121544 FYPO:0000400 tor1∆tor2 -19 showed only the 2C peak, and no 1C peak appeared at 36 °C
PMID:17121544 PBO:0103528 (mimic nitrogen starvation response, When starved for nitrogen, on the other hand, the cells divide twice and then arrest at G1) At 4 h and 8 h after the shift to36 °C, the average cell length was reduced to 6.4 μm and6.2 μm, respectively, which were ∼50% decreases com-pared to wild-type cells (13.0 μm and 12.9 μm). Similar tsresults were obtained for tor2 -19. It is of note that, in contrast to the reduced length, the cell width remained constant in these mutant cells.
PMID:17130122 FYPO:0003669 assayed using artificial reporter construct ura4 containing two introns and one exon from nda3
PMID:17130122 FYPO:0003669 assayed using artificial reporter construct ura4 containing two introns and one exon from nda3
PMID:17130122 FYPO:0003669 assayed using artificial reporter construct ura4 containing two introns and one exon from nda3
PMID:17130122 FYPO:0003669 assayed using artificial reporter construct ura4 containing two introns and one exon from nda3
PMID:17178839 PBO:0035373 fig 2 a/b
PMID:17178839 PBO:0035372 fig 2 a/b
PMID:17178839 FYPO:0005435 fig 3c
PMID:17178839 FYPO:0002060 fig 3C
PMID:17178839 PBO:0093580 fig 4A
PMID:17178839 PBO:0093616 fig 4A
PMID:17178839 PBO:0093630 fig 4A
PMID:17178839 PBO:0093586 fig 4A
PMID:17178839 PBO:0035375 fig 4B
PMID:17178839 PBO:0035376 fig 4B
PMID:17178839 PBO:0035377 fig 4C
PMID:17178839 FYPO:0002060 fig 3A
PMID:17178839 FYPO:0002060 fig 1A
PMID:17178839 FYPO:0002058 fig 1B
PMID:17178839 FYPO:0002061 fig 1B
PMID:17178839 FYPO:0002061 fig 3B
PMID:17178839 FYPO:0005437 Fig. 4D
PMID:17178839 FYPO:0002060 fig 1A
PMID:17178839 FYPO:0000671 not sure if this is correct....
PMID:17178839 FYPO:0000671 not sure if this is correct....
PMID:17178839 PBO:0035374 fig 2 a/b
PMID:17178839 FYPO:0003165 fig 1c/d
PMID:17178839 FYPO:0002060 fig 1A
PMID:17178839 FYPO:0002061 fig 1B
PMID:17178839 FYPO:0002061 fig 1B
PMID:17178839 FYPO:0002060 fig 1B
PMID:17190600 PBO:0111599 H4K20me2 modified histone binding
PMID:17190600 PBO:0111598 H4K20me2 modified histone binding
PMID:17190600 PBO:0111597 H4K20me2 modified histone binding
PMID:17192844 FYPO:0000488 The wildtype cross yielded 81 ± 7.5% viable spores, the pnu1Δ cross 82 ± 3%. As far as tested, no change of meiosis and recombination was detected in mutants abolishing the function of the Pnu1 (End1) nuclease.
PMID:17211518 FYPO:0002800 proteasomal
PMID:17213188 FYPO:0002926 binding by Pab2
PMID:17222800 FYPO:0003720 25S rRNA positions 2304, 2497
PMID:17276356 FYPO:0002321 However, similar to dap1D, yeast carrying the HA-dap1 Y138F plasmid accumulated 24-methylene lanosterol, ergosta-5,7,24(28)-trienol, and ergosta-5,7- dienol, reflecting defects in Erg11 and Erg5 (Figure 3B). These data indicate that dap1 Y138F is a loss-of-function mutation and that Dap1 function requires bound heme.
PMID:17276356 FYPO:0009071 sensitive to the inhibitors of sterol syn- thesis itraconazole and CoCl2 (Figure 1D).
PMID:17276356 FYPO:0000990 *******************elevated amounts of the ergosterol biosynthetic inter- mediates 2. upon loss of Dap1, cells accumulated 24-methylene lanosterol, ergosta- 5,7,24(28)-trienol, and ergosta-5,7-dienol, substrates for Erg11 and Erg5. 4-methylene lanosterol, ergosta-5,7,24(28)-tri- enol, and ergosta-5,7-dienol, Figure 1B. Ergo- sta-5,7-dienol is not a normal pathway intermediate, but forms when Erg5 is inhibited (Figure S1)
PMID:17276356 PBO:0092067 Expression of dap1+ mRNA was induced in the absence of oxygen in a Sre1-de- pendent manner (Figure 1A),
PMID:17276356 FYPO:0002060 dap1D cells were viable under normal growth con- ditions but .....
PMID:17276356 FYPO:0002321 ...contained a reduced amount of ergosterol and elevated amounts of the ergosterol biosynthetic inter- mediates 24-methylene lanosterol, ergosta-5,7,24(28)-tri- enol, and ergosta-5,7-dienol, consistent with defects at the Erg11 and Erg5 enzymatic steps (Figure 1B).
PMID:17276356 PBO:0112614 These data demonstrate that Dap1 is required in vivo for the activity of Erg11 and Erg5, the entire complement of cytochrome P450 enzymes in fission yeast.
PMID:17276356 PBO:0112615 These data demonstrate that Dap1 is required in vivo for the activity of Erg11 and Erg5, the entire complement of cytochrome P450 enzymes in fission yeast.
PMID:17276356 PBO:0112616 These data demonstrate that Dap1 is required in vivo for the activity of Erg11 and Erg5, the entire complement of cytochrome P450 enzymes in fission yeast.
PMID:17289569 PBO:0095651 6B
PMID:17289569 GO:0000183 by TGS
PMID:17289569 GO:0000183 by TGS
PMID:17289569 GO:0030466 by TGS
PMID:17289569 GO:0030466 by TGS
PMID:17289569 GO:0030466 by TGS
PMID:17289569 PBO:0100952 part of tgs
PMID:17289569 PBO:0100953 4B clr3 at telomeres were reduced to the same extent in mutant strains disrupted for either Ccq1 or Taz1,
PMID:17289569 PBO:0100953 4B clr3 at telomeres were reduced to the same extent in mutant strains disrupted for either Ccq1 or Taz1,
PMID:17289569 PBO:0100954 4B while the levels of Ccq1 at telomeres, relative to those in wild-type cells, were unchanged in clr3D cells but decreased in taz1D
PMID:17289569 PBO:0100955 4B while the levels of Ccq1 at telomeres, relative to those in wild-type cells, were unchanged in clr3D cells but decreased in taz1D
PMID:17289569 PBO:0100953 4B
PMID:17289569 PBO:0100956 4B We found that Clr3 localization at telomere ends was completely abolished in cells defective in both Taz1 and RNAi pathways.
PMID:17289569 PBO:0100955 4B However, defect in RNAi pathway had no impact on Ccq1 localization
PMID:17289569 PBO:0100952 part of tgs
PMID:17289569 PBO:0100957 (Figure 4C), Levels of Clr3 and Mit1 were dramati- cally reduced at subtelomeres in swi6 mutant strains
PMID:17289569 GO:0031509 by TGS
PMID:17289569 GO:0031509 by TGS
PMID:17289569 PBO:0100958 In contrast to hetero- chromatic loci, SHREC recruitment to euchromatic sites was unaffected in the absence of Swi6, as shown by Clr3 and Mit1 localization at a locus encoding a noncoding RNA and an intergenic region (Figure 4D).
PMID:17289569 PBO:0100959 In contrast to hetero- chromatic loci, SHREC recruitment to euchromatic sites was unaffected in the absence of Swi6, as shown by Clr3 and Mit1 localization at a locus encoding a noncoding RNA and an intergenic region (Figure 4D).
PMID:17289569 PBO:0094283 pericentromeric repeats, the silent mat locus, telo- meres, and rDNA loci were derepressed in strains lacking any individual core component of SHREC (Figure 5A).
PMID:17289569 PBO:0094283 pericentromeric repeats, the silent mat locus, telo- meres, and rDNA loci were derepressed in strains lacking any individual core component of SHREC (Figure 5A).
PMID:17289569 PBO:0094283 pericentromeric repeats, the silent mat locus, telo- meres, and rDNA loci were derepressed in strains lacking any individual core component of SHREC (Figure 5A).
PMID:17289569 PBO:0094283 pericentromeric repeats, the silent mat locus, telo- meres, and rDNA loci were derepressed in strains lacking any individual core component of SHREC (Figure 5A).
PMID:17289569 PBO:0095651 pericentromeric repeats, the silent mat locus, telo- meres, and rDNA loci were derepressed in strains lacking any individual core component of SHREC (Figure 5A).
PMID:17289569 PBO:0095651 pericentromeric repeats, the silent mat locus, telo- meres, and rDNA loci were derepressed in strains lacking any individual core component of SHREC (Figure 5A).
PMID:17289569 PBO:0095651 pericentromeric repeats, the silent mat locus, telo- meres, and rDNA loci were derepressed in strains lacking any individual core component of SHREC (Figure 5A).
PMID:17289569 PBO:0095651 pericentromeric repeats, the silent mat locus, telo- meres, and rDNA loci were derepressed in strains lacking any individual core component of SHREC (Figure 5A).
PMID:17289569 PBO:0094681 pericentromeric repeats, the silent mat locus, telo- meres, and rDNA loci were derepressed in strains lacking any individual core component of SHREC (Figure 5A).
PMID:17289569 PBO:0094681 pericentromeric repeats, the silent mat locus, telo- meres, and rDNA loci were derepressed in strains lacking any individual core component of SHREC (Figure 5A).
PMID:17289569 PBO:0094681 pericentromeric repeats, the silent mat locus, telo- meres, and rDNA loci were derepressed in strains lacking any individual core component of SHREC (Figure 5A).
PMID:17289569 PBO:0094681 pericentromeric repeats, the silent mat locus, telo- meres, and rDNA loci were derepressed in strains lacking any individual core component of SHREC (Figure 5A).
PMID:17289569 PBO:0100960 pericentromeric repeats, the silent mat locus, telo- meres, and rDNA loci were derepressed in strains lacking any individual core component of SHREC (Figure 5A).
PMID:17289569 PBO:0100960 pericentromeric repeats, the silent mat locus, telo- meres, and rDNA loci were derepressed in strains lacking any individual core component of SHREC (Figure 5A).
PMID:17289569 PBO:0100960 pericentromeric repeats, the silent mat locus, telo- meres, and rDNA loci were derepressed in strains lacking any individual core component of SHREC (Figure 5A).
PMID:17289569 PBO:0100960 pericentromeric repeats, the silent mat locus, telo- meres, and rDNA loci were derepressed in strains lacking any individual core component of SHREC (Figure 5A).
PMID:17289569 PBO:0094688 pericentromeric repeats, the silent mat locus, telo- meres, and rDNA loci were derepressed in strains lacking any individual core component of SHREC (Figure 5A).
PMID:17289569 FYPO:0000966 (Figure 5B) we found increases in H3K14ac levels and greater Pol II occupancy at the reporter embedded within pericentromeric heterochromatin in....strains lacking SHREC components
PMID:17289569 FYPO:0000966 (Figure 5B) we found increases in H3K14ac levels and greater Pol II occupancy at the reporter embedded within pericentromeric heterochromatin in....strains lacking SHREC components
PMID:17289569 FYPO:0000966 (Figure 5B) we found increases in H3K14ac levels and greater Pol II occupancy at the reporter embedded within pericentromeric heterochromatin in....strains lacking SHREC components
PMID:17289569 FYPO:0000966 (Figure 5B) we found increases in H3K14ac levels and greater Pol II occupancy at the reporter embedded within pericentromeric heterochromatin in....strains lacking SHREC components
PMID:17289569 PBO:0112083 (Figure 5B) we found increases in H3K14ac levels and greater Pol II occupancy at the reporter embedded within pericentromeric heterochromatin in....strains lacking SHREC components
PMID:17289569 PBO:0100962 The role of SHREC in transcriptional silencing could be decoupled from the cis-PTGS function of the RNAi machinery since impaired SHREC had no effect on the localization of RITS Agol subunit at heterochromatin (Figure 5D).
PMID:17289569 FYPO:0002836 (Figure 5E). Enhanced transcriptional-machinery occupancy at heterochromatic repeats in SHREC defective cells,..should result in elevated repeat transcripts ...corresponding increase in siRNA production.
PMID:17289569 FYPO:0002836 (Figure 5E). Enhanced transcriptional-machinery occupancy at heterochromatic repeats in SHREC defective cells,..should result in elevated repeat transcripts ...corresponding increase in siRNA production.
PMID:17289569 FYPO:0002836 (Figure 5E). Enhanced transcriptional-machinery occupancy at heterochromatic repeats in SHREC defective cells,..should result in elevated repeat transcripts ...corresponding increase in siRNA production.
PMID:17289569 FYPO:0002836 (Figure 5E). Enhanced transcriptional-machinery occupancy at heterochromatic repeats in SHREC defective cells,..should result in elevated repeat transcripts ...corresponding increase in siRNA production.
PMID:17289569 PBO:0094283 (Figure 6A) both clr3D232N and mit1K587A mutant alleles alleviated silencing of a marker gene inserted at pericentromeric repeats
PMID:17289569 PBO:0094283 (Figure 6A) both clr3D232N and mit1K587A mutant alleles alleviated silencing of a marker gene inserted at pericentromeric repeats
PMID:17289569 GO:0000183 by TGS
PMID:17289569 PBO:0095651 (Figure 6B)
PMID:17289569 PBO:0094681 6B
PMID:17289569 PBO:0094681 6B
PMID:17289569 GO:0031508 by TGS
PMID:17289569 FYPO:0003704 6D
PMID:17289569 FYPO:0001168 6D
PMID:17289569 FYPO:0000853 6E
PMID:17289569 GO:0031509 by TGS
PMID:17289569 GO:0030466 by TGS
PMID:17289569 GO:0000183 by TGS
PMID:17289569 GO:0031508 by TGS
PMID:17289569 GO:0031508 by TGS
PMID:17289569 GO:0031508 by TGS
PMID:17289569 GO:0031509 by TGS
PMID:17304215 PBO:0111973 (Figure 1B) The absence of Swi2 or Sfr1 did not affect the cellular expression level of the Swi5-EGFP protein .
PMID:17304215 PBO:0111973 (Figure 1B) The absence of Swi2 or Sfr1 did not affect the cellular expression level of the Swi5-EGFP protein .
PMID:17304215 GO:0005634 (Figure 1A) In normally growing cells, Swi5-EGFP localized to the nucleus and exhibited diffuse nuclear staining with a few distinct foci
PMID:17304215 GO:0005634 Figure 2A
PMID:17304215 PBO:0111971 On the other hand, the nuclei of sfr1D cells contained Swi5-EGFP foci,
PMID:17304223 FYPO:0005165 foci disappear in HU; without HU foci appear but with abnormal dynamics
PMID:17304223 FYPO:0005165 foci disappear in HU; without HU foci appear but with abnormal dynamics
PMID:17307401 PBO:0093560 worse than either single mutant
PMID:17307401 PBO:0093629 worse than either single mutant
PMID:17307401 PBO:0093580 same as mus81delta alone
PMID:17307401 PBO:0093613 same as mus81delta alone
PMID:17307401 PBO:0093616 same as mus81delta alone
PMID:17307401 PBO:0093630 same as mus81delta alone
PMID:17307401 PBO:0093580 worse than either single mutant
PMID:17307401 PBO:0093613 worse than either single mutant
PMID:17307401 PBO:0093616 worse than either single mutant
PMID:17307401 PBO:0093613 worse than either single mutant
PMID:17307401 PBO:0093629 worse than either single mutant
PMID:17307401 PBO:0093616 worse than either single mutant
PMID:17310250 FYPO:0004743 Fig. 6A
PMID:17310250 PBO:0112834 Fig. 6A
PMID:17310250 PBO:0112834 Fig. 6A
PMID:17310250 PBO:0112833 Fig. 6A
PMID:17310250 PBO:0112832 Fig. 6A
PMID:17310250 FYPO:0004743 Fig. 6A
PMID:17310250 PBO:0098773 Fig. 6A
PMID:17310250 PBO:0098760 Fig. 6A
PMID:17310250 PBO:0112831 Fig. 6A
PMID:17310250 PBO:0112830 Fig. 6A
PMID:17310250 PBO:0112830 Fig. 6A
PMID:17310250 PBO:0112830 Fig. 6A
PMID:17310250 PBO:0112829 These results indicate that the slicer activity of Ago1 is required for the in vivo conversion of double-stranded siRNA to single-stranded siRNA
PMID:17310250 PBO:0104710 Fig. 5B
PMID:17310250 PBO:0105770 Fig. 5B
PMID:17310250 PBO:0104710 Fig. 5B
PMID:17310250 FYPO:0004201 Fig. 5C
PMID:17310250 FYPO:0004201 Fig. 5C
PMID:17310250 FYPO:0006992 Fig. 5B
PMID:17310250 PBO:0112828 Nonetheless Arb1, by itself and/or together with Arb2, is a direct inhibitor of the slicer activity of fission yeast Ago1. Fig. 4D
PMID:17310250 GO:0005737 Fig. 3A
PMID:17310250 GO:0005634 Fig. 3A
PMID:17310250 GO:0005721 Fig. 2E
PMID:17310250 GO:0005721 Fig. 2D and E
PMID:17310250 FYPO:0002835 Fig. 2C
PMID:17310250 PBO:0105770 Fig. 1C
PMID:17310250 PBO:0105770 Fig. 1C
PMID:17310250 PBO:0112827 Fig. 1D
PMID:17310250 PBO:0095652 Fig. 1C
PMID:17310250 PBO:0098773 Fig. 1D
PMID:17310250 PBO:0098773 Fig. 1D
PMID:17310250 PBO:0095652 Fig. 1C
PMID:17310250 PBO:0105770 Fig. 1C
PMID:17310250 PBO:0112827 Fig. 1D
PMID:17317928 FYPO:0003075 assayed substrate: myelin basic protein; assayed enzyme is, or is bound to, Pmo25
PMID:17317928 FYPO:0001382 assayed substrate: myelin basic protein; assayed enzyme is, or is bound to, Pmo25
PMID:17317928 FYPO:0002700 assayed substrate: myelin basic protein; assayed enzyme is, or is bound to, Pmo25
PMID:17317928 FYPO:0002700 assayed substrate: myelin basic protein; assayed enzyme is, or is bound to, Pmo25
PMID:17317928 FYPO:0002700 assayed substrate: myelin basic protein; assayed enzyme is, or is bound to, Pmo25
PMID:17317928 FYPO:0001382 assayed substrate: myelin basic protein; assayed enzyme is, or is bound to, Pmo25
PMID:17339332 GO:0006357 same pathway
PMID:17352737 FYPO:0004439 anaphase, elongating beyond cell end resulting in long curved spindle, requested
PMID:17363370 FYPO:0006299 figur 2d rhp6 resulted in enhanced silencing of the otr1::ura4, as shown by reduced growth on medium lacking uracil (Fig. 2D)
PMID:17363370 GO:0033503 Fig. 1C
PMID:17363370 GO:0033503 Fig. 1C
PMID:17363370 GO:0033503 Fig. 1C
PMID:17363370 GO:0033503 Fig. 1C
PMID:17363370 PBO:0020446 Fig 1D
PMID:17363370 PBO:0020446 Fig 1D
PMID:17363370 PBO:0020446 Fig 1D
PMID:17363370 PBO:0020446 Fig 1D
PMID:17363370 PBO:0020446 Fig 1D
PMID:17363370 PBO:0107145 HULC revealed that slower migrating band representing ubH2B was missing in cells lacking either Bre1 homologs (i.e. Rfp1 or Rfp2) or Shf1. These analyses suggest that components of HULC are required for ubiquitination of H2B.
PMID:17363370 PBO:0107145 HULC revealed that slower migrating band representing ubH2B was missing in cells lacking either Bre1 homologs (i.e. Rfp1 or Rfp2) or Shf1. These analyses suggest that components of HULC are required for ubiquitination of H2B.
PMID:17363370 FYPO:0002922 figur 2b
PMID:17363370 FYPO:0002922 figur 2b
PMID:17363370 FYPO:0002922 figur 2b
PMID:17363370 FYPO:0002922 figur 2b
PMID:17363370 FYPO:0002922 figur 2b
PMID:17363370 FYPO:0006299 figur 2d rhp6 resulted in enhanced silencing of the otr1::ura4, as shown by reduced growth on medium lacking uracil (Fig. 2D)
PMID:17363370 FYPO:0006299 figur 2d rhp6 resulted in enhanced silencing of the otr1::ura4, as shown by reduced growth on medium lacking uracil (Fig. 2D)
PMID:17363370 FYPO:0006299 figur 2d rhp6 resulted in enhanced silencing of the otr1::ura4, as shown by reduced growth on medium lacking uracil (Fig. 2D)
PMID:17363370 FYPO:0007334 Overexpression of Rhp6 abro- gates silencing of the otr1::ura4 reporter, resulting in the loss of cell viability on medium supple- mented with FOA (Fig. 3A
PMID:17363370 FYPO:0007844 Interestingly, levels of trim- ethylated H3K9 (H3K9me3) were significantly reduced, although the levels of monomethylated H3K9 (H3K9me1) were increased at the dg repeat element and otr1::ura4 (Fig. 3B).
PMID:17363370 PBO:0107146 Interestingly, levels of trim- ethylated H3K9 (H3K9me3) were significantly reduced, although the levels of monomethylated H3K9 (H3K9me1) were increased at the dg repeat element and otr1::ura4 (Fig. 3B).
PMID:17363370 FYPO:0007843 (supplemental Fig. 2
PMID:17363370 FYPO:0002360 Fig. 4, A and B
PMID:17363370 PBO:0107147 Fig. 4, A and B
PMID:17363370 FYPO:0002360 Fig. 4, A and B
PMID:17363370 PBO:0107147 Fig. 4, A and B
PMID:17363370 FYPO:0002360 Fig. 4, A and B
PMID:17363370 PBO:0107147 Fig. 4, A and B
PMID:17363370 FYPO:0005071 Interestingly, the H2B-K119R mutation sig- nificantly enhanced silencing of the otr1::ura4 (Fig. 5A),
PMID:17363370 PBO:0107148 fig 5D
PMID:17363370 PBO:0107149 fig 5D
PMID:17369611 PBO:0111587 However, H3-K56R, rtt109Δ, and the H3-K56R/rtt109Δ mutant cells formed colonies of variable pink indicating a slight decrease in silencing at centromeres (Fig. 4A). This might indicate a cross-talk of H3 Lys-56-Ac with the establishment or the maintenance of other activating or repressing histone modifications required for proper centromeric heterochromatin formation.
PMID:17434129 FYPO:0007508 TEL2L only
PMID:17434129 FYPO:0002061 data not shown
PMID:17434129 FYPO:0002061 data not shown
PMID:17434129 PBO:0107043 TEL2L only
PMID:17434129 GO:0006338 also from localization and phenotypes
PMID:17434129 PBO:0100344 TEL2L only
PMID:17434129 GO:0006338 also from localization and phenotypes
PMID:17440621 PBO:0108790 they only show that this is part of a complex that demethylates H3K9 so there is a chance it is not active?
PMID:17442892 FYPO:0002638 inferred from the fact growth is impaired in the double mutatn spc7-23/mad2 OR spc7-23/mph1 are growth impaired, so assumption is that spindle checkpoint is active in mutant
PMID:17450151 FYPO:0005523 bulk antisense transcripts
PMID:17450151 FYPO:0005315 bulk antisense transcripts
PMID:17450151 FYPO:0000887 bulk antisense transcripts
PMID:17450151 FYPO:0006361 bulk antisense transcripts
PMID:17450151 FYPO:0006987 bulk antisense transcripts
PMID:17450151 FYPO:0003547 bulk antisense transcripts
PMID:17450151 FYPO:0000888 bulk antisense transcripts
PMID:17450151 FYPO:0004137 bulk antisense transcripts
PMID:17450151 FYPO:0002355 bulk antisense transcripts
PMID:17450151 PBO:0095841 sense strand
PMID:17450151 PBO:0095840 sense strand
PMID:17450151 FYPO:0003557 bulk antisense transcripts
PMID:17452352 PBO:0099040 fig6
PMID:17452352 PBO:0099050 5d
PMID:17452352 PBO:0099055 5d
PMID:17452352 PBO:0099052 5d
PMID:17452352 PBO:0102188 fig7
PMID:17452352 PBO:0102186 fig7
PMID:17452352 PBO:0102189 fig7
PMID:17452352 PBO:0102186 fig7
PMID:17452352 PBO:0102188 fig7
PMID:17452352 PBO:0102190 fig7
PMID:17452352 PBO:0102191 fig7
PMID:17452352 PBO:0102187 fig7
PMID:17452352 PBO:0102193 "chromatin binding shown, and regulation of transcription shown. no evidence for dna binding BUT later paper by akayama and Toda state that "" Ams2 directly binds a consensus ""AACCCT-box"" that exists in the 5' franking regions of these histone genes."" and says that ams2 is sole responsible TF + cites this paper."
PMID:17452352 PBO:0102192 "chromatin binding shown, and regulation of transcription shown. no evidence for dna binding BUT later paper by akayama and Toda state that "" Ams2 directly binds a consensus ""AACCCT-box"" that exists in the 5' franking regions of these histone genes."" and says that ams2 is sole responsible TF + cites this paper."
PMID:17452352 PBO:0102191 fig7
PMID:17452352 PBO:0102187 fig7
PMID:17452352 PBO:0102190 fig7
PMID:17452352 PBO:0102189 fig7
PMID:17452352 PBO:0099054 5d
PMID:17452352 PBO:0099050 5c
PMID:17452352 PBO:0099041 fig6
PMID:17452352 PBO:0099039 fig6
PMID:17452352 PBO:0099042 fig6
PMID:17452352 PBO:0099053 5d
PMID:17452352 PBO:0102187 5a
PMID:17452352 PBO:0102186 5a
PMID:17452352 GO:0045944 bet this is a term Val hates :p
PMID:17452352 PBO:0099055 5c
PMID:17452352 PBO:0099054 5c
PMID:17452352 PBO:0099053 5c
PMID:17452352 PBO:0099052 5c
PMID:17452352 PBO:0099051 5c
PMID:17452352 PBO:0099051 5d
PMID:17452625 GO:1904530 regulates binding by myosin; assayed in vitro using rabbit actin and unspecified myosin motor domain
PMID:17486116 FYPO:0002638 assayed using bub1
PMID:17510629 FYPO:0007656 Hence, from these results it was evident that Hrp1, Hrp3 and Nap1 occupancy in vivo generally correlated with increased nucleosome densities in the corresponding mutants, and that this effect was most pronounced in promoter regions.
PMID:17510629 FYPO:0007656 Hence, from these results it was evident that Hrp1, Hrp3 and Nap1 occupancy in vivo generally correlated with increased nucleosome densities in the corresponding mutants, and that this effect was most pronounced in promoter regions.
PMID:17510629 FYPO:0007656 Hence, from these results it was evident that Hrp1, Hrp3 and Nap1 occupancy in vivo generally correlated with increased nucleosome densities in the corresponding mutants, and that this effect was most pronounced in promoter regions.
PMID:17512405 PBO:0110926 Surprisingly, in cid14D cells, neither Chp1 nor Swi6 binding was signifi- cantly reduced at several heterochromatic loci, includ- ing mat3M::ura4+, imr1R::ura4+, the subtelomeric tlh1+ gene, and cen-dg and cen-dh repeats, as assayed by chromatin immunoprecipitation experiments (ChIP) (Fig- ures 3A and 3B).
PMID:17512405 PBO:0105941 Like cid14D, Cid14 active site mutations had dramatically reduced centromeric siRNA levels (Fig- ure 6D),
PMID:17512405 PBO:0105941 While we were not able to detect any centromeric siRNAs in cid12D cells, centromeric siRNAs were about 22-fold reduced in cid14D compared to wild-type cells (Figure 6B). and However, centromeric siRNAs from cid14D were barely detectable on total RNA northern blots (Figure 6A).
PMID:17512405 FYPO:0007334 Loss of imr1R::ura4+ and mat3M::ura4+ silencing in cid14D cells could be rescued by overexpressing Cid14wt (pRep- Cid14) but not by Cid14DADA (pRep-Cid14DADA) (Fig- ure 5F).
PMID:17512405 GO:0033895 In order to directly determine whether Cid14 is a bona fide poly(A) polymerase, we assayed recombinant wild-type or mutant Cid14 (GST-Cid14wt or GST-Cid14DADA, respec- tively; Figure 5A) for polyadenylation activity in vitro and found that wild-type Cid14 was able to extend a synthetic oligo(A)15 RNAno ac- tivity was detected in the presence of pyrimidines (CTP or UTP) (Figure 5D).
PMID:17512405 PBO:0110936 Importantly, Cid14 activity was completely abolished in Cid14DADA (Figure 5B)
PMID:17512405 GO:1990817 In order to directly determine whether Cid14 is a bona fide poly(A) polymerase, we assayed recombinant wild-type or mutant Cid14 (GST-Cid14wt or GST-Cid14DADA, respec- tively; Figure 5A) for polyadenylation activity in vitro and found that wild-type Cid14 was able to extend a synthetic oligo(A)15 RNA but not an oligo(dA)15 DNA substrate (Figures 5B, 5C, and 5E).
PMID:17512405 PBO:0110935 we observed a 3-fold increase in tlh1+ RNA levels in dcr1D cells and a 10-fold increase in mtr4-1 cells (Figures 4F and 4H), indicating that both RNAi and TRAMP contribute to the full silencing of this subtelomeric gene.
PMID:17512405 PBO:0110935 we observed a 3-fold increase in tlh1+ RNA levels in dcr1D cells and a 10-fold increase in mtr4-1 cells (Figures 4F and 4H), indicating that both RNAi and TRAMP contribute to the full silencing of this subtelomeric gene.
PMID:17512405 PBO:0110934 we observed 7-fold and a 25-fold increases in tlh1+ transcript levels in rrp6D and dis3-54 cells, respectively, and 33- and 100- fold increases in cid14D and clr4D cells, respectively (Figures 4G and S3)
PMID:17512405 PBO:0110934 we observed 7-fold and a 25-fold increases in tlh1+ transcript levels in rrp6D and dis3-54 cells, respectively, and 33- and 100- fold increases in cid14D and clr4D cells, respectively (Figures 4G and S3)
PMID:17512405 PBO:0110933 we observed 7-fold and a 25-fold increases in tlh1+ transcript levels in rrp6D and dis3-54 cells, respectively, and 33- and 100- fold increases in cid14D and clr4D cells, respectively (Figures 4G and S3)
PMID:17512405 FYPO:0004604 we observed 7-fold and a 25-fold increases in tlh1+ transcript levels in rrp6D and dis3-54 cells, respectively, and 33- and 100- fold increases in cid14D and clr4D cells, respectively (Figures 4G and S3)
PMID:17512405 FYPO:0002834 figure 2 &4
PMID:17512405 FYPO:0002834 figure 2 &4
PMID:17512405 FYPO:0002834 figure 2 &4
PMID:17512405 PBO:0110932 Consistent with a role for the exosome in degrad- ing heterochromatic ura4+ transcripts, we observed elevated ura4+ transcript levels in rrp6D compared to wild-type cells (Figures 4C–4E).
PMID:17512405 FYPO:0007336 However, we observed loss of silencing of mat3M:::ura4+ in cells carrying a hypomorphic allele of mtr4+ (mtr4-1, Figures 4F and 4H), suggesting the involvement of a TRAMP-like complex.
PMID:17512405 FYPO:0002335 We found that the deletion of air1+ had no effect on heterochromatic gene silencing (Figure S2
PMID:17512405 GO:0031499 Cid14 copurified with two proteins that are homologs of Mtr4 and Air1 (Figures 4A and 4B). Thus, like Trf4 in S. cerevisiae, Cid14 is found in a complex together with Air1 and Mtr4, which we refer to as spTRAMP (S. pombe TRAMP).
PMID:17512405 GO:0031499 Cid14 copurified with two proteins that are homologs of Mtr4 and Air1 (Figures 4A and 4B). Thus, like Trf4 in S. cerevisiae, Cid14 is found in a complex together with Air1 and Mtr4, which we refer to as spTRAMP (S. pombe TRAMP).
PMID:17512405 GO:0031499 Cid14 copurified with two proteins that are homologs of Mtr4 and Air1 (Figures 4A and 4B). Thus, like Trf4 in S. cerevisiae, Cid14 is found in a complex together with Air1 and Mtr4, which we refer to as spTRAMP (S. pombe TRAMP).
PMID:17512405 PBO:0110931 Furthermore, consistent with a CTGS model for silencing of mat3M::ura4+, none of the tested mutants af- fected RNApII occupancy at this locus (Figure 3C).
PMID:17512405 PBO:0110930 In addition, while H3K9 methylation was lost in clr4D cells, only a slight reduction in H3K9 methylation was observed in cid14D cells (Figures 3A and 3B)
PMID:17512405 PBO:0110929 Surprisingly, in cid14D cells, neither Chp1 nor Swi6 binding was signifi- cantly reduced at several heterochromatic loci, includ- ing mat3M::ura4+, imr1R::ura4+, the subtelomeric tlh1+ gene, and cen-dg and cen-dh repeats, as assayed by chromatin immunoprecipitation experiments (ChIP) (Fig- ures 3A and 3B).
PMID:17512405 PBO:0110928 Surprisingly, in cid14D cells, neither Chp1 nor Swi6 binding was signifi- cantly reduced at several heterochromatic loci, includ- ing mat3M::ura4+, imr1R::ura4+, the subtelomeric tlh1+ gene, and cen-dg and cen-dh repeats, as assayed by chromatin immunoprecipitation experiments (ChIP) (Fig- ures 3A and 3B).
PMID:17512405 PBO:0110927 Surprisingly, in cid14D cells, neither Chp1 nor Swi6 binding was signifi- cantly reduced at several heterochromatic loci, includ- ing mat3M::ura4+, imr1R::ura4+, the subtelomeric tlh1+ gene, and cen-dg and cen-dh repeats, as assayed by chromatin immunoprecipitation experiments (ChIP) (Fig- ures 3A and 3B).
PMID:17512405 PBO:0110925 Surprisingly, in cid14D cells, neither Chp1 nor Swi6 binding was signifi- cantly reduced at several heterochromatic loci, includ- ing mat3M::ura4+, imr1R::ura4+, the subtelomeric tlh1+ gene, and cen-dg and cen-dh repeats, as assayed by chromatin immunoprecipitation experiments (ChIP) (Fig- ures 3A and 3B).
PMID:17512405 PBO:0110924 Surprisingly, in cid14D cells, neither Chp1 nor Swi6 binding was signifi- cantly reduced at several heterochromatic loci, includ- ing mat3M::ura4+, imr1R::ura4+, the subtelomeric tlh1+ gene, and cen-dg and cen-dh repeats, as assayed by chromatin immunoprecipitation experiments (ChIP) (Fig- ures 3A and 3B).
PMID:17512405 FYPO:0006995 Finally, deletion of the other four members of the fission yeast Cid14/Trf4/5 poly(A) polymerase family did not affect silencing of an imr1R::ura4+ reporter gene (Figure 2H).
PMID:17512405 FYPO:0006995 Finally, deletion of the other four members of the fission yeast Cid14/Trf4/5 poly(A) polymerase family did not affect silencing of an imr1R::ura4+ reporter gene (Figure 2H).
PMID:17512405 FYPO:0006995 Finally, deletion of the other four members of the fission yeast Cid14/Trf4/5 poly(A) polymerase family did not affect silencing of an imr1R::ura4+ reporter gene (Figure 2H).
PMID:17512405 FYPO:0006995 Finally, deletion of the other four members of the fission yeast Cid14/Trf4/5 poly(A) polymerase family did not affect silencing of an imr1R::ura4+ reporter gene (Figure 2H).
PMID:17512405 FYPO:0007336 We found that deletion of cid14+ resulted in a complete loss of ura4+ silencing at all the tested loci as assayed by growth on 5-FOA-containing medium (Figures 2A–2C).
PMID:17512405 FYPO:0007335 We found that deletion of cid14+ resulted in a complete loss of ura4+ silencing at all the tested loci as assayed by growth on 5-FOA-containing medium (Figures 2A–2C).
PMID:17512405 FYPO:0007334 We found that deletion of cid14+ resulted in a complete loss of ura4+ silencing at all the tested loci as assayed by growth on 5-FOA-containing medium (Figures 2A–2C).
PMID:17512405 PBO:0111106 Quantification of the signals revealed that Ago1 contained about 3-fold more antisense than sense ura4+ siRNAs. etc....(figure 1)
PMID:17531813 PBO:0108410 The same experiment was repeated, but HU was added at the time of release, allowing cells to progress through mitosis and stall after initiation of DNA replication. In that case, Cdc2 tyrosine 15 phosphorylation reappeared after 100 min and increased further with time. Cig2 remained present at a high level, indicating that the Cdc2-Cig2 com- plex was inhibited (Figure 5B)
PMID:17531813 PBO:0092600 2A
PMID:17531813 PBO:0092600 2A; during mitotic DNA replication checkpoint
PMID:17531813 PBO:0108409 Fig 1C
PMID:17531813 PBO:0108406 Fig 6B
PMID:17531813 PBO:0094961 Fig 6B
PMID:17531813 PBO:0108405 Fig 6 B
PMID:17531813 PBO:0108404 Fig 5B
PMID:17531813 PBO:0105277 Fig 5B
PMID:17531813 PBO:0108403 Fig5A cdc18 disappears at the end of S-phase in cig2+ strain and accumulates in the absence of cig2
PMID:17531813 PBO:0108402 Fig 4D In the absence of rad26, cdc18 is unable to stabilise rad3 on chromatin
PMID:17531813 PBO:0108401 Fig 4A
PMID:17531813 PBO:0108400 Fig 4A
PMID:17531813 PBO:0108399 Fig 4 A
PMID:17531813 PBO:0108399 Fig 4 A
PMID:17531813 PBO:0108398 Fig3 top 2 two panels (ve jacky syuggested Presence of stalled replication forks after DNA checkpoint inactivation, i just used normal initiation Figure 3. Replication Structures Are Not Lost When Cdc18 Is Depleted)
PMID:17531813 PBO:0108397 Figure 2D top of lower panel.
PMID:17531813 PBO:0108396 Figure 2C lower panel. cds1 is no longer phosphorylated because rad3 is absent in absence of cdc18
PMID:17531813 PBO:0108395 Figure 2B upper right panel. In the cytosol rad3 is present in absence of cdc18
PMID:17531813 PBO:0108394 Figure 2B lower right panel. rad3 is not present in the chromatin fraction in the absence of cdc18
PMID:17531813 PBO:0108392 Fig 1C
PMID:17531813 PBO:0108392 Fig 1C
PMID:17531813 PBO:0108393 Fig 1C (vw data not shown, but assume are elongated)
PMID:17531813 PBO:0098712 Fig 1C
PMID:17531813 PBO:0108392 Fig 1B
PMID:17531813 PBO:0108392 Fig 1B
PMID:17531816 PBO:0101406 ......as were Chp1 and the mutant Tas3WG protein (Figure 2C).
PMID:17531816 PBO:0101401 We have previously demonstrated that Tas3 binds directly to Chp1 (Petrie et al., 2005). In addition, Tas3 binds to Ago1 and this interaction is independent of Chp1 (Figure 1A). Thus, Tas3 forms a bridge linking the Chp1 chromodomain protein to Ago1.
PMID:17531816 PBO:0094679 (dg repeat) Centromeric transcripts were only marginally elevated in tas3WG cells, in marked contrast to the 10- to 20-fold accumulation of transcripts in tas3-, dcr1-, or ago1-null cells (Figure 2B).
PMID:17531816 FYPO:0001513 Consistent with these findings, tas3WG mutant cells showed no defects in chromosome segregation (Table S2).
PMID:17531816 PBO:0101405 Chromatin immunoprecipitation (ChIP) analyses showed that Ago1 was indeed localized at centromeres in the tas3WG mutant, a
PMID:17531816 FYPO:0002837 Further, centromeric siRNAs were similarly abundant in tas3WG and tas3+ cells (Figure 2D).
PMID:17531816 PBO:0101407 ......as were Chp1 and the mutant Tas3WG protein (Figure 2C).
PMID:17531816 PBO:0094679 F276A-ago1 (Figure S3B) caused a slight defect in silencing of the dg cen::ura4+ reporter (Figure S3C).
PMID:17531816 PBO:0094684 the double mutant (tas3WG, F276Aago1) displayed markedly elevated levels of total centromeric transcripts (Figure 2E), similar to an ago1 null.
PMID:17531816 FYPO:0006076 centromeric siRNAs were present in the F276Aago1 and tas3WG single mutants but were undetectable in the double mutant (Figure 2F).
PMID:17531816 FYPO:0003241 centromeric siRNAs were present in the F276Aago1 and tas3WG single mutants but were undetectable in the double mutant (Figure 2F).
PMID:17531816 GO:0031508 ESTABLISHMENT. The reestablishmentof centromeric heterochromatin was then monitored after reintroduction of clr4+. Addition of clr4+to tas3+ cells allowed efficient establishment of heterochromatinand silencing of the cen::ura4+ transgene atdg (Figure 3A). In marked contrast, on reintroduction ofclr4+, cells expressing tas3WG failed to silence the cen::ura4+ reporter
PMID:17531816 FYPO:0003098 Tas3WG Cells Cannot Efficiently Establish De Novo Centromeric Heterochromatin
PMID:17531816 FYPO:0004744 Tas3WG Cells Cannot Efficiently Establish De Novo Centromeric Heterochromatin
PMID:17538026 FYPO:0002060 fig1 a
PMID:17538026 FYPO:0002061 fig1a
PMID:17538026 PBO:0102471 fig 6 B
PMID:17538026 PBO:0102471 fig 6 B
PMID:17538026 PBO:0102470 fig 4
PMID:17538026 PBO:0102469 fig 4
PMID:17538026 PBO:0102469 fig 4
PMID:17538026 FYPO:0002061 table 2
PMID:17538026 FYPO:0002061 table 2
PMID:17538026 FYPO:0002060 fig1 a
PMID:17538026 FYPO:0002060 fig1 a
PMID:17538026 PBO:0033837 figure 3, B and D
PMID:17538026 GO:0005730 igure 3, B and D
PMID:17538026 GO:0005730 fig 3a
PMID:17538026 FYPO:0004506 fig1 B
PMID:17538026 FYPO:0004506 fig1 B
PMID:17538026 PBO:0037119 fig1 2
PMID:17538026 PBO:0037118 fig1 2
PMID:17556368 PBO:0096992 add note in curator feedback to get double mutant phenotypes
PMID:17556368 PBO:0096993 add note in curator feedback to get double mutant phenotypes
PMID:17556368 PBO:0096990 add note in curator feedback to get double mutant phenotypes
PMID:17556368 PBO:0096991 add note in curator feedback to get double mutant phenotypes
PMID:17561805 FYPO:0002638 tested through observing no de;ay when checkpoin is inactivated
PMID:17579515 FYPO:0004396 Figure S4)
PMID:17579515 FYPO:0003787 Figure 2 C check (also nuclear envelope protrusion?
PMID:17579515 FYPO:0001734 Figure 3A and 3B, and Video S3)
PMID:17579515 PBO:0096904 (Figure 1).
PMID:17579515 PBO:0096905 4G
PMID:17579515 PBO:0096906 Figure 6C
PMID:17579515 PBO:0033900 Figure 6C (ablated Nuclear envelope)
PMID:17579515 FYPO:0002061 S1
PMID:17579515 FYPO:0000619 (APC) activation occurred and chromosome cohesion was lost (Figure 1A and 1B).
PMID:17579515 FYPO:0004536 (APC) activation occurred and chromosome cohesion was lost (Figure 1A and 1B).
PMID:17579515 FYPO:0005380 Figure S4 /Figure 3A and 3B, and Video S3)
PMID:17596513 PBO:0112601 E. coli ispA mutant used as assay system
PMID:17596513 GO:0004161 E. coli ispA mutant used as assay system
PMID:17632059 PBO:0096126 fig s4e movie S2
PMID:17632059 FYPO:0002890 S3
PMID:17632059 FYPO:0000927 S3
PMID:17632059 FYPO:0000927 S3
PMID:17632059 FYPO:0000927 S3
PMID:17632059 FYPO:0002890 S3
PMID:17632059 FYPO:0003835 S3
PMID:17632059 FYPO:0003835 S3
PMID:17632059 PBO:0096125 table S3
PMID:17632059 PBO:0096124 table S3
PMID:17632059 PBO:0096123 table S3
PMID:17632059 PBO:0096122 table S3
PMID:17632059 PBO:0096121 fig3D
PMID:17632059 PBO:0096120 fig3
PMID:17632059 PBO:0096119 fig3 V-shaped patterns indicating multiple spindles
PMID:17632059 PBO:0096118 fig3
PMID:17632059 PBO:0096117 fig3
PMID:17632059 FYPO:0006363 fig3
PMID:17632059 FYPO:0006389 In taz1Dlig4D zygotes, SPBs move normally during the horsetail stage even though they are rarely associated with chromatin. However, as the horsetail stage ends and meiosis I begins, the Pcp1-GFP signals appear brighter than in WT cells and are markedly disorganized (Figure 2B; 75 min
PMID:17632059 FYPO:0000485 Fig 1c
PMID:17632059 FYPO:0000485 Fig 1c
PMID:17632059 FYPO:0000485 Fig 1c
PMID:17632059 PBO:0096111 fig1B
PMID:17632059 PBO:0096110 fig1B
PMID:17632059 PBO:0096109 fig1B
PMID:17632059 PBO:0096108 fig1B
PMID:17632059 PBO:0096107 fig1c
PMID:17632059 PBO:0096106 fig1b
PMID:17632059 PBO:0096103 fig1B
PMID:17632059 PBO:0096104 fig1B
PMID:17632059 PBO:0096105 fig1b
PMID:17632059 PBO:0096104 fig1B
PMID:17632059 PBO:0096103 fig1B
PMID:17632059 PBO:0096102 fig1B
PMID:17632059 FYPO:0006383 fig1f
PMID:17632059 FYPO:0000681 fig1e twice their share of DNA and SPBs.
PMID:17632059 PBO:0096101 fig1c
PMID:17632059 FYPO:0000681 fig1c
PMID:17632059 FYPO:0004077 fig1b
PMID:17632059 PBO:0096131 fig3D (I)
PMID:17632059 PBO:0096130 table S3
PMID:17632059 FYPO:0006365 Matching synonym SPB detached from nucleuss fix syn
PMID:17677001 PBO:0100885 Figure 4B
PMID:17677001 PBO:0095962 Figure 4C
PMID:17677001 PBO:0100886 Figure S8
PMID:17677001 FYPO:0003217 Figure 2A
PMID:17677001 PBO:0100883 Figure 3B
PMID:17677001 PBO:0100879 Figure 2B
PMID:17677001 PBO:0100881 Figure 2B
PMID:17677001 FYPO:0003217 Figure 2A
PMID:17677001 PBO:0100881 Figure 2B
PMID:17677001 PBO:0100880 Figure 2B
PMID:17677001 PBO:0100882 Figure 2B
PMID:17677001 PBO:0100881 Figure 2B
PMID:17677001 PBO:0100880 Figure 2B
PMID:17677001 FYPO:0003217 Figure 2A
PMID:17677001 PBO:0100882 Figure 2B
PMID:17677001 PBO:0100881 Figure 2B
PMID:17677001 PBO:0100880 Figure 2B
PMID:17677001 PBO:0100879 Figure 2B
PMID:17677001 PBO:0100879 Figure 2B
PMID:17677001 GO:0061638 Figure S1
PMID:17677001 PBO:0100882 Figure 2B
PMID:17677001 PBO:0100880 Figure 2B
PMID:17677001 PBO:0100882 Figure 2B
PMID:17677001 FYPO:0004331 Figure 3A EXP says increased, but is normal compared to WT (i.e ura4 insertion derepresses)
PMID:17677001 PBO:0100879 Figure 2B
PMID:17677001 PBO:0100884 Figure 3C spreading is still within the central domain, to the flanking tRNAs
PMID:17690116 PBO:0102115 Fig1C rad3ts cells over expressing the mutated pREP4X-cdc18 construct do not rereplicate at 25°C or 36°C (the permissive and non permissive temperatures for rad3ts). This is in contrast to Control cells expressing cdc18+ from pREP3X promoter at 32°C (Fig1D , Table 2) which don't activate the mitotic DNA checkpoint and undergo DNA re-replicatiom
PMID:17690116 PBO:0102117 Fig2 A,C cells arrested due to activation of the rad3 (permissive temperature) have normal nuclear to cell size ratio (NC ratio) compared to cdc25-22 at restrictive temp 2 hr
PMID:17690116 PBO:0102123 Fig6A,B
PMID:17690116 PBO:0102119 Fig4A
PMID:17690116 PBO:0019114 Fig4C At the permissive temperature 25*C rad3 is active but checkpoint cannot be activated in absence of chk1
PMID:17690116 PBO:0019114 Fig4C At 25°C rad3 is active but checkpoint cannot be activated in absence of rad9
PMID:17690116 PBO:0019114 Fig4C At 25°C rad3 is active but checkpoint cannot be activated in absence of rad17
PMID:17690116 PBO:0102114 Fig1B At 25°C the permissive temperature rad3ts the checkpoint is active and cells expressing the mutant form of pREP4X cdc18 from the screen elongate
PMID:17690116 PBO:0102115 Fig1C rad3ts cells over expressing the mutated pREP4X-cdc18 construct do not rereplicate at 25°C or 36°C (the permissive and non permissive temperatures for rad3ts). This is in contrast to Control cells expressing cdc18+ from pREP3X promoter at 32°C (Fig1D , Table 2) which don't activate the mitotic DNA checkpoint and undergo DNA re-replicatiom
PMID:17690116 PBO:0102116 Fig 2A cdc18T6A expression at 25°C causes cell elongation due to activation of the mitotic DNA replication checkpoint ( permissive temperature for rad3ts)
PMID:17690116 PBO:0102115 Fig2B cells arrested due to activation of the rad3 checkpoint gene do not rereplicate
PMID:17690116 PBO:0102124 Fig3 and previous figs shows lack of re replication with moderate increase in cdc18 protein level
PMID:17690116 PBO:0019114 Fig4C At 25°C rad3 is active but checkpoint cannot be activated in absence of rad1
PMID:17690116 PBO:0019114 Fig4C At 25°C rad3 is active but checkpoint cannot be activated in absence of rad26
PMID:17690116 PBO:0019114 Fig4C At 25°C rad3 is active but checkpoint cannot be activated in absence of crb2
PMID:17690116 PBO:0020446 Fig4C at 25°C rad3ts is active and the checkpoint is activated in absence of cds1
PMID:17690116 PBO:0020446 Fig4C at the permissive temperature rad3ts is active and the checkpoint is activated in absence of mrc1
PMID:17690116 PBO:0102120 Fig 5A
PMID:17690116 PBO:0037515 Fig 5B
PMID:17690116 PBO:0102121 Fig5C
PMID:17690116 PBO:0102122 Fig5C
PMID:17690116 PBO:0102123 Fig6A,B
PMID:17690116 PBO:0037130 Fig1B This is the mutant form of pREP4X cdc18 from the screen At 25°C rad3 checkpoint is active and cells elongate, At 36°C rad3 is inactive and cells do not elongate when cdc18+ is expressed from pREP4X promoter,
PMID:17690116 PBO:0037130 Fig 2A when cdc18TA6 is overexpressed at 36°C (non permissive temperature for rad3ts ) cells continue to grow and divide normally ( permissive temperature for cdc18TA6)
PMID:17690116 FYPO:0002176 Fig 4C At 25°C rad3 is active but checkpoint cannot be activated in absence of hus1
PMID:17690116 PBO:0102125 Fig3 and previous figs shows lack of re replication with moderate increase in cdc18 protein level
PMID:17690116 PBO:0102126 Fig 6C shows Chromosome III smear is present throughout the cell cycle
PMID:17690116 FYPO:0006494 Fig7A, B, C after crossing out of cdc18TA6 chromosome size is stabilised and a single band is seen on PFGE which varies in size. If strains with larger Chr III are culture for <30 generations Chromosome III gradually reduces in size
PMID:17690116 FYPO:0007513 Fig 8A, B
PMID:17690116 PBO:0102127 Fig9A
PMID:17690116 PBO:0098709 Fig9B, C reb1D reduces amount inappropriate recombination at DNA repeats leading to a reduction in cell elongation during checkpoint activation
PMID:17690116 PBO:0102125 The western in Fig 3 actually shows the TAP tagged version but they use the two strains interchangeable so don't actually show data for this strain CCL9
PMID:17690116 PBO:0102128 Fig3 This is the mutant form of pREP4X cdc18 from the screen
PMID:17690116 PBO:0102129 Fig1B At 36°C the restrictive temperature for rad3ts the checkpoint is inactive and cells expressing the mutant form of pREP4X cdc18 from the screen do not elongate and are able to form colonies
PMID:17690116 PBO:0037130 Fig 2A cells expressing cdc18T6A at 36°C do not elongate at the nonpermissive temperature for rad3ts due to inactivation of the mitotic DNA replication checkpoint
PMID:17690116 PBO:0102130 Fig3 cdc18 expressed from pREP3X is at a high level. They argue that higher levels cdc18 lead to rereplication and lower levels lead to a rad3 dependent block but no rereplication
PMID:17690116 PBO:0094205 Fig9B, C rad52D reduces amount inappropriate recombination at DNA repeats leading to a reduction in cell elongation during checkpoint activation
PMID:17690116 PBO:0102117 Fig2 A,C cells arrested due to activation of the rad3 (permissive temperature) have normal nuclear to cell size ratio (NC ratio) compared to cdc25-22 at restrictive temp 2 hr
PMID:17690116 PBO:0102118 Fig2D different to when pREP3X cdc18+ is over expressed in G2 block which show replicate intermediates and cells undergo re replication
PMID:17804800 PBO:0092665 emsa
PMID:17868468 GO:0006264 deleted existing genome maintence term, and annotated this instead, all things considered...
PMID:17881496 PBO:0038222 Fig. 1A
PMID:17881496 FYPO:0005719 ABOLISHED Figure 3 B
PMID:17881496 FYPO:0005719 Figure 3 A
PMID:17881496 FYPO:0000620 Figure 3 A
PMID:17881496 GO:1990942 Fig. 3A
PMID:17881496 FYPO:0003302 Fig. 1B
PMID:17881729 PBO:0105768 the evidence isn't great
PMID:17936710 PBO:0093619 same as either single mutant
PMID:17936710 PBO:0093613 same as either single mutant
PMID:17936710 GO:0000706 actually inferred (IC) from combination of phenotype plus GO:0000014 MF
PMID:17936710 FYPO:0002150 spores from mre11d/mre11d homozygous diploid
PMID:17936710 PBO:0095337 spores from mre11d/mre11d rec12d/rec12d homozygous diploid
PMID:17936710 PBO:0108142 assayed at ctp1 promoter
PMID:17936710 PBO:0095337 spores from ctp1d/ctp1d rec12d/rec12d homozygous diploid
PMID:17936710 FYPO:0002150 spores from ctp1d/ctp1d homozygous diploid
PMID:17936710 PBO:0095338 spores from rec12d/rec12d homozygous diploid
PMID:17937917 GO:0005524 (site B)
PMID:17937917 GO:0016208 (site B)
PMID:17937917 GO:0043531 (site A)
PMID:18030666 FYPO:0002336 spatial extent
PMID:18030666 FYPO:0002336 spatial extent
PMID:18030666 FYPO:0002336 spatial extent
PMID:18030666 FYPO:0007477 epigenetic variegation both 5-FOA-resistant and -sensitive colonies were found
PMID:18030666 FYPO:0002336 spatial extent
PMID:18030666 FYPO:0002336 spatial extent
PMID:18030666 FYPO:0002336 spatial extent
PMID:18030666 FYPO:0002336 spatial extent
PMID:18030666 FYPO:0002336 "spatial extent. "" These results suggested that the 5-FOA-resistant phenotype of the original mutants was indeed due to ura4 repression, presumably as a result of heterochromatin assembly occurring outside the inverted repeat region."""
PMID:18030666 FYPO:0002336 "spatial extent ********"" These results suggested that the 5-FOA-resistant phenotype of the original mutants was indeed due to ura4 repression, presumably as a result of heterochromatin assembly occurring outside the inverted repeat region."""
PMID:18030666 FYPO:0002336 spatial extent ******The assay is Ura4 expression as a reporter gene for whether heterochromatin is spreading beyond the normal boundry, which it isn't here and so the toxic analogue results in growth attenuation. But sensitivity to FOA isn't the phenotype of interest, that's just the tool
PMID:18042546 PBO:0102872 time course after transcription shutoff, so actually measuring degradation
PMID:18042546 PBO:0102871 all microarray (table 1); arz1 also northern (fig 1)
PMID:18042546 PBO:0102870 all microarray (table 1); arz1 also northern (fig 1)
PMID:18042546 PBO:0102864 all microarray (table 1); arz1 also northern (fig 1)
PMID:18042546 PBO:0102869 all microarray (table 1); arz1 also northern (fig 1)
PMID:18042546 PBO:0102868 all microarray (table 1); arz1 also northern (fig 1)
PMID:18042546 PBO:0102867 all microarray (table 1); arz1 also northern (fig 1)
PMID:18042546 PBO:0102866 all microarray (table 1); arz1 also northern (fig 1)
PMID:18042546 PBO:0102865 all microarray (table 1); arz1 also northern (fig 1)
PMID:18042546 PBO:0101588 all microarray (table 1); arz1 also northern (fig 1)
PMID:18042546 PBO:0102861 all microarray (table 1); arz1 also northern (fig 1)
PMID:18042546 PBO:0102862 all microarray (table 1); arz1 also northern (fig 1)
PMID:18042546 PBO:0102863 all microarray (table 1); arz1 also northern (fig 1)
PMID:18057023 PBO:0112410 Fig. 1B
PMID:18057023 PBO:0112422 Fig. 8B
PMID:18057023 PBO:0112421 Fig. 8B
PMID:18057023 PBO:0112420 Fig. 8A
PMID:18057023 PBO:0112416 Fig. 7A
PMID:18057023 PBO:0112415 Fig. 7A
PMID:18057023 PBO:0112417 Fig. 7A
PMID:18057023 PBO:0112416 Fig. 7A
PMID:18057023 PBO:0112415 Fig. 7A
PMID:18057023 PBO:0112417 Fig. 7A
PMID:18057023 PBO:0112416 Fig. 7A
PMID:18057023 PBO:0112415 Fig. 7A
PMID:18057023 PBO:0095113 Fig. 3
PMID:18057023 PBO:0112414 Fig. 2B
PMID:18057023 PBO:0112414 Fig. 2B
PMID:18057023 PBO:0112414 Fig. 2B
PMID:18057023 PBO:0112413 Fig. 1B
PMID:18057023 PBO:0112412 Fig. 1B
PMID:18057023 PBO:0112411 Fig. 1B
PMID:18057023 PBO:0112408 Fig. 1A
PMID:18057023 FYPO:0001315 Fig. 1A
PMID:18057023 FYPO:0001315 Fig. 1A
PMID:18057023 PBO:0112407 Fig. 1A
PMID:18057023 PBO:0112407 Fig. 1A
PMID:18057023 PBO:0112408 Fig. 1A
PMID:18057023 FYPO:0001315 Fig. 1B
PMID:18057023 PBO:0112404 Fig. 1A
PMID:18057023 PBO:0112405 Fig. 1A
PMID:18057023 FYPO:0001315 Fig. 1B
PMID:18057023 FYPO:0001315 Fig. 1B
PMID:18057023 PBO:0112409 Fig. 1B
PMID:18057023 PBO:0112406 Fig. 1A
PMID:18057023 PBO:0112406 Fig. 1A
PMID:18057023 PBO:0112410 Fig. 1B
PMID:18057023 PBO:0112423 Fig. 8B
PMID:18057023 PBO:0112419 Fig. 8A
PMID:18057023 PBO:0112418 Fig. 8A
PMID:18057023 PBO:0112417 Fig. 7A
PMID:18057023 PBO:0112416 Fig. 7A
PMID:18057023 PBO:0112415 Fig. 7A
PMID:18057023 PBO:0112417 Fig. 7A
PMID:18059460 GO:0008574 speckles in Fig. 4A
PMID:18060866 GO:0051285 localization independent of actin cytoskeleton (assayed using latrunculin A) and microtubule cytoskeleton (assayed using carbendazim)
PMID:18061564 PBO:0099339 figure 6F
PMID:18061564 GO:0051256 FORMATION
PMID:18061564 GO:0001578 bundle maintenence https://github.com/geneontology/go-ontology/issues/18215
PMID:18061564 PBO:0099331 minus end
PMID:18061564 FYPO:0000904 in overlap zones
PMID:18061564 PBO:0099333 activation
PMID:18061564 PBO:0099337 fig6
PMID:18061564 PBO:0099338 figure 6F
PMID:18079700 PBO:0098318 Figure 3 C/E during G1
PMID:18079700 PBO:0098316 Figure 3 C/E
PMID:18079700 FYPO:0000450 Rad21
PMID:18079700 PBO:0098316 Figure 3 C/E
PMID:18079700 PBO:0098313 Figure 3 B
PMID:18079700 FYPO:0002060 Supplementary Figure S2
PMID:18079700 PBO:0098315 Figure 3 A/B
PMID:18079700 PBO:0098317 Figure 3 B
PMID:18079700 PBO:0098314 Figure 3 A (but not S phase)
PMID:18079700 PBO:0098313 Figure 3 A
PMID:18079700 GO:0007064 maintenence
PMID:18079700 PBO:0098316 Figure 3C and E
PMID:18093330 FYPO:0001982 fig 1
PMID:18093330 FYPO:0007068 Fig8
PMID:18093330 FYPO:0007068 Fig8
PMID:18157149 MOD:00427 I guess this can be changed once we can do RNA mods
PMID:18157152 MOD:00427 this is a protein modification so should be changed once we can do RNA mods
PMID:18160711 FYPO:0002702 region between NdeI and XhoI sites deleted
PMID:18160711 FYPO:0002702 truncated at PacI site
PMID:18160711 FYPO:0002702 region between NsiI sites deleted
PMID:18165685 GO:0051015 comment: assayed using assembled Arp2/3 complex, so perhaps some subunits should have contributes_to (but most subunits, maybe all, make contact with actin in the model in http://jcb.rupress.org/content/180/5/887)
PMID:18165685 GO:0051015 comment: assayed using assembled Arp2/3 complex, so perhaps some subunits should have contributes_to (but most subunits, maybe all, make contact with actin in the model in http://jcb.rupress.org/content/180/5/887)
PMID:18165685 GO:0051015 comment: assayed using assembled Arp2/3 complex, so perhaps some subunits should have contributes_to (but most subunits, maybe all, make contact with actin in the model in http://jcb.rupress.org/content/180/5/887)
PMID:18165685 GO:0051015 comment: assayed using assembled Arp2/3 complex, so perhaps some subunits should have contributes_to (but most subunits, maybe all, make contact with actin in the model in http://jcb.rupress.org/content/180/5/887)
PMID:18165685 GO:0051015 comment: assayed using assembled Arp2/3 complex, so perhaps some subunits should have contributes_to (but most subunits, maybe all, make contact with actin in the model in http://jcb.rupress.org/content/180/5/887)
PMID:18165685 GO:0051015 comment: assayed using assembled Arp2/3 complex, so perhaps some subunits should have contributes_to (but most subunits, maybe all, make contact with actin in the model in http://jcb.rupress.org/content/180/5/887)
PMID:18165685 GO:0051015 comment: assayed using assembled Arp2/3 complex, so perhaps some subunits should have contributes_to (but most subunits, maybe all, make contact with actin in the model in http://jcb.rupress.org/content/180/5/887)
PMID:18184749 GO:0032541 supp 1A
PMID:18184749 PBO:0110558 (Figure 1B, left panel),
PMID:18184749 PBO:0110559 (Figure 1A, right panel). Figure 1C
PMID:18184749 GO:0042175 supp 1A
PMID:18184749 PBO:0110560 (Figure 1A, right panel). Figure 1C
PMID:18184749 GO:0042175 supp 1A
PMID:18184749 PBO:0110555 (Figure 1A, right panel). Figure 1C
PMID:18184749 PBO:0110556 (Figure 1B, left panel),
PMID:18184749 GO:0032541 supp 1A
PMID:18184749 FYPO:0002872 (to cell division site) We confirmed that the actomyosin ring structure was important for polarization of the early secretory compartments by examiningthe spatial distribution of the tER and Golgi compartmentsin cells with compromised function of the myosin lightchainCdc4p
PMID:18184749 FYPO:0002872 abnormal ER polarization (ectopic)
PMID:18184749 FYPO:0002872 (abnormal ER polarization) We observed a striking reduction in the number of cells exhibiting clear polarization of the tER in cdc15-140 cells already at the permissive temperature of 24°C (Figure 5A, bottom panel),
PMID:18184749 PBO:0110557 (Figure 1B, left panel),
PMID:18223116 PBO:0106352 fig2
PMID:18223116 PBO:0107754 fig2
PMID:18223116 PBO:0107750 fig2
PMID:18223116 PBO:0107749 fig2
PMID:18223116 PBO:0107756 fig2
PMID:18223116 PBO:0111377 fig6, it doesn't bind dna according to later studies
PMID:18223116 PBO:0107016 fig2
PMID:18223116 PBO:0107753 fig2
PMID:18223116 PBO:0107746 fig2
PMID:18223116 PBO:0107747 fig2
PMID:18223116 PBO:0107015 fig2
PMID:18223116 PBO:0107748 fig2
PMID:18223116 PBO:0107745 fig2
PMID:18223116 PBO:0107755 fig2
PMID:18223116 PBO:0107752 fig2
PMID:18223116 PBO:0107751 fig2
PMID:18256284 PBO:0033843 figure 1B (plus end)
PMID:18256284 PBO:0033844 figure 1B (plus end)
PMID:18256284 PBO:0033846 figure 1A
PMID:18256284 PBO:0033849 figure 1B (plus end)
PMID:18256284 PBO:0033845 figure 1B (plus end)
PMID:18256284 PBO:0033842 figure 1A
PMID:18256290 PBO:0096598 increased more than pxl1delta alone
PMID:18256290 PBO:0096598 increased more than pxl1delta alone
PMID:18256290 PBO:0096598 less levere than pxl1 null
PMID:18256290 GO:0110085 localization dependent on filamentous actin (GO:0031941); tested using latrunculin A
PMID:18256290 PBO:0096598 less levere than pxl1 null
PMID:18256290 PBO:0096598 increased more than pxl1delta alone
PMID:18256290 PBO:0096598 increased more than pxl1delta alone
PMID:18256290 PBO:0096598 increased more than pxl1delta alone
PMID:18262494 PBO:0033440 (Fig. 1B)
PMID:18262494 FYPO:0001919 after chromosome segregation
PMID:18262494 FYPO:0000030 with extreme sister chromtid oscillations
PMID:18272786 FYPO:0001365 data from table; nothing more specific shown
PMID:18272786 FYPO:0001365 data from table; nothing more specific shown
PMID:18272786 FYPO:0001365 data from table; nothing more specific shown
PMID:18272786 FYPO:0001365 data from table; nothing more specific shown
PMID:18272786 FYPO:0001365 data from table; nothing more specific shown
PMID:18272786 GO:0110085 dependent on F-actin (assayed using Latrunculin A)
PMID:18276645 PBO:0107664 normal oxygen level
PMID:18276645 PBO:0109064 normal oxygen level
PMID:18328707 PBO:0104866 GTP-bound Figure 4E, polarization localization to both cell ends
PMID:18328707 PBO:0104857 Fig 1D
PMID:18328707 PBO:0104865 GTP-bound Figure 4E
PMID:18328707 PBO:0096623 FigS1D
PMID:18328707 MOD:01455 fig 1D
PMID:18328707 PBO:0104856 Fig 1
PMID:18328707 PBO:0104858 Fig 1D (pom1 is catalytically active but not localized to cell ends)
PMID:18328707 PBO:0104858 Fig 1
PMID:18328707 PBO:0104859 old end
PMID:18328707 PBO:0104860 Fig1SE to cell cortex of (newnon growing) cell tip from medial cortex
PMID:18328707 PBO:0104864 GTP bound fig 3C
PMID:18328707 PBO:0103573 active GTP bound form
PMID:18328707 GO:0005515 Figure 3B
PMID:18328707 PBO:0020227 GTP bound active form
PMID:18328707 PBO:0104863 GTP bound
PMID:18328707 PBO:0104856 Fig 1
PMID:18328707 PBO:0104856 Fig 1
PMID:18328707 PBO:0100644 Figure 3A
PMID:18328707 PBO:0104862 Fig 2C
PMID:18328707 PBO:0104861 Fig1SE to cell cortex of (new) cell tip from medial cortex
PMID:18328707 PBO:0104861 Fig1SE to cell cortex of (new) cell tip from medial cortex
PMID:18328707 PBO:0104868 *****OLD*****waiting for GO
PMID:18328707 PBO:0104858 Fig 1D
PMID:18328707 FYPO:0000024 Figure 4E
PMID:18331722 PBO:0104195 in vitro assay
PMID:18331722 GO:1990949 First, we have shown that a true APC/C substrate regulates the activity of the APC/C. Cells might precisely control protein levels of each or a subset of APC/C substrate to fine-tune the APC/C itself....Mes1 transcripts and protein levels peak in late MI (Izawa et al., 2005; Mata et al., 2002) when Mes1 seques- ters the Fizzy family of proteins to inhibit APC/C, in turn slowing down cyclin B proteolysis (‘‘APC/C inhibited’’ in Figure 4G). At the same time, Mes1 is inhibited through ubiquitylation by APC/C to allow partial APC/C activation required for anaphase I onset.
PMID:18337696 FYPO:0003118 at time 0. they don't look at nitrogen starvation for very long, only 60 mins
PMID:18344406 PBO:0093616 Interestingly, hst4� cells were sensitive to MMS and CPT (Fig. 1A)
PMID:18344406 PBO:0093617 Interestingly, similar to the hst4� mutant, both K56R and K56Q mutants were sensitive to MMS and CPT. However, the histone H3 K56Q mutant, which mimics the constitutively acetylated state, was less sensitive to MMS and CPT than the K56R mutant, which mimics the constitutively deacetylated state.
PMID:18344406 PBO:0093616 Interestingly, similar to the hst4� mutant, both K56R and K56Q mutants were sensitive to MMS and CPT.
PMID:18344406 FYPO:0003481 Like hst4� cells, both histone H3 mutant cells were very elongated, and a percentage of these cells exhibited abnormal DAPI staining (Fig. 7A).
PMID:18344406 PBO:0111114 Like hst4� cells, both histone H3 mutant cells were very elongated, and a percentage of these cells exhibited abnormal DAPI staining (Fig. 7A).
PMID:18344406 PBO:0111113 Like hst4� cells, both histone H3 mutant cells were very elongated, and a percentage of these cells exhibited abnormal DAPI staining (Fig. 7A).
PMID:18344406 FYPO:0002060 Both mutant strains were viable and able to grow at 32°C.
PMID:18344406 PBO:0093559 Both mutant strains were viable and able to grow at 32°C. However, like the hst4� strain, the histone H3 K56R mutant strains had slight growth defects compared to the strain containing a single copy of the H3 histone (Fig. 7B, first panel).
PMID:18344406 GO:0140861 These results collectively suggest that alterations in K56 acetylation are dependent upon the presence of Hst4 in the cell, and more importantly, they suggest that the levels of Hst4 are regulated in response to cell cycle progression and DNA damage.
PMID:18344406 PBO:0093616 H184Y mutation were as sensitive to MMS as the hst4� strains were, indicating that Hst4 enzymatic activity was important for cells to be resistant to MMS.
PMID:18344406 PBO:0111112 These results (Fig. 4C) showed that the acetylation of H3 K56 is cell cycle regulated and occurred during the S phase of the cell cycle.
PMID:18344406 FYPO:0007632 In the absence of Sir2, we observed elevated levels of histone H3 K9 and histone H4 K16, which was con- sistent with previous reports (17, 48).
PMID:18344406 FYPO:0000871 In the absence of Sir2, we observed elevated levels of histone H3 K9 and histone H4 K16, which was con- sistent with previous reports (17, 48).
PMID:18344406 FYPO:0008160 The hst4� mutant did not show significant changes in the acetylation levels of histone H3 K9 or K14 and histone H4 K16 compared to the wild-type control (Fig. 4A).
PMID:18344406 FYPO:0008161 The hst4� mutant did not show significant changes in the acetylation levels of histone H3 K9 or K14 and histone H4 K16 compared to the wild-type control (Fig. 4A).
PMID:18344406 FYPO:0003223 The hst4� mutant did not show significant changes in the acetylation levels of histone H3 K9 or K14 and histone H4 K16 compared to the wild-type control (Fig. 4A).
PMID:18344406 FYPO:0002061 However, every single repair mutant that we tested was synthetically sick in combination with hst4� when cells were grown on medium containing MMS (Fig. 3).
PMID:18344406 FYPO:0002061 However, every single repair mutant that we tested was synthetically sick in combination with hst4� when cells were grown on medium containing MMS (Fig. 3).
PMID:18344406 FYPO:0002061 However, every single repair mutant that we tested was synthetically sick in combination with hst4� when cells were grown on medium containing MMS (Fig. 3).
PMID:18344406 FYPO:0002061 However, every single repair mutant that we tested was synthetically sick in combination with hst4� when cells were grown on medium containing MMS (Fig. 3).
PMID:18344406 FYPO:0002061 However, every single repair mutant that we tested was synthetically sick in combination with hst4� when cells were grown on medium containing MMS (Fig. 3).
PMID:18344406 FYPO:0002060 Tetrad analysis demonstrating synthetic lethality of representatives of the DNA damage checkpoint mutant crb2� and rad3� are shown in Fig. 2A
PMID:18344406 FYPO:0002060 Tetrad analysis demonstrating synthetic lethality of representatives of the DNA damage checkpoint mutant crb2� and rad3� are shown in Fig. 2A
PMID:18344406 FYPO:0002060 Tetrad analysis demonstrating synthetic lethality of representatives of the DNA damage checkpoint mutant crb2� and rad3� are shown in Fig. 2A
PMID:18344406 FYPO:0002060 Tetrad analysis demonstrating synthetic lethality of representatives of the DNA damage checkpoint mutant crb2� and rad3� are shown in Fig. 2A
PMID:18344406 FYPO:0002151 Tetrad analysis demonstrating synthetic lethality of representatives of the DNA damage checkpoint mutant crb2� and rad3� are shown in Fig. 2A
PMID:18344406 FYPO:0000502 Wild-type cells showed a peak of septation approximately 80 min after release, whereas the hst4� cells showed a delayed peak of septation at 120 min (see Fig. S2 in the supplemental material).
PMID:18344406 FYPO:0008162 In cells lacking Hst4, Chk1 was phosphorylated even in the absence of MMS exposure, and this phosphorylation did not significantly in- crease upon exposure to MMS (Fig. 2B).
PMID:18344406 FYPO:0002151 Tetrad analysis demonstrating synthetic lethality of representatives of the DNA damage checkpoint mutant crb2� and rad3� are shown in Fig. 2A
PMID:18344406 FYPO:0002151 Tetrad analysis demonstrating synthetic lethality of representatives of the DNA damage checkpoint mutant crb2� and rad3� are shown in Fig. 2A
PMID:18344406 FYPO:0002151 Tetrad analysis demonstrating synthetic lethality of representatives of the DNA damage checkpoint mutant crb2� and rad3� are shown in Fig. 2A
PMID:18344406 FYPO:0002151 Tetrad analysis demonstrating synthetic lethality of representatives of the DNA damage checkpoint mutant crb2� and rad3� are shown in Fig. 2A
PMID:18344406 PBO:0111111 If this signal is not generated, cells mutant go through the cell cycle with damage and eventually die.
PMID:18344406 FYPO:0001925 hst4� cells behaved as wild-type cells did and were able to survive exposure to gamma irradiation (Fig. 1C).
PMID:18344406 PBO:0093631 significantly sensitive to HU. less than that of wild-type cells but higher than that of checkpoint mutant rad3� cells (Fig. 1B).
PMID:18344406 FYPO:0000963 significantly sensitive to HU.
PMID:18344406 FYPO:0004928 Our fluorescence microscopic analysis also clearly indicated that a significant percentage of the hst4� cells in culture had fragmented DNA (see Fig. S1 in the sup- plemental material).
PMID:18344406 PBO:0093613 Interestingly, hst4� cells were sensitive to MMS and CPT (Fig. 1A)
PMID:18378696 FYPO:0000089 same as either single mutant
PMID:18378696 PBO:0093586 same as nbs1delta alone
PMID:18378696 FYPO:0000089 same as nbs1delta alone
PMID:18378696 PBO:0093586 same as either single mutant
PMID:18378696 PBO:0093630 same as nbs1delta alone
PMID:18378696 FYPO:0000088 same as nbs1delta alone
PMID:18378696 PBO:0093619 same as rad51delta alone
PMID:18378696 PBO:0093630 same as either single mutant
PMID:18391219 GO:0002143 "provides the sulfur....seems ok based on the def ""The process in which a uridine residue at position 34 in the anticodon of a tRNA is post-transcriptionally thiolated at the C2 position. **This process involves transfer of a sulfur from cysteine to position C2 by several steps"""
PMID:18399988 PBO:0095423 they show transfer to a heterologous cytochrome p450 enzyme, but pombe doesn't have any mitochondrial ones.
PMID:18411246 PBO:0103895 (Fig. 3A)
PMID:18411246 FYPO:0004952 enclosure arrow in Figs 4Ci,ii)
PMID:18411246 FYPO:0001914 Fig. 5B
PMID:18411246 PBO:0103894 Fig. 2A
PMID:18411246 PBO:0023044 Fig. 2B
PMID:18411246 PBO:0103896 (Fig. 3A)
PMID:18414064 PBO:0098973 penetrance at 4 hours
PMID:18414064 PBO:0098969 penetrance at 4 hours; increases upon longer time at restrictive temp
PMID:18414064 PBO:0098974 penetrance at 4 hours
PMID:18414064 FYPO:0001387 same with or without TBZ
PMID:18414064 FYPO:0001387 same with or without TBZ
PMID:1849107 PBO:0103716 also assayed using lacZ under fbp1 promoter
PMID:1849107 PBO:0103717 also assayed using lacZ under fbp1 promoter
PMID:1849107 PBO:0103717 also assayed using lacZ under fbp1 promoter
PMID:1849107 PBO:0103716 also assayed using lacZ under fbp1 promoter
PMID:1849107 PBO:0103717 also assayed using lacZ under fbp1 promoter
PMID:1849107 PBO:0103716 also assayed using lacZ under fbp1 promoter
PMID:1849107 PBO:0103716 also assayed using lacZ under fbp1 promoter
PMID:1849107 FYPO:0001869 git2-1 is effectively null, even though it isn't a complete deletion of the coding sequence
PMID:1849107 FYPO:0001660 git2-1 is effectively null, even though it isn't a complete deletion of the coding sequence
PMID:1849107 PBO:0103715 glycerol = derepressing for glucose repression also assayed using lacZ under fbp1 promoter (and maltose carbon source, also derepressing)
PMID:1849107 PBO:0103716 also assayed using lacZ under fbp1 promoter
PMID:1849107 PBO:0103717 also assayed using lacZ under fbp1 promoter
PMID:1849107 PBO:0103716 also assayed using lacZ under fbp1 promoter
PMID:1849107 PBO:0103716 also assayed using lacZ under fbp1 promoter
PMID:1849107 PBO:0103717 also assayed using lacZ under fbp1 promoter
PMID:1849107 PBO:0103717 also assayed using lacZ under fbp1 promoter
PMID:1849107 PBO:0103716 also assayed using lacZ under fbp1 promoter
PMID:1849107 PBO:0103717 also assayed using lacZ under fbp1 promoter
PMID:1849107 PBO:0103717 also assayed using lacZ under fbp1 promoter
PMID:1849107 PBO:0103716 also assayed using lacZ under fbp1 promoter
PMID:1849107 PBO:0103717 also assayed using lacZ under fbp1 promoter
PMID:1849107 PBO:0103716 also assayed using lacZ under fbp1 promoter
PMID:1849107 PBO:0103716 also assayed using lacZ under fbp1 promoter
PMID:1849107 PBO:0103716 also assayed using lacZ under fbp1 promoter
PMID:1849107 PBO:0103716 also assayed using lacZ under fbp1 promoter
PMID:1849107 PBO:0103716 also assayed using lacZ under fbp1 promoter
PMID:1849107 PBO:0103716 also assayed using lacZ under fbp1 promoter
PMID:18493607 PBO:0094679 same as sir2+ overexpression alone
PMID:18493607 PBO:0092751 present throughout mitotic cell cycle
PMID:18493607 PBO:0093564 slighly more severe than sir2+ overexpression alone
PMID:18495844 PBO:0104279 Fig3B
PMID:18495844 PBO:0104277 Fig1B
PMID:18495844 PBO:0104278 Fig1B normal interphase MTs required to establish early orientation of mitotic spindle by aligning SPBs with long axis of cell
PMID:18495844 PBO:0104278 Fig1B and 2B,C normal MTs required to establish early orientation of mitotic spindle by aligning SPBs with long axis of cell
PMID:18495844 PBO:0104280 Fig3B,C
PMID:18495844 PBO:0104280 Fig3B,C As expected, the range of SPB trajectory angles was much wider than in wild-type cells (Fig. 2C, Fig. 3B,C
PMID:18495844 PBO:0104281 Fig3B
PMID:18495844 FYPO:0005691 Fig 2B
PMID:18495844 FYPO:0005691 Fig 2 A-C This oscillatory movement was not perturbed by Latrunculin A treatment, but was lost in cells treated with MBC or in mto1Δ cells, and was reduced in tip1Δ cells
PMID:18504300 PBO:0112313 Fig. 5
PMID:18504300 PBO:0099112 Fig. 5
PMID:18504300 PBO:0021460 Fig. 5
PMID:18504300 PBO:0112312 Fig. 5
PMID:18514516 PBO:0095386 same as either single mutant
PMID:18514516 PBO:0095386 same as either single mutant
PMID:18514516 PBO:0095390 same as either single mutant
PMID:18514516 PBO:0095390 same as either single mutant
PMID:18514516 PBO:0095386 same as either single mutant
PMID:18562692 FYPO:0000324 Fig. 6C
PMID:18562692 FYPO:0006917 Fig. 6C
PMID:18562692 FYPO:0006917 Fig. 6C
PMID:18562692 FYPO:0006917 Fig. 6C
PMID:18562692 FYPO:0006917 Fig. 6C
PMID:18562692 FYPO:0006917 Fig. 6C
PMID:18562692 FYPO:0006917 Fig. 6C
PMID:18562692 FYPO:0006917 Fig. 6C
PMID:18562692 FYPO:0006917 Fig. 6C
PMID:18562692 FYPO:0006917 Fig. 1
PMID:18562692 FYPO:0007388 Fig. 1
PMID:18562692 FYPO:0001778 Fig. 5B
PMID:18562692 FYPO:0002022 Fig. 3
PMID:18562692 FYPO:0006917 Fig. 4
PMID:18562692 FYPO:0000324 Fig. 5A
PMID:18562692 PBO:0099145 Fig. 5B
PMID:18562692 PBO:0099146 Fig. 5A
PMID:18562692 PBO:0099147 Fig. 5A
PMID:18562692 FYPO:0000324 Fig. 6C
PMID:18562692 FYPO:0000324 Fig. 6C
PMID:18615848 FYPO:0002019 same as swi7-H4 alone, i.e. it's dominant
PMID:1863602 GO:0010515 maybe not shown strongly in this paper but I'm trying to get the git genes annotated to this term because pka1 phosphorylates rst2 which excludes rst2 from the nucleus. rst2 when in the nucleus activates ste11 transcription.
PMID:18640983 FYPO:0007061 in vitro
PMID:18653539 FYPO:0002060 figure 1A
PMID:18653539 FYPO:0001673 figure 1 C
PMID:18653539 FYPO:0004168 figure 8B
PMID:18653539 FYPO:0004168 figure 8B
PMID:18653539 PBO:0096560 figure 1A, 8A
PMID:18653539 FYPO:0006275 Fig. 1D
PMID:18653539 FYPO:0006276 Fig. 1D, Fig. 1F
PMID:18653539 PBO:0096560 figure 1B
PMID:18653539 FYPO:0005585 figure 2A
PMID:18653539 FYPO:0004695 figure 2A
PMID:18653539 FYPO:0006289 figure 2A
PMID:18653539 FYPO:0004168 figure 8B
PMID:18653539 FYPO:0004168 figure 8B
PMID:18653539 FYPO:0003975 Fig 2 F during veg phase
PMID:18662319 GO:0034634 also L-gamma-glutamyl-L-cysteine
PMID:18667531 FYPO:0004329 nulcleolus inheritance
PMID:18667531 FYPO:0001234 synthetic sick when combined with a deletion of the Holliday junction endonuclease Mus81 (Figure 2, C and D).
PMID:18667531 FYPO:0001234 synthetic sick when combined with a deletion of the Holliday junction endonuclease Mus81 (Figure 2, C and D).
PMID:18667531 FYPO:0002061 synthetic sick when combined with a deletion of the Holliday junction endonuclease Mus81 (Figure 2, C and D).
PMID:18667531 FYPO:0002061 synthetic sick when combined with a deletion of the Holliday junction endonuclease Mus81 (Figure 2, C and D).
PMID:18667531 PBO:0104010 The Nse1-Nse3 interaction is not perturbed by dele- tion of Nse1 NH-RING as tested by yeast two-hybrid assay, which is consistent with a previous report (Figure 5B and Sergeant et al., 2005).
PMID:18667531 PBO:0093556 The RING, C197A, C199A, and C197A/C199A mutants were mildly temperature sensi- tive but grew normally at 25°C (Figure 2A and data not shown)
PMID:18667531 PBO:0093556 The RING, C197A, C199A, and C197A/C199A mutants were mildly temperature sensi- tive but grew normally at 25°C (Figure 2A and data not shown)
PMID:18667531 PBO:0093556 The RING, C197A, C199A, and C197A/C199A mutants were mildly temperature sensi- tive but grew normally at 25°C (Figure 2A and data not shown)
PMID:18667531 FYPO:0001357 The RING, C197A, C199A, and C197A/C199A mutants were mildly temperature sensi- tive but grew normally at 25°C (Figure 2A and data not shown)
PMID:18667531 FYPO:0001357 The RING, C197A, C199A, and C197A/C199A mutants were mildly temperature sensi- tive but grew normally at 25°C (Figure 2A and data not shown)
PMID:18667531 FYPO:0001357 The RING, C197A, C199A, and C197A/C199A mutants were mildly temperature sensi- tive but grew normally at 25°C (Figure 2A and data not shown)
PMID:18667531 FYPO:0000674 The C219A mutant was not temperature sensitive (Figure 2A).
PMID:18667531 GO:0006281 On the basis of these data, we propose that the Nse1 NH-RING contributes to the DNA repair functions of the Smc5-Smc6 holocomplex.
PMID:18676809 PBO:0105611 Conversely, mutations disrupting dimerization did not disrupt -H2A.1 binding (Fig. 3C).
PMID:18676809 PBO:0105610 the Ser666Arg and Cys663Arg mutants ran as monomeric species in gel filtration, indicative of disruption of their dimerization
PMID:18676809 PBO:0105610 the Ser666Arg and Cys663Arg mutants ran as monomeric species in gel filtration, indicative of disruption of their dimerization
PMID:18676809 PBO:0105609 Consistent with their observed structural roles, charge reversal mutations Arg616Glu, Lys617Glu, and Lys619Glu all abolished Crb2–BRCT2 interaction with the peptide (Fig. 3A),
PMID:18676809 PBO:0105609 Consistent with their observed structural roles, charge reversal mutations Arg616Glu, Lys617Glu, and Lys619Glu all abolished Crb2–BRCT2 interaction with the peptide (Fig. 3A),
PMID:18676809 PBO:0105609 Consistent with their observed structural roles, charge reversal mutations Arg616Glu, Lys617Glu, and Lys619Glu all abolished Crb2–BRCT2 interaction with the peptide (Fig. 3A),
PMID:18676809 PBO:0105607 Consistent with their observed structural roles, charge reversal mutations Arg616Glu, Lys617Glu, and Lys619Glu all abolished Crb2–BRCT2 interaction with the peptide (Fig. 3A),
PMID:18676809 PBO:0105607 Consistent with their observed structural roles, charge reversal mutations Arg616Glu, Lys617Glu, and Lys619Glu all abolished Crb2–BRCT2 interaction with the peptide (Fig. 3A),
PMID:18676809 PBO:0105607 Consistent with their observed structural roles, charge reversal mutations Arg616Glu, Lys617Glu, and Lys619Glu all abolished Crb2–BRCT2 interaction with the peptide (Fig. 3A),
PMID:18676809 FYPO:0000088 fig 4 a
PMID:18676809 FYPO:0000088 fig 4 a
PMID:18676809 FYPO:0000088 fig 4 a
PMID:18676809 FYPO:0000006 fig 4 a
PMID:18676809 FYPO:0000085 fig 4 a
PMID:18676809 FYPO:0000085 fig 4 a
PMID:18676809 FYPO:0000085 fig 4 a
PMID:18676809 FYPO:0000268 fig 4 a
PMID:18676809 FYPO:0000268 fig 4 a
PMID:18676809 FYPO:0000268 fig 4 a
PMID:18676809 PBO:0105612 Conversely, mutations disrupting dimerization did not disrupt -H2A.1 binding (Fig. 3C).
PMID:18676809 PBO:0105612 Conversely, mutations disrupting dimerization did not disrupt -H2A.1 binding (Fig. 3C).
PMID:18676809 PBO:0105611 Conversely, mutations disrupting dimerization did not disrupt -H2A.1 binding (Fig. 3C).
PMID:18716626 FYPO:0007993 (Fig. 3c) Accordingly, the replacement of Val 242 with Glu (VE) in Sgo1 abolished the interaction with Swi6 while preserving the interaction with Par1, a subunit of PP2A. An immunoprecipitation assay also supports the loss of the interaction of Sgo1-VE with Swi6
PMID:18716626 PBO:0096744 (Fig. 3c) Accordingly, the replacement of Val 242 with Glu (VE) in Sgo1 abolished the interaction with Swi6 while preserving the interaction with Par1, a subunit of PP2A. An immunoprecipitation assay also supports the loss of the interaction of Sgo1-VE with Swi6
PMID:18716626 FYPO:0002353 (Supplementary Fig. 3a). We confirmed that the expression of Psc3–2CD does not restore transcriptional silencing in swi6D cells
PMID:18716626 PBO:0096734 (Fig. 1e, f) As predicted, the additional expression of Psc3–2CD (but not of 2CD alone) improved the localization of the cohesin complex to the peri-centromeric regions and also centromeric cohesion in swi6D cells
PMID:18716626 PBO:0096734 (Supplementary Fig. 2a) , but not in another heterochromatin-defect- ive strain, clr4D, which lacks H3K9me (ref. 7)
PMID:18716626 PBO:0096743 (Fig. 3c) Accordingly, the replacement of Val 242 with Glu (VE) in Sgo1 abolished the interaction with Swi6 while preserving the interaction with Par1, a subunit of PP2A. An immunoprecipitation assay also supports the loss of the interaction of Sgo1-VE with Swi6
PMID:18716626 FYPO:0003182 (Fig. 3f). The assay of chromosome segregation further revealed that sgo1-VE cells provoke nondisjunction in meiosis II, similarly to swi6D cells
PMID:18716626 FYPO:0007994 (Fig. 3f and Supplementary Fig. 8). The Sgo1-VE protein, when fused with CDand thereby localized to the centromere, can perform its full functionin protecting Rec8
PMID:18716626 PBO:0112512 (Fig. 2a, b) As with sgo1D cells, swi6D cells undergo intact meiosis I but suffer a nondisjunction of sister chromatids in meiosis II
PMID:18716626 PBO:0096734 (Supplementary Fig. 2a) We confirmed that Psc3–2CD, as well as 2CD, itself localizesat discrete nuclear dots in swi6D cell
PMID:18716626 PBO:0096733 Fig. 1a–d
PMID:18716626 FYPO:0000964 Fig. 1a–d
PMID:18716626 FYPO:0001513 Fig. 1a–d
PMID:18716626 FYPO:0002353 Fig. 1a
PMID:18716626 PBO:0112511 (Fig. 2a, b) As with sgo1D cells, swi6D cells undergo intact meiosis I but suffer a nondisjunction of sister chromatids in meiosis II
PMID:18716626 PBO:0109343 various: These results indicate that Swi6 is crucial in localizing Sgo1 and thereby promotes the protection of cohesin from separase during anaphase I.
PMID:18716626 PBO:0096735 figure 1g 30% cells?
PMID:18716626 FYPO:0003182 (Fig. 2a, b) As with sgo1D cells, swi6D cells undergo intact meiosis I but suffer a nondisjunction of sister chromatids in meiosis II
PMID:18716626 PBO:0096738 (Supplementary Fig. 4). The transcriptional silencing of Swi6 is not relevant to this function, because swi6-sm1 cells have intact meiotic chromosome segregation
PMID:18716626 PBO:0096739 (Fig. 2e) Sgo1 localization is impaired in swi6D cells
PMID:18716626 PBO:0096740 (Fig. 2f) Sgo1–CD did indeed localize at the centromere regardless of swi6D
PMID:18716626 PBO:0112512 (Fig. 2a, b) As with sgo1D cells, swi6D cells undergo intact meiosis I but suffer a nondisjunction of sister chromatids in meiosis II
PMID:18723894 FYPO:0003084 no barrier activity with reversed polarity as in rtf1-S154L single mutant
PMID:18723894 FYPO:0003084 no barrier activity with reversed polarity as in rtf1-S154L single mutant
PMID:18723894 FYPO:0003352 "RTS1 inversion background abolishes DSB formation; ""decreased"" level in rtf1-W405G is relative to wild type and above the inverted-RTS1 background level"
PMID:18769921 FYPO:0001386 during vegetative growth because non-sporulating strains used
PMID:18769921 FYPO:0004437 during vegetative growth because non-sporulating strains used
PMID:18769921 FYPO:0001839 during vegetative growth because non-sporulating strains used
PMID:18769921 FYPO:0001839 during vegetative growth because non-sporulating strains used
PMID:18769921 PBO:0093631 slightly worse than sfr1delta alone
PMID:18769921 PBO:0093618 slightly more sensitive at low temperature than standard
PMID:18769921 FYPO:0000473 during vegetative growth because non-sporulating strains used
PMID:18794373 FYPO:0007206 arrest at Ter2 and Ter3 sites abolished
PMID:18794373 FYPO:0007206 arrest at Ter2 and Ter3 sites abolished
PMID:18794373 GO:0110035 binds at Ter3 site
PMID:18794373 FYPO:0007206 arrest at Ter2 and Ter3 sites abolished
PMID:18794373 FYPO:0007206 arrest at Ter2 and Ter3 sites abolished
PMID:18794373 FYPO:0007206 arrest at Ter2 and Ter3 sites abolished
PMID:18794373 FYPO:0007206 arrest at Ter2 and Ter3 sites abolished
PMID:18809570 PBO:0095652 Fig. 8H
PMID:18809570 PBO:0095653 Fig. 1B and C
PMID:18809570 PBO:0095651 Fig. 1B and C
PMID:18809570 PBO:0095651 Fig. 1D
PMID:18809570 FYPO:0002336 Fig. 1D
PMID:18809570 PBO:0095651 Fig. 1D
PMID:18809570 PBO:0095652 Fig. 1E
PMID:18809570 PBO:0112671 Fig. 2C
PMID:18809570 PBO:0112672 Fig. 2D
PMID:18809570 PBO:0095653 Fig. 2E
PMID:18809570 PBO:0095652 Fig. 2G
PMID:18809570 GO:0031507 Chp2’s function is not exclusively associated with the establishment step and that its continued activity is critical for the maintenance of heterochromatin. Fig. 3
PMID:18809570 PBO:0112673 Fig. 4A
PMID:18809570 PBO:0112674 Fig. 4A
PMID:18809570 PBO:0109218 Fig. 4A
PMID:18809570 PBO:0112675 Fig. 4A
PMID:18809570 PBO:0112676 Fig. 4A
PMID:18809570 PBO:0112676 Fig. 4A
PMID:18809570 PBO:0112677 Fig. 4D
PMID:18809570 PBO:0112678 Fig. 4D
PMID:18809570 PBO:0111115 Fig. 4D
PMID:18809570 PBO:0112679 Fig. 4D
PMID:18809570 PBO:0111115 Fig. 4D
PMID:18809570 PBO:0112679 Fig. 4D
PMID:18809570 FYPO:0002360 Fig. 5A
PMID:18809570 PBO:0098583 Fig. 5A
PMID:18809570 PBO:0098583 Fig. 5A
PMID:18809570 PBO:0108390 Fig. 5A
PMID:18809570 PBO:0111587 Fig. 5A
PMID:18809570 PBO:0111587 Fig. 5A
PMID:18809570 PBO:0095651 Fig. 5B
PMID:18809570 PBO:0095651 Fig. 5B
PMID:18809570 PBO:0112680 Fig. 7B
PMID:18809570 PBO:0112681 Fig. 7A
PMID:18809570 GO:0005721 Fig. 7A
PMID:18809570 GO:0140720 Fig. 7A
PMID:18809570 GO:0031934 Fig. 7A
PMID:18809570 PBO:0111014 Fig. 7A
PMID:18809570 PBO:0112682 Fig. 7A
PMID:18809570 PBO:0101110 Fig. 7B
PMID:18809570 GO:0005721 Fig. 7B
PMID:18809570 GO:0140720 Fig. 7B
PMID:18809570 GO:0031934 Fig. 7B
PMID:18809570 PBO:0095651 Fig. 8D
PMID:18809570 PBO:0095653 Fig. 8D
PMID:18809570 PBO:0095652 Fig. 8D
PMID:18809570 PBO:0095653 Fig. 8D
PMID:18809570 PBO:0095652 Fig. 8H
PMID:18809570 PBO:0095653 Fig. 8H
PMID:18809570 PBO:0095651 Fig. 8H
PMID:18809570 PBO:0095651 Fig. 9A
PMID:18809570 FYPO:0002336 Fig. 9A
PMID:18809570 PBO:0112683 Fig. 9C
PMID:18809570 FYPO:0007633 Fig. 9D
PMID:18809570 FYPO:0008209 Fig. 9D
PMID:18820678 PBO:0111102 In the rst22 mutant, transcripts a, b, and c are expressed normally, whereas transcript d is absent (Fig. 4A).
PMID:18820678 PBO:0111104 In the rst22 mutant, transcripts a, b, and c are expressed normally, whereas transcript d is absent (Fig. 4A).
PMID:18820678 PBO:0111103 In the atf1- mutant, transcripts a and b are expressed normally, whereas tran- scripts c and d are absent (Fig. 4A).
PMID:18820678 PBO:0111102 In the atf1- mutant, transcripts a and b are expressed normally, whereas tran- scripts c and d are absent (Fig. 4A).
PMID:18820678 PBO:0111101 In the atf1- mutant, transcripts a and b are expressed normally, whereas tran- scripts c and d are absent (Fig. 4A).
PMID:18820678 PBO:0111100 In the atf1- mutant, transcripts a and b are expressed normally, whereas tran- scripts c and d are absent (Fig. 4A).
PMID:18820678 FYPO:0008156 Expression of transcript c is not restored in the atf12tup112tup122 mutant, sug- gesting that Atf1 is essential to induce transcript c.
PMID:18820678 PBO:0111103 In the rst22 mutant, transcripts a, b, and c are expressed normally, whereas transcript d is absent (Fig. 4A).
PMID:18820678 FYPO:0004171 Moreover, fbp11 derepression is recovered by deleting both tup111 and tup121, indicating that Atf1 and Rst2 are dispensable for fbp11 induction in the absence of both Tup proteins
PMID:18820678 FYPO:0004171 Moreover, fbp11 derepression is recovered by deleting both tup111 and tup121, indicating that Atf1 and Rst2 are dispensable for fbp11 induction in the absence of both Tup proteins
PMID:18820678 PBO:0111105 Chromatin remodelling events and RNAPII loading around the TATA box are severely impaired in an atf12 mutant, demonstrating that the progression of ncRNA initi- ation events mediated by Atf1 is essential to convert chromatin to an RNAPII accessible state (Fig. 4B).
PMID:18820678 PBO:0111100 In the rst22 mutant, transcripts a, b, and c are expressed normally, whereas transcript d is absent (Fig. 4A).
PMID:18849471 GO:0004585 qualifier=major
PMID:18854158 FYPO:0000085 no extension because growth is decreased generally, making expressivity hard to judge
PMID:18854158 FYPO:0000268 no extension because growth is decreased generally, making expressivity hard to judge
PMID:18854158 FYPO:0000267 no extension because growth is decreased generally, making expressivity hard to judge
PMID:18854158 FYPO:0000268 no extension because growth is decreased generally, making expressivity hard to judge
PMID:18854158 FYPO:0000085 no extension because growth is decreased generally, making expressivity hard to judge
PMID:18854158 FYPO:0000085 no extension because growth is decreased generally, making expressivity hard to judge
PMID:18854158 FYPO:0000267 no extension because growth is decreased generally, making expressivity hard to judge
PMID:18854158 PBO:0100306 abolished interaction between wt and mutant; interaction partially restored if both copies are mutant
PMID:18854158 FYPO:0000267 no extension because growth is decreased generally, making expressivity hard to judge
PMID:18854158 FYPO:0000268 no extension because growth is decreased generally, making expressivity hard to judge
PMID:18854158 FYPO:0000268 no extension because growth is decreased generally, making expressivity hard to judge
PMID:18854158 PBO:0100306 abolished interaction between wt and mutant; interaction partially restored if both copies are mutant
PMID:18854158 FYPO:0000085 no extension because growth is decreased generally, making expressivity hard to judge
PMID:18854158 FYPO:0000267 no extension because growth is decreased generally, making expressivity hard to judge
PMID:18948543 FYPO:0003619 However, at the permissive temperature of 25°C (at which centromeric silencing was alleviated), splicing efficiency was similar to that in wild-type cells (Fig. 2A).
PMID:18948543 PBO:0105941 Moreover, mutants that alleviated cen1:ade6+ silencing also displayed increased levels of noncoding centromeric otr transcripts and concomitant reductions in centromeric siRNA accumulation, with prp10-1 showing the most severe silencing defects (Fig. 1C
PMID:18948543 FYPO:0003412 In contrast, mutations in prp5 (Prp46Sc/PLRG1Hs), prp8 (Prp2Sc/DHX16Hs), prp10 (Hsh155Sc/ SF3B1Hs), and prp12 (Rse1Sc/SF3B2Hs), like cwf10 and prp39, alleviated cen1:ade6+ silencing (Fig. 1B) and increased cen1:ade6+ transcript accumulation (Fig. 1C, ade6)
PMID:18948543 FYPO:0003412 In contrast, mutations in prp5 (Prp46Sc/PLRG1Hs), prp8 (Prp2Sc/DHX16Hs), prp10 (Hsh155Sc/ SF3B1Hs), and prp12 (Rse1Sc/SF3B2Hs), like cwf10 and prp39, alleviated cen1:ade6+ silencing (Fig. 1B) and increased cen1:ade6+ transcript accumulation (Fig. 1C, ade6)
PMID:18948543 FYPO:0003412 In contrast, mutations in prp5 (Prp46Sc/PLRG1Hs), prp8 (Prp2Sc/DHX16Hs), prp10 (Hsh155Sc/ SF3B1Hs), and prp12 (Rse1Sc/SF3B2Hs), like cwf10 and prp39, alleviated cen1:ade6+ silencing (Fig. 1B) and increased cen1:ade6+ transcript accumulation (Fig. 1C, ade6)
PMID:18948543 FYPO:0003412 In contrast, mutations in prp5 (Prp46Sc/PLRG1Hs), prp8 (Prp2Sc/DHX16Hs), prp10 (Hsh155Sc/ SF3B1Hs), and prp12 (Rse1Sc/SF3B2Hs), like cwf10 and prp39, alleviated cen1:ade6+ silencing (Fig. 1B) and increased cen1:ade6+ transcript accumulation (Fig. 1C, ade6)
PMID:18948543 FYPO:0000220 In contrast, mutations in prp5 (Prp46Sc/PLRG1Hs), prp8 (Prp2Sc/DHX16Hs), prp10 (Hsh155Sc/ SF3B1Hs), and prp12 (Rse1Sc/SF3B2Hs), like cwf10 and prp39, alleviated cen1:ade6+ silencing (Fig. 1B) and increased cen1:ade6+ transcript accumulation (Fig. 1C, ade6)
PMID:18948543 FYPO:0004201 Moreover, mutants that alleviated cen1:ade6+ silencing also displayed increased levels of noncoding centromeric otr transcripts and concomitant reductions in centromeric siRNA accumulation, with prp10-1 showing the most severe silencing defects (Fig. 1C
PMID:18948543 PBO:0094684 In contrast, mutations in prp5 (Prp46Sc/PLRG1Hs), prp8 (Prp2Sc/DHX16Hs), prp10 (Hsh155Sc/ SF3B1Hs), and prp12 (Rse1Sc/SF3B2Hs), like cwf10 and prp39, alleviated cen1:ade6+ silencing (Fig. 1B) and increased cen1:ade6+ transcript accumulation (Fig. 1C, ade6)
PMID:18948543 FYPO:0000220 In contrast, mutations in prp5 (Prp46Sc/PLRG1Hs), prp8 (Prp2Sc/DHX16Hs), prp10 (Hsh155Sc/ SF3B1Hs), and prp12 (Rse1Sc/SF3B2Hs), like cwf10 and prp39, alleviated cen1:ade6+ silencing (Fig. 1B) and increased cen1:ade6+ transcript accumulation (Fig. 1C, ade6)
PMID:18948543 FYPO:0004742 we surveyed several additional ts lethal splicing mutants for silencing defects at the permissive temperature (11-14). Only particular splicing mutants affected silencing. Silencing of a centromeric cen1:ade6+ marker gene (Fig. 1A) remained intact in the presence of prp1 (Prp6Sc/Hs), prp2 (U2AFHs), prp3 (Prp3Sc/PRPF3Hs), or prp4 (PRPF4BHs) mutations
PMID:18948543 FYPO:0004742 we surveyed several additional ts lethal splicing mutants for silencing defects at the permissive temperature (11-14). Only particular splicing mutants affected silencing. Silencing of a centromeric cen1:ade6+ marker gene (Fig. 1A) remained intact in the presence of prp1 (Prp6Sc/Hs), prp2 (U2AFHs), prp3 (Prp3Sc/PRPF3Hs), or prp4 (PRPF4BHs) mutations
PMID:18948543 FYPO:0004742 we surveyed several additional ts lethal splicing mutants for silencing defects at the permissive temperature (11-14). Only particular splicing mutants affected silencing. Silencing of a centromeric cen1:ade6+ marker gene (Fig. 1A) remained intact in the presence of prp1 (Prp6Sc/Hs), prp2 (U2AFHs), prp3 (Prp3Sc/PRPF3Hs), or prp4 (PRPF4BHs) mutations
PMID:18948543 FYPO:0004742 we surveyed several additional ts lethal splicing mutants for silencing defects at the permissive temperature (11-14). Only particular splicing mutants affected silencing. Silencing of a centromeric cen1:ade6+ marker gene (Fig. 1A) remained intact in the presence of prp1 (Prp6Sc/Hs), prp2 (U2AFHs), prp3 (Prp3Sc/PRPF3Hs), or prp4 (PRPF4BHs) mutations
PMID:18948543 FYPO:0000220 In contrast, mutations in prp5 (Prp46Sc/PLRG1Hs), prp8 (Prp2Sc/DHX16Hs), prp10 (Hsh155Sc/ SF3B1Hs), and prp12 (Rse1Sc/SF3B2Hs), like cwf10 and prp39, alleviated cen1:ade6+ silencing (Fig. 1B) and increased cen1:ade6+ transcript accumulation (Fig. 1C, ade6)
PMID:18948543 FYPO:0000220 In contrast, mutations in prp5 (Prp46Sc/PLRG1Hs), prp8 (Prp2Sc/DHX16Hs), prp10 (Hsh155Sc/ SF3B1Hs), and prp12 (Rse1Sc/SF3B2Hs), like cwf10 and prp39, alleviated cen1:ade6+ silencing (Fig. 1B) and increased cen1:ade6+ transcript accumulation (Fig. 1C, ade6)
PMID:18948543 FYPO:0003412 In contrast, mutations in prp5 (Prp46Sc/PLRG1Hs), prp8 (Prp2Sc/DHX16Hs), prp10 (Hsh155Sc/ SF3B1Hs), and prp12 (Rse1Sc/SF3B2Hs), like cwf10 and prp39, alleviated cen1:ade6+ silencing (Fig. 1B) and increased cen1:ade6+ transcript accumulation (Fig. 1C, ade6)
PMID:18948543 FYPO:0003412 In contrast, mutations in prp5 (Prp46Sc/PLRG1Hs), prp8 (Prp2Sc/DHX16Hs), prp10 (Hsh155Sc/ SF3B1Hs), and prp12 (Rse1Sc/SF3B2Hs), like cwf10 and prp39, alleviated cen1:ade6+ silencing (Fig. 1B) and increased cen1:ade6+ transcript accumulation (Fig. 1C, ade6)
PMID:18948543 FYPO:0004201 Moreover, mutants that alleviated cen1:ade6+ silencing also displayed increased levels of noncoding centromeric otr transcripts and concomitant reductions in centromeric siRNA accumulation, with prp10-1 showing the most severe silencing defects (Fig. 1C
PMID:18948543 FYPO:0000220 In contrast, mutations in prp5 (Prp46Sc/PLRG1Hs), prp8 (Prp2Sc/DHX16Hs), prp10 (Hsh155Sc/ SF3B1Hs), and prp12 (Rse1Sc/SF3B2Hs), like cwf10 and prp39, alleviated cen1:ade6+ silencing (Fig. 1B) and increased cen1:ade6+ transcript accumulation (Fig. 1C, ade6)
PMID:18948543 PBO:0111071 Chromatin immunoprecipitation (ChIP) revealed that splicing mutants cwf10-1 and prp10-1 (but not prp2-1) exhibited only a modest decrease in levels of H3K9me2 associated with both centromere repeats and cen1:ura4+ (Fig. 3A and fig. S3).
PMID:18948543 PBO:0111071 Chromatin immunoprecipitation (ChIP) revealed that splicing mutants cwf10-1 and prp10-1 (but not prp2-1) exhibited only a modest decrease in levels of H3K9me2 associated with both centromere repeats and cen1:ura4+ (Fig. 3A and fig. S3).
PMID:18948543 PBO:0108387 Chromatin immunoprecipitation (ChIP) revealed that splicing mutants cwf10-1 and prp10-1 (but not prp2-1) exhibited only a modest decrease in levels of H3K9me2 associated with both centromere repeats and cen1:ura4+ (Fig. 3A and fig. S3).
PMID:18948543 FYPO:0003097 (Fig. 3A and fig. S3).
PMID:18948543 PBO:0097401 Chromatin immunoprecipitation (ChIP) revealed that splicing mutants cwf10-1 and prp10-1 (but not prp2-1) exhibited only a modest decrease in levels of H3K9me2 associated with both centromere repeats and cen1:ura4+ (Fig. 3A and fig. S3).
PMID:18948543 PBO:0097401 Chromatin immunoprecipitation (ChIP) revealed that splicing mutants cwf10-1 and prp10-1 (but not prp2-1) exhibited only a modest decrease in levels of H3K9me2 associated with both centromere repeats and cen1:ura4+ (Fig. 3A and fig. S3).
PMID:18948543 FYPO:0003412 We therefore constructed strains in which the endogenous ago1+ and hrr1+ genes were replaced by cDNAs. Even in these strains, the prp10-1 mutation alleviated silencing as in wild-type cells (Fig. 2C, white colonies).
PMID:18948543 FYPO:0003412 We therefore constructed strains in which the endogenous ago1+ and hrr1+ genes were replaced by cDNAs. Even in these strains, the prp10-1 mutation alleviated silencing as in wild-type cells (Fig. 2C, white colonies).
PMID:18948543 FYPO:0003619 However, at the permissive temperature of 25°C (at which centromeric silencing was alleviated), splicing efficiency was similar to that in wild-type cells (Fig. 2A).
PMID:18948543 FYPO:0003619 However, at the permissive temperature of 25°C (at which centromeric silencing was alleviated), splicing efficiency was similar to that in wild-type cells (Fig. 2A).
PMID:18948543 FYPO:0003619 However, at the permissive temperature of 25°C (at which centromeric silencing was alleviated), splicing efficiency was similar to that in wild-type cells (Fig. 2A).
PMID:18948543 FYPO:0003619 However, at the permissive temperature of 25°C (at which centromeric silencing was alleviated), splicing efficiency was similar to that in wild-type cells (Fig. 2A).
PMID:18948543 FYPO:0004201 Moreover, mutants that alleviated cen1:ade6+ silencing also displayed increased levels of noncoding centromeric otr transcripts and concomitant reductions in centromeric siRNA accumulation, with prp10-1 showing the most severe silencing defects (Fig. 1C
PMID:18948543 FYPO:0003619 However, at the permissive temperature of 25°C (at which centromeric silencing was alleviated), splicing efficiency was similar to that in wild-type cells (Fig. 2A).
PMID:18951025 PBO:0106929 one or more of mutated serine residues
PMID:18951025 PBO:0106929 one or more of mutated serine residues
PMID:18957202 PBO:0096189 ilencing at the imr region in lid2-phd2 and lid2-phd3 mutants was significantly impaired while lid2-phd1 showed only a slight defect (Figure 7A).
PMID:18957202 FYPO:0000877 Obvious reduction of H3K9 methylation was also observed in lid2-phd2 and lid2-phd3 mutants (Figure S9)
PMID:18957202 FYPO:0000877 Obvious reduction of H3K9 methylation was also observed in lid2-phd2 and lid2-phd3 mutants (Figure S9)
PMID:18957202 PBO:0105306 We also examined the GFP-Swi6 distribution in the mutants (Figure 7B). While the lid2-phd1 mutant is similar to the WT, the nuclei in the lid2-phd2 and lid2-phd3 mutants often contained excessive GFP- Swi6 dots, suggesting that euchromatin assembly is disrupted in the mutants (Figure 7B).
PMID:18957202 PBO:0093562 As shown in Figure 2E, lid2-j, like clr8Δ, is hypersensitive to TBZ
PMID:18957202 PBO:0105540 28% of the cells contained fragmented nuclear DNA (Figure 2D), indicating that the mutant nucleus is disorganized.
PMID:18957202 FYPO:0003481 WT and frequently exhibited an aberrant elongated cell shape (Figure 2C)
PMID:18957202 FYPO:0002151 tetrad analysis. We deleted one copy of lid2+ by kanamycin reporter gene replacement (kan+) in a WT diploid strain (lid2+/lid2Δ::kan+) and tetrad analysis was performed after sporulation. Only two germinating spores from a tetrad were viable, confirming that lid2+ is an essential gene
PMID:18957202 GO:0005721 GFP-Lid2 is resistant to detergent extraction indicating Lid2 is a chromatin-binding protein (Figure 2A).showed enrichment of DNA from centromeres and the mating-type region, indicating Lid2 is associated with heterochromatin (Figure 2B).
PMID:18957202 GO:0031934 GFP-Lid2 is resistant to detergent extraction indicating Lid2 is a chromatin-binding protein (Figure 2A).showed enrichment of DNA from centromeres and the mating-type region, indicating Lid2 is associated with heterochromatin (Figure 2B).
PMID:18957202 GO:0003682 GFP-Lid2 is resistant to detergent extraction indicating Lid2 is a chromatin-binding protein (Figure 2A).
PMID:18957202 GO:0005634 Figure 2A
PMID:18957202 PBO:0101470 Figure 1A
PMID:18957202 FYPO:0007334 We found that deletion of the Lid2 JmjC domain resulted in the complete loss of ura4+ silencing at both the otr and imr loci (Figure 3A and Figure 7A).
PMID:18957202 FYPO:0007335 We found that deletion of the Lid2 JmjC domain resulted in the complete loss of ura4+ silencing at both the otr and imr loci (Figure 3A and Figure 7A).
PMID:18957202 FYPO:0007336 mating-type region was likewise reduced (Figure 3A)
PMID:18957202 FYPO:0004170 As shown in Figure 3B, H3K9 methylation at the centromere was completely abolished.
PMID:18957202 FYPO:0007338 In contrast, H3K4me3 methylation was increased significantly (Figure 3C)
PMID:18957202 PBO:0094673 drastic reduction of Swi6 binding (Figure 3D).
PMID:18957202 PBO:0105541 We then determined whether Lid2 is required for the recruitment of Clr4 to heterochromatin. We carried out a ChIP experiment using lid2-j or clr8Δ containing a N-terminal FLAG-tagged Clr4. The localization of Clr4 at centromeres is abrogated in both mutants (Figure 3E).
PMID:18957202 PBO:0105541 We then determined whether Lid2 is required for the recruitment of Clr4 to heterochromatin. We carried out a ChIP experiment using lid2-j or clr8Δ containing a N-terminal FLAG-tagged Clr4. The localization of Clr4 at centromeres is abrogated in both mutants (Figure 3E).
PMID:18957202 FYPO:0000874 overexpressing Lid2 enhances H3K9 methylation (Figures 5G and H)
PMID:18957202 PBO:0105542 H3K4me3 staining was reduced to nearly undetectable levels in 82% of the cells overexpressing Lid2, suggesting that Lid2 can specifically demethylate H3K4 me3 (Figure 4B)
PMID:18957202 FYPO:0007339 forward and reverse centromeric strands were detected in lid2-j and accumulated at the same level as in clr8Δ, suggesting that Lid2 is involved in the RNAi pathway.
PMID:18957202 FYPO:0000220 forward and reverse centromeric strands were detected in lid2-j and accumulated at the same level as in clr8Δ, suggesting that Lid2 is involved in the RNAi pathway.
PMID:18957202 PBO:0105543 As shown in Figure 5C, siRNA is barely detectable.
PMID:18957202 PBO:0103965 As shown in Figure 5D, the association of Ago1 with the centromere is significantly reduced in lid2-j, indicating that Lid2 is required for RITS to load onto centromeres.
PMID:18957202 PBO:0105544 In WT cells, Myc- Clr8 associates with centromere otr regions, but not in lid2-j suggesting that Lid2 is required for Clr8 association with heterochromatin (Figure 5E).
PMID:18957202 GO:0005721 GFP-Lid2 is resistant to detergent extraction indicating Lid2 is a chromatin-binding protein (Figure 2A).showed enrichment of DNA from centromeres and the mating-type region, indicating Lid2 is associated with heterochromatin (Figure 2B).
PMID:18957202 PBO:0105545 As shown in Figure 5E, while Lid2 accumulated at centromeres in the WT, the centromere localization of Lid2 in the clr8 mutant is significantly decreased.
PMID:18957202 PBO:0094283 Figure 5F, the point mutation resulted in a significant loss of silencing at the centromere otr region.
PMID:18957202 FYPO:0004170 ChIP assays indicated that H3K9me2 methylation at the region was abolished, while H3K4me3 methylation was increased more than seven-fold (Figure S2)
PMID:18957202 FYPO:0007337 ChIP assays indicated that H3K9me2 methylation at the region was abolished, while H3K4me3 methylation was increased more than seven-fold (Figure S2)
PMID:18957202 PBO:0105546 the point mutation had little effect on the interaction of Lid2 with its interacting partners, such as Cul4 and Set1 (Figure S3 and S8).
PMID:18957202 PBO:0105547 the point mutation had little effect on the interaction of Lid2 with its interacting partners, such as Cul4 and Set1 (Figure S3 and S8).
PMID:18957202 PBO:0105306 We next examined Swi6 localization in the lid2-j mutant using N-terminal tagged GFP-Swi6. In WT vegetative cells, 3–4 GFP-Swi6 spots are observed. This is because the three centromeres cluster on the nuclear envelope in the vicinity of the spindle pole body whereas telomeres loosely cluster on the nuclear envelope, apart from centromeres. clr4 and clr8 mutants have a diffuse Swi6 localization due to the disruption of heterochromatin. To our surprise, we did not see the same GFP-Swi6 pattern in the lid2-j mutant as in clr8Δ. Rather, we found that 78% of the cells contain more than 5 GFP-Swi6 spots, with nearly 30% having more than 10 spots (Figure 6A). The abnormal distribution of Swi6 also can be observed in meiotic horsetail stage nuclei (Figure 6A). The aberrant Swi6 localization is not caused by defects in centromere or telomere clustering since the distribution of centromeres and telomeres, as marked by Cnp1-GFP or Taz1-GFP respectively, is unaffected in the lid2-j mutant (Figure S4). We further confirmed that telomeres cluster normally by visualizing their distribution in a lid2-j strain carrying mCherry-Swi6 and the telomere marker Taz1-GFP (Figure S4). These results suggest that heterochromatin is induced in euchromatic regions in lid2-j.
PMID:18957202 PBO:0105548 RNAI dependent
PMID:18957202 FYPO:0007345 About 50% (2665 out of 5241) of the genes in the genome were downregulated in mutant cells compared to WT (Figure 6C and Table S3), consistent with the formation of ectopic heterochromatin.
PMID:18957202 FYPO:0000825 We further noted the striking similarity of the genome-wide transcription profiles of the lid2-j and lsd1Δ mutants (Figure 6C), suggest
PMID:18957202 PBO:0105549 In contrast to the overexpression of Lid2 alone, which leads to a dramatic decrease in H3K4me3 (Figure 4B), reduction of H3K4me3 is minimal when Set1 or Lsd1 is also overexpressed (Figure 4C).
PMID:18957202 PBO:0105549 We also examined the GFP-Swi6 distribution in the mutants (Figure 7B). While the lid2-phd1 mutant is similar to the WT, the nuclei in the lid2-phd2 and lid2-phd3 mutants often contained excessive GFP- Swi6 dots, suggesting that euchromatin assembly is disrupted in the mutants (Figure 7B).
PMID:18957202 PBO:0096189 ilencing at the imr region in lid2-phd2 and lid2-phd3 mutants was significantly impaired while lid2-phd1 showed only a slight defect (Figure 7A).
PMID:18957202 PBO:0095834 ilencing at the imr region in lid2-phd2 and lid2-phd3 mutants was significantly impaired while lid2-phd1 showed only a slight defect (Figure 7A).
PMID:1899284 GO:0001228 also supported by complementation of S.c. deletion
PMID:19001497 PBO:0036769 fig 1 D
PMID:19001497 PBO:0036769 fig 1 D, 1 E
PMID:19001497 PBO:0098074 fig 1 D, 1 E
PMID:19001497 FYPO:0004511 Fig 1 E
PMID:19001497 FYPO:0002112 Fig4c
PMID:19001497 PBO:0098087 we conclude that the function of Mto2 in MT nucleation is mediated primarily, if not exclusively, via its binding to Mto1. Moreover, the failure of Mto1-334 to immunoprecipitate the γ-TuC indicates that the Mto1-Mto2 interaction is required for an efficient association of Mto1 with the γ-TuC, as detected in cytoplasmic extracts.
PMID:19001497 PBO:0098086 fig 1 D, 1 E
PMID:19001497 PBO:0098086 fig 1 D, 1 E
PMID:19001497 PBO:0098082 Fig4a
PMID:19001497 FYPO:0004511 Fig 1 E
PMID:19001497 PBO:0098083 Fig4c
PMID:19001497 FYPO:0005696 Fig4D
PMID:19001497 FYPO:0005699 Fig4D
PMID:19001497 FYPO:0004511 Fig 1 E
PMID:19001497 FYPO:0005691 supplementary material Movies 2-4).
PMID:19001497 FYPO:0005691 supplementary material Movies 2-4).
PMID:19001497 FYPO:0005691 supplementary material Movies 2-4).
PMID:19001497 FYPO:0004619 supplementary material Movies 2-4).
PMID:19001497 PBO:0098081 fig3
PMID:19001497 PBO:0098086 fig 1 D
PMID:19001497 PBO:0036769 fig 1 D, 1 E
PMID:19001497 PBO:0098085 fig 4 F
PMID:19001497 PBO:0098084 supplementary material Fig. S1)
PMID:19001497 PBO:0098085 fig 4 F
PMID:19001497 PBO:0098087 we conclude that the function of Mto2 in MT nucleation is mediated primarily, if not exclusively, via its binding to Mto1. Moreover, the failure of Mto1-334 to immunoprecipitate the γ-TuC indicates that the Mto1-Mto2 interaction is required for an efficient association of Mto1 with the γ-TuC, as detected in cytoplasmic extracts.
PMID:19001497 PBO:0098084 supplementary material Fig. S1)
PMID:19001497 FYPO:0005696 Fig 1 E
PMID:19001497 PBO:0098081 fig3
PMID:19001497 PBO:0098075 fig 2 a (this fig also has expression level for mutant alleles)
PMID:19001497 GO:0044732 fig 2 BC
PMID:19001497 GO:0000923 fig 2 BC
PMID:19001497 GO:0031021 fig 2 BC
PMID:19001497 PBO:0098076 Fig 2 D-F
PMID:19001497 PBO:0098076 Fig 2 D-F
PMID:19001497 PBO:0094146 Fig 2 D-F
PMID:19001497 PBO:0094146 Fig 2 D-F
PMID:19001497 PBO:0098077 Fig 2 D-F
PMID:19001497 PBO:0098078 Fig 2 D-F
PMID:19001497 PBO:0098078 Fig 2 D-F
PMID:19001497 PBO:0098079 Fig 2 D-F
PMID:19001497 PBO:0094143 Fig 2 D-F
PMID:19001497 PBO:0094143 Fig 2 D-F
PMID:19001497 PBO:0098080 fig3
PMID:19001497 PBO:0019206 fig 1 C
PMID:19001497 PBO:0019206 fig 1 C
PMID:19001497 PBO:0019223 fig 1 C
PMID:19001497 PBO:0019206 fig 1 C
PMID:19023408 GO:0035861 ChIP
PMID:19023408 GO:0045027 forms covalent linkage upon binding (wouldn't normally use ChIP as IDA for DNA binding MF, but the phenol extraction with or without protease adds more confidence)
PMID:19023408 FYPO:0005911 Southern blot
PMID:19023408 FYPO:0005136 Southern blot
PMID:19023408 FYPO:0005136 microarray
PMID:19023408 FYPO:0005136 Southern blot
PMID:19023408 FYPO:0005911 Southern blot
PMID:19023408 FYPO:0005911 Southern blot
PMID:19026779 PBO:0107732 Figure 4D
PMID:19026779 PBO:0107730 Figure 4D
PMID:19026779 PBO:0107732 Figure 4D
PMID:19026779 PBO:0107733 Figure 4D
PMID:19026779 PBO:0107732 Figure 4D
PMID:19026779 PBO:0107732 Figure 4D
PMID:19026779 PBO:0107730 Figure 4D
PMID:19026779 PBO:0107732 Figure 4D
PMID:19026779 PBO:0107730 Figure 4D
PMID:19026779 PBO:0107731 Figure 4D
PMID:19026779 PBO:0107730 Figure 4D
PMID:19026779 PBO:0107730 Figure 4D
PMID:19026779 PBO:0107730 Figure 4D
PMID:19026779 PBO:0112758 Figure 4D
PMID:19026779 PBO:0107730 Figure 4D
PMID:19026779 PBO:0107730 Figure 4D
PMID:19026779 PBO:0107733 Figure 4D
PMID:19026779 PBO:0107734 Figure 4D
PMID:19026779 PBO:0107730 Figure 4D
PMID:19026779 PBO:0107732 Figure 4D
PMID:19026779 PBO:0107733 Figure 4D
PMID:19026779 PBO:0107732 Figure 4D
PMID:19026779 PBO:0107730 Figure 4D
PMID:19026779 PBO:0107733 Figure 4D
PMID:19026779 PBO:0107732 Figure 4D
PMID:19026779 PBO:0107732 Figure 4D
PMID:19026779 PBO:0107730 Figure 4D
PMID:19026779 PBO:0094855 Figure 4D
PMID:19033384 PBO:0033377 Use of Western blot to assay phosphorylation levels GO:0071494= cellular response to UVC GO:1990253 = cellular response to leucine starvation (TG freeform submission) GO:0070301 = cellular repsonse to H2O2
PMID:19033384 GO:0031571 The checkpoint doesn't sense all types of dna damage eg that caused by gamma radiation or DNA adduct formation by PUVA
PMID:19033384 PBO:0033376 Use of Western blot to assay phosphorylation levels GO:0071494= cellular response to UVC GO:1990253 = cellular response to leucine starvation (TG freeform submission) GO:0070301 = cellular repsonse to H2O2
PMID:19033384 PBO:0100016 Use of Western blot to assay phosphorylation levels GO:0071494= cellular response to UVC GO:1990253 = cellular response to leucine starvation (TG freeform submission) GO:0070301 = cellular repsonse to H2O2
PMID:19033384 PBO:0033378 Use of Western blot to assay phosphorylation levels GO:0071494= cellular response to UVC GO:1990253 = cellular response to leucine starvation (TG freeform submission) GO:0070301 = cellular repsonse to H2O2
PMID:19033384 PBO:0021986 Use of Western blot to assay phosphorylation levels GO:0071494= cellular response to UVC GO:1990253 = cellular response to leucine starvation (TG freeform submission) GO:0070301 = cellular repsonse to H2O2
PMID:19033384 PBO:0021987 Use of Western blot to assay phosphorylation levels GO:0071494= cellular response to UVC GO:1990253 = cellular response to leucine starvation (TG freeform submission) GO:0070301 = cellular repsonse to H2O2
PMID:19033384 PBO:0021985 Use of Western blot to assay phosphorylation levels GO:0071494= cellular response to UVC GO:1990253 = cellular response to leucine starvation (TG freeform submission) GO:0070301 = cellular repsonse to H2O2
PMID:19033384 PBO:0021984 Use of Western blot to assay phosphorylation levels GO:0071494= cellular response to UVC GO:1990253 = cellular response to leucine starvation (TG freeform submission) GO:0070301 = cellular repsonse to H2O2
PMID:19037096 GO:0008574 Figure 4, A and B, and Supplemen- tal Movie S1
PMID:1905818 GO:0003924 (changed to GTPase from signal transducer)
PMID:1905818 FYPO:0000280 haploid, either mating type
PMID:19075108 FYPO:0008204 Fig. 2 and 3
PMID:19075108 PBO:0112543 Fig. 1A
PMID:19075108 PBO:0112544 Fig. 1A
PMID:19075108 PBO:0112545 Fig. 1A
PMID:19075108 PBO:0112546 Fig. 1A
PMID:19075108 PBO:0112547 Fig. 2A and C
PMID:19075108 PBO:0112548 Fig. 2A and C
PMID:19075108 PBO:0112549 Fig. 2A and C
PMID:19075108 PBO:0112548 Fig. 2A and C
PMID:19075108 PBO:0112550 Fig. 2B and C
PMID:19075108 PBO:0112550 Fig. 2B and C
PMID:19075108 PBO:0112550 Fig. 2B and C
PMID:19075108 PBO:0112550 Fig. 2B and C
PMID:19075108 PBO:0112551 Fig. 2B and C
PMID:19075108 PBO:0112551 Fig. 2B and C
PMID:19075108 PBO:0112551 Fig. 2B and C
PMID:19075108 PBO:0112551 Fig. 2B and C
PMID:19075108 FYPO:0006005 Fig. 2B
PMID:19075108 FYPO:0008204 Fig. 2 and 3
PMID:19075108 PBO:0112552 Fig. 4
PMID:19075108 PBO:0112553 Fig. 5A, B and C
PMID:19075108 FYPO:0007827 Fig. 5D
PMID:19075108 FYPO:0007827 Fig. 5D
PMID:19075108 PBO:0112554 These results furthered the notion that the function of Mid1p and corti- cal nodes was important for organization of normal actomy- osin rings in early mitosis.
PMID:19111658 GO:0003723 binds centromeric transcripts
PMID:19117951 FYPO:0002355 mat1Msmto REIIdelta mat2::ura4
PMID:19117951 FYPO:0001234 mat1Msmto REIIdelta mat2::ura4
PMID:19117951 FYPO:0001886 mat1Msmto REIIdelta mat2::ura4
PMID:19117951 FYPO:0000156 mat1Msmto REIIdelta mat2::ura4 gave dark staining with iodine, metastable and switch to the opposite state at a low rate
PMID:19117951 FYPO:0000156 gave dark staining with iodine,switch to the opposite state at a low rate
PMID:19117951 FYPO:0000156 gave dark staining with iodine,switch to the opposite state at a low rate
PMID:19117951 FYPO:0002346 mat1Msmto REIIdelta mat2::ura4
PMID:19117951 PBO:0098599 mat1Msmto REIIdelta mat2::ura4
PMID:19117951 PBO:0108055 mat1Msmto REIIdelta mat2::ura4
PMID:19117951 PBO:0108056 heterochromatin
PMID:19117951 FYPO:0000877 mat1Msmto REIIdelta mat2::ura4
PMID:19139265 PBO:0096679 fig9
PMID:19139265 FYPO:0002061 Fig. S5
PMID:19139265 PBO:0102283 fig8
PMID:19139265 FYPO:0002061 Fig. S5
PMID:19150433 PBO:0094912 covalent binding between topoisomerase and DNA
PMID:19150433 PBO:0094915 covalent binding between topoisomerase and DNA
PMID:19150433 PBO:0094913 covalent binding between topoisomerase and DNA
PMID:19150433 PBO:0094913 covalent binding between topoisomerase and DNA
PMID:19150433 PBO:0094913 covalent binding between topoisomerase and DNA
PMID:19150433 PBO:0094916 covalent binding between topoisomerase and DNA
PMID:19150433 PBO:0094912 covalent binding between topoisomerase and DNA
PMID:19155267 GO:0030378 Table S1, Supplementary Data
PMID:19155267 GO:0008721 Table S1, Supplementary Data
PMID:19155267 GO:0003941 Table S1, Supplementary Data
PMID:19158664 PBO:0095481 "closest we can get to ""at stalled fork"" with available terms"
PMID:19164572 PBO:0112534 Table S1
PMID:19164572 PBO:0112516 Fig. 1B
PMID:19164572 PBO:0112517 Fig. 1C
PMID:19164572 PBO:0112518 Fig. 1D
PMID:19164572 PBO:0112519 Fig. 1E
PMID:19164572 FYPO:0000863 Fig. 1F
PMID:19164572 FYPO:0008203 Fig. 1G
PMID:19164572 PBO:0112520 Fig. 1H
PMID:19164572 PBO:0112521 Table S1
PMID:19164572 PBO:0112522 Table S1
PMID:19164572 PBO:0112523 Table S1
PMID:19164572 PBO:0112524 Table S1
PMID:19164572 PBO:0112525 Table S1
PMID:19164572 PBO:0112526 Table S1
PMID:19164572 PBO:0112527 Table S1
PMID:19164572 PBO:0112528 Table S1
PMID:19164572 PBO:0112529 Table S1
PMID:19164572 PBO:0112530 Table S1
PMID:19164572 PBO:0112531 Table S1
PMID:19164572 PBO:0112532 Table S1
PMID:19164572 PBO:0112533 Table S1
PMID:19164572 PBO:0112535 Table S1
PMID:19164572 PBO:0112536 Table S1
PMID:19164572 PBO:0112537 Table S1
PMID:19164572 FYPO:0006299 Fig. 2A
PMID:19164572 FYPO:0000887 Fig. 2B
PMID:19164572 PBO:0112538 Fig. 2C
PMID:19164572 FYPO:0003412 Fig. 2A
PMID:19164572 FYPO:0003412 Fig. 2A
PMID:19164572 PBO:0112539 Fig. 3
PMID:19164572 PBO:0112540 Fig. 4B
PMID:19164572 PBO:0110928 Fig. 4B
PMID:19164572 PBO:0112541 Fig. 4B
PMID:19164572 PBO:0112541 Fig. 4B
PMID:19164572 FYPO:0002827 Fig. 4D
PMID:19164572 FYPO:0000472 Fig. 4E
PMID:19164572 FYPO:0000472 Fig. 4E
PMID:19164572 FYPO:0000472 Fig. 5
PMID:19164572 FYPO:0000472 Fig. 5
PMID:19164572 FYPO:0000472 Fig. 5
PMID:19164572 PBO:0112542 Fig. S2
PMID:19185548 GO:0000724 qualifier=different_pathway
PMID:19185548 GO:0000724 qualifier=different_pathway
PMID:19189958 FYPO:0001357 Figure 1
PMID:19189958 FYPO:0002104 Figure 1
PMID:19189958 FYPO:0002061 Figue 5B As expected for the rgf31 shut-off, the cells died in the presence of thiamine (promoter off).
PMID:19189958 PBO:0102195 Figure 2b
PMID:19189958 FYPO:0007905 Figure 3A
PMID:19189958 PBO:0102196 Figure 2A
PMID:19189958 FYPO:0002060 Figue 5B How- ever, their growth was rescued in the presence of sorbitol
PMID:19189958 FYPO:0002061 Figue 5B As expected for the rgf31 shut-off, the cells died in the presence of thiamine (promoter off).
PMID:19189958 FYPO:0002060 Figue 5B How- ever, their growth was rescued in the presence of sorbitol
PMID:19189958 PBO:0102201 Our results indicate that Rgf1p and Rgf2p share an essential role as Rho1p activators, and they suggest that in the absence of Rgf1p, Rgf2p takes over the essential functions for Rho1p during vegetative growth.
PMID:19189958 FYPO:0002060 Figure 1 Rgf2p, a Rho1-GEF Required for Sporulation in S. pombe 1329 6A (top) shows that rgf2 expressed from plasmids, containing the rgf21 genomic promoter (pGR13) or the strongest nmt1 promoter (pGR70), fully rescued the lysis and the Csp hypersensitivity of rgf1D cells in medium containing thiamine.
PMID:19189958 PBO:0102202 47% of cells
PMID:19189958 PBO:0102203 10% of cells
PMID:19189958 PBO:0102201 Our results indicate that Rgf1p and Rgf2p share an essential role as Rho1p activators, and they suggest that in the absence of Rgf1p, Rgf2p takes over the essential functions for Rho1p during vegetative growth.
PMID:19189958 FYPO:0001357 We also examined cell viability of stationary phase rgf2D and rgf21 cultures incubated for 4 days at 28°; both strains were found to be .90% viable during this period.
PMID:19189958 FYPO:0001310 90% viability ? We also examined cell viability of stationary phase rgf2D and rgf21 cultures incubated for 4 days at 28°; both strains were found to be .90% viable during this period.
PMID:19189958 FYPO:0000121 Figure 2
PMID:19189958 GO:0140748 "Figure 3 ""This result indicates that Rgf2p is in- volved in b-glucan biosynthesis during sporulation."" figure4c These results clearly indicate that Rgf2p is involved in the regulation of b(1,3)-glucan biosynthesis."
PMID:19189958 PBO:0102197 Figure 4c positive
PMID:19189958 PBO:0102196 Figure 2A
PMID:19189958 PBO:0102196 Figure 2A
PMID:19189958 GO:0005632 Figure 3B
PMID:19189958 PBO:0102198 the amount of active Rho1p increased considerably in the strain over- expressing Rgf2p as compared with the wild-type strain (Figure 4B
PMID:19189958 FYPO:0002177 Asexpected,over- expression of the rgf2-PTTRD mutant in a pREP3X vector produced viable cells and no multiseptated phenotype was seen, even at very long times of derepresion in the absence of thiamine (Figure 4A).
PMID:19189958 FYPO:0000590 Figure 2
PMID:19189958 FYPO:0000478 Figure 2A
PMID:19189958 FYPO:0007436 cells were larger than wild-type cells and displayed multiple abnormal septa.
PMID:19189958 PBO:0102199 GS activity was threefold higher than that observed in the wild-type strain (Figure 4C)
PMID:19189958 PBO:0102200 GS activity was threefold higher than that observed in the wild-type strain (Figure 4C)
PMID:19189958 FYPO:0002061 None of the 11 spores predicted to be rgf1This31 rgf2Tura1 was viable, strongly supporting the idea that simultaneous disruption of rgf11 and rgf21 is lethal. To eliminate the possibility that these mutations might be affecting only sporulation or germination, we also tested for synthetic lethality during vegetative growth
PMID:19189958 FYPO:0002060 Figure 5B viable and phenotypically in- distinguishable from the ehs2-1 mutant
PMID:19189958 FYPO:0004927 Figure 2A
PMID:19202278 FYPO:0002447 absent beta 1,3 gal
PMID:19202289 GO:0005886 (Fig. 2D)
PMID:19202289 FYPO:0000121 Fig. 1A
PMID:19202289 FYPO:0003563 Fig. 1A
PMID:19202289 FYPO:0003563 Fig. 1B
PMID:19202289 FYPO:0003798 Fig. 1B
PMID:19202289 FYPO:0002061 Fig. 1B
PMID:19202289 FYPO:0003905 (data not shown).
PMID:19202289 FYPO:0000307 (Fig. 2B)
PMID:19202289 GO:0032120 (Fig. 2B)
PMID:19202289 GO:0005628 (Fig. 2D)
PMID:19202289 FYPO:0002060 (Fig. 3C)
PMID:19202289 FYPO:0002060 (Fig. 3C)
PMID:19202289 FYPO:0000590 (Fig. 3A and B)
PMID:19202289 FYPO:0000590 (Fig. 3A and B)
PMID:19202289 GO:0032120 (Fig. 3B)
PMID:19202289 GO:0032120 (Fig. 3B)
PMID:19205745 PBO:0093561 temp semi-permissive for cdc6-23 alone
PMID:19205745 PBO:0093561 temp semi-permissive for cdc20-M10 alone
PMID:19205745 PBO:0093561 temp semi-permissive for pol1-1 alone
PMID:19205745 PBO:0093561 temp semi-permissive for cdc6-23 alone
PMID:19205745 PBO:0093581 temp semi-permissive for cdc6-23 alone
PMID:19205745 PBO:0093581 temp semi-permissive for cdc6-23 alone
PMID:19211838 FYPO:0002150 spores from homozygous diploids
PMID:19211838 FYPO:0002150 spores from homozygous diploids
PMID:19211838 FYPO:0002150 spores from homozygous diploids
PMID:19211838 FYPO:0002150 spores from homozygous diploids
PMID:19211838 FYPO:0002150 spores from homozygous diploids
PMID:19211838 FYPO:0002150 spores from homozygous diploids
PMID:19211838 FYPO:0002150 spores from homozygous diploids
PMID:19211838 PBO:0095337 spores from homozygous diploids
PMID:19211838 PBO:0095337 spores from homozygous diploids
PMID:19211838 FYPO:0002150 spores from homozygous diploids
PMID:19211838 FYPO:0002150 spores from homozygous diploids
PMID:19214192 GO:0140445 present throughout cell cycle but at higher level in late S phase
PMID:19214192 PBO:0105817 present in late S
PMID:19214192 GO:0140445 present throughout cell cycle but at higher level in S phase
PMID:19214192 GO:0140445 present at roughly constant level throughout cell cycle
PMID:19214192 PBO:0105817 DNA polymerases present in late S; epsilon (cdc20) earlier than alpha (pol1) or delta (cdc6)
PMID:19214192 PBO:0105817 present in late S
PMID:19214192 GO:0140445 present throughout cell cycle but at higher level in S phase
PMID:19214192 PBO:0105817 DNA polymerases present in late S; epsilon (cdc20) earlier than alpha (pol1) or delta (cdc6)
PMID:19214192 PBO:0105817 present in late S
PMID:19214192 GO:0140445 present throughout cell cycle but at lower level in S phase
PMID:19214192 PBO:0105817 present in late S, as late as pols alpha & delta
PMID:19214192 PBO:0105817 DNA polymerases present in late S; epsilon (cdc20) earlier than alpha (pol1) or delta (cdc6)
PMID:19217404 FYPO:0003740 abolished, fig1 d
PMID:19217404 FYPO:0003740 abolished, fig1 d
PMID:19217404 FYPO:0003740 abolished, fig1 d
PMID:19217404 FYPO:0003740 abolished, fig1 d
PMID:19217404 PBO:0099221 fig S10
PMID:19217404 FYPO:0003740 abolished, fig1 d
PMID:19217404 FYPO:0003740 abolished, fig1 d
PMID:19250904 PBO:0093619 same as either single mutant
PMID:19250904 GO:0042393 assayed using purified HeLa histone octamers
PMID:19250904 PBO:0093629 same as either single mutant
PMID:19250904 PBO:0093619 same as either single mutant
PMID:19250904 PBO:0093629 same as either single mutant
PMID:19250904 PBO:0093629 same as either single mutant
PMID:19250904 PBO:0093619 same as either single mutant
PMID:19250904 PBO:0093629 same as either single mutant
PMID:19250904 PBO:0093620 same as either single mutant
PMID:19250904 PBO:0093619 same as either single mutant
PMID:19250904 PBO:0093630 same as either single mutant
PMID:19279143 GO:1902413 Notably, Pmk1, the mitogen-activated protein kinase (MAPK), which regulates cell integrity (Toda et al., 1996; Sugiura et al., 1999; Sugiura et al., 2003), directly phosphorylates Nrd1, thereby negatively regulating the ac- tivity of Nrd1 to bind to and stabilize Cdc4 mRNA. We propose that the MAPK-dependent phosphorylation of the RNA-binding protein Nrd1 may serve as a novel mechanism for the regulation of myosin mRNA and cytokinesis in fission yeast.
PMID:19279143 PBO:0105388 fig 4F
PMID:19279143 PBO:0105387 fig 4F
PMID:19279143 PBO:0105385 """Thus, Nrd1 di- rectly binds with Cdc4 mRNA in vivo and in vitro"""
PMID:19328067 PBO:0111290 positive regulation
PMID:19328067 PBO:0095887 (All at eng2 CDS)
PMID:19328067 PBO:0103631 (All at eng2 CDS)
PMID:19328067 PBO:0103633 "Mcs6 ""primes"" Rpb1 for phosphorylation by cdk9"
PMID:19328067 PBO:0095887 (All at eng2 CDS)
PMID:19328067 PBO:0103630 (All at eng2 CDS)
PMID:19328067 PBO:0103629 (All at eng2 CDS)
PMID:19330768 FYPO:0004588 G2 temperature shift
PMID:19330768 FYPO:0000802 in arrested cells, indicating independent of cell cycle progression
PMID:19330768 FYPO:0000141 G1 temperature shift
PMID:1934126 FYPO:0000681 same as cdc25-22 single mutant
PMID:1934126 FYPO:0000681 same as cdc25-22 single mutant
PMID:1934126 FYPO:0000681 same as cdc25-22 single mutant
PMID:1934126 FYPO:0000681 same as cdc25-22 single mutant
PMID:19357077 PBO:0111600 Activation of Cds1 requires the recruitment by Mrc1 and subsequent phosphorylation of threonine 11 by Rad3. Phosphorylation of threonine 11 promotes homodimerization of Cds1, which facilitates the autophosphorylation of threonine 328 in the kinase domains of the dimer partners. Phosphorylation of threonine 328 directly activates Cds1. The kinase activity of Cds1 is low during a normal cell cycle. However, it increases dramatically during a perturbed S phase.
PMID:19362535 PBO:0111582 e. Interestingly, the Chp1 chromodomain bound both H3K9me2 and H3K9me3 peptides with significantly higher affinity than either Clr4 or Swi6 (Table 1), and all proteins bound H3K9me3 more tightly than H3K9me2. ||we solved the crystal structure of the Chp1 chromodomain (CD) in complex with an H3K9me3 peptide (Figure 1C; Table 2).
PMID:19362535 PBO:0101959 The efficiency of chromosome segregation was also monitored in clr4+ reintroduction chp1 mutant cells (Table S4) and closely correlated with Chp1’s binding efficiency. Mutants with >5-fold reduction in H3K9me-binding efficiency that cannot establish centromeric heterochromatin exhibited elevated rates of chromosome missegregation.
PMID:19362535 PBO:0112173 The observed affinities ranged from close to wild-type to complete loss of specific binding. The F61A mutant showed little reduction in binding affinity compared with wild-type Chp1. A
PMID:19362535 PBO:0112174 TheSwi6 V82E mutant bound H3K9me2 with 5-fold higher affinity than wild-type Swi6 (Table 1; Figure S2A),
PMID:19362535 PBO:0112175 Introduction of an E80V mutation, corresponding to V21 of Chp1, into Swi6V82E further increased Swi6’s affinity by 2-fold (Table 1; Figure S2A).
PMID:19362535 FYPO:0002835 . While chp1D and chp1CDD cells lack centromeric siRNAs, they were present in all other mutants with the exception of V24R.
PMID:19362535 FYPO:0004742 . Interestingly, cells expressing most of the mutant alleles of chp1 showed no defect in heterochromatin assembly as measured in this assay (Figure 3A), with the exception of the double mutant E23V; V24M and the V24R chp1 mutant, which did show silencing defects.
PMID:19362535 FYPO:0004742 . Interestingly, cells expressing most of the mutant alleles of chp1 showed no defect in heterochromatin assembly as measured in this assay (Figure 3A), with the exception of the double mutant E23V; V24M and the V24R chp1 mutant, which did show silencing defects.
PMID:19362535 FYPO:0003412 . Interestingly, cells expressing most of the mutant alleles of chp1 showed no defect in heterochromatin assembly as measured in this assay (Figure 3A), with the exception of the double mutant E23V; V24M and the V24R chp1 mutant, which did show silencing defects.
PMID:19362535 FYPO:0003412 . Interestingly, cells expressing most of the mutant alleles of chp1 showed no defect in heterochromatin assembly as measured in this assay (Figure 3A), with the exception of the double mutant E23V; V24M and the V24R chp1 mutant, which did show silencing defects.
PMID:19362535 PBO:0111405 The efficiency of chromosome segregation was also monitored in clr4+ reintroduction chp1 mutant cells (Table S4) and closely correlated with Chp1’s binding efficiency. Mutants with >5-fold reduction in H3K9me-binding efficiency that cannot establish centromeric heterochromatin exhibited elevated rates of chromosome missegregation.
PMID:19362535 FYPO:0002837 Surprisingly, when we monitored the presence of centromeric siRNAs in these clr4+ reintroduction strains, we found that even mutants that were defective for establishment of centromeric heterochromatin efficiently synthesized siRNAs derived from both the dg and dh centromeric repeats (Figure 5C)
PMID:19362535 FYPO:0002837 Surprisingly, when we monitored the presence of centromeric siRNAs in these clr4+ reintroduction strains, we found that even mutants that were defective for establishment of centromeric heterochromatin efficiently synthesized siRNAs derived from both the dg and dh centromeric repeats (Figure 5C)
PMID:19362535 PBO:0111398 Results for Chp1 localization were similar to those seen in maintenance strains with mutants such as E23Vchp1clr4D to clr4+ and V24Mchp1clr4D to clr4+ showing little association with centromeres, whereas F61Achp1clr4D to clr4+ was enriched at levels close to wild-type Chp1clr4D to clr4+
PMID:19362535 PBO:0111398 Results for Chp1 localization were similar to those seen in maintenance strains with mutants such as E23Vchp1clr4D to clr4+ and V24Mchp1clr4D to clr4+ showing little association with centromeres, whereas F61Achp1clr4D to clr4+ was enriched at levels close to wild-type Chp1clr4D to clr4+
PMID:19362535 PBO:0111406 Results for Chp1 localization were similar to those seen in maintenance strains with mutants such as E23Vchp1clr4D to clr4+ and V24Mchp1clr4D to clr4+ showing little association with centromeres, whereas F61Achp1clr4D to clr4+ was enriched at levels close to wild-type Chp1clr4D to clr4+
PMID:19362535 PBO:0111407 centromeric H3K9me2 levels were low in many of the chp1 chromodomain clr4+ reintroduction strains and closely mirrored the levels of Chp1 recruitment in the various centromeric H3K9me2 levels were low in many of the chp1 chromodomain clr4+ reintroduction strains and closely mirrored the levels of Chp1 recruitment in the various mutant backgrounds (Figure 6B).
PMID:19362535 PBO:0111407 centromeric H3K9me2 levels were low in many of the chp1 chromodomain clr4+ reintroduction strains and closely mirrored the levels of Chp1 recruitment in the various centromeric H3K9me2 levels were low in many of the chp1 chromodomain clr4+ reintroduction strains and closely mirrored the levels of Chp1 recruitment in the various mutant backgrounds (Figure 6B).
PMID:19362535 PBO:0111407 centromeric H3K9me2 levels were low in many of the chp1 chromodomain clr4+ reintroduction strains and closely mirrored the levels of Chp1 recruitment in the various centromeric H3K9me2 levels were low in many of the chp1 chromodomain clr4+ reintroduction strains and closely mirrored the levels of Chp1 recruitment in the various mutant backgrounds (Figure 6B).
PMID:19362535 PBO:0111408 centromeric H3K9me2 levels were low in many of the chp1 chromodomain clr4+ reintroduction strains and closely mirrored the levels of Chp1 recruitment in the various centromeric H3K9me2 levels were low in many of the chp1 chromodomain clr4+ reintroduction strains and closely mirrored the levels of Chp1 recruitment in the various mutant backgrounds (Figure 6B).
PMID:19362535 PBO:0111408 High copy expression of clr4+ in the E23Vchp1clr4D and in the V24Mchp1clr4D cells allowed efficient establishment of centromeric heterochromatin (Figure 6C). Thus, the establishment defect of chp1 mutants with reduced H3K9me-binding affinity can be compensated by an increased dosage of clr4+ .
PMID:19362535 PBO:0111408 High copy expression of clr4+ in the E23Vchp1clr4D and in the V24Mchp1clr4D cells allowed efficient establishment of centromeric heterochromatin (Figure 6C). Thus, the establishment defect of chp1 mutants with reduced H3K9me-binding affinity can be compensated by an increased dosage of clr4+ .
PMID:19362535 PBO:0108963 e. Interestingly, the Chp1 chromodomain bound both H3K9me2 and H3K9me3 peptides with significantly higher affinity than either Clr4 or Swi6 (Table 1), and all proteins bound H3K9me3 more tightly than H3K9me2. || we solved the crystal structure of the Chp1 chromodomain (CD) in complex with an H3K9me3 peptide (Figure 1C; Table 2). S10 of histone H3 is phosphorylated during mitosis and displaces HP1 proteins (including Swi6) from chromatin (Fischle et al., 2005; Hirota et al., 2005; Yamada et al., 2005). We investigated whether binding of Swi6 and Chp1 to H3K9me peptides was affected by S10 phosphorylation and found a strong reduction in both Chp1- and Swi6-binding affinity (Table S2; Figure S2B),
PMID:19362535 PBO:0108963 e. Interestingly, the Chp1 chromodomain bound both H3K9me2 and H3K9me3 peptides with significantly higher affinity than either Clr4 or Swi6 (Table 1), and all proteins bound H3K9me3 more tightly than H3K9me2. || we solved the crystal structure of the Chp1 chromodomain (CD) in complex with an H3K9me3 peptide (Figure 1C; Table 2).S10 of histone H3 is phosphorylated during mitosis and displaces HP1 proteins (including Swi6) from chromatin (Fischle et al., 2005; Hirota et al., 2005; Yamada et al., 2005). We investigated whether binding of Swi6 and Chp1 to H3K9me peptides was affected by S10 phosphorylation and found a strong reduction in both Chp1- and Swi6-binding affinity (Table S2; Figure S2B),
PMID:19362535 PBO:0108963 e. Interestingly, the Chp1 chromodomain bound both H3K9me2 and H3K9me3 peptides with significantly higher affinity than either Clr4 or Swi6 (Table 1), and all proteins bound H3K9me3 more tightly than H3K9me2. || we solved the crystal structure of the Chp1 chromodomain (CD) in complex with an H3K9me3 peptide (Figure 1C; Table 2).S10 of histone H3 is phosphorylated during mitosis and displaces HP1 proteins (including Swi6) from chromatin (Fischle et al., 2005; Hirota et al., 2005; Yamada et al., 2005). We investigated whether binding of Swi6 and Chp1 to H3K9me peptides was affected by S10 phosphorylation and found a strong reduction in both Chp1- and Swi6-binding affinity (Table S2; Figure S2B),
PMID:19362535 PBO:0094684 .High levels of centromeric transcripts also accumulated in these establishment-defective clr4+ reintroduction strains E23Vchp1clr4D to clr4+, V24Mchp1clr4D to clr4+, and N59Achp1clr4D to clr4+, but not in the establishment-competent F61Achp1clr4D to clr4+ cells (Figure 5B; Figure S9A)
PMID:19362535 FYPO:0004982 . Interestingly, cells expressing most of the mutant alleles of chp1 showed no defect in heterochromatin assembly as measured in this assay (Figure 3A), with the exception of the double mutant E23V; V24M and the V24R chp1 mutant, which did show silencing defects.
PMID:19362535 PBO:0111396 Unlike chp1 null cells, which showed 23% of mitotic cells undergoing chromosome missegregation, the chromodomain point-mutated strains, with the exception of V24Rchp1, showed few cells undergoing aberrant mitoses (Table S3).
PMID:19362535 FYPO:0002835 . While chp1D and chp1CDD cells lack centromeric siRNAs, they were present in all other mutants with the exception of V24R.
PMID:19362535 FYPO:0002835 . While chp1D and chp1CDD cells lack centromeric siRNAs, they were present in all other mutants with the exception of V24R.
PMID:19362535 FYPO:0002835 . While chp1D and chp1CDD cells lack centromeric siRNAs, they were present in all other mutants with the exception of V24R.
PMID:19362535 FYPO:0002837 . While chp1D and chp1CDD cells lack centromeric siRNAs, they were present in all other mutants with the exception of V24R.
PMID:19362535 PBO:0112172 A second class of mutants showed a 5- to 17-fold reduction in binding affinity for H3K9me2 compared with the wild-type Chp1 chromodomain (V21A, E23V, N59A, and V24M). A
PMID:19362535 PBO:0112172 A second class of mutants showed a 5- to 17-fold reduction in binding affinity for H3K9me2 compared with the wild-type Chp1 chromodomain (V21A, E23V, N59A, and V24M). A
PMID:19362535 PBO:0112172 A second class of mutants showed a 5- to 17-fold reduction in binding affinity for H3K9me2 compared with the wild-type Chp1 chromodomain (V21A, E23V, N59A, and V24M). A
PMID:19362535 PBO:0112172 A second class of mutants showed a 5- to 17-fold reduction in binding affinity for H3K9me2 compared with the wild-type Chp1 chromodomain (V21A, E23V, N59A, and V24M). A
PMID:19362535 PBO:0112171 *A third class showed a more profound reduction in binding affinity: the E23V,V24M mutant reduced binding affinity 40 fold,
PMID:19362535 FYPO:0003431 , and the V24R mutant abolished the specificity of the chromodomain interaction for K9 methylated peptides (Kd > 500 mM).
PMID:19362535 PBO:0111665 e. Interestingly, the Chp1 chromodomain bound both H3K9me2 and H3K9me3 peptides with significantly higher affinity than either Clr4 or Swi6 (Table 1), and all proteins bound H3K9me3 more tightly than H3K9me2. || we solved the crystal structure of the Chp1 chromodomain (CD) in complex with an H3K9me3 peptide (Figure 1C; Table 2).S10 of histone H3 is phosphorylated during mitosis and displaces HP1 proteins (including Swi6) from chromatin (Fischle et al., 2005; Hirota et al., 2005; Yamada et al., 2005). We investigated whether binding of Swi6 and Chp1 to H3K9me peptides was affected by S10 phosphorylation and found a strong reduction in both Chp1- and Swi6-binding affinity (Table S2; Figure S2B),
PMID:19362535 PBO:0111665 e. Interestingly, the Chp1 chromodomain bound both H3K9me2 and H3K9me3 peptides with significantly higher affinity than either Clr4 or Swi6 (Table 1), and all proteins bound H3K9me3 more tightly than H3K9me2. || we solved the crystal structure of the Chp1 chromodomain (CD) in complex with an H3K9me3 peptide (Figure 1C; Table 2).S10 of histone H3 is phosphorylated during mitosis and displaces HP1 proteins (including Swi6) from chromatin (Fischle et al., 2005; Hirota et al., 2005; Yamada et al., 2005). We investigated whether binding of Swi6 and Chp1 to H3K9me peptides was affected by S10 phosphorylation and found a strong reduction in both Chp1- and Swi6-binding affinity (Table S2; Figure S2B),
PMID:19362535 PBO:0111665 e. Interestingly, the Chp1 chromodomain bound both H3K9me2 and H3K9me3 peptides with significantly higher affinity than either Clr4 or Swi6 (Table 1), and all proteins bound H3K9me3 more tightly than H3K9me2. || we solved the crystal structure of the Chp1 chromodomain (CD) in complex with an H3K9me3 peptide (Figure 1C; Table 2). S10 of histone H3 is phosphorylated during mitosis and displaces HP1 proteins (including Swi6) from chromatin (Fischle et al., 2005; Hirota et al., 2005; Yamada et al., 2005). We investigated whether binding of Swi6 and Chp1 to H3K9me peptides was affected by S10 phosphorylation and found a strong reduction in both Chp1- and Swi6-binding affinity (Table S2; Figure S2B),
PMID:19362535 PBO:0111583 e. Interestingly, the Chp1 chromodomain bound both H3K9me2 and H3K9me3 peptides with significantly higher affinity than either Clr4 or Swi6 (Table 1), and all proteins bound H3K9me3 more tightly than H3K9me2. || we solved the crystal structure of the Chp1 chromodomain (CD) in complex with an H3K9me3 peptide (Figure 1C; Table 2).
PMID:19362535 PBO:0111584 e. Interestingly, the Chp1 chromodomain bound both H3K9me2 and H3K9me3 peptides with significantly higher affinity than either Clr4 or Swi6 (Table 1), and all proteins bound H3K9me3 more tightly than H3K9me2. || we solved the crystal structure of the Chp1 chromodomain (CD) in complex with an H3K9me3 peptide (Figure 1C; Table 2).
PMID:19362535 FYPO:0002835 . While chp1D and chp1CDD cells lack centromeric siRNAs, they were present in all other mutants with the exception of V24R.
PMID:19362535 FYPO:0003099 *******reassembly/nucleation********* Reintegration of clr4+ into cells bearing the chp1 chromodomain mutants showed a striking separation of phenotypes, with some mutants unable to re-establish centromeric heterochromatin (e.g., E23Vchp1clr4D to clr4+, V24Mchp1clr4D to clr4+, and N59Achp1clr4D to clr4+) and others showing efficient re-establishment (e.g., F61Achp1clr4D to clr4+), as assessed by silencing of the cen::ura4+ transgene (Figure 5A).
PMID:19362535 FYPO:0003099 *******reassembly/nucleation********* Reintegration of clr4+ into cells bearing the chp1 chromodomain mutants showed a striking separation of phenotypes, with some mutants unable to re-establish centromeric heterochromatin (e.g., E23Vchp1clr4D to clr4+, V24Mchp1clr4D to clr4+, and N59Achp1clr4D to clr4+) and others showing efficient re-establishment (e.g., F61Achp1clr4D to clr4+), as assessed by silencing of the cen::ura4+ transgene (Figure 5A).
PMID:19362535 PBO:0111400 *******abolished /de novo******* Reintegration of clr4+ into cells bearing the chp1 chromodomain mutants showed a striking separation of phenotypes, with some mutants unable to re-establish centromeric heterochromatin (e.g., E23Vchp1clr4D to clr4+, V24Mchp1clr4D to clr4+, and N59Achp1clr4D to clr4+) and others showing efficient re-establishment (e.g., F61Achp1clr4D to clr4+), as assessed by silencing of the cen::ura4+ transgene (Figure 5A).
PMID:19362535 PBO:0111400 *******abolished /de novo*******. Reintegration of clr4+ into cells bearing the chp1 chromodomain mutants showed a striking separation of phenotypes, with some mutants unable to re-establish centromeric heterochromatin (e.g., E23Vchp1clr4D to clr4+, V24Mchp1clr4D to clr4+, and N59Achp1clr4D to clr4+) and others showing efficient re-establishment (e.g., F61Achp1clr4D to clr4+), as assessed by silencing of the cen::ura4+ transgene (Figure 5A).
PMID:19362535 PBO:0111400 ******abolished /de novo********** Reintegration of clr4+ into cells bearing the chp1 chromodomain mutants showed a striking separation of phenotypes, with some mutants unable to re-establish centromeric heterochromatin (e.g., E23Vchp1clr4D to clr4+, V24Mchp1clr4D to clr4+, and N59Achp1clr4D to clr4+) and others showing efficient re-establishment (e.g., F61Achp1clr4D to clr4+), as assessed by silencing of the cen::ura4+ transgene (Figure 5A).
PMID:19362535 FYPO:0004742 d loss of maintenance of heterochromatin was seen in cells expressing both Tas3WG and E23Vchp1, unlike cells expressing either single mutant
PMID:19362535 FYPO:0007334 d loss of maintenance of heterochromatin was seen in cells expressing both Tas3WG and E23Vchp1, unlike cells expressing either single mutant
PMID:19362535 FYPO:0007334 d loss of maintenance of heterochromatin was seen in cells expressing both Tas3WG and E23Vchp1, unlike cells expressing either single mutant
PMID:19362535 FYPO:0007334 d loss of maintenance of heterochromatin was seen in cells expressing both Tas3WG and E23Vchp1, unlike cells expressing either single mutant
PMID:19362535 FYPO:0004742 + . In contrast, the F61Achp1; F276Aago1 mutant strain showed no defect in the silencing of the reporter (Figure 4D).
PMID:19362535 FYPO:0007334 . We found, however, that introduction of F276Aago1 into either the E23Vchp1 or V24Mchp1 mutants resulted in loss of silencing of cen::ura4+ .
PMID:19362535 FYPO:0002837 . While chp1D and chp1CDD cells lack centromeric siRNAs, they were present in all other mutants with the exception of V24R.
PMID:19362535 FYPO:0007334 . We found, however, that introduction of F276Aago1 into either the E23Vchp1 or V24Mchp1 mutants resulted in loss of silencing of cen::ura4+ .
PMID:19362535 FYPO:0007334 . We found, however, that introduction of F276Aago1 into either the E23Vchp1 or V24Mchp1 mutants resulted in loss of silencing of cen::ura4+ .
PMID:19362535 FYPO:0007334 . We found, however, that introduction of F276Aago1 into either the E23Vchp1 or V24Mchp1 mutants resulted in loss of silencing of cen::ura4+ .
PMID:19362535 FYPO:0008070 , unlike chp1 null cells, there was no significant decrease in centromeric H3K9me2 or Swi6 association in any of the chp1 mutants tested (Figures 4B and 4C; Figure S5B).
PMID:19362535 FYPO:0008070 , unlike chp1 null cells, there was no significant decrease in centromeric H3K9me2 or Swi6 association in any of the chp1 mutants tested (Figures 4B and 4C; Figure S5B).
PMID:19362535 FYPO:0008070 , unlike chp1 null cells, there was no significant decrease in centromeric H3K9me2 or Swi6 association in any of the chp1 mutants tested (Figures 4B and 4C; Figure S5B).
PMID:19362535 FYPO:0008070 , unlike chp1 null cells, there was no significant decrease in centromeric H3K9me2 or Swi6 association in any of the chp1 mutants tested (Figures 4B and 4C; Figure S5B).
PMID:19362535 FYPO:0008070 , unlike chp1 null cells, there was no significant decrease in centromeric H3K9me2 or Swi6 association in any of the chp1 mutants tested (Figures 4B and 4C; Figure S5B).
PMID:19362535 FYPO:0008070 , unlike chp1 null cells, there was no significant decrease in centromeric H3K9me2 or Swi6 association in any of the chp1 mutants tested (Figures 4B and 4C; Figure S5B).
PMID:19362535 FYPO:0002837 . While chp1D and chp1CDD cells lack centromeric siRNAs, they were present in all other mutants with the exception of V24R.
PMID:19362535 FYPO:0002837 . While chp1D and chp1CDD cells lack centromeric siRNAs, they were present in all other mutants with the exception of V24R.
PMID:19362535 FYPO:0002837 . While chp1D and chp1CDD cells lack centromeric siRNAs, they were present in all other mutants with the exception of V24R.
PMID:19362535 FYPO:0008070 , unlike chp1 null cells, there was no significant decrease in centromeric H3K9me2 or Swi6 association in any of the chp1 mutants tested (Figures 4B and 4C; Figure S5B).
PMID:19362535 FYPO:0002837 . While chp1D and chp1CDD cells lack centromeric siRNAs, they were present in all other mutants with the exception of V24R.
PMID:19362535 FYPO:0004201 . While chp1D and chp1CDD cells lack centromeric siRNAs, they were present in all other mutants with the exception of V24R.
PMID:19362535 PBO:0111397 Surprisingly, in contrast to robust association of wild-type Chp1 at the centromeric outer repeat sites, we found only very low levels of many of the mutant Chp1 proteins at centromeres under our standard ChIP conditions (Figure 4A and Figure S5A)
PMID:19362535 PBO:0111013 Surprisingly, in contrast to robust association of wild-type Chp1 at the centromeric outer repeat sites, we found only very low levels of many of the mutant Chp1 proteins at centromeres under our standard ChIP conditions (Figure 4A and Figure S5A)
PMID:19362535 PBO:0111399 Surprisingly, in contrast to robust association of wild-type Chp1 at the centromeric outer repeat sites, we found only very low levels of many of the mutant Chp1 proteins at centromeres under our standard ChIP conditions (Figure 4A and Figure S5A)
PMID:19362535 PBO:0111399 Surprisingly, in contrast to robust association of wild-type Chp1 at the centromeric outer repeat sites, we found only very low levels of many of the mutant Chp1 proteins at centromeres under our standard ChIP conditions (Figure 4A and Figure S5A)
PMID:19362535 PBO:0111398 Surprisingly, in contrast to robust association of wild-type Chp1 at the centromeric outer repeat sites, we found only very low levels of many of the mutant Chp1 proteins at centromeres under our standard ChIP conditions (Figure 4A and Figure S5A)
PMID:19362535 PBO:0111398 Surprisingly, in contrast to robust association of wild-type Chp1 at the centromeric outer repeat sites, we found only very low levels of many of the mutant Chp1 proteins at centromeres under our standard ChIP conditions (Figure 4A and Figure S5A)
PMID:19362535 PBO:0111398 Surprisingly, in contrast to robust association of wild-type Chp1 at the centromeric outer repeat sites, we found only very low levels of many of the mutant Chp1 proteins at centromeres under our standard ChIP conditions (Figure 4A and Figure S5A)
PMID:19362535 PBO:0111398 Surprisingly, in contrast to robust association of wild-type Chp1 at the centromeric outer repeat sites, we found only very low levels of many of the mutant Chp1 proteins at centromeres under our standard ChIP conditions (Figure 4A and Figure S5A)
PMID:19362535 PBO:0111398 Surprisingly, in contrast to robust association of wild-type Chp1 at the centromeric outer repeat sites, we found only very low levels of many of the mutant Chp1 proteins at centromeres under our standard ChIP conditions (Figure 4A and Figure S5A)
PMID:19362535 PBO:0094684 .High levels of centromeric transcripts also accumulated in these establishment-defective clr4+ reintroduction strains E23Vchp1clr4D to clr4+, V24Mchp1clr4D to clr4+, and N59Achp1clr4D to clr4+, but not in the establishment-competent F61Achp1clr4D to clr4+ cells (Figure 5B; Figure S9A)
PMID:19362535 PBO:0094684 .High levels of centromeric transcripts also accumulated in these establishment-defective clr4+ reintroduction strains E23Vchp1clr4D to clr4+, V24Mchp1clr4D to clr4+, and N59Achp1clr4D to clr4+, but not in the establishment-competent F61Achp1clr4D to clr4+ cells (Figure 5B; Figure S9A)
PMID:19362535 PBO:0111401 The efficiency of chromosome segregation was also monitored in clr4+ reintroduction chp1 mutant cells (Table S4) and closely correlated with Chp1’s binding efficiency. Mutants with >5-fold reduction in H3K9me-binding efficiency that cannot establish centromeric heterochromatin exhibited elevated rates of chromosome missegregation.
PMID:19362535 PBO:0111402 The efficiency of chromosome segregation was also monitored in clr4+ reintroduction chp1 mutant cells (Table S4) and closely correlated with Chp1’s binding efficiency. Mutants with >5-fold reduction in H3K9me-binding efficiency that cannot establish centromeric heterochromatin exhibited elevated rates of chromosome missegregation.
PMID:19362535 PBO:0111403 The efficiency of chromosome segregation was also monitored in clr4+ reintroduction chp1 mutant cells (Table S4) and closely correlated with Chp1’s binding efficiency. Mutants with >5-fold reduction in H3K9me-binding efficiency that cannot establish centromeric heterochromatin exhibited elevated rates of chromosome missegregation.
PMID:19362535 PBO:0111404 The efficiency of chromosome segregation was also monitored in clr4+ reintroduction chp1 mutant cells (Table S4) and closely correlated with Chp1’s binding efficiency. Mutants with >5-fold reduction in H3K9me-binding efficiency that cannot establish centromeric heterochromatin exhibited elevated rates of chromosome missegregation.
PMID:19363481 FYPO:0001234 Figure 5
PMID:19363481 FYPO:0001234 Figure 5
PMID:19363481 FYPO:0001234 Figure 5
PMID:19363481 FYPO:0001234 Figure 5
PMID:19363481 FYPO:0002150 Figure 5
PMID:19363481 FYPO:0001234 Figure 5
PMID:19363481 FYPO:0002150 Figure 5
PMID:19363481 FYPO:0001234 Figure 5
PMID:19363481 FYPO:0001234 Figure 5
PMID:19363481 FYPO:0001234 Figure 5
PMID:19363481 FYPO:0001234 Figure 5
PMID:19363481 FYPO:0001234 Figure 5
PMID:19363481 FYPO:0001234 Figure 5
PMID:19363481 FYPO:0001234 Figure 5
PMID:19363481 FYPO:0001234 Figure 5
PMID:19363481 FYPO:0001234 Figure 5
PMID:19363481 FYPO:0000088 slow growth phenotype and heterogeneity in cell length; reflecting elevated levels of spontaneous DNA damage and “constitutive” activation of the DNA damage checkpoint in these cells (Fig. 4a and data not shown).
PMID:19363481 FYPO:0002150 Figure 5
PMID:19363481 FYPO:0002150 Figure 5
PMID:19363481 FYPO:0001355 slow growth phenotype and heterogeneity in cell length; reflecting elevated levels of spontaneous DNA damage and “constitutive” activation of the DNA damage checkpoint in these cells (Fig. 4a and data not shown).
PMID:19363481 PBO:0099529 slow growth phenotype and heterogeneity in cell length; reflecting elevated levels of spontaneous DNA damage and “constitutive” activation of the DNA damage checkpoint in these cells (Fig. 4a and data not shown).
PMID:19363481 PBO:0099528 Strikingly, a GST-Rad60 SLD2E380R construct did not detectably interact with Ubc9-TAP (Fig. 3a),
PMID:19363481 GO:0005515 SLD1
PMID:19366728 FYPO:0006518 fragmented
PMID:19366728 FYPO:0006518 fragmented
PMID:19366728 FYPO:0006518 fragmented
PMID:19366728 FYPO:0006518 fragmented
PMID:19366728 FYPO:0006518 fragmented
PMID:19366728 FYPO:0006518 fragmented
PMID:19366728 FYPO:0006518 fragmented
PMID:19366728 FYPO:0006518 fragmented
PMID:19366728 FYPO:0006518 fragmented
PMID:19366728 FYPO:0006518 fragmented
PMID:19366728 FYPO:0006518 fragmented
PMID:19366728 FYPO:0006518 fragmented
PMID:19366728 FYPO:0006518 fragmented
PMID:19373772 PBO:0019716 during mitotic M phase?
PMID:19373772 PBO:0019715 "happens during mitotic M phase? term will be renames ""mitochondrial membrane fission"""
PMID:19373772 FYPO:0000251 non fermentable carbon source
PMID:19373772 PBO:0019714 "happens during mitotic M phase? term will be renames ""mitochondrial membrane fission"""
PMID:19394293 FYPO:0005929 At the dg and dh repeats, we found a consistent 2- to 3-fold reduction in mutant Tas3 occupancy compared to wild-type (Figure 5B, compare lanes 3–6 with lane 2; and Figure 5C). Also, consistent with the otr1R::ura4+ silencing data (Figure 3B), mutant Tas3-TAM proteins associated with the ura4+ insert at otr1R less efficiently than wild-type Tas3 (Figure 5D, compare lanes 3–6 with lane 2; and Figure 5E). In
PMID:19394293 FYPO:0004205 To determine the effect of tas3-TAM mutations on cen siRNAs levels, we performed northern blot analysis on RNAs isolated from wild-type, tas3D, and tas3-TAM mutant cells. We found a dramatic reduction in the levels of both total (Figure 4C) and Ago1-purified (Figure 4D) cen siRNAs in all tas3-TAM mutants compared to wild-type.
PMID:19394293 FYPO:0004205 To determine the effect of tas3-TAM mutations on cen siRNAs levels, we performed northern blot analysis on RNAs isolated from wild-type, tas3D, and tas3-TAM mutant cells. We found a dramatic reduction in the levels of both total (Figure 4C) and Ago1-purified (Figure 4D) cen siRNAs in all tas3-TAM mutants compared to wild-type.
PMID:19394293 FYPO:0003411 Figure 3. tas3-TAM Mutations Cause a Dramatic Loss of ura4+ Silencing at imr1 but Only a Modest Loss at otr1 (A) Schematic diagram of S. pombe centromere (cen) 1. The
PMID:19394293 FYPO:0003411 Figure 3.
PMID:19394293 FYPO:0003411 Figure 3. tas3-TAM Mutations Cause a Dramatic Loss of ura4+ Silencing at imr1 but Only a Modest Loss at otr1 (A) Schematic diagram of S. pombe centromere (cen) 1. The
PMID:19394293 FYPO:0003411 Figure 3. tas3-TAM Mutations Cause a Dramatic Loss of ura4+ Silencing at imr1 but Only a Modest Loss at otr1 (A) Schematic diagram of S. pombe centromere (cen) 1. The
PMID:19394293 FYPO:0003411 Figure 3. tas3-TAM Mutations Cause a Dramatic Loss of ura4+ Silencing at imr1 but Only a Modest Loss at otr1 (A) Schematic diagram of S. pombe centromere (cen) 1. The
PMID:19394293 PBO:0101404 Figure 3. To rule out that the observed silencing defects were due to instability of the mutant Tas3 proteins, we examined the levels of wild-type and mutant Tas3 protein by western blotting and found that the mutant proteins were expressed to similar levels as the wild-type protein (Figure 3C).
PMID:19394293 PBO:0101404 (Figure 3C).
PMID:19394293 PBO:0101404 (Figure 3C).
PMID:19394293 PBO:0101404 (Figure 3C).
PMID:19394293 FYPO:0004205 To determine the effect of tas3-TAM mutations on cen siRNAs levels, we performed northern blot analysis on RNAs isolated from wild-type, tas3D, and tas3-TAM mutant cells. We found a dramatic reduction in the levels of both total (Figure 4C) and Ago1-purified (Figure 4D) cen siRNAs in all tas3-TAM mutants compared to wild-type.
PMID:19394293 FYPO:0008072 Surprisingly, we found no defect in H3K9me in tas3DTAM compared to wild-type cells at native centromeric repeats (dg1, imr1, imr2-1, or imr2-2) or the ura4+ inserts (for imr1R::ura4+,
PMID:19394293 FYPO:0004205 To determine the effect of tas3-TAM mutations on cen siRNAs levels, we performed northern blot analysis on RNAs isolated from wild-type, tas3D, and tas3-TAM mutant cells. We found a dramatic reduction in the levels of both total (Figure 4C) and Ago1-purified (Figure 4D) cen siRNAs in all tas3-TAM mutants compared to wild-type.
PMID:19394293 FYPO:0008073 We found that mutant proteins coimmunoprecipitated with Chp1 and FLAG-Ago1 with similar efficiency as the wild-type protein (Figures 4A and 4B, compare lane 1 with lanes 2–5). This result demonstrates that RITS complex formation is not affected in tas3-TAM mutants and that theCterminus of Tas3 is not involved in Chp1 or Ago1 binding (also shown in Partridge et al. [2007]).
PMID:19416828 FYPO:0003352 "RTS1 inversion background abolishes DSB formation; ""decreased"" level in rtf1-W405G is relative to wild type and above the inverted-RTS1 background level"
PMID:19417105 GO:0018444 figure 1
PMID:19417105 FYPO:0001645 (Fig. 5B)
PMID:19417105 FYPO:0001645 (Fig. 5B)
PMID:19417105 FYPO:0001645 (Fig. 5B)
PMID:19417105 FYPO:0001355 figure 5A
PMID:19417105 FYPO:0002061 figure 5A
PMID:19417105 FYPO:0001355 figure 5A
PMID:19417105 PBO:0102568 (Supplemental Table S1).
PMID:19417105 PBO:0102568 (Supplemental Table S1).
PMID:19417105 PBO:0102567 (Supplemental Table S1).
PMID:19417105 PBO:0102566 (Supplemental Table S1).
PMID:19417105 PBO:0102566 (Supplemental Table S1).
PMID:19417105 PBO:0102566 (Supplemental Table S1).
PMID:19417105 PBO:0102566 (Supplemental Table S1).
PMID:19417105 PBO:0102566 Supplemental Table S1; Supplemental Fig. S3
PMID:19417105 PBO:0102566 Supplemental Table S1; Supplemental Fig. S3
PMID:19417105 PBO:0102566 Supplemental Table S1; Supplemental Fig. S3
PMID:19417105 PBO:0102566 Supplemental Table S1; Supplemental Fig. S3
PMID:19417105 PBO:0102566 Supplemental Table S1; Supplemental Fig. S3
PMID:19417105 GO:0018444 figure 1
PMID:19422421 PBO:0103155 actually 25 degrees, but calling it low to make distinction from inviable at 30
PMID:19422421 GO:0000785 increased chromatin association in presence of HU
PMID:19422421 PBO:0093580 25 degrees (permissive for hsk1-89)
PMID:19422421 PBO:0093561 25 degrees (permissive for hsk1-89)
PMID:19422421 PBO:0093629 25 degrees (permissive for hsk1-89)
PMID:19422421 PBO:0093616 25 degrees (permissive for hsk1-89)
PMID:19422421 FYPO:0001357 actually 25 degrees, but calling it low to make distinction from inviable at 30
PMID:19422421 FYPO:0002061 30 degrees
PMID:19422421 PBO:0093631 25 degrees, but calling it low to make distinction from inviable at 30
PMID:19422421 PBO:0093581 25 degrees, but calling it low to make distinction from inviable at 30
PMID:19422421 PBO:0093617 25 degrees, but calling it low to make distinction from inviable at 30
PMID:19422421 PBO:0103154 actually 25 degrees, but calling it low to make distinction from inviable at 30
PMID:19422421 PBO:0093559 25 degrees (permissive for hsk1-89)
PMID:19422421 PBO:0093580 25 degrees (permissive for hsk1-89)
PMID:19422421 PBO:0093616 25 degrees (permissive for hsk1-89)
PMID:19427212 PBO:0112446 Fig. 1C
PMID:19427212 PBO:0112445 Fig. 1B
PMID:19427212 PBO:0112445 Fig. 1B
PMID:19427212 PBO:0112445 Fig. 1B
PMID:19427212 PBO:0112445 Fig. 1B
PMID:19427212 PBO:0112285 Fig. 1B
PMID:19427212 PBO:0112453 Fig. 3A
PMID:19427212 PBO:0112455 Fig. 3C and D
PMID:19427212 PBO:0112454 Fig. 3C and D
PMID:19427212 PBO:0112449 Fig. 3B
PMID:19427212 PBO:0112449 Fig. 3B
PMID:19427212 PBO:0112452 Fig. 2D
PMID:19427212 PBO:0112451 Fig. 2D
PMID:19427212 PBO:0112450 Fig. 2B
PMID:19427212 PBO:0112287 Fig. 2B
PMID:19427212 PBO:0112449 Fig. 2B
PMID:19427212 PBO:0112446 Fig. 2C
PMID:19427212 PBO:0112446 Fig. 2C
PMID:19427212 PBO:0112447 Fig. 2C
PMID:19427212 PBO:0112448 Fig. 2C
PMID:19427212 PBO:0112447 Fig. 1C
PMID:19427212 PBO:0112285 Fig. 1B
PMID:19427212 PBO:0112285 Fig. 1B
PMID:19427212 PBO:0112456 Fig. 3C and D
PMID:19427212 PBO:0112457 We conclude that fission yeast cytokinesis uses two over- lapping mechanisms to position Mid1 at the central cortex. First, Cdr2 anchors Mid1 at the medial cortex during interphase through a physical interaction.
PMID:19427212 GO:1902408 Fig. 4
PMID:19430462 GO:0036450 urg1, gar2, act1, adh1, pof9 and hcn1 mRNAs were shown to be direct targets by cRACE sequence analysis.
PMID:19430466 PBO:0104404 Fig. 2j
PMID:19430466 GO:0008017 Fig. 2c
PMID:19430466 PBO:0104402 Fig. 1f ATP-dependent Supplementary Information, Movie 1)
PMID:19430466 PBO:0104403 Fig. 2d, lane 4
PMID:19430466 PBO:0104404 Fig. 2j
PMID:19430466 GO:0005872 homodimer
PMID:19431238 GO:0051285 ocalization independent of actin cytoskeleton (assayed using latrunculin A) and microtubule cytoskeleton (assayed using carbendazim)
PMID:19431238 GO:0005938 ocalization independent of actin cytoskeleton (assayed using latrunculin A) and microtubule cytoskeleton (assayed using carbendazim)
PMID:1943699 PBO:0098027 assay construct also has nt change G36C to distinguish from snu2+ transcript
PMID:1943699 PBO:0098027 assay construct also has nt change G36C to distinguish from snu2+ transcript
PMID:1943699 PBO:0106466 assay construct also has nt change G36C to distinguish from snu2+ transcript
PMID:1943699 PBO:0098027 assay construct also has nt change G36C to distinguish from snu2+ transcript
PMID:1943699 PBO:0098027 assay construct also has nt change G36C to distinguish from snu2+ transcript
PMID:1944266 FYPO:0001759 assayed substrate: rabbit muscle phosphorylase
PMID:19454013 PBO:0095500 Rad21
PMID:19454013 PBO:0095499 Rad21
PMID:19474789 PBO:0108328 Fig. 2a and Supplementary Fig. 3a
PMID:19474789 PBO:0103732 all data These data indi- cate that Pom1 functions in a dose-dependent manner to delay entry into mitosis through negative regulation of the Cdr2-Cdr1-Wee1 pathway. The pom1D size phenotype is not as severe as wee11 deletion, indicating that further Wee1 regulatory mechanisms are likely to be operating. We conclude that Pom1 is a potential functional link between polarized cell growth and mitotic entry by regulating these two processes.
PMID:19474789 PBO:0103729 Figure 4 d
PMID:19474789 PBO:0096314 Supplementary Table 2 These experiments support the pom1 gradient model, pom1 is delocalized in tea1 delete
PMID:19474789 PBO:0095711 Supplementary Table 2 These experiments support the pom1 gradient model, pom1 is delocalized in tea1 delete
PMID:19474789 PBO:0096312 Supplementary Table 2 These experiments support the pom1 gradient model, pom1 is delocalized in tea1 delete
PMID:19474789 PBO:0096311 Supplementary Table 2
PMID:19474789 PBO:0107661 all data These data indi- cate that Pom1 functions in a dose-dependent manner to delay entry into mitosis through negative regulation of the Cdr2-Cdr1-Wee1 pathway. The pom1D size phenotype is not as severe as wee11 deletion, indicating that further Wee1 regulatory mechanisms are likely to be operating. We conclude that Pom1 is a potential functional link between polarized cell growth and mitotic entry by regulating these two processes.
PMID:19474789 PBO:0108336 all data These data indi- cate that Pom1 functions in a dose-dependent manner to delay entry into mitosis through negative regulation of the Cdr2-Cdr1-Wee1 pathway. The pom1D size phenotype is not as severe as wee11 deletion, indicating that further Wee1 regulatory mechanisms are likely to be operating. We conclude that Pom1 is a potential functional link between polarized cell growth and mitotic entry by regulating these two processes.
PMID:19474789 GO:0031569 all data These data indi- cate that Pom1 functions in a dose-dependent manner to delay entry into mitosis through negative regulation of the Cdr2-Cdr1-Wee1 pathway. The pom1D size phenotype is not as severe as wee11 deletion, indicating that further Wee1 regulatory mechanisms are likely to be operating. We conclude that Pom1 is a potential functional link between polarized cell growth and mitotic entry by regulating these two processes.
PMID:19474789 PBO:0094619 Supplementary Fig. 10
PMID:19474789 PBO:0095711 fig3
PMID:19474789 PBO:0095711 fig3
PMID:19474789 PBO:0096314 fig3
PMID:19474789 PBO:0096314 fig3
PMID:19474789 PBO:0096312 fig3
PMID:19474789 PBO:0096314 fig3
PMID:19474789 PBO:0096314 fig3
PMID:19474789 PBO:0096314 fig3
PMID:19474789 PBO:0096314 fig3
PMID:19474789 PBO:0096314 fig3
PMID:19474789 PBO:0096314 fig3
PMID:19474789 PBO:0096311 fig3
PMID:19474789 PBO:0095712 fig3
PMID:19474789 PBO:0108335 Supplementary Figure S8
PMID:19474789 PBO:0108334 Supplementary Figure S8
PMID:19474789 PBO:0108333 Supplementary Figure S8
PMID:19474789 PBO:0108332 Supplementary Figure S8
PMID:19474789 PBO:0108331 Fig. 2a and Supplementary Fig. 3a
PMID:19474789 PBO:0108331 Fig. 2a and Supplementary Fig. 3a
PMID:19474789 PBO:0107426 Fig. 2a and Supplementary Fig. 3a
PMID:19474789 PBO:0107426 Fig. 2a and Supplementary Fig. 3a
PMID:19474789 PBO:0107426 Fig. 2a and Supplementary Fig. 3a
PMID:19474789 PBO:0107426 Fig. 2a and Supplementary Fig. 3a
PMID:19474789 PBO:0108330 Fig. 3a
PMID:19474789 PBO:0110567 Supplementary Fig. 6
PMID:19474789 PBO:0107817 Supplementary Fig. 6
PMID:19474789 PBO:0107428 Fig. 2a and Supplementary Fig. 3a
PMID:19474789 PBO:0107428 Fig. 2a and Supplementary Fig. 3a
PMID:19474789 PBO:0107817 Fig. 2a and Supplementary Fig. 3a
PMID:19474789 PBO:0024116 Fig. 2c,d,e
PMID:19474789 PBO:0018346 Fig. 2c,d,e
PMID:19474789 PBO:0018540 Fig. 2c,d,e
PMID:19474789 FYPO:0003481 Supplementary Table 1
PMID:19474789 PBO:0094428 Fig. 2a and Supplementary Fig. 3a
PMID:19474789 PBO:0108327 Fig. 2a and Supplementary Fig. 3a
PMID:19474789 PBO:0107426 Fig. 2a and Supplementary Fig. 3a
PMID:19474789 PBO:0107426 Fig. 2a and Supplementary Fig. 3a
PMID:19474789 PBO:0107426 Fig. 2a and Supplementary Fig. 3a
PMID:19474789 PBO:0018540 Fig 1 a,b
PMID:19474789 PBO:0018540 Fig 1 a,b
PMID:19474789 PBO:0018540 Fig 1 a,b
PMID:19474789 PBO:0018540 Fig. 1c and Supplementary Fig. 2a
PMID:19474792 PBO:0094966 table1
PMID:19474792 PBO:0096311 Table 1
PMID:19474792 FYPO:0003481 Table 1
PMID:19474792 FYPO:0001355 fig 1b
PMID:19474792 FYPO:0003481 Table 1
PMID:19474792 PBO:0103724 Table 1
PMID:19474792 FYPO:0003481 Table 1
PMID:19474792 PBO:0103724 Table 1
PMID:19474792 PBO:0094966 table1
PMID:19474792 PBO:0095712 table1
PMID:19474792 PBO:0095711 table1
PMID:19474792 PBO:0095712 table1
PMID:19474792 FYPO:0003481 Table 1
PMID:19474792 PBO:0096311 Table 1
PMID:19474792 FYPO:0003481 Table 1
PMID:19474792 PBO:0096311 Table 1
PMID:19474792 PBO:0096311 Table 1
PMID:19474792 PBO:0094966 table1
PMID:19474792 PBO:0094966 table1
PMID:19474792 PBO:0103725 fig 1d ie not blocked in g2
PMID:19474792 PBO:0103726 Fig. 1e Fig. 1f)
PMID:19474792 PBO:0103727 Fig. 1e in vitro link from epistastis and delayed cdc2 phosphorylation
PMID:19474792 PBO:0096180 fig 1g
PMID:19474792 GO:0051285 Supplementary Fig. 2
PMID:19474792 GO:0051285 Supplementary Fig. 2
PMID:19474792 PBO:0024047 Supplementary Fig. 3
PMID:19474792 PBO:0024047 Supplementary Fig. 3
PMID:19474792 PBO:0103728 Supplementary Fig. 4
PMID:19474792 PBO:0103729 Fig. 2a and data not shown
PMID:19474792 PBO:0103729 Fig. 2a and data not shown
PMID:19474792 PBO:0103729 Fig. 2a and data not shown
PMID:19474792 PBO:0103730 cortex
PMID:19474792 FYPO:0001355 fig 1b
PMID:19474792 FYPO:0001355 fig 1b
PMID:19474792 FYPO:0001357 or is this reduced with low exressivity?
PMID:19474792 FYPO:0003481 Table 1 and Fig. 2d
PMID:19474792 FYPO:0001234 Table 1 and Fig. 2d
PMID:19474792 PBO:0103731 Table 1 and Fig. 2d
PMID:19474792 FYPO:0003736 (Fig. 3b).
PMID:19474792 FYPO:0003736 (Fig. 3b).
PMID:19474792 FYPO:0003307 (Fig. 3b).
PMID:19474792 FYPO:0002516 (Fig. 3b).
PMID:19474792 FYPO:0003736 (Fig. 3b).
PMID:19474792 PBO:0103732 Fig. 1e in vitro link from epistastis and delayed cdc2 phosphorylation
PMID:19486165 FYPO:0000032 Figure 4 C
PMID:19486165 FYPO:0002720 Fig. 5B
PMID:19486165 FYPO:0000046 Fig. 5C
PMID:19486165 FYPO:0000046 Fig. 5C
PMID:19486165 FYPO:0000046 Fig. 5C
PMID:19486165 FYPO:0000086 Fig. 1A
PMID:19486165 FYPO:0001234 Fig. 1A
PMID:19486165 FYPO:0002061 Fig. 1A
PMID:19486165 FYPO:0002061 (data not shown).
PMID:19486165 FYPO:0000110 Fig. 1C
PMID:19486165 GO:0042175 Fig. 2A
PMID:19486165 GO:0005635 Fig. 2B
PMID:19486165 PBO:0093574 (Fig. 7B)
PMID:19486165 PBO:0093574 (Fig. 7B)
PMID:19486165 PBO:0093574 (Fig. 7B)
PMID:19486165 PBO:0097639 (Fig. 7B)
PMID:19486165 PBO:0097639 (Fig. 7B)
PMID:19486165 PBO:0097639 (Fig. 7B)
PMID:19486165 FYPO:0000110 figure 7 A
PMID:19486165 PBO:0097638 Fig. 6C
PMID:19486165 FYPO:0000650 (Fig. 4B)
PMID:19486165 FYPO:0002061 Figure 4 C
PMID:19486165 FYPO:0000046 Figure 4 C
PMID:19486165 FYPO:0002060 Fig. 5A
PMID:19487457 FYPO:0007426 Figure 1 and 2 We conclude that it is the new SPB that fails to activate and insert into the nuclear envelope in cut12.1 mutants.
PMID:19487457 FYPO:0007428 monopolar
PMID:19487457 GO:0140480 insertion
PMID:19487457 PBO:0107114 Surprisingly, in 50% (n = 79) of the cut12.1 cells that successfully completed mitosis, an efflux of the NLS-GFP–-Gal marker accompanied mitotic commitment (Fig. 7, C and D).
PMID:19487457 FYPO:0007426 Figure 1 and 2 We conclude that it is the new SPB that fails to activate and insert into the nuclear envelope in cut12.1 mutants.
PMID:19487457 PBO:0107111 gapped membrane distortions in the nuclear envelope of cut12.1 cells at 36°C (Fig. 3, A–D). 7D
PMID:19487457 PBO:0107111 (Fig. 4 C and Video 3)
PMID:19487457 FYPO:0007427 our ability to identify cells in which an active SPB had apparently lost its association with the membrane completely and fallen into the middle of the nucleus (Fig. 3 E) and the proximity of the SPB to these gaps in the membrane (Fig. 3, A–C).
PMID:19487457 FYPO:0007428 monopolar
PMID:19487457 FYPO:0007427 our ability to identify cells in which an active SPB had apparently lost its association with the membrane completely and fallen into the middle of the nucleus (Fig. 3 E) and the proximity of the SPB to these gaps in the membrane (Fig. 3, A–C).
PMID:19487461 FYPO:0006575 section titled MBF-dependent gene expression...these cells undergo G1 transcription, a seemingly normal Sphase (no region specific amplifications) and can only reinitiate replication once size per genome is minimal size.
PMID:19487461 PBO:0100211 Fig1G amount of tos1-GFP in nucleus is dependent on cdc10
PMID:19487461 PBO:0021770 Fig 1B
PMID:19487461 FYPO:0006822 Fig1A BrdU incorporation wee1-50 strain analysed at 32°C
PMID:19487461 FYPO:0001425 Fig5A
PMID:19523829 FYPO:0002638 increased dlocalization of mad2 to kinetochore
PMID:19543678 PBO:0099033 (Fig. 3)
PMID:19543678 PBO:0099032 (Fig. 3)
PMID:19543678 PBO:0099031 from PM (Fig. 3c
PMID:19546237 GO:0010971 during recovery from stress
PMID:19570908 FYPO:0005904 myo2
PMID:19570908 FYPO:0005904 myo2
PMID:19570908 PBO:0095205 25 degrees C, i.e. lower end of normal temp. range; penetrance higher at 29 degrees C
PMID:19570908 GO:1902404 request and use GO:new positive regulation of (MF) microfilament motor activity instead? depends on ancestry of motor activity branch
PMID:19571115 FYPO:0002060 Fig. 5B
PMID:19571115 PBO:0108193 fig1
PMID:19571115 PBO:0108195 fig5D
PMID:19571115 FYPO:0007572 Fig. 5a
PMID:19571115 FYPO:0000411 Fig. 5B
PMID:19571115 PBO:0108194 fig1
PMID:19592249 PBO:0095924 figure 2a abolished
PMID:19592249 PBO:0095921 figure 1a
PMID:19592249 GO:0090267 fig1
PMID:19592249 PBO:0095922 figure 1E apc complex binding
PMID:19592249 PBO:0095923 figure 1E apc complex binding
PMID:19592249 FYPO:0002638 figure2
PMID:19592249 FYPO:0002638 figure2
PMID:19592249 PBO:0095925 figure 2a abolished
PMID:19592249 GO:1902426 fig2
PMID:19592249 PBO:0095920 figure 1a
PMID:19605557 PBO:0100329 figure 6
PMID:19605557 FYPO:0007797 However, GII activity is significantly reduced in the microsomal fraction of GII cells (Figure 2B), suggesting that GII is involved in ER localization of GII
PMID:19605557 PBO:0100329 figure 6
PMID:19605557 GO:0106407 GII Is Required for an Efficient In Vitro Glucose Trimming from G2M9 and G1M9
PMID:19605557 PBO:0100329 figure 6
PMID:19605557 PBO:0100329 figure 6
PMID:19606211 SO:0001528 See Fig. 1
PMID:19606211 SO:0001531 Sequence LVIAMDQLNL mentioned in the text
PMID:19624755 PBO:0107025 fig5
PMID:19624755 PBO:0106298 localized to large endosomal structures
PMID:19624755 PBO:0093720 Dapl2 and Dapm1 cells were more sensitive when exposed to 34 °C or to 5 mM VPA com- pared with those of Dapl4 and Daps1 cells
PMID:19624755 PBO:0093720 Dapl2 and Dapm1 cells were more sensitive when exposed to 34 °C or to 5 mM VPA com- pared with those of Dapl4 and Daps1 cells
PMID:19624755 PBO:0106298 localized to large endosomal structures
PMID:19624755 PBO:0106298 localized to large endosomal structures
PMID:19624755 PBO:0107027 localized to large endosomal structures
PMID:19624755 GO:0005794 n wild-type cells, most of Krp1- red fluorescent protein (RFP) colocalized with GFP- Vrg4 (Fig. 7a), indicating that Krp1 mainly localized to the Golgi apparatus
PMID:19624755 PBO:0093641 (Fig. 2b) D-apl2 and D-apm1 cells was completely inhibited in the presence of FK506
PMID:19624755 PBO:0093558 Dapl2 and Dapm1 cells were more sensitive when exposed to 34 °C or to 5 mM VPA com- pared with those of Dapl4 and Daps1 cells
PMID:19624755 GO:0005794 n wild-type cells, most of Krp1- red fluorescent protein (RFP) colocalized with GFP- Vrg4 (Fig. 7a), indicating that Krp1 mainly localized to the Golgi apparatus
PMID:19624755 PBO:0106298 localized to large endosomal structures
PMID:19624755 PBO:0106298 localized to large endosomal structures
PMID:19624755 PBO:0093641 (Fig. 2b) D-apl2 and D-apm1 cells was completely inhibited in the presence of FK506
PMID:19624755 PBO:0093645 (Fig. 2b) whereas that of Dapl4 and Daps1 cells was partially inhibited
PMID:19624755 PBO:0093558 Dapl2 and Dapm1 cells were more sensitive when exposed to 34 °C or to 5 mM VPA com- pared with those of Dapl4 and Daps1 cells
PMID:19624755 PBO:0093558 Dapl2 and Dapm1 cells were more sensitive when exposed to 34 °C or to 5 mM VPA com- pared with those of Dapl4 and Daps1 cells
PMID:19624755 PBO:0106298 localized to large endosomal structures
PMID:19624755 PBO:0106298 localized to large endosomal structures
PMID:19624755 GO:0005768 Fig. 6a, wt, arrowheads
PMID:19624755 GO:0005794 Fig4. suggesting that the four adaptin subunits of the AP-1 complex are all localized to the Golgi ⁄ endosomes.
PMID:19624755 PBO:0107023 fig5
PMID:19624755 PBO:0107023 fig5
PMID:19624755 PBO:0107024 fig5
PMID:19624755 PBO:0107025 fig5
PMID:19624755 PBO:0107025 fig5
PMID:19624755 PBO:0107026 fig5
PMID:19624755 PBO:0107026 fig5
PMID:19624755 GO:0005886 Fig. 6a, wt, arrowheads
PMID:19625445 PBO:0033281 Fig 1
PMID:19625445 PBO:0101763 figure 4A IS THIS NORMAL OR EVEN HIGHER THAN WT? (this is higher than wis1DD-cpc2delet so must be increased
PMID:19625445 PBO:0099926 figure 4A IS THIS NORMAL OR EVEN HIGHER THAN WT?
PMID:19625445 PBO:0101762 figure 4A
PMID:19625445 PBO:0101761 Figure 3D
PMID:19625445 PBO:0095501 Fig 2D
PMID:19625445 PBO:0101760 Fig 2D
PMID:19625445 PBO:0101753 Fig 2A
PMID:19625445 PBO:0101759 Fig 2A
PMID:19625445 PBO:0101758 Fig 2B
PMID:19625445 PBO:0101757 Fig 2B
PMID:19625445 PBO:0101756 Fig 2A
PMID:19625445 PBO:0101764 Figure 3D
PMID:19625445 PBO:0101765 Figure 3D
PMID:19625445 PBO:0101766 Figure 3D
PMID:19625445 PBO:0101756 Fig 2B
PMID:19625445 PBO:0101756 Fig 2A
PMID:19625445 FYPO:0007520 Fig 2B
PMID:19625445 PBO:0101755 Fig 2A
PMID:19625445 PBO:0101752 fig 1D
PMID:19625445 PBO:0101752 fig 1D
PMID:19625445 PBO:0101751 fig 1D
PMID:19625445 PBO:0101751 fig 1D
PMID:19625445 PBO:0099872 Fig 1C
PMID:19625445 PBO:0099871 Fig 1C
PMID:19625445 FYPO:0007520 Fig 1 C
PMID:19625445 PBO:0101767 Figure 4B
PMID:19625445 PBO:0101768 Figure 4B
PMID:19625445 PBO:0101769 Figure 4B
PMID:19625445 PBO:0101770 Figure 4B
PMID:19625445 PBO:0101771 Figure 4B
PMID:19625445 PBO:0101772 Figure 4c
PMID:19625445 PBO:0101773 Figure 4c
PMID:19625445 PBO:0101774 Fig 2A
PMID:19625445 PBO:0101774 Fig 2A
PMID:19625445 PBO:0095212 Figure 5A
PMID:19625445 PBO:0101775 Figure 5A
PMID:19625445 PBO:0101776 Figure 5B
PMID:19625445 PBO:0094763 Figure 5B
PMID:19625445 PBO:0101777 Figure 5B
PMID:19625445 PBO:0101778 Figure 5B
PMID:19625445 PBO:0101779 figure 5D
PMID:19625445 PBO:0101780 figure 5D
PMID:19625445 PBO:0093612 figure 6a
PMID:19625445 PBO:0099902 figure 6a
PMID:19625445 PBO:0093612 figure 6a
PMID:19625445 PBO:0099902 figure 6a
PMID:19625445 FYPO:0001037 figure 6a
PMID:19625445 FYPO:0000961 figure 6a
PMID:19625445 PBO:0101754 Fig 2A
PMID:19625445 PBO:0101753 Fig 2A
PMID:19625445 PBO:0093577 figure 6a
PMID:19625445 PBO:0093576 figure 6a
PMID:19625445 PBO:0093578 figure 6a
PMID:19625445 PBO:0093578 figure 6a
PMID:19625445 PBO:0101781 figure 6c,d
PMID:19625445 PBO:0101782 Figure 7
PMID:19625445 PBO:0101783 Figure 7
PMID:19625445 PBO:0101784 Figure 7
PMID:19625445 FYPO:0002444 fig8
PMID:19625445 FYPO:0007525 fig8
PMID:19625445 PBO:0101785 fig9A
PMID:19625445 PBO:0097115 Figure 3D
PMID:19625445 PBO:0099872 Fig 1C
PMID:19625445 PBO:0099872 Fig 1C
PMID:19625445 PBO:0032799 Fig 1
PMID:19625445 PBO:0101750 Fig 1
PMID:19625445 PBO:0101750 Fig 1
PMID:19625445 FYPO:0000223 Fig 1
PMID:19625445 FYPO:0002106 Fig 1 IS THIS SMALL OR STUBBY? 11.6 +/- 0.45
PMID:19625445 PBO:0101750 Fig 1 16.5 +/- 0.78
PMID:19625445 PBO:0097115 Figure 9B
PMID:19625445 PBO:0101786 Figure 9B
PMID:19625445 PBO:0095212 Figure 9
PMID:19625445 PBO:0101775 Figure9
PMID:19627505 GO:0070867 localization requires F-actin (assayed using latrunculin A) and membrane rafts (assayed using filipin)
PMID:19636559 FYPO:0004481 not shown, from text
PMID:19636559 PBO:0103845 not shown, from text
PMID:19636559 PBO:0103845 not shown, from text
PMID:19643199 FYPO:0001423 fig 1 d this term should really be trafficing
PMID:19643199 FYPO:0001423 fig 1 d
PMID:19643199 PBO:0095556 fig 1 c
PMID:19643199 FYPO:0006266 fig 1 d
PMID:19646873 PBO:0095264 2f
PMID:19646873 PBO:0105342 2f
PMID:19646873 PBO:0105341 2f
PMID:19646873 PBO:0095264 S2
PMID:19646873 PBO:0105340 2f
PMID:19680287 PBO:0096315 Fig. 1B, S3
PMID:19680287 FYPO:0003762 Fig. 1A
PMID:19680287 FYPO:0004318 Fig. 1A
PMID:19680287 FYPO:0004318 Fig. 1A
PMID:19680287 FYPO:0004318 Fig. 1A
PMID:19680287 FYPO:0004318 Fig. 1A
PMID:19680287 FYPO:0006428 (Fig 3C), showed a similar fraction of mono-oriented chromosomes as wild-type cells
PMID:19680287 PBO:0105460 Fig. 3B/C moved down from congresssion to abnormal mitotic sister chromatid biorientation ?
PMID:19680287 FYPO:0004396 Fig. S10
PMID:19680287 PBO:0105461 Fig. 3B/C. SEE ABOVE
PMID:19680287 PBO:0105462 Fig. 3B/C
PMID:19680287 PBO:0105463 Fig. 3E
PMID:19680287 PBO:0105464 Fig. 3E
PMID:19680287 PBO:0105464 Fig. 3E
PMID:19680287 PBO:0105465 Fig. 3E, S9
PMID:19680287 PBO:0105466 Fig. S7
PMID:19680287 PBO:0105459 Fig. 2B
PMID:19680287 PBO:0037150 Fig. 2B
PMID:19680287 FYPO:0005684 Fig. 2A assayed with plo1 GFP
PMID:19680287 PBO:0096323 Fig. S6C/D
PMID:19680287 PBO:0096323 Fig. S6C/D
PMID:19680287 PBO:0096322 Fig. S6A/B
PMID:19680287 FYPO:0003762 Fig. S2B
PMID:19680287 FYPO:0004318 Fig. S2B
PMID:19680287 FYPO:0004318 Fig. S2B
PMID:19680287 FYPO:0003762 Fig. S2A
PMID:19680287 FYPO:0004318 Fig. S2A
PMID:19680287 FYPO:0004318 Fig. S2A
PMID:19680287 PBO:0096322 Fig. 1B, S3
PMID:19680287 PBO:0105465 Fig. 3E, S9
PMID:19680287 PBO:0105458 Fig. 1B, S3
PMID:19680287 PBO:0096316 Fig. 1B, S3
PMID:19680287 FYPO:0005720 rarely showed a delay in bi-orienting chromosomes that had been pulled towards one SPB (Fig 3B,D; supplementary Fig S4F online).
PMID:19686686 PBO:0033576 mitotic anaphase B, mitotic telophase
PMID:19686686 PBO:0109478 interacts with unmodified Ase1 PR:000027520
PMID:19686686 PBO:0033572 interphase, prophase, metaphase,anaphase A
PMID:19686686 PBO:0033573 interphase, prophase, metaphase,anaphase A
PMID:19686686 PBO:0021821 interphase, prophase, metaphase,anaphase A
PMID:19686686 PBO:0033574 interphase, prophase, metaphase,anaphase A
PMID:19686686 PBO:0022963 mitotic anaphase B
PMID:19686686 FYPO:0005342 fig 1e
PMID:19686686 FYPO:0005342 fig 1e
PMID:19686686 FYPO:0005342 fig 1e
PMID:19686686 FYPO:0005342 fig 1e
PMID:19686686 FYPO:0005342 fig 1e
PMID:19686686 FYPO:0005342 fig 1e
PMID:19686686 FYPO:0005342 fig 1e
PMID:19686686 FYPO:0000620 with monopolar spindle
PMID:19686686 PBO:0033575 mitotic anaphase B, mitotic telophase
PMID:19686686 GO:1990023 fig 4 a
PMID:19686686 GO:1990023 fig 4 a
PMID:19686686 PBO:0095690 cdc2 dependent phophorylation (fig. 4B)
PMID:19686686 PBO:0094040 cdc2 dependent phophorylation (fig. 5B)
PMID:19686686 PBO:0095694 Fig. 5C
PMID:19686686 FYPO:0003268 Fig. 5C
PMID:19686686 FYPO:0005343 Fig. 5C
PMID:19686686 PBO:0095689 Fig. 5C
PMID:19686686 PBO:0095696 Figure 3 D
PMID:19686686 PBO:0095696 Figure 3 D
PMID:19686686 PBO:0095696 Figure 3 D
PMID:19686686 PBO:0095697 Figure 3 D
PMID:19686686 PBO:0095697 Figure 3 D
PMID:19686686 PBO:0109478 interacts with unmodified Klp9 PR:000027705
PMID:19693008 PBO:0110856 Combining Dago1 with Dpht1 resulted in synergistic upregulation of antisense transcripts, as in Dclr4 Dpht1 (Fig. 2a). When Dpht1 was combined with mutant alleles of clr4 or rik1—components of the Clr4-containing methyltransferase complex (ClrC)7—the resultant double mutants showed severe growth defects and a large, synergistic increase in antisense RNAs at .20% of genes (Fig. 2a and Supplementary Figs 5 and 7a, b). Consistent with ClrC directly participating in antisense suppression, Rik1 was found at the convergent loci (Supplementary Fig. 7c).
PMID:19693008 PBO:0110856 Deletion of exosome subunit rrp6 led to an antisense profile closely resembling that of Dclr4 Dpht1, with read- through antisense RNA covering entire ORFs at convergent genes (Fig. 3b). When Dpht1 was combined with mutant alleles of clr4 or rik1—components of the Clr4-containing methyltransferase complex (ClrC)7—the resultant double mutants showed severe growth defects and a large, synergistic increase in antisense RNAs at .20% of genes (Fig. 2a and Supplementary Figs 5 and 7a, b). Consistent with ClrC directly participating in antisense suppression, Rik1 was found at the convergent loci (Supplementary Fig. 7c).
PMID:19693008 PBO:0110857 However, antisense RNAs did not accumulate extensively in Dswi6 cells and the synergistic increase in antisense RNAs observed in the Dclr4 Dpht1 mutant was not observed in the Dswi6 Dpht1 mutant (Fig. 2a). Thus, ClrC and Ago1 contribute to antisense suppression by a new mechanism(s).
PMID:19693008 PBO:0110850 When Dpht1 was combined with mutant alleles of clr4 or rik1—components of the Clr4-containing methyltransferase complex (ClrC)7—the resultant double mutants showed severe growth defects and a large, synergistic increase in antisense RNAs at .20% of genes (Fig. 2a and Supplementary Figs 5 and 7a, b). Consistent with ClrC directly participating in antisense suppression, Rik1 was found at the convergent loci (Supplementary Fig. 7c).
PMID:19693008 PBO:0110854 affected chromatin association of Swr1, distribution of H2A.Z across the genome (Supplementary Fig. 2c).
PMID:19693008 PBO:0110850 When Dpht1 was combined with mutant alleles of clr4 or rik1—components of the Clr4-containing methyltransferase complex (ClrC)7—the resultant double mutants showed severe growth defects and a large, synergistic increase in antisense RNAs at .20% of genes (Fig. 2a and Supplementary Figs 5 and 7a, b). Consistent with ClrC directly participating in antisense suppression, Rik1 was found at the convergent loci (Supplementary Fig. 7c).
PMID:19693008 PBO:0110850 When Dpht1 was combined with mutant alleles of clr4 or rik1—components of the Clr4-containing methyltransferase complex (ClrC)7—the resultant double mutants showed severe growth defects and a large, synergistic increase in antisense RNAs at .20% of genes (Fig. 2a and Supplementary Figs 5 and 7a, b). Consistent with ClrC directly participating in antisense suppression, Rik1 was found at the convergent loci (Supplementary Fig. 7c).
PMID:19693008 PBO:0110850 When Dpht1 was combined with mutant alleles of clr4 or rik1—components of the Clr4-containing methyltransferase complex (ClrC)7—the resultant double mutants showed severe growth defects and a large, synergistic increase in antisense RNAs at .20% of genes (Fig. 2a and Supplementary Figs 5 and 7a, b). Consistent with ClrC directly participating in antisense suppression, Rik1 was found at the convergent loci (Supplementary Fig. 7c).
PMID:19693008 PBO:0110856 When Dpht1 was combined with mutant alleles of clr4 or rik1—components of the Clr4-containing methyltransferase complex (ClrC)7—the resultant double mutants showed severe growth defects and a large, synergistic increase in antisense RNAs at .20% of genes (Fig. 2a and Supplementary Figs 5 and 7a, b). Consistent with ClrC directly participating in antisense suppression, Rik1 was found at the convergent loci (Supplementary Fig. 7c).
PMID:19693008 PBO:0110856 When Dpht1 was combined with mutant alleles of clr4 or rik1—components of the Clr4-containing methyltransferase complex (ClrC)7—the resultant double mutants showed severe growth defects and a large, synergistic increase in antisense RNAs at .20% of genes (Fig. 2a and Supplementary Figs 5 and 7a, b). Consistent with ClrC directly participating in antisense suppression, Rik1 was found at the convergent loci (Supplementary Fig. 7c).
PMID:19693008 PBO:0110850 the synergistic increase in antisense RNAs observed in the Dclr4 Dpht1 mutant was not observed in the Dswi6 Dpht1 mutant (Fig. 2a).
PMID:19693008 FYPO:0005071 Dpht1 causes a slight increase in silencing at the pericentromeric region, but H3K9me distribution at heterochromatic loci is not severely altered (Supplementary Fig. 4a).
PMID:19693008 PBO:0110855 At euchromatic loci, H2A.Z localizes preferentially in intergenic regions (Supplementary Fig. 3b)
PMID:19693008 PBO:0110850 (Delta)pht1 caused a disproportionate increase in antisense transcripts at many (,5–8%) euchromatic loci (Fig. 1e–g and Supplementary Fig. 5), as confirmed by PCR with strand-specific reverse transcrip- tion (RT–PCR; Fig. 1f).
PMID:19696784 PBO:0106851 fig 1 c
PMID:19696784 PBO:0106858 figure5
PMID:19696784 PBO:0106856 (Fig 3B)
PMID:19696784 PBO:0106855 (Fig 3B)
PMID:19696784 PBO:0106859 supplementary Fig S6 online
PMID:19696784 PBO:0106857 (Fig 3B)
PMID:19696784 PBO:0106852 fig 1 c
PMID:19696784 PBO:0106853 Fig 2A,B
PMID:19713940 PBO:0095570 observed after short-duration overexpression
PMID:19713940 FYPO:0002437 temperature restrictive for cdc25-22
PMID:19713940 FYPO:0002437 temperature restrictive for cdc25-22
PMID:19713940 FYPO:0002437 temperature restrictive for cdc25-22
PMID:19713940 GO:0051015 assayed using N-terminal Rng2-Ns fragment or calponin homology domain (CHD) fragment
PMID:19723888 PBO:0093629 fig1A
PMID:19723888 PBO:0093629 figure 1B
PMID:19723888 PBO:0093630 fig1A
PMID:19723888 PBO:0093580 fig1C
PMID:19723888 PBO:0093581 fig1C
PMID:19723888 PBO:0093580 fig1C,D
PMID:19723888 PBO:0093581 fig1C
PMID:19723888 PBO:0093580 fig1C
PMID:19723888 PBO:0097772 fig1D
PMID:19723888 PBO:0093581 fig1C
PMID:19723888 PBO:0097774 fig 2
PMID:19723888 PBO:0093629 fig1A
PMID:19723888 PBO:0093629 fig1A
PMID:19723888 PBO:0093629 fig1A
PMID:19723888 PBO:0093629 fig1A
PMID:19723888 PBO:0093629 fig1A
PMID:19723888 PBO:0093629 figure 1B
PMID:19723888 PBO:0093629 fig1A
PMID:19723888 PBO:0093630 fig1A
PMID:19723888 PBO:0093631 figure 1B
PMID:19723888 PBO:0093629 figure 1B
PMID:19723888 PBO:0093629 figure 1B
PMID:19723888 PBO:0095096 Fig 2A III
PMID:19723888 PBO:0093629 figure 1B
PMID:19723888 PBO:0093629 figure 1B
PMID:19723888 PBO:0093631 figure 1B
PMID:19723888 PBO:0093630 figure 1B
PMID:19723888 PBO:0097773 fig1C
PMID:19723888 PBO:0097773 fig1C
PMID:19723888 PBO:0097772 fig1D
PMID:19723888 PBO:0093630 fig1A
PMID:19723888 PBO:0093580 fig1C
PMID:19723888 PBO:0093581 fig1C
PMID:19723888 PBO:0093581 fig1D
PMID:19723888 PBO:0093630 fig1A
PMID:19723888 PBO:0097774 fig 2
PMID:19723888 FYPO:0001903 figure 2B
PMID:19723888 FYPO:0001903 Fig 2A III
PMID:19723888 FYPO:0001903 Fig 2A III
PMID:19723888 FYPO:0000650 Fig 2A III
PMID:19723888 PBO:0093630 fig1A
PMID:19723888 PBO:0093630 fig1A
PMID:19736319 FYPO:0005055 arrested normal size (multiple rounds of cytokinesis) in interphase
PMID:19736319 FYPO:0002000 add to def, septated in interphase. one compartment is anucleate
PMID:19736319 PBO:0108323 2% fig 6a. to dauughter
PMID:19736319 PBO:0108322 2% fig 6a
PMID:19736319 PBO:0021746 Fig. 4 B and not depicted
PMID:19736319 PBO:0108321 fig 4d
PMID:19736319 PBO:0018345 Fig. 4 B and not depicted
PMID:19736319 FYPO:0001493 Fig. S1 C, arrows
PMID:19736319 FYPO:0005369 Fig. S1 B and not depicted
PMID:19758558 PBO:0103657 Fig. S3D
PMID:19798055 FYPO:0005452 decreased overall
PMID:19804755 MOD:01455 residues include one or more of S77, T78, T79, S87, and T89, and other(s)
PMID:19804755 PBO:0100522 ctp-Phosphorylated
PMID:19879140 FYPO:0006725 MT spindown assay.
PMID:19879140 GO:0008017 Biochemistry
PMID:19879140 FYPO:0001944 MT spindown assay
PMID:19915592 FYPO:0000227 Knockout or depletion of H2A.Z in Sc 15 or mammalian cells 5 leads to increased rates of chromosome loss. This phenotype was also observed if any component of the Sp Pht1Ac pathway is disrupted, including mutants in swr1 (and msc1), pht1 (pht1Δ, −4KR or −4KQ), or mst1 (Supplementary Table 2 and 16,25,26).
PMID:19915592 FYPO:0000283 (iii) entanglement leading to breakage, where broken pieces of chromatin with no kinetochore lag on the spindle (Fig. 4b).
PMID:19915592 FYPO:0000227 Knockout or depletion of H2A.Z in Sc 15 or mammalian cells 5 leads to increased rates of chromosome loss. This phenotype was also observed if any component of the Sp Pht1Ac pathway is disrupted, including mutants in swr1 (and msc1), pht1 (pht1Δ, −4KR or −4KQ), or mst1 (Supplementary Table 2 and 16,25,26).
PMID:19915592 FYPO:0000227 Knockout or depletion of H2A.Z in Sc 15 or mammalian cells 5 leads to increased rates of chromosome loss. This phenotype was also observed if any component of the Sp Pht1Ac pathway is disrupted, including mutants in swr1 (and msc1), pht1 (pht1Δ, −4KR or −4KQ), or mst1 (Supplementary Table 2 and 16,25,26).
PMID:19915592 FYPO:0000227 Knockout or depletion of H2A.Z in Sc 15 or mammalian cells 5 leads to increased rates of chromosome loss. This phenotype was also observed if any component of the Sp Pht1Ac pathway is disrupted, including mutants in swr1 (and msc1), pht1 (pht1Δ, −4KR or −4KQ), or mst1 (Supplementary Table 2 and 16,25,26).
PMID:19915592 FYPO:0000227 Knockout or depletion of H2A.Z in Sc 15 or mammalian cells 5 leads to increased rates of chromosome loss. This phenotype was also observed if any component of the Sp Pht1Ac pathway is disrupted, including mutants in swr1 (and msc1), pht1 (pht1Δ, −4KR or −4KQ), or mst1 (Supplementary Table 2 and 16,25,26).
PMID:19915592 GO:0000812 figure2b
PMID:19915592 GO:0000812 figure2b
PMID:19915592 GO:0000812 figure2b
PMID:19915592 GO:0000812 figure2b
PMID:19915592 FYPO:0001355 This partial rescue was specific, as pht1Δ was synthetic with rad21-K1, a mutant in the condensin- related complex cohesin, which holds sister-chromatids together prior to anaphase onset.
PMID:19915592 FYPO:0001355 This partial rescue was specific, as pht1Δ was synthetic with rad21-K1, a mutant in the condensin- related complex cohesin, which holds sister-chromatids together prior to anaphase onset.
PMID:19915592 FYPO:0006372 (iii) entanglement leading to breakage, where broken pieces of chromatin with no kinetochore lag on the spindle (Fig. 4b).
PMID:19915592 FYPO:0000227 Knockout or depletion of H2A.Z in Sc 15 or mammalian cells 5 leads to increased rates of chromosome loss. This phenotype was also observed if any component of the Sp Pht1Ac pathway is disrupted, including mutants in swr1 (and msc1), pht1 (pht1Δ, −4KR or −4KQ), or mst1 (Supplementary Table 2 and 16,25,26).
PMID:19915592 GO:0000812 figure2b
PMID:19915592 FYPO:0000227 Knockout or depletion of H2A.Z in Sc 15 or mammalian cells 5 leads to increased rates of chromosome loss. This phenotype was also observed if any component of the Sp Pht1Ac pathway is disrupted, including mutants in swr1 (and msc1), pht1 (pht1Δ, −4KR or −4KQ), or mst1 (Supplementary Table 2 and 16,25,26).
PMID:19915592 FYPO:0002061 lethal >34°C (Fig. 1c).
PMID:19915592 PBO:0110297 reduction in Pht1Ac (Fig. 1d), indicating that Pht1 acetylation is Mst1-dependent.
PMID:19915592 GO:0000812 figure2b
PMID:19915592 GO:0000812 figure2b
PMID:19915592 GO:0000812 figure2b
PMID:19915592 GO:0000812 figure2b
PMID:19915592 GO:0000812 figure2b
PMID:19915592 PBO:0092504 p SWR-C required for the efficient acetylation of the histone (Fig. 2b), most likely because of inefficient assembly of the variant into chromatin in each background (Fig. 2c). Thus a pathway first identified in Sc also operates in Sp: SWR-C inserts Pht1 into chromatin, where it is acetylated by Mst1.
PMID:19915592 GO:0000812 figure2b
PMID:19915592 GO:0000812 figure2b
PMID:19915592 GO:0000812 figure2b
PMID:19915592 GO:0000812 figure2b
PMID:19915592 GO:0000812 figure2b
PMID:19915592 GO:0000785 Cell fractionation showed that Pht1Ac is chromatin-associated, though acetylation is not required for entry to this cellular compartment (Figs. 1e–f)
PMID:19933844 GO:0140861 Deletion of this Iec1 protein or the Ino80 complex subunit arp8, ies6, or ies2 causes defects in DNA damage repair, the response to replication stress, and nucleotide metabolism.
PMID:19933844 GO:0140861 Deletion of this Iec1 protein or the Ino80 complex subunit arp8, ies6, or ies2 causes defects in DNA damage repair, the response to replication stress, and nucleotide metabolism.
PMID:19933844 GO:0140861 Deletion of this Iec1 protein or the Ino80 complex subunit arp8, ies6, or ies2 causes defects in DNA damage repair, the response to replication stress, and nucleotide metabolism.
PMID:19933844 GO:0140861 Deletion of this Iec1 protein or the Ino80 complex subunit arp8, ies6, or ies2 causes defects in DNA damage repair, the response to replication stress, and nucleotide metabolism.
PMID:19933844 GO:0045815 Deletion of this Iec1 protein or the Ino80 complex subunit arp8, ies6, or ies2 causes defects in DNA damage repair, the response to replication stress, and nucleotide metabolism.
PMID:19933844 GO:0045815 Deletion of this Iec1 protein or the Ino80 complex subunit arp8, ies6, or ies2 causes defects in DNA damage repair, the response to replication stress, and nucleotide metabolism.
PMID:19933844 GO:0045815 Deletion of this Iec1 protein or the Ino80 complex subunit arp8, ies6, or ies2 causes defects in DNA damage repair, the response to replication stress, and nucleotide metabolism.
PMID:19933844 GO:0045815 Deletion of this Iec1 protein or the Ino80 complex subunit arp8, ies6, or ies2 causes defects in DNA damage repair, the response to replication stress, and nucleotide metabolism.
PMID:19942659 FYPO:0003728 Like the gms1D mutant, neither the uge1D strain nor the uge1Dgal10D strain reacted with PNA (Fig. 2b
PMID:19942659 GO:0003978 major
PMID:19942659 PBO:0108463 minor
PMID:19942852 PBO:0102699 1D
PMID:19942852 FYPO:0006593 1D
PMID:19942852 PBO:0102700 fig3
PMID:19942852 PBO:0019218 fig1
PMID:19942852 FYPO:0002061 fig1
PMID:19942852 PBO:0102698 S2 &3
PMID:19942852 PBO:0019218 fig1
PMID:19942852 FYPO:0005380 1D
PMID:19942852 FYPO:0002061 fig1
PMID:19942852 FYPO:0005380 1D
PMID:19942852 PBO:0102701 fig3
PMID:19942852 PBO:0102702 fig3
PMID:19942852 FYPO:0006593 1D
PMID:19942852 FYPO:0000274 1D
PMID:19942852 PBO:0102706 fig6a
PMID:19942852 FYPO:0000274 1D
PMID:19942852 PBO:0102705 fig6a
PMID:19942852 PBO:0102699 1D
PMID:19942852 PBO:0102698 S2 &3
PMID:19948483 FYPO:0002061 Fig. 3
PMID:19948483 FYPO:0008007 Fig. 3
PMID:19948483 PBO:0101996 Fig. 3
PMID:19948483 FYPO:0005045 Fig. 3
PMID:19948484 PBO:0095335 they say periphery in the text but it has TM domains
PMID:19948484 PBO:0095336 they say periphery in the text but it has TM domains
PMID:19948484 PBO:0095347 this is an adaptor
PMID:19965387 FYPO:0004318 fig2c, in psc3-1T background
PMID:19965387 PBO:0112750 H2A-S121 phosphorylation was completely abolished in bub1-KD cells, although a similar amount of H2A was detected (Fig. 1G).
PMID:19965387 PBO:0102074 fusion experiments fig3
PMID:19965387 PBO:0102073 fusion experiments fig3
PMID:19965387 PBO:0102074 fusion experiments fig3
PMID:19965387 PBO:0102073 fusion experiments fig3
PMID:19965387 PBO:0102072 4g
PMID:19965387 PBO:0102072 4g
PMID:19965387 PBO:0102072 4g
PMID:19965387 PBO:0102071 4g
PMID:19965387 PBO:0102059 fig 3a
PMID:19965387 PBO:0102059 fig 3a
PMID:19965387 PBO:0102070 4c
PMID:19965387 PBO:0101329 4c
PMID:19965387 PBO:0102065 S6
PMID:19965387 PBO:0102064 S6
PMID:19965387 PBO:0102064 S6
PMID:19965387 PBO:0102065 S6
PMID:19965387 PBO:0102064 S6
PMID:19965387 PBO:0102065 S6
PMID:19965387 PBO:0102064 S6
PMID:19965387 PBO:0102063 fig 3a
PMID:19965387 PBO:0102063 fig S3
PMID:19965387 PBO:0102063 fig S3
PMID:19965387 FYPO:0006423 S3, mes1delta background
PMID:19965387 FYPO:0006423 S3, mes1delta background
PMID:19965387 FYPO:0006423 S3, mes1delta background
PMID:19965387 FYPO:0006423 S3, mes1delta background
PMID:19965387 PBO:0102062 fig S5
PMID:19965387 PBO:0102061 fig 3a
PMID:19965387 PBO:0102060 fig 3a
PMID:19965387 PBO:0102062 fig 3a
PMID:19965387 PBO:0102061 fig 3a
PMID:19965387 PBO:0102060 fig 3a
PMID:19965387 PBO:0102059 fig 3a
PMID:19965387 PBO:0102059 fig 3a
PMID:19965387 PBO:0102059 fig 3a
PMID:19965387 FYPO:0003182 fig 2f
PMID:19965387 FYPO:0003182 fig 2f
PMID:19965387 FYPO:0003182 fig 2f
PMID:19965387 FYPO:0003182 fig 2f
PMID:19965387 FYPO:0005634 fig 2e
PMID:19965387 FYPO:0005634 fig 2e
PMID:19965387 FYPO:0005634 fig 2e
PMID:19965387 FYPO:0005634 fig 2e
PMID:19965387 FYPO:0004318 fig2c, in psc3-1T background
PMID:19965387 FYPO:0004318 fig2c, in psc3-1T background
PMID:19965387 FYPO:0004318 fig2c, in psc3-1T background
PMID:19965387 PBO:0112749 This signal was abolished in cell extracts prepared from h2a-SA cells, in which Ser 121 is replaced with alanine (H2A-S121A) in both the hta1+ and hta2+ genes (Fig. 1G).
PMID:19965387 PBO:0112748 This signal was abolished in cell extracts prepared from h2a-SA cells, in which Ser 121 is replaced with alanine (H2A-S121A) in both the hta1+ and hta2+ genes (Fig. 1G).
PMID:20062003 FYPO:0006076 2D
PMID:20062003 FYPO:0007009 4
PMID:20062003 FYPO:0007009 4
PMID:20062003 FYPO:0007009 4
PMID:20062003 FYPO:0007010 3
PMID:20062003 FYPO:0007009 4
PMID:20062003 FYPO:0007009 4
PMID:20062003 FYPO:0007009 S1
PMID:20062003 FYPO:0007009 S1
PMID:20062003 FYPO:0007009 S1
PMID:20062003 FYPO:0007009 4
PMID:20075862 FYPO:0001408 3a left panel
PMID:20089861 FYPO:0008054 Indeed, the R288K and Q364R mutations in SpHCS confer diminished sensitivity to feedback inhibition by L-lysine in vitro and in vivo (Table 2 and Fig. 4)
PMID:20089861 FYPO:0008054 Indeed, the R288K and Q364R mutations in SpHCS confer diminished sensitivity to feedback inhibition by L-lysine in vitro and in vivo (Table 2 and Fig. 4)
PMID:20094029 GO:0005634 Forms gamma H2A dependent nuclear foci when over-expressed
PMID:20110347 FYPO:0004895 25 degrees
PMID:20110347 FYPO:0001355 25 or 32 degrees; latter semi-permissive for cdc8-27 alone
PMID:20110347 FYPO:0001357 25 degrees
PMID:20110347 PBO:0104411 32 degrees
PMID:20110347 FYPO:0004895 32 degrees
PMID:20110347 PBO:0101716 32 degrees; semi-permissive for cdc8-27 alone
PMID:20110347 FYPO:0001355 32 degrees
PMID:20110347 FYPO:0003339 25 degrees
PMID:20110347 FYPO:0004430 25 degrees
PMID:20123974 FYPO:0000487 increased unequal sister chromatid recombination
PMID:20123974 FYPO:0000485 also ctp1,rec12,rad22,rti1,rad51,dmc1 unequal sister chromatid recombination (USCR)
PMID:20123974 FYPO:0000487 increased unequal sister chromatid recombination
PMID:20123974 FYPO:0000487 increased unequal sister chromatid recombination
PMID:20129053 FYPO:0003701 snoRNAs with extended poly(A) tails accumulate in these foci
PMID:20129053 FYPO:0003701 snoRNAs with extended poly(A) tails accumulate in these foci
PMID:20140190 PBO:0106743 same as nbs1-c60-delta alone
PMID:20140190 PBO:0106748 full-length Rad3 or Rad3-kd-delta
PMID:20140190 PBO:0101083 full-length Rad3 or Rad3-kd-delta
PMID:20140190 PBO:0106743 same as nbs1-c60-delta alone
PMID:20164182 PBO:0108243 unstressed cells
PMID:20164182 PBO:0095167 unstressed cells
PMID:20164182 PBO:0108243 unstressed cells
PMID:20164182 PBO:0095167 unstressed cells
PMID:20164182 PBO:0106771 unstressed cells
PMID:20164182 PBO:0106771 unstressed cells
PMID:20164182 PBO:0095167 unstressed cells
PMID:20164182 PBO:0108243 unstressed cells
PMID:20164182 PBO:0095167 unstressed cells
PMID:20164182 PBO:0108243 unstressed cells
PMID:20164182 PBO:0095167 unstressed cells
PMID:20164182 PBO:0095167 unstressed cells
PMID:20164182 PBO:0095167 unstressed cells
PMID:20164182 PBO:0095167 unstressed cells
PMID:20164182 PBO:0108243 unstressed cells
PMID:20164182 PBO:0106771 unstressed cells
PMID:20164182 PBO:0108243 unstressed cells
PMID:20164182 PBO:0095167 unstressed cells
PMID:20211136 FYPO:0003412 endogenous ade6
PMID:20211136 PBO:0098760 this is the endogenous dg repeat
PMID:20211136 FYPO:0004170 abolished at exogenous RNA polII transcribed gene
PMID:20211136 PBO:0112179 not sure which clrc subunit it binds to?
PMID:20226666 PBO:0102628 Figure 1
PMID:20226666 PBO:0102629 Figure 1
PMID:20226666 FYPO:0000229 Figure 1 in interphase
PMID:20226666 FYPO:0007664 Figure 1 in interphase
PMID:20230746 PBO:0108901 involved in negative regulation of transcription via transcription factor catabolism
PMID:20299449 PBO:0020274 IMP evidence for sir2 being the major HDAC, IDA for mst1 being HAT
PMID:20299449 PBO:0096407 IMP evidence for sir2 being the major HDAC, IDA for mst1 being HAT
PMID:20299449 PBO:0020274 IMP evidence for sir2 being the major HDAC, IDA for mst1 being HAT
PMID:20299449 MOD:00723 IMP evidence for sir2 being the major HDAC, IDA for mst1 being HAT
PMID:20356456 GO:0008379 The peroxidase activity of BCP (bacterioferritin comigratory protein) was similar to that of TPx.
PMID:20360683 FYPO:0003917 assayed using GFP reporter with or without premature stop codons
PMID:20360683 FYPO:0003947 assayed using ypt3 reporter with or without premature stop codons
PMID:20360683 FYPO:0003917 assayed using GFP reporter with or without premature stop codons
PMID:20360683 FYPO:0003947 assayed using ypt3 reporter with or without premature stop codons
PMID:2038306 PBO:0102100 CDC2HS is not recognised by anti cdc2 antibody 4711 and so does not contribute to the level of kinase activity assayed. S. pombe cdc2+ is on a multi copy plasmid pMNScdc2 Figure 4A lane 1
PMID:2038306 PBO:0037130 the endogenous copy of cdc2 has been replaced by cdc2 from human cells CDC2HS. S. pombe cdc2+ is expressed from episomal pMNScdc2 in presence of thiamine. The cdc2 is therefore not really over expressed but I was unable to say it was 'not assayed' Figure 3C
PMID:2038306 PBO:0102101 cdc2-DL5 is over expressed from episomal pMNScdc2DL5. CDC2HS is not recognised by anti cdc2 antibody 4711 and so does not contribute to the level of cdc2-DL5 kinase activity assayed. Figure 4A lane pMNSDL5-
PMID:2038306 PBO:0037125 pMNScdc2-DL5 fails to rescue cdc2-33 mutant at the restrictive temperature. Do not say how this was assayed
PMID:2038306 PBO:0037126 pMNScdc2-DL5 is integrated cells observed after 30 hours over expression Figure 2. In the paper they call this plasmid pMNSDL5 I have added cdc2-DL5 for clarity . The pMNS21L plasmid used for isolating this cdc2 mutant has since been rename pREP1.
PMID:2038306 PBO:0037127 Data not shown. pMNScdc2-DL5 is integrated
PMID:2038306 PBO:0024451 cdc2-DL5 is over expressed from episomal pMNScdc2DL5. The endogenous cdc2+ has been replaced by the human cdc2 gene CDC2HS. Same phenotype as shown in Figure 2
PMID:2038306 PBO:0037125 pMNScdc2-DL5 is an episomal plasmid.
PMID:2038306 PBO:0093712 the endogenous copy of cdc2 has been replaced by cdc2 from human cells CDC2HS. S. pombe cdc2+ is on an episomal plasmid pMNScdc2 Figure 3D
PMID:2038306 PBO:0037128 pMNScdc2-DL5 is integrated
PMID:2038306 PBO:0093712 CDC2HS complements cdc2delete phenotype Figure 4B
PMID:2038306 PBO:0102101 cdc2-DL5 is expressed from episomal pMNScdc2DL5. CDC2HS is not recognised by anti cdc2 antibody 4711 and so does not contribute to the level of cdc2-DL5 kinase activity Figure 4A lane pMNSDL5-
PMID:2038306 PBO:0024304 Data not shown. pMNScdc2-DL5 is integrated
PMID:2038306 PBO:0096052 co ip of cdc2-DL5 and endogenous CDC2HS with anti cdc13 SP4 shows reduced kinase activity compared to CDC2HS alone Figure 7. cdc2-DL5 is on episomal pMNS cdc2DL5. The authors argue that inactive cdc2-DL5 may titrate away factors required for cdc2 kinase activity but unless I have misunderstood the experiment I think this could just as well be interpreted as SP4 iping a mixture of active and inactive cdc2 kinase activity and thus less total cdc2 kinase activity
PMID:2038306 PBO:0024451 pMNScdc2-DL5 is integrated. Cells observed after 12 hours over expression Figure 2. In the paper they call this plasmid pMNSDL5 I have added cdc2-DL5 for clarity . The pMNS21L plasmid used for isolating this cdc2 mutant has since been rename pREP1.
PMID:20383139 PBO:0109330 fig3a
PMID:20383139 PBO:0109329 fig3a par1, the regulatory subunit was used in the assay
PMID:20383139 PBO:0101019 fig 3 c
PMID:20383139 PBO:0101028 Fig. 5c
PMID:20383139 PBO:0101025 Fig. 5b
PMID:20383139 PBO:0101027 fig 5c
PMID:20383139 PBO:0101026 fig 5B
PMID:20383139 PBO:0101025 Fig. 5b
PMID:20383139 PBO:0101025 Fig. 5b
PMID:20383139 PBO:0101009 Fig 1e
PMID:20383139 PBO:0101008 Fig 1d
PMID:20383139 PBO:0101010 fig1e
PMID:20383139 FYPO:0001357 fig1b
PMID:20383139 FYPO:0001357 fig1b
PMID:20383139 FYPO:0001357 fig1b
PMID:20383139 FYPO:0001355 fig1b
PMID:20383139 PBO:0101024 Fig. S5
PMID:20383139 PBO:0101024 Fig. S5
PMID:20383139 PBO:0101021 separation
PMID:20383139 PBO:0101013 Fig. 2b
PMID:20383139 FYPO:0001513 fig 1d
PMID:20383139 PBO:0033208 Fig. S1a
PMID:20383139 PBO:0101014 Fig. 2b
PMID:20383139 PBO:0101023 fig 4 c
PMID:20383139 PBO:0101016 Fig. 2b
PMID:20383139 PBO:0101017 fig3a
PMID:20383139 PBO:0101017 fig3a
PMID:20383139 PBO:0101015 Fig. 2b
PMID:20383139 PBO:0101018 fig 3 c
PMID:20434336 PBO:0098959 (Figure S3A)
PMID:20434336 PBO:0100844 Figures2A and 2B
PMID:20434336 PBO:0100844 Figures2A and 2B
PMID:20434336 PBO:0100843 Figures2A and 2B
PMID:20434336 PBO:0100845 Figures2A and 2B
PMID:20434336 PBO:0100845 Figures2A and 2B cortical/tubular
PMID:20434336 PBO:0100845 Figures2A and 2B cortical/tubular
PMID:20434336 PBO:0100846 Fig 2D tubular/cortical
PMID:20434336 PBO:0100847 fig3
PMID:20434336 PBO:0100841 Fig 1
PMID:20434336 PBO:0100842 figure S1C
PMID:20434336 PBO:0100842 figure S1B
PMID:20434336 PBO:0019716 Fig 1
PMID:20434336 PBO:0100849 fig3
PMID:20434336 GO:0005635 Fig1
PMID:20434336 PBO:0100843 Figures2A and 2B
PMID:20434336 PBO:0099441 Figures2A and 2B
PMID:20434336 PBO:0100849 fig3
PMID:20434336 PBO:0100840 Fig 1
PMID:20434336 PBO:0019716 Fig 1
PMID:20434336 PBO:0019716 Fig 1
PMID:20434336 GO:0005635 Fig1
PMID:20434336 PBO:0100841 Fig1
PMID:20434336 PBO:0100840 Fig1
PMID:20434336 PBO:0100841 Fig 1
PMID:20434336 PBO:0100840 Fig 1
PMID:20434336 PBO:0100848 fig3
PMID:20434336 GO:1990608 data not shown
PMID:20434336 PBO:0100842 figure S1C
PMID:20434336 PBO:0100853 Fig 4E
PMID:20434336 PBO:0095196 Fig3 C
PMID:20434336 PBO:0100852 Fig3 C
PMID:20434336 PBO:0100850 fig3
PMID:20434336 PBO:0100851 Fig3 C protein distributed in cortex
PMID:20434336 PBO:0100850 fig3
PMID:20452294 FYPO:0005183 assayed with Ub-Pcn1 fusion; wild type Pcn1 absent; Pcn1-K164R present but previously shown not to be ubiquitinated at all
PMID:20452294 FYPO:0005221 PCNA trimerization
PMID:20452294 FYPO:0005221 PCNA trimerization
PMID:20452294 FYPO:0005183 assayed with Ub-Pcn1 fusion; wild type Pcn1 absent; Pcn1-K164R present but previously shown not to be ubiquitinated at all
PMID:20452294 FYPO:0005183 assayed with Ub-Pcn1 fusion; wild type Pcn1 absent; Pcn1-K164R present but previously shown not to be ubiquitinated at all
PMID:20452294 FYPO:0005183 assayed with Ub-Pcn1 fusion; wild type Pcn1 absent; Pcn1-K164R present but previously shown not to be ubiquitinated at all
PMID:20452294 FYPO:0005183 assayed with Ub-Pcn1 fusion; wild type Pcn1 absent; Pcn1-K164R present but previously shown not to be ubiquitinated at all
PMID:20452294 FYPO:0005183 assayed with Ub-Pcn1 fusion; wild type Pcn1 absent; Pcn1-K164R present but previously shown not to be ubiquitinated at all
PMID:20452294 FYPO:0005183 assayed with Ub-Pcn1 fusion; wild type Pcn1 absent; Pcn1-K164R present but previously shown not to be ubiquitinated at all
PMID:20452294 FYPO:0005183 assayed with Ub-Pcn1 fusion; wild type Pcn1 absent; Pcn1-K164R present but previously shown not to be ubiquitinated at all
PMID:20517925 FYPO:0006207 Fig. 3D
PMID:20517925 FYPO:0002022 formation
PMID:20517925 FYPO:0001011 Fig. S1
PMID:20517925 FYPO:0007151 Fig. 1B oreover, actin cables often significantly overgrew in these cells while the actin ring formation seemed to be unaf- fected.
PMID:20517925 FYPO:0004652 Fig. 1B
PMID:20517925 FYPO:0004964 Fig. 1B
PMID:20517925 FYPO:0005430 Fig. 1B
PMID:20517925 PBO:0099013 Fig. 3D
PMID:20547592 FYPO:0002350 fig 6 D
PMID:20547592 FYPO:0002350 fig 6 c
PMID:20547592 PBO:0037739 Figure 5A
PMID:20547592 PBO:0023514 fig 5 b
PMID:20547592 PBO:0021023 fig 5 a
PMID:20547592 FYPO:0002060 fig 1
PMID:20547592 PBO:0037736 fig 1
PMID:20547592 PBO:0037738 Figure 5A
PMID:20547592 PBO:0037494 Figure 6E)
PMID:20547592 FYPO:0002350 (Figure 7B)
PMID:20547592 FYPO:0001487 Figure 8A and B (fairly similar expression orofiles)
PMID:20547592 PBO:0102400 (Figure 7A)
PMID:20547592 PBO:0037741 fig 5 b
PMID:20547592 PBO:0023812 figure 6 a
PMID:20547592 PBO:0037737 fig 1 nuclear
PMID:20547592 FYPO:0000158 fig 1 c
PMID:20547592 PBO:0037494 fig 2 e suggesting that Vgl1 might escort RNA from ER-associated polyribosomes to the cytosol under thermal stress.
PMID:20547592 FYPO:0005488 fig 5 e
PMID:20547592 FYPO:0001387 figure 4
PMID:20603077 PBO:0110173 Cdc12 pulls down only 27% as much Cdc15 in a similar block and release experiment (Supp. Fig. 1B)
PMID:20605454 PBO:0103369 polII CTD; probably S5 but can't rule out effect on S7
PMID:20605454 PBO:0103375 at act1 & sam1
PMID:20605454 PBO:0103375 at act1 & sam1
PMID:20605454 PBO:0103376 at ste11
PMID:20605454 PBO:0103376 at ste11
PMID:20605454 PBO:0103382 at ste11
PMID:20605454 PBO:0103369 pol II CTD; probably S2 but can't rule out effect on S7
PMID:20605454 PBO:0103383 at ste11
PMID:20622008 FYPO:0002353 at genes
PMID:20622014 PBO:0103350 pol II localization to sme2 locus
PMID:20622014 PBO:0103342 temperature restrictive for mmi1-ts3
PMID:20622014 PBO:0103339 temperature restrictive for mmi1-ts3
PMID:20622014 PBO:0103343 temperature restrictive for mmi1-ts3
PMID:20622014 PBO:0103337 temperature restrictive for mmi1-ts3
PMID:20622014 PBO:0103340 temperature restrictive for mmi1-ts3
PMID:20623139 PBO:0093645 low expressivity
PMID:20623139 PBO:0093641 high expressivity
PMID:20624975 FYPO:0005423 fig 5C
PMID:20624975 FYPO:0005423 Fig. S5 B–E
PMID:20624975 FYPO:0000904 depolymerization (cytoplasmic?)
PMID:2065367 PBO:0020021 incomplete penetrance due to translational frameshifting
PMID:2065367 PBO:0020022 incomplete penetrance due to translational frameshifting
PMID:2065367 PBO:0020024 incomplete penetrance due to translational frameshifting
PMID:2065367 PBO:0020025 incomplete penetrance due to translational frameshifting
PMID:2065367 PBO:0020023 incomplete penetrance due to translational frameshifting
PMID:2065367 FYPO:0000684 severity is variable, and segregates over successive generations (but not 2:2)
PMID:2065367 PBO:0020020 incomplete penetrance due to translational frameshifting
PMID:20661445 PBO:0023774 Rad3 dependent
PMID:20661445 PBO:0096209 Rad3 dependent
PMID:20661445 PBO:0023773 Rad3 dependent
PMID:20661445 PBO:0023774 Rad3 dependent
PMID:20661445 PBO:0023775 Rad3 dependent
PMID:20661445 PBO:0023775 Rad3 dependent
PMID:20661445 PBO:0096210 Phosphorylated at Tf2-type retrotransposons and wtf elements during S-phase, Rad3-dependent
PMID:20661445 PBO:0033541 Phosphorylated at Tf2-type retrotransposons and wtf elements during S-phase
PMID:20661445 PBO:0021093 ChIP
PMID:20661445 PBO:0096218 Phosphorylated at mating type locus during S-phase, Rad3-dependent
PMID:20661445 PBO:0096218 Phosphorylated at mating type locus during S-phase in Rad3 dependent manner
PMID:20661445 PBO:0096219 Phosphorylated at centromeres during S-phase, Rad3 dependent
PMID:20661445 PBO:0023773 Phosphorylated at centromeres during S-phase, Rad3 dependent
PMID:20661445 PBO:0096219 Phosphorylated at centromeres during S-phase, Rad3 dependent
PMID:20661445 PBO:0023773 Phosphorylated at centromeres during S-phase, Rad3 dependent
PMID:20661445 PBO:0096220 Phosphorylated at Tf2-type retrotransposons and wtf elements during S-phase
PMID:20661445 PBO:0023773 Rad3 dependent
PMID:20661445 PBO:0096209 Rad3 dependent
PMID:20661445 PBO:0096208 Rad3 dependent
PMID:20661445 PBO:0096208 Rad3 dependent
PMID:20679485 PBO:0111564 Crb2 binds phosphorylated histone H2A (Hta1 Serine-129 and Hta2 Serine-128) through its C-terminal BRCT domains
PMID:20679485 PBO:0103260 Crb2 binds phosphorylated histone H2A (Hta1 Serine-129 and Hta2 Serine-128) through its C-terminal BRCT domains
PMID:20705466 PBO:0098637 temperature semi-permissive for cdc8-27
PMID:20705466 PBO:0106975 temperature semi-permissive for cdc8-27
PMID:20705466 PBO:0098637 temperature semi-permissive for cdc8-27
PMID:20705466 PBO:0106972 temperature semi-permissive for cdc8-27
PMID:20705471 PBO:0098637 temperature permissive for cdc8-27
PMID:20736315 PBO:0102340 Fig4
PMID:20736315 PBO:0102341 Fig1B
PMID:20736315 PBO:0102342 Fig1B
PMID:20739936 FYPO:0005366 Fig 1i
PMID:20739936 PBO:0098653 Bir1-N-5A abolished the interaction with Sgo2, whereas Bir1-N-5D retained the interaction (Fig. 2h)
PMID:20739936 PBO:0098640 fig1d,k
PMID:20739936 PBO:0098641 fig1c
PMID:20739936 PBO:0098646 Fig. 1e also The in vivo phosphorylation of Bir1 at prometaphase but not interphase was further confirmed by a phospho-specific antibody against one of the CDK sites, Bir1-pS244 (Supplementary Fig. 2).
PMID:20739936 FYPO:0001007 The cdc13-M7 mutant is suppressed by bir1-8D
PMID:20739936 PBO:0098642 fig 1k
PMID:20739936 PBO:0093562 fig1
PMID:20739936 FYPO:0003503 figb
PMID:20739936 FYPO:0003481 fig 1b
PMID:20739936 PBO:0098643 fig S1. Nuclear staining of anaphase cells showed that the cdc13-M7 mutant, but not the conventional cdc13-117 mutant, often exhibited lagging chromosomes at anaphase (Fig. 1c).
PMID:20739936 PBO:0098644 fig S1
PMID:20739936 PBO:0096770 fig1j
PMID:20739936 FYPO:0005366 Fig 1h
PMID:20739936 PBO:0098649 fig2a,b. figS5
PMID:20739936 PBO:0098649 fig2a,b. figS5
PMID:20739936 PBO:0098654 Supplementary Fig. 8a)
PMID:20739936 PBO:0098646 Fig. 1e also The in vivo phosphorylation of Bir1 at prometaphase but not interphase was further confirmed by a phospho-specific antibody against one of the CDK sites, Bir1-pS244 (Supplementary Fig. 2).
PMID:20739936 PBO:0098646 Fig. 1e also The in vivo phosphorylation of Bir1 at prometaphase but not interphase was further confirmed by a phospho-specific antibody against one of the CDK sites, Bir1-pS244 (Supplementary Fig. 2).
PMID:20739936 PBO:0098639 fig 1c
PMID:20739936 PBO:0098646 Fig. 1e also The in vivo phosphorylation of Bir1 at prometaphase but not interphase was further confirmed by a phospho-specific antibody against one of the CDK sites, Bir1-pS244 (Supplementary Fig. 2).
PMID:20739936 PBO:0098646 Fig. 1e also The in vivo phosphorylation of Bir1 at prometaphase but not interphase was further confirmed by a phospho-specific antibody against one of the CDK sites, Bir1-pS244 (Supplementary Fig. 2).
PMID:20739936 PBO:0098646 Fig. 1e also The in vivo phosphorylation of Bir1 at prometaphase but not interphase was further confirmed by a phospho-specific antibody against one of the CDK sites, Bir1-pS244 (Supplementary Fig. 2).
PMID:20739936 PBO:0111072 Fig. 1e/Fig. 1f
PMID:20739936 PBO:0098646 Fig. 1e also The in vivo phosphorylation of Bir1 at prometaphase but not interphase was further confirmed by a phospho-specific antibody against one of the CDK sites, Bir1-pS244 (Supplementary Fig. 2).
PMID:20739936 PBO:0093562 fig1j
PMID:20739936 PBO:0098646 Fig. 1e also The in vivo phosphorylation of Bir1 at prometaphase but not interphase was further confirmed by a phospho-specific antibody against one of the CDK sites, Bir1-pS244 (Supplementary Fig. 2).
PMID:20739936 PBO:0111964 figS6
PMID:20739936 PBO:0098651 fig2a
PMID:20739936 PBO:0098650 fig2a
PMID:20739936 PBO:0095380 figS6
PMID:20739936 PBO:0096770 suppressed at comparable level to Bir1–CD, These results indicate that once they are tethered at centromeres, the functionality is indistinguishable between Bir1 and Bir1-8A. Supporting this conclusion, complex formation of the CPC was intact in bir1-8A cells (Supplementary Fig. 7).
PMID:20739936 PBO:0036900 Supplementary Fig. 8a)
PMID:20739936 PBO:0098653 Bir1-N-5A abolished the interaction with Sgo2, whereas Bir1-N-5D retained the interaction (Fig. 2h)
PMID:20739936 PBO:0098649 fig2a,b. figS5
PMID:20739936 PBO:0098648 fig1S4/ figS5
PMID:20799962 PBO:0093561 same as rid2-1 alone
PMID:20799962 PBO:0093560 same as rid1-1 alone
PMID:20805322 PBO:0098359 assayed substrate MBP
PMID:20805322 PBO:0098359 assayed substrate MBP
PMID:20805322 PBO:0098360 assayed substrate MBP
PMID:20805322 PBO:0098361 assayed substrate MBP
PMID:20805322 GO:0032956 negative reg of polarization/remodelling
PMID:20805322 PBO:0098352 assayed substrate MBP
PMID:20805322 PBO:0098351 assayed substrate casein
PMID:20805322 PBO:0098357 Fig. 1 A and Table I)
PMID:20805322 PBO:0098352 assayed substrate MBP
PMID:20805322 PBO:0098352 assayed substrate MBP
PMID:20807799 PBO:0097713 PR:000037081= tropomyosin cdc8, acetylated form (fission yeast)
PMID:20807799 PBO:0106962 acetylated Cdc82 so could use PR:000037081
PMID:20807799 PBO:0106964 "vw: I used ""added by naa20 which is the catalytic subunit for naa25"""
PMID:20807799 PBO:0020501 GO:0051329= mitotic interphase
PMID:20826461 PBO:0035494 Fig. 1
PMID:20826461 GO:0043332 (Fig. 1C
PMID:20826461 PBO:0037653 Fig. 1
PMID:20826461 PBO:0100782 (Fig. 1F
PMID:20826461 PBO:0100782 (Fig. 1F
PMID:20826461 PBO:0033557 fig 2A
PMID:20826461 PBO:0100783 fig 2A
PMID:20826461 PBO:0100784 fig 2A
PMID:20826461 PBO:0100785 fig 2B
PMID:20826461 PBO:0100786 fig 2C
PMID:20826461 PBO:0100786 fig 2C
PMID:20826461 PBO:0100787 fig 2C
PMID:20826461 PBO:0100787 fig 2C
PMID:20826461 FYPO:0004953 fig 4
PMID:20826461 PBO:0100788 fig 5
PMID:20826461 PBO:0100789 fig 5
PMID:20826461 PBO:0100790 fig 5
PMID:20826461 PBO:0100791 fig 6
PMID:20826461 PBO:0100792 fig 6
PMID:20826461 PBO:0037648 fig 6
PMID:20826461 PBO:0100793 fig 5
PMID:20826461 PBO:0100794 fig 6
PMID:20826805 GO:0000920 seems to play a minor role - ppk11 physically interacts with pmo25. ppk11 deletion mutants have less pmo25 at the cell division site. This is not so important under optimal conditions but becomes important when cells are stressed. The phenotype of MOR mutants is excaberated by ppk11-delta.
PMID:20826805 PBO:0018576 if it is there after cytokinesis + during anaphase B, then I guess it is safe to say that it is there during cytokinesis too..
PMID:20826805 GO:2000100 seems to play a minor role - ppk11 physically interacts with pmo25. ppk11 deletion mutants have less pmo25 at the cell division site. This is not so important under optimal conditions but becomes important when cells are stressed. The phenotype of MOR mutants is excaberated by ppk11-delta.
PMID:20826805 PBO:0021076 if it is there after cytokinesis + during anaphase B, then I guess it is safe to say that it is there during cytokinesis too..
PMID:20826805 GO:2000100 seems to play a minor role - ppk11 physically interacts with pmo25. ppk11 deletion mutants have less pmo25 at the cell division site. This is not so important under optimal conditions but becomes important when cells are stressed. The phenotype of MOR mutants is excaberated by ppk11-delta.
PMID:20829365 FYPO:0001158 figure 3
PMID:20829365 FYPO:0001309 figure 1 a
PMID:20829365 FYPO:0007098 figure 5
PMID:20829365 PBO:0099780 figure 2 a
PMID:20829365 PBO:0099782 figure 3
PMID:20829365 FYPO:0001168 figure 3
PMID:20829365 PBO:0099781 figure 3
PMID:20829365 FYPO:0004874 figure 3
PMID:20829365 FYPO:0001420 figure 1 a
PMID:20829365 FYPO:0001103 figure 2 a
PMID:20833892 PBO:0035495 fig 3 B WT 10%
PMID:20854854 PBO:0019806 fig 1a
PMID:20854854 PBO:0103039 fig 1a
PMID:20854854 FYPO:0002061 fig 1c
PMID:20854854 FYPO:0002447 fig 3
PMID:20854854 FYPO:0002447 fig 3
PMID:20854854 FYPO:0001234 fig 1b
PMID:20854854 FYPO:0000106 fig 1c
PMID:20854854 PBO:0103040 I don't understand the chemistry well enough to know how the HPLC shows this but I think this is enough evidence?
PMID:20854854 FYPO:0002637 fig 1c
PMID:20854854 FYPO:0001420 fig 1b
PMID:20854854 PBO:0038207 fig 1a
PMID:20876564 FYPO:0004481 Fig. 2A
PMID:20876564 FYPO:0002177 Fig. 2B
PMID:20876564 FYPO:0006117 Fig. 2B
PMID:20876564 PBO:0112768 Fig. 3A
PMID:20876564 FYPO:0002021 Fig. 6D
PMID:20876564 PBO:0093558 Fig. 4A
PMID:20876564 PBO:0093558 Fig. 4A
PMID:20876564 PBO:0093558 Fig. 4A
PMID:20876564 PBO:0093558 Fig. 4A
PMID:20876564 PBO:0093558 Fig. 4A
PMID:20876564 FYPO:0000674 Fig. 4A
PMID:20876564 FYPO:0000674 Fig. 4A
PMID:20876564 FYPO:0000674 Fig. 4A
PMID:20876564 FYPO:0000674 Fig. 4A
PMID:20876564 PBO:0093558 Fig. 4A
PMID:20876564 FYPO:0000674 Fig. 4A
PMID:20876564 FYPO:0000674 Fig. 4A
PMID:20876564 PBO:0093556 Fig. 4A
PMID:20876564 PBO:0112770 Fig. 3A
PMID:20876564 PBO:0112770 Fig. 3A
PMID:20876564 PBO:0112769 Fig. 3A
PMID:20876564 FYPO:0003028 Fig. 6C
PMID:20876564 FYPO:0003028 Fig. 6C
PMID:20876564 PBO:0093560 Fig. 6B
PMID:20876564 FYPO:0007388 Fig. 6A
PMID:20876564 FYPO:0002021 Fig. 6A
PMID:20876564 FYPO:0000674 Fig. 4B
PMID:20876564 PBO:0093560 Fig. 1A
PMID:20876564 FYPO:0001357 Fig. 1A and B
PMID:20876564 FYPO:0001357 Fig. 1A
PMID:20876564 FYPO:0001357 Fig. 1A
PMID:20876564 FYPO:0002024 Fig. 1A
PMID:20876564 FYPO:0004103 Fig. 1A
PMID:20876564 FYPO:0004103 Fig. 1A
PMID:20876564 PBO:0093558 Fig. 4B
PMID:20876564 PBO:0093558 Fig. 4B
PMID:20876564 FYPO:0004103 Fig. 1A
PMID:20876564 FYPO:0000841 Fig. 1B
PMID:20876564 GO:0044732 Fig. 1C
PMID:20876564 FYPO:0001357 Fig. 2A
PMID:20876564 PBO:0093560 Fig. 2A
PMID:20876564 PBO:0093560 Fig. 2A
PMID:20876564 PBO:0093558 Fig. 2A
PMID:20876564 PBO:0093558 Fig. 4B
PMID:20876564 PBO:0093558 Fig. 4B
PMID:20876564 PBO:0093559 Fig. 4B
PMID:20876564 PBO:0093559 Fig. 4B
PMID:20876564 PBO:0093559 Fig. 4B
PMID:20876564 PBO:0093559 Fig. 4B
PMID:20876564 PBO:0093559 Fig. 4B
PMID:20876564 FYPO:0000674 Fig. 4B
PMID:20876564 FYPO:0003028 Fig. 6D
PMID:20876564 FYPO:0003028 Fig. 6D
PMID:20876564 PBO:0093558 Fig. 4A
PMID:20876564 PBO:0093558 Fig. 4A
PMID:20876564 PBO:0093558 Fig. 4A
PMID:20876564 PBO:0093558 Fig. 4A
PMID:20876564 PBO:0093558 Fig. 4A
PMID:20876564 PBO:0093558 Fig. 4A
PMID:20876564 PBO:0093556 Fig. 2A
PMID:20885790 PBO:0093580 less sensitive than ssb3delta alone
PMID:20890290 PBO:0104007 Second, eRF1 and Dom34 increase the bind- ing of GTP to eRF3 and Hbs1, respectively, and GTP increases the binding of eRF1 and Dom34 to eRF3 and Hbs1, respectively28,32,33 (Fig. 6 and Supplementary Table 1). These interactions suggest that in both complexes the status of the nucleotide affects the interaction of the proteins and thereby modulates the function of the complex.
PMID:20890290 PBO:0104008 Second, eRF1 and Dom34 increase the bind- ing of GTP to eRF3 and Hbs1, respectively, and GTP increases the binding of eRF1 and Dom34 to eRF3 and Hbs1, respectively28,32,33 (Fig. 6 and Supplementary Table 1). These interactions suggest that in both complexes the status of the nucleotide affects the interaction of the proteins and thereby modulates the function of the complex.
PMID:20924116 FYPO:0006555 ternary complex normally forms with Swi1-Swi3 and Mrc1 on DNA
PMID:20924116 FYPO:0006555 ternary complex normally forms with Swi1-Swi3 and Mrc1 on DNA
PMID:20924116 FYPO:0006555 ternary complex normally forms with Swi1-Swi3 and Mrc1 on DNA
PMID:20924116 FYPO:0006555 ternary complex normally forms with Swi1-Swi3 and Mrc1 on DNA
PMID:20929775 PBO:0108926 phosphorylated
PMID:20929775 PBO:0108926 phosphorylated
PMID:20929775 PBO:0104309 K9-mehtylated
PMID:20929775 PBO:0108926 phosphorylated
PMID:20929775 PBO:0104309 K9-mehtylated
PMID:20929775 PBO:0104309 K9 methyl;ated
PMID:20935472 PBO:0023853 during metaphase
PMID:20935472 PBO:0097541 Thus, we conclude that Cdc2 activity prevents precocious localization of Mde4 to the metaphase spindle.
PMID:20937798 PBO:0093609 in supp fig1 shows weak sensitivity at high cadmium concentrations
PMID:20944394 GO:0110101 https://github.com/geneontology/go-ontology/issues/15345
PMID:20967237 FYPO:0007859 video S3
PMID:20967237 PBO:0097626 Fig1A,B In the presence of MBC the % cut cells in wild type is almost identical to mad2 Delta at 32 and 35°c suggesting that the spindle assembly checkpoint is not active or overidden above 32°C in wild type cells in presence of MBC.
PMID:20967237 PBO:0100723 Fig4D
PMID:20967237 PBO:0100719 Fig2 A
PMID:20967237 PBO:0100720 Fig 3F
PMID:20967237 PBO:0100718 Fig1E
PMID:20967237 PBO:0100718 Fig1C
PMID:20967237 PBO:0100722 Fig4A
PMID:20967237 PBO:0100727 Fig6D,E in presence of LatA + MBC there is no SPB separation compared to + MBC only where SPBs can separate
PMID:20967237 FYPO:0004318 Fig2B in this case (high temp + MBC) cells can proceed through cell cycle and replicate their DNA
PMID:20967237 PBO:0095672 Fig3G suggests nuclear fission is independent of spindle checkpoint
PMID:20967237 PBO:0100723 Fig4E
PMID:20967237 PBO:0100726 Fig4C followed the presence of clp1 in the nucleolus to monitor cen3
PMID:20967237 PBO:0097954 Fig1D; microtubules absent
PMID:20967237 PBO:0100718 Fig1D
PMID:20967237 PBO:0100718 Fig1D
PMID:20967237 FYPO:0007858 Fig1D
PMID:20967237 PBO:0100724 Fig4B
PMID:20967237 FYPO:0002004 Fig3B just a short microtubule stub remains
PMID:20967237 FYPO:0007858 Fig2c in presence of MBC cells re-enter S phase earlier than in the absence of MBC
PMID:20967237 FYPO:0004367 Fig2c
PMID:20967237 FYPO:0003762 Fig2B in this case (high temp no MBC) the checkpoint is active at high temperature and cells are blocked in cell cycle progression at 36°C.
PMID:20967237 PBO:0100721 Fig3E
PMID:20967237 FYPO:0007859 Fig3 D
PMID:20967237 FYPO:0000133 Fig3C
PMID:20967237 PBO:0100725 data not shown
PMID:20967237 FYPO:0007862 Fig5A
PMID:20974849 PBO:0112443 Fig. 5F
PMID:20974849 GO:0010971 As a whole, our findings suggest that both Cdr2-dependent and -independent mechanisms are responsible for the increased Wee1 levels and the G2/M defect in cpc2D cells.
PMID:20974849 PBO:0112437 Fig. 5F
PMID:20974849 FYPO:0000405 Fig. 5G
PMID:20974849 PBO:0112431 Fig. 5G
PMID:20974849 PBO:0096312 Fig. 5E
PMID:20974849 PBO:0096314 Fig. 5E
PMID:20974849 PBO:0096832 Fig. 5C
PMID:20974849 PBO:0112442 Fig. 5D
PMID:20974849 PBO:0112441 Fig. 5D
PMID:20974849 PBO:0112440 Fig. 5C
PMID:20974849 PBO:0112439 Fig. 5B
PMID:20974849 PBO:0112438 Fig. 5A
PMID:20974849 PBO:0112437 Fig. 4C
PMID:20974849 PBO:0112436 Fig. 4C
PMID:20974849 PBO:0112435 Fig. 4C
PMID:20974849 PBO:0112434 Fig. 4B
PMID:20974849 GO:0043024 Importantly, by using a strain expressing a mutant version of Cpc2 (R36D/K38E) with reduced ability to associate with ribosomes in vivo (22), we also showed that ribosome binding of Cpc2 is critical for proper control of cell size at the G2/M boundary (Fig. 4A).
PMID:20974849 PBO:0096311 Fig. 4A
PMID:20974849 FYPO:0004481 Fig. 3B
PMID:20974849 PBO:0093558 Fig. 3B
PMID:20974849 PBO:0093561 Fig. 3B
PMID:20974849 PBO:0093559 Fig. 3B
PMID:20974849 PBO:0112433 Fig. 3C
PMID:20974849 PBO:0112433 Fig. 3C
PMID:20974849 PBO:0112432 Fig. 3C
PMID:20974849 PBO:0112432 Fig. 3C
PMID:20974849 PBO:0096312 Fig. 3B
PMID:20974849 PBO:0096311 Fig. 3B
PMID:20974849 FYPO:0000405 Fig. 3A
PMID:20974849 PBO:0096314 Fig. 3A
PMID:20974849 PBO:0112431 Fig. 3A
PMID:20974849 PBO:0096311 Fig. 3A
PMID:20974849 GO:2000045 Fig. 2
PMID:20974849 FYPO:0004481 Fig. 1C
PMID:20974849 PBO:0093558 Fig. 1C
PMID:20974849 PBO:0093556 Fig. 1C
PMID:20974849 PBO:0093561 Fig. 1C
PMID:20974849 PBO:0093559 Fig. 1C
PMID:20974849 PBO:0093559 Fig. 1C
PMID:20974849 PBO:0096314 Fig. 1D
PMID:20974849 PBO:0096312 Fig. 1D
PMID:20974849 FYPO:0000012 Fig. 1B
PMID:20974849 PBO:0096311 Fig. 1A
PMID:20980623 PBO:0100822 several types of defects in FSM de- velopment in dma1 cells (Figure 6B). These defects roughly fell into three classes: (1) initially FSM formation was normal and appeared as sphere structure, but subse- quently it became smaller or collapsed (asterisks in Figure 6B); (2) crescent-shaped structures did not properly develop into cup-like structures (open arrows in Figure 6B); and (3) crescent-shaped structures broke into multiple GFP-Psy1- contaning structures which could not develop into round mature FSMs (arrows in Figure 6B).
PMID:20980623 PBO:0111998 Figure 3B Figure 4B the initiation of spore formation was delayed for 2 h com- pared with wild-type cells, and also the efficiency of spore formation was dramatically dropped with only 60% of cells containing spores
PMID:20980623 FYPO:0000587 the initiation of spore formation was delayed for 2 h com- pared with wild-type cells, and also the efficiency of spore formation was dramatically dropped with only 60% of cells containing spores (Figure 3B).
PMID:20980623 PBO:0100818 figS1
PMID:20980623 FYPO:0000583 dma1 spg1-106 and dma1 mob1-1 cells were com- pletely unable to sporulate under conditions in which single spg1-106 or mob1-1 mutants were not apparently compro- mised for sporulation (Figure 8, A and B), suggesting that Dma1 might function in parallel with Spg1 and Mob1 in sporulation.
PMID:20980623 FYPO:0000583 dma1 spg1-106 and dma1 mob1-1 cells were com- pletely unable to sporulate under conditions in which single spg1-106 or mob1-1 mutants were not apparently compro- mised for sporulation (Figure 8, A and B), suggesting that Dma1 might function in parallel with Spg1 and Mob1 in sporulation.
PMID:20980623 FYPO:0000583 dma1 spg1-106 and dma1 mob1-1 cells were com- pletely unable to sporulate under conditions in which single spg1-106 or mob1-1 mutants were not apparently compro- mised for sporulation (Figure 8, A and B), suggesting that Dma1 might function in parallel with Spg1 and Mob1 in sporulation.
PMID:20980623 PBO:0100821 upplemental Figure S3
PMID:20980623 PBO:0100818 figS1
PMID:20980623 PBO:0100817 Fig 2 B&C At anaphase II, however, many of the Dma1-GFP signals did not accumulate at SPBs
PMID:20980623 GO:0035974 fig2
PMID:20980623 FYPO:0003066 Figure 4E
PMID:20980623 PBO:0100820 upplemental Figure S3
PMID:20980623 FYPO:0003066 Figure 4E
PMID:21035342 PBO:0107586 "vw: From review:Rab small GTPase emerges as a regulator of TOR complex 2 ""Consistently, we successfully collected genetic and biochemical data to support the notion that Sat1 and Sat4 form a GEF complex for Ryh1 GTPase in S. pombe. (7). I agree the data supports this model."
PMID:21035342 PBO:0107586 "vw: From review:Rab small GTPase emerges as a regulator of TOR complex 2 ""Consistently, we successfully collected genetic and biochemical data to support the notion that Sat1 and Sat4 form a GEF complex for Ryh1 GTPase in S. pombe. (7). I agree the data supports this model."
PMID:21035342 GO:0019887 vw: bit 61 is importabt for torc2 regulation by ryh1
PMID:21035342 PBO:0111686 "(this is a bit of a fudge. It should probably be molecular signal transducer but that does not exist and I am prevented from using high level terms) vw: From review:Rab small GTPase emerges as a regulator of TOR complex 2""Consistently, we successfully collected genetic and biochemical data to supportthe notion that Sat1 and Sat4 form a GEF complex for Ryh1 GTPase in S. pombe. (7).I agree the data supports this model. Moreover, the Ryh1 I44E mutant fails to promote TORC2 signaling, implying that GTP-dependent interaction of Ryh1 with TORC2 via the effector domain drives TORC2-Gad8 signaling."
PMID:21095590 GO:0045739 phosphorylation of rad9 by DDK releases rad9 from damaged chromatin and allows repair factors to come in. fig6
PMID:21095590 GO:0045739 phosphorylation of rad9 by DDK releases rad9 from damaged chromatin and allows repair factors to come in. fig6
PMID:21095590 PBO:0110104 phosphorylation of rad9 by DDK releases rad9 from damaged chromatin and allows repair factors to come in. fig6
PMID:21095590 FYPO:0001931 fig 5b
PMID:21095590 FYPO:0001931 fig 5b
PMID:21098122 FYPO:0000085 no expressivity extension because of decreased growth when untreated
PMID:21098122 FYPO:0000268 no expressivity extension because of decreased growth when untreated
PMID:21098122 FYPO:0000267 no expressivity extension because of decreased growth when untreated
PMID:21098122 FYPO:0000267 no expressivity extension because of decreased growth when untreated
PMID:21098122 FYPO:0000268 no expressivity extension because of decreased growth when untreated
PMID:21098122 FYPO:0000085 no expressivity extension because of decreased growth when untreated
PMID:21098122 PBO:0104121 nuclease-dead allele
PMID:21098122 FYPO:0000268 no expressivity extension because of decreased growth when untreated
PMID:21098122 FYPO:0000085 no expressivity extension because of decreased growth when untreated
PMID:21098122 FYPO:0000267 no expressivity extension because of decreased growth when untreated
PMID:21098141 PBO:0023514 In SGs after hyperosmotic shock (1 M KCl) but not after glucose deprivation
PMID:21099360 PBO:0093581 same as hsk1-89 alone
PMID:21099360 PBO:0100922 30 degrees; same as hsk1-89 alone
PMID:21099360 PBO:0102368 25 degrees, same as hsk1-89 alone
PMID:21099360 FYPO:0001357 30 degrees; restrictive for hsk1-89 alone
PMID:21099360 PBO:0100922 30 degrees; same as hsk1-89 alone
PMID:21099360 PBO:0102368 25 degrees, same as hsk1-89 alone
PMID:21099360 PBO:0102368 25 degrees
PMID:21099360 PBO:0100922 30 degrees
PMID:21099360 PBO:0093581 same as hsk1-89 alone
PMID:21099360 PBO:0093581 same as hsk1-89 alone
PMID:21099360 FYPO:0001382 MBP substrate
PMID:21099360 PBO:0102364 25 degrees
PMID:21099360 PBO:0094250 30 degrees
PMID:21099360 FYPO:0001355 30 degrees
PMID:21099360 PBO:0100922 30 degrees; same as hsk1-89 alone
PMID:21099360 PBO:0102368 25 degrees, same as hsk1-89 alone
PMID:21099360 PBO:0100922 30 degrees; same as hsk1-89 alone
PMID:21099360 PBO:0102368 25 degrees, same as hsk1-89 alone
PMID:21099360 PBO:0102370 in SQ/TQ clusters . , activated_by(CHEBI:29035)
PMID:21099360 PBO:0102371 not in SQ/TQ clusters
PMID:21099360 PBO:0100905 at ars2004 and oriChr2-1266, during early S phase
PMID:21099360 GO:0031573 hsk1 phenotypes more informative than mrc1 itself
PMID:21107719 GO:0071944 localization independent of actin cytoskeleton (assayed using latrunculin A) and microtubule cytoskeleton (assayed using carbendazim)
PMID:21113731 GO:0005794 Microscopy co-localization
PMID:21118717 GO:0047555 Active against both cAMP and cGMP based on its ability to confer resistance to exogenous cyclic nucleotides. Fig. 1A, B
PMID:21118717 GO:0004115 Active against both cAMP and cGMP based on its ability to confer resistance to exogenous cyclic nucleotides. Fig. 1A, B
PMID:21118717 PBO:0100388 Deletion of both cyr1/git2 and cgs2 produces cells that are hypersensitive to both exogenous cAMP and cGMP as these can activate PKA at low micromolar concentrations. Fig. 1A, B
PMID:21131906 FYPO:0000168 nda1- background to activate splindle checkpoint
PMID:21131906 PBO:0098869 un- ubiquitinated
PMID:21131906 FYPO:0000168 nda1- background to activate spindle checkpoint
PMID:21131906 FYPO:0000168 nda1 background to activate spindle checkpoint
PMID:21148300 PBO:0097265 Cdc42-GTP assayed with CRIB
PMID:21148300 PBO:0097265 Cdc42-GTP assayed with CRIB
PMID:21148300 PBO:0097265 Cdc42-GTP assayed with CRIB
PMID:21148300 PBO:0097265 Cdc42-GTP assayed with CRIB
PMID:21151114 PBO:0020366 SO:0000286 = LTR
PMID:21151114 PBO:0026298 independent of Clr4
PMID:21151114 PBO:0026298 independent of Clr4
PMID:21151114 PBO:0097280 independent of Clr4
PMID:21151114 PBO:0097281 independent of Clr4
PMID:21151114 PBO:0097131 independent of Clr4
PMID:21151114 PBO:0098170 independent of Clr4
PMID:21151114 PBO:0103746 independent of Clr4
PMID:21151114 PBO:0103747 independent of Clr4
PMID:21151114 PBO:0103748 independent of Clr4
PMID:21151114 PBO:0020366 SO:0000286 = LTR
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21182284 MOD:00046 i) unknown kinase ii) asynchronous cells iii) unknown
PMID:21211723 PBO:0102542 We also found that double mutants carrying mutations in clr3 or mit1 along with either asf1-1 or hip1Δ showed cumulative derepression of repeat elements (Figure 3A and S4), indicating overlapping functions for Asf1/HIRA and SHREC.
PMID:21211723 PBO:0102542 We also found that double mutants carrying mutations in clr3 or mit1 along with either asf1-1 or hip1Δ showed cumulative derepression of repeat elements (Figure 3A and S4), indicating overlapping functions for Asf1/HIRA and SHREC.
PMID:21211723 PBO:0102542 We also found that double mutants carrying mutations in clr3 or mit1 along with either asf1-1 or hip1Δ showed cumulative derepression of repeat elements (Figure 3A and S4), indicating overlapping functions for Asf1/HIRA and SHREC.
PMID:21211723 PBO:0102542 We also found that double mutants carrying mutations in clr3 or mit1 along with either asf1-1 or hip1Δ showed cumulative derepression of repeat elements (Figure 3A and S4), indicating overlapping functions for Asf1/HIRA and SHREC.
PMID:21211723 PBO:0102548 However, when asf1-1 or hip1Δ were combined with clr6 or alp13 mutant alleles, double mutants did not show additive defects on silencing as compared to the single mutants (Figure 3A and S4).
PMID:21211723 FYPO:0008151 We observed nucleosome free regions at 5′ ends of genes followed by positioned nucleosomes in open reading frames (Figure S7A). Comparison of nucleosome occupancy across heterochromatin domains in asf1, clr3 or asf1clr3 mutant cells to wild-type cells identified several sites showing depletion of nucleosomes in mutant cells.
PMID:21211723 FYPO:0005516 We observed nucleosome free regions at 5′ ends of genes followed by positioned nucleosomes in open reading frames (Figure S7A). Comparison of nucleosome occupancy across heterochromatin domains in asf1, clr3 or asf1clr3 mutant cells to wild-type cells identified several sites showing depletion of nucleosomes in mutant cells.
PMID:21211723 FYPO:0005516 In general, changes observed in clr3 and asf1 single mutants were weaker as compared to asf1clr3 double mutant that showed substantial reduction in the nucleosome occupancy (Figure 5).
PMID:21211723 FYPO:0005516 We observed nucleosome free regions at 5′ ends of genes followed by positioned nucleosomes in open reading frames (Figure S7A). Comparison of nucleosome occupancy across heterochromatin domains in asf1, clr3 or asf1clr3 mutant cells to wild-type cells identified several sites showing depletion of nucleosomes in mutant cells.
PMID:21211723 FYPO:0000963 However, both Asf1 and Clr6 complex-II mutants were not sensitive to hydoxyurea (Figure S6)
PMID:21211723 FYPO:0000963 However, both Asf1 and Clr6 complex-II mutants were not sensitive to hydoxyurea (Figure S6)
PMID:21211723 FYPO:0000089 We also found that asf1-1 cells were hypersensitive to genotoxic agents such as bleomycin, camptothecin and methylmethane sulfonate (Figure S6)
PMID:21211723 FYPO:0000085 We also found that asf1-1 cells were hypersensitive to genotoxic agents such as bleomycin, camptothecin and methylmethane sulfonate (Figure S6)
PMID:21211723 FYPO:0000095 more sensitive to bleomycin-induced damage, as indicated by the disappearance of full- length chromosome bands and the appearance of a smear of broken DNA fragments (Figure 4E).
PMID:21211723 GO:0045815 Thus, in addition to silencing heterochromatic repeats, Asf1 prevents antisense transcription at euchromatic loci.
PMID:21211723 FYPO:0003557 Notably, asf1-1 produced a disproportionate increase in antisense transcripts – constituting a large proportion of probes upregulated. Detailed expression profiling of individual loci showed that the antisense transcripts upregulated in asf1-1 mutants were also upregulated in hip1Δ and alp13Δ cells (Figure 4A and 4B).
PMID:21211723 FYPO:0008150 Interestingly, asf1-1, but not hip1Δ, also showed substantial increase in the levels of transcripts derived from intergenic portions of rDNA repeat loci (Figure S5B).
PMID:21211723 FYPO:0005917 Moreover, asf1-1 and hip1Δ showed upregulation of sense and antisense transcripts corresponding to subtelomeric genes located within heterochromatic domains (Figure S5A).
PMID:21211723 FYPO:0005917 Moreover, asf1-1 and hip1Δ showed upregulation of sense and antisense transcripts corresponding to subtelomeric genes located within heterochromatic domains (Figure S5A).
PMID:21211723 FYPO:0004347 Based on the genetic analyses, it was possible that Asf1/HIRA facilitate histone deacetylation by Clr6. Asf1 co-immunoprecipitated with Clr6 complex subunits Alp13 and Clr6 (Figure 3B). Moreover, asf1-1 and hip1Δ exhibited a substantial increase in bulk H3K9ac levels, in a manner similar to alp13Δ (Figure 3C).). To confirm this further, we performed ChIP-chip analyses of H3K9ac. Both alp13Δ and asf1-1 mutants showed widespread increase in H3K9ac, as compared to the wild-type cells. Notably, although 30% of the probes in our microarray correspond to intergenic regions, nearly all probes affected by asf1-1 and alp13Δ reside in coding regions (Figure 3D and 3E).
PMID:21211723 FYPO:0004347 Based on the genetic analyses, it was possible that Asf1/HIRA facilitate histone deacetylation by Clr6. Asf1 co-immunoprecipitated with Clr6 complex subunits Alp13 and Clr6 (Figure 3B). Moreover, asf1-1 and hip1Δ exhibited a substantial increase in bulk H3K9ac levels, in a manner similar to alp13Δ (Figure 3C).). To confirm this further, we performed ChIP-chip analyses of H3K9ac. Both alp13Δ and asf1-1 mutants showed widespread increase in H3K9ac, as compared to the wild-type cells. Notably, although 30% of the probes in our microarray correspond to intergenic regions, nearly all probes affected by asf1-1 and alp13Δ reside in coding regions (Figure 3D and 3E).
PMID:21211723 FYPO:0007217 Based on the genetic analyses, it was possible that Asf1/HIRA facilitate histone deacetylation by Clr6. Asf1 co-immunoprecipitated with Clr6 complex subunits Alp13 and Clr6 (Figure 3B). Moreover, asf1-1 and hip1Δ exhibited a substantial increase in bulk H3K9ac levels, in a manner similar to alp13Δ (Figure 3C).). To confirm this further, we performed ChIP-chip analyses of H3K9ac. Both alp13Δ and asf1-1 mutants showed widespread increase in H3K9ac, as compared to the wild-type cells. Notably, although 30% of the probes in our microarray correspond to intergenic regions, nearly all probes affected by asf1-1 and alp13Δ reside in coding regions (Figure 3D and 3E).
PMID:21211723 FYPO:0004347 Based on the genetic analyses, it was possible that Asf1/HIRA facilitate histone deacetylation by Clr6. Asf1 co-immunoprecipitated with Clr6 complex subunits Alp13 and Clr6 (Figure 3B). Moreover, asf1-1 and hip1Δ exhibited a substantial increase in bulk H3K9ac levels, in a manner similar to alp13Δ (Figure 3C).). To confirm this further, we performed ChIP-chip analyses of H3K9ac. Both alp13Δ and asf1-1 mutants showed widespread increase in H3K9ac, as compared to the wild-type cells. Notably, although 30% of the probes in our microarray correspond to intergenic regions, nearly all probes affected by asf1-1 and alp13Δ reside in coding regions (Figure 3D and 3E).
PMID:21211723 PBO:0102548 However, when asf1-1 or hip1Δ were combined with clr6 or alp13 mutant alleles, double mutants did not show additive defects on silencing as compared to the single mutants (Figure 3A and S4).
PMID:21211723 FYPO:0003412 asf1-1 alleviated silencing of the ura4+ inserted at the outer centromeric repeat region (otr1R::ura4+) and within a centromere-homologous (cenH) element at the silent mat locus (Kint2::ura4+), in a manner similar to HIRA null mutants (Figure 1C).
PMID:21211723 FYPO:0000470 asf1-1 and HIRA mutants were defective in mating-type switching, as indicated by the light iodine staining of the colonies (Figure 1F)
PMID:21211723 PBO:0111079 Defective mating-type switching in heterochromatin mutants results in poor iodine staining of colonies, in contrast to the dark staining of wild-type colonies (Jia et al., 2004). asf1-1 and HIRA mutants were defective in mating-type switching, as indicated by the light iodine staining of the colonies (Figure 1F).
PMID:21211723 PBO:0111079 Defective mating-type switching in heterochromatin mutants results in poor iodine staining of colonies, in contrast to the dark staining of wild-type colonies (Jia et al., 2004). asf1-1 and HIRA mutants were defective in mating-type switching, as indicated by the light iodine staining of the colonies (Figure 1F).
PMID:21211723 PBO:0111079 Defective mating-type switching in heterochromatin mutants results in poor iodine staining of colonies, in contrast to the dark staining of wild-type colonies (Jia et al., 2004). asf1-1 and HIRA mutants were defective in mating-type switching, as indicated by the light iodine staining of the colonies (Figure 1F).
PMID:21211723 PBO:0111079 Defective mating-type switching in heterochromatin mutants results in poor iodine staining of colonies, in contrast to the dark staining of wild-type colonies (Jia et al., 2004). asf1-1 and HIRA mutants were defective in mating-type switching, as indicated by the light iodine staining of the colonies (Figure 1F).
PMID:21211723 PBO:0111079 Defective mating-type switching in heterochromatin mutants results in poor iodine staining of colonies, in contrast to the dark staining of wild-type colonies (Jia et al., 2004). asf1-1 and HIRA mutants were defective in mating-type switching, as indicated by the light iodine staining of the colonies (Figure 1F).
PMID:21211723 PBO:0111079 Defective mating-type switching in heterochromatin mutants results in poor iodine staining of colonies, in contrast to the dark staining of wild-type colonies (Jia et al., 2004). asf1-1 and HIRA mutants were defective in mating-type switching, as indicated by the light iodine staining of the colonies (Figure 1F).
PMID:21211723 FYPO:0003096 Whereas asf1-1 cells showed slight reduction in levels of H3K9me, Swi6 and Chp2, the levels of these factors in hip1Δ appeared comparable to wild type (Figure 2A and 2B).
PMID:21211723 FYPO:0003235 Whereas asf1-1 cells showed slight reduction in levels of H3K9me, Swi6 and Chp2, the levels of these factors in hip1Δ appeared comparable to wild type (Figure 2A and 2B).
PMID:21211723 PBO:0111080 ChIP-chip showed that Hip1 was enriched throughout heterochromatin domains in the wild-type cells (Figure 2D, 2E, and S3). In the absence of Swi6, Hip1 localization was restricted to transcribed dg/dh repeats, and it failed to spread outward to the surrounding sequences (Figure 2D, 2E, and S3).
PMID:21211723 GO:0033696 not sue if this is quite the correct term, but it is the old spreading term
PMID:21211723 PBO:0102548 Consistent with both TGS and cis-PTGS contributing to heterochromatin silencing, combining asf1-1 or hip1Δ with tas3Δ resulted in synergistic defects in heterochromatic silencing (Figure 3A).
PMID:21211723 PBO:0102548 Consistent with both TGS and cis-PTGS contributing to heterochromatin silencing, combining asf1-1 or hip1Δ with tas3Δ resulted in synergistic defects in heterochromatic silencing (Figure 3A).
PMID:21211723 PBO:0102527 We also found that double mutants carrying mutations in clr3 or mit1 along with either asf1-1 or hip1Δ showed cumulative derepression of repeat elements (Figure 3A and S4), indicating overlapping functions for Asf1/HIRA and SHREC.
PMID:21211723 PBO:0102542 Consistent with both TGS and cis-PTGS contributing to heterochromatin silencing, combining asf1-1 or hip1Δ with tas3Δ resulted in synergistic defects in heterochromatic silencing (Figure 3A).
PMID:21211723 PBO:0102542 Consistent with both TGS and cis-PTGS contributing to heterochromatin silencing, combining asf1-1 or hip1Δ with tas3Δ resulted in synergistic defects in heterochromatic silencing (Figure 3A).
PMID:21211723 PBO:0102542 Consistent with both TGS and cis-PTGS contributing to heterochromatin silencing, combining asf1-1 or hip1Δ with tas3Δ resulted in synergistic defects in heterochromatic silencing (Figure 3A).
PMID:21211723 PBO:0102542 Consistent with both TGS and cis-PTGS contributing to heterochromatin silencing, combining asf1-1 or hip1Δ with tas3Δ resulted in synergistic defects in heterochromatic silencing (Figure 3A).
PMID:21211723 PBO:0102542 Consistent with both TGS and cis-PTGS contributing to heterochromatin silencing, combining asf1-1 or hip1Δ with tas3Δ resulted in synergistic defects in heterochromatic silencing (Figure 3A).
PMID:21211723 PBO:0102548 We also found that double mutants carrying mutations in clr3 or mit1 along with either asf1-1 or hip1Δ showed cumulative derepression of repeat elements (Figure 3A and S4), indicating overlapping functions for Asf1/HIRA and SHREC.
PMID:21217703 PBO:0108127 An arginine substitution of Ile379 or Leu383 of Taz1 or Ile655 of SpRap1 at the center of the hydrophobic interface completely abolished the Taz1RBM-SpRap1RCT interaction (Fig. 6a).
PMID:21217703 FYPO:0002907 Three mutants (Taz1 I379R, Taz1 L383R, and Rap1 I655R) with no detectable Taz1-SpRap1 interaction clearly exhibited altered mobility bands representing intra-chromosome fusions (Fig. 6e).
PMID:21217703 PBO:0108127 An arginine substitution of Ile379 or Leu383 of Taz1 or Ile655 of SpRap1 at the center of the hydrophobic interface completely abolished the Taz1RBM-SpRap1RCT interaction (Fig. 6a).
PMID:21217703 PBO:0108127 An arginine substitution of Ile379 or Leu383 of Taz1 or Ile655 of SpRap1 at the center of the hydrophobic interface completely abolished the Taz1RBM-SpRap1RCT interaction (Fig. 6a).
PMID:21217703 PBO:0108127 An arginine substitution of Ile379 or Leu383 of Taz1 or Ile655 of SpRap1 at the center of the hydrophobic interface completely abolished the Taz1RBM-SpRap1RCT interaction (Fig. 6a).
PMID:21217703 PBO:0093636 Consistent with the published results, deletion of taz1+ or rap1+ from yeast cells resulted in a dramatic increase in telomere length and length heterogeneity compared to wild-type cells (Fig. 6c).
PMID:21217703 PBO:0108126 An arginine substitution of Ile379 or Leu383 of Taz1 or Ile655 of SpRap1 at the center of the hydrophobic interface completely abolished the Taz1RBM-SpRap1RCT interaction (Fig. 6a).
PMID:21217703 PBO:0093636 Three point mutants (Taz1 I379R, Taz1 L383R, and Rap1 I655R) that completely abolished the Taz1-SpRap1 interaction in the ITC assay displayed a rap1Δ– and taz1Δ-like telomere length defect (Figs. 6b and 6c)
PMID:21217703 PBO:0108126 An arginine substitution of Ile379 or Leu383 of Taz1 or Ile655 of SpRap1 at the center of the hydrophobic interface completely abolished the Taz1RBM-SpRap1RCT interaction (Fig. 6a).
PMID:21217703 PBO:0108126 An arginine substitution of Ile379 or Leu383 of Taz1 or Ile655 of SpRap1 at the center of the hydrophobic interface completely abolished the Taz1RBM-SpRap1RCT interaction (Fig. 6a).
PMID:21256022 GO:0005515 binding site L405 ndc80 loop
PMID:21256022 PBO:0102183 affecting dis1
PMID:21300781 PBO:0021527 Lysine 105 and Lysine 106 are acetylated in an Eso1 dependent manner. Psm3 acetylation on K105 K106 contribute to counteract the cohesin release activity of Wpl1.
PMID:21300781 PBO:0021527 Lysine 105 and Lysine 106 are acetylated in an Eso1 dependent manner. Psm3 acetylation on K105 K106 contribute to counteract the cohesin release activity of Wpl1.
PMID:21300781 PBO:0106616 Lysine 105 and Lysine 106 are acetylated in an Eso1 dependent manner. Psm3 acetylation on K105 K106 contribute to counteract the cohesin release activity of Wpl1.
PMID:21300781 FYPO:0001355 fig7
PMID:21300781 PBO:0106616 Lysine 105 and Lysine 106 are acetylated in an Eso1 dependent manner. Psm3 acetylation on K105 K106 contribute to counteract the cohesin release activity of Wpl1.
PMID:21307936 GO:0005515 supp fig 9A
PMID:21317872 PBO:0095159 poly(A) tails longer in rrp6delta alone, but wild type not shown for meiotic cell cycle so can't annotate rrp6delta phenotype as normal or increased length
PMID:21317872 GO:0071920 colocalization with Pcf11
PMID:21317872 PBO:0095158 poly(A) tails longer in rrp6delta alone, but wild type not shown for meiotic cell cycle so can't annotate rrp6delta phenotype as normal or increased length
PMID:21317872 FYPO:0000584 presumably in homozygous diploid
PMID:21357609 FYPO:0000809 Mitochondrial dye showed diffuse staining. they think it is a loss of membrane potential so the dye is not drawn in properly
PMID:21376595 PBO:0110300 We conclude that Mid1p recruits Rng2p to cortical nodes at the division site and that Rng2p, in turn, recruits other components of the actomyosin ring to cortical nodes, thereby ensuring correct placement of the division site.
PMID:21376600 PBO:0112286 Fig. S2B
PMID:21376600 PBO:0112286 Fig. S2B
PMID:21376600 PBO:0112287 Fig. S2B
PMID:21376600 PBO:0112298 Fig. 4B
PMID:21376600 PBO:0112297 Fig. 4B
PMID:21376600 PBO:0112294 Fig. S3H
PMID:21376600 PBO:0112296 Fig. S3H
PMID:21376600 PBO:0112287 Fig. S2B
PMID:21376600 PBO:0112288 Fig. S2E
PMID:21376600 PBO:0112289 Fig. S2E
PMID:21376600 FYPO:0001368 Fig. 3
PMID:21376600 PBO:0112290 Fig. 3C
PMID:21376600 PBO:0112291 Fig. 3C
PMID:21376600 PBO:0112294 Fig. 3D
PMID:21376600 PBO:0112293 Fig. 3D
PMID:21376600 PBO:0112292 Fig. 3D
PMID:21376600 PBO:0112295 Fig. 3D
PMID:21376600 PBO:0112280 Plo1 localization to the contractile ring was abolished in the Mid1-T517A mutant (Figures S1C and S1D; 0 of 66 mitotic T517A cells with Plo1-GFP at the contractile ring compared to 26 of 58 in control mitotic cells)
PMID:21376600 PBO:0094506 Fig. 2A and E
PMID:21376600 PBO:0094506 Fig. 2A and E
PMID:21376600 MOD:00046 Fig. 2A and E
PMID:21376600 PBO:0094506 Fig. 2A and E
PMID:21376600 PBO:0094506 Fig. 2A and E
PMID:21376600 PBO:0094506 Fig. 2A and E
PMID:21376600 PBO:0112276 Fig. 1B
PMID:21376600 PBO:0112276 Fig. 1B
PMID:21376600 PBO:0112277 Fig. 1C
PMID:21376600 PBO:0093476 Fig. 1C, D and 2A, E
PMID:21376600 PBO:0112281 Fig. 2B
PMID:21376600 PBO:0112282 Fig. 2B
PMID:21376600 PBO:0112283 Fig. 2B
PMID:21376600 PBO:0112284 Fig. 2B
PMID:21376600 PBO:0112278 Fig. 1C, D and 2A, E
PMID:21376600 PBO:0112279 Fig. 1E
PMID:21376600 GO:1903499 These data altogether reveal mechanisms by which Plo1 acts as a key temporal coordinator of contractile ring assembly events in fission yeast.
PMID:21376600 PBO:0112285 Fig. S2B
PMID:21376600 PBO:0112285 Fig. S2B
PMID:21376600 PBO:0112285 Fig. S2B
PMID:21376600 PBO:0112285 Fig. S2B
PMID:21389117 GO:0005515 fig 7A
PMID:21389117 FYPO:0005382 also fzr3
PMID:21389117 GO:0005515 fig 7A
PMID:21389117 GO:0005515 fig 7A
PMID:21389117 GO:0005515 fig 7A
PMID:21389117 FYPO:0004994 fig2B
PMID:21389117 PBO:0107807 fig2A
PMID:21389117 PBO:0104199 fig 6C
PMID:21389117 PBO:0104199 fig 6C
PMID:21389117 FYPO:0003379 fig2B
PMID:21389117 FYPO:0003380 fig2B
PMID:21389117 FYPO:0003379 fig2A
PMID:21389117 PBO:0107804 fig2A
PMID:21389117 FYPO:0003379 fig 1c, no tetranucleates
PMID:21389117 FYPO:0001000 fig 1B: 4 nuclei appear later than normal.
PMID:21389117 FYPO:0000587 fig 1B: 4 nuclei appear later than normal.
PMID:21389117 FYPO:0005412 fig 1B: 4 nuclei appear later than normal.
PMID:21389117 PBO:0107794 I'm not completely sure if the Slp1-APC degrades mes1 or only ubiquitinates it, but this is most likely correct?...
PMID:21389117 GO:1990950 i changed this to +ve reg /AL
PMID:21389117 FYPO:0005382 also fzr2 &3
PMID:21429938 PBO:0097898 cross between h+ and h- deletions, allowed to sporulate immediately
PMID:21429938 PBO:0095337 cross between h+ and h- deletions, allowed to sporulate immediately
PMID:21429938 PBO:0095338 cross between h+ and h- deletions, allowed to sporulate immediately
PMID:21429938 FYPO:0002485 cross between h+ and h- deletions, allowed to sporulate immediately
PMID:21436456 GO:0005515 A yeast two-hybrid screen using full-length Clr4 as the bait identified Mlo3 (12) as an interacting protein (table S1). Mlo3 is related to Saccharomyces cerevisiae Yra1 and mammalian Aly/REF (13) and is required for nuclear export of RNA (13). Immunoprecipitation analysis detected Mlo3 interacting with Clr4 (Fig. 1A) and another ClrC subunit, Rik1 (fig. S1). Moreover, recombinant Mlo3 bound Clr4, and this interaction was mediated by the amino-terminal (amino acids 1 to 55) and carboxy-terminal (amino acids 134 to 199) regions of Mlo3 (fig. S2), known to bind mRNA export machinery (13). Thus, Clr4 associates with Mlo3 in vitro and in vivo.
PMID:21436456 PBO:0108263 However, mlo3Δ resulted in a considerable increase in the levels of centromeric repeat transcripts, although to a lesser extent than in clr4Δ (Fig. 1B).
PMID:21436456 PBO:0108263 However, mlo3Δ resulted in a considerable increase in the levels of centromeric repeat transcripts, although to a lesser extent than in clr4Δ (Fig. 1B).
PMID:21436456 PBO:0110849 Expression profiling of mlo3Δ cells on both DNA strands showed dramatic accumulation of antisense RNAs at euchromatic loci (~23.5% of genes) (fig. S7), in particular at convergent genes (fig. S8)
PMID:21436456 PBO:0110850 However, the mlo3-A h2a.zΔ double mutant showed a synergistic increase in antisense RNAs (18.6% of genes) (Fig. 3C and figs. S8 and S9)Because clr4Δ and ago1Δ enhance antisense RNA levels when combined with a variant histone h2a.zΔ (10), we examined the mlo3-A mutant transcriptome with or without H2A.Z. Like clr4Δ and ago1Δ, mlo3-A also showed weak up- regulation of antisense RNAs (4.7% genes) (fig. S9).
PMID:21436456 GO:0071040 Thus, Mlo3 physically associates with TRAMP, a complex involved in the surveillance and degradation of aberrant RNA by the exosome. In this regard, the antisense profile of mlo3Δ closely resembles that of rrp6Δ (Fig. 3, C and E, and fig. S8).
PMID:21436456 PBO:0110853 Mlo3 is required for suppression of antisense RNAs targeted by Clr4 and by the exosome. (A) Strand-specific RTPCR of RNA isolated from WT and mlo3Δ
PMID:21436456 PBO:0110852 Mlo3 is required for suppression of antisense RNAs targeted by Clr4 and by the exosome. (A) Strand-specific RTPCR of RNA isolated from WT and mlo3Δ
PMID:21436456 PBO:0110851 Mlo3 is required for suppression of antisense RNAs targeted by Clr4 and by the exosome. (A) Strand-specific RTPCR of RNA isolated from WT and mlo3Δ
PMID:21436456 FYPO:0004201 Interestingly, mlo3-A caused a decrease in levels of centromeric siRNA as compared to WT (Fig. 2D).
PMID:21436456 PBO:0110848 A methylation assay using recombinant Mlo3 carrying single- or double-mutant combinations showed that Clr4 methylates K167 of Mlo3 in vitro (Fig. 2B).
PMID:21436456 PBO:0110847 A methylation assay using recombinant Mlo3 carrying single- or double-mutant combinations showed that Clr4 methylates K167 of Mlo3 in vitro (Fig. 2B).
PMID:21436456 PBO:0110846 Recombinant Clr4 could methylate the carboxy- terminal region of Mlo3, but not the amino-terminal or middle region (Fig. 2A). Within the carboxy-terminal region, lysines 165 and 167 are in a sequence context that resembles H3K9. We mutated these and lysines 179 and 180 to alanine. A methylation assay using recombinant Mlo3 carrying single- or double-mutant combinations showed that Clr4 methylates K167 of Mlo3 in vitro (Fig. 2B).
PMID:21436456 GO:0140746 [vw I did not use processing because this seems to be catabolism] Thus, in addition to creating H3K9me binding sites for RITS, Clr4 physically and functionally links RITS to Mlo3 to mediate processing of centromeric transcripts.
PMID:21436456 FYPO:0004201 Indeed, mlo3Δ caused severe reduction in the levels of centromeric siRNAs (Fig. 1D).
PMID:21436456 PBO:0110845 his interaction was not sensitive to DNase I and RNase A treatment but was severely compromised upon loss of Clr4 (Fig. 1C), suggesting that Clr4 connects Mlo3 to RNA interference (RNAi).
PMID:21436456 FYPO:0004201 Further reduction in siRNAs was observed in mlo3-A H3K9R double mutant (Fig. 2D), although a residual signal seemed to be present when compared to clr4Δ.
PMID:21436456 PBO:0110844 We found that Mlo3 coimmunoprecipitated with Chp1, a subunit of RITS (Fig. 1C).
PMID:21436456 FYPO:0003557 Because clr4Δ and ago1Δ enhance antisense RNA levels when combined with a variant histone h2a.zΔ (10), we examined the mlo3-A mutant transcriptome with or without H2A.Z. Like clr4Δ and ago1Δ, mlo3-A also showed weak up- regulation of antisense RNAs (4.7% genes) (fig. S9).
PMID:21436456 FYPO:0005522 However, mlo3Δ resulted in a considerable increase in the levels of centromeric repeat transcripts, although to a lesser extent than in clr4Δ (Fig. 1B).
PMID:21436456 PBO:0108265 However, mlo3Δ resulted in a considerable increase in the levels of centromeric repeat transcripts, although to a lesser extent than in clr4Δ (Fig. 1B).
PMID:21436456 GO:0000791 Mlo3 showed a broad distribution at euchromatic loci and a relative depletion at heterochromatic regions (figs. S5 and S6).
PMID:21436456 FYPO:0002359 Figure S3. mlo3∆ cells maintain H3K9me2 and Swi6 localization at centromeres, mating type locus and subtelomeric loci
PMID:21436456 FYPO:0000862 Figure S3. mlo3∆ cells maintain H3K9me2 and Swi6 localization at centromeres, mating type locus and subtelomeric loci
PMID:21436456 PBO:0110843 Figure S3. mlo3∆ cells maintain H3K9me2 and Swi6 localization at centromeres, mating type locus and subtelomeric loci
PMID:21437270 FYPO:0005371 ch16
PMID:21441914 FYPO:0000088 no expressivity extension because of decreased growth when untreated
PMID:21441914 FYPO:0000085 no expressivity extension because of decreased growth when untreated
PMID:21441914 FYPO:0000267 no expressivity extension because of decreased growth when untreated
PMID:21441914 FYPO:0000268 no expressivity extension because of decreased growth when untreated
PMID:21441914 FYPO:0000088 no expressivity extension because of decreased growth when untreated
PMID:21441914 FYPO:0000268 no expressivity extension because of decreased growth when untreated
PMID:21441914 FYPO:0000088 no expressivity extension because of decreased growth when untreated
PMID:21441914 FYPO:0000085 no expressivity extension because of decreased growth when untreated
PMID:21441914 FYPO:0000085 no expressivity extension because of decreased growth when untreated
PMID:21441914 FYPO:0000088 no expressivity extension because of decreased growth when untreated
PMID:21441914 FYPO:0000268 no expressivity extension because of decreased growth when untreated
PMID:21441914 FYPO:0000267 no expressivity extension because of decreased growth when untreated
PMID:21441914 FYPO:0000085 no expressivity extension because of decreased growth when untreated
PMID:21441914 FYPO:0000088 no expressivity extension because of decreased growth when untreated
PMID:21441914 FYPO:0000268 no expressivity extension because of decreased growth when untreated
PMID:21441914 FYPO:0000267 no expressivity extension because of decreased growth when untreated
PMID:21441914 FYPO:0000085 no expressivity extension because of decreased growth when untreated
PMID:21441914 FYPO:0000267 no expressivity extension because of decreased growth when untreated
PMID:21441914 FYPO:0000267 no expressivity extension because of decreased growth when untreated
PMID:21441914 FYPO:0000268 no expressivity extension because of decreased growth when untreated
PMID:21444751 FYPO:0002826 Collectively, these results indicate that in fission yeast, a ?-TuRC- like complex exists as a stable structure in vivo independent of the Mto1/2 complex
PMID:21449049 FYPO:0007100 mei4-N136A combined with pat1-114 was efficiently blocked at the meiosis I onset with telomere clustered at SPBs (in the bouquet configuration) at 32˚C, which arrest can be released by a temperature shift down to 25˚C.
PMID:21449049 FYPO:0007100 mei4-N136A combined with pat1-114 was efficiently blocked at the meiosis I onset with telomere clustered at SPBs (in the bouquet configuration) at 32˚C, which arrest can be released by a temperature shift down to 25˚C.
PMID:21450810 PBO:0100550 C11-F32S was more active in yJI1 than in yYH1, while wild-type C11 had no effect (Sector 4).
PMID:21450810 PBO:0100550 Rpc2-T455I was clearly more active (white) in yJI1 than in yYH1, consistent with dT(6) readthrough as expected.
PMID:21481773 PBO:0112757 inhibitor GO:0031543 peptidyl-proline dioxygenase activity Importantly, Sre1N also failed to accumulate in NLS-ofd1 nro1Δ cells in the absence of oxygen despite the restored Ofd1 nuclear localization (Fig. 4B, lanes 10–12). Taken together, these data support previous studies and demonstrate that Nro1 functions as a direct inhibitor of Ofd1 in Sre1N
PMID:21481773 PBO:0112689 sre1 n terminus isoform***********In nro1Δ cells with Ofd1 retained in the cytosol due to the loss of Nro1-mediated nuclear localization, Sre1N failed to accumulate in anaerobic conditions (Fig. 4B, lanes 7–9).
PMID:21481773 PBO:0112690 sre1 n terminus isoform***********. As previously reported, Sre1N accumulated in sre1N cells under anaerobic conditions (Fig. 4B, lanes 1–3)(Lee et al., 2009).
PMID:21481773 PBO:0112688 (with ofd1)
PMID:21481773 PBO:0112684 Ofd1 was enriched in the nucleus with little cytosolic staining consistent with previous findings (Fig. 3A)(
PMID:21481773 PBO:0112686 In sre1N nro1Δ cells, Ofd1 showed diffuse cytosolic staining indicating that Nro1 is required for Ofd1 nuclear localization. Staining for Ofd1 was specific as ofd1Δ cells showed no signal. Together, these results show that nuclear localization of Ofd1 is linked to Nro1.
PMID:21481773 PBO:0112685 Ofd1 was enriched in the nucleus with little cytosolic staining consistent with previous findings (Fig. 3A)(
PMID:21518960 FYPO:0001249 assayed at ars1 and ars2004 (early-firing origins)
PMID:21518960 FYPO:0005108 assayed elongation from ori1-200
PMID:21518960 PBO:0105449 comment assayed at ars1 and ars2004
PMID:21518960 FYPO:0005107 comment assayed at ars1 and ars2004
PMID:21518960 FYPO:0005107 comment assayed at ars1 and ars2004
PMID:21518960 PBO:0105447 assayed at ars1 and ars2004 (early-firing origins)
PMID:21518960 PBO:0100905 predominantly at early-firing origins including ars1 and ars2004, but not AT1041; Mrc1 associates with origins later than MCM complex, but slightly earlier than Cdc45
PMID:21518960 FYPO:0001249 assayed at ars1 and ori1-200 (early-firing origins); only affects origins normally bound by Mrc1
PMID:21518960 PBO:0105448 assayed elongation from ars1 and ars2004 (early-firing origins)
PMID:21536008 GO:0016651 "heterologous cytc as acceptor. they had to include this as etp1 wouldn't accept an electron otherwise. ""S. pombe does not express any endogenous mitochondrial cytochromes P450 that could act as terminal electron acceptors"""
PMID:21540296 PBO:0035590 fig 7a
PMID:21540296 FYPO:0002060 fig 1a
PMID:21540296 FYPO:0002061 fig 1a
PMID:21540296 FYPO:0002061 fig 1a
PMID:21540296 PBO:0035577 t-shift on mitotic entry fig1d
PMID:21540296 PBO:0035578 t-shift on mitotic entry fig1d
PMID:21540296 PBO:0035579 t-shift on mitotic entry fig1c
PMID:21540296 PBO:0035579 t-shift on mitotic entry fig1c
PMID:21540296 FYPO:0001513 t-shift on mitotic entry fig1c
PMID:21540296 PBO:0103824 t-shift on mitotic entry fig1c
PMID:21540296 FYPO:0005424 t-shift on mitotic entry fig1c
PMID:21540296 PBO:0035583 fig 4
PMID:21540296 MOD:00046 fig 5c
PMID:21540296 PBO:0035594 figure 7e
PMID:21540296 PBO:0035593 figure 7c, no rescue of cnd-2
PMID:21540296 FYPO:0002061 figure 7c, no rescue of cnd-2
PMID:21540296 PBO:0035592 fig 7a
PMID:21540296 PBO:0035592 fig 7a
PMID:21540296 PBO:0035590 fig 7a
PMID:21540296 PBO:0035590 fig 7a
PMID:21540296 PBO:0035591 fig 7a
PMID:21561865 MOD:00047 present at basal level; increased in presence of hydroxyurea
PMID:21561865 MOD:00047 present at basal level; increased in presence of hydroxyurea
PMID:21610214 GO:0043169 sulphate
PMID:21633354 PBO:0093730 all tested chromosome loci (Fig. 2g).
PMID:21633354 FYPO:0003286 decreased along arms
PMID:21633354 PBO:0107913 centromeric
PMID:21633354 PBO:0107914 H3-pS10 used to detect ark1 activity
PMID:21633354 PBO:0093730 condensin, which subunit assayed?
PMID:21633354 FYPO:0001357 In contrast, the growth defect and TBZ sensitivity of pcs1Δ cells are not suppressed by the sfc3-1 mutation, whereas they are suppressed by an increase in kinetochore condensin (Fig. 1d).
PMID:21633354 PBO:0093730 all tested chromosome loci (Fig. 2g).
PMID:21633354 PBO:0093563 we engineered a Cnd2–Cnp3C fusion protein, which targets kinetochores through the Cnp3C domain32, even in pcs1Δ cells. The expression of this fusion protein largely suppresses the growth defect, sensitivity to thiabendazole (TBZ, a microtubule destabilizing drug) and the incidence of lagging chromosomes in pcs1Δ cells, whereas neither Cnd2 nor Cnp3C protein alone suppresses these phenotypes (Fig. 1c and Supplementary Fig. 7). These
PMID:21652630 FYPO:0000421 see S5A
PMID:21652630 FYPO:0002858 in fig s4b there is septal material hanging around one cell end
PMID:21664573 FYPO:0000168 ABOLISHED Fig 2 C
PMID:21664573 PBO:0111956 fig 1A
PMID:21664573 FYPO:0002061 fig 3A. bub3 Δklp5 double mutants arrest as inviable micro-colonies of cells
PMID:21664573 PBO:0111957 fig 1A
PMID:21664573 FYPO:0005727 fig 2 b
PMID:21664573 FYPO:0005726 fig 2 b c
PMID:21664573 FYPO:0002060 (Supplemental Figure 2B)
PMID:21664573 FYPO:0002060 (Supplemental Figure 2B)
PMID:21664573 FYPO:0002060 (Supplemental Figure 2B)
PMID:21664573 FYPO:0002060 (Supplemental Figure 2B)
PMID:21664573 FYPO:0002061 (Supplemental Figure 2B)
PMID:21664573 FYPO:0002060 (Figure 1D, Supplemental Figure 2A)
PMID:21664573 FYPO:0002060 (Figure 1D, Supplemental Figure 2A)
PMID:21664573 FYPO:0002060 (Figure 1D, Supplemental Figure 2A)
PMID:21664573 FYPO:0002060 (Figure 1D, Supplemental Figure 2A)
PMID:21664573 PBO:0036897 in vitro (Figure 1C & 2D)
PMID:21664573 PBO:0111958 fig 1A
PMID:21664573 PBO:0036900 Figure 5B
PMID:21664573 PBO:0036900 Figure 5B
PMID:21664573 FYPO:0005726 (Figure 4E).
PMID:21664573 FYPO:0005726 (Figure 4E).
PMID:21664573 PBO:0105625 Figure 5B
PMID:21664573 PBO:0105624 Figure 5B
PMID:21664573 PBO:0036897 Figure 5B
PMID:21664573 PBO:0036897 Figure 5B
PMID:21664573 FYPO:0005728 Fig 4d NORMAL SILENCING
PMID:21664573 FYPO:0005728 Fig 4d NORMAL SILENCING
PMID:21664573 FYPO:0005728 Fig 4c NORMAL SILENCING
PMID:21664573 FYPO:0005727 fig 3 b
PMID:21664573 FYPO:0005727 fig 3 b
PMID:21664573 FYPO:0005727 fig 3 b
PMID:21664573 FYPO:0001234 fig 3a.
PMID:21676862 GO:0071933 Fig 1
PMID:21693583 FYPO:0001234 Fig. 8B
PMID:21693583 PBO:0102392 Fig. 8A
PMID:21693583 GO:0030036 MF? myo1
PMID:21693583 PBO:0102393 Fig. 8B
PMID:2170029 FYPO:0006822 high temp is permissive
PMID:2170029 FYPO:0001234 high temp is permissive
PMID:2170029 PBO:0095579 std temp is restrictive
PMID:2170029 PBO:0095578 high temp is permissive
PMID:2170029 FYPO:0002061 temperature restrictive for dis2cs alone
PMID:2170029 FYPO:0001234 temperature restrictive for dis2cs alone
PMID:2170029 FYPO:0002061 temperature permissive for dis2cs alone
PMID:2170029 FYPO:0001234 temperature restrictive for dis2cs alone
PMID:2170029 FYPO:0001234 temperature restrictive for dis2cs alone
PMID:2170029 FYPO:0001234 temperature restrictive for dis2cs alone
PMID:21703453 PBO:0093464 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 PBO:0093464 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 PBO:0093464 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 PBO:0093464 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 PBO:0093464 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 PBO:0093464 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 PBO:0093464 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 PBO:0093465 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 PBO:0093465 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 PBO:0093465 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 PBO:0093465 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 PBO:0093465 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 PBO:0093465 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 PBO:0093465 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 PBO:0093465 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 MOD:00047 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 PBO:0093465 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 PBO:0096621 This alleles recruits Pom1 to ectopic sites at the lateral plasma membrane
PMID:21703453 GO:0051286 Requires auto-phosphorylation to be restricted to cell tips (not restricted to cell tips for Pom1-6A and Pom1-KD allele)s
PMID:21703453 GO:0005886 "recombinant Pom1 N-terminus (MBP-Pom11–699) was able to bind directly to several, but not all, negatively charged lipids, namely phosphatidylserine, phosphatidylinositol phosphates, and cardiolipin in a protein-lipid overlay assay (Figure 2D). Phosphatidylserine and phosphatidylinositol phosphates are components of the plasma membrane. Cardiolipin is mostly found in the inner mitochondrial membrane, and so it is unclear whether this interaction exists in vivo. We also note that, probably due to its high global positive charge (+15.5 for MBP-Pom11–699, +25 for Pom11–699 at pH 7), MBP-Pom11–699 bound the nitrocellulose membrane, resulting in significant background. Together, these experiments suggest that Pom1 directly associates with lipids at the plasma membrane through its basic region."""
PMID:21703453 GO:0106186 see https://github.com/geneontology/go-annotation/issues/4758
PMID:21703453 PBO:0096620 not restricted to cell tips
PMID:21703453 PBO:0096620 not restricted to cell tips
PMID:21703453 PBO:0096619 in tea4-RVXF* background
PMID:21703453 PBO:0096617 required for detachment from plasma membrane
PMID:21703453 PBO:0096616 required for detachment from plasma membrane
PMID:21703453 GO:0051285 Requires auto-phosphorylation to be restricted to cell tips (not restricted to cell tips for Pom1-6A and Pom1-KD allele)s
PMID:21703453 PBO:0093464 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 PBO:0093464 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 MOD:00046 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 MOD:00046 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 GO:0051286 Requires auto-phosphorylation to be restricted to cell tips (not restricted to cell tips for Pom1-6A and Pom1-KD allele)s
PMID:21703453 PBO:0093464 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 PBO:0093464 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 MOD:00046 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 PBO:0093464 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 MOD:00046 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 MOD:00046 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 MOD:00046 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 MOD:00046 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 MOD:00046 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 MOD:00046 I guess some might be false positives but Sophie said it should be ok.
PMID:21703453 PBO:0093464 I guess some might be false positives but Sophie said it should be ok.
PMID:2172964 FYPO:0000761 both partners cyr1delta
PMID:21775631 PBO:0101474 Figure S2A
PMID:21775631 PBO:0101474 Figure S2A
PMID:21775631 PBO:0097865 Figure S2B
PMID:21775631 PBO:0100820 Figure S2B
PMID:21775631 FYPO:0001915 Figure 1A Figure 5D
PMID:21775631 PBO:0101474 Figure S2A
PMID:21775631 PBO:0101475 Figure S2B
PMID:21811607 FYPO:0001460 basal transcription is meaningless because emm contains calcium
PMID:21813639 GO:1902969 candidate for involved_in_or_involved_in_regulation_of qualifier
PMID:21828039 FYPO:0003073 homozygous diploid
PMID:21832151 PBO:0024920 endosomal localization requires F-actin (assayed using latrunculin A)
PMID:21847092 GO:0008270 bound by the C-terminal dsrbd domain
PMID:21849474 FYPO:0006617 Fig 1A
PMID:21849474 FYPO:0006617 Fig1A Fig2A
PMID:21849474 FYPO:0006617 Fig 1A
PMID:21849474 FYPO:0006617 Fig 1A Fig2A
PMID:21849474 FYPO:0006617 Fig 1A
PMID:21849474 FYPO:0006617 Fig 1A
PMID:21849474 PBO:0098579 Fig7A, B localisation of rga4 by blt1+ is more extensive than wild type rga4 localisation but rescues the wide cell phenotype of the rga4 deletion
PMID:21849474 GO:0031520 Fig9 cdc42-CRIB-GFP localisation is actin dependent and sensitive to low levels (10mM) Lat A
PMID:21849474 FYPO:0001293 Fig2B
PMID:21849474 FYPO:0001294 Fig 2 C
PMID:21849474 FYPO:0001294 Fig 2 C
PMID:21849474 PBO:0098563 Fig 3 increased cell width compared to single mutants
PMID:21849474 PBO:0098563 Fig 3 increased cell width compared to single mutants
PMID:21849474 FYPO:0006616 Fig 1B
PMID:21849474 FYPO:0006616 Table 1 not suppressed by sorbitol
PMID:21849474 FYPO:0006616 Fig 1A
PMID:21849474 PBO:0098580 Fig4D
PMID:21849474 PBO:0098576 Fig6C
PMID:21849474 PBO:0098575 Fig 6B fusion protein driven from nmt41 promoter
PMID:21849474 PBO:0098564 Fig 3 cell width is wider than either of the single mutants
PMID:21849474 FYPO:0006616 Fig 3 no increase in cell width compared to single mutants
PMID:21849474 PBO:0098565 Figure 4 A
PMID:21849474 PBO:0098565 Figure 4 A
PMID:21849474 PBO:0098566 Figure 4 A
PMID:21849474 PBO:0098574 Fig 6A fusion protein driven from nmt41 promoter
PMID:21849474 PBO:0098573 Fig5
PMID:21849474 PBO:0098567 Fig4B
PMID:21849474 PBO:0098568 Fig4B
PMID:21849474 GO:0031520 Fig4B, Fig8 localisation is actin dependent
PMID:21849474 GO:0031520 Fig4B, Fig8 localisation is actin dependent
PMID:21849474 GO:0016328 Fig4A
PMID:21849474 PBO:0098572 Fig5
PMID:21849474 PBO:0098571 Fig5
PMID:21849474 FYPO:0001293 Fig2B
PMID:21849474 PBO:0098570 Fig4D
PMID:21849474 PBO:0098569 Fig4C
PMID:21849474 PBO:0098577 Fig6C
PMID:21849474 PBO:0098578 Fig7A, B
PMID:21849474 FYPO:0006616 Fig 1B
PMID:21849474 FYPO:0006616 Fig 1B
PMID:21849474 FYPO:0006616 Fig 1B
PMID:21849474 FYPO:0006616 Fig 1B
PMID:21849474 FYPO:0006616 Fig 1B
PMID:21849474 FYPO:0006616 Fig 1B
PMID:21849474 FYPO:0006616 Fig 1B
PMID:21849474 FYPO:0006616 Fig 1B
PMID:21849474 FYPO:0006616 Fig 1B
PMID:21849474 FYPO:0006616 Fig 1B
PMID:21849474 FYPO:0002104 Table 1 wide phenotype suppressed by sorbitol
PMID:21849474 FYPO:0006616 Table 1 not suppressed by sorbitol
PMID:21849474 FYPO:0006616 Table 1 not suppressed by sorbitol
PMID:21849474 FYPO:0006616 Table 1 not suppressed by sorbitol
PMID:21849474 FYPO:0006616 Table 1 not suppressed by sorbitol
PMID:21849474 FYPO:0006616 Table 1 not suppressed by sorbitol
PMID:21849474 FYPO:0006616 Table 1 not suppressed by sorbitol
PMID:21849474 FYPO:0006616 Table 1 not suppressed by sorbitol
PMID:21849474 FYPO:0006616 Table 1 not suppressed by sorbitol
PMID:21849474 FYPO:0006616 Table 1 not suppressed by sorbitol
PMID:21849474 FYPO:0006617 Fig 1A
PMID:21849474 FYPO:0006617 Fig 1A
PMID:21849474 FYPO:0006617 Fig 1A
PMID:21849474 FYPO:0006617 Table 1A
PMID:21885283 PBO:0107964 Figure 3C
PMID:21885283 FYPO:0002060 Table I
PMID:21885283 FYPO:0002060 Table I
PMID:21885283 FYPO:0002060 Table I
PMID:21885283 FYPO:0002060 Table I
PMID:21885283 FYPO:0002060 Table I
PMID:21885283 FYPO:0002060 Table I
PMID:21885283 PBO:0018844 Figures 1A, 1B and S1B - S1I; TableI
PMID:21885283 PBO:0107960 Figures 1A, 1B and S1B - S1I; TableI
PMID:21885283 PBO:0018844 Figures 1A, 1B and S1B - S1I; TableI
PMID:21885283 PBO:0018470 Figures 1A, 1B and S1B - S1I; TableI
PMID:21885283 PBO:0097713 Figures 1A, 1B and S1B - S1I; TableI
PMID:21885283 PBO:0018844 Figures 1A, 1B and S1B - S1I; TableI
PMID:21885283 PBO:0107960 Figures 1A, 1B and S1B - S1I; TableI
PMID:21885283 PBO:0018345 Figures 1A, 1B and S1B - S1I; TableI
PMID:21885283 PBO:0018345 Figures 1A, 1B and S1B - S1I; TableI
PMID:21885283 PBO:0097629 Figures 1A, 1B and S1B - S1I; TableI
PMID:21885283 PBO:0097713 Figures 1A, 1B and S1B - S1I; TableI
PMID:21885283 PBO:0097713 Figures 1A, 1B and S1B - S1I; TableI
PMID:21885283 PBO:0098289 Figures 1A, 1B and S1B - S1I; TableI
PMID:21885283 GO:0030139 Figures 1A, 1B and S1B - S1I; TableI
PMID:21885283 PBO:0099724 Figure S1K
PMID:21885283 PBO:0107961 Figure S1K
PMID:21885283 FYPO:0000082 TAble II
PMID:21885283 FYPO:0002061 TAble II
PMID:21885283 FYPO:0002061 TAble II
PMID:21885283 FYPO:0000422 Figure 2A
PMID:21885283 FYPO:0000422 Figure 2A
PMID:21885283 GO:0072583 Figure 2A
PMID:21885283 GO:0072583 Figure 2A
PMID:21885283 FYPO:0000190 Figures 2I – 2K and S3G – S3O)
PMID:21885283 FYPO:0000190 Figures 2I – 2K and S3G – S3O)
PMID:21885283 PBO:0107962 Figures 2L, S3P– S3R
PMID:21885283 PBO:0107962 Figures 2L, S3P– S3R
PMID:21885283 FYPO:0005476 Figure 3B
PMID:21885283 PBO:0107963 Figure 3B
PMID:21885283 PBO:0107962 Figures 3B
PMID:21885283 PBO:0107965 Figure 3D
PMID:21885283 PBO:0107966 Figure 3G
PMID:21885283 GO:0034314 Figure 2A
PMID:21892171 FYPO:0003235 More importantly, mlo3Δ restored H3K9me and Swi6 localization at otr1R::ura4+ and endogenous centromeric repeats in ago1Δ mutant (Fig. 1 c–d)
PMID:21892171 PBO:0110865 However, we found that simultaneous deletion of mlo3 and ago1 restored Rik1 enrichment at cenH (Fig. 6b).
PMID:21892171 PBO:0108387 combining rrp6Δ with ago1Δ largely abolished H3K9me levels at otr1R::ura4+ and dg repeats (Fig. 5c).
PMID:21892171 FYPO:0003235 More importantly, mlo3Δ restored H3K9me and Swi6 localization at otr1R::ura4+ and endogenous centromeric repeats in ago1Δ mutant (Fig. 1 c–d)
PMID:21892171 PBO:0104709 Moreover, cid14Δ suppressed the silencing defect caused by ago1Δ, as indicated by reduction in the levels of dg/dh transcript in cid14Δ ago1Δ as compared to ago1Δ (Fig. 4c).
PMID:21892171 PBO:0097401 Remarkably, loss of Cid14 subunit of TRAMP affects RNAi-independent heterochromatin formation in a manner similar to mlo3Δ. Loss of Cid14 restored H3K9me at otr1R::ura4+ and centromeric repeats in ago1Δ mutant (Fig. 4a–b).
PMID:21892171 PBO:0097401 In contrast, mlo3Δ resulted in considerable restoration of H3K9me at centromeres in clr3Δ ago1Δ cells (Fig. 3b).
PMID:21892171 PBO:0108387 trs1delta failed to restore H3K9me at otr1R::ura4+ in clr3Δ ago1Δ cells (Fig. 3a).
PMID:21892171 PBO:0108387 trs1delta failed to restore H3K9me at otr1R::ura4+ in clr3Δ ago1Δ cells (Fig. 3a).
PMID:21892171 PBO:0104709 resulted in variegated suppression of silencing defects in ago1Δ and dcr1Δ mutants (Fig. 2b and Supplementary Fig. 2b)
PMID:21892171 FYPO:0004065 and changes in the distribution of RNAPII at body of genes (Supplementary Fig. 3c)
PMID:21892171 FYPO:0000084 Deletion of tfs1, which led to 6- azauracil (6-AU) sensitivity (Fig. 2a)
PMID:21892171 PBO:0110864 Mutant cells lacking SHREC subunit Clr3 show marked increase in RNAPII occupancy at centromeric repeats10,11,31
PMID:21892171 PBO:0110863 Mutant cells lacking SHREC subunit Clr3 show marked increase in RNAPII occupancy at centromeric repeats10,11,31
PMID:21892171 PBO:0093563 As expected, cells carrying ago1Δ or dcr1Δ showed severe sensitivity to TBZ, (figure 1e)
PMID:21892171 PBO:0093563 As expected, cells carrying ago1Δ or dcr1Δ showed severe sensitivity to TBZ, (figure 1e)
PMID:21892171 PBO:0093562 As expected, cells carrying ago1Δ or dcr1Δ showed severe sensitivity to TBZ, (figure 1e)
PMID:21892171 PBO:0104709 mlo3Δ also restored silencing and heterochromatin formation at centromeres in dcr1Δ mutant (Supplementary Fig. 2a).
PMID:21892171 GO:0000791 As expected for a factor involved in mRNP formation26,30, Mlo3 interacted with a euchromatic gene (fbp1) transcript (Fig. 1f).
PMID:21892171 PBO:0110862 More importantly, mlo3Δ restored H3K9me and Swi6 localization at otr1R::ura4+ and endogenous centromeric repeats in ago1Δ mutant (Fig. 1 c–d)
PMID:21892171 GO:0000775 Importantly, Mlo3 also interacted with dh transcript (Fig. 1f), consistent with results of ChIP analyses showing Mlo3 enrichment at transcribing centromeric repeats30.As expected for a factor involved in mRNP formation26,30, Mlo3 interacted with a euchromatic gene (fbp1) transcript (Fig. 1f).
PMID:21892171 FYPO:0006992 (Supplementary Fig. 1)
PMID:21892171 FYPO:0006992 (Supplementary Fig. 1)
PMID:21892171 FYPO:0006992 (Fig. 1a).
PMID:21892171 PBO:0104709 Whereas ago1Δ alleviated silencing of a ura4+ reporter inserted at an outer centromeric repeat region (otr1R::ura4+), simultaneous deletions of mlo3 and ago1 restored centromeric silencing (Fig. 1a). T
PMID:21892171 PBO:0105770 ***ABOLISHED***** Whereas ago1Δ alleviated silencing of a ura4+ reporter inserted at an outer centromeric repeat region (otr1R::ura4+), simultaneous deletions of mlo3 and ago1 restored centromeric silencing (Fig. 1a). T
PMID:21892183 PBO:0104112 microtubule sliding brake https://www.ebi.ac.uk/interpro/entry/InterPro/IPR007882/#PUB00070924
PMID:21920317 PBO:0112505 >inc merotelic kinetochore attachment
PMID:21920317 PBO:0112504 Fig 4 B
PMID:21920317 FYPO:0005383 Fig 4 A
PMID:21920317 PBO:0109773 fig 1D
PMID:21920317 PBO:0035389 ( Figure S3 A)
PMID:21920317 PBO:0037712 ( Figure 1 A) phase II (metaphase) was substantially extended
PMID:21920317 PBO:0112503 fig 1D
PMID:21920317 PBO:0037711 fig 1D although sister kinetochore split, segregation ends up mostly normal
PMID:21920317 PBO:0112502 fig 1D
PMID:21920317 PBO:0109773 fig 1D
PMID:21920317 PBO:0037711 fig 1D although sister kinetochore sometimes split, segregation ends up mostly normal
PMID:21920317 PBO:0112502 fig 1D
PMID:21920317 PBO:0109773 fig 1D
PMID:21920317 PBO:0037711 fig 1D although sister kinetochore split, segregation ends up mostly normal
PMID:21920317 PBO:0112502 fig 1D
PMID:21920317 FYPO:0003177 Figure 1C, 1D bipolar attachment of univalents
PMID:21920317 FYPO:0005512 ( Figure 1B) We found that virtually all rec12D cells (n = 240) eventually relo- calized Ark1 to the spindle (Figure 1B), indicating that the SAC ultimately becomes satisfied in achiasmate meiosis.
PMID:21920317 PBO:0097907 ( Figure 1B)
PMID:21920317 PBO:0035382 ( Figure 1 A) continuous rate of spindle elongation (I)
PMID:21920317 GO:0031619 prevents bipolar attachment
PMID:21920317 GO:0031619 prevents bipolar attachment
PMID:21920317 GO:0031619 prevents bipolar attachment (Ask Takeshi if this fits better rec role)
PMID:21920317 PBO:0097918 Fig 6
PMID:21920317 PBO:0112506 fig 4
PMID:21920317 PBO:0109779 fig 4B
PMID:21931816 PBO:0099311 Ser-2 of the heptad repeat
PMID:21945095 PBO:0100906 during replication fork processing
PMID:21945095 PBO:0100906 during replication fork processing
PMID:21945095 PBO:0100906 during replication fork processing
PMID:21945095 PBO:0100906 during replication fork processing
PMID:21945095 PBO:0100905 during mitotic DNA replication initiation
PMID:21945095 PBO:0100905 during mitotic DNA replication initiation
PMID:21945095 GO:0031261 also inferred from interaction with Cdc23 and from timing of localization to chromatin at origins
PMID:21945095 GO:0043596 delete if superseded; authors not sure if it's just a detection issue, but they don't see Rad4 moving away from origins as Mcm10 does
PMID:21945095 PBO:0100905 during mitotic DNA replication initiation
PMID:21949882 GO:0016706 moved down from GO:0016706 30/8/2014 . activated_by(CHEBI:29033)
PMID:21965289 GO:1902425 dis2 is required for the retreival of unclustered kinetochores in nsk delete (additive chromosome segregation defects)
PMID:21979813 PBO:0096915 4E decreased kinetochore mono orientation at meiosis I
PMID:21979813 PBO:0096915 4E decreased kinetochore mono orientation at meiosis I
PMID:21979813 PBO:0096911 2C
PMID:21979813 PBO:0096911 2C
PMID:21979813 FYPO:0000209 2B abolished kinetochore mono orientation at meiosis I
PMID:21979813 PBO:0096914 Fig 4AB
PMID:21979813 FYPO:0000209 2B abolished mono orientation at meiosis I
PMID:21979813 PBO:0096912 2C
PMID:21979813 PBO:0096915 4E decreased kinetochore mono orientation at meiosis I
PMID:21979813 PBO:0096909 1B
PMID:21979813 PBO:0096911 2C
PMID:21981922 PBO:0110274 primarily mediated in the nucleus, as the deletion of ski7, which encodes a cytosolic-specific exosome cofactor, did not perturb rpl30-2 expression (Figure 2A, lane 9, and Figures 2B and 2C).
PMID:21981922 PBO:0110275 Northern blot analysis of RNA prepared from the rrp6D strain revealed robust upregu- lation of rpl30-2 mRNA and pre-mRNA, 5- and 18-fold, respec- tively (Figure 2A, lane 7, and Figures 2B and 2C),
PMID:21981922 PBO:0110276 whereas rpl30-2 mRNA and pre-mRNA were upregulated 1.5- and 3.5- fold, respectively, using RNA from the dis3 mutant (Figure 2A, lane 5, and Figures 2B and 2C).
PMID:21981922 PBO:0110275 rpl30-2 mRNA and pre-mRNA were higher in the pab2D dis3-54 double-mutant strain compared to the single dis3-54 mutant (Figure 2A, compare lanes 5 and 6, and Figures 2B and 2C).
PMID:21981922 PBO:0110277 In contrast, the expression of nonpolyadenylated rpl30-2 from the ribozyme construct was largely insensitive to Pab2- and Rrp6-dependent degradation (Figure 3C, lanes 4–6).
PMID:21981922 PBO:0110274 Consistent with this, rpl30-2 expression levels were unaffected in the rrp6D strain when rpl30-2 was ex- pressed from the intronless construct (Figure 1B, lanes 4 and 6), similar to results using the pab2D mutant (Figure 1B, lane 5).
PMID:21981922 PBO:0110275 however, depletion of Mtr4 in the pab2D strain increased the levels of rpl30-2 mRNA and pre-mRNA compared to the single pab2D strain (Figure 2D, compare lanes 4 and 8).
PMID:21981922 PBO:0110274 Interestingly, the intronless rpl30-2 construct resulted in increased levels of mRNA relative to the intron-containing construct (Figure 1B, lanes 1 and 4); yet, mRNA levels were not increased in the pab2D strain when rpl30-2 was expressed from the intronless construct (Figure 1B, lanes 4 and 5, and Figure 1C).
PMID:21981922 PBO:0110274 Similar results were obtained with a conditional strain in which the genomic copy of mtr4 is expressed from the thiamine-sensi- tive nmt1+ promoter: depletion of Mtr4 did not affect rpl30-2 pre- mRNA and mRNA levels (Figure 2D, compare lanes 3 and 7)
PMID:21981922 PBO:0110275 However, the deletion of cid14 in the pab2D strain increased the levels of rpl30-2 mRNA and pre-mRNA compared to the single pab2D strain (Figure 2A, compare lanes 2 and 4).
PMID:21981922 FYPO:0002926 he ability of Pab2 to bind a poly(A) substrate was completely lost after the substitution of a conserved phenylalanine (F75R) residue within the RNA recognition motif of Pab2 (Figures S3C and S3D).
PMID:21981922 FYPO:0002926 Similarly, a Pab2 variant in which the 11 arginine resi- dues within the arginine/glycine-rich domain were substituted to alanine (R-to-A) showed no poly(A) binding (Figure S3)
PMID:21981922 PBO:0110272 Impor- tantly, Pab2 variants F75R and R-to-A did not rescue the increased levels of rpl30-2 transcripts observed in the pab2D strain (Figure 3E, lanes 2–4), although the two Pab2 variants defective in poly(A) binding were expressed at levels similar to wild-type Pab2 (Figure 3F).
PMID:21981922 PBO:0110272 Impor- tantly, Pab2 variants F75R and R-to-A did not rescue the increased levels of rpl30-2 transcripts observed in the pab2D strain (Figure 3E, lanes 2–4), although the two Pab2 variants defective in poly(A) binding were expressed at levels similar to wild-type Pab2 (Figure 3F).
PMID:21981922 PBO:0092053 we found a 2-fold increase in rpl30-2 mRNA levels after shifting cells growing at 25�C to 37�C (Figure 4A, lanes 1 and 2, and Figure 4B).
PMID:21981922 PBO:0110278 XXXXXXXinresponse to high termperatureXXXXXXX. RNA level expressed from the ribosomal protein-coding gene, rpl30-2, was increased by 4.5-fold in the absence of Pab2 (Lemay et al., 2010). To independently validate this result, we compared rpl30-2 mRNA levels between wild-type and pab2D strains by northern analysis and confirmed a 3-fold incemperature-dependent upregulation of rpl30-2 required Pab2, as it was not observed in a pab2D strain that is defective in pre-mRNA decay (Figure 4A, lanes 3 and 4, and Figure 4B).
PMID:21981922 PBO:0110278 XXXXXXXinresponse to high termperatureXXXXXXX. If negative control of pre-mRNA decay is mainly responsible for the upregulation of rpl30-2 after heat shock, we predicted that rpl30-2 expression from the intronless construct, which is insensitive to Pab2/Rrp6-mediated pre-mRNA decay (Figures 1B and 1C), would not respond to heat stress. Accord- ingly, a wild-type strain that expressed the intronless version of rpl30-2 showed no increase in mRNA levels after heat shock (Figure 4C, lanes 1 and 2, and Figure 4D).
PMID:21981922 PBO:0110284 Strikingly, we noted a 6-fold decrease in the percentage of unspliced rpl30-2 transcript in the absence of Rpl30-1 relative to the wild-type (Figure S5A)
PMID:21981922 PBO:0110278 In agreement with the direct role of Rpl30-1 in the control of rpl30-2 expression, excess Rpl30-1 re- sulted in decreased levels of rpl30-2 mRNA (Figure 6D, lane 4).
PMID:21981922 PBO:0110274 Analysis of RNA from cid14D cells showed normal levels of rpl30-2 pre-mRNA and mRNA (Figure 2A, lane 3, and Figures 2B and 2C)
PMID:21981922 PBO:0110272 RNA level expressed from the ribosomal protein-coding gene, rpl30-2, was increased by 4.5-fold in the absence of Pab2 (Lemay et al., 2010). To independently validate this result, we compared rpl30-2 mRNA levels between wild-type and pab2D strains by northern analysis and confirmed a 3-fold increase of rpl30-2 mRNA in pab2 null cells (Figure 1A, lanes 1 and 2). The use of an intron-specific probe confirmed that the slower- migrating rpl30-2 transcript is the unspliced pre-mRNA (Fig- ure 1A, lane 4).
PMID:21981922 PBO:0110273 specific to one of the two rpl30 paralogs, as the expression of rpl30-1 was unchanged in pab2D cells (Figure 1A).
PMID:21981922 PBO:0110275 In contrast, no cumulative increase in the levels of rpl30-2 tran- scripts was observed in the pab2D rrp6D double-mutant strain relative to the single rrp6D strain (Figure 2A, lanes 7 and 8, and Figures 2B and 2C).
PMID:22017871 PBO:0104135 ubiquitin dependent due to need for rhp6 -AL
PMID:22017871 PBO:0104135 ubiquitin dependent due to need for rhp6 -AL
PMID:22017871 PBO:0104136 ubiquitin dependent due to need for rhp6 -AL
PMID:22017871 PBO:0104138 fig 7c shows direct dna binding
PMID:22017871 PBO:0104142 vw updated
PMID:22024164 PBO:0098899 genome-wide detection
PMID:22024164 FYPO:0001250 assayed using ars2004; not abolished as in hsk1delta alone (but single mutant not shown)
PMID:22024164 FYPO:0001357 actually 25 degrees, but calling it low to make distinction from inviable at 30
PMID:22024164 FYPO:0001249 at late-firing or dormant origins; genome-wide detection
PMID:22024164 FYPO:0001250 genome-wide detection
PMID:22024164 FYPO:0001249 early-firing origins; HU absent
PMID:22024164 FYPO:0001249 at late-firing or dormant origins; genome-wide detection
PMID:22024164 FYPO:0001250 assayed using ars2004; not abolished as in hsk1delta alone (but single mutant not shown)
PMID:22024164 FYPO:0001387 "30 degrees, ""high"" compared to 25 degrees"
PMID:22024164 FYPO:0002061 30 degrees
PMID:22024164 FYPO:0002061 30 degrees
PMID:22024167 PBO:0095671 vw >50% activity
PMID:22033972 GO:0032798 structure
PMID:2203537 PBO:0105792 Figure 3 A
PMID:2203537 PBO:0035363 Figure 3 A
PMID:2203537 PBO:0035360 85% at 160 min
PMID:2203537 PBO:0037182 30% at 120 min. (archery bow)
PMID:2203537 PBO:0098343 Figure 3 A
PMID:22042620 GO:0006643 fig7
PMID:22042620 FYPO:0002237 Fig. S5 B
PMID:22042620 FYPO:0002328 Fig. S5 B
PMID:22042620 FYPO:0002328 Fig. S5 B
PMID:22042620 FYPO:0002237 Fig. S5 B
PMID:22042620 FYPO:0002328 Fig. S5 B
PMID:22042620 GO:0006998 fig7
PMID:22042620 FYPO:0000135 Fig. 7 indicated by NDB cholesterol
PMID:22042620 GO:0006998 fig7
PMID:22042620 PBO:0104497 Fig. 1, A and B;
PMID:22042620 PBO:0104497 Fig. S2, B and C
PMID:22042620 FYPO:0007426 Fig. 3 and Fig. S3, for comparative images of an inserted pro-metaphase wild-type SPB, see Fig. S1 B
PMID:22042620 GO:0090307 not required after insertion
PMID:22042620 FYPO:0000338 Fig. S5 B
PMID:22042620 FYPO:0002328 Fig. S5 B
PMID:22064476 FYPO:0003244 tested using several genes, and reporter construct to test mutations at or near splice sites
PMID:22065639 PBO:0022135 GO:0000236= mitotic prometaphase
PMID:22081013 PBO:0107597 Real time PCR analyses of transcripts derived from the dg or dh outer repeats of the centromere (Figure 3a) demonstrated that whereas cells lacking Chp1 displayed strong accumulation of transcripts, centromeric heterochromatin was unaffected by the loss of the PIN domain in chp1ΔC strains (Figure 3b,c,d Supplementary Figure 9).
PMID:22081013 PBO:0107597 3f
PMID:22081013 PBO:0107598 3f In marked contrast, subtelomeric tlh transcripts (Figure 3a) accumulated in chp1ΔC strains (Figure 3b,e Supplementary Figure 9).
PMID:22081013 FYPO:0003412 3g
PMID:22081013 PBO:0107598 In marked contrast, subtelomeric tlh transcripts (Figure 3a) accumulated in chp1ΔC strains (Figure 3b,e Supplementary Figure 9).
PMID:22084197 GO:0006284 FYPO:0007229
PMID:22085934 GO:0005515 . We used Dcp2 constructs of increasing length (Figure 1D) and found that a Dcp2 region located between residues 255 and 266 is required for the interaction with Edc3 (Figure 1D, lane 3 versus lanes 1 and 2). B
PMID:22085934 PBO:0095398 (Supplementary Figure S8C
PMID:22085934 GO:0005515 In summary, our data show that the Edc3 and Scd6 LSm domains compete for the same Dcp2- binding motifs and that both interactions are mutually exclusive
PMID:22085934 PBO:0095396 (Figure 6A)
PMID:22093869 FYPO:0003928 The phenotype is assessed by the high-throughput sequencing.
PMID:22093869 FYPO:0003928 The phenotype is assessed by the high-throughput sequencing.
PMID:22093869 FYPO:0003928 The phenotype is assessed by the high-throughput sequencing.
PMID:22093869 FYPO:0003928 The phenotype is assessed by the high-throughput sequencing.
PMID:22119525 FYPO:0001226 fig 2A
PMID:22132152 FYPO:0001198 fig 1, 7
PMID:22132152 GO:0005789 n agreement, the corresponding fractions 15–22 iso- lated from the fission yeast strain expressing GFP-tagged Cta4p were immuno-reactive with anti-GFP antibodies
PMID:22132152 PBO:0096345 fig 8 increased calcinurin activity
PMID:22132152 PBO:0107591 fig 6
PMID:22132152 FYPO:0006706 fig 2
PMID:22132152 PBO:0107590 fig 6
PMID:22132152 PBO:0107589 fig 6
PMID:22132152 FYPO:0001457 fig 5
PMID:22132152 FYPO:0000843 fig 5
PMID:22132152 FYPO:0006707 fig 2, 4
PMID:22134091 FYPO:0006180 fig 1c
PMID:22134091 FYPO:0003307 22.3%
PMID:22134091 FYPO:0001943 increased affinity
PMID:22134091 FYPO:0005681 in vitro
PMID:22134091 FYPO:0005681 in vitro
PMID:22134091 FYPO:0002636 fig7F
PMID:22134091 FYPO:0002636 fig7F
PMID:22134091 FYPO:0000964 fig S2
PMID:22134091 FYPO:0005681 in vitro
PMID:22134091 PBO:0100712 fig2B
PMID:22134091 PBO:0100713 fig2AB
PMID:22134091 PBO:0100714 fig2
PMID:22134091 FYPO:0000274 Fig. S3A
PMID:22134091 FYPO:0005681 in vitro
PMID:22134091 FYPO:0000903 fig3
PMID:22134091 FYPO:0003566 Fig.
PMID:22134091 FYPO:0000276 ig. S1B-j
PMID:22134091 FYPO:0000903 fig3
PMID:22140232 PBO:0093796 same as ssp2delta alone
PMID:22140232 PBO:0020037 (Fig. 2A). We found that Ssp2-GFP mainly localized in the nucleus both in glucose-starved cells and in cells grown in glucose-rich medium
PMID:22140232 PBO:0038094 (Fig. 2A). We found that Ssp2-GFP mainly localized in the nucleus both in glucose-starved cells and in cells grown in glucose-rich medium
PMID:22140232 PBO:0102609 ssp2 inferred from mutant phenotype
PMID:22140232 PBO:0093796 same as ssp2delta alone
PMID:22140232 FYPO:0001176 same as ssp2delta alone
PMID:22140232 PBO:0102610 same as ssp2delta alone
PMID:22140232 PBO:0102611 same as ssp2delta alone
PMID:22140232 PBO:0102612 same as ssp2delta alone
PMID:22140232 FYPO:0005742 same as ssp2delta alone
PMID:22140232 PBO:0102616 same as ssp2delta alone
PMID:22140232 PBO:0102621 OK, this MF is a stretch, but based on everything we know phenotypes, export of phosphorylated (typical TF regulation, ortholog etc, I'm confident these phenotypes can be used with curator knowledge to infer this.
PMID:22144463 PBO:0103484 . The loss of Dicer (Dcr1) or Argonaute (Ago1) caused only partial or no reduction in H3K9me at heterochromatin islands except island 5, which showed considerable reduction of H3K9me (fig. S4, A and B). . Moreover, de novo targeting of H3K9me to ssm4 and mei4 occurred even in the absence of Ago1, albeit at levels lower than those of the wild type (fig. S4C), suggesting that additional RNAi-independent mechanism(s) target heterochromatin to meiotic loci. W
PMID:22144463 GO:1902794 during vegetative growth, near genes normally expressed in meiotic cell cycle
PMID:22144463 PBO:0103485 . Deletion of sir2 encoding a nicotinamide adenine dinucleotide– dependent HDAC (3) caused defective H3K9me at the majority of islands (fig. S5A), but SHREC subunits were dispensable (fig. S5B).
PMID:22144463 GO:1902801 negative ::
PMID:22144463 FYPO:0007530 Insertion of the mei4 DSR at the 3′ untranslated region of ura4 resulted in H3K9me at this site, especially when ura4-DSR was expressed (Fig. 2C), and ssm4 lacking its DSR failed to nucleate H3K9me (fig. S8).
PMID:22144463 GO:1902794 during vegetative growth, near genes normally expressed in meiotic cell cycle
PMID:22144909 PBO:0106387 (serine 2)
PMID:22172946 PBO:0037494 fig 2
PMID:22172946 PBO:0037494 fig 2
PMID:22172946 PBO:0093678 fig 1 a
PMID:22172946 PBO:0093678 fig 1 a
PMID:22172946 PBO:0037495 fig3
PMID:22173095 PBO:0102374 fig 7 sdj mutant is unstable
PMID:22173095 PBO:0102374 fig 7 sdj mutant is unstable
PMID:22173095 PBO:0102373 fig 7
PMID:22173095 PBO:0102372 abolished homodimerization Fig. 6,
PMID:22180499 FYPO:0003335 floculation inhibited by galactose
PMID:22184248 GO:0005515 recruitment
PMID:22184248 FYPO:0002638 We also examined localization of Mad2. Mad2 remained on kinetochores in more than 80% of the cells, indicating that the spindle checkpoint was kept active (Fig. S1 B and C)
PMID:22184248 FYPO:0002061 fig 1a
PMID:22184248 FYPO:0000620 fig 1B As shown in Fig. 1B, when Mph1-KD was expressed from pREP41, it caused a weak growth inhibition, which was partially relieved by deletion of mad2+ or mph1+, indicating that expression of Mph1-KD from pREP41 caused a weak delay in mitotic progression as well as a growth defect for a reason unrelated to the checkpoint ac- tivation. We speculate that partially degraded Mph1-KD pro- teins (Fig. S2B) might be toxic to some extent.
PMID:22184248 FYPO:0000620 As shown in Fig. 3A, ex- pression of Mph1-Ndc80-GFP from pREP81 caused an arrest in the wild-type background.
PMID:22184248 FYPO:0002060 figure 1a
PMID:22184248 FYPO:0000620 fig 1B As shown in Fig. 1B, when Mph1-KD was expressed from pREP41, it caused a weak growth inhibition, which was partially relieved by deletion of mad2+ or mph1+, indicating that expression of Mph1-KD from pREP41 caused a weak delay in mitotic progression as well as a growth defect for a reason unrelated to the checkpoint ac- tivation. We speculate that partially degraded Mph1-KD pro- teins (Fig. S2B) might be toxic to some extent.
PMID:22184248 FYPO:0001234 fig 1B As shown in Fig. 1B, when Mph1-KD was expressed from pREP41, it caused a weak growth inhibition, which was partially relieved by deletion of mad2+ or mph1+, indicating that expression of Mph1-KD from pREP41 caused a weak delay in mitotic progression as well as a growth defect for a reason unrelated to the checkpoint ac- tivation. We speculate that partially degraded Mph1-KD pro- teins (Fig. S2B) might be toxic to some extent.
PMID:22184248 PBO:0099035 recruitment (is this the right way around?)
PMID:22184248 FYPO:0000620 When Mad2 was turned on, the index of the chromosome condensation gradually increased from 0 to more than 50%. Binucleate cells, which passed through anaphase, however, did not increase. These results indicated that when Mad2 was turned on, the cells, which were initially at the boundary of G2/M, were arrested before anaphase (Fig. 5B).
PMID:22184248 FYPO:0002060 figure 1a
PMID:22184248 FYPO:0006917 It failed to cause an arrest in a strain lacking mad2+, indicating that the arrest was due to activation of the spindle checkpoint.
PMID:22184248 FYPO:0000620 As shown in Fig. 3A, ex- pression of Mph1-Ndc80-GFP from pREP81 caused an arrest in the wild-type background.
PMID:22184248 FYPO:0002061 fig 1a
PMID:22184248 FYPO:0002060 figure 1a
PMID:22184248 FYPO:0002060 figure 1a
PMID:22235339 PBO:0103124 also assayed using bulk histones from calf thymus
PMID:22235339 PBO:0103125 also assayed using bulk histones from calf thymus
PMID:22235339 PBO:0103123 also assayed using bulk histones from calf thymus
PMID:22267499 FYPO:0001357 Figure 1 A
PMID:22267499 PBO:0111480 Table2
PMID:22267499 FYPO:0006802 Figure 4b
PMID:22267499 FYPO:0000648 Figure 4b
PMID:22267499 FYPO:0006802 Figure 4b
PMID:22267499 FYPO:0006802 Figure 4b
PMID:22267499 FYPO:0000648 Figure 4b
PMID:22267499 FYPO:0000648 Figure 4b
PMID:22267499 FYPO:0000648 Figure 4b
PMID:22267499 FYPO:0004103 Figure 4b
PMID:22267499 FYPO:0004103 Figure 4b
PMID:22267499 GO:0031029 Together, these data lead us to conclude that Ypa2p is involved in determining the timing of mitotic commitment, establishing cell morphology, positioning of the division site, regulation of the SIN, and in completion of cytokinesis.
PMID:22267499 PBO:0111475 Table 3
PMID:22267499 GO:0005737 Both the GFP-Ypa1p and GFP-Ypa2p proteins showed a uniform cyto- plasmic localization and a faint nuclear signal.
PMID:22267499 PBO:0094648 Figure 1 A
PMID:22267499 PBO:0094648 Figure 1 A
PMID:22267499 FYPO:0001357 Figure 1 A
PMID:22267499 PBO:0095634 Figure 1 A
PMID:22267499 FYPO:0002061 Figure 1 A
PMID:22267499 PBO:0111474 Table 3
PMID:22267499 FYPO:0002061 The double mutant ppa2-6 ppa1–D was synthetically lethal (Table 4), even when tetrads were dissected at 36� and 32�, the permissive temperature for ppa2-6.
PMID:22267499 FYPO:0002061 The double mutant ppa2-6 ppa1–D was synthetically lethal (Table 4), even when tetrads were dissected at 36� and 32�, the permissive temperature for ppa2-6.
PMID:22267499 FYPO:0002061 The double mutant ppa2-6 ppa1–D was synthetically lethal (Table 4), even when tetrads were dissected at 36� and 32�, the permissive temperature for ppa2-6.
PMID:22267499 FYPO:0002061 The double mutant ppa2-6 ppa1–D was synthetically lethal (Table 4), even when tetrads were dissected at 36� and 32�, the permissive temperature for ppa2-6.
PMID:22267499 FYPO:0002430 ppa2-6 is cold sensitive and undergoes only a few divisions after a shift to 19� (Table S1, Figure 1, A and B).
PMID:22267499 FYPO:0002061 ppa2-6 is cold sensitive and undergoes only a few divisions after a shift to 19� (Table S1, Figure 1, A and B).
PMID:22267499 PBO:0111473 Table 3
PMID:22267499 FYPO:0002280 The double mutant wee1-50 ypa2–D was syntheti- cally lethal, with the germinating spore giving rise to one or two small, rounded cells at 29� (DNS)�
PMID:22267499 FYPO:0002061 The double mutant wee1-50 ypa2–D was syntheti- cally lethal, with the germinating spore giving rise to one or two small, rounded cells at 29 (DNS)�
PMID:22267499 GO:0031029 These data therefore implicate Ypa2p and Ppa2p in establishing SIN protein asymmetry during anaphase.
PMID:22267499 FYPO:0000648 Measurement of ypa2–D cells revealed that they divide at a reduced cell length at both the permissive and restrictive temperatures, similar to ppa2–D (Table 2).
PMID:22267499 GO:0005737 Both the GFP-Ypa1p and GFP-Ypa2p proteins showed a uniform cyto- plasmic localization and a faint nuclear signal.
PMID:22267499 PBO:0111476 Table 3
PMID:22267499 PBO:0111477 Table 3
PMID:22267499 PBO:0111478 Table 3
PMID:22267499 PBO:0111479 Table2
PMID:22268381 PBO:0096782 ocalization of Dcr1-GFP and GFP-Ago1 was not affected by the loss of Sal3 activity (Figure S1).
PMID:22268381 FYPO:0001513 fig 5
PMID:22268381 PBO:0096781 GFP-Rdp1 was not detected in the nuclei of most cells (Figure 1B).
PMID:22268381 PBO:0096785 fig 5
PMID:22268381 PBO:0096781 GFP-Rdp1 was not detected in the nuclei of most cells (Figure 1B).
PMID:22268381 FYPO:0003094 Moreover, expression of the Rdp1-SV40-NLS construct appeared to suppress centromeric transcript levels below that those found in wild type
PMID:22268381 PBO:0096787 fig 5
PMID:22268381 FYPO:0000091 fig 4
PMID:22268381 FYPO:0000091 fig 4
PMID:22268381 FYPO:0000220 Pericentric transcript levels are increased in sal3 mutants
PMID:22268381 PBO:0096784 onsistent with the scenario in which Rdp1 is a cargo for Sal3, we were able to detect stable interaction between tagged Rdp1 and Sal3 by co-immunoprecipitation (Figure 2B).
PMID:22268381 FYPO:0003094 Moreover, expression of the Rdp1-SV40-NLS construct appeared to suppress centromeric transcript levels below that those found in wild type
PMID:22268381 PBO:0096786 fig 5
PMID:22268381 PBO:0096783 localization of Dcr1-GFP and GFP-Ago1 was not affected by the loss of Sal3 activity (Figure S1).
PMID:22279046 FYPO:0000268 same as hsk1-89 alone
PMID:22279046 FYPO:0001249 same as hsk1-89 alone
PMID:22279046 FYPO:0000085 same as hsk1-89 alone
PMID:22279046 FYPO:0000089 same as hsk1-89 alone
PMID:22279046 FYPO:0000268 same as hsk1-89 alone
PMID:22279046 FYPO:0000088 same as hsk1-89 alone
PMID:22279046 FYPO:0000085 same as hsk1-89 alone
PMID:22279046 FYPO:0000089 same as hsk1-89 alone
PMID:22279046 FYPO:0000088 same as hsk1-89 alone
PMID:22291963 GO:0005634 in asf1-33 at higher temperature
PMID:22291963 PBO:0097785 mild expressivity
PMID:22292001 PBO:0093558 5
PMID:22292001 GO:0000712 "strong contender for GO's ""acts upstream of or within"" (RO:0002264) gp-term relation"
PMID:22292001 GO:0000712 "strong contender for GO's ""acts upstream of or within"" (RO:0002264) gp-term relation"
PMID:22292001 FYPO:0007101 during meiosis I
PMID:22292001 FYPO:0007101 during meiosis I
PMID:22292001 PBO:0104345 5
PMID:22292001 FYPO:0000674 5
PMID:22292001 FYPO:0007102 5d
PMID:22292001 FYPO:0007101 1d
PMID:22292001 FYPO:0007101 during meiosis I
PMID:22292001 FYPO:0007102 5d
PMID:22292001 FYPO:0007102 5d
PMID:22292001 FYPO:0000913 1a
PMID:22292001 FYPO:0007102 1d
PMID:22292001 FYPO:0007103 1d
PMID:22292001 FYPO:0000678 fig2
PMID:22292001 FYPO:0006426 fig2
PMID:22292001 FYPO:0007104 fig2
PMID:22292001 PBO:0104344 5c
PMID:22292001 PBO:0104342 5c
PMID:22292001 PBO:0104343 5c
PMID:22292001 PBO:0104342 5c
PMID:22292001 PBO:0093557 5
PMID:22292001 FYPO:0006419 fig3d
PMID:22292001 FYPO:0007105 fig3e
PMID:22292001 FYPO:0007105 fig3e
PMID:22292001 FYPO:0000678 fig4
PMID:22292001 PBO:0093558 5
PMID:22292001 PBO:0093557 5
PMID:22328580 PBO:0105472 Fig 3A
PMID:22328580 PBO:0105473 Fig 3A
PMID:22328580 FYPO:0002350 Figure 4, A and B,
PMID:22328580 FYPO:0002350 fig 4 D
PMID:22328580 PBO:0021023 Figure Figures 5D, 6C
PMID:22328580 PBO:0021023 Figure Figures 5D, 6C
PMID:22328580 PBO:0021023 Figure Figures 5D, 6C
PMID:22328580 FYPO:0002350 fig 4 D
PMID:22328580 FYPO:0002350 fig 4 D
PMID:22328580 FYPO:0002350 Figure 4, A and B,
PMID:22328580 FYPO:0002350 Figure 4, A and B,
PMID:22328580 FYPO:0002350 Figure 4, A and B,
PMID:22328580 FYPO:0002350 Figure 4, A and B,
PMID:22328580 PBO:0021023 fig 1
PMID:22328580 PBO:0021023 Figure 2D
PMID:22328580 FYPO:0002350 Fig. 3B Figure 4, A and B,
PMID:22328580 FYPO:0002350 Fig. 3B Figure 4, A and B,
PMID:22344254 FYPO:0003031 Fig. 1B and Fig. 1C, respectively Gtr2, and in particular Gtr1, inhibit sexual differentiation in rich medium.
PMID:22344254 GO:0000329 The observed pattern was identical, regardless of the presence or not of amino acids in the medium. To confirm the localization to the vacuole membrane, we stained the gtr1-gfp cells with the lipophilic vacuolar membrane fluorescent dye FM4-64. As shown in Fig. 2B, Gtr1–GFP colocalized with FM4-64 staining, indicating that Gtr1–GFP is concentrated at the membranes of vacuoles in S. pombe.
PMID:22344254 GO:0005774 As shown in Fig. 3, GFP–Tor2, GFP–Mip1 and Pop3–GFP showed similar GFP signals that colocalized with FM4-64 staining. Thus, the three components of the TORC1 complex showed vacuolar membrane localization, independently of the presence or not of amino acids in the medium.
PMID:22344254 GO:0000329 As shown in Fig. 3, GFP–Tor2, GFP–Mip1 and Pop3–GFP showed similar GFP signals that colocalized with FM4-64 staining. Thus, the three components of the TORC1 complex showed vacuolar membrane localization, independently of the presence or not of amino acids in the medium.
PMID:22344254 GO:0000329 As shown in Fig. 3, GFP–Tor2, GFP–Mip1 and Pop3–GFP showed similar GFP signals that colocalized with FM4-64 staining. Thus, the three components of the TORC1 complex showed vacuolar membrane localization, independently of the presence or not of amino acids in the medium.
PMID:22344254 FYPO:0000280 fig 4a
PMID:22344254 FYPO:0000280 fig 4a
PMID:22344254 PBO:0108021 the Gtr1–Gtr2 heterodimer and TORC1 are located in the vacuolar membrane independently of the presence of amino acids. However, only when amino acids are present in the medium does the Gtr1–Gtr2 heterodimer interact physically with TORC1 and activate the TOR pathway to induce cell growth and repress sexual differentiation.
PMID:22344254 PBO:0108021 the Gtr1–Gtr2 heterodimer and TORC1 are located in the vacuolar membrane independently of the presence of amino acids. However, only when amino acids are present in the medium does the Gtr1–Gtr2 heterodimer interact physically with TORC1 and activate the TOR pathway to induce cell growth and repress sexual differentiation.
PMID:22344254 PBO:0097468 ********nitrogen replete/with aa
PMID:22344254 FYPO:0001234 The doubling time of vam6D was shorter in the presence of amino acids, indicating that these cells were still able to respond, at least partially, to the presence of amino acids (Fig. 5A) and that Vam6 has an important role in regulating cell growth in S. pombe but is not essential for responding to the availability of amino acids.
PMID:22344254 FYPO:0001357 We introduced Gtr1Q61L in a vam6D background and found that the double mutant was able to grow normally (Fig. 5B), indicating that constitutively active Gtr1 rescues the cell growth defect of the vam6D mutant.
PMID:22344254 PBO:0108022 These results suggest that Vam6 functions upstream of Gtr1, possibly by acting as a GEF.
PMID:22344254 FYPO:0004482 FM4-64 stained only small vesicles in the cytoplasm of vam6D cells, confirming a defect in vacuolar fusion in these cells.
PMID:22344254 FYPO:0002716 FM4-64 stained only small vesicles in the cytoplasm of vam6D cells, confirming a defect in vacuolar fusion in these cells.
PMID:22344254 FYPO:0004482 FM4-64 stained only small vesicles in the cytoplasm of vam6D cells, confirming a defect in vacuolar fusion in these cells.
PMID:22344254 PBO:0097468 *****nitrogen replete/with aa***** vam6D mutant cells showed similar Rps6 phosphorylation levels to that of wild-type cells in the absence of amino acids. However, in contrast to wild- type cells, vam6D cells did not show an increase in Rps6 phosphorylation in the presence of amino acids.
PMID:22344254 PBO:0108023 ***********nitrogen replete/with aa. AND during aa starvation***********vam6D mutant cells showed similar Rps6 phosphorylation levels to that of wild-type cells in the absence of amino acids. However, in contrast to wild- type cells, vam6D cells did not show an increase in Rps6 phosphorylation in the presence of amino acids.
PMID:22344254 GO:0000329 fig6
PMID:22344254 FYPO:0001234 Fig. 1A Loss of Gtr1 or Gtr2 resulted in the inability of the cells to grow properly, and they divided with a doubling time longer than that of wild-type cells
PMID:22344254 FYPO:0003031 Fig. 1B and Fig. 1C, respectively Gtr2, and in particular Gtr1, inhibit sexual differentiation in rich medium.
PMID:22344254 GO:1990131 We observed that Gtr2–RFP co-precipitated with Gtr1 (Fig. 2D) and that the Gtr1–Gtr2 interaction was stronger in cells growing in the presence of amino acids, indicating that the formation of the heterodimer is stimulated by amino acids.
PMID:22344254 GO:0000329 The observed pattern was identical, regardless of the presence or not of amino acids in the medium. To confirm the localization to the vacuole membrane, we stained the gtr1-gfp cells with the lipophilic vacuolar membrane fluorescent dye FM4-64. As shown in Fig. 2B, Gtr1–GFP colocalized with FM4-64 staining, indicating that Gtr1–GFP is concentrated at the membranes of vacuoles in S. pombe.
PMID:22344254 FYPO:0001234 Fig. 1A Loss of Gtr1 or Gtr2 resulted in the inability of the cells to grow properly, and they divided with a doubling time longer than that of wild-type cells
PMID:22344254 FYPO:0001234 Fig. 1A Loss of Gtr1 or Gtr2 resulted in the inability of the cells to grow properly, and they divided with a doubling time longer than that of wild-type cells
PMID:22344254 FYPO:0001234 Fig. 1A Loss of Gtr1 or Gtr2 resulted in the inability of the cells to grow properly, and they divided with a doubling time longer than that of wild-type cells
PMID:22344254 FYPO:0001234 Fig. 1A Loss of Gtr1 or Gtr2 resulted in the inability of the cells to grow properly, and they divided with a doubling time longer than that of wild-type cells
PMID:22344254 FYPO:0001420 Fig. 1A Loss of Gtr1 or Gtr2 resulted in the inability of the cells to grow properly, and they divided with a doubling time longer than that of wild-type cells
PMID:22344694 PBO:0106009 not shown direct binding but want to capture the fact that it binds the oxidised form
PMID:22344694 PBO:0106009 not shown direct binding but want to capture the fact that it binds the oxidised form
PMID:22349564 FYPO:0001437 Figure 1A
PMID:22349564 FYPO:0001437 Figure 1A
PMID:22349564 FYPO:0003730 Figure 1A
PMID:22349564 FYPO:0003730 Figure 1A
PMID:22349564 FYPO:0003730 Figure 1A
PMID:22349564 FYPO:0001938 5E
PMID:22349564 PBO:0096237 Cox1 was clearly less stable in the Δmss51 mutant than in the wild- type, while Cox2 was poorly labeled in the mutant even before starting the chase, as noted before (Figure 5C).
PMID:22349564 PBO:0096238 Cox2 was detectable in Δmss51 purified mitochondria, although its level was greatly reduced (Figure 5C), consistent with the reduced 35S labeling (Figure 5A)
PMID:22349564 PBO:0105071 Northern blots revealed no defect in the accumulation of mature messengers (Figure 5B)
PMID:22349564 PBO:0105068 Northern blots revealed no defect in the accumulation of mature messengers (Figure 5B)
PMID:22349564 PBO:0105065 As expected, Δppr4 cells clearly lacked Cox1
PMID:22349564 PBO:0105066 Cytb, Cox1, 2 and 3 were clearly visible, although Cox2 was less strongly labeled in both mutants, especially Δmss51 (Figure 5A)
PMID:22349564 PBO:0105065 Cytb, Cox1, 2 and 3 were clearly visible, although Cox2 was less strongly labeled in both mutants, especially Δmss51 (Figure 5A)
PMID:22349564 PBO:0105064 Cytb, Cox1, 2 and 3 were clearly visible, although Cox2 was less strongly labeled in both mutants, especially Δmss51 (Figure 5A)
PMID:22349564 FYPO:0007624 Δmss51 cells showed normal cytochrome b and c1 peaks, but cytochromes aa3 were not detectable.
PMID:22349564 GO:0034551 Thus, in S. pombe, Mss51 appears to be required at a post-translational step of complex IV biogenesis
PMID:22349564 FYPO:0000441 Similarly to the Δcbp3 and Δcbp6 mutants, Δmss51 cells were resistant to antimycin A on glucose medium, showing that they contain a functional complex V
PMID:22349564 FYPO:0003730 (Figure 4B) A deletion mutants showed a clear growth defect on galactose medium
PMID:22349564 GO:0031966 The tagged Mss51 was detected only in the mitochondrial fraction and like Cox2 was strongly resistant to carbonate extraction (Figure 4A), indicating that it is a membrane protein.
PMID:22349564 PBO:0105070 absent respiratory complex III. Figure 2D As expected, the higher molecular weight bands of complex III were absent in the Δppr4 mutant, which lacks complex IV
PMID:22349564 PBO:0105069 absent respiratory complex III Figure 2D In both Δcbp6 and control Δcytb mitochondria, complex III was completely lacking (lanes 3 and 4)
PMID:22349564 FYPO:0007623 Figure 2D In both Δcbp6 and control Δcytb mitochondria, complex III was completely lacking (lanes 3 and 4)
PMID:22349564 PBO:0096238 Figure 2C Thus, virtually all of the Cytb protein synthesized in the Δcbp6 mutant is degraded
PMID:22349564 PBO:0105068 Figure 2A Both the cytb and cox2 mRNAs were present at normal levels in the Δcbp6 mutant
PMID:22349564 PBO:0105067 Figure 2A Both the cytb and cox2 mRNAs were present at normal levels in the Δcbp6 mutant
PMID:22349564 PBO:0105066 Figure 1C
PMID:22349564 PBO:0105065 Figure 1C
PMID:22349564 PBO:0105064 Figure 1C
PMID:22349564 GO:0005739 Figure S4A, B, C
PMID:22349564 PBO:0105066 Figure 1C
PMID:22349564 PBO:0105065 Figure 1C
PMID:22349564 PBO:0105064 Figure 1C
PMID:22349564 FYPO:0007623 Figure 1B
PMID:22349564 FYPO:0007623 Figure 1B
PMID:22349564 FYPO:0000441 Figure 1A
PMID:22354040 PBO:0098698 fig 7 c
PMID:22354040 PBO:0098696 Fig 7 A
PMID:22354040 GO:0042162 Fig 7
PMID:22354040 PBO:0098697 Fig 7 B
PMID:22354040 PBO:0095770 Fig 7B
PMID:22354040 FYPO:0002239 figure 8 A
PMID:22375066 GO:0031588 These results indicated that Ssp2 interacts physically with Amk2 and Cbs2 in vivo, showing that AMPK is indeed a αβγ heterotrimer and that these three subunits interact even under optimal growth conditions.
PMID:22375066 GO:0031588 These results indicated that Ssp2 interacts physically with Amk2 and Cbs2 in vivo, showing that AMPK is indeed a αβγ heterotrimer and that these three subunits interact even under optimal growth conditions.
PMID:22375066 GO:0031588 These results indicated that Ssp2 interacts physically with Amk2 and Cbs2 in vivo, showing that AMPK is indeed a αβγ heterotrimer and that these three subunits interact even under optimal growth conditions.
PMID:22375066 GO:0140648 ( positive). AMPK is required for proper advance entry into mitosis in nitrogen-starved cells and arrest in G1 before Start.
PMID:22375066 GO:0140648 ( positive). AMPK is required for proper advance entry into mitosis in nitrogen-starved cells and arrest in G1 before Start.
PMID:22375066 PBO:0096471 This finding suggested that inactive AMPK is excluded from the nucleus and, upon activation by glucose or nitrogen starvation, part of the AMPK moves into the nucleus.
PMID:22375066 GO:0010514 ( positive). AMPK is required for proper advance entry into mitosis in nitrogen-starved cells and arrest in G1 before Start.
PMID:22375066 PBO:0096473 This result shows that Ssp2 phosphorylation by Ssp1 is required to trigger the nuclear accumulation of the former upon nitrogen or glucose starvation, and that if Ssp2 is not phosphorylated it remains in a cytoplasmic localization, regardless of the nutritional conditions of the cell.
PMID:22375066 GO:0010514 positive
PMID:22375066 GO:0010514 positive
PMID:22375066 GO:0010514 ( positive). AMPK is required for proper advance entry into mitosis in nitrogen-starved cells and arrest in G1 before Start.
PMID:22419817 GO:0031028 "vw deleted ""+ve regulation of"""
PMID:22426534 PBO:0101049 genes in extensions are assayed as represntative of highly transcribed genes
PMID:22426534 PBO:0101051 genes in extensions are assayed as represntative of highly transcribed genes
PMID:22426534 PBO:0101052 genes in extensions are assayed as represntative of highly transcribed genes
PMID:22426534 PBO:0101053 genes in extensions are assayed as represntative of highly transcribed genes
PMID:22426534 PBO:0101050 genes in extensions are assayed as represntative of highly transcribed genes
PMID:22431512 PBO:0102103 localization independent of Ago1
PMID:22431512 PBO:0102103 SO:0001843 =ATF1/CRE; localization independent of Ago1
PMID:22431512 PBO:0102102 localization independent of Ago1
PMID:22431512 PBO:0102102 localization independent of Ago1
PMID:22438582 PBO:0101885 6A
PMID:22438582 PBO:0022389 Figure 1
PMID:22438582 PBO:0101878 5A
PMID:22438582 PBO:0101877 5A
PMID:22438582 PBO:0101882 5A
PMID:22438582 PBO:0101879 Figure 1
PMID:22438582 PBO:0101879 Figure 1
PMID:22438582 PBO:0101879 Figure 1
PMID:22438582 FYPO:0000583 S6
PMID:22438582 FYPO:0000583 S6
PMID:22438582 PBO:0022389 Figure 1
PMID:22438582 PBO:0101879 Figure 1
PMID:22438582 PBO:0100759 Figure 1
PMID:22438582 GO:1990395 MEIOTIC ! Plo1 protein reorganize spindle body during meiosis: Plo1 starts to localize to spindle pole body at the onset of meiosis I, and recruits Cut12 (and Pcp1), which was absent during meiotic prophase.
PMID:22438582 PBO:0022389 Figure 1
PMID:22438582 PBO:0022389 Figure 1
PMID:22438582 PBO:0101882 5
PMID:22438582 PBO:0101882 5
PMID:22438582 FYPO:0000151 FIG 4B
PMID:22438582 PBO:0101874 5F
PMID:22438582 PBO:0101883 6A
PMID:22438582 PBO:0101884 6A
PMID:22438582 PBO:0101886 6A
PMID:2245912 PBO:0097658 cells homozygous for stf1-1 form small colonies at restrictive temperature ~20-200 cells
PMID:2245912 PBO:0020446 cells heterozygous for stf1-1 are more elongated that stf1-1 homozygous cells
PMID:2245912 PBO:0097657 the restrictive temperature for a cdc25-22 diploid is 32°C
PMID:2245912 FYPO:0000674 Table 3 suppressor of cdc25-22
PMID:2245912 PBO:0097658 cells heterozygous for stf1-1 form small colonies at restrictive temperature ~20-200 cells
PMID:2245912 PBO:0020446 cells homozygous for stf1-1 are not as elongated as stf1-1 heterozygous cells at restrictive temperature
PMID:2245912 PBO:0097659 stf1-1/stf1-2 cells are not as elongated as stf1-1 heterozygous cells at restrictive temperature
PMID:2245912 PBO:0097658 stf1-1/stf1-3 cells form small colonies at restrictive temperature ~20-200 cells
PMID:2245912 FYPO:0000674 Table 4 stf1-1 is a suppressor of cdc25-M51
PMID:2245912 FYPO:0000674 Table 4 suppressor of cdc25-disruption occasional cdc- cells observed
PMID:2245912 PBO:0020446 stf1-1/stf1-3 cells are not as elongated as stf1-1 heterozygous cells at restrictive temperature
PMID:2245912 PBO:0097660 Table 4
PMID:2245912 FYPO:0001490 Table 5 no genetic interaction with stf1-1
PMID:2245912 FYPO:0001490 Table 5 no genetic interaction with stf1-1
PMID:2245912 FYPO:0001490 Table 5 no genetic interaction with stf1-1
PMID:2245912 FYPO:0001492 Table 5 no genetic interaction with stf1-1.
PMID:2245912 FYPO:0001492 Table 5 This mutant is a revertant of cdc2-M35
PMID:2245912 FYPO:0001490 Table 5 no genetic interaction with stf1-1 cdc2-59 is a cold sensitive cdc2 mutant cdc at low (25°C) temperature and wee at high temperature (35°C)
PMID:2245912 FYPO:0006822 Table 5 no genetic interaction with stf1-1
PMID:2245912 FYPO:0006822 Table 5 no genetic interaction with stf1-1
PMID:2245912 FYPO:0006822 Table 5 cdc2-3w and stf1-1 have additive effect on cdc25-22 cell size at restrictive temperature
PMID:2245912 FYPO:0006822 Table 6 wee1-50 and stf1-1 have an additive effect to suppress cdc25-22 phenotype at the restrictive temperature
PMID:2245912 FYPO:0006822 Table 6
PMID:2245912 PBO:0093770 Table 7 Cells are slightly shorter at high temperature when stf1-1 present
PMID:2245912 PBO:0093770 Table 7 Cells are slightly shorter at high temperature when stf1-1 present
PMID:2245912 FYPO:0001490 dis2+ over expression reverses the stf1-1 suppression cdc25-22
PMID:2245912 FYPO:0006822 Table 5 cdc2-1w and stf1-1 have additive effect on cdc25-22 cell size at restrictive temperature
PMID:2245912 FYPO:0001492 Table 5 cdc2-1w rescues cdc25-22 but cells are long
PMID:2245912 FYPO:0001491 Table 5
PMID:2245912 FYPO:0001492 Table 8 no genetic interaction with stf1-1
PMID:2245912 FYPO:0001490 Table 8 no genetic interaction with stf1-1
PMID:2245912 FYPO:0001492 Table 4 suppressor of cdc25-disruption occasional cdc- cells observed
PMID:2245912 FYPO:0001492 Table 4 stf1-1 is a suppressor of cdc25-M51
PMID:2245912 FYPO:0001492 Table 4 suppressor of cdc25-22
PMID:2245912 FYPO:0001492 Table 4 suppressor of cdc25-22
PMID:2245912 PBO:0097658 same phenotype as cells homozygous for stf1-1
PMID:2245912 PBO:0020446 same phenotype as cells homozygous for stf1-1
PMID:2245912 PBO:0097660 Table 4
PMID:2245912 FYPO:0000674 Table 4 suppressor of cdc25-22
PMID:2245912 FYPO:0000674 Table 4 suppressor of cdc25-22
PMID:2245912 FYPO:0006822 Table 5 no genetic interaction with stf1-1
PMID:2245912 FYPO:0006822 Table 5 no genetic interaction with stf1-1
PMID:2245912 FYPO:0001492 Table 5 This mutant is a revertant of cdc2-M35
PMID:22474355 PBO:0111713 ChIP analyses showed that Ers1 localization at the mating type locus (cenH) and telomeres was severely de- creased in swi6Δ and clr4Δ cells (Fig. S5A).
PMID:22474355 PBO:0111707 To test the hypothesis that the nu- clear dot localization of Ers1 was attributable to an interaction with H3K9me-bound CD proteins, EGFP-Ers1WT localization was next examined in swi6Δ, chp1Δ, and chp2Δ cells. The localization of EGFP-Ers1WT was clearly abolished in swi6Δ cells similar to that observed in clr4Δ, whereas WT localization patterns were retained in the chp1Δ and chp2Δ cells (Fig. 4C and Fig. S4C).
PMID:22474355 PBO:0111707 To test the hypothesis that the nu- clear dot localization of Ers1 was attributable to an interaction with H3K9me-bound CD proteins, EGFP-Ers1WT localization was next examined in swi6Δ, chp1Δ, and chp2Δ cells. The localization of EGFP-Ers1WT was clearly abolished in swi6Δ cells similar to that observed in clr4Δ, whereas WT localization patterns were retained in the chp1Δ and chp2Δ cells (Fig. 4C and Fig. S4C).
PMID:22474355 PBO:0111708 sug- gesting that a physical association with Swi6, but not the other CD proteins, was required for the heterochromatic localization of Ers1.
PMID:22474355 PBO:0111709 Moreover, the interaction between Ers1 and Swi6 was weakened by the presence of the C62 mutation (Fig. 4 D and E). Taken together, these results suggested that Ers1 associates with both Hrr1 and Swi6, and that the C62 mutation impairs both associations.
PMID:22474355 PBO:0111710 The localizations of Hrr1-Flag and Rdp1-Flag at centro- meric repeats were also found to be severely compromised in both ers1Δ and swi6Δ mutant cells (Fig. 5 A and B).
PMID:22474355 PBO:0111710 The localizations of Hrr1-Flag and Rdp1-Flag at centro- meric repeats were also found to be severely compromised in both ers1Δ and swi6Δ mutant cells (Fig. 5 A and B).
PMID:22474355 PBO:0111711 The localizations of Hrr1-Flag and Rdp1-Flag at centro- meric repeats were also found to be severely compromised in both ers1Δ and swi6Δ mutant cells (Fig. 5 A and B).
PMID:22474355 PBO:0111711 The localizations of Hrr1-Flag and Rdp1-Flag at centro- meric repeats were also found to be severely compromised in both ers1Δ and swi6Δ mutant cells (Fig. 5 A and B).
PMID:22474355 PBO:0111712 This is also con- sistent with a previous report that the deletion of swi6+ decreases the centromeric localization of Rdp1 (14). These results support the idea that the heterochromatic localization of RDRC requires Ers1 and that, in turn, Ers1 localization depends on Swi6.
PMID:22474355 PBO:0111713 ChIP analyses showed that Ers1 localization at the mating type locus (cenH) and telomeres was severely de- creased in swi6Δ and clr4Δ cells (Fig. S5A).
PMID:22474355 FYPO:0002835 defective siRNA production (Fig. 1C),
PMID:22474355 PBO:0111704 derepression of a ura4+ marker gene integrated into the outermost Fig. 1. (otr) pericentromeric repeat of chromosome 1 (otr1R::ura4+) (Fig. 1a)
PMID:22474355 PBO:0111704 derepression of a ura4+ marker gene integrated into the outermost Fig. 1. (otr) pericentromeric repeat of chromosome 1 (otr1R::ura4+) (Fig. 1a)
PMID:22474355 PBO:0111704 derepression of a ura4+ marker gene integrated into the outermost Fig. 1. (otr) pericentromeric repeat of chromosome 1 (otr1R::ura4+) (Fig. 1a)
PMID:22474355 PBO:0111718 This was in contrast to Hrr1 or Rdp1, whose association was severely reduced in swi6Δ cells (10–20%) to levels comparable to those of clr4Δ cells.
PMID:22474355 PBO:0111717 This was in contrast to Hrr1 or Rdp1, whose association was severely reduced in swi6Δ cells (10–20%) to levels comparable to those of clr4Δ cells.
PMID:22474355 PBO:0111706 To test the hypothesis that the nu- clear dot localization of Ers1 was attributable to an interaction with H3K9me-bound CD proteins, EGFP-Ers1WT localization was next examined in swi6Δ, chp1Δ, and chp2Δ cells. The localization of EGFP-Ers1WT was clearly abolished in swi6Δ cells similar to that observed in clr4Δ, whereas WT localization patterns were retained in the chp1Δ and chp2Δ cells (Fig. 4C and Fig. S4C).
PMID:22474355 PBO:0111716 In swi6Δ cells, Chp1 association with the centromeric dg or dh repeat locus decreased partially (70– 80%) but was still much greater than that observed in clr4Δ cells (Fig. 5 A and B).
PMID:22474355 PBO:0111715 In contrast, a high level of Ers1 was detected at telomeres in hrr1Δ cells (Fig. S5C).
PMID:22474355 PBO:0111714 ChIP analyses showed that Ers1 localization at the mating type locus (cenH) and telomeres was severely de- creased in swi6Δ and clr4Δ cells (Fig. S5A).
PMID:22474355 GO:0005721 . Similar to that previously observed, EGFP-Ers1WT showed a distinct nuclear dot pattern in WT cells consistent with a locali- zation to heterochromatin (Fig. 4B and Fig. S4B)
PMID:22474355 PBO:0111704 derepression of a ura4+ marker gene integrated into the outermost Fig. 1. (otr) pericentromeric repeat of chromosome 1 (otr1R::ura4+) (Fig. 1a)
PMID:22474355 PBO:0111714 ChIP analyses showed that Ers1 localization at the mating type locus (cenH) and telomeres was severely de- creased in swi6Δ and clr4Δ cells (Fig. S5A).
PMID:22474355 PBO:0111706 Moreover, the nuclear dot localization of EGFP-Ers1WT was completely abolished in clr4Δ cells (Fig. 4C), indicating that the activity of Clr4 was also required for Ers1 localization in the nucleus.
PMID:22474355 PBO:0111705 . In contrast, EGFP-Ers1C62 showed a more diffuse signal with weak nuclear dots (Fig. 4B and Fig. S4 C and D), suggesting that the correct localization of Ers1 was impaired by the C62 mutation.
PMID:22474355 PBO:0111703 derepression of a ura4+ marker gene integrated into the outermost Fig. 1. (otr) pericentromeric repeat of chromosome 1 (otr1R::ura4+) (Fig. 1a)
PMID:22474355 FYPO:0000220 increased levels of noncoding centromeric transcripts (Fig. 1B)
PMID:22484924 GO:0006895 (protein)
PMID:22484924 PBO:0104298 Fig. 2D
PMID:22484924 PBO:0095511 fig 2d
PMID:22484924 PBO:0104297 fig 2c
PMID:22484924 FYPO:0000423 fig4 (I moved this down from abnormal endocytisis, is that OK?)
PMID:22484924 FYPO:0004482 fig 4
PMID:22484924 PBO:0104296 vw, moved down to -decreased protein targeting to vacuole, with protein secreted
PMID:22484924 PBO:0099384 fig 5c
PMID:22496451 PBO:0023351 "allele tyep ""unknown"" because neither nt nor aa position 324 is A"
PMID:22508988 PBO:0099618 fig 1a
PMID:22508988 PBO:0099624 fig 3B
PMID:22508988 PBO:0099625 fig 4 A/B
PMID:22508988 GO:0005515 fig1 carboxy terminal region
PMID:22508988 PBO:0099626 fig 4 A/B
PMID:22508988 PBO:0111494 . The preference of the conserved Cdk9 catalytic domain in fission yeast and metazoans for Ser7-modified CTD substrates, moreover, implies a conserved mechanism to impose order on the Pol II transcription cycle.
PMID:22508988 PBO:0099618 fig 1a in vitro /in vivo
PMID:22508988 PBO:0103372 (Fig. 6C) Immunoblot analysis indicated that Mcs6 phosphorylates Ser2, Ser5, and Ser7
PMID:22508988 PBO:0103372 (Fig. 6C) Immunoblot analysis indicated that Mcs6 phosphorylates Ser2, Ser5, and Ser7
PMID:22508988 PBO:0103372 (Fig. 6C) Immunoblot analysis indicated that Mcs6 phosphorylates Ser2, Ser5, and Ser7
PMID:22508988 PBO:0111962 (Fig. 6C) Immunoblot analysis indicated that Mcs6 phosphorylates Ser2, Ser5, and Ser7
PMID:22508988 PBO:0103373 S. pombe Cdk9 also generated Ser2-P and Ser5-P signals but was relatively inefficient at phosphorylating Ser7.
PMID:22508988 PBO:0103373 S. pombe Cdk9 also generated Ser2-P and Ser5-P signals but was relatively inefficient at phosphorylating Ser7.
PMID:22508988 PBO:0099622 fig 2d Spt5-T1P (CTD repeat 1 residue)
PMID:22508988 PBO:0099623 fig 3B
PMID:22508988 GO:0005515 fig1 carboxy terminal region
PMID:22508988 PBO:0111962 S. pombe Cdk9 also generated Ser2-P and Ser5-P signals but was relatively inefficient at phosphorylating Ser7.
PMID:22508988 PBO:0099618 fig 1a
PMID:22508988 FYPO:0007074 fig 2c
PMID:22508988 PBO:0099621 fig 2c
PMID:22508988 PBO:0099621 fig 2c MPA exacerbates growth impairment in mutants defective in transcript elongation (8, 11, 50), although the precise mechanism of this effect is un- known (34)
PMID:22508988 FYPO:0001357 fig 2c
PMID:22508988 FYPO:0002141 fig 2c
PMID:22508988 PBO:0093560 fig 2c
PMID:22508988 PBO:0093554 fig 2c
PMID:22508988 PBO:0093560 fig 2c
PMID:22508988 PBO:0093554 fig 2c
PMID:22508988 FYPO:0006821 fig 2b
PMID:22508988 GO:0004674 (We also compared the activities of kinase complexes generated by translation in vitro toward Spt5. By this measurement also, Cdk9 and Cdk9C were stimulated to similar extents by Csk1 (Fig. 1F),(is this an physiological substrate?)
PMID:22508988 PBO:0099620 fig 1e in vitro
PMID:22508988 PBO:0099619 fig 1a
PMID:22508988 PBO:0099622 fig 2d Spt5-T1P (CTD repeat 1 residue)
PMID:22558440 PBO:0109950 I specifically used that term name because I did not want to discriminate whether Cuf2 is a negative or a positive regulator of transcription, even though in the paper we have put emphasis on the fact that meiotic genes are up-regulated in the absence of Cuf2 (so that Cuf2 would be a repressor). The reason is that there are also many other genes that are down-regulated in the cuf2delta mutant compare to WT. We still don't know which effect is direct and/or indirect. Thus, we don't want to exclude that Cuf2 might act as an activator, a repressor or both, for now.
PMID:22558440 PBO:0109949 I specifically used that term name because I did not want to discriminate whether Cuf2 is a negative or a positive regulator of transcription, even though in the paper we have put emphasis on the fact that meiotic genes are up-regulated in the absence of Cuf2 (so that Cuf2 would be a repressor). The reason is that there are also many other genes that are down-regulated in the cuf2delta mutant compare to WT. We still don't know which effect is direct and/or indirect. Thus, we don't want to exclude that Cuf2 might act as an activator, a repressor or both, for now.
PMID:22573890 FYPO:0004653 fig 5
PMID:22573890 PBO:0097713 fig 3 A
PMID:22573890 PBO:0018345 fig 3 A
PMID:22573890 PBO:0098289 fig 3 A
PMID:22573890 FYPO:0006559 fig 5 6 min late
PMID:22573890 FYPO:0000651 fig 6
PMID:22573890 FYPO:0004895 fig 5
PMID:22573890 FYPO:0006187 fig 5
PMID:22573890 PBO:0098290 fig S2
PMID:22573890 PBO:0111999 fig 2a (WT 10% @36degrees)
PMID:22573890 PBO:0098286 fig 2a
PMID:22573890 PBO:0098288 figure 2 B/C
PMID:22573890 FYPO:0000650 fig 6
PMID:22582262 GO:0007129 "rec12 phenotype indicates that Sme2 role in synapsis is independent of meiotic recombination; NEEDS TO BE REGULATION OF SYNAPSISa change to the GO ""pairing"" definition requested""https://sourceforge.net/p/geneontology/ontology-requests/10607/"
PMID:22582262 GO:0007129 "rec12 phenotype indicates that Sme2 role in synapsis is independent of meiotic recombination; NEEDS TO BE REGULATION OF SYNAPSISa change to the GO ""pairing"" definition requested""https://sourceforge.net/p/geneontology/ontology-requests/10607/"
PMID:22645648 FYPO:0002672 Figure1a
PMID:22645648 FYPO:0004481 """At 37C, the cell number increase of both mutants ceased."""
PMID:22645648 FYPO:0005369 """At 37C, the cell number increase of both mutants ceased."""
PMID:22645648 PBO:0093779 Mild sensitivity compared to tor2-S (L2048S)
PMID:22645648 GO:0038202 TOR kinase activity was measured using immunoprecipitated proteins (Fig.2)
PMID:22645648 FYPO:0001122 Figure4e
PMID:22645648 FYPO:0000012 Figure4ab
PMID:22645648 FYPO:0005430 Figure4d
PMID:22645648 PBO:0096180 Dephosphorylation of Cdc2 Tyr15 PO4 is delayed in this mutant
PMID:22645648 FYPO:0002060 Figure1a/6a . Rapamycin rescued cut1-21 and cut1-693 at 338C
PMID:22645648 FYPO:0001019 Figure4d
PMID:22645648 FYPO:0002060 Figure 6
PMID:22645648 FYPO:0002060 Figure1a
PMID:22645648 FYPO:0002061 Figure1a/6a . Rapamycin rescued cut1-21 and cut1-693 at 338C
PMID:22645648 FYPO:0002672 Figure6
PMID:22645648 FYPO:0002061 Figure 6
PMID:22645648 FYPO:0002061 Figure1a
PMID:22645654 FYPO:0000089 Fig1d
PMID:22645654 FYPO:0001387 Fig1h
PMID:22645654 FYPO:0000088 Fig2e
PMID:22645654 FYPO:0001930 Fig1d
PMID:22645654 FYPO:0000268 Fig.1d, e, f
PMID:22645654 FYPO:0000088 Fig1d
PMID:22645654 FYPO:0000268 Fig2e
PMID:22645654 FYPO:0002573 Fig3a-g (evidence: immunpflouresence)
PMID:22645654 FYPO:0002573 Fig4
PMID:22645654 FYPO:0004385 Fig5
PMID:22645654 FYPO:0005438 Fig5
PMID:22645654 FYPO:0004385 Fig7
PMID:22645654 FYPO:0002060 fig 2b,c
PMID:22645654 FYPO:0001926 fig 2b,c
PMID:22645654 GO:1990814 Data from three experiments: DNA reannealing (renaturation assay) using heat-denatured DNA (ssDNA); Removal of RPA proteins associated with ssDNA, RPA-coated heat-denatured DNA (ssDNA) is renaturated; Removal of RNA associated with ssDNA, RNA/DNA hybrid is denatured by renaturation activity of condensin SMC
PMID:22645654 FYPO:0000085 Fig1d
PMID:22645654 FYPO:0004031 Fig1f (evidence:immunoblot using anti-thymine dimer anitbodies)
PMID:22645654 FYPO:0003844 Fig1g
PMID:22658721 PBO:0095271 small
PMID:22658721 FYPO:0004371 NMeed to check, its decreased duration of replication arrest?
PMID:22658721 PBO:0095272 bulky
PMID:22660415 PBO:0093563 Fig. 5E
PMID:22660415 PBO:0093562 Fig. 5E
PMID:22660415 PBO:0112085 Fig. 2G
PMID:22660415 PBO:0112086 Accordingly, Bub3 and Mad3 localized at kinetochores in a manner identical to Bub1 in spc7-12A and spc7-12E cells,
PMID:22660415 PBO:0112087 Accordingly, Bub3 and Mad3 localized at kinetochores in a manner identical to Bub1 in spc7-12A and spc7-12E cells,
PMID:22660415 PBO:0112088 Fig. 1B This Bub1 enrichment is diminished in the spc7-23 mutant at a restrictive temperature24 (Fig. 1b).
PMID:22660415 PBO:0112055 Fig. 1E
PMID:22660415 PBO:0112085 Fig. 1C
PMID:22660415 PBO:0112089 Strikingly, in spc7-12E cells, Bub1 localized at kinetochores throughout the entire cell cycle. Fig. 2H, I and S3C
PMID:22660415 PBO:0112209 However, the coexpression of Bub1 and Bub3 enabled this complex to interact with Spc7-12E. Fig. 4C
PMID:22660415 PBO:0112091 Fig. 4B
PMID:22660415 PBO:0112092 Fig. 4B
PMID:22660415 PBO:0112233 Fig. 5A
PMID:22660415 PBO:0103768 Fig. 5C
PMID:22660415 PBO:0112094 Fig. 5B
PMID:22660415 PBO:0093559 Fig. 5E
PMID:22660415 FYPO:0002638 The expression of this fusion protein impairs normal cell growth because of robust SAC activation (Supplementary Fig. S1b,c)
PMID:22660415 PBO:0097991 Fig. 1A
PMID:22660415 PBO:0097991 Moreover, fission yeast Mph1 (MPS1 homologue), which also localizes to kinetochores only at prometaphase (Supplementary Fig. S1a and Fig. 1D)
PMID:22660415 PBO:0112095 Fig. 1D
PMID:22660415 PBO:0112096 Thus, Thr 77 and the MELT repeats in Spc7 are in vitro target sites of Mph1 kinase. Fig. 2
PMID:22660415 PBO:0112097 Fig. 2I
PMID:22660415 PBO:0112097 Fig. 2I
PMID:22660415 PBO:0112098 Fig. 2I
PMID:22660415 PBO:0112098 Fig. 2I
PMID:22660415 PBO:0112100 Fig. 2I
PMID:22660415 PBO:0112102 Fig. 2I
PMID:22660415 PBO:0112102 Fig. 2I
PMID:22660415 PBO:0112091 Fig. 4B
PMID:22660415 PBO:0112092 Fig. 4B
PMID:22660415 PBO:0112210 Fig. 4C
PMID:22660415 PBO:0112234 Fig. 5A
PMID:22660415 PBO:0112234 Fig. 5A
PMID:22660415 PBO:0112233 Fig. 5A
PMID:22660415 PBO:0112233 Fig. 5A
PMID:22660415 PBO:0112233 Fig. 5A
PMID:22660415 PBO:0112234 Fig. 5A.
PMID:22660415 PBO:0112234 Fig. 5A.
PMID:22660415 PBO:0112094 Fig. 5B
PMID:22660415 PBO:0112094 Fig. 5B
PMID:22660415 PBO:0112094 Fig. 5B
PMID:22660415 PBO:0112105 Fig. 5B
PMID:22660415 PBO:0112106 Fig. 5B
PMID:22660415 PBO:0112211 Fig. 5B
PMID:22660415 PBO:0112233 Fig. 5C
PMID:22660415 PBO:0112235 Fig. 5C
PMID:22660415 PBO:0112235 Fig. 5C
PMID:22660415 PBO:0112235 Fig. 5C
PMID:22660415 PBO:0112235 Fig. 5C
PMID:22660415 PBO:0112235 Fig. 5C
PMID:22660415 PBO:0112235 Fig. 5C
PMID:22660415 PBO:0103768 Fig. 5C
PMID:22660415 PBO:0096163 Fig. 5C
PMID:22660415 PBO:0096163 Fig. 5C
PMID:22660415 PBO:0103767 Fig. 5C
PMID:22660415 PBO:0103767 Fig. 5C
PMID:22660415 PBO:0093559 Fig. 5E
PMID:22660415 PBO:0093559 Fig. 5E
PMID:22660415 PBO:0093562 Fig. 5E
PMID:22660415 PBO:0093562 Fig. 5E
PMID:22660415 PBO:0093562 Fig. 5E
PMID:22660415 FYPO:0001357 Fig. 5F
PMID:22660415 PBO:0093563 Fig. 5F
PMID:22660415 PBO:0093563 Fig. 5F
PMID:22660415 PBO:0103768 Fig. 5F
PMID:22660415 PBO:0103768 Fig. 5F
PMID:22660415 GO:0090266 Thus, the dual regulation of Bub1 by Bub3, suppression of ectopic activation out of the kinetochore and the promotion of its kinetochore recruitment, may play a key role in establishing the robust kinetochore-based SAC activation system.
PMID:22660415 PBO:0100097 During this analysis, we found that at least four sites (Thr 77, Thr 338, Thr 507 and Thr 552) are phosphorylated by Mph1 in vitro (Supplementary Fig. S2).
PMID:22660415 PBO:0100097 During this analysis, we found that at least four sites (Thr 77, Thr 338, Thr 507 and Thr 552) are phosphorylated by Mph1 in vitro (Supplementary Fig. S2).
PMID:22660415 PBO:0100097 During this analysis, we found that at least four sites (Thr 77, Thr 338, Thr 507 and Thr 552) are phosphorylated by Mph1 in vitro (Supplementary Fig. S2).
PMID:22660415 PBO:0100097 During this analysis, we found that at least four sites (Thr 77, Thr 338, Thr 507 and Thr 552) are phosphorylated by Mph1 in vitro (Supplementary Fig. S2).
PMID:22660415 PBO:0112108 Fig. 5E
PMID:22660415 PBO:0112109 although the kinetochore localization of Spc7-12A protein was intact (Fig. 2f),
PMID:22660415 FYPO:0004318 Accordingly, the ectopic localization of Bub1 and the mitotic delay induced by Cnp3C–Mph1 were abolished by the spc7-12A mutation (Supplementary Fig. S3a)
PMID:22660415 PBO:0112099 Fig. 2I
PMID:22660415 PBO:0112101 Fig. 2I
PMID:22660415 PBO:0112101 Fig. 2I
PMID:22661707 PBO:0102208 more specific term required, during GO:0034599)
PMID:22665807 PBO:0096308 2A
PMID:22665807 PBO:0096308 2A
PMID:22665807 PBO:0096308 2A
PMID:22665807 PBO:0096307 2A
PMID:22665807 PBO:0096308 1d
PMID:22665807 FYPO:0006822 figure 2A
PMID:22665807 PBO:0096307 2A
PMID:22665807 PBO:0096306 1d
PMID:22665807 PBO:0096305 1c
PMID:22665807 PBO:0096308 2A
PMID:22665807 PBO:0096308 2A
PMID:22665807 PBO:0096310 3a
PMID:22665807 FYPO:0004474 3b
PMID:22665807 PBO:0096304 Table S1 and Figure S1
PMID:22665807 PBO:0096304 Table S1 and Figure S1
PMID:22665807 PBO:0096303 Table S1 and Figure S1
PMID:22665807 PBO:0096303 Table S1 and Figure S1
PMID:22665807 PBO:0096303 Table S1 and Figure S1
PMID:22665807 PBO:0096303 Table S1 and Figure S1
PMID:22665807 PBO:0096303 Table S1 and Figure S1
PMID:22665807 PBO:0096311 4b
PMID:22665807 PBO:0096311 4b
PMID:22665807 PBO:0096311 4b
PMID:22665807 PBO:0096304 Table S1 and Figure S1
PMID:22665807 PBO:0096304 Table S1 and Figure S1
PMID:22665807 PBO:0096303 Table S1 and Figure S1
PMID:22665807 PBO:0096311 4b
PMID:22665807 PBO:0096311 4b
PMID:22665807 PBO:0096312 4b
PMID:22665807 PBO:0096312 4b
PMID:22665807 PBO:0096312 4b
PMID:22665807 PBO:0096312 4b
PMID:22665807 PBO:0096314 4b
PMID:22665807 PBO:0096303 Table S1 and Figure S1
PMID:22682245 FYPO:0002061 implies that dna2 E560A alone is inviable
PMID:22682245 GO:1990601 cleaves unpaired nascent DNA in replication forks (vw replaced GO:0045145)
PMID:22682245 FYPO:0002060 implies that dna2 K961T alone is viable
PMID:22683269 GO:0003723 assayed using bulk RNA
PMID:22684255 FYPO:0000400 fig 4d
PMID:22684255 FYPO:0000400 fig 4d
PMID:22684255 FYPO:0000400 fig 4d
PMID:22684255 FYPO:0000400 fig 4d
PMID:22684255 FYPO:0000400 fig 4d
PMID:22684255 FYPO:0003306 Figure 3a
PMID:22684255 FYPO:0003306 Figure 3a
PMID:22684255 FYPO:0003481 Figure 3a. t (Table 1) indicating that inhibition of Sid2 or Fin1 delayed the timing of mitotic commitment until a new size threshold for division was me
PMID:22684255 PBO:0092296 fig 1a
PMID:22684255 FYPO:0003481 Figure 3a. t (Table 1) indicating that inhibition of Sid2 or Fin1 delayed the timing of mitotic commitment until a new size threshold for division was me
PMID:22684255 GO:0010971 """mitotic commitment'"
PMID:22684255 GO:0010971 (Figure 4b) confirming that each kinase promotes mitotic commitment.
PMID:22684255 FYPO:0000405 fig 4d
PMID:22684255 FYPO:0000405 fig 4d
PMID:22684255 FYPO:0000400 fig 4d
PMID:22684255 FYPO:0003306 fig 4d
PMID:22684255 FYPO:0000400 fig 4d
PMID:22684255 PBO:0097831 Figure 1b
PMID:22684255 PBO:0097831 Figure 1b
PMID:22684255 PBO:0100301 Figure 1g
PMID:22684255 PBO:0100301 Figure 1g
PMID:22684255 PBO:0100302 Figure 2f lanes 1, 2
PMID:22684255 PBO:0100303 Figure 2f lanes 1, 2
PMID:22684255 PBO:0100302 Figure 2f lanes 1, 2
PMID:22684255 FYPO:0000400 fig 4d
PMID:22684255 PBO:0100305 upstream of pom1
PMID:22696680 PBO:0103480 Supplemental Figure S1, C–E
PMID:22696680 PBO:0019801 fig 1A
PMID:22696680 PBO:0018346 fig 1A
PMID:22696680 PBO:0037217 (growing) fig 1A
PMID:22696680 FYPO:0004731 Figure 1
PMID:22696680 FYPO:0004731 Figure 1
PMID:22696680 FYPO:0002760 Figure 1
PMID:22696680 FYPO:0002760 Figure 1
PMID:22696680 FYPO:0001234 Figure 2A
PMID:22696680 FYPO:0002112 Figure 2A
PMID:22696680 FYPO:0002818 Figure 2B
PMID:22696680 FYPO:0005797 Figure 2C
PMID:22696680 FYPO:0005681 Figure 2D Figure 2F
PMID:22696680 FYPO:0005682 Figure 2D Figure 2F
PMID:22696680 PBO:0103479 Supplemental Figure S1, C–E
PMID:22696680 PBO:0098921 Supplemental Figure S1, C–E
PMID:22696680 GO:0061863 Figure 3, Supplemental Table S2, and Supplemental Figure S4
PMID:22705791 FYPO:0003164 not sure if it is endo, exo or both? so went with more general term
PMID:22705791 GO:0004518 not sure if it is endo, exo, or both. It is def acting on DNA. More specific terms for DNA specify endo or exo.
PMID:22711988 PBO:0103997 implies that MIND complex is required for Sos7 to localize to the kinetochore
PMID:22711988 GO:0000776 kinetochore localization requires MIND complex
PMID:22718908 FYPO:0006728 BrdU incorporation
PMID:22718908 FYPO:0006726 inferred from normal localization of CMG proteins at origin
PMID:22718908 FYPO:0006728 BrdU incorporation
PMID:22718908 PBO:0103928 inferred from localization of proteins distal to origin
PMID:22718908 PBO:0103909 inferred from localization of proteins distal to origin
PMID:22718908 FYPO:0006728 BrdU incorporation
PMID:22718908 FYPO:0006727 BrdU incorporation
PMID:22718908 PBO:0103909 inferred from localization of proteins distal to origin
PMID:22718908 PBO:0103920 inferred from localization of proteins distal to origin
PMID:22723423 GO:0000400 Fml1 binds to the four-way junction at a displacement (D) loop.
PMID:22723423 GO:0009378 Fml1 catalyses the dissociation of displacement (D) loops
PMID:22727667 PBO:0111538 binds H3K9me
PMID:22727667 PBO:0111540 binds H3K9me
PMID:22727667 PBO:0111539 binds H3K9me
PMID:22737087 PBO:0093559 Fig2. reduced growth may not be specific to aneuploidy as it also interact with gtb1 though looks quite good to me
PMID:22737087 PBO:0104054 Table1 Fig1 affects C1 and C2 type colonies
PMID:22737087 PBO:0093558 Fig 3A This strain is disomic for Chromosome 3
PMID:22737087 PBO:0104055 Fig 3B This strain is disomic for Chromosome 3
PMID:22737087 FYPO:0007391 Fig 4 Type C1 colonies have highly elongated cells and are due to various types of aneuploidy. Authors suggest that not3 is required to maintain cell growth
PMID:22737087 FYPO:0001326 All the genes affect by at least 1.5 fold (141) are reported in Table S2
PMID:22737087 FYPO:0001326 All the genes affect by at least 1.5 fold (61) are reported in Table S2
PMID:22737087 FYPO:0001326 All the genes affect by at least 1.5 fold (17) are reported in Table S2
PMID:22737087 PBO:0104055 Table 2 This strain is disomic for Chromosome 3
PMID:22737087 PBO:0093558 Fig 3A This strain is disomic for Chromosome 3
PMID:22737087 PBO:0104055 Fig 3B This strain is disomic for Chromosome 3
PMID:22737087 PBO:0104055 Table 2 This strain is disomic for Chromosome 3
PMID:22737087 PBO:0093560 Fig6.
PMID:22737087 PBO:0093560 Fig6.
PMID:22737087 PBO:0093560 Fig6
PMID:22737087 PBO:0093560 Fig6
PMID:22737087 PBO:0093560 Fig6
PMID:22737087 PBO:0093560 Fig6. reduced growth may not be specific to aneuploidy as it also interacts with gtb1-93
PMID:22737087 PBO:0104054 Fig1, Table1 affects C1 and C2 type colonies
PMID:22737087 PBO:0104054 Fig1, Table1 affects C1 type colonies
PMID:22737087 PBO:0104054 Fig1, Table1 affects C1 type colonies
PMID:22737087 PBO:0104055 Table 2 This strain is disomic for Chromosome 3
PMID:22737087 PBO:0104055 Table 2 This strain is disomic for Chromosome 3
PMID:22737087 PBO:0104054 Fig2.
PMID:22737087 PBO:0104054 Fig1, Table1 affects C1 more than C2 type colonies
PMID:22737087 PBO:0093560 Fig S1 decreased aneuploid cell viability during vegetative growth
PMID:22737087 PBO:0093561 data not shown decreased aneuploid cell viability during vegetative growth
PMID:22737087 PBO:0093561 Fig S1, decreased aneuploid cell viability during vegetative growth
PMID:22737087 PBO:0093559 Fig S1, decreased aneuploid cell viability during vegetative growth
PMID:22737087 PBO:0093560 Fig2. decreased aneuploid cell viability during vegetative growth
PMID:22737087 PBO:0093560 Fig2.
PMID:22737087 PBO:0093560 Fig2.
PMID:22737087 PBO:0104054 Fig1, Table1 affects C1 and C2 type colonies
PMID:22737087 PBO:0093560 Fig2. decreased aneuploid cell viability during vegetative growth
PMID:22737087 PBO:0093560 Fig2. decreased aneuploid cell viability during vegetative growth
PMID:22737087 FYPO:0007391 data not shown
PMID:22737087 FYPO:0007391 data not shown
PMID:22737087 FYPO:0007391 data not shown
PMID:22737087 FYPO:0007391 data not shown
PMID:22737087 FYPO:0001357 Fig2 normal population growth in presence of aneuploid cells
PMID:22737087 FYPO:0001357 Fig2 normal population growth in presence of aneuploid cells
PMID:22737087 PBO:0093560 Fig2. reduced growth may not be specific to aneuploidy as it also interacts with gtb1
PMID:22768388 FYPO:0002672 S1 E
PMID:22768388 FYPO:0000082 fig 1 A
PMID:22768388 FYPO:0000082 fig 1 A
PMID:22768388 FYPO:0003218 Figures S1C and S1D
PMID:22768388 FYPO:0005177 Figures S1C
PMID:22768388 FYPO:0001492 Figures 1B
PMID:22768388 FYPO:0001492 Figures 1B
PMID:22768388 FYPO:0000118 Figures 1B
PMID:22768388 FYPO:0000118 Figures 1B
PMID:22768388 FYPO:0001234 Figur 1 c
PMID:22768388 FYPO:0001357 figure 1c
PMID:22768388 FYPO:0001234 Figur 1 c
PMID:22768388 FYPO:0001234 Figur 1 c
PMID:22768388 FYPO:0001357 figure 1c
PMID:22768388 FYPO:0001357 figure 1c
PMID:22768388 FYPO:0000674 S1 E
PMID:22768388 FYPO:0003503 data not shown
PMID:22768388 PBO:0104835 fig 4C
PMID:22768388 FYPO:0002360 data not shown
PMID:22768388 FYPO:0002834 fig S4
PMID:22768388 FYPO:0000082 fig 1 A
PMID:22768388 FYPO:0000082 fig 1 A
PMID:22768388 FYPO:0000082 fig 1 A
PMID:22768388 FYPO:0000674 S1 E
PMID:22768388 FYPO:0000674 S1 E
PMID:22768388 FYPO:0000674 S1 E
PMID:22768388 FYPO:0002672 S1 E
PMID:22768388 FYPO:0002672 S1 E
PMID:22768388 FYPO:0002672 S1 E
PMID:22792081 FYPO:0003489 cdc25-22 background
PMID:22792081 GO:0005515 This interaction depends on the phosphorylation of Crb2 on the T73 and S80 residues.
PMID:22792081 FYPO:0001270 cdc25-22 background
PMID:22792081 FYPO:0001270 cdc25-22 background
PMID:22792081 FYPO:0003489 cdc25-22 background
PMID:22792081 PBO:0111547 This interaction depends on the phosphorylation of Crb2 on the T73 and S80 residues.
PMID:22792081 PBO:0104543 This interaction depends on the phosphorylation of Crb2 on the T73 and S80 residues.
PMID:22792081 PBO:0019232 cdc25-22 background
PMID:22792081 PBO:0019232 cdc25-22 background
PMID:22809626 PBO:0022948 "happens during metaphase and happens during anaphase. I can't say ""decreased during cytokinesis"", only option would be to say ""not during cytokinesis"" which isn't strictly true."
PMID:22809626 PBO:0022949 "happens during metaphase and happens during anaphase. I can't say ""decreased during cytokinesis"", only option would be to say ""not during cytokinesis"" which isn't strictly true."
PMID:22809626 PBO:0022948 "happens during metaphase and happens during anaphase. I can't say ""decreased during cytokinesis"", only option would be to say ""not during cytokinesis"" which isn't strictly true."
PMID:22809626 PBO:0022949 "happens during metaphase and happens during anaphase. I can't say ""decreased during cytokinesis"", only option would be to say ""not during cytokinesis"" which isn't strictly true."
PMID:22825872 PBO:0096318 Mph1 localizes to unattached kinetochores in bub3D cells (Fig. 2A).
PMID:22825872 PBO:0096318 Fig. 4A and S1
PMID:22825872 FYPO:0003307 (Fig. 3C) (inhibiting Ark1 does not rescue the Mph1-kinetochore targeting, arguing that Ark1 is upstream)
PMID:22825872 PBO:0096320 Fig. 4B Fig. S5
PMID:22825872 PBO:0096330 Fig. 3B. Indeed, Ark1 and Mph1 are fully or partially required for the kinetochore enrichment of all other SAC proteins (Fig. 4A; supplementary material Figs S5–S10).
PMID:22825872 GO:0090267 Together this suggests that Ark1 is directly and continuously required to maintain Mph1 localization to kinetochores.
PMID:22825872 FYPO:0004318 In the presence of Mph1-D1-302, the SAC response in bub3D cells was abrogated (Fig. 2C), demonstrating that recruitment of Mph1 to kinetochores is necessary for SAC function in bub3D cells.
PMID:22825872 FYPO:0005781 In the presence of Mph1-D1-150, the SAC was still functional in bub3D cells, although the mitotic delay was shorter than in mph1-D1-150 or bub3D cells (Fig. 2C).
PMID:22825872 FYPO:0004318 and the fraction of cells, in which a signal could be detected (supplementary material Fig. S1), were similar between bub3+ and bub3D cells
PMID:22825872 PBO:0096331 (Fig. S9F)
PMID:22825872 FYPO:0003762 and the fraction of cells, in which a signal could be detected (supplementary material Fig. S1), were similar between bub3+ and bub3D cells
PMID:22825872 PBO:0096328 35% cells (Fig. 1E,F).
PMID:22825872 FYPO:0003736 rescued by deletion of mad2, which (forced recruitment of Mph1 artificially promoted SAC signaling andthat the fusion to Mis12 did not impair kinetochore function.
PMID:22825872 PBO:0096327 (60% cells) Forced recruitment of wild-type Mph1 to kinetochores lead to apronounced delay in mitosis and a growth defect (Fig. 1E,F),
PMID:22825872 PBO:0096326 This is S4B and C
PMID:22825872 PBO:0096319 Fig. 4A and S7
PMID:22825872 PBO:0096319 (Fig. 4C).
PMID:22825872 PBO:0096318 The shorter truncation (Mph1-D1-150) maintained kinetochore localization and SAC signaling,
PMID:22825872 FYPO:0003762 The shorter truncation (Mph1-D1-150) maintained kinetochore localization and SAC signaling,
PMID:22825872 FYPO:0004318 ditto
PMID:22825872 PBO:0096317 abolished both kinetochore localization and SAC signaling (Fig. 1C,D), suggesting that kinetochore localization is crucial for SAC activity.
PMID:22825872 PBO:0096316 Fig. 4A and S8
PMID:22825872 PBO:0096316 Fig. 4A and S8
PMID:22825872 PBO:0096315 Fig. 4A and S7
PMID:22825872 FYPO:0003307 (Fig. 3C)increased mitotic index (Fig. S4A)
PMID:22825872 PBO:0096325 This is S4B and C
PMID:22825872 PBO:0096324 This is S4B and C
PMID:22825872 PBO:0096316 This is S8E and F. Indeed, Ark1 and Mph1 are fully or partially required for the kinetochore enrichment of all other SAC proteins (Fig. 4A; supplementary material Figs S5–S10).
PMID:22825872 PBO:0096317 Fig.3A. When proper chromosome attachment was prevented by a conditional mutation in kinesin-5 (cut7-446), Mph1 localized to kinetochores, but the enrichment was abrogated by chemical genetic inhibition of Ark1 with the small molecule 1NM-PP1 (Fig. 3A).
PMID:22825872 PBO:0096315 Indeed, Ark1 and Mph1 are fully or partially required for the kinetochore enrichment of all other SAC proteins (Fig. 4A; supplementary material Figs S5–S10).
PMID:22825872 PBO:0096315 Fig. 4C
PMID:22825872 PBO:0096322 (Fig. 4B).
PMID:22825872 PBO:0096316 Fig. S8
PMID:22825872 PBO:0096315 Fig. S7
PMID:22825872 PBO:0096323 Fig. S6 Indeed, Ark1 and Mph1 are fully or partially required for the kinetochore enrichment of all other SAC proteins (Fig. 4A; supplementary material Figs S5–S10).
PMID:22825872 PBO:0096322 Fig. S5
PMID:22825872 PBO:0096321 Fig. 4A and S9
PMID:22891259 GO:0032153 fig1 /figs1?
PMID:22891259 GO:0031671 Explosive cell separation due to a weak primary septum. Absence of a secondary septum.
PMID:22891259 GO:0005886 Localized at cell tips, actomyosin contractile ring and septum
PMID:22891259 GO:0032153 fig1 /figs1?
PMID:22891673 PBO:0018345 normal localization in several mutants indicates that Sec3 localization is independent of exocytosis and vesicle-mediated transport along microtubules
PMID:22891673 FYPO:0000639 decreased septum closure
PMID:22891673 FYPO:0000639 decreased/delayed septum closure
PMID:22891673 FYPO:0000650 septation index increased gradually over time
PMID:22891673 FYPO:0000230 At the end of ring constriction Filamentous projections from the unclosed ring toward the cytoplasm
PMID:22891673 FYPO:0000650 septation index constantly high
PMID:22891673 FYPO:0000424 Assayed by FM4-64 uptake
PMID:22891673 FYPO:0002438 Weak actin cables
PMID:22891673 FYPO:0002526 assayed at 32C, which is semi-permissive for sec3-913
PMID:22905165 PBO:0018345 GFP-Cfh3 figure 1 A
PMID:22905165 PBO:0098289 GFP-Cfh3 figure 1 A
PMID:22905165 PBO:0022652 Cdc15-GFP However, we observed that a number of the Cdc15-GFP and the GFP-Cdc4 rings were asymmetric or broken.
PMID:22905165 PBO:0105436 S1
PMID:22905165 PBO:0035602 Cdc15-GFP
PMID:22905165 PBO:0035602 Cdc15-GFP supplemental figure S3
PMID:22905165 PBO:0096859 GFP-Bgs1
PMID:22905165 PBO:0105439 GFP-Bgs1
PMID:22905165 PBO:0105440 figure S2, A protein distributed in cortex
PMID:22905165 PBO:0105441 1B in which the SIN signal does not turn off, Cfh3p localized to the edge of the growing septa and it remained at the septal area after the septa had been completed. Thus, Cfh3p can arrive at the cell midzone in the absence of the SIN pathway but it requires that the SIN signal must be turned off for it to be removed from the cell equator after mitosis
PMID:22905165 PBO:0105442 1B in which the SIN signal does not turn off, Cfh3p localized to the edge of the growing septa and it remained at the septal area after the septa had been completed. Thus, Cfh3p can arrive at the cell midzone in the absence of the SIN pathway but it requires that the SIN signal must be turned off for it to be removed from the cell equator after mitosis
PMID:22905165 PBO:0105443 1B
PMID:22905165 PBO:0022652 (used sorbitol but multiple stresses were tested) Cdc15-GFP However, we observed that a number of the Cdc15-GFP and the GFP-Cdc4 rings were asymmetric or broken.
PMID:22905165 PBO:0105433 S1
PMID:22905165 PBO:0105434 S1
PMID:22905165 PBO:0105435 S1
PMID:22912768 PBO:0096134 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPBPB10D8.03) (mah 2014-08-05)
PMID:22912768 PBO:0096132 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPBPB10D8.03) (mah 2014-08-05)
PMID:22912768 PBO:0096133 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPBPB10D8.03) (mah 2014-08-05)
PMID:22912768 PBO:0095154 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPBPB10D8.03) (mah 2014-08-05)
PMID:22912768 PBO:0095155 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPBPB10D8.03) (mah 2014-08-05)
PMID:22912768 PBO:0096135 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPBPB10D8.03) (mah 2014-08-05)
PMID:22912768 PBO:0096136 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPBPB10D8.03) (mah 2014-08-05)
PMID:22918943 FYPO:0003339 Figure 3A
PMID:22918943 GO:0110115 Figure 1A, 2A
PMID:22918943 GO:0071341 Figure 1A, 2A
PMID:22918943 PBO:0095811 Figure 5, I, J, and L
PMID:22918943 PBO:0095812 Figure 5, I, J, and L
PMID:22918943 PBO:0095813 Figure 5, I, J, and L
PMID:22918943 FYPO:0001364 Figure 3A
PMID:22918943 FYPO:0004594 Figure 7
PMID:22918943 PBO:0095814 Figure 7
PMID:22918952 PBO:0099900 unspecfied RxxS site(s)
PMID:22918952 PBO:0099901 unspecfied RxxS site(s)
PMID:22918954 FYPO:0003203 fig 3B
PMID:22918954 PBO:0099643 fig 3B
PMID:22918954 PBO:0099646 Figure 4
PMID:22918954 PBO:0099646 Figure 4
PMID:22918954 PBO:0099646 Figure 4
PMID:22918954 FYPO:0004750 fig 3B
PMID:22918954 PBO:0099646 Figure 4
PMID:22918954 PBO:0098959 fig 3B asymettrically localized septum
PMID:22918954 PBO:0099646 Figure 4
PMID:22918954 PBO:0099644 fig 3B
PMID:22918954 PBO:0099645 fig 3B
PMID:22918954 PBO:0099645 fig 3B
PMID:22918954 PBO:0099645 fig 3B
PMID:22918954 PBO:0099644 fig 3B
PMID:22918954 PBO:0099644 fig 3B
PMID:22918954 PBO:0099646 Figure 4
PMID:22918954 PBO:0099647 Figure 4
PMID:22959349 PBO:0020538 Cdc2 phosphorylates Rap1 at Thr378, Ser422, and Ser513 during M phase. Ser456 of Rap1 is also phosphorylated during M phase by an unknown kinase. Ser213 of Rap1 is phosphorylated throughout the cell cycle. These phosphorylations are required for the efficient detachment of telomeres from the nuclear envelope.
PMID:22959349 PBO:0104364 Cdc2 phosphorylates Rap1 at Thr378, Ser422, and Ser513 during M phase. Ser456 of Rap1 is also phosphorylated during M phase by an unknown kinase. Ser213 of Rap1 is phosphorylated throughout the cell cycle. These phosphorylations are required for the efficient detachment of telomeres from the nuclear envelope.
PMID:22959349 PBO:0020539 Cdc2 phosphorylates Rap1 at Thr378, Ser422, and Ser513 during M phase. Ser456 of Rap1 is also phosphorylated during M phase by an unknown kinase. Ser213 of Rap1 is phosphorylated throughout the cell cycle. These phosphorylations are required for the efficient detachment of telomeres from the nuclear envelope.
PMID:22959349 PBO:0103680 at Ser/Thr-Pro site
PMID:22959349 PBO:0020543 cdc2 phosphorylates rap1. phosphorylated rap1 binds bqt4 less efficiently. rap1-bqt4 binding is required for telomere tethering at nuclear periphery. In WT cells telomere tehtering is abolished during M phase.
PMID:22959349 PBO:0103680 at Ser/Thr-Pro site
PMID:22959349 PBO:0104363 Cdc2 phosphorylates Rap1 at Thr378, Ser422, and Ser513 during M phase. Ser456 of Rap1 is also phosphorylated during M phase by an unknown kinase. Ser213 of Rap1 is phosphorylated throughout the cell cycle. These phosphorylations are required for the efficient detachment of telomeres from the nuclear envelope.
PMID:22959349 PBO:0103680 at Ser/Thr-Pro site
PMID:22959349 PBO:0104363 Cdc2 phosphorylates Rap1 at Thr378, Ser422, and Ser513 during M phase. Ser456 of Rap1 is also phosphorylated during M phase by an unknown kinase. Ser213 of Rap1 is phosphorylated throughout the cell cycle. These phosphorylations are required for the efficient detachment of telomeres from the nuclear envelope.
PMID:22976295 PBO:0025356 blotted for rps601 & rps602 simultaneously
PMID:22976295 PBO:0025355 blotted for rps601 & rps602 simultaneously
PMID:22976295 PBO:0025357 blotted for rps601 & rps602 simultaneously
PMID:22976295 PBO:0025355 blotted for rps601 & rps602 simultaneously
PMID:22976295 PBO:0025356 blotted for rps601 & rps602 simultaneously
PMID:22976295 PBO:0025357 blotted for rps601 & rps602 simultaneously
PMID:22976295 PBO:0097450 both rps proteins in extension because blot is for both of them
PMID:22976295 PBO:0097451 both rps proteins in extension because blot is for both of them
PMID:22976295 PBO:0097452 both rps proteins in extension because blot is for both of them
PMID:22976295 PBO:0097453 both rps proteins in extension because blot is for both of them
PMID:22976295 PBO:0097454 both rps proteins in extension because blot is for both of them
PMID:22976295 PBO:0097455 In this experiment, we utilized a Psk1 mutant (Thr415Glu), a phospho-mimetic mutant of its hydrophobic motif, as the mutant exhibited higher activity than the wild-type protein. As shown in Fig. 2C, the Psk1 protein phosphorylated Rsp6 in vitro. However, the Rsp6 mutant that has two potential serine phosphorylation sites changed to alanine was not phosphorylated by Psk1.
PMID:22976295 PBO:0110437 in vitro assay using rps602 so I am inferring rps601
PMID:22976295 PBO:0097459 not shown
PMID:22976295 PBO:0097454 both rps proteins in extension because blot is for both of them
PMID:22976295 PBO:0097454 both rps proteins in extension because blot is for both of them
PMID:22976295 PBO:0097468 both rps proteins in extension because blot is for both of them
PMID:22976295 PBO:0097469 both rps proteins in extension because blot is for both of them
PMID:22976295 PBO:0097468 both rps proteins in extension because blot is for both of them
PMID:22976295 PBO:0097469 both rps proteins in extension because blot is for both of them
PMID:22976295 PBO:0097468 both rps proteins in extension because blot is for both of them
PMID:22976295 PBO:0097469 both rps proteins in extension because blot is for both of them
PMID:22976295 PBO:0097468 both rps proteins in extension because blot is for both of them
PMID:22976295 PBO:0097469 both rps proteins in extension because blot is for both of them
PMID:22976295 GO:0038202 "I guess everything in the signaling cascade that isn't the ""final effector"" is part of the signaling cascade?"
PMID:22976295 GO:0038202 "I guess everything in the signaling cascade that isn't the ""final effector"" is part of the signaling cascade?"
PMID:22976295 PBO:0097477 in vitro assay using rps602 so I am inferring rps601
PMID:22987637 FYPO:0005758 "for evidence, ""BrdU incorporation assay evidence used in manual assertion"" (ECO:0001155) would be applicable."
PMID:22987637 PBO:0104501 "for evidence, ""BrdU incorporation assay evidence used in manual assertion"" (ECO:0001155) would be applicable."
PMID:22988247 PBO:0097487 This gene has been named as otg2 in the article.
PMID:22988247 PBO:0097487 This gene has been named as otg3 in the article.
PMID:22988247 FYPO:0003354 This gene has been named as otg1 in the article.
PMID:22990236 PBO:0034977 SO:0001899 = dh repeat
PMID:23028377 GO:0140713 move down to histone chaperone (H3-?)
PMID:23032292 FYPO:0000854 spacing is wrong as well as occupancy
PMID:23051734 GO:0070648 localization
PMID:23051734 GO:0070649 required for wildtype rates of actin cable retrograde flow in myo52∆ cells
PMID:23066505 GO:0036498 RIDD? - there is no RIDD term in GO, Val wants to wait with this
PMID:23066505 PBO:0099504 ire1 breaks down mRNAs during ER stress, however bip1 is unusual in that ire1 cleavage stabilizes it
PMID:23071723 FYPO:0000972 throughout cell cycle, with peak at M/G1
PMID:23084836 FYPO:0007270 Figures 6A and 6B hst4Δ and clr6-1 HDAC mutations, but not other HDAC mutations, significantly compromised Tf clustering and the association of Tf cluster with centromeres; Figures 6A and 6B)
PMID:23084836 FYPO:0004890 As previously shown, telomere tethering was significantly compromised in rap1Δ and bqt4Δ cells (Figure S2C; Chikashige et al., 2009).
PMID:23084836 PBO:0101845 (Figures S2A and S2B). AND As previously shown, telomere tethering was significantly compromised in rap1Δ and bqt4Δ cells (Figure S2C; Chikashige et al., 2009).
PMID:23084836 FYPO:0007269 (Figures S2A and S2B)
PMID:23084836 FYPO:0007269 The FISH data revealed that telomere clustering was not affected by pku70Δ and pku80Δ, but telomere tethering to the nuclear periphery was significantly compromised by pkuΔ (P < 0.001, Mann-Whitney U test), suggesting that telomere clustering and tethering to the nuclear periphery are distinct processes (Figures S2A and S2B)
PMID:23084836 FYPO:0001870 clustering and tethering of centromeres to the nuclear periphery were not affected in pku70Δ and pku80Δ cells, although Ku does localize at centromeres (Figures 1E, 3A, and 3B)
PMID:23084836 FYPO:0002335 Figure S1C
PMID:23084836 PBO:0101844 1A
PMID:23084836 GO:0005721 1A
PMID:23084836 GO:0099115 1A
PMID:23084836 PBO:0101848 Figure 6E). H3K56 acetylation antagonizes Tf clustering at centromeres. binding of Ku was reduced and enhanced in hst4Δ and rtt109Δ cells, respectively
PMID:23084836 PBO:0101849 Figure 6E). H3K56 acetylation antagonizes Tf clustering at centromeres. binding of Ku was reduced and enhanced in hst4Δ and rtt109Δ cells, respectively
PMID:23084836 PBO:0101850 We observed that Ku localization was diffuse after DNA damage, but this diffusion was inhibited by rtt109Δ (Figure 7D)
PMID:23084836 FYPO:0007270 Figures 6A and 6B) see above
PMID:23084836 FYPO:0005545 Figures 6A and 6B) see above
PMID:23084836 FYPO:0007270 Figures 6A and 6B) see above
PMID:23084836 FYPO:0005545 Figures 6A and 6B), see above
PMID:23084836 FYPO:0007271 Moreover, only the rtt109Δ HAT mutations, but not other HAT mutations, significantly promoted the association of Tf cluster with centromeres, whereas none of the HAT mutations affected Tf clustering (Figures 6C and 6D).
PMID:23084836 FYPO:0001870 clustering and tethering of centromeres to the nuclear periphery were not affected in pku70Δ and pku80Δ cells, although Ku does localize at centromeres (Figures 1E, 3A, and 3B)
PMID:23084836 FYPO:0005545 Interestingly, Tf clustering was impaired by pku70Δ and pku80Δ at a level similar to that observed in abp1Δ cells (Figure 2A).
PMID:23084836 FYPO:0005545 Interestingly, Tf clustering was impaired by pku70Δ and pku80Δ at a level similar to that observed in abp1Δ cells (Figure 2A).
PMID:23084836 FYPO:0005545 Interestingly, Tf clustering was impaired by pku70Δ and pku80Δ at a level similar to that observed in abp1Δ cells (Figure 2A).
PMID:23084836 FYPO:0004890 As previously shown, telomere tethering was significantly compromised in rap1Δ and bqt4Δ cells (Figure S2C; Chikashige et al., 2009).
PMID:23084836 PBO:0101846 Figure 6E). H3K56 acetylation antagonizes Tf clustering at centromeres. binding of Ku was reduced and enhanced in hst4Δ and rtt109Δ cells, respectively,
PMID:23084836 PBO:0101847 Figure 6E). H3K56 acetylation antagonizes Tf clustering at centromeres. binding of Ku was reduced and enhanced in hst4Δ and rtt109Δ cells, respectivelyWe examined how H3K56 acetylation antagonizes Tf clustering at centromeres. Remarkably, binding of Ku was reduced and enhanced in hst4Δ and rtt109Δ cells, respectively, suggesting that H3K56 acetylation has an inhibitory effect on Ku binding to Tf elements (Figure 6E).
PMID:23084836 FYPO:0002335 Figure S1C
PMID:23084836 FYPO:0005545 We found that Tf clustering and the association of Tf cluster with centromeres were significantly compromised in the cut14-208 condensin mutant Figures 4A and 4B),
PMID:23084836 FYPO:0007270 We found that Tf clustering and the association of Tf cluster with centromeres were significantly compromised in the cut14-208 condensin mutant Figures 4A and 4B),
PMID:23084836 FYPO:0007270 (NOTE IS STILL LOCALIZED TO NUCLEAR ERIPHERY) Remarkably, the association of Tf elements with centromeres was significantly compromised in pkuΔ cells (P < 0.00001, Mann-Whitney U test; Figures 3D and 3E).
PMID:23084836 FYPO:0007270 (NOTE IS STILL LOCALIZED TO NUCLEAR ERIPHERY) Remarkably, the association of Tf elements with centromeres was significantly compromised in pkuΔ cells (P < 0.00001, Mann-Whitney U test; Figures 3D and 3E).
PMID:23087209 PBO:0102452 Sid2 kinase phosphorylates Klp2 on serine residues 113 and 123 based on both in vitro and in vivo evidence. Phosphorylation on these residues disrupts interaction of Klp2 with Mal3.
PMID:23087209 MOD:00046 Sid2 kinase phosphorylates Klp2 on serine residues 113 and 123 based on both in vitro and in vivo evidence. Phosphorylation on these residues disrupts interaction of Klp2 with Mal3.
PMID:23087209 MOD:00046 Sid2 kinase phosphorylates Klp2 on serine residues 113 and 123 based on both in vitro and in vivo evidence. Phosphorylation on these residues disrupts interaction of Klp2 with Mal3.
PMID:23093942 FYPO:0003587 assayed by PCR in strain with RTS1 replication fork barrier inserted near ori3006/7
PMID:23093942 FYPO:0003587 assayed by PCR in strain with RTS1 replication fork barrier inserted near ori3006/7
PMID:23093942 FYPO:0001740 assayed in strain with RTS1 replication fork barrier inserted near ori3006/7
PMID:23093942 FYPO:0001740 assayed by PCR in strain with RTS1 replication fork barrier inserted near ori3006/7
PMID:23093942 FYPO:0003588 assayed in strain with RTS1 replication fork barrier inserted near ori3006/7
PMID:23093943 PBO:0102291 Cyk3-GFP localized to the CR and division site during cytokinesis, and it was retained at new ends immediately following cell division (Figure 4F).
PMID:23093943 PBO:0097713 As was observed previously [28], cytoplasmic Fic1-GFP localizes to cell tips during interphase and later to the CR during cell division (Figure 3A).
PMID:23093943 PBO:0018345 As was observed previously [28], cytoplasmic Fic1-GFP localizes to cell tips during interphase and later to the CR during cell division (Figure 3A).
PMID:23093943 PBO:0099938 fig 3c
PMID:23093943 PBO:0102283 fig 3C
PMID:23093943 PBO:0102284 fFigure 3D–3F
PMID:23093943 PBO:0038218 T-shapes always arose in cells that the tea1D growth pattern dictated should grow at their new ends (Figure 2D–2E) but that actually grew at neither (Figure 2E and 2G)
PMID:23093943 FYPO:0001355 S1F
PMID:23093943 FYPO:0001355 S1F
PMID:23093943 PBO:0102285 Figure 3G
PMID:23093943 FYPO:0002061 S1F
PMID:23093943 PBO:0102282 Figure 1F–1G
PMID:23093943 FYPO:0000026 Figure 4A–4C and Figure S3A–S3B
PMID:23093943 PBO:0102286 Mutation of PxxPs 10 and 11 in combination, or P257 of PxxP 11 alone, abolished the two-hybrid interaction (Figure S3D), and the P257A mutation eliminated co-immunoprecipitation of Fic1- FLAG3 with Cdc15 in vivo (Figure 4D).
PMID:23093943 FYPO:0000026 Figure 4A–4C and Figure S3A–S3B
PMID:23093943 PBO:0102281 fiigure S1B–S1C
PMID:23093943 PBO:0097167 fiigure S1B–S1C
PMID:23093943 PBO:0102280 fiigure S1B–S1C
PMID:23093943 PBO:0102279 fig 1b fig2
PMID:23093943 FYPO:0003535 fig 1b
PMID:23093943 PBO:0102288 fig 4c
PMID:23093943 PBO:0102289 fig 4c
PMID:23093943 PBO:0102290 fig 4c
PMID:23093943 PBO:0099938 fig S3F
PMID:23093943 PBO:0097713 Cyk3-GFP localized to the CR and division site during cytokinesis, and it was retained at new ends immediately following cell division (Figure 4F).
PMID:23093943 PBO:0102292 Fic1 most likely functions during late stages of cytokinesis. In line with this idea, the percentage of fic1D cells that had undergone ingression but were still joined at their division sites was more than four times that of wild-type cells (Figure 5A–5B).
PMID:23093943 GO:1902404 Consistent with early cytokinesis events proceeding appropri- ately without Fic1, time-lapse imaging of myosin regulatory light chain Rlc1-GFP [47,48] along with spindle pole body marker Sid4-GFP revealed that the CR formed and constricted normally in fic1D cells (Figure 5C–5D). However, at the termination of CR constriction, parts of the CR persisted at the division plane (Figure 5E–5G and Figure S4D).
PMID:23093943 PBO:0102288 fig 4c/ figure 6a
PMID:23093943 PBO:0102293 Loss of Eng1 or its cooperating glucanase, Agn1 [34], resulted in high percentages of monopolar growth (Figure 6C–6D and Figure S5A)
PMID:23093943 PBO:0102293 Loss of Eng1 or its cooperating glucanase, Agn1 [34], resulted in high percentages of monopolar growth (Figure 6C–6D and Figure S5A)
PMID:23093943 PBO:0102296 Figure S5B
PMID:23093943 PBO:0102296 Figure S5B
PMID:23093943 FYPO:0003776 Cells lacking Fic1 or its interacting partners Cyk3 or Imp2 were significantly more invasive than wild-type cells (Figure 9A–9B).
PMID:23093943 FYPO:0003776 Cells lacking Fic1 or its interacting partners Cyk3 or Imp2 were significantly more invasive than wild-type cells (Figure 9A–9B).
PMID:23093943 FYPO:0003776 Cells lacking Fic1 or its interacting partners Cyk3 or Imp2 were significantly more invasive than wild-type cells (Figure 9A–9B).
PMID:23093943 FYPO:0003776 In addition to these strains, we found other cytokinesis mutants exhibiting high degrees of monopolar growth (spn1D, cdc7-24, and vps24D) to also be highly invasive and to form pseudohyphal projections into 2% agar (Figure 9A–9B and Figure S7A)
PMID:23112169 GO:0032132 binds O6-alkylguanine, 2-aminopurine and 2,6-diaminopurine
PMID:23115244 FYPO:0002010 evidence=mas spec, can I wang this into another evidence code or should we add it (or something similar?)
PMID:23122962 GO:0060261 This possibility was confirmed by global expression profiling, showing that only 55 genes were significantly affected in the absence of Cdk11. I (and srb mediator association) showed that the absence of either cdk11 or cdk8 resulted in very similar defects (up- or downregulation) that were more pronounced in the cdk8 mutant (Figure 2C). Quantitative RT-PCR confirmed this effect on representative genes and showed, in addition, that the expression defects were not cumulated in the double cdk8 cdk11 mutant (Fig- ure 2D).
PMID:23122962 PBO:0111452 Therefore, we found no evidence of Cdk11 being a genuine CTD kinase in fission yeast.
PMID:23122962 PBO:0111453 Therefore, we found no evidence of Cdk11 being a genuine CTD kinase in fission yeast.
PMID:23122962 PBO:0111454 Combining the large-scale phosphoproteome data set and sequence alignment (Figures S4B and S4C), we determined that putative phosphoacceptors and in vitro analysis demon- strated that Cdk11 phosphorylates Med4 on three residues (Fig- ure 3B: S115, S204, and S218
PMID:23122962 GO:0000307 A tandem affinity purification (TAP) identified physical partners of Cdk11, including an unchar- acterized cyclin (SPAC1296.05c) that was confirmed to bind Cdk11 in independent coimmunoprecipitation experiments (Fig- ure 1C and 1D).
PMID:23122962 GO:0005634 Fluorescence microscopy revealed that Cdk11 was expressed and mainly concentrated in the nucleus (Figure 1A).
PMID:23122962 GO:2001178 *****mediator L complex assembly******At the contrary, the interaction between the kinase module subunit Cdk8 and the head subunit Med27 was completely abrogated when Cdk11 was inactivated (Figure 4B, middle panel). This role of Cdk11 in Mediator integrity was likely mediated by phosphorylation of Med27 and Med4 on the sites identified above (Figures 3 and 4A), because the inter- action between Cdk8 and either the Med27 or Med4 phos- phorylation mutants was specifically lost (Figure 4B, right panel). In contrast, the phosphorylation mutants of Med27 and Med4 still interacted with the middle subunit Med7 (Fig- ure 4B, right panel). These data indicate that the association of the kinase submodule and the S-Mediator requires the phosphorylation of Med27 and Med4 by Cdk11.
PMID:23122962 GO:2001178 ******mediator L complex asembly******At the contrary, the interaction between the kinase module subunit Cdk8 and the head subunit Med27 was completely abrogated when Cdk11 was inactivated (Figure 4B, middle panel). This role of Cdk11 in Mediator integrity was likely mediated by phosphorylation of Med27 and Med4 on the sites identified above (Figures 3 and 4A), because the inter- action between Cdk8 and either the Med27 or Med4 phos- phorylation mutants was specifically lost (Figure 4B, right panel). In contrast, the phosphorylation mutants of Med27 and Med4 still interacted with the middle subunit Med7 (Fig- ure 4B, right panel). These data indicate that the association of the kinase submodule and the S-Mediator requires the phosphorylation of Med27 and Med4 by Cdk11.
PMID:23122962 PBO:0107730 In addition, while the inactivation of the well- described CTD serine 5 or serine 2 kinases (Mcs6 [Cdk7] and Lsk1 [Cdk12], respectively) specifically decreased the phos- phorylation level of these two residues in vivo, the absence of cdk11 had no effect (Figure 1F).
PMID:23122962 PBO:0111454 Combining the large-scale phosphoproteome data set and sequence alignment (Figures S4B and S4C), we determined that putative phosphoacceptors and in vitro analysis demon- strated that Cdk11 phosphorylates Med4 on three residues (Fig- ure 3B: S115, S204, and S218
PMID:23122962 PBO:0107732 In addition, while the inactivation of the well- described CTD serine 5 or serine 2 kinases (Mcs6 [Cdk7] and Lsk1 [Cdk12], respectively) specifically decreased the phos- phorylation level of these two residues in vivo, the absence of cdk11 had no effect (Figure 1F).
PMID:23122962 PBO:0096825 in contrast to Mcs6 (the Cdk7 ortholog), which readily phosphor- ylated the GST-CTD fusion in vitro (Figure 1E) (Drogat and Her- mand, 2012)
PMID:23122962 GO:0140834 Therefore, we found no evidence of Cdk11 being a genuine CTD kinase in fission yeast.
PMID:23122962 GO:0000785 The previously reported connection between Cdk11 and tran- scription, together with its nuclear localization and copurifica- tion with transcription regulators (although at weak level) led us to test its chromatin association. Gene-specific chromatin immunoprecipitation (ChIP) experiments showed that Cdk11- hemagglutinin (HA) was enriched onto chromatin compared to an untagged control (data not shown), and a genome-wide ChIP-on-chip analysis showed a broad distribution of Cdk11- HA.
PMID:23122962 GO:0140836 Therefore, we found no evidence of Cdk11 being a genuine CTD kinase in fission yeast.
PMID:23122962 PBO:0111120 in contrast to Mcs6 (the Cdk7 ortholog), which readily phosphor- ylated the GST-CTD fusion in vitro (Figure 1E) (Drogat and Her- mand, 2012)
PMID:23122962 GO:0000307 A tandem affinity purification (TAP) identified physical partners of Cdk11, including an unchar- acterized cyclin (SPAC1296.05c) that was confirmed to bind Cdk11 in independent coimmunoprecipitation experiments (Fig- ure 1C and 1D).
PMID:23122962 PBO:0111120 in contrast to Mcs6 (the Cdk7 ortholog), which readily phosphor- ylated the GST-CTD fusion in vitro (Figure 1E) (Drogat and Her- mand, 2012)
PMID:23128140 GO:0051010 NMR + substrate
PMID:23133674 GO:0005515 fig1 Y2H
PMID:23133674 GO:0005515 fig1 Y2H
PMID:23133674 GO:0005515 bqt1 is fused to the activation domain
PMID:23133674 GO:0005515 fig1 only bqt1 is fused to the activation domain (that's why I am not adding this function to bqt2)
PMID:23133674 GO:0005515 Y2H fig 1
PMID:23166349 GO:0005515 Coimmunoprecipitation, yeast-two-hybrid
PMID:23166349 PBO:0109468 Further supported by PMID:25057016
PMID:23188080 FYPO:0004287 affects intermolecular, but not intramolecular, end joining
PMID:23188080 FYPO:0004287 affects intermolecular, but not intramolecular, end joining
PMID:23188080 FYPO:0004287 affects intermolecular, but not intramolecular, end joining
PMID:23188080 FYPO:0004287 affects intermolecular, but not intramolecular, end joining
PMID:23188080 FYPO:0004287 affects intermolecular, but not intramolecular, end joining
PMID:23188080 FYPO:0004287 affects intermolecular, but not intramolecular, end joining
PMID:23188080 FYPO:0004287 affects intermolecular, but not intramolecular, end joining
PMID:23200991 GO:1902917 inferred from localization plus GTPase activity
PMID:23200991 PBO:0037256 Observed with probe for active Cdc42 (CRIB)
PMID:23200991 PBO:0038209 Observed with probe for active Cdc42 (CRIB)
PMID:2320127 MOD:00046 Fig1c Serine is the major phosphoamino acid
PMID:2320127 PBO:0107935 Fig4a. Cells blocked in mitosis
PMID:2320127 MOD:00047 Fig1c threonine is the minor phosphoamino acid
PMID:2320127 PBO:0107935 Fig4a. Cells blocked in G2
PMID:23209828 PBO:0099848 MBC sensitivity phenotype and ubiquitylation and degradation phenotype
PMID:23209828 PBO:0099848 MBC sensitivity phenotype and ubiquitylation and degradation phenotype
PMID:23209828 GO:0061631 MBC resistance phenotype and pap1 ubiquitylation phenotype
PMID:23209828 PBO:0099843 Pap1 is ubiquitylated by Rhp6 and Ubr1
PMID:23209828 PBO:0099842 Pap1 is ubiquitylated by Rhp6 and Ubr1
PMID:23209828 PBO:0099849 MBC resistance phenotype and pap1 ubiquitylation phenotype
PMID:23211746 PBO:0095371 same as exo1delta alone
PMID:23211746 PBO:0095371 same as rad2delta alone
PMID:23211746 FYPO:0002553 gel electrophoresis + southern blot
PMID:23211746 FYPO:0000089 same as exo1delta alone
PMID:23211746 FYPO:0000089 same as chk1delta alone
PMID:23211746 FYPO:0000089 same as rad2delta alone
PMID:23211746 FYPO:0000268 same as chk1delta alone
PMID:23223230 PBO:0108760 In the array analysis, one of the most repressed genes in response to zinc deficiency was adh1, whereas one of the most highly expressed transcripts under this condition was an antisense transcript at this locus (Fig. 1A).
PMID:23223230 PBO:0108587 However, the larger band preferentially accumulated under zinc-replete conditions in wild-type cells and constitutively accumulated in SPCC13B11.02c cells. Thus, changes in adh1AS levels influence the levels of Adh1 protein, suggesting that this mechanism may exist to conserve zinc.
PMID:23223230 PBO:0108586 When adh1AS and adh1 transcript levels were examined in SPCC13B11.02c cells, the adh1AS transcript was not detected, and adh1 mRNAs were detected in both zinc-limited and zinc-replete cells (Fig. 1C).
PMID:23223230 PBO:0108585 When adh1AS and adh1 transcript levels were examined in SPCC13B11.02c cells, the adh1AS transcript was not detected, and adh1 mRNAs were detected in both zinc-limited and zinc-replete cells (Fig. 1C).
PMID:23223230 PBO:0108759 Taken together, the Northern and array analyses indicate that adh1AS transcripts preferentially accumulate in zinc-limited cells, whereas adh1 mRNAs accumulate in zinc-replete cells.
PMID:23223230 PBO:0092155 In the array analysis, one of the most repressed genes in response to zinc deficiency was adh1, whereas one of the most highly expressed transcripts under this condition was an antisense transcript at this locus (Fig. 1A).
PMID:23223230 PBO:0108584 In the array analysis, one of the most repressed genes in response to zinc deficiency was adh1, whereas one of the most highly expressed transcripts under this condition was an antisense transcript at this locus (Fig. 1A).
PMID:23231582 PBO:0100021 also inferred from chromatin localization and reporter gene expression
PMID:23231582 PBO:0100048 at pho1+ and SPBC1271.09
PMID:23231582 GO:0000122 represses Pho7-mediated transcription activationin phosphate-replete conditions; does not regulate Pho7 DNA binding
PMID:23236291 FYPO:0005277 Figure 8E (PMID:23236291)
PMID:23236291 FYPO:0005504 Figure 6A (PMID:23236291)
PMID:23236291 FYPO:0004153 Figure 7A (PMID:23236291)
PMID:23236291 FYPO:0000155 Figure 3 (PMID: 23236291)
PMID:23236291 FYPO:0000155 Figure 3 (PMID: 23236291)
PMID:23236291 FYPO:0003776 Figure 8D (PMID: 23236291)
PMID:23236291 GO:1900735 Figure 6A and 6C (PMID:23236291)
PMID:23236291 FYPO:0000155 Figure 8D (PMID: 23236291)
PMID:23236291 FYPO:0003318 Figure 8B (PMID: 23236291)
PMID:23236291 FYPO:0003335 Figure 8A (PMID: 23236291)
PMID:23236291 FYPO:0000155 Figure 3 (PMID: 23236291)
PMID:23236291 FYPO:0000155 Figure 3 (PMID: 23236291)
PMID:23236291 FYPO:0000155 Figure 3 (PMID: 23236291)
PMID:23236291 FYPO:0000155 Figure 3 (PMID: 23236291)
PMID:23236291 PBO:0107311 Requested new term from Sequence Ontology: CArG-box
PMID:23236291 FYPO:0000155 Figure 3 (PMID: 23236291)
PMID:23236291 FYPO:0000155 Figure 3 (PMID: 23236291)
PMID:23236291 FYPO:0003318 Figure 1B (PMID: 23236291)
PMID:23236291 FYPO:0003335 Figure 1A (PMID: 23236291)
PMID:23236291 GO:1900735 Figure 1A and 1B (PMID: 23236291)
PMID:23236291 FYPO:0000155 Figure 8D (PMID: 23236291)
PMID:23236291 FYPO:0004153 Figure 7A (PMID:23236291)
PMID:23236291 FYPO:0001252 Figure 8E (PMID:23236291)
PMID:23236291 FYPO:0003335 Figure 8B (PMID:23236291)
PMID:23236291 FYPO:0003318 Figure 8B (PMID:23236291)
PMID:23236291 FYPO:0003335 Figure 8D (PMID: 23236291)
PMID:23236291 FYPO:0000155 Figure 8D (PMID: 23236291)
PMID:23236291 FYPO:0000155 Figure 8D (PMID: 23236291)
PMID:23236291 FYPO:0000155 Figure 8D (PMID: 23236291)
PMID:23245849 GO:0140431 Mag2 binds stronger to the abasic oligonucleotide than to non-damaged DNA (Figure 2), with a dissociation rate constant more than 15 times higher for non-damaged DNA (kd 26 × 10−3 s −1) as compared to DNA containing the AP site analogue tetrahydrofuran (THF) (kd 1.6 × 10−3 s−1). Mag2 injected on sensor chips coated with oligonucleotides containing a single ethenoadenine or 8-oxoguanine lesion showed the same resonance levels as non-damaged DNA (data not shown), demonstrating that Mag2 preferentially binds to AP sites in DNA.
PMID:23245849 GO:0005634 Figure 1C
PMID:23245849 GO:0006307 multiple experiments
PMID:23245849 PBO:0093616 supp S1 Also the MMS sensitivity of the nth1 − mutant was suppressed by the deletion of mag1 but not mag2 (Figure S1), which contrasts previous results (Kanamitsu et al., 2007). We do not know the reason for this discrepancy, but it could be because of different strain backgrounds, as the strains used by Kanamisu and co-workers tolerate much higher MMS doses (0.03% versus 0.007% in our experiments)
PMID:23245849 PBO:0093616 fig 1D
PMID:23245849 FYPO:0000957 fig 1D
PMID:23245849 PBO:0093616 fig 1D
PMID:23245849 GO:0003905 A. Unexpectedly, Mag2 showed no DNA glycosylase activity for alkylated bases, even at very high enzyme concentration and under different assay conditions (titration of NaCl, Mg2+, ATP; data not shown). Further, heterologous expression of Mag2 did neither rescue the extreme alkylation sensitive phenotype of an E. coli mutant lacking the two 3mA DNA glycosylases AlkA and Tag, nor the corresponding Saccharomyces cerevisiae mag1 deletion mutant (data not shown). Mag2 was assayed for activity towards a variety of different base lesions which are known substrates for other DNA glycosylases including alkylated, oxidized and deaminated bases, base mismatches and AP sites; however no enzymatic activity was observed for any of the lesions tested (Table S1) Crystal Structure of Mag2 in Complex With DNA Reveals Novel Non-Enzymatic AP Site Recognition and DNA Sculpting
PMID:23254763 FYPO:0002061 FIgure 2. +25 μg/ml Hyg.B
PMID:23254763 PBO:0095408 FIgure 2
PMID:23254763 PBO:0095408 FIgure 2
PMID:23254763 PBO:0093561 FIgure 2.
PMID:23254763 PBO:0093561 FIgure 2.
PMID:23254763 PBO:0093561 FIgure 2.
PMID:23254763 PBO:0093561 FIgure 2.
PMID:23254763 PBO:0093561 FIgure 2.
PMID:23254763 PBO:0093561 FIgure 2.
PMID:23254763 PBO:0093561 FIgure 2.
PMID:23254763 PBO:0093561 FIgure 2.
PMID:23254763 PBO:0093561 FIgure 2. +25 μg/ml Hyg.B
PMID:23254763 PBO:0093561 FIgure 2. +25 μg/ml Hyg.B
PMID:23254763 PBO:0093561 FIgure 2. +25 μg/ml Hyg.B
PMID:23254763 PBO:0093561 FIgure 2. +25 μg/ml Hyg.B
PMID:23254763 PBO:0093561 FIgure 2. +25 μg/ml Hyg.B
PMID:23254763 PBO:0093561 FIgure 2. +25 μg/ml Hyg.B
PMID:23254763 PBO:0093561 FIgure 2. +25 μg/ml Hyg.B
PMID:23254763 FYPO:0002061 FIgure 2. +25 μg/ml Hyg.B
PMID:23254763 FYPO:0006807 Fig 3. galactose-specific HRP-PNA staining was used to detect quantitative differences in the galactosyla- tion of cell-surface proteins
PMID:23254763 FYPO:0003727 Fig 3. galactose-specific HRP-PNA staining was used to detect quantitative differences in the galactosyla- tion of cell-surface proteins
PMID:23254763 FYPO:0001317 fig 5a There was no difference in ght2+ expression levels between wild-type and uge1Δgal10Δ cells that have a reduced level of cytosolic UDP-galactose (Suzuki et al. 2010), indicating that expression of ght2+ is not influenced by intracellular UDP-galactose concentration
PMID:23254763 FYPO:0001317 fig 5a There was no difference in ght2+ expression levels between wild-type and uge1Δgal10Δ cells that have a reduced level of cytosolic UDP-galactose (Suzuki et al. 2010), indicating that expression of ght2+ is not influenced by intracellular UDP-galactose concentration
PMID:23254763 FYPO:0001317 fig 5a There was no difference in ght2+ expression levels between wild-type and uge1Δgal10Δ cells that have a reduced level of cytosolic UDP-galactose (Suzuki et al. 2010), indicating that expression of ght2+ is not influenced by intracellular UDP-galactose concentration
PMID:23254763 PBO:0095408 FIgure 2
PMID:23254763 PBO:0095408 FIgure 2
PMID:23254763 PBO:0095408 FIgure 2
PMID:23254763 PBO:0095408 FIgure 2
PMID:23254763 PBO:0095408 FIgure 2
PMID:23254763 PBO:0095408 FIgure 2
PMID:23254763 PBO:0093561 FIgure 2.
PMID:23254763 PBO:0095407 complemented by S. cerevisiae GAL2
PMID:23254763 PBO:0095408 FIgure 2. +25 μg/ml Hyg.B
PMID:23260662 GO:0071515 Fig. 3A
PMID:23260662 GO:0011000 inferred directness from effects of different alleles and of mutations elsewhere (swi1delta, clr4delta, or mat1-SS2)
PMID:23260662 GO:1902681 inferred indirectness from author description and different effect of swi1delta
PMID:23260662 PBO:0104354 same as lsd1-E918 single mutant
PMID:23260662 PBO:0104354 same as lsd1-E918 single mutant
PMID:23260662 PBO:0104354 same as lsd1-E918 single mutant
PMID:23260662 GO:0071515 inferred directness from effects of different alleles and of mutations elsewhere (swi1delta, clr4delta, or mat1-SS2)
PMID:23260662 PBO:0104354 same as lsd1-E918 single mutant
PMID:23273506 FYPO:0000695 Figures 4B and 4C: Asp56Ser mutation endows Mag2 with the ability to excise εA at levels similar to Mag1.
PMID:23297348 MOD:00046 S244, S278, S501, S755, T831, and S852 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S48, S71, S103, S113, S140, S171, S195, S206, S221, S236, T240, T255, S257, S289, S344, S379, S399, and T411 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S48, S71, S103, S113, S140, S171, S195, S206, S221, S236, T240, T255, S257, S289, S344, S379, S399, and T411 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S48, S71, S103, S113, S140, S171, S195, S206, S221, S236, T240, T255, S257, S289, S344, S379, S399, and T411 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S48, S71, S103, S113, S140, S171, S195, S206, S221, S236, T240, T255, S257, S289, S344, S379, S399, and T411 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S48, S71, S103, S113, S140, S171, S195, S206, S221, S236, T240, T255, S257, S289, S344, S379, S399, and T411 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S48, S71, S103, S113, S140, S171, S195, S206, S221, S236, T240, T255, S257, S289, S344, S379, S399, and T411 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S48, S71, S103, S113, S140, S171, S195, S206, S221, S236, T240, T255, S257, S289, S344, S379, S399, and T411 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S48, S71, S103, S113, S140, S171, S195, S206, S221, S236, T240, T255, S257, S289, S344, S379, S399, and T411 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S48, S71, S103, S113, S140, S171, S195, S206, S221, S236, T240, T255, S257, S289, S344, S379, S399, and T411 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S48, S71, S103, S113, S140, S171, S195, S206, S221, S236, T240, T255, S257, S289, S344, S379, S399, and T411 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S48, S71, S103, S113, S140, S171, S195, S206, S221, S236, T240, T255, S257, S289, S344, S379, S399, and T411 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S48, S71, S103, S113, S140, S171, S195, S206, S221, S236, T240, T255, S257, S289, S344, S379, S399, and T411 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S48, S71, S103, S113, S140, S171, S195, S206, S221, S236, T240, T255, S257, S289, S344, S379, S399, and T411 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S48, S71, S103, S113, S140, S171, S195, S206, S221, S236, T240, T255, S257, S289, S344, S379, S399, and T411 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S48, S71, S103, S113, S140, S171, S195, S206, S221, S236, T240, T255, S257, S289, S344, S379, S399, and T411 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S430, T451, S479, S491, T509, and T577 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S430, T451, S479, S491, T509, and T577 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S430, T451, S479, S491, T509, and T577 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S118, S143, and T379 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S118, S143, and T379 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 T123 and S334 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S118, S143, and T379 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S118, S143, and T379 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 T123 and S334 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 T297 and S364 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00047 T61, T71, S75, S156, S171, S361, S497, and S947 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00047 T61, T71, S75, S156, S171, S361, S497, and S947 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00047 S244, S278, S501, S755, T831, and S852 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 PBO:0101808 serine residues, presumably some or all of those mutated
PMID:23297348 PBO:0101808 serine residues, presumably some or all of those mutated
PMID:23297348 PBO:0101808 serine residues, presumably some or all of those mutated
PMID:23297348 MOD:00046 S370 was identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S74 and S95 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S74 and S95 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S558 was identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S301 and S499 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S301 and S499 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S216 and S298 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S216 and S298 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S65 was identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S148 was identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00047 T106 was identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S220 was identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S436 was identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S372 was identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00047 T554 was identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S411 was identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S147, S242, S270, S316, and S354 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S147, S242, S270, S316, and S354 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S147, S242, S270, S316, and S354 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S147, S242, S270, S316, and S354 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S147, S242, S270, S316, and S354 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00047 S430, T451, S479, S491, T509, and T577 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00047 S430, T451, S479, S491, T509, and T577 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00047 S430, T451, S479, S491, T509, and T577 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S345 was identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 T61, T71, S75, S156, S171, S361, S497, and S947 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 T61, T71, S75, S156, S171, S361, S497, and S947 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 T61, T71, S75, S156, S171, S361, S497, and S947 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 T61, T71, S75, S156, S171, S361, S497, and S947 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 T61, T71, S75, S156, S171, S361, S497, and S947 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 T61, T71, S75, S156, S171, S361, S497, and S947 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S196 and S252 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S196 and S252 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S502 was identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S674 was identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S183 and S372 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S183 and S372 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S57 and S206 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S57 and S206 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S303 was identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00047 T297 and S364 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S321 was identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S267 was identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00047 S48, S71, S103, S113, S140, S171, S195, S206, S221, S236, T240, T255, S257, S289, S344, S379, S399, and T411 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00047 S48, S71, S103, S113, S140, S171, S195, S206, S221, S236, T240, T255, S257, S289, S344, S379, S399, and T411 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00047 S48, S71, S103, S113, S140, S171, S195, S206, S221, S236, T240, T255, S257, S289, S344, S379, S399, and T411 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00047 S118, S143, and T379 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00047 T123 and S334 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S332, S700, and S732 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S332, S700, and S732 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S332, S700, and S732 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 Phosphorylation site S265 was identified by mass spectrometry.
PMID:23297348 MOD:00046 S244, S278, S501, S755, T831, and S852 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S244, S278, S501, S755, T831, and S852 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S244, S278, S501, S755, T831, and S852 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 MOD:00046 S244, S278, S501, S755, T831, and S852 were identified as phosphorylation sites by mass spectrometry.
PMID:23297348 GO:0005654 Localization of Clp1 to nucleoplasm requires the presence of the nuclear localization sequence (NLS), which was identified to locate right at the end of the C-terminal.
PMID:23297348 GO:0006606 Sal3 is required for the nuclear import of Clp1 as shown by microscopy.
PMID:23311928 FYPO:0001357 non-flocculating cells
PMID:23314747 PBO:0096683 Cnp1 localisation to centromere reduced in teb1-1 cells grown at 36C (based on immunofluorescence)
PMID:23314747 FYPO:0002687 Southern Blot of teb1-1 cells grown at permissive and restrictive temperatures shows no change in telomere length, compared to wild type cells
PMID:23314747 PBO:0099858 AACCCT box, subtelomere
PMID:23314747 PBO:0097201 AACCCT box, subtelomere
PMID:23314747 PBO:0095974 AACCCT box, subtelomere
PMID:23333317 PBO:0100160 Fig1 C 2 hybrid
PMID:23333317 PBO:0100158 Fig1c 2-hybrid
PMID:23333317 PBO:0100157 Fig1 C 2 hybrid
PMID:23333317 PBO:0100196 Fig 1b, F and G. (T75T78 PHOSPHORYLATED FORM)
PMID:23333317 PBO:0100195 Fig 1b, F and G. (T75T78 UNPHOSPHORYLATED FORM)
PMID:23333317 PBO:0111088 T75
PMID:23333317 PBO:0100194 T75T78
PMID:23333317 PBO:0100187 Fig5B plo1 decreased specific activity
PMID:23333317 PBO:0100188 Fig5B DELAYED
PMID:23333317 PBO:0100192 Fig5B
PMID:23333317 PBO:0100181 Fig5B plo1 increased specific activity
PMID:23333317 PBO:0100182 Fig5B
PMID:23333317 FYPO:0000674 Fig2E
PMID:23333317 PBO:0093556 Fig1. Rescue of cdc25-22 but not restored to full growth (partial rescue)
PMID:23333317 PBO:0093557 Fig1. Rescue of cdc25-22 but not restored to full growth (partial rescue)
PMID:23333317 PBO:0093556 Fig 1. Rescue of cdc25-22 but not restored to full growth (partial rescue)
PMID:23333317 PBO:0093557 Fig 1. Rescue of cdc25-22 but not restored to full growth (partial rescue)
PMID:23333317 PBO:0093557 Fig1. Rescue of cdc25-22 but not restored to full growth (partial rescue)
PMID:23333317 PBO:0093557 Fig1. Rescue of cdc25-22 but not restored to full growth (partial rescue). [ie The cut12.s11 (G71V) mutation enables cdc25+ null cells (cdc25.D) to form microcolonies of 1 to 20 cells [14]. ]
PMID:23333317 PBO:0100193 Fig1H cdc25-22 cut12R531STOP can grow at higher temperature in presence of cut12. G71V mutation. (vw changed form increased to normal, compared to WT)
PMID:23333317 PBO:0100179 Fig5B
PMID:23333317 PBO:0100178 Fig5B
PMID:23333317 PBO:0100177 Fig5B plo1 increased specific activity
PMID:23333317 PBO:0100192 Fig5B
PMID:23333317 PBO:0100179 Fig5B
PMID:23333317 PBO:0100178 Fig5B
PMID:23333317 PBO:0100177 Fig5B plo1 increased specific activity
PMID:23333317 PBO:0100179 Fig5B
PMID:23333317 PBO:0100188 Fig5B DELAYED
PMID:23333317 PBO:0100193 Fig1H cdc25-22 cut12R531STOP can grow at higher temperature in presence of cut12. G71V mutation. (vw changed form increased to normal, compared to WT)
PMID:23333317 PBO:0100199 Fig2H (VWI added this and man=de the original 'abnormal cell size' small (variable size at division, mixed sized see #3800)
PMID:23333317 PBO:0100198 Fig2H
PMID:23333317 PBO:0100160 Fig1C 2 hybrid
PMID:23333317 PBO:0100160 Fig1C 2 hybrid
PMID:23333317 PBO:0100179 Fig5B
PMID:23333317 PBO:0100177 Fig5B plo1 increased specific activity
PMID:23333317 PBO:0100178 Fig5B
PMID:23333317 PBO:0100180 Fig5B
PMID:23333317 PBO:0100181 Fig5B plo1 increased specific activity
PMID:23333317 PBO:0100182 Fig5B
PMID:23333317 PBO:0100179 Fig5B
PMID:23333317 PBO:0100181 Fig5B plo1 increased specific activity
PMID:23333317 PBO:0100182 Fig5B
PMID:23333317 PBO:0100178 Fig5B
PMID:23333317 PBO:0100177 Fig5B plo1 increased specific activity
PMID:23333317 PBO:0100179 Fig5B
PMID:23333317 PBO:0100178 Fig5B. premature recruitment of protein to the mitotic SPB
PMID:23333317 PBO:0100177 Fig5B plo1 increased specific activity
PMID:23333317 PBO:0100176 Fig5A plo1 localisation to SPB is dependent on fin1 activity
PMID:23333317 PBO:0100175 Fig5A plo1 localisation to SPB is dependent on fin1 activity
PMID:23333317 PBO:0100174 vw: could this one be abolished? Fig5A No change in recruitment of plo1 to SPB when fin1 is inactivated T75 T78 mutated to D
PMID:23333317 PBO:0100173 Fig5A No increase in recruitment of plo1 to SPB when fin1 is active if T75 T78 mutated to A
PMID:23333317 PBO:0100172 Fig4F T75 T78 no longer phosphorylated and dis2 remains bound to cut12
PMID:23333317 PBO:0100171 Fig4F dis2 remains bound to cut12
PMID:23333317 PBO:0100168 Fig4E in absence of fin1 activity dis2 remains bound to cut 12
PMID:23333317 PBO:0100167 Fig4A an antibody that recognized Cut12 when phosphorylated on T75 [Figure S2C] alone established that MPF phosphorylates T75 in vitro [Figure 4D]).
PMID:23333317 PBO:0100166 Fig4A fin1 activation is dependent on sid1
PMID:23333317 PBO:0100183 Fig5B
PMID:23333317 PBO:0100181 Fig5B plo1 increased specific activity
PMID:23333317 PBO:0100166 Fig4A HU arrest Fig4E synchronous culture
PMID:23333317 PBO:0100165 Fig2I Fig3C double mutant cut12.T75A T78A binds dis2
PMID:23333317 PBO:0100164 Fig2I single mutant cut12. T78D reduces dis2 binding
PMID:23333317 PBO:0100164 Fig2I single mutant cut12. T75D reduces dis2 binding
PMID:23333317 PBO:0100163 Fig2I single mutant cut12.T78A binds Dis2
PMID:23333317 PBO:0100163 Fig2I single mutant cut12. T75A binds dis2
PMID:23333317 PBO:0093557 Fig2E single mutant T75D does not rescue cdc25-22 as well as double T75DT78D or singleT78D mutants. (vw: changed to decreased)
PMID:23333317 PBO:0093557 Fig2E single mutant T78D does not rescue cdc25-22 as well as double T75DT78D. (vw changed from increased to decreased as we are comparing to WT , bottom row)
PMID:23333317 FYPO:0004481 Fig 2E unphosphorylatable cut12 mutants are unable to rescue cdc25 mutant (vw changed from decreased to abolished?)
PMID:23333317 FYPO:0000674 Fig 2E phospho mimetic cdc12 mutant rescues cdc25 mutant
PMID:23333317 PBO:0097660 Fig2H
PMID:23333317 FYPO:0000674 Fig2G
PMID:23333317 FYPO:0000674 "Fig1A, 2A. vw""Fig 1. Rescue of cdc25-22 but not restored to full growth (partial rescue)"""
PMID:23333317 PBO:0100162 Fig1 E
PMID:23333317 PBO:0100161 Fig1E
PMID:23333317 PBO:0100160 Fig1E
PMID:23333317 PBO:0100160 Fig1E
PMID:23333317 PBO:0100160 Fig1 E
PMID:23333317 PBO:0100159 Fig1C increased interaction in 2 hybrid
PMID:23333317 PBO:0100159 Fig1D
PMID:23333317 PBO:0100158 Fig1D
PMID:23333317 PBO:0100157 Fig1 D & E
PMID:23333317 PBO:0100182 Fig5B
PMID:23333317 PBO:0100183 Fig5B
PMID:23333317 PBO:0100187 Fig5B plo1 decreased specific activity
PMID:23333317 FYPO:0000674 Fig 2E phospho mimetic cdc12 mutant rescues cdc25 mutant
PMID:23333317 PBO:0100189 Fig5B
PMID:23333317 PBO:0100187 Fig5B plo1 decreased specific activity
PMID:23333317 PBO:0100188 Fig5B DELAYED
PMID:23333317 PBO:0100189 Fig5B
PMID:23333317 PBO:0100190 Fig5B plo1 increased specific activity
PMID:23333317 PBO:0100184 Fig5B
PMID:23333317 PBO:0100180 Fig5B
PMID:23333317 PBO:0100190 Fig5B plo1 increased specific activity
PMID:23333317 PBO:0100184 Fig5B
PMID:23333317 PBO:0100191 Fig5B
PMID:23333317 PBO:0100158 Fig1D
PMID:23333317 PBO:0100158 Fig1c 2-hybrid
PMID:23333317 FYPO:0000674 Fig 2E phospho mimetic cdc12 mutant rescues cdc25 mutant
PMID:23348717 PBO:0099730 assayed using AspRec8c–FGFP construct
PMID:23348717 PBO:0099730 assayed using cell growth with AspRec8c–FGFP–Mei2SATA construct (degradation frees Mei2SATA to arrest cell cycle)
PMID:23348717 PBO:0099729 also assayed using AspRec8c–FGFP construct, which persists longer than unmodified full-length Rec8
PMID:23348717 FYPO:0003299 assayed using ArgDHFRts–HA–Mcm4ts construct or AspRec8c–FGFP construct
PMID:23348717 PBO:0099730 assayed using AspRec8c–FGFP construct
PMID:23348717 PBO:0099730 assayed using ArgDHFRts–HA–Mcm4ts construct or AspRec8c–FGFP construct
PMID:23349636 PBO:0099925 more specifically, response to mitotic DNA replication checkpoint signaling
PMID:23349808 PBO:0024047 during G2 phase of mitotic cell cycle
PMID:23349808 PBO:0024047 during G2 phase of mitotic cell cycle
PMID:23349808 PBO:0024047 during G2 phase of mitotic cell cycle
PMID:23349808 PBO:0097713 during cytokinesis
PMID:23349808 PBO:0024047 during G2 phase of mitotic cell cycle
PMID:23394829 GO:0044732 also present in early anaphase; disappears by late anaphase
PMID:23394829 PBO:0023023 also present in early anaphase; disappears by late anaphase
PMID:23395004 PBO:0101941 ChIP-CHIP, rec27-205::GFP-kanMX6(C-terminal GFP tag)
PMID:23395004 FYPO:0004585 rec25-204::GFP-kanMX6(C-terminal GFP tag)
PMID:23395004 FYPO:0004585 mug20::GFP-kanMX6(C-terminal GFP tag)
PMID:23395004 FYPO:0004585 mug20::GFP-kanMX6(C-terminal GFP tag)
PMID:23395004 FYPO:0004585 mug20::GFP-kanMX6(C-terminal GFP tag)
PMID:23395004 FYPO:0003615 ChIP-CHIP, rec12-201::6His-2FLAG(C-terminal 6His-2FLAG tag)
PMID:23395004 FYPO:0004585 mug20::GFP-kanMX6(C-terminal GFP tag)
PMID:23395004 PBO:0101944 rec27-205::GFP-kanMX6(C-terminal GFP tag)
PMID:23395004 PBO:0101942 mug20::GFP-kanMX6(C-terminal GFP tag)
PMID:23395004 PBO:0101942 mug20::GFP-kanMX6(C-terminal GFP tag)
PMID:23395004 PBO:0101942 mug20::GFP-kanMX6(C-terminal GFP tag)
PMID:23395004 PBO:0101943 rec25-204::GFP-kanMX6(C-terminal GFP tag)
PMID:23395004 FYPO:0003615 ChIP-CHIP, rec12-201::6His-2FLAG(C-terminal 6His-2FLAG tag)
PMID:23395004 FYPO:0003615 ChIP-CHIP, rec12-201::6His-2FLAG(C-terminal 6His-2FLAG tag)
PMID:23395004 FYPO:0003615 ChIP-CHIP, rec12-201::6His-2FLAG(C-terminal 6His-2FLAG tag)
PMID:23395004 FYPO:0003181 ChIP-CHIP, rec12-201::6His-2FLAG(C-terminal 6His-2FLAG tag)
PMID:23395004 FYPO:0004585 ChIP-CHIP, rec27-205::GFP-kanMX6(C-terminal GFP tag)
PMID:23395004 PBO:0101942 mug20::GFP-kanMX6(C-terminal GFP tag)
PMID:23427262 PBO:0111960 vw after attachment
PMID:23427262 PBO:0111961 vw after attachment
PMID:23442800 GO:1902426 required for ubiquitination of Slp1
PMID:23462181 GO:0000935 Fig. 2A and B
PMID:23462181 PBO:0018634 Fig. 2A and B
PMID:23462181 PBO:0018346 Fig. 2A and B
PMID:23462181 GO:0051286 Fig. 2A and B
PMID:23462181 GO:0005730 Fig. 2A and B
PMID:23496905 FYPO:0002060 Figure 1
PMID:23496905 PBO:0099397 Figure 3
PMID:23496905 FYPO:0002060 Figure 1
PMID:23496905 PBO:0099396 fig 2
PMID:23496905 FYPO:0002060 Figure 1
PMID:23496905 PBO:0099396 fig 2
PMID:23496905 PBO:0099399 fig 4 (40% act remaining)
PMID:23496905 PBO:0099399 fig 4 (60%)
PMID:23496905 PBO:0099398 Figure 2
PMID:23496905 FYPO:0002060 Figure 1
PMID:23496905 GO:0000338 fig 2
PMID:23496905 PBO:0099396 fig 2
PMID:23496905 FYPO:0002060 Figure 1
PMID:23496905 PBO:0099397 Figure 3
PMID:23496905 PBO:0099397 Figure 3
PMID:23496905 PBO:0099396 fig 2
PMID:23496905 PBO:0099397 Figure 3
PMID:23503588 FYPO:0002064 in vitro
PMID:23551936 PBO:0021255 cellular response to rapamycin = GO:0072752 cellular response to caffeine =GO:0071313
PMID:23551936 PBO:0021256 cellular response to rapamycin = GO:0072752 cellular response to caffeine =GO:0071313
PMID:23555033 PBO:0092698 occurs_at CSL_response_element in vivo
PMID:23555033 GO:0045944 overexpression
PMID:23555033 PBO:0096540 to CSL_response_element
PMID:23555033 PBO:0096538 to CSL_response_element
PMID:23555033 PBO:0092698 occurs_at CSL_response_element, overexpression, in vitro
PMID:23555033 PBO:0096541 major region affecting localization between aa 395â465
PMID:23576550 PBO:0099232 anti-alpha-tubulin antibody used; included both pombe alpha-tubulin gene names in extension
PMID:23576550 PBO:0099233 anti-alpha-tubulin antibody used; included both pombe alpha-tubulin gene names in extension
PMID:23609449 PBO:0103289 figure 10 (check specificty). Taken together, the results demonstrate that substitution of Trp-409 in the context of the full-length GIIβ has a moderate to high (60% inhibitory) effect on GII activity.
PMID:23609449 GO:0140767 binds the non trimmed part of the N-glycan
PMID:23609449 PBO:0103289 figure 10 (check specificty)
PMID:23615450 FYPO:0002060 complements deletion
PMID:23615450 FYPO:0002060 complements deletion
PMID:23615450 PBO:0104668 Figure 1D
PMID:23615450 PBO:0104667 Figure 1C and Supplemental Figure S1C
PMID:23615450 PBO:0104666 Figure 1E and Supplemental Figure S1C
PMID:23615450 FYPO:0002061 (Figure 3).
PMID:23615450 FYPO:0002061 (Figure 3).
PMID:23615450 FYPO:0000161 (Figure 3).
PMID:23615450 GO:0005515 Supple- mental Figure S9C)
PMID:23615450 PBO:0104676 in interphase
PMID:23615450 PBO:0104673 complements deletion Figure 6A
PMID:23615450 PBO:0104669 Figure 4F inferred penetrance because growth not m,uch affected
PMID:23615450 FYPO:0001496 Figure 4F
PMID:23615450 PBO:0104670 Figure 4C
PMID:23615450 PBO:0104671 Figure 4C
PMID:23615450 PBO:0101823 Figure 1E and Supplemental Figure S1C
PMID:23615450 PBO:0104672 complements deletion Figure 6A
PMID:23615450 PBO:0096761 complements deletion Figure 6A
PMID:23615450 PBO:0104674 complements deletion Figure 6A
PMID:23615450 PBO:0101822 Figure 1E and Supplemental Figure S1C
PMID:23615450 FYPO:0000639 complements deletion Figure 6A
PMID:23615450 FYPO:0001357 Figure 4F
PMID:23615450 PBO:0101816 complements deletion
PMID:23615450 FYPO:0004653 fig 5
PMID:23615450 GO:0051015 Kd ≈ 20 μM Supplemental Figure S5B
PMID:23615450 FYPO:0001368 complements deletion
PMID:23615450 FYPO:0002060 complements deletion
PMID:23615450 FYPO:0004097 complements deletion
PMID:23615450 FYPO:0001368 complements deletion
PMID:23615450 FYPO:0002060 complements deletion
PMID:23628763 PBO:0101103 binds chromatin at promoter, and phenotypes suggest this
PMID:23628763 GO:0045944 boosts expression of the APC activator Fzr1/Mfr1
PMID:23628763 FYPO:0002773 fig2
PMID:23628763 PBO:0101099 fig3c
PMID:23628763 PBO:0101100 fig3c
PMID:23658229 PBO:0103136 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPBPB10D8.03) (mah 2014-08-05)
PMID:23658229 PBO:0103135 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPBPB10D8.03) (mah 2014-08-05)
PMID:23658229 PBO:0095151 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPBPB10D8.03) (mah 2014-08-05)
PMID:23658229 PBO:0096136 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPBPB10D8.03) (mah 2014-08-05)
PMID:23658229 PBO:0103138 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPBPB10D8.03) (mah 2014-08-05)
PMID:23658229 PBO:0095154 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPBPB10D8.03) (mah 2014-08-05)
PMID:23658229 PBO:0095155 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPBPB10D8.03) (mah 2014-08-05)
PMID:23658229 PBO:0103137 deleted this extension because it refers to a pseudogene: annotation_extension=assayed_using(PomBase:SPBPB10D8.03) (mah 2014-08-05)
PMID:23671279 PBO:0099237 RNA level increases upon amitrole exposure in wild type but not mutant
PMID:23671279 PBO:0099236 RNA level increases upon amitrole exposure in wild type but not mutant
PMID:23671279 PBO:0099235 RNA level increases upon amitrole exposure in wild type but not mutant
PMID:23671279 PBO:0099243 RNA level increases upon amitrole exposure in wild type but not mutant
PMID:23671279 FYPO:0001097 same as cpc2delta alone
PMID:23671279 PBO:0099241 RNA level increases upon amitrole exposure in wild type but not mutant
PMID:23671279 PBO:0099240 RNA level increases upon amitrole exposure in wild type but not mutant
PMID:23671279 PBO:0099253 same as cpc2delta alone
PMID:23671279 PBO:0099244 same as gcn2delta alone
PMID:23671279 PBO:0099239 RNA level increases upon amitrole exposure in wild type but not mutant
PMID:23671279 PBO:0099254 worse than cpc2delta alone
PMID:23671279 PBO:0099238 RNA level increases upon amitrole exposure in wild type but not mutant
PMID:23671279 PBO:0099237 RNA level increases upon amitrole exposure in wild type but not mutant
PMID:23671279 PBO:0099242 RNA level increases upon amitrole exposure in wild type but not mutant
PMID:23671279 FYPO:0001097 same as either single mutant
PMID:23671279 PBO:0099243 RNA level increases upon amitrole exposure in wild type but not mutant
PMID:23671279 PBO:0099242 RNA level increases upon amitrole exposure in wild type but not mutant
PMID:23671279 PBO:0099241 RNA level increases upon amitrole exposure in wild type but not mutant
PMID:23671279 PBO:0099240 RNA level increases upon amitrole exposure in wild type but not mutant
PMID:23671279 PBO:0099239 RNA level increases upon amitrole exposure in wild type but not mutant
PMID:23671279 PBO:0099238 RNA level increases upon amitrole exposure in wild type but not mutant
PMID:23671279 PBO:0099236 RNA level increases upon amitrole exposure in wild type but not mutant
PMID:23671279 PBO:0099235 RNA level increases upon amitrole exposure in wild type but not mutant
PMID:23671279 GO:0140469 vw edited
PMID:23677513 FYPO:0002345 same as hus1delta alone
PMID:23677513 FYPO:0002344 same as rad9delta alone
PMID:23677513 FYPO:0002344 same as hus1delta alone
PMID:23677513 FYPO:0000102 same as rad9delta alone
PMID:23677513 FYPO:0000102 same as hus1delta alone
PMID:23677513 FYPO:0000095 same as rad9delta alone
PMID:23677513 FYPO:0000095 same as hus1delta alone
PMID:23677513 FYPO:0002345 same as rad9delta alone
PMID:23687372 PBO:0102420 occurs_during(G1 to G0 transition)
PMID:23687372 FYPO:0000708 homothallic h90
PMID:23687372 FYPO:0000712 move down to G1, nitrogen induced
PMID:23687372 PBO:0102422 occurs_during(G1 to Go transition)
PMID:23687372 FYPO:0000708 homothallic h90
PMID:23687372 PBO:0102419 occurs_during(G1 to G0 transition)
PMID:23687372 PBO:0102418 occurs_during(G1 to G0 transition)
PMID:23695302 FYPO:0000223 they don't say whether the OEP populations continue to grow like normal (viable/inviable). Also data not shown.
PMID:23754748 FYPO:0002059 fig s1, can't tell after germination or before
PMID:23770677 PBO:0098967 We incubated cell ghosts in the presence of ATP and the myosin-II ATPase inhibitor blebbistatin (0.1 mM; ref. 17). Whereas rings underwent rapid contraction in the absence of blebbistatin, ring contraction was abolished in the presence of blebbistatin (Fig. 3a, nD8).
PMID:23770679 FYPO:0007110 fig 4c
PMID:23770679 FYPO:0007110 fig 4c
PMID:23770679 PBO:0100760 fig 4d
PMID:23770679 PBO:0100761 fig 4d
PMID:23770679 FYPO:0007108 figure 4c
PMID:23770679 PBO:0100762 figure 4
PMID:23770679 FYPO:0006427 fig 5b
PMID:23770679 PBO:0100763 Fig 5. d,e (unattached)
PMID:23770679 FYPO:0000209 fig 5b
PMID:23770679 PBO:0100764 Fig 6a
PMID:23770679 PBO:0100765 Figure 6 b/d (d used chromosome tethered polo mutants, I did not curate these phenotypes)
PMID:23770679 PBO:0100759 Is this phase correct
PMID:23770679 PBO:0100766 polo consensus fig 6b
PMID:23770679 PBO:0100767 Supp Fig S6
PMID:23770679 PBO:0100768 Supp Fig S6
PMID:23770679 PBO:0100769 Fig 6c or abolished?
PMID:23770679 PBO:0100770 Fig 7
PMID:23770679 FYPO:0000209 fig 7c
PMID:23770679 GO:1990571 The Alp7-Alp14 complex localises to kinetochores prior to meiosis I independently of microtubules, which does not seem to occur in mitosis.
PMID:23770679 PBO:0100773 The Nuf2 complex interacts with the Alp7-Alp14 complex phosphorylated by the polo kinase Plo1
PMID:23770679 PBO:0100759 Is this phase correct
PMID:23770679 PBO:0100759 Is this phase correct
PMID:23770679 FYPO:0007108 fig 3d
PMID:23770679 FYPO:0007109 fig 3d
PMID:23770679 PBO:0100758 Fig 3b
PMID:23770679 PBO:0100757 fig 2G
PMID:23770679 FYPO:0007112 Fig 2 b-d nvolved in kinetochore retrieval during meiotic prophase
PMID:23770679 FYPO:0007112 Fig 2 b-d involved in kinetochore retrieval during meiotic prophase
PMID:23770679 PBO:0100756 fig 2g
PMID:23770679 FYPO:0007108 figure 2a
PMID:23770679 FYPO:0007107 meiosis I
PMID:23770679 PBO:0100755 The Nuf2 complex interacts with the Alp7-Alp14 complex phosphorylated by the polo kinase Plo1
PMID:23770679 GO:1990571 The Alp7-Alp14 complex localises to kinetochores prior to meiosis I independently of microtubules, which does not seem to occur in mitosis.
PMID:23770679 GO:1990571 The Alp7-Alp14 complex localises to kinetochores prior to meiosis I independently of microtubules, which does not seem to occur in mitosis.
PMID:23851719 GO:0140673 results in retaining specifically modified histone H3 at the genes in question
PMID:23874237 PBO:0021600 The SO ID's correspond to tRNA lys/gln/glu
PMID:23874237 PBO:0021602 The SO ID's correspond to tRNA lys/gln/glu
PMID:23874237 PBO:0021601 The SO ID's correspond to tRNA lys/gln/glu
PMID:23885124 GO:0044732 throughout cell cycle; present in approximately equal stoichiometry with Alp4/GCP2 (immunoblotting and quantification of GFP-Mzt1 and GFP-Alp4 signals at the SPB)
PMID:23885124 GO:0008275 throughout cell cycle; present in approximately equal stoichiometry with Alp4/GCP2 (immunoblotting and quantification of GFP-Mzt1 and GFP-Alp4 signals at the SPB)
PMID:23907979 FYPO:0001357 Figure 4B, the activation of Rho1p, through the expres- sion of a constitutively active form of Rho1p or overex- pression of the wild-type Rho1p or Rgf1p, efficiently restored the growth of a strain (P81nmt-mtl2 wsc1D) unable to grow in the presence of thiamine (promoter off).
PMID:23907979 PBO:0101751 mtl2D cells were unable to grow on plates sup- plemented with 0.5 lg/mL Csp, whereas the wild-type cells were able to withstand concentrations of up to 5 lg/ mL
PMID:23907979 PBO:0101751 (Figure 4A) expression of rho1+, rgf1+, and rgf2+ restored the growth of an mtl2D mutant in the presence of the antifungal agent, whereas overexpression of rgf3+ did not suppress the growth defect.
PMID:23907979 PBO:0101751 (Figure 4A) expression of rho1+, rgf1+, and rgf2+ restored the growth of an mtl2D mutant in the presence of the antifungal agent, whereas overexpression of rgf3+ did not suppress the growth defect.
PMID:23907979 PBO:0101751 (Figure 4A) expression of rho1+, rgf1+, and rgf2+ restored the growth of an mtl2D mutant in the presence of the antifungal agent, whereas overexpression of rgf3+ did not suppress the growth defect.
PMID:23907979 PBO:0101751 mtl2D cells were unable to grow on plates sup- plemented with 0.5 lg/mL Csp, whereas the wild-type cells were able to withstand concentrations of up to 5 lg/ mL
PMID:23907979 PBO:0102603 In tea4D cells, Wsc1p-GFP localized mainly to the growing tip that was stained with Cfw (Fig. 3C).
PMID:23907979 GO:0005886 Wsc1p-GFP was found along the entire plasma membrane, but appeared much more concen- trated in patches at the cell ends. We also noted that Wsc1p-GFP accumulated in intracellular compartments (Fig. 3C and D).
PMID:23907979 FYPO:0007910 Repres- sion of mtl2+ promoted cell lysis and the cells shrunk without the release of cytoplasmic material.
PMID:23907979 FYPO:0000647 Repres- sion of mtl2+ promoted cell lysis and the cells shrunk without the release of cytoplasmic material.
PMID:23907979 PBO:0102606 . Interest- ingly, mtl2D and wsc1D mutants contained much less Rho1p-GTP than wild-type cells when the cultures were grown in the presence of 0.1 lg/mL of Csp for 16 h prior to harvesting (Fig. 4C)
PMID:23907979 FYPO:0000760 The mating rate was not affected in mtl2Dh+ 9 mtl2Dh� or wsc1Dh+ 9 wsc1Dh� homozygous crosses,
PMID:23907979 FYPO:0000760 The mating rate was not affected in mtl2Dh+ 9 mtl2Dh� or wsc1Dh+ 9 wsc1Dh� homozygous crosses,
PMID:23907979 PBO:0093590 Deletion of mtl2+ rendered cells hypersensitive to caffeine, vanadate, NaCl, H2O2, and SDS (see Fig. S1).
PMID:23907979 PBO:0094276 Deletion of mtl2+ rendered cells hypersensitive to caffeine, vanadate, NaCl, H2O2, and SDS (see Fig. S1).
PMID:23907979 PBO:0102602 Deletion of mtl2+ rendered cells hypersensitive to caffeine, vanadate, NaCl, H2O2, and SDS (see Fig. S1).
PMID:23907979 PBO:0093626 Deletion of mtl2+ rendered cells hypersensitive to caffeine, vanadate, NaCl, H2O2, and SDS (see Fig. S1).
PMID:23907979 FYPO:0002627 Moreover, when we looked at the cell wall composition of mtl2D mutants we found a decrease in the total amount of glucose incorpo- rated in the cell wall as compared with wild-type cells (30% in wild-type cells and 25% in mtl2D). The differ- ence was mainly due to a decrease in the b–glucan content (17% in the wild type and 13% in the mtl2D) (Fig. 1E).
PMID:23907979 PBO:0102601 We found that GS activity was slightly reduced in mtl2D null cells (Fig. 1D)
PMID:23907979 FYPO:0002061 The wsc1Drgf2D double mutant was viable, but we failed to find any double- mutant spore wsc1Drgf1D. T
PMID:23907979 FYPO:0000021 described as rounded , but more 'stubby'
PMID:23907979 FYPO:0001357 The wsc1D and mtl2D mutants grew well under standard growth conditions at both 28 and 37°C and entered the stationary phase at the same time as the wild-type cul- tures.
PMID:23907979 PBO:0093578 Deletion of mtl2+ rendered cells hypersensitive to caffeine, vanadate, NaCl, H2O2, and SDS (see Fig. S1).
PMID:23907979 PBO:0101751 wsc1D cell growth was inhibited above 2 lg/mL of Csp (Fig. 1C)
PMID:23907979 PBO:0101752 mtl2D cells were unable to grow on plates sup- plemented with 0.5 lg/mL Csp, whereas the wild-type cells were able to withstand concentrations of up to 5 lg/ mL
PMID:23907979 PBO:0102600 ~8% of the cells in the wsc1D mutant and 15% of the cells in mtl2D were lysed (Fig. 1B)
PMID:23907979 PBO:0102599 ~8% of the cells in the wsc1D mutant and 15% of the cells in mtl2D were lysed (Fig. 1B)
PMID:23907979 FYPO:0001315 wsc1D and mtl2D cells did not exhibit any evident morphological changes (Fig. 1B)
PMID:23907979 FYPO:0001315 wsc1D and mtl2D cells did not exhibit any evident morphological changes (Fig. 1B)
PMID:23907979 GO:0005886 Mtl2p-GFP showed an even membrane distribution with little intra- cellular signals.
PMID:23907979 GO:0031520 Wsc1p-GFP was found along the entire plasma membrane, but appeared much more concen- trated in patches at the cell ends. We also noted that Wsc1p-GFP accumulated in intracellular compartments (Fig. 3C and D).
PMID:23907979 FYPO:0001357 The wsc1D and mtl2D mutants grew well under standard growth conditions at both 28 and 37°C and entered the stationary phase at the same time as the wild-type cul- tures.
PMID:23907979 PBO:0102605 . Interest- ingly, mtl2D and wsc1D mutants contained much less Rho1p-GTP than wild-type cells when the cultures were grown in the presence of 0.1 lg/mL of Csp for 16 h prior to harvesting (Fig. 4C)
PMID:23907979 PBO:0102604 . Interest- ingly, mtl2D and wsc1D mutants contained much less Rho1p-GTP than wild-type cells when the cultures were grown in the presence of 0.1 lg/mL of Csp for 16 h prior to harvesting (Fig. 4C)
PMID:23907979 PBO:0099857 GTP bound modified form. Interest- ingly, mtl2D and wsc1D mutants contained much less Rho1p-GTP than wild-type cells when the cultures were grown in the presence of 0.1 lg/mL of Csp for 16 h prior to harvesting (Fig. 4C)
PMID:23907979 PBO:0099857 GTP bound modified form . Interestingly, mtl2D and wsc1D mutants contained much less Rho1p-GTP than wild-type cells when the cultures were grown in the presence of 0.1 lg/mL of Csp for 16 h prior to harvesting (Fig. 4C)
PMID:23907979 FYPO:0001357 The wsc1D and mtl2D mutants grew well under standard growth conditions at both 28 and 37°C and entered the stationary phase at the same time as the wild-type cul- tures.
PMID:23936074 PBO:0112081 increased staining of all chromatin
PMID:23936074 PBO:0095821 assayed using minichromosomes and internal telomeric repeat arrays
PMID:23956092 FYPO:0001496 was branched, elongated, multiseptate cell
PMID:23962284 FYPO:0002059 we don't know if they germinate or not
PMID:23962284 PBO:0103049 recombinant hal3 not a strong inhibitor in vitro
PMID:23966468 PBO:0099793 This is inferred from a combination of genetic interactions, localizations and phenocopy experiments, it has not been directly assayed but it feels 'safe' (VW)
PMID:23966468 PBO:0099784 FYPO_EXT:0000001=high penetracne
PMID:23977061 PBO:0104044 effect on secretion is specific for cell wall enzymes; secretion of acid phosphatase is normal (but assayed acid phosphatase activity in medium, so can't tell which gene(s))
PMID:23977061 GO:0006887 I changed this to exocytosis. This is required for cell wall organization, as it is causally upstream (val)
PMID:23986474 PBO:0108019 (Fig. 2B). The M167F mutation in either the orb5.as1 or orb5.as2 backbone generated the orb5.as8 and orb5.as9 alleles, which were more sensitive to analogue inhibition than the respective parental allele
PMID:23986474 FYPO:0005344 as arrested at 36 ̊C for 4.25 hours and released into synchronous mitosis by Wee1 inhibition using 30 mM 3BrB-PP1. The figure shows tubulin immunofluorescence and DAPI signals of cells 3 hours after release to reveal the characteristic ‘crows foot’ configuration of microtubules of cut7 mutants as the two halves of the mitotic spindle fail to interdigitate.
PMID:23986474 PBO:0033178 Analogue-released wee1.as8 cdc25.22 cut9.665 cells transiently accumulated much higher levels of metaphase spindles than wild-type cells before they ‘leaked’ through this mitotic arrest to execute telophase and cytokinesis with the classic ‘cut’ phenotype that originally led to the identification of the cut9.665 mutation (Fig. 6A,B)
PMID:23986474 FYPO:0000620 dns
PMID:23986474 FYPO:0006917 fig 4c.
PMID:23986474 FYPO:0001357 fig 3c. We therefore compared the ability of wee1.as1 and wee1.as8 to suppress cdc25.22 lethality at 36 ̊C. Inhibition of Wee1.as8 but not Wee1.as1 activity with analogue addition suppressed cdc25.22 lethality at 36 ̊C (Fig. 3B). A comparison of four ATP analogues revealed that the suppression (and therefore Wee1 inhibition) was most effective with 3BrB-PP1 (Fig. 3C).
PMID:23986474 FYPO:0001357 fig 3c. We therefore compared the ability of wee1.as1 and wee1.as8 to suppress cdc25.22 lethality at 36 ̊C. Inhibition of Wee1.as8 but not Wee1.as1 activity with analogue addition suppressed cdc25.22 lethality at 36 ̊C (Fig. 3B). A comparison of four ATP analogues revealed that the suppression (and therefore Wee1 inhibition) was most effective with 3BrB-PP1 (Fig. 3C).
PMID:23986474 FYPO:0002061 fig 3c
PMID:23986474 PBO:0095711 (Table 1; Fig. 3A)
PMID:23986474 PBO:0095711 (Table 1; Fig. 3A)
PMID:23986474 FYPO:0001125 rb5.as8 inhibition did not produce the ‘orb’ phenotype observed in the original orb5.ts mutants at the restrictive temperature (data not shown)
PMID:23986474 PBO:0108019 (Fig. 2B). The M167F mutation in either the orb5.as1 or orb5.as2 backbone generated the orb5.as8 and orb5.as9 alleles, which were more sensitive to analogue inhibition than the respective parental allele
PMID:23986474 PBO:0108020 Fig. 2B orb5.as2 displayed moderate sensitivity to 30 mM of 3BrB-PP1, whereas orb5.as1 showed none
PMID:23986474 PBO:0108020 Fig. 2B orb5.as2 displayed moderate sensitivity to 30 mM of 3BrB-PP1, whereas orb5.as1 showed none
PMID:23986474 PBO:0108020 Fig. 2B orb5.as2 displayed moderate sensitivity to 30 mM of 3BrB-PP1, whereas orb5.as1 showed none
PMID:23986474 FYPO:0002061 DNS
PMID:23986474 PBO:0108019 Fig 1
PMID:23986474 PBO:0108019 Fig 1.
PMID:23986474 PBO:0108019 Fig 1.
PMID:23986474 PBO:0108019 Fig 1. Chronic exposure to analogue through growth on solid medium reiterated the acute impact of analogue inhibition in liquid culture (Fig. 1A) and established that plo1.as8 is most effectively inhibited by 3BrB- PP1 (Fig. 1B).
PMID:23986474 PBO:0108020 Fig. 2B orb5.as2 displayed moderate sensitivity to 30 mM of 3BrB-PP1, whereas orb5.as1 showed none
PMID:23986474 PBO:0108019 fig 1. Chronic exposure to analogue through growth on solid medium reiterated the acute impact of analogue inhibition in liquid culture (Fig. 1A) and established that plo1.as8 is most effectively inhibited by 3BrB- PP1 (Fig. 1B).
PMID:23986474 FYPO:0000444 The static FACS profiles established that replication was indeed inhibited in analogue-released cdc10.v50 wee1.as8 cdc25.22 cells after analogue addition (Fig. 7B, right panel).
PMID:24003116 PBO:0100861 directly regulates adh4
PMID:24003116 PBO:0100862 Via EMSA binds directly to adh4 promoter.
PMID:24003116 FYPO:0001552 Grown in EMM + 200uM ZnSo4. Measurements made via ICP-MS.
PMID:24003116 FYPO:0001534 Grown in EMM + 200uM ZnSo4. Measurements made via ICP-MS.
PMID:24003116 FYPO:0001552 Grown in EMM + 200uM ZnSo4. Measurements made via ICP-MS.
PMID:24003116 GO:0005634 Visualized via Florescence using an integrated LOZ1::GFP construct grown in EMM +/- ZnSo4
PMID:24006256 GO:0010971 Dnt1 down-regulates Wee1 kinase. Had to remove extensions: independent_of(PomBase:Cdc25)| independent_of(PomBase:Rad3)| independent_of(PomBase:Chk1)| independent_of(PomBase:Cds1)| independent_of(PomBase:Clp1)| independent_of(PomBase:Pom1)| independent_of(PomBase:Cut12)| dependent_on(PomBase:Wee1) | acts_upstream_of(wee1) (mah 2015-11-06)
PMID:24006256 FYPO:0006822 wee1-50 epistatic to dnt1delta; shows that cell cycle regulation by Dnt1 depends on Wee1
PMID:24006488 PBO:0098801 fig4
PMID:24006488 PBO:0098802 fig4
PMID:24006488 PBO:0098799 fig4
PMID:24006488 MOD:00696 Serine 114 and Threonine 115 are phosphorylated by Cds1 upon activation of the DNA replication checkpoint. Yox1 phosphorylation by Cds1 releases Yox1 from MBF and activates MBF-dependent transcription.
PMID:24006488 PBO:0098801 fig4
PMID:24006488 PBO:0098794 Serine 720 and Serine 732 are phosphorylated by Chk1 Phosphorylation releases MBF from DNA and represses transcription of MBF-dependent genes.
PMID:24006488 PBO:0098794 Serine 720 and Serine 732 are phosphorylated by Chk1 Phosphorylation releases MBF from DNA and represses transcription of MBF-dependent genes.
PMID:24006488 PBO:0098802 fig4
PMID:24006488 PBO:0098804 localizes the MBF complex
PMID:24006488 PBO:0098800 fig4
PMID:24013504 FYPO:0003107 dependent_on(GO:0006312)| not_dependent_on(GO:0007004)
PMID:24021628 GO:0006360 heterologous complemetation of S. c HMO1
PMID:24039245 PBO:0107152 in vitro assay with purified proteins
PMID:24047646 PBO:0103987 Fig1 In early G2 nif1 localisation is monopolar and in late G2 it is bipolar
PMID:24047646 PBO:0103988 Fig1
PMID:24047646 PBO:0103989 Fig1
PMID:24047646 PBO:0103988 Fig1
PMID:24047646 GO:0071341 Fig1
PMID:24047646 FYPO:0006822 Fig3, Table 1
PMID:24047646 FYPO:0006822 Fig3, Table 1
PMID:24047646 FYPO:0006822 Fig3, Table 1
PMID:24047646 FYPO:0005207 Fig 6, shows pom1delta cells still have G2-M size control
PMID:24047646 FYPO:0005207 Fig 6, shows nif1delta cells still have G2-M size control
PMID:24047646 FYPO:0005206 Fig 6, shows wee1-50 cells at restrictive temperature have lost G2-M size control
PMID:24055157 PBO:0106631 assayed with human CK1, process from phenotypes (dma1 dependent pathway)
PMID:24055157 FYPO:0002060 In corroboration of these findings, sid4(T275A) mutants were refractory to dma1 overexpression lethality (Figure 2D).
PMID:24055157 FYPO:0004537 cells bypassed the arrest after 5 hrs (Figure 2C).
PMID:24055157 FYPO:0004537 cells bypassed the arrest after 5 hrs (Figure 2C). ......These data indicate that mutating T275 eliminates Dma1-dependent checkpoint signaling.
PMID:24055157 PBO:0096161 Thus, phosphorylation on both T275 and S278 is necessary and sufficient to support binding of the Dma1 FHA domain to Sid4 and Sid4 ubiquitination.
PMID:24055157 PBO:0094517 Although Dma1-GFP still localized to SPBs in sid4(T275A) mutant cells (Figure S1F),
PMID:24055157 PBO:0106628 Although Dma1-GFP still localized to SPBs in sid4(T275A) mutant cells (Figure S1F),
PMID:24055157 PBO:0094517 Although Dma1-GFP still localized to SPBs in sid4(T275A) mutant cells (Figure S1F),
PMID:24055157 PBO:0106627 mutating S278 to a glutamate did not affect Sid4 ubiquitination (Figure 1D).
PMID:24055157 PBO:0094510 Although mutating S278 to alanine abolished Sid4 ubiquitination (Figure 1D)
PMID:24055157 PBO:0106626 In dma1Δ cells, a single slower migrating form of Sid4 was detected, which was collapsed by phosphatase treatment, indicating that Sid4 is phosphorylated in vivo (Figure 1A, lanes 3 and 4). In vivo radiolabeling experiments validated Sid4 as a phospho-protein and revealed that Sid4 is phosphorylated on serines and threonines (Figure S1A–C).
PMID:24055157 PBO:0106631 assayed with human CK1
PMID:24055157 PBO:0106630 Hhp1-GFP localization at SPBs is Sid4 independent (Figure S3E)
PMID:24055157 PBO:0106629 Hhp1-GFP localization at SPBs is Sid4 independent (Figure S3E)
PMID:24055157 GO:0005816 In cells growing asynchronously, both Hhp1-GFP and Hhp2-GFP localized to the nucleus, SPBs, and the cell division site, although Hhp2-GFP was more prominent at the division site compared to Hhp1-GFP (Figure 3B).
PMID:24055157 GO:0005634 In cells growing asynchronously, both Hhp1-GFP and Hhp2-GFP localized to the nucleus, SPBs, and the cell division site, although Hhp2-GFP was more prominent at the division site compared to Hhp1-GFP (Figure 3B).
PMID:2406029 FYPO:0001916 same as cdc2-ww single mutant
PMID:24074952 MOD:00047 residue=T235 | residue=T187, annotation_extension=added_by(CDK COMPLEX, CDC2 AND CDC13) | residue=T215
PMID:24074952 MOD:00047 residue=T235 | residue=T187, annotation_extension=added_by(CDK COMPLEX, CDC2 AND CDC13) | residue=T215
PMID:24074952 MOD:00047 residue=T235 | residue=T187, annotation_extension=added_by(CDK COMPLEX, CDC2 AND CDC13) | residue=T215
PMID:24081329 PBO:0094607 evidence for all FYPO:0001908 = northern blot
PMID:24095277 GO:0016891 does it produce 5' monoesters?
PMID:24095277 PBO:0101060 has substrates centromere outer repeat transcripts and polyA mRNA. Activated by mg2+
PMID:24095277 PBO:0108681 has substrates centromere outer repeat transcripts and polyA mRNA. Activated by mg2+
PMID:24115772 GO:1903475 dependent on septation initiation signaling (GO:0031028)
PMID:24115772 PBO:0018470 during(GO:0051329)
PMID:24118096 GO:1990355 Trx1's involvement in tis process is to recycle mxr1 for met-O conversion to met
PMID:24127216 GO:0030041 fig 1D-G
PMID:24127216 PBO:0096493 fig1b
PMID:24127216 FYPO:0003001 fig3e
PMID:24127216 FYPO:0003001 fig3e
PMID:24127216 PBO:0104781 figs2a
PMID:24127216 FYPO:0003014 fig2a
PMID:24127216 FYPO:0001365 fig2a
PMID:24127216 FYPO:0001368 figS1a
PMID:24127216 FYPO:0002998 fig 1h
PMID:24127216 FYPO:0003000 fig 1d-g
PMID:24127216 PBO:0096493 fig1b
PMID:24127216 FYPO:0002998 fig1a
PMID:24127216 FYPO:0003000 fig 1d-g
PMID:24127216 GO:1903475 Truncation of Cdc12 at N-terminus leads to a requirement of For3 actin assembly for contractile ring assembly. AL -also see fig 2fgh
PMID:24127216 GO:1903475 Truncation of Cdc12 at N-terminus leads to a requirement of For3 actin assembly for contractile ring assembly.
PMID:24127216 PBO:0099316 Depends on Cdc15 to localize to the contractile ring during Anaphase A. Viewed by fluorescent fusion protein. AL - exists during anaphase A and anaphase B
PMID:24127216 PBO:0104780 Depends on Cdc15 to localize to the contractile ring during Anaphase A. Viewed by fluorescent fusion protein. AL - exists during anaphase A and anaphase B
PMID:24146635 FYPO:0000082 36 degrees (not brief heat shock)
PMID:24146635 FYPO:0001326 Global gene expression profile (RNAseq) of deletion similar to that of heat-stressed wild type.
PMID:24146635 PBO:0020827 shorter duration of heat exposure (up to ~45 min)
PMID:24146635 FYPO:0001326 Global gene expression profile (RNAseq) of deletion similar to that of heat-stressed wild type.
PMID:24146635 PBO:0020826 prolonged heat exposure (more than ~45 min)
PMID:24146635 PBO:0020826 prolonged heat exposure (more than ~45 min)
PMID:24146635 PBO:0099108 """Both Gef1-3YFP and Scd1-GFP exhibited bipolar localization in majority of late wild type cells"""
PMID:24146635 PBO:0020827 shorter duration of heat exposure (up to ~45 min)
PMID:24146635 PBO:0020826 prolonged heat exposure (more than ~45 min)
PMID:24146635 PBO:0020826 prolonged heat exposure (more than ~45 min)
PMID:24146635 PBO:0020827 shorter duration of heat exposure (up to ~45 min)
PMID:24146635 PBO:0020826 prolonged heat exposure (more than ~45 min)
PMID:24146635 PBO:0020826 prolonged heat exposure (more than ~45 min)
PMID:24146635 PBO:0099108 """Both Gef1-3YFP and Scd1-GFP exhibited bipolar localization in majority of late wild type cells"""
PMID:24146635 PBO:0023812 punctate; shorter duration of heat exposure (up to ~45 min)
PMID:24147005 FYPO:0006539 7c
PMID:24147005 FYPO:0006538 6A
PMID:24155978 PBO:0093578 5S
PMID:24155978 PBO:0102936 all independent of Sty1 (effects of H2O2 & NAC unchanged in sty1delta)
PMID:24155978 PBO:0102935 5X
PMID:24161933 PBO:0099160 Even reduction to about 10% of the original Mad1 level, which is hardly visible by fluorescence microscopy (Fig. 2e), did not fully abolish the SAC
PMID:24161933 PBO:0099161 5a.
PMID:24161933 FYPO:0004318 abundances of 40% or lower, cells lacked checkpoint activity.
PMID:24161933 PBO:0099162 (Fig. 2d)
PMID:24161933 FYPO:0003762 In cells with 30% Mad1, the checkpoint was markedly impaired in minimal medium, although largely functional in rich medium
PMID:24161933 PBO:0112078 65% of endogenous mad2 level, Fig. S4
PMID:24161933 PBO:0112074 300% of endogenous mad1 level, Fig. S4
PMID:24161933 PBO:0112079 30% of endogenous mad3 level, Fig. S4
PMID:24161933 PBO:0112075 10% of endogenous mad1 level, Fig. S4
PMID:24161933 PBO:0112080 40% of endogenous slp1 level, Fig. S4
PMID:24161933 PBO:0112074 500% of endogenous mad1 level, Fig. S4
PMID:24161933 PBO:0112076 30% of endogenous mad1 level, Fig. S4
PMID:24161933 PBO:0112077 10% of endogenous mad2 level, Fig. S4
PMID:24161933 PBO:0018530 fig1
PMID:24167631 FYPO:0001178 FYPO:0001178 + PECO:0000240 captures info for requested new term (Term name: loss of viability upon long-term nutrient starvation Definition: A cell population phenotype in which a smaller than normal proportion of the population remains viable when cells in a culture in stationary phase are deprived of nitrogen. Use this term to annotate experiments in which a culture is cultivated in stationary phase under nitrogen-depleted conditions for a long time (more than 1 week), and then the number of cells viable enough to form a colony upon return to conditions supporting vegetative growth is measured and compared to wild type.) -mah
PMID:24186976 GO:0005515 supp fig7
PMID:24186976 GO:0005515 supp fig7
PMID:24224056 GO:0045944 in response to carbon source change from glucose to maltose regulates agl1
PMID:24224056 FYPO:0002924 The decrease in cell growth on maltose medium is suppressed by neighboring wild-type cells but not by agl1 delta cells, which are defective in maltase secretion.
PMID:24224056 GO:0045944 in response to carbon source change from glucose to maltose regulates agl1
PMID:24239120 FYPO:0004307 Fig. 1
PMID:24239120 PBO:0094481 Fig. 4
PMID:24239120 PBO:0094480 Fig. 3
PMID:24239120 PBO:0094480 Fig. 3
PMID:24239120 PBO:0094479 Fig. 3
PMID:24239120 FYPO:0007961 Fig. 4
PMID:24239120 PBO:0094478 Fig. 3
PMID:24239120 PBO:0094477 Fig. 3
PMID:24239120 FYPO:0006917 Fig. 2 (This is a rescue of FYPO:0000324)
PMID:24239120 FYPO:0006259 Fig. 2 (This is a rescue of FYPO:0004395)
PMID:24239120 FYPO:0006259 Fig. 2 (This is a rescue of FYPO:0004395)
PMID:24239120 PBO:0094474 Fig. S1 (This is a partial rescue of FYPO:0004307)
PMID:24239120 FYPO:0006917 Fig. S1 (This is a rescue of FYPO:0000324)
PMID:24239120 FYPO:0006917 Fig. S1 (This is a rescue of FYPO:0000324)
PMID:24239120 PBO:0094476 Fig. S1 The authors define it as prolongued prophase-metaphase , but since they use the degradation as cdc13 as a marker, it really is anaphase onset that is measured.
PMID:24239120 FYPO:0000324 Fig. S1 The authors define it as prolongued prophase-metaphase , but since they use the degradation as cdc13 as a marker, it really is anaphase onset that is measured.
PMID:24239120 FYPO:0000324 Fig. S1 The authors define it as prolongued prophase-metaphase , but since they use the degradation as cdc13 as a marker, it really is anaphase onset that is measured.
PMID:24239120 FYPO:0000324 Fig. S1 The authors define it as prolongued prophase-metaphase , but since they use the degradation as cdc13 as a marker, it really is anaphase onset that is measured.
PMID:24239120 FYPO:0007960 Fig. S1
PMID:24239120 FYPO:0007959 Fig. S1
PMID:24239120 FYPO:0006259 Fig. 1
PMID:24239120 FYPO:0006259 Fig. 1
PMID:24239120 FYPO:0006259 Fig. 1
PMID:24239120 FYPO:0006259 Fig. 1
PMID:24239120 FYPO:0006259 Fig. 1
PMID:24239120 FYPO:0006259 Fig. 1
PMID:24239120 FYPO:0004395 Fig. 1
PMID:24239120 PBO:0094475 Fig. 1
PMID:24239120 PBO:0094474 Fig. 1
PMID:24239120 FYPO:0004307 Fig. 1
PMID:24240238 FYPO:0004742 silencing normal as long as heterochromatin assembly can take place normally
PMID:24240238 FYPO:0002019 Southern blot to detect telomeric sequence
PMID:24240238 FYPO:0002019 Southern blot to detect telomeric sequence
PMID:24240238 FYPO:0004744 experiment introduced otr::ura4+ in either a silenced state (from wild-type cells) or a desilenced state (from clr4delta cells) into poz1delta dcr1delta cells by genetic crosses
PMID:24240238 FYPO:0002687 Southern blot to detect telomeric sequence
PMID:24240238 FYPO:0002687 Southern blot to detect telomeric sequence
PMID:24240238 FYPO:0002687 Southern blot to detect telomeric sequence
PMID:24240238 FYPO:0002687 Southern blot to detect telomeric sequence
PMID:24240238 FYPO:0002687 Southern blot to detect telomeric sequence
PMID:24244528 FYPO:0007603 decreased. (atpase activity assay) However, -E1 motors exhibited relatively low activity under either condition (Figure S1). These experiments performed in the absence of actin suggest that defects in -E1 motors are not specific to actin displacement and motility, and probably reflect a general defect in conformation and function.
PMID:24244528 FYPO:0003526 However, most filaments (99%) bound by -E1 were non-motile, while most filaments bound by wild-type Myo2p were motile (Movie S2).
PMID:24244528 PBO:0096789 However, the lower molecular weight form of -E1 failed to accumulate over time following protease addition (Figure 4C), suggesting an altered conformation more sensitive to proteolysis.
PMID:24244528 PBO:0096788 Our data indicates thatRng3p is required to establish active Myo2p motors.The control experiments (where cells were shifted to 37uC at 22hours post-induction) indicated that Rng3p was not essential formaintaining Myo2p motility once an active population of motorshad been synthesized, as previously reported [24]...........Collectively our findings suggest that Rng3p is required to generate an active and stable population of Myo2p motors.
PMID:24247430 GO:0031139 I think this is real i.e. downregulation of growth to allow differentiation
PMID:24268782 PBO:0105248 vw: fixed extensions to link F-P and to delete GO:0051091 vw: move up to from thioredoxin-disulfide reductase activity
PMID:24268782 PBO:0105247 vw: fixed extensions to link F-P and to delete GO:0051091
PMID:24291789 GO:0030892 Fig. 2a,b and Extended Data Fig. 2a
PMID:24291789 GO:0032116 Fig. 1a
PMID:24291789 GO:0032116 Fig. 1a
PMID:24291789 PBO:0105281 Fig. 1c,d (part_of extension is 'positive regulation of mitotic cohesin loading'
PMID:24291789 PBO:0105281 Fig. 1c,d part_of extension is 'positive regulation of mitotic cohesin loading'
PMID:24291789 GO:0007064 (Fig. 2e) Fig. 2f) Fig. 3a,b).
PMID:24291789 GO:0003690 Fig. 2a,b and Extended Data Fig. 2a
PMID:24291789 GO:0003690 Fig. 2a,b and Extended Data Fig. 2a
PMID:24291789 GO:0003690 Fig. 2a,b and Extended Data Fig. 2a
PMID:24291789 GO:0003690 Fig. 2a,b and Extended Data Fig. 2a
PMID:24291789 GO:0030892 Fig. 2a,b and Extended Data Fig. 2a
PMID:24291789 GO:0030892 Fig. 2a,b and Extended Data Fig. 2a
PMID:24291789 GO:0030892 Fig. 2a,b and Extended Data Fig. 2a
PMID:24291789 PBO:0105282 fig 4 b part_of extension is 'positive regulation of mitotic cohesin loading'
PMID:24291789 GO:0007064 (Fig. 3b), suggesting that cohesin in principle achieves topological loading onto DNA independently of a cohesin loader, albeit inefficiently.
PMID:24291789 GO:0007064 (Fig. 2e) Fig. 2f) Fig. 3a,b). contributes to, mis4 is sufficient?
PMID:24291789 GO:0007064 (Fig. 3b), suggesting that cohesin in principle achieves topological loading onto DNA independently of a cohesin loader, albeit inefficiently.
PMID:24291789 GO:0007064 (Fig. 3b), suggesting that cohesin in principle achieves topological loading onto DNA independently of a cohesin loader, albeit inefficiently.
PMID:24291789 GO:0007064 (Fig. 3b), suggesting that cohesin in principle achieves topological loading onto DNA independently of a cohesin loader, albeit inefficiently.
PMID:24297439 FYPO:0006822 Effect of sck1 deletion to increase cell length in git3 delete cells depends on Gpa2 activity. Otherwise, Sck1 acts in parallel with Pka1 to increase cell length.
PMID:24297439 GO:0005515 Two hybrid interaction using Gpa2K270E activated protein with Sck1.
PMID:24297439 PBO:0106128 it's a bit indirect, but they show this via consensus site mutations....I think it is borderline ok
PMID:24297439 GO:0005515 Two hybrid interaction using Gpa2K270E activated protein with Sck1.
PMID:24313451 GO:0101005 assayed using cell extract, overexpressed protien and synthetic UB conjugate
PMID:24314397 GO:0030378 inhibited by α-(hydroxymethyl)serine (CHEBI:28187)
PMID:24316795 FYPO:0003481 high overexpression
PMID:24316795 FYPO:0000339 high concentration (1 uM) 3MB-PP1
PMID:24316795 FYPO:0001018 high concentration (1 uM) 3MB-PP1
PMID:24316795 FYPO:0003150 low concentration (<0.25 uM) 3MB-PP1
PMID:24316795 PBO:0107141 low concentration (<0.25 uM) 3MB-PP1
PMID:24316795 FYPO:0006822 high concentration (1 uM) 3MB-PP1
PMID:24316795 FYPO:0006822 low concentration (<0.25 uM) 3MB-PP1
PMID:24316795 FYPO:0006822 low concentration (<0.25 uM) 3MB-PP1
PMID:24316795 GO:0010971 Negatively regulated by Pom1 via phosphorylation of C-ter
PMID:24316795 GO:0031569 Cdr2 phosphorylated by Pom1 at the CTD negatively regulates its activity
PMID:24316795 PBO:0103727 Phosphorylates cdr2 at S755 in vitro
PMID:24316795 PBO:0094966 same as cdr2-S755A-758A alone
PMID:24316795 PBO:0094966 same as cdr2-S755A-758A alone
PMID:24316795 PBO:0096622 Pom1-as1 protein may preferentially localize to non-growing end.
PMID:24316795 FYPO:0001124 moderate overexpression
PMID:24316795 PBO:0103729 high concentration (1 uM) 3MB-PP1
PMID:24327658 GO:0010895 hhp2 deletion increases steady-state ergosterol
PMID:24327658 GO:0005515 Binds specifically to active Sre1 transcription factor and not full-length precursor
PMID:24327658 PBO:0096022 in vitro kinase assay using recombinant Sre1 aa 1-440
PMID:24327658 PBO:0108902 in vitro kinase assay using recombinant Sre1 aa 1-440
PMID:24327658 PBO:0096021 in vitro kinase assay using recombinant Sre1 aa 1-440
PMID:24327658 FYPO:0003251 Ok as a single mutant despite sre1-N mutant?
PMID:24327658 GO:0000122 accelerates degradation of active Sre1 transcription factor
PMID:24344203 PBO:0101640 same as isp7+ overexpression alone
PMID:24344203 PBO:0101636 isp7+ overexpression decreases Gad8's kinase activity towards substrate Fkh2
PMID:24344203 PBO:0101640 same as isp7+ overexpression alone
PMID:24475199 FYPO:0002834 Expression level up 3 times
PMID:24475199 FYPO:0002834 Expression level up 2 times
PMID:24475199 FYPO:0002834 Expression level up 2 times
PMID:24475199 FYPO:0002827 Expression level up 25 times
PMID:24475199 FYPO:0002834 Expression level up 2 times
PMID:24475199 FYPO:0002827 Expression level up 23 times
PMID:24475199 FYPO:0002827 Expression level up 38 times
PMID:24475199 FYPO:0002827 Expression level up 43 times
PMID:24475199 FYPO:0002827 Expression level up 31 times
PMID:24475199 FYPO:0002827 Expression level up 22 times
PMID:24475199 FYPO:0002827 Expression level up 8 times.
PMID:24475199 FYPO:0002827 Expression level up 35 times
PMID:24475199 FYPO:0002834 Expression level up 2.5 times
PMID:24475199 FYPO:0002834 Expression level up 2 times
PMID:24477934 PBO:0096319 Fig S4a
PMID:24477934 PBO:0096319 Fig S4a
PMID:24477934 FYPO:0005781 Fig S4a
PMID:24477934 FYPO:0005781 Fig S4a
PMID:24477934 FYPO:0005781 Fig S4a
PMID:24477934 FYPO:0004318 (Fig 1F
PMID:24477934 FYPO:0004318 fig1F
PMID:24477934 FYPO:0004318 Fig1F
PMID:24477934 FYPO:0004318 Fig1F
PMID:24477934 PBO:0096315 Fig 1A, C–E
PMID:24477934 PBO:0096316 Fig 1A, C–E
PMID:24477934 PBO:0104982 Fig S4A
PMID:24477934 PBO:0104982 Fig S4A
PMID:24477934 PBO:0104982 Fig1C/D
PMID:24477934 FYPO:0004318 Fig 1I–L
PMID:24477934 PBO:0104983 Fig 1I–L
PMID:24477934 PBO:0104982 Fig 1I–L
PMID:24477934 PBO:0104984 Fig3 B/C
PMID:24477934 PBO:0104984 Fig3 B/C
PMID:24477934 PBO:0095474 Fig 3 D
PMID:24477934 PBO:0095474 Fig 3D
PMID:24477934 PBO:0096320 Fig S1B
PMID:24477934 PBO:0104985 Fig S1B
PMID:24477934 PBO:0104986 Fig S1I
PMID:24477934 PBO:0104987 Fig S1I
PMID:24477934 PBO:0104988 Fig S1I
PMID:24477934 FYPO:0004318 Fig S2F
PMID:24477934 FYPO:0004318 Fig S2F
PMID:24477934 PBO:0104982 Fig S2C,D,E
PMID:24477934 PBO:0104982 Fig S2C,D,E
PMID:24477934 PBO:0104989 Fig S2C,D,E
PMID:24477934 PBO:0096319 Fig S2C,D,E
PMID:24477934 PBO:0104990 Fig S2F
PMID:24477934 PBO:0104991 Fig S2F
PMID:24477934 PBO:0095479 Fig S1A and D
PMID:24477934 PBO:0104992 Fig 1A, C–E
PMID:24477934 PBO:0104992 Fig 1A, C–D
PMID:24477934 PBO:0095479 1H
PMID:24477934 PBO:0104993 Fig 1H
PMID:24477934 PBO:0096319 Fig S4a
PMID:24477934 PBO:0104994 Fig 1H
PMID:24477934 FYPO:0004318 Fig 2B
PMID:24477934 FYPO:0004318 (Fig (Fig 2D and E). mad1 localized did not rescue,
PMID:24477934 PBO:0104995 Fif 3F
PMID:24477934 PBO:0104996 . A complex between the checkpoint proteins Mad1 and Mad2 provides a platform for Mad2:Mad2 dimerization at unattached kinetochores, which enables Mad2 to delay anaphase. Here, we show that mutations in Bub1 and within the Mad1 C-terminal domain impair the kinetochore localization of Mad1:Mad2 and abrogate checkpoint activity. Artificial kinetochore recruitment of Mad1 in these mutants co-recruits Mad2; however, the checkpoint remains non-functional. We identify specific mutations within the C-terminal head of Mad1 that impair checkpoint activity without affecting the kinetochore localization of Bub1, Mad1 or Mad2. Hence, Mad1 potentially in conjunction with Bub1 has a crucial role in checkpoint signalling in addition to presenting Mad2.
PMID:24477934 FYPO:0003762 Fig S4a
PMID:24477934 FYPO:0003762 Fig S4a
PMID:24477934 FYPO:0003762 Fig S4a
PMID:24477934 FYPO:0003762 Fig S4a
PMID:24477934 FYPO:0003762 Fig S4a
PMID:24477934 FYPO:0003762 Fig S4a
PMID:24477934 PBO:0096319 Fig S4a
PMID:24477934 PBO:0096319 Fig S4a
PMID:24477934 PBO:0096319 Fig S4a
PMID:24477934 PBO:0096319 Fig S4a
PMID:24478458 PBO:0108730 phosphorylates rgf1 during HU response, part of maintenance of protien lcoation in nucleus
PMID:24493644 PBO:0096066 fig5
PMID:24514900 PBO:0102728 high penetrance
PMID:24514900 GO:0032220 Required for phosphatydil serine reorganization at the inner leaflet of plasma membrande during cell fusion
PMID:24514900 PBO:0105619 low expressivity
PMID:24521463 PBO:0097692 mild phenotype
PMID:24521463 PBO:0094265 mild expressivity
PMID:24521463 PBO:0093576 low expressivity
PMID:24521463 PBO:0094264 high expressivity (strong phenotype)
PMID:24521463 FYPO:0002060 decreased cell pop is not a child of this term
PMID:24554432 GO:2000784 sufficient to trigger cell shape change when targeted to cell sides by fusion with Cdr2
PMID:24554432 GO:2000114 sufficient to trigger cell shape change when targeted to cell sides by fusion with Cdr2
PMID:24554432 GO:2000114 necessary to trigger cell shape change upon Tea4 targeting to cell sides by fusion with Cdr2
PMID:24554432 GO:0030010 sufficient to trigger cell shape change when targeted to cell sides by fusion with Cdr2; tea1/pom1 double mutant phenotype shows that Tea4 role is independent of Pom1
PMID:24554432 GO:2000784 necessary to trigger cell shape change upon Tea4 targeting to cell sides by fusion with Cdr2
PMID:24569997 PBO:0105209 changed from transcription because mrna measured fig2 (copper excess)
PMID:24569997 PBO:0105204 figur 5B
PMID:24569997 PBO:0105204 figure 5B
PMID:24569997 PBO:0105211 changed from transcription because mrna measured fig2
PMID:24569997 PBO:0025347 Observed at this location during spore maturation by indirect immunofluorescence
PMID:24569997 PBO:0105206 changed from transcription because mrna measured (fig 1)
PMID:24569997 PBO:0105207 changed from transcription because mrna measured (fig 1)
PMID:24569997 PBO:0105208 changed from transcription because mrna measured (fig 1)
PMID:24569997 PBO:0105209 *******during copper excess****** changed from transcription because mrna measured fig2
PMID:24583014 PBO:0105365 Fig. 1B,
PMID:24583014 PBO:0105366 Fig. 1A
PMID:24583014 PBO:0101464 Fig. 1D,E
PMID:24583014 FYPO:0004301 figure S1B
PMID:24583014 FYPO:0000274 Fig. S1B,C
PMID:24583014 PBO:0105367 Fig. 3A,B,E, securin abnormally stabilized during anaphase
PMID:24583014 FYPO:0006646 Fig. 2B,C
PMID:24583014 FYPO:0005684 Fig. 2B,C
PMID:24583014 FYPO:0007403 Fig. 2A, , complex seen here in anaphase although it normally forms in prometaphase and disassembles before anaphase
PMID:24583014 PBO:0105362 Fig. 1A indicating that CDK1 activity remained high
PMID:24583014 PBO:0105363 Fig. 1A
PMID:24583014 PBO:0105364 Fig. 1A
PMID:24586893 PBO:0093563 the extension means that the phenotype has low expressivity (i.e. weak sensitivity)
PMID:24637836 PBO:0093563 sensitivity is weak.
PMID:24637836 GO:0005737 Fluorescence microscopy of Sec13 tagged with GFP at either its N-terminal or C-terminal end.
PMID:24637836 FYPO:0001355 Our strains expressing GFP-tagged nucleoporins were all viable, but four of them (spNup45-GFP, spNup184-GFP, GFP-spRae1, and spNup189n-GFP) showed growth deficiencies
PMID:24637836 PBO:0093579 sensitivity is weak.
PMID:24637836 PBO:0093563 sensitivity is weak
PMID:24637836 PBO:0093563 weak sensitivity
PMID:24637836 PBO:0093579 sensitivity is weak.
PMID:24652833 PBO:0102211 no MF possible
PMID:24652833 GO:0009262 it affects suc22 binding to cdc22. There is no evidence thta it is involved in catabolism and I dont think I can make a MF from it.
PMID:24662054 GO:0140750 binds both DNA and histone. Not sure if the H3 preference is an artefact of in vitro system
PMID:24662054 PBO:0097229 binds both DNA and histone. Not sure if the H3 preference is an artefact of in vitro system
PMID:24663817 PBO:0093616 3D
PMID:24663817 PBO:0100314 C13Y and K56R mutations completely eliminated the phosphorylation of Chk1 in MMS-treated cells (Fig. 3A)
PMID:24663817 PBO:0100314 C13Y and K56R mutations completely eliminated the phosphorylation of Chk1 in MMS-treated cells (Fig. 3A)The slight decrease in Cds1 phosphorylation may be caused indirectly by a minor defect in DNA replication
PMID:24663817 PBO:0100313 C13Y and K56R mutations completely eliminated the phosphorylation of Chk1 in MMS-treated cells (Fig. 3A)
PMID:24663817 PBO:0100313 C13Y and K56R mutations completely eliminated the phosphorylation of Chk1 in MMS-treated cells (Fig. 3A)
PMID:24663817 PBO:0093581 1D
PMID:24663817 PBO:0093581 1D
PMID:24663817 PBO:0093581 1D,Fig. 2B
PMID:24663817 PBO:0093581 1D,Fig. 2B
PMID:24663817 PBO:0093617 1D
PMID:24663817 FYPO:0002061 We found that combinations of the previously reported E368K mutation [47] with K56R or F303S were lethal suggesting a defect in DNA replication.
PMID:24663817 PBO:0093581 1D, Fig. 2B
PMID:24663817 PBO:0100323 (phosphorylated rad9)
PMID:24663817 MOD:00696 affected by rad4
PMID:24663817 PBO:0100318 Fig. 5A and B
PMID:24663817 PBO:0093617 1D, Fig. 2B
PMID:24663817 FYPO:0002061 We found that combinations of the previously reported E368K mutation [47] with K56R or F303S were lethal suggesting a defect in DNA replication.
PMID:24663817 PBO:0100319 3a/b
PMID:24663817 PBO:0100318 C13Y-K56R mutation abolished the interaction with Crb2 (Fig. 5C), not Rad9 (Fig. 5A and B).
PMID:24663817 PBO:0093617 1D,Fig. 2B
PMID:24663817 PBO:0100317 E368K mutation abolished the binding to Rad9 as previously reported [47] (Fig. 5A and B)
PMID:24663817 PBO:0100316 C13Y-K56R mutation abolished the interaction with Crb2 (Fig. 5C), not Rad9 (Fig. 5A and B).
PMID:24663817 PBO:0100315 The C13Y and K56R mutations abolished the scaffolding function of Rad4 required for the activation of Chk1 but not Rad3
PMID:24663817 PBO:0093617 f3
PMID:24663817 PBO:0093617 f3
PMID:24663817 PBO:0093580 3D
PMID:24663817 PBO:0093580 3D
PMID:24663817 PBO:0093616 3D
PMID:24663817 PBO:0093617 1D, Fig. 2B
PMID:24663817 FYPO:0000725 Interestingly, the DC mutant with the deletion of the whole C-terminus between amino acid 498 and 648 was resistant to HU and MMS almost like the wild type cells (Fig. 1D and 2B). The only difference we could readily find for the DC mutant was that the protein level was higher than in the wild type cells (Fig. 2C), suggesting that the C-terminus may not contain a robust AAD (see below).
PMID:24663817 PBO:0100321 3a/b
PMID:24663817 PBO:0100317 Consistent with the previous report [58], the interaction between Rad9 and Rad4 was dependent on Rad9 phosphorylation because the phosphorylation site mutant Rad9-T412A could not pull-down Rad4 (Fig. 5A, first lane on the left) and the interaction between Rad9 and Rad4 was sensitive to l-phosphatase treatment (Fig. S5A).
PMID:24663817 PBO:0100320 3a/b. cds1-T11
PMID:24696293 FYPO:0000087 supp fig
PMID:24710126 FYPO:0003410 convert to double mutant (cnp1 overexpression)
PMID:24710126 FYPO:0005071 central core
PMID:24710126 FYPO:0005071 central core
PMID:24713849 GO:1990477 Observed in cells undergoing vegetative growth.
PMID:24713849 GO:1990477 Observed in cells undergoing vegetative growth.
PMID:24713849 GO:1990477 Observed in cells undergoing vegetative growth.
PMID:24713849 PBO:0094860 mei4 ssm4 crs1 rec8 spo5
PMID:24713849 PBO:0095143 mei4 ssm4 crs1 rec8 spo5
PMID:24713849 PBO:0094861 mei4 ssm4 crs1 rec8 spo5
PMID:24713849 PBO:0094862 mei4 ssm4 crs1 rec8 spo5
PMID:24713849 PBO:0094859 mei4 ssm4 crs1 rec8 spo5
PMID:24713849 PBO:0101249 "[Term] id: FYPO_EXT:0000003 name: low def: ""small fraction of cells (penetrance) or weak phenotype (expressivity)"" [PomBase:curators]"
PMID:24713849 PBO:0101245 mei4 ssm4 crs1 rec8 spo5
PMID:24713849 PBO:0095161 mei4 ssm4 crs1 rec8 spo5
PMID:24713849 PBO:0101244 mei4 ssm4 crs1 rec8 spo5
PMID:24713849 PBO:0101243 mei4 ssm4 crs1 rec8 spo5
PMID:24713849 PBO:0095160 mei4 ssm4 crs1 rec8 spo5
PMID:24713849 PBO:0094862 mei4 ssm4 crs1 rec8 spo5
PMID:24713849 PBO:0094861 mei4 ssm4 crs1 rec8 spo5
PMID:24713849 PBO:0095143 mei4 ssm4 crs1 rec8 spo5
PMID:24713849 GO:1990477 Observed in cells undergoing vegetative growth.
PMID:24713849 PBO:0094860 mei4 ssm4 crs1 rec8 spo5
PMID:24713849 GO:1990477 Observed in cells undergoing vegetative growth.
PMID:24713849 GO:1990477 Observed in cells undergoing vegetative growth.
PMID:24713849 PBO:0094859 mei4 ssm4 crs1 rec8 spo5
PMID:24741065 PBO:0097925 tor2 phosphorylates mei2. Phosphorylated mei2 is ubiquitylated which targets it for degradation via the proteasome.
PMID:24741065 PBO:0097921 phosphorylation of mei2 targets it for degradation via the proteasome
PMID:24755092 GO:0010494 SPAC12G12.09-mCherry localizes to stress granules
PMID:24755092 GO:0010494 Exo2-GFP localizes to stress granules
PMID:24758716 GO:0019172 qualifier=major
PMID:24758716 GO:0019172 qualifier=major
PMID:24758716 GO:0019172 qualifier=minor Hsp3106 (synonym: spDJ-1) has a lower in vitro glyoxalase III activity than Hsp3101 and Hsp3102
PMID:24768994 GO:0005635 Figure 2A
PMID:24768994 GO:0005515 Figure 2B
PMID:24768994 GO:0005634 Figure 3
PMID:24768994 GO:0005737 Figure 3
PMID:24768994 GO:0005515 Figure 2B
PMID:24768994 FYPO:0001407 Figure 5
PMID:24768994 FYPO:0000684 Figure 5
PMID:24768994 FYPO:0000684 Figure 5
PMID:24768994 PBO:0104274 Figure 2C
PMID:24774534 FYPO:0002060 fig6
PMID:24774534 PBO:0100347 add other complex members
PMID:24774534 FYPO:0002060 fig6
PMID:24774534 FYPO:0002061 fig6
PMID:24774534 FYPO:0002060 fig6
PMID:24774534 FYPO:0002060 fig6
PMID:24774534 FYPO:0002060 fig6
PMID:24774534 FYPO:0002060 fig6
PMID:24774534 FYPO:0002061 fig6
PMID:24774534 FYPO:0002060 fig6
PMID:24774534 FYPO:0002060 fig6
PMID:24774534 FYPO:0002060 fig6
PMID:24787148 PBO:0103362 ubiquitin monmomer inhibits sst2
PMID:24790093 PBO:0108213 Yeast two hybrid
PMID:24790095 GO:0110085 exists_during( metaphase? anaphase A????)
PMID:24790095 PBO:0024047 mitotic interphase
PMID:24790095 GO:0110085 exists_during( metaphase? anaphase A????)
PMID:24798735 PBO:0019539 "this annotation extension means ""small fraction of cells"""
PMID:24798735 PBO:0020891 "this annotation extension means ""small fraction of cells"""
PMID:24798735 PBO:0023418 "this annotation extension means ""small fraction of cells"""
PMID:24798735 PBO:0019669 "this annotation extension means ""small fraction of cells"""
PMID:24806815 PBO:0111551 Mdb1 binds to Hta1 phosphorylated on Ser-129. PR:000027566 = H2A phosphorylated on S129
PMID:24806815 GO:0035861 This localisation requires phosphorylated histone H2A.
PMID:24815688 FYPO:0003743 "transferres from term suggestion to allow approval decreased growth under low-glucose conditions Definition: ""decreased growth under low-glucose conditions"" is an ""decreased cell population growth"" that occurs specifically on media supplied with a lower concentration of glucose than regular media. ditto all the others"
PMID:24818994 PBO:0099111 figure 1 A
PMID:24818994 GO:0070139 Figure 1 A
PMID:24818994 PBO:0101445 Figures 3 and 6
PMID:24818994 PBO:0101445 Figures 3 and 6
PMID:24818994 GO:0005737 Figures 3 and 6
PMID:24818994 GO:0005634 Figures 3 and 6
PMID:24818994 PBO:0101444 Figure 5A, +
PMID:24818994 GO:0005737 minor
PMID:24818994 FYPO:0002061 figure 1D
PMID:24818994 FYPO:0000104 figure 1D
PMID:24818994 PBO:0101443 Figure 1 A
PMID:24818994 GO:0016929 Figure 1 A
PMID:24818994 FYPO:0000088 figure 1D
PMID:24831008 PBO:0099224 fig1
PMID:24831008 PBO:0099223 fig4
PMID:24831008 PBO:0099223 fig4
PMID:24831008 PBO:0099222 Fig 2
PMID:24831008 PBO:0099222 Fig 2
PMID:24831008 PBO:0099222 Fig 2
PMID:24831008 PBO:0099222 Fig 2
PMID:24831008 PBO:0099227 Figure 7 - the goal of the experiments in this figure is to map the minimal region of loz1 that is required for zinc-responsiveness by generating gene fusion with MtfA, a transcription factor from Aspergillus nidulans that contains a double zinc finger domain with high similarity to Loz1 from S. pombe, but contains no other similarity. When expressed in S. pombe this gene fusion was regulated by zinc, suggesting that the region necessary for zinc responsiveness in S. pombe, maps to the zinc finger domains and an upstream accessory domain
PMID:24831008 PBO:0099231 Figure 7 - the goal of the experiments in this figure is to map the minimal region of loz1 that is required for zinc-responsiveness by generating gene fusion with MtfA, a transcription factor from Aspergillus nidulans that contains a double zinc finger domain with high similarity to Loz1 from S. pombe, but contains no other similarity. When expressed in S. pombe this gene fusion was regulated by zinc, suggesting that the region necessary for zinc responsiveness in S. pombe, maps to the zinc finger domains
PMID:24831008 PBO:0099228 RNA transcript expression is increased during the stress response to zinc ions, but the increase is less than the transcript levels seen with full de-repression
PMID:24831008 PBO:0099224 Figure 7 - the goal of the experiments in this figure is to map the minimal region of loz1 that is required for zinc-responsiveness by generating gene fusion with MtfA, a transcription factor from Aspergillus nidulans that contains a double zinc finger domain with high similarity to Loz1 from S. pombe, but contains no other similarity. When expressed in S. pombe this gene fusion was regulated by zinc, suggesting that the region necessary for zinc responsiveness in S. pombe, maps to the zinc finger domains and an upstream accessory domain
PMID:24831008 PBO:0099224 fig1
PMID:24831008 PBO:0099228 RNA transcript expression is increased during the stress response to zinc ions, but the increase is less than the transcript levels seen with full de-repression
PMID:24831008 PBO:0099228 RNA transcript expression is increased during the stress response to zinc ions, but the increase is less than the transcript levels seen with full de-repression
PMID:24831008 PBO:0099226 fig2
PMID:24831008 PBO:0099225 fig 4g
PMID:24847916 FYPO:0003928 The phenotype is assessed by the high-throughput sequencing.
PMID:24876389 PBO:0096271 ubiquitinated probably at K263.
PMID:24876389 PBO:0096283 have guessed at deleted residues
PMID:24876389 PBO:0096275 abolished internalization
PMID:24876389 PBO:0096275 abolished internalization
PMID:24876389 PBO:0096275 abolished internalization
PMID:24876389 PBO:0096275 internalization abolished
PMID:24876389 PBO:0096272 SPBC18H10.20c protein appears to have a function as arrestin-related trafficking adaptor, which is involved in ubiquitination of membrane transporters and subcellular localization of them. val, I changed the 'with' field to pub1, but I want to also add *****
PMID:24920274 PBO:0104604 "the def includes ""maintenance of lcoalization WITHIN nucleus"" so it fits the def, but maybe the term looks weird"
PMID:24920274 PBO:0104608 at sme2 locus (one of several exosome foci in nucleus during vegetative growth)
PMID:24920274 PBO:0104608 at sme2 locus (one of several exosome foci in nucleus during vegetative growth)
PMID:24920274 PBO:0104596 figS1
PMID:24920274 PBO:0104597 figS1
PMID:24920274 PBO:0104594 figS1
PMID:24920274 PBO:0104595 figS1
PMID:24920274 FYPO:0000583 figS1
PMID:24920274 FYPO:0000583 figS1
PMID:24920274 PBO:0104600 figS1
PMID:24920274 PBO:0095590 figS1
PMID:24920274 PBO:0104597 figS1
PMID:24920274 PBO:0104602 fig3
PMID:24920274 PBO:0104596 figS1
PMID:24920274 PBO:0104603 fig3
PMID:24920274 PBO:0104604 "the def includes ""maintenance of lcoalization WITHIN nucleus"" so it fits the def, but maybe the term looks weird"
PMID:24920274 PBO:0094908 abnormal RNA localization to chromatin
PMID:24920274 PBO:0104599 figS1
PMID:24920274 PBO:0104594 figS1
PMID:24920274 PBO:0104603 fig3
PMID:24920274 PBO:0104595 figS1
PMID:24920274 PBO:0104602 fig3
PMID:24920274 PBO:0104598 figS1
PMID:24920823 PBO:0019669 low penetrance
PMID:24920823 PBO:0019671 anaphase B
PMID:24920823 PBO:0094078 medium penetrance
PMID:24920823 PBO:0093476 S326, T429, S499: added by cyclin-dependent kinase (Cdk1)
PMID:24920823 PBO:0093475 S248, T412, T502, S533: added by cyclin-dependent kinase (Cdk1)
PMID:24920823 PBO:0093475 S248, T412, T502, S533: added by cyclin-dependent kinase (Cdk1)
PMID:24920823 PBO:0093475 S248, T412, T502, S533: added by cyclin-dependent kinase (Cdk1)
PMID:24920823 FYPO:0004562 results from collapse of actomyosin contractile ring
PMID:24920823 PBO:0093476 S326, T429, S499: added by cyclin-dependent kinase (Cdk1)
PMID:24920823 PBO:0093475 S248, T412, T502, S533: added by cyclin-dependent kinase (Cdk1)
PMID:24920823 GO:0031031 Term name: supports establishment of SIN asymmetry Definition: characterized by asymmetric localization of the SIN initiator kinase Cdc7 in anaphase
PMID:24920823 PBO:0101805 affecting Cdc7
PMID:24920823 PBO:0103495 targets Byr4 at S248A, S326A, T412A, T429A, S499A, T502A, S533A, results in Byr4 removal from metaphase spindle pole bodies
PMID:24920823 PBO:0103496 Cdk1-dependent, Cdk1 non-phosphorylatable Byr4 localizes to one or both SPBs in >90% of metaphase cells
PMID:24925530 FYPO:0003107 starts with longer telomeres than wild type, which then shorten
PMID:24928430 FYPO:0006103 Fig. 3 - minor rescue
PMID:24928430 FYPO:0008008 Fig. 1
PMID:24928430 FYPO:0009000 Fig. 1
PMID:24928430 FYPO:0000899 Fig. 2
PMID:24928430 FYPO:0006103 Fig. 3
PMID:24928430 FYPO:0009001 Fig. 3
PMID:24928430 FYPO:0006103 Fig. 3 - minor rescue
PMID:24928430 FYPO:0009001 Fig. 3 - minor rescue
PMID:24928430 FYPO:0009001 Fig. 3 - minor rescue
PMID:24928430 FYPO:0006103 Fig. 4 - minor rescue
PMID:24928430 FYPO:0006103 Fig. 4 - minor rescue
PMID:24928510 PBO:0106582 protein phosphorylation assayed in vitro
PMID:24928510 PBO:0096003 Phosphorylation assayed in vitro
PMID:24928510 PBO:0096003 Phosphorylation assayed in vitro
PMID:24928510 PBO:0096003 Phosphorylation assayed in vitro
PMID:24928510 PBO:0106561 Protein phosphorylation assayed in vitro
PMID:24928510 PBO:0106561 Protein phosphorylation assayed in vitro
PMID:24928510 PBO:0106563 protein phosphorylation assayed in vitro
PMID:24928510 PBO:0096003 Phosphorylation assayed in vitro
PMID:24928510 PBO:0106563 protein phosphorylation assayed in vitro
PMID:24928510 PBO:0106579 protein phosphorylation assayed in vitro
PMID:24928510 PBO:0106579 protein phosphorylation assayed in vitro
PMID:24928510 PBO:0096003 Phosphorylation assayed in vitro
PMID:24928510 PBO:0096003 protein phosphorylation assayed in vitro
PMID:24928510 PBO:0096003 protein phosphorylation assayed in vitro
PMID:24928510 PBO:0101351 Phosphorylation assayed in vitro
PMID:24928510 PBO:0106580 protein phosphorylation assayed in vitro
PMID:24928510 PBO:0106579 protein phosphorylation assayed in vitro
PMID:24936793 GO:0071218 also inferrable (IC) from GO:0051787
PMID:24937146 PBO:0098527 affecting Alp7
PMID:24937146 PBO:0098529 affecting Pcp1 and Alp4
PMID:24937146 PBO:0094143 affecting Pcp1 and Alp4
PMID:24939935 PBO:0093557 Fig. 1D
PMID:24939935 PBO:0093561 Fig. 1D
PMID:24939935 PBO:0093558 Fig. 1D
PMID:24939935 FYPO:0008182 Fig. 4E
PMID:24939935 FYPO:0002061 Fig. 4D
PMID:24939935 FYPO:0002061 Fig. 4D
PMID:24939935 FYPO:0002061 Fig. 4D
PMID:24939935 PBO:0093560 Fig. 4D
PMID:24939935 FYPO:0004481 Fig. 4D
PMID:24939935 PBO:0093561 Fig. 4D
PMID:24939935 PBO:0093557 Fig. 4D
PMID:24939935 FYPO:0008181 Fig. 1G
PMID:24939935 FYPO:0008181 Fig. 1G
PMID:24939935 FYPO:0008181 Fig. 1G
PMID:24939935 FYPO:0008181 Fig. 1G
PMID:24939935 PBO:0093559 Fig. 1D
PMID:24939935 PBO:0111611 We report crystal structures of Pce1 bound to Pol2 CTD and Spt5 CTD ligands. Key findings are that (1) the CTDs of Pol2 and Spt5 interact with completely distinct sites on the NTase and OB domains of the fission yeast GTase, respectively, and (2) whereas the interface of GTase with the Pol2 CTD is dependent on Ser5 phosphorylation, GTase binding to Spt5 CTD is antagonized by Thr1 phosphor- ylation.
PMID:24939935 PBO:0111611 We report crystal structures of Pce1 bound to Pol2 CTD and Spt5 CTD ligands. Key findings are that (1) the CTDs of Pol2 and Spt5 interact with completely distinct sites on the NTase and OB domains of the fission yeast GTase, respectively, and (2) whereas the interface of GTase with the Pol2 CTD is dependent on Ser5 phosphorylation, GTase binding to Spt5 CTD is antagonized by Thr1 phosphor- ylation.
PMID:24939935 FYPO:0008181 Fig. 1G
PMID:24939935 FYPO:0008181 Fig. 1G
PMID:24939935 FYPO:0002061 Fig. 1D
PMID:24939935 FYPO:0002061 Fig. 1D
PMID:24939935 FYPO:0002061 Fig. 1D
PMID:24939935 PBO:0093556 Fig. 1D
PMID:24939935 PBO:0093557 Fig. 1D
PMID:24939935 PBO:0093558 Fig. 1D
PMID:24939935 PBO:0093561 Fig. 1D
PMID:24939935 PBO:0093558 Fig. 1D
PMID:24945319 GO:0005847 I don't really know how to do this: I would like to say that SPAC824.04, Ppn1 and Dis2 are part of a protein module associated with the CPF. We have named this module the DPS module. Lack of this module does not affect the formation of the core CPF (all other CPF sub-units remain associated as a complex).
PMID:24945319 GO:0005847 I don't really know how to do this: I would like to say that SPAC824.04, Ppn1 and Dis2 are part of a protein module associated with the CPF. We have named this module the DPS module. Lack of this module does not affect the formation of the core CPF (all other CPF sub-units remain associated as a complex).
PMID:24945319 GO:0005847 I don't really know how to do this: I would like to say that SPAC824.04, Ppn1 and Dis2 are part of a protein module associated with the CPF. We have named this module the DPS module. Lack of this module does not affect the formation of the core CPF (all other CPF sub-units remain associated as a complex).
PMID:24947517 FYPO:0002061 Fig. 6A
PMID:24947517 PBO:0035611 Fig. 3A
PMID:24947517 GO:0032153 Fig. 5A
PMID:24947517 FYPO:0001357 Fig. 1B
PMID:24947517 FYPO:0001357 Fig. 1B
PMID:24947517 FYPO:0001315 Fig. 1B
PMID:24947517 FYPO:0000650 Fig. 1C
PMID:24947517 FYPO:0005628 Fig 1 D (decreased rate of cell separation)
PMID:24947517 FYPO:0000673 Fig 1 D
PMID:24947517 PBO:0098140 Fig 1 E
PMID:24947517 PBO:0098140 Fig 1 E
PMID:24947517 PBO:0098141 fig 1 F
PMID:24947517 PBO:0097059 Fig 1 F
PMID:24947517 PBO:0035615 Fig 1 F
PMID:24947517 PBO:0019669 fig 1 F
PMID:24947517 PBO:0098142 Figure 3 C
PMID:24947517 PBO:0098142 Figure 3 C
PMID:24947517 PBO:0098143 Data not shown
PMID:24947517 PBO:0098144 Data not shown
PMID:24947517 PBO:0098145 Fig. 3F
PMID:24947517 PBO:0098145 Fig. 3F
PMID:24947517 PBO:0098145 Fig. 3F
PMID:24947517 PBO:0098146 Data not shown
PMID:24947517 PBO:0098147 Data not shown
PMID:24947517 GO:0016192 (Fig. 6D)
PMID:24947517 PBO:0098155 Fig 6 D.
PMID:24947517 PBO:0095634 Fig 6 C, D
PMID:24947517 FYPO:0002061 Fig 6 C.
PMID:24947517 PBO:0098154 Fig 6 B.
PMID:24947517 PBO:0098153 Fig 6 B.
PMID:24947517 PBO:0098152 Fig 6 B.
PMID:24947517 FYPO:0002060 Fig 6 B.
PMID:24947517 FYPO:0002060 Fig 6 B.
PMID:24947517 FYPO:0002061 Fig 6 B.
PMID:24947517 FYPO:0002061 Fig. 6A
PMID:24947517 PBO:0098151 Fig 5 B
PMID:24947517 PBO:0098150 Fig 5 A
PMID:24947517 GO:0005886 Fig. 5A
PMID:24947517 GO:0005515 Fig 4 C,D,E
PMID:24947517 PBO:0098149 Fig. 4A
PMID:24947517 PBO:0092529 Fig. 4A
PMID:24947517 PBO:0098148 Fig 4 A
PMID:24947517 PBO:0098148 Fig 4 A
PMID:24947517 PBO:0035620 Fig 4 A
PMID:24947517 PBO:0098148 Fig 4 A
PMID:24954052 PBO:0111559 PR:000037081= ID for acetylated form of cdc8
PMID:24954052 PBO:0111560 GO:0051286 = cell tip PR:000037082 = ID for unacetylated form of cdc8
PMID:24954111 PBO:0102133 fig1 In wild-type cells, monopolar or nonpolar spindles were not observed (Fig. 4C).
PMID:24954111 PBO:0102132 fig1
PMID:24954111 FYPO:0000678 Fig 6 A,B even in the presence of the bipolar spindle
PMID:24954111 FYPO:0006366 never observed 54/54
PMID:24954111 FYPO:0006366 never observed 37/37
PMID:24954111 PBO:0102137 bipolar/spindle defects caused by the loss of telomere clustering were rescued by stopping nuclear movement.
PMID:24954111 PBO:0102137 bipolar spindle defects caused by the loss of telomere clustering were rescued by stopping nuclear movement.
PMID:24954111 PBO:0102138 spindle defects caused by the loss of telomere clustering were rescued by stopping nuclear movement.
PMID:24954111 PBO:0102131 fig1
PMID:24957674 GO:0006325 xap5 genetically interacts with pht1 to repress antisense transcripts. In the ∆xap5∆pht1 double mutants the level of antisense transcription is exacerbated as observed using RNA-seq. Selected loci also showed antisense RNA production in histone deacetylase (HDACs) gene mutants.
PMID:24957674 PBO:0100330 SO:0000141 = The sequence of DNA located either at the end of the transcript that causes RNA polymerase to terminate transcription. SO:0000186 - LTR SO:0000101 - transposable element
PMID:24957674 PBO:0098752 SO:0000141 = The sequence of DNA located either at the end of the transcript that causes RNA polymerase to terminate transcription. SO:0000186 - LTR SO:0000101 - transposable element
PMID:24957674 PBO:0100331 SO:0000141 = The sequence of DNA located either at the end of the transcript that causes RNA polymerase to terminate transcription. SO:0000186 - LTR SO:0000101 - transposable element
PMID:24963130 PBO:0018346 GO:0000087 mitotic M-phase
PMID:24963130 PBO:0032878 should this move down to lobate? http://www.pombase.org/spombe/related/FYPO:0002005
PMID:24963130 PBO:0020179 GO:0000236 mitotic prometaphase
PMID:24963130 PBO:0099264 (GO:0000279) = mitotic M-phase
PMID:24963130 FYPO:0002636 2 sub populations spindle elongation delayed during anaphase A spindle elongation delayed during anaphase B
PMID:24997422 FYPO:0001164 ). Interestingly, growth of transformants over- expressing truncated Fxn1 with a disrupted mitochondrial localization sequence (Fxn1Δ2–11) is similar to pREP3X at all concentrations of thi- amine (Fig. 1A). These observations demonstrate that the growth inhi- bition resulting from Fxn1 overexpression is related to mitochondrial levels or improper processing of Fxn1.
PMID:25002536 PBO:0097280 LTR and ncRNA
PMID:25002536 PBO:0097281 LTR and ncRNA
PMID:25002536 GO:0000785 occurs at LTR and ncRNA
PMID:25002536 GO:0000785 occurs at LTR and ncRNA
PMID:25002536 PBO:0097280 occurs at LTR and ncRNA
PMID:25002536 PBO:0097281 occurs at LTR and ncRNA
PMID:25009287 GO:1990463 Skb1 and Slf1 (SPAC821.03C) mutually depend to form node-like structures on the plasma membrane.
PMID:25009287 GO:1990463 Skb1 and Slf1 (SPAC821.03C) mutually depend to form node-like structures on the plasma membrane.
PMID:25015293 PBO:0102768 same as spt20delta alone
PMID:25015293 PBO:0102774 multinucleate inferred from DNA content
PMID:25015293 PBO:0102768 same as spt20delta alone
PMID:25015293 PBO:0102768 same as spt20delta alone
PMID:25015293 GO:0005737 punctate
PMID:25015293 PBO:0102762 multinucleate inferred from DNA content
PMID:25015293 PBO:0102762 multinucleate inferred from DNA content
PMID:25015293 PBO:0102774 multinucleate inferred from DNA content
PMID:25015293 PBO:0102762 multinucleate inferred from DNA content
PMID:25040903 FYPO:0000024 Figure S1C
PMID:25040903 FYPO:0001492 Figure S1C
PMID:25040903 PBO:0099499 Figure S1E
PMID:25040903 PBO:0099500 Figure S1E
PMID:25057016 PBO:0109497 Fig. 4 (BiFC)
PMID:25057016 PBO:0092631 Good evidence for this is the colocalisation with cnp3 in Fig. 3A in the csi1D background, where alp7 does not go to the spindle, or nda3 mutant where the spindle does not form, but alp7 still goes to the kinetochore, as seen by cnp3
PMID:25057016 PBO:0109492 Thorough experiments throughout using both full deletions as well as phospho mutants. Direct physical interaction is confirmed by Y2H
PMID:25057016 FYPO:0003840 Fig. 1
PMID:25057016 PBO:0093565 Fig. 1
PMID:25057016 PBO:0093565 Fig. 1
PMID:25057016 FYPO:0003840 Fig. 1
PMID:25057016 FYPO:0003566 Fig. 2
PMID:25057016 FYPO:0003566 Fig. 2
PMID:25057016 PBO:0109493 Fig. S1D
PMID:25057016 PBO:0109494 Fig. 3
PMID:25057016 PBO:0109495 Fig. 3
PMID:25057016 PBO:0109496 Fig. 3
PMID:25057016 PBO:0109497 Fig. 4
PMID:25057016 PBO:0109497 Fig. 4
PMID:25057016 PBO:0109497 Fig. 4 (BiFC)
PMID:25057016 PBO:0109494 Fig. 4
PMID:25057016 FYPO:0009114 Fig. 4
PMID:25057016 FYPO:0003566 Fig. 4
PMID:25057016 FYPO:0003840 Fig. 4
PMID:25057016 PBO:0109495 Fig. 4
PMID:25057016 PBO:0109494 Fig. 4
PMID:25057016 PBO:0109495 Fig. 4
PMID:25057016 FYPO:0009114 Fig. 4
PMID:25057016 FYPO:0003566 Fig. 4
PMID:25057016 FYPO:0003840 Fig. 4
PMID:25057016 PBO:0109498 Fig. S5D
PMID:25057016 FYPO:0000228 Fig. 6
PMID:25057016 FYPO:0000228 Fig. 6
PMID:25057016 FYPO:0000228 Fig. 6
PMID:25066056 GO:0045547 rer2 was shown to be indispensable subunit of dehydrodolichyl diphosphate synthase. It is not active cis-prenyltransferase by itself but it forms active enzyme with nus1
PMID:25066056 GO:0045547 nus1 was shown to be indispensable subunit of dehydrodolichyl diphosphate synthase. It is not active cis-prenyltransferase by itself but it forms active enzyme with rer2 (SPAC4D7.04c)
PMID:25066056 FYPO:0002061 The heterozygous deletion h+/ h+ strains with exchanged one copy of SPBC2A9.06c ORFs for kanMX4 cassette (Genome-wide Deletion Mutant Library (Bioneer) was able to produce viable spores only when transformed with plasmid expressing Giardia lamblia cis-prenyltransferase but not carrying empty vector.
PMID:25081204 GO:0106057 prz1 is the pombe equivalent to NFAT (functional equivalent rather than orholog)
PMID:25081204 GO:0106057 prz1 is the pombe equivalent to NFAT (functional equivalent rather than orholog)
PMID:25081204 PBO:0097246 cmk1 seems to phosphorylate prz1 which makes prz1 cytoplasmic. During response to calcium, calcineurin dephosphorylates prz1 and it goes to the nucleus.
PMID:25081204 FYPO:0001122 the pop grows more slowly but I guess they are viable en large
PMID:25103238 PBO:0022383 large fraction of cells = annotation_extension=has_penetrance(FYPO_EXT:0000001)
PMID:25103238 GO:0140480 Failure of NE fenestration during mitosis in the double tts1del cut1-6 mutant
PMID:25106870 GO:0004523 fig5
PMID:25106870 GO:0003887 fig 1
PMID:25106870 GO:0070716 RER should probably be a child of this
PMID:25106870 GO:0042276 Tolerance of the 8oxoguanine lesion during DNA gap-filling inserting the ribonucleotide ATP. This acitivity can be coupled to the non-homologous end joining (NHEJ) of double strand breaks (DSBs). changed from dna repair to translesion synthesis. /AL
PMID:25106870 GO:1990516 Incision of ribonucleotides paired to 8oxoguanine in the DNA
PMID:25109267 GO:1990748 Ricinoleic acid, RA moieties from phospholipids
PMID:25122751 FYPO:0003908 At stress response genes
PMID:25195688 GO:1990536 transmembrane import into Golgi lumen
PMID:25195688 GO:1990536 transmembrane import into Golgi lumen
PMID:25203555 PBO:0100996 regulator of structure-specific DNA nuclease
PMID:25203555 GO:0005515 not sure
PMID:25204792 PBO:0107951 defect in sexual development in response to zinc or iron limitation
PMID:25204792 PBO:0107954 defect in sexual development in response to zinc or iron limitation
PMID:25245948 PBO:0102503 cDNA; no introns
PMID:25245948 PBO:0102503 cDNA; no introns
PMID:25245948 PBO:0094688 cDNA; no introns
PMID:25245948 FYPO:0003555 cDNA; no introns
PMID:25245948 PBO:0102504 cDNA; no introns
PMID:25245948 PBO:0102504 cDNA; no introns
PMID:25254656 FYPO:0005485 figure 3C
PMID:25254656 FYPO:0005799 igure 3B Figure 3C
PMID:25254656 FYPO:0005682 Figure 4A)
PMID:25254656 FYPO:0006893 figure 3C the N erminal domain has a dominent -ve effect in in vitro assay (not expression should ne n/a)
PMID:25254656 FYPO:0003328 Figure S15
PMID:25254656 FYPO:0006892 figure 3C
PMID:25254656 GO:0052843 in vitro Figure S1A, right pane
PMID:25254656 GO:0000828 in vitro Figure S1A, right pane
PMID:25254656 PBO:0096502 Figure 4E
PMID:25254656 PBO:0096501 Figure 4E
PMID:25254656 FYPO:0003328 Figure 3A
PMID:25254656 FYPO:0000091 Figure S2A
PMID:25313826 GO:1990426 the CAF-1 complex promotes Replication-coupled homologous recombination at blocked replication forks.
PMID:25313826 GO:1990426 the CAF-1 complex promotes Replication-coupled homologous recombination at blocked replication forks.
PMID:25313826 GO:1990426 the CAF-1 complex promotes Replication-coupled homologous recombination at blocked replication forks.
PMID:25318672 FYPO:0001355 permissive temperature for bbl1-9
PMID:25318672 FYPO:0000674 Mutant cells grow normally in liquid minimal medium supplemented with choline.
PMID:25318672 FYPO:0006934 Determined by thin layer chromatography (TLC)
PMID:25318672 PBO:0095685 restrictive temperature for bbl1-9
PMID:25318672 FYPO:0002061 restrictive temperature for bbl1-9
PMID:25318672 PBO:0096383 Determined by thin layer chromatography (TLC)
PMID:25318672 FYPO:0000674 Mutant cells grow normally in liquid minimal medium supplemented with ethanolamine.
PMID:25318672 FYPO:0006934 Determined by thin layer chromatography (TLC)
PMID:25318672 FYPO:0006934 Determined by thin layer chromatography (TLC)
PMID:25318672 FYPO:0001357 restrictive temperature for bbl1-9
PMID:25318672 PBO:0096380 At the restrictive temperature of 36C, cells accumulate very large lipid droplets surrounded by the endoplasmic reticulum. These lipid droplets arise from persistent growth rather than fusion.
PMID:25318672 PBO:0095634 Slow population growth rate can be rescued by supplementing the minimal medium with choline or ethanolamine, the precursors required for phospholipid biosynthesis through the de novo Kennedy pathway
PMID:25318672 PBO:0096379 At high temperature (36C), the mutant protein appeared to bind PA nearly as well as the wild-type enzyme but exhibited a strongly decreased rate of catalysis.
PMID:25318672 FYPO:0000674 Mutant cells grow normally in liquid rich medium
PMID:25318672 PBO:0096381 The endoplasmic reticulum is wrapped around the abnormally large lipid droplets
PMID:25330395 FYPO:0003107 Tpz1-L439R,L445R disrupts interaction with Ccq1 but retain interactions with Pot1 and Poz1 based on co-IP experiments.
PMID:25330395 FYPO:0003107 Tpz1-L449R disrupts interaction with Ccq1 but retain interactions with Pot1 and Poz1 based on co-IP experiments. In combination with poz1 deletion, telomeres become unprotected and cells survive by circularizing chromosomes. Telomerase cannot be recruited to telomeres since Rad3/Tel1-dependent phosphorylation of Ccq1 Thr93, essential for promoting Ccq1-Est1 interaction and telomerase recruitment, is eliminated by tpz1-L449R.
PMID:25330395 FYPO:0002019 Tpz1-[1-485] disrupts interaction with Poz1 but retain interactions with Pot1 and Ccq1 based on co-IP experiments. In combination with ccq1 deletion, telomeres become unprotected and cells survive by circularizing chromosomes. Telomerase recruitment to telomeres is increased since Rad3/Tel1-dependent phosphorylation of Ccq1 Thr93, essential for promoting Ccq1-Est1 interaction and telomerase recruitment, is increased in tpz1-[1-485] cells.
PMID:25330395 FYPO:0002019 Tpz1-W498R,I501R disrupts interaction with Poz1 but retain interactions with Pot1 and Ccq1 based on co-IP experiments. In combination with ccq1 deletion, telomeres become unprotected and cells survive by circularizing chromosomes. Telomerase recruitment to telomeres is increased since Rad3/Tel1-dependent phosphorylation of Ccq1 Thr93, essential for promoting Ccq1-Est1 interaction and telomerase recruitment, is increased in tpz1-W498R,I501R cells.
PMID:25332400 PBO:0092711 Importantly,CK2-mediated phosphorylation had a similar effect on the nucleosome-binding specificities of fly HP1a and S.pombe Swi6. (Figure 6A)
PMID:25348260 PBO:0110012 Fig. 3
PMID:25348260 PBO:0110012 Fig. 3
PMID:25348260 PBO:0110015 Fig. 3
PMID:25348260 PBO:0110015 Fig. 3
PMID:25348260 PBO:0110014 Fig. 3
PMID:25348260 PBO:0110014 Fig. 3
PMID:25348260 PBO:0110013 Fig. 3
PMID:25348260 PBO:0110013 Fig. 3
PMID:25348260 PBO:0110012 Fig. 3
PMID:25375240 PBO:0095416 figure 5E
PMID:25375240 PBO:0095418 Figure 7D
PMID:25375240 FYPO:0001270 Figure 4G
PMID:25375240 FYPO:0004396 Tracking of the inter-SPB distance indicated that the kinetics of spindle elongation in the kis1-1 mad2D double mutant was ameliorated compared with the kis1-1 single mutant (Figure S9).
PMID:25375240 PBO:0095421 indicated by increased mad2 on unattached kinetochores
PMID:25375240 FYPO:0002060 Figure 7D
PMID:25378562 FYPO:0000116 Sensitive to 3 mM ZnCl2. Suppressed by overexpression of budding yeast VAM7.
PMID:25378562 GO:0006896 Vsl1p is a partner of Pep12p, and mainly functions on the prevacuolar and vacuolar membrane.
PMID:25378562 GO:0006896 Vsl1p is a partner of Pep12p, and mainly functions on the prevacuolar and vacuolar membrane.
PMID:25378562 FYPO:0001423 mutants defective in vacuolar sorting do not deliver SpCPY to the 185 vacuole but rather to the outside of the cells.
PMID:25378562 FYPO:0001945 mutants defective in vacuolar sorting do not deliver SpCPY to the 185 vacuole but rather to the outside of the cells.
PMID:25378562 FYPO:0000116 Sensitive to 3 mM ZnCl2
PMID:25392932 PBO:0098562 SO:0001272 = tRNA gene
PMID:25392932 GO:0006386 Our data only demonstrate that this true for RNA Polymerase III // MOVED UP TO 'REGULATION' FROM NEG REG BASED ON NEW PUBLICATION
PMID:25392932 PBO:0098562 SO:0001272 = tRNA gene
PMID:25402480 PBO:0104437 "SO:0000407 = 18s rRNA, the genes are the 18s genes of the ""correct length"" so I guess we want them in there if we want to be able to make the ""connections"" from the info in the database? Though I guess this regions isnt properly sequenced.."
PMID:25402480 PBO:0104436 "SO:0000407 = 18s rRNA, the genes are the 18s genes of the ""correct length"" so I guess we want them in there if we want to be able to make the ""connections"" from the info in the database? Though I guess this regions isnt properly sequenced.."
PMID:25402480 PBO:0104435 "SO:0000407 = 18s rRNA, the genes are the 18s genes of the ""correct length"" so I guess we want them in there if we want to be able to make the ""connections"" from the info in the database? Though I guess this regions isnt properly sequenced.."
PMID:25402480 FYPO:0002061 "They couldn't make the knockout in haploid, and diploid inviable, hence inferring inviable vegetative rather than more general ""inviable cell pop"" (or inviable spore pop)"
PMID:25402480 PBO:0104438 "SO:0000407 = 18s rRNA, the genes are the 18s genes of the ""correct length"" so I guess we want them in there if we want to be able to make the ""connections"" from the info in the database? Though I guess this regions isnt properly sequenced.."
PMID:25404562 PBO:0106682 strain lacked Gm34 in its tRNAPhe, and had Cm levels comparable to those of wild type (0.86 versus 0.91 moles/mole) (Table 3; Fig. 4A).
PMID:25404562 FYPO:0001357 Fig. 3A
PMID:25404562 PBO:0106681 Table 2
PMID:25404562 PBO:0110009 specific term requested
PMID:25404562 FYPO:0001234 Fig. 2A (11 days for visible colonies)
PMID:25404562 PBO:0106683 yW formation was impaired in the Sp trm734△ mutant (44% of wild-type levels) and to a lesser extent in the Sp trm732△ mutant (73%) (Fig. 4F), consistent with the increased m1G levels (Table 3; Fig. 4A)
PMID:25404562 PBO:0110010 specific term requested
PMID:25404562 PBO:0106682 Table 2
PMID:25404562 PBO:0106686 Table 2
PMID:25404562 PBO:0106687 Table 2
PMID:25404562 PBO:0106688 Table 2
PMID:25404562 PBO:0106689 Table 2
PMID:25404562 PBO:0106690 Table 2
PMID:25404562 PBO:0106691 Table 2
PMID:25404562 PBO:0106692 Table 2
PMID:25404562 PBO:0106681 Table 2
PMID:25404562 PBO:0106686 Table 2
PMID:25404562 PBO:0106687 Table 2
PMID:25404562 PBO:0106690 Table 2
PMID:25404562 PBO:0106681 Table 2
PMID:25404562 PBO:0106686 Table 2
PMID:25404562 PBO:0106687 Table 2
PMID:25404562 PBO:0106688 Table 2
PMID:25404562 PBO:0106689 Table 2
PMID:25404562 PBO:0106690 diploid lacked detectable Cm in its tRNAPhe and had normal levels of Gm compared with that from wild type (0.88 versus 0.90 moles/mole) (Table 3; Fig. 4A)
PMID:25404562 PBO:0106691 strain lacked Gm34 in its tRNAPhe, and had Cm levels comparable to those of wild type (0.86 versus 0.91 moles/mole) (Table 3; Fig. 4A).
PMID:25404562 PBO:0106681 diploid lacked detectable Cm in its tRNAPhe and had normal levels of Gm compared with that from wild type (0.88 versus 0.90 moles/mole) (Table 3; Fig. 4A)
PMID:25404562 PBO:0106683 yW formation was impaired in the Sp trm734△ mutant (44% of wild-type levels) and to a lesser extent in the Sp trm732△ mutant (73%) (Fig. 4F), consistent with the increased m1G levels (Table 3; Fig. 4A)
PMID:25404562 PBO:0106685 specific term requested
PMID:25410910 PBO:0098171 yes it looks like pol II?! (val: changed to DNA binding term)
PMID:25411334 FYPO:0000026 check supp S2A
PMID:25411334 FYPO:0000026 check supp S2A
PMID:25411334 FYPO:0000117 check supp S2A is this increased septation index?
PMID:25411334 PBO:0023657 changed from bud neck to medial cortex ring but the def will be updated so it does not refer to double ring https://sourceforge.net/p/geneontology/ontology-requests/11819/ || depends on septins to localize to the division site.
PMID:25411334 PBO:0099793 A GEF of Rho4
PMID:25411334 FYPO:0000026 check supp S2A
PMID:25411338 GO:0031520 during cellular response to glucose starvation
PMID:25411338 PBO:0106537 the level of ght5 transcription, which increases in the WT during glucose limitation, fails to increase in this mutant cells in low-glucose medium.
PMID:25411338 PBO:0106536 The ght5 gene, the transcription of which is repressed in the WT cells, is transcribed at a high level in the presence of 111 mM glucose in the scr1 delta cells.
PMID:25411338 PBO:0094264 strong phenotype = has_severity(FYPO_EXT:0000001)
PMID:25411338 PBO:0106538 The Ght5 protein, which is localized on the plasma membrane in the WT, fails to be localized on the plasma membrane, accumulating in the cytoplasm.
PMID:25411338 PBO:0094264 strong phenotype = has_severity(FYPO_EXT:0000001)
PMID:25411338 PBO:0106538 The Ght5 protein, which is localized on the plasma membrane in the WT, fails to be localized on the plasma membrane, accumulating in the cytoplasm.
PMID:25411338 PBO:0106538 The Ght5 protein, which is localized on the plasma membrane in the WT, fails to be localized on the plasma membrane, accumulating in the cytoplasm.
PMID:25411338 PBO:0106538 The Ght5 protein, which is localized on the plasma membrane in the WT, fails to be localized on the plasma membrane, accumulating in the cytoplasm.
PMID:25411338 PBO:0024683 during cellular response to glucose starvation
PMID:25411338 PBO:0106537 the level of ght5 transcription, which increases in the WT during glucose limitation, fails to increase in this mutant cells in low-glucose medium.
PMID:25411338 GO:0031520 during cellular response to glucose starvation
PMID:25411338 GO:0031520 during cellular response to glucose starvation
PMID:25414342 FYPO:0005658 101.4% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim; skewed recombinant categories (Fig. 5D, Table S6)
PMID:25414342 FYPO:0002485 38.5% of wild-type recombination assayed between ura4+-aim2 and his3+-aim (Fig. 4B, Table S5)
PMID:25414342 FYPO:0003179 33.7% of wild-type recombination assayed between ade6-3083 and ade6-469 (Fig. 4A, Table S5)
PMID:25414342 FYPO:0005657 (Fig. 4C, Table S5)
PMID:25414342 FYPO:0000581 83.9% of wild-type spore viability (Fig. 4D, Table S5)
PMID:25414342 FYPO:0005578 (Table S2)
PMID:25414342 FYPO:0003891 (Table S2)
PMID:25414342 FYPO:0005659 117% of wild-type recombination assayed at various loci (Fig. 1, Table S2)
PMID:25414342 FYPO:0000581 78.4% of wild-type spore viability (Table S2)
PMID:25414342 FYPO:0002485 28.9% of wild-type recombination assayed between ura4+-aim2 and his3+-aim (Fig. 4B, Table S5)
PMID:25414342 FYPO:0003179 39.7% of wild-type recombination assayed between ade6-3083 and ade6-469 (Fig. 4A, Table S5)
PMID:25414342 FYPO:0005660 85.9% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim (Fig. 4C, Table S5)
PMID:25414342 FYPO:0000581 61.1% of wild-type spore viability (Fig. 4D, Table S5)
PMID:25414342 FYPO:0002485 61.0% of wild-type recombination assayed between ura4+-aim2 and his3+-aim (Fig. 3B, Table S4)
PMID:25414342 FYPO:0003179 42.4% of wild-type recombination assayed between ade6-3083 and ade6-469 (Fig. 3A, Table S4)
PMID:25414342 FYPO:0005660 82.9% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim (Fig. 4C, Table S5)
PMID:25414342 FYPO:0004993 95.2% of wild-type spore viability (Fig. 3D, Table S4)
PMID:25414342 FYPO:0002485 48.0% of wild-type recombination assayed between ura4+-aim2 and his3+-aim (Fig. 3B, Table S4)
PMID:25414342 FYPO:0003179 27.7% of wild-type recombination assayed between ade6-3083 and ade6-469 (Fig. 3A, Table S4)
PMID:25414342 FYPO:0005660 82.2% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim (Fig. 3C, Table S4)
PMID:25414342 FYPO:0004993 108.5% of wild-type spore viability (Fig. 3D, Table S4)
PMID:25414342 FYPO:0002485 49.0% of wild-type recombination assayed between ura4+-aim2 and his3+-aim (Fig. 3B, Table S4)
PMID:25414342 FYPO:0003179 49.2% of wild-type recombination assayed between ade6-3083 and ade6-469 (Fig. 3A, Table S4)
PMID:25414342 FYPO:0005660 90.5% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim (Fig. 3C, Table S4)
PMID:25414342 FYPO:0004993 133.5% of wild-type spore viability (Fig. 3D, Table S4)
PMID:25414342 FYPO:0002485 16.3% of wild-type recombination assayed between ura4+-aim2 and his3+-aim (Fig. 4B, Table S5)
PMID:25414342 FYPO:0003179 9.7% of wild-type recombination assayed between ade6-3083 and ade6-469 (Fig. 4A, Table S5)
PMID:25414342 FYPO:0005660 87.6% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim (Fig. 4C, Table S5)
PMID:25414342 FYPO:0000581 77.7% of wild-type spore viability (Fig. 4D, Table S5)
PMID:25414342 FYPO:0002485 31.4% of wild-type recombination assayed between ura4+-aim2 and his3+-aim (Table S6)
PMID:25414342 FYPO:0003179 8.0% of wild-type recombination assayed between ade6-3083 and ade6-469 (Fig. 6, Table S6)
PMID:25414342 FYPO:0005657 (Fig. 5, Table S6)
PMID:25414342 FYPO:0000581 43.6% of wild-type spore viability (Table S6)
PMID:25414342 FYPO:0002485 0.9% of wild-type recombination assayed between ura4+-aim2 and his3+-aim (Table S3)
PMID:25414342 FYPO:0003179 12.3% of wild-type recombination assayed between ade6-3083 and ade6-469 (Table S3)
PMID:25414342 FYPO:0005660 1.7% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim (Fig. 2B, Table S3)
PMID:25414342 FYPO:0000581 47% of wild-type spore viability (Fig. 2A, Table S3), 18.3-fold higher spore viability than mus81 single mutant
PMID:25414342 FYPO:0002485 19.1% of wild-type recombination assayed between ura4+-aim2 and his3+-aim (Table S3)
PMID:25414342 FYPO:0003179 2.2% of wild-type recombination assayed between ade6-3083 and ade6-469 (Table S3)
PMID:25414342 FYPO:0005660 10.5% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim (Fig. 2B, Table S3)
PMID:25414342 FYPO:0000581 42.9% of wild-type spore viability, 16.7-fold higher spore viability than mus81 single mutant (Fig. 2A, Table S3)
PMID:25414342 FYPO:0002485 26.0% of wild-type recombination assayed between ura4+-aim2 and his3+-aim (Table S3)
PMID:25414342 FYPO:0003179 30.1% of wild-type recombination assayed between ade6-3083 and ade6-469 (Table S3)
PMID:25414342 FYPO:0005660 9.9% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim (Fig. 2B, Table S3)
PMID:25414342 FYPO:0000581 21.2% of wild-type spore viability, 8.3-fold higher spore viability than mus81 single mutant (Fig. 2A, Table S3)
PMID:25414342 FYPO:0002485 6.4% of wild-type recombination assayed between ura4+-aim2 and his3+-aim (Table S3)
PMID:25414342 FYPO:0003179 57.9% of wild-type recombination assayed between ade6-3083 and ade6-469 (Table S3)
PMID:25414342 FYPO:0005660 7.8% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim (Fig. 2B, Table S3)
PMID:25414342 FYPO:0000581 28.9% of wild-type spore viability, 11.3-fold higher spore viability than mus81 single mutant (Fig. 2A, Table S3)
PMID:25414342 FYPO:0002485 58.1% of wild-type recombination assayed between ura4+-aim2 and his3+-aim (Table S3)
PMID:25414342 FYPO:0003179 36.3% of wild-type recombination assayed between ade6-3083 and ade6-469 (Table S3)
PMID:25414342 FYPO:0005660 6.9% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim (Fig. 2B, Table S3)
PMID:25414342 FYPO:0000581 44.7% of wild-type spore viability, 17.4-fold higher spore viability than mus81 single mutant (Fig. 2A, Table S3)
PMID:25414342 FYPO:0002485 48.0% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, epistatic relationship (Fig.3B, Table S4)
PMID:25414342 FYPO:0003179 32.3% of wild-type recombination assayed between ade6-3083 and ade6-469, epistatic relationship (Fig. 3A, Table S4)
PMID:25414342 FYPO:0005660 85.8% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim, epistatic relationship (Fig. 3C, Table S4)
PMID:25414342 FYPO:0004993 117.1% of wild-type spore viability (Fig. 3D, Table S4)
PMID:25414342 FYPO:0002485 55.5% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, epistatic relationship (Fig. 3B, Table S4)
PMID:25414342 FYPO:0003179 44.4% of wild-type recombination assayed between ade6-3083 and ade6-469, epistatic relationship (Fig. 3A, Table S4)
PMID:25414342 FYPO:0005660 78.6% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim, epistatic relationship (Fig. 3C, Table S4)
PMID:25414342 FYPO:0004993 104.8% of wild-type spore viability (Fig. 3D, Table S4)
PMID:25414342 FYPO:0002485 0% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, synergistic relationship (Fig. 4B, Table S5)
PMID:25414342 FYPO:0004993 91.68% of wild-type spore viability, epistatic relationship (Table S6)
PMID:25414342 FYPO:0002485 38.89% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, epistatic relationship (Table S6)
PMID:25414342 FYPO:0003179 0.42% of wild-type recombination assayed between ade6-3083 and ade6-469, synergistic relationship (Fig. 4A, Table S5)
PMID:25414342 FYPO:0000581 3.7% of wild-type spore viability, synergistic relationship (Fig. 4D, Table S5)
PMID:25414342 FYPO:0002485 4.5% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, synergistic relationship (Fig. 4B, Table S5)
PMID:25414342 FYPO:0003179 2.5% of wild-type recombination assayed between ade6-3083 and ade6-469, synergistic relationship (Fig. 4A, Table S5)
PMID:25414342 FYPO:0005660 18.5% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim, synergistic relationship (Fig. 4C, Table S5)
PMID:25414342 FYPO:0000581 13.0% of wild-type spore viability, synergistic relationship (Fig. 4D, Table S5)
PMID:25414342 FYPO:0002485 33.5% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, epistatic relationship (Fig. 4B, Table S5)
PMID:25414342 FYPO:0003179 14.2% of wild-type recombination assayed between ade6-3083 and ade6-469, epistatic relationship (Fig. 4A, Table S5)
PMID:25414342 FYPO:0005660 84.1% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim, epistatic relationship (Fig. 4C, Table S5)
PMID:25414342 FYPO:0000581 93.8% of wild-type spore viability, epistatic relationship (Fig. 4D, Table S5)
PMID:25414342 FYPO:0002485 26.4% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, epistatic relationship (Fig. 4B, Table S5)
PMID:25414342 FYPO:0003179 25.7% of wild-type recombination assayed between ade6-3083 and ade6-469, epistatic relationship (Fig. 4A, Table S5)
PMID:25414342 FYPO:0005660 91.4% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim, epistatic relationship (Fig. 4C, Table S5)
PMID:25414342 FYPO:0000581 76.9% of wild-type spore viability, epistatic relationship (Fig. 4D, Table S5)
PMID:25414342 FYPO:0002485 0% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, synergistic relationship (Fig. 4B, Table S5)
PMID:25414342 FYPO:0003179 2.1% of wild-type recombination assayed between ade6-3083 and ade6-469, synergistic relationship (Fig. 4A, Table S5)
PMID:25414342 FYPO:0005657 106.7% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim, epistatic relationship (Fig. 4C, Table S5)
PMID:25414342 FYPO:0000581 9.9% of wild-type spore viability, synergistic relationship (Fig. 4D, Table S5)
PMID:25414342 FYPO:0002485 65.3% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, epistatic relationship (Fig. 4B, Table S5)
PMID:25414342 FYPO:0003179 21.1% of wild-type recombination assayed between ade6-3083 and ade6-469, epistatic relationship (Fig. 4A, Table S5)
PMID:25414342 FYPO:0005660 76.7% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim, synergistic relationship; skewed recombinant classes (Figs. 4C & 7A, Table S5)
PMID:25414342 FYPO:0000581 55.5% of wild-type spore viability, synergistic relationship (Fig. 4D, Table S5)
PMID:25414342 FYPO:0002485 54.0% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, epistatic relationship (Table S5)
PMID:25414342 FYPO:0003179 31.1% of wild-type recombination assayed between ade6-3083 and ade6-469, epistatic relationship (Table S5)
PMID:25414342 FYPO:0005660 75.2% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim, synergistic relationship (Fig. S2, Table S5)
PMID:25414342 FYPO:0000581 50.7% of wild-type spore viability, synergistic relationship (Table S5)
PMID:25414342 FYPO:0000581 15.4% of wild-type spore viability, synergistic relationship (Table S6)
PMID:25414342 FYPO:0002485 76.1% of wild-type recombination assayed between ade6-3083 and ade6-469 (Table S6)
PMID:25414342 FYPO:0003179 7.2% of wild-type recombination assayed between ade6-3083 and ade6-469, epistatic relationship - similar to rqh1delta (Fig. 6, Table S6)
PMID:25414342 FYPO:0005659 124.3% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim, epistatic relationship - similar to fml1delta (Fig. 5, Table S6)
PMID:25414342 FYPO:0000581 60.64% of wild-type spore viability, epistatic relationship (Table S6)
PMID:25414342 FYPO:0003179 7.4% of wild-type recombination assayed between ade6-3083 and ade6-469, epistatic relationship (Fig.6A, Table S6)
PMID:25414342 FYPO:0002485 24.3% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, epistatic relationship (Table S6)
PMID:25414342 FYPO:0005659 115.17% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim, epistatic relationship (Fig. 5A, Table S6)
PMID:25414342 FYPO:0002485 25.9% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, epistatic relationship (Table S6)
PMID:25414342 FYPO:0003179 2.55% of wild-type recombination assayed between ade6-3083 and ade6-469, synergistic relationship (Fig.6A, Table S6)
PMID:25414342 FYPO:0005659 115.12% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim, synergistic relationship (Fig. 5A, Table S6)
PMID:25414342 FYPO:0000581 54.78% of wild-type spore viability, epistatic relationship (Table S6)
PMID:25414342 FYPO:0002485 28.85% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, epistatic relationship (Table S6)
PMID:25414342 FYPO:0003179 3.55% of wild-type recombination assayed between ade6-3083 and ade6-469 (Fig.6A, Table S6)
PMID:25414342 FYPO:0003179 10.34% of wild-type recombination assayed between ade6-3083 and ade6-469, epistatic relationship (Fig.6D, Table S6)
PMID:25414342 FYPO:0000581 21.46% of wild-type spore viability, synergistic relationship (Table S6)
PMID:25414342 FYPO:0002485 45.45% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, epistatic relationship (Table S6)
PMID:25414342 FYPO:0003179 15.59% of wild-type recombination assayed between ade6-3083 and ade6-469 (Fig.6D, Table S6)
PMID:25414342 FYPO:0005659 114.54% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim; skewed recombinant categories (Fig. 5D, Table S6)
PMID:25414342 FYPO:0000581 20.24% of wild-type spore viability (Table S6)
PMID:25414342 FYPO:0002485 55.49% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, epistatic relationship (Table S6)
PMID:25414342 FYPO:0003179 37.89% of wild-type recombination assayed between ade6-3083 and ade6-469, similar to dmc1Δ-12 and rlp1Δ single mutants, but higher than dmc1Δ-12 rlp1Δ double mutant (Fig.6E, Table S6)
PMID:25414342 FYPO:0005660 79.92% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim; skewed recombinant categories (Figs. 5E & 7A, Table S6)
PMID:25414342 FYPO:0000581 7.8% of wild-type spore viability, synergistic relationship (Table S6)
PMID:25414342 FYPO:0002485 30.92% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, epistatic relationship (Table S6)
PMID:25414342 FYPO:0003179 9.88% of wild-type recombination assayed between ade6-3083 and ade6-469, epistatic relationship (Fig.6E, Table S6)
PMID:25414342 FYPO:0005658 101.76% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim; skewed recombinant categories (Figs. 5E & 7A, Table S6)
PMID:25414342 FYPO:0000581 31.18% of wild-type spore viability (Table S6)
PMID:25414342 FYPO:0002485 20.15% of wild-type recombination assayed between ura4+-aim2 and his3+-aim (Table S6)
PMID:25414342 FYPO:0003179 6.87% of wild-type recombination assayed between ade6-3083 and ade6-469, epistatic relationship (Fig.6E, Table S6)
PMID:25414342 FYPO:0005659 111.2% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim; skewed recombinant classes (Figs. 5E & 7A, Table S6)
PMID:25414342 FYPO:0005659 119.91% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim, epistatic relationship (Fig. 5A, Table S6)
PMID:25414342 FYPO:0002485 55.62% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, partial rescue from rad55Δ levels (Table S6)
PMID:25414342 FYPO:0003179 35.42% of wild-type recombination assayed between ade6-3083 and ade6-469, epistatic relationship (Fig.6B, Table S6)
PMID:25414342 FYPO:0005659 111.64% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim, epistatic relationship (Fig. 5B, Table S6)
PMID:25414342 FYPO:0000581 53.76% of wild-type spore viability, epistatic relationship (Table S6)
PMID:25414342 FYPO:0002485 15.19% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, epistatic relationship (Table S6)
PMID:25414342 FYPO:0003179 8.87% of wild-type recombination assayed between ade6-3083 and ade6-469, epistatic relationship (Fig.6B, Table S6)
PMID:25414342 FYPO:0005659 127.22% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim, synergistic relationship (Fig. 5B, Table S6)
PMID:25414342 FYPO:0000581 3.68% of wild-type spore viability, synergistic relationship (Table S6)
PMID:25414342 FYPO:0002485 15.53% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, epistatic relationship (Table S6)
PMID:25414342 FYPO:0003179 12.19% of wild-type recombination assayed between ade6-3083 and ade6-469, epistatic relationship (Fig.6B, Table S6)
PMID:25414342 FYPO:0005659 136.75% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim, synergistic relationship (Fig. 5B, Table S6)
PMID:25414342 FYPO:0000581 4.11% of wild-type spore viability (Table S6)
PMID:25414342 FYPO:0002485 69.41% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, epistatic relationship (Table S6)
PMID:25414342 FYPO:0003179 36.88% of wild-type recombination assayed between ade6-3083 and ade6-469, epistatic relationship (Fig.6C, Table S6)
PMID:25414342 FYPO:0005658 101.33% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim; higher than rlp1ÃÂ-7, lower than fml1ÃÂ, skewed recombinant categories (Figs. 5C & 7A, Table S6)
PMID:25414342 FYPO:0002485 46.52% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, epistatic relationship (Table S6)
PMID:25414342 FYPO:0003179 52.08% of wild-type recombination assayed between ade6-3083 and ade6-469, epistatic relationship (Table S6)
PMID:25414342 FYPO:0005658 102.17% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim, higher than rdl1Δ-25, lower than fml1Δ, skewed recombinant categories (Fig. S3, Table S6)
PMID:25414342 FYPO:0000581 73.46% of wild-type spore viability, epistatic relationship (Table S6)
PMID:25414342 FYPO:0002485 32.13% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, epistatic relationship (Table S6)
PMID:25414342 FYPO:0003179 8.33% of wild-type recombination assayed between ade6-3083 and ade6-469, epistatic relationship (Fig.6C, Table S6)
PMID:25414342 FYPO:0005659 116.19% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim, synergistic relationship (Fig. 5C, Table S6)
PMID:25414342 FYPO:0000581 37.75% of wild-type spore viability, epistatic relationship (Table S6)
PMID:25414342 FYPO:0002485 59.57% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, epistatic relationship (Table S6)
PMID:25414342 FYPO:0003179 7.33% of wild-type recombination assayed between ade6-3083 and ade6-469, epistatic relationship (Fig.6C, Table S6)
PMID:25414342 FYPO:0005659 130.25% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim, synergistic relationship (Fig. 5C, Table S6)
PMID:25414342 FYPO:0000581 21.45% of wild-type spore viability, synergistic relationship (Table S6)
PMID:25414342 FYPO:0002485 49.8% of wild-type recombination assayed between ura4+-aim2 and his3+-aim, epistatic relationship (Table S6)
PMID:25414342 FYPO:0003179 27.08% of wild-type recombination assayed between ade6-3083 and ade6-469, epistatic relationship (Fig.6D, Table S6)
PMID:25414342 FYPO:0005659 122.65% of wild-type recombination assayed between ura4+-aim2 - ade6-3083 and ade6-469 - his3+-aim, epistatic relationship (Fig. 5D, Table S6)
PMID:25414342 FYPO:0000581 13.87% of wild-type spore viability (Table S6)
PMID:25417108 GO:0006386 occurs at rDNA, tRNA gene, protein coding gene
PMID:25417108 FYPO:0004814 affecting: highly transcribed genes antisense transcription of tDNA and rDNA
PMID:25417108 GO:0006369 occurs at rDNA, tRNA gene, protein coding gene
PMID:25417108 FYPO:0004819 Affecting Rad52 enrichment at rDNA
PMID:25417108 FYPO:0004817 affecting antisense transcription at rDNA
PMID:25417108 FYPO:0004818 affecting antisense transcription at tDNA
PMID:25417108 PBO:0095377 occurs at tDNA
PMID:25417108 FYPO:0004813 affecting: highly transcribed genes antisense transcription of tDNA and rDNA
PMID:25417108 FYPO:0003103 Affecting Dcr1-terminated genes
PMID:25417108 FYPO:0004812 affecting: highly transcribed genes antisense transcription of tDNA and rDNA
PMID:25417108 FYPO:0004820 Affecting Rad52 enrichment at rDNA
PMID:25417108 GO:0006363 occurs at rDNA, tRNA gene, protein coding gene
PMID:25428589 PBO:0093562 prevented nc-tgp1 transcription, induced tgp1þ expression to levels observed in 1343D levels and increased sensitivity of these cells to TBZ, HU and caffeine (Fig. 3b,c). These analyses demonstrate that it is nc-tgp1, not nc-1343, that is critical for repressing tgp1þ in the presence of phosphate.
PMID:25428589 FYPO:0004161 In agreement with this, significantly less RNAPII associates with the nc-tgp1 transcription unit in both phosphate- starved wild-type cells and phosphate-replete 1343D cells, which do not transcribe nc-tgp1 (Fig. 4c).
PMID:25428589 PBO:0096772 The size and levels of the nc-1343 transcript increased in exosome defective (rrp6D) cells, but not cells lacking Mmi1 or Red1 (Fig. 2c,d; Supplementary Fig. 4). T
PMID:25428589 PBO:0096778 In addition, the transcript levels of tgp1þ, nc-tgp1, nc-1343, pho1þ and nc-pho1 were unaffected by loss of RNAi (for example, ago1D or dcr1D) or heterochromatin components (for example, clr4D or swi6D) (Fig. 5b; Supplementary Fig. 7a
PMID:25428589 PBO:0096776 In addition, the transcript levels of tgp1þ, nc-tgp1, nc-1343, pho1þ and nc-pho1 were unaffected by loss of RNAi (for example, ago1D or dcr1D) or heterochromatin components (for example, clr4D or swi6D) (Fig. 5b; Supplementary Fig. 7a
PMID:25428589 PBO:0096775 Northern analysis identified that an B1.9kb nc-tgp1 RNA accumulates in rrp6D, mmi1D and red1D, but not in wild-type cells (Fig. 2e,f; Supplementary Fig. 4).
PMID:25428589 PBO:0096775 Northern analysis identified that an B1.9kb nc-tgp1 RNA accumulates in rrp6D, mmi1D and red1D, but not in wild-type cells (Fig. 2e,f; Supplementary Fig. 4).
PMID:25428589 PBO:0096775 Northern analysis identified that an B1.9kb nc-tgp1 RNA accumulates in rrp6D, mmi1D and red1D, but not in wild-type cells (Fig. 2e,f; Supplementary Fig. 4).
PMID:25428589 FYPO:0000964 Trun- cations of nc-1343 (that is, AD and BD) that retain its 50 end did not result in the drug-sensitivity phenotype presented by 1343D cells (Fig. 3b) and, similarly, did not induce tgp1þ expression (Fig. 3c)
PMID:25428589 FYPO:0000964 Trun- cations of nc-1343 (that is, AD and BD) that retain its 50 end did not result in the drug-sensitivity phenotype presented by 1343D cells (Fig. 3b) and, similarly, did not induce tgp1þ expression (Fig. 3c)
PMID:25428589 PBO:0096774 We identified a consensus DSR motif for Mmi1 binding at position þ820 nt within the nc-tgp1 transcript and RNA IP (RIP) experiments confirmed a direct interaction between Mmi1 and the nc-tgp1 RNA (Supplementary Fig. 5).
PMID:25428589 PBO:0096773 The size and levels of the nc-1343 transcript increased in exosome defective (rrp6D) cells, but not cells lacking Mmi1 or Red1 (Fig. 2c,d; Supplementary Fig. 4). T
PMID:25428589 PBO:0096772 The size and levels of the nc-1343 transcript increased in exosome defective (rrp6D) cells, but not cells lacking Mmi1 or Red1 (Fig. 2c,d; Supplementary Fig. 4). T
PMID:25428589 PBO:0096776 In addition, the transcript levels of tgp1þ, nc-tgp1, nc-1343, pho1þ and nc-pho1 were unaffected by loss of RNAi (for example, ago1D or dcr1D) or heterochromatin components (for example, clr4D or swi6D) (Fig. 5b; Supplementary Fig. 7a
PMID:25428589 PBO:0096776 In addition, the transcript levels of tgp1þ, nc-tgp1, nc-1343, pho1þ and nc-pho1 were unaffected by loss of RNAi (for example, ago1D or dcr1D) or heterochromatin components (for example, clr4D or swi6D) (Fig. 5b; Supplementary Fig. 7a
PMID:25428589 PBO:0096776 In addition, the transcript levels of tgp1þ, nc-tgp1, nc-1343, pho1þ and nc-pho1 were unaffected by loss of RNAi (for example, ago1D or dcr1D) or heterochromatin components (for example, clr4D or swi6D) (Fig. 5b; Supplementary Fig. 7a
PMID:25428589 PBO:0096779 In contrast, nc-tgp1, nc-pho1 and sme2þ RNA levels were clearly elevated in cells lacking Mmi1-mediated exosome degradation (mmi1D and rrp6D). Th
PMID:25428589 PBO:0096780 Our ChIP analyses confirmed that Pho7–green fluorescent protein (Pho7–GFP) accumulates on the pho1 þ promoter in phosphate- depleted cells (Supplementary Fig. 8). In addition, Pho7–GFP levels accumulate over the region upstream of tgp1þ when activated (Fig. 6a
PMID:25428589 PBO:0111000 We therefore conclude that tgp1(+) is regulated by transcriptional interference.
PMID:25428589 PBO:0096769 (repressed condition; Fig. 1c)
PMID:25428589 PBO:0093562 Cells lacking SPNCRNA.1343 (ncRNA.1343 for short) displayed a phenotype: hypersensitivity to TBZ, HU and caffeine but not to temperature extremities, ultraviolet- irradiation or oxidative stress (Supplementary Fig. 1c and Supplementary Fig. 2).
PMID:25428589 PBO:0096770 To determine whether the drug sensitivity of 1343D cells is a direct result of increased tgp1þ expression, the tgp1þ gene was deleted from 1343D cells (tgp1D1343D). This manipulation restored TBZ, HU and caffeine tolerance to levels comparable with wild-type cells (Fig. 1d). We conclude that increased tgp1þ expression is directly responsible for the drug-sensitivity phenotype of cells lacking ncRNA.1343.
PMID:25428987 PBO:0020227 mitotic interphase
PMID:25451933 GO:0051014 SpAip1 dramatically stimulated severing by 100 nM cofilin, with a maximum rate at 1.5 M SpAip1 and lower rates at higher concentrations (Fig. 3C).At all SpAip1 concentrations tested 80% of new barbed ends created by severing events depolymerized (Fig. 3D) at rates that decreased insignificantly with SpAip1 concentration (Fig. 3E). These depolymerization rates were higher than published values (2), likely because severing near barbed ends was difficult to distin- guish from filament depolymerization.
PMID:25451933 FYPO:0007573 As a result, ring constriction in aip1 cells takes 5 min less than in wild type cells (Table 3). Overall, cytokinesis was 16 min (24%) faster in aip1 cells than wild type cells, because the maturation period was shorter and the rings constricted faster.
PMID:25451933 GO:0003786 competatively with cofilin
PMID:25451933 FYPO:0007573 Surprisingly, contractile rings began to constrict earlier in aip1 cells than wild type cells (Fig. 7, A and B, and Table 3), foreshortening the maturation period before constriction
PMID:25451933 FYPO:0006187 igs. 6B and C and Table 3
PMID:25451933 FYPO:0001366 The fission yeast lacking Aip1 have normal appearing actin patches, cables, and contractile rings (Fig. 5B).
PMID:25471935 FYPO:0005764 assayed Cdc20 recruitment
PMID:25472718 FYPO:0006259 Fig. 5D
PMID:25472718 PBO:0037884 Fig 1A
PMID:25472718 FYPO:0002061 (supplementary material Fig. S1A
PMID:25472718 FYPO:0000674 fig 2 A
PMID:25472718 PBO:0093556 fig 2 A
PMID:25472718 FYPO:0001387 fig S2B
PMID:25472718 FYPO:0001387 fig S2B
PMID:25472718 PBO:0101239 Overall, our data suggest that Klp5–Klp6 delivers PP1 to the attached kinetochores, thereby promoting SAC silencing.
PMID:25472718 FYPO:0004307 Fig. 5D
PMID:25472718 PBO:0101242 Fig. 5A
PMID:25472718 FYPO:0004310 Fig. 5A
PMID:25472718 FYPO:0001387 Fig. 5A
PMID:25472718 PBO:0101233 Fig. 4E reduced by >70%
PMID:25472718 PBO:0035594 Fig. 1C; Fig. 3D
PMID:25472718 PBO:0094476 Fig. 1C; Fig. 3D
PMID:25472718 PBO:0097264 fig 3C
PMID:25472718 PBO:0097264 fig 3A
PMID:25472718 FYPO:0000674 fig 3A
PMID:25472718 FYPO:0000674 fig 3A
PMID:25472718 FYPO:0000674 fig 3A
PMID:25472718 PBO:0101240 In any case, the results shown here imply that Klp5–Klp6 localises to the kinetochores through interaction with the Alp7–Alp14 complex.
PMID:25472718 PBO:0101240 In any case, the results shown here imply that Klp5–Klp6 localises to the kinetochores through interaction with the Alp7–Alp14 complex.
PMID:25472718 PBO:0101239 Overall, our data suggest that Klp5–Klp6 delivers PP1 to the attached kinetochores, thereby promoting SAC silencing.
PMID:25472718 PBO:0101231 Fig. 2C,D
PMID:25472718 FYPO:0001387 fig 2A
PMID:25472718 PBO:0101232 fig 3 d
PMID:25472718 PBO:0101233 Fig. 4E reduced by >70%
PMID:25472718 FYPO:0001905 Fig. 4C,D)
PMID:25472718 PBO:0101234 Fig. 4A,B
PMID:25472718 PBO:0101235 Fig. 4A,B
PMID:25472718 FYPO:0000674 fig 1A
PMID:25472718 PBO:0093561 Fig 1A
PMID:25472718 PBO:0101236 (Fig. 1C–E; Type I
PMID:25472718 PBO:0101237 (Fig. 1C–E; Type I
PMID:25472718 PBO:0101238 (Fig. 1C–E; Type I
PMID:25473118 PBO:0102181 fig6
PMID:25473118 FYPO:0003339 the ring seems to start off forming normally but maturation is delayed, this leads to delayed constriction.
PMID:25473118 PBO:0018576 independent of actin
PMID:25473118 PBO:0102105 fig6
PMID:25487150 GO:0005515 unphosphorylated form
PMID:25500221 PBO:0099955 secretion of acid phosphatase
PMID:25500221 PBO:0099955 secretion of acid phosphatase
PMID:25501814 PBO:0107511 fig1c
PMID:25501814 PBO:0107514 (Fig. 3C).
PMID:25501814 PBO:0107513 Cdc7p–GFP never disappeared from the old SPB (Sohrmann et al., 1998) and the type 1 nodes did not reform (Fig. 3B; supplementary material Movie 3)
PMID:25501814 PBO:0107512 fig 2g
PMID:25501814 PBO:0107510 fig1
PMID:25501814 PBO:0099316 fig1
PMID:25501814 PBO:0018634 fig1
PMID:25501814 PBO:0023023 fig1
PMID:25501814 PBO:0018845 fig1
PMID:25501814 PBO:0018845 fig1
PMID:25519804 PBO:0106417 high suppression of phenotype
PMID:25519804 FYPO:0003911 efficient suppression of ade6-M26; very poor suppression of ade6-M375
PMID:25519804 FYPO:0003911 suppresses ade6-M26 efficiently; suppresses ade6-M375 weakly
PMID:25519804 PBO:0106417 high suppression of phenotype
PMID:25519804 PBO:0106418 low suppression of phenotype
PMID:25520186 FYPO:0002061 I only captured the OEX experiment
PMID:25520186 MOD:00047 Auto-phosphorylation occurred in the presence of ATP in vitro
PMID:25520186 MOD:00047 Auto-phosphorylation occurred in the presence of ATP in vitro
PMID:25520186 MOD:00047 Auto-phosphorylation occurred in the presence of ATP in vitro
PMID:25520186 MOD:00047 Auto-phosphorylation occurred in the presence of ATP in vitro
PMID:25520186 FYPO:0002060 I only captured the OEX Experiment
PMID:25520186 PBO:0097184 full-length Cut14 present; not sure how to interpret this, check
PMID:25520186 PBO:0097184 full-length Cut14 present; not sure how to interpret this, check
PMID:25520186 PBO:0097184 full-length Cut14 present; not sure how to interpret this, check
PMID:25520186 PBO:0097183 of condensin complex
PMID:25520186 PBO:0097182 of condensin complex
PMID:25520186 MOD:00046 Auto-thiophosphorylation occurred in the presence of ATP gamma-S in vitro
PMID:25520186 MOD:00046 Auto-thiophosphorylation occurred in the presence of ATP gamma-S in vitro
PMID:25520186 MOD:00046 Auto-thiophosphorylation occurred in the presence of ATP gamma-S in vitro
PMID:25520186 MOD:00046 Auto-thiophosphorylation occurred in the presence of ATP gamma-S in vitro
PMID:25520186 MOD:00046 Auto-thiophosphorylation occurred in the presence of ATP gamma-S in vitro
PMID:25520186 MOD:00046 Auto-thiophosphorylation occurred in the presence of ATP gamma-S in vitro
PMID:25520186 MOD:00046 Auto-thiophosphorylation occurred in the presence of ATP gamma-S in vitro
PMID:25520186 MOD:00583 Auto-thiophosphorylation occurred in the presence of ATP gamma-S in vitro
PMID:25520186 MOD:00047 Auto-phosphorylation occurred in the presence of ATP in vitro
PMID:25533340 FYPO:0003584 increased end-joining activity in vegetative cells
PMID:25533340 PBO:0022125 This looks like direct regulation because it phosphorylates xlf1
PMID:25533340 PBO:0103462 phosphorylated by cdc2 phosphorylated in G2 phase inhibits nonhomologous end joining S192
PMID:25533340 PBO:0103463 phosphorylated by cdc2 phosphorylated in G2 phase inhibits nonhomologous end joining S192
PMID:25533340 PBO:0103464 phosphorylated by cdc2 phosphorylated in G2 phase inhibits nonhomologous end joining T180
PMID:25533340 PBO:0103465 phosphorylated by cdc2 phosphorylated in G2 phase inhibits nonhomologous end joining T180
PMID:25533340 FYPO:0000482 leu1
PMID:25533348 PBO:0098718 fig 3 A
PMID:25533348 PBO:0098723 fig 3 A
PMID:25533348 PBO:0033098 WT 3%
PMID:25533348 PBO:0033099 WT 3%
PMID:25533348 PBO:0098715 WT 3%
PMID:25533348 PBO:0033097 WT 3%
PMID:25533348 PBO:0098727 fig 3 A
PMID:25533348 PBO:0098724 fig 3 A
PMID:25533348 PBO:0098725 fig 3 A
PMID:25533348 PBO:0098726 fig 3 A
PMID:25533348 PBO:0098707 greater range of legths
PMID:25533348 PBO:0098708 greater range of legths
PMID:25533348 PBO:0098707 greater range of legths
PMID:25533348 PBO:0098720 fig 3 A
PMID:25533348 PBO:0098719 fig 3 A
PMID:25533348 PBO:0098717 fig 3 A
PMID:25533348 PBO:0098722 fig 3 A
PMID:25533348 PBO:0098721 fig 3 A
PMID:25533956 PBO:0105397 fig5 e
PMID:25533956 PBO:0105398 fig5 e
PMID:25533956 PBO:0105399 RECRUITS
PMID:25543137 GO:0042026 hsp104 refolds dicer and is required for robust centromeric silencing at 37°C
PMID:25543137 PBO:0104383 Dcr1 represses hsp104 levels
PMID:25543137 FYPO:0004808 A prionogenic reporter (S. cerevisiae Sup35 prion domain) aggregates in cytoplasmic inclusions in dcr1Δ
PMID:25543137 PBO:0104384 Dcr1 is not released from cytoplasmic inclusions at 37°C in hsp104Î
PMID:25543137 GO:0005737 Diffuse cytoplasmic localisation at 37°C, no stress granules
PMID:25543137 PBO:0023812 Dcr1 localizes in electron-dense cytoplasmic inclusions at 37°C together with hsp104. Hsp104 is required for dissolution of these inclusions.
PMID:25543137 GO:0005634 Nuclear localization at 30°C
PMID:25543137 PBO:0023812 Cytoplasmic localisation in electron-dense inclusions at 37°C
PMID:25543137 GO:0005634 Nuclear localization at 30°C
PMID:25590601 PBO:0101539 strong phenotype = has_severity(FYPO_EXT:0000001)
PMID:25590601 PBO:0023216 ii) removed during glucose starvation ii) observed during nitrogen starvation iv) S546
PMID:25590601 PBO:0023217 ii) removed during nitrogen starvation iv) T415
PMID:25590601 PBO:0023218 ii) in the presence of glucose
PMID:25590601 PBO:0023214 ii) removed during glucose starvation ii) observed during nitrogen starvation iv) S546
PMID:25590601 PBO:0023215 ii) removed during glucose starvation ii) observed during nitrogen starvation iv) S546
PMID:25590601 PBO:0101537 iii) decreased during glucose starvation
PMID:25619765 FYPO:0000227 cen2-lacO
PMID:25619765 FYPO:0000227 pNBg was used
PMID:25619998 PBO:0097963 (S2)
PMID:25619998 GO:1990189 (S2)
PMID:25619998 PBO:0097964 (S2)
PMID:25639242 FYPO:0007434 figure 6E
PMID:25639242 PBO:0101663 causally upstream of ssp2
PMID:25639242 PBO:0101660 Fig 6G
PMID:25639242 PBO:0101659 fig s4c&d
PMID:25639242 PBO:0101662 However, no difference in CaMKKSsp1 protein levels or phos- ppk34 phorylation status was observed in CaMKK .D mutants compared with wild-type cells (Figures S4A and S4B
PMID:25639242 PBO:0037529 causally upstream of ssp2
PMID:25639242 PBO:0101661 An increase in AMPKaSsp2 Thr189 phosphorylation was also observed in the cbs2 .D AMPKg .D double mutant (Figure S2F).
PMID:25639242 FYPO:0007434 figure 4D
PMID:25639242 FYPO:0007434 figure 4E
PMID:25639242 FYPO:0007434 figure 4D
PMID:25639242 PBO:0093770 figure 2b 9% longer
PMID:25639242 FYPO:0007434 figure 2a
PMID:25639242 FYPO:0007434 figure 6E
PMID:25639242 PBO:0101660 fig 6A
PMID:25639242 FYPO:0002673 S3A
PMID:25639242 PBO:0101653 2D & 4B
PMID:25639242 FYPO:0007434 fig 3B
PMID:25639242 FYPO:0007434 fig 3d
PMID:25639242 FYPO:0007434 Fig 3G
PMID:25639242 PBO:0101659 However, no difference in CaMKKSsp1 protein levels or phos- ppk34 phorylation status was observed in CaMKK .D mutants compared with wild-type cells (Figures S4A and S4B
PMID:25639242 PBO:0101657 figure 5a
PMID:25639242 FYPO:0007434 FIG 3F DECOUPLED CELL GROWTH ASND DIVISION
PMID:25639242 FYPO:0005206 FIG 3F
PMID:25639242 PBO:0101656 figure S2g
PMID:25639242 PBO:0101654 figure S2B
PMID:25639242 PBO:0101653 Figure 4C
PMID:25639242 PBO:0101653 Fig 4C
PMID:25639242 FYPO:0007434 Fig 3C
PMID:25639242 FYPO:0007434 figure 2a
PMID:25688133 FYPO:0004747 LifeAct-mCherry Sid4-GFP
PMID:25688133 FYPO:0004737 LifeAct-mCherry Sid4-GFP
PMID:25688133 FYPO:0004737 LifeAct-mCherry Sid4-GFP
PMID:25688133 PBO:0099724 mCherry-cdc15,Rlc-GFP
PMID:25688133 PBO:0101703 Cdc12-mNeonGreen, Ain1-GFP, GFP-Adf1
PMID:25688133 PBO:0095196 mCherry-cdc15,Rlc-GFP
PMID:25688133 PBO:0099724 mCherry-cdc15,Rlc-GFP
PMID:25688133 PBO:0095196 mCherry-cdc15,Rlc-GFP
PMID:25688133 GO:1990808 residues 20â-40 in synthetic peptide/ dissociation constant of 1.1 nM
PMID:25688133 PBO:0108656 residues 20â-40 in synthetic peptide/ dissociation constant of 1.1 nM
PMID:25688133 FYPO:0004747 LifeAct-mCherry Sid4-GFP
PMID:25688133 FYPO:0000729 Live-cell imaging of Rlc1-GFP Sid4-GFP 26% slower
PMID:25688133 PBO:0101703 Cdc12-mNeonGreen, GFP-Adf1, Ain1-GFP
PMID:25688133 FYPO:0000729 Live-cell imaging of Rlc1-GFP Sid4-GFP 23% slower
PMID:25688133 PBO:0096493 smears as does not self associate, but localizes to medial cortex
PMID:25724335 GO:0005739 Gene name : aco2
PMID:25724335 GO:0032543 Gene name : aco2
PMID:25724335 FYPO:0002061 Gene name : aco2
PMID:25724335 GO:0005634 Gene name : aco2
PMID:25724335 FYPO:0004530 Gene name : aco2
PMID:25724335 GO:0005737 Gene name : aco2
PMID:25736293 FYPO:0000903 Fig. 7F; supplementary material Table S1
PMID:25736293 PBO:0107637 microtubule cortical anchor (microtubule site clamp) add to other dynactin complex
PMID:25736293 PBO:0107637 microtubule cortical anchor (microtubule site clamp) add to other dynactin complex
PMID:25736293 GO:1903754 (Fig. 5C
PMID:25736293 FYPO:0005988 3B?
PMID:25736293 FYPO:0000903 Fig. 7F; supplementary material Table S1
PMID:25736293 PBO:0107639 S4A
PMID:25736293 PBO:0107638 S4A
PMID:25736293 PBO:0107638 S4A
PMID:25736293 GO:0051285 fig 4 A
PMID:25736293 FYPO:0000964 figS1B
PMID:25736293 FYPO:0000964 figS1B
PMID:25736293 PBO:0107632 figS1B
PMID:25736293 PBO:0107635 Figure S2C
PMID:25736293 PBO:0107644 fig 6a
PMID:25736293 PBO:0107632 figS1B
PMID:25736293 FYPO:0000927 fig 5 c
PMID:25736293 FYPO:0005988 fig 5 c
PMID:25736293 PBO:0107633 figS1B
PMID:25736293 FYPO:0002177 figS1B
PMID:25736293 FYPO:0002177 figS1B
PMID:25736293 FYPO:0002177 figS1B
PMID:25736293 PBO:0107644 fig 6a
PMID:25736293 PBO:0107635 Figure S2C
PMID:25736293 PBO:0107643 S4B
PMID:25736293 GO:0005515 figure S2
PMID:25736293 PBO:0107645 abnormal movement of dynein
PMID:25736293 PBO:0107646 abnormal movement of dynein
PMID:25736293 GO:0005515 figure S2
PMID:25736293 PBO:0107647 fig 7a
PMID:25736293 GO:0035974 (Fig. 5C
PMID:25736293 PBO:0107632 fig 7a
PMID:25736293 PBO:0107636 fig 7A
PMID:25736293 FYPO:0000903 Fig. 7F; supplementary material Table S1
PMID:25736293 FYPO:0000903 Fig. 7F; supplementary material Table S1
PMID:25736293 PBO:0107634 (Fig. 1C; supplementary material Fig. S1C),
PMID:25736293 PBO:0107634 (Fig. 1C; supplementary material Fig. S1C),
PMID:25736293 PBO:0107634 (Fig. 1C; supplementary material Fig. S1C),
PMID:25736293 PBO:0107633 figS1B
PMID:25736293 FYPO:0000903 Fig. 7F; supplementary material Table S1
PMID:25736293 PBO:0107640 S4B
PMID:25736293 PBO:0107639 S4A
PMID:25736293 PBO:0107637 microtubule cortical anchor (microtubule site clamp) add to other dynactin complex
PMID:25736293 FYPO:0005990 fig 3 B , supp S 3 B) abolished microtubule cortical anchoring
PMID:25736293 PBO:0107641 S4B
PMID:25736293 PBO:0107637 microtubule cortical anchor (microtubule site clamp) add to other dynactin complex
PMID:25736293 FYPO:0000964 figS1B
PMID:25736293 FYPO:0000964 figS1B
PMID:25736293 PBO:0107642 S4B
PMID:25736293 PBO:0107636 fig 3 B , supp S 3 B)
PMID:25736293 GO:0005938 accumulates on shrinking microtubules Fig. 2B,
PMID:25736293 GO:0035974 accumulates on shrinking microtubules Fig. 2B,
PMID:25736293 GO:1903754 accumulates on shrinking microtubules Fig. 2B,
PMID:25771684 PBO:0097388 "Affecting Sre1 is ""abolished protein processing"" that is specific for defects in Sre1 protein processing."
PMID:25771684 PBO:0098096 "The term ""Decreased protein binding to Sre1"" is ""decreased protein binding"" that is specific for decreased binding to the protein Sre1."
PMID:25778919 GO:0044820 Together, these experiments suggest that Aurora-dependent re- moval of Swi6/HP1 and consequently cohesin Rad21 from telo- meres in early mitosis contributes to telomere dispersion.
PMID:25778919 PBO:0108462 fig7
PMID:25778919 FYPO:0006264 fig 4
PMID:25778919 FYPO:0005343 Fig 2 D
PMID:25778919 PBO:0108462 fig6
PMID:25778919 PBO:0108461 fig 6
PMID:25778919 PBO:0108454 telomere disjunction
PMID:25778919 PBO:0108453 (Fig. 2 A, 0–3 min, arrows)
PMID:25778919 GO:0120110 (requested negative regulation of) synonym mitotic telomere dispersion during metaphase
PMID:25778919 PBO:0108457 Fig 3
PMID:25778919 PBO:0108458 Fig 3D
PMID:25778919 PBO:0108459 Fig 3
PMID:25778919 PBO:0108460 Fig. 5 A
PMID:25778919 GO:0044820 Together, these experiments suggest that Aurora-dependent re- moval of Swi6/HP1 and consequently cohesin Rad21 from telo- meres in early mitosis contributes to telomere dispersion.
PMID:25778919 FYPO:0006267 Fig. 4 decreased telomere dispersion
PMID:25778919 FYPO:0004330 Fig. S4 A
PMID:25778919 FYPO:0006267 fig 4 decreased telomere dispersion
PMID:25778919 PBO:0108456 Fig 2 CD decreased telomere dispersion
PMID:25778919 FYPO:0005442 Fig 2 CD
PMID:25778919 PBO:0108455 Fig. S2 A, right
PMID:25793410 FYPO:0004752 10 ug/ml phleomycin for 4 h followed by recovery on YES
PMID:25793410 PBO:0024650 Rad3-dependent phosphorylation of Chk1 is observed in the presence of phleomycin, but this is suppressed by KCl concentrations above 0.3 M
PMID:25793410 FYPO:0002344 Sensitivity was rescued by 0.6 M KCl but not 60 mM KCl, 10 ug/ml phleomycin for 4 h followed by recovery on YES
PMID:25793410 FYPO:0002344 Sensitivity was rescued less efficiently than for the wt by 150 - 600 mM KCl
PMID:25793410 FYPO:0002344 Sensitivity was rescued by 0.6 M KCl, 10 ug/ml phleomycin for 4 h followed by recovery on YES
PMID:25793410 FYPO:0000633 10 ug/ml G418 for 4 h followed by recovery on YES
PMID:25793410 FYPO:0001719 Sensitivity was rescued by 0.6 M KCl 4 mM lithium for 4 h followed by recovery on YES
PMID:25793410 FYPO:0003559 Sensitivity was rescued by 0.6 M, but not 60 mM KCl, 40 ug/ml doxorubicin for 4 h followed by recovery on YES
PMID:25793410 FYPO:0003559 Sensitivity was rescued by 0.6 M KCl, 40 ug/ml doxorubicin for 4 h followed by recovery on YES
PMID:25793410 FYPO:0002344 Sensitivity was rescued by 150 mM, but not 70 mM KCl, 10 ug/ml phleomycin for 4 h followed by recovery on YES
PMID:25793410 FYPO:0004751 100 ug/ml G418 for 4 h followed by recovery on YES
PMID:25795664 PBO:0093614 spd1 deletion suppresses brc1delta ddb1delta sensitivity to DNA damage agents
PMID:25795664 PBO:0093618 spd1 deletion suppresses brc1delta ddb1delta sensitivity to DNA damage agents
PMID:25795664 PBO:0093617 spd1 deletion suppresses brc1delta csn1delta sensitivity to DNA damage agents
PMID:25795664 PBO:0093581 spd1 deletion suppresses brc1delta csn1delta sensitivity to DNA damage agents
PMID:25795664 PBO:0093630 spd1 deletion suppresses brc1delta csn1delta sensitivity to DNA damage agents
PMID:25795664 PBO:0093581 spd1 deletion suppresses brc1delta ddb1delta sensitivity to DNA damage agents
PMID:25795664 FYPO:0000085 same as brc1delta alone
PMID:25795664 FYPO:0000088 same as brc1delta alone
PMID:25795664 FYPO:0000268 same as brc1delta alone
PMID:25795664 FYPO:0001690 spd1 deletion suppresses csn1delta sensitivity to DNA damage agents
PMID:25795664 FYPO:0000957 spd1 deletion suppresses csn1delta sensitivity to DNA damage agents
PMID:25795664 FYPO:0000963 spd1 deletion suppresses csn1delta sensitivity to DNA damage agents
PMID:25795664 FYPO:0000969 spd1 deletion suppresses csn1delta sensitivity to DNA damage agents
PMID:25795664 PBO:0093614 spd1 deletion suppresses brc1delta csn1delta sensitivity to DNA damage agents
PMID:25795664 PBO:0093631 spd1 deletion suppresses brc1delta ddb1delta sensitivity to DNA damage agents
PMID:25795664 FYPO:0002573 same as in csn1delta alone
PMID:25795664 FYPO:0001234 A spd1 deletion partially suppresses the synthetic growth defect in a brc1 ddb1 double mutant background
PMID:25795664 FYPO:0001234 A spd1 deletion partially suppresses the synthetic growth defect in a brc1 csn1 double mutant background
PMID:25795664 FYPO:0000972 more than in csn1delta alone
PMID:25798942 GO:0006338 ATPase domain mutant phenotype fig 5 and S6
PMID:25803873 GO:0004175 no peptidase activity acting on azocoll substrate in isp6 null
PMID:25837586 PBO:0103556 more severe in presence of LatA
PMID:25837586 PBO:0099084 Decreased levels of Cdc42 and Cdc42-GTP
PMID:25837586 GO:0030427 Not affected by short-term actin cytoskeleton depolymerization by Latrunculin A
PMID:25837586 FYPO:0000672 Internally tagged functional allele, allowing live-imaging of Cdc42
PMID:25837586 PBO:0097265 Normal levels of Cdc42 and Cdc42-GTP (CRIB)
PMID:25837586 PBO:0103551 Increased levels of Cdc42 and Cdc42-GTP (CRIB)
PMID:25837586 PBO:0097265 Normal levels of Cdc42 and Cdc42-GTP (CRIB)
PMID:25837586 PBO:0099084 Decreased levels of Cdc42 and Cdc42-GTP (CRIB)
PMID:25837586 PBO:0103551 Increased levels of Cdc42 and Cdc42-GTP (CRIB)
PMID:25847133 PBO:0024930 GO:0000087 = mitosis
PMID:25847133 PBO:0107100 This mutant protein decreased chromatin binding at heat-shock genes, ssa1+ and hsp90+
PMID:25847133 FYPO:0000141 Abnormally streaked chromosomes in anaphase
PMID:25847133 PBO:0107099 Cut14 accumulates at the mitotically-upregulated gene regions in mitosis. Cut14 enrichment requires a forkhead transcription factor Sep1.
PMID:25847133 PBO:0107098 Cut14 accumulates at the mitotically-upregulated gene regions in mitosis. Cut14 enrichment requires a forkhead transcription factor Sep1.
PMID:25869666 GO:0000743 Phenocopies dhc1
PMID:25869666 PBO:0098119 Localization of GFP-tagged protein
PMID:25869666 PBO:0098121 Fig. S3A
PMID:25869666 PBO:0098120 Localization of GFP-tagged protein
PMID:25869666 GO:0000743 Delayed nuclear congresion in dhc1D (Fig. 1) and double deletion dhc1D klp2D completely abolishes nuclear congression (Fig. 1))
PMID:25869666 PBO:0098122 Fig. 1
PMID:25869666 PBO:0098123 Fig. 1
PMID:25869666 PBO:0098122 Fig. 1
PMID:25869666 PBO:0098124 Fig. 1
PMID:25869666 FYPO:0007162 Fig. S1
PMID:25869666 PBO:0098123 Fig. 4
PMID:25869666 PBO:0098123 Fig. 4
PMID:25869666 PBO:0098125 Fig. 1
PMID:25869666 PBO:0098126 Fig. 1
PMID:25869666 PBO:0098127 Fig. 4
PMID:25869666 PBO:0098123 Fig. 1
PMID:25869666 GO:0008569 Single deletion slows down nuclear congression (minus-end diretcted), double deletion with dhc1 inhibits it.
PMID:25869666 GO:0008569 Single deletion slows down nuclear congression (minus-end diretcted), double deletion with klp2 inhibits it.
PMID:25869666 GO:0000743 Delayed nuclear congresion in klp2D (Fig. 1) and double deletion dhc1D klp2D completely abolishes nuclear congression (Fig. 1))
PMID:25891897 PBO:0033406 zygotic
PMID:25891897 FYPO:0000478 azygotic meiosis, rem1 and crs1 do not have a major role in azygotic meiosis
PMID:25891897 PBO:0033403 zygotic meiosis/ Random spore analysis
PMID:25891897 PBO:0033402 zygotic meiosis
PMID:25891897 FYPO:0000478 azygotic
PMID:25891897 FYPO:0000478 azygotic// presence of 4x fusion protein restores the ability of cig1 cig2 puc1 rem1 quadruple deletion strain to undergo pre meiotic DNA replication
PMID:25891897 FYPO:0000478 zygotic//presence of 4x fusion protein restores the ability of cig1 cig2 puc1 rem1 quadruple deletion strain to undergo pre meiotic DNA replication
PMID:25891897 FYPO:0000478 azygotic/ slight advance in the timing of MI and MII
PMID:25891897 PBO:0033401 zygotic/ random spore analysis
PMID:25891897 FYPO:0000478 zygotic / >80% of asci have 4 spores
PMID:25891897 PBO:0033400 zygotic
PMID:25891897 PBO:0033398 zygotic
PMID:25891897 PBO:0033399 zygotic random spore analysis
PMID:25891897 PBO:0033397 zygotic meiosis random spore analysis
PMID:25891897 PBO:0033396 zygotic
PMID:25891897 PBO:0033395 zygotic
PMID:25891897 PBO:0033394 zygotic meiosis random spore analysis
PMID:25891897 FYPO:0004608 presence of more than 2 SPBs dots after meiotic nuclear divisions 19.6% zygotes exhibit abnormal meiotic division during zygotic meiosis
PMID:25891897 PBO:0033392 This phenotype is not seen when cells undergo azygotic meiosis
PMID:25891897 PBO:0033391 zygotic meiosis random spore analysis
PMID:25891897 PBO:0033390 zygotic meiosis random spore analysis,
PMID:25891897 FYPO:0003379 azygotic meiotic cell cycle/timing of pre-meiotic DNA replication is normal
PMID:25891897 FYPO:0003378 azygotic meiotic cell cyle
PMID:25891897 PBO:0033389 zygotic meiosis random spore analysis,
PMID:25891897 FYPO:0003563 azygotic/ slight advance in the timing of MI and MII
PMID:25891897 PBO:0033332 zygotic
PMID:25891897 PBO:0033404 zygotic
PMID:25891897 PBO:0033405 zygotic
PMID:25891897 PBO:0033407 zygotic
PMID:25891897 PBO:0033408 zygotic
PMID:25891897 FYPO:0000478 zygotic
PMID:25959226 FYPO:0000339 which interacts with the N-terminus of Mid1 and stabilizes Mid1 at the division plane (Ye et al., 2012; Zhu et al., 2013). As expected, mid13A gef2Δ double mutants had strong synthetic defects in division-plane placement and septum formation at 36°C (Figure 6, F–H).
PMID:25959226 FYPO:0004456 In contrast, the monomeric Mid13A remained concentrated in the nucleus and its signals on the plasma membrane were more widespread, even reached the cell poles (Figure 6E
PMID:25959226 GO:0005546 Interestingly, it binds to PI(4,5)P2 strongly, with a Kd up to 0.12 μM (Figure 3C and 3D).
PMID:25959226 PBO:0098839 Mutations of the hydrophobic C2-C2 interface shifted Mid1 into monomeric state (Figure 6A),
PMID:25959226 PBO:0098840 which showed > 10-fold lower affinity to PI(4,5)P2 (Figure 3D).
PMID:25959226 PBO:0098841 In contrast, monomerization only slightly reduced the affinity to PS.
PMID:25959226 FYPO:0006005 Indeed, the morphology and positioning of the contractile ring marked with myosin regulatory light chain Rlc1 were normal in mid13A cells (Figure S6, C-D)
PMID:25959226 FYPO:0006186 However, contractile ring assembly was significantly faster in mid13A than in mid1+ cells (Figure S6, C–F),
PMID:25959226 FYPO:0000339 which interacts with the N-terminus of Mid1 and stabilizes Mid1 at the division plane (Ye et al., 2012; Zhu et al., 2013). As expected, mid13A gef2Δ double mutants had strong synthetic defects in division-plane placement and septum formation at 36°C (Figure 6, F–H).
PMID:25965521 FYPO:0000089 same as mus81delta alone; mus81 epistatic
PMID:25965521 FYPO:0000088 same as mus81delta alone; mus81 epistatic
PMID:25965521 FYPO:0000268 same as mus81delta alone; mus81 epistatic
PMID:25965521 FYPO:0000089 same as mus81delta alone; mus81 epistatic
PMID:25965521 FYPO:0000085 same as mus81delta alone; mus81 epistatic
PMID:25965521 FYPO:0000088 same as mus81delta alone; mus81 epistatic
PMID:25965521 FYPO:0000268 same as mus81delta alone; mus81 epistatic
PMID:25965521 FYPO:0000085 same as mus81delta alone; mus81 epistatic
PMID:25965521 FYPO:0000088 same as mus81delta alone; mus81 epistatic
PMID:25965521 FYPO:0000268 same as mus81delta alone; mus81 epistatic
PMID:25965521 FYPO:0000089 same as mus81delta alone; mus81 epistatic
PMID:25965521 FYPO:0000085 same as mus81delta alone; mus81 epistatic
PMID:25965521 FYPO:0000088 same as mus81delta alone; mus81 epistatic
PMID:25965521 PBO:0093631 same as brc1delta alone; brc1 epistatic
PMID:25965521 PBO:0093618 same as brc1delta alone; brc1 epistatic
PMID:25965521 PBO:0093615 same as brc1delta alone; brc1 epistatic
PMID:25965521 PBO:0093579 same as brc1delta alone; brc1 epistatic
PMID:25965521 FYPO:0000089 same as brc1delta alone; brc1 epistatic
PMID:25965521 PBO:0093618 same as brc1delta alone; brc1 epistatic
PMID:25965521 PBO:0093631 same as brc1delta alone; brc1 epistatic
PMID:25965521 PBO:0093615 same as brc1delta alone; brc1 epistatic
PMID:25965521 PBO:0093579 same as brc1delta alone; brc1 epistatic
PMID:25965521 FYPO:0002573 same as either single mutant
PMID:25965521 FYPO:0002573 same as either single mutant
PMID:25965521 FYPO:0000268 same as mus81delta alone; mus81 epistatic
PMID:25965521 FYPO:0000089 same as mus81delta alone; mus81 epistatic
PMID:25965521 FYPO:0000085 same as mus81delta alone; mus81 epistatic
PMID:25977474 FYPO:0000032 abnormal cleavage furrow disc formation fig 3
PMID:25977474 FYPO:0000032 abnormal cleavage furrow disc formation fig 3
PMID:25977474 FYPO:0000032 abnormal cleavage furrow disc formation fig 3
PMID:25977474 FYPO:0000032 abnormal cleavage furrow disc formation fig 3
PMID:25977474 FYPO:0000032 abnormal cleavage furrow disc formation fig 3
PMID:25987607 FYPO:0004396 I think the pkl rigor is spb tethered here?
PMID:25987607 PBO:0108308 I want to represent the microtubule based-transporter function and cargo
PMID:25987607 PBO:0108312 Fig. 5 B and Videos 1–4
PMID:25987607 PBO:0108309 I want to represent the microtubule based-transporter function and cargo
PMID:25987607 FYPO:0002636 Fig. 5 B and Videos 1–4
PMID:25987607 PBO:0018346 during mitotic M phase
PMID:25987607 FYPO:0006173 Fig. 5 B and Videos 1–4
PMID:25987607 PBO:0108310 Fig. 5 B and Videos 1–4
PMID:25987607 PBO:0018346 during mitotic M phase
PMID:25987607 PBO:0018346 during mitotic M phase
PMID:25987607 FYPO:0003787 non additive
PMID:25989903 PBO:0110921 Similar to previous reports, we detected significantly increased intronic reads in the exosome mutant rrp6D strain (Fig. 4a,b).
PMID:25989903 GO:0071030 exosome dependent
PMID:25989903 GO:0071030 exosome dependent
PMID:25989903 FYPO:0008113 Similar to previous reports, we detected significantly increased intronic reads in the exosome mutant rrp6D strain (Fig. 4a,b).
PMID:25989903 GO:0071030 exosome dependent
PMID:25989903 GO:0071030 This analysis revealed that in the ctr1D or nrl1D mutant strains, both the intronic and also the surrounding exonic sequence coverage showed similar increases, while the expression of genes without introns was unaffected (Supplementary Fig. 4c,d). This result strongly suggests that the elevated level of intronic reads in the mutant strains is the consequence of the inefficient degradation of unspliced or mis-
PMID:25989903 PBO:0110921 Similar to previous reports, we detected significantly increased intronic reads in the exosome mutant rrp6D strain (Fig. 4a,b).
PMID:25989903 FYPO:0008113 Similar to previous reports, we detected significantly increased intronic reads in the exosome mutant rrp6D strain (Fig. 4a,b).
PMID:25989903 FYPO:0008113 Similar to previous reports, we detected significantly increased intronic reads in the exosome mutant rrp6D strain (Fig. 4a,b).
PMID:25989903 FYPO:0008113 Similar to previous reports, we detected significantly increased intronic reads in the exosome mutant rrp6D strain (Fig. 4a,b).
PMID:25989903 GO:0071039 exosome dependent
PMID:25989903 GO:0071031 meiotic genes ....Overall, our experiments show that the MTREC complex is specifically recruited to CUTs and meiotic mRNAs, and it plays a key role in their degradation by the nuclear exosome.
PMID:25989903 FYPO:0002960 Deletion of iss10 or mmi1 only affects meiotic mRNAs
PMID:25989903 FYPO:0002960 Deletion of iss10 or mmi1 only affects meiotic mRNAs
PMID:25989903 FYPO:0008148 In contrast, deletion or mutation alleles of the MTREC complex lead to significant accumulation of all types of CUTs and also meiotic mRNAs. This effect is comparable to the level of CUT accumulation in the nuclear exosome subunit rrp6 deletion (Fig. 2a,b)
PMID:25989903 FYPO:0002960 In contrast, deletion or mutation alleles of the MTREC complex lead to significant accumulation of all types of CUTs and also meiotic mRNAs. This effect is comparable to the level of CUT accumulation in the nuclear exosome subunit rrp6 deletion (Fig. 2a,b)
PMID:25989903 FYPO:0008148 In contrast, deletion or mutation alleles of the MTREC complex lead to significant accumulation of all types of CUTs and also meiotic mRNAs. This effect is comparable to the level of CUT accumulation in the nuclear exosome subunit rrp6 deletion (Fig. 2a,b)
PMID:25989903 FYPO:0008148 In contrast, deletion or mutation alleles of the MTREC complex lead to significant accumulation of all types of CUTs and also meiotic mRNAs. This effect is comparable to the level of CUT accumulation in the nuclear exosome subunit rrp6 deletion (Fig. 2a,b)
PMID:25989903 FYPO:0002960 In contrast, deletion or mutation alleles of the MTREC complex lead to significant accumulation of all types of CUTs and also meiotic mRNAs. This effect is comparable to the level of CUT accumulation in the nuclear exosome subunit rrp6 deletion (Fig. 2a,b)
PMID:25989903 FYPO:0002960 In contrast, deletion or mutation alleles of the MTREC complex lead to significant accumulation of all types of CUTs and also meiotic mRNAs. This effect is comparable to the level of CUT accumulation in the nuclear exosome subunit rrp6 deletion (Fig. 2a,b)
PMID:25989903 FYPO:0008152 Surprisingly, deletion of the S. pombe Trf4/5 orthologue, cid14, showed only a minor effect on CUTs at a genome-wide level (Fig. 2a,b)
PMID:25989903 FYPO:0008148 As previously reported, deletion of rrp6 leads to strong accumulation of CUTs and a small group of mRNAs that are mostly involved in meiosis16,23,25,29,30,35.
PMID:25989903 FYPO:0002960 As previously reported, deletion of rrp6 leads to strong accumulation of CUTs and a small group of mRNAs that are mostly involved in meiosis16,23,25,29,30,35.
PMID:25993311 FYPO:0005986 fig 3
PMID:25993311 FYPO:0005986 fig 3
PMID:25993311 PBO:0106054 table2
PMID:25993311 PBO:0112555 table2
PMID:25993311 PBO:0099293 table2
PMID:25993311 FYPO:0000488 Table S3
PMID:25993311 FYPO:0000488 Table S3
PMID:25993311 PBO:0101138 table 1
PMID:25993311 PBO:0101665 table 1
PMID:25993311 PBO:0106060 fig 2 a
PMID:25993311 PBO:0101138 table 1
PMID:25993311 PBO:0101138 table 1
PMID:25993311 PBO:0101138 table 2
PMID:25993311 PBO:0101138 table 2
PMID:25993311 PBO:0106061 table 3
PMID:25993311 FYPO:0000488 table 3
PMID:25993311 FYPO:0000488 table 3
PMID:25993311 FYPO:0004585 fig 3
PMID:25993311 FYPO:0004585 fig 3
PMID:25993311 FYPO:0000488 Table S3
PMID:25993311 FYPO:0000488 Table S3
PMID:25993311 PBO:0106060 fig 2 a
PMID:25993311 PBO:0105331 fig2
PMID:25993311 PBO:0105331 fig2
PMID:25993311 PBO:0106060 fig 2 a
PMID:25993311 FYPO:0001033 table 2
PMID:25993311 GO:0090006 table 1
PMID:25993311 GO:0090006 table 1
PMID:25993311 PBO:0106059 table2
PMID:25993311 PBO:0106058 table2
PMID:25993311 PBO:0106057 table2
PMID:25993311 PBO:0106056 table2
PMID:26007660 GO:0120108 https://github.com/geneontology/go-ontology/issues/12379 I submitted an EC NTR
PMID:26031557 PBO:0098186 Fig. 4
PMID:26031557 PBO:0098183 Fig. S2 Pkl1md-GFP localized primarily to the spindle poles and almost completely rescued the protrusion phenotype
PMID:26031557 PBO:0098182 Fig. 2. It's only a bit worse (+3% chromosome loss). Not sure if worth including
PMID:26031557 PBO:0098181 Fig. 2. I guess reporter gene assay is the right category, since they do this with the minichrosome bearing the ade6 gene from cerevisiae to rescue ade6-M210
PMID:26031557 PBO:0098180 Fig. 2
PMID:26031557 PBO:0098179 Fig. 1. I guess reporter gene assay is the right category, since they do this with the minichrosome bearing the ade6 gene from cerevisiae to rescue ade6-M210
PMID:26031557 PBO:0098185 Fig. 3 MT buckling during prolonged contact with the cell tip cortex—its associated chromosome mass to the medial cell division site (Fig. 3c). Subsequent cytokinesis appeared to cut through the chromosome mass, resulting in aneuploidy in 12% of mitotic cells.
PMID:26031557 FYPO:0000324 Fig. 3 This is important as it indicates that the delay in pkl1D is likely not due to a delay in chromosome capture, but rather spindle formation in prophase.
PMID:26031557 FYPO:0000324 Fig. 3
PMID:26031557 FYPO:0005709 Fig. S2 Pkl1md-GFP localized primarily to the spindle poles
PMID:26031557 PBO:0098187 Fig. S4
PMID:26031557 PBO:0098184 Fig. S2 In contrast, in pkl1D msd1D cells, Pkl1md-GFP localized primarily to the spindle and only partially rescued the protrusion phenotype
PMID:26088418 PBO:0107811 increased length hererogeneity*****************. Indeed, yeast cells expressing the L431R and L445R mutants exhibited significant loss of function in telomere length regulation and showed long and highly heterogenous telomeres that were as severe as that in taz1Δ cells (Figure 1K)
PMID:26088418 PBO:0107811 increased length hererogeneity*****************. Indeed, yeast cells expressing the L431R and L445R mutants exhibited significant loss of function in telomere length regulation and showed long and highly heterogenous telomeres that were as severe as that in taz1Δ cells (Figure 1K)
PMID:26088418 PBO:0107810 Mutant proteins were expressed at a comparable level as wild-type Taz1 (data not shown).
PMID:26088418 PBO:0107810 Mutant proteins were expressed at a comparable level as wild-type Taz1 (data not shown).
PMID:26088418 PBO:0107814 he L445R mutation caused a 10-fold decrease in DNA binding with a Kd of ~7 μM (Figure 1I), suggesting that Taz1 homodimerization is
PMID:26088418 GO:0042162 While wild-type Taz1 bound to DNA with an equilibrium dissociation constant (Kd) of ~600 nM (Figure 1I), the L445R mutation caused a 10-fold decrease in DNA binding with a Kd of ~7 μM (Figure 1I), suggesting that Taz1 homodimerization is required for its efficient association with the telomeric DNA in vitro.
PMID:26088418 PBO:0107811 increased length hererogeneity
PMID:26088418 FYPO:0006464 increased length hererogeneity. taz1-4A cells still exhibited extremely heterogeneous telomeres similar to taz1Δ and taz1-4R cells (Figure 1E).
PMID:26088418 PBO:0107811 increased length hererogeneity
PMID:26088418 PBO:0107810 Both mutant proteins were expressed at near wild-type levels, suggesting that these acidic residues are not required for protein stability (data not shown).
PMID:26088418 PBO:0107810 Both mutant proteins were expressed at near wild-type levels, suggesting that these acidic residues are not required for protein stability (data not shown).
PMID:26092938 PBO:0104502 decreased local concentration of the myosin-II
PMID:26092938 PBO:0104502 decreased local concentration of the myosin-II
PMID:26092938 PBO:0104503 localization of the myosin-II is abolished
PMID:26092938 PBO:0096672 large portion of the mutant forms cytoplasmic dots
PMID:26092938 PBO:0104504 increased local concentration of the myosin-II
PMID:26098872 PBO:0093560 figure 8a
PMID:26098872 PBO:0101262 figure 8c
PMID:26098872 PBO:0093559 figure 8a
PMID:26098872 PBO:0093560 figure 8 b
PMID:26098872 FYPO:0001357 figure 8a
PMID:26108447 FYPO:0003860 Figure 6
PMID:26108447 FYPO:0003860 Figure 6
PMID:26108447 FYPO:0002640 Figure 6
PMID:26108447 FYPO:0002766 Figure 6
PMID:26108447 FYPO:0003860 Figure 6
PMID:26108447 FYPO:0002766 Figure 6
PMID:26108447 FYPO:0002766 Figure 6
PMID:26108447 FYPO:0002766 Figure 6
PMID:26108447 FYPO:0003860 Figure 6
PMID:26108447 FYPO:0002766 Figure 6
PMID:26108447 FYPO:0002766 Figure 6
PMID:26108447 FYPO:0003860 Figure 6
PMID:26108447 FYPO:0002766 Figure 6
PMID:26108447 FYPO:0003860 Figure 6
PMID:26108447 FYPO:0003358 Figure 6
PMID:26122634 FYPO:0004688 polysomal profiling
PMID:26122634 FYPO:0004688 polysomal profiling
PMID:26124291 FYPO:0005565 Fig 7 E
PMID:26124291 GO:0099079 Fig 6 C
PMID:26124291 PBO:0035552 (Fig. 4 C)
PMID:26124291 PBO:0035552 (Fig. 4 C)
PMID:26124291 FYPO:0004614 Fig 7 CD abnormal Q-MT bundle elongation upon G1 re-entry/interphase bundle reassembly
PMID:26124291 PBO:0035552 (Fig. 4 C)
PMID:26124291 PBO:0035552 (Fig. 4 C)
PMID:26124291 GO:0099079 Fig 6 C
PMID:26124291 GO:0099079 Fig S5A C
PMID:26124291 PBO:0095573 FFig. S5 E
PMID:26124291 PBO:0035552 (Fig. 4 C)
PMID:26124291 PBO:0035552 (Fig. 4 C)
PMID:26124291 PBO:0095574 Fig Fig. S5 E
PMID:26124291 PBO:0035555 Fig 7 E/F
PMID:26131711 GO:0005515 Chk1 binds to the unphosphorylated form of Cdc2 kinase
PMID:26131711 PBO:0098160 modified forms of Cdc2 present differ from wild type, but are same as in cdc2-1w alone
PMID:26131711 PBO:0098160 modified forms of Cdc2 present differ from wild type, but are same as in cdc2-1w alone
PMID:26131711 PBO:0098160 modified forms of Cdc2 present differ from wild type
PMID:26131711 GO:0072435 Chk1 binds to the unphosphorylated form of Cdc2 kinase
PMID:26131711 GO:0005515 Chk1 binds to the unphosphorylated form of Cdc2 kinase
PMID:26131711 GO:0005515 Chk1 binds to the unphosphorylated form of Cdc2 kinase
PMID:26131711 GO:0005515 Chk1 binds to the unphosphorylated form of Cdc2 kinase
PMID:26131711 PBO:0098160 modified forms of Cdc2 differ from both wild type and cdc2-1w alone
PMID:26131711 GO:0005515 Chk1 binds to the unphosphorylated form of Cdc2 kinase
PMID:26132084 PBO:0097177 fig 5 SH3 domain of Cdc15 is required for the proper concentration of Pxl1 at the CAR
PMID:26132084 PBO:0097175 fig 3C&D vw: changed to incomplete septum
PMID:26132084 FYPO:0005873 figure 4B
PMID:26132084 FYPO:0005871 fig 4C
PMID:26132084 PBO:0097174 figure 1 A,B
PMID:26132084 FYPO:0005289 figure 1c
PMID:26132084 PBO:0097173 P.P. Bgs4 and Ags1 abnormal localization in the septum membrane
PMID:26132084 PBO:0097178 Fig 2D and 2E
PMID:26132084 PBO:0097172 P.P. Bgs4 and Ags1 abnormal localization in the septum membrane
PMID:26132084 PBO:0097179 figure 3
PMID:26132084 FYPO:0003890 fig6 Coupling of the Actomyosin ring contraction and septation onsetRing sliding even after the onset of septum synthesis, causing a longitudinal deposition along the plasma membrane of linear β-glucan as detected by CW staining until septum ingression started
PMID:26132084 FYPO:0003210 figure 1
PMID:26132084 FYPO:0004495 fig 3C
PMID:26132084 FYPO:0000117 fig6
PMID:26132084 FYPO:0003338 Fig 2A and B fragmented with RLC strands
PMID:26137436 FYPO:0002060 table 1
PMID:26137436 PBO:0101077 we failed to detect a band corresponding to the full-length Nup189 fused with GFP (Nup98–Nup96–GFP), indicating that autocleavage occurs with no remains of the joint molecule. The same bands corresponding to Nup98 and Nup96-GFP were also detected in the splicing-defective mutant, as expected (Fig. 2B and C,
PMID:26150232 GO:1903077 of cell tip
PMID:26152587 FYPO:0001355 fig1a
PMID:26152587 PBO:0018647 Gaf1-GFP is found in the nucleus following nitrogen starvation but not glucose starvation
PMID:26152587 PBO:0100226 1h in proline medium
PMID:26152587 PBO:0100227 assayed by nuclear localization of Gaf1-GFP
PMID:26152587 PBO:0100239 assayed by nuclear localization of Gaf1-GFP
PMID:26152587 PBO:0100239 assayed by nuclear localization of Gaf1-GFP
PMID:26152587 PBO:0100238 assayed by nuclear localization of Gaf1-GFP
PMID:26152587 PBO:0100238 assayed by nuclear localization of Gaf1-GFP
PMID:26152587 PBO:0100237 assayed by nuclear localization of Gaf1-GFP
PMID:26152587 PBO:0100228 assayed by nuclear localization of Gaf1-GFP
PMID:26152587 PBO:0100228 assayed by nuclear localization of Gaf1-GFP
PMID:26152587 PBO:0100226 1h in proline medium, a mild phenotype
PMID:26152587 PBO:0100230 1h in proline medium, a mild phenotype
PMID:26152587 PBO:0100230 1h in proline medium, a mild phenotype
PMID:26152587 PBO:0100231 a mild phenotype
PMID:26152587 PBO:0100232 fig1a
PMID:26152587 FYPO:0001357 fig1a
PMID:26152587 PBO:0100231 a mild phenotype
PMID:26152587 FYPO:0001357 fig1a
PMID:26152587 FYPO:0001357 fig1a
PMID:26152587 FYPO:0001357 fig1a
PMID:26152587 FYPO:0001357 fig1a
PMID:26152587 FYPO:0001357 fig1a
PMID:26152587 FYPO:0001357 fig1a
PMID:26152587 PBO:0020038 Gaf1-GFP is found in the nucleus following nitrogen starvation but not glucose starvation
PMID:26152587 PBO:0020040 Gaf1-GFP is found in the nucleus following nitrogen starvation but not glucose starvation
PMID:26160178 PBO:0096388 affecting binding to histone H2A (hta1)
PMID:26160178 PBO:0096385 affecting binding to Mdb1
PMID:26221037 PBO:0099745 modification(s) not identified
PMID:26221037 PBO:0099745 modification(s) not identified
PMID:26221037 PBO:0099741 higher than without nup132d
PMID:26221037 PBO:0099739 higher than without nup132d
PMID:26258632 PBO:0093562 fig1a
PMID:26258632 PBO:0093564 fig1a
PMID:26258632 PBO:0097989 kinetochore localization of Cut7 is unaffected
PMID:26258632 PBO:0097988 fig2a (diminished relocation from kinetochore)
PMID:26258632 PBO:0033340 fig 5 c
PMID:26258632 PBO:0093564 fig1a
PMID:26258632 PBO:0093562 fig1a
PMID:26258632 PBO:0097990 fig1e
PMID:26258632 PBO:0097991 figure 2a GO:0000236=mitotic prometaphase
PMID:26258632 PBO:0018845 figure 2a (GO:0000090= mitotic anaphase)
PMID:26258632 PBO:0096319 fig2a
PMID:26258632 PBO:0097992 fig2a
PMID:26258632 PBO:0033341 fig1b
PMID:26258632 FYPO:0004318 fig 3 a/b
PMID:26258632 PBO:0033345 fig 3c
PMID:26258632 FYPO:0005220 ABOLISHED tetermerization
PMID:26258632 FYPO:0005220 ABOLISHED tetermerization fig4f monomer
PMID:26258632 FYPO:0000030 "fig 5c ""gliding"" new GO term requested"
PMID:26258632 PBO:0097990 fig1e
PMID:26258632 FYPO:0003762 Fig. 2b (mad1 locaizes to unattached kinetochores) and fig 3a
PMID:26258632 PBO:0112052 fig2d
PMID:26258632 PBO:0093562 fig 3 b
PMID:26258632 FYPO:0004318 fig 3 a/b
PMID:26258632 PBO:0023853 fig2d GO:0000089= mitotic metaphase unattached kinetohore nda3-KM311 arrested cell
PMID:26258632 FYPO:0004318 fig 3 a/b
PMID:26258632 PBO:0033342 fig1b
PMID:26258632 PBO:0033342 fig1b
PMID:26258632 PBO:0033343 fig1b
PMID:26258632 PBO:0093562 fig1a
PMID:26258632 PBO:0093562 fig1a
PMID:26264592 PBO:0094771 Fig. 6
PMID:26264592 PBO:0101499 Fig. 1
PMID:26264592 PBO:0094738 Fig.1
PMID:26264592 PBO:0094738 Fig.1
PMID:26264592 PBO:0094738 Fig.2
PMID:26264592 PBO:0094738 Fig.2
PMID:26264592 PBO:0094738 Fig.2
PMID:26264592 PBO:0094738 Fig.2
PMID:26264592 PBO:0094738 Fig.2
PMID:26264592 PBO:0094738 Fig.2
PMID:26264592 PBO:0094738 Fig.2
PMID:26264592 PBO:0094738 Fig.2
PMID:26264592 PBO:0094738 Fig.2
PMID:26264592 PBO:0094738 Fig.2
PMID:26264592 PBO:0111501 Fig. 3C
PMID:26264592 PBO:0093557 Fig. 7A
PMID:26264592 FYPO:0002061 Fig. 7A
PMID:26264592 FYPO:0002061 Fig. 7A
PMID:26264592 FYPO:0002061 Fig. 7A
PMID:26264592 FYPO:0002061 Fig. 7A
PMID:26264592 FYPO:0002061 Fig. 7A
PMID:26264592 FYPO:0002061 Fig. 7A
PMID:26264592 PBO:0093554 Fig. 7A
PMID:26264592 PBO:0093560 Fig. 7A
PMID:26264592 PBO:0093559 Fig. 7A
PMID:26264592 PBO:0111502 Fig. 3C
PMID:26264592 PBO:0111503 Fig. 3C
PMID:26264592 PBO:0094772 Fig. 4C
PMID:26264592 PBO:0094772 Fig. 4C
PMID:26264592 PBO:0094775 Fig. 4C
PMID:26264592 PBO:0094772 Fig. 4C
PMID:26264592 PBO:0094775 Fig. 4C
PMID:26264592 PBO:0094775 Fig. 4C
PMID:26264592 PBO:0094773 Fig. 4A
PMID:26264592 PBO:0094773 Fig. 4A
PMID:26264592 PBO:0094773 Fig. 4A
PMID:26264592 PBO:0098250 Fig. 4A
PMID:26264592 PBO:0098250 Fig. 4A
PMID:26264592 PBO:0098250 Fig. 4A
PMID:26264592 PBO:0093559 Fig. 7A
PMID:26264592 PBO:0093553 Fig. 7A
PMID:26264592 PBO:0093553 Fig. 7A
PMID:26264592 PBO:0111634 negative extracellular phosphate aquisition (S5P,P6?,S7P)
PMID:26264592 GO:0030643 negative extracellular phosphate aquisition
PMID:26264592 PBO:0111672 negative extracellular phosphate aquisition (S5P,P6?,S7P)
PMID:26264592 PBO:0111671 negative extracellular phosphate aquisition (S5P,P6?,S7P)
PMID:26264592 GO:0030643 negative regulation of extracellular phosphate aquisition
PMID:26264592 GO:0030643 negative regulation of extracellular phosphate aquisition
PMID:26264592 PBO:0094772 Fig. S4
PMID:26264592 PBO:0094773 Fig. S4
PMID:26264592 PBO:0111504 Fig. S3
PMID:26264592 PBO:0111504 Fig. S3
PMID:26264592 PBO:0111504 Fig. S3
PMID:26264592 PBO:0101499 Fig. 7B
PMID:26264592 PBO:0111504 Fig. 5A
PMID:26264592 PBO:0111505 Fig. 5B
PMID:26264592 PBO:0111506 Fig. 5B
PMID:26264592 PBO:0111507 Fig. 5C
PMID:26264592 PBO:0098248 Fig. 6
PMID:26264592 PBO:0098248 Fig. 6
PMID:26264592 PBO:0098248 Fig. 6
PMID:26264592 PBO:0094738 Fig. 6
PMID:26264592 PBO:0094738 Fig. 6
PMID:26264592 PBO:0094738 Fig. 6
PMID:26264592 PBO:0094771 Fig.1
PMID:26264592 PBO:0101499 Fig. 6
PMID:26264592 PBO:0094771 Fig. 6
PMID:26264592 PBO:0111504 Fig. S3
PMID:26264592 PBO:0111509 Fig. S2
PMID:26264592 PBO:0111508 Fig. S2
PMID:26264592 PBO:0111508 Fig. S2
PMID:26264592 PBO:0111508 Fig. S2
PMID:26264592 PBO:0094777 Fig. S1
PMID:26264592 PBO:0094777 Fig. S1
PMID:26264592 PBO:0094777 Fig. S1
PMID:26264592 PBO:0094777 Fig. S1
PMID:26264592 PBO:0094777 Fig. S1
PMID:26264592 PBO:0093556 Fig. 7A
PMID:26264592 PBO:0101499 Fig. 1
PMID:26264592 PBO:0101499 Fig. 1
PMID:26264592 PBO:0101499 Fig. 1
PMID:26264592 PBO:0101499 Fig. 1
PMID:26264592 PBO:0101499 Fig. 1
PMID:26264592 PBO:0101499 Fig. 1
PMID:26264592 PBO:0094771 Fig.1
PMID:26264592 PBO:0094771 Fig.1
PMID:26275423 GO:0000939 Chromatin immunoprecipitation of this protein is highly enriched for centromeric sequences.
PMID:26275423 GO:0000775 Chromatin immunoprecipitation of this protein is highly enriched for centromeric sequences.
PMID:26275423 GO:0000775 Chromatin immunoprecipitation of this protein is highly enriched in centromeric DNA
PMID:26275423 GO:0000775 Chromatin immunoprecipitation of this protein is highly enriched in centromeric DNA
PMID:26275423 GO:0000775 Chromatin immunoprecipitation of this protein is highly enriched for centromeric sequences.
PMID:26275423 GO:0000775 Chromatin immunoprecipitation of this protein is highly enriched for centromeric sequences.
PMID:26365378 GO:0005515 s3
PMID:26365378 PBO:0098887 "microscopy shows ""protein localization to vacuole with protein mislocalized to cytosol"" but with additional vacuolar processing phenotypes I think we can make the BP phenotypes /AL"
PMID:26365378 PBO:0110838 Indirect evidence, could be upstream
PMID:26365378 PBO:0110838 Indirect evidence, could be upstream
PMID:26365378 PBO:0110838 Indirect evidence, could be upstream
PMID:26365378 PBO:0098887 4h
PMID:26365378 FYPO:0006294 macroautophagy? - selective autophagy is a child of macroautophagy
PMID:26365378 GO:0005515 s3
PMID:26366556 PBO:0018467 low penetrance
PMID:26366556 FYPO:0006822 low penetrance
PMID:26366556 GO:0019216 ChIP-seq and microarray data indicate that Cbf11 regulates lipid metabolism genes.
PMID:26366556 PBO:0021323 determined by EMSA. Substrate: dsDNA oligonucleotide derived from promoters of cut6 and ptl1 genes (contain the CSL_response_element)
PMID:26366556 PBO:0101187 determined by expression microarrays from cbf11 knock-out cells growing exponentially in YES. targets: SPAC22A12.06c, ptl1, lcf1, lcf2, cut6, SPCC1281.06c
PMID:26366556 PBO:0101186 determined by expression microarrays from cbf11 knock-out cells growing exponentially in YES. targets: SPAC22A12.06c, ptl1, lcf1, lcf2, cut6, SPCC1281.06c
PMID:26366556 PBO:0101185 determined by expression microarrays from cbf11 knock-out cells growing exponentially in YES. targets: SPAC22A12.06c, ptl1, lcf1, lcf2, cut6, SPCC1281.06c
PMID:26366556 PBO:0101184 determined by expression microarrays from cbf11 knock-out cells growing exponentially in YES. targets: SPAC22A12.06c, ptl1, lcf1, lcf2, cut6, SPCC1281.06c
PMID:26366556 PBO:0101183 determined by expression microarrays from cbf11 knock-out cells growing exponentially in YES. targets: SPAC22A12.06c, ptl1, lcf1, lcf2, cut6, SPCC1281.06c
PMID:26366556 PBO:0101182 determined by expression microarrays from cbf11 knock-out cells growing exponentially in YES. targets: SPAC22A12.06c, ptl1, lcf1, lcf2, cut6, SPCC1281.06c
PMID:26366556 FYPO:0001122 large fractions of both abnormally long and abnormally short cells are present in the population
PMID:26366556 PBO:0101181 low penetrance
PMID:26368543 PBO:0096806 Chk1
PMID:26368543 PBO:0096807 Chk1
PMID:26401015 PBO:0094446 abolishes preference for K4-trimethylated H3
PMID:26401015 PBO:0094447 acetyltransferase normally processive in presence of K4-trimethylated H3 (bound by Sgf29)
PMID:26401015 PBO:0094446 abolishes preference for K4-trimethylated H3
PMID:26401015 PBO:0094447 acetyltransferase normally processive in presence of K4-trimethylated H3 (bound by Sgf29)
PMID:26412298 GO:0061578 Inferred from in vitro biochemical assay using K63-linked di-ubiquitinase (vw JAnel made this annotation , I transferred from process to MF)
PMID:26422458 GO:0051537 Biochemical and mutagenic studies demonstrated that the [2Fe-2S]2+ cluster substantially inhibits the phosphatase activity of Asp1, thereby increasing its net kinase activity.
PMID:26424849 GO:0016428 in response to queuosine incorporation into tRNA-Asp
PMID:26424849 PBO:0035522 waiting for go-ontology/issues/12536
PMID:26436826 PBO:0103249 alkaline DNA preparation
PMID:26436826 PBO:0103248 alkaline DNA preparation
PMID:26438724 GO:0033696 changed from: heterochromatin organization involved in chromatin silencing
PMID:26438724 GO:0031507 changed from: heterochromatin organization involved in chromatin silencing
PMID:26438724 FYPO:0004201 fig6
PMID:26438724 FYPO:0006362 fig6
PMID:26438724 PBO:0098760 EV3
PMID:26438724 PBO:0098773 EV3
PMID:26438724 PBO:0104231 supp 1b
PMID:26438724 PBO:0104232 supp 1b
PMID:26438724 PBO:0104233 supp 1b
PMID:26438724 FYPO:0004137 EV3
PMID:26438724 FYPO:0002355 EV3
PMID:26438724 FYPO:0004743 EV3
PMID:26438724 FYPO:0003045 4a
PMID:26438724 FYPO:0005286 4a
PMID:26438724 FYPO:0004749 4a
PMID:26438724 PBO:0104234 EV3
PMID:26438724 PBO:0104235 EV3
PMID:26438724 PBO:0104236 fig5
PMID:26438724 PBO:0104237 fig5
PMID:26438724 PBO:0104236 fig5
PMID:26438724 PBO:0104237 fig5
PMID:26438724 PBO:0104236 fig5
PMID:26438724 PBO:0104237 fig5
PMID:26438724 FYPO:0000220 supp 1b
PMID:26443059 FYPO:0005053 actually inferred from protein binding phenotypes
PMID:26443059 FYPO:0005053 actually inferred from protein binding phenotypes
PMID:26443240 PBO:0095326 Pom1 does not relocalize to cell sides
PMID:26443240 PBO:0095326 Pom1 does not relocalize to cell sides
PMID:26443240 PBO:0095332 Pom1 relocalization to cell sides
PMID:26443240 GO:0031117 through negative regulation of Cls1
PMID:26443240 PBO:0095326 Pom1 does not relocalize to cell sides
PMID:26443240 PBO:0095326 Pom1 does not relocalize to cell sides
PMID:26443240 PBO:0095330 Pom1 relocalizes to cell sides
PMID:26443240 PBO:0095330 Pom1 relocalizes to cell sides
PMID:26443240 PBO:0095330 Pom1 relocalizes to cell sides
PMID:26443240 PBO:0095330 Pom1 relocalizes to cell sides
PMID:26443240 PBO:0095330 Pom1 relocalizes to cell sides
PMID:26443240 PBO:0095330 Pom1 does not relocalize to cell sides
PMID:26443240 PBO:0095326 Pom1 does not relocalize to cell sides
PMID:26443240 PBO:0095327 Tea4 does not relocalize to cell sides
PMID:26443240 GO:0005634 absent when glucose limited
PMID:26443240 PBO:0095326 Pom1 does not relocalize to cell sides
PMID:26483559 FYPO:0005634 fig 9A
PMID:26483559 PBO:0036883 fig 9A
PMID:26483559 FYPO:0005634 fig 9A
PMID:26483559 FYPO:0000579 fig 9A
PMID:26483559 PBO:0036882 fig 9A
PMID:26483559 PBO:0036884 fig 9A
PMID:26483559 FYPO:0005574 Fig. S2
PMID:26483559 PBO:0036882 fig 9A
PMID:26483559 GO:1905318 fig 9a, there other evidence elsewhere but we don't have this annotation on mad2 at present...
PMID:26483559 FYPO:0005510 (Fig. 1 B)
PMID:26483559 PBO:0036880 fig 9A
PMID:26483559 PBO:0104214 (Fig. 6) increased or premature
PMID:26483559 FYPO:0005509 fig1b (vw moved down form) abnormal meiotic chromosome segregation
PMID:26483559 PBO:0104215 (Fig. 6) increased or premature
PMID:26483559 PBO:0104216 (Fig. 8, B and C), increased or premature
PMID:26483559 PBO:0035153 Fig 2
PMID:26483559 FYPO:0004093 Fig. 3, A and B; Fig. S5
PMID:26483559 PBO:0036881 fig 9A
PMID:26483559 FYPO:0004667 (Fig. 4, C and D)
PMID:26483559 FYPO:0005384 (Fig. 1 B)
PMID:26483559 FYPO:0005383 (Fig. 1 D)
PMID:26483559 PBO:0104217 (Fig. 1 D)
PMID:26483559 FYPO:0005512 Fig S1. Assayed by assaying depletion of securin from spindle
PMID:26483559 PBO:0104218 (Fig. 7, B and C)
PMID:26483559 PBO:0104219 (Fig. 7 C)
PMID:26483559 FYPO:0005634 fig 9A
PMID:26483559 FYPO:0005634 fig 9A
PMID:26483559 FYPO:0005634 fig 9A
PMID:26483559 FYPO:0005634 fig 9A
PMID:26483559 FYPO:0005634 fig 9A
PMID:26499799 GO:0030295 cerevisiae substrate
PMID:26518661 PBO:0095642 (Figure 4)
PMID:26518661 FYPO:0006985 (Figure 1)
PMID:26518661 PBO:0095634 (Figure 1)
PMID:26518661 FYPO:0000024 (Figure 1)
PMID:26518661 FYPO:0001125 (Figure 1)
PMID:26518661 FYPO:0006985 (Figure 2)
PMID:26518661 FYPO:0006986 (Figure 2)
PMID:26518661 FYPO:0006986 (Figure 2)
PMID:26518661 FYPO:0001355 (Figure 2)
PMID:26518661 FYPO:0006985 (Figure 2)
PMID:26518661 FYPO:0006986 (Figure 2)
PMID:26518661 FYPO:0006986 (Figure 2)
PMID:26518661 FYPO:0006986 (Figure 2)
PMID:26518661 FYPO:0006986 (Figure 2)
PMID:26518661 FYPO:0006987 (Figure 4)
PMID:26518661 FYPO:0004138 (Figure 4)
PMID:26518661 FYPO:0000862 (Figure 4)
PMID:26518661 PBO:0095637 (Figure 4)
PMID:26518661 PBO:0095638 (Figure 4)
PMID:26518661 PBO:0095639 (Figure 4)
PMID:26518661 PBO:0095640 (Figure 4)
PMID:26518661 PBO:0095641 (Figure 4)
PMID:26518661 FYPO:0006988 (Figure 4)
PMID:26518661 FYPO:0006989 (Figure 4)
PMID:26518661 FYPO:0006989 (Figure 4)
PMID:26518661 PBO:0095643 (Figure 4)
PMID:26518661 PBO:0095644 (Figure 4)
PMID:26518661 PBO:0095644 (Figure 4)
PMID:26518661 PBO:0093562 (Figure 5)
PMID:26518661 PBO:0093564 (Figure 5)
PMID:26518661 PBO:0093564 (Figure 5)
PMID:26518661 FYPO:0001839 (Figure 5)
PMID:26518661 FYPO:0001839 (Figure 5)
PMID:26518661 FYPO:0005371 (Figure 5)
PMID:26518661 FYPO:0006992 (Figure 5)
PMID:26518661 FYPO:0006992 (Figure 5)
PMID:26518661 FYPO:0006993 (Figure 5)
PMID:26518661 FYPO:0006993 (Figure 5)
PMID:26518661 FYPO:0006993 (Figure 5)
PMID:26518661 FYPO:0004742 (Figure 5)
PMID:26518661 FYPO:0006994 (Figure 5)
PMID:26518661 PBO:0094679 (Figure 5) (VW: fixed from normal to decreased -compared to WT)
PMID:26518661 FYPO:0006995 (Figure 5)
PMID:26518661 FYPO:0006995 (Figure 5)
PMID:26518661 FYPO:0006995 (Figure 5)
PMID:26518661 FYPO:0006995 (Figure 5)
PMID:26518661 FYPO:0003411 (Figure 5)
PMID:26518661 FYPO:0003411 (Figure 5)
PMID:26518661 FYPO:0003411 (Figure 5)
PMID:26518661 FYPO:0003411 (Figure 5)
PMID:26518661 FYPO:0003411 (Figure 5)
PMID:26518661 FYPO:0003411 (Figure 5)
PMID:26518661 FYPO:0003411 (Figure 5)
PMID:26518661 FYPO:0003094 (Figure 5)
PMID:26518661 FYPO:0006986 (Figure 2)
PMID:26518661 FYPO:0006986 (Figure 2)
PMID:26518661 PBO:0095645 ev4
PMID:26518661 PBO:0095646 ev4
PMID:26518661 FYPO:0004748 (Figure 7)
PMID:26518661 FYPO:0006997 (Figure 7)
PMID:26518661 FYPO:0006998 (Figure 7)
PMID:26518661 FYPO:0007000 (Figure 7)
PMID:26518661 FYPO:0007001 (Figure 7)
PMID:26518661 FYPO:0007002 (Figure 7)
PMID:26518661 FYPO:0007000 (Figure 7)
PMID:26518661 FYPO:0007001 (Figure 7)
PMID:26518661 FYPO:0007002 (Figure 7)
PMID:26518661 FYPO:0007003 (Figure 7)
PMID:26518661 PBO:0095647 (Figure 7)
PMID:26518661 PBO:0095648 (Figure 7)
PMID:26518661 PBO:0095649 (Figure 7)
PMID:26518661 PBO:0095650 (Figure 7)
PMID:26518661 PBO:0095651 (Figure 7)
PMID:26518661 PBO:0095652 (Figure 7)
PMID:26518661 PBO:0095653 (Figure 7)
PMID:26518661 FYPO:0004376 (Figure 7)
PMID:26518661 FYPO:0002336 (Figure 7)
PMID:26518661 FYPO:0002336 (Figure 7)
PMID:26518661 FYPO:0002336 ev4,ef
PMID:26527280 PBO:0102436 Fig. S3A,B (control for increased proteasome in nucleus)
PMID:26527280 PBO:0097772 Fig. S2B
PMID:26527280 PBO:0102443 (Figure S2F export of CDK1 from the nucleus, which depends on cyclin B degradation ,, was delayed
PMID:26527280 PBO:0097773 Fig. 3A/B
PMID:26527280 PBO:0097772 Fig. 3E/F
PMID:26527280 FYPO:0004705 (Figures 3B and 3D). sister chromatid separation (which depends on securin degradation, not on cyclin B degradation) was delayed as well
PMID:26527280 FYPO:0004310 chromosomes failed to split, but Plo1 was removed from SPBs with timing similar to that in wild-type cells (Figures 2A and 2C).
PMID:26527280 FYPO:0001946 chromosomes failed to split, but Plo1 was removed from SPBs with timing similar to that in wild-type cells (Figures 2A and 2C).
PMID:26527280 PBO:0102442 In contrast, there was only a very slight delay in sister chromatid separation (Figures 2A and 2B).
PMID:26527280 PBO:0097773 Figure 2A Plo1 to SPBs persisted for more than 20 min
PMID:26527280 FYPO:0001357 Fig. 1I
PMID:26527280 FYPO:0001357 Fig. 1J
PMID:26527280 PBO:0102441 Fig. 4G,H
PMID:26527280 PBO:0102440 Fig. S6L,M
PMID:26527280 PBO:0102439 Fig. S6D
PMID:26527280 PBO:0102438 Fig. S3I,J
PMID:26527280 PBO:0101464 Fig. S3G,H
PMID:26527280 PBO:0101464 Fig. S3D
PMID:26527280 PBO:0102437 Fig. S3A,C
PMID:26527280 PBO:0102434 Fig. 5C
PMID:26527280 PBO:0102434 Fig. 4D,E
PMID:26527280 FYPO:0002151 Fig. 7D,E (tetrad dissection)
PMID:26527280 PBO:0038172 (tetrad disection) Fig. 7D,E
PMID:26527280 PBO:0038176 (tetrad dioscection) Fig. 7C,E
PMID:26527280 PBO:0102435 Fig. 6G, S7F,G, TUBE pull-down
PMID:26536126 GO:0000139 nitrogen rich condition
PMID:26536126 FYPO:0000647 cell lysis on uracil depleted medium
PMID:26536126 FYPO:0005173 assayed_using(PomBase:fur4)
PMID:26536126 GO:0005783 grown in EMM or YES medium
PMID:26536126 FYPO:0001012 auxotrophic for cytosine, uridine and UMP
PMID:26536126 GO:1905530 uracil uptake enhancement in pub1 deletion
PMID:26536126 GO:0000324 nitrogen rich condition
PMID:26536126 PBO:0107662 inability to take up 14-C uracil in fur4 deletion mutant
PMID:26545917 FYPO:0002060 2c
PMID:26545917 PBO:0099158 they don't actually use pombe isu1 because they couldn't purify it, but they try both C. thermophilum and S. cerevisiae Isu1 and get similar results & sequence conservation is good to pombe.
PMID:26545917 PBO:0099158 they don't actually use pombe isu1 because they couldn't purify it, but they try both C. thermophilum and S. cerevisiae Isu1 and get similar results & sequence conservation is good to pombe.
PMID:26582768 PBO:0098561 SO:0000236 = ORF, SO:0001799=outer repeat, SO:0000186 = LTR retrotransposon
PMID:26582768 FYPO:0000089 Increased MMS sensitivity
PMID:26582768 FYPO:0000089 Increased MMS sensitivity
PMID:26582768 PBO:0097889 SO:0000236 = ORF, SO:0001799=outer repeat, SO:0000186 = LTR retrotransposon
PMID:26582768 PBO:0096037 SO:0000236 = ORF, SO:0001799=outer repeat, SO:0000186 = LTR retrotransposon
PMID:26582768 PBO:0098752 SO:0000236 = ORF, SO:0001799=outer repeat, SO:0000186 = LTR retrotransposon
PMID:26652183 PBO:0097362 5 or 10 J/m2 UV; Fig. 3I, Fig. 4A, Fig. S6
PMID:26652183 PBO:0097360 5 J/m2 UV; Delay is greater than rad51delta alone (see Fig. S7)
PMID:26652183 PBO:0097360 25 J/m2 UV; delay is greater than rad51delta alone (Fig. 5A)
PMID:26652183 PBO:0097362 5 or 10 J/m2 UV; similar sensitivity to rev1delta and rev3delta single mutants (Fig. 3I, Fig. 4A, Fig. S6)
PMID:26652183 PBO:0097363 5 J/m2 UV; similar sensitivity to eso1-D147N single mutant (Fig. 3H)
PMID:26652183 PBO:0097363 5 J/m2 UV; sensitivity similar to rad8delta and rhp18delta single mutants (Fig. 3G)
PMID:26652183 PBO:0097363 5 J/m2 UV; Fig. S3
PMID:26652183 PBO:0093629 5 J/m2 UV; Sensitivity is greater than rad51delta or eso1-D147N single mutants (see Fig. S7)
PMID:26652183 PBO:0097361 5 J/m2 UV; Fig. 1B, Fig. 3E
PMID:26652183 PBO:0097360 5 J/m2 UV; Fig. 1B
PMID:26652183 PBO:0035668 5 J/m2 UV; Fig 1A, Fig. S2
PMID:26652183 PBO:0097359 5 J/m2 UV; figure 1B, figure 3D, figure S6
PMID:26652183 PBO:0097363 5 J/m2 UV; Fig. 3D
PMID:26652183 PBO:0097363 5 J/m2 UV; Fig. 3E
PMID:26652183 PBO:0035673 5 J/m2 UV; Fig. 3I, Fig. 4A, Fig. S6
PMID:26652183 PBO:0035673 5 J/m2 UV; Fig. 3I, Fig. 4A, Fig. S6
PMID:26652183 PBO:0035673 5 J/m2 UV; Fig. 3B
PMID:26652183 PBO:0097364 5 J/m2 UV; Fig. 3C
PMID:26652183 PBO:0097365 2 or 5 J/m2 UV; Fig. 3F, Fig. S6
PMID:26652183 PBO:0097359 5 J/m2 UV; duration is similar to eso1-D147N alone (see Fig. 3H)
PMID:26652183 PBO:0097363 2 or 5 J/m2 UV; Fig. 3F, Fig. S6
PMID:26652183 PBO:0097362 5 or 10 J/m2 UV; Fig. 3I, Fig. 4A, Fig. S6
PMID:26652183 PBO:0097363 5 J/m2 UV; Fig. 3C
PMID:26652183 FYPO:0005625 5 or 10 J/m2 UV; Fig. 3I, Fig. 4A, Fig. S6
PMID:26652183 FYPO:0005625 5 or 10 J/m2 UV; Fig. 3I, Fig. 4A, Fig. S6
PMID:26652183 PBO:0097359 5 J/m2 UV; duration is similar to rad8delta or rhp18delta single mutants (see Fig. 3G)
PMID:26670050 PBO:0111162 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111163 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111164 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111165 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111166 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111167 enrichment in CRAC > 10-fold
PMID:26670050 GO:0005515 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111169 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111170 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111171 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111172 SPCC1235.04c
PMID:26670050 PBO:0111173 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111174 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111175 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111176 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111177 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111178 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111179 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111180 enrichment in CRAC > 10-fold
PMID:26670050 GO:0106222 enrichment in CRAC > 10-fold; Mmi1 binds the 5' extended region of the overlapping regulatory lncRNA prt
PMID:26670050 PBO:0111181 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111182 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111183 SPBC1289.13c
PMID:26670050 PBO:0111184 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111185 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111186 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111187 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111188 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111189 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111190 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111191 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111192 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111193 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111194 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111195 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111196 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111197 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111198 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111199 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111200 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111201 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111202 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111203 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111204 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111360 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111361 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111207 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111208 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111209 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111210 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111211 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111212 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111213 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111214 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111215 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111216 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111217 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111218 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0099700 increase > 5-fold
PMID:26670050 PBO:0111134 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111135 enrichment in CRAC > 10-fold
PMID:26670050 GO:0106222 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0099654 affects unspliced pre-mRNA
PMID:26670050 PBO:0099655 gene locus: rps2202
PMID:26670050 PBO:0111137 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111138 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111139 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111140 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111141 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111142 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111143 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111144 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111145 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111146 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111147 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111148 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111149 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111150 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111151 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111152 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111153 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111154 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111155 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0099655 gene locus affected: rps2202
PMID:26670050 PBO:0099656 increase > 50-fold
PMID:26670050 PBO:0099657 increase > 10-fold
PMID:26670050 PBO:0099658 increase > 10-fold
PMID:26670050 PBO:0099659 increase > 5-fold
PMID:26670050 PBO:0099660 increase > 5-fold
PMID:26670050 PBO:0099661 increase > 5-fold
PMID:26670050 PBO:0099662 increase > 5-fold
PMID:26670050 PBO:0099663 increase > 10-fold
PMID:26670050 PBO:0097114 increase > 10-fold
PMID:26670050 PBO:0099664 increase > 10-fold
PMID:26670050 PBO:0099665 increase > 10-fold
PMID:26670050 PBO:0099666 increase > 10-fold
PMID:26670050 PBO:0099667 increase > 10-fold
PMID:26670050 PBO:0099668 increase > 5-fold
PMID:26670050 PBO:0099669 increase > 5-fold
PMID:26670050 PBO:0099670 increase > 5-fold
PMID:26670050 PBO:0099671 increase > 5-fold
PMID:26670050 PBO:0099672 increase > 5-fold
PMID:26670050 PBO:0099673 increase > 5-fold
PMID:26670050 PBO:0099674 increase > 5-fold
PMID:26670050 PBO:0099675 increase > 5-fold
PMID:26670050 PBO:0099676 increase > 5-fold
PMID:26670050 PBO:0099677 increase > 5-fold
PMID:26670050 PBO:0099678 increase > 5-fold
PMID:26670050 PBO:0099679 increase > 5-fold
PMID:26670050 PBO:0099680 increase > 5-fold
PMID:26670050 PBO:0099681 increase > 5-fold
PMID:26670050 PBO:0099682 increase > 5-fold
PMID:26670050 PBO:0099683 increase > 5-fold
PMID:26670050 PBO:0099684 increase > 5-fold
PMID:26670050 PBO:0099685 increase > 5-fold
PMID:26670050 PBO:0099686 increase > 5-fold
PMID:26670050 PBO:0099687 increase > 5-fold
PMID:26670050 PBO:0099688 increase > 5-fold
PMID:26670050 PBO:0099689 increase > 5-fold
PMID:26670050 PBO:0099690 increase > 5-fold
PMID:26670050 PBO:0099691 increase > 5-fold
PMID:26670050 PBO:0111157 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111158 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111159 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111160 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111161 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111219 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111220 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111221 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111222 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111223 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111224 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111225 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111226 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111227 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111228 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111229 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111230 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0111055 enrichment in CRAC > 10-fold
PMID:26670050 PBO:0099693 increase > 40-fold
PMID:26670050 PBO:0099694 increase > 10-fold
PMID:26670050 PBO:0099695 increase > 10-fold
PMID:26670050 PBO:0109063 increase > 5-fold
PMID:26670050 PBO:0099697 increase > 5-fold
PMID:26670050 PBO:0099698 increase > 5-fold
PMID:26670050 PBO:0099699 increase > 5-fold
PMID:26670050 PBO:0099701 increase > 5-fold
PMID:26670050 PBO:0099702 increase > 5-fold
PMID:26670050 PBO:0099703 increase > 5-fold
PMID:26670050 PBO:0099704 increase > 5-fold
PMID:26670050 PBO:0099705 increase > 5-fold
PMID:26670050 PBO:0099706 increase > 5-fold
PMID:26670050 PBO:0099707 increase > 5-fold
PMID:26670050 PBO:0099708 increase > 5-fold
PMID:26670050 PBO:0099709 increase > 5-fold
PMID:26670050 PBO:0099710 increase > 5-fold
PMID:26670050 PBO:0099655 gene locus affected: dbp2
PMID:26670050 PBO:0099655 gene affected: rps2202
PMID:26670050 PBO:0099652 Fig. S4B
PMID:26670050 PBO:0099711 fig S5e
PMID:26670050 PBO:0099712 increase > 5-fold
PMID:26670050 PBO:0111326 enrichment in CRAC > 10-fold (vw changed dpp2->dbp2)
PMID:26687354 FYPO:0005556 (Figure 6A)
PMID:26687354 FYPO:0005555 (Figure 6A)
PMID:26687354 GO:0030892 (checked) Figure 1C
PMID:26687354 GO:0007064 (fig 2)
PMID:26687354 GO:0007064 (fig 2)
PMID:26687354 GO:0007064 (Checked) (Figure 2B) (dependent on pds5)
PMID:26687354 GO:0007064 (Figure 2B)
PMID:26687354 PBO:0034924 (checked) figure 3B
PMID:26687354 PBO:0034924 (checked) figure 3B
PMID:26687354 PBO:0034924 figure 3B
PMID:26687354 PBO:0104474 (Figure S4C)
PMID:26687354 GO:0030892 (checked) Figure 1C
PMID:26687354 PBO:0035235 (Figure 6C) acetylated form acts as a DNA sensor
PMID:26687354 PBO:0035231 exit gate opening https://github.com/geneontology/go-ontology/issues/12608 (checked) (Figures 4B and S4A) current extension is part of mitotic cohesin unloading
PMID:26687354 FYPO:0005557 (Figure 6C)
PMID:26687354 PBO:0035230 figure 3B
PMID:26687354 FYPO:0005557 figure 3B
PMID:26687354 PBO:0035233 (Figure 6B) acetylated form acts as a DNA sensor
PMID:26697368 FYPO:0005301 link to GEO dataset- GSE71820
PMID:26697368 FYPO:0004490 link to GEO dataset- GSE71820
PMID:26702831 GO:0005886 2c in cos7
PMID:26730850 PBO:0106554 Fig 3
PMID:26730850 GO:1905746 regulation of efficiency at weak donor
PMID:26730850 FYPO:0000561 (S1 Fig)
PMID:26730850 PBO:0106553 Figure 1D
PMID:26730850 PBO:0106552 Figure 1D
PMID:26730850 PBO:0106551 Figure 4 efficiency of introns displaying weak splice sites
PMID:26730850 PBO:0106550 Figure 3+5 efficiency/ of introns displaying weak splice sites
PMID:26730850 FYPO:0000012 Figure 1A-1C transient growth arrest
PMID:26730850 PBO:0095406 Figure 1D efficiency/ of introns displaying weak splice sites
PMID:26730850 PBO:0106550 Figure 1D efficiency/ of introns displaying weak splice sites
PMID:26730850 FYPO:0000333 Figure 1C transient
PMID:26730850 PBO:0109724 Figure 1D and 2D - examined via RT-PCR Figure 2A examined via RNA-Seq
PMID:26730850 PBO:0106554 Fig 3
PMID:26730850 PBO:0106550 Fig 3
PMID:26730850 PBO:0106551 Fig 4
PMID:26730850 PBO:0106551 Fig 4
PMID:26730850 PBO:0106555 Fig 5
PMID:26730850 PBO:0106550 Fig 3
PMID:26730850 PBO:0106551 Fig 4
PMID:26730850 PBO:0106555 Fig 5
PMID:26730850 PBO:0106550 Fig 5
PMID:26730850 PBO:0106555 Fig 5
PMID:26730850 PBO:0106555 Fig 5
PMID:26730850 PBO:0106554 Fig 5
PMID:26730850 PBO:0106555 Fig 5
PMID:26730850 PBO:0106554 Fig 5
PMID:26730850 PBO:0106554 Fig 3
PMID:26730850 PBO:0106554 Fig3
PMID:26730850 PBO:0106557 Fig 4
PMID:26730850 PBO:0106557 Fig 4
PMID:26730850 PBO:0106556 Fig 4
PMID:26730850 PBO:0106551 Fig 4
PMID:26730850 PBO:0106556 Fig 4
PMID:26730850 PBO:0106554 Fig 3
PMID:26730850 PBO:0106555 Fig 3
PMID:26730850 PBO:0106550 Fig 3
PMID:26730850 PBO:0106554 Fig 3
PMID:26730850 PBO:0106555 Fig 3
PMID:26744419 FYPO:0006429 fig 3d
PMID:26744419 PBO:0093559 fig 1b
PMID:26744419 PBO:0095834 fig 1b
PMID:26744419 PBO:0093563 fig S1c
PMID:26744419 PBO:0094679 fig 1c
PMID:26744419 PBO:0098755 fig 5c
PMID:26744419 PBO:0098756 Fig 5c
PMID:26744419 GO:0072766 Fig 4 b & c
PMID:26744419 GO:0140698 Fig 1c,Fig 4e
PMID:26744419 PBO:0098757 pericentric Fig 1c, In conclusion, while other tethering mechanisms in S. pombe could be functionally coupled to heterochroma- tin, the LEM-mediated centromere recruitment and the MSC-dependent silencing are independent mechanisms, although they are mediated by the same protein.
PMID:26744419 PBO:0098758 Fig 1c SHOULD BRE ORGANIZATION
PMID:26744419 PBO:0095652 fig 1c
PMID:26744419 PBO:0097950 fig 1c
PMID:26744419 PBO:0095834 fig 6d
PMID:26744419 PBO:0097950 fig 6e
PMID:26744419 PBO:0098759 fig 6c
PMID:26744419 FYPO:0004924 fig 6c
PMID:26744419 FYPO:0003555 fig 6e
PMID:26744419 FYPO:0002360 fig 6d
PMID:26744419 PBO:0095834 fig 6d
PMID:26744419 PBO:0095834 fig 6d
PMID:26744419 PBO:0097950 fig 6e
PMID:26744419 PBO:0097950 fig 6e
PMID:26744419 PBO:0098760 fig 3c
PMID:26744419 PBO:0098761 fig 6a (in combination with csi1∆; phenocopies lem2∆ csi1∆)
PMID:26744419 PBO:0098762 Fig 7b
PMID:26744419 PBO:0098763 Fig 7b
PMID:26744419 PBO:0098764 fig 5c
PMID:26744419 PBO:0098765 Fig 5b
PMID:26744419 PBO:0098765 Fig 5b
PMID:26744419 PBO:0098766 Fig 5b
PMID:26744419 PBO:0098766 Fig 5b
PMID:26744419 FYPO:0004342 fig 1c
PMID:26744419 PBO:0095834 fig S2
PMID:26744419 PBO:0095834 fig S2
PMID:26744419 FYPO:0004742 1d
PMID:26744419 FYPO:0002360 1d
PMID:26744419 PBO:0098767 1d
PMID:26744419 PBO:0098767 1d
PMID:26744419 FYPO:0002360 S4
PMID:26744419 PBO:0095834 fig S2
PMID:26744419 PBO:0096188 fig S2
PMID:26744419 PBO:0096189 fig S2
PMID:26744419 PBO:0111255 fig 1c
PMID:26744419 PBO:0111256 s2
PMID:26744419 PBO:0094679 s2
PMID:26744419 PBO:0094679 s2
PMID:26744419 PBO:0097656 fig 3
PMID:26744419 PBO:0094282 fig 3
PMID:26744419 PBO:0111256 fig 3
PMID:26744419 FYPO:0003411 fig 3
PMID:26744419 PBO:0111256 fig 3
PMID:26744419 PBO:0111256 fig 3
PMID:26744419 PBO:0094283 fig 3
PMID:26744419 PBO:0098769 s5a
PMID:26744419 PBO:0111257 3b
PMID:26744419 PBO:0111255 3b
PMID:26744419 PBO:0111255 3b
PMID:26744419 PBO:0111258 3b
PMID:26744419 PBO:0098772 fig 3c
PMID:26744419 PBO:0098784 Fig 5c. parent GO:0003682?
PMID:26744419 PBO:0098783 Fig 5c. parent GO:0003682?
PMID:26744419 PBO:0111257 fig 1c
PMID:26744419 PBO:0094282 s10
PMID:26744419 PBO:0094679 fig 1c
PMID:26744419 PBO:0094679 s10
PMID:26744419 PBO:0094679 s10
PMID:26744419 PBO:0097656 7
PMID:26744419 PBO:0094681 fig 7
PMID:26744419 PBO:0111257 7
PMID:26744419 PBO:0111257 7
PMID:26744419 PBO:0111257 7
PMID:26744419 PBO:0097950 fig 7
PMID:26744419 PBO:0097950 fig 7
PMID:26744419 PBO:0097950 fig 7
PMID:26744419 PBO:0097950 fig 7
PMID:26744419 PBO:0098782 Fig 7b
PMID:26744419 PBO:0098781 Fig 7b
PMID:26744419 PBO:0098780 Fig 7b
PMID:26744419 PBO:0098779 Fig 7b
PMID:26744419 PBO:0098778 5
PMID:26744419 GO:0005635 5
PMID:26744419 PBO:0098777 4e
PMID:26744419 PBO:0098776 4e
PMID:26744419 PBO:0098776 4e
PMID:26744419 PBO:0098775 fig 4
PMID:26744419 PBO:0098774 fig 4
PMID:26744419 PBO:0098773 fig 3c
PMID:26746798 PBO:0100920 fig 2 C
PMID:26746798 PBO:0100919 fig 2 C
PMID:26746798 PBO:0100918 fig 2 C
PMID:26746798 PBO:0097986 fig 2 B
PMID:26746798 PBO:0100920 fig 2 C
PMID:26746798 PBO:0023560 Fig 7B
PMID:26746798 PBO:0097986 fig 2 B
PMID:26746798 PBO:0100313 fig 2 B
PMID:26746798 PBO:0093616 fig 2 A
PMID:26746798 PBO:0093618 fig 2 A
PMID:26746798 PBO:0093618 fig 2 A
PMID:26746798 PBO:0093581 fig 1 A
PMID:26746798 PBO:0093581 fig 1 A
PMID:26746798 PBO:0093579 fig 1 A
PMID:26746798 PBO:0033073 Fig 7B
PMID:26746798 FYPO:0000229 Fig 7A
PMID:26746798 PBO:0093579 fig 1 A
PMID:26746798 PBO:0093581 fig 1 A
PMID:26746798 PBO:0093579 fig 1 A
PMID:26746798 PBO:0093580 fig 1 A
PMID:26746798 PBO:0093580 fig 1 A
PMID:26746798 PBO:0093579 fig 1 A Defect in Checkpoint Signaling.
PMID:26746798 FYPO:0000963 fig 6
PMID:26746798 FYPO:0000963 fig 6
PMID:26746798 FYPO:0000963 fig 6
PMID:26746798 FYPO:0000963 fig 6
PMID:26746798 PBO:0100926 fig 3C
PMID:26746798 PBO:0094254 fig 3C
PMID:26746798 PBO:0094254 fig 3C
PMID:26746798 PBO:0094255 fig 3C
PMID:26746798 PBO:0100924 fig 3B
PMID:26746798 PBO:0100925 fig 3B
PMID:26746798 PBO:0100924 fig 3B
PMID:26746798 PBO:0100923 fig 3A
PMID:26746798 PBO:0100922 fig 3A
PMID:26746798 PBO:0100922 fig 3A
PMID:26746798 PBO:0100921 fig 2 C
PMID:26749213 GO:0051285 fig 1B
PMID:26749213 PBO:0035059 (Supporting Information Fig. S4A)
PMID:26749213 PBO:0035049 (Fig. 3B–D) (Fig. 4A and movies 3 and 4) slow dynamics of actin patch components: Sla1, wsc1, arc5, Crn1
PMID:26749213 PBO:0100968 moved down from abnormal protein localization to cell tip (new term)
PMID:26749213 PBO:0035047 (Fig. 6D); evidence: filipin staining
PMID:26749213 PBO:0035060 FM4-64 uptake (I made Henars original annotation into a double mutant so the attribution has changed)
PMID:26749213 GO:0051285 fig 1B
PMID:26749213 GO:0072583 moved down drom endocytosis. Delayed FM4-64 uptake when in combination with a clathrin mutationSlow dynamics of endocytic patch markers
PMID:26749213 FYPO:0001235 fig 2 D
PMID:26749213 FYPO:0002061 fig 2 d
PMID:26749213 GO:0051285 fig 1B
PMID:26749213 FYPO:0004247 fig. S2 A&B
PMID:26749213 PBO:0100976 Fig. S2C
PMID:26749213 PBO:0098628 fig 1c
PMID:26749213 PBO:0100966 fig 7b
PMID:26749213 GO:0032153 fig 1B
PMID:26749213 GO:0032153 fig 1B
PMID:26749213 GO:0032153 fig 1B
PMID:26749213 PBO:0100973 figure 1a
PMID:26749213 PBO:0100972 figure 1a
PMID:26749213 PBO:0100971 figure 1a
PMID:26749213 PBO:0100970 moved down to new term from :protein mislocalized to cytoplasm during vegetative growth
PMID:26749213 PBO:0100969 moved down to new term from :protein mislocalized to cytoplasm during vegetative growth
PMID:26776736 PBO:0095954 MOVE EXTENSION DOWN TO NITROGEN This can be inferred from all of the proposed EXP and is part of the proposed model, we can delete if we can make in a better way
PMID:26776736 PBO:0095951 vw, changed to directly activates and added part_of Phosphorylation of Igo1 was severely impaired in cells deleted for ppk18 or expressing a kinase-dead version of ppk18 (ppk18- K595A or ppk18-KD) but was still present in cek1-deleted cells (Figure 4B), consistent with the idea that Ppk18 is the main greatwall kinase that phosphorylates Igo1 in medium with low nitrogen. They are deomstrating that the system is conserved...In Xenopus and mammalian cells, phosphorylation of ENSA by greatwall at serine 67 promotes its binding to and inhibition of PP2A$B55 phosphatase [8, 9]. enough evidence for function by IMP ALSO Our genetic and physiological data is in agreement with published work in budding yeast, Drosophila, Xenopus, and mammalian cells indicating that greatwall phosphorylates endo- sulfine to inhibit PP2A$B55 [8, 9, 27, 28, 35]. To test whether Igo1 is a direct target of Ppk18, we performed Ppk18 in vitro kinase assays using purified recombinant Igo1 and Igo1-S64A, as sub- strates. Extracts from wild-type (ppk18+) and Myc-tagged (ppk18-13myc) Ppk18 cells, treated for 1 hr with rapamycin in or- der to activate Ppk18, were immunoprecipitated with anti-c-Myc monoclonal antibodies. Ppk18-13myc immunoprecipitates were able to phosphorylate in vitro wild-type Igo1, but not Igo1-S64A Our genetic and physiological data is in agreement with published work in budding yeast, Drosophila, Xenopus, and mammalian cells indicating that greatwall phosphorylates endo- sulfine to inhibit PP2A$B55 [8, 9, 27, 28, 35]. To test whether Igo1 is a direct target of Ppk18, we performed Ppk18 in vitro kinase assays using purified recombinant Igo1 and Igo1-S64A, as sub- strates. Extracts from wild-type (ppk18+) and Myc-tagged (ppk18-13myc) Ppk18 cells, treated for 1 hr with rapamycin in or- der to activate Ppk18, were immunoprecipitated with anti-c-Myc monoclonal antibodies. Ppk18-13myc immunoprecipitates were able to phosphorylate in vitro wild-type Igo1, but not Igo1-S64A Our genetic and physiological data is in agreement with published work in budding yeast, Drosophila, Xenopus, and mammalian cells indicating that greatwall phosphorylates endo- sulfine to inhibit PP2A$B55 [8, 9, 27, 28, 35]. To test whether Igo1 is a direct target of Ppk18, we performed Ppk18 in vitro kinase assays using purified recombinant Igo1 and Igo1-S64A, as sub- strates. Extracts from wild-type (ppk18+) and Myc-tagged (ppk18-13myc) Ppk18 cells, treated for 1 hr with rapamycin in or- der to activate Ppk18, were immunoprecipitated with anti-c-Myc monoclonal antibodies. Ppk18-13myc immunoprecipitates were able to phosphorylate in vitro wild-type Igo1, but not Igo1-S64A (Figure S4A), indicating that fission yeast Ppk18 can act as a greatwall kinase.
PMID:26776736 PBO:0035246 important when growing on poor nitrogen sources
PMID:26776736 PBO:0095952 again confirms other systems Endosulfines are small phosphoproteins, highly conserved from yeasts to humans, that specifically bind to and inhibit the PP2A$B55 protein phosphatase subcomplex [8, 9]. PP2A$B55 has been shown to be cell-cycle-regulated in Xenopus, following the opposite pattern of activity to Cdk1$Cyclin B (high in inter- phase and low in mitosis) [15]. To determine whether Ser64-phosphorylated Igo1 inhibits the PP2A$B55 (PP2A$Pab1 in fission yeast) phosphatase activity, we purified PP2A$Pab1 phosphatase from cells expressing GST- Pab1 using glutathione sepharose beads and assayed them for phosphatase activity. Wild-type Igo1 thiophosphorylated in vitro at Ser64 by Xenopus Greatwall, but not Igo1-S64A, in- hibited more than 90% the phosphatase activity of PP2A$Pab1 (B55) (Figures S4B and S4C). This result indicates that Ser64- phosphorylated Igo1 inhibits the activity of PP2A$B55, analogous to the situation in budding yeast [27, 28, 35] and animal cells [8, 9].
PMID:26776736 GO:0035556 we need to give this a signal treansduction parentage positive regulation of G2/M transition of mitotic cell cycle involved in cellular response to nitrogen starvation
PMID:26804021 PBO:0101334 fig 5
PMID:26804021 FYPO:0005758 Fig. 7a
PMID:26804021 PBO:0101334 fig 5
PMID:26804021 PBO:0101333 fig 5
PMID:26804021 PBO:0101333 fig 5
PMID:26804021 PBO:0101333 fig 5
PMID:26804021 FYPO:0005917 fig 5A
PMID:26804021 FYPO:0005917 fig 5A
PMID:26804021 FYPO:0005917 fig 5 C
PMID:26804021 FYPO:0005917 fig 5A
PMID:26804021 FYPO:0006260 fig 4c
PMID:26804021 FYPO:0006260 fig 4
PMID:26804021 PBO:0101330 fig 3 B
PMID:26804021 GO:0000775 fig 1a
PMID:26804021 PBO:0101329 fig 1a. AND fig 4 (knob)
PMID:26804021 PBO:0101328 fig 4c
PMID:26804021 PBO:0101332 fig 3 B
PMID:26804021 PBO:0101332 fig 3 B
PMID:26804021 PBO:0101331 fig S6 check allele????
PMID:26804021 PBO:0101330 fig 3 D
PMID:26804021 PBO:0101334 fig 5
PMID:26804021 FYPO:0006272 Fig. 7b increased occurance
PMID:26804917 PBO:0102857 EMSA fig4
PMID:26804917 PBO:0112058 EMSA fig4
PMID:26804917 PBO:0102847 Serine 481 is phosphorylated by Cig2/Cdc2 during meiosis I. Phosphorylation decreases Fkh2 DNA binding affinity
PMID:2682257 PBO:0106437 Fig6a B. Cells contain cdc2-F15 mutant on multi copy LEU2+ plasmid.
PMID:2682257 PBO:0093560 Data not shown assayed by colony growth on plates
PMID:2682257 PBO:0037729 Fig6b C-F. Cells contain cdc2-F15 mutant on multi copy LEU2+ plasmid.
PMID:2682257 PBO:0106436 Fig6b C-F. Cells contain cdc2-F15 mutant on multi copy LEU2+ plasmid.
PMID:2682257 PBO:0023760 Figs 1, 2, 3, 4,5 cells blocked in late G2 and in mid mitosis . I have used the term MOD00048 as I'm told that tyrosine phosphorylation is always 04' but in the paper they just show that the Y15 residue is phosphorylated
PMID:2682257 PBO:0094620 Fig6aC. Cells contain cdc2-F19 mutant on multi copy LEU2+ plasmid.
PMID:2682257 PBO:0037727 Fig6b C-F. Cells contain cdc2-F15 mutant on multi copy LEU2+ plasmid.
PMID:2682257 PBO:0093712 Fig 6b C-F. Cells contain cdc2-F15 mutant on multi copy LEU2+ plasmid.
PMID:2682257 PBO:0106435 Figs 1, 2, 3, 4,5 cells blocked in late G2 and in mid mitosis . I have used the term MOD00048 as I'm told that tyrosine phosphorylation is always 04' but in the paper they just show that the Y15 residue is phosphorylated
PMID:2682257 FYPO:0002085 Fig6bB. Cells contain cdc2-F19 mutant on multi copy LEU2+ plasmid.
PMID:26832414 PBO:0108388 Fig. 4B
PMID:26832414 PBO:0112009 Fig. 4F
PMID:26832414 FYPO:0006299 Fig. 4C
PMID:26832414 PBO:0112008 Fig. 4D
PMID:26832414 PBO:0104710 Fig. 4A
PMID:26832414 PBO:0094283 Fig. 3B
PMID:26832414 PBO:0094283 Fig. 3B
PMID:26869222 PBO:0037344 This is in presence of 30µM Cutin-1 for 6 hours. Wild type cells show 36.3% abnormal chromosome segregation in same conditions
PMID:26869222 PBO:0035594 cells grown at 29°C for 6 hours in 30µM Cutin-1
PMID:26869222 PBO:0035594 cells grown at 29°C for 6 hours in 30µM Cutin-1
PMID:26869222 PBO:0037342 This is in presence of 30µM Cutin-1 for 6 hours. Wild type cells show 36.3% abnormal chromosome segregation in same conditions
PMID:26869222 PBO:0100991 Growth was assayed in presence of 10µM Cutin-1.
PMID:26869222 PBO:0100991 assayed in presence of 30µM Cutin-1 for 6 hours shows no chromosome defects or cell length defects growth in presence of 10-100µM Cutin-1 for 15 hours at 100µM Cutin-1 reduced to 70% compared to ~10% in wild type
PMID:26869222 PBO:0100991 +10µM Cutin-1
PMID:26869222 PBO:0037350 Cells show increased mitotic chromosome segregation defects in presence of Cutin-1
PMID:26869222 PBO:0100994 the resistance to Cutin-1 is dependent on nuclear size. Longer cells have a larger nucleus and are more resistant compared to smaller cells with a smaller nucleus
PMID:26869222 PBO:0100992 cells grown at 29°C for 6 hours in 30µM Cutin-1
PMID:26869222 PBO:0100991 cells grown at 29°C for 6 hours in 30µM Cutin-1
PMID:26869222 PBO:0037351 cells grown at 29°C
PMID:26869222 PBO:0100991 cells grown at 29°C for 6 hours in 30µM Cutin-1
PMID:26869222 PBO:0037352 Cells grown at 29°C
PMID:26869222 PBO:0099529 cells grown at 29°C for 6 hours in 30µM Cutin-1
PMID:26869222 PBO:0037348 cells grown at 29°C for 6 hours in 30µM Cutin-1
PMID:26869222 PBO:0100995 Cells show partial resistance to 30µM Cutin-1 for 6 hours.
PMID:26869222 PBO:0100991 growth in presence of 10-100µM Cutin-1 for 15 hours at 100µM Cutin-1 reduced to 70% compared to ~10% in wild type; assayed in presence of 30µM Cutin-1 for 6 hours shows no chromosome defects or cell length defects
PMID:26869222 PBO:0100993 The size of the nucleus is not actually abnormal, it is the right size for the cell size but is variable because of the variable cell size at division
PMID:26877082 PBO:0099935 Figure 2D (single clump!) condensation
PMID:26877082 FYPO:0000134 Figure 4A
PMID:26877082 PBO:0020891 Figures 2
PMID:26877082 PBO:0099936 Figure 2D abnormal cable clusering
PMID:26877082 PBO:0038070 Figures 2C
PMID:26877082 PBO:0099935 Figure 2D (single clump!) condensation
PMID:26877082 FYPO:0000419 Figures 1A, S1A, S1B, 1D, S1E medial ring assembly
PMID:26877082 PBO:0038073 Figure Figure S4C
PMID:26877082 FYPO:0002872 Figures 1A, S1A, S1B, 1D, S1E
PMID:26882497 PBO:0100096 "they don't show the ""added during"" data so this is a bit anectdotal from the text"
PMID:26882497 PBO:0095476 2bc,5
PMID:26882497 MOD:00046 in text relevant to fig1
PMID:26882497 PBO:0095474 2bc,5
PMID:26882497 PBO:0100097 "they don't show the ""added during"" data so this is a bit anectdotal from the text"
PMID:26882497 PBO:0100098 "they don't show the ""added during"" data so this is a bit anectdotal from the text"
PMID:26882497 PBO:0100098 "they don't show the ""added during"" data so this is a bit anectdotal from the text"
PMID:26882497 MOD:00046 in text relevant to fig1
PMID:26882497 MOD:00046 in text relevant to fig1
PMID:26882497 PBO:0100110 4a
PMID:26882497 MOD:00047 in text relevant to fig1
PMID:26882497 PBO:0100096 "they don't show the ""added during"" data so this is a bit anectdotal from the text"
PMID:26882497 PBO:0109101 1b
PMID:26882497 PBO:0100096 "they don't show the ""added during"" data so this is a bit anectdotal from the text"
PMID:26882497 PBO:0100096 "they don't show the ""added during"" data so this is a bit anectdotal from the text"
PMID:26882497 PBO:0100099 1b
PMID:26882497 PBO:0100100 1d
PMID:26882497 PBO:0100101 1d
PMID:26882497 PBO:0100102 1d
PMID:26882497 PBO:0100103 2a 20 mins after synchronized released into mitosis. I wouldn't want to guess exactly what stage of mitosis this is
PMID:26882497 FYPO:0000094 S3
PMID:26882497 FYPO:0001687 S3
PMID:26882497 FYPO:0001687 S3
PMID:26882497 PBO:0037610 2bc
PMID:26882497 FYPO:0001687 S3
PMID:26882497 PBO:0095476 2bc,5
PMID:26882497 FYPO:0005781 2bc
PMID:26882497 FYPO:0003762 2b
PMID:26882497 FYPO:0004318 2b
PMID:26882497 PBO:0100104 text to fig2
PMID:26882497 PBO:0100105 text to fig2
PMID:26882497 PBO:0100096 "they don't show the ""added during"" data so this is a bit anectdotal from the text"
PMID:26882497 PBO:0100094 1a - they don't really show that the modification is phosphorylation, but considering the rest of the data this annotation seems ok.
PMID:26882497 GO:0007094 it looks like it is involved in MAINTAINING the checkpoint, fig S4A and 2C
PMID:26882497 GO:0007094 Fig S4A and 2C
PMID:26882497 GO:0007094 Fig S4A and 2C
PMID:26882497 PBO:0100111 4a
PMID:26882497 PBO:0100111 5a
PMID:26882497 PBO:0100112 5a
PMID:26882497 PBO:0100113 5a
PMID:26882497 PBO:0100110 5a
PMID:26882497 PBO:0100112 5a
PMID:26882497 PBO:0100113 5a
PMID:26882497 FYPO:0005781 2bc,5
PMID:26882497 PBO:0100114 Fig6 they incubate with 3 different E2s so can't specify a substrate
PMID:26882497 GO:1990757 3 E2s mixed in the same assay so can't specify a substrate
PMID:26890608 PBO:0021142 cellular response to HU = GO:0072711
PMID:26891792 FYPO:0003559 Fig. 4
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0003559 Fig. 4
PMID:26891792 PBO:0093678 Fig. 4
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 PBO:0093680 Fig. 5
PMID:26891792 PBO:0093678 Fig. 4
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 PBO:0093678 Fig. 4
PMID:26891792 FYPO:0003559 Fig. 4
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 PBO:0093679 Fig. 5
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0003559 Fig. 4
PMID:26891792 FYPO:0003559 Fig. 4
PMID:26891792 FYPO:0000021 Fig. 3
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 PBO:0093680 Fig. 5
PMID:26891792 PBO:0093678 Fig. 4
PMID:26891792 PBO:0093679 Fig. 5
PMID:26891792 FYPO:0000098 Fig. 1
PMID:26891792 PBO:0093679 Fig. 5
PMID:26900649 PBO:0108072 "chromatin recruiter Together, we concluded that the primary defects observed in the ndc80-AK01 mutant can be attributed to impaired Mph1 recruitment to kinetochores, which leads to failure in recruitment of the other SAC components and abortive mitotic arrest. COUld also get 'upstream of/affects SAC"""
PMID:26912660 PBO:0100552 exists during veg growth & glucose starv & HU stress
PMID:26912660 PBO:0097545 exists during veg growth & glucose starv & HU stress
PMID:26912660 PBO:0100551 exists during veg growth & glucose starv & HU stress
PMID:26941334 GO:0110085 localization dependent on actin cytoskeleton
PMID:26942678 FYPO:0005858 some up some down
PMID:26942678 GO:1990251 Erh1 localizes with Mmi1 both during mitotic cell cycle and meiosis
PMID:26942678 FYPO:0005857 some up some down
PMID:26942678 FYPO:0000877 author statement
PMID:26960792 PBO:0108438 can't assess viability
PMID:26960792 PBO:0108438 can't assess viability
PMID:26960792 PBO:0108426 growing tips were longer and thinner than those of wild-type cells. This morphology is similar to the one caused by overexpression of Rga4.
PMID:26960792 PBO:0108232 RhoGAP, GTPase activating protein for Cdc42 and Rho2
PMID:26960792 PBO:0108438 can't assess viability
PMID:26960792 PBO:0108437 hard to be more specific when cell shape is also abnormal (Rga6 normally goes to lateral cortex & non-growing tip)
PMID:26960792 PBO:0023536 can't assess viability
PMID:26960792 PBO:0108438 can't assess viability
PMID:26960792 PBO:0108438 can't assess viability
PMID:26960792 PBO:0108438 can't assess viability
PMID:26990381 GO:0032541 This was especially true in the case of Are1p. mYFP-Are1p and mYFP-Are2p were both localized throughout the nuclear and cortical/peripheral ER (Figure 2A,B). We repeated these experiments in wild-type genetic backgrounds and saw qualitatively similar YFP signal patterns (Figure 2C,D). Thus, the localizations of these two enzymes do not provide evidence to explain polarized lipid droplet formation in either cdc25-22 or wild-type fission yeast cells
PMID:26990381 FYPO:0007342 analysis revealed that both strains had reduced whole-cell and lipid droplet TAG levels (Figure 3F,I).
PMID:26990381 FYPO:0007342 analysis revealed that both strains had reduced whole-cell and lipid droplet TAG levels (Figure 3F,I).
PMID:26990381 FYPO:0005585 analysis revealed that both strains had reduced whole-cell and lipid droplet TAG levels (Figure 3F,I).
PMID:26990381 FYPO:0005585 analysis revealed that both strains had reduced whole-cell and lipid droplet TAG levels (Figure 3F,I).
PMID:26990381 FYPO:0007343 Yeast cells lacking both genes (plh1Δdga1Δ) had no droplets but instead showed vesicle-shaped BODIPY 493/503-stained structures when grown in YE5S (Figure 3J).
PMID:26990381 FYPO:0002061 The same cells were not viable when grown in YPO (Figure S2B,C).
PMID:26990381 GO:0140042 Thus, plh1Δdga1Δ double knockouts appear to have hampered droplet biogenesis events and it is probable that TAG plays a crucial role in the ER escape hatch mechanism with minimal amounts needed even for SE lipid droplet formation [40].
PMID:26990381 GO:0140042 Thus, plh1Δdga1Δ double knockouts appear to have hampered droplet biogenesis events and it is probable that TAG plays a crucial role in the ER escape hatch mechanism with minimal amounts needed even for SE lipid droplet formation [40].
PMID:26990381 PBO:0098222 As expected, these cells contained negligible amounts of TAG after lysis and TLC analysis (Figure 3K).
PMID:26990381 GO:0032541 mYFP-Dga1p and mYFP-Plh1p were both localized throughout the nuclear and cortical/peripheral ER (Figure 4A,B).
PMID:26990381 GO:0032541 mYFP-Dga1p and mYFP-Plh1p were both localized throughout the nuclear and cortical/peripheral ER (Figure 4A,B).
PMID:26990381 GO:0097038 mYFP-Dga1p and mYFP-Plh1p were both localized throughout the nuclear and cortical/peripheral ER (Figure 4A,B).
PMID:26990381 GO:0097038 mYFP-Dga1p and mYFP-Plh1p were both localized throughout the nuclear and cortical/peripheral ER (Figure 4A,B).
PMID:26990381 GO:0097038 mYFP-Dga1p and mYFP-Plh1p were both localized throughout the nuclear and cortical/peripheral ER (Figure 4A,B).
PMID:26990381 GO:0097038 This was especially true in the case of Are1p. mYFP-Are1p and mYFP-Are2p were both localized throughout the nuclear and cortical/peripheral ER (Figure 2A,B). We repeated these experiments in wild-type genetic backgrounds and saw qualitatively similar YFP signal patterns (Figure 2C,D). Thus, the localizations of these two enzymes do not provide evidence to explain polarized lipid droplet formation in either cdc25-22 or wild-type fission yeast cells
PMID:26990381 PBO:0096874 There were a negligible number of BODIPY 493/503-stained droplets throughout those elongated double knockout cells compared to positive controls (Figure 1F,G).
PMID:26990381 GO:0032541 This was especially true in the case of Are1p. mYFP-Are1p and mYFP-Are2p were both localized throughout the nuclear and cortical/peripheral ER (Figure 2A,B). We repeated these experiments in wild-type genetic backgrounds and saw qualitatively similar YFP signal patterns (Figure 2C,D). Thus, the localizations of these two enzymes do not provide evidence to explain polarized lipid droplet formation in either cdc25-22 or wild-type fission yeast cells
PMID:26990381 GO:0097038 This was especially true in the case of Are1p. mYFP-Are1p and mYFP-Are2p were both localized throughout the nuclear and cortical/peripheral ER (Figure 2A,B). We repeated these experiments in wild-type genetic backgrounds and saw qualitatively similar YFP signal patterns (Figure 2C,D). Thus, the localizations of these two enzymes do not provide evidence to explain polarized lipid droplet formation in either cdc25-22 or wild-type fission yeast cells
PMID:27023709 FYPO:0005387 fig. 2i
PMID:27023709 GO:0002183 fig 2 H, cell free system
PMID:27023709 FYPO:0005387 fig. 2i
PMID:27023709 GO:0002183 fig 2 H, cell free system
PMID:27023709 GO:0002183 fig 2 H, cell free system
PMID:27023709 GO:0002183 fig 2 H, cell free system
PMID:27023709 GO:0002183 fig 2 H, cell free system
PMID:27023709 FYPO:0005387 fig. 2i
PMID:27069798 GO:0051015 Bundling activity inferred from pull-down experiments as well as from fluorescence microscopy
PMID:27075176 GO:0051017 mixed orientations
PMID:27075176 GO:0032432 (Figure 3A and Supplemental Video 3).
PMID:27075176 PBO:0097847 6C
PMID:27075176 PBO:0097848 6C
PMID:27075176 PBO:0097849 6C
PMID:27075176 PBO:0097850 6C
PMID:27075176 PBO:0097851 6C
PMID:27075176 PBO:0097852 6C
PMID:27075176 PBO:0097845 (Figure 1, C and D).
PMID:27082518 FYPO:0003440 Fiig 6 AB
PMID:27082518 PBO:0097580 Fig S6 B probably due to delayed fusion of TRAPP containing vesicles with PM
PMID:27082518 PBO:0019716 fig 1 B
PMID:27082518 PBO:0019716 fig 1 C-E
PMID:27082518 PBO:0019716 fig 1 C-E
PMID:27082518 PBO:0097581 Fig S6 C probably due to delayed fusion of TRAPP containing vesicles with PM
PMID:27082518 FYPO:0002086 fig 7D
PMID:27082518 PBO:0097576 Fig 7E
PMID:27082518 PBO:0097577 Fig 7E
PMID:27082518 PBO:0097577 Fig 7E
PMID:27082518 FYPO:0005543 Fig S 3 B
PMID:27082518 PBO:0022838 fig 5a
PMID:27082518 FYPO:0001368 fig 6 AB
PMID:27082518 FYPO:0001904 fig 6 AB
PMID:27082518 PBO:0097578 Fig S6A
PMID:27082518 FYPO:0001364 fig 6 AB
PMID:27082518 PBO:0097579 Fig S6A
PMID:27082518 FYPO:0002087 fig 7C/D
PMID:27082518 FYPO:0002088 fig 7C/D
PMID:27082518 FYPO:0002060 Fig 6E
PMID:27082518 FYPO:0003440 fig 6c
PMID:27082518 FYPO:0002061 Figure S4D
PMID:27082518 PBO:0035171 Fig 6E
PMID:27082518 PBO:0035172 Fig 6E
PMID:27082518 PBO:0097574 Fig S4E
PMID:27082518 PBO:0097575 Fig S4F and S4G
PMID:27082518 FYPO:0002088 fig 7A
PMID:27082518 PBO:0097573 Fig 3B
PMID:27082518 PBO:0097572 Fig 3B
PMID:27082518 FYPO:0002088 fig 2H, 7A
PMID:27098497 PBO:0099553 distal to break point
PMID:27098497 PBO:0099568 same as without htb1-K119R
PMID:27098497 FYPO:0002553 same as without csn1delta
PMID:27098497 FYPO:0002553 same as without csn5delta
PMID:27098497 PBO:0098835 same as without exo1+ overexpression
PMID:27098497 FYPO:0002553 same as without exo1delta
PMID:27098497 PBO:0098835 same as without exo1delta
PMID:27098497 PBO:0093617 same as rhp6delta alone
PMID:27098497 PBO:0093617 same as rhp6delta alone
PMID:27098497 FYPO:0002553 worse than without rqh1delta
PMID:27101289 PBO:0034987 binds with high affinity to diverged S. pombe telomeric repeats
PMID:27101289 GO:0043565 binds with high affinity to mammalian-type 5'-TTAGGG-3' telomeric repeats, and with very low affinity to diverged S. pombe telomeric repeats // I moved this to sequence specific DNA binding, appears to be author intent AL
PMID:27146110 PBO:0107270 Figure 1, 2
PMID:27146110 FYPO:0003779 Figure 2
PMID:27146110 FYPO:0006084 Table 1
PMID:27146110 FYPO:0006084 Table 1
PMID:27146110 FYPO:0006084 Table 1
PMID:27146110 FYPO:0006084 Table 1
PMID:27146110 PBO:0107271 Figure 1, 2
PMID:27146110 PBO:0107272 Figure 1, 2
PMID:27146110 PBO:0107273 Figure 1, 2
PMID:27146110 PBO:0107274 Figure 1, 2
PMID:27146110 FYPO:0006041 Figure 2
PMID:27146110 FYPO:0006041 Figure 2
PMID:27146110 FYPO:0006041 Figure 2
PMID:27146110 FYPO:0004021 *****The definition of this term is not right Figure 2
PMID:27146110 FYPO:0004021 *****The definition of this term is not right Figure 2
PMID:27146110 FYPO:0005364 Figure 2
PMID:27146110 FYPO:0005364 Figure 2
PMID:27146110 FYPO:0006043 Figure 2
PMID:27146110 FYPO:0005960 Figure 3
PMID:27146110 PBO:0107270 Figure 3
PMID:27146110 PBO:0107275 Figure 4
PMID:27146110 PBO:0107276 Figure 4
PMID:27146110 FYPO:0006045 Figure 5
PMID:27146110 FYPO:0006045 Figure 5
PMID:27146110 FYPO:0006046 Figure 5
PMID:27146110 FYPO:0006047 Figure 5
PMID:27146110 FYPO:0006049 Figure 6
PMID:27146110 FYPO:0006049 Figure 6
PMID:27146110 FYPO:0006049 Figure 6
PMID:27146110 FYPO:0006049 Figure 6
PMID:27146110 FYPO:0004101 Figure 7 &1
PMID:27146110 FYPO:0004101 Figure 7
PMID:27146110 FYPO:0004101 Figure 7
PMID:27146110 FYPO:0004101 Figure 7
PMID:27146110 FYPO:0004705 ***DELAYED Figure 7
PMID:27146110 FYPO:0004705 DELAYED Figure 7
PMID:27146110 FYPO:0004705 Figure 7
PMID:27146110 FYPO:0005342 Figure 8
PMID:27146110 FYPO:0005342 Figure 8
PMID:27146110 FYPO:0006044 Figure 8 (anaphase B)
PMID:27151298 PBO:0105079 K63-ubiquitin chain from 3 to 8 ubiquitin molecules
PMID:27151298 PBO:0105082 Delete K63-ubiquitin chains from 3 to 8 ubiquitins
PMID:27151298 PBO:0105109 K63-diubiquitin chain
PMID:27151298 PBO:0105108 K63-ubiquitin chain from 3 to 8 ubiquitin molecules
PMID:27151298 PBO:0108725 K63-diubiquitin chain
PMID:27168121 FYPO:0001861 Figure 3D
PMID:27168121 FYPO:0001919 Figure 3C
PMID:27168121 FYPO:0000324 Figure 3E
PMID:27168121 FYPO:0000972 Figure 3C
PMID:27168121 GO:0005515 Fig 1 C
PMID:27168121 FYPO:0001492 Figure 3B
PMID:27168121 PBO:0018576 fig 1b
PMID:27168121 PBO:0018421 fig 1 b
PMID:27168121 FYPO:0001492 Figure 3B
PMID:27183912 PBO:0097656 comma separated extension as can't distinguish transcipts (identical seq)
PMID:27183912 PBO:0111256 can't distinguish tlh1 and tlh2 as identical sequences hence comma separated; assayed_using(PomBase:tlh1),assayed_using(PomBase:tlh2)
PMID:27188733 PBO:0099545 says increased proportion, which is a synonym
PMID:27191590 FYPO:0005193 Fig 6C
PMID:27191590 FYPO:0001501 Fig 6C
PMID:27191590 PBO:0108130 Fig 6B
PMID:27191590 PBO:0108131 Fig 6D
PMID:27191590 FYPO:0005193 Fig 7C
PMID:27191590 FYPO:0001501 Fig 7C
PMID:27191590 FYPO:0001164 Fig 1C, Fig 4
PMID:27191590 FYPO:0001501 Fig 1C, Fig 4
PMID:27191590 FYPO:0005193 Fig 1C, Fig 6C, Fig 7C, Fig S5
PMID:27191590 MOD:00696 Fig 6E-G
PMID:27191590 GO:0005737 Fig 1B
PMID:27191590 FYPO:0001501 Fig 6C
PMID:27191590 PBO:0108129 Fig 6B
PMID:27191590 PBO:0108881 happens during cellular resposne to BFA Fig 3A, Fig 4A-B, Fig 5B, Fig S3
PMID:27191590 FYPO:0000123 Fig 5A
PMID:27191590 FYPO:0001501 Fig 4D
PMID:27191590 FYPO:0001501 Fig 4E
PMID:27191590 FYPO:0005193 Fig 6C
PMID:27194449 FYPO:0003347 of human pyruvyltransferase activity for the LacNAc-pNP
PMID:27194449 FYPO:0003347 of human pyruvyltransferase activity for the LacNAc-pNP
PMID:27268234 FYPO:0007472 Fig. S6
PMID:27268234 FYPO:0008221 Fig. S5A
PMID:27268234 FYPO:0008221 Fig. S5A
PMID:27268234 FYPO:0008222 Fig. S5B
PMID:27268234 FYPO:0008222 Fig. S5B
PMID:27268234 FYPO:0008223 Fig. S5B
PMID:27268234 FYPO:0008224 Fig. S5B
PMID:27268234 PBO:0112815 Fig. 3B
PMID:27268234 PBO:0112814 Fig. 3A
PMID:27268234 FYPO:0007472 Fig. S6
PMID:27268234 FYPO:0003557 Fig. S6
PMID:27268234 FYPO:0003557 Fig. S6
PMID:27268234 PBO:0112813 Fig. 3B
PMID:27268234 PBO:0112812 Fig. 3A
PMID:27325741 FYPO:0002061 temperature permissive for ts cdc17-K42
PMID:27325741 FYPO:0002061 temperature permissive for ts cdc17-K42
PMID:27325741 FYPO:0002061 temperature permissive for ts cdc17-K42
PMID:27327046 FYPO:0002177 fig S2 & 3
PMID:27327046 PBO:0097060 fig S2 & 3
PMID:27327046 FYPO:0001357 fig S2 & 3
PMID:27327046 PBO:0097058 I changed the evidence from IDA to IMP /AL
PMID:27327046 PBO:0097059 Figures 2 and 3A, B
PMID:27327046 GO:0140116 Expression of fex1 from a plasmid in fex1Del/fex2Del double deletion mutant rescues fluoride sensitivity.
PMID:27327046 FYPO:0001357 fig S2 & 3
PMID:27327046 GO:0140116 Deletion of both homologues fex1 and fex2 make cells highly sensitive to fluoride. Expression of fex1 from a plasmid in fex1Del/fex2Del double deletion mutant rescues fluoride sensitivity.
PMID:27327046 PBO:0097058 I changed the evidence from IDA to IMP /AL
PMID:27334362 FYPO:0000878 Fig. 3C (made this specific for inner and added decreased at outer)
PMID:27334362 GO:0061638 Fig. 3A,B changed from CENP-A containing nucleosome (val)
PMID:27334362 FYPO:0002061 fig 9 D
PMID:27334362 FYPO:0005371 Fig. 2D
PMID:27334362 FYPO:0005554 fig 3 c
PMID:27334362 PBO:0037732 fig 3 c split into decreased at outer, abolished at inner (val)
PMID:27334362 FYPO:0005371 Fig. 2D
PMID:27334362 PBO:0035014 (Fig. 2D) additive
PMID:27334362 FYPO:0002060 fig 9 D
PMID:27334362 FYPO:0002060 fig 9 D
PMID:27334362 FYPO:0000888 fig 3 c
PMID:27334362 FYPO:0001357 fig 6b
PMID:27334362 FYPO:0000887 fig 7 B
PMID:27334362 FYPO:0002061 fig 9D
PMID:27334362 GO:0005637 fig 1A
PMID:27334362 FYPO:0001357 Fig. 2C)
PMID:27334362 GO:0005637 fig 1a
PMID:27334362 FYPO:0002430 fig 9A
PMID:27334362 PBO:0037733 Fig 8B/tableB
PMID:27334362 FYPO:0000888 fig 3 c
PMID:27334362 FYPO:0004745 fig 3 c
PMID:27334362 PBO:0035021 Fig 8B/tableB
PMID:27334362 FYPO:0001839 Fig 8B/tableB
PMID:27334362 FYPO:0005554 fig3 c
PMID:27334362 PBO:0105899 Fig3 D, added assayed genes, vw
PMID:27334362 PBO:0105898 Fig3 D, added assayed genes, vw
PMID:27334362 FYPO:0005554 fig 3 c split into decreased at outer, abolished at inner (val)
PMID:27334362 PBO:0105897 Fig3 D, added assayed genes, vw
PMID:27334362 FYPO:0000887 fig 7 B
PMID:27334362 FYPO:0001234 Fig. 2B
PMID:27334362 PBO:0035015 fig 2a
PMID:27334362 PBO:0035014 fig 2D
PMID:27350684 PBO:0098383 splicing of rad21, nda3 and mad2 is also affected
PMID:27350684 PBO:0105963 splicing of rad21, nda3 and mad2 is also affected
PMID:27350684 FYPO:0001387 conditional synthetic lethal with rna14-11
PMID:27350684 PBO:0105964 splicing of rad21, nda3 and mad2 is also affected
PMID:27350684 PBO:0105965 splicing of rad21, nda3 and mad2 is also affected
PMID:27365210 PBO:0110966 These results demon- strate that pFal1, Red5, and Red1 are required to generate spliced rec8+ mRNA during starvation-induced meiosis.
PMID:27365210 FYPO:0001355 While viable, pfal1Δ showed a strong growth defect at all three temperatures tested (Fig. 1A).
PMID:27365210 FYPO:0001355 While viable, pfal1Δ showed a strong growth defect at all three temperatures tested (Fig. 1A).
PMID:27365210 FYPO:0001355 While viable, pfal1Δ showed a strong growth defect at all three temperatures tested (Fig. 1A).
PMID:27365210 GO:0000785 S. pombe, pFal1 localizes to chromatin-contain- ing regions of the nucleus and is not restricted to the nucleolus.
PMID:27365210 GO:0030874 S. pombe, pFal1 localizes to chromatin-contain- ing regions of the nucleus and is not restricted to the nucleolus.
PMID:27365210 PBO:0108651 We chose to study mei4 + and ssm4 + transcripts because they both contain a DSR region (.........we observed an increase in mei4 + and ssm4 + transcripts during vegetative growth in cells containing red5-2 (Fig. 1D).
PMID:27365210 PBO:0108636 We chose to study mei4 + and ssm4 + transcripts because they both contain a DSR region (.........we observed an increase in mei4 + and ssm4 + transcripts during vegetative growth in cells containing red5-2 (Fig. 1D).
PMID:27365210 PBO:0110962 We chose to study mei4 + and ssm4 + transcripts because they both contain a DSR region (.........we observed an increase in mei4 + and ssm4 + transcripts during vegetative growth in cells containing red5-2 (Fig. 1D).
PMID:27365210 PBO:0110963 Diploid pfal1Δ−/− cells show a decreased sporulation efficien- cy compared to wild-type cells (Fig. 2B). Less than 5% of pfal1Δ−/− cells sporulated, and ∼20% form misshapen asci on SPA medium (Fig. 2C), suggesting a meiotic defect.
PMID:27365210 PBO:0110964 Diploid red5-2 cells show severe sporulation defects, with <1% of cells producing asci.
PMID:27365210 PBO:0110965 qRT-PCR results show a large increase in rec8+ transcript levels during meiosis in wild-type cells, but no increase in pfal1Δ and red5-2 mutants (Fig. 3A).
PMID:27365210 PBO:0110965 qRT-PCR results show a large increase in rec8+ transcript levels during meiosis in wild-type cells, but no increase in pfal1Δ and red5-2 mutants (Fig. 3A).
PMID:27365210 PBO:0110962 We chose to study mei4 + and ssm4 + transcripts because they both contain a DSR region (.........we observed an increase in mei4 + and ssm4 + transcripts during vegetative growth in cells containing red5-2 (Fig. 1D).
PMID:27365210 PBO:0110966 These results demon- strate that pFal1, Red5, and Red1 are required to generate spliced rec8+ mRNA during starvation-induced meiosis.
PMID:27365210 PBO:0110966 These results demon- strate that pFal1, Red5, and Red1 are required to generate spliced rec8+ mRNA during starvation-induced meiosis.
PMID:27365210 PBO:0110966 These results demon- strate that pFal1, Red5, and Red1 are required to generate spliced rec8+ mRNA during starvation-induced meiosis.
PMID:27365210 FYPO:0008147 Consistent with the meiotic defects, this shift did not occur efficiently in diploid homozygous pfal1 and red1 mutants, reflected by a decreased splicing index (Fig. 3).
PMID:27365210 FYPO:0008147 Consistent with the meiotic defects, this shift did not occur efficiently in diploid homozygous pfal1 and red1 mutants, reflected by a decreased splicing index (Fig. 3).
PMID:27365210 FYPO:0008147 Consistent with the meiotic defects, this shift did not occur efficiently in diploid homozygous pfal1 and red1 mutants, reflected by a decreased splicing index (Fig. 3).
PMID:27365210 GO:0035145 We can easily detect interaction between pFal1- Myc and Mnh1-FTP (Fig. 4A).
PMID:27365210 GO:0035145 We can easily detect interaction between pFal1- Myc and Mnh1-FTP (Fig. 4A).
PMID:27365210 GO:0035145 We also observed interactions of pFal1-Myc with Rnps1-GFP and Y14-HA (Fig. 4B,D).
PMID:27365210 GO:0035145 We also observed interactions of pFal1-Myc with Rnps1-GFP and Y14-HA (Fig. 4B,D).
PMID:27365210 PBO:0110967 loss of mnh1 causes severe sporulation defects (Fig. 4F),
PMID:27365210 FYPO:0008147 Using qRT- PCR, we found a reduction in spliced meiotic transcripts of rec8+ in mnhΔ1−/− but not y14Δ−/− or rnps1Δ−/− (Fig. 5A),
PMID:27385337 FYPO:0002023 figure 5 d/ figure 6
PMID:27385337 PBO:0096613 figure 4 G (localizes as a dot rather than a disk)
PMID:27385337 PBO:0096614 Supplemental Figure S4B
PMID:27385337 PBO:0034985 Supplemental Figure S4F and Table 2
PMID:27385337 PBO:0096601 table 1, fig 3 C
PMID:27385337 FYPO:0002023 figure 5 d/ figure 6
PMID:27385337 PBO:0096601 fig 3 C
PMID:27385337 PBO:0095095 Figure 1F
PMID:27385337 PBO:0038150 Figure 3 F
PMID:27385337 PBO:0096611 figure 4 G
PMID:27385337 PBO:0096607 fig5a
PMID:27385337 PBO:0096603 Figure 4 F
PMID:27385337 PBO:0038151 figure 3 F
PMID:27385337 PBO:0096607 fig 5 a
PMID:27385337 PBO:0096606 table 1
PMID:27385337 PBO:0038152 figure 3 F
PMID:27385337 PBO:0038153 figure 3 F
PMID:27385337 PBO:0096603 table 1
PMID:27385337 PBO:0096605 table 1
PMID:27385337 PBO:0096603 table 1
PMID:27385337 PBO:0096603 table 1
PMID:27385337 PBO:0096604 table 1
PMID:27385337 PBO:0096603 table 1
PMID:27385337 PBO:0096604 table 1
PMID:27385337 PBO:0096603 table 1
PMID:27385337 PBO:0096602 table 1
PMID:27385337 PBO:0038155 figure 3 F
PMID:27385337 PBO:0096612 fig 3 C
PMID:27385337 PBO:0096612 fig 3 C
PMID:27385337 PBO:0038155 figure 3 F
PMID:27385337 PBO:0038154 figure 3 F
PMID:27388936 PBO:0093560 fig 8a
PMID:27388936 PBO:0101262 fig 8c
PMID:27388936 PBO:0093561 fig 8a
PMID:27388936 FYPO:0005440 fig 5 b
PMID:27388936 PBO:0093560 fig 5 a
PMID:27388936 PBO:0093561 fig 5 a
PMID:27388936 PBO:0096314 fig 8c
PMID:27398807 PBO:0093613 30 degrees; semi-permissive for slx8-29
PMID:27398807 FYPO:0006822 30 degrees; semi-permissive for slx8-29
PMID:27398807 FYPO:0001357 30 degrees; semi-permissive for slx8-29
PMID:27398807 PBO:0093579 30 degrees; semi-permissive for slx8-29
PMID:27398807 PBO:0093560 30 degrees; semi-permissive for slx8-29
PMID:27398807 PBO:0099747 30 degrees; semi-permissive for slx8-29
PMID:27398807 FYPO:0001357 30 degrees; semi-permissive for slx8-29
PMID:27398807 FYPO:0000963 30 degrees; semi-permissive for slx8-29
PMID:27398807 FYPO:0001357 30 degrees; semi-permissive for slx8-29
PMID:27398807 PBO:0093579 30 degrees; semi-permissive for slx8-29
PMID:27398807 PBO:0093559 30 degrees; semi-permissive for slx8-29
PMID:27398807 FYPO:0000088 30 degrees; semi-permissive for slx8-29
PMID:27398807 FYPO:0000088 30 degrees; semi-permissive for slx8-29
PMID:27398807 FYPO:0000088 30 degrees; semi-permissive for slx8-29
PMID:27398807 FYPO:0000089 30 degrees; semi-permissive for slx8-29
PMID:27398807 PBO:0093580 30 degrees C
PMID:27398807 PBO:0093614 30 degrees C
PMID:27398807 PBO:0093561 30 degrees; semi-permissive for slx8-29
PMID:27398807 PBO:0107296 30 degrees C
PMID:27398807 PBO:0099741 30 degrees C
PMID:27398807 FYPO:0000963 30 degrees; semi-permissive for slx8-29
PMID:27401558 PBO:0101484 ChIP at rps2 gene
PMID:27401558 PBO:0101485 ChIP at rps2 gene
PMID:27401558 PBO:0101484 ChIP at rps2 gene
PMID:27401558 PBO:0101485 ChIP at rps2 gene
PMID:27401558 PBO:0101484 ChIP at rps2 gene
PMID:27401558 PBO:0101498 ChIP at rps2 gene
PMID:27444384 GO:0051536 through conserved cysteines
PMID:27451393 FYPO:0000091 Fig. G
PMID:27451393 FYPO:0000877 fig 5A
PMID:27451393 PBO:0103719 DNS
PMID:27451393 GO:0033553 Fig. 3, A–D
PMID:27451393 GO:0061638 Fig. 2, B and C Fig. 2, D and E
PMID:27451393 GO:0061638 Fig. 2, F and G
PMID:27451393 PBO:0103720 DNS
PMID:27451393 FYPO:0000877 fig 5A
PMID:27451393 GO:0005515 Fig. 1A
PMID:27451393 GO:0005515 Fig. 1A
PMID:27451393 FYPO:0003411 Fig. 1B, D, E
PMID:27451393 FYPO:0003411 Fig. 1B, D, E
PMID:27451393 FYPO:0000091 Fig. G
PMID:27451393 PBO:0103718 Fig. 4, A and B
PMID:27451393 PBO:0112084 Fig. 5, C and D
PMID:27451393 PBO:0103721 Fig. 5, C and D
PMID:27451393 FYPO:0004604 Fig. 3E
PMID:27451393 FYPO:0004604 Fig. 3E
PMID:27451393 GO:0099115 Fig. 3, A–D
PMID:27548313 FYPO:0000141 VW: I changed Ken-Ichi BP annotation to phenotype (Kenichi comment mitotic defects mitotic defects caused by 343.20 deletion)
PMID:27548313 FYPO:0000141 VW: I changed Ken-Ichi BP annotation to phenotype (Kenichi comment mitotic defects mitotic defects caused by eng1 deletion)
PMID:27548313 FYPO:0000141 VW: I changed Ken-Ichi BP annotation to phenotype (Kenichi comment mitotic defects mitotic defects caused by ace2 deletion)
PMID:27558664 PBO:0097285 affecting sua1 affecting cys11 affecting met14
PMID:27558664 PBO:0097288 affecting gst2
PMID:27558664 PBO:0097288 affecting gst2
PMID:27558664 PBO:0097285 affecting sua1 affecting cys11 affecting met14
PMID:27558664 PBO:0097286 affecting sua1 affecting cys11 affecting met14
PMID:27558664 PBO:0097288 affecting gst2
PMID:27558664 PBO:0097285 affecting sua1 affecting cys11 affecting met14
PMID:27558664 PBO:0097286 affecting sua1 affecting cys11 affecting met14
PMID:27558664 PBO:0097286 affecting sua1 affecting cys11 affecting met14
PMID:27558664 PBO:0097287 affecting sua1 affecting cys11 affecting met14
PMID:27558664 PBO:0097287 affecting sua1 affecting cys11 affecting met14
PMID:27558664 PBO:0097287 affecting sua1 affecting cys11 affecting met14
PMID:27587357 FYPO:0002196 Fig 3
PMID:27587357 GO:0000139 deleted in error, added back
PMID:27587357 GO:0000139 deleted in error, added back
PMID:27587357 GO:0000139 deleted in error, added back
PMID:27587357 GO:0000139 deleted in error, added back
PMID:27587357 GO:0000139 deleted in error, added back
PMID:27587357 GO:0005789 deleted in error, added back
PMID:27587357 FYPO:0002196 Fig 3
PMID:27587357 FYPO:0002196 Fig 3
PMID:27587357 FYPO:0003333 Fig 3
PMID:27587357 FYPO:0003333 Fig 3
PMID:27587357 FYPO:0005760 Fig 3
PMID:27587357 FYPO:0005760 Fig 3
PMID:27587357 FYPO:0002061 Fig 3
PMID:27587357 FYPO:0002061 Fig 3
PMID:27587357 FYPO:0003333 fig1d
PMID:27587357 FYPO:0006273 see ttps://github.com/pombase/fypo/issues/3152#issuecomment-340506554 A reduced UDP-glucose transport is a decreased transporter activity that produces an abnormal lower level of UDP-glucose in the endoplasmic reticulum lumen
PMID:27587357 FYPO:0002482 fig1d
PMID:27587357 FYPO:0002061 fig1
PMID:27587357 GO:0006491 endoplasmic reticulum quality control of glycoprotein folding The quality control of glycoprotein folding is a process that facilitates glycoprotein folding and retains in the endoplasmic reticulum folding intermediates.
PMID:27587357 GO:0005458 (vw: inferred from cell wall galactomannan defects)
PMID:27587357 PBO:0105973 (vw: inferred from cell wall galactomannan defects)
PMID:27587357 PBO:0105976 Fig 3
PMID:27587357 FYPO:0002196 Fig 3
PMID:27587357 GO:0000139 deleted in error, added back
PMID:27611590 FYPO:0005765 assayed Cdc20 recruitment
PMID:27611590 FYPO:0005768 assayed Cdc20 recruitment
PMID:27611590 FYPO:0005767 assayed Cdc20 recruitment
PMID:27611590 FYPO:0005766 assayed Cdc20 recruitment
PMID:27613427 PBO:0094268 AA medium (Rose et al 1990 Methods in Yeast Genetics: A Laboratory Course Manual, Cold Spring Harbor Laboratory Press, Cold Spring Harbor, NY.)
PMID:27613427 PBO:0093612 AA medium (Rose et al 1990 Methods in Yeast Genetics: A Laboratory Course Manual, Cold Spring Harbor Laboratory Press, Cold Spring Harbor, NY.)
PMID:27618268 PBO:0104636 fig 3C
PMID:27618268 PBO:0104643 Together, these data indicate that Mph1 (Mps1) kinase and Dis2 (PP1) phosphatase antagonistically regulate the interaction of Mad1 and Mad2 with Bub1 in fission yeast, most likely through phosphorylation of the conserved central motif of Bub1.
PMID:27618268 PBO:0104642 Together, these data indicate that Mph1 (Mps1) kinase and Dis2 (PP1) phosphatase antagonistically regulate the interaction of Mad1 and Mad2 with Bub1 in fission yeast, most likely through phosphorylation of the conserved central motif of Bub1.
PMID:27618268 PBO:0104638 ((Figure S4C)). non kinetochore bound
PMID:27618268 PBO:0101480 (Figures 4C and S4B). non kinetochore bound
PMID:27618268 PBO:0104641 (Figures 4C and S4B). non kinetochore bound
PMID:27618268 PBO:0104636 Figures 4B and S4A
PMID:27618268 PBO:0104640 Figures 4B and S4A
PMID:27618268 PBO:0101483 Figure S3E
PMID:27618268 PBO:0104640 Figure S3E
PMID:27618268 PBO:0104639 Figure S3E
PMID:27618268 PBO:0104638 fig 3C
PMID:27618268 PBO:0104637 fig 3C
PMID:27618268 FYPO:0000168 Figure 2D
PMID:27618268 FYPO:0000168 Figure 2E (how is this abnormal? i got confused here)
PMID:27618268 PBO:0104635 fig 2E
PMID:27618268 PBO:0095476 fig 2D
PMID:27618268 PBO:0104634 (Figure 2B)
PMID:27618268 PBO:0101454 (Figure 2A)
PMID:27618268 PBO:0104633 (Figure 2A)
PMID:27618268 PBO:0095476 fig 1D
PMID:27618268 PBO:0095476 fig 1D
PMID:27618268 FYPO:0003762 fig 1B
PMID:27618268 FYPO:0003762 fig 1B
PMID:27618268 FYPO:0003762 fig 1B
PMID:27618268 FYPO:0003762 fig 1B
PMID:27618268 FYPO:0005781 fig 1B
PMID:27618268 FYPO:0005781 fig 1B
PMID:27618268 PBO:0104632 fig 1A
PMID:27618268 PBO:0104632 fig 1A
PMID:27618268 PBO:0104631 fig 1A
PMID:27618268 PBO:0104630 fig 1A
PMID:27618268 PBO:0104630 fig 1A
PMID:27618268 PBO:0104629 fig 1A
PMID:27627185 PBO:0108748 (unphosphorylated form of tif211)
PMID:27627185 PBO:0095935 (unphosphorylated form of tif211) inhibited by stress-inducedphosphorylation of Ser51 in the a subunit of eIF2(tif211)
PMID:27630265 PBO:0097862 localizations at spindle poles during meiotic anaphase I (Figure 6, Supplemental Figure S3)
PMID:27630265 PBO:0097861 during meiosis (Figure 5, Supplemental Figure S4)
PMID:27630265 PBO:0037651 initiation of forespore membrane delayed (Figure 3, Table 2)
PMID:27630265 PBO:0035494 Figure 4, 5, Supplemental Figure S4
PMID:27630265 PBO:0037653 Figure 4, 5
PMID:27630265 FYPO:0004609 Supplemental Figure S12
PMID:27630265 PBO:0037641 Figure 2
PMID:27630265 PBO:0025347 from metaphase II to postmeiosis (Figure 2)
PMID:27630265 FYPO:0002060 Figure 1
PMID:27630265 FYPO:0002061 Figure 1
PMID:27630265 PBO:0097864 Figure 5C, Supplemental Figure S4B
PMID:27630265 GO:0032120 Figure 1 and Supplemental Figure S1
PMID:27630265 GO:0005515 Spo13 interacted with both GTP- and GDP-bound forms of Ypt3 (Figure 7, Supplemental Figure S8).
PMID:27630265 PBO:0097865 upplemental Figure S5A
PMID:27630265 PBO:0097866 Figure 6A and Supplemental Figure S3)
PMID:27630265 PBO:0097867 upplemental Figure S5A
PMID:27630265 PBO:0097868 Figure 6A and Supplemental Figure S3)
PMID:27630265 PBO:0097869 upplemental Figure S5A
PMID:27630265 FYPO:0002061 Figure 1
PMID:27630265 PBO:0037642 Figure 1, Supplemental Figure S1
PMID:27630265 PBO:0097859 in vegetative cells (Supplemental Figure S10);
PMID:27630265 PBO:0097860 in sporulating cells (Figure 9, Supplemental Figure S9) (Supplemental Figure S10)
PMID:27630265 GO:0005085 Sec2 interacted with specifically with GTP- bound forms of Ypt3 (Figure 7, Supplemental Figure S8).
PMID:27630265 GO:0071341 (Figure 8A)
PMID:27630265 GO:0051285 (Figure 8A)
PMID:27630265 GO:0005628 (Figure 8A)
PMID:27630265 PBO:0097870 (Supplemental Figure S10A)
PMID:27630265 PBO:0097871 (Supplemental Figure S10A)
PMID:27630265 PBO:0097872 (Supplemental Figure S10A)
PMID:27630265 PBO:0097869 (Supplemental Figure S11B)
PMID:27630265 PBO:0037648 Supplemental Figure S11
PMID:27630265 PBO:0097869 (Supplemental Figure S11B)
PMID:27630265 PBO:0097873 localizations at spindle poles during meiotic anaphase I (Figure 6, Supplemental Figure S6)
PMID:27630265 PBO:0097873 localizations at spindle poles during meiotic anaphase I (Figure 6, Supplemental Figure S6)
PMID:27630265 PBO:0097863 Supplemental Figure S11
PMID:27630265 PBO:0037650 (Supplemental Figure S11)
PMID:27630265 PBO:0035494 Figure 8, Supplemental Figure S9
PMID:27630265 PBO:0037641 Figure 6, Supplemental Figure S6
PMID:27630265 PBO:0097860 localizations at spindle poles during meiotic anaphase I (Figure 6, Supplemental Figure S6)
PMID:27648579 PBO:0103241 not increased (relative to wild type Hht3+/Clr4+) as with hht3-K9M alone
PMID:27648579 PBO:0103234 substrate: recombinant mono-nucleosomes
PMID:27648579 PBO:0103243 substrate: bulk histone octamers
PMID:27648579 PBO:0103241 not increased (relative to wild type Hht3+/Clr4+) as with hht3-K9M alone
PMID:27655872 PBO:0103866 PRECURSOR Fig 5E and F
PMID:27655872 PBO:0095816 Western blot analysis show Sre1 cleavage defect under low oxygen
PMID:27655872 PBO:0095816 "Fig 2B, lanes ""Sre1 cleavage defect under low oxygen"""
PMID:27655872 PBO:0103872 Fig 8
PMID:27655872 PBO:0095816 Fig 9A
PMID:27655872 PBO:0103861 Fig 3D,
PMID:27655872 PBO:0103861 Fig 3D, compare lanes 3 and 4
PMID:27655872 PBO:0103861 Fig 3D,
PMID:27655872 PBO:0103860 Fig 3A, lane 3
PMID:27655872 PBO:0103859 Fig 3A, lane 3
PMID:27655872 PBO:0103859 Fig 3A, lane 4 both cleavage products
PMID:27655872 PBO:0096888 Fig 2G, lanes 6–8
PMID:27655872 PBO:0096888 Fig 2G, lanes 10– 12
PMID:27655872 PBO:0099029 Fig 9A
PMID:27655872 PBO:0095816 Fig 2C
PMID:27655872 PBO:0095816 Fig 2C
PMID:27655872 PBO:0103862 PRECURSOR Figure 3 E
PMID:27655872 PBO:0103858 Fig 2D, lane 3
PMID:27655872 PBO:0103865 PRECURSOR Fig 5D and F (4.5 fold)
PMID:27655872 FYPO:0001245 Fig 8A
PMID:27655872 PBO:0103872 Fig 8
PMID:27655872 PBO:0103857 Fig 2B, lanes 5–13
PMID:27655872 PBO:0095816 "Fig 2B, lanes ""Sre1 cleavage defect under low oxygen"""
PMID:27655872 PBO:0103868 Fig 5E and F
PMID:27655872 PBO:0103866 PRECURSOR Fig 5E and F
PMID:27655872 PBO:0094110 Fig 2A
PMID:27655872 FYPO:0001245 Fig 8A
PMID:27655872 PBO:0103869 fig 6 B
PMID:27655872 FYPO:0002061 Fig 2A
PMID:27655872 FYPO:0001245 Fig 2A
PMID:27655872 FYPO:0001422 Fig 8C 8D Western blot analysis show decreased Sre1 cleavage activation under low oxygen
PMID:27655872 PBO:0103869 fig 6 B
PMID:27655872 PBO:0103871 Fig 7A, lanes 4–6
PMID:27655872 GO:0000139 Fig 1E
PMID:27655872 PBO:0103870 fig 6 B
PMID:27655872 PBO:0103870 fig 6 B
PMID:27655872 GO:0005515 Fig 7A, lanes 4–6
PMID:27655872 PBO:0103867 PRECURSOR Fig 5E and F
PMID:27655872 PBO:0103859 Fig 3D, compare lanes 3 and 4
PMID:27655872 PBO:0103861 Fig 3D,
PMID:27655872 PBO:0103866 PRECURSOR Fig 5E and F
PMID:27655872 PBO:0108957 Fig 3E and Figure 3 D
PMID:27655872 PBO:0103866 PRECURSOR Fig 5E and F
PMID:27655872 PBO:0103866 PRECURSOR Fig 5E and F
PMID:27655872 PBO:0095816 Fig 9A
PMID:27655872 PBO:0103866 PRECURSOR Fig 5E and F
PMID:27655872 PBO:0110516 Fig 3E and Figure 3 D
PMID:27655872 PBO:0095816 Fig 8C 8D Western blot analysis show Sre1 cleavage defect under low oxygen
PMID:27655872 PBO:0095816 Western blot analysis show Sre1 cleavage defect under low oxygen
PMID:27655872 PBO:0095816 Western blot analysis show Sre1 cleavage defect under low oxygen
PMID:27655872 PBO:0103875 Fig 3A, lane 4 both cleavage products
PMID:27655872 PBO:0103873 Fig 9A
PMID:27664110 PBO:0100416 severe growth delay on both fermentable (Glucose) and respiratory (Ethanol Glycerol) media at the restrictive temperature, while it behaved like the wild-type at permissive tempera- ture
PMID:27664110 PBO:0093558 1b severe growth delay on both fermentable (Glucose) and respiratory (Ethanol Glycerol) media at the restrictive temperature, while it behaved like the wild-type at permissive tempera- ture
PMID:27664110 FYPO:0000256 3
PMID:27664110 FYPO:0003004 3
PMID:27664110 PBO:0100415 severe growth delay on both fermentable (Glucose) and respiratory (Ethanol Glycerol) media at the restrictive temperature, while it behaved like the wild-type at permissive tempera- ture
PMID:27664110 PBO:0100416 severe growth delay on both fermentable (Glucose) and respiratory (Ethanol Glycerol) media at the restrictive temperature, while it behaved like the wild-type at permissive tempera- ture
PMID:27664110 FYPO:0000256 text
PMID:27664110 FYPO:0000256 text
PMID:27664110 PBO:0094264 severe growth delay on both fermentable (Glucose) and respiratory (Ethanol Glycerol) media at the restrictive temperature, while it behaved like the wild-type at permissive tempera- ture
PMID:27664110 FYPO:0000256 text
PMID:27664110 FYPO:0002009 1c
PMID:27664110 FYPO:0003810 2
PMID:27664110 PBO:0100417 2
PMID:27664110 PBO:0100416 severe growth delay on both fermentable (Glucose) and respiratory (Ethanol Glycerol) media at the restrictive temperature, while it behaved like the wild-type at permissive tempera- ture
PMID:27664110 PBO:0094264 severe growth delay on both fermentable (Glucose) and respiratory (Ethanol Glycerol) media at the restrictive temperature, while it behaved like the wild-type at permissive tempera- ture
PMID:27664110 PBO:0094264 severe growth delay on both fermentable (Glucose) and respiratory (Ethanol Glycerol) media at the restrictive temperature, while it behaved like the wild-type at permissive tempera- ture
PMID:27664110 FYPO:0000078 3
PMID:27664222 PBO:0095000 Figure 5A
PMID:27664222 PBO:0022693 Figure 5A
PMID:27664222 GO:0034599 detoxification of thiol disulphide (in response to disulphide stress)
PMID:27664222 PBO:0094983 Fig- ure 3A
PMID:27664222 PBO:0094984 Fig- ure 3A
PMID:27664222 FYPO:0000726 subcategory of oxidative stress known as GSH or disulfide stress (4). Indeed, a lower GSH/GSSG ratio was found after treatment with diamide or Cd (Supplementary Figure S4) in WT and in the SPBC29A10.12Δ strain
PMID:27664222 FYPO:0000096 Supplementary Figure S1B
PMID:27664222 FYPO:0000799 Supplementary Figure S1B
PMID:27664222 GO:0005737 Figure 5A
PMID:27664222 FYPO:0001037 Supplemen- tary Figure S3A NaCl or KCl)
PMID:27664222 PBO:0094985 Fig- ure 3A
PMID:27664222 PBO:0094996 Fig- ure 3A
PMID:27664222 PBO:0094997 Fig- ure 3A
PMID:27664222 PBO:0094998 Fig- ure 3A
PMID:27664222 PBO:0094999 diamide-induced promoters
PMID:27664222 FYPO:0000962 Supplemen- tary Figure S3A
PMID:27664222 PBO:0094986 Fig- ure 3A
PMID:27664222 PBO:0094989 Fig- ure 3A
PMID:27664222 PBO:0094987 Fig- ure 3A
PMID:27664222 PBO:0094988 Fig- ure 3A
PMID:27664222 PBO:0094995 Fig- ure 3A
PMID:27664222 PBO:0094990 Fig- ure 3A
PMID:27664222 PBO:0094991 Fig- ure 3A
PMID:27664222 PBO:0094994 Fig- ure 3A
PMID:27664222 FYPO:0000763 Figure 2A
PMID:27664222 FYPO:0002693 Figure 2A
PMID:27664222 GO:0001228 Fig- ure 3A
PMID:27664222 PBO:0094993 Fig- ure 3A
PMID:27664222 PBO:0094992 Fig- ure 3A
PMID:27664222 GO:0034599 detoxification of thiol disulphide (in response to disulphide stress)
PMID:27664222 GO:0006366 detoxification of thiol disulphide (in response to disulphide stress)
PMID:27666591 PBO:0093564 Figure 5C
PMID:27666591 PBO:0110819 Figure 5B
PMID:27666591 PBO:0095880 Figure 5C
PMID:27666591 GO:0140898 Figure 5A
PMID:27666591 PBO:0095871 Fig- ure 7D
PMID:27666591 PBO:0095871 Figure 1A. Figures S1C–S1E
PMID:27666591 FYPO:0001870 Figures S1A and S1B
PMID:27666591 PBO:0095873 Figures S2A and S2B
PMID:27666591 FYPO:0001234 Figures 1F and S2B
PMID:27666591 FYPO:0005887 Figure 2D
PMID:27666591 PBO:0095874 Figures 2D and S3B
PMID:27666591 FYPO:0002061 Figure 3A
PMID:27666591 PBO:0095875 Figure 4C
PMID:27666591 PBO:0095876 Figure S5B)
PMID:27666591 FYPO:0000091 Figure 7C)
PMID:27666591 PBO:0095872 Figure 2A
PMID:27666591 PBO:0093564 Figures 2B and 2C
PMID:27666591 PBO:0093562 Figure 5C
PMID:27666591 PBO:0095881 Figure 7B
PMID:27666591 PBO:0095882 7e
PMID:27666591 PBO:0095883 7F
PMID:27666591 PBO:0095871 Figure 1B Figure S1F
PMID:27666591 FYPO:0005887 Figure 1B Figure S1F
PMID:27666591 FYPO:0000091 Figure S1F
PMID:27666591 GO:0140898 not sure if this is quite right
PMID:27666591 PBO:0095870 VW: added exists_during..
PMID:27666591 FYPO:0000228 Figure S1G
PMID:27666591 PBO:0095877 Figure 4D
PMID:27666591 PBO:0095878 Figure 5A
PMID:27687771 GO:0045944 target genes: cut6, vht1, bio2
PMID:27687771 PBO:0104369 at cut6 gene promoter
PMID:27687771 PBO:0104368 target genes: cut6, vht1, bio2
PMID:27687771 PBO:0104367 target genes: cut6, vht1, bio2
PMID:27687771 PBO:0101186 target genes: cut6, vht1, bio2
PMID:27687866 FYPO:0000972 acetaldehyde absent
PMID:27687866 FYPO:0000972 acetaldehyde absent
PMID:27687866 FYPO:0000972 acetaldehyde absent
PMID:27697865 FYPO:0005976 fig5
PMID:27697865 FYPO:0006476 Fig. S4
PMID:27697865 PBO:0098849 fig 6E
PMID:27697865 FYPO:0004438 fig4
PMID:27697865 FYPO:0005342 fig4E
PMID:27697865 FYPO:0000324 fig 5c
PMID:27697865 FYPO:0000274 fig 5c
PMID:27697865 GO:0110162 (anaphase)
PMID:27697865 FYPO:0004236 fig 1A
PMID:27697865 PBO:0098846 fig 6E
PMID:27697865 FYPO:0001513 Fig.
PMID:27697865 FYPO:0001513 Fig.
PMID:27697865 FYPO:0000228 6E
PMID:27697865 FYPO:0001355 fig6A
PMID:27697865 FYPO:0002638 vw: changed to increased activation, and D333A allele (as compared to WT)
PMID:27697865 PBO:0098848 fig6 fig 7
PMID:27729451 PBO:0106913 replced GO:1990601 (which acts on ss DNA)
PMID:27736299 PBO:0106447 Fig3. nup45 level reduced to ~45% decreased protein level in heterozygous diploid cell during vegetative growth
PMID:27736299 PBO:0106448 Fig3. Cpc2 level reduced to about 55% decreased protein level in heterozygous diploid cell during vegetative growth
PMID:27736299 PBO:0093767 Fig1. 8.74% longer than control mean
PMID:27736299 PBO:0095711 Fig1. 10.86% shorter than control mean
PMID:27736299 PBO:0106450 Fig3. Pom1 level reduced to ~55% decreased protein level in heterozygous diploid cell during vegetative growth
PMID:27736299 PBO:0095711 Fig1. 11.15% shorter than control mean
PMID:27736299 PBO:0106446 Fig3. Sal3 level reduced to ~48% decreased protein level in heterozygous diploid cell during vegetative growth
PMID:27736299 PBO:0094266 Fig1. 10.81% longer than control mean
PMID:27736299 PBO:0106445 Fig3. Cdr1 level reduced to ~55% decreased protein level in heterozygous diploid cell during vegetative growth
PMID:27736299 PBO:0094266 Fig1. 11.63% longer than control mean
PMID:27736299 PBO:0106444 Fig3. Cdc2 level reduced to about 48% decreased protein level in heterozygous diploid cell during vegetative growth
PMID:27736299 PBO:0094266 Fig1. 14.43% longer than control mean
PMID:27736299 PBO:0106443 Fig3. cdc25 level reduced to ~48% decreased protein level in heterozygous diploid cell during vegetative growth
PMID:27736299 PBO:0094266 Fig1. 15.55% longer than control mean
PMID:27736299 PBO:0106442 Fig3. Nup186 level reduced to ~45% decreased protein level in heterozygous diploid cell during vegetative growth
PMID:27736299 PBO:0094266 Fig1. 15.82% longer than control mean
PMID:27736299 PBO:0097048 Fig3. cdc13 level reduced to ~44% decreased protein level in heterozygous diploid cell during vegetative growth
PMID:27736299 PBO:0094266 Fig1. 16.78% longer than control mean
PMID:27736299 PBO:0106441 Fig3 Nup97 level reduced to ~55% decreased protein level in heterozygous diploid cell during vegetative growth
PMID:27736299 PBO:0094266 Fig1. 18.92% longer than control mean
PMID:27736299 PBO:0106440 Fig3. Nsp1 level reduced to ~45% decreased protein level in heterozygous diploid cell during vegetative growth
PMID:27736299 PBO:0094266 Fig1. 19.29% longer than control mean
PMID:27736299 PBO:0106439 Fig3. Nup184 level reduced to 30% decreased protein level in heterozygous diploid cell during vegetative growth
PMID:27736299 PBO:0093767 Fig1. 8.80% longer than control mean
PMID:27736299 PBO:0097393 Fig3. Ppa2 reduced to~45% decreased protein level in heterozygous diploid cell during vegetative growth
PMID:27736299 PBO:0106449 Fig3. Suc1 level reduced to ~60% decreased protein level in heterozygous diploid cell during vegetative growth
PMID:27736299 PBO:0095712 Fig1. 9.10% shorter than control mean
PMID:27736299 PBO:0094266 Fig1. 23.46% longer than control mean
PMID:27736299 PBO:0106438 Fig3. Dea2 level reduced to 50%
PMID:27736299 PBO:0106451 Fig3. Nup189 level reduced to ~50% decreased protein level in heterozygous diploid cell during vegetative growth
PMID:27736299 PBO:0095711 Fig1. 16.50% shorter than control mean
PMID:27736299 PBO:0094967 Fig3 Wee1 level reduced to ~32% decreased protein level in heterozygous diploid cell during vegetative growth
PMID:27736299 PBO:0019143 Fig1. 31.94% longer than control mean
PMID:27736299 PBO:0093767 Fig1. 8.78% longer than control mean
PMID:27737912 PBO:0104260 fig 6
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 PBO:0101393 Increase of stalled RNA polymerase I at rDNA during G0 phase; nuc1-FLAG
PMID:27738016 PBO:0101393 Increase of stalled RNA polymerase I at rDNA during G0 phase; nuc1-FLAG
PMID:27738016 PBO:0101392 Increase of stalled RNA polymerase I at rDNA during G0 phase; nuc1-FLAG
PMID:27738016 PBO:0101392 Increase of stalled RNA polymerase I at rDNA during G0 phase; nuc1-FLAG
PMID:27738016 PBO:0101391 Decreased RNA polymerase I at rDNA during vegetative growth; nuc1-FLAG
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0004032 Increased RNA polymerase II at rDNA during vegetative growth
PMID:27738016 FYPO:0007639 Increased gH2AX/H2A ratio (marker of DNA damage) at rDNA during G0; 2 day G0 ChIP
PMID:27738016 FYPO:0007639 Increased gH2AX/H2A ratio (marker of DNA damage) at rDNA during G0; 2 day G0 ChIP
PMID:27738016 FYPO:0007639 Increased gH2AX/H2A ratio (marker of DNA damage) at rDNA during G0; 2 day G0 ChIP
PMID:27738016 FYPO:0007639 Increased gH2AX/H2A ratio (marker of DNA damage) at rDNA during G0; 2 day G0 ChIP
PMID:27738016 FYPO:0000429 G0-exit
PMID:27738016 PBO:0101396 Rad22-YFP, G0-exit
PMID:27738016 FYPO:0002835 small-RNA-seq
PMID:27738016 FYPO:0004817 small-RNA-seq
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0000091 15 ug/ml thiabendazole
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 PBO:0101389 S13; Tetrad dissection
PMID:27738016 PBO:0101388 S13; Tetrad dissection
PMID:27738016 PBO:0101388 S13; Tetrad dissection
PMID:27738016 FYPO:0007553 G0 viability assay
PMID:27738016 FYPO:0006660 G0 viability assay
PMID:27738016 FYPO:0006518 G0 viability assay
PMID:27738016 PBO:0101387 2 day G0 ChIP
PMID:27738016 FYPO:0006079 2 day G0 ChIP
PMID:27738016 PBO:0094072 G0 viability assay
PMID:27738016 FYPO:0007553 G0 viability assay
PMID:27738016 FYPO:0006660 G0 viability assay
PMID:27738016 FYPO:0006518 G0 viability assay
PMID:27738016 FYPO:0007553 G0 viability assay
PMID:27738016 FYPO:0000091 15 ug/ml thiabendazole
PMID:27738016 FYPO:0000091 15 ug/ml thiabendazole
PMID:27738016 FYPO:0000091 15 ug/ml thiabendazole
PMID:27738016 FYPO:0000091 15 ug/ml thiabendazole
PMID:27738016 FYPO:0007553 G0 viability assay
PMID:27738016 FYPO:0007553 24h G0 cell microscopy
PMID:27738016 FYPO:0007553 G0 viability assay
PMID:27738016 FYPO:0007553 G0 viability assay
PMID:27738016 FYPO:0007553 24h G0 cell microscopy
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 FYPO:0007553 G0 viability assay
PMID:27738016 FYPO:0007553 24h G0 cell microscopy
PMID:27738016 PBO:0098933 G0 viability assay
PMID:27738016 PBO:0098933 G0 viability assay
PMID:27738016 PBO:0098933 G0 viability assay
PMID:27738016 PBO:0098933 G0 viability assay
PMID:27738016 FYPO:0007553 G0 viability assay
PMID:27738016 FYPO:0007553 24h G0 cell microscopy
PMID:27738016 FYPO:0007553 G0 viability assay
PMID:27738016 FYPO:0007553 24h G0 cell microscopy
PMID:27738016 FYPO:0007553 G0 viability assay
PMID:27738016 FYPO:0007553 24h G0 cell microscopy
PMID:27738016 FYPO:0007553 G0 viability assay
PMID:27738016 FYPO:0007553 24h G0 cell microscopy
PMID:27738016 FYPO:0007553 G0 viability assay
PMID:27738016 FYPO:0007553 24h G0 cell microscopy
PMID:27738016 FYPO:0007553 G0 viability assay
PMID:27738016 FYPO:0007553 24h G0 cell microscopy
PMID:27738016 FYPO:0007553 G0 viability assay
PMID:27738016 FYPO:0007553 24h G0 cell microscopy
PMID:27738016 FYPO:0007553 G0 viability assay
PMID:27738016 FYPO:0007553 24h G0 cell microscopy
PMID:27738016 FYPO:0007553 G0 viability assay
PMID:27738016 FYPO:0007553 24h G0 cell microscopy
PMID:27738016 FYPO:0007553 G0 viability assay
PMID:27738016 FYPO:0007553 24h G0 cell microscopy
PMID:27738016 FYPO:0007553 G0 viability assay
PMID:27738016 FYPO:0007553 24h G0 cell microscopy
PMID:27738016 FYPO:0007553 24h G0 cell microscopy
PMID:27738016 FYPO:0007553 G0 viability assay
PMID:27738016 FYPO:0006935 24h G0 cell microscopy
PMID:27738016 PBO:0101386 G0 viability assay
PMID:27738016 PBO:0101386 G0 viability assay
PMID:27738016 PBO:0101386 G0 viability assay
PMID:27738016 FYPO:0007629 G0 viability assay
PMID:27738016 PBO:0101386 G0 viability assay
PMID:27738016 PBO:0101386 G0 viability assay
PMID:27738016 PBO:0101386 G0 viability assay
PMID:27738016 PBO:0101381 24h G0 cell microscopy
PMID:27738016 FYPO:0006660 G0 viability assay
PMID:27738016 FYPO:0006518 G0 viability assay
PMID:27738016 PBO:0101386 G0 viability assay
PMID:27738016 PBO:0101386 G0 viability assay
PMID:27738016 FYPO:0006660 G0 viability assay
PMID:27738016 PBO:0101386 G0 viability assay
PMID:27738016 FYPO:0000964 15 ug/ml thiabendazole
PMID:27738016 FYPO:0000091 15 ug/ml thiabendazole
PMID:27738016 FYPO:0000091 15 ug/ml thiabendazole
PMID:27738016 FYPO:0000091 15 ug/ml thiabendazole
PMID:27738016 FYPO:0000091 15 ug/ml thiabendazole
PMID:27738016 FYPO:0000091 15 ug/ml thiabendazole
PMID:27738016 PBO:0101381 24h G0 cell microscopy
PMID:27738016 FYPO:0006518 G0 viability assay
PMID:27738016 PBO:0101381 24h G0 cell microscopy
PMID:27738016 FYPO:0006518 G0 viability assay
PMID:27738016 PBO:0101381 24h G0 cell microscopy
PMID:27738016 FYPO:0006518 G0 viability assay
PMID:27738016 FYPO:0007553 G0 viability assay
PMID:27738016 FYPO:0007553 24h G0 cell microscopy
PMID:27738016 FYPO:0000091 15 ug/ml thiabendazole
PMID:27738016 GO:0070317 mutant defective in maintenance of quiescence
PMID:27738016 GO:0070317 mutant defective in maintenance of quiescence
PMID:27738016 FYPO:0000069 Fig S6; 15 ug/ml or 20 ug/ml thiabendazole
PMID:27738016 FYPO:0000069 Fig S6; 15 ug/ml or 20 ug/ml thiabendazole
PMID:27738016 FYPO:0000069 Fig S6; 15 ug/ml or 20 ug/ml thiabendazole
PMID:27738016 FYPO:0000069 Fig S6; 15 ug/ml or 20 ug/ml thiabendazole
PMID:27738016 FYPO:0007553 24h G0 cell microscopy
PMID:27738016 GO:0070317 mutant defective in maintenance of quiescence
PMID:27746023 PBO:0105076 during nitrogen starvation. Although many mutants in the SAPK pathway have defects in mating and meiosis, this result may help to explain why sty1D and wis1D mutants in particular continue to elongate upon N starvation, unlike other mutants in the pathway
PMID:27746023 FYPO:0000646 arrested
PMID:27746023 PBO:0105074 Movie S4. Sty1 activity is critical for maintaining a non-polarized Cdc42 module in N-starved quiescent cells.
PMID:27746023 PBO:0105077 Movie S4. Sty1 activity is critical for maintaining a non-polarized Cdc42 module in N-starved quiescent cells.
PMID:27746023 PBO:0105075 Figure S1B
PMID:27746023 PBO:0105074 Figures 2A and S1A; Movie S1
PMID:27746023 FYPO:0006634 unlike WT cell elongation continued after actin depolymerization, (Figures 2A and 2B; Movie S1) conclusions. 1. the SAPK pathway is required for CRIB dispersal after LatA treatment. 2 the actin cytoskeleton per se is not required for stability of the Cdc42 polarity module at cell tips. 3. cell elongation can occur in the complete absence of the actin cytoskeleton.
PMID:27746023 FYPO:0006634 unlike WT cell elongation continued after actin depolymerization, (Figures 2A and 2B; Movie S1) conclusions. 1. the SAPK pathway is required for CRIB dispersal after LatA treatment. 2 the actin cytoskeleton per se is not required for stability of the Cdc42 polarity module at cell tips. 3. cell elongation can occur in the complete absence of the actin cytoskeleton.
PMID:27746023 PBO:0105075 Figure 2C
PMID:27746023 PBO:0105074 Figure 2C
PMID:27746023 PBO:0105074 Figure 2D
PMID:27746023 PBO:0105074 Figures S1C and S1D
PMID:27746023 PBO:0105074 Figures S1C and S1D
PMID:27811944 PBO:0099388 mutation destabilized Sre1 precursor and prevented Sre1 proteolytic cleavage
PMID:27811944 PBO:0099389 mutation destabilized Sre1 precursor and prevented Sre1 proteolytic cleavage
PMID:27811944 PBO:0099388 deletion of Sre1 aa 877-900 also destabilized Sre1 and prevented proteolytic activation
PMID:27851962 GO:0030014 Figure 1
PMID:27851962 GO:0030014 Figure 1
PMID:27851962 GO:0030014 Figure 1
PMID:27851962 GO:0030014 Figure 1
PMID:27851962 GO:0030014 Figure 1
PMID:27851962 GO:0030014 Figure 1
PMID:27851962 GO:0030014 Figure 1
PMID:27852900 PBO:0097762 fig 8a
PMID:27852900 PBO:0097771 fig 7
PMID:27852900 PBO:0097770 fig 7
PMID:27852900 FYPO:0006547 Figure 3, A and E
PMID:27852900 FYPO:0006547 Figure 3, A and E
PMID:27852900 PBO:0097767 fig 4 GFP-LactC2 probe expressed from pREP3X
PMID:27852900 PBO:0097769 GFP-LactC2 probe expressed from pREP3X
PMID:27852900 PBO:0097769 GFP-LactC2 probe expressed from pREP3X
PMID:27852900 PBO:0097768 fig4 GFP-LactC2 probe expressed from pREP3X
PMID:27852900 PBO:0097769 GFP-LactC2 probe expressed from pREP3X
PMID:27852900 PBO:0097768 fig 4B. GFP-LactC2 probe expressed from pREP3X
PMID:27852900 PBO:0097767 GFP-LactC2 probe expressed from pREP3X
PMID:27852900 FYPO:0004963 Figure 5D
PMID:27852900 PBO:0097763 Figure 8e
PMID:27852900 FYPO:0004964 fig8d
PMID:27852900 FYPO:0002297 fig 8d
PMID:27852900 PBO:0019132 fig 8 a
PMID:27852900 PBO:0097762 fig 8 a
PMID:27871365 GO:0006281 from later paper: We speculate that SPRTN is able to degrade DPCs to peptide adducts that are sufficiently small for efficient TLS. https://www.sciencedirect.com/science/article/pii/S1097276518309948
PMID:27871365 GO:0003697 3H
PMID:27871365 GO:0003690 3H
PMID:27872152 PBO:0093562 Fig. 7D)
PMID:27872152 GO:0005515 (Fig. 2A) (Fig. 2B; Fig. S2B).
PMID:27872152 PBO:0108496 adaptor for dis1-microtubule
PMID:27872152 FYPO:0002061 (Fig. 7B,C)
PMID:27872152 PBO:0108497 Fig. 7E issues/2984
PMID:27872152 PBO:0108498 (2.0% versus <0.1%) (Fig. 7F)
PMID:27872152 PBO:0093562 Fig. 7D)
PMID:27872152 PBO:0093562 Fig. 7D)
PMID:27886462 PBO:0100385 Table 4
PMID:27886462 FYPO:0000245 Figure 1A
PMID:27886462 FYPO:0003004 figure 3C
PMID:27886462 PBO:0100365 figure 2A
PMID:27886462 PBO:0100365 figure 2A
PMID:27886462 PBO:0099519 Figure 4
PMID:27886462 PBO:0100375 Table 3
PMID:27886462 PBO:0100376 Table 3
PMID:27886462 PBO:0100377 Table 3
PMID:27886462 PBO:0100378 Table 3
PMID:27886462 PBO:0100379 Table 3
PMID:27886462 PBO:0100380 Table 3
PMID:27886462 PBO:0100381 Table 3
PMID:27886462 PBO:0109849 figure 3A
PMID:27886462 PBO:0109849 figure 3A
PMID:27886462 PBO:0109849 figure 3A
PMID:27886462 PBO:0100382 Table 3
PMID:27886462 PBO:0100383 Table 4
PMID:27886462 PBO:0100384 Table 4
PMID:27886462 PBO:0100374 Figure 4, Table 3
PMID:27886462 PBO:0100373 Figure 4, Table 3
PMID:27886462 PBO:0100386 Table 4
PMID:27886462 PBO:0100387 Table 4
PMID:27886462 PBO:0100372 Figure 4, Table 3
PMID:27886462 PBO:0100371 Figure 4, Table 3
PMID:27886462 FYPO:0001357 Figure 1A
PMID:27886462 FYPO:0003730 Figure 1C
PMID:27886462 FYPO:0003730 Figure 1C
PMID:27886462 FYPO:0003730 Figure 1C
PMID:27886462 FYPO:0003730 Figure 1C
PMID:27886462 FYPO:0003730 Figure 1C
PMID:27886462 FYPO:0005760 Figure 1B
PMID:27886462 FYPO:0005760 Figure 1B
PMID:27886462 PBO:0109849 figure 3A
PMID:27886462 PBO:0100365 figure 2A
PMID:27886462 PBO:0100365 figure 2A
PMID:27886462 FYPO:0005760 Figure 1B
PMID:27886462 FYPO:0005760 Figure 1B
PMID:27886462 PBO:0100370 Figure 4, Table 3
PMID:27886462 PBO:0100369 Figure 4, Table 3
PMID:27886462 FYPO:0003004 figure 3C
PMID:27886462 PBO:0094194 figure 3C
PMID:27886462 FYPO:0001357 Figure 1A
PMID:27886462 FYPO:0001357 Figure 1A
PMID:27886462 FYPO:0001357 Figure 1A
PMID:27886462 FYPO:0003730 Figure 1C
PMID:27886462 FYPO:0003730 Figure 1C
PMID:27886462 FYPO:0003730 Figure 1C
PMID:27886462 FYPO:0000245 Figure 1A
PMID:27886462 FYPO:0000245 Figure 1A
PMID:27886462 FYPO:0000245 Figure 1A
PMID:27886462 PBO:0100368 Figure 4, Table 3
PMID:27886462 PBO:0100367 Table 2
PMID:27886462 PBO:0100366 Table 2
PMID:27886462 PBO:0094529 Table 2
PMID:27886462 PBO:0094532 Table 2
PMID:27886462 FYPO:0000245 Figure 1A
PMID:27886462 PBO:0094530 Table 2
PMID:27886462 PBO:0094523 Table 2
PMID:27886462 PBO:0094526 Table 2
PMID:27886462 PBO:0094527 Table 2
PMID:27886462 PBO:0094524 Table 2
PMID:27886462 FYPO:0003004 figure 3C
PMID:27889481 PBO:0098191 Figure 1 E and all (n=50, p<0.01) those SPBs failing to recruit Alp4 show SPB separation problems and failed spindle nucleation (Figure 1E).
PMID:27889481 PBO:0098203 (Figure 4B)
PMID:27889481 PBO:0098202 (Figure 3DE)
PMID:27889481 PBO:0098201 fig 3DE
PMID:27889481 PBO:0098200 (Figure 3DE) At restrictive temperature, a population of sad1.2 cells emerges in which all three centromeres are clearly dissociated from the SPB
PMID:27889481 PBO:0098199 fig 3DE sad1.2 cells often show extra Mis6-GFP foci unassociated with the SPB, even at permissive temperature
PMID:27889481 PBO:0098198 Figure S4B
PMID:27889481 PBO:0098197 Figure S4B
PMID:27889481 PBO:0098196 Figures 3B–C, S4A
PMID:27889481 PBO:0098195 Figures 3B–C, S4A
PMID:27889481 PBO:0035494 Figure 1D
PMID:27889481 PBO:0098194 Figure 3A. Sad1.2-GFP remains stably associated with the SPB throughout interphase, in contrast to Sad1.1-GFP, which is destabilized at 36°C
PMID:27889481 FYPO:0005736 Figure I
PMID:27889481 FYPO:0002061 fig2c
PMID:27889481 FYPO:0002060 fig2c
PMID:27889481 FYPO:0002061 fig2c
PMID:27889481 FYPO:0001234 fig2c
PMID:27889481 FYPO:0007487 Figure 1C, I Figure 1F and 1G. We previously observed a tendency for the SPB to dissociate from the NE just prior to meiotic spindle formation in the bqt1Δ setting (Fennell et al., 2015; Tomita and Cooper, 2007); indeed, SPBs showing problems in separation typically appear to dislodge into the cytoplasm (Figure 1C, yellow arrowheads
PMID:27889481 PBO:0035493 Figure 1B
PMID:27889481 PBO:0098193 Figure 3A. Sad1.2-GFP remains stably associated with the SPB throughout interphase, in contrast to Sad1.1-GFP, which is destabilized at 36°C
PMID:27889481 PBO:0035494 Figure 1B
PMID:27889481 PBO:0098192 Figure In 100% of the bqt1Δ cells that show monopolar spindles (n=11), those spindles are nucleated specifically from the old SPB (Figure S1I). Hence, failed spindle nucleation in the absence of the bouquet is specific to the new SPB.
PMID:27889481 FYPO:0006363 Figure 1
PMID:27889481 PBO:0098189 Figure 1C In contrast, in the absence of the bouquet, the duplicated SPBs often fail to separate . Indeed, 75.5% of bqt1Δ cells with defective meiosis show problems in SPB separation at MI
PMID:27889481 PBO:0098188 Figure 1C In contrast, in the absence of the bouquet, the duplicated SPBs often fail to separate. Indeed, 75.5% of bqt1Δ cells with defective meiosis show problems in SPB separation at MI
PMID:27889481 FYPO:0007486 Figure 1
PMID:27889481 PBO:0098190 Figure 1 E In contrast, Alp4 localization is defective (ie one or both SPB signals lack any detectable Alp4 colocalization at MI onset) in 59% of bqt1Δ meiocytes (n= 100, p<0.01) from the onset of MI onwards,
PMID:27889481 PBO:0035493 Figure 1D
PMID:27889481 FYPO:0002060 fig6
PMID:27889481 FYPO:0004367 fig6
PMID:27889481 FYPO:0000737 abolished
PMID:27889481 FYPO:0004160 Figure 5C. spindle formation occurs normally at both MI and MII in sad1.2 meiosis
PMID:27889481 PBO:0098206 Figure 5B. centromeres are also released from LINC in bouquet-defective cells
PMID:27889481 PBO:0098205 fig 5.C
PMID:27889481 PBO:0098204 (Figures 4D–E, S5B, S5D) sad1.2 cells exhibiting total centromere dissociation not only fail to insert but also appear to separate from the NE, dislodging into the cytoplasm
PMID:27898700 PBO:0096858 Fig 4
PMID:27898700 PBO:0096854 Fig 4
PMID:27898700 PBO:0095928 Fig 4
PMID:27898700 PBO:0096857 Fig 4
PMID:27898700 PBO:0096856 Fig 4
PMID:27898700 PBO:0096855 Fig S4D S4E
PMID:27898700 PBO:0096854 Fig 4
PMID:27898700 PBO:0037854 fig 1C
PMID:27898700 FYPO:0001368 fig 1FG
PMID:27898700 FYPO:0002423 fig 1B swollen multiseptate elongated
PMID:27898700 PBO:0037852 fig 1C
PMID:27898700 FYPO:0004653 fig 1FG
PMID:27898700 FYPO:0001365 fig 1FG
PMID:27898700 PBO:0096853 Fig S3B
PMID:27898700 PBO:0037851 fig 1A
PMID:27898700 PBO:0095928 Fig 4
PMID:27898700 FYPO:0001369 fig 1FG slides along axis from midpoint
PMID:27898700 FYPO:0003205 Fig 2 A
PMID:27898700 FYPO:0005871 Fig 2 A
PMID:27898700 FYPO:0005469 fig 1A during cytokinesis
PMID:27898700 FYPO:0005872 Fig 2 A
PMID:27898700 FYPO:0005873 Fig 2 A (2x WT)
PMID:27898700 FYPO:0001035 Fig 2 A (3x WT)
PMID:27898700 PBO:0096852 Fig S3B
PMID:27898700 PBO:0037853 fig 1C
PMID:27901072 PBO:0099059 asynchronous fig 3a
PMID:27901072 PBO:0099049 asynchronous fig 3a
PMID:27901072 PBO:0099048 asynchronous fig 3a
PMID:27901072 PBO:0099047 1d
PMID:27901072 PBO:0099067 fig6
PMID:27901072 PBO:0099063 asynchronous fig 3a
PMID:27901072 PBO:0099061 asynchronous fig 3a
PMID:27901072 PBO:0099060 asynchronous fig 3a
PMID:27901072 PBO:0099050 asynchronous fig 3a
PMID:27901072 PBO:0099058 asynchronous fig 3a
PMID:27901072 PBO:0099057 asynchronous fig 3a
PMID:27901072 PBO:0099056 asynchronous fig 3a
PMID:27901072 PBO:0099063 asynchronous fig 3a
PMID:27901072 PBO:0099062 asynchronous fig 3a
PMID:27901072 PBO:0099061 asynchronous fig 3a
PMID:27901072 PBO:0099060 asynchronous fig 3a
PMID:27901072 PBO:0099059 asynchronous fig 3a
PMID:27901072 PBO:0099058 asynchronous fig 3a
PMID:27901072 PBO:0099057 asynchronous fig 3a
PMID:27901072 PBO:0099056 asynchronous fig 3a
PMID:27901072 PBO:0099055 asynchronous fig 3a
PMID:27901072 PBO:0099054 asynchronous fig 3a
PMID:27901072 PBO:0099053 asynchronous fig 3a
PMID:27901072 PBO:0099052 asynchronous fig 3a
PMID:27901072 PBO:0099051 asynchronous fig 3a
PMID:27902423 FYPO:0002061 Promoter analysis
PMID:27902423 FYPO:0002061 Promoter analysis
PMID:27902423 FYPO:0001407 Promoter analysis
PMID:27966061 FYPO:0005886 indicates Hsf1 activation
PMID:27974503 GO:0006896 Cpy missorting in null mutant
PMID:27974503 GO:0034044 Suquence homology, localization, co-immunoprecipitation
PMID:27974503 PBO:0093595 Slow growth. Reduced colony size
PMID:27974503 GO:0006896 Cpy1 missorting in null mutant
PMID:27974503 GO:0034044 Sequence similarityto ChAPs, protein localization, Co-immunoprecipitation
PMID:27974503 GO:0043001 Abnormal GFP-Syb1 localization
PMID:27974503 GO:0043001 Abnormal GFP-Syb1 distribution
PMID:27974503 GO:0006896 Cpy1 missorting in null mutant
PMID:27974503 GO:0006895 Aberrant Golgi stacks
PMID:27974503 GO:0006896 Cpy1 missorting in null mutant
PMID:27984744 FYPO:0006518 Fig. 1B
PMID:27984744 FYPO:0006518 Fig. 1A
PMID:27984744 FYPO:0006518 Fig. 1B
PMID:27984744 FYPO:0004276 ChIP-seq; Fig. 1C-D
PMID:27984744 FYPO:0006518 Fig. S2
PMID:27984744 PBO:0101377 Fig. 2A-B
PMID:27984744 FYPO:0007629 Fig. 1A
PMID:27984744 FYPO:0007629 Fig. 1B
PMID:27984744 FYPO:0007629 Fig. 1A
PMID:27984744 FYPO:0007629 Fig. 1B
PMID:27984744 PBO:0101377 Fig. 2E-F
PMID:27984744 PBO:0101377 Fig. 2E-F
PMID:27984744 PBO:0101377 Fig. 2E-F
PMID:27984744 FYPO:0006518 Fig. 1A
PMID:27984744 FYPO:0006518 Fig. 1B
PMID:27984744 FYPO:0006518 Fig. 1A
PMID:27984744 FYPO:0006518 Fig. 1B
PMID:27984744 FYPO:0006518 Fig. 1A
PMID:28011631 PBO:0105894 figure S2
PMID:28011631 FYPO:0004925 Fig. 4F Isp3-GFP was improperly assembled in the dga1Δplh1Δ mutant.
PMID:28011631 GO:0140043 Fig. 1F and Fig. 2C
PMID:28011631 GO:0140043 Fig. 1H and Fig. 3B
PMID:28011631 GO:0140043 Fig. 3B
PMID:28011631 GO:0030476 Fig. 4F Assembly of Isp3-GFP onto the spore surface was defective in the dga1Δplh1Δ mutant.
PMID:28011631 PBO:0105893 figure S2
PMID:28011631 FYPO:0006051 Figure S3 LP clustering at nucleus
PMID:28011631 FYPO:0000808 2C
PMID:28011631 PBO:0105895 2C (also in lantrunculin treated sceels indicating actin dependeny)
PMID:28011631 FYPO:0006051 2C (also in lantrunculin treated sceels indicating actin dependeny)
PMID:28011631 FYPO:0006053 2C (also in lantrunculin treated sceels indicating actin dependeny)
PMID:28011631 FYPO:0006003 Fig. 3B normal lipid droplet localization to FSM leading edge
PMID:28011631 FYPO:0006053 Fig. 3B (also in lantrunculin treated sceels indicating actin dependeny)
PMID:28011631 FYPO:0004993 Fig. 4A
PMID:28011631 FYPO:0006054 Fig. 3B (also in lantrunculin treated sceels indicating actin dependeny)
PMID:28011631 GO:0140042 (Fig. 4B)
PMID:28011631 GO:0140042 (Fig. 4B)
PMID:28011631 PBO:0105896 Fig. 4A,C)
PMID:28011631 GO:0019915 Fig. 4B The dga1Δplh1Δ mutant possessed few lipid droplets.
PMID:28011631 PBO:0105892 Fig. 4A, 4C, and 4D Using spore colony formation assay and microscopic observation, most of the dga1Δplh1Δ mutant spores failed to form colonies showed no sign of germination.
PMID:28011631 GO:0019915 Fig. 4B The dga1Δplh1Δ mutant possessed few lipid droplets.
PMID:28017606 PBO:0097628 136 amino acids of Mad1 containing a coiled-coil region (CC) were removed, preventing Mad1-Mad2 interaction with Mlps and the nuclear envelope and also removing the Cut7 interaction site. These mad1-DCC cells were also able to arrest efficiently when TetR-Spc7-9TE and TetR-D(1-302)Mph1 were co-expressed (Figure 3E). We conclude that the Mad and Bub proteins do not need to be enriched at kinetochores, spindle poles, or the nuclear periphery for a robust checkpoint arrest to be generated in fission yeast. Most likely a diffuse, soluble pool of Spc7
PMID:28017606 FYPO:0007438 advance (by �4 hr) in the timing of arrest in bub3D cells arresting due to Spc7-9TE cells (although there is no effect with Spc7-wt, see Figure S4C).
PMID:28017606 GO:0007094 This demonstrates that the ‘‘activated’’ Spc7-9TE binding platform is sufficient to recruit these three checkpoint proteins constitutively, and that this works ectopically and thus does not require additional kinetochore factors. and Figure 1C. thus, we believe that this Spc7-Bub-Mad3 complex likely acts as an independent signaling module
PMID:28017606 PBO:0097625 Spc7-wt arrested significantly faster than Spc7-9TE, with $60% mitotic arrest after 12 hr compared to 16 hr for Spc7-9TE.
PMID:28017606 PBO:0097627 Strains co-expressing Spc7 and Mph1 do not accumulate Mad2-GFP at spindle poles in strains containing the mad1-KAKA mutation that disrupts the Mad1-Cut7 kinesin motor interaction.
PMID:28017606 PBO:0097624 Figures 1D and 1E / ectopic. show a very striking result: co-expression of TetR-Spc7-9TE with TetR-D(1-302)Mph1 was sufficient to arrest cells in mitosis.
PMID:28031482 PBO:0094665 Fig 6 C
PMID:28031482 PBO:0094656 Fig. 4H, right panel
PMID:28031482 PBO:0094657 Fig. 5A
PMID:28031482 PBO:0094658 Fig. 5C
PMID:28031482 PBO:0094659 Fig. 5B
PMID:28031482 PBO:0094660 Fig. 5D
PMID:28031482 GO:0005737 Fig. 5G, left panel
PMID:28031482 FYPO:0000784 Fig. 5G, left panel
PMID:28031482 PBO:0094661 Fig. 5G, left panel
PMID:28031482 PBO:0094663 Figure 6 c
PMID:28031482 PBO:0094664 Fig 6 D
PMID:28031482 FYPO:0002061 figure 7A
PMID:28031482 PBO:0094664 Fig 6 D
PMID:28031482 PBO:0094648 Fig 6 D
PMID:28031482 PBO:0094670 Fig 6 C
PMID:28031482 PBO:0094669 Fig 6 C
PMID:28031482 PBO:0094668 Fig 6 C
PMID:28031482 PBO:0094667 Fig 6 C
PMID:28031482 PBO:0094666 Fig 6 C
PMID:28031482 PBO:0094662 Figure 6 A
PMID:28031482 PBO:0094663 Figure 6 c
PMID:28031482 PBO:0094654 figure 2D
PMID:28031482 PBO:0094653 figure 2B
PMID:28031482 PBO:0094652 figure 1 E
PMID:28031482 PBO:0094651 figure 1 D
PMID:28031482 PBO:0094650 figure 1 E
PMID:28031482 PBO:0094664 Fig 6 D
PMID:28031482 PBO:0094664 Fig 6 D
PMID:28031482 PBO:0094664 Fig 6 D
PMID:28031482 PBO:0094649 figure 1 E
PMID:28031482 FYPO:0001234 Fig 6 D
PMID:28031482 FYPO:0001234 Fig 6 D
PMID:28031482 PBO:0094655 Fig. 4D
PMID:28031482 FYPO:0001896 Fig. 4B Fig. 4D
PMID:28031482 FYPO:0001895 Fig. 2B
PMID:28031482 FYPO:0005993 figure 2D
PMID:28031482 PBO:0094671 Fig 6 C
PMID:28031482 PBO:0094672 Fig 6 C
PMID:28031482 FYPO:0001234 Fig 6 D
PMID:28031482 PBO:0094648 Fig 6 D
PMID:28031482 GO:0000290 pdc2 is required for mRNA decapping. Fig. 2A 2B
PMID:28031482 GO:0000932 Fig. 1D
PMID:28103117 PBO:0101618 fig 2a
PMID:28103117 PBO:0111515 fig 2a
PMID:28103117 PBO:0099452 fig3a Cdk1 consensus sites
PMID:28103117 PBO:0099453 changes in phosphrylation level fig4 Wee1 to remain in the partially phosphorylated form throughout the cell cycle (Fig. S2)
PMID:28103117 PBO:0099454 changes in phosphorylation level Figs. 5A, B and S2)
PMID:28103117 PBO:0111514 fig 2a
PMID:28103117 PBO:0099453 changes in phosphorylation level Figs. 5A, B and S2)
PMID:28103117 PBO:0099454 changes in phosphrylation level fig4 Wee1 to remain in the partially phosphorylated form throughout the cell cycle (Fig. S2)
PMID:28103117 PBO:0111513 fig 2a For example, in the second cell cycle, Wee1 phosphorylation was initiated at the end of G2 (180 minutes) and reached a maximum level at metaphase (200 minutes), just before Cdc13 degradation in anaphase (220 minutes).
PMID:28103117 PBO:0099448 fig 2a
PMID:28103117 FYPO:0005955 The cell cycle was 20 min longer in clp1D cells compared with wild type cells.
PMID:28103117 PBO:0101618 fig 2a
PMID:28103117 PBO:0099449 fig 2a
PMID:28160081 FYPO:0006331 fig2B
PMID:28160081 FYPO:0000245 fig 5
PMID:28160081 FYPO:0006333 fig2B
PMID:28160081 FYPO:0006331 fig2B
PMID:28160081 FYPO:0006331 fig2B
PMID:28160081 FYPO:0000245 fig2A
PMID:28160081 FYPO:0000245 fig 2A
PMID:28160081 FYPO:0000245 fig 2A
PMID:28160081 FYPO:0000245 fig 2A
PMID:28160081 FYPO:0006331 fig2B
PMID:28160081 FYPO:0001309 fig 4c
PMID:28178520 FYPO:0005683 Fig 4 D
PMID:28178520 PBO:0107476 Figure 4E
PMID:28178520 PBO:0025602 vw: moved down to nucleoplasm
PMID:28178520 PBO:0022963 Fig 1 requires Clp1 activity
PMID:28178520 PBO:0022963 Fig 1 requires Klp9, Clp1 activity
PMID:28178520 GO:0000022 requires motor activity
PMID:28178520 FYPO:0005343 FIg 3
PMID:28178520 PBO:0022963 fig1
PMID:28178520 PBO:0107446 Figure 1B and S1B,C
PMID:28178520 PBO:0105361 Figure 1B and S1B,C
PMID:28178520 PBO:0107447 Figure 1B and S1B,C
PMID:28178520 PBO:0107448 Figure 1B and S1B,C
PMID:28178520 PBO:0107449 Figure 1B and S1B,C
PMID:28178520 PBO:0107450 Figure 1B and S1B,C
PMID:28178520 PBO:0107451 Figure 1B and S1B,C
PMID:28178520 PBO:0107452 Figure 1B and S1B,C
PMID:28178520 PBO:0107453 Figure 1B and S1B,C
PMID:28178520 PBO:0107454 Figure 1B and S1B,C
PMID:28178520 PBO:0018645 Figure 1C
PMID:28178520 PBO:0107455 (Figures S1D and S1E)
PMID:28178520 PBO:0107453 (Figure 1D)
PMID:28178520 PBO:0107454 (Figure 1D)
PMID:28178520 PBO:0101952 Figure 1B and S1B,C
PMID:28178520 PBO:0107446 Figure 1B and S1B,C
PMID:28178520 PBO:0107456 Figure 1E
PMID:28178520 PBO:0107457 (Figures 1G and 1I; Figure S1F)
PMID:28178520 PBO:0095694 (Figures 1G and 1I; Figure S1F)
PMID:28178520 PBO:0107446 Figure 1H
PMID:28178520 PBO:0097607 (Figures 1H)
PMID:28178520 PBO:0107454 (Figures 1H)
PMID:28178520 PBO:0107458 Figure 1I
PMID:28178520 PBO:0107459 Figure 1I
PMID:28178520 PBO:0095694 (Figures 1J)
PMID:28178520 PBO:0095694 (Figures 1J)
PMID:28178520 PBO:0101201 (Figures 1J)
PMID:28178520 PBO:0107460 (Figures 1J)
PMID:28178520 PBO:0107461 (Figures 1J)
PMID:28178520 PBO:0107462 (Figures 1J)
PMID:28178520 PBO:0097610 (Figures 1J)
PMID:28178520 PBO:0107463 (Figures 1J)
PMID:28178520 PBO:0107463 (Figures 1J)
PMID:28178520 PBO:0097610 (Figures 1J)
PMID:28178520 PBO:0097932 (Figures S2A)
PMID:28178520 PBO:0097932 (Figures S2A)
PMID:28178520 PBO:0107464 (Figures S2B)
PMID:28178520 FYPO:0006475 (Figures S2B)
PMID:28178520 PBO:0101954 figure 2A
PMID:28178520 PBO:0107467 Figure 2A; Figure S3A
PMID:28178520 FYPO:0000324 Figure 2A; Figure S3A
PMID:28178520 PBO:0107468 Figure S3B
PMID:28178520 PBO:0095920 Figure S3B
PMID:28178520 PBO:0107469 Figure 2B
PMID:28178520 PBO:0107470 Figure 2B
PMID:28178520 PBO:0107471 Figure S3C/D
PMID:28178520 PBO:0107472 (Figure S4C)
PMID:28178520 FYPO:0006646 Fig 5
PMID:28178520 FYPO:0005684 Fig 5
PMID:28178520 FYPO:0006646 Fig 4 D
PMID:28178520 FYPO:0005684 Fig 4 D
PMID:28178520 FYPO:0005684 Fig 4 D
PMID:28178520 FYPO:0005684 Fig 4 A
PMID:28178520 FYPO:0006646 Fig 4 A
PMID:28178520 FYPO:0006646 Fig 4 A
PMID:28178520 FYPO:0006646 Fig 4 A
PMID:28178520 PBO:0107479 (Figure 5B)
PMID:28178520 PBO:0107478 (Figure 5B)
PMID:28178520 PBO:0107473 (Figure S4C)
PMID:28178520 PBO:0107474 (Figure S4C)
PMID:28178520 PBO:0107475 (Figure S4C)
PMID:28178520 FYPO:0005684 Figure 4A
PMID:28178520 FYPO:0006257 Fig 5
PMID:28178520 FYPO:0005683 Fig 5
PMID:28178520 PBO:0107477 Figure 4E
PMID:28178520 FYPO:0004833 Fig 4 D
PMID:28178520 FYPO:0006257 Fig 4 D
PMID:28178520 FYPO:0005683 Fig 4 A
PMID:28178520 FYPO:0005684 Fig 4 A
PMID:28178520 FYPO:0006257 Fig 4 A
PMID:28178520 FYPO:0006257 Fig 4 A
PMID:28178520 FYPO:0006257 Fig 4 A
PMID:28178520 FYPO:0005684 Fig 4 A
PMID:28178520 FYPO:0005684 Fig 4 A
PMID:28178520 FYPO:0005683 Fig 4 D
PMID:28191457 PBO:0107140 Phenotype is inherited in non-Mendelian manner, via protein aggregates (prion-like).
PMID:28191457 PBO:0107139 SDS-PAGE followed by western blotting and proteinase K treatment. Dot plots with extracts for pellet, soluble and total cell fractions with and without pre-treatment with 2% SDS. SDD-AGE gels of samples treated at room temperature and at 95°C, both with and without curing with GdnHCl.
PMID:28193844 GO:0000329 fig4
PMID:28193844 GO:0140357 6a
PMID:28193844 GO:0000324 fig4
PMID:28193844 GO:0015886 6
PMID:28193844 PBO:0094472 8b
PMID:28193844 MOD:00171 they show it is GPI anchored, the specified residue is predicted
PMID:28193844 FYPO:0006890 9
PMID:28202541 PBO:0106196 improved relative to WT Sre1
PMID:28202541 PBO:0106193 Ost1-mCherry increased signal in ER
PMID:28202541 PBO:0106191 Scp1-13xMyc used for Scp1, pulled on Myc
PMID:28202541 PBO:0106195 Ost1-mCherry, mCherry antibody
PMID:28202541 FYPO:0002448 pulled on Dsc2
PMID:28202541 PBO:0106192 Anp1-GFP mislocalized from Golgi puncta to ER and vacuole
PMID:28202541 PBO:0106194 Anp1-GFP degradation as assayed by appearance of free GFP
PMID:28218250 PBO:0096562 ChIP-seq
PMID:28218250 PBO:0096563 ChIP-seq
PMID:28218250 PBO:0096562 ChIP-seq
PMID:28218250 PBO:0096563 ChIP-seq
PMID:28218250 FYPO:0005950 ChIP-seq
PMID:28218250 FYPO:0005952 ChIP-seq
PMID:28218250 FYPO:0005950 ChIP-seq
PMID:28218250 FYPO:0005951 ChIP-seq
PMID:28218250 PBO:0096563 ChIP-seq
PMID:28218250 FYPO:0005950 ChIP-seq
PMID:28218250 PBO:0096562 ChIP-seq
PMID:28218250 PBO:0096564 ChIP-seq; same severity as spt16-1 alone
PMID:28218250 PBO:0096564 ChIP-seq
PMID:28218250 PBO:0096565 ChIP-seq
PMID:28218250 PBO:0096562 ChIP-seq
PMID:28218250 PBO:0096562 ChIP-seq
PMID:28218250 PBO:0096565 ChIP-seq
PMID:28218250 PBO:0096562 ChIP-seq
PMID:28242692 PBO:0097302 Fig 1C
PMID:28242692 FYPO:0002085 Fig. 1B, supp table S1
PMID:28242692 PBO:0097301 Fig 1A
PMID:28242692 FYPO:0001733 Fig. 2B)
PMID:28242692 FYPO:0000772 severe leaking; Fig. 3B, arrow; Fig. 3 C and D, quantifi- cation, figure 4 B
PMID:28242692 PBO:0097300 Fig. 1 D–F
PMID:28242692 PBO:0097305 cells with abnormal NE morphology at the beginning of the exper- iment, by contrast, lost nuclear GFP completely over the time course (Fig. S3B). Thus, cytoplasmic GFP resulted from loss of nuclear integrity rather than from defects in nuclear import.
PMID:28242692 PBO:0097304 partial leaking; Fig. 3B, arrow; Fig. 3 C and D, quantifi- cation
PMID:28242692 PBO:0097304 partial leaking; Fig. 3B, arrow; Fig. 3 C and D, quantifi- cation
PMID:28242692 PBO:0097304 partial leaking; Fig. 3B, arrow; Fig. 3 C and D, quantifi- cation
PMID:28242692 FYPO:0006019 4B, arrowheads, and Fig. 5B
PMID:28242692 PBO:0097303 Fig S1C
PMID:28242692 FYPO:0003751 Remarkably, double-mutant cells displayed WT-like nuclei, although a few examples of probable nuclear fenestrations were observed in lem2Δ single-mutant cells (Fig. 5G).
PMID:28242692 FYPO:0003751 Remarkably, double-mutant cells displayed WT-like nuclei, although a few examples of probable nuclear fenestrations were observed in lem2Δ single-mutant cells (Fig. 5G).
PMID:28242692 PBO:0097303 Fig S1C
PMID:28242692 FYPO:0001513 rescue
PMID:28242692 PBO:0097024 Fig S1AB
PMID:28242692 PBO:0097302 Fig 1C
PMID:28242692 FYPO:0003973 and the NPCs that were present were localized to re- gions that were largely free of karmellae and tubulo-vesicular structures (Fig. 4D).
PMID:28242692 FYPO:0006018 Fig. 4B, asterisk
PMID:28242692 FYPO:0002085 Fig. 1B, supp table S1
PMID:28242692 FYPO:0001420 Fig. 1C
PMID:28242692 PBO:0097302 Fig 1C
PMID:28264193 PBO:0100361 Supp2
PMID:28264193 PBO:0100358 fig5 fusion mutant not currently capturable
PMID:28264193 PBO:0100360 Supp
PMID:28264193 PBO:0100361 Supp2
PMID:28264193 PBO:0100361 Supp2
PMID:28264193 PBO:0100361 Supp2
PMID:28264193 PBO:0100361 Supp2
PMID:2827111 FYPO:0002061 table1
PMID:2827111 GO:0003917 fig 7 B
PMID:2827111 FYPO:0002061 table 1
PMID:2827111 FYPO:0001234 table 1
PMID:2827111 FYPO:0002061 table1
PMID:28281664 FYPO:0001122 Figure 3.
PMID:28281664 PBO:0103667 figure 1a
PMID:28281664 PBO:0093606 Figure 1B
PMID:28281664 PBO:0103667 Figure 2
PMID:28281664 PBO:0103668 Figure 2
PMID:28281664 PBO:0103669 figure 1d
PMID:28281664 PBO:0103670 figure 1c & d
PMID:28281664 PBO:0100665 figure 1D
PMID:28281664 PBO:0103667 Figure 2
PMID:28281664 PBO:0103667 Figure 2.
PMID:28281664 PBO:0103671 Figure 2
PMID:28281664 PBO:0093605 Figure 3.
PMID:28281664 PBO:0096662 Figure 3.
PMID:28281664 PBO:0097116 Figure 3.
PMID:28281664 PBO:0103672 Figure 3.
PMID:28281664 PBO:0103674 Figure 1
PMID:28281664 PBO:0095677 Figure 1D
PMID:28281664 PBO:0103675 Figure 2
PMID:28281664 PBO:0093606 Figure 2
PMID:28281664 PBO:0103675 Figure 2
PMID:28281664 PBO:0103676 Figure 2
PMID:28281664 PBO:0095677 Figure 3.
PMID:28281664 PBO:0093578 Figure 3.
PMID:28281664 FYPO:0001122 figure 1b divides longer than WT in the same conditions
PMID:28281664 PBO:0103678 Figure 3.
PMID:28292899 PBO:0100312 Fig. 6
PMID:28292899 FYPO:0000927 Fig. 7
PMID:28292899 FYPO:0000927 Fig. 7
PMID:28292899 PBO:0100310 Fig. 1A, Inset and Movie S1/ number of Mcp5 molecules per cluster 10 ± 2 ( Fig. 1D)
PMID:28292899 GO:0005546 Fig 2 & Fig. 3C
PMID:28292899 PBO:0100311 Fig. 4 D–F
PMID:28292899 PBO:0100311 Fig. 5B
PMID:28292899 FYPO:0002674 Fig. 5B A(ALSO FOR THE myo-1TH3 domain deletion(need genotype description)
PMID:28292899 FYPO:0003835 Fig. 5B
PMID:28292899 FYPO:0003835 Fig. 5B
PMID:28292918 FYPO:0004286 normal NHEJ repair of hairpin-capped chromosome breaks
PMID:28292918 FYPO:0004286 normal NHEJ repair of hairpin-capped chromosome breaks
PMID:28292918 FYPO:0004287 decreased NHEJ repair of hairpin-capped chromosome breaks
PMID:28292918 FYPO:0004287 decreased NHEJ repair of hairpin-capped chromosome breaks
PMID:28292918 FYPO:0004287 decreased NHEJ repair of hairpin-capped chromosome breaks
PMID:28292918 FYPO:0004286 normal NHEJ repair of hairpin-capped chromosome breaks
PMID:28292918 FYPO:0004287 decreased NHEJ repair of hairpin-capped chromosome breaks
PMID:28292918 FYPO:0004287 decreased NHEJ repair of hairpin-capped chromosome breaks
PMID:28292918 FYPO:0004287 decreased NHEJ repair of hairpin-capped chromosome breaks
PMID:28292918 FYPO:0004287 decreased NHEJ repair of hairpin-capped chromosome breaks
PMID:28292918 FYPO:0004287 decreased NHEJ repair of hairpin-capped chromosome breaks
PMID:28292918 FYPO:0004286 normal NHEJ repair of hairpin-capped chromosome breaks
PMID:28292918 FYPO:0004287 decreased NHEJ repair of hairpin-capped chromosome breaks
PMID:28292918 FYPO:0004286 normal NHEJ repair of hairpin-capped chromosome breaks
PMID:28334955 PBO:0096239 figure 9 F
PMID:28334955 PBO:0096238 figure 9 F
PMID:28334955 FYPO:0003335 Supplementary Figure S3B (abolished by galactose addition)
PMID:28334955 PBO:0096237 figure 9 F
PMID:28334955 PBO:0096240 figure 9 F
PMID:28334955 PBO:0096239 figure 9 F
PMID:28334955 PBO:0096238 figure 9 F
PMID:28334955 PBO:0096237 figure 9 F
PMID:28334955 PBO:0096226 Fig 7 A
PMID:28334955 GO:0035694 Based on what we know about lon in other species, i think the rescue of mpa1 phenotype is enough to predict a catabolic role
PMID:28334955 PBO:0096248 figure 9 d
PMID:28334955 PBO:0096247 figure Supp S8
PMID:28334955 PBO:0096229 fig 1B inferred from
PMID:28334955 PBO:0096228 fig 1B
PMID:28334955 PBO:0096227 fig 1B
PMID:28334955 PBO:0096246 fig 9C
PMID:28334955 PBO:0096227 fig 1B
PMID:28334955 PBO:0096226 Fig 1 A
PMID:28334955 PBO:0093796 Fig 1 A
PMID:28334955 PBO:0093793 Fig 1 A
PMID:28334955 GO:0070131 We named this gene mpa1
PMID:28334955 PBO:0093796 Fig 7 A
PMID:28334955 GO:0005739 figure 6 a
PMID:28334955 PBO:0096245 figure 9A
PMID:28334955 GO:0005759 figure 6 c
PMID:28334955 PBO:0096241 figure 8 D
PMID:28334955 PBO:0096240 figure 8 D
PMID:28334955 PBO:0096239 figure 8 D
PMID:28334955 GO:0005739 figure 6 a
PMID:28334955 GO:0005759 figure 6 c
PMID:28334955 FYPO:0002106 S3
PMID:28334955 FYPO:0002380 S3
PMID:28334955 PBO:0096231 S3
PMID:28334955 PBO:0096232 Figure 2B (barely detectable level )
PMID:28334955 PBO:0096233 Figure 2B
PMID:28334955 PBO:0096234 Figure 2B
PMID:28334955 PBO:0096235 Figure 2B, 8B,8C
PMID:28334955 FYPO:0002582 Figure 2C
PMID:28334955 PBO:0096244 figure 8 A
PMID:28334955 PBO:0096233 Figure 8B,8C
PMID:28334955 PBO:0096232 Figure 8B,8C (barely detectable level )
PMID:28334955 PBO:0093796 Fig 1 C
PMID:28334955 PBO:0093793 Fig 1 C
PMID:28334955 PBO:0093605 Fig 1 E/F
PMID:28334955 FYPO:0004153 Supplementary Figure S3B
PMID:28334955 PBO:0096240 figure 9 F
PMID:28334955 PBO:0096238 figure 8 D
PMID:28334955 PBO:0096237 figure 8 D
PMID:28334955 PBO:0096236 figure 8 D
PMID:28334955 PBO:0096234 Figure 8B,8C
PMID:28334955 PBO:0096229 fig 1B inferred from
PMID:28334955 FYPO:0004153 Supplementary Figure S7
PMID:28334955 PBO:0093605 Fig 7 c
PMID:28334955 PBO:0096227 fig 7 B
PMID:28338873 GO:0051017 assayed in vitro
PMID:28338873 FYPO:0006026 assayed in vitro
PMID:28343969 PBO:0098610 Fig 2 B
PMID:28343969 FYPO:0002060 Fig S4A
PMID:28343969 FYPO:0002061 Fig S4A
PMID:28343969 PBO:0098605 Fig S2A, S2C
PMID:28343969 PBO:0098620 (Figures S4D and S4E
PMID:28343969 PBO:0098606 Fig 1B
PMID:28343969 PBO:0109337 figure 1 E Thus, although Eso1, Wpl1, and Hrk1 all bind to the same surface of Pds5, we assume that they do not always compete for binding because of the excess amounts of Pds5 in the cells. Thus, HIM in Pds5 and PIM in Hrk1 are required solely for centromeric Hrk1 localization and its function, at least in the context of targeting the CPC to centromeres.
PMID:28343969 PBO:0098608 figure 1 E
PMID:28343969 PBO:0095072 Fig 4G
PMID:28343969 PBO:0095072 Fig 4G
PMID:28343969 PBO:0093564 Fig 4f
PMID:28343969 PBO:0093562 Fig 4f
PMID:28343969 PBO:0093557 Fig 4f
PMID:28343969 PBO:0098619 Fig S4A
PMID:28343969 PBO:0098619 Fig S4A
PMID:28343969 PBO:0093558 Fig 4f
PMID:28343969 PBO:0098618 Fig 4E
PMID:28343969 PBO:0098618 Fig 4E
PMID:28343969 FYPO:0002061 4C
PMID:28343969 PBO:0098603 18degC Fig 2C, 2D, 2G This phenotype is largely suppressed by tethering Hrk1 to centromeres. (bw, I made an annotation to represent this suppression below)
PMID:28343969 PBO:0022253 (Figures S4D and S4E
PMID:28343969 PBO:0022253 (Figures S4D and S4E
PMID:28343969 PBO:0098604 Fig 4F, 4H (cut9-665 move to background for this one)
PMID:28343969 PBO:0098604 Fig 4H (cut9-665 move to background for this one)
PMID:28343969 PBO:0098602 Fig 2C, 2D, 2G
PMID:28343969 FYPO:0002061 4C
PMID:28343969 PBO:0098617 fig 4b
PMID:28343969 PBO:0098617 fig 4b
PMID:28343969 FYPO:0006521 S4A
PMID:28343969 FYPO:0006521 S4A
PMID:28343969 PBO:0098616 fig S4B
PMID:28343969 PBO:0098615 Fig 2 F
PMID:28343969 PBO:0098614 Fig 2E
PMID:28343969 PBO:0098614 Fig 2E
PMID:28343969 PBO:0098613 Fig 2F WT is about the same?
PMID:28343969 PBO:0098613 Fig 2F WT is about the same?
PMID:28343969 PBO:0098612 "Fig 2C this represents Yoshi's suggestion"" An Ark1 reduction can become a reason of merotelic attachment, which is also caused by a defect in kinetochore structures.)"" has_penetrance high , assayed_using ark1"
PMID:28343969 PBO:0098612 "Fig 2C (vw: this represents Yoshi's suggestion"" An Ark1 reduction can become a reason of merotelic attachment, which is also caused by a defect in kinetochore structures.)"""
PMID:28343969 PBO:0098611 Fig 2AB
PMID:28343969 PBO:0098611 Fig 2AB
PMID:28343969 PBO:0098610 Fig 2 B
PMID:28343969 PBO:0098619 Fig S4A
PMID:28343969 PBO:0098609 Fig 2AB
PMID:28343969 PBO:0098609 Fig 2AB
PMID:28343969 PBO:0098620 (Figures S4D and S4E
PMID:28345447 FYPO:0002865 restored by depletion of ammonium
PMID:28345447 FYPO:0002865 restored by depletion of ammonium
PMID:28345447 FYPO:0002865 restored by depletion of ammonium
PMID:28345447 FYPO:0002865 restored by depletion of ammonium
PMID:28345447 FYPO:0002865 restored by depletion of ammonium
PMID:28366743 PBO:0096925 Fig. 3 A/B present in interphase
PMID:28366743 PBO:0095474 Fig 1B
PMID:28366743 PBO:0095474 Fig 1B
PMID:28366743 FYPO:0004367 Fig. 4A
PMID:28366743 FYPO:0003762 Fig. 2C/D, S2B,
PMID:28366743 PBO:0095476 Fig. 2C/D, S2B,
PMID:28366743 PBO:0096935 Figure S3B
PMID:28366743 PBO:0096934 Figure S3B
PMID:28366743 PBO:0096933 Figure S3B
PMID:28366743 PBO:0096933 Figure S3B
PMID:28366743 FYPO:0004318 Fig 1B
PMID:28366743 PBO:0095475 fig 4A
PMID:28366743 PBO:0095474 Fig1B
PMID:28366743 PBO:0095475 Fig1b
PMID:28366743 PBO:0095476 Fig 1B
PMID:28366743 PBO:0096932 Figure S3B
PMID:28366743 PBO:0096932 Figure S3B
PMID:28366743 PBO:0095476 Fig S1G
PMID:28366743 PBO:0096924 Fig. 3B
PMID:28366743 PBO:0096931 Fig S3B
PMID:28366743 PBO:0096925 Fig. 3B
PMID:28366743 PBO:0096921 Fig 4D
PMID:28366743 PBO:0096926 Fig. 4C
PMID:28366743 PBO:0096927 Fig. 4C
PMID:28366743 PBO:0096920 Figure 4D
PMID:28366743 PBO:0096926 Fig. 4C
PMID:28366743 PBO:0096921 figure 4D. s
PMID:28366743 PBO:0096921 Figure 4D
PMID:28366743 PBO:0095475 Figures 1FandS1H).
PMID:28366743 FYPO:0004318 (Figure 1F
PMID:28366743 FYPO:0004318 supp S1h
PMID:28366743 PBO:0096926 figure 4C. synchronous mitotic cells
PMID:28366743 PBO:0096922 fig 3.a
PMID:28366743 PBO:0096923 figur 3A
PMID:28366743 PBO:0096929 Fig. 1C synchronous mitotic cells
PMID:28366743 PBO:0096922 figur 3A
PMID:28366743 PBO:0096928 synchronous mitotic cells fig 1c
PMID:28366743 PBO:0096923 fig 3a
PMID:28366743 PBO:0096924 Fig. 3 A/B present in interphase cells
PMID:28366743 PBO:0096930 Figure S1e
PMID:28366744 FYPO:0005783 fig 1 c
PMID:28366744 PBO:0095469 fig 2a
PMID:28366744 PBO:0095924 figure 2b
PMID:28366744 PBO:0105661 Figures 3A and 3B
PMID:28366744 PBO:0105662 (Figure 3B).
PMID:28366744 PBO:0105663 (Figure 3A).
PMID:28366744 PBO:0105664 Figure 3A
PMID:28366744 PBO:0105663 (Figure 3A).
PMID:28366744 PBO:0105665 (Figure 3B).
PMID:28366744 GO:0031145 Deletion increases levels of mitotic checkpoint complex associated with the anaphase promoting complex in mitosis.
PMID:28366744 GO:0031145 Required for mitotic checkpoint complex binding to the anaphase promoting complex.
PMID:28366744 FYPO:0004318 vw I changed the genotype/ Fig 1 A (checkpoint assay)
PMID:28366744 FYPO:0005727 vw; I changed the genotype here
PMID:28366744 PBO:0105657 "vw changed term from ""reduced ubiquitin ligase activity"""
PMID:28366744 FYPO:0004318 Fig 1 A (checkpoint assay)
PMID:28366744 FYPO:0004318 Fig 1 A (checkpoint assay)
PMID:28366744 FYPO:0004318 Fig 1 A (checkpoint assay)
PMID:28366744 FYPO:0004318 Fig 1 A (checkpoint assay)
PMID:28366744 FYPO:0004318 Fig 1 A (checkpoint assay)
PMID:28366744 FYPO:0005783 fig 1 c
PMID:28366744 PBO:0105660 fig 2a
PMID:28366744 PBO:0095469 fig 2a
PMID:28366744 FYPO:0007173 fig 1 c
PMID:28366744 PBO:0105658 fig S1
PMID:28366744 PBO:0105659 fig 2a
PMID:28367989 PBO:0111620 S2P form
PMID:28377506 FYPO:0001934 fig4
PMID:28377506 FYPO:0000726 fig4D
PMID:28377506 FYPO:0000963 "fig 7: ""unlike the hem13-1 mutant, the hem12 and hem14 null mutants of the heme biosynthesis pathway are insensitive to HU"""
PMID:28377506 FYPO:0000963 "fig 7: ""unlike the hem13-1 mutant, the hem12 and hem14 null mutants of the heme biosynthesis pathway are insensitive to HU"""
PMID:28377506 FYPO:0001934 fig4
PMID:2837764 GO:0005786 assayed using mammalian proteins
PMID:28388826 FYPO:0006566 data not shown
PMID:28388826 FYPO:0006566 data not shown
PMID:28404620 FYPO:0006109 sequencing of Ago1-bound siRNA
PMID:28404620 FYPO:0006109 sequencing of Ago1-bound siRNA
PMID:28404620 FYPO:0006110 sequencing of Ago1-bound siRNA
PMID:28404620 FYPO:0006109 sequencing of Ago1-bound siRNA
PMID:28404620 PBO:0097042 uses Pol ii-RNA immunoprecipitation
PMID:28404620 PBO:0097041 also uses Pol ii-RNA immunoprecipitation
PMID:28404620 FYPO:0002827 uses Pol ii-RNA immunoprecipitation
PMID:28404620 FYPO:0006109 sequencing of Ago1-bound siRNA
PMID:28404620 FYPO:0006109 sequencing of Ago1-bound siRNA
PMID:28404620 PBO:0097039 also uses Pol ii-RNA immunoprecipitation
PMID:28404620 PBO:0098754 uses histone H3 RNA immunoprecipitation
PMID:28404620 FYPO:0006109 sequencing of Ago1-bound siRNA
PMID:28410370 PBO:0102726 phenotype more severe when crossed to fus1∆
PMID:28410370 FYPO:0006108 wider distribution along shmoo tip
PMID:28410370 PBO:0105710 wider localization
PMID:28410370 PBO:0105710 wider localization
PMID:28410370 PBO:0105710 wider localization
PMID:28410370 PBO:0105712 wider localization at the shmoo tip
PMID:28410370 PBO:0102726 stronger phenotype when crossed to fus1∆
PMID:28410370 PBO:0105710 Wider localization at shmoo tip
PMID:28410370 FYPO:0004806 Strong phenotype in crosses with fus1∆.
PMID:28410370 PBO:0102727 more severe phenotype when crossed to fus1delta
PMID:28410370 PBO:0102726 more severe phenotype when crossed to fus1∆
PMID:28410370 PBO:0105713 wider localization
PMID:28410370 PBO:0105712 wider localization
PMID:28432181 PBO:0100750 snRNA/ complementation of yeast pus1
PMID:28438891 GO:0000785 Fig EV5
PMID:28438891 GO:0045875 type 2 cohesion (still bound) MITOTIC
PMID:28438891 GO:0045875 MIOTOTIC
PMID:28438891 MOD:00046 Fig 3C
PMID:28438891 FYPO:0002060 Fig 4E
PMID:28438891 FYPO:0002061 Figure 5 B (exacerbates )
PMID:28438891 FYPO:0002060 Fig 5A
PMID:28438891 PBO:0099132 required for Rad21 dephosphorylation
PMID:28438891 PBO:0099133 type 2 cohesion (still bound)
PMID:28438891 FYPO:0002061 Fig 1C
PMID:28438891 FYPO:0001357 Fig 1C
PMID:28438891 FYPO:0002061 Fig 1C
PMID:28438891 FYPO:0002061 Fig 1C
PMID:28438891 PBO:0096226 Fig 1C
PMID:28438891 PBO:0096226 Fig 1C
PMID:28438891 PBO:0096226 Fig 1C
PMID:28438891 FYPO:0001357 Fig 1C
PMID:28438891 FYPO:0001357 Fig 1C
PMID:28438891 FYPO:0001357 Fig 1D
PMID:28438891 FYPO:0001357 Fig 1D
PMID:28438891 PBO:0096226 Fig 1C
PMID:28438891 PBO:0096226 Fig 1C
PMID:28438891 PBO:0096226 Fig 1C
PMID:28438891 PBO:0099134 Fig 3C
PMID:28438891 PBO:0095073 Fig 3C
PMID:28438891 PBO:0095073 Fig 3C
PMID:28438891 PBO:0099135 Fig 3C
PMID:28438891 FYPO:0001357 fig 4
PMID:28438891 GO:0005515 fig 7
PMID:28467824 FYPO:0000826 Mutations that are predicted to impair middle module sta- bility also lead to a general decrease in RNA synthesis (Extended Data Fig. 4d), showing that the middle module is globally required for transcription. (I use txn rather than RNA level because we know it is transcription)
PMID:28467824 FYPO:0000826 Mutations that are predicted to impair middle module sta- bility also lead to a general decrease in RNA synthesis (Extended Data Fig. 4d), showing that the middle module is globally required for transcription. (I use txn rather than RNA level because we know it is transcription)
PMID:28469148 PBO:0102481 ura1 met5
PMID:28469148 PBO:0102481 ura1 met5
PMID:28469148 PBO:0102481 ura1 met5
PMID:28469148 PBO:0102473 ade6 arg1
PMID:28469148 PBO:0102480 lys3 ura1
PMID:28469148 PBO:0102481 ura1 met5
PMID:28469148 PBO:0102480 lys3 ura1
PMID:28469148 PBO:0102481 ura1 met5
PMID:28469148 PBO:0102480 lys3 ura1
PMID:28469148 PBO:0102480 lys3 ura1
PMID:28469148 PBO:0102479 lys3 ura1
PMID:28469148 PBO:0102480 lys3 ura1
PMID:28475874 FYPO:0003589 in response to a single blocked replisome
PMID:28475874 FYPO:0006086 in response to a single blocked replisome
PMID:28475874 FYPO:0005236 in response to a single blocked replisome
PMID:28475874 FYPO:0004251 in response to a single blocked replisome
PMID:28475874 FYPO:0003589 in response to a single blocked replisome
PMID:28475874 GO:0031297 In the absence of Rad51, newly replicated strands are extensively resected at dysfunctional replication forks thus generating mitotic sister chromatid bridging
PMID:28475874 GO:0031297 In the absence of Rad52, newly replicated strands are extensively resected at dysfunctional replication forks thus generating mitotic sister chromatid bridging.
PMID:28475874 FYPO:0003589 in response to a single blocked replisome
PMID:28476936 FYPO:0007785 Fig S1A, Fig1B,C
PMID:28476936 FYPO:0007786 Fig 2
PMID:28476936 PBO:0098321 Fig S1A, Fig1
PMID:28476936 FYPO:0007786 Fig 5 supplements added
PMID:28476936 FYPO:0007786 Fig 5 supplements added
PMID:28476936 FYPO:0007786 Fig 5 supplements added
PMID:28476936 FYPO:0007786 Fig 2
PMID:28476936 FYPO:0007786 Fig 2
PMID:28476936 FYPO:0007786 Fig 2
PMID:28476936 FYPO:0007786 Fig 2
PMID:28476936 FYPO:0007787 Fig4A, C, E, F no supplements added
PMID:28476936 PBO:0098322 Fig4D no supplements added
PMID:28476936 FYPO:0007786 Fig 5 supplements added
PMID:28476936 FYPO:0007786 Fig 5 supplements added
PMID:28476936 FYPO:0007786 Fig 5 supplements added
PMID:28476936 FYPO:0007786 Fig 5 supplements added
PMID:28476936 FYPO:0007786 Fig 5 supplements added
PMID:28476936 PBO:0098323 Fig5 supplements added
PMID:28476936 FYPO:0007786 FigS5 in this situation gad8 overexpression is unable to promote growth i. This show that Sck2 is the main S6 kinase effector of promoting growth in this situation
PMID:28476936 FYPO:0007786 FigS5 in this situation psk1 only causes a small increase in cell length increase compared to Sck2 . This show that Sck2 is the main S6 kinase effector of promoting growth in this situation
PMID:28476936 FYPO:0007786 FigS5 in this situation Sck1 only causes a small increase in cell length increase compared to Sck2 . This show that Sck2 is the main S6 kinase effector of promoting growth in this situation
PMID:28476936 FYPO:0001235 Fig S4A cell growth at G2/M1 arrest is dependent on transcription. no supplements added
PMID:28476936 FYPO:0007786 Fig 5 supplements added
PMID:28476936 FYPO:0007786 Fig 2
PMID:28476936 FYPO:0007786 Fig 2
PMID:28476936 FYPO:0007786 Fig 5 supplements added
PMID:28476936 FYPO:0007786 Fig 5 supplements added
PMID:28476936 FYPO:0007786 Fig 5 supplements added
PMID:28476936 FYPO:0007786 Fig 2, Fig3, Fig4B
PMID:28479325 FYPO:0001317 We find that the size dependent expression of Cdc25 does not require the 5′ UTR of its transcript, showing that this mechanism of translational regulation is not necessary for size dependent expression (Figure S3A).
PMID:28479325 GO:0031569 We propose that the size-dependent expression of the cdc25 transcript is the mechanism that allows cells to divide at a particular size, but it is not the mechanism which regulates what that size is.
PMID:28479325 FYPO:0001124 normal cell size. homeostasis
PMID:28479325 PBO:0097937 arelatively constant concentration during G2, as previously observed [2mRNA quantitation was obtained by Nanostring experiments.
PMID:28479325 PBO:0097937 mRNA quantitation was obtained by Nanostring experiments.
PMID:28479325 PBO:0092427 mRNA quantitation was obtained by Nanostring experiments.
PMID:28479325 PBO:0092427 During G2, the concentration of Cdc25 increases about 2 fold (Figure 1A)
PMID:28481910 PBO:0093559 same as cdc20-M10 alone
PMID:28481910 FYPO:0006031 BrdU incorporation
PMID:28481910 FYPO:0006031 BrdU incorporation
PMID:28481910 FYPO:0003923 BrdU incorporation
PMID:28481910 FYPO:0005108 BrdU incorporation
PMID:28497540 PBO:0095101 fig 2b
PMID:28497540 PBO:0109670 fig 1B
PMID:28497540 PBO:0112490 fig 1B, 1D
PMID:28497540 FYPO:0006423 fig 1B
PMID:28497540 PBO:0112491 fig 1C
PMID:28497540 FYPO:0006424 fig 1C
PMID:28497540 PBO:0112492 fig 1D
PMID:28497540 PBO:0112493 fig 1E
PMID:28497540 PBO:0112494 fig 1F
PMID:28497540 GO:1990813 fig 1 EF
PMID:28497540 PBO:0109676 fig 1B
PMID:28497540 PBO:0112495 fig 1F
PMID:28497540 FYPO:0003606 (Fig. 2B)
PMID:28497540 PBO:0112491 fig 5C
PMID:28497540 PBO:0095111 fig S2A
PMID:28497540 PBO:0095113 Fig 3C
PMID:28497540 PBO:0095114 during interphase (not usually located then)
PMID:28497540 PBO:0095101 fig 4A
PMID:28497540 PBO:0095115 fig 4A
PMID:28497540 PBO:0095113 Fig 3C
PMID:28497540 PBO:0112491 fig 5
PMID:28497540 PBO:0112490 fig 5
PMID:28497540 GO:1990813 fig 1 B
PMID:28497540 PBO:0095110 mph1Δ cells (Fig. 2B)
PMID:28497540 PBO:0109340 Fig. E
PMID:28497540 PBO:0095110 Fig. S5
PMID:28497540 PBO:0095117 Fig. S5
PMID:28497540 PBO:0112495 fig 5
PMID:28497540 PBO:0095118 Fig. 5C
PMID:28497540 PBO:0095119 Fig. 5C
PMID:28497540 PBO:0095120 4B
PMID:28497540 PBO:0095112 S4
PMID:28497540 PBO:0109339 RECRUITS
PMID:28497540 PBO:0095111 mph1Δ cells (Fig. 2B)
PMID:28497540 FYPO:0003606 `s4
PMID:28497540 PBO:0109340 Fig. 3A,B
PMID:28497540 PBO:0109341 recruits
PMID:28497540 PBO:0095100 Fig 2b
PMID:28513584 FYPO:0005343 Fig. S4
PMID:28513584 PBO:0103046 Fig. 3
PMID:28513584 GO:0061805 cut7D pkl1D klp9off does not elongate during anaphase B, cut7D pkl1D klp9D lethal, deleting all other kinesins except klp9 did not affect elongation after removing cut7
PMID:28513584 GO:0061804 cut7D pkl1D cls1off lethal
PMID:28513584 GO:0061804 cut7D pkl1D ase1D lethal
PMID:28513584 PBO:0103048 Fig. S3D and the fact that is required for bipolar spindle formation
PMID:28513584 FYPO:0000049 Fig. S3E
PMID:28513584 FYPO:0002085 Fig. S4
PMID:28513584 PBO:0103047 Fig. 3
PMID:28513584 PBO:0103045 Fig. 3
PMID:28513584 PBO:0103044 Fig. 3
PMID:28513584 FYPO:0000049 Fig. 3
PMID:28513584 FYPO:0000324 Fig. 2
PMID:28513584 FYPO:0004395 Fig. 2
PMID:28513584 FYPO:0000049 Main text (Figure S2 seems wrongly labelled)
PMID:28513584 FYPO:0005342 Fig. 2
PMID:28513584 FYPO:0004395 Fig. 2
PMID:28513584 FYPO:0001053 Fig. 2 (main text)
PMID:28513584 FYPO:0006174 Fig. 2
PMID:28513584 FYPO:0000049 Fig. 2
PMID:28513584 FYPO:0001574 Fig. S1 Not really abnormal, should be just bipolar
PMID:28513584 FYPO:0000276 Fig. S1
PMID:28513584 FYPO:0004085 Fig. 1
PMID:28513584 PBO:0097932 Fig. 1
PMID:28515144 PBO:0096808 Reduced ssp2-T189 phosphorylation under osmotic stress
PMID:28515144 PBO:0096810 Increased duration of ssp2-T189 phosphorylation under osmotic stress
PMID:28515144 PBO:0096810 Increased duration of ssp2-T189 phosphorylation under osmotic stress
PMID:28515144 PBO:0096810 Increased duration of ssp2-T189 phosphorylation under osmotic stress
PMID:28515144 PBO:0096809 Abolished ssp2-T189 phosphorylation under osmotic stress
PMID:28515144 PBO:0096808 Reduced ssp2-T189 phosphorylation under osmotic stress
PMID:28515144 PBO:0096810 Increased duration of ssp2-T189 phosphorylation under osmotic stress
PMID:28533364 GO:0170008 Second, Dcp1 stabilizes the fold of the Dcp2 RD, especially around the split active site, as revealed by hydrogen deuterium exchange rates (SI Appendix, Fig. S13). Finally, Edc1 enforces the active orientation in Dcp2 (Fig. 1 B–D) through specific interaction between its YAG activation motif and Dcp2.
PMID:28533364 GO:0170008 Second, Dcp1 stabilizes the fold of the Dcp2 RD, especially around the split active site, as revealed by hydrogen deuterium exchange rates (SI Appendix, Fig. S13). Finally, Edc1 enforces the active orientation in Dcp2 (Fig. 1 B–D) through specific interaction between its YAG activation motif and Dcp2.
PMID:28541282 GO:0140746 fig 5d,e. Only in presence of cid14/16 does rrp6 degrade ago1 bound rnas. This mechanism protects the genome from uncontrolled small RNAs
PMID:28541282 GO:0140746 see comment on cid14
PMID:28545058 FYPO:0006926 Fig1D
PMID:28545058 FYPO:0006926 Fig1A,B
PMID:28545058 FYPO:0006926 Fig1A,B
PMID:28545058 FYPO:0006926 Fig1A,B
PMID:28545058 FYPO:0006926 Fig1A,B
PMID:28545058 FYPO:0006926 Fig1A,B
PMID:28545058 FYPO:0006926 Fig1A,B
PMID:28545058 FYPO:0006926 Fig1A,B
PMID:28545058 FYPO:0006926 Fig1D
PMID:28545058 FYPO:0001221 Fig1D
PMID:28545058 FYPO:0001221 Fig1D
PMID:28545058 FYPO:0006926 Fig1D
PMID:28545058 FYPO:0006926 Fig1D
PMID:28545058 PBO:0097191 Fig4C cut6-621 partial suppresses the increased NC ratio of rae1-167 so not sure whether increased NC ration is the correct term
PMID:28545058 PBO:0097192 Fig 4D
PMID:28545058 PBO:0097193 Fig 4D
PMID:28545058 FYPO:0006926 Fig1A,B
PMID:28545058 FYPO:0006926 Fig1A,B
PMID:28545058 FYPO:0006926 Fig1A,B
PMID:28545058 FYPO:0006926 Fig1A,B
PMID:28545058 FYPO:0006926 Fig1A,B
PMID:28545058 FYPO:0006926 Fig1A,B
PMID:28545058 PBO:0097191 Fig 4c
PMID:28545058 PBO:0097188 Fig 4C,D
PMID:28545058 FYPO:0001221 Fig1D
PMID:28545058 FYPO:0001221 Fig1D
PMID:28545058 FYPO:0006926 Fig1D
PMID:28545058 FYPO:0006926 Fig1D
PMID:28545058 PBO:0097188 Fig2 A,B
PMID:28545058 PBO:0097189 Fig2 A,B
PMID:28545058 PBO:0097190 FigS1C,D
PMID:28545058 FYPO:0001221 Fig 4A
PMID:28545058 PBO:0097188 Fig2A
PMID:28545058 FYPO:0000836 Fig3A,B
PMID:28545058 FYPO:0000836 Fig3B Table S4 mass spec used to show that there is bulk accumulation of nuclear localised protein rather than a few specific proteins
PMID:28545058 FYPO:0001221 Fig2A, B
PMID:28545058 FYPO:0003286 Fig3A
PMID:28545058 FYPO:0000911 nuclear accumulation of mRNA ************S5 Table microarrays used
PMID:28545058 PBO:0097188 Fig2A
PMID:28545058 PBO:0097188 Fig2A
PMID:28545058 FYPO:0001221 Fig 2A
PMID:28545058 FYPO:0001221 Fig4 A,B
PMID:28545058 FYPO:0001673 Fig4 A,B
PMID:28545058 FYPO:0006926 Fig1D
PMID:28545058 FYPO:0006926 Fig1D
PMID:28545058 FYPO:0002061 data not shown
PMID:28545058 FYPO:0000769 Fig1C
PMID:28545058 FYPO:0000769 Fig1C rpn15 is called dss1 in this paper
PMID:28545058 FYPO:0006926 Fig1A,B In the paper this strain is called dss1
PMID:28545058 FYPO:0001221 Fig1 D
PMID:28545058 FYPO:0001221 Fig1D
PMID:28552615 GO:0061995 "Is this translocase activaty or ""dislocase activity?"" Fig 5 (val, added substrate top2, this term will probably merge into displacement activityu). GO:0061995"
PMID:28552615 PBO:0112756 vw edited based on https://github.com/geneontology/go-annotation/issues/5239
PMID:28552615 FYPO:0002775 (Fig. S1C)
PMID:28552615 FYPO:0002775 (Fig. S1C)
PMID:28552615 FYPO:0002775 (Fig. S1C)
PMID:28552615 FYPO:0002775 (Fig. S1C)
PMID:28552615 FYPO:0002775 (Fig. S1C)
PMID:28552615 GO:0005515 s2e
PMID:28552615 PBO:0098735 (Fig. 2h)
PMID:28552615 PBO:0098736 (Fig. 2h)
PMID:28552615 PBO:0098735 (Fig. 2h)
PMID:28552615 PBO:0098737 (Fig. 2i)
PMID:28552615 PBO:0098739 (Fig. 3a)
PMID:28552615 FYPO:0002775 (Fig. S1C)
PMID:28552615 FYPO:0002775 (Fig. S1C)
PMID:28552615 PBO:0098733 (Fig. S1E)
PMID:28552615 FYPO:0000957 (Fig. S1B)
PMID:28552615 FYPO:0001690 (Fig. S1B)
PMID:28552615 FYPO:0000963 (Fig. S1B)
PMID:28552615 FYPO:0000969 (Fig. S1B)
PMID:28552615 GO:0003918 3F and G
PMID:28552615 PBO:0098740 (Fig. S1C, 3A)
PMID:28552615 PBO:0112756 vw edited based on https://github.com/geneontology/go-annotation/issues/5239
PMID:28572514 PBO:0107768 see comment above
PMID:28572514 FYPO:0006212 vw: moved down to new FYPO:0006212 before germ outgrowth, during copper starvation
PMID:28572514 PBO:0105204 Fig. 7
PMID:28572514 FYPO:0006212 vw: moved down to new FYPO:0006212 before germ outgrowth, during copper starvation
PMID:28572514 FYPO:0006214 vw: made more specific, during copper starvation
PMID:28572514 PBO:0105204 fig7
PMID:28572514 PBO:0107769 fig 9
PMID:28572514 GO:0005886 fig5
PMID:28572514 PBO:0107770 fig7
PMID:28572514 PBO:0107770 fig7
PMID:28572514 GO:0005628 fig 6
PMID:28572514 PBO:0019744 fig 6
PMID:28572514 PBO:0107770 fig7
PMID:28572514 PBO:0107766 vw: changed to match previous session terms RNA ...from cuf1 mutant spores showed loss of copper starvation-dependent induction of ctr4 and ctr5 gene expression, indicating that the copper-dependent reg ulation of ctr4 and ctr5 mRNAs required Cuf1 during germination and outgrowth.
PMID:28572514 PBO:0107767 see comment above
PMID:28572514 FYPO:0006212 vw: moved down to new FYPO:0006212
PMID:28586299 FYPO:0006920 Figure 4C; decreased frequency of gene conversions at direct repeat recombination reporter
PMID:28586299 FYPO:0006920 Figure 4B; decreased frequency of deletions at direct repeat recombination reporter
PMID:28586299 FYPO:0000167 Figure 4C; increased frequency of deletions at direct repeat recombination reporter
PMID:28586299 FYPO:0006920 Figure 4A; decreased frequency of deletions and gene conversions at direct repeat recombination reporter
PMID:28586299 FYPO:0006921 Figure 2; decreased frequency of gene conversions but unaltered frequency of deletions at direct repeat recombination reporter; deletions in a rad51∆ mutant depend on Rad52
PMID:28600551 FYPO:0005968 fig 1
PMID:28600551 FYPO:0005968 I can never remember why e.g. sodium chloride isn't a child to salt stress
PMID:28600551 PBO:0103782 fig 2d
PMID:28600551 PBO:0103783 fig 2e
PMID:28600551 PBO:0103784 fig 2e
PMID:28600551 PBO:0103785 fig 3d
PMID:28600551 PBO:0103785 fig 3d
PMID:28600551 FYPO:0000852 fig 1 c
PMID:28600551 FYPO:0000852 fig 1 - They say they use YES in methods and fig2
PMID:28600551 FYPO:0000852 fig 1 - They say they use YES in methods and fig2
PMID:28600551 FYPO:0003743 fig 1 - They say they use YES in methods and fig2
PMID:28600551 FYPO:0003743 fig 1 - They say they use YES in methods and fig2
PMID:28600551 FYPO:0003743 fig 1 - They say they use YES in methods and fig2
PMID:28600551 FYPO:0003743 fig 1 - They say they use YES in methods and fig2
PMID:28600551 FYPO:0003743 fig 1 - They say they use YES in methods and fig2
PMID:28600551 FYPO:0003743 fig 1 - They say they use YES in methods and fig2
PMID:28600551 PBO:0103776 fig 1 - They say they use YES in methods and fig2
PMID:28600551 FYPO:0003743 fig 1 - They say they use YES in methods and fig2
PMID:28600551 PBO:0103778 fig 2a
PMID:28600551 PBO:0103778 fig 2a
PMID:28600551 FYPO:0004765 fig 3c
PMID:28600551 PBO:0103786 fig 2a
PMID:28600551 FYPO:0004765 fig 4
PMID:28600551 FYPO:0004765 fig 4
PMID:28600551 PBO:0103776 fig 4
PMID:28600551 PBO:0103776 fig 4
PMID:28600551 PBO:0103776 fig 4
PMID:28600551 PBO:0103776 fig 4
PMID:28600551 PBO:0103778 fig 4
PMID:28600551 PBO:0103778 fig 4
PMID:28600551 PBO:0101662 fig 5
PMID:28600551 PBO:0101662 fig 5
PMID:28600551 PBO:0103787 fig 5
PMID:28600551 PBO:0103788 fig 5
PMID:28600551 FYPO:0000303 fig 5
PMID:28600551 FYPO:0000303 fig 5
PMID:28600551 PBO:0100647 fig 5
PMID:28600551 FYPO:0000584 fig 5
PMID:28600551 FYPO:0000584 fig 5
PMID:28600551 FYPO:0000584 fig 5
PMID:28600551 PBO:0103789 fig 5
PMID:28600551 FYPO:0006712 fig 5
PMID:28600551 FYPO:0006712 fig 5
PMID:28600551 PBO:0103790 fig 5
PMID:28600551 FYPO:0006713 fig 5
PMID:28600551 FYPO:0006713 fig 5
PMID:28600551 FYPO:0006714 fig 5
PMID:28600551 FYPO:0006714 fig 5
PMID:28600551 FYPO:0006714 fig 5
PMID:28600551 FYPO:0001987 fig 1d
PMID:28600551 PBO:0103777 fig 2a
PMID:28600551 PBO:0103778 fig 2a
PMID:28600551 PBO:0103779 fig 2c
PMID:28600551 PBO:0103780 fig 2c
PMID:28600551 PBO:0103781 fig 2d
PMID:28600551 FYPO:0001987 fig 1d
PMID:28600551 FYPO:0001987 fig 1d
PMID:28600551 FYPO:0005968 fig 1
PMID:28619713 PBO:0103586 fig 6 C
PMID:28619713 GO:0061496 Fig. S1 B
PMID:28619713 FYPO:0001791 fig 6 C
PMID:28619713 GO:0061496 Fig. S1 B
PMID:28619713 GO:0140480 Our data suggest that Sad1 is present at the SPB early to set up structures that will trigger SPB inser- tion before the cell even enters mitosis.fig6
PMID:28619713 GO:0140480 rename term https://github.com/geneontology/go-ontology/issues/14887 Our data suggest that Sad1 is present at the SPB early to set up structures that will trigger SPB inser- tion before the cell even enters mitosis.fig6
PMID:28631612 PBO:0092298 """antidote"" product of longer alternative transcript; assayed by expressing S.k. ortholog in S.p."
PMID:28631612 GO:0072324 """poison"" product of shorter alternative transcript;assayed by expressing S.k. ortholog in S.p."
PMID:28640807 PBO:0093559 aerobic conditions
PMID:28640807 PBO:0093560 aerobic conditions
PMID:28640807 PBO:0093560 aerobic conditions
PMID:28640807 PBO:0093560 aerobic conditions
PMID:28640807 PBO:0097692 2 mM Glutathione restores aerobic growth.
PMID:28640807 PBO:0093559 aerobic conditions
PMID:28640807 FYPO:0003238 2 mM Glutathione restores aerobic growth.
PMID:28640807 PBO:0093560 aerobic conditions
PMID:28640807 PBO:0099137 Increased Cdc22 oxidation attenuated by 2 mM Glutathione. Increased Cdc22 oxidation attenuated by deleting tpx1.
PMID:28640807 PBO:0099137 Increased Cdc22 oxidation attenuated by 2 mM Glutathione. Increased Cdc22 oxidation attenuated by deleting tpx1.
PMID:28640807 PBO:0093560 aerobic conditions
PMID:28652406 PBO:0105837 Atf1.7M-HA are constitutively bound to the gpd1 and hsp9 promoters both before and after stress
PMID:28652406 FYPO:0000087 �atf1 expressing the mutant named HA-Atf1.6M, lacking sites 5 to 10 in Atf1, was as sensitive to growth on peroxide-containing plates as cells lacking Atf1.
PMID:28652406 FYPO:0000962 Concomitantly, although expression of HA-Atf1.10M was not able to suppress the sensitivity to peroxides of strain �atf1 (supplemental Fig. S1C and Fig. 1G), expression of HAAtf1.10D alleviated this phenotype (Fig. 1G).
PMID:28652406 PBO:0105835 Importantly, expression of the phospho-mimicking HA-Atf1.10D (Fig. 2B) or HA-Atf1.6D (Fig S3, C and D) bypasses the requirement for a MAP kinase in the transcription process, which questions the direct participation of the kinase in Pol II initiation and/or elongation.
PMID:28652406 PBO:0105835 Strains expressing wild-type Atf1 or Atf1.7M or Atf1.7D mutants displayed the same patterns of tolerance to peroxides and activation of stress genes as the constitutive amino-terminally tagged versions (supplemental Fig S4, B and C).
PMID:28652406 PBO:0105836 ditto
PMID:28652406 PBO:0105835 allows stress-dependent activation of ctt1 and srx1 to the same extent as wild-type cells; however, it constitutively induces expression of gpd1 and hsp9 (Fig. 2A).
PMID:28652406 PBO:0105834 whereas the expression of all stress genes in cells expressing HAAtf1.10D was not altered by sty1 deletion. Concomitantly
PMID:28652406 PBO:0094384 ditto
PMID:28652406 PBO:0100901 ditto
PMID:28652406 PBO:0097079 ditto
PMID:28652406 PBO:0094384 expression of the Sty1-independent Atf1.7D-HA mutant cannot bypass the absence of Pcr1, as shown by the lack of transcription of stress genes (Fig. 4C).
PMID:28652406 PBO:0105838 whether Atf1 binding to DNA is dependent on the presence of Pcr1; as shown in Fig. 4D, Atf1-GFP is not recruited to DNA in �pcr1 cells, with the only exception of srx1
PMID:28652406 PBO:0105837 ditto
PMID:28652406 PBO:0105244 whereas the expression of all stress genes in cells expressing HAAtf1.10D was not altered by sty1 deletion. Concomitantly
PMID:28652406 PBO:0105836 whereas the expression of all stress genes in cells expressing HAAtf1.10D was not altered by sty1 deletion. Concomitantly
PMID:28652406 PBO:0105836 allows stress-dependent activation of ctt1 and srx1 to the same extent as wild-type cells; however, it constitutively induces expression of gpd1 and hsp9 (Fig. 2A).
PMID:28652406 FYPO:0000087 the HA-Atf1.1M mutant was fully able to suppress the sensitivity to peroxides of strain �atf1, expression of the HA-Atf1.10M and 11M mutants did not alleviate this phenotype (supplemental Fig. S1C).
PMID:28652406 FYPO:0000087 ditto
PMID:28652406 PBO:0097080 ditto
PMID:28652406 PBO:0105840 that Pap1 is dispensable for the activation of gpd1 and hsp9 but required for ctt1 and srx1 (Fig. 5A)
PMID:28652406 PBO:0105835 whereas the expression of all stress genes in cells expressing HAAtf1.10D was not altered by sty1 deletion. Concomitantly
PMID:28652406 FYPO:0000962 expression of HA-Atf1.10D fully suppressed all stress defects of cells lacking Sty1 (Fig. 2C).
PMID:28652406 PBO:0100901 2A,cells expressing the hypophosphorylation mutant HA-Atf1.10M are not able to fully trigger the ctt1 and srx1 genes after H2O2 stress
PMID:28652406 FYPO:0000087 the HA-Atf1.1M mutant was fully able to suppress the sensitivity to peroxides of strain �atf1, expression of the HA-Atf1.10M and 11M mutants did not alleviate this phenotype (supplemental Fig. S1C).
PMID:28652406 FYPO:0000962 vw, I deleted Caludias annotation by mistake when comparing to the older partially completed session by Laura, so adding back !
PMID:28652406 PBO:0105845 As shown in Fig. 2B, the capacity of HA-Atf1.10M to activate hsp9 and gpd1 after stress imposition was abolished in the absence of Sty1,
PMID:28652406 PBO:0105844 As shown in Fig. 2B, the capacity of HA-Atf1.10M to activate hsp9 and gpd1 after stress imposition was abolished in the absence of Sty1,
PMID:28652406 PBO:0105838 ....whereas it is never recruited to these promoters in cells expressing Pap1.C523D (Fig. 5D).
PMID:28652406 PBO:0105842 Atf1 is constitutively bound to srx1 and ctt1 in strain �trr1....
PMID:28652406 FYPO:0001485 the HA-Atf1.1M mutant was fully able to suppress the sensitivity to peroxides of strain �atf1, expression of the HA-Atf1.10M and 11M mutants did not alleviate this phenotype (supplemental Fig. S1C).
PMID:28652406 PBO:0105841 ditto
PMID:28652406 PBO:0105838 Regarding the role of Pap1 and Atf1 at these genes, ChIP analysis indicates that the stress-dependent recruitment of Atf1 to ctt1 and srx1 promoters is dependent on Pap1 (Fig. 5C).
PMID:28656962 FYPO:0001355 Strains lacking Ypt7 (ypt7Δ, bhd1Δ ypt7Δ, ypt71Δ ypt7Δ) displayed a significant growth defect in the low amino-acid condition (EMM plates supplemented with low concentration of amino acids) compared to WT strains, or bhd1Δ and ypt71Δ strains (Fig. 5b).
PMID:28656962 FYPO:0001357 figure 5 b
PMID:28656962 FYPO:0001357 figure 5 b
PMID:28656962 FYPO:0001355 Strains lacking Ypt7 (ypt7Δ, bhd1Δ ypt7Δ, ypt71Δ ypt7Δ) displayed a significant growth defect in the low amino-acid condition (EMM plates supplemented with low concentration of amino acids) compared to WT strains, or bhd1Δ and ypt71Δ strains (Fig. 5b).
PMID:28656962 PBO:0099985 These data suggest that Bhd1 and Ypt71 (but not Ypt7) functionally interact and, in agreement with the mammalian cell data, negatively regulate TORC1 activity in response to amino-acid deprivation.
PMID:28656962 PBO:0099985 These data suggest that Bhd1 and Ypt71 (but not Ypt7) functionally interact and, in agreement with the mammalian cell data, negatively regulate TORC1 activity in response to amino-acid deprivation.
PMID:28656962 FYPO:0000077 To determine whether these proteins are related to TORC1 signalling, we treated bhd1Δ, ypt71Δ, ypt7Δ and double deletion strains with 200 ng ml−1 of rapamycin and found that all of the strains grew better than WT cells (Fig. 5b).
PMID:28656962 PBO:0109156 We observed that loss of Bhd1 and Ypt71, but not Ypt7, resulted in increased TORC1 activity, as determined by an increase in Rps6 and p70 S6K phosphorylation levels when cells were deprived of amino acids (Fig. 5a, compare lanes 1, 3, 5 and 7).
PMID:28656962 FYPO:0001357 figure 5 b
PMID:28656962 PBO:0109157 We observed that loss of Bhd1 and Ypt71, but not Ypt7, resulted in increased TORC1 activity, as determined by an increase in Rps6 and p70 S6K phosphorylation levels when cells were deprived of amino acids (Fig. 5a, compare lanes 1, 3, 5 and 7).
PMID:28656962 FYPO:0001355 Strains lacking Ypt7 (ypt7Δ, bhd1Δ ypt7Δ, ypt71Δ ypt7Δ) displayed a significant growth defect in the low amino-acid condition (EMM plates supplemented with low concentration of amino acids) compared to WT strains, or bhd1Δ and ypt71Δ strains (Fig. 5b).
PMID:28656962 FYPO:0000077 To determine whether these proteins are related to TORC1 signalling, we treated bhd1Δ, ypt71Δ, ypt7Δ and double deletion strains with 200 ng ml−1 of rapamycin and found that all of the strains grew better than WT cells (Fig. 5b).
PMID:28656962 FYPO:0000077 To determine whether these proteins are related to TORC1 signalling, we treated bhd1Δ, ypt71Δ, ypt7Δ and double deletion strains with 200 ng ml−1 of rapamycin and found that all of the strains grew better than WT cells (Fig. 5b).
PMID:28656962 FYPO:0001355 Strains lacking Ypt7 (ypt7Δ, bhd1Δ ypt7Δ, ypt71Δ ypt7Δ) displayed a significant growth defect in the low amino-acid condition (EMM plates supplemented with low concentration of amino acids) compared to WT strains, or bhd1Δ and ypt71Δ strains (Fig. 5b).
PMID:28656962 FYPO:0001355 Strains lacking Ypt7 (ypt7Δ, bhd1Δ ypt7Δ, ypt71Δ ypt7Δ) displayed a significant growth defect in the low amino-acid condition (EMM plates supplemented with low concentration of amino acids) compared to WT strains, or bhd1Δ and ypt71Δ strains (Fig. 5b).
PMID:28659415 GO:0070941 Pil1p form filaments. Pil1 exchanges rapidly at the ends of these filaments in vivo.
PMID:28659415 GO:0036286 Pil1p form filaments. Pil1 exchanges rapidly at the ends of these filaments in vivo.
PMID:28667014 FYPO:0006131 LC-MS/MS and enzymatic assays were used to measure gluconate accumulation in wild-type and idn1Δ
PMID:28667014 FYPO:0006131 LC-MS/MS
PMID:28667014 FYPO:0006131 idn1Δ loz1Δ – enhances gluconate accumulation when compared to idn1Δ cells LC-MS/MS and enzymatic assays were used to measure gluconate accumulation in wild-type, idn1Δ
PMID:28674280 PBO:0103012 same as snf22delta alone
PMID:28674280 PBO:0103012 same as snf22delta alone
PMID:28674280 PBO:0103012 same as snf22delta alone
PMID:28765164 PBO:0099881 fig2e
PMID:28765280 FYPO:0002060 Fig 1A
PMID:28765280 FYPO:0002060 figure 1D
PMID:28765280 PBO:0095316 Fig. 7A
PMID:28765280 PBO:0095316 Fig. 7A
PMID:28765280 FYPO:0002060 Fig 7A
PMID:28765280 FYPO:0002060 Fig 7A
PMID:28765280 PBO:0095314 (Fig. 6G).
PMID:28765280 PBO:0095311 Fig. 1EF
PMID:28765280 FYPO:0002060 Fig 1B
PMID:28765280 PBO:0095312 3b
PMID:28765280 PBO:0095310 we could probly go to increased degradation because of the bortezombin exp
PMID:28765280 FYPO:0002061 figure 1B
PMID:28765280 FYPO:0000673 Fig 1B
PMID:28765280 FYPO:0002060 Fig 2A
PMID:28765280 PBO:0038207 figure 2
PMID:28765280 PBO:0095313 3b
PMID:28765280 FYPO:0002060 Fig 6A
PMID:28765280 FYPO:0000673 Fig 6C
PMID:28765280 PBO:0095314 Fig 6C
PMID:28765280 PBO:0095315 6 ef
PMID:28771613 PBO:0108417 1E
PMID:28771613 PBO:0108424 unfortunately no direct binding data, but physical interactions have been shown in other organisms
PMID:28771613 PBO:0108423 The preRC- loading delay was abolished in the irradiated gcn1Δ cells (Fig 3C),
PMID:28771613 PBO:0108423 The preRC- loading delay was abolished in the irradiated gcn1Δ cells (Fig 3C),
PMID:28771613 PBO:0108418 2B
PMID:28771613 PBO:0108420 1E
PMID:28771613 PBO:0108419 1E
PMID:28775153 FYPO:0006865 Fig4C. DAPI staining. I have requested a new term and included response to streptonigrin but should it be more general e.g. response to DNA damaging agent (if this is known)
PMID:28775153 FYPO:0000229 Fig4B. DAPI staining. I have requested a new term and included response to streptonigrin but should it be more general e.g. response to DNA damaging agent (if this is known)
PMID:28775153 FYPO:0000229 Fig4D. DAPI staining. I have requested a new term and included response to streptonigrin but should it be more general e.g. response to DNA damaging agent (if this is known)
PMID:28784611 GO:0005886 Fig 1B
PMID:28784611 GO:0005886 Figure 1B
PMID:28784611 FYPO:0003278 "i requested reduced plasma membrane PIP issues/3117 GFP-2xPH(Plc delta) ""localization The PI(4,5)P2 sensor GFP-2×PH(PLCδ) (Stefan et al., 2002) was reduced at the cell cortex and the division site in efr3Δ compared with WT (Fig. 1 D), indicating that PIP PM abundance is reduced in efr3Δ"""
PMID:28784611 PBO:0102562 Fig 2 A-C
PMID:28784611 FYPO:0002061 Fig. S1, C and D)
PMID:28784611 PBO:0102561 Fig 2 A-C
PMID:28784611 PBO:0098958 Figure 3E
PMID:28784611 PBO:0102556 Figure 3C
PMID:28784611 PBO:0098955 Figure 3B
PMID:28784611 PBO:0102557 Figure 3D
PMID:28784611 FYPO:0006005 fig 5 B CR slid- ing events no longer occurred in myo51Δ efr3Δ
PMID:28784611 GO:0005886 Figure 1B
PMID:28784611 FYPO:0002061 Fig. S1, C and D)
PMID:28784611 FYPO:0001489 Figure S1D
PMID:28784611 FYPO:0002061 Figure S1C
PMID:28784611 FYPO:0005905 Figure S2A-B
PMID:28784611 FYPO:0006005 fig 5 B CR slid- ing events no longer occurred in myo51Δ efr3Δ
PMID:28784611 FYPO:0005020 Figure S2A-B
PMID:28784611 PBO:0102558 Figure S2E
PMID:28784611 PBO:0102559 Figure 1C
PMID:28784611 PBO:0102560 Figure 1C
PMID:28784611 PBO:0102565 Fig 3 A (in table, data not shown)
PMID:28784611 FYPO:0002061 Fig. S2 D
PMID:28784611 PBO:0102564 Fig 2 A-C
PMID:28784611 GO:1903475 naintenence
PMID:28784611 GO:0007009 phospholipid biosynthesis?
PMID:28784611 FYPO:0004293 fig 1 A&B
PMID:28784611 FYPO:0000339 Figure 1A
PMID:28784611 FYPO:0002253 fig 5A
PMID:28784611 FYPO:0002253 fig S2C
PMID:28806726 FYPO:0006241 inhibition of origin firing requires intra-S checkpoint (fig. 5)
PMID:28806726 FYPO:0006241 inhibition of origin firing requires intra-S checkpoint (fig. 5)
PMID:28806726 FYPO:0006242 replication forks stall with partial dependence on intra-S checkpoint (fig. 6)
PMID:28806726 FYPO:0006241 inhibition of origin firing requires intra-S checkpoint (fig. 5)
PMID:28806726 FYPO:0006242 replication forks stall with partial dependence on intra-S checkpoint (fig. 6)
PMID:28806726 FYPO:0006242 replication forks stall with partial dependence on intra-S checkpoint (fig. 6)
PMID:28806726 FYPO:0003923 untreated (table S1)
PMID:28806726 FYPO:0006240 replication forks slow independently of intra-S checkpoint (fig. 6)
PMID:28811350 PBO:0096424 consensus recognition sequence 5'-TCG(G/C)(A/T)xxTTxAA
PMID:28811350 PBO:0096423 consensus recognition sequence 5'-TCG(G/C)(A/T)xxTTxAA
PMID:28811350 PBO:0096422 consensus recognition sequence 5'-TCG(G/C)(A/T)xxTTxAA
PMID:28811350 PBO:0096420 consensus recognition sequence 5'-TCG(G/C)(A/T)xxTTxAA
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated from MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28821619 FYPO:0001245 generated by MMS mutagenesis
PMID:28825727 FYPO:0006248 hic and 3C pcr fig 2d increased mitotic intra centromere connection
PMID:28825727 FYPO:0006302 fig 3 hi-C
PMID:28825727 FYPO:0006302 (vw made more specific) Hi-C Supplementary Figs. 1b,f and 4a–c
PMID:28825727 FYPO:0000214 hi C????? Supplementary Figs. 1b,f and 4a–c
PMID:28825727 FYPO:0000214 Supplementary Figs. 1b,f and 4a–c Cnd3 depletion following promoter shut-off and auxin-induced degron activation
PMID:28825727 FYPO:0006302 fig 2b hi-C difference assay
PMID:28825727 FYPO:0006302 Cnd3 depletion following promoter shut-off and auxin-induced degron activation
PMID:28825727 FYPO:0000214 Cnd3 depletion following promoter shut-off and auxin-induced degron activation
PMID:28827290 FYPO:0002061 fig 3
PMID:28827290 FYPO:0002061 fig 3
PMID:28827290 FYPO:0001357 fig 6
PMID:28827290 FYPO:0001357 fig 6
PMID:28827290 PBO:0094554 figure 2B
PMID:28827290 FYPO:0001357 fig 6
PMID:28827290 PBO:0101837 fig 2D
PMID:28827290 PBO:0101836 wt 68% fig 2C
PMID:28827290 GO:0000775 fig 2C
PMID:28827290 PBO:0101835 fig 2B
PMID:28827290 FYPO:0002061 fig 3
PMID:28827290 FYPO:0002060 fig 4
PMID:28827290 FYPO:0002061 fig 3
PMID:28827290 FYPO:0002061 fig 3
PMID:28827290 PBO:0101833 fig 1B
PMID:28827290 FYPO:0002061 fig 3
PMID:28827290 PBO:0101834 fig 1B
PMID:28827290 FYPO:0002061 fig 2
PMID:28827290 FYPO:0002061 fig 2
PMID:28827290 FYPO:0002060 fig 4
PMID:28827290 FYPO:0002061 fig 3
PMID:28827290 FYPO:0002061 fig 3
PMID:28827290 FYPO:0002060 fig 4
PMID:28827290 FYPO:0001355 fig 5
PMID:28827290 FYPO:0001355 fig 5
PMID:28827290 PBO:0094438 fig 5
PMID:28827290 FYPO:0001357 fig 6
PMID:28827290 FYPO:0001357 fig 8
PMID:28827290 PBO:0101838 fig 7
PMID:28827290 FYPO:0001357 fig 6
PMID:28827290 FYPO:0001357 fig 6
PMID:28827290 FYPO:0002061 fig 3
PMID:28827290 FYPO:0002061 fig 3
PMID:28841135 PBO:0108111 mRNA co-immunoprecipitated with ribosomes
PMID:28882432 FYPO:0001157 fig 3
PMID:28904333 PBO:0100463 30 degrees
PMID:28904333 FYPO:0006843 especially at centromere; also at other regions where Ino80 complex normally binds
PMID:28904333 FYPO:0006843 especially at centromere; also at other regions where Ino80 complex normally binds
PMID:28904333 PBO:0100463 25 degrees
PMID:28914606 GO:0009898 Furthermore, the FRET signal of mCherry-Cdc15 with two other F-BAR domains (GFP-Imp2 and GFP-Rga7) indicates that all three cytokinesis F-BARs are packed in close proximity upon the membrane
PMID:28914606 GO:0009898 Furthermore, the FRET signal of mCherry-Cdc15 with two other F-BAR domains (GFP-Imp2 and GFP-Rga7) indicates that all three cytokinesis F-BARs are packed in close proximity upon the membrane
PMID:28914606 GO:0009898 A strong FRET signal between mCherry-Cdc15 and Acyl-GFP is consistent with the binding of Cdc15’s F-BAR to anionic phospholipids within the plasma membrane
PMID:28924043 PBO:0107344 Cdr1-K41A remains in nodes; Cdr1+ not tagged
PMID:28924043 PBO:0107341 Cdr1-K41A remains unphosphorylated; Cdr1+ not tagged
PMID:28924043 PBO:0107336 combination of in vitro kinase assay and mutant phenotypes
PMID:28924043 PBO:0107333 Cdr2 does not exit nodes (unlike Cdr1) upon osmotic stress
PMID:28934464 GO:0003714 5D a bit tenuous but we don't have this annotated..
PMID:28934464 PBO:0107976 fig 3E
PMID:28934464 PBO:0107971 fig 3C
PMID:28934464 PBO:0107975 fig 3E
PMID:28934464 PBO:0107974 fig 3D
PMID:28934464 PBO:0107973 fig 3D
PMID:28934464 PBO:0107969 fig S2D
PMID:28934464 PBO:0107969 fig 3B
PMID:28934464 PBO:0107970 fig 3C
PMID:28934464 PBO:0107972 fig 3C
PMID:28934464 GO:0140585 I replaced GO:0090579 dsDNA loop formation as per https://github.com/geneontology/go-annotation/issues/3610
PMID:28934464 GO:0003714 5D a bit tenuous but we don't have this annotated..
PMID:28934464 PBO:0107969 fig 3B
PMID:28934464 PBO:0107970 fig 3C
PMID:28944093 FYPO:0000271 can't disambiguate salt from specific calcium sensitivity in these experiments
PMID:28944093 FYPO:0000098 can't disambiguate salt from specific calcium sensitivity in these experiments
PMID:28944093 FYPO:0000098 can't disambiguate salt from specific calcium sensitivity in these experiments
PMID:28944093 FYPO:0000271 can't disambiguate salt from specific calcium sensitivity in these experiments
PMID:28947618 PBO:0109691 Fig 5B; Appendix Fig S5A and B
PMID:28947618 GO:0045292 Intron-Specific pre-mRNA Splicing
PMID:28947618 PBO:0106840 Fig 8B in spliceosome
PMID:28947618 PBO:0106839 (Fig 7A)
PMID:28947618 PBO:0106838 (Fig 7A)
PMID:28947618 PBO:0106837 (Fig 7A)
PMID:28947618 GO:0005681 Fig 4A
PMID:28947618 PBO:0106836 Fig 3E LysSde2-C (pro-obo/term-requests/119/), is N-end rule substrate
PMID:28947618 PBO:0106835 Fig 3E (N-end rule pathway substrate) assayed_using(LysSde2-C)
PMID:28947618 PBO:0106834 Fig 2D
PMID:28947618 PBO:0106834 Fig 2D
PMID:28947618 PBO:0106832 Fig 2A &B
PMID:28947618 PBO:0106833 Appendix Fig S2A
PMID:28947618 PBO:0106832 fig 1B
PMID:28947618 PBO:0106832 fig 1B
PMID:28947618 FYPO:0003244 assayed_using SPBC1778.02 | assayed_using SPAC227.16C | assayed_using SPBP16F5.02
PMID:28947618 PBO:0106831 (endo) mutant does not cleave Sde2 precursor
PMID:28947618 PBO:0106830 (endo) mutant does not cleave Sde2 precursor
PMID:28947618 PBO:0109713 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109712 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109711 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109710 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109709 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109708 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109707 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109706 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109705 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109704 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109703 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109702 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109701 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109700 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109699 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109698 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109697 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109696 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109695 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109694 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109693 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109692 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109690 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109689 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109688 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109687 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109686 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109685 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109684 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109683 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109682 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109681 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109680 Fig 5B; Appendix Fig S5A and B
PMID:28947618 PBO:0109679 Fig 5B; Appendix Fig S5A and B
PMID:28947618 FYPO:0001355 Fig EV2B processing defective, does not complement sde2Δ
PMID:28947618 FYPO:0001355 Fig EV2B processing defective, does not complement sde2Δ
PMID:28947618 FYPO:0001355 Fig EV2B processing defective, does not complement sde2Δ
PMID:28947618 FYPO:0001355 Fig EV2B processing defective, does not complement sde2Δ
PMID:28947618 FYPO:0001357 Fig EV2B normal processing, complements sde2Δ
PMID:28947618 FYPO:0001357 Fig EV2B normal processing, complements sde2Δ
PMID:28947618 FYPO:0001355 processing defective, does not complement sde2Δ
PMID:28947618 FYPO:0001355 reduced processing, complements partially sde2Δ
PMID:28947618 FYPO:0001355 normal processing, complements partially sde2Δ
PMID:28947618 FYPO:0001355 normal processing, complements partially sde2Δ
PMID:28947618 FYPO:0001355 normal processing, complements partially sde2Δ
PMID:28947618 FYPO:0001355 normal processing, protein very stable, complements partially sde2Δ
PMID:28947618 FYPO:0001355 normal processing, protein stable, complements partially sde2Δ
PMID:28947618 FYPO:0001355 normal processing, protein unstable,complements partially sde2Δ
PMID:28947618 FYPO:0001355 normal processing, protein very stable, complements partially sde2Δ
PMID:28947618 FYPO:0001575 processing defective, does not complement sde2Δ
PMID:28947618 FYPO:0001355 normal processing, complements partially sde2Δ
PMID:28947618 FYPO:0003244 Fig 3C) decreased cell growth, normal processing, protein very stable, complements partially sde2Δ; over expression causes growth defect in hub1-1 strain, defective in telomeric silencing and genome stability
PMID:28947618 FYPO:0001355 normal processing, protein very stable, complements partially sde2Δ
PMID:28947618 FYPO:0001355 normal processing, protein stable, complements partially sde2Δ
PMID:28947618 FYPO:0001355 normal processing, complements partially sde2Δ
PMID:28947618 FYPO:0001355 normal processing, protein very stable, complements partially sde2Δ
PMID:28947618 FYPO:0001355 normal processing, protein stable, complements partially sde2Δ
PMID:28947618 FYPO:0001355 normal processing, protein unstable, complements partially sde2Δ
PMID:28947618 FYPO:0001355 normal processing, protein unstable, complements partially sde2Δ
PMID:28947618 FYPO:0001355 normal processing, protein very stable, does not complement sde2Δ
PMID:28947618 FYPO:0001355 fig 1 D complements partially sde2Δ
PMID:28947618 FYPO:0001575 fig 1 D does not complement sde2Δ
PMID:28947618 FYPO:0001355 processing defective, does not complement sde2Δ
PMID:28947618 FYPO:0001355 normal processing, complements partially sde2Δ
PMID:28947618 FYPO:0001355 normal processing, protein very stable, complements partially sde2Δ
PMID:28947618 FYPO:0003244 does not complement sde2Δ, defective in telomeric silencing and genome stability
PMID:28947618 PBO:0109678 decreased cell population growth at high temperature
PMID:28947618 GO:0045292 Intron-Specific pre-mRNA Splicing
PMID:28947618 GO:0005634 column_17 Sde2UBL
PMID:28947618 FYPO:0003244 does not grow at high temperature, defective pre-mRNA splicing, assayed_using SPBC1778.02 | assayed_using SPAC227.16C | assayed_using SPBP16F5.02
PMID:28974540 PBO:0104459 fig 5 D-G nuclear envelope
PMID:28974540 GO:0005635 5A
PMID:28974540 PBO:0104456 fig 5b nuclear envelope
PMID:28974540 PBO:0104457 fig 5b
PMID:28974540 PBO:0104460 fig 6
PMID:28974540 PBO:0104446 fig 6
PMID:28974540 PBO:0104458 fig 5 D-G nuclear envelope
PMID:28974540 GO:0005635 5A
PMID:28974540 FYPO:0000227 fig1
PMID:28974540 FYPO:0000324 Fig. S2 B
PMID:28974540 PBO:0104441 fig 1b
PMID:28974540 FYPO:0002638 Fig. S3
PMID:28974540 PBO:0104442 added affected genes as extensions fig 3 A-C
PMID:28974540 PBO:0104443 added affected genes as extensions fig 3 A-C
PMID:28974540 PBO:0104444 added affected genes as extensions fig 3 A-C
PMID:28974540 PBO:0104445 added affected genes as extensions fig 3 A-C
PMID:28974540 PBO:0104446 added affected genes as extensions fig 3 A-C
PMID:28974540 PBO:0104447 added affected genes as extensions fig 3 A-C
PMID:28974540 PBO:0104448 added affected genes as extensions fig 3 A-C
PMID:28974540 PBO:0104449 added affected genes as extensions fig 3 A-C
PMID:28974540 PBO:0033477 Fig. S2 A & 1E
PMID:28974540 FYPO:0002649 vw: moved down to elongated (update fypo?) fig 1e
PMID:28974540 GO:0017056 fig 1a + others
PMID:28974540 FYPO:0000284 fig 1C
PMID:28974540 PBO:0104450 fig 1
PMID:28974540 PBO:0104451 fig S2
PMID:28974540 PBO:0104452 s3 C
PMID:28974540 PBO:0100719 s3 E
PMID:28974540 PBO:0095380 Fig. S3, G and H
PMID:28974540 PBO:0104453 Fig. S3 I additive, do we know %?
PMID:28974540 PBO:0099862 added affected genes as extensions fig 3 E
PMID:28974540 PBO:0104454 added affected genes as extensions fig 3 E
PMID:28974540 FYPO:0002061 fig 2E
PMID:28974540 FYPO:0002061 fig 2E
PMID:28974540 FYPO:0003094 fig 3
PMID:28974540 FYPO:0002061 fig 2E
PMID:28974540 FYPO:0006353 fig 3
PMID:28974540 FYPO:0002061 fig 2E
PMID:28974540 FYPO:0004314 fig 3 G
PMID:28974540 PBO:0104446 fig 4a
PMID:28974540 PBO:0104455 fig 4c
PMID:28974540 FYPO:0002061 fig 2E
PMID:28974540 PBO:0104446 fig 4e
PMID:28974540 FYPO:0002061 fig 2E
PMID:28974540 FYPO:0002061 fig 2E
PMID:28974540 FYPO:0002061 fig 2E
PMID:28974540 PBO:0104461 fig 6
PMID:28974540 MOD:01148 (Fig. 4 G and see the Ubiquitin pull-down section of Materials and methods).
PMID:28976798 GO:0005515 fig1
PMID:28976798 GO:0005515 fig1
PMID:28976798 GO:0005515 fig1
PMID:28976798 GO:0005515 fig1
PMID:28976798 PBO:0099345 fig 1 D
PMID:28977643 GO:0045003 mhf1-L78R
PMID:28977649 PBO:0107500 Asn GUU, Gly CCC, Ile AAU, Leu AAG, Leu CAA, Leu CAG, Leu UAG, Phe GAA, Ser AGA, Ser GCU, Thr AGU, Trp CAA
PMID:28977649 PBO:0107509 tRNA-Ser GCU and tRNA-Ser AGA unaffected
PMID:28977649 PBO:0107508 tRNA-Ser GCU and tRNA-Ser AGA unaffected
PMID:28977649 PBO:0107507 tRNA-Ser GCU and tRNA-Ser AGA unaffected
PMID:28977649 PBO:0107506 tRNA-Ser GCU and tRNA-Ser AGA unaffected
PMID:28977649 PBO:0107505 tRNA-Ser GCU and tRNA-Ser AGA unaffected
PMID:28977649 PBO:0107504 tRNA-Ser GCU and tRNA-Ser AGA unaffected
PMID:28977649 PBO:0107503 affects tRNA-Ser UGA/CGA; suggests tRNA-Ser UGA/CGA misfolding due to decreased dimethylation of G26, but modification not assayed directly for this tRNA
PMID:28977649 PBO:0107503 affects tRNA-Ser UGA/CGA; suggests tRNA-Ser UGA/CGA misfolding due to decreased dimethylation of G26, but modification not assayed directly for this tRNA
PMID:28977649 PBO:0107502 Asn GUU, Gly CCC, Ile AAU, Leu AAG, Leu CAA, Leu CAG, Leu UAG, Phe GAA, Ser AGA, Ser GCU, Thr AGU, Trp CAA
PMID:28977649 PBO:0107501 Asn GUU, Gly CCC, Ile AAU, Leu AAG, Leu CAA, Leu CAG, Leu UAG, Phe GAA, Ser AGA, Ser GCU, Thr AGU, Trp CAA
PMID:28977649 PBO:0107499 Asn GUU, Gly CCC, Ile AAU, Leu AAG, Leu CAA, Leu CAG, Leu UAG, Phe GAA, Ser AGA, Ser GCU, Thr AGU, Trp CAA
PMID:28977649 PBO:0107498 Asn GUU, Gly CCC, Ile AAU, Leu AAG, Leu CAA, Leu CAG, Leu UAG, Phe GAA, Ser AGA, Ser GCU, Thr AGU, Trp CAA
PMID:28977649 PBO:0107497 Asn GUU, Gly CCC, Ile AAU, Leu AAG, Leu CAA, Leu CAG, Leu UAG, Phe GAA, Ser AGA, Ser GCU, Thr AGU, Trp CAA
PMID:28977649 PBO:0107496 Asn GUU, Gly CCC, Ile AAU, Leu AAG, Leu CAA, Leu CAG, Leu UAG, Phe GAA, Ser AGA, Ser GCU, Thr AGU, Trp CAA
PMID:28977649 PBO:0107495 Asn GUU, Gly CCC, Ile AAU, Leu AAG, Leu CAA, Leu CAG, Leu UAG, Phe GAA, Ser AGA, Ser GCU, Thr AGU, Trp CAA
PMID:28977649 PBO:0107498 Ile AAU, Leu UAG, Leu CAG, Phe GAA, Ser GCU
PMID:28977649 PBO:0107497 Ile AAU, Leu UAG, Leu CAG, Phe GAA, Ser GCU
PMID:28977649 PBO:0107496 Ile AAU, Leu UAG, Leu CAG, Phe GAA, Ser GCU
PMID:28977649 PBO:0107495 Ile AAU, Leu UAG, Leu CAG, Phe GAA, Ser GCU
PMID:28982178 FYPO:0000249 40 fold less
PMID:29021344 FYPO:0002061 Figure 4B
PMID:29021344 PBO:0095235 Figure S5D
PMID:29021344 PBO:0095235 Figure S5D
PMID:29021344 PBO:0095234 Figure 2E
PMID:29021344 FYPO:0002060 (Supplemental Figure S1A).
PMID:29021344 FYPO:0002061 Figure 4A and Supplemental Figure S4
PMID:29021344 FYPO:0005343 Figure 2G
PMID:29021344 FYPO:0002061 Figure 4A and Supplemental Figure S4
PMID:29021344 FYPO:0002061 Figure 4A and Supplemental Figure S4
PMID:29021344 FYPO:0002061 Figure 4A and Supplemental Figure S4
PMID:29021344 FYPO:0003241 fig3C
PMID:29021344 FYPO:0005343 Figure 1F
PMID:29032152 FYPO:0001926 fig 2
PMID:29032152 PBO:0094648 fig 1, 3b
PMID:29032152 PBO:0094648 fig 3b
PMID:29032152 PBO:0101315 inferred from combined experiments
PMID:29032152 PBO:0101314 fig 4
PMID:29032152 GO:0005515 fig4
PMID:29032152 FYPO:0001689 fig 2
PMID:29032152 FYPO:0000089 fig2 b,c
PMID:29032152 FYPO:0002550 fig2
PMID:29032152 PBO:0101314 fig 4
PMID:29032152 FYPO:0000957 fig 3e
PMID:29032152 PBO:0101316 Table 3
PMID:29032152 PBO:0101314 fig 4
PMID:29032152 PBO:0095685 fig 3b
PMID:29032152 PBO:0095685 fig 3b
PMID:29032152 FYPO:0001357 fig 3b
PMID:29032152 PBO:0095685 fig 3b
PMID:29032152 PBO:0101316 Table 3
PMID:29032152 PBO:0101316 Table 3
PMID:29032152 PBO:0101316 Table 3
PMID:29032152 PBO:0101317 Table 3
PMID:29032152 FYPO:0000969 fig 3e
PMID:29032152 FYPO:0001234 fig 1
PMID:29032152 FYPO:0001021 fig 2a
PMID:29032152 FYPO:0001689 fig 3e
PMID:29079657 PBO:0097752 fig2 and supp table
PMID:29079657 PBO:0097752 fig2 and supp table
PMID:29079657 PBO:0097753 fig2 and supp table
PMID:29079657 PBO:0097752 fig2 and supp table
PMID:29079657 PBO:0097753 fig2 and supp table
PMID:29079657 PBO:0097752 fig2 and supp table
PMID:29079657 PBO:0097753 fig2 and supp table
PMID:29079657 PBO:0097752 fig2 and supp table
PMID:29079657 PBO:0097753 fig2 and supp table
PMID:29079657 PBO:0097752 fig2 and supp table
PMID:29079657 PBO:0097753 fig2 and supp table
PMID:29079657 PBO:0097753 fig2 and supp table
PMID:29079657 PBO:0097752 fig2 and supp table
PMID:29079657 PBO:0097753 fig2 and supp table
PMID:29079657 PBO:0097752 fig2 and supp table
PMID:29079657 PBO:0097753 fig2 and supp table
PMID:29079657 PBO:0097752 fig2 and supp table
PMID:29079657 PBO:0097753 fig2 and supp table
PMID:29079657 PBO:0097752 fig2 and supp table
PMID:29079657 PBO:0097753 fig2 and supp table
PMID:29079657 PBO:0097752 fig2 and supp table
PMID:29079657 PBO:0097753 fig2 and supp table
PMID:29079657 PBO:0097752 fig2 and supp table
PMID:29079657 PBO:0097753 fig2 and supp table
PMID:29079657 PBO:0097752 fig2 and supp table
PMID:29079657 PBO:0097753 fig2 and supp table
PMID:29079657 PBO:0097752 fig2 and supp table
PMID:29079657 PBO:0097753 fig2 and supp table
PMID:29079657 PBO:0097752 fig2 and supp table
PMID:29079657 PBO:0097753 fig2 and supp table
PMID:29079657 PBO:0097752 fig2 and supp table
PMID:29079657 PBO:0097753 fig2 and supp table
PMID:29079657 PBO:0097752 fig2 and supp table
PMID:29079657 GO:0010515 fig1
PMID:29079657 GO:1900237 To conclude, upon nutrient starvation, TORC2 functions as both an activator and an inhibitor of sexual differentiation, the latter being mediated by Taf12 phosphorylation.
PMID:29079657 PBO:0097752 fig2 and supp table
PMID:29079657 PBO:0097753 fig2 and supp table
PMID:29079657 PBO:0097753 fig2 and supp table
PMID:29079657 PBO:0097752 fig2 and supp table
PMID:29079657 PBO:0097753 fig2 and supp table
PMID:29079657 PBO:0097754 fig6
PMID:2908246 PBO:0038194 mild over expression of cdc2+ on multi copy plasmid rescues the cdc13-117 ts phenotype
PMID:2908246 FYPO:0001234 mild over expression of cdc13+ on multi copy plasmid pYep13 causes slow growth
PMID:2908246 PBO:0099003 Fig 3
PMID:2908246 PBO:0099005 mild over expression of cdc13+ on multi copy plasmid pYep13 rescues the cdc13-117 ts phenotype. .
PMID:2908246 PBO:0099004 Fig 3
PMID:29084823 PBO:0104939 Fig4A,B Zfs is hyperphosphorylated in response to nitrogen depletion
PMID:29084823 FYPO:0001147 Fig3A deletion of puc1 increases mating efficiency of zfs1 delta to WT
PMID:29084823 PBO:0104931 Figure 1A Sup Fig1
PMID:29084823 FYPO:0001890 "jack suggested ""up regulation of protein binding RNAs because normally bound by zfs1"" I'm using this to make the sequestering GO annotation."
PMID:29084823 PBO:0104933 Figure 1C
PMID:29084823 PBO:0104940 Fig4D Sup Fig3 the hyperphosphoryated zfs1 (3rd band higest). Gad8 is required to hyperphosphorylate zfs1. In Fig4C they also show that TOR inhibition by Torin stimulates hyerphosphorylation of Zfs1
PMID:29084823 PBO:0104932 Figure 1C
PMID:29084823 PBO:0104943 Fig5E
PMID:29084823 PBO:0020460 Fig4A,B about 10%? of Zfs1 is phosphorylated during vegetative growth
PMID:29084823 PBO:0104941 Fig 5B, construct 3
PMID:29084823 PBO:0104942 Fig5C,D
PMID:29084823 PBO:0093825 Fig3A
PMID:29084823 PBO:0104935 Fig 2D, E, Sup Fig 2
PMID:29084823 PBO:0104934 Fig 2B,C fig6a
PMID:29084823 PBO:0104944 Fig5E
PMID:29084823 PBO:0104945 Fig6A
PMID:29084823 PBO:0104951 Fig6A,B
PMID:29084823 PBO:0104952 RNA
PMID:29084823 PBO:0104936 Fig3C
PMID:29084823 PBO:0104937 Fig3C
PMID:29084823 PBO:0104938 Fig3C, Fig7A shows that zfs1delta shows high mating efficiency at nitrogen levels which suppress mating in wild type cells wild type cells
PMID:29084823 PBO:0093825 Fig3A deletion of cig2 does not rescue mating efficiency zfs1delta
PMID:29084823 PBO:0104948 Fig5E
PMID:29084823 PBO:0104942 Fig5C,D
PMID:29084823 PBO:0093825 Fig3B varying the copy number of pJKpuc1+ leads to varying levels of sporulation efficiency in wild type cells increased puc1 mRNA causes reduced mating efficiency
PMID:29084823 PBO:0104949 Fig5E
PMID:29084823 PBO:0104945 Fig6A
PMID:29084823 PBO:0104945 Fig6A
PMID:29084823 PBO:0104950 Fig6A,B
PMID:29084823 PBO:0104935 Fig6 A,B
PMID:29084823 PBO:0104950 Fig6A,B
PMID:29084823 PBO:0104947 Fig6A,B
PMID:29084823 PBO:0099114 Fig7A shows that puc1delta shows increased mating efficiency at nitrogen levels which suppress mating in wild type cells
PMID:29084823 PBO:0104946 Fig6A
PMID:29084823 PBO:0104946 Fig6A
PMID:29084823 PBO:0104947 Fig6A,B
PMID:29084823 PBO:0093825 Fig3A deletion of cig1 does not rescue mating efficiency of zfs1 delta
PMID:29109278 FYPO:0004742 otr1R(SphI)::ura4+
PMID:29109278 PBO:0094282 otr1R(SphI)::ura4+
PMID:29109278 PBO:0094283 otr1R(SphI)::ura4+
PMID:29109278 PBO:0094283 otr1R(SphI)::ura4+
PMID:29109278 PBO:0105308 otr1R(SphI)::ura4+
PMID:29109278 PBO:0105309 otr1R(SphI)::ura4+
PMID:29109278 FYPO:0003412 otr1R(SphI)::ura4+
PMID:29109278 FYPO:0004604 tel2L::ura4+
PMID:29109278 FYPO:0002827 mat3M::ura4+
PMID:29109278 PBO:0094679 otr1R(SphI)::ura4+
PMID:29109278 PBO:0094679 otr1R(SphI)::ura4+
PMID:29109278 PBO:0094679 otr1R(SphI)::ura4+
PMID:29123917 PBO:0102320 Later stage of meiotic prophase, observed by co-localisation with Taz1
PMID:29123917 PBO:0102320 Later stage of meiotic prophase, observed by co-localisation with Taz1
PMID:29123917 PBO:0102323 fig6
PMID:29123917 FYPO:0006372 S10 E and F
PMID:29134248 GO:0070867 Fusion domain
PMID:29134248 GO:0032220 plasma membrane fusion during conjugation
PMID:29134248 GO:0032220 plasma membrane fusion during conjugation
PMID:29136238 FYPO:0003575 Fig3
PMID:29136238 FYPO:0006429 Fig3
PMID:29136238 FYPO:0004743 Fig3
PMID:29136238 PBO:0097950 Fig2
PMID:29136238 PBO:0094282 Fig2
PMID:29136238 PBO:0094681 Fig2
PMID:29136238 PBO:0094283 Fig2
PMID:29136238 PBO:0107683 Fig2
PMID:29136238 PBO:0107682 Fig1
PMID:29136238 PBO:0097234 Fig4/5
PMID:29136238 FYPO:0000088 fig7
PMID:29136238 PBO:0107686 and observed a preferential association of Swi6 with Y41F over Y41p peptide, suggest- ing that phosphorylation of H3Y41 counteracts the interac- tion of Swi6 with histone H3 (Supplementary Figure S6A).
PMID:29136238 PBO:0107685 and observed a preferential association of Swi6 with Y41F over Y41p peptide, suggest- ing that phosphorylation of H3Y41 counteracts the interac- tion of Swi6 with histone H3 (Supplementary Figure S6A).
PMID:29136238 PBO:0101106 Fig1
PMID:29136238 PBO:0107687 Fig4
PMID:29136238 PBO:0107684 and observed a preferential association of Swi6 with Y41F over Y41p peptide, suggest- ing that phosphorylation of H3Y41 counteracts the interac- tion of Swi6 with histone H3 (Supplementary Figure S6A).
PMID:29136238 PBO:0107688 Fig4/5
PMID:29136238 FYPO:0006395 Fig3
PMID:29136238 PBO:0094682 Fig4
PMID:29149597 PBO:0095032 The localization of Poz1, Tpz1 and Rap1 proteins are assayed.
PMID:29149597 PBO:0095034 The localization of Poz1, Tpz1 and Rap1 proteins are assayed.
PMID:29149597 PBO:0095032 The localization of Poz1, Tpz1 and Rap1 proteins are assayed.
PMID:29149597 PBO:0095033 The localization of Poz1, Tpz1 and Rap1 proteins are assayed.
PMID:29149597 PBO:0095034 The localization of Poz1, Tpz1 and Rap1 proteins are assayed.
PMID:29149597 PBO:0095033 The localization of Poz1, Tpz1 and Rap1 proteins are assayed.
PMID:29167352 FYPO:0002060 (Fig. 1C
PMID:29167352 FYPO:0002060 (Fig. 1C
PMID:29167352 FYPO:0002060 (Fig. 1C
PMID:29167352 PBO:0101442 ~30% of the double mutant cells exhibited the monopolar spindle phenotype.
PMID:29167352 GO:1990810 fig 4. Klp2 is not required, but acts collaboratively with Pkl1, in anchoring the spindle microtubule to the mitotic SPB
PMID:29167352 FYPO:0002060 (Fig. 1C
PMID:29167352 FYPO:0001489 28 celcius
PMID:29167352 GO:0072686 often in a punctate manner
PMID:29167352 FYPO:0002060 (Fig. 1C
PMID:29167352 FYPO:0002060 (Fig. 1C 28 Celcius
PMID:29167439 PBO:0102676 limit subtelomeric DNA amplification in G0
PMID:29167439 FYPO:0006507 require for subtelomeric DNA amplification in G0
PMID:29167439 FYPO:0006507 Require for subtelomeric DNA amplification in G0
PMID:29167439 FYPO:0006507 increase with telomere shortening and time in quiescence
PMID:29167439 PBO:0102675 increase with telomere shortening and time in quiescence
PMID:29180432 PBO:0108186 fig 4
PMID:29180432 PBO:0109271 fig 3
PMID:29180432 PBO:0108189 figure 3
PMID:29180432 PBO:0108192 figure 3
PMID:29180432 PBO:0108191 increased duration of metaphase Fig. 5E
PMID:29180432 FYPO:0006800 Fig. 5 B and D
PMID:29180432 PBO:0098308 fig 5 (measured at 4 um spindle. WT has 6%)
PMID:29180432 PBO:0108187 fig 6
PMID:29180432 PBO:0108185 fig 2G
PMID:29180432 PBO:0108185 fig 2G
PMID:29180432 PBO:0108186 fig 2G
PMID:29180432 PBO:0108188 fig6
PMID:29180432 FYPO:0002638 fig 5f
PMID:29180432 PBO:0108188 fig3
PMID:29194511 FYPO:0003241 Figure S1A and B
PMID:29194511 PBO:0102787 Figure 3E-F, Supplementary figure 8 C-D
PMID:29194511 PBO:0102787 Figure 3C-D, Supplementary Figure 8A-B
PMID:29194511 FYPO:0001234 Figure 2A,B,C
PMID:29194511 PBO:0101834 Figure 2E-F, supplementary figure 5
PMID:29194511 PBO:0102788 Figure 2G, supplementary figure 4
PMID:29194511 FYPO:0003241 Figure S1A and B
PMID:29194511 FYPO:0003241 Figure S1A and B
PMID:29194511 FYPO:0003241 Figure S1A and B
PMID:29194511 PBO:0102789 fig 1b &C
PMID:29194511 PBO:0102790 fig 1b &C and 3H
PMID:29194511 PBO:0102791 fig 1b &C and 3H
PMID:29194511 PBO:0102792 fig 1b &C
PMID:29194511 PBO:0102793 fig 1b &C
PMID:29194511 PBO:0102794 fig 1b &C
PMID:29194511 PBO:0102795 fig 1b &C
PMID:29194511 PBO:0102793 fig 1b &C
PMID:29194511 PBO:0102796 fig 1b &C
PMID:29194511 FYPO:0003241 fig 4a
PMID:29194511 FYPO:0003241 fig 4a
PMID:29194511 FYPO:0006353 fig 4b
PMID:29194511 FYPO:0006353 fig 4b
PMID:29194511 GO:0005515 fig 5
PMID:29214404 FYPO:0000873 at telomeres 1L, 2R
PMID:29214404 FYPO:0004137 at telomere 1R
PMID:29214404 PBO:0094683 at telomeres 1L, 1R, 2L, 2R
PMID:29214404 PBO:0100489 greater decrease at telomeres 1R and 2L than at 1L and 2R
PMID:29215009 FYPO:0006320 upstream reporter
PMID:29215009 FYPO:0006320 upstream reporter
PMID:29215009 FYPO:0003589 same as either single mutant
PMID:29215009 FYPO:0006318 same as exo1delta alone
PMID:29216371 PBO:0095218 IMP evidence for part_of extension
PMID:29216371 PBO:0095218 IMP evidence for part_of extension
PMID:29249658 GO:0005515 fig 3h
PMID:29249658 PBO:0103099 fig 3D
PMID:29249658 PBO:0103102 Figure 3D
PMID:29249658 PBO:0103103 Figure S-3F
PMID:29249658 PBO:0103103 Figure S-3F
PMID:29249658 PBO:0099941 fig 1 `D,E ~55%
PMID:29249658 PBO:0103108 Fig 4F (lasso)
PMID:29249658 PBO:0103107 Fig 4F
PMID:29249658 PBO:0103106 figure S4C
PMID:29249658 PBO:0103106 figure S4C
PMID:29249658 PBO:0103105 figure S4C
PMID:29249658 PBO:0103105 figure S4C
PMID:29249658 FYPO:0000118 Fig 4C D
PMID:29249658 FYPO:0000013 Fig 4C D
PMID:29249658 PBO:0103104 Figure 3H
PMID:29249658 PBO:0103101 Figure S-3F
PMID:29249658 PBO:0103102 Figure S-3F
PMID:29249658 PBO:0103102 Figure S-3F
PMID:29249658 PBO:0103101 Figure S-3F
PMID:29249658 PBO:0103100 fig 3
PMID:29249658 PBO:0103099 fig 3
PMID:29249658 PBO:0103098 fig 3D
PMID:29249658 PBO:0103097 fig S3A
PMID:29249658 PBO:0103097 fig 3c
PMID:29249658 PBO:0103096 fig 3B
PMID:29249658 PBO:0103096 fig 3A
PMID:29249658 FYPO:0000224 fig 2A
PMID:29249658 PBO:0103095 figure 2
PMID:29249658 PBO:0103094 figure 2
PMID:29249658 PBO:0103093 figure 2
PMID:29249658 PBO:0103092 fig 2
PMID:29249658 PBO:0103089 fig 2A
PMID:29249658 FYPO:0000223 fig 2A
PMID:29249658 PBO:0103091 fig 2A
PMID:29249658 PBO:0103091 fig 2A
PMID:29249658 PBO:0103090 figure 2D
PMID:29249658 PBO:0103089 fig 2A
PMID:29249658 PBO:0103089 fig 2A
PMID:29249658 PBO:0103088 CHeCK phenotypes
PMID:29249658 PBO:0103087 fig 1
PMID:29249658 PBO:0103086 fig 1
PMID:29249658 PBO:0103084 fig 1B
PMID:29249658 PBO:0103084 fig 1B
PMID:29249658 PBO:0103085 figure 1c
PMID:29249658 FYPO:0002021 fig 1
PMID:29259000 FYPO:0006313 fig 2A abolished entry into meiosis (at pre meiosis?)
PMID:29259000 FYPO:0000280 fig2A
PMID:29259000 FYPO:0006128 fig S5A
PMID:29259000 FYPO:0002222 fig 5D
PMID:29259000 PBO:0102150 fig 5
PMID:29259000 FYPO:0000485 Figure 4
PMID:29259000 PBO:0102149 Figure 4A and B: MI NDJ
PMID:29259000 PBO:0102148 Figure 4A and B: MI NDJ
PMID:29259000 PBO:0102147 Figure S3C-E
PMID:29259000 PBO:0102146 Figure S3C-E
PMID:29259000 FYPO:0000485 Figure 3F
PMID:29259000 PBO:0102145 fig 3D
PMID:29259000 PBO:0102144 fig 3D
PMID:29259000 FYPO:0000583 fig2 abolished asci formation
PMID:29259000 FYPO:0006314 fig2
PMID:29259000 FYPO:0006313 fig 2A abolished entry into meiosis (at pre meiosis?)
PMID:29259000 PBO:0102152 fig5
PMID:29259000 PBO:0102151 fig 7D,E,F
PMID:29259000 PBO:0035494 Figure 6
PMID:29259000 FYPO:0006316 fig 5E
PMID:29290560 FYPO:0000539 Fig 3D
PMID:29290560 FYPO:0000537 Fig 3D
PMID:29290560 PBO:0096459 Figure 2E
PMID:29290560 PBO:0096458 Fig 2A
PMID:29290560 FYPO:0006330 (Figure 1F) ER-PM uncoupling
PMID:29290560 PBO:0096457 Figures 1D and S1F
PMID:29290560 FYPO:0006330 Figures 1D and S1F ER-PM uncoupling *********lateral PM
PMID:29290560 FYPO:0006330 Figures 1C and S1C ER-PM contact removal
PMID:29290560 GO:0140268 fig1
PMID:29290560 PBO:0108726 fig1 ER plasma membrane tethering ER-PM contact removal OR abnormal ER-PM contact formation
PMID:29290560 PBO:0019141 Figure 3C
PMID:29290560 PBO:0019141 Figure 3C
PMID:29290560 FYPO:0001945 Fig 3D
PMID:29290560 PBO:0019132 FIg 3C
PMID:29292846 GO:0005635 fig4
PMID:29292846 GO:0003690 DNA binding site: 1-60 a.a.
PMID:29292846 PBO:0104332 fig5
PMID:29292846 GO:0019237 Deletion of LEM domain decreases the association of Lem2 at the centromere
PMID:29292846 GO:0005515 fig 1a residues 200-307
PMID:29292846 PBO:0104333 fig2
PMID:29292846 PBO:0104334 fig2
PMID:29292846 PBO:0104333 fig2
PMID:29292846 PBO:0104333 fig2
PMID:29292846 PBO:0104333 fig2
PMID:29292846 FYPO:0000655 fig3
PMID:29292846 FYPO:0000659 fig3
PMID:29292846 FYPO:0000655 fig3
PMID:29292846 GO:0005635 fig4
PMID:29292846 GO:0044732 fig4
PMID:29292846 PBO:0104339 fig 5
PMID:29292846 FYPO:0002967 fig5
PMID:29292846 FYPO:0005612 fig5
PMID:29292846 PBO:0104337 fig5
PMID:29292846 PBO:0104336 fig5
PMID:29292846 PBO:0104335 fig5
PMID:29319508 PBO:0097995 An increased resistance to cell lysis induced by the presence of higher concentration of 2-deoxyglucose in the vegetative growth phase of life cycle of cell
PMID:29319508 FYPO:0000064 An increased resistance to cell lysis induced by the presence of higher concentration of 2-deoxyglucose in the vegetative growth phase of cell
PMID:29319508 FYPO:0000064 An increased resistance to cell lysis induced by the presence of higher concentration of 2-deoxyglucose in the vegetative growth phase of cell
PMID:29319508 PBO:0093822 A phenotype in which a cell lyses, i.e. the plasma membrane ruptures and cytoplasm is lost, in presence of higher concentration of 2-deoxyglucose.
PMID:29319508 FYPO:0000064 An increased resistance to cell lysis induced by the presence of higher concentration of 2-deoxyglucose in the vegetative growth phase of cell
PMID:29319508 FYPO:0000064 An increased resistance to cell lysis induced by the presence of higher concentration of 2-deoxyglucose in the vegetative growth phase of cell
PMID:29330317 GO:0006433 fig3
PMID:29330317 GO:0006421 fig3
PMID:29343550 FYPO:0004737 Figure 4A LifeAct-mcherry
PMID:29343550 PBO:0106492 Figure 3A allele tagged with mNeonGreen
PMID:29343550 PBO:0099724 Figure 4C 4Cmcherry
PMID:29343550 FYPO:0004741 Figure 4A LifeAct-mcherry
PMID:29343550 FYPO:0004741 Figure 4A LifeAct-mcherry
PMID:29343550 FYPO:0004740 Figure 4A LifeAct-mcherry issues/3215
PMID:29343550 FYPO:0003339 Figure 5
PMID:29343550 FYPO:0005020 Figure 5
PMID:29343550 FYPO:0003339 Figure 5
PMID:29343550 FYPO:0001365 Figure 5
PMID:29343550 PBO:0106949 Figure 4E-F tagged with GFP
PMID:29343550 PBO:0106951 Figure 1A-B
PMID:29343550 PBO:0106952 Figure 1C
PMID:29343550 FYPO:0002060 Figure 2C DAPI, methyl blue
PMID:29343550 PBO:0106492 Figure 3A allele tagged with mNeonGreen
PMID:29343550 PBO:0106948 Figure 4E tagged with GFP
PMID:29343550 PBO:0099724 Figure 4Cmcherry
PMID:29343550 FYPO:0002177 Figure 2C DAPI, methyl blue
PMID:29352077 FYPO:0002060 figure 4
PMID:29352077 FYPO:0002060 figure 4
PMID:29352077 FYPO:0002060 figure 4
PMID:29352077 PBO:0107889 figure 4F
PMID:29352077 FYPO:0002060 figure 4
PMID:29352077 FYPO:0002060 figure 4
PMID:29352077 FYPO:0002060 figure 3
PMID:29352077 FYPO:0002060 figure 3
PMID:29352077 FYPO:0002060 figure 3
PMID:29352077 FYPO:0002060 figure 3
PMID:29352077 FYPO:0002060 figure 3
PMID:29352077 FYPO:0002060 figure 3
PMID:29352077 FYPO:0002060 figure 3
PMID:29352077 FYPO:0001513 figure 3
PMID:29352077 FYPO:0001513 figure 3
PMID:29352077 FYPO:0001513 figure 3
PMID:29352077 FYPO:0001513 figure 3
PMID:29352077 FYPO:0001513 figure 3
PMID:29352077 FYPO:0001513 figure 3
PMID:29352077 FYPO:0001513 figure 3
PMID:29352077 FYPO:0002060 figure 4
PMID:29352077 FYPO:0002060 figure 4
PMID:29352077 FYPO:0002060 figure 2
PMID:29352077 FYPO:0001513 figure 2
PMID:29414789 PBO:0101896 Primer Extension Analysis
PMID:29414789 PBO:0096175 Primer extension analysis
PMID:29414789 PBO:0094613 Primer extension analysis
PMID:29414789 PBO:0101896 Primer extension analysis
PMID:29414789 PBO:0097322 Northern blot and primer extension analysis
PMID:29414789 PBO:0097330 Northern blot and primer extension analysis
PMID:29414789 PBO:0096175 Northern blot and primer extension analysis
PMID:29414789 PBO:0096175 Northern blot and primer extension analysis
PMID:29414789 PBO:0097322 Northern blot and primer extension analysis
PMID:29414789 PBO:0101897 Primer extension analysis
PMID:29414789 PBO:0101897 Primer extension analysis
PMID:29414789 PBO:0101897 Primer extension analysis
PMID:29414789 FYPO:0002243 8c
PMID:29414789 GO:0140256 GONEW: negative regulation of cellular response to phosphate starvation
PMID:29414789 PBO:0094613 Primer extension analysis
PMID:29414789 PBO:0096175 Primer extension analysis
PMID:29422501 PBO:0101688 fig2
PMID:29422501 PBO:0101688 fig2
PMID:29422501 PBO:0101688 fig2
PMID:29422501 PBO:0101688 fig 1 a
PMID:29422501 PBO:0101694 fig1 c
PMID:29422501 PBO:0101695 fig1 c
PMID:29422501 PBO:0101696 fig 1c
PMID:29422501 PBO:0101696 fig 1c
PMID:29422501 PBO:0101702 fig 3a
PMID:29422503 PBO:0095740 Est1 showed similar expression level in pof8∆ cells as wild-type cells.
PMID:29422503 GO:0140445 (created to replace WT phenotype annotation) Fig. 1e
PMID:29422503 PBO:0095764 fig 1 c/d
PMID:29422503 PBO:0095757 fig 5
PMID:29422503 FYPO:0002687 fig 5
PMID:29422503 PBO:0095756 fig 5
PMID:29422503 PBO:0095767 fig 1 e
PMID:29422503 PBO:0095739 Telomere binding of Est1 is reduced in pof8∆ cells.
PMID:29422503 PBO:0095767 fig 1 e
PMID:29422503 PBO:0095767 fig 1 e
PMID:29422503 PBO:0095766 fig 1 c/d
PMID:29422503 PBO:0095765 fig 1 c/d
PMID:29422503 PBO:0095738 moderately reduced less severe thanin ter1∆ cells.
PMID:29422503 PBO:0095738 Trt1 expression level detected by western blot is reduced in ter1∆ cells.
PMID:29422503 PBO:0095737 Based on ChIP, ter1∆ cause loss of telomerase (Trt1) localization at telomeres.
PMID:29422503 FYPO:0002239 fig 5
PMID:29422503 PBO:0095755 Fig. 4e
PMID:29422503 PBO:0095754 Fig. 4d
PMID:29422503 PBO:0095751 Lsm3 protein level was not affected by est1∆.
PMID:29422503 PBO:0095750 Fig. 4f Lsm3 binding to telomeres was not affected by est1∆.
PMID:29422503 PBO:0095751 Lsm3 protein level was not affected by trt1∆.
PMID:29422503 PBO:0095750 Fig. 4f Lsm3 binding to telomeres was not affected by trt1∆.
PMID:29422503 PBO:0095751 Lsm3 protein level was not affected by ter1∆.
PMID:29422503 PBO:0095753 Lsm3 binding was detected at ars2004, non-ARS, ade6+ and his1+ loci. In ter1∆ cells, Lsm3 binding to those non-telmeric sites were increased.
PMID:29422503 PBO:0095752 Fig. 4f Lsm3 binding at telomeres is increased by ter1∆.
PMID:29422503 PBO:0095751 Lsm3 protein level was not affected by pof8∆.
PMID:29422503 PBO:0095750 Fig. 4f
PMID:29422503 PBO:0095749 Fig. 4c Lsm3-TER1 interaction is abolished in pof8∆ cells.
PMID:29422503 PBO:0095748 Fig 4 a Expression level of telomerase RNA TER1 is reduced but not eliminated in pof8∆ cells. Expression level for telomerase RNA pre-cursor was not affected by pof8∆.
PMID:29422503 PBO:0095747 Trt1-TER1 interaction is reduced but not eliminated in pof8-∆[289-4020]. Extent of reduction in Trt1-TER1 is similar to pof8∆ cells.
PMID:29422503 PBO:0095746 Fig. 3a Pof8-TER1 interaction is not affected by est1∆.
PMID:29422503 PBO:0095745 Fig. 3a) Pof8-TER1 interaction is reduced but not eliminated in trt1∆ cells.
PMID:29422503 PBO:0095745 Fig. 3a Pof8-TER1 interaction is reduced but not eliminated in ccq1∆.
PMID:29422503 PBO:0095744 Pof8 expression was not affected by est1∆.
PMID:29422503 PBO:0095743 fig 1 e Localization of Pof8 at telomeres is reduced but not eliminated in est1∆.
PMID:29422503 PBO:0095744 Pof8 expression level is not affected by trt1∆.
PMID:29422503 PBO:0095743 fig 1 e Localization of Pof8 at telomeres is reduced but not eliminated in trt1∆.
PMID:29422503 PBO:0095744 Pof8 expression level is not affected in ccq1∆.
PMID:29422503 PBO:0095743 fig 1 e Localization of Pof8 at telomeres is reduced but not eliminated in ccq1∆.
PMID:29422503 PBO:0095744 Pof8 expression level was not altered in ter1∆ cells.
PMID:29422503 PBO:0095743 fig 1 e Localization of Pof8 at telomeres is reduced but not eliminated in ter1∆.
PMID:29422503 PBO:0095740 Est1 expression level detected by western in ter1∆ cells was similar to Est1 level in ter1+ (wild-type) cells.
PMID:29422503 PBO:0095739 Est1 binding to telomeres is reduced to near no binding in ter1∆, based on ChIP assay.
PMID:29422503 PBO:0095742 fig 3 b
PMID:29422503 PBO:0095741 Fig. 3c Interaction between Est1 and TER1 was not affected by pof8∆.
PMID:29422503 PBO:0095736 fig 1 c/d Trt1-myc ChIP
PMID:29422503 FYPO:0003106 pof8∆ rif1∆ cells showed short telomeres, very similar to pof8∆ cells.
PMID:29422503 PBO:0095735 pof8∆ poz1∆ cells showed very slightly shortend telomeres, rather than highly elongated telomeres in poz1∆ cells. (This strain showed longer telomere than pof8∆ cells.)
PMID:29422503 PBO:0095735 pof8∆ rap1∆ cells showed shortened telomeres, more similar to pof8∆, rather than highly elongated telomeres in rap1∆ cells.
PMID:29422503 PBO:0095772 Supplementary Fig. 4
PMID:29422503 PBO:0095747 fig 5
PMID:29422503 GO:1904868 figs 1-3
PMID:29422503 PBO:0095772 Supplementary Fig. 4
PMID:29422503 PBO:0095773 Supplementary Fig. 4
PMID:29422503 PBO:0095758 Trt1 binding is reduced to ~69% of pof8+ cells, but not as severely reduced as pof8∆ cells (~35%).
PMID:29422503 FYPO:0003106 fig 6 pof8-Y330A cells show as short telomere as pof8∆ cells.
PMID:29422503 PBO:0095759 fig 6 b
PMID:29422503 FYPO:0003106 fig 6 pof8-R343A cells show as short telomere as pof8∆ cells.
PMID:29422503 FYPO:0003106 fig 6 pof8-∆[390-402] cells show as short telomere as pof8∆ cells.
PMID:29422503 FYPO:0003106 fig 6 pof8-∆[289-402] cells show as short telomere as pof8∆ cells.
PMID:29422503 PBO:0095759 fig 6
PMID:29422503 PBO:0095748 fig 6
PMID:29422503 PBO:0095772 Supplementary Fig. 4
PMID:29422503 GO:1904868 figs 1-3
PMID:29422503 PBO:0095771 (created to replace WT phenotype annotation)
PMID:29422503 PBO:0095770 (created to replace WT phenotype)
PMID:29422503 GO:0003682 (created to replace WT phenotype)
PMID:29422503 PBO:0095769 (created to replace WT phenotype annotation) lsm3-myc chip
PMID:29422503 GO:0070034 (created to replace WT phenotype annotation)
PMID:29422503 PBO:0095768 (created to replace WT phenotype annotation) fig 3 b
PMID:29422503 PBO:0095769 (created to replace WT phenotype annotation) est1-myc chip
PMID:29422503 PBO:0095769 (created to replace WT phenotype annotation) trt1-myc chip
PMID:29422503 PBO:0095768 fig 3a (created to replace WT phenotype annotation)
PMID:29422503 FYPO:0003106 figure 1 a
PMID:29422503 FYPO:0003107 fig1 Lose telomere signal, much like trt1∆ cells.
PMID:29422503 PBO:0095737 Trt1 binding is reduced to ~58% of pof8+ cells, but not as severely reduced as pof8∆ cells (~35%).
PMID:29422503 PBO:0095737 Trt1 binding is reduced to ~70% of pof8+ cells, but not as severely reduced as pof8∆ cells (~35%).
PMID:29422503 PBO:0095737 Trt1 binding is reduced to ~80% of pof8+ cells, but not as severely reduced as pof8∆ cells (~35%).
PMID:29422503 GO:0007004 Fig 1
PMID:29422503 FYPO:0003106 figure 1a Telomere shortening is similar to pof8∆ cells.
PMID:29422503 PBO:0093634 pof8∆ taz1∆ showed much shorter telomere length (almost like wild-type cells) than taz1∆ cells, but showed some rearrangement in sub-telomeres.
PMID:29424342 PBO:0102643 fig5
PMID:29424342 PBO:0102651 6
PMID:29424342 PBO:0102650 6
PMID:29424342 PBO:0102649 6
PMID:29424342 PBO:0102643 ts background fig5
PMID:29424342 PBO:0102642 ts background fig5
PMID:29424342 PBO:0102648 4
PMID:29424342 PBO:0102647 4
PMID:29424342 PBO:0102646 4
PMID:29424342 PBO:0102645 4
PMID:29424342 PBO:0102644 4
PMID:29424342 PBO:0099879 4b
PMID:29424342 GO:0006406 fig2
PMID:29424342 PBO:0102642 fig5
PMID:29432178 PBO:0100854 Fig. 3A
PMID:29432178 FYPO:0001357 Fig. 3A
PMID:29432178 FYPO:0006473 Fig. 3E
PMID:29432178 PBO:0100857 Fig. 3B during normal growth
PMID:29432178 PBO:0100856 Fig. 3A
PMID:29432178 FYPO:0006474 Ribosome profiling and matching RNA-seq in gcn2Δ cells treated or untreated with 3-AT revealed that the majority of the translationally induced genes did not respond to amino acid starvation (Fig. 2B)
PMID:29432178 FYPO:0006444 the expression of most genes induced by amino acid starvation in wild-type cells was not up-regulated, confirming that Gcn2 is the major mediator of this response
PMID:29432178 FYPO:0001234 Can we say somewhere - overexpresses genes involved by amino acid starvation, or something similar?
PMID:29453312 PBO:0092569 Active Ras1 is localized to cell poles during mitotic growth
PMID:29453312 PBO:0096695 In the absence of efc25 Ras1 is not activated at the cell cortex
PMID:29453312 PBO:0096697 In the absence of efc25 Ras1 is not activated at the cell cortex
PMID:29453312 PBO:0096693 ras1 mutant cells undergo precocious fusion resulting in cell lysis
PMID:29453312 PBO:0096701 In the absence of gap1 Ras activity increases and decorates the entire cortex of vegetative growing cells
PMID:29453312 GO:1902917 Ras activity increases during the mating process and is maximum at the fusion site just before the fusion event.
PMID:29453312 GO:1990819 Active Ras1 co-localizes with the actin fusion focus during the process of cell-cell fusion
PMID:29453312 PBO:0096692 ras1 mutant cells undergo precocious fusion resulting in cell lysis
PMID:29453312 PBO:0096694 Active Ras1 is localized to cell poles during mitotic growth
PMID:29453312 PBO:0092569 Ative Ras1 localizes to septa during mitotic growth
PMID:29453312 GO:1990819 Ste6 co-localizes with the actin fusion focus during the process of cell-cell fusion
PMID:29453312 PBO:0096694 Active Ras1 is localized to cell poles during mitotic growth
PMID:29458562 PBO:0096250 fig4
PMID:29458562 FYPO:0002060 Fig. 2
PMID:29458562 FYPO:0004085 Fig. 2
PMID:29458562 FYPO:0004085 Fig. 2
PMID:29458562 PBO:0096258 fig4
PMID:29458562 PBO:0096255 fig4
PMID:29458562 PBO:0096256 fig4
PMID:29458562 PBO:0096257 fig4
PMID:29458562 PBO:0096254 fig3
PMID:29458562 PBO:0096253 fig3
PMID:29458562 PBO:0096252 fig3
PMID:29458562 FYPO:0004153 DNS
PMID:29458562 FYPO:0000245 Fig. 2
PMID:29458562 FYPO:0000562 fig2 (likey due to intron encoded maturase)
PMID:29458562 PBO:0096251 fig3 abolished
PMID:29514920 PBO:0110564 Fig 1A
PMID:29514920 PBO:0107824 fig2B
PMID:29514920 PBO:0101337 fig 3A, fig 3B Fig. S2, A and B IN TRANSIENT BURSTS & progressive increase in the number of Wee1 nodes as a function of cell size, ... 20X in Wee1 nodes in large cells versus small cells (Fig. 4 B).
PMID:29514920 PBO:0107815 affecting Wee1
PMID:29514920 PBO:0107815 Affecting Wee1 vw Increased , term pending
PMID:29514920 PBO:0107816 fig 3D Affecting Wee1
PMID:29514920 PBO:0102684 affecting Cdr1 vw:ig. S2, F and G
PMID:29514920 PBO:0023824 figure 2D Epistatic to cdr2delta
PMID:29514920 PBO:0107817 Fig 2C protein localizes to cytoplasm, nucleus, and spindle-pole body.
PMID:29514920 PBO:0023824 figure 2D Epistatic to cdr2delta
PMID:29514920 PBO:0107825 figure 2B
PMID:29514920 PBO:0110565 Fig 1A
PMID:29514920 PBO:0107821 Fig. 1A
PMID:29514920 PBO:0107431 Fig 1B
PMID:29514920 PBO:0107825 figure 2B
PMID:29514920 PBO:0107824 figure 2B
PMID:29514920 PBO:0107822 Fig 1A
PMID:29514920 PBO:0107822 Fig 1A
PMID:29514920 PBO:0107823 Fig. 1A
PMID:29514920 PBO:0107823 Fig 1C
PMID:29529046 PBO:0102039 The reporter gene was the the ZapCY1 high affinity zinc-responsive FRET reporter. As this reporter is located in the cytosol and nucleus it measures zinc availability in these compartments (so the Term name should really be increased cytoplasm (not cellular) zinc level)
PMID:29529046 PBO:0102051 Fig 8
PMID:29529046 PBO:0102051 Fig 8
PMID:29529046 PBO:0102050 Fig 8
PMID:29529046 PBO:0102049 Fig 8
PMID:29529046 PBO:0102048 Fig 8
PMID:29529046 PBO:0102047 Fig 8
PMID:29529046 PBO:0102045 Fig 8
PMID:29529046 PBO:0102046 Fig 8
PMID:29529046 PBO:0111437 Zhf1 is required for the rapid transport of zinc ions out of the cytosol during a zinc shock (a condition where there is a rapid influx of zinc into a cell)
PMID:29529046 GO:0120127 A key finding of our work is that Zhf1 does NOT transport zinc out of the cytosol under conditions of zinc ion starvation
PMID:29529046 PBO:0102038 Fig 5A/B In this paper we used a high affinity zinc-responsive FRET sensor (ZapCY1) to measure zinc ion availability in the cytosol under conditions of zinc deficiency. Thus, in addition to accumulating high levels of total cellular zinc - this manuscript shows that loz1D cells also accumulate higher levels of zinc in the cytosol. This accumulation is also dependent upon Zrt1 as this phenotype is not observed in a loz1 zrt1 double mutant
PMID:29529046 PBO:0102039 The reporter gene was the the ZapCY1 high affinity zinc-responsive FRET reporter. As this reporter is located in the cytosol and nucleus it measures zinc availability in these compartments (so the Term name should really be increased cytoplasm (not cellular) zinc level)
PMID:29529046 FYPO:0001534 The experiment performed was to measure total cellular zinc ion levels in a zrt1D strain during a zinc shock (Figure 4A)
PMID:29529046 PBO:0102040 "We made the term ""zinc ion import into organelle""in GO becuse it fits better witht the descendants"
PMID:29529046 PBO:0102041 "We made the term ""zinc ion import into organelle""in GO becuse it fits better witht the descendants"
PMID:29529046 PBO:0102042 The reporter gene was the the ZapCY1 high affinity zinc-responsive FRET reporter. As this reporter is located in the cytosol and nucleus it measures zinc availability in these compartments (so the Term name should really be increased cytoplasm (not cellular) zinc level)
PMID:29529046 PBO:0102039 The reporter gene was the the ZapCY1 high affinity zinc-responsive FRET reporter. As this reporter is located in the cytosol and nucleus it measures zinc availability in these compartments (so the Term name should really be increased cytoplasm (not cellular) zinc level)
PMID:29529046 PBO:0102043 The reporter genes used were the ZapCY1 high affinity and ZapCY2 low affinity zinc-responsive FRET reporter. As this reporter is located in the cytosol and nucleus it measures zinc availability in these compartments (so the Term name should really be increased cytoplasm (not cellular) zinc level)
PMID:29529046 GO:0006882 Zrg17 also transports zinc out of the cytosol when zinc is available (as well as when it is limiting)
PMID:29529046 PBO:0102044 Fig 4 BE
PMID:29529046 PBO:0093559 Figure 1 (EDTA, zinc chelator)
PMID:29529046 PBO:0093561 Figure 1 (EDTA, zinc chelator)
PMID:29529046 PBO:0102039 fig6
PMID:29549126 GO:0020037 fig6
PMID:29549126 PBO:0106478 assayed using heme analog ZnMP
PMID:29549126 PBO:0106479 assayed using heme analog ZnMP
PMID:29549126 FYPO:0007397 assayed using heme analog ZnMP
PMID:29549126 GO:0016020 fig7
PMID:29549126 GO:0016020 fig7
PMID:29549126 GO:1904334 3B,C,
PMID:29549126 GO:1904334 3B,C, We therefore concluded that Shu1 is required for hemin acquisition when hemin is present at very low concentrations (0.075 M), whereas its presence is dispens- able under conditions of high hemin concentrations
PMID:29549126 GO:0020037 fig6
PMID:29596413 PBO:0095604 fig 7C
PMID:29596413 PBO:0095606 fig 7C supression of trm7-delta
PMID:29596413 PBO:0095603 fig 7C
PMID:29596413 PBO:0095600 fig 7
PMID:29596413 PBO:0095602 fig 7
PMID:29596413 PBO:0095608 fig 7C supression of trm7-delta
PMID:29596413 PBO:0095601 fig 7
PMID:29596413 PBO:0095607 fig 7C
PMID:29596413 PBO:0095608 fig 7C supression of trm7-delta
PMID:29596413 PBO:0095606 fig 7C supression of trm7-delta
PMID:29596413 PBO:0095609 fig 7C supression of trm7-delta
PMID:29596413 PBO:0095610 fig 7C supression of trm7-delta
PMID:29596413 PBO:0095599 fig 7
PMID:29596413 PBO:0095605 fig 7C
PMID:29610759 PBO:0105326 fig 1
PMID:29610759 PBO:0098985 figs 1 & 4
PMID:29610759 PBO:0098985 figs 1 & 4
PMID:29610759 PBO:0098985 enriched at mat1 right border and cenH left border; fig 1
PMID:29610759 PBO:0105324 fig 2
PMID:29610759 PBO:0105325 fig 1
PMID:29610759 PBO:0105327 fig 5
PMID:29610759 FYPO:0005353 at MPS1
PMID:29618061 PBO:0108864 Interestingly, elevated pho1 levels were observed in prt-1�, prt-2�, and prt-3� (Figure 3B, lanes 1– 4) suggesting that element(s) responsible for pho1 silencing are located within the 5′ part of prt.
PMID:29618061 PBO:0110999 However, mug14 is not affected in this exosome mutant, suggesting that the gene is likely to be regulated only at the transcrip- tional level (Figure 5a).
PMID:29618061 PBO:0110998 In agreement with a previously demonstrated role for the nuclear exosome complex in the degradation of meiotic transcripts during mitosis, we observe increased levels of meu19 and meu31 in rrp6� (Figure 5B and C).
PMID:29618061 PBO:0110997 In agreement with a previously demonstrated role for the nuclear exosome complex in the degradation of meiotic transcripts during mitosis, we observe increased levels of meu19 and meu31 in rrp6� (Figure 5B and C).
PMID:29618061 PBO:0096776 . clr4�, or the dou- ble mutant clr3�clr4� (Supplementary Figure S3A, lane 4 and 5), also revealed no change in mRNA expression lev- els. These results indicate that unlike pho1, tgp1 repression
PMID:29618061 PBO:0096778 . clr4�, or the dou- ble mutant clr3�clr4� (Supplementary Figure S3A, lane 4 and 5), also revealed no change in mRNA expression lev- els. These results indicate that unlike pho1, tgp1 repression
PMID:29618061 PBO:0096776 . clr4�, or the dou- ble mutant clr3�clr4� (Supplementary Figure S3A, lane 4 and 5), also revealed no change in mRNA expression lev- els. These results indicate that unlike pho1, tgp1 repression
PMID:29618061 PBO:0096778 No detectable increase in either tgp1 or nc-tgp1 was observed in sir2�, strains harbouring a clr6 mutation (Supplementary Figure S3A, lanes 6–8)
PMID:29618061 PBO:0110989 To directly assess whether this is the case and that the two proteins function as part of the same pathway we performed a Northern blot to compare a double mu- tant clr3�set1� with the respective single mutants (Figure 3D). We found that the double mutant did not lead to higher pho1 derepression as compared to single set1�, indicating that both proteins do indeed function in the same pathway.
PMID:29618061 PBO:0096778 . clr4�, or the dou- ble mutant clr3�clr4� (Supplementary Figure S3A, lane 4 and 5), also revealed no change in mRNA expression lev- els. These results indicate that unlike pho1, tgp1 repression
PMID:29618061 GO:1902794 *******move down to new term*******. Instead, our data suggest that Set1 is likely to function via a different HDAC (Clr3) in transcriptional repression in fis- sion yeast.
PMID:29618061 PBO:0110989 . Interest- ingly, deletion of the H3K4 methyltransferase Set1 leads to derepression of pho1 (Figure 3C). In contrast, deletion of the H3K36 methyltransferase Set2 only had a minor effect on pho1 derepression, suggesting that the mechanism un- derlying pho1 silencing primarily relies on histone methy- lation by Set1
PMID:29618061 PBO:0110995 In the case of prt-3�, this phenotype is likely a result of lost Mmi1 recruitment since this mu- tant lacks the DSR motifs we previously mapped ((5,37), Figure 3A, Mmi1 CRAC). We tested Mmi1 recruitment to the prt locus in this mutant and it is indeed defective (data not shown).
PMID:29618061 PBO:0110958 No change in pho1 ex- pression could be detected for either prt-4� or prt-5� (Fig- ure 3B, lanes 5 and 6).
PMID:29618061 PBO:0110958 No change in pho1 ex- pression could be detected for either prt-4� or prt-5� (Fig- ure 3B, lanes 5 and 6).
PMID:29618061 PBO:0108864 Interestingly, elevated pho1 levels were observed in prt-1�, prt-2�, and prt-3� (Figure 3B, lanes 1– 4) suggesting that element(s) responsible for pho1 silencing are located within the 5′ part of prt.
PMID:29618061 PBO:0108864 Interestingly, elevated pho1 levels were observed in prt-1�, prt-2�, and prt-3� (Figure 3B, lanes 1– 4) suggesting that element(s) responsible for pho1 silencing are located within the 5′ part of prt.
PMID:29618061 PBO:0110989 as expected, northern blot analysis revealed no obvious additive effect compared to the ncpro� single mu- tant (Figure 2E).
PMID:29618061 PBO:0110989 Of the TSA-sensitive HDACs, Clr3 was the only one that had an effect on pho1 expression, with its deletion resulting in increased pho1 mRNA levels (Figure 1B).
PMID:29618061 PBO:0110958 In contrast, deletion of TSA- insensitive sir2, which contributes to transcriptional silenc- ing at constitutive heterochromatin, had no effect on pho1 expression (Figure 1B, lane 5).
PMID:29618061 PBO:0110990 This revealed that Clr3 indeed local- izes to the gene, particularly at the non-coding region (Fig- ure 1C).
PMID:29618061 PBO:0096776 No detectable increase in either tgp1 or nc-tgp1 was observed in sir2�, strains harbouring a clr6 mutation (Supplementary Figure S3A, lanes 6–8)
PMID:29618061 PBO:0096778 No detectable increase in either tgp1 or nc-tgp1 was observed in sir2�, strains harbouring a clr6 mutation (Supplementary Figure S3A, lanes 6–8)
PMID:29618061 PBO:0096776 No detectable increase in either tgp1 or nc-tgp1 was observed in sir2�, strains harbouring a clr6 mutation (Supplementary Figure S3A, lanes 6–8)
PMID:29618061 PBO:0096776 Unlike at pho1, we found that deletion of clr3 has no discernible induction ef- fect on tgp1
PMID:29618061 PBO:0096777 Co- incident with Seb1 loss, tgp1 mRNA levels start to accrue (Supplementary Figure S3A, lane 13)
PMID:29618061 PBO:0096777 We found accumulation of tgp1 in the seb1-1 mutant compared to wild-type (Supplementary Figure S3A, compare lanes 1 and 2).
PMID:29618061 PBO:0110989 Northern blot (Supplementary Figure S1A). Compared to wild-type pho1 mRNA levels, a slight accumulation was de- tected for all strains. However, this is less pronounced than in clr3�, indicating that Clr3 is unlikely to entirely depend on Clr2 or other components of SHREC for recruitment to pho1.
PMID:29618061 PBO:0110989 Northern blot (Supplementary Figure S1A). Compared to wild-type pho1 mRNA levels, a slight accumulation was de- tected for all strains. However, this is less pronounced than in clr3�, indicating that Clr3 is unlikely to entirely depend on Clr2 or other components of SHREC for recruitment to pho1.
PMID:29618061 PBO:0110989 Northern blot (Supplementary Figure S1A). Compared to wild-type pho1 mRNA levels, a slight accumulation was de- tected for all strains. However, this is less pronounced than in clr3�, indicating that Clr3 is unlikely to entirely depend on Clr2 or other components of SHREC for recruitment to pho1.
PMID:29618061 PBO:0110991 (Figure 1D). We found that loss of Clr3 leads to in- creased Pol II levels upstream of the pho1 promoter and particularly across the gene body.
PMID:29618061 PBO:0110992 an increase in the lev- els of H3K14ac could be detected by ChIP-qPCR (Figure 1E);
PMID:29618061 PBO:0110993 Re- markably, this mutant showed an additive accumulation of pho1 mRNA levels (Figure 2A) and displayed a slow growth phenotype considerably more severe than either of the sin- gle mutants, clr3� or clr4� (Figure 2B).
PMID:29618061 PBO:0110993 Re- markably, this mutant showed an additive accumulation of pho1 mRNA levels (Figure 2A) and displayed a slow growth phenotype considerably more severe than either of the sin- gle mutants, clr3� or clr4� (Figure 2B).
PMID:29618061 PBO:0110993 Re- markably, this mutant showed an additive accumulation of pho1 mRNA levels (Figure 2A) and displayed a slow growth phenotype considerably more severe than either of the sin- gle mutants, clr3� or clr4� (Figure 2B).
PMID:29618061 PBO:0110994 We found that, in the absence of non-coding transcription in a strain lacking the prt promoter (ncpro�) (5), Clr3 recruitment to pho1 was re- duced (Figure 2C).
PMID:29618061 PBO:0110992 H3K14ac levels were also increased in this strain (Figure 2D), similar to that seen in clr3� (Fig- ure 1E)
PMID:29618061 PBO:0110996 To test whether Clr3 recruitment depends on Set1 we per- formed ChIP-qPCR. In support of Set1 acting upstream of Clr3 we found the HDAC’s recruitment to the pho1 locus to be compromised in a set1� strain (Figure 3E).
PMID:29632066 PBO:0104930 fig S1B
PMID:29632066 PBO:0104930 fig S1B
PMID:29632066 PBO:0104930 fig S1B
PMID:29641590 FYPO:0001135 fig3
PMID:29641590 GO:0000472 A1 cleavage
PMID:29641590 GO:0000480 A0 cleavage
PMID:29641590 GO:0000447 A2 cleavage
PMID:29641590 FYPO:0007064 fig3
PMID:29641590 FYPO:0007065 fig3
PMID:29641590 FYPO:0007063 fig3
PMID:29689193 FYPO:0006745 thicker and thinner, disrupted homeostasis
PMID:29689193 GO:1903338 Promotes cell wall thickness hoemostasis
PMID:29689193 GO:1903338 Promotes cell wall thickness hoemostasis
PMID:29689193 GO:1903338 Promotes cell wall thickness hoemostasis
PMID:29689193 FYPO:0006746 figure 2 F
PMID:29689193 FYPO:0001035 figure 3B
PMID:29689193 FYPO:0001035 figure 3B
PMID:29689193 FYPO:0003889 fig 3C
PMID:29689193 FYPO:0006745 thicker and thinner, disrupted homeostasis
PMID:29689193 FYPO:0006745 thicker and thinner, disrupted homeostasis
PMID:29699848 PBO:0102404 abolished interaction with gad8
PMID:29699848 PBO:0102403 affect interaction with Tor1
PMID:29735656 FYPO:0002061 figure 2 AB inactive separase, uncleavable kleisin
PMID:29735656 FYPO:0002060 figure 2 AB inactive separase, uncleavable kleisin
PMID:29735656 FYPO:0002061 figure 2 AB inactive separase, uncleavable kleisin
PMID:29735656 FYPO:0000088 S4
PMID:29735656 FYPO:0000085 S4
PMID:29735656 PBO:0098320 figure 3c
PMID:29735656 PBO:0098320 fig 4e
PMID:29735656 FYPO:0000268 figure 4d
PMID:29735656 FYPO:0002060 figure 1 A
PMID:29735656 FYPO:0002060 figure 3, figure S1B
PMID:29735656 FYPO:0002060 figure 1 A
PMID:29735656 FYPO:0002060 figure 1 A
PMID:29735656 FYPO:0002060 figure 1 A
PMID:29735656 FYPO:0002060 figure 3, figure S1B
PMID:29735656 FYPO:0002060 figure 3, figure S1B
PMID:29735656 FYPO:0002060 figure 3, figure S1B
PMID:29735656 FYPO:0002060 fig 4b
PMID:29735656 FYPO:0002060 figure 3, figure S1B
PMID:29735656 FYPO:0002060 figure 3, figure S1B
PMID:29735656 FYPO:0002060 fig 4b
PMID:29735656 FYPO:0002060 figure 3, figure S1B
PMID:29735656 FYPO:0002060 figure 3, figure S1B
PMID:29735656 FYPO:0002060 figure 3, figure S1B
PMID:29735656 FYPO:0002060 figure 3, figure S1B
PMID:29735656 FYPO:0002060 figure 3, figure S1B
PMID:29735656 FYPO:0002060 figure 3, figure S1B
PMID:29735656 FYPO:0002060 fig 4b
PMID:29735656 FYPO:0002060 figure 3, figure S1B
PMID:29735656 FYPO:0002060 figure 1 A
PMID:29735656 FYPO:0002060 figure 1 A
PMID:29735656 FYPO:0002060 figure 1 A
PMID:29735656 FYPO:0002060 figure 1 A
PMID:29735656 FYPO:0002060 figure 1 A
PMID:29735656 FYPO:0002060 figure 1 A
PMID:29735656 FYPO:0002060 figure 1 A
PMID:29735656 FYPO:0002060 figure 1A, supp S1A
PMID:29735656 FYPO:0002060 figure 1A, supp S1A
PMID:29735656 FYPO:0002060 figure 2 AB inactive separase, uncleavable kleisin
PMID:29735745 PBO:0105506 Fig. 3 D
PMID:29735745 PBO:0105528 binds to the consensus sequence CCCCAY (Fig. 4)
PMID:29735745 PBO:0105528 binds to the consensus sequence CCCCAY (Fig. 4)
PMID:29735745 FYPO:0002061 Fig. 2 D
PMID:29735745 FYPO:0001357 Fig 2 B
PMID:29735745 FYPO:0001513 Fig 2 B
PMID:29735745 PBO:0105527 Fig. 3 D
PMID:29735745 PBO:0105527 Fig. 3 D
PMID:29735745 PBO:0105526 Fig. 3 D
PMID:29735745 PBO:0105526 Fig. 3 D
PMID:29735745 PBO:0105525 Fig. 3 D
PMID:29735745 PBO:0105525 Fig. 3 D
PMID:29735745 PBO:0105524 Fig. 3 D
PMID:29735745 PBO:0105524 Fig. 3 D
PMID:29735745 PBO:0105523 Fig. 3 D
PMID:29735745 PBO:0105523 Fig. 3 D
PMID:29735745 PBO:0105522 Fig. 3 D
PMID:29735745 PBO:0105522 Fig. 3 D
PMID:29735745 PBO:0105521 Fig. 3 D
PMID:29735745 PBO:0105521 Fig. 3 D
PMID:29735745 PBO:0105520 Fig. 3 D
PMID:29735745 PBO:0105520 Fig. 3 D
PMID:29735745 PBO:0105519 Fig. 3 D
PMID:29735745 PBO:0105519 Fig. 3 D
PMID:29735745 PBO:0105518 Fig. 3 D
PMID:29735745 PBO:0105518 Fig. 3 D
PMID:29735745 PBO:0105517 Fig. 5 A, B, C; Fig. 7 C
PMID:29735745 PBO:0105517 Fig. 5 A, B, C; Fig. 7 C
PMID:29735745 GO:0000977 binds to the consensus sequence CCCCAY (Fig. 4)
PMID:29735745 GO:0000977 binds to the consensus sequence CCCCAY (Fig. 4)
PMID:29735745 PBO:0018530 Video S2
PMID:29735745 PBO:0018530 Video S2
PMID:29735745 PBO:0018677 Fig. 2 C
PMID:29735745 PBO:0018677 Fig. 2 C
PMID:29735745 FYPO:0000214 Fig. 5 H
PMID:29735745 FYPO:0004099 Fig. 5 H
PMID:29735745 FYPO:0001357 Fig S2 F
PMID:29735745 FYPO:0001357 Fig. S2 F
PMID:29735745 FYPO:0001357 Fig S2 F
PMID:29735745 FYPO:0001357 Fig. S2 F
PMID:29735745 FYPO:0001357 Fig. S2 F
PMID:29735745 FYPO:0001357 Fig. S2 F
PMID:29735745 FYPO:0004099 Fig. S2 D
PMID:29735745 FYPO:0004099 Fig. S2 D
PMID:29735745 FYPO:0004099 Fig. S2 D
PMID:29735745 FYPO:0004099 Fig. S2 D
PMID:29735745 FYPO:0004099 Fig. S2 D
PMID:29735745 FYPO:0004099 Fig S2 D
PMID:29735745 FYPO:0004099 Fig. S2 D
PMID:29735745 PBO:0105516 Fig 7 D
PMID:29735745 PBO:0105514 Fig. 7 C
PMID:29735745 FYPO:0001357 Fig. 7 B
PMID:29735745 PBO:0096226 Fig. 7 B
PMID:29735745 PBO:0105516 Fig. 7 C
PMID:29735745 FYPO:0001357 Fig. 7 B
PMID:29735745 FYPO:0002151 Fig. 7 B
PMID:29735745 FYPO:0001420 Fig. 5 G
PMID:29735745 FYPO:0001420 Fig. 5G
PMID:29735745 FYPO:0004099 Fig. 7 D
PMID:29735745 FYPO:0004099 Fig. S2 D
PMID:29735745 FYPO:0004099 Fig. S2 D
PMID:29735745 FYPO:0000214 Fig. 1 D
PMID:29735745 FYPO:0004481 Fig. 1 C
PMID:29735745 FYPO:0004481 Fig. 1 C
PMID:29735745 PBO:0032915 Fig. 1 E
PMID:29735745 PBO:0101242 Fig. 1 E
PMID:29735745 FYPO:0000159 Fig. 1 D
PMID:29735745 PBO:0033591 Fig. 1 E
PMID:29735745 FYPO:0001234 Fig. 7 B
PMID:29735745 FYPO:0002061 Fig. 6 B
PMID:29735745 FYPO:0004099 Fig. 6 D
PMID:29735745 FYPO:0001420 Fig 6 B, C
PMID:29735745 FYPO:0001420 Fig. 6 B, C
PMID:29735745 FYPO:0001420 Fig. 6 B, C
PMID:29735745 FYPO:0001420 Fig. 6 B, C
PMID:29735745 FYPO:0001420 Fig. 6 B, C
PMID:29735745 FYPO:0001420 Fig. 6 B, C
PMID:29735745 FYPO:0001420 Fig. 6 B, C
PMID:29735745 FYPO:0001420 Fig. 6 B, C
PMID:29735745 FYPO:0001234 Fig. 6 B, C
PMID:29735745 FYPO:0001234 Fig. 6 B, C
PMID:29735745 FYPO:0001420 Fig. 5 F
PMID:29735745 PBO:0105516 Fig. 5 C
PMID:29735745 PBO:0093732 Fig. 5 B
PMID:29735745 PBO:0105516 Fig. 5 C
PMID:29735745 PBO:0093733 Fig. 5 B
PMID:29735745 PBO:0093732 Fig. 5 B
PMID:29735745 PBO:0093733 Fig. 5 B
PMID:29735745 PBO:0105355 Fig. 5 A
PMID:29735745 PBO:0105515 Fig. 5 A
PMID:29735745 PBO:0105354 Fig. 5 A
PMID:29735745 PBO:0105514 Fig. 5 A, 5 C
PMID:29735745 PBO:0105513 Fig. 3 D
PMID:29735745 PBO:0105512 Fig. 3 D
PMID:29735745 PBO:0105511 Fig. 3 D
PMID:29735745 PBO:0105510 Fig. 3 D
PMID:29735745 PBO:0105509 Fig. 3 D
PMID:29735745 PBO:0105508 Fig. 3 D
PMID:29735745 PBO:0105507 Fig. 3 D
PMID:29735745 FYPO:0004481 Fig. 1 C
PMID:29735745 PBO:0105500 Fig. 2 D
PMID:29735745 FYPO:0001357 Fig. 2 D
PMID:29735745 FYPO:0002061 Fig. 2 D
PMID:29735745 PBO:0105501 Fig. 2 D
PMID:29735745 PBO:0105502 Fig. 3 D
PMID:29735745 PBO:0105503 Fig. 3 D
PMID:29735745 PBO:0105504 Fig. 3 D
PMID:29735745 PBO:0105505 Fig. 3 D
PMID:29742018 PBO:0106094 in vitro, casein substrate
PMID:29742018 PBO:0106099 Hhp1 accumulates at SPB when spindle checkpoint activated
PMID:29742018 PBO:0106092 normal with and without spindle checkpoint activation
PMID:29742018 PBO:0106091 in vitro, casein substrate
PMID:29742018 PBO:0106088 normal with and without spindle checkpoint activation
PMID:29742018 PBO:0106102 in vitro, casein substrate
PMID:29742018 PBO:0106102 in vitro, casein substrate
PMID:29742018 PBO:0106103 in vitro, casein substrate
PMID:29742018 PBO:0106102 in vitro, casein substrate
PMID:29742018 PBO:0106095 in vitro, casein substrate
PMID:29742018 PBO:0106096 in vitro, casein substrate
PMID:29769606 PBO:0112463 Intriguingly, we found that both Sgo2 centromeric localization during mitosis and Sgo1 centromeric localization during meiosis I were dramatically delocalized in the K119D and K119E mutants as well as the H2A-S121A mutant (Fig. 3C–E).
PMID:29769606 PBO:0112464 Te recombinant proteins of fssion yeast H2A (SpHta1) were also purifed. An in vitro kinase assay using these recombinant proteins showed that the H2A-K119D and the H2A-K119E mutants, as well as the H2A-S121A mutant, were not signifcantly phosphorylated by Bub1, whereas H2A-K119R mutant proteins were phosphorylated by Bub1 (Fig. 4B).
PMID:29769606 PBO:0112463 Intriguingly, we found that both Sgo2 centromeric localization during mitosis and Sgo1 centromeric localization during meiosis I were dramatically delocalized in the K119D and K119E mutants as well as the H2A-S121A mutant (Fig. 3C–E).
PMID:29769606 FYPO:0000091 We found that malonyl-mimetic K119D and K119E mutants showed sensitivity to a microtubule depolymerizing agent (TBZ) in the same way the H2A-S121A mutant had (Fig. S3B),
PMID:29769606 FYPO:0003182 Consistently, sister chromatid non-disjunction at meiosis II was signifcantly increased in the K119D and K119E mutants as well as the H2A-S121A mutant (Fig. S3D).
PMID:29769606 FYPO:0000091 We found that malonyl-mimetic K119D and K119E mutants showed sensitivity to a microtubule depolymerizing agent (TBZ) in the same way the H2A-S121A mutant had (Fig. S3B),
PMID:29769606 FYPO:0000091 We found that malonyl-mimetic K119D and K119E mutants showed sensitivity to a microtubule depolymerizing agent (TBZ) in the same way the H2A-S121A mutant had (Fig. S3B),
PMID:29769606 FYPO:0000091 We found that malonyl-mimetic K119D and K119E mutants showed sensitivity to a microtubule depolymerizing agent (TBZ) in the same way the H2A-S121A mutant had (Fig. S3B),
PMID:29769606 PBO:0112465 Te recombinant proteins of fssion yeast H2A (SpHta1) were also purifed. An in vitro kinase assay using these recombinant proteins showed that the H2A-K119D and the H2A-K119E mutants, as well as the H2A-S121A mutant, were not signifcantly phosphorylated by Bub1, whereas H2A-K119R mutant proteins were phosphorylated by Bub1 (Fig. 4B).
PMID:29769606 PBO:0096739 Intriguingly, we found that both Sgo2 centromeric localization during mitosis and Sgo1 centromeric localization during meiosis I were dramatically delocalized in the K119D and K119E mutants as well as the H2A-S121A mutant (Fig. 3C–E).
PMID:29769606 PBO:0112463 Intriguingly, we found that both Sgo2 centromeric localization during mitosis and Sgo1 centromeric localization during meiosis I were dramatically delocalized in the K119D and K119E mutants as well as the H2A-S121A mutant (Fig. 3C–E).
PMID:29769606 PBO:0112463 Intriguingly, we found that both Sgo2 centromeric localization during mitosis and Sgo1 centromeric localization during meiosis I were dramatically delocalized in the K119D and K119E mutants as well as the H2A-S121A mutant (Fig. 3C–E).
PMID:29769606 PBO:0112465 Te recombinant proteins of fssion yeast H2A (SpHta1) were also purifed. An in vitro kinase assay using these recombinant proteins showed that the H2A-K119D and the H2A-K119E mutants, as well as the H2A-S121A mutant, were not signifcantly phosphorylated by Bub1, whereas H2A-K119R mutant proteins were phosphorylated by Bub1 (Fig. 4B).
PMID:29769606 FYPO:0003182 Consistently, sister chromatid non-disjunction at meiosis II was signifcantly increased in the K119D and K119E mutants as well as the H2A-S121A mutant (Fig. S3D).
PMID:29769606 FYPO:0003182 Consistently, sister chromatid non-disjunction at meiosis II was signifcantly increased in the K119D and K119E mutants
PMID:29769606 FYPO:0003182 Consistently, sister chromatid non-disjunction at meiosis II was signifcantly increased in the K119D and K119E mutants
PMID:29769606 PBO:0112466 An acetyl-mimetic H2A-K119Q mutation slightly inhibited Bub1-mediated H2A phosphorylation (Fig. 4B)
PMID:29769606 PBO:0112466 An acetyl-mimetic H2A-K119Q mutation slightly inhibited Bub1-mediated H2A phosphorylation (Fig. 4B)
PMID:29769606 PBO:0112465 Te recombinant proteins of fssion yeast H2A (SpHta1) were also purifed. An in vitro kinase assay using these recombinant proteins showed that the H2A-K119D and the H2A-K119E mutants, as well as the H2A-S121A mutant, were not signifcantly phosphorylated by Bub1, whereas H2A-K119R mutant proteins were phosphorylated by Bub1 (Fig. 4B).
PMID:29769606 PBO:0112465 Te recombinant proteins of fssion yeast H2A (SpHta1) were also purifed. An in vitro kinase assay using these recombinant proteins showed that the H2A-K119D and the H2A-K119E mutants, as well as the H2A-S121A mutant, were not signifcantly phosphorylated by Bub1, whereas H2A-K119R mutant proteins were phosphorylated by Bub1 (Fig. 4B).
PMID:29769606 FYPO:0003182 Consistently, sister chromatid non-disjunction at meiosis II was signifcantly increased in the K119D and K119E mutants
PMID:29769606 FYPO:0005633 Consistently, sister chromatid non-disjunction at meiosis II was signifcantly increased in the K119D and K119E mutants
PMID:29769606 PBO:0096739 Intriguingly, we found that both Sgo2 centromeric localization during mitosis and Sgo1 centromeric localization during meiosis I were dramatically delocalized in the K119D and K119E mutants as well as the H2A-S121A mutant (Fig. 3C–E).
PMID:29769606 PBO:0096739 Intriguingly, we found that both Sgo2 centromeric localization during mitosis and Sgo1 centromeric localization during meiosis I were dramatically delocalized in the K119D and K119E mutants as well as the H2A-S121A mutant (Fig. 3C–E).
PMID:29769606 PBO:0112463 Intriguingly, we found that both Sgo2 centromeric localization during mitosis and Sgo1 centromeric localization during meiosis I were dramatically delocalized in the K119D and K119E mutants as well as the H2A-S121A mutant (Fig. 3C–E).
PMID:29769606 PBO:0112463 Intriguingly, we found that both Sgo2 centromeric localization during mitosis and Sgo1 centromeric localization during meiosis I were dramatically delocalized in the K119D and K119E mutants as well as the H2A-S121A mutant (Fig. 3C–E).
PMID:29769606 PBO:0096739 Intriguingly, we found that both Sgo2 centromeric localization during mitosis and Sgo1 centromeric localization during meiosis I were dramatically delocalized in the K119D and K119E mutants as well as the H2A-S121A mutant (Fig. 3C–E).
PMID:29769606 PBO:0096739 Intriguingly, we found that both Sgo2 centromeric localization during mitosis and Sgo1 centromeric localization during meiosis I were dramatically delocalized in the K119D and K119E mutants as well as the H2A-S121A mutant (Fig. 3C–E).
PMID:29769606 PBO:0096739 Intriguingly, we found that both Sgo2 centromeric localization during mitosis and Sgo1 centromeric localization during meiosis I were dramatically delocalized in the K119D and K119E mutants as well as the H2A-S121A mutant (Fig. 3C–E).
PMID:29769606 PBO:0112465 Te recombinant proteins of fssion yeast H2A (SpHta1) were also purifed. An in vitro kinase assay using these recombinant proteins showed that the H2A-K119D and the H2A-K119E mutants, as well as the H2A-S121A mutant, were not signifcantly phosphorylated by Bub1, whereas H2A-K119R mutant proteins were phosphorylated by Bub1 (Fig. 4B).
PMID:29769606 PBO:0112465 Te recombinant proteins of fssion yeast H2A (SpHta1) were also purifed. An in vitro kinase assay using these recombinant proteins showed that the H2A-K119D and the H2A-K119E mutants, as well as the H2A-S121A mutant, were not signifcantly phosphorylated by Bub1, whereas H2A-K119R mutant proteins were phosphorylated by Bub1 (Fig. 4B).
PMID:29774234 FYPO:0000122 loss of telomeric and subtelomeric sequences at high temperature
PMID:29774234 PBO:0093557 same as stn1-226 alone
PMID:29774234 FYPO:0000266 Sensitive to HU, CPT and MMS
PMID:29774234 PBO:0093557 slightly better growth than stn1-226 alone
PMID:29774234 PBO:0097405 Exacerbated at high temperature
PMID:29804820 PBO:0108720 However, the interaction is significantly diminished when either L32 (Mis16D1–32), or both L32 (Mis16D1–32) and L32/W33 (Mis16D1–33), are deleted (Figures 6A and 6B). In contrast, the Mis16-H4a1 interaction was only mildly affected in the context of the Mis16D1–33 truncation. These findings strongly suggest that Mis16 L32 and W33 participate in specific interactions with Eic1 but not histone H4. To verify these observations in vivo, we performed
PMID:29804820 PBO:0108723 However, the interaction is significantly diminished when either L32 (Mis16D1–32), or both L32 (Mis16D1–32) and L32/W33 (Mis16D1–33), are deleted (Figures 6A and 6B). In contrast, the Mis16-H4a1 interaction was only mildly affected in the context of the Mis16D1–33 truncation. These findings strongly suggest that Mis16 L32 and W33 participate in specific interactions with Eic1 but not histone H4. To verify these observations in vivo, we performed
PMID:29804820 PBO:0108722 However, the interaction is significantly diminished when either L32 (Mis16D1–32), or both L32 (Mis16D1–32) and L32/W33 (Mis16D1–33), are deleted (Figures 6A and 6B). In contrast, the Mis16-H4a1 interaction was only mildly affected in the context of the Mis16D1–33 truncation. These findings strongly suggest that Mis16 L32 and W33 participate in specific interactions with Eic1 but not histone H4. To verify these observations in vivo, we performed
PMID:29804820 PBO:0108721 However, the interaction is significantly diminished when either L32 (Mis16D1–32), or both L32 (Mis16D1–32) and L32/W33 (Mis16D1–33), are deleted (Figures 6A and 6B). In contrast, the Mis16-H4a1 interaction was only mildly affected in the context of the Mis16D1–33 truncation. These findings strongly suggest that Mis16 L32 and W33 participate in specific interactions with Eic1 but not histone H4. To verify these observations in vivo, we performed
PMID:29804820 PBO:0108720 However, the interaction is significantly diminished when either L32 (Mis16D1–32), or both L32 (Mis16D1–32) and L32/W33 (Mis16D1–33), are deleted (Figures 6A and 6B). In contrast, the Mis16-H4a1 interaction was only mildly affected in the context of the Mis16D1–33 truncation. These findings strongly suggest that Mis16 L32 and W33 participate in specific interactions with Eic1 but not histone H4. To verify these observations in vivo, we performed
PMID:29804820 PBO:0108719 (Figures 6A and 6B).
PMID:29804820 FYPO:0001355 FIgure 4D
PMID:29804820 GO:0098654 The Stoichiometry of the S. pombe Mis18 Holo-Complex Is (Mis16)2:(Eic1)2:(Mis18)4 T
PMID:29804820 GO:0098654 The Stoichiometry of the S. pombe Mis18 Holo-Complex Is (Mis16)2:(Eic1)2:(Mis18)4 T
PMID:29804820 GO:0098654 The Stoichiometry of the S. pombe Mis18 Holo-Complex Is (Mis16)2:(Eic1)2:(Mis18)4 T
PMID:29804820 GO:0005515 A Homodimer of the Mis18 C-Terminal Domain Interacts with a Mis16-Eic1 Heterodimer
PMID:29813053 FYPO:0006831 Fig S3D. The timing of septation onset depends on the AR function. The start of septation is delayed when the function of the AR unconventional type II myosin Myp2 is compromised.
PMID:29813053 FYPO:0006833 Fig 5E. Timely activation of septum synthesis does not depend on SIN asymmetry. Defective SIN-Inhibitory Phosphatase (SIP) complex csc2Δ cells were examined. The data of cells of C, D and E are developed in S2 Table.
PMID:29813053 FYPO:0006831 Fig 6. The levels of Etd1 and Rho1 regulate the timing of septation start. (A) The timing of septum deposition onset correlates with the start of increase of Etd1 in the cell middle. Cells were grown inMMwithout thiamine (GFP-etd1+ induced) at 25ÊC for 24 h and imaged as in Fig 1. (B) The increase of Etd1 in the cell middle and concomitant initiation of septation are delayed in long cells. Cells were analyzed as in A after 3.5 h of cell cycle arrest at 36ÊC. Graphs to the right show the total fluorescence of GFP-Etd1 at the cell poles and middle in the series to the left. A.U., arbitrary units. Arrow, cortical localization of Etd1 in the cell middle. Dashed outlines indicate the ROIs used to measure the total fluorescence of GFP-Etd1 in the corresponding regions of the cell. (C) The timing of septation onset is dependent on the level of etd1+. Cells expressing endogenous etd1+ and 41X-GFP-etd1+ grown at 32ÊC for 24 h either in the absence (ON, high etd1+ level; n = 4, 34 cells) or in the presence of thiamine (OFF, wild-type etd1+ level; n = 2, 11 cells), and cells expressing etd1Δ 81X-etd1+ grown for 15 h with thiamine (OFF, very low etd1+ level; n = 3, 23 cells), just before the emergence of SIN phenotype were analyzed as in A.
PMID:29813053 FYPO:0006832 Fig 6. The levels of Etd1 and Rho1 regulate the timing of septation start. (A) The timing of septum deposition onset correlates with the start of increase of Etd1 in the cell middle. Cells were grown inMMwithout thiamine (GFP-etd1+ induced) at 25ÊC for 24 h and imaged as in Fig 1. (B) The increase of Etd1 in the cell middle and concomitant initiation of septation are delayed in long cells. Cells were analyzed as in A after 3.5 h of cell cycle arrest at 36ÊC. Graphs to the right show the total fluorescence of GFP-Etd1 at the cell poles and middle in the series to the left. A.U., arbitrary units. Arrow, cortical localization of Etd1 in the cell middle. Dashed outlines indicate the ROIs used to measure the total fluorescence of GFP-Etd1 in the corresponding regions of the cell. (C) The timing of septation onset is dependent on the level of etd1+. Cells expressing endogenous etd1+ and 41X-GFP-etd1+ grown at 32ÊC for 24 h either in the absence (ON, high etd1+ level; n = 4, 34 cells) or in the presence of thiamine (OFF, wild-type etd1+ level; n = 2, 11 cells), and cells expressing etd1Δ 81X-etd1+ grown for 15 h with thiamine (OFF, very low etd1+ level; n = 3, 23 cells), just before the emergence of SIN phenotype were analyzed as in A.
PMID:29813053 FYPO:0006832 Fig 6. The levels of Etd1 and Rho1 regulate the timing of septation start. (F) The start of septum deposition is dependent on the level of rho1+. Cells expressing endogenous rho1+ and 3Xrho1+ grown at 32ÊC for 16 h either without (ON, high rho1+ level; n = 2, 14 cells) or with thiamine (OFF, wild-type rho1+ level; n = 2, 16 cells) were analyzed.
PMID:29813053 FYPO:0006832 Fig 7. The spindle and the proximity of the nucleus to the division site are required for proper septum synthesis activation in fission yeast. (A) Scheme of the steps required to prevent nuclear separation and to maintain or separate the undivided nucleus from the cell middle and/or from the division site. (A-1 and C) Nucleus and division site are maintained in the cell middle; cells were treated for 90 min and imaged with methyl 2-benzimidazolecarbamate (or carbendazim, MBC, 50 μg ml-1) to avoid spindle assembly and nuclear separation. (A-2 and D) Nucleus and division site are relocated to a cell end; cells were treated for 45 min, centrifuged to displace the nucleus, treated 45 more min and visualized with MBC. (A-3 and E) The nucleus is relocated and separated from the division plane; cells were treated for 90 min, centrifuged and examined with MBC. (B) mad2Δ cells were grown and imaged without MBC as in Fig 1. The mad2Δ cells were used to avoid a delay caused by the activation of the spindle assembly checkpoint. (C-E) The premature and uncoupled septation start caused by the absence of the spindle depends on the position of the nucleus. mad2Δ cells were processed as in A to prevent nuclear separation and to maintain or separate the undivided nucleus from the cell middle and/or the division site. (C) The nucleus and division site are maintained in the cell middle. (F) The nucleus and division site are relocated to a cell end. (E) The nucleus is relocated and separated from the division plane. MBC-treated cells were imaged as in B. Anaphase A onset was considered as time zero. Graphs to the right are as in Fig 4. Dashed lines and arrowheads: green, anaphase A onset; dark blue, septum synthesis start; light blue, septum ingression onset. White arrowhead: first CW-stained septum synthesis detection. White arrow: first CW-staining increase showing septum ingression. A.U., arbitrary units. (F) Uncoupled septum synthesis and ingression timing with MBC is restored to wild-type levels when the undivided nucleus is separated from the division site. Table showing the time between anaphase A (green) and septum synthesis start (dark blue) or septum ingression onset (light blue) in the indicated cells. Parenthesis: n, number of experiments and cells; T, delay in septum synthesis and ingression start with respect to control cells with MBC as in C.
PMID:29813053 FYPO:0000639 Fig 7. The spindle and the proximity of the nucleus to the division site are required for proper septum synthesis activation in fission yeast. (A) Scheme of the steps required to prevent nuclear separation and to maintain or separate the undivided nucleus from the cell middle and/or from the division site. (A-1 and C) Nucleus and division site are maintained in the cell middle; cells were treated for 90 min and imaged with methyl 2-benzimidazolecarbamate (or carbendazim, MBC, 50 μg ml-1) to avoid spindle assembly and nuclear separation. (A-2 and D) Nucleus and division site are relocated to a cell end; cells were treated for 45 min, centrifuged to displace the nucleus, treated 45 more min and visualized with MBC. (A-3 and E) The nucleus is relocated and separated from the division plane; cells were treated for 90 min, centrifuged and examined with MBC. (B) mad2Δ cells were grown and imaged without MBC as in Fig 1. The mad2Δ cells were used to avoid a delay caused by the activation of the spindle assembly checkpoint. (C-E) The premature and uncoupled septation start caused by the absence of the spindle depends on the position of the nucleus. mad2Δ cells were processed as in A to prevent nuclear separation and to maintain or separate the undivided nucleus from the cell middle and/or the division site. (C) The nucleus and division site are maintained in the cell middle. (F) The nucleus and division site are relocated to a cell end. (E) The nucleus is relocated and separated from the division plane. MBC-treated cells were imaged as in B. Anaphase A onset was considered as time zero. Graphs to the right are as in Fig 4. Dashed lines and arrowheads: green, anaphase A onset; dark blue, septum synthesis start; light blue, septum ingression onset. White arrowhead: first CW-stained septum synthesis detection. White arrow: first CW-staining increase showing septum ingression. A.U., arbitrary units. (F) Uncoupled septum synthesis and ingression timing with MBC is restored to wild-type levels when the undivided nucleus is separated from the division site. Table showing the time between anaphase A (green) and septum synthesis start (dark blue) or septum ingression onset (light blue) in the indicated cells. Parenthesis: n, number of experiments and cells; T, delay in septum synthesis and ingression start with respect to control cells with MBC as in C.
PMID:29813053 FYPO:0006831 Fig 2. The start of septation scales with anaphase B progression and cell size in fission yeast. and correlates linearly with the cell length.
PMID:29813053 GO:1905758 Fig 56E; also inferred from localization timing
PMID:29813053 FYPO:0006831 Fig 5B. Septation start is delayed when the function of Sid2 is compromised. Cells were grown in YES at 25C, shifted to 28C for 4 h and imaged as in Fig 1. The data are developed in Table 1 and Table 3.
PMID:29813053 FYPO:0006831 Fig S3E. The timing of septation onset depends on the AR function. The start of septation is delayed when the function of the AR F-BAR protein Cdc15 is compromised.
PMID:29813053 FYPO:0006831 Fig 2. The start of septation scales with anaphase B progression and cell size in fission yeast and correlates linearly with the cell length.
PMID:29813053 FYPO:0006832 Fig 2. The start of septation scales with anaphase B progression and cell size in fission yeast and correlates linearly with the cell length.
PMID:29813053 FYPO:0006832 Fig 2. The start of septation scales with anaphase B progression and correlates linearly with the cell length.
PMID:29813053 FYPO:0006832 Fig 4E and F. Inactivation of Cdc2 kinase in early mitosis induces a very premature septation onset. ATP-analogue sensitive cdc2-asM17 mutant cells carrying Cdc13-GFP were G2-arrested by growth in the presence of 1 μM1-NP-PP1 for 3.5 h at 32C. Then, the cells were G2-released by transfer to a fresh medium and imaged to detect the entry into mitosis. Cdc2 was inactivated during early mitosis transferring the cells to a fresh medium containing either DMSO or 10 μM1-NP-PP1.
PMID:29813053 FYPO:0003201 Fig 3
PMID:29813053 FYPO:0006834 Fig 3
PMID:29813053 FYPO:0006831 S5 Fig. The establishment of SIN asymmetry and the timely activation of septum synthesis do not depend on each other. (A, B) Early log-phase wild-type and thermosensitive cps1-191 (Bgs1) mutant cells were grown in YES at 25ÊC, shifted to 28ÊC for 1 h (A) or 32ÊC for 30 min (B) to produce a gradual delay in the onset of septum synthesis of cps1-191 mutant, and imaged as in Fig 5C. Anaphase B onset is considered as time zero (T = 0). White arrow: first CWstained detection of septum synthesis. Arrowheads: green, anaphase B onset; blue, septum deposition start (time immediately before septum detection with CW); red, complete asymmetry of SIN Cdc7, being Cdc7-GFP completely lost from one SPB. The data of this figure are developed in S2 Table. (C) The timing of septation onset is not related to the asymmetry of SIN. Early log-phase wild-type cells were grown in YES at 25ÊC, 28ÊC or 32ÊC, imaged as in Fig 5C and the timings of SIN asymmetry and of septation onset were determined with respect to the anaphase B onset (see also the data in S2 Table).
PMID:29813053 GO:1905757 Fig 4D & E
PMID:29813053 GO:1905758 Fig 5B, Table 1; also inferred from localization timing
PMID:29813053 GO:1905758 Fig 56A-D; also inferred from localization timing
PMID:29844133 FYPO:0001407 beware using old strains, phenotypic changes observed.
PMID:29844133 PBO:0094265 Beware using aged colonies, cell size recovery observed.
PMID:29851556 GO:0035861 in the presence or absence of Nbs1
PMID:29851556 PBO:0100532 localization of mutated protein assayed
PMID:29866182 PBO:0098376 Tas3-Myc
PMID:29866182 PBO:0098375 FLAG-Ago1, Arb1-Myc
PMID:29866182 PBO:0098375 FLAG-Ago1, Arb1-Myc
PMID:29866182 PBO:0098371 FLAG-Ago1
PMID:29866182 PBO:0098372 Myc-Ago1
PMID:29866182 PBO:0098372 Myc-Ago1
PMID:29866182 PBO:0098371 FLAG-Ago1
PMID:29898918 PBO:0111499 present in cycling cells and meiosis I cells. Required for cellular resistance to MMS and CPT.
PMID:29898918 MOD:00085 Required for cellular resistance to MMS and CPT.
PMID:29898918 PBO:0093617 Epistatic genetic interaction (same as mus81delta alone)
PMID:29898918 PBO:0093617 Epistatic genetic interaction (same as eme1delta alone)
PMID:29898918 FYPO:0000085 Epistatic genetic interaction (same as mus81delta alone)
PMID:29898918 PBO:0093559 Epistatic genetic interaction (same as mus81delta alone)
PMID:29898918 PBO:0093559 Epistatic genetic interaction (same as eme1delta alone)
PMID:29898918 PBO:0093617 slightly worse than srs2delta alone
PMID:29898918 FYPO:0000085 Epistatic genetic interaction (same as mus81delta alone)
PMID:29898918 PBO:0093617 slightly worse than srs2delta alone
PMID:29898918 PBO:0111500 present in cycling cells and meiosis I cells. Required for cellular resistance to MMS and CPT.
PMID:29899453 PBO:0093559 Fig 3e
PMID:29899453 PBO:0099591 fig 1c
PMID:29899453 PBO:0107369 Extended Data Fig 10
PMID:29899453 PBO:0107369 Extended Data Fig 10
PMID:29899453 PBO:0107369 Extended Data Fig 10
PMID:29899453 PBO:0107358 Fig 5c.
PMID:29899453 PBO:0107368 fig 1d
PMID:29899453 PBO:0107368 fig 1d
PMID:29899453 PBO:0107367 fig 1d
PMID:29899453 FYPO:0002061 figure 3 e
PMID:29899453 FYPO:0006614 figure 3 e Also increased termination index Fig. 4e
PMID:29899453 FYPO:0006613 Extended Data Fig 3a ig. 2c, Extended Data Fig. 3b–d)
PMID:29899453 GO:1904595 Extended data figure 9
PMID:29899453 PBO:0107366 extended data figure 9 decreased RNA pol2 localization to chromatin (occurs at termination sites)
PMID:29899453 FYPO:0005260 FIgure 3d. Extended fig 8d (vw: some suppression?)
PMID:29899453 PBO:0107365 fig 6a.b
PMID:29899453 PBO:0107365 fig 6a.b
PMID:29899453 PBO:0107363 Fig. 2e, Extended Data Fig. 4c
PMID:29899453 PBO:0107363 Fig. 2e, Extended Data Fig. 4b
PMID:29899453 PBO:0107362 Extended Data Fig 3a ig. 2c, Extended Data Fig. 3b–d)
PMID:29899453 PBO:0107361 Extended Data Fig 2f
PMID:29899453 PBO:0107361 Extended Data Fig 2f
PMID:29899453 PBO:0107361 Fig. 2d,
PMID:29899453 PBO:0094008 Fig S2, Extended Data Fig. 2d
PMID:29899453 PBO:0099622 Fig S2, Extended Data Fig. 2c
PMID:29899453 PBO:0107360 check this addition Fig. 2a, Extended Data Fig. 2a
PMID:29899453 PBO:0107359 Fig. 1d, Extended Data Fig. 1d)
PMID:29899453 PBO:0107359 Fig. 1d, Extended Data Fig. 1d)
PMID:29899453 PBO:0099591 fig 1c
PMID:29899453 PBO:0107350 Fig 1c, Extended Data Fig 2a
PMID:29899453 PBO:0107349 fig 1b
PMID:29899453 PBO:0092258 Fig 1B vw: corrected back to dis2 not cdk9!
PMID:29899453 PBO:0107350 fig 1b
PMID:29899453 FYPO:0000080 Fig 3e
PMID:29899453 PBO:0107351 vw: I changed the allele to the multi gene genotype to reflect the comment. Extended Data Fig 2c Fcp1 inactivation stabilizes Rpb1 Ser2 phosphorylation after Lsk1 inhibition. Fission-yeast strains, lsk1as or lsk1as fcp1-452, were grown at 30 °C and shifted to 37 °C (or not shifted), treated for the indicated time with 20 μM 3-MB-PP1, and analysed by immunoblotting for Pol II Ser2 phosphorylation
PMID:29899453 PBO:0107352 Extended Data Fig 2f .(cdk9as, cdk9as ssu72C13S, ssu72C13S)
PMID:29899453 PBO:0107353 Extended Data Fig 5d .
PMID:29899453 PBO:0107353 Extended Data Fig 6a,b ChIP–qPCR analysis at the rps17a+ gene. Comparison of pSpt5:Spt5 ratio in the indicated strains upstream and downstream of the CPS at 30 °C (left) and comparison of the ratio between dis2+ and dis2-11 cells at 18 °C (right). Extended Data Fig 6a,b
PMID:29899453 PBO:0107354 Extended Data Fig 6e Cdk9 does not restrict chromatin recruitment of Sds21.
PMID:29899453 PBO:0107355 Extended Data Fig 4a Cdk9 inhibition increased chromatin recruitment of Dis2
PMID:29899453 PBO:0107355 Extended Data Fig 4d Added Dis2 extension
PMID:29899453 PBO:0107355 Extended Data Fig 4d (vw: fixed allele)
PMID:29899453 PBO:0107356 Extended Data Fig 5a vw: fixed allele and target
PMID:29899453 PBO:0107357 Extended Data Fig 5a vw: fixed allele and target
PMID:29899453 PBO:0107358 Extended Data Fig 5a vw: based on EXP and comment changed allele from psf2 to cdk9 (P.P. Core CPF recruitment to chromatin is unaffected by Cdk9 inhibition). pfs2 pla1 cft1
PMID:29899453 PBO:0099591 Fig 1b
PMID:29914874 FYPO:0004750 Supplementary Figure S3
PMID:29914874 FYPO:0001234 Supplementary Fig. S3
PMID:29914874 FYPO:0001234 Supplementary Fig. S3
PMID:29914874 FYPO:0000017 Supplementary Fig. S3
PMID:29914874 FYPO:0001234 Supplementary Fig. S3
PMID:29914874 FYPO:0000005 Supplementary Fig. S3
PMID:29914874 FYPO:0001234 Supplementary Table S3
PMID:29914874 FYPO:0001234 Supplementary Fig. S3
PMID:29930085 PBO:0018345 Figure 1
PMID:29930085 GO:0005938 Figure 1
PMID:29930085 GO:0110085 Figure 1
PMID:29930085 PBO:0103568 Figure 2
PMID:29930085 PBO:0103568 Figure 3, Figure 4, Figure S2, Movie 2, Movie 3, Movie 4
PMID:29930085 PBO:0103568 Figure 3, Movie 2
PMID:29930085 FYPO:0002104 Figure 4, Movie 4
PMID:29930085 FYPO:0002104 Figure 4, Figure S3, Movie 4
PMID:29930085 FYPO:0002104 Figure 4, Movie 4
PMID:29930085 PBO:0103568 Figure 6, Figure S6, Movie 7
PMID:29930085 PBO:0103568 Figure 7, Movie 9
PMID:29930085 FYPO:0002150 Figure S3
PMID:29930085 FYPO:0002150 Figure S3
PMID:29930085 PBO:0019153 Figure S6, Movie 8
PMID:29930085 GO:0005737 Figure 5, Figure S4, Movie 5
PMID:29930085 GO:0110085 Figure 5, Figure S4, Movie 5
PMID:29930085 GO:1902716 Figure 1
PMID:29930085 GO:0110085 Figure 1
PMID:29930085 PBO:0020227 Figure 1
PMID:29930085 GO:0110085 Figure 1
PMID:29930085 PBO:0018345 Figure 1
PMID:29930085 PBO:0103568 Figure S6, Movie 8
PMID:29930085 PBO:0019141 Figure 7, Figure S8
PMID:29930085 FYPO:0002104 Figure 7, Figure S8
PMID:29930085 FYPO:0006617 S1
PMID:29930085 FYPO:0005465 fig2 movie1
PMID:29930085 FYPO:0005465 fig 1 interphase arrest
PMID:29930085 PBO:0096676 fig 1 interphase arrest (requested during interphase)
PMID:29930085 PBO:0094706 fig 1 interphase arrest (requested during interphase)
PMID:29930085 PBO:0103569 fig 1 interphase arrest (requested during interphase)
PMID:29930085 PBO:0097442 fig 1 interphase arrest (requested during interphase)
PMID:29930085 PBO:0103570 fig 1 interphase arrest
PMID:29930085 PBO:0103571 fig 1 interphase arrest
PMID:29930085 FYPO:0005465 fig 2 interphase arrest
PMID:29930085 PBO:0103572 (PORTLI GROWTH) fig 2 interphase arrest https://github.com/pombase/fypo/issues/3339
PMID:29930085 PBO:0103573 fig 3
PMID:29930085 PBO:0103573 fig 3
PMID:29930085 PBO:0103572 PORTLI GROWTH (Figs 3B and 4B; Movie 2) https://github.com/pombase/fypo/issues/3339
PMID:29930085 PBO:0103572 PORTLI GROWTH (Figs 3B and 4B; Movie 2) https://github.com/pombase/fypo/issues/3339
PMID:29930085 FYPO:0003316 Figure 4,AB
PMID:29930085 PBO:0103574 Figure S3
PMID:29930085 FYPO:0002104 Figure 4, Movie 4
PMID:29930085 FYPO:0002060 Fig. 5B
PMID:29930085 FYPO:0005465 Fig. 5B
PMID:29930085 PBO:0103572 PORTLI GROWTH Fig S6 https://github.com/pombase/fypo/issues/3339
PMID:29930085 PBO:0103575 PORTLI GROWTH Fig S6 https://github.com/pombase/fypo/issues/3339
PMID:29930085 PBO:0103576 (PORTLI GROWTH) fig 6 c https://github.com/pombase/fypo/issues/3339
PMID:29930085 PBO:0103577 PORTLI Growth Figure 6, Figure S6, Movie 7 https://github.com/pombase/fypo/issues/3339
PMID:29930085 PBO:0103572 Portli Figure 7, Movie 9 https://github.com/pombase/fypo/issues/3339
PMID:29930085 PBO:0103578 figure 7D
PMID:29930085 PBO:0093708 figure 7d
PMID:29930085 FYPO:0006639 fig 7c
PMID:29975113 PBO:0096157 temporal localization pattern Figure S2B
PMID:29975113 PBO:0096153 (Vw, because mutants are related to WT, I changed this to 'normal'), Dma1-I194A-mNeonGreen displays transient loss from SPB during anaphase, just like wildtype Dma1.
PMID:29975113 PBO:0096158 Figure 2G
PMID:29975113 PBO:0096149 (DNS) Dma1-I194A constitutively localizes to SPB throughout the cell cycle. Dma1-I194A localizes more intensely at one of the two SPBs for most of mitosis
PMID:29975113 PBO:0096150 Figure 2B and C
PMID:29975113 FYPO:0001491 Figure S2D dma1-GFP sid4-GBP-mCherry cells are very sick, if not die. ppc89-DUB rescued the synthetic sick phenotype of dma1-GFP sid4-GBP-mCherry. The cells have reduced levels of multi-nucleate and kissing nuclei compared with dma1-GFP sid4-GBP-mCherry.
PMID:29975113 PBO:0023023 Figures 1B and S1A Dma1-mNeonGreen became enriched at SPBs prior to SPB separation. It appeared to transiently leave SPBs during anaphase B, returning before telophase and then leaving again after cell division. Dma1 SPB transient loss happens before the development of Cdc7 SPB localiztion asymmetry. Dma1 failed to return to SPBs in late anaphase in cdc7-24 cells at restrictive temperature. Dma1 could be detected on majority SPBs in cdc16-116 cells at restrictive temperature, suggesting high SIN activity promote Dma1 SPB re-accumulation at the end of anaphase.
PMID:29975113 PBO:0019716 Figure 1B and S1B Dma1-mNeonGreen forms a ring at cell division site during early mitosis. Then it leaves and returns to cell division site during mitosis. Dma1 transiently leaves cell division site before Sid2 appears at the cell division site.
PMID:29975113 GO:0031030 [ dma1 unubiquitinated, sid4 phosphorylated] When Dma1-GFP is permanently tethered to SPBs by Sid4-GBP-mCherry, cells displayed multi-nucleate and kissing nuclei indicative of SIN and cytokinesis failure.
PMID:29975113 GO:0071341 Figure 1B and S1B
PMID:29975113 PBO:0096158 Figure 2D
PMID:29975113 PBO:0096159 These data are consistent with auto-ubiquitination triggering Dma1 destruction.
PMID:29975113 PBO:0096156 Figure S2A
PMID:29975113 PBO:0096154 Figure 2D in vivo
PMID:29975113 FYPO:0002060 Figure S2D
PMID:29975113 PBO:0096151 Figure S2B
PMID:29975157 FYPO:0000123 Fig. S2A
PMID:29975157 FYPO:0002071 Fig. 2D; live cell imaging
PMID:29975157 FYPO:0005289 Fig. 3; live cell imaging
PMID:29975157 PBO:0098955 Fig. 4A; live cell imaging
PMID:29975157 PBO:0098956 Fig. 4B; live cell imaging
PMID:29975157 PBO:0098957 Fig. 4C; live cell imaging
PMID:29975157 PBO:0098958 Fig. 4D; live cell imaging
PMID:29975157 FYPO:0006624 Fig. 5B; Live cell imaging of PIP3 sensor
PMID:29975157 FYPO:0006623 Fig. 5B; Live cell imaging of PIP3 sensor
PMID:29975157 FYPO:0006623 Fig. 5B; Live cell imaging of PIP3 sensor
PMID:29975157 FYPO:0002253 Fig. 1B; DAPI and methyl blue staining
PMID:29975157 FYPO:0000339 Fig. 1B; DAPI and methyl blue staining
PMID:29975157 FYPO:0006624 Fig. 5B; Live cell imaging of PIP3 sensor
PMID:29975157 FYPO:0006623 Fig. 5B; Live cell imaging of PIP3 sensor
PMID:29975157 FYPO:0006625 Fig. 5C; Live cell imaging of PIP2 lipid sensor
PMID:29975157 FYPO:0006627 Fig. 5C; Live cell imaging of PIP2 lipid sensor
PMID:29975157 FYPO:0006625 Fig. 5C; Live cell imaging of PIP2 lipid sensor
PMID:29975157 FYPO:0006626 Fig. 5C; Live cell imaging of PIP2 lipid sensor
PMID:29975157 FYPO:0002253 Fig. S1F; DAPI and methyl blue staining
PMID:29975157 PBO:0098959 Fig. S1F; DAPI and methyl blue staining
PMID:29975157 PBO:0098954 Fig. 1B; DAPI and methyl blue staining
PMID:29975157 FYPO:0002253 Fig. 1B; DAPI and methyl blue staining
PMID:29975157 FYPO:0000339 Fig. 1B; DAPI and methyl blue staining
PMID:29975157 FYPO:0006628 Fig. 5A; Live cell imaging of PIP4 lipid sensor
PMID:29975157 FYPO:0001369 Fig. 2A-C; live cell imaging
PMID:29975157 FYPO:0002253 Fig. S1F; DAPI and methyl blue staining
PMID:29975157 FYPO:0006628 Fig. 5A; Live cell imaging of PIP4 lipid sensor
PMID:29975157 FYPO:0006628 Fig. 5A; Live cell imaging of PIP4 lipid sensor
PMID:29975157 FYPO:0006629 Fig. 5A; Live cell imaging of PIP4 lipid sensor
PMID:29975157 FYPO:0006628 Fig. 5A; Live cell imaging of PIP4 lipid sensor
PMID:29975157 FYPO:0000339 Fig. S2E
PMID:29975157 FYPO:0001369 Fig. 2A-C; live cell imaging
PMID:29975157 FYPO:0002253 Fig. 1B; DAPI and methyl blue staining
PMID:29975157 PBO:0098954 Fig. 1B; DAPI and methyl blue staining
PMID:29975157 FYPO:0000339 Fig. 1B; DAPI and methyl blue staining
PMID:29975157 FYPO:0002253 Fig. 1B; DAPI and methyl blue staining
PMID:29975157 FYPO:0002253 Fig. 1B; DAPI and methyl blue staining
PMID:29975157 FYPO:0002253 Fig. 1B; DAPI and methyl blue staining
PMID:29975157 FYPO:0002253 Fig. 1B; DAPI and methyl blue staining
PMID:29975157 FYPO:0002253 Fig. 1B; DAPI and methyl blue staining
PMID:29975157 FYPO:0002253 Fig. 1B; DAPI and methyl blue staining
PMID:29975157 FYPO:0002253 Fig. 1B; DAPI and methyl blue staining
PMID:29975157 FYPO:0002253 Fig. 1B
PMID:29975157 FYPO:0001369 Fig. S2C,D
PMID:29975157 FYPO:0000339 Fig. S2A-D
PMID:29975157 FYPO:0002253 Fig. S1F; DAPI and methyl blue staining
PMID:30003614 FYPO:0002236 fig 4
PMID:30003614 FYPO:0006632 fig 4 normal level of free fatty acid
PMID:30003614 FYPO:0002227 fig 4
PMID:30003614 FYPO:0004695 fig 4
PMID:30003614 FYPO:0000808 increased number of lipid droples/cell fig 3b/c
PMID:30003614 FYPO:0002061 fig 5 = cerulenin
PMID:30044717 PBO:0018421 fig1
PMID:30044717 PBO:0019669 Fig 2B
PMID:30044717 PBO:0107401 Fig2a (vw: average survival ~ 7 cell cycles)
PMID:30044717 FYPO:0004653 Fig 5
PMID:30044717 FYPO:0002061 fig 5B
PMID:30044717 FYPO:0001581 fig 5B
PMID:30044717 GO:0032153 Fig 7E
PMID:30044717 GO:0035838 Fig 7E
PMID:30044717 GO:0090689 Figure 6E
PMID:30044717 PBO:0107422 Fig. S6B
PMID:30044717 PBO:0108997 Fig5D and Movie 5
PMID:30044717 FYPO:0001494 fig 5b
PMID:30044717 FYPO:0002061 fig 5B
PMID:30044717 PBO:0107419 Fig S2,E
PMID:30044717 PBO:0107420 fig S4E
PMID:30044717 PBO:0108998 Figure 7
PMID:30044717 PBO:0105130 fig S4E
PMID:30044717 FYPO:0001355 fig 2b
PMID:30044717 FYPO:0002061 fig 2a
PMID:30044717 GO:0001786 Fig S3 DE
PMID:30044717 GO:0005546 Fig S3 DE
PMID:30044717 PBO:0107419 Fig S2,E
PMID:30044717 PBO:0107419 Fig S2C,E
PMID:30044717 PBO:0107418 fig S2
PMID:30044717 PBO:0107418 fig S2
PMID:30044717 PBO:0107417 Supp S1G
PMID:30044717 PBO:0107417 Supp S1F
PMID:30044717 PBO:0107416 Figure 1
PMID:30044717 PBO:0107413 fig 4
PMID:30044717 PBO:0107410 Fig 5C
PMID:30044717 PBO:0107408 fig 6A
PMID:30044717 PBO:0107407 Fig 5C
PMID:30044717 PBO:0019669 Fig S4C
PMID:30044717 PBO:0035615 Fig S4C
PMID:30044717 PBO:0107404 Fig S4C
PMID:30044717 PBO:0107403 Fig S4C
PMID:30044717 PBO:0018576 Figure 1
PMID:30053106 GO:0070336 requires long flap (binding affinity much higher with 27-nt than 15-nt flap)
PMID:30072377 PBO:0103668 Fig. 3B, Fig. 4A,B
PMID:30072377 PBO:0103668 Fig. 3C, D; Fig. 4A,B
PMID:30072377 FYPO:0006779 Fig. 4C. Resistant to 1mM spermidine at 37C.
PMID:30072377 PBO:0103668 Fig. 4A,B
PMID:30072377 FYPO:0006779 Fig. 4C Resistant to 1 mM spermidine at 37C.
PMID:30072439 PBO:0093561 Partial suppression of growth defect in the presence of sorbitol
PMID:30072439 PBO:0096875 Sorbitol addition partly suppresses beta-glucan accumulation in cwh43-G753R mutant cells
PMID:30072439 PBO:0093556 Suppression of temperature sensitivity by 1.2M sorbitol
PMID:30072439 PBO:0093556 Suppression of temperature sensitivity by 1.2M sorbitol
PMID:30072439 PBO:0093560 Synthetic growth defect between cwh43-G753R mutant and dga1Δ plh1Δ double deletion mutant.
PMID:30072439 PBO:0093556 Suppression of temperature sensitivity by 1.2M sorbitol
PMID:30072439 PBO:0093557 Partial suppression of growth defect in the presence of sorbitol
PMID:30072439 PBO:0093558 Synthetic growth defect between cwh43-G753R mutant and dga1Δ plh1Δ double deletion mutant.
PMID:30072439 FYPO:0006970 decreased cellular diphosphoglycerate level
PMID:30072439 FYPO:0006951 increased cellular dimethyl-histidine level during vegetative growth
PMID:30072439 PBO:0093556 Suppression of temperature sensitivity by 1.2M sorbitol
PMID:30072439 FYPO:0004165 Normal glucose consumption, but cell division is sensitive to low glucose condition
PMID:30072439 PBO:0096874 Lack of lipid droplet formation
PMID:30072439 PBO:0096874 Lack of lipid droplet formation
PMID:30072439 FYPO:0002327 Revealed by thin layer chromatography
PMID:30072439 FYPO:0002227 Revealed by lipidomic analysis using mass spectrometry, thin layer chromatography, and lipid droplet staining
PMID:30072439 FYPO:0003516 Drastic changes in antioxidants, sugar derivatives, amino acid derivatives, organic acids, coenzyme A (CoA), and nucleotide derivatives. Most of these compounds are biomarkers for nutritional starvation (low-glucose or nitrogen-starvation).
PMID:30072439 GO:1990578 However, in scs2Δ scs22Δ double deletion mutant cells, localization of both Cwh43–GFP and AHDL– mCherry at the plasma membrane disappeared, and, instead, accumulated in the cytoplasm
PMID:30076928 PBO:0106502 RT-PCR
PMID:30076928 PBO:0106504 transcription read through by PCR
PMID:30076928 FYPO:0000227 mini-chromosome loss assay
PMID:30076928 PBO:0106501 transcription read through by PCR
PMID:30076928 PBO:0106503 RT-PCR
PMID:30089114 MOD:01148 polyubiquitylated
PMID:30089114 GO:0034080 Heterochromatin structure protects native CENP-A from ubiquitin-mediated degradation.
PMID:30089908 PBO:0112056 Regulation of asymmetric gene expression from parental genomes
PMID:30089908 FYPO:0002052 Fig. 4a, Extended Data Fig. 4c, Supplementary Video 7b
PMID:30089908 FYPO:0001147 Fig. 4a, Extended Data Fig. 4c, Supplementary Video 7b
PMID:30089908 FYPO:0006014 never ending search for mating partner by P cell
PMID:30089908 FYPO:0006014 Fig. 2c never ending search for mating partner
PMID:30089908 GO:0032220 Homothalic pak2∆ partners exhibit fusion efficiency decrease of ~20% as compared to wildtype partner fusion. Homothalic pak2∆ cells undergo transient fusion with frequency of ~10%, which is absent in wildtype matings.
PMID:30089908 FYPO:0000413 fig 1 II
PMID:30089908 PBO:0112050 Regulation of asymmetric gene expression from parental genomes Factor that regulates differential gene expression of homologous parental gene copies
PMID:30089908 GO:0005737 M-cells
PMID:30089908 GO:0005634 P-cells (rapid) M-cells (delayed)
PMID:30089908 GO:0005634 Extended Data Fig. 3b, Supplementary Video 5a
PMID:30089908 GO:0140538 GO:0140538 +name: negative regulation of conjugation with zygote https://github.com/geneontology/go-ontology/issues/16329
PMID:30089908 GO:0140538 GO:0140538 +name: negative regulation of conjugation with zygote https://github.com/geneontology/go-ontology/issues/16329
PMID:30089908 FYPO:0006669 (Fig. 1a, type IIIa
PMID:30089908 PBO:0096712 Fig. 1a, type IIIb
PMID:30089908 FYPO:0006672 abolished karyogamy with transient cytogamy (this is a bit like twin haploid meiosis? should be siblings? also looks like karyogamy failure)
PMID:30089908 FYPO:0000678 abolished karyogamy with transient cytogamy (this is a bit like twin haploid meiosis? should be siblings? also looks like karyogamy failure)
PMID:30089908 FYPO:0006673 Figure 1c
PMID:30089908 PBO:0096713 Extended data figure 1 F dominant over shk2 downstream sporulation phenotypes
PMID:30089908 PBO:0096714 Fig. 1g
PMID:30089908 PBO:0096715 Fig. 1a, type IIIb
PMID:30089908 PBO:0096716 ******abolished, in M cells*******Fig. 2a, Supplementary Video 5, Fig. 2b, Supplementary Video 2a Importantly, mei3 was also asymmetrically expressed in WT...zygotes first express the meiotic inducer Mei3 from the P genome.
PMID:30089908 GO:0062071 go-ontology/issues/16327
PMID:30089908 PBO:0096718 Fig. 3d, Supplementary Video 5b
PMID:30089908 PBO:0096717 *******to nucleus of opposite mating type cell******
PMID:30089908 PBO:0112050 Regulation of asymmetric gene expression from parental genomes Factor that regulates differential gene expression of homologous parental gene copies
PMID:30089908 PBO:0112056 Regulation of asymmetric gene expression from parental genomes
PMID:30089908 PBO:0096720 Extended Data Fig. 5e, f, Supplementary Video 9; see also ref. 1
PMID:30089908 PBO:0096719 Extended Data Fig. 5e, f, Supplementary Video 9; see also ref. 1
PMID:30089908 FYPO:0001886 in M-cell
PMID:30089908 FYPO:0006014 Fig. 4a, Extended Data Fig. 4c, Supplementary Video 7b
PMID:30102332 GO:0006368 also inferred from orthology, interactions, and chromatin localization (ChIP)
PMID:30102332 FYPO:0000650 Figure 5.
PMID:30102332 FYPO:0000650 Figure 5.
PMID:30102332 GO:0006368 also inferred from orthology, interactions, and chromatin localization (ChIP)
PMID:30102332 GO:0006368 also inferred from orthology, interactions, and chromatin localization (ChIP)
PMID:30102332 FYPO:0004903 Figures 4 & 5.
PMID:30102332 FYPO:0004903 Figures 4 & 5.
PMID:30102332 FYPO:0000650 Figure 5.
PMID:30102332 FYPO:0004903 Figures 4 & 5.
PMID:30104346 PBO:0107547 evidence is combination of ChIP in this paper plus data in other publications showing that Ctp1 binds DNA directly
PMID:30104346 PBO:0107548 evidence is combination of ChIP in this paper plus data in other publications showing that Rad52 binds DNA directly
PMID:30104346 PBO:0107547 evidence is combination of ChIP in this paper plus data in other publications showing that Rad50 orthologs (and therefore almost certainly Sc Rad50) binds DNA directly
PMID:30110338 PBO:0111554 H3 K9me3 https://github.com/geneontology/go-ontology/issues/16331
PMID:30110338 PBO:0103520 H3 K9me3
PMID:30110338 PBO:0111555 H3 K9me3 https://github.com/geneontology/go-ontology/issues/16331
PMID:30110338 PBO:0111553 H3 K9me3 https://github.com/geneontology/go-ontology/issues/16331
PMID:30116786 PBO:0107395 Fig 4E
PMID:30116786 FYPO:0000238 Fig. 3F loss of mitotic competence
PMID:30116786 PBO:0107389 Fig 4E
PMID:30116786 PBO:0107388 Fig 4E
PMID:30116786 PBO:0107387 Fig 4E
PMID:30116786 PBO:0107386 Fig 4E
PMID:30116786 PBO:0107385 Fig 4E
PMID:30116786 FYPO:0006667 fig 3C
PMID:30116786 PBO:0107378 Fig 3
PMID:30116786 PBO:0107390 Fig 4E
PMID:30116786 PBO:0107391 Fig 4E
PMID:30116786 PBO:0107392 Fig 4E
PMID:30116786 PBO:0112759 Fig 4E
PMID:30116786 PBO:0107394 Fig 4E
PMID:30116786 PBO:0107383 Fig 4E
PMID:30116786 PBO:0107382 Fig 4E
PMID:30116786 PBO:0107381 Fig 4C
PMID:30116786 PBO:0107380 Fig 4E
PMID:30116786 FYPO:0006662 Fig S3
PMID:30116786 PBO:0107379 Fig 4A,E
PMID:30116786 FYPO:0002552 Fig 3
PMID:30116786 FYPO:0002552 Fig 3
PMID:30116786 PBO:0107378 Fig 3
PMID:30116786 PBO:0018802 fig 3B
PMID:30116786 PBO:0107377 fig 3B
PMID:30116786 FYPO:0006660 Fig. 3F loss of mitotic competence
PMID:30116786 PBO:0107384 Fig 4E
PMID:30134042 PBO:0094701 assayed at cdc18 and cdc22
PMID:30134042 PBO:0094700 assayed at cdc18 and cdc22
PMID:30134042 PBO:0094700 assayed at cdc18 and cdc22
PMID:30134042 PBO:0094697 assayed at cdc18 and cdc22
PMID:30134042 PBO:0094697 assayed at cdc18 and cdc22
PMID:30134042 PBO:0094697 assayed at cdc18 and cdc22
PMID:30134042 PBO:0094697 assayed at cdc18 and cdc22
PMID:30134042 PBO:0094697 assayed at cdc18 and cdc22
PMID:30134042 PBO:0094696 assayed at cdc18 and cdc22
PMID:30134042 PBO:0094697 assayed at cdc18 and cdc22
PMID:30134042 PBO:0094697 assayed at cdc18 and cdc22
PMID:30134042 PBO:0094696 assayed at cdc18 and cdc22
PMID:30201262 FYPO:0002061 SFig5
PMID:30201262 FYPO:0001904 Temperature was shifted at anaphase B.
PMID:30201262 FYPO:0000161 Temperature was shifted at prophase or metaphase.
PMID:30201262 FYPO:0007200 fig 1.
PMID:30201262 FYPO:0007201 fig6
PMID:30201262 PBO:0107957 fig6
PMID:30201262 PBO:0107958 fig6
PMID:30212894 PBO:0094771 correlation with gel shift assays
PMID:30212894 PBO:0101499 correlation with gel shift assays
PMID:30212894 PBO:0101499 correlation with gel shift assays
PMID:30212894 PBO:0094771 correlation with gel shift assays
PMID:30212894 PBO:0094771 correlation with gel shift assays
PMID:30212894 PBO:0094771 correlation with gel shift assays
PMID:30212894 PBO:0101499 correlation with gel shift assays
PMID:30212894 PBO:0094771 correlation with gel shift assays
PMID:30212894 PBO:0101499 correlation with gel shift assays
PMID:30212894 PBO:0094771 correlation with gel shift assays
PMID:30212894 PBO:0101499 correlation with gel shift assays
PMID:30212894 PBO:0098248 correlation with gel shift assays
PMID:30212894 PBO:0101499 correlation with gel shift assays
PMID:30212894 PBO:0094771 correlation with gel shift assays
PMID:30212894 PBO:0104165 correlation with gel shift assays
PMID:30212894 PBO:0094771 correlation with gel shift assays
PMID:30212894 PBO:0101499 correlation with gel shift assays
PMID:30212894 FYPO:0001045 correlation with gel shift assays
PMID:30212894 PBO:0101499 correlation with gel shift assays
PMID:30212894 FYPO:0001045 correlation with gel shift assays
PMID:30212894 FYPO:0006658 correlation with gel shift assays
PMID:30212894 PBO:0094771 correlation with gel shift assays
PMID:30212894 PBO:0104166 correlation with gel shift assays
PMID:30212894 PBO:0101499 correlation with gel shift assays
PMID:30217891 PBO:0103042 fig3
PMID:30217891 FYPO:0004602 S14
PMID:30217891 PBO:0103043 fig3
PMID:30279276 PBO:0100645 Cdc42-GTP assayed with CRIB; broad zones of activity
PMID:30280012 FYPO:0000082 Figure S5A, S5B,
PMID:30280012 PBO:0093577 Fig 6
PMID:30280012 PBO:0093576 Fig 6
PMID:30280012 PBO:0093576 Fig 6
PMID:30280012 PBO:0093577 Fig 6
PMID:30280012 PBO:0093577 Fig 6
PMID:30280012 PBO:0093577 Fig 6
PMID:30280012 FYPO:0002177 Fig S5C, S6
PMID:30282034 PBO:0100139 at transcription_termination_signal
PMID:30282034 PBO:0095888 at transcription_termination_signal
PMID:30282034 PBO:0100139 at transcription_termination_signal
PMID:30282034 PBO:0100141 at transcription_termination_signal
PMID:30332655 PBO:0107863 inferred from phenotypes and from direct assay using human calcineurin
PMID:30348841 PBO:0094940 mutations in brc1 weaken interaction with nse6
PMID:30348841 PBO:0094939 Nse4 sumoylation at wild type level
PMID:30348841 PBO:0094938 Nse4 sumoylation reduced in brc1Δ
PMID:30348841 PBO:0094937 Nse4 sumoylation undetectable in nse6Δ
PMID:30348841 PBO:0094936 deletion of Brc1 significantly reduced Nse4 residence at binding sites tested under normal and genotoxic stress
PMID:30348841 PBO:0094936 deletion of Nse5 strongly reduced Nse4 residence at binding sites tested under normal and genotoxic stress
PMID:30348841 PBO:0094944 As anticipated, the MMS-induced SUMOylation of Nse4-TAP in wild-type cells was detectable upon immunoprecipitation (IP) of Nse4 without overexpression or initial enrichment of SUMO (Fig. 4A)
PMID:30348841 PBO:0094942 Notably, however, deletion of either Nse5 or Nse6 strongly reduced Nse4 residence at all binding sites tested, which was most evident under conditions of genotoxic stress that stimu- late de novo Smc5-Smc6 loading
PMID:30348841 PBO:0094936 deletion of Nse6 strongly reduced Nse4 residence at binding sites tested under normal and genotoxic stress
PMID:30348841 PBO:0094933 Nse4 foci gone in nse6 mutant cells; Nts1 overexpression background to mitigate nse6Δ genotoxin sensitivity
PMID:30348841 PBO:0094935 physical interaction between brc1-T672A and Smc5
PMID:30348841 PBO:0094934 physical interaction between brc1-T672A and Nse6
PMID:30348841 PBO:0094933 fig 1 a: brc1 mutant abolishes Nse4 nuclear foci in HU/MMS treated cells
PMID:30348841 PBO:0094932 fig 1 brc1 mutant cells expressing brc1-T672A are deficient in Nse4 foci formation
PMID:30348841 PBO:0094933 Nse4 foci gone in nse6 mutant cells; Nts1 overexpression background to mitigate nse6Δ genotoxin sensitivity
PMID:30348841 PBO:0094945 MMS-induced Nse4 SUMOylation was also reduced in brc1 cells but was similar to wild-type in rhp18 cells, which support normal Nse4-GFP focus formation (Fig. 4B)
PMID:30348841 PBO:0094943 Notably, however, deletion of either Nse5 or Nse6 strongly reduced Nse4 residence at all binding sites tested, which was most evident under conditions of genotoxic stress that stimu- late de novo Smc5-Smc6 loading
PMID:30348841 PBO:0093580 nse2-SA brc1 cells are more sensitive to genotoxins than either single mutant (Fig. 4C).
PMID:30355493 PBO:0105005 2d
PMID:30355493 PBO:0105009 3c
PMID:30355493 PBO:0105007 2d
PMID:30355493 PBO:0105008 2d
PMID:30355493 PBO:0105002 2d
PMID:30355493 PBO:0105001 S3C
PMID:30355493 PBO:0105003 2d
PMID:30355493 PBO:0105002 2d
PMID:30355493 PBO:0105004 2d
PMID:30355493 PBO:0105003 2d
PMID:30355493 PBO:0105005 fig4
PMID:30355493 PBO:0105006 2d
PMID:30355770 FYPO:0001045 Fig. 2A
PMID:30355770 FYPO:0001045 Fig. 7D
PMID:30355770 FYPO:0001045 Fig. 7D
PMID:30355770 FYPO:0003267 Fig. 7D
PMID:30355770 FYPO:0003267 Fig. 7D
PMID:30355770 FYPO:0003267 Fig. 7D
PMID:30355770 FYPO:0003267 Fig. 7D
PMID:30355770 FYPO:0002060 Fig. S8
PMID:30355770 FYPO:0002061 Fig. S8
PMID:30355770 FYPO:0002061 Fig. S8
PMID:30355770 FYPO:0001045 Fig. 4B
PMID:30355770 PBO:0108849 Fig. 4B
PMID:30355770 PBO:0108849 Fig. 4B
PMID:30355770 FYPO:0002243 Fig. 4B
PMID:30355770 PBO:0108848 Fig. S5
PMID:30355770 FYPO:0002243 Fig. S5
PMID:30355770 FYPO:0001045 Fig. S5
PMID:30355770 PBO:0108847 Fig. S6
PMID:30355770 PBO:0108847 Fig. S6
PMID:30355770 PBO:0108847 Fig. S6
PMID:30355770 FYPO:0001045 Fig. 2A
PMID:30355770 FYPO:0001045 Fig. 2A
PMID:30355770 FYPO:0001045 Fig. 2A
PMID:30355770 FYPO:0001045 Fig. 2A
PMID:30355770 FYPO:0001045 Fig. 2A
PMID:30355770 FYPO:0001045 Fig. 2A
PMID:30355770 FYPO:0003267 Fig. 2A
PMID:30355770 FYPO:0003267 Fig. 2A
PMID:30355770 FYPO:0001045 Fig. 2A
PMID:30355770 FYPO:0001045 Fig. 2A
PMID:30355770 FYPO:0001045 Fig. 2A
PMID:30355770 PBO:0108846 Fig. 2B
PMID:30355770 PBO:0108845 Fig. 2B
PMID:30355770 PBO:0108844 Fig. 2B
PMID:30355770 PBO:0108843 Fig. 2B
PMID:30355770 PBO:0108843 Fig. 2B
PMID:30355770 FYPO:0001045 Fig. 2A
PMID:30355770 FYPO:0001045 Fig. 2A
PMID:30355770 FYPO:0001045 Fig. 2A
PMID:30355770 FYPO:0001045 Fig. 2A
PMID:30355770 FYPO:0001045 Fig. 2A
PMID:30355770 FYPO:0001045 Fig. 2A
PMID:30355770 FYPO:0002243 Fig. 2A
PMID:30389790 FYPO:0006980 fig 3b
PMID:30389790 GO:0004573 Glucosidase 1, a type II membrane protein with a luminal hydrolytic domain, removes the outermost glucose from protein-linked Glc3Man9GlcNAc2 in the endoplasmic reticulum
PMID:30389790 FYPO:0000672 figure 5c
PMID:30389790 FYPO:0001910 figure 5c hypoglycosylation
PMID:30389790 FYPO:0001211 fig 6
PMID:30389790 FYPO:0001211 fig 6
PMID:30389790 PBO:0095685 fig 5b
PMID:30389790 FYPO:0001124 figure 5c
PMID:30389790 FYPO:0001357 figure 5b and S2
PMID:30389790 FYPO:0000805 fig 10
PMID:30389790 FYPO:0001035 fig 10
PMID:30389790 PBO:0095685 fig 5b
PMID:30389790 FYPO:0006982 fig 10
PMID:30389790 FYPO:0006981 fig S4
PMID:30389790 FYPO:0007030 fig S4
PMID:30389790 FYPO:0001211 fig 6
PMID:30389790 PBO:0095634 fig 5b
PMID:30389790 PBO:0095685 fig 5b
PMID:30389790 PBO:0093561 fig 5b
PMID:30389790 PBO:0093561 fig 2b
PMID:30389790 PBO:0093560 fig 2b
PMID:30389790 FYPO:0002060 figure 5 and 11 (no loss of viability )
PMID:30393157 PBO:0094537 table2
PMID:30393157 PBO:0094547 Fig. 5A
PMID:30393157 FYPO:0005823 Fig. 2C/D
PMID:30393157 FYPO:0006661 fig 2E/F
PMID:30393157 FYPO:0006661 fig 2E/F
PMID:30393157 FYPO:0006661 fig 2E/F
PMID:30393157 FYPO:0006661 fig 2E/F
PMID:30393157 FYPO:0001673 figure 3D
PMID:30393157 FYPO:0005823 Fig. 2C/D
PMID:30393157 FYPO:0000375 figure 3D
PMID:30393157 FYPO:0003810 fig 4
PMID:30393157 FYPO:0004944 fig 4
PMID:30393157 FYPO:0003004 fig 4
PMID:30393157 PBO:0094523 table2
PMID:30393157 PBO:0094524 table2
PMID:30393157 PBO:0094525 table2
PMID:30393157 PBO:0094526 table2
PMID:30393157 PBO:0094527 table2
PMID:30393157 PBO:0094530 table2
PMID:30393157 PBO:0094529 table2
PMID:30393157 PBO:0094528 table2
PMID:30393157 PBO:0094546 Fig. 5A
PMID:30393157 PBO:0094545 Fig. 5A
PMID:30393157 PBO:0094544 Fig. 5A
PMID:30393157 PBO:0094543 Fig. 5A
PMID:30393157 PBO:0094542 Fig. 5A
PMID:30393157 PBO:0094541 Fig. 5A
PMID:30393157 PBO:0094540 table2
PMID:30393157 PBO:0094539 table2
PMID:30393157 PBO:0094538 table2
PMID:30393157 PBO:0094536 table2
PMID:30393157 PBO:0094535 table2
PMID:30393157 PBO:0094534 table2
PMID:30393157 PBO:0094533 table2
PMID:30393157 PBO:0094532 table2
PMID:30393157 PBO:0094531 table2
PMID:30393157 FYPO:0005823 fig 1A
PMID:30393157 PBO:0094522 fig 1C/D
PMID:30393157 FYPO:0002061 Fig. 2B
PMID:30393157 FYPO:0002061 Fig. 2B
PMID:30393157 FYPO:0002061 Fig. 2B
PMID:30393157 FYPO:0002061 Fig. 2B
PMID:30393157 FYPO:0005823 Fig. 2C/D
PMID:30393157 FYPO:0005823 Fig. 2C/D
PMID:30393157 FYPO:0005823 Fig. 2C/D
PMID:3040264 FYPO:0001683 fig 2 a no spindle rod like chromsomes
PMID:3040264 FYPO:0001683 2b
PMID:3040264 FYPO:0002071 fig 2 a
PMID:3040264 FYPO:0002018 fig 2 a no spindle rod like chromsomes
PMID:3040264 PBO:0037114 table1
PMID:3040264 PBO:0037113 fig 2 b (uncondensed chromosomes)
PMID:3040264 GO:0007076 fig 2 B
PMID:3040264 PBO:0037116 table1
PMID:3040264 FYPO:0003145 fig 2 b (uncondensed chromosomes)
PMID:3040264 PBO:0037115 table1
PMID:3040264 FYPO:0000620 fig 2 a no spindle rod like chromsomes
PMID:30427751 PBO:0108002 figure 5GH
PMID:30427751 PBO:0107999 Therefore, we concluded that Rsp1 is required to prevent excessive accumulation of Mto1
PMID:30427751 PBO:0108003 figure 5I
PMID:30427751 FYPO:0004511 figure6D
PMID:30427751 FYPO:0005686 figure6AC
PMID:30427751 PBO:0107996 figure 2 A with increased loc to spb
PMID:30427751 PBO:0108004 figure6AC
PMID:30427751 PBO:0107995 figure 2 B
PMID:30427751 PBO:0107994 figure 2 A with increased loc to spb
PMID:30427751 FYPO:0000234 figure 1 G/H (from preexisting microtubules)
PMID:30427751 FYPO:0005558 figure 1
PMID:30427751 PBO:0107997 figure 2 B
PMID:30427751 PBO:0107998 figure 2 B
PMID:30427751 PBO:0107999 Therefore, we concluded that Rsp1 is required to prevent excessive accumulation of Mto1
PMID:30427751 PBO:0108000 figure 5A
PMID:30427751 PBO:0108001 figure 5A
PMID:30427751 GO:0005515 fig 5A (recruitment)
PMID:30451685 FYPO:0004247 Figure 4C,D
PMID:30451685 FYPO:0003507 Figure 2D and Figure 2—figure supplement 2
PMID:30451685 FYPO:0006786 Figure 2D and Figure 2—figure supplement 2
PMID:30451685 FYPO:0006785 Figure 2—figure supplement 2
PMID:30451685 FYPO:0003507 Figure 2D and Figure 2—figure supplement 2
PMID:30451685 FYPO:0006786 Figure 2D and Figure 2—figure supplement 2
PMID:30451685 FYPO:0001245 Figure 4E
PMID:30451685 FYPO:0000116 Figure 4E
PMID:30451685 FYPO:0006784 Figures 4C and 4D; assayed_using cpy1
PMID:30451685 FYPO:0006785 Figure 2—figure supplement 2
PMID:30451685 FYPO:0003507 Figure 2D and Figure 2—figure supplement 2
PMID:30451685 FYPO:0004247 Figure 2—figure supplement 1D
PMID:30451685 FYPO:0006579 Figures 2C, 2D, and Figure 2—figure supplement 2
PMID:30451685 FYPO:0001245 Figures 2C, 2D, and Figure 2—figure supplement 2
PMID:30451685 FYPO:0000116 Figures 2C, 2D, and Figure 2—figure supplement 2
PMID:30451685 PBO:0108006 Figures 2A and 2B; assayed_using cpy1
PMID:30451685 FYPO:0006579 Figures 2C, 2D, and Figure 2—figure supplement 2
PMID:30451685 FYPO:0001245 Figures 2C, 2D, and Figure 2—figure supplement 2
PMID:30451685 FYPO:0000116 Figures 2C, 2D, and Figure 2—figure supplement 2
PMID:30451685 PBO:0108005 Figures 2A and 2B; assayed_using cpy1
PMID:30451685 GO:0000329 Figure 1 (direct assay for vacuolar membrane) and Figure 1-figure supplement 1 (sequence feature evidence for transmembrane)
PMID:30451685 GO:0000329 when SpHfl1 was overexpressed from a strong nmt1 promoter, the cytosolic signal of mYFP-SpAtg8 disappeared and the vacuole membrane localization of mYFP-SpAtg8 became much more conspicuous (Figure 1F).
PMID:30451685 GO:0007033 Figure 2
PMID:30451685 GO:0007033 Figure 2 and Figure 2-figure supplement 1
PMID:30451685 PBO:0108009 Figure 3—figure supplement 1A, 2B
PMID:30451685 PBO:0108010 Figure 3—figure supplement 1A
PMID:30451685 FYPO:0004247 Figure 3—figure supplement 1B
PMID:30451685 PBO:0108011 Figure 3—figure supplement 2
PMID:30451685 PBO:0108011 Figure 3—figure supplement 2
PMID:30451685 PBO:0108011 Figure 4—figure supplement 1B; isothermal titration calorimetry (ITC)
PMID:30451685 PBO:0108008 Figure 3—figure supplement 1A, 2B
PMID:30451685 PBO:0108008 Figure 3—figure supplement 1A, 2B
PMID:30451685 PBO:0108008 Figure 3—figure supplement 1A, 2B
PMID:30451685 PBO:0108008 Figure 3—figure supplement 1A, 2B
PMID:30451685 FYPO:0006784 Figure 3—figure supplement 1B, 2B; assayed_using cpy1
PMID:30451685 FYPO:0006784 Figure 3—figure supplement 1B, 2B; assayed_using cpy1
PMID:30451685 FYPO:0006784 Figure 3—figure supplement 1B, 2B; assayed_using cpy1
PMID:30451685 FYPO:0006786 Figure 2D and Figure 2—figure supplement 2
PMID:30451685 PBO:0108008 Figure 3—figure supplement 1
PMID:30451685 FYPO:0000385 Figure 2—figure supplement 1A
PMID:30451685 FYPO:0000116 Figures 2C, 2D, and Figure 2—figure supplement 2; same as either single mutant
PMID:30451685 FYPO:0001245 Figures 2C, 2D, and Figure 2—figure supplement 2; same as either single mutant
PMID:30451685 FYPO:0006579 Figures 2C, 2D, and Figure 2—figure supplement 2; same as either single mutant
PMID:30451685 PBO:0108009 Figure 3—figure supplement 1A, 2B
PMID:30451685 PBO:0108009 Figure 3—figure supplement 1A, 2B
PMID:30451685 PBO:0108009 Figure 3—figure supplement 1A, 2B
PMID:30451685 PBO:0108009 Figure 3—figure supplement 1A, 2B
PMID:30451685 FYPO:0006784 Figure 3—figure supplement 1B, 2B; assayed_using cpy1
PMID:30451685 PBO:0108012 Figure 3—figure supplement 2
PMID:30451685 PBO:0108012 Figure 3—figure supplement 2
PMID:30451685 PBO:0108012 Figure 3—figure supplement 2
PMID:30451685 PBO:0108013 Figure 4A; isothermal titration calorimetry (ITC)
PMID:30451685 PBO:0108013 Figure 4—figure supplement 1C; isothermal titration calorimetry (ITC)
PMID:30451685 PBO:0108014 Figure 4A; isothermal titration calorimetry (ITC)
PMID:30451685 PBO:0108015 Figure 4—figure supplement 1B; isothermal titration calorimetry (ITC)
PMID:30451685 PBO:0108015 Figure 4—figure supplement 1B; isothermal titration calorimetry (ITC)
PMID:30451685 PBO:0108015 Figure 4A; isothermal titration calorimetry (ITC)
PMID:30451685 PBO:0108015 Figure 4—figure supplement 1B; isothermal titration calorimetry (ITC)
PMID:30451685 PBO:0108015 Figure 4—figure supplement 1B; isothermal titration calorimetry (ITC)
PMID:30451685 PBO:0108010 Figure 4B
PMID:30451685 PBO:0108010 Figure 4B
PMID:30451685 PBO:0108010 Figure 4B
PMID:30451685 PBO:0108010 Figure 4B
PMID:30451685 PBO:0108016 Figure 4B
PMID:30451685 FYPO:0006785 Figure 2—figure supplement 2
PMID:30451685 PBO:0108016 Figure 4B
PMID:30451685 PBO:0108008 Figure 4B
PMID:30451685 FYPO:0004247 Figure 4C,D
PMID:30451685 FYPO:0004247 Figure 4C,D
PMID:30451685 FYPO:0004247 Figure 4C,D
PMID:30451685 FYPO:0004247 Figure 4C,D
PMID:30451685 FYPO:0004247 Figure 4C,D
PMID:30451685 FYPO:0004247 Figure 4C,D
PMID:30451685 PBO:0108009 Figure 3—figure supplement 1A, 2B
PMID:30451685 PBO:0108008 Figure 3—figure supplement 1A, 2B
PMID:30451685 FYPO:0006784 Figure 3—figure supplement 1B, 2B; assayed__using cpy1
PMID:30462301 FYPO:0006515 Supple- mentary Figure S5B
PMID:30462301 PBO:0100093 suggested by Junko
PMID:30462301 PBO:0100089 Figure 6B and Supplementary Figure S8C
PMID:30462301 PBO:0103856 Figure 6B and Supple- mentary Figure S8B
PMID:30462301 PBO:0103856 Figure 6B and Supple- mentary Figure S8B
PMID:30462301 PBO:0103856 Figure 6B and Supplementary Figure S8C)
PMID:30462301 PBO:0103855 Figure 6B and Supplementary Fig- ure S8B
PMID:30462301 PBO:0103855 Figure 6B and Supplementary Fig- ure S8B
PMID:30462301 PBO:0103855 Figure 6B and Supplementary Fig- ure S8B
PMID:30462301 GO:0005515 competatively with lem2
PMID:30462301 PBO:0103854 Figure 4F and Supplementary Figure S7F
PMID:30462301 PBO:0103853 Supplementary Figure S7E
PMID:30462301 PBO:0103853 Supplementary Figure S7E
PMID:30462301 PBO:0103853 Figure 4A
PMID:30462301 PBO:0103853 Supplementary Figure S7E
PMID:30462301 PBO:0103852 Figure 4A
PMID:30462301 PBO:0103852 Figure 4A
PMID:30462301 PBO:0103852 Figure 4A
PMID:30462301 GO:0005515 competatively with sad1
PMID:30462301 PBO:0103851 Supplementary Figure S7A-D)
PMID:30462301 FYPO:0001894 Figure 3
PMID:30462301 FYPO:0001894 Figure 3
PMID:30462301 FYPO:0001894 Figure 3
PMID:30462301 FYPO:0001894 Figure 3
PMID:30462301 FYPO:0000172 Figure 3B and Supplementary Figure S6
PMID:30462301 FYPO:0006366 Figure 3B and Supplementary Figure S6
PMID:30462301 FYPO:0000172 Figure 3B and Supplementary Figure S6
PMID:30462301 FYPO:0006366 Figure 3B and Supplementary Figure S6
PMID:30462301 FYPO:0004791 Figure 3A
PMID:30462301 FYPO:0004791 Figure 3A
PMID:30462301 FYPO:0004791 Figure 3A
PMID:30462301 FYPO:0004791 Figure 3A
PMID:30462301 FYPO:0006515 Supple- mentary Figure S5B
PMID:30462301 FYPO:0006515 Supple- mentary Figure S5B
PMID:30462301 FYPO:0006515 Supple- mentary Figure S5B
PMID:30462301 FYPO:0006515 Supple- mentary Figure S5B
PMID:30462301 PBO:0103848 Supple- mentary Figure S4A)
PMID:30462301 PBO:0103848 Figure 2E and Supple- mentary Figure S4B
PMID:30462301 PBO:0103847 Supple- mentary Figure S4A)
PMID:30462301 PBO:0103847 Supple- mentary Figure S4A)
PMID:30462301 PBO:0103847 Supple- mentary Figure S4A)
PMID:30462301 PBO:0100089 Figure 2C, D, Supple- mentary Figure S3A and C
PMID:30462301 PBO:0100089 Figure 2C, D, Supple- mentary Figure S3A and C
PMID:30462301 PBO:0100089 (Fig- ure 2D, Supplementary Figure S3B and C
PMID:30462301 PBO:0100089 (Fig- ure 2D, Supplementary Figure S3B and C
PMID:30462301 PBO:0103846 Figure 2C, Supplementary Figure S3A and C
PMID:30462301 PBO:0100089 Figure 2C, Supplementary Figure S3A and C
PMID:30462301 PBO:0100089 Figure 2C, Supplementary Figure S3A and C
PMID:30462301 PBO:0100088 Supplementary Figure S1A-E
PMID:30463883 PBO:0102980 figure 2 AB
PMID:30463883 FYPO:0002060 at 36 degrees Celsius
PMID:30463883 PBO:0102980 figure 2 AB
PMID:30463883 FYPO:0002060 at 36 degrees Celsius
PMID:30463883 PBO:0102980 figure 2 AB
PMID:30463883 FYPO:0006884 The mitotic spindle has two poles but is thicker than normal.
PMID:30463883 FYPO:0006884 The mitotic spindle has two poles but is thicker than normal.
PMID:30463883 FYPO:0002060 at 33 degrees Celsius
PMID:30463883 FYPO:0002060 at 33 degrees Celsius
PMID:30463883 FYPO:0002060 at 33 degrees Celsius
PMID:30463883 FYPO:0002060 at 36 degrees Celsius
PMID:30463883 FYPO:0002060 at 33 degrees Celsius
PMID:30463883 FYPO:0002060 at 36 degrees Celsius
PMID:30463883 FYPO:0002060 at 36 degrees Celsius
PMID:30463883 FYPO:0002060 at 36 degrees Celsius
PMID:30463883 PBO:0102980 figure 2 AB
PMID:30463883 PBO:0102981 figure 2 AB
PMID:30471998 GO:0034314 Dip1 activates Arp2/3 complex to nucleate linear actin filaments analogous to branched actin filaments created by Wsp1-mediated Arp2/3 complex activation. These Dip1-Arp2/3 complex nucleated filaments act as seeds for Wsp1-mediated Arp2/3 complex branching nucleation.
PMID:30475921 PBO:0092298 wtf18-2 allele assayed
PMID:30475921 PBO:0019133 when wtf13 antidote not present (homozygous, wtf13poison/wtf13+, or wtf13poison/wtf13Δ
PMID:30475921 FYPO:0006793 wtf13 driver, wtf18 suppressor
PMID:30475921 FYPO:0006793 wtf13 driver, wtf18 suppressor
PMID:30475921 FYPO:0006793 wtf13 driver, wtf18 suppressor
PMID:30475921 FYPO:0006793 wtf13 driver, wtf18 suppressor
PMID:30475921 FYPO:0006790 suppresses wtf13 drive
PMID:30503780 FYPO:0002687 fig S5B
PMID:30503780 PBO:0100088 fig 2 D
PMID:30503780 PBO:0100089 figure 2D
PMID:30503780 PBO:0100089 figure 2D
PMID:30503780 PBO:0100089 figure 2D
PMID:30503780 GO:0003677 figure3 (incompatible with rap1 binding)
PMID:30503780 FYPO:0000658 fig4
PMID:30503780 FYPO:0000658 fig4
PMID:30503780 GO:0005515 incompatible with DNA binding
PMID:30503780 FYPO:0005612 fig S5B
PMID:30503780 FYPO:0005612 fig S5B
PMID:30503780 FYPO:0002687 fig S5B (southern blot)
PMID:30503780 FYPO:0004791 Figures 5A and 5B
PMID:30503780 FYPO:0004093 fig S5B
PMID:30503780 FYPO:0004093 fig S5B
PMID:30503780 FYPO:0004791 Figures 5A and 5B
PMID:30503780 PBO:0100093 (transeferred from Junk's session PMID:30462301)
PMID:30503780 PBO:0100092 (transeferred from Junk's session PMID:30462301)
PMID:30503780 FYPO:0000590 (transeferred from Junk's session PMID:30462301)
PMID:30503780 FYPO:0000590 (transeferred from Junk's session PMID:30462301)
PMID:30503780 PBO:0100091 Figures 5C
PMID:30503780 PBO:0100090 Figures 5C
PMID:30503780 FYPO:0004791 Figures 5A and 5B
PMID:30528393 GO:0005829 although this was not assayed it can be deduced from the requirement of both cca1 andd 2 to add CCA
PMID:30528393 GO:0005829 although this was not assayed it can be deduced from the requirement of both cca1 andd 2 to add CCA
PMID:30528393 GO:0005739 although this was not assayed it can be deduced from the requirement of both cca1 andd 2 to add CCA
PMID:30528393 GO:0005739 although this was not assayed it can be deduced from the requirement of both cca1 andd 2 to add CCA
PMID:30530492 FYPO:0000464 glycosphingolipid transport
PMID:30530492 GO:0140351 glucosylceramide, galactosylceramide
PMID:30573453 PBO:0096296 fig6
PMID:30573453 PBO:0096188 (Figure S7)
PMID:30573453 PBO:0096189 (Figure S7)
PMID:30573453 PBO:0096189 FIgure S7
PMID:30573453 PBO:0096302 fig6
PMID:30573453 PBO:0095834 fig6
PMID:30573453 PBO:0096301 (figure S8)
PMID:30573453 PBO:0096300 (Figure S8)
PMID:30573453 PBO:0096299 FIgure S8
PMID:30573453 PBO:0096298 FIgure S8
PMID:30573453 FYPO:0006814 fig6
PMID:30573453 FYPO:0000967 fig6
PMID:30573453 FYPO:0006814 fig6
PMID:30573453 FYPO:0000966 fig6
PMID:30573453 FYPO:0002336 (Figure 3a)
PMID:30573453 FYPO:0002336 (Figure 3a)
PMID:30573453 PBO:0095652 (Figure 3a)
PMID:30573453 PBO:0096291 (Figure 2c)
PMID:30573453 FYPO:0000703 2d
PMID:30573453 FYPO:0000833 2d
PMID:30573453 PBO:0095652 (Figure 2c)
PMID:30573453 PBO:0094679 (Figure 2c)
PMID:30573453 FYPO:0003575 fig5
PMID:30573453 PBO:0096294 (Figure 4c)
PMID:30573453 FYPO:0006814 fig5
PMID:30573453 FYPO:0003575 fig5
PMID:30573453 PBO:0096295 fig5
PMID:30573453 FYPO:0000966 fig5
PMID:30573453 PBO:0094679 (Figure 2c)
PMID:30573453 FYPO:0003574 fig5
PMID:30573453 PBO:0096297 fig6
PMID:30573453 FYPO:0003411 fig6
PMID:30573453 PBO:0095834 fig6
PMID:30573453 PBO:0094282 FIgure S4
PMID:30573453 PBO:0094679 (Figure 4d)
PMID:30573453 PBO:0096292 FIgure 4C
PMID:30601114 FYPO:0006809 figure 2 B
PMID:30601114 FYPO:0006809 figure 2 B
PMID:30601114 PBO:0101038 figure 2 B
PMID:30601114 FYPO:0006809 Figure 2A and Figure 2–figure supplement 1B-E
PMID:30601114 FYPO:0006809 Figure 2A and Figure 2–figure supplement 1B-E
PMID:30601114 FYPO:0002134 ADD DOMAIN WHEN SO TERM AVAILABLE Figure 2A and Figure 2–figure supplement 1B-E
PMID:30601114 GO:1905762 Figure 1–figure supplement 1A
PMID:30601114 PBO:0101033 Figure 1–figure supplement 1B/Figure 1–figure supplement 1C
PMID:30601114 GO:0062104 PRE element Figure 1–figure supplement 1B/Figure 1–figure supplement 1C
PMID:30601114 PBO:0101034 Figure 1A and Figure 1–figure supplement 1D- E)
PMID:30601114 PBO:0101034 Figure 1A and Figure 1–figure supplement 1D- E)
PMID:30601114 PBO:0101035 Figure 1A and Figure 1–figure supplement 1D- E) (I think it is correct to describe as an enzyme regulator (MF, because it increases processivity.)
PMID:30601114 PBO:0101036 Figure 1B and Figure 1–figure supplement 1D-E (I think it is correct to describe as an enzyme regulator (MF, because it increases processivity.)
PMID:30601114 FYPO:0006809 figure 2 B
PMID:30601114 PBO:0101038 figure 2 B
PMID:30601114 PBO:0101038 figure 2 B
PMID:30601114 PBO:0101038 figure 2 B
PMID:30601114 FYPO:0006809 figure 2 B
PMID:30601114 PBO:0101039 figure 2 B
PMID:30601114 PBO:0101039 figure 2 B
PMID:30601114 PBO:0101038 figure 2
PMID:30601114 GO:1905762 Figure 1–figure supplement 1A
PMID:30602572 FYPO:0007196 Klp5/Klp6 cells exhibited a fission frequency that was half that of WT
PMID:30602572 FYPO:0000895 (Fig. S5B) Furthermore, in Klp4 cells, which typically contain sev- eral short mitochondria (Fig. 1A), absence of Dnm1 results in a single large, fused mitochondrion
PMID:30602572 FYPO:0003820 Fig 1C observed that Klp5/Klp6 contained only 2.3 0.4 (mean S.E.).
PMID:30602572 PBO:0096097 Figure 2C the mitochondria have a fission frequency that is almost double that of wild-type
PMID:30602572 PBO:0096096 Figure 1B the anti-parallel microtubule bundles are only about half the length of wild-type bundles
PMID:30602572 PBO:0096095 Figure 6B
PMID:30602572 PBO:0109848 Figure 1C-D
PMID:30602572 PBO:0109848 Figure 6C-D Increased mitochondrial numbers and decreased mitochondrial sizes with overall mitochondrial volume same as what is observed in wild-type cells
PMID:30602572 PBO:0109849 We counted 23.3 1.4 (mean S.E.) mitochondria in Klp5/Klp6 cells lacking Mmb1 (Fig. 6C), which was not significantly different from Mmb1 cells
PMID:30602572 FYPO:0003810 WT cells highly overex- pressing Dnm1 had 11.6 0.2 mitochondria (mean S.E.), which is twice that of WT cells
PMID:30626735 PBO:0093630 75 J/m^2; Andres SN et al. (2019)
PMID:30626735 PBO:0101188 Andres SN et al. (2019)
PMID:30626735 PBO:0093620 200 Gy; Andres SN et al. (2019)
PMID:30635402 MOD:00046 Identified by mass spectrometry
PMID:30635402 MOD:00046 Identified by mass spectrometry
PMID:30635402 MOD:00046 Identified by mass spectrometry
PMID:30635402 MOD:00046 Identified by mass spectrometry
PMID:30635402 MOD:00046 Identified by mass spectrometry
PMID:30635402 MOD:00047 Identified by mass spectrometry
PMID:30635402 FYPO:0000228 ICRF-193, a bisdioxopiperazine derivative [meso-4,4-(2,3-butanediyl)-bis (2,6-piperazinedione)], is a catalytic topo II inhibitor
PMID:30635402 FYPO:0005739 This phenotype is observed in the presence of ICRF-193, a bisdioxopiperazine derivative [meso-4,4-(2,3-butanediyl)-bis (2,6-piperazinedione)], a catalytic topo II inhibitor.
PMID:30635402 PBO:0106862 also assayed directly using human CKII
PMID:30635402 PBO:0108715 These phosphorylation sites were identified by the phos-tag analysis, phospho-specific antibodies, and in vitro phosphorylation assay
PMID:30640914 PBO:0103599 Cellular fractionation; affecting Rec25
PMID:30640914 PBO:0103591 Recombination assay; assayed region: leu1-his5 interval
PMID:30640914 PBO:0103592 mbs1 hotspot quantification
PMID:30640914 PBO:0103593 Recombination assay; assayed region: ade6 gene
PMID:30640914 PBO:0103594 Recombination assay; assayed region: leu1-his5 interval
PMID:30640914 PBO:0103592 mbs1 hotspot quantification
PMID:30640914 PBO:0103595 Recombination assay; assayed region: ade6 gene
PMID:30640914 PBO:0102476 Recombination assay; assayed region: ade6 gene
PMID:30640914 PBO:0102476 Recombination assay; assayed region: ade6 gene
PMID:30640914 FYPO:0004993 s1
PMID:30640914 FYPO:0006841 S2
PMID:30640914 FYPO:0005650 fig s4
PMID:30640914 FYPO:0004610 fig8
PMID:30640914 PBO:0103596 Recombination assay; assayed region: leu1-his5 interval
PMID:30640914 PBO:0103597 mbs1 hotspot quantification
PMID:30640914 FYPO:0005650 S4
PMID:30640914 PBO:0102476 Recombination assay; assayed region: ade6 gene
PMID:30640914 PBO:0103598 mbs1 hotspot quantification
PMID:30640914 FYPO:0004610 fig8
PMID:30640914 FYPO:0005650 S2
PMID:30640914 FYPO:0004628 S2
PMID:30640914 FYPO:0004628 S2
PMID:30640914 FYPO:0000581 S1A
PMID:30640914 PBO:0103598 mbs1 hotspot quantification
PMID:30640914 FYPO:0006838 Rec25 visualization
PMID:30640914 FYPO:0006838 Rec25 visualization
PMID:30640914 PBO:0103599 Cellular fractionation; affecting Rec25
PMID:30640914 FYPO:0004993 S1A
PMID:30640914 PBO:0103599 Cellular fractionation; affecting Rec25
PMID:30640914 PBO:0103592 mbs1 hotspot quantification
PMID:30640914 PBO:0103595 Recombination assay; assayed region: ade6 gene
PMID:30640914 PBO:0103596 Recombination assay; assayed region: leu1-his5 interval
PMID:30640914 PBO:0103598 mbs1 hotspot quantification
PMID:30640914 FYPO:0006838 Rec25 visualization
PMID:30640914 PBO:0103595 Recombination assay; assayed region: ade6 gene
PMID:30640914 PBO:0103595 Recombination assay; assayed region: ade6 gene
PMID:30640914 PBO:0103595 Recombination assay; assayed region: ade6 gene
PMID:30640914 PBO:0102476 Recombination assay; assayed region: ade6 gene
PMID:30640914 PBO:0102476 Recombination assay; assayed region: ade6 gene
PMID:30640914 PBO:0103593 Recombination assay; assayed region: ade6 gene
PMID:30640914 PBO:0103593 Recombination assay; assayed region: ade6 gene
PMID:30640914 PBO:0102476 Recombination assay; assayed region: ade6 gene
PMID:30640914 PBO:0103593 Recombination assay; assayed region: ade6 gene
PMID:30640914 FYPO:0004993 S1A
PMID:30640914 FYPO:0004993 S1A
PMID:30646830 GO:0016428 trm401 (Trm4a) methylates C34 of tRNA-Leu (CAA) and tRNA-Pro (CGG) as well as all C48 tRNA methylation sites. Methylates C34 only on intron-containing tRNA.
PMID:30646830 PBO:0095187 Abolished tRNA cytosine-5 methylation of C49 and C50 (tRNA bisulphite sequencing)
PMID:30646830 GO:0016428 trm402 (Trm4b) methylates C49 and C50 of tRNAs
PMID:30646830 PBO:0095187 abolished tRNA C34, C48 methylation (trna bisulphite sequencing)
PMID:30649994 PBO:0108066 3E
PMID:30649994 GO:1901612 Supplemental Figure S2
PMID:30649994 PBO:0108066 3E
PMID:30649994 PBO:0018826 4b
PMID:30649994 FYPO:0006896 3E
PMID:30649994 FYPO:0006896 3E
PMID:30649994 GO:0070300 Supplemental Figure S2
PMID:30649994 PBO:0108065 S3
PMID:30652128 FYPO:0006811 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096839 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096839 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096842 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096838 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096842 Monitoring an extra-chromosome ChL
PMID:30652128 FYPO:0001742 Pulse-field gel electrophoresis (PFGE), Polymerase chain reaction (PCR), Monitoring an extra-chromosome ChL
PMID:30652128 FYPO:0001742 Pulse-field gel electrophoresis (PFGE), Polymerase chain reaction (PCR), Monitoring an extra-chromosome ChL
PMID:30652128 FYPO:0001742 Pulse-field gel electrophoresis (PFGE), Polymerase chain reaction (PCR), Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096838 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096839 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096838 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096842 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096842 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096842 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096839 Monitoring an extra-chromosome ChL
PMID:30652128 FYPO:0006811 Monitoring an extra-chromosome ChL
PMID:30652128 FYPO:0006811 Monitoring an extra-chromosome ChL
PMID:30652128 FYPO:0006811 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096839 Monitoring an extra-chromosome ChL
PMID:30652128 FYPO:0006811 Monitoring an extra-chromosome ChL
PMID:30652128 FYPO:0006811 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096842 Monitoring an extra-chromosome ChL
PMID:30652128 FYPO:0006811 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096839 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0093563 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0103454 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0103454 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0103454 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0103455 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096842 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0103455 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0103455 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0103456 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096839 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096839 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096839 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096842 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096838 Monitoring an extra-chromosome ChL
PMID:30652128 FYPO:0006811 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096842 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096842 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096842 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096842 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0094685 tfs1∆ reduced centromere noncoding RNA in the clr4∆ strain. Northern blot assay
PMID:30652128 FYPO:0006810 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0094685 rpd1-S7A reduced centromere noncoding RNA in the clr4∆ strain. Northern blot assay
PMID:30652128 FYPO:0006811 Monitoring an extra-chromosome ChL
PMID:30652128 FYPO:0001740 rpd1-S7A increased the rate of gross chromosomal rearrangement in the otherwise wild-type background. Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096838 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096839 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096838 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096838 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096838 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096838 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096838 Monitoring an extra-chromosome ChL
PMID:30652128 PBO:0096838 Monitoring an extra-chromosome ChL
PMID:30658998 FYPO:0006910 fig 1B
PMID:30658998 FYPO:0006914 fig 1B
PMID:30658998 FYPO:0006913 fig 1B
PMID:30658998 FYPO:0006911 fig 1B
PMID:30658998 FYPO:0006034 supressed dna fragmentation
PMID:30658998 FYPO:0006034 supressed dna fragmentation
PMID:30658998 FYPO:0003769 fig 1D supressed by hexestrol or clomifene
PMID:30658998 FYPO:0003810 fig 1C supressed by hexestrol
PMID:30658998 FYPO:0002061 fig 1B
PMID:30658998 FYPO:0003769 fig 1D
PMID:30658998 FYPO:0003810 fig 1C
PMID:30658998 FYPO:0001355 fig 1B
PMID:30659798 GO:0008017 fig2
PMID:30659798 GO:0003777 fig 2f
PMID:30667359 FYPO:0007006 Figure 6C
PMID:30667359 FYPO:0006920 Figure 6B
PMID:30667359 FYPO:0007005 Figure 6C
PMID:30667359 FYPO:0006920 Figure 6B
PMID:30667359 FYPO:0007005 Figure 6C
PMID:30667359 FYPO:0000167 Figure 2B
PMID:30667359 FYPO:0006920 Figure 2B
PMID:30667359 FYPO:0007005 Figure 2B
PMID:30667359 FYPO:0007005 Figure 2B
PMID:30667359 FYPO:0007007 Figure 6C
PMID:30667359 FYPO:0007006 Figure 6C
PMID:30667359 FYPO:0007006 Figure 6C
PMID:30667359 FYPO:0007007 Figure 6c
PMID:30715423 PBO:0102227 Reduced translation of transcripts with a mitochondrial function that is mediated by queuosine-modified tRNAs is abrogated in pmt1∆.
PMID:30715423 PBO:0102226 Reduced translation of transcripts with a mitochondrial function that is mediated by queuosine-modified tRNAs is abrogated in pmt1∆.
PMID:30715423 PBO:0102225 Reduced translation of transcripts with a mitochondrial function that is mediated by queuosine-modified tRNAs is abrogated in pmt1∆.
PMID:30715423 GO:1990145 ... Q-modification in tRNAs is to improve translation ofC-ending codons relative to U-ending codons in S. pombe.
PMID:30715423 PBO:0102224 Reduced translation of transcripts with a mitochondrial function that is mediated by queuosine-modified tRNAs is abrogated in pmt1∆.
PMID:30715423 PBO:0102222 Reduced translation of transcripts with a mitochondrial function that is mediated by queuosine-modified tRNAs is abrogated in pmt1∆.
PMID:30715423 PBO:0102221 No queuosine-mediated reduction of translational errors at GGC (Gly) and UGC (Tyr) codons
PMID:30715423 PBO:0102223 Reduced translation of transcripts with a mitochondrial function that is mediated by queuosine-modified tRNAs is abrogated in pmt1∆.
PMID:30726745 FYPO:0001045 Figure 7A
PMID:30726745 PBO:0095262 Figure 2, Figure 3.
PMID:30726745 PBO:0095261 Figure 1
PMID:30726745 PBO:0095262 Figure 2, Figure 3
PMID:30726745 GO:1902716 Figure 6
PMID:30726745 FYPO:0001903 Figure 7C, 7D
PMID:30726745 FYPO:0001903 Figure 7C, 7D
PMID:30726745 FYPO:0003267 Figure 7A
PMID:30726745 FYPO:0001045 Figure 7A
PMID:30726745 FYPO:0001903 Figure 7C, 7D
PMID:30726745 PBO:0095263 Figure 7C, 7D
PMID:30726745 FYPO:0001045 Figure 7A
PMID:30726745 PBO:0095263 Figure S5
PMID:30759079 FYPO:0006927 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006927 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006927 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006927 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006927 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006927 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006926 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006926 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006926 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006926 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006926 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006926 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006927 Fig6 The nuclear envelope is marked with Cut11-GFP
PMID:30759079 FYPO:0006927 Fig6 The nuclear envelope is marked with Cut11-GFP
PMID:30759079 FYPO:0002256 data not shown
PMID:30759079 FYPO:0002256 data not shown
PMID:30759079 FYPO:0002256 data not shown
PMID:30759079 FYPO:0006927 Fig6 The nuclear envelope is marked with Cut11-GFP
PMID:30759079 FYPO:0006926 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006926 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006926 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006926 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006926 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006926 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006926 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006926 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006926 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006926 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006926 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006927 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30759079 FYPO:0006927 Table 1 The nuclear envelope for all the mutants analysed is marked with Ish1-yEGFP integrated in the gene deletion locus. The the NC ratio of the control is reduced from 0.08 to 0.05.
PMID:30773398 FYPO:0002919 Figure 1E
PMID:30773398 PBO:0033658 Fig 3
PMID:30773398 GO:0005515 homodimer
PMID:30773398 FYPO:0006858 Figure S2
PMID:30773398 FYPO:0006858 Figure S2
PMID:30773398 FYPO:0006858 Figure S2
PMID:30773398 FYPO:0006858 Figure S2
PMID:30773398 FYPO:0006858 Figure S2
PMID:30773398 FYPO:0006858 Figure S2
PMID:30773398 FYPO:0006857 Figure 1E
PMID:30773398 FYPO:0006857 Figure 1E
PMID:30773398 FYPO:0002919 Figure 1E
PMID:30773398 GO:0046975 Figs 1C, S1
PMID:30773398 PBO:0101843 Figs 1B, 1D, 1F, S1, S2
PMID:30773398 PBO:0101842 Figs 1B, 1D, 1F, S1, S2
PMID:30773398 PBO:0101841 Figs 1B, 1D, 1F, S1, S2
PMID:30773398 GO:0005737 Fig 1a
PMID:30773398 GO:0005634 Fig 1a
PMID:30796050 PBO:0102806 Fig S1
PMID:30796050 FYPO:0006860 Fig 3; less intense Y arc in 2D gel
PMID:30796050 FYPO:0006859 Fig 3; less intense Y arc in 2D gel
PMID:30796050 PBO:0104037 Fig 3
PMID:30796050 FYPO:0005402 Fig 2, S2
PMID:30796050 PBO:0104036 Fig 2
PMID:30796050 PBO:0095229 Fig 1
PMID:30796050 PBO:0104035 Fig 1
PMID:30796050 PBO:0093632 Fig 1
PMID:30796050 PBO:0104038 Fig 4
PMID:30796050 PBO:0093632 Fig 1
PMID:30796050 PBO:0102806 Fig 1
PMID:30796050 PBO:0097407 Fig 4
PMID:30796050 PBO:0102806 Fig S1
PMID:30796050 PBO:0102806 Fig S2
PMID:30796050 PBO:0102806 Fig S2
PMID:30796050 PBO:0102806 Fig EV2
PMID:30796050 PBO:0093632 Fig S2
PMID:30796050 PBO:0093632 Fig S2
PMID:30796050 PBO:0093632 Fig S3
PMID:30796050 PBO:0093632 Fig S3
PMID:30796050 PBO:0093632 Fig S3
PMID:30796050 PBO:0093632 Fig S3
PMID:30796050 PBO:0093632 Fig S3
PMID:30796050 PBO:0093634 Fig 1
PMID:30796050 PBO:0093634 Fig 4
PMID:30796050 PBO:0093636 Fig 1
PMID:30796050 PBO:0093636 Fig 2
PMID:30796050 PBO:0097410 Fig 3
PMID:30796050 PBO:0104037 Fig EV3
PMID:30796050 PBO:0104039 Fig EV3
PMID:30796050 PBO:0093634 Fig EV3; restrictive temperature for cdc2-M68
PMID:30796050 PBO:0104041 also inferred from orthology and various genetic interactions
PMID:30796050 PBO:0093632 Fig 2
PMID:30796050 PBO:0093632 Fig 2
PMID:30796050 PBO:0093632 Fig 3
PMID:30796050 PBO:0093632 Fig 4
PMID:30796050 PBO:0093632 Fig 4
PMID:30796050 PBO:0093632 Fig S3
PMID:30806623 PBO:0097932 Fig. 6
PMID:30806623 FYPO:0007958 Fig. 5
PMID:30806623 FYPO:0005342 Fig. 6
PMID:30806623 FYPO:0005342 Fig. 6
PMID:30806623 FYPO:0005343 Fig. 6
PMID:30806623 FYPO:0005342 Fig. 6
PMID:30806623 FYPO:0005343 Fig. 3
PMID:30806623 FYPO:0005706 Fig. 3
PMID:30806623 FYPO:0007958 Fig. 1
PMID:30806623 FYPO:0003268 Fig. 1
PMID:30806623 FYPO:0004310 Fig. 1
PMID:30806623 FYPO:0004310 Fig. 1
PMID:30806623 FYPO:0000648 Fig. 1
PMID:30806623 FYPO:0001492 Fig. 1
PMID:30810475 GO:0045292 Required for the splicing of several genome-wide transcripts. Inferred from transcriptome sequencing of the mutant strain prp16F528S. Splicing defects in transcripts validated by RT-PCR assays.
PMID:30810475 GO:0016887 In vitro RNA helicase activity using recombinant protein encoded by the helicase domain of Prp16
PMID:30810475 FYPO:0004742 fig7
PMID:30810475 FYPO:0003412 fig7
PMID:30810475 FYPO:0003412 fig7
PMID:30810475 PBO:0103152 fig7
PMID:30810475 PBO:0103151 fig7
PMID:30810475 PBO:0103152 figS6,7
PMID:30810475 PBO:0103151 figS6,7
PMID:30810475 PBO:0103150 figS6,7
PMID:30810475 PBO:0103149 figS6,7
PMID:30810475 FYPO:0000091 fig7
PMID:30810475 FYPO:0001919 fig7 they say fragmented nucleus but they stained chromosomes, not nuclear envelope
PMID:30810475 FYPO:0000229 fig7
PMID:30810475 FYPO:0001917 fig7
PMID:30810475 PBO:0103148 fig6
PMID:30810475 PBO:0103147 fig6
PMID:30810475 PBO:0103146 fig4
PMID:30810475 PBO:0095406 fig4
PMID:30810475 FYPO:0001355 fig4
PMID:30810475 PBO:0100020 fig4
PMID:30810475 PBO:0100020 fig4
PMID:30810475 PBO:0093556 fig1
PMID:30810475 PBO:0093557 fig1
PMID:30810475 FYPO:0002061 fig1
PMID:30810475 PBO:0103145 fig1b - for dga1 normal splicing of intonr 3, abnormal intron 2, S4
PMID:30810475 PBO:0103144 fig1b - for dga1 normal splicing of intonr 3, abnormal intron 2, S4
PMID:30810475 PBO:0095902 fig1b - for dga1 normal splicing of intonr 3, abnormal intron 2, S4
PMID:30810475 PBO:0103143 fig1b - for dga1 normal splicing of intonr 3, abnormal intron 2, S4
PMID:30810475 PBO:0095406 fig1b - for dga1 normal splicing of intonr 3, abnormal intron 2, S4
PMID:30810475 PBO:0103142 fig1b
PMID:30810475 PBO:0098392 fig1b
PMID:30810475 PBO:0100020 fig1b
PMID:30810475 PBO:0095406 fig1b
PMID:30810475 FYPO:0000082 fig1
PMID:30810475 FYPO:0000082 fig1
PMID:30810475 FYPO:0000674 fig1
PMID:30810475 FYPO:0001357 fig1
PMID:30810475 FYPO:0002141 fig1
PMID:30810475 PBO:0103141 Required for splicing of introns with strong 5' splice site - U6 snRNA and branch site - U2 snRNA interactions
PMID:30810475 GO:0034458 In vitro RNA helicase activity using recombinant protein encoded by the helicase domain of Prp16
PMID:30840879 PBO:0097517 fig 3 e
PMID:30840879 GO:0070273 MEMBRANE LIPID BINDING Rga7 F-BAR preferred membranes rich in PI(4)P and PI(4,5)P2 (Figure 3D)
PMID:30840879 PBO:0097538 fig 2A Figure 2A
PMID:30840879 PBO:0097537 2b normal lpid binding
PMID:30840879 PBO:0097536 1F
PMID:30840879 PBO:0097517 fig 1B
PMID:30840879 GO:0005546 MEMBRANE LIPID BINDING Rga7 F-BAR preferred membranes rich in PI(4)P and PI(4,5)P2 (Figure 3D)
PMID:30840879 PBO:0096613 fig 2A Figure 2A
PMID:30840879 PBO:0097517 fig 1B
PMID:30840879 PBO:0097518 Figure 2A
PMID:30840879 PBO:0096613 fig 3e
PMID:30840879 PBO:0097517 fig 3e
PMID:30840879 PBO:0097519 fig 3 c
PMID:30840879 PBO:0097520 fig 3 c
PMID:30840879 PBO:0097520 fig 3c
PMID:30840879 PBO:0097521 fig 2b
PMID:30840879 PBO:0097524 fig 4
PMID:30840879 PBO:0097534 GFP-Rga7(277–695) alone, lacking the majority of the F-BAR domain, could not localize to the PM, resulting in massive cell lysis
PMID:30840879 PBO:0097535 F-BAR/BAR domain adaptors Rng10(751–950) interacts directly with the Rga7 F-BAR domain
PMID:30840879 PBO:0097536 To test for a direct interaction, we performed in vitro binding assays using recombinant Rng10 C terminus and the Rga7 F-BAR (Figures 1D and S2A). GST- Rng10(751–1,038) efficiently bound His6-Rga7(1–320) with a dissociation constant (Kd) of 0.43 μM (Figures 1D, 1E, and S2B).
PMID:30840879 PBO:0097536 1F Defining the Rga7-binding motif within Rng10 further, we found that Rng10(751–950) bound Rga7(1–320) with a similar Kd of 0.69 μM (Figures 1F, 1G, and S2B)
PMID:30853434 PBO:0094419 Figure 2E-F (live cell imaging)
PMID:30853434 PBO:0094418 Figure 4A-B (live cell imaging)
PMID:30853434 FYPO:0005905 Figure 3A-B (Live-cell time-lapse imaging)
PMID:30853434 FYPO:0001365 Figure 3A-B (Live-cell time-lapse imaging)
PMID:30853434 PBO:0094417 Figure 2A-B (vw changed to cell division site during M-phase from septum) (live cell imaging)
PMID:30853434 PBO:0094416 Figure 1D-G (live cell imaging)
PMID:30853434 PBO:0094415 Figure 3A-B (Live-cell time-lapse imaging)
PMID:30853434 PBO:0094414 increased binding by about 2 fold from Figure 4C-D
PMID:30853434 FYPO:0007474 Figure 4E (moved from wee) (skewed towards small, low severity)
PMID:30853434 FYPO:0003481 Figure 4H (vw moved down to FYPO:0003481) (live cell DIC)
PMID:30853434 FYPO:0003439 Figure 4G (live cell DIC)
PMID:30853434 FYPO:0001223 Figure 4G (live cell DIC)
PMID:30853434 FYPO:0003210 Figure 4G (live cell DIC)
PMID:30853434 FYPO:0003210 Figure 4I (Live-cell time-lapse imaging)
PMID:30853434 PBO:0094430 Figure S1
PMID:30853434 PBO:0094422 Figure 1C
PMID:30853434 PBO:0094430 Figure S1
PMID:30853434 PBO:0094430 Figure S1
PMID:30853434 PBO:0094430 Figure S1
PMID:30853434 PBO:0094430 Figure S1
PMID:30853434 PBO:0094429 Figure S3C-D (live cell imaging)
PMID:30853434 PBO:0094428 Figure S3A (live cell imaging)
PMID:30853434 PBO:0094427 Figure S2C (live cell imaging)
PMID:30853434 PBO:0094426 Figure S2A-B (live cell imaging)
PMID:30853434 PBO:0094425 Figure S2A-B (vw changed from FYPO:0001677 to FYPO:0002874 to match rlc1) (live cell imaging)
PMID:30853434 PBO:0094430 Figure S1
PMID:30853434 PBO:0094421 Figure 1H-I (live cell imaging)
PMID:30853434 FYPO:0002873 Figure 3C-D
PMID:30853434 FYPO:0002873 Figure 3D (live cell DIC)
PMID:30853434 PBO:0094435 Figure S4A
PMID:30853434 PBO:0094434 Fig 2 E-F
PMID:30853434 PBO:0094433 FIg 1 D
PMID:30853434 PBO:0024047 FIg 1 D
PMID:30853434 PBO:0018677 FIg 1 D
PMID:30853434 FYPO:0003210 Figure 3C-D (live cell DIC)
PMID:30853434 PBO:0094431 Figure 1H-I (live cell imaging)
PMID:30853434 PBO:0094432 Figure S3C-D (live cell imaging)
PMID:30853434 PBO:0094432 Figure S3A (live cell imaging)
PMID:30853434 PBO:0094431 Figure S4A (live cell imaging)
PMID:30853434 PBO:0094420 Figure S4C-D
PMID:30853434 FYPO:0003481 Figure S4F and G (vw move to FYPO:0006822 and requested parentage fix in FYPO) (live cell DIC)
PMID:30853434 FYPO:0006822 Figure S4F & H (vw move to FYPO:0006822 and requested parentage fix in FYPO) (live cell DIC)
PMID:30853434 FYPO:0003481 Figure S4G (vw moved down to FYPO:0003481) (live cell DIC)
PMID:30853434 FYPO:0003481 Figure S4F and G (vw move to FYPO:0006822 and requested parentage fix in FYPO) (live cell DIC)
PMID:30853434 FYPO:0006822 Figure S4F&H (live cell DIC)
PMID:30853434 FYPO:0003210 Figure 4G (live cell DIC)
PMID:30853434 PBO:0094431 Figure S4A (live cell imaging)
PMID:30853434 PBO:0094424 Figure S2A-B (vw changed from FYPO:0001677 to FYPO:0002874 to match rlc1) (live cell imaging)
PMID:30853434 PBO:0094423 Figure S2A-B (vw changed from FYPO:0001677 to FYPO:0002874 to match rlc1) (live cell imaging)
PMID:30862564 FYPO:0003125 converted from bp by cc
PMID:30862564 FYPO:0003125 converted from bp by cc
PMID:30967422 PBO:0104182 figure2b
PMID:30967422 PBO:0104187 figure2b
PMID:30967422 PBO:0104186 figure2b
PMID:30967422 PBO:0104185 figure2b
PMID:30973898 PBO:0095942 figure 5A
PMID:30973898 PBO:0105558 figure S2A
PMID:30973898 PBO:0095942 figure 5A
PMID:30973898 PBO:0095942 figure 5A
PMID:30973898 PBO:0095942 figure 5A
PMID:30973898 PBO:0105564 figure 4C
PMID:30973898 PBO:0105564 figure 4C
PMID:30973898 FYPO:0002061 figure 3A
PMID:30973898 FYPO:0002059 figure 3A
PMID:30973898 PBO:0093562 figure 3A
PMID:30973898 PBO:0095942 figure 3A
PMID:30973898 PBO:0102086 figure 2D
PMID:30973898 PBO:0105563 figure 2D
PMID:30973898 PBO:0105562 Figure 2D
PMID:30973898 PBO:0022298 Figure 2D
PMID:30973898 FYPO:0002061 figure 2C
PMID:30973898 PBO:0093562 figure 2C
PMID:30973898 PBO:0095942 figure 2C
PMID:30973898 PBO:0095942 figure 2C
PMID:30973898 PBO:0105560 figure 2B (two hybrid)
PMID:30973898 PBO:0105561 figure 2B (two hybrid)
PMID:30973898 PBO:0105560 figure 2B (two hybrid)
PMID:30973898 PBO:0093564 figure1 B
PMID:30973898 FYPO:0000964 figure1 A
PMID:30973898 FYPO:0001686 figure1 A
PMID:30973898 FYPO:0003809 figure1 A
PMID:30973898 FYPO:0005947 figure1 A
PMID:30973898 PBO:0093564 figure1 A
PMID:30973898 PBO:0093567 figure1 A
PMID:30973898 FYPO:0000107 figure1 A
PMID:30973898 FYPO:0001214 figure1 A
PMID:30973898 FYPO:0000229 figure 4 DAPI staining
PMID:30973898 PBO:0105556 figure 4 C mini-chromosome Ch16 loss assay
PMID:30973898 PBO:0093562 figure 5A
PMID:30973898 PBO:0105557 mini-chromosome Ch16 loss assay
PMID:30973898 FYPO:0000964 figure 1B
PMID:30973898 PBO:0093562 Fig 1D
PMID:30973898 PBO:0093562 Fig 1D
PMID:30973898 PBO:0095942 figure 3A
PMID:30973898 PBO:0105558 figure S2A
PMID:30973898 PBO:0105559 figure S2B
PMID:30973898 PBO:0105560 figure 2B (two hybrid)
PMID:30973898 PBO:0095942 figure 5A
PMID:30973898 PBO:0105559 figure S2B
PMID:30975915 FYPO:0002061 Figure 1
PMID:30975915 FYPO:0000088 Fig. 4B
PMID:30975915 FYPO:0001234 Fig. 4A
PMID:30975915 FYPO:0002061 Figure 3
PMID:30975915 FYPO:0002061 Figure 1
PMID:30975915 FYPO:0002061 Figure 3
PMID:30975915 FYPO:0000088 Fig. 4B
PMID:30975915 FYPO:0000963 Fig. 4B
PMID:30975915 FYPO:0001839 Fig 4
PMID:30975915 FYPO:0002360 Fig 4
PMID:30975915 FYPO:0002061 Figure 1
PMID:30975915 FYPO:0001357 Figure 1
PMID:30975915 FYPO:0002061 figure 1A
PMID:30975915 FYPO:0002061 figure3
PMID:30975915 FYPO:0002061 Fig. 2B
PMID:30992049 FYPO:0000085 25 degrees; same as mst1-L344S alone
PMID:30992049 PBO:0093615 hhf1 and hhf3 are wild-type. Only hhf2 is mutated.
PMID:30992049 PBO:0093617 hhf1 and hhf3 are wild-type. Only hhf2 is mutated.
PMID:30992049 PBO:0093615 hhf2 and hhf3 are wild-type. Only hhf2 is mutated.
PMID:30992049 FYPO:0000095 hhf1 and hhf3 are wild-type. Only hhf2 is mutated.
PMID:30992049 FYPO:0000085 grows normally at 25 degrees but not at 30 degrees
PMID:30992049 PBO:0093613 grows normally at 25 degrees but not at 30 degrees
PMID:30992049 FYPO:0001355 grows normally at 25 degrees but not at 30 degrees
PMID:30992049 FYPO:0002550 hhf1 and hhf3 are wild-type. Only hhf2 is mutated.
PMID:30992049 PBO:0093617 same as swi1delta alone
PMID:30992049 PBO:0093614 grows normally at 25 degrees but not at 30 degrees
PMID:30992049 PBO:0093615 hhf2 and hhf3 are wild-type. Only hhf2 is mutated.
PMID:30992049 PBO:0093615 same as nmt81-vid21 alone
PMID:30996236 PBO:0095634 Fig 2
PMID:30996236 PBO:0095634 Fig 2
PMID:30996236 PBO:0095634 Fig 2
PMID:30996236 PBO:0095634 Fig 2
PMID:30996236 PBO:0095634 Fig 2
PMID:30996236 PBO:0095634 Fig 2
PMID:30996236 PBO:0095685 Fig 2
PMID:30996236 FYPO:0001357 Fig 2
PMID:30996236 FYPO:0002674 Fig 3
PMID:30996236 FYPO:0002674 Fig 3
PMID:30996236 FYPO:0002674 Fig 3
PMID:30996236 FYPO:0001357 Fig 2
PMID:30996236 FYPO:0002674 Fig 3
PMID:30996236 FYPO:0002674 Fig 3
PMID:30996236 FYPO:0002674 Fig 3
PMID:30996236 FYPO:0002674 Fig 3
PMID:30996236 FYPO:0002674 Fig 3
PMID:30996236 FYPO:0002674 Fig 3
PMID:30996236 FYPO:0001357 Fig 2
PMID:30996236 FYPO:0001234 Fig 2
PMID:30996236 FYPO:0001357 Fig 2
PMID:30996236 PBO:0095685 Fig 2
PMID:30996236 PBO:0094648 Fig 2
PMID:30996236 PBO:0095634 Fig 2
PMID:30996236 FYPO:0002674 Fig 3
PMID:30996236 FYPO:0002674 Fig 3
PMID:30996236 FYPO:0002674 Fig 3
PMID:30996236 FYPO:0002674 Fig 3
PMID:31000521 PBO:0096838 Fig 7 using minichromosome
PMID:31000521 PBO:0104293 5C
PMID:31000521 PBO:0104292 5E
PMID:31000521 PBO:0104286 Fig-2C
PMID:31000521 PBO:0104292 5B
PMID:31000521 FYPO:0000091 SUPP S1
PMID:31000521 FYPO:0006811 Fig 7 using minichromosome
PMID:31000521 FYPO:0003412 fig 7 B
PMID:31000521 FYPO:0004742 fig 7B
PMID:31000521 PBO:0104288 fig 3B
PMID:31000521 PBO:0097773 Fig-2C
PMID:31000521 PBO:0104285 Fig-2A Spindle pole-to-pole distance was measured based on the distance of duplicated SPBs revealed by Sad1-DsRed.
PMID:31000521 PBO:0104284 (vw 3B? changed from normal to lagging, added penetrance) dfp1-CFP-2CD rescues minichromosome loss in the absence of Swi6.
PMID:31000521 PBO:0104283 Fig-2A Spindle pole-to-pole distance was measured based on the distance of duplicated SPBs revealed by Sad1-DsRed.
PMID:31000521 FYPO:0004310 (VW changed to multi allele) The delay of m-to-G1/S phase transition in swi6∆ and dfp1-3A was abolished after deleting mad2.
PMID:31000521 FYPO:0000634 5B abolish Swi6 protein localization to centromere during vegetative growth
PMID:31000521 FYPO:0004742 Fig 7B
PMID:31000521 FYPO:0001007 (vw: changed genotype to add swi6 delt) dfp1-CFP-2CD restores lagging chromosomes in the absence of Swi6. Rad21 locates to centromere in dfp1-CFP-2CD mutants.
PMID:31000521 FYPO:0001513 (Figure 3B Chp1 fails to accumulate at noncentromeric location in the absence of Chp2 and Swi6.
PMID:31000521 PBO:0104282 (Figure 3B vw changed more specific to lagging chromosmes) Increase the frequency of mitotic cells showing lagging chromosomes. Rad21 fails to accumulate at centromere in the absence of Swi6.
PMID:31000521 FYPO:0004310 ) Rad21 locates to centromere in dfp1-3A mutants.
PMID:31000521 PBO:0097772 Fig-2C
PMID:31000521 PBO:0104287 Figure 3B
PMID:31000521 PBO:0096842 Fig 7 using minichromosome
PMID:31000521 PBO:0096838 Fig 7 using minichromosome
PMID:31000521 PBO:0104291 Figure 3B
PMID:31000521 PBO:0104290 Figure 3B
PMID:31000521 PBO:0104289 Figure 3B
PMID:31000521 FYPO:0003412 fig 7 B
PMID:31000521 FYPO:0003412 fig 7 B
PMID:31000521 PBO:0104293 Rad21-GFP enrichment at the centromere is unaffected in swi6-sm1 (Figure S4C)
PMID:31000521 FYPO:0001513 The swi6-sm1 allele disrupts silencing without lagging chro- mosomes (Yamagishi et al. 2008) (Figure S4, A and B). We observed a similar frequency of lagging chromosomes in wild-type (1%) and swi6-sm1 mutants (1.03%).
PMID:31015410 FYPO:0001221 Fig1 and Fig1supp data
PMID:31015410 FYPO:0001221 Fig4 a,c
PMID:31015410 PBO:0107673 Fig 4a,c
PMID:31015410 PBO:0107678 Fig 1 (normal compaction)
PMID:31015410 PBO:0107677 Fig 3e
PMID:31015410 PBO:0107676 Fig3e suppression of nem1delta
PMID:31015410 PBO:0107675 Fig3d, OE lem2 supresses the increased NC ratio of rae1-167
PMID:31015410 FYPO:0001221 Fig3d
PMID:31015410 PBO:0097191 supp data Fig 1b,c
PMID:31015410 PBO:0097189 supp Fig 7 supression of lem2delta
PMID:31015410 FYPO:0001380 Fig 3c
PMID:31015410 PBO:0107674 Fig 3c
PMID:31015410 PBO:0107671 Fig3f
PMID:31015410 PBO:0107673 Fig 4a,c
PMID:31015410 PBO:0097188 Fig 4,b,c ENHANCER OF N/C ratio of lem2/rae1
PMID:31015410 FYPO:0001221 Fig4 a,c
PMID:31015410 GO:0031965 Supp Fig6
PMID:31015410 PBO:0107672 supp Fig6a
PMID:31015410 PBO:0107671 Fig3f
PMID:31015410 PBO:0107670 Fig3c,d, OE SUPRESSOR OF NEM1delta lem2 supresses the increased NC ratio of nem1 delta
PMID:31015410 PBO:0097191 Fig 3c
PMID:31015410 FYPO:0001221 Fig3a,b
PMID:31015410 PBO:0107669 Fig2 d,e,f,g,h supp fig6b
PMID:31015410 PBO:0107668 Fig2a,b,c
PMID:31015410 PBO:0097191 Fig 1a shows the lem2 chromatin binding domain is not required to restrict enhancement of the NC ratio of rae1-167
PMID:31015410 PBO:0097191 Fig 1a,b,c
PMID:31015410 PBO:0097191 Fig 1
PMID:31015410 FYPO:0001221 Fig1 supp data
PMID:31015410 FYPO:0001221 Fig1 supp data
PMID:31015410 FYPO:0001221 Fig1 supp data
PMID:31015410 FYPO:0001221 Fig1 supp data
PMID:31015410 FYPO:0001221 Fig1 supp data
PMID:31015410 FYPO:0001221 Fig1 supp data
PMID:31030285 PBO:0105857 fig S1
PMID:31030285 PBO:0105857 fig S1
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105859 fig S1
PMID:31030285 FYPO:0006978 Fig6
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105857 fig S1
PMID:31030285 FYPO:0004167 cell growth is faster than wild type in glycerol and ethanol medium
PMID:31030285 PBO:0105856 Coq4 protein is increased but Dlp1, Coq3, Coq5, and Coq8 are not
PMID:31030285 PBO:0105855 Coq4 protein is decreased but Dlp1, Coq3, Coq5 and Coq8 are not
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105865 not shown
PMID:31030285 PBO:0105864 Fig7
PMID:31030285 PBO:0105863 Fig7
PMID:31030285 PBO:0105862 Fig7
PMID:31030285 PBO:0105860 Fig7
PMID:31030285 PBO:0105861 Fig7
PMID:31030285 PBO:0105862 Fig7
PMID:31030285 PBO:0105863 Fig7
PMID:31030285 PBO:0105861 Fig7
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 FYPO:0000442 cell growth is slower than wild type in glycerol and ethanol medium
PMID:31030285 PBO:0105857 fig S1
PMID:31030285 PBO:0105857 fig S1
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 FYPO:0001420 fig8
PMID:31030285 PBO:0105858 fig S1
PMID:31030285 PBO:0105857 fig S1
PMID:31041892 PBO:0096763 Figure 4
PMID:31041892 PBO:0096768 Figure 5
PMID:31041892 FYPO:0005905 Figure 4; blt1∆/gef2∆ phenotype equivalent to blt1∆ or gef2∆ single mutants
PMID:31041892 FYPO:0005905 Figure 4; blt1∆/gef2∆ phenotype equivalent to blt1∆ or gef2∆ single mutants
PMID:31041892 PBO:0096767 Figure 3
PMID:31041892 PBO:0096767 Figure 3
PMID:31041892 PBO:0096764 Figure 2
PMID:31041892 PBO:0096764 Figure 2
PMID:31041892 PBO:0096766 Figure 3; blt1∆/gef2∆ phenotype equivalent to blt1∆ or gef2∆ single mutants
PMID:31041892 PBO:0096760 Figure 2; blt1∆/gef2∆ phenotype equivalent to blt1∆ or gef2∆ single mutants
PMID:31041892 PBO:0019202 fig1
PMID:31041892 PBO:0019202 fig1
PMID:31041892 PBO:0019202 fig1
PMID:31041892 FYPO:0004646 blt1∆/gef2∆ phenotype equivalent to blt1∆ or gef2∆ single mutants
PMID:31041892 PBO:0096765 Figure 3; blt1∆/gef2∆ phenotype equivalent to blt1∆ or gef2∆ single mutants
PMID:31041892 PBO:0096764 Figure 2; blt1∆/gef2∆ phenotype equivalent to blt1∆ or gef2∆ single mutants
PMID:31041892 FYPO:0005905 Figure 4; blt1∆/gef2∆ phenotype equivalent to blt1∆ or gef2∆ single mutants
PMID:31041892 PBO:0096763 Figure 4; blt1∆/gef2∆ phenotype equivalent to blt1∆ or gef2∆ single mutants
PMID:31041892 PBO:0096763 Figure 4
PMID:31041892 PBO:0096762 Figure 5
PMID:31041892 PBO:0096761 Figure 3
PMID:31041892 PBO:0096761 Figure 3
PMID:31041892 PBO:0096760 Figure 2
PMID:31041892 PBO:0096760 Figure 2
PMID:31053915 GO:1990748 detoxification
PMID:31053915 GO:1990748 detoxification
PMID:31053915 GO:0008171 catechol O-methyltransferase activity
PMID:31053915 GO:0010340 catechol O-methyltransferase activity (Vw I kept this as o-methytransferase since no report of catachols in fission yeast)
PMID:31072933 FYPO:0002060 figure S3
PMID:31072933 PBO:0100825 Figure 1G/ figur2
PMID:31072933 PBO:0100825 figure 1G
PMID:31072933 PBO:0100825 figure 1G
PMID:31072933 PBO:0100826 fig 2
PMID:31072933 PBO:0100829 figure 1G
PMID:31072933 PBO:0100830 figure 1G
PMID:31072933 PBO:0100831 figure 1G
PMID:31072933 PBO:0098320 figure 6c
PMID:31072933 PBO:0100832 figure 6c
PMID:31072933 PBO:0100832 figure 6c
PMID:31072933 PBO:0098320 figure 6c
PMID:31072933 PBO:0098320 figure 6c
PMID:31072933 PBO:0098320 figure 6c
PMID:31072933 PBO:0098320 figure 6c
PMID:31072933 PBO:0098320 figure 6c
PMID:31072933 PBO:0100832 figure S7A
PMID:31072933 PBO:0100832 figure S7A
PMID:31072933 PBO:0100832 figure S7A
PMID:31072933 PBO:0100832 figure S7A
PMID:31072933 PBO:0099134 (Rescued to WT level) Rad21 phosphorylation level in cohesin hinge cs mutants is rescued by Δwpl1, while the loss of the Rad21 protein level in cohesin hinge ts mutants cannot be rescued by Δwpl1
PMID:31072933 FYPO:0002061 figure 1c
PMID:31072933 FYPO:0002061 figure 1c
PMID:31072933 FYPO:0002061 figure 1c
PMID:31072933 FYPO:0002061 figure 1c
PMID:31072933 FYPO:0002060 figure 1c
PMID:31072933 FYPO:0002060 figure 1c
PMID:31072933 FYPO:0002060 figure 1c
PMID:31072933 FYPO:0002060 figure 1c
PMID:31072933 FYPO:0002060 figure 1c
PMID:31072933 FYPO:0002060 figure 1c
PMID:31072933 FYPO:0002060 figure 1c
PMID:31072933 FYPO:0002060 figure 1c
PMID:31072933 FYPO:0002060 figure 1c
PMID:31072933 FYPO:0002061 figure 1c
PMID:31072933 FYPO:0002060 figure 1c
PMID:31072933 FYPO:0002060 figure 1c
PMID:31072933 FYPO:0002060 figure 1c
PMID:31072933 FYPO:0002060 figure 1c
PMID:31072933 FYPO:0002060 figure 1c
PMID:31072933 FYPO:0002060 figure 1e
PMID:31072933 FYPO:0002060 figure 1e
PMID:31072933 FYPO:0002061 figure S8
PMID:31072933 FYPO:0002061 figure S8
PMID:31072933 FYPO:0001355 figure 5C
PMID:31072933 FYPO:0002061 Fig 5C
PMID:31072933 FYPO:0001355 figure 5C
PMID:31072933 FYPO:0002060 figure 4D-H
PMID:31072933 FYPO:0002060 figure 4D-H
PMID:31072933 FYPO:0002060 figure 4D-H
PMID:31072933 FYPO:0002060 figure 4 AB
PMID:31072933 FYPO:0002060 figure 4 AB
PMID:31072933 FYPO:0002060 figure 4 AB
PMID:31072933 FYPO:0002060 figure 4 AB
PMID:31072933 FYPO:0002060 figure 4 AB
PMID:31072933 FYPO:0002060 figure 1e
PMID:31072933 PBO:0100827 figure2
PMID:31072933 FYPO:0002060 figure 2C
PMID:31072933 FYPO:0002060 figure S3
PMID:31072933 FYPO:0002060 figure S3
PMID:31072933 FYPO:0002060 figure S3
PMID:31072933 FYPO:0002060 figure S3
PMID:31072933 FYPO:0002060 figure 3F
PMID:31072933 FYPO:0002060 figure 3A
PMID:31072933 FYPO:0002060 figure 3A
PMID:31072933 FYPO:0002060 figure 3A
PMID:31072933 FYPO:0002060 figure 3A
PMID:31072933 FYPO:0002060 figure S3
PMID:31072933 FYPO:0002060 figure S3
PMID:31072933 FYPO:0002060 figure S3
PMID:31072933 FYPO:0002060 figure S3
PMID:31072933 FYPO:0002060 figure S3
PMID:31072933 FYPO:0002060 figure S3
PMID:31072933 FYPO:0002060 figure S3
PMID:31072933 FYPO:0002060 figure S3
PMID:31072933 FYPO:0002060 figure S3
PMID:31072933 FYPO:0002060 figure S3
PMID:31072933 FYPO:0002060 figure S3
PMID:31072933 FYPO:0002060 figure S3
PMID:31072933 FYPO:0002060 figure S3
PMID:31072933 FYPO:0002060 figure 3A
PMID:31072933 FYPO:0002060 figure 3A
PMID:31072933 FYPO:0002060 figure 3A
PMID:31072933 FYPO:0002060 figure 3A
PMID:31072933 FYPO:0001355 figure 1c
PMID:31072933 FYPO:0001355 fig 3 B
PMID:31072933 FYPO:0001355 fig 3 B
PMID:31072933 FYPO:0001355 fig 3 B
PMID:31072933 FYPO:0002060 figure S4
PMID:31072933 FYPO:0002060 figure S4
PMID:31072933 FYPO:0002060 figure S4
PMID:31072933 FYPO:0002060 figure S3
PMID:31072933 FYPO:0002060 figure S3
PMID:31072933 FYPO:0002060 figure S3
PMID:31089172 FYPO:0002061 Figure 4A
PMID:31089172 FYPO:0002061 Fig. 6
PMID:31089172 FYPO:0002061 Fig. 6
PMID:31089172 FYPO:0002061 Fig. 6
PMID:31089172 FYPO:0006917 fig 6
PMID:31089172 PBO:0101954 Figure 6C-E
PMID:31089172 PBO:0097932 Figure 6C-E
PMID:31089172 PBO:0097932 Figure 5E
PMID:31089172 PBO:0097932 Figure 5E
PMID:31089172 PBO:0097932 Figure 5E
PMID:31089172 PBO:0097932 Figure 5E
PMID:31089172 FYPO:0002061 Fig. 5D and Supplementary Fig. S2A,C
PMID:31089172 FYPO:0002061 Fig. 5D and Supplementary Fig. S2A,C
PMID:31089172 FYPO:0002061 Fig. 5D and Supplementary Fig. S2A,C
PMID:31089172 FYPO:0002061 Fig. 5D and Supplementary Fig. S2A,C
PMID:31089172 PBO:0101953 Fig. 5B,C)
PMID:31089172 PBO:0101953 Fig. 5B,C)
PMID:31089172 PBO:0095688 Fig. 5B,C)
PMID:31089172 PBO:0095688 Fig. 5B,C)
PMID:31089172 FYPO:0002061 Figure 4A
PMID:31089172 PBO:0101952 fig 4
PMID:31089172 PBO:0101951 fig 4
PMID:31089172 PBO:0101948 fig 2 A/B
PMID:31089172 PBO:0101948 fig 2 A/B
PMID:31089172 PBO:0101949 fig 4
PMID:31089172 PBO:0097932 Figure 4AB
PMID:31089172 PBO:0097932 Figure 4AB
PMID:31089172 FYPO:0003268 fig 2 C/D
PMID:31089172 FYPO:0003268 fig 2 C/D
PMID:31089172 FYPO:0003268 fig 2 C/D
PMID:31089172 FYPO:0006917 fig 2 E
PMID:31089172 FYPO:0006917 fig 2 E
PMID:31089172 FYPO:0000324 fig 2 E
PMID:31089172 FYPO:0002061 Fig. 3A top
PMID:31089172 FYPO:0002061 Fig. 3
PMID:31089172 FYPO:0002061 Fig. 3
PMID:31089172 FYPO:0002060 Fig. 3
PMID:31089172 FYPO:0002060 Fig. 3
PMID:31089172 FYPO:0002061 Fig. 3
PMID:31089172 FYPO:0002060 Fig. 4A
PMID:31089172 FYPO:0002061 Figure 4A
PMID:31089172 FYPO:0002061 Figure 4A
PMID:31089172 FYPO:0002061 Figure 4A
PMID:31089172 FYPO:0002061 Figure 4A
PMID:31089172 FYPO:0002061 Figure 4A
PMID:31089172 PBO:0097932 Figure 4AB
PMID:31089172 PBO:0097932 Figure 4AB
PMID:31089172 PBO:0033572 Fig. 4A
PMID:31089172 PBO:0021821 Fig. 4A
PMID:31089172 PBO:0097932 Figure 4AB
PMID:31089172 PBO:0101950 Figure 4AB
PMID:31089172 PBO:0101949 Figure 4AB
PMID:31089172 PBO:0101949 Figure 4AB
PMID:31089172 PBO:0101949 Figure 4AB
PMID:31089172 FYPO:0006918 Figure 4AB
PMID:31089172 PBO:0024749 Fig. 4A
PMID:31089172 FYPO:0004833 Figure 4AB
PMID:31116668 PBO:0098990 1e
PMID:31116668 GO:0031520 1d (vw: localized by the secretory pathway)
PMID:31116668 FYPO:0006005 fig4
PMID:31116668 GO:0009992 fig 5
PMID:31116668 FYPO:0006899 5c
PMID:31131414 FYPO:0002019 Southern blot; same as rap1-7A single mutant
PMID:31149897 FYPO:0006921 Fig 6
PMID:31149897 FYPO:0000473 Figure 3A; increased spontaneous direct repeat recombination
PMID:31149897 FYPO:0006922 PCNA foci persist longer than normal, and form large bright patches before disappearing (Fig 2).
PMID:31149897 FYPO:0006920 elg1∆ exhibits reduced direct repeat recombination associated with replication fork collapse at the RTS1 replication fork barrier
PMID:31149897 FYPO:0000167 Fig 4
PMID:31149897 PBO:0097857 Fig 4
PMID:31149897 FYPO:0000167 Fig 4
PMID:31149897 FYPO:0000167 Fig 4; very small difference from fbh1delta alone
PMID:31149897 FYPO:0006921 Fig 6
PMID:31149897 FYPO:0006923 Fig 3
PMID:31149897 FYPO:0006924 Fig 5
PMID:31149897 FYPO:0006925 Fig 5
PMID:31178220 GO:1901612 SpTam41 interacts strongly with cardiolipin (CL)
PMID:31201205 GO:0005886 Fig.3
PMID:31201205 GO:0005886 Fig.3
PMID:31201205 GO:0005635 Fig.3
PMID:31201205 GO:0005635 Fig.3
PMID:31201205 GO:0005783 Fig.3
PMID:31201205 GO:0005783 Fig.3
PMID:31201205 FYPO:0001234 The resulting cwh43 pdt1Δ 201 double mutant partly recovered colony formation capacity at 36°C, compared to that of the 202 cwh43 single mutant (Fig. 2D).
PMID:31201205 FYPO:0002061 Fig. 2BC
PMID:31201205 PBO:0102632 Figure 4
PMID:31201205 FYPO:0002061 Fig. 2BC
PMID:31201205 FYPO:0002061 Fig. 2BC
PMID:31201205 FYPO:0002061 Fig. 2BC
PMID:31201205 FYPO:0002061 Fig. 2BC
PMID:31201205 PBO:0102632 Figure 4
PMID:31201205 FYPO:0002903 small viable
PMID:31201205 PBO:0096876 Figure 6
PMID:31201205 FYPO:0002903 Figure 5 (vw: changed to pear, descendent of spherical)
PMID:31201205 FYPO:0002251 Figure 5, (VW: I made this more specific- figure 1E (36) this phenotype in increased in the presence of magnesium
PMID:31201205 FYPO:0006660 figure 7B
PMID:31201205 FYPO:0006660 figure 7B
PMID:31201205 FYPO:0006935 figure 7B small, viable
PMID:31201205 FYPO:0002048 figure 7B small viable
PMID:31201205 FYPO:0002060 figure 7
PMID:31201205 PBO:0102635 Figure 6
PMID:31201205 PBO:0096875 Figure 6
PMID:31201205 PBO:0102634 Figure 4
PMID:31201205 PBO:0102634 Figure 4
PMID:31201205 PBO:0102633 Figure 4
PMID:31201205 PBO:0102633 Figure 4
PMID:31201205 PBO:0102633 Figure 4
PMID:31206516 FYPO:0007479 Loss of Clr4 abolished red-white variegation in the epe1Δ ade6-m210 background, indicating a requirement for the H3K9 methyltransferase Clr4. clr3 and sir2, which encode his- tone deacetylases, are required for self-propagation of heterochromatin [30–34]. The introduc- tion of clr3Δ or sir2Δ into the epe1Δ background also induced a uniform red phenotype. Similarly, loss of Swi6 suppressed variegation.
PMID:31206516 PBO:0110796 The H297A substitution slightly impaired the interaction (S4G Fig), which was confirmed by the results of a bait-prey exchange experiment. We performed co-immunoprecipitation analysis of Swi6 with Epe1H297A. Con- sistent with the results of yeast two-hybrid assay, the Epe1H297A mutant interacted with Swi6 with a slightly lower efficiency than wild-type Epe1 (Fig 4H).
PMID:31206516 PBO:0110797 (vw: variegated population) These results suggested that the white phenotype of W70 was not linked to otr1R::ade6+. The re-appearance of red colonies from epe1Δ W70 cells (Fig 1C) suggested that the white phenotype was due to epigenetic rather than genetic alterations.
PMID:31206516 PBO:0110798 Since loss of Epe1 increases H3K9me levels at subtel1L and 2L [23, 24], we hypothesized that the ade5 gene was silenced by ectopi- cally deposited H3K9me, which arrested red pigment formation.
PMID:31206516 FYPO:0007479 Loss of Clr4 abolished red-white variegation in the epe1Δ ade6-m210 background, indicating a requirement for the H3K9 methyltransferase Clr4. clr3 and sir2, which encode his- tone deacetylases, are required for self-propagation of heterochromatin [30–34]. The introduc- tion of clr3Δ or sir2Δ into the epe1Δ background also induced a uniform red phenotype. Similarly, loss of Swi6 suppressed variegation.
PMID:31206516 PBO:0110800 Unlike loss of Epe1, the H297A mutation generated few pink/white colonies in the ade6-m210 background (Fig 4A); indeed, 96.2% of Epe1H297A cells formed WT-like red colonies, while 61.7% of epe1Δ cells did.
PMID:31206516 GO:0033696 Thus, we concluded that ectopic heterochromatin-mediated repression of ade5 caused the white phenotype of the epe1Δ W70 strain.
PMID:31206516 PBO:0110799 We next examined the requirement for Ago1 and Taz1 for epe1Δ-induced variegation, because both factors are involved in subtelomeric constitutive heterochromatin formation [5]. epe1Δ ago1Δ, epe1Δ taz1Δ, and epe1Δ ago1Δ taz1Δ strains displayed red-white variegated phe- notypes (S2A and S2B Fig), indicating that neither RNAi nor Taz1 was essential for epe1Δ- induced variegation.
PMID:31206516 PBO:0110801 We introduced Epe1ΔN into ade6-m210 cells to examine the effect of the ΔN mutation on the suppression of ectopic heterochromatin formation. Epe1ΔN cells formed pink/white colonies with a slightly lower frequency than epe1Δ cells (Fig 4K), indicating that the NTA domain contributed to the suppression of ectopic heterochromatin-mediated variegation.
PMID:31206516 FYPO:0002876 We found that deletion of the N-terminal 171 amino acids (Epe1ΔN) abolished transcriptional activation by Epe1 and the N-terminal 208 amino acids (Epe1N208) activated transcription of the HIS3 reporter independently of JmjC (Fig 4I), suggesting that the N-terminal 171 amino acids region is required for the transcriptional activation activity.
PMID:31206516 FYPO:0007479 However, how Epe1 finds target sites to prevent ectopic heterochromatin formation is unknown. Since Epe1 physically interacts with the bromodomain protein Bdf2, which is required for heterochromatin-euchromatin boundary formation [14], we predicted that Bdf2 would recruit Epe1 to the target sites. However, bdf2Δ cells showed an almost uniform red phenotype in the ade6-m210 background (S4H Fig), suggesting that Bdf2 was not related to suppression of variegation and ectopic heterochromatin formation.
PMID:31206516 PBO:0110802 However, consistent with the previous report [13], the C-terminal half of Epe1 (487–948 amino acids region) interacted with Swi6 in the yeast two-hybrid system, but the N-terminal half (1–486) did not (S4I Fig).
PMID:31206516 PBO:0110803 However, consistent with the previous report [13], the C-terminal half of Epe1 (487–948 amino acids region) interacted with Swi6 in the yeast two-hybrid system, but the N-terminal half (1–486) did not (S4I Fig).
PMID:31206516 PBO:0110799 We next examined the requirement for Ago1 and Taz1 for epe1Δ-induced variegation, because both factors are involved in subtelomeric constitutive heterochromatin formation [5]. epe1Δ ago1Δ, epe1Δ taz1Δ, and epe1Δ ago1Δ taz1Δ strains displayed red-white variegated phe- notypes (S2A and S2B Fig), indicating that neither RNAi nor Taz1 was essential for epe1Δ- induced variegation.
PMID:31206516 PBO:0110799 We next examined the requirement for Ago1 and Taz1 for epe1Δ-induced variegation, because both factors are involved in subtelomeric constitutive heterochromatin formation [5]. epe1Δ ago1Δ, epe1Δ taz1Δ, and epe1Δ ago1Δ taz1Δ strains displayed red-white variegated phe- notypes (S2A and S2B Fig), indicating that neither RNAi nor Taz1 was essential for epe1Δ- induced variegation.
PMID:31206516 FYPO:0007479 Loss of Clr4 abolished red-white variegation in the epe1Δ ade6-m210 background, indicating a requirement for the H3K9 methyltransferase Clr4. clr3 and sir2, which encode his- tone deacetylases, are required for self-propagation of heterochromatin [30–34]. The introduc- tion of clr3Δ or sir2Δ into the epe1Δ background also induced a uniform red phenotype. Similarly, loss of Swi6 suppressed variegation.
PMID:31206516 FYPO:0007479 Loss of Clr4 abolished red-white variegation in the epe1Δ ade6-m210 background, indicating a requirement for the H3K9 methyltransferase Clr4. clr3 and sir2, which encode his- tone deacetylases, are required for self-propagation of heterochromatin [30–34]. The introduc- tion of clr3Δ or sir2Δ into the epe1Δ background also induced a uniform red phenotype. Similarly, loss of Swi6 suppressed variegation.
PMID:31206516 FYPO:0007479 Loss of Clr4 abolished red-white variegation in the epe1Δ ade6-m210 background, indicating a requirement for the H3K9 methyltransferase Clr4. clr3 and sir2, which encode his- tone deacetylases, are required for self-propagation of heterochromatin [30–34]. The introduc- tion of clr3Δ or sir2Δ into the epe1Δ background also induced a uniform red phenotype. Similarly, loss of Swi6 suppressed variegation.
PMID:31206516 FYPO:0007479 Loss of Clr4 abolished red-white variegation in the epe1Δ ade6-m210 background, indicating a requirement for the H3K9 methyltransferase Clr4. clr3 and sir2, which encode his- tone deacetylases, are required for self-propagation of heterochromatin [30–34]. The introduc- tion of clr3Δ or sir2Δ into the epe1Δ background also induced a uniform red phenotype. Similarly, loss of Swi6 suppressed variegation.
PMID:31206516 FYPO:0007479 Loss of Clr4 abolished red-white variegation in the epe1Δ ade6-m210 background, indicating a requirement for the H3K9 methyltransferase Clr4. clr3 and sir2, which encode his- tone deacetylases, are required for self-propagation of heterochromatin [30–34]. The introduc- tion of clr3Δ or sir2Δ into the epe1Δ background also induced a uniform red phenotype. Similarly, loss of Swi6 suppressed variegation.
PMID:31206516 FYPO:0007479 Loss of Clr4 abolished red-white variegation in the epe1Δ ade6-m210 background, indicating a requirement for the H3K9 methyltransferase Clr4. clr3 and sir2, which encode his- tone deacetylases, are required for self-propagation of heterochromatin [30–34]. The introduc- tion of clr3Δ or sir2Δ into the epe1Δ background also induced a uniform red phenotype. Similarly, loss of Swi6 suppressed variegation.
PMID:31206516 PBO:0110795 FLAG ChIP analysis revealed that H297A reduced appreciably Epe1 enrichment on centromeric dg repeats and IRC3 (Fig 4G), a centro- meric boundary sequence where Epe1 accumulates to a high level [12, 14
PMID:31217286 PBO:0112024 Fig. 6D
PMID:31217286 PBO:0112020 Fig. 4C
PMID:31217286 FYPO:0008169 Fig. 6A and B
PMID:31217286 PBO:0112011 Fig. S6
PMID:31217286 PBO:0112012 Fig. 6D
PMID:31217286 PBO:0112014 Fig. S1E and F
PMID:31217286 PBO:0112015 Fig. 2
PMID:31217286 PBO:0112016 Fig. 2
PMID:31217286 PBO:0112017 Fig. 3
PMID:31217286 PBO:0112018 Fig. 4A
PMID:31217286 PBO:0112019 Fig. 4B
PMID:31217286 PBO:0112010 Fig. 1
PMID:31217286 FYPO:0007677 Fig. 1C
PMID:31217286 GO:0005783 Fig. S1D
PMID:31217286 PBO:0112021 Fig. 6C
PMID:31217286 PBO:0112022 Fig. 6C
PMID:31217286 PBO:0112023 Fig. 5A
PMID:31217286 PBO:0112011 Fig. 1D
PMID:31217286 PBO:0112012 Phenotype of Erg25 overexpression is suppressed by Erg11 inhibition. Fig. 1E
PMID:31217286 PBO:0112013 Fig. S1C
PMID:31217286 PBO:0112013 Fig. S1C
PMID:31239353 FYPO:0007044 fig1
PMID:31239353 GO:0004035 Figure 1A
PMID:31239353 FYPO:0007044 fig1
PMID:31239353 FYPO:0007044 10-100 micromolar
PMID:31239353 PBO:0095247 figure 4 hat although processing of Pho8 is dependent upon the growth phase of cells, zinc is the major factor that limits Pho8 activity in vivo
PMID:31239353 PBO:0095249 Figure 1B and 1C
PMID:31239353 PBO:0095248 abolished ?
PMID:31239353 PBO:0095248 fig1 abolished?
PMID:31239353 FYPO:0007045 fig1
PMID:31239353 PBO:0095247 figure 4 hat although processing of Pho8 is dependent upon the growth phase of cells, zinc is the major factor that limits Pho8 activity in vivo
PMID:31239353 PBO:0095246 Pho8 abundance is increased in high zinc in a loz1 deletion strain (Figure 2B and 2C)
PMID:31239353 PBO:0095245 consistent with Loz1 facilitating the repression of pho8 gene expression in high zinc (Figure 2A)
PMID:31239353 FYPO:0007048 figure 7
PMID:31239353 FYPO:0007047 figure 7
PMID:31239353 FYPO:0007042 reduced during conditions of zinc shock (Figure 8 and Figure 9). (as Pho8 binds its zinc cofactors inside of the secretory pathway, it activity is dependent upon zinc transporters that supply zinc ions to the secretory pathway
PMID:31239353 PBO:0095242 pho8 transcript and protein levels are increased in high zinc BUT ZINC DEPENDENT CHAnges are independent of transcript levels
PMID:31239353 PBO:0095251 Figure 5D
PMID:31239353 PBO:0095250 Figure 5D
PMID:31239353 PBO:0095243 Figure 1B and 1C
PMID:31239353 PBO:0095244 Figure 2B
PMID:31239353 FYPO:0007043 figure 5B
PMID:31239353 FYPO:0007043 Figure 5B
PMID:31239353 GO:0106219 (DIRECTLY_ACTIVATES pho8 GO:0004035) As zinc did not affect Pho8 stability, processing, or dimerization, we hypothesized that the activity of Pho8 is directly affected by cellular zinc status. .. .....Taken together these results are consistent with yeast maintaining an inactive 5 Zinc-dependent alkaline phosphatase activity pool of Pho8 in low zinc, which can be rapidly activated as soon as zinc is available.
PMID:31239353 FYPO:0007041 figure 8
PMID:31239353 FYPO:0007048 figure 7
PMID:31239353 FYPO:0007044 reduced alkaline phosphatase activity and Pho8 dimerization (assayed via an EGS cross linking experiment - see Figures 6C and 6D)
PMID:31239353 FYPO:0007044 reduced alkaline phosphatase activity and Pho8 dimerization (assayed via an EGS cross linking experiment - see Figures 6C and 6D)
PMID:31239353 GO:0004035 Figure 1A Zinc-dependen
PMID:31257143 FYPO:0004318 figure 2D
PMID:31257143 PBO:0101478 Figure 2B demonstrates robust arres 3b 80% 12 hours
PMID:31257143 FYPO:0004318 figure 2d
PMID:31257143 FYPO:0004318 figure 2d
PMID:31257143 PBO:0101483 Figure S4
PMID:31257143 FYPO:0002638 Figure 2B demonstrates robust arres
PMID:31257143 PBO:0101482 Figure S4
PMID:31257143 PBO:0101478 3b 80% 12 hours
PMID:31257143 FYPO:0002638 Figures S3B and S3C
PMID:31257143 FYPO:0002638 Figures S3B and S3D
PMID:31260531 PBO:0103435 Rep2 locates SAGA complex at MBF-regulated promoters.
PMID:31260531 PBO:0103437 chromatin association at MCBs is part of positive regulation of G1/S transition of mitotic cell cycle
PMID:31269446 FYPO:0002664 18 °C
PMID:31269446 GO:0090052 si independent pericentric heterochromatin formation CPF and RNAi Act in Parallel to Assemble Centromeric Heterochromatin
PMID:31269446 GO:0090052 si independent pericentric heterochromatin formation CPF and RNAi Act in Parallel to Assemble Centromeric Heterochromatin
PMID:31269446 FYPO:0002173 18 °C
PMID:31269446 FYPO:0003049 18 °C
PMID:31269446 FYPO:0003049 18 °C
PMID:31269446 PBO:0111618 non-canonical termination sites
PMID:31269446 FYPO:0000080 18 °C
PMID:31269446 FYPO:0000080 18 °C
PMID:31269446 FYPO:0002664 18 °C
PMID:31269446 FYPO:0007213 18 °C
PMID:31269446 FYPO:0003049 18 °C
PMID:31269446 FYPO:0002173 18 °C
PMID:31269446 FYPO:0000080 18 °C
PMID:31269446 FYPO:0002664 18 °C
PMID:31269446 FYPO:0007213 18 °C
PMID:31269446 PBO:0111618 non-canonical termination sites
PMID:31269446 FYPO:0003049 18 °C
PMID:31269446 PBO:0111618 non-canonical termination sites
PMID:31269446 FYPO:0007213 18 °C
PMID:31276301 PBO:0106675 Fig 4b
PMID:31276301 FYPO:0005706 Table 2 Figures 5a–d and S2)
PMID:31276301 FYPO:0005880 fig 6
PMID:31276301 FYPO:0000733 Furthermore, abnormally elon- gated cytoplasmic and spindle MTs were frequently observed in these cells (Figure 6).
PMID:31276301 PBO:0106671 Fig 4a
PMID:31276301 PBO:0106672 fig 4d
PMID:31276301 PBO:0106673 fig. 4e
PMID:31276301 PBO:0106674 fig. 4e
PMID:31276301 FYPO:0003190 (Table 3)
PMID:31276301 FYPO:0002060 Figure S1a
PMID:31276301 FYPO:0003702 Figure S1a
PMID:31276301 FYPO:0003717 Figure S1a
PMID:31276301 FYPO:0004652 Figure S1a
PMID:31276301 FYPO:0004097 Figure S1a
PMID:31276301 FYPO:0002215 fig 6
PMID:31276301 FYPO:0004429 Furthermore, abnormally elon- gated cytoplasmic and spindle MTs were frequently observed in these cells (Figure 6).
PMID:31276301 FYPO:0007182 Table 3
PMID:31276301 PBO:0106677 Fig 4e
PMID:31276301 PBO:0106676 Fig 4a
PMID:31276301 FYPO:0004622 Figure 7b
PMID:31276588 FYPO:0002059 Figure 1E
PMID:31276588 PBO:0094771 Figure 1F
PMID:31276588 PBO:0094771 Figure 1F.
PMID:31276588 PBO:0094738 Figure 1C
PMID:31276588 FYPO:0000047 Figure 1B
PMID:31276588 PBO:0094738 Figure 1C
PMID:31276588 FYPO:0000047 Figure 1B
PMID:31276588 PBO:0094774 Figure 1D
PMID:31276588 FYPO:0000080 Figure 2C
PMID:31276588 PBO:0094771 Figure 2A
PMID:31276588 FYPO:0002061 Figure 2C
PMID:31276588 PBO:0094773 Figure 1D
PMID:31276588 FYPO:0000080 Figure 2C
PMID:31276588 PBO:0094774 Figure 1D
PMID:31276588 FYPO:0000080 Figure 1B
PMID:31276588 PBO:0098248 Figure 1C
PMID:31276588 FYPO:0002061 Figure 2C
PMID:31276588 FYPO:0002061 Figure 2C
PMID:31276588 GO:0180034 lncRNA. Specifically, it is hypothesized that loss of the Ser7-PO4 or Ser5-PO4 marks leads to precocious termination of prt lncRNA transcription prior to the pho1 promoter and loss of the Thr4-PO4 mark reduces termination and hence increases transcription across the pho1 promoter (8) (Figure 1A).
PMID:31276588 PBO:0094772 Figure 1D
PMID:31276588 PBO:0094773 Figure 1D
PMID:31276588 PBO:0098285 Octo phosphatase IP8 is a relevant substrate for the Aps1 pyrophos- phatase with respect to phosphate homeostasis.
PMID:31276588 FYPO:0001357 reporter system
PMID:31276588 FYPO:0002061 Figure 2C
PMID:31276588 FYPO:0002061 Figure 2C
PMID:31276588 FYPO:0002059 Figure 1E
PMID:31276588 PBO:0111666 target genes pho1, pho84, and tgp1
PMID:31276588 FYPO:0002061 Figure 2C
PMID:31276588 FYPO:0002061 Figure 2C
PMID:31276588 PBO:0111667 target genes repressing lncRNAd
PMID:31276588 FYPO:0002061 Figure 2C
PMID:31276588 FYPO:0000080 Figure 1B
PMID:31276588 PBO:0098248 Figure 1C
PMID:31276588 PBO:0094772 Figure 1D
PMID:31278118 PBO:0097427 fig 1D/E
PMID:31278118 FYPO:0002336 fig7
PMID:31278118 PBO:0097416 table 1
PMID:31278118 PBO:0097416 table1
PMID:31278118 PBO:0097431 However, the localization of Pds5 to euchromatic locations was unaffected in hetero- chromatin-deficient cells (Figure 5E)
PMID:31278118 FYPO:0002336 Figure 6B
PMID:31278118 PBO:0097429 cells revealed that H3K9me2 was notably decreased at cen- tromeres and telomeres in pds5D (Figure 3, A and B).
PMID:31278118 PBO:0097432 ue to their antagonistic roles in cohesion establish- ment, the lethality of eso1D can be suppressed by deletion of wpl1 (Feytout et al. 2011; Kagami et al. 2011). Whereas wpl1D did not show defects in heterochromatic silencing, the eso1D wpl1D double mutant showed derepression of mat2P::ura4+ and haploid meiosis similar to pds5D cells (Figure 6A)
PMID:31278118 FYPO:0002827 Figure S5 Moreover, when we deleted pds5 in cells lacking Eso1 and/or Wpl1, the levels of haploid meiosis displayed by double or triple mutants were comparable to that of single-mutant pds5D
PMID:31278118 PBO:0097430 cells revealed that H3K9me2 was notably decreased at cen- tromeres and telomeres in pds5D (Figure 3, A and B).
PMID:31278118 PBO:0097426 fig 1D/E
PMID:31278118 PBO:0097431 However, the localization of Pds5 to euchromatic locations was unaffected in hetero- chromatin-deficient cells (Figure 5E)
PMID:31278118 FYPO:0002336 Figure 6B
PMID:31278118 FYPO:0002827 Figure S5
PMID:31278118 PBO:0097416 ue to their antagonistic roles in cohesion establish- ment, the lethality of eso1D can be suppressed by deletion of wpl1 (Feytout et al. 2011; Kagami et al. 2011). Whereas wpl1D did not show defects in heterochromatic silencing, the eso1D wpl1D double mutant showed derepression of mat2P::ura4+ and haploid meiosis similar to pds5D cells (Figure 6A)
PMID:31278118 FYPO:0002336 Figure 6B
PMID:31278118 PBO:0097420 fig 2B (Figure S1B and Table S2). This variegated staining pattern is a char- acteristic of mutants that are known to be defective in the main- tenance of heterochromatin and that show a reduction, but not loss, of H3K9me levels (Taneja et al. 2017). Indeed, ChIP anal- yses of H3K9 di- and trimethylation (H3K9me2/3) showed a reduction in heterochromatic H3K9 marks at or near mat2P in pds5D (Figure 2B).
PMID:31278118 PBO:0097422 Fig 5 B vw: moved pds5 to assayed target
PMID:31278118 FYPO:0002336 Figure 6A)
PMID:31278118 PBO:0097423 fig1 d
PMID:31278118 PBO:0097425 fig 1D/E
PMID:31278118 FYPO:0002336 fig7
PMID:31278118 PBO:0095651 Compared to the single ago1D or pds5D deletion mutants, the ago1D pds5D double mutant showed severe loss-of-silencing of Kint2::ura4+ (Figure S2C).
PMID:31278118 FYPO:0007376 Figure 4A https://github.com/pombase/fypo/issues/3693
PMID:31285271 FYPO:0001234 fig4h
PMID:31285271 FYPO:0003125 fig4
PMID:31285271 PBO:0099579 2d
PMID:31285271 PBO:0099580 2d
PMID:31285271 PBO:0099581 2d
PMID:31285271 GO:0016282 Fig.2 Asc1 associates with polysomes.
PMID:31285271 GO:0001731 cytoplasmic translation is a parent to this term
PMID:31285271 PBO:0099585 3e
PMID:31285271 PBO:0037494 Fig5. Asc1 colocalized with stress granule proteins in response to heat shock.
PMID:31285271 PBO:0099575 1d
PMID:31285271 PBO:0099576 1e
PMID:31285271 PBO:0099577 2d
PMID:31285271 PBO:0099578 2d
PMID:31285271 PBO:0099584 3e
PMID:31285271 PBO:0099583 3a
PMID:31285271 PBO:0099582 3a
PMID:31285271 PBO:0099586 6f
PMID:31285271 PBO:0099251 6
PMID:31285271 FYPO:0000046 fig4h
PMID:31289327 FYPO:0000012 5
PMID:31289327 FYPO:0002019 S2
PMID:31289327 FYPO:0002019 S2
PMID:31289327 FYPO:0002019 S2
PMID:31289327 FYPO:0002019 S2
PMID:31289327 PBO:0100058 4a
PMID:31289327 FYPO:0000012 5
PMID:31294478 FYPO:0007013 2b
PMID:31294478 PBO:0098170 coincident with 5S_rRNA_gene NTR https://github.com/The-Sequence-Ontology/SO-Ontologies/issues/472
PMID:31294478 PBO:0098170 coincident with 5S_rRNA_gene NTR https://github.com/The-Sequence-Ontology/SO-Ontologies/issues/472
PMID:31294478 PBO:0098170 coincident with 5S_rRNA_gene NTR https://github.com/The-Sequence-Ontology/SO-Ontologies/issues/472
PMID:31294478 PBO:0098170 coincident with 5S_rRNA_gene NTR https://github.com/The-Sequence-Ontology/SO-Ontologies/issues/472
PMID:31294478 PBO:0106252 AL fig 4. vincent: We have assayed the presence of read-through transcripts at SPATRNAPRO.02, SPCTRNAARG.10, SPBTRNATYR.04, SPBTRNAARG.05, SPCTRNASER.09, SPCTRNATHR.10 using strand-specific RT-qPCR. We also used Northern blots and 3' RACE to confirm the presence of read-through transcripts at SPATRNAPRO.02.
PMID:31294478 PBO:0106254 AL fig 4. vincent: We have assayed the presence of read-through transcripts at SPATRNAPRO.02, SPCTRNAARG.10, SPBTRNATYR.04, SPBTRNAARG.05, SPCTRNASER.09, SPCTRNATHR.10 using strand-specific RT-qPCR. We also used Northern blots and 3' RACE to confirm the presence of read-through transcripts at SPATRNAPRO.02.
PMID:31294478 FYPO:0001134 2b
PMID:31294478 FYPO:0007012 2b
PMID:31294478 FYPO:0007013 2b
PMID:31294478 FYPO:0007014 2b
PMID:31294478 FYPO:0007013 2b
PMID:31294478 FYPO:0001134 2b
PMID:31294478 FYPO:0007012 2b
PMID:31294478 PBO:0106267 3
PMID:31294478 PBO:0106253 AL fig 4. vincent: We have assayed the presence of read-through transcripts at SPATRNAPRO.02, SPCTRNAARG.10, SPBTRNATYR.04, SPBTRNAARG.05, SPCTRNASER.09, SPCTRNATHR.10 using strand-specific RT-qPCR. We also used Northern blots and 3' RACE to confirm the presence of read-through transcripts at SPATRNAPRO.02.
PMID:31294478 PBO:0106272 4
PMID:31294478 PBO:0106271 4
PMID:31294478 PBO:0106270 4
PMID:31294478 PBO:0106269 4
PMID:31294478 PBO:0106268 3
PMID:31294478 FYPO:0002061 Figure 5B
PMID:31294478 PBO:0098170 COINCIDENT WITH 5S_rRNA_gene NTR https://github.com/The-Sequence-Ontology/SO-Ontologies/issues/472
PMID:31294478 PBO:0106247 fig 1b We have shown using ChIP-seq experiments that Sen1 associates with all types of RNA polymerase III-transcribed genes. This includes tRNA_genes, 5S rRNA_genes, snu6 and srp7 but not the TFIIIC-bound COC sites.
PMID:31294478 PBO:0098562 fig 1 A and F
PMID:31294478 PBO:0106249 AL fig 4. and 5c vincent: We have assayed the presence of read-through transcripts at SPATRNAPRO.02, SPCTRNAARG.10, SPBTRNATYR.04, SPBTRNAARG.05, SPCTRNASER.09, SPCTRNATHR.10 using strand-specific RT-qPCR. We also used Northern blots and 3' RACE to confirm the presence of read-through transcripts at SPATRNAPRO.02.
PMID:31294478 PBO:0106250 AL fig 4. and 5c vincent: We have assayed the presence of read-through transcripts at SPATRNAPRO.02, SPCTRNAARG.10, SPBTRNATYR.04, SPBTRNAARG.05, SPCTRNASER.09, SPCTRNATHR.10 using strand-specific RT-qPCR. We also used Northern blots and 3' RACE to confirm the presence of read-through transcripts at SPATRNAPRO.02.
PMID:31294478 PBO:0106251 AL fig 4. and 5c vincent: We have assayed the presence of read-through transcripts at SPATRNAPRO.02, SPCTRNAARG.10, SPBTRNATYR.04, SPBTRNAARG.05, SPCTRNASER.09, SPCTRNATHR.10 using strand-specific RT-qPCR. We also used Northern blots and 3' RACE to confirm the presence of read-through transcripts at SPATRNAPRO.02.
PMID:31294478 PBO:0106252 AL fig 4. and 5c vincent: We have assayed the presence of read-through transcripts at SPATRNAPRO.02, SPCTRNAARG.10, SPBTRNATYR.04, SPBTRNAARG.05, SPCTRNASER.09, SPCTRNATHR.10 using strand-specific RT-qPCR. We also used Northern blots and 3' RACE to confirm the presence of read-through transcripts at SPATRNAPRO.02.
PMID:31294478 PBO:0106253 AL fig 4. and 5c vincent: We have assayed the presence of read-through transcripts at SPATRNAPRO.02, SPCTRNAARG.10, SPBTRNATYR.04, SPBTRNAARG.05, SPCTRNASER.09, SPCTRNATHR.10 using strand-specific RT-qPCR. We also used Northern blots and 3' RACE to confirm the presence of read-through transcripts at SPATRNAPRO.02.
PMID:31294478 PBO:0106254 AL fig 4. and 5c vincent: We have assayed the presence of read-through transcripts at SPATRNAPRO.02, SPCTRNAARG.10, SPBTRNATYR.04, SPBTRNAARG.05, SPCTRNASER.09, SPCTRNATHR.10 using strand-specific RT-qPCR. We also used Northern blots and 3' RACE to confirm the presence of read-through transcripts at SPATRNAPRO.02.
PMID:31294478 PBO:0106255 AL fig 4. and 5c vincent: We have assayed the presence of read-through transcripts at SPATRNAPRO.02, SPCTRNAARG.10, SPBTRNATYR.04, SPBTRNAARG.05, SPCTRNASER.09, SPCTRNATHR.10 using strand-specific RT-qPCR. We also used Northern blots and 3' RACE to confirm the presence of read-through transcripts at SPATRNAPRO.02.
PMID:31294478 GO:0030874 ChIP-qPCR of Dbl8 indicates that Dbl8 is enriched at the rDNA and at highly-expressed RNAPII-transcribed genes
PMID:31294478 PBO:0106257 2c, 5d
PMID:31294478 PBO:0106258 2c, 5d
PMID:31294478 PBO:0106259 2c, 5d
PMID:31294478 PBO:0106260 2c, 5d
PMID:31294800 GO:0035925 UAAU motif
PMID:31315658 FYPO:0006518 Additional file 1: Fig. S1b, c
PMID:31315658 FYPO:0006518 Additional file 1: Fig. S1b, c
PMID:31315658 FYPO:0006518 (Fig. 1c)
PMID:31315658 FYPO:0006518 Additional file 1: Fig. S1b, c
PMID:31315658 FYPO:0007471 n sharp contrast, the H3K9me2 levels remained constant in leo1∆ cells throughout G0 phase (Fig. 2; Additional file 2: Fig. S2
PMID:31332096 FYPO:0004372 reduced chk1 phosphorylation
PMID:31332096 PBO:0101079 elimination of Rad3-specific phosphorylation
PMID:31341193 PBO:0107611 Increased co-localization with Cfr1
PMID:31341193 PBO:0107628 fig1
PMID:31341193 PBO:0107628 fig1
PMID:31341193 GO:0005770 Fig1 (major)
PMID:31341193 GO:0005802 Fig1 (minor)
PMID:31341193 PBO:0107623 isp6 delta supresses the abnormal Vps10 processing detected in vps35 delta strain
PMID:31341193 GO:0000328 Microscopy
PMID:31341193 GO:0031906 Microscopy
PMID:31341193 PBO:0107623 isp6 delta supresses the abnormal Vps10 processing detected in ent3 delta gga21 delta gga22 delta strain
PMID:31341193 PBO:0107623 isp6 delta suppresses Vps10 abnormal processing observed in ent3 delta gga22 delta strain
PMID:31341193 PBO:0107623 isp6 delta supresses the abnormal Vps10 proessing detected in gga21 delta gga22 delta strain
PMID:31341193 FYPO:0001355 Reduced growth on 0.6M KCl plates
PMID:31341193 FYPO:0001355 Reduced growth at 37ºC on YES agar plates
PMID:31341193 PBO:0107622 fig 7
PMID:31341193 PBO:0107621 fig 7 Syb1 co-localizes with late endosome markers
PMID:31341193 PBO:0107620 Dot-Blot test
PMID:31341193 PBO:0107617 Increased co-localization with Cfr1
PMID:31341193 PBO:0107616 Reduced co-localization with the PI3P probe Cherry-FYVE
PMID:31341193 PBO:0107614 Reduced co-localization with the PI3P probe Cherry-FYVE
PMID:31341193 PBO:0107613 FIg 3 Increased co-localization with Cfr1
PMID:31341193 GO:0005802 Co-localization with TGN marker
PMID:31341193 PBO:0107612 Reduced co-localyzation with the PI3P probe Cherry-FYVE
PMID:31341193 PBO:0107611 fig 1 Increased colocalization with Cfr1
PMID:31341193 FYPO:0005947 28ºC
PMID:31341193 FYPO:0000674 37ºC
PMID:31341193 FYPO:0007055 Evaluated by measuring the size of Vps10-GFP foci
PMID:31341193 PBO:0107609 Dot-Blot assay
PMID:31341193 PBO:0107608 fig5
PMID:31341193 PBO:0107606 fig 1d
PMID:31341193 PBO:0107607 Fig 1 a-c
PMID:31341193 PBO:0107606 Fig 1 a-c
PMID:31341193 GO:0032588 Microscopy
PMID:31341193 PBO:0107631 this is in a mutant but I guess it occurs physiologicall?
PMID:31341193 PBO:0107629 fig1
PMID:31341193 PBO:0107629 fig1
PMID:31341193 PBO:0107608 fig5
PMID:31341193 PBO:0107628 fig1
PMID:31350787 FYPO:0000962 fig1
PMID:31350787 PBO:0095092 fig4B
PMID:31350787 FYPO:0001409 fig1
PMID:31350787 PBO:0093797 "fig 1A they say it is dramatically reduced....between med/low severity... ""dramatically reduced on glycerol medium, which requires high mitochondrial respiratory activity at 30 °C"""
PMID:31350787 FYPO:0001934 fig2A The Dmti2 mutant was not able to grow at all on medium containing glycerol at the restrictive temperature of 37 °C
PMID:31350787 FYPO:0005825 figb
PMID:31350787 PBO:0093576 fig1
PMID:31350787 GO:0005759 Fig. 3
PMID:31350787 GO:0005759 Fig. 3
PMID:31350787 PBO:0093578 "fig 1A """
PMID:31350787 PBO:0094264 "fig 1A """
PMID:31350787 PBO:0095091 "fig 1A """
PMID:31350787 FYPO:0007121 fig1
PMID:31350787 FYPO:0001164 fig1
PMID:31350787 FYPO:0001409 fig1
PMID:31350787 FYPO:0001164 fig1
PMID:31350787 FYPO:0007122 fig6
PMID:31350787 FYPO:0004529 fig5
PMID:31350787 FYPO:0002056 fig5
PMID:31366733 PBO:0103309 fig7
PMID:31366733 PBO:0103309 fig7
PMID:31366733 PBO:0103309 fig7
PMID:31366733 PBO:0103309 fig7
PMID:31366733 PBO:0103309 fig7
PMID:31371524 PBO:0107535 figure 6
PMID:31371524 GO:0005515 inhinits hhf4 binding
PMID:31371524 PBO:0107533 figure 2
PMID:31371524 PBO:0107534 figure 2
PMID:31371524 PBO:0107534 figure 2
PMID:31371524 PBO:0107533 figure 4
PMID:31371524 PBO:0107536 figure 6
PMID:31427431 FYPO:0000069 2f
PMID:31427431 PBO:0019232 7, type II cells
PMID:31427431 PBO:0097933 7
PMID:31427431 PBO:0097933 7
PMID:31427431 PBO:0097933 7
PMID:31427431 PBO:0097932 7
PMID:31427431 FYPO:0005342 7
PMID:31427431 FYPO:0005342 7
PMID:31427431 FYPO:0001846 6
PMID:31427431 FYPO:0001846 6
PMID:31427431 FYPO:0001846 6
PMID:31427431 FYPO:0000228 6
PMID:31427431 PBO:0097931 6
PMID:31427431 FYPO:0000228 6
PMID:31427431 FYPO:0007071 6
PMID:31427431 FYPO:0007071 6
PMID:31427431 FYPO:0007071 6
PMID:31427431 FYPO:0000141 5
PMID:31427431 FYPO:0000324 5
PMID:31427431 FYPO:0000733 5
PMID:31427431 FYPO:0001943 4
PMID:31427431 FYPO:0000733 s2
PMID:31427431 FYPO:0000733 s2
PMID:31427431 FYPO:0000069 2f
PMID:31427431 FYPO:0000069 2f
PMID:31427431 FYPO:0000069 2f
PMID:31427431 FYPO:0000228 2
PMID:31427431 FYPO:0000228 2
PMID:31427431 FYPO:0000324 2
PMID:31427431 FYPO:0000324 2
PMID:31427431 FYPO:0000030 2
PMID:31427431 FYPO:0000030 2
PMID:31427431 PBO:0097927 1f
PMID:31427431 FYPO:0000069 1e
PMID:31427431 FYPO:0000069 1e
PMID:31427431 FYPO:0001357 S1
PMID:31427431 FYPO:0000082 1b
PMID:31427431 FYPO:0000080 1b
PMID:31427431 FYPO:0000674 1b
PMID:31427431 FYPO:0001357 1b
PMID:31427431 FYPO:0001357 1b
PMID:31427431 FYPO:0001357 1b
PMID:31427431 FYPO:0001357 1b
PMID:31427431 FYPO:0000674 1b
PMID:31427431 FYPO:0000674 1b
PMID:31427431 FYPO:0002141 1b
PMID:31427431 FYPO:0002141 1b
PMID:31427431 FYPO:0000080 1b
PMID:31427431 FYPO:0002059 1
PMID:31456006 FYPO:0007120 leucine auxotroph background
PMID:31456006 FYPO:0005549 leucine auxotroph background
PMID:31456006 FYPO:0007119 bunch of auxotrophic backgrounds shown - indicative of a.a. starvation
PMID:31468675 FYPO:0002827 measured by cell growth spot assay
PMID:31468675 FYPO:0002827 partial derepression of marker gene at silent mating-type cassette; measured by cell growth spot assay
PMID:31468675 FYPO:0006993 measured by cell growth spot assay
PMID:31468675 PBO:0097202 spot assay
PMID:31468675 GO:0000792 colocalizes with H3K9me2
PMID:31468675 FYPO:0002827 measured by cell growth spot assay
PMID:31468675 GO:0000792 colocalizes with H3K9me2
PMID:31468675 GO:0000792 colocalizes with H3K9me2
PMID:31477575 PBO:0101352 S1
PMID:31477575 GO:0005938 3c
PMID:31477575 GO:0005829 3c
PMID:31477575 PBO:0101363 fig1
PMID:31477575 PBO:0101365 fig2b
PMID:31477575 PBO:0101366 fig2b
PMID:31477575 PBO:0101367 fig2b
PMID:31477575 PBO:0101368 fig2b
PMID:31477575 PBO:0101369 fig2b
PMID:31477575 PBO:0101363 fig1
PMID:31477575 GO:0005515 fig1
PMID:31477575 PBO:0101352 S3B
PMID:31477575 PBO:0101370 S3B
PMID:31477575 PBO:0101352 S3B
PMID:31477575 PBO:0101352 S1
PMID:31477575 PBO:0101352 S1
PMID:31477575 PBO:0101352 S1
PMID:31477575 PBO:0101352 S1
PMID:31477575 PBO:0101363 fig1
PMID:31477575 PBO:0101352 S1
PMID:31477575 PBO:0101352 S1
PMID:31477575 PBO:0101352 S1
PMID:31477575 PBO:0101352 S1
PMID:31483748 PBO:0101859 Reduced Rad21 binding to chromosome arms
PMID:31483748 FYPO:0007192 fig1 B–G
PMID:31483748 FYPO:0000969 fig2
PMID:31483748 FYPO:0000963 fig2
PMID:31483748 FYPO:0000957 fig2
PMID:31483748 FYPO:0000957 fig2
PMID:31483748 FYPO:0000957 fig2
PMID:31483748 FYPO:0000957 fig2
PMID:31483748 FYPO:0000089 Figure 2C No increase in severity to mto1 delete
PMID:31483748 PBO:0093616 Figure 2C
PMID:31483748 PBO:0093616 Figure 2C
PMID:31483748 FYPO:0007191 Figure 3, A and B
PMID:31483748 GO:0005634 We examined whether Mto1 localizes to DNA repair factories and found that Mto1-mCherry was not detectable within the nucleus, as previously shown (Sawin et al., 2004; Venkatram et al.)
PMID:31483748 FYPO:0007209 issues/3588 Figure 5, A–E
PMID:31483748 FYPO:0000957 fig2
PMID:31483748 FYPO:0000085 fig2
PMID:31483748 FYPO:0000267 fig2
PMID:31483748 FYPO:0000089 Figure 2A
PMID:31483748 FYPO:0000089 Figure S1A
PMID:31483748 FYPO:0000089 Figure S1A
PMID:31483748 FYPO:0000972 Figure 3, A and B . number and intensity
PMID:31483748 FYPO:0006921 Recombination rates were decreased by 10-fold in mto1∆ strains in both recombination substrates (Figure 4B)
PMID:31483748 FYPO:0000185 Recombination rates were decreased by 10-fold in mto1∆ strains in both recombination substrates (Figure 4B)
PMID:31483748 FYPO:0007209 issues/3588 decreased
PMID:31495586 PBO:0102712 Figure 4
PMID:31495586 FYPO:0006108 Figure 3
PMID:31495586 FYPO:0002021 Figure 6
PMID:31495586 FYPO:0002030 Figure 6
PMID:31495586 PBO:0102710 Figure6
PMID:31495586 PBO:0102711 Figure 6
PMID:31495586 PBO:0102713 Figure 4 and 6
PMID:31495586 PBO:0102714 Figure 4 and 6
PMID:31495586 PBO:0102715 Figure 4 and 6
PMID:31495586 PBO:0102716 Figure1
PMID:31495586 PBO:0102716 Figure1
PMID:31495586 PBO:0102717 Increased 4-fold, Figure2
PMID:31495586 PBO:0102718 Figure 3
PMID:31495586 PBO:0102719 Figure 3
PMID:31495586 PBO:0102720 Figure 1
PMID:31495586 PBO:0102721 Figure 2
PMID:31495586 PBO:0102717 Increased 4-fold, FigureS1
PMID:31495586 PBO:0102717 Increased 4-fold, Figure2
PMID:31495586 PBO:0102722 Figure 3
PMID:31495586 PBO:0102723 Figure 3
PMID:31495586 PBO:0102724 Figure 3
PMID:31495586 PBO:0102725 Figure 3, assayed using Myo52
PMID:31495586 PBO:0102726 Figure 2
PMID:31495586 PBO:0102726 Figure 2
PMID:31495586 PBO:0102727 Figure 2
PMID:31495586 PBO:0102727 Figure 2
PMID:31495586 PBO:0102728 Figure 2
PMID:31495586 PBO:0102728 Figure 2
PMID:31495586 FYPO:0000413 Figure 2
PMID:31495586 FYPO:0000413 Figure 2
PMID:31495586 PBO:0102729 Figure5
PMID:31495586 PBO:0102729 Figure5
PMID:31495586 PBO:0102730 Figure 4 and 6
PMID:31495586 PBO:0102731 Figure 5, assayed using Myo52
PMID:31495586 PBO:0102732 Figure 5, assayed using Myo52
PMID:31495586 PBO:0102732 Figure 5, assayed using Myo52
PMID:31495586 PBO:0102716 Figure 5
PMID:31495586 PBO:0102731 Figure 3, assayed using Myo52
PMID:31495586 FYPO:0007095 assayed using CHD, FigureS1
PMID:31495586 PBO:0102733 FigureS3
PMID:31495586 PBO:0102722 FigureS3
PMID:31495586 PBO:0102719 FigureS3
PMID:31495586 PBO:0102723 FigureS3
PMID:31495586 PBO:0102734 Figure S5, assayed using LifeAct
PMID:31495586 PBO:0102732 Figure3, S4, assayed using Myo52 and Fus1
PMID:31495586 FYPO:0007095 Figure S1, assayed using CHD
PMID:31495586 PBO:0102733 Figure S3
PMID:31495586 PBO:0102722 Figure S3
PMID:31495586 PBO:0102719 Figure S3
PMID:31495586 PBO:0102723 Figure S3
PMID:31495586 PBO:0102735 1.1 fold, Figure S2
PMID:31495586 PBO:0102711 Figure S6
PMID:31495586 PBO:0102711 Figure S6
PMID:31495586 PBO:0102711 Figure S6
PMID:31495586 PBO:0102736 Figure S6
PMID:31495586 FYPO:0006081 FigureS5, assayed using LifeAct
PMID:31495586 FYPO:0006081 FigureS5, assayed using LifeAct
PMID:31495586 FYPO:0007095 Figure2, Increased 1.5-fold, assayed using CHD
PMID:31495586 PBO:0102733 Figure 3
PMID:31495586 PBO:0102737 Figure 4
PMID:31495586 PBO:0097695 Figure6
PMID:31495586 PBO:0097695 Figure6
PMID:31495586 PBO:0102738 Figure6
PMID:31495586 PBO:0102739 Figure6
PMID:31509478 FYPO:0001904 synonym =ring collapse fig3F
PMID:31509478 FYPO:0003343 fig3
PMID:31509478 FYPO:0005543 Figure 3E)
PMID:31509478 PBO:0099934 figS3C
PMID:31509478 FYPO:0003343 fig3
PMID:31509478 FYPO:0000650 fig3
PMID:31509478 FYPO:0002059 fig 1
PMID:31509478 PBO:0099934 figS3C
PMID:31509478 FYPO:0002059 figure1
PMID:31509478 FYPO:0000650 fig3
PMID:31509478 FYPO:0005840 3F
PMID:31509478 FYPO:0005543 Figure 3E)
PMID:31509478 PBO:0099932 Figure 6A
PMID:31509478 FYPO:0002060 fig1
PMID:31509478 PBO:0099934 figS3C
PMID:31509478 PBO:0099934 figS3C
PMID:31509478 FYPO:0002177 fig3
PMID:31509478 FYPO:0002059 fig2
PMID:31509478 PBO:0096673 fig6
PMID:31515876 PBO:0102514 ChIP-seq, RNA-seq and northern blot analysis demonstrate that this transcript is repressed in high zinc in a manner that is dependent upon Loz1 (Table 1, Figure 3B and 3C)
PMID:31515876 PBO:0102513 ChIP-seq, RNA-seq and northern blot analysis demonstrate that this transcript is repressed in high zinc in a manner that is dependent upon Loz1 (Table 1, Figure 3B and 3C)
PMID:31515876 PBO:0102515 When Loz1 is expressed at a constant level inside of cells, it binds to the zrt1 promoter in high zinc conditions and not in low zinc conditions (consistent with its role in gene repression in high zinc conditions
PMID:31515876 PBO:0102511 ChIP-seq, RNA-seq and northern blot analysis demonstrate that this transcript is repressed in high zinc in a manner that is dependent upon Loz1 (Table 1, Figure 3B and 3C)
PMID:31515876 PBO:0102512 ChIP-seq, RNA-seq and northern blot analysis demonstrate that this transcript is repressed in high zinc in a manner that is dependent upon Loz1 (Table 1, Figure 3B and 3C)
PMID:31515876 PBO:0102518 When Loz1 is expressed at a constant level inside of cells, it binds to the adh4 promoter in high zinc conditions and not in low zinc conditions (consistent with its role in gene repression in high zinc conditions
PMID:31515876 PBO:0102517 Loz1 represses gene expression when zinc is in excess and growth in zinc deficient media leads to de-repression of its target genes. Expression from the pgk1DTATA promoter leads to higher levels of Loz1 accumulating inside of cells, which in turn leads to higher levels of gene repression under low zinc conditions (Figure 1B)
PMID:31515876 PBO:0102516 ADD SO TERM WHEN AVAILABLE Mutagenesis of 3 Loz1 response elements in the SPBC1348.06c promoter resulted in the promoter no longer being repressed in high zinc in a manner that is dependent upon Loz1 (see Figure 4). The minimal Loz1 DNA binding domain (amino acids 426-522) also binds to this motif in vitro (supplemental Fig 2), and multiple copies of this element are able to confer Loz1-mediated gene repression in a minimal reporter system - see figure 6)
PMID:31515876 PBO:0102505 deletion of loz1 leads to increased expression of this transcript in high zinc growth conditions (inferred from RNA seq analysis - see Table 1).
PMID:31515876 PBO:0102506 deletion of loz1 leads to increased expression of this transcript in high zinc growth conditions (inferred from RNA seq analysis - see Table 1).
PMID:31515876 PBO:0102507 ChIP-seq, RNA-seq and northern blot analysis demonstrate that this transcript is repressed in high zinc in a manner that is dependent upon Loz1 (Table 1, Figure 3B and 3C)
PMID:31515876 PBO:0102508 ChIP-seq, RNA-seq and reporter gene analysis demonstrate that this transcript is repressed in high zinc in a manner that is dependent upon Loz1 (Table 1, Figure 4)
PMID:31515876 PBO:0102509 deletion of loz1 leads to increased expression of this transcript in high zinc growth conditions (inferred from RNA seq analysis - see Table 1).
PMID:31515876 PBO:0102510 ChIP-seq, RNA-seq and northern blot analysis demonstrate that this transcript is repressed in high zinc in a manner that is dependent upon Loz1 (Table 1, Figure 3B and 3C)
PMID:31532702 PBO:0105592 figure 1B
PMID:31532702 FYPO:0007083 28 ~ 32 min, Figure 3B; and 24 ~ 28 min, Figure S3B)
PMID:31532702 FYPO:0007081 Figure S3B, C pentrance, frequently like quadruple
PMID:31532702 PBO:0105600 Figure 2A
PMID:31532702 PBO:0105593 single nucleus
PMID:31532702 PBO:0105599 meiosis I inital Figure 3B, C
PMID:31532702 PBO:0105598 top, Figure 3B, C)
PMID:31532702 FYPO:0002060 I didn't check the supp, but probably can only make this annotation?
PMID:31532702 PBO:0105597 Figure 2A
PMID:31532702 FYPO:0004668 Figure S5
PMID:31532702 FYPO:0006475 28 ~ 32 min, Figure 3B; and 24 ~ 28 min, Figure S3B)
PMID:31532702 GO:0000073 The Nuf2-containing kinetochore complex serves as a physical fulcrum for microtubule-dependent SPB separation
PMID:31532702 FYPO:0004159 figure 1B
PMID:31532702 PBO:0095634 Figure 5B
PMID:31532702 PBO:0105601 Figure 5C, D
PMID:31532702 PBO:0095634 Figure 5E
PMID:31532702 FYPO:0000732 Figure 5E
PMID:31532702 FYPO:0000732 Figure S6
PMID:31532702 FYPO:0003566 Figure 5G (this term referes to initial
PMID:31532702 FYPO:0002060 Figure 5H
PMID:31532702 FYPO:0002060 Figure 5I
PMID:31532702 FYPO:0003566 Figure 6A
PMID:31532702 FYPO:0007080 Figure 6D, E
PMID:31532702 PBO:0105602 meiotic . The Nuf2-containing kinetochore complex serves as a physical fulcrum for microtubule-dependent SPB separation
PMID:31532702 PBO:0105596 Figure figure 1B, D
PMID:31532702 PBO:0105595 Figure 1D, E . monopolar?
PMID:31538680 FYPO:0000006 Mutant proliferates faster and with shorter lag than wildtype in sublethal concentrations of hydroxyurea, phleomycin or doxorubicin
PMID:31538680 FYPO:0000006 Mutant proliferates faster and with shorter lag than wildtype in sublethal concentrations of hydroxyurea, phleomycin or doxorubicin
PMID:31538680 PBO:0105152 Mutant proliferates faster and with shorter lag than wildtype in sublethal concentrations of hydroxyurea, phleomycin or doxorubicin
PMID:31562247 PBO:0097037 figure 4c
PMID:31562247 FYPO:0000056 fig 3a
PMID:31562247 FYPO:0003896 As shown in Fig. 5A, the changes in mitochondrial morphology were similar within 40 min of glucose starvation in the three mutant and WT cells
PMID:31562247 FYPO:0003896 Indeed, no noticeable change in mitochondrial morphology or altered mitochondrion numbers were found in the three mutant cells cultured in glucose-rich EMM (Fig. 5, C and D).
PMID:31562247 FYPO:0002780 As shown in Fig. 6, A and B, ROS production under glucose starvation was reduced, but not abolished, in the absence of Dnm1 because only 25% of dnm1 cells were DCDHF-DA– positive after glucose starvation.
PMID:31562247 PBO:0097036 figure 4c
PMID:31562247 PBO:0097038 figure 4ab
PMID:31562247 FYPO:0007611 (with decreased total volume -. new term requested) Throughout the period of glucose starvation, mito- chondria in dnm1 cells did not appear to fragment but shrunk over time (Fig. 3A). mitochondrion numbers remained largely unchanged during glucose starvation (Fig. 3B)
PMID:31562247 PBO:0097038 figure 4ab
PMID:31563844 PBO:0110209 We observed a severe loss of mitochondrial DNA from the exo5Δ rad2Δ strain compared to the wild-type and single mutants, suggesting that Exo5 and FEN1 are redundantly required for mitochondrial DNA maintenance (Fig. 2C).
PMID:31563844 GO:0032042 The results from these experiments establish a redundant function in mitochondria for Exo5 and FEN1, presumably operating during the final steps of DNA replication in order to generate ligatable nicks.
PMID:31563844 GO:0032042 The results from these experiments establish a redundant function in mitochondria for Exo5 and FEN1, presumably operating during the final steps of DNA replication in order to generate ligatable nicks.
PMID:31563844 PBO:0093630 However, the exo5Δ mutant is more sensitive than isogenic wild-type to UV-irradiation and alkylating agents (Fig. 5A).
PMID:31563844 FYPO:0000102 Furthermore, the deletion is particularly hypersensitive to interstrand crosslinking (ICL) agents such as 8-methoxypsoralen (Fig. 5B) and cis-platin (Fig. 5C). 8- methoxypsoralen intercalates into the DNA and forms interstrand crosslinks upon irradiation with visible light [23].
PMID:31563844 PBO:0093616 Fission yeast Exo1 exonuclease is involved in Okazaki fragment maturation, double-strand break repair, mismatch repair, and interstrand crosslink repair [27–29]. While the single exo1Δ and exo5Δ mutants showed a comparable sensitivity to UV, MMS and ICL agents, the double mutant exo1Δ exo5Δ showed an increased sensitivity to these agents, indicating that Exo1 and Exo5 repair these damages with partial redundancy (Fig. 5A, Supplementary Fig. S4E).
PMID:31563844 PBO:0110229 spExo5 showed activity on either substrate, with a preference for the 5’-ended substrate (Supplementary Fig. S2B).
PMID:31563844 PBO:0093616 Fission yeast Exo1 exonuclease is involved in Okazaki fragment maturation, double-strand break repair, mismatch repair, and interstrand crosslink repair [27–29]. While the single exo1Δ and exo5Δ mutants showed a comparable sensitivity to UV, MMS and ICL agents, the double mutant exo1Δ exo5Δ showed an increased sensitivity to these agents, indicating that Exo1 and Exo5 repair these damages with partial redundancy (Fig. 5A, Supplementary Fig. S4E).
PMID:31563844 PBO:0093629 The UV sensitivity of a rad13Δ mutant, the 3’-endonuclease that functions in nucleotide excision repair (ortholog of human XPG) is increased in the double mutant with exo5Δ, suggesting that Exo5 does not have a function in nucleotide excision repair.
PMID:31563844 PBO:0093629 The UV sensitivity of a rad13Δ mutant, the 3’-endonuclease that functions in nucleotide excision repair (ortholog of human XPG) is increased in the double mutant with exo5Δ, suggesting that Exo5 does not have a function in nucleotide excision repair.
PMID:31563844 PBO:0094312 Furthermore, the deletion is particularly hypersensitive to interstrand crosslinking (ICL) agents such as 8-methoxypsoralen (Fig. 5B) and cis-platin (Fig. 5C). 8- methoxypsoralen intercalates into the DNA and forms interstrand crosslinks upon irradiation with visible light [23].
PMID:31563844 PBO:0094311 The crosslink sensitivity of pso2Δ is substantially higher than that of exo5Δ (Fig. 5B, C), while the double mutant exo5Δ pso2Δ shows an increased sensitivity to cis-platin (Fig. 5C, Supplementary Fig. S5B
PMID:31563844 PBO:0094311 The crosslink sensitivity of pso2Δ is substantially higher than that of exo5Δ (Fig. 5B, C), while the double mutant exo5Δ pso2Δ shows an increased sensitivity to cis-platin (Fig. 5C, Supplementary Fig. S5B
PMID:31563844 GO:0036298 The Fanconi branch of ICL repair is represented by fml1+ and fan1+. Exo5+ is epistatic with fml1+, i.e. the double mutant is not more sensitive than the single mutants (Fig. 5E). Likewise, the exo5Δfan1Δ double mutant is not more sensitive than the single mutants (Supplementary Fig. S5A). These data suggest that Exo5 functions in the Fanconi pathway of ICL repair.
PMID:31563844 GO:0036298 The Fanconi branch of ICL repair is represented by fml1+ and fan1+. Exo5+ is epistatic with fml1+, i.e. the double mutant is not more sensitive than the single mutants (Fig. 5E). Likewise, the exo5Δfan1Δ double mutant is not more sensitive than the single mutants (Supplementary Fig. S5A). These data suggest that Exo5 functions in the Fanconi pathway of ICL repair.
PMID:31563844 FYPO:0000102 Exo5Δ and pli1Δ show synergistic interactions indicating that they operate in different, competing pathways (Fig. 5F).
PMID:31563844 PBO:0094311 Exo5Δ and pli1Δ show synergistic interactions indicating that they operate in different, competing pathways (Fig. 5F).
PMID:31563844 PBO:0094311 Exo5Δ and pli1Δ show synergistic interactions indicating that they operate in different, competing pathways (Fig. 5F).
PMID:31563844 PBO:0110228 spExo5 showed activity on either substrate, with a preference for the 5’-ended substrate (Supplementary Fig. S2B).
PMID:31563844 GO:0051539 The purified enzyme shows an absorption at 410 nm, characteristic of a [4Fe-4S] iron-sulfur cluster (Fig. 1B,C).
PMID:31563844 GO:0051539 The purified enzyme shows an absorption at 410 nm, characteristic of a [4Fe-4S] iron-sulfur cluster (Fig. 1B,C).
PMID:31563844 PBO:0110206 Consistent with these studies, mutation of either of the analogous active site aspartates to alanines (D176A, D207A), abrogated the nuclease activity of spExo5 (Supplementary Fig. S2A).
PMID:31563844 PBO:0110206 Consistent with these studies, mutation of either of the analogous active site aspartates to alanines (D176A, D207A), abrogated the nuclease activity of spExo5 (Supplementary Fig. S2A).
PMID:31563844 FYPO:0002061 Under these highly inducing conditions, Exo5-FLAG levels were increased dramatically, and cells carrying the Exo5+ plasmid showed a negative growth phenotype (Supplementary Fig. S3B).
PMID:31563844 GO:0005739 The affinity-purified wild-type Exo5-FLAG protein showed two prominent species by immunoblot blot analysis (Fig. 2A). The upper band is consistent with the predicted molecular weight of spExo5-3XFLAG protein (~50 kDa), while the lower band is consistent with that of a protein starting at Met58, followed by loss of a small signal peptide upon mitochondrial entry (~43 kDa). Importantly, the M58A mutant lacked the lower band, as one would expect if translation of the mitochondrial species started at Met58 with the M58A mutation eliminating this initiation. Conversely, the Δ(1-57) mutant showed only the lower band, further supporting our model.
PMID:31563844 GO:0005634 The affinity-purified wild-type Exo5-FLAG protein showed two prominent species by immunoblot blot analysis (Fig. 2A). The upper band is consistent with the predicted molecular weight of spExo5-3XFLAG protein (~50 kDa), while the lower band is consistent with that of a protein starting at Met58, followed by loss of a small signal peptide upon mitochondrial entry (~43 kDa). Importantly, the M58A mutant lacked the lower band, as one would expect if translation of the mitochondrial species started at Met58 with the M58A mutation eliminating this initiation. Conversely, the Δ(1-57) mutant showed only the lower band, further supporting our model.
PMID:31563844 GO:0005739 Wild-type Exo5+ showed diffuse cytoplasmic fluorescence and both nuclear and punctate mitochondrial fluorescence. The Exo5-M58A mutant showed diffuse cytoplasmic/nuclear fluorescence, but lacked punctate fluorescence suggesting its exclusion from the mitochondria. The Δ(1-57) mutant showed only punctate staining suggesting that this truncated form of Exo5 is solely localized to the mitochondria (Supplementary Table 2). Therefore, both sets of data are consistent with a model in which mitochondrial localization of spExo5 proceeds through translational initiation at Met58, whereas initiation at Met1 yields predominantly the cytoplasmic and nuclear forms.
PMID:31563844 GO:0005634 Wild-type Exo5+ showed diffuse cytoplasmic fluorescence and both nuclear and punctate mitochondrial fluorescence. The Exo5-M58A mutant showed diffuse cytoplasmic/nuclear fluorescence, but lacked punctate fluorescence suggesting its exclusion from the mitochondria. The Δ(1-57) mutant showed only punctate staining suggesting that this truncated form of Exo5 is solely localized to the mitochondria (Supplementary Table 2). Therefore, both sets of data are consistent with a model in which mitochondrial localization of spExo5 proceeds through translational initiation at Met58, whereas initiation at Met1 yields predominantly the cytoplasmic and nuclear forms.
PMID:31563844 FYPO:0002061 This lethality was not due to the nuclease activity of the protein, since overexpression of the nuclease-deficient mutant (exo5-D207A) showed similar lethality.
PMID:31563844 PBO:0102116 Examination of the cell morphology revealed that the cells were elongated, indicative of checkpoint activation [17] (Fig. 4B
PMID:31563844 PBO:0110207 Examination of the cell morphology revealed that the cells were elongated, indicative of checkpoint activation [17] (Fig. 4B
PMID:31563844 FYPO:0003503 However, while overexpression of exo5-D207A in a rad3Δ background eliminated the cell elongation phenotype, it did not suppress lethality (Fig. 4A,B)
PMID:31563844 FYPO:0003503 However, while overexpression of exo5-D207A in a rad3Δ background eliminated the cell elongation phenotype, it did not suppress lethality (Fig. 4A,B)
PMID:31563844 FYPO:0002061 However, while overexpression of exo5-D207A in a rad3Δ background eliminated the cell elongation phenotype, it did not suppress lethality (Fig. 4A,B)
PMID:31563844 FYPO:0002060 S. pombe exo5Δ strains are viable, indicating that spExo5 is not essential for mitochondrial genome stability (Fig. 2B).
PMID:31563844 FYPO:0002061 Interestingly, while neither the single exo5Δ nor rad2Δ mutant is associated with a detectable mitochondrial growth phenotype, the double mutant exo5Δ rad2Δ showed a failure to grow on media lacking a fermentable carbon source (Fig. 2B).
PMID:31563844 PBO:0093559 The double mutant also showed a minor growth defect on rich media containing glucose (Fig. 5D)
PMID:31563844 PBO:0093559 The double mutant also showed a minor growth defect on rich media containing glucose (Fig. 5D)
PMID:31563844 PBO:0110209 We observed a severe loss of mitochondrial DNA from the exo5Δ rad2Δ strain compared to the wild-type and single mutants, suggesting that Exo5 and FEN1 are redundantly required for mitochondrial DNA maintenance (Fig. 2C).
PMID:31575705 FYPO:0000957 Figure 1A
PMID:31575705 FYPO:0000957 Figure 1A
PMID:31575705 FYPO:0006318 RTS1-RFB assay
PMID:31575705 FYPO:0006686 fig1
PMID:31575705 FYPO:0000089 The fft3-K418R-myc strain exhibited similar sensitivity to CPT and MMS than fft3Δ cells, indicating that the ATPase activity is required to promote cell re- sistance to replication stress.
PMID:31575705 FYPO:0006318 Fig 2 C RTS1-RFB assay
PMID:31575705 FYPO:0000089 Fig 1A growth inhibited by 0.005% MMS after 4 days
PMID:31575705 FYPO:0007254 normal replciation restart/ HR-mediated fork restart RTS1-RFB assay. urprisingly, the induction of downstream RS in fft3-K418R-myc strain was similar to the one observed in wild-type cells (Fig 4D, bottom panel). This finding indicates that the lack of the ATPase activity does not impact the efficiency of HR-mediated fork restart.
PMID:31575705 FYPO:0003586 decreased replciation restart fig1 indicating that only one-third of forks arrested at the RTS1-RFB are efficiently restarted in the absence of Fft3.
PMID:31575705 GO:0000785 constitutive
PMID:31582398 PBO:0104161 Figure. 3C, D, E, F and Video 5 mitochondrial mixing during meiosis
PMID:31582398 PBO:0104162 Figure. 5C, D normal (increased mitochondrial segregation during meiosis)
PMID:31582398 PBO:0104161 Figure. 3C, D, E, F and Video 5 mitochondrial mixing during meiosis
PMID:31582398 PBO:0104164 "tetrad dissection ""in the absence of Mcp5 in rho+ parental strain (strain PHP4xVA074; see Table S1), only 31.3% of the tetrads dissected (n = 16 tetrads) exhibited mtDNA segregation similar to that observed in Fig. 6 D."""
PMID:31582398 FYPO:0007276 To verify that the attachment to microtubules was not necessary for segregation during meiosis, we employed parental cells lacking the microtubule-mitochondrial linker protein Mmb1 (Fu et al., 2011). Additionally, one of the parental cells had its mitochondria fluorescently labeled. In zygotes and asci resulting from this cross, we observed that parental mito- chondria continued to remain segregated (Fig. S2, C and D).
PMID:31584934 FYPO:0007160 fig. 3
PMID:31584934 PBO:0105882 fig. 3c
PMID:31584934 PBO:0105883 coincident with replication fork barrier but dependent on JM formation - not sure if we can be more specific here than nuclear chromatin?
PMID:31584934 FYPO:0000085 fig. 6
PMID:31584934 FYPO:0001690 fig. 6
PMID:31584934 FYPO:0001690 fig. 6
PMID:31584934 FYPO:0000085 fig. 6
PMID:31584934 FYPO:0000957 fig. 6
PMID:31584934 FYPO:0000085 fig. 6
PMID:31584934 FYPO:0000089 fig. 6
PMID:31584934 FYPO:0000957 fig. 6
PMID:31584934 FYPO:0000473 fig. 7
PMID:31584934 FYPO:0000095 fig. 6
PMID:31584934 FYPO:0003906 fig. 6
PMID:31584934 FYPO:0003906 fig. 6
PMID:31584934 FYPO:0000089 fig. 6
PMID:31584934 FYPO:0002151 """Consistent with this, we found that the deletion of pcf1 is synthetic lethal with the deletion of hip1, the gene encoding one subunit of the fission yeast HIRA complex (S4A Fig). T"""
PMID:31584934 PBO:0105875 "changed to decreased from abolished based on ""H3-FLAG association with H3-H113D-HA was severely reduced"""
PMID:31584934 PBO:0093560 fig. 2
PMID:31584934 PBO:0105881 """Reciprocally, H3-H113D-HA association with wt H3 and H4 were severely reduced"""
PMID:31584934 GO:0006335 fig. 3,4
PMID:31584934 FYPO:0007160 fig. 3
PMID:31615333 FYPO:0006613 Figure S3
PMID:31615333 PBO:0097132 Figure 2 and 3
PMID:31615333 PBO:0097134 Figure 2 and S3
PMID:31615333 PBO:0097134 Figure 2 and S3
PMID:31615333 FYPO:0006613 Figure S3
PMID:31615333 PBO:0097132 Figure 2 and 3
PMID:31615333 FYPO:0006613 Figure S3
PMID:31615333 PBO:0097133 Figure S1
PMID:31615333 PBO:0097133 Figure 2, detected by northern blot analysis
PMID:31615333 PBO:0097134 Figure 2 and S3
PMID:31615333 FYPO:0003165 Figure 1c
PMID:31615768 PBO:0094438 fig3a by cen2-GFP observation
PMID:31615768 PBO:0094441 fig 3
PMID:31615768 FYPO:0007126 fig 1C
PMID:31615768 FYPO:0005722 fig 1C
PMID:31615768 PBO:0094440 figureS4
PMID:31615768 FYPO:0006174 1A
PMID:31615768 PBO:0094439 S2
PMID:31615768 PBO:0037411 S2A/4
PMID:31615768 FYPO:0002061 S1
PMID:31615768 PBO:0094444 1E unbundled microtubules seen in early mitosis
PMID:31615768 PBO:0094437 1E unbundled microtubules seen in early mitosis
PMID:31615768 PBO:0094443 fig 4
PMID:31615768 PBO:0094442 fig 4
PMID:31615768 PBO:0024749 S2A/4
PMID:31615768 GO:0000776 S2A
PMID:31615768 FYPO:0002061 fig 3I
PMID:31615768 FYPO:0003307 fig 3
PMID:31615768 FYPO:0002638 fig 3
PMID:31618856 FYPO:0004315 fig 3
PMID:31618856 FYPO:0005694 Figure 2D
PMID:31618856 FYPO:0000131 fig 4
PMID:31618856 FYPO:0005681 defective in microtubule growth during both interphase and mitosis
PMID:31618856 FYPO:0005699 appears to retain normal microtubule nucleation activity
PMID:31618856 FYPO:0002061 fig1
PMID:31618856 PBO:0102760 fig 4
PMID:31618856 FYPO:0006475 fig 4
PMID:31641022 FYPO:0002060 fig2
PMID:31641022 PBO:0097920 "chnaged from ""increased rate of sporulation"""
PMID:31644361 PBO:0102681 Figure 1H (in vitro) Cdr1 directly phosphory- lated Wee1, but Cdr1(K41A) did not ().
PMID:31644361 FYPO:0001124 Fig1 In contrast, Cdr2 overexpression induced hyperphosphoryla- tion of Wee1 but no change in Cdk1-pY15
PMID:31644361 PBO:0094002 Figure 1 D Phosphorylation of Wee1 in fission yeast cells was reduced in the catalytically inactive mutant cdr1(K41A)
PMID:31644361 PBO:0102680 Cdr1 directly phosphory- lated Wee1, but Cdr1(K41A) did not (Figure 1H).
PMID:31644361 PBO:0094002 Figure 3 A onsistent with this model, wee1(4A) phosphorylation was reduced when compared with wild type, and its phosphorylation was not altered by cdr1∆ or cdr2∆ (
PMID:31644361 PBO:0020446 deed, cdr1∆ wee1(4A) cells divided at the same size as cdr1∆ cells
PMID:31644361 FYPO:0002061 (Figure 3C) Both wee1(4A) and cdr1∆ were synthetically lethal with cdc25-dD
PMID:31644361 FYPO:0002061 (Figure 3C) Both wee1(4A) and cdr1∆ were synthetically lethal with cdc25-dD
PMID:31644361 PBO:0102682 (Figure 3, A and D). We confirmed that wee1(4A) protein level does not increase and still localizes to cortical nodes
PMID:31644361 PBO:0101181 Accordingly, the size of wee1(4A) cells was largely (but not entirely) insensitive to Cdr1 overexpression (Figure 3G).
PMID:31644361 PBO:0111082 (Figure 4A). We confirmed that S. pombe Cdk1- asM17 directly thiophosphorylates Wee1 and Wee1(K596L)
PMID:31644361 PBO:0102684 Figure 5B) We tested the effects of artificially recruiting mEGFP-cdr1(∆460-482) back to nodes using cdr2-GFP- binding peptide (GBP)-mCherry, which contains the GBP. In this system, mEGFP-cdr1(∆460-482) colocalized with cdr2-GBP-mCherry at nodes.
PMID:31644361 PBO:0099234 Along with enhanced Wee1 hyperphosphorylation, these cells di- vided at a smaller size than wild-type cells. These results show that Cdr1 localization to nodes is a limiting factor for phosphorylation of Wee1 and cell size at division
PMID:31644361 PBO:0020446 Figure 3 B
PMID:31644361 PBO:0102677 Fig 1B Cdr1 overexpression induced hyperphosphorylation of Wee1 and loss of Cdk1-pY15, indicating inhibition of Wee1 kinase activity,
PMID:31644361 PBO:0102678 Fig1B Cdr1 overexpression induced hyperphosphorylation of Wee1 and loss of Cdk1-pY15, indicating inhibition of Wee1 kinase activity,
PMID:31644361 PBO:0102677 Fig1B. In contrast, Cdr2 overexpression induced hyperphosphoryla- tion of Wee1 but no change in Cdk1-pY15
PMID:31644361 PBO:0102679 Fig1B Cdr1 overexpression induced hyperphosphorylation of Wee1 and loss of Cdk1-pY15, indicating inhibition of Wee1 kinase activity,
PMID:31644361 PBO:0093712 Fig 1C overexpression of Cdr1 but not of Cdr2 re- sulted in reduced cell size in cdr1∆cdr2∆ cells (Figure 1C
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 PBO:0109290 Fig. 3
PMID:31657618 PBO:0109290 Fig. 3
PMID:31657618 PBO:0109290 Fig. 3
PMID:31657618 PBO:0109290 Fig. 3
PMID:31657618 PBO:0109290 Fig. 3
PMID:31657618 PBO:0109290 Fig. 3
PMID:31657618 FYPO:0001122 Fig. 4
PMID:31657618 FYPO:0001122 Fig. 4
PMID:31657618 FYPO:0001122 Fig. 4
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31657618 FYPO:0009060 Table
PMID:31712578 FYPO:0004993 Table S3
PMID:31712578 FYPO:0004993 Table S3
PMID:31712578 FYPO:0004993 Table S3
PMID:31712578 FYPO:0004993 Table S3
PMID:31712578 FYPO:0004993 Table S3
PMID:31712578 FYPO:0003612 Table S3; spore viability lower than wild type (~50% of wild-type viability)
PMID:31712578 FYPO:0003612 Table S3; spore viability similar to wild type
PMID:31712578 FYPO:0003612 Table S3; spore viability similar to wild type
PMID:31712578 FYPO:0003612 Table S3; spore viability similar to wild type
PMID:31712578 FYPO:0003612 Table S3; spore viability similar to wild type
PMID:31712578 FYPO:0003612 Table S3; spore viability similar to wild type
PMID:31712578 FYPO:0003612 Table S3; spore viability similar to wild type
PMID:31712578 FYPO:0003612 Table S3; spore viability similar to wild type
PMID:31712578 FYPO:0003612 Table S3
PMID:31712578 FYPO:0004993 Table S3
PMID:31712578 FYPO:0004993 Table S3
PMID:31719112 PBO:0103649 temperature permissive for mcm4/cdc21-M68
PMID:31719112 PBO:0103649 temperature restrictive for cdc22-M45
PMID:31719163 PBO:0019716 localizes to division site after Gef1 and Scd2, but before contractile ring constriction begins
PMID:31719163 PBO:0019716 localizes to division site before Scd1, and before contractile ring constriction begins
PMID:31719163 PBO:0019716 localizes to division site before Scd1, and before contractile ring constriction begins
PMID:31748520 FYPO:0008117 See Figure 3a-b Describes the biogenesis of a multisubunit complex from nascent proteins. Could be linked to pombase ID of one or several components of the complex
PMID:31748520 PBO:0101995 RNA-seq
PMID:31748520 PBO:0109870 Decreased levels of Tra1 and Tra2 in SAGA and NuA4 complexes, respectively Figure 2
PMID:31748520 FYPO:0001216 Normal Tra1 interaction with SAGA complex
PMID:31748520 FYPO:0001855 RNA-seq
PMID:31748520 FYPO:0001522 whereas tra1-Sctra1 strains show no growth defects, as compared with wild-type cells (Fig. 5d).
PMID:31748520 FYPO:0000963 whereas tra1-Sctra1 strains show no growth defects, as compared with wild-type cells (Fig. 5d).
PMID:31748520 PBO:0109869 Impor- tantly, quantitative MS analyses show that both Tra1-SpTra2 and Tra1-ScTra1 hybrid mutant proteins efficiently copurify with Tti2 (Supplementary Fig. 9b).
PMID:31748520 GO:0140463 Such distinct architectural roles provide a functional validation of the recent structural studies of yeast SAGA and NuA4, which showed that Tra1 occupies a peripheral position within SAGA
PMID:31748520 GO:0005198 Tra2 contributes to the scaffolding and stabilisation of the entire NuA4 complex.
PMID:31748520 PBO:0109868 Silver staining analysis showed that Hsp90 inactivation causes a specific decrease of Tra1 in Spt7 purification eluates (Supplementary Fig. 6). effect is modest in this hypomorphic mutant, this observation supports the conclusion that Hsp90, like TTT, contributes to the de novo assembly of Tra1 into SAGA.
PMID:31748520 PBO:0109867 RNA-seq
PMID:31748520 PBO:0109866 RNA-seq
PMID:31748520 PBO:0093626 (Fig. 5d)
PMID:31748520 PBO:0109865 Decreased Tra1 interaction with SAGA complex
PMID:31748520 PBO:0109865 Abolished Tra1 interaction with SAGA complex
PMID:31748520 PBO:0109865 Abolished Tra1 interaction with SAGA complex
PMID:31748520 PBO:0109865 Abolished Tra1 interaction with SAGA complex
PMID:31748520 FYPO:0008120 Abolished Tra1 interaction with SAGA complex
PMID:31748520 PBO:0109865 Abolished Tra1 interaction with SAGA complex spt20Δ mutants, without any other visible changes in its overall migration profile (Fig. 6a). Spt20 is therefore essential for Tra1 incorporation into SAGA.
PMID:31748520 PBO:0109854 RNA-seq
PMID:31748520 PBO:0093580 (Fig. 5d) Phenotypic analyses of tra1-Sptra2 and tra1-Sctra1 strains showed that tra1-Sptra2 mutants are sensitive to HU and caffeine, similar to tra1Δ mutants
PMID:31748520 FYPO:0008121 See Figure 4
PMID:31748520 FYPO:0008117 See Figure 3c-d
PMID:31748520 PBO:0109864 Decreased levels of Tra1 and Tra2 in SAGA and NuA4 complexes, respectively Figure 2
PMID:31748520 PBO:0109863 (Fig.1e, f) spt7/tra1 pho84 and mei2 promoters. and spt7/tras ssa2 promoter
PMID:31748520 PBO:0109862 (Fig.1e, f) spt7/tra1 pho84 and mei2 promoters. and spt7/tras ssa2 promoter
PMID:31748520 PBO:0109861 (Fig.1e, f) spt7/tra1 pho84 and mei2 promoters. and spt7/tras ssa2 promoter
PMID:31748520 PBO:0109850 MS analyses revealed a tenfold reduction of Tra1 from SAGA when Tti2 is depleted, as compared with control conditions (Fig. 2a). Similarly, we observed about a twofold reduction of Tra2 levels from NuA4 (Fig. 2b). Both approaches showed decreased interaction between newly synthesised Tra1 and affinity purified Spt7 in cells partially depleted of Tel2. These results demonstrate that TTT contributes to the de novo incorporation of Tra1 into the SAGA complex.
PMID:31748520 PBO:0109851 . Similarly, we observed about a twofold reduction of Tra2 levels from NuA4 (Fig. 2b).
PMID:31748520 PBO:0109854 RNA-seq
PMID:31748520 PBO:0101995 RNA-seq
PMID:31777937 GO:0140432 A novel 5′-hydroxyl dinucleotide hydrolase activity for the DXO/Rai1 family of enzymes
PMID:31811152 PBO:0105429 C24 locus. fig2
PMID:31811152 PBO:0105431 Figure 4b (live cell observation)
PMID:31811152 PBO:0105421 Figure 1b (live cell observation)
PMID:31811152 PBO:0105418 Figure 1b (live cell observation)
PMID:31811152 PBO:0105417 Figure 1b (live cell observation)
PMID:31811152 PBO:0105416 Figure 1b, Figure 4b (live cell observation)
PMID:31811152 PBO:0105419 Figure 4a
PMID:31811152 PBO:0105420 Figure 1b (live cell observation)
PMID:31811152 PBO:0105416 Figure 1b (live cell observation)
PMID:31811152 PBO:0105416 Figure 1b (live cell observation)
PMID:31811152 PBO:0105417 Figure 1b (live cell observation)
PMID:31811152 PBO:0105432 Figure 4b (live cell observation)
PMID:31811152 PBO:0105430 Figure 4b,
PMID:31811152 PBO:0105428 C24 locus. fig2
PMID:31811152 PBO:0105427 fig2
PMID:31811152 PBO:0105427 fig2
PMID:31811152 PBO:0105426 Figure 1c
PMID:31811152 PBO:0105426 Figure 1c
PMID:31811152 PBO:0105422 Figure 4a. homologous pairing examined at C24 locus
PMID:31811152 PBO:0105416 Figure 1b, (live cell observation)
PMID:31833215 FYPO:0000245 same as maf1delta alone
PMID:31837996 PBO:0104317 RNA-seq
PMID:31837996 FYPO:0000854 similar to pob3delta alone
PMID:31837996 PBO:0104318 similar to pob3delta alone
PMID:31837996 PBO:0104317 RNA-seq
PMID:31837996 PBO:0104321 assayed using bulk histones
PMID:31837996 PBO:0104322 assayed using bulk histones
PMID:31837996 FYPO:0005917 RNA-seq
PMID:31837996 FYPO:0005917 RNA-seq
PMID:31837996 PBO:0104317 RNA-seq
PMID:31848341 GO:0042393 binds H3-H4 dimer; assayed in vitro using Xenopus histones
PMID:31895039 PBO:0095054 Fig. 7. The phenotype is exacerbated by pph3 deletion and rescued by pef1 deletion
PMID:31895039 PBO:0095053 Pef1 ablation or chemical inactivation of its kinase activity stimulates Rad21 and Mis4 binding to their cognates sites on chromosomes. The effect in most prominent in the G1 phase of the mitotic cycle.
PMID:31895039 GO:0005634 Psm1 and Mis4 are found in Pef1 immunoprecipitates (Fig. 5AB)
PMID:31895039 PBO:0095055 Figure 2—figure supplement 1
PMID:31895039 FYPO:0002060 36.5°C
PMID:31895039 FYPO:0002060 Fig.1 36.5°C
PMID:31895039 PBO:0095056 Fig. 2
PMID:31895039 FYPO:0002060 Fig. 1 36.5°C
PMID:31895039 PBO:0095057 fig1c
PMID:31895039 PBO:0095058 Fig.1
PMID:31895039 PBO:0095059 Fig.1
PMID:31895039 FYPO:0002060 Figure 1—figure supplement 1
PMID:31895039 FYPO:0002061 Figure 1—figure supplement 1
PMID:31895039 FYPO:0001234 "Figure 1—figure supplement 1. ""although colonies were tiny and grew very slowly"""
PMID:31895039 PBO:0095060 Fig.5
PMID:31895039 PBO:0095061 Phosphorylates Rad21 on threonine 262. Fig.5
PMID:31895039 FYPO:0002061 Fig.7
PMID:31895039 FYPO:0000674 Fig.7
PMID:31895039 FYPO:0002060 Fig.7 34°C
PMID:31895039 FYPO:0000674 Fig.7
PMID:31895039 PBO:0095062 Fig.7. Phenotype suppressed by the deletion of pef1
PMID:31895039 PBO:0095063 Fig.7. Phenotype suppressed by the deletion of pef1
PMID:31895039 FYPO:0002061 34°C, Fig.7
PMID:31895039 FYPO:0002060 34°C, Fig.7
PMID:31895039 FYPO:0002060 Fig.5
PMID:31895039 FYPO:0002060 Fig.8
PMID:31895039 FYPO:0002060 Fig.8
PMID:31895039 FYPO:0002060 Fig.8
PMID:31895039 FYPO:0002060 Fig.8
PMID:31895039 FYPO:0002060 Fig.8
PMID:31895039 PBO:0095064 Fig.8
PMID:31895039 PBO:0095065 Fig.8
PMID:31895039 PBO:0095066 Fig.1
PMID:31895039 PBO:0095067 Fig.1
PMID:31895039 PBO:0033478 Fig.1
PMID:31895039 PBO:0095068 Fig.6
PMID:31895039 PBO:0095069 Fig.7
PMID:31895039 PBO:0095054 Fig.7
PMID:31895039 PBO:0095069 Fig.4
PMID:31895039 PBO:0095054 Fig.4
PMID:31895039 PBO:0095070 Fig.7. Phenotype suppressed by the deletion of the pef1 gene
PMID:31895039 PBO:0095071 Fig.7. Phenotype suppressed by the deletion of the pef1 gene
PMID:31895039 FYPO:0002061 Fig.1b
PMID:31895039 PBO:0095072 Fig.2 supp1
PMID:31895039 PBO:0095073 "Figure 5Dm : ""In vitro Rad21 phosphorylation was abolished when Pef1 was purified from psl1 deleted cells"""
PMID:31895039 PBO:0095073 (Figure 5E and Figure 5—figure supplement 1). Replacement of T262 by an alanine abolished in vitro Rad21 phosphorylation by Pef1-GFP
PMID:31895039 PBO:0095073 fig 5g
PMID:31895039 PBO:0095075 antagonises pef1
PMID:31911490 PBO:0106144 (Fig. 1D). In addition, basal Sty1 activity was significantly higher in exponentially growing rnc1 cells ex- pressing a genomic C-terminal hemagglutinin (HA)-tagged version of the MAP kinase, compared to wild-type cells or a pmk1 mutant
PMID:31911490 PBO:0106176 Fig. 4B
PMID:31911490 PBO:0106179 I think these can be mopre specific decreased catabolism (ie increased stability in contract ti increased expression))
PMID:31911490 PBO:0106180 A nonphosphorylatable GST-Rnc1 fusion [GST-Rnc1(S/T6A)] expressed in fission yeast was several times less effective than the wild type (GST-Rnc1) in binding wak1, wis1 , atf1 , pyp1 , and pyp2 mRNAs in vitro (Fig. 5A)
PMID:31911490 PBO:0106138 and enhanced expression of Wak1, Wis1, and Pyp1 proteins during unperturbed growth (Fig. 5C) a
PMID:31911490 PBO:0106184 A nonphosphorylatable GST-Rnc1 fusion [GST-Rnc1(S/T6A)] expressed in fission yeast was several times less effective than the wild type (GST-Rnc1) in binding wak1, wis1 , atf1 , pyp1 , and pyp2 mRNAs in vitro (Fig. 5A)
PMID:31911490 PBO:0106183 A nonphosphorylatable GST-Rnc1 fusion [GST-Rnc1(S/T6A)] expressed in fission yeast was several times less effective than the wild type (GST-Rnc1) in binding wak1, wis1 , atf1 , pyp1 , and pyp2 mRNAs in vitro (Fig. 5A)
PMID:31911490 PBO:0106182 A nonphosphorylatable GST-Rnc1 fusion [GST-Rnc1(S/T6A)] expressed in fission yeast was several times less effective than the wild type (GST-Rnc1) in binding wak1, wis1 , atf1 , pyp1 , and pyp2 mRNAs in vitro (Fig. 5A)
PMID:31911490 PBO:0106181 A nonphosphorylatable GST-Rnc1 fusion [GST-Rnc1(S/T6A)] expressed in fission yeast was several times less effective than the wild type (GST-Rnc1) in binding wak1, wis1 , atf1 , pyp1 , and pyp2 mRNAs in vitro (Fig. 5A)
PMID:31911490 PBO:0106164 fig 4h
PMID:31911490 FYPO:0006822 12.13 + 0.1
PMID:31911490 PBO:0106160 fig2C
PMID:31911490 FYPO:0001122 fig 1B
PMID:31911490 PBO:0106159 I think these can be mopre specific decreased catabolism (ie increased stability in contract ti increased expression))
PMID:31911490 PBO:0106158 I think these can be mopre specific decreased catabolism (ie increased stability in contract ti increased expression))
PMID:31911490 PBO:0106157 Fig. 5B
PMID:31911490 PBO:0093712 fig 5e
PMID:31911490 PBO:0106138 Fig 2B
PMID:31911490 FYPO:0006822 (Fig. 1B)
PMID:31911490 PBO:0106167 Fig. 1B
PMID:31911490 PBO:0106167 Fig. 1B cell length at division either of pmk1 cells or in a mutant strain lacking the dual-specificity phos- phatase Pmp1 that dephosphorylates and inactivates Pmk1 in vivo (14), ... was similar to that of wild-type cells (Fig. 1B)
PMID:31911490 PBO:0101762 fig 3f
PMID:31911490 PBO:0106170 fig 5C
PMID:31911490 PBO:0093712 Fig. 1B Fig. 1C (14.040.25 versus 11.980.29m, respectively)
PMID:31911490 PBO:0106146 FIg2
PMID:31911490 PBO:0106155 Pyp2 protein levels increased 2 times in the mutant background (Fig. 5C), but they were of a lower magnitude than that in rnc1 versus wild-type cells (8 to 9 times) (Fig. 2C
PMID:31911490 PBO:0106157 I think these can be mopre specific decreased catabolism (ie increased stability in contract ti increased expression))
PMID:31911490 FYPO:0006822 (Fig. 1B)
PMID:31911490 PBO:0092746 These results suggest that while T50 is a main phosphorylation site for Sty1 within Rnc1, other phosphosites are likely targeted by this kinase in vivo.
PMID:31932483 FYPO:0000087 Fig 4B; 0.5 mM H2O2 in agar
PMID:31932483 FYPO:0000087 Fig 4B; 0.5 mM H2O2 in agar
PMID:31932483 FYPO:0000087 Fig 4B; 0.5 mM H2O2 in agar
PMID:31932483 FYPO:0005947 Fig 4B; 1 M KCl in agar
PMID:31932483 PBO:0101320 Fig. 4A
PMID:31932483 MOD:00210 Fig. 3
PMID:31932483 PBO:0101321 Fig. 2
PMID:31932483 FYPO:0005947 Fig 4B; 1 M KCl in agar
PMID:31932483 FYPO:0001214 Fig 4B; 1 M KCl in agar
PMID:31932483 FYPO:0007332 Fig. 6F
PMID:31932483 PBO:0101318 Fig. 6E
PMID:31932483 PBO:0101319 Fig. 7E
PMID:31932483 FYPO:0000962 Fig 4B; 0.5 mM H2O2 in agar
PMID:31932483 FYPO:0000962 Fig 4B; 0.5 mM H2O2 in agar
PMID:31932483 FYPO:0000962 Fig 4B; 0.5 mM H2O2 in agar
PMID:31932483 FYPO:0000962 Fig 4B; 0.5 mM H2O2 in agar
PMID:31932483 FYPO:0005947 Fig 4B; 1 M KCl in agar
PMID:31932483 FYPO:0005947 Fig 4B; 1 M KCl in agar
PMID:31932483 FYPO:0005947 Fig 4B; 1 M KCl in agar
PMID:31932483 FYPO:0005947 Fig 4B; 1 M KCl in agar
PMID:31941401 FYPO:0000674 Fig. S2)
PMID:31941401 PBO:0108221 Figure 1G)
PMID:31941401 PBO:0108221 Figure 1G)
PMID:31941401 PBO:0108221 Figure 1G)
PMID:31941401 PBO:0108222 Figure 1G)
PMID:31941401 PBO:0105271 Pho8Δ60 assay (Fig. S3A).
PMID:31941401 FYPO:0006295 Figure 2A Pho8Δ60 autophagy assay
PMID:31941401 PBO:0108220 Figure 3A,B
PMID:31941401 PBO:0105271 In contrast, Pho8Δ60 activity was only restored to about half of the wild-type level when expressing Atg38[AIM mut]. AND Tdh1-YFP processing assay
PMID:31941401 FYPO:0006295 Fig. S2)
PMID:31941401 PBO:0105271 Pho8Δ60 assay (Fig. S3A).
PMID:31941401 FYPO:0006266 Fig. S2
PMID:31941401 FYPO:0006295 Figure 1B
PMID:31941401 PBO:0108228 Figure 3A,B ut reduced the PAS accumulation of the ...t Atg14, ...s Atg18b and Atg24b, Atg2, Atg5, Atg16, and Atg8
PMID:31941401 PBO:0108227 Figure 3A,B ut reduced the PAS accumulation of the ...t Atg14, ...s Atg18b and Atg24b, Atg2, Atg5, Atg16, and Atg8
PMID:31941401 PBO:0108226 Figure 3A,B ut reduced the PAS accumulation of the ...t Atg14, ...s Atg18b and Atg24b, Atg2, Atg5, Atg16, and Atg8
PMID:31941401 PBO:0108225 Figure 3A,B ut reduced the PAS accumulation of the ...t Atg14, ...s Atg18b and Atg24b, Atg2, Atg5, Atg16, and Atg8
PMID:31941401 PBO:0108224 Figure 3A,B ut reduced the PAS accumulation of the ...t Atg14, ...s Atg18b and Atg24b, Atg2, Atg5, Atg16, and Atg8
PMID:31941401 PBO:0108223 Figure 3A,B ut reduced the PAS accumulation of the ...t Atg14, ...s Atg18b and Atg24b, Atg2, Atg5, Atg16, and Atg8
PMID:31941401 PBO:0108222 Figure 1G)
PMID:31941401 PBO:0108221 Figure 1F
PMID:31941401 PBO:0108221 Figure 1E
PMID:31980821 FYPO:0002955 As previously shown, we ob- served that telomere erosion and STEEx formation in ter1 cells correlates with defects to exit properly from G0 (22)
PMID:31980821 PBO:0094925 Indeed, in bqt4 ter1 cells the percentage of cells that are unable to form a colony increased in correlation with the massive accumulation of STEEx at D1 and D3 of senes- cence
PMID:31980821 FYPO:0006516 5A. bqt4delta/ telomerase + cells exhibited wild-type telomeres that were stable in post-mitotic cells
PMID:31980821 PBO:0038206 In contrast to ter1 cells in which the loss of growth capacity was progressive, the growth of bqt4 ter1 cells was severely impaired (Figure 4A and Supplementary Fig- ure S2).
PMID:31980821 PBO:0094919 When ter1+ gene was deleted in bqt4 cells, we observed that the combination of telomere erosion and NE dissociation provokes a massive accumula- tion of TERRA in Vg cells and this robust increase in tran- scription is even stronger after 48H in quiescence
PMID:31980821 PBO:0094920 TERRA level was higher in bqt4 than WT in vegetative cells and this difference was substantially inten- sified after 48H in quiescence (Figure 6A),
PMID:31980821 FYPO:0007414 2B
PMID:31980821 FYPO:0007269 Figure 2D We found that telomere attrition observed in the absence of telomerase did not significantly impair telomere hyperclusterization in quiescence. However, telomere clus- terization did not reach WT level in ter1 cells after 3 days in G0.
PMID:31980821 FYPO:0007419 2D althouh also the percentage of cells that contain a unique telomeric cluster in G0 after streaks 3 and 4 (Fig- ure 2D). We found that telomere attrition observed in the absence of telomerase did not significantly impair telomere hyperclusterization in quiescence. However, telomere clus- terization did not reach WT level in ter1 cells after 3 days in G0.
PMID:31980821 FYPO:0007419 3D We confirmed that telomere foci moved from nuclear periphery to a more central area (zone 1 to zone 2 or 3) in bqt4 Vg cells
PMID:31980821 FYPO:0007419 zoning of telomere foci within the nuclear envelope was severely impaired in bqt4 ter1 for vegetative and qui- escent cells (Supplementary Figure S3D and E).
PMID:31980821 FYPO:0007419 zoning of telomere foci within the nuclear envelope was severely impaired in bqt4 ter1 for vegetative and qui- escent cells (Supplementary Figure S3D and E).
PMID:31980821 PBO:0094921 STEEx were readily detected as two bands at 1500 and 900 bp, the highest one being prevalent (Figure 5A, right panel). Strikingly, we observed a massive accumulation of STEEx in quiescent bqt4 ter1 cells at early time points of quiescence (Figure 5A).
PMID:31980821 PBO:0094922 TERRA level was higher in bqt4 than WT in vegetative cells and this difference was substantially inten- sified after 48H in quiescence (Figure 6A),
PMID:31980821 PBO:0094923 When ter1+ gene was deleted in bqt4 cells, we observed that the combination of telomere erosion and NE dissociation provokes a massive accumula- tion of TERRA in Vg cells and this robust increase in tran- scription is even stronger after 48H in quiescence
PMID:31980821 PBO:0094924 accumulation of TERRA depends on Cid14, a RNA poly adenyl-transferase, (Supplementary Figure S5)
PMID:32012158 PBO:0105690 figure 5A
PMID:32012158 PBO:0105675 figure 1 a
PMID:32012158 PBO:0105676 figure 1 a
PMID:32012158 PBO:0094605 figure S3A
PMID:32012158 PBO:0094604 figure S3A
PMID:32012158 FYPO:0006821 figure S3A
PMID:32012158 FYPO:0002085 figure S3A
PMID:32012158 PBO:0105680 figure 2
PMID:32012158 PBO:0105679 figure 1 a
PMID:32012158 PBO:0095145 figure 2
PMID:32012158 PBO:0105686 figure 5A
PMID:32012158 PBO:0105678 figure 1 a
PMID:32012158 PBO:0105681 figure S3A COULD ALSO ADD TO ANTISENS RPL402, BUT NOT ANNOTATED
PMID:32012158 PBO:0105684 figure 3A
PMID:32012158 PBO:0105683 The interaction between these proteins was abolished in the absence of red1 (Fig 3A), suggesting that Red1 physically links Mmi1 with the exosome. and Fig 4B The direct binding of Red1 with Rrp6 was also observed (Fig 4B).
PMID:32012158 PBO:0105682 figure S3A COULD ALSO ADD TO ANTISENS RPL402, BUT NOT ANNOTATED
PMID:32012158 PBO:0105681 figure S3A COULD ALSO ADD TO ANTISENS RPL402, BUT NOT ANNOTATED
PMID:32012158 PBO:0105681 figure S3A COULD ALSO ADD TO ANTISENS RPL402, BUT NOT ANNOTATED IN GENOME
PMID:32012158 PBO:0105687 figure 5B
PMID:32012158 PBO:0094866 figure S3A
PMID:32012158 PBO:0094605 figure S3A
PMID:32012158 PBO:0094604 figure S3A
PMID:32012158 PBO:0094866 figure S3A
PMID:32012158 PBO:0105677 figure 1 a
PMID:32012158 PBO:0095145 figure 5B
PMID:32012158 PBO:0105688 figure 6 a
PMID:32012158 PBO:0105689 figure 1 a
PMID:32023460 PBO:0103690 decreased Pil1 protein abundance Figure S1F
PMID:32023460 PBO:0103693 (Figure 4 S4B).
PMID:32023460 PBO:0103691 Pil1 lacking the C terminus failed to interact with Scs2 (Figure S5F
PMID:32023460 GO:0007029 cortical
PMID:32023460 FYPO:0007263 resulting in the formation of fewer punctate eisosomes (Figure S1B).
PMID:32023460 PBO:0103689 (Figure S1F). increased Pil1 phosphorylation was detected in these cells
PMID:32023460 FYPO:0007263 PMID:32023460 Of note, the PM coverage of eisosomes was also reduced in scs2Dscs22D cells (Figure S1B), implicating VAPs in the regulation of eisosome assembly.
PMID:32023460 FYPO:0002872 (Figures 1A and 1B) (EM) data also confirmed that eisosomes/MCC associated with the cER, especially with curved cER rims, over the lateral cell cortex in WT (Figures 1C and S1A). Such an asso- ciation was abolished in scs2Dscs22D cells lacking ER-PM con- tacts.(the Exp says more but I don't know how to capture that)
PMID:32023460 FYPO:0007268 the cortical tubular ER pattern changes slower than wild type
PMID:32023460 FYPO:0007268 the cortical tubular ER pattern changes slower than wild type
PMID:32023460 FYPO:0007273 increased cortical ER remodeling dynamics the cortical tubular ER pattern changes faster than wild type
PMID:32023460 FYPO:0007273 increased cortical ER remodeling dynamics
PMID:32023460 FYPO:0007273 increased cortical ER remodeling dynamics
PMID:32023460 FYPO:0007268 the cortical tubular ER pattern changes slower than wild type
PMID:32023460 FYPO:0007268 (Figure 3A) decreased cortical ER remodeling dynamics the cortical tubular ER pattern changes slower than wild type
PMID:32023460 FYPO:0007268 (Figure S3C). the cortical tubular ER pattern changes slower than wild type
PMID:32023460 FYPO:0007268 (Figure 3A) the cortical tubular ER pattern changes slower than wild type
PMID:32023460 FYPO:0007273 (Fig- ure S5G). the cortical tubular ER pattern changes faster than wild type
PMID:32023460 FYPO:0007273 fig2 increased cortical ER remodeling dynamics
PMID:32023460 FYPO:0007273 fig2 increased cortical ER remodeling dynamics
PMID:32023460 FYPO:0007273 fig2 the cortical tubular ER pattern changes faster than wild type
PMID:32023460 FYPO:0007265 (Figure S1F). Pil1 mis-assembled into fewer and longer filaments
PMID:32023460 FYPO:0007268 Figure S3D) VW CHANGED GENOTYPE TO INCLUDE pil1 delta background. sey1 deleta is impled
PMID:32023460 PBO:0103688 decreased Pil1 protein abundance Figure S1F
PMID:32023460 FYPO:0006330 (Figure 4 S4B).
PMID:32023460 FYPO:0006330 (Figure 4 S4B).
PMID:32023460 FYPO:0006330 (Figure 4 S4B).
PMID:32023460 FYPO:0006330 (Figure 4 S4B).
PMID:32032353 PBO:0092298 S.p. wtf13 assayed; doesn't specify which isoform (or if it's both)
PMID:32032353 PBO:0092298 S.p. wtf13 assayed; doesn't specify which isoform (or if it's both)
PMID:32032353 PBO:0092298 assayed by expressing S.k. ortholog in S.p.
PMID:32032353 GO:0005783 assayed by expressing S.k. ortholog in S.p.
PMID:32032353 GO:0110134 inferred from crosses involving hemizygous diploids
PMID:32032353 GO:0110134 inferred from crosses involving hemizygous diploids
PMID:32032353 PBO:0092298 assayed by expressing S.k. ortholog in S.p.
PMID:32032353 FYPO:0000590 Both wtf21 alleles were found at equal frequency in the viable spores.
PMID:32047038 FYPO:0000969 (Fig. 5H) This defect in UV-resistance can be rescued by wild-type SpCsn2, but not its IP6 binding-deficient K70E mutant .
PMID:32047038 FYPO:0000268 (Fig. 5H) This defect in UV-resistance can be rescued by wild-type SpCsn2, but not its IP6 binding-deficient K70E mutant .
PMID:32047038 FYPO:0000268 (Fig. 5H) This defect in UV-resistance can be rescued by wild-type SpCsn2, but not its IP6 binding-deficient K70E mutant .
PMID:32047038 PBO:0095188 (Fig. 5G) The IP6-binding pocket formed between CSN2 and Rbx1 is remarkably conserved from yeasts to plants and humans (Figs. 2D and 3D). Deleting ipk1, the yeast IP6 synthase, abolishes Csn2 interaction with Cul1 in Schizosaccharomyces pombe,
PMID:32053662 PBO:0105866 figure5 a-c
PMID:32053662 PBO:0105869 6d
PMID:32053662 PBO:0105870 6bc
PMID:32053662 PBO:0105870 6bc
PMID:32053662 PBO:0105870 6bc
PMID:32053662 PBO:0105870 6bc
PMID:32053662 PBO:0105870 6bc
PMID:32053662 PBO:0105869 6d
PMID:32053662 PBO:0105868 6d
PMID:32053662 PBO:0105867 figure5 a-c
PMID:32053662 PBO:0105866 figure5 a-c
PMID:32053662 PBO:0105866 figure5 a-c
PMID:32053662 PBO:0105866 figure5 a-c
PMID:32053662 PBO:0105867 figure5 a-c
PMID:32053662 PBO:0105866 figure5 a-c
PMID:32053662 PBO:0105866 figure5 a-c
PMID:32062975 FYPO:0000091 fig 6B
PMID:32062975 FYPO:0003736 Figure 6A
PMID:32062975 FYPO:0001903 Figure 6A
PMID:32062975 FYPO:0000141 Figure 6A
PMID:32071154 FYPO:0002350 figure 2C
PMID:32071154 PBO:0106940 figure 6F
PMID:32071154 PBO:0106940 figure 6F
PMID:32071154 PBO:0106937 fig 2B
PMID:32071154 FYPO:0007317 polysome profile
PMID:32071154 PBO:0106936 vw: changed from slow growth (6hr)
PMID:32071154 FYPO:0002348 fig 5C
PMID:32071154 FYPO:0007321 fig 4
PMID:32071154 FYPO:0007323 fig4
PMID:32071154 FYPO:0007323 fig 4
PMID:32071154 FYPO:0001896 Fig 6a
PMID:32071154 FYPO:0001896 Fig 6a
PMID:32071154 FYPO:0001896 Fig 6a
PMID:32071154 FYPO:0007319 fig 5C
PMID:32071154 FYPO:0007319 fig 5C
PMID:32071154 FYPO:0007319 fig 5C
PMID:32071154 FYPO:0001896 Fig 6a
PMID:32071154 FYPO:0001897 Figure 6E
PMID:32071154 FYPO:0007321 fig 4
PMID:32071154 FYPO:0007321 fig 4
PMID:32071154 FYPO:0007321 fig 4
PMID:32071154 FYPO:0002061 polysome profile
PMID:32071154 FYPO:0002061 Fig 7B
PMID:32071154 FYPO:0002061 Fig 7B
PMID:32071154 FYPO:0001897 Figure 6E
PMID:32071154 FYPO:0007323 fig4
PMID:32071154 FYPO:0001357 Fig 7B
PMID:32071154 FYPO:0002061 Fig 7
PMID:32071154 FYPO:0002061 Fig 7B
PMID:32071154 FYPO:0002061 Fig 7
PMID:32071154 FYPO:0002061 Fig 7
PMID:32071154 FYPO:0002061 Fig 7
PMID:32075773 FYPO:0007299 fig2B S2B-D
PMID:32075773 FYPO:0007299 fig2B S2B-D
PMID:32075773 FYPO:0007300 fig2B S2B-D
PMID:32075773 FYPO:0007299 fig2B S2B-D
PMID:32075773 FYPO:0007299 fig2B S2B-D
PMID:32075773 FYPO:0007299 fig2B S2B-D
PMID:32075773 FYPO:0007299 fig2B S2B-D
PMID:32075773 PBO:0108266 Figure 1B
PMID:32075773 PBO:0108267 Figure 1B.
PMID:32075773 PBO:0100916 37� C is a moderate heat shock for fission yeast, which does not slow growth nor exerts toxicity to wild-type cultures, but significantly affects the viability of cells lacking stress signaling components, such as the MAP kinase Sty1 (Figures 1E and S1B).
PMID:32075773 FYPO:0007301 Fig S2A
PMID:32075773 FYPO:0007301 Fig S2
PMID:32075773 FYPO:0007301 Fig S2
PMID:32075773 FYPO:0007301 Fig S2
PMID:32075773 FYPO:0007301 Fig S2
PMID:32075773 FYPO:0002348 fig 3D) Lack of Mas5 abolishes both PAC formation and the assembly of stress granules.
PMID:32075773 PBO:0108269 fig 4D
PMID:32075773 PBO:0108269 fig 4D
PMID:32084401 PBO:0097956 Fig 2G when plo1 is advanced on to the spindle pole body cdc13HPM is also advanced
PMID:32084401 PBO:0097955 Fig 2G when plo1 is advanced on to the spindle pole body cdc13HPM is also advanced
PMID:32084401 FYPO:0002061 Fig2A cells expressing only cdc13HPM are unable to form colonies
PMID:32084401 PBO:0018346 cdc13HPM mutant can localise to SPB in mitosis
PMID:32084401 PBO:0097955 Fig 2G when plo1 is advanced on to the spindle pole body cdc13HPM is also advanced
PMID:32084401 PBO:0097956 Fig 2G when plo1 is advanced on to the spindle pole body cdc13HPM is also advanced
PMID:32084401 PBO:0097957 Fig 2H when plo1 kinase is inactivated at the restrictive temperature the HPM mutant does not bind to the SPB after release into mitosis
PMID:32084401 PBO:0097951 Fig S1D cdc13+ and cdc13HPM are not differentially sensitive to rum1. S phase same in both strains in absence of rum1
PMID:32084401 FYPO:0001357 FigS1A,C cells arrested G1 in low nitrogen then released into S phase at restrictive temperature cells the tested for viability at 25°C after S phase with only ccdc13hpm
PMID:32084401 PBO:0097956 Fig 2G when plo1 is advanced on to the spindle pole body cdc13HPM is also advanced
PMID:32084401 PBO:0097955 Fig 2G when plo1 is advanced on to the spindle pole body cdc13HPM is also advanced
PMID:32084401 PBO:0018634 cdc13HPM mutant fails to localise to the SPB during G2
PMID:32084401 PBO:0097959 Fig3A when an integrated copy of cdc13HPM (at leu1 locus) is expressed from the cdc13 promoter the endogenous cdc13+ cells are advanced into mitosis. This suggests cdc13HPM can do some of events required for mitotic entry. This is independent of the G1/S cyclins
PMID:32084401 PBO:0097958 Fig2H cdc13HPM localisation to SPB in mitosis is dependent on plo1 activity
PMID:32084401 PBO:0097951 Fig1B cells blocked in G1 by nitrogen starvation and released in presence of nitrogen into S phase with cdc13+ switched off
PMID:32084401 PBO:0097952 FigS1-E cdc2 Y15 phosphorylation same in cdc13+ control and cdc13HPM strain endogenous cdc13+ is completely degraded so does not contribute in the HPM mutant
PMID:32084401 PBO:0097953 Fig2B-D Endogenous untagged nmt 41cdc13+ is expressed to allow cells to proceed into mitosis tagged exogenous cdc13HPM or cdc13+ control can be seen at SPB
PMID:32084401 PBO:0097954 Fig2A cells are unable to enter mitosis in absence of cdc13+ expression-no septated cells
PMID:32084401 PBO:0097958 Fig2H cdc13HPM localisation to SPB in mitosis is dependent on plo1 activity
PMID:32084401 FYPO:0000776 FIGURE S1E Wee1-dependent CDK-Y15 phosphorylation was similar between Cdc13HPM-CDK and Cdc13WT-CDK
PMID:32101481 FYPO:0007393 (Figure 2, C and
PMID:32101481 PBO:0100705 the slow-migrating, phosphorylated forms of Cdc15 were reduced in pom1Δ cells (Figure 3B), and recombinant Pom1 efficiently phosphorylated recombinant N-terminal (Cdc15N; amino acids [aa]1–460) ||||||. later....We conclude that Cdc15 is a key substrate in the Pom1-mediated tip occlusion pathway.
PMID:32101481 PBO:0100706 Figure 6, A and B
PMID:32101481 PBO:0100707 Figure 6, A and B
PMID:32101481 PBO:0100695 Figure 1A and 1B
PMID:32101481 PBO:0100698 4B?
PMID:32101481 PBO:0100699 Though the length of CR formation (node appearance to complete ring) was similar in wild type, cdc15-22A, and cdc15-22D, the periods of maturation (interval between CR formation and constriction initiation) and constriction (start to end of CR diameter decrease) were shorter in cdc15-22A and longer in cdc15-22D (Figure 4F).
PMID:32101481 PBO:0100702 Indeed, the percentage of tip septa was significantly reduced in mid1Δ pom1as1 cdc15-22D cells (Figure 4G).
PMID:32101481 PBO:0100704 Figure 6E
PMID:32101481 PBO:0100702 Figure 6D Indeed, deleting components of the CR scaffolded by Cdc15 (e.g., pxl1 or fic1) suppressed tip septation in mid1Δ pom1as1cells to a similar degree as cdc15-22D (Figure 6, D and E).
PMID:32101481 PBO:0100704 Figure 2D
PMID:32101745 PBO:0099440 Figure S5 However, the truncation did not reduce Iss1 interaction with Rrp6
PMID:32101745 PBO:0099439 Figure 5F the iss1-DC truncation did disrupt its interaction with Mmi1.
PMID:32101745 PBO:0099438 Figure 5B the iss1-DC mutation significantly reduced H3K9me2 at both ssm4 and mei4).
PMID:32101745 PBO:0094605 fig 4g & S4. /Figure 5A)
PMID:32101745 FYPO:0005420 fig 4e The 73 genes with increased expression in the iss1-DC mutant were evaluated for common functions and were strongly enriched for factors important for iron assimilation GO:0033212.
PMID:32101745 PBO:0099436 Figure 5B the iss1-DC mutation significantly reduced H3K9me2 at both ssm4 and mei4).
PMID:32101745 PBO:0094283 figure 3E
PMID:32101745 GO:1990251 Figure 5H. We found that Iss1 assembles into nuclear dots, and these co-localized with Pla1, indicating that Iss1 also assembles in vivo with RNA elimination factors
PMID:32101745 PBO:0094679 figure 3A/B
PMID:32101745 FYPO:0001357 figure 3A
PMID:32101745 PBO:0099437 3' mrna extension figure Figure 4C; Figure S3 Although the percentage of total reads was relatively small, the iss1-DC mutation caused a reproducible and statistically sig- nificant extension of the 30 end of transcripts by about 200 nt.
PMID:32101745 FYPO:0004170 figure 3F
PMID:32101745 PBO:0094604 fig 4g & S4. /Figure 5A)
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen, spot assay
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007359 spot assay
PMID:32142608 FYPO:0007359 spot assay
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007359 plate-based screen, spot assay
PMID:32142608 FYPO:0007358 spot assay
PMID:32142608 FYPO:0007359 spot assay
PMID:32142608 FYPO:0007359 spot assay
PMID:32142608 FYPO:0007358 plate-based screen, spot assay
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007359 spot assay
PMID:32142608 FYPO:0007358 plate-based screen, spot assay
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 MOD:00046 Phosphorylated during growth in media containing heavy water.
PMID:32142608 FYPO:0007359 spot assay
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007359 spot assay
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen, spot assay
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen, spot assay
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 spot assay
PMID:32142608 FYPO:0007359 spot assay
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen
PMID:32142608 FYPO:0007358 plate-based screen, spot assay
PMID:32168916 PBO:0101609 Figure 4 SAP155K700E restopred splicing to prp10-1
PMID:32168916 PBO:0101608 Figure 4 (ALSO TFIIH but not sure which sunbunit)
PMID:32168916 FYPO:0002060 Figure S4
PMID:32168916 FYPO:0002060 Figure S4
PMID:32168916 FYPO:0002060 Figure S4
PMID:32168916 FYPO:0002060 Figure S4
PMID:32168916 PBO:0101607 Figure 4 (ALSO TFIIH but not sure which sunbunit)
PMID:32168916 FYPO:0004085 fig3
PMID:32168916 FYPO:0004085 fig3
PMID:32168916 PBO:0101610 Figure 3 & S4(ALSO TFIIH but not sure which sunbunit)
PMID:32168916 PBO:0101609 Figure 3 & S4(ALSO TFIIH but not sure which sunbunit)
PMID:32204793 PBO:0105171 Figure 7—figure supplement 1B; spot test
PMID:32204793 PBO:0105171 Figure 7—figure supplement 1B; spot test
PMID:32204793 PBO:0105170 Figure 1—figure supplement 1A, Figure 7C,D, Figure 7—figure supplement 1A; spot test and survival assay
PMID:32204793 PBO:0105170 Figure 1—figure supplement 1A; spot test
PMID:32204793 PBO:0105170 Figure 1—figure supplement 1A; spot test
PMID:32204793 PBO:0105172 in complex with Swi5; Figure 6
PMID:32204793 PBO:0105172 in complex with Sfr1; Figure 6
PMID:32204793 PBO:0110075 actually inferred from combination of in vitro assay and phenotypes; Figures 1 & 5, including supplements
PMID:32204793 PBO:0110075 actually inferred from combination of in vitro assay and phenotypes; Figures 1 & 5, including supplements
PMID:32204793 FYPO:0007346 Figure 7A,B; spot test and survival assay
PMID:32204793 FYPO:0007346 Figure 7A,B; spot test and survival assay
PMID:32204793 FYPO:0007346 Figure 7A,B; spot test and survival assay
PMID:32204793 PBO:0105166 Figure 5B, Figure 5—figure supplement 1C
PMID:32204793 PBO:0105167 Figure 6—figure supplement 1
PMID:32204793 PBO:0105168 Figure 5B, Figure 5—figure supplement 1C
PMID:32204793 PBO:0105169 Figure 5B, Figure 5—figure supplement 1C
PMID:32204793 PBO:0105168 Figure 5B, Figure 5—figure supplement 1C
PMID:32204793 PBO:0105169 Figure 6—figure supplement 1
PMID:32204793 FYPO:0000265 Figure 1D, Figure 1—figure supplement 1; spot test and survival assay
PMID:32204793 FYPO:0000265 Figure 1D, Figure 1—figure supplement 1; spot test and survival assay
PMID:32204793 PBO:0105170 Figure 7C,D; spot test and survival assay
PMID:32204793 PBO:0105171 Figure 7C,D; spot test and survival assay
PMID:32204793 PBO:0105171 Figure 7C,D; spot test and survival assay
PMID:32204793 PBO:0105170 Figure 7—figure supplement 1B; spot test
PMID:32269268 PBO:0107531 Fig 1
PMID:32269268 PBO:0107525 "25 degrees C; using ""low temperature"" to distinguish from 30 degrees C; Fig 1"
PMID:32269268 PBO:0107530 Fig 1
PMID:32269268 PBO:0107529 Fig 1
PMID:32269268 PBO:0033972 "25 degrees C; using ""low temperature"" to distinguish from 30 degrees C; Fig 1"
PMID:32269268 PBO:0107528 Fig 1
PMID:32269268 PBO:0107526 Fig 1
PMID:32269268 PBO:0107527 Fig 1
PMID:32269268 PBO:0107524 "25 degrees C; using ""low temperature"" to distinguish from 30 degrees C; Fig 1"
PMID:32269268 PBO:0107526 Fig 1
PMID:32269268 PBO:0107525 Fig 1
PMID:32269268 FYPO:0007531 Fig 5
PMID:32269268 FYPO:0000220 Fig 4
PMID:32269268 FYPO:0004573 Fig 4
PMID:32269268 FYPO:0004137 Fig 2
PMID:32269268 PBO:0107524 "25 degrees C; using ""low temperature"" to distinguish from 30 degrees C; Fig 1"
PMID:32269268 PBO:0107523 Fig 1
PMID:32269268 FYPO:0000220 Fig S2
PMID:32269268 FYPO:0004573 Fig 2, S1
PMID:32269268 GO:0140720 [vw added to cover missing EXP annotation based on localization phenotype below]
PMID:32269268 FYPO:0007654 Fig 5
PMID:32269268 FYPO:0007653 Fig 5
PMID:32269268 FYPO:0007226 Fig 5
PMID:32277274 FYPO:0007209 figb
PMID:32277274 PBO:0106053 fig2
PMID:32277274 FYPO:0000460 figa
PMID:32282918 PBO:0094840 Figure 11
PMID:32282918 FYPO:0002085 Figure 1
PMID:32282918 PBO:0094852 Figure S7
PMID:32282918 PBO:0094849 Figure S7
PMID:32282918 PBO:0094848 Figure S7
PMID:32282918 PBO:0094847 Figure S7
PMID:32282918 PBO:0094844 Figure S7
PMID:32282918 PBO:0094843 Figure S7
PMID:32282918 PBO:0094842 Figure S7
PMID:32282918 PBO:0094841 Figure S7
PMID:32282918 PBO:0094840 Figure S7
PMID:32282918 PBO:0094839 Figure S7
PMID:32282918 PBO:0094838 Figure S7
PMID:32282918 PBO:0094837 Figure S7
PMID:32282918 PBO:0094834 Figure S7
PMID:32282918 PBO:0094833 Figure S7
PMID:32282918 PBO:0094832 Figure S7
PMID:32282918 PBO:0094828 Figure S7
PMID:32282918 PBO:0094822 Figure S7
PMID:32282918 PBO:0094817 Figure S7
PMID:32282918 PBO:0094815 Figure S7
PMID:32282918 PBO:0094812 Figure S7
PMID:32282918 PBO:0094810 Figure S7
PMID:32282918 PBO:0094805 Figure S7
PMID:32282918 PBO:0094803 Figure S7
PMID:32282918 PBO:0094800 Figure S7
PMID:32282918 PBO:0094796 Figure S7
PMID:32282918 PBO:0094795 Figure S7
PMID:32282918 PBO:0094794 Figure S7
PMID:32282918 PBO:0094792 Figure S7
PMID:32282918 PBO:0094791 Figure S7
PMID:32282918 PBO:0094789 Figure S7
PMID:32282918 PBO:0094788 Figure S7
PMID:32282918 PBO:0094785 Figure S7
PMID:32282918 PBO:0094773 Figure S7
PMID:32282918 PBO:0094781 Figure S7
PMID:32282918 PBO:0094772 Figure S7
PMID:32282918 PBO:0094778 Figure S7
PMID:32282918 FYPO:0002059 Figure S3
PMID:32282918 FYPO:0002059 Figure S3
PMID:32282918 FYPO:0001355 Figure S3
PMID:32282918 FYPO:0001355 Figure S3
PMID:32282918 FYPO:0002059 Figure S3
PMID:32282918 FYPO:0002059 Figure S3
PMID:32282918 FYPO:0001355 Figure S3
PMID:32282918 FYPO:0001355 Figure S3
PMID:32282918 FYPO:0000082 Figure 1
PMID:32282918 FYPO:0001357 Figure 9B
PMID:32282918 FYPO:0001357 Figure 9B
PMID:32282918 FYPO:0001357 Figure 7A
PMID:32282918 FYPO:0001357 Figure 7A
PMID:32282918 FYPO:0001357 Figure 5C
PMID:32282918 FYPO:0001357 Figure S3
PMID:32282918 FYPO:0001357 Figure S3
PMID:32282918 FYPO:0001357 Figure 1
PMID:32282918 FYPO:0001357 Figure 1
PMID:32282918 FYPO:0001357 Figure 1
PMID:32282918 PBO:0094857 Figure S2
PMID:32282918 PBO:0094857 Figure S2
PMID:32282918 PBO:0094857 Figure S2
PMID:32282918 PBO:0094857 Figure S2
PMID:32282918 PBO:0094857 Figure S2
PMID:32282918 PBO:0094856 Figure S2
PMID:32282918 PBO:0094856 Figure S2
PMID:32282918 PBO:0094856 Figure S2
PMID:32282918 PBO:0094856 Figure S2
PMID:32282918 PBO:0094856 Figure S1
PMID:32282918 FYPO:0008034 Figure S1
PMID:32282918 PBO:0094855 Figure S1
PMID:32282918 PBO:0094854 Figure S1
PMID:32282918 PBO:0094853 Figure S1
PMID:32282918 PBO:0094852 Figure 11
PMID:32282918 PBO:0094851 Figure 11
PMID:32282918 PBO:0094850 Figure 11
PMID:32282918 PBO:0094849 Figure 11
PMID:32282918 PBO:0094848 Figure 11
PMID:32282918 PBO:0094847 Figure 11
PMID:32282918 PBO:0094846 Figure 11
PMID:32282918 PBO:0094845 Figure 11
PMID:32282918 PBO:0094844 Figure 11
PMID:32282918 PBO:0094843 Figure 11
PMID:32282918 PBO:0094842 Figure 11
PMID:32282918 PBO:0094841 Figure 11
PMID:32282918 PBO:0094839 Figure 11
PMID:32282918 PBO:0094838 Figure 11
PMID:32282918 PBO:0094837 Figure 11
PMID:32282918 PBO:0094836 Figure 11
PMID:32282918 PBO:0094835 Figure 11
PMID:32282918 PBO:0094834 Figure 11
PMID:32282918 PBO:0094833 Figure 11
PMID:32282918 PBO:0094832 Figure 11
PMID:32282918 PBO:0094831 Figure 11
PMID:32282918 PBO:0094852 Figure 11
PMID:32282918 PBO:0094851 Figure 11
PMID:32282918 PBO:0094850 Figure 11
PMID:32282918 PBO:0094849 Figure 11
PMID:32282918 PBO:0094848 Figure 11
PMID:32282918 PBO:0094847 Figure 11
PMID:32282918 PBO:0094856 Figure S2
PMID:32282918 PBO:0094846 Figure 11
PMID:32282918 PBO:0094845 Figure 11
PMID:32282918 PBO:0094844 Figure 11
PMID:32282918 PBO:0094843 Figure 11
PMID:32282918 PBO:0094842 Figure 11
PMID:32282918 PBO:0094841 Figure 11
PMID:32282918 PBO:0094840 Figure 11
PMID:32282918 PBO:0094839 Figure 11
PMID:32282918 PBO:0094838 Figure 11
PMID:32282918 PBO:0094837 Figure 11
PMID:32282918 PBO:0094836 Figure 11
PMID:32282918 PBO:0094835 Figure 11
PMID:32282918 PBO:0094834 Figure 11
PMID:32282918 PBO:0094833 Figure 11
PMID:32282918 PBO:0094832 Figure 11
PMID:32282918 PBO:0094831 Figure 11
PMID:32282918 PBO:0094830 Figure 10
PMID:32282918 PBO:0094829 Figure 10
PMID:32282918 PBO:0094828 Figure 10
PMID:32282918 PBO:0094826 Figure 10
PMID:32282918 PBO:0094825 Figure 10
PMID:32282918 PBO:0094822 Figure 10
PMID:32282918 PBO:0094821 Figure 10
PMID:32282918 PBO:0094820 Figure 10
PMID:32282918 PBO:0094819 Figure 10
PMID:32282918 PBO:0094817 Figure 10
PMID:32282918 PBO:0094815 Figure 10
PMID:32282918 PBO:0094814 Figure 10
PMID:32282918 PBO:0094813 Figure 10
PMID:32282918 PBO:0094812 Figure 10
PMID:32282918 PBO:0094811 Figure 10
PMID:32282918 PBO:0094810 Figure 10
PMID:32282918 PBO:0094809 Figure 10
PMID:32282918 PBO:0094808 Figure 10
PMID:32282918 PBO:0094807 Figure 10
PMID:32282918 PBO:0094806 Figure 10
PMID:32282918 PBO:0094804 Figure 10
PMID:32282918 PBO:0094779 Figure 10
PMID:32282918 PBO:0094803 Figure 10
PMID:32282918 PBO:0094800 Figure 10
PMID:32282918 PBO:0094798 Figure 10
PMID:32282918 PBO:0094797 Figure 10
PMID:32282918 PBO:0094796 Figure 10
PMID:32282918 PBO:0094794 Figure 10
PMID:32282918 PBO:0094792 Figure 10
PMID:32282918 PBO:0094790 Figure 10
PMID:32282918 PBO:0094789 Figure 10
PMID:32282918 PBO:0094788 Figure 10
PMID:32282918 PBO:0094786 Figure 10
PMID:32282918 PBO:0094785 Figure 10
PMID:32282918 PBO:0094784 Figure 10
PMID:32282918 PBO:0094773 Figure 10
PMID:32282918 PBO:0094783 Figure 10
PMID:32282918 PBO:0094782 Figure 10
PMID:32282918 PBO:0094781 Figure 10
PMID:32282918 PBO:0094780 Figure 10
PMID:32282918 PBO:0094772 Figure 10
PMID:32282918 PBO:0094778 Figure 10
PMID:32282918 PBO:0094830 Figure 10
PMID:32282918 PBO:0094829 Figure 10
PMID:32282918 PBO:0094828 Figure 10
PMID:32282918 PBO:0094827 Figure 10
PMID:32282918 PBO:0094826 Figure 10
PMID:32282918 PBO:0094825 Figure 10
PMID:32282918 PBO:0094824 Figure 10
PMID:32282918 PBO:0094823 Figure 10
PMID:32282918 PBO:0094822 Figure 10
PMID:32282918 PBO:0094821 Figure 10
PMID:32282918 PBO:0094820 Figure 10
PMID:32282918 PBO:0094819 Figure 10
PMID:32282918 PBO:0094818 Figure 10
PMID:32282918 PBO:0094817 Figure 10
PMID:32282918 PBO:0094816 Figure 10
PMID:32282918 PBO:0094815 Figure 10
PMID:32282918 PBO:0094814 Figure 10
PMID:32282918 PBO:0094813 Figure 10
PMID:32282918 PBO:0094812 Figure 10
PMID:32282918 PBO:0094811 Figure 10
PMID:32282918 PBO:0094810 Figure 10
PMID:32282918 PBO:0094809 Figure 10
PMID:32282918 PBO:0094808 Figure 10
PMID:32282918 PBO:0094807 Figure 10
PMID:32282918 PBO:0094806 Figure 10
PMID:32282918 PBO:0094805 Figure 10
PMID:32282918 PBO:0094804 Figure 10
PMID:32282918 PBO:0094779 Figure 10
PMID:32282918 PBO:0094803 Figure 10
PMID:32282918 PBO:0094802 Figure 10
PMID:32282918 PBO:0094801 Figure 10
PMID:32282918 PBO:0094800 Figure 10
PMID:32282918 PBO:0094799 Figure 10
PMID:32282918 PBO:0094798 Figure 10
PMID:32282918 PBO:0094797 Figure 10
PMID:32282918 PBO:0094796 Figure 10
PMID:32282918 PBO:0094795 Figure 10
PMID:32282918 PBO:0094794 Figure 10
PMID:32282918 PBO:0094793 Figure 10
PMID:32282918 PBO:0094792 Figure 10
PMID:32282918 PBO:0094791 Figure 10
PMID:32282918 PBO:0094790 Figure 10
PMID:32282918 PBO:0094789 Figure 10
PMID:32282918 PBO:0094788 Figure 10
PMID:32282918 PBO:0094787 Figure 10
PMID:32282918 PBO:0094786 Figure 10
PMID:32282918 PBO:0094785 Figure 10
PMID:32282918 PBO:0094784 Figure 10
PMID:32282918 PBO:0094783 Figure 10
PMID:32282918 PBO:0094782 Figure 10
PMID:32282918 PBO:0094781 Figure 10
PMID:32282918 PBO:0094780 Figure 10
PMID:32282918 PBO:0094778 Figure 10
PMID:32282918 FYPO:0001355 Figure 9B
PMID:32282918 FYPO:0001355 Figure 9B
PMID:32282918 FYPO:0001355 Figure 9B
PMID:32282918 FYPO:0001355 Figure 9B
PMID:32282918 FYPO:0001355 Figure 9B
PMID:32282918 FYPO:0001355 Figure 9B
PMID:32282918 FYPO:0000080 Figure 9B
PMID:32282918 FYPO:0000080 Figure 9B
PMID:32282918 FYPO:0000082 Figure 9B
PMID:32282918 PBO:0094777 Figure 9C
PMID:32282918 PBO:0094771 Figure 9C
PMID:32282918 PBO:0094738 Figure 9C
PMID:32282918 PBO:0094738 Figure 9C
PMID:32282918 PBO:0094738 Figure 7B
PMID:32282918 PBO:0094738 Figure 7B and 8B
PMID:32282918 PBO:0094771 Figure 8B
PMID:32282918 PBO:0094771 Figure 8B
PMID:32282918 PBO:0094771 Figure 8B
PMID:32282918 PBO:0094771 Figure 8B
PMID:32282918 PBO:0094771 Figure 8B
PMID:32282918 PBO:0094771 Figure 8B
PMID:32282918 FYPO:0001357 Figure 8A
PMID:32282918 FYPO:0001357 Figure 8A
PMID:32282918 FYPO:0001357 Figure 8A
PMID:32282918 FYPO:0001357 Figure 8A
PMID:32282918 FYPO:0001357 Figure 8A
PMID:32282918 FYPO:0002059 Figure 7A
PMID:32282918 FYPO:0002059 Figure 7A
PMID:32282918 FYPO:0002059 Figure 7A
PMID:32282918 FYPO:0002059 Figure 7A
PMID:32282918 PBO:0094738 Figure 7B
PMID:32282918 FYPO:0000080 Figure 7A, pin∆ rescues the lethality of aps1∆ asp1-H397A
PMID:32282918 FYPO:0001357 Figure 7A
PMID:32282918 PBO:0094771 Figure 6B
PMID:32282918 PBO:0094771 Figure 6B
PMID:32282918 PBO:0094771 Figure 6B
PMID:32282918 PBO:0094771 Figure 6B
PMID:32282918 PBO:0094771 Figure 6B
PMID:32282918 FYPO:0001357 Figure 6A
PMID:32282918 FYPO:0001357 Figure 6A
PMID:32282918 FYPO:0001357 Figure 6A
PMID:32282918 FYPO:0001357 Figure 6A
PMID:32282918 FYPO:0001357 Figure 6A
PMID:32282918 PBO:0094771 Figure 6B
PMID:32282918 PBO:0094771 Figure 6B
PMID:32282918 PBO:0094771 Figure 6B
PMID:32282918 PBO:0094771 Figure 6B
PMID:32282918 PBO:0094771 Figure 6B
PMID:32282918 FYPO:0001355 Figure 5B
PMID:32282918 FYPO:0001357 Figure 5B
PMID:32282918 FYPO:0001357 Figure 5B
PMID:32282918 FYPO:0001357 Figure 5B
PMID:32282918 FYPO:0001357 Figure 5B
PMID:32282918 FYPO:0000080 Figure 5A
PMID:32282918 FYPO:0002059 Figure 5A
PMID:32282918 FYPO:0002059 Figure 5A
PMID:32282918 FYPO:0000082 Figure 5A
PMID:32282918 FYPO:0000082 Figure 5A
PMID:32282918 FYPO:0000082 Figure 5A
PMID:32282918 FYPO:0002059 Figure 5A
PMID:32282918 FYPO:0002059 Figure 5A
PMID:32282918 FYPO:0000082 Figure 5A
PMID:32282918 FYPO:0000082 Figure 5A
PMID:32282918 FYPO:0000082 Figure 5A
PMID:32282918 PBO:0094776 Figure 3B
PMID:32282918 PBO:0094775 Figure 3B
PMID:32282918 PBO:0094774 Figure 3B
PMID:32282918 PBO:0094773 Figure 3B
PMID:32282918 PBO:0094772 Figure 3B
PMID:32282918 PBO:0094774 Figure 3B
PMID:32282918 PBO:0094773 Figure 3B Figure 10
PMID:32282918 PBO:0094772 Figure 3B & Figure 10
PMID:32282918 PBO:0094738 Figure 3A
PMID:32282918 PBO:0094771 Figure 3A and 9C
PMID:32282918 PBO:0094771 Figure 3A
PMID:32282918 FYPO:0001355 Figure 2
PMID:32282918 FYPO:0001355 Figure 2
PMID:32282918 FYPO:0000080 Figure 2
PMID:32282918 FYPO:0000080 Figure 2
PMID:32282918 FYPO:0000080 Figure 2
PMID:32282918 FYPO:0000080 Figure 2
PMID:32282918 FYPO:0000080 Figure 2
PMID:32282918 FYPO:0002059 Figure 1
PMID:32282918 FYPO:0002059 Figure 1
PMID:32282918 FYPO:0002059 Figure 1
PMID:32282918 FYPO:0002059 Figure 1
PMID:32282918 FYPO:0002085 Figure 1
PMID:32282918 FYPO:0000080 Figure 1
PMID:32282918 FYPO:0000080 Figure 1
PMID:32282918 FYPO:0000082 Figure 1
PMID:32282918 FYPO:0000082 Figure 1
PMID:32282918 FYPO:0000080 Figure 1
PMID:32282918 FYPO:0000082 Figure 1
PMID:32282918 FYPO:0000082 Figure 1
PMID:32295063 FYPO:0007339 compared to lsd1-ao single mutant
PMID:32295063 FYPO:0003412 compared to Lsd1-ao single mutant
PMID:32295063 PBO:0102536 Loss of the HMG domain of Lsd2 (but not Lsd1) produces inviable cells (lethal).
PMID:32295063 PBO:0102539 KΔ::ade6+ monitored by qRT-PCR
PMID:32295063 PBO:0102552 KΔ::ade6+ monitored by qRT-PCR
PMID:32295063 PBO:0102522 KΔ::ade6+ monitored by qRT-PCR
PMID:32319721 PBO:0100665 CFU counts
PMID:32320462 FYPO:0007676 Evaluated with D4H sterol sensor
PMID:32320462 FYPO:0007678 Evaluated with D4H sterol sensor
PMID:32320462 FYPO:0007677 Evaluated with D4H sterol sensor
PMID:32320462 FYPO:0007677 Evaluated with D4H sterol sensor
PMID:32320462 FYPO:0007678 Evaluated with D4H sterol sensor
PMID:32320462 FYPO:0007678 Evaluated with D4H sterol sensor
PMID:32320462 FYPO:0007678 Evaluated with D4H sterol sensor
PMID:32320462 FYPO:0007678 Evaluated with D4H sterol sensor
PMID:32320462 FYPO:0007440 Sterols do not accumulate in endosomes after treatement with CK-666
PMID:32320462 FYPO:0007440 Sterols do not accumulate in endosomes after treatement with CK-666
PMID:32320462 FYPO:0007440 Sterols accumulate in endosomes
PMID:32320462 FYPO:0007678 Evaluated with D4H sterol sensor
PMID:32320462 FYPO:0007678 Evaluated with D4H sterol sensor
PMID:32320462 FYPO:0007678 Evaluated with D4H sterol sensor
PMID:32320462 FYPO:0007678 Evaluated with D4H sterol sensor
PMID:32320462 FYPO:0007677 Evaluated with D4H sterol sensor
PMID:32320462 FYPO:0007439 Eisosomes protruding towards cell interior
PMID:32320462 FYPO:0007440 Sterols do not accumulate in endosomes
PMID:32320462 FYPO:0007678 Evaluated with D4H sterol sensor
PMID:32320462 FYPO:0007676 Evaluated with D4H sterol sensor
PMID:32320462 FYPO:0007677 Evaluated with D4H sterol sensor; internal structures
PMID:32320462 FYPO:0004963 Evaluated with D4H sterol sensor
PMID:32320462 FYPO:0007678 Evaluated with D4H sterol sensor
PMID:32320462 FYPO:0007678 Evaluated with D4H sterol sensor
PMID:32320462 FYPO:0007678 Evaluated with D4H sterol sensor
PMID:32320462 FYPO:0007676 Evaluated with D4H sterol sensor
PMID:32320462 FYPO:0007678 Evaluated with D4H sterol sensor
PMID:32320462 FYPO:0007676 Evaluated with D4H sterol sensor
PMID:32327557 PBO:0097689 5ug/mL
PMID:32327557 PBO:0097678 Fig. 3
PMID:32327557 PBO:0097679 Fig. 3
PMID:32327557 PBO:0097682 Fig. 3
PMID:32327557 PBO:0097681 Fig. 3
PMID:32327557 PBO:0097690 Fig. 2
PMID:32327557 PBO:0097677 Fig. 3
PMID:32327557 PBO:0097688 Small rescue of cut7D pkl1D
PMID:32327557 PBO:0097687 Fig. 4
PMID:32327557 PBO:0097686 Fig. 4
PMID:32327557 PBO:0097685 Fig. 4
PMID:32327557 PBO:0097684 Fig. 3
PMID:32327557 PBO:0097681 Fig. 3
PMID:32327557 PBO:0097680 Fig. 3
PMID:32327557 PBO:0097681 Fig. 3
PMID:32327557 PBO:0097673 Fig. 2
PMID:32327557 PBO:0112499 Fig. 2
PMID:32327557 PBO:0097675 Fig. 2
PMID:32327557 PBO:0097676 Fig. 2
PMID:32327557 PBO:0097682 Fig. 3
PMID:32327557 FYPO:0007987 Fig. 2
PMID:32327557 PBO:0097683 Fig. 3
PMID:32341083 PBO:0033071 HU absent
PMID:32341083 PBO:0104393 HU absent
PMID:32341083 PBO:0033067 HU absent
PMID:32341083 FYPO:0001513 HU absent
PMID:32355220 FYPO:0007423 An extrachromosome ChLC
PMID:32355220 FYPO:0006811 An extrachromosome ChLC
PMID:32355220 FYPO:0006810 An extrachromosome ChLC
PMID:32355220 FYPO:0007425 ade6B/ade6X at the ura4 locus
PMID:32355220 PBO:0095490 ade6B/ade6X at cen1
PMID:32355220 PBO:0095490 ade6B/ade6X at cen1
PMID:32355220 PBO:0095493 ade6B/ade6X at cen1
PMID:32355220 PBO:0095493 ade6B/ade6X at cen1
PMID:32355220 PBO:0095490 ade6B/ade6X at cen1
PMID:32355220 PBO:0095491 ade6B/ade6X at the ura4 locus
PMID:32355220 PBO:0095492 ade6B/ade6X at the ura4 locus
PMID:32355220 PBO:0095491 ade6B/ade6X at the ura4 locus
PMID:32355220 FYPO:0006811 An extrachromosome ChLC
PMID:32355220 FYPO:0006811 An extrachromosome ChLC
PMID:32355220 FYPO:0006810 An extrachromosome ChLC
PMID:32355220 FYPO:0006810 An extrachromosome ChLC
PMID:32355220 FYPO:0007425 ade6B/ade6X at the ura4 locus
PMID:32355220 FYPO:0006811 An extrachromosome ChLC
PMID:32355220 FYPO:0000185 ade6B/ade6X at the ura4 locus
PMID:32355220 FYPO:0007423 PFGE; An extrachromosome ChLC
PMID:32355220 PBO:0095494 ade6B/ade6X at cen1
PMID:32355220 PBO:0095494 ade6B/ade6X at cen1
PMID:32355220 PBO:0095494 ade6B/ade6X at cen1
PMID:32355220 FYPO:0007424 PFGE; An extrachromosome ChLC
PMID:32355220 FYPO:0007424 PFGE; An extrachromosome ChLC
PMID:32355220 FYPO:0007423 An extrachromosome ChLC
PMID:32355220 FYPO:0001859 An extrachromosome ChLC
PMID:32355220 FYPO:0001742 An extrachromosome ChLC
PMID:32355220 PBO:0095495 ade6B/ade6X at cen1
PMID:32355220 PBO:0095494 ade6B/ade6X at cen1
PMID:32355220 PBO:0095494 ade6B/ade6X at cen1
PMID:32355220 PBO:0095493 ade6B/ade6X at cen1
PMID:32355220 PBO:0095493 ade6B/ade6X at cen1
PMID:32355220 PBO:0095493 ade6B/ade6X at cen1
PMID:32355220 FYPO:0005788 ade6B/ade6X at cen1
PMID:32355220 FYPO:0001742 PFGE; An extrachromosome ChLC
PMID:32355220 FYPO:0001742 PFGE; An extrachromosome ChLC
PMID:32355220 FYPO:0007423 An extrachromosome ChLC
PMID:32355220 FYPO:0007423 An extrachromosome ChLC
PMID:32355220 FYPO:0006810 An extrachromosome ChLC
PMID:32355220 FYPO:0007423 An extrachromosome ChLC
PMID:32355220 FYPO:0000185 ade6B/ade6X at the ura4 locus
PMID:32355220 FYPO:0006810 An extrachromosome ChLC
PMID:32355220 FYPO:0007425 ade6B/ade6X at the ura4 locus
PMID:32355220 FYPO:0006811 An extrachromosome ChLC
PMID:32355220 FYPO:0006811 An extrachromosome ChLC
PMID:32361273 PBO:0104793 fig 2 This conserved inhibitory phosphorylation occurs as the Cdc2-Cdc13 complex is being formed to prevent its premature activation during G2 phase
PMID:32361273 PBO:0104791 fig 2
PMID:32361273 PBO:0104790 fig 1C (i.e normal TOR signalloing)
PMID:32361273 PBO:0104789 fig S1A
PMID:32361273 PBO:0096075 fig S1A
PMID:32361273 PBO:0023774 Figure S4D
PMID:32361273 PBO:0104791 deletion mutants of either ste9 or rum1 fail to degrade Cdc13 (Figures S4A and S4B).
PMID:32361273 PBO:0104791 deletion mutants of either ste9 or rum1 fail to degrade Cdc13 (Figures S4A and S4B).
PMID:32361273 PBO:0104801 (TAP-Par1F314Q), this interaction was reduced (Figure 6C)
PMID:32361273 PBO:0103204 Deletion of par1 also affected the survival of the wee1-50 mutant (Figure 4C), and this worsening of the phenotype corre- lated with the inability of the double wee1-50 par1D mutant to accumulate Rum1 (Figure 4D).
PMID:32361273 PBO:0020550 Figure S4D
PMID:32361273 PBO:0104799 fig 2
PMID:32361273 PBO:0099448 Figure S4D
PMID:32361273 PBO:0104800 fig 4 Notably, loss of cig1 and cig2 utterly overrode these defects,
PMID:32361273 FYPO:0001387 Deletion of par1 also affected the survival of the wee1-50 mutant (Figure 4C), and this worsening of the phenotype corre- lated with the inability of the double wee1-50 par1D mutant to accumulate Rum1 (Figure 4D).
PMID:32361273 PBO:0104795 fig 2E, S2A
PMID:32361273 PBO:0104795 fig S2 B
PMID:32361273 PBO:0093823 fig1
PMID:32361273 PBO:0101618 Figure S4D
PMID:32361273 FYPO:0003345 1D. The cells also presented a defect in the degradation of the cyclin Cdc13 and a delay in the dephosphorylation of Ste9
PMID:32361273 FYPO:0007476 2G. the use of cdc10 mutant backgrounds is common for checking the ability of cells to arrest in G1
PMID:32361273 FYPO:0000708 fig7A
PMID:32361273 FYPO:0001043 fig1
PMID:32361273 PBO:0097920 fig1
PMID:32361273 FYPO:0004233 Delay in the dephosphoryaltion of Ste9 and defect in the degradation of the cyclin Cdc13 in nitrogen starvation
PMID:32361273 FYPO:0000708 fig1
PMID:32361273 PBO:0104802 protein phophatase substrate adaptor
PMID:32361273 PBO:0096829 fig 7
PMID:32361273 FYPO:0001000 fig3
PMID:32361273 FYPO:0001043 fig3b
PMID:32361273 PBO:0104795 fig 2F
PMID:32361273 FYPO:0001043 fig3
PMID:32361273 PBO:0104797 fig 3
PMID:32361273 PBO:0104794 fig 2D length is 7.5 micron cf WT 6.2 in same conditions
PMID:32361273 PBO:0104792 fig 2
PMID:32361273 PBO:0104798 fig 2F
PMID:32361273 PBO:0094966 fig 2D length is 10.299 micron cf WT 12.7 in same conditions
PMID:32414915 PBO:0100930 The Meu13-Mcp7 complex activates the initiation step of DNA strand exchange by Dmc1. The Meu13-Mcp7 complex also stimulates Rad51-driven strand exchange to a much less extent in the presence of the Swi5-Sfr1 complex.
PMID:32414915 PBO:0100930 The Meu13-Mcp7 complex activates the initiation step of DNA strand exchange by Dmc1. The Meu13-Mcp7 complex also stimulates Rad51-driven strand exchange to a much less extent in the presence of the Swi5-Sfr1 complex.
PMID:32415063 FYPO:0002052 Importantly, cwf10-1 rescued the sporulation defect observed in rrp6Δ caused by the silencing of the byr2 gene by nam1 lncRNA (Fig. 2e), similar to pir2-1 (Fig. 1f).
PMID:32415063 PBO:0111099 Moreover, quantitative ChIP analyses showed enrichment of Clr3 and Pob3 at prt-pho1 in WT cells and a reduced localization in pir2-1 cells (Fig. 5e).
PMID:32415063 PBO:0111098 Moreover, quantitative ChIP analyses showed enrichment of Clr3 and Pob3 at prt-pho1 in WT cells and a reduced localization in pir2-1 cells (Fig. 5e).
PMID:32415063 PBO:0111097 However, the ago1Δ clr3Δ double mutant showed cumulative de-repression of pho1 (Fig. 5d).
PMID:32415063 PBO:0111097 However, the ago1Δ clr3Δ double mutant showed cumulative de-repression of pho1 (Fig. 5d).
PMID:32415063 PBO:0111097 However, the ago1Δ clr3Δ double mutant showed cumulative de-repression of pho1 (Fig. 5d).
PMID:32415063 PBO:0111092 The loss of Clr3 or Pob3 caused an increase in pho1 transcript levels, consistent with their involvement in repression by lncRNA8,38, but the extent of upregulation was less than in pir2-1 (Fig. 5c).
PMID:32415063 PBO:0111092 The loss of Clr3 or Pob3 caused an increase in pho1 transcript levels, consistent with their involvement in repression by lncRNA8,38, but the extent of upregulation was less than in pir2-1 (Fig. 5c).
PMID:32415063 PBO:0111092 Cells lacking Ago1 showed a considerable increase in pho1 transcript levels as determined by northern blot analysis (Fig. 4e), but the observed effect was weaker than in pir2-1 or cwf10-1, suggesting that additional factors likely cooperate with Pir2- splicing machinery.
PMID:32415063 PBO:0111096 We next wondered whether cryptic introns are required for Pir2- dependent generation of siRNAs. Mutations of the pho1 cryptic intron splice sites in rrp6Δ cells abolished the production of siRNAs mapping to the entire prt lncRNA, including the region upstream of pho1 (Fig. 4d). This result suggests that the cryptic intron acts as part of the prt lncRNA to engage RNAi machinery. Importantly, siRNAs mapping to other loci were not affected (Fig. 4d and Supplementary Fig. 5),
PMID:32415063 FYPO:0006076 We then analyzed the role of Pir2 in siRNA production in cells lacking Rrp6, which show accumulation of lncRNAs and robust repression of their target loci. We found that siRNAs, which ranged in size from 20–24 nt and mapped to lncRNAs targeting pho1 and byr2, were abolished in both pir2-1 and cwf10-1 mutant backgrounds (Fig. 4c and Supplementary Fig. 4a, b). Pir2 was also required for siRNA production at Tf2 elements, pericentromeric repeats, and other loci (Fig. 4c, Supplementary Fig. 5 and Supplementary Data 2).
PMID:32415063 FYPO:0006076 We then analyzed the role of Pir2 in siRNA production in cells lacking Rrp6, which show accumulation of lncRNAs and robust repression of their target loci. We found that siRNAs, which ranged in size from 20–24 nt and mapped to lncRNAs targeting pho1 and byr2, were abolished in both pir2-1 and cwf10-1 mutant backgrounds (Fig. 4c and Supplementary Fig. 4a, b).
PMID:32415063 PBO:0111095 Interestingly, this interaction was impaired in the cwf10- 1 mutant, indicating that splicing factors are required for asso- ciation of Pir2 with Hrr1 (Fig. 4b)
PMID:32415063 PBO:0111092 Remarkably, strains carrying splice site mutations showed significant upregulation of the pho1 transcript (Fig. 3c), similar to the effect observed in pir2-1, cwf10- 1 and prtΔ (Figs. 1b, 2c and Supplementary Fig. 1b)
PMID:32415063 PBO:0111092 Remarkably, strains carrying splice site mutations showed significant upregulation of the pho1 transcript (Fig. 3c), similar to the effect observed in pir2-1, cwf10- 1 and prtΔ (Figs. 1b, 2c and Supplementary Fig. 1b)
PMID:32415063 GO:0031047 These results confirm the biological significance of Pir2 association with splicing machinery and show that these factors collaborate to promote gene repression by lncRNAs.
PMID:32415063 PBO:0111092 A significant increase in the level of both pho1 and byr2 mRNAs in cwf10-1 as compared to WT confirmed that the splicing machinery indeed affects the expression of genes repressed by lncRNAs (Fig. 2c)
PMID:32415063 PBO:0111091 A significant increase in the level of both pho1 and byr2 mRNAs in cwf10-1 as compared to WT confirmed that the splicing machinery indeed affects the expression of genes repressed by lncRNAs (Fig. 2c)
PMID:32415063 PBO:0111089 The lncRNA-mediated repression of pho1 was impaired in cbc1-1 cells (Supplementary Fig. 1e), sug-
PMID:32415063 PBO:0111092 The lncRNA-mediated repression of pho1 was impaired in cbc1-1 cells (Supplementary Fig. 1e),
PMID:32415063 FYPO:0002052 Remarkably, entry into meiosis and sporulation efficiency were restored in pir2-1 rrp6Δ cells (Fig. 1f).
PMID:32415063 PBO:0093929 We asked if Pir2 is also required for the repression of byr2 that is observed upon the accumulation of nam1 lncRNA in cells lacking Rrp6. Since byr2 is required for meiotic induction, cells lacking Rrp6 are defective in sporulation (Fig. 1f)11.
PMID:32415063 GO:0031047 Supporting the function of Pir2 and lncRNA in the same pathway, we found no additive effect on pho1 expression in the pir2-1 prtΔ double mutant when compared to the effect in the single mutants (Fig. 1e).
PMID:32415063 GO:0106222 Moreover, RNA immunoprecipitation sequencing analysis (RIP-seq) showed that Pir2 binds to the lncRNAs (Fig. 1d and Supplementary Fig. 1d)
PMID:32415063 PBO:0111093 Chromatin immuno- precipitation followed by sequencing (ChIP-seq) confirmed Pir2 enrichment at lncRNAs, including prt and nam1 (Fig. 1c and Supplementary Fig. 1c)
PMID:32415063 PBO:0111092 (Fig. 1b), similar to the effect observed upon deletion of the lncRNA (Supplementary Fig. 1b)6,7,11.
PMID:32415063 PBO:0111091 (Fig. 1b), similar to the effect observed upon deletion of the lncRNA (Supplementary Fig. 1b)6,7,11.
PMID:32415063 PBO:0111092 (Fig. 1b), similar to the effect observed upon deletion of the lncRNA (Supplementary Fig. 1b)6,7,11.
PMID:32415063 PBO:0111091 (Fig. 1b), similar to the effect observed upon deletion of the lncRNA (Supplementary Fig. 1b)6,7,11.
PMID:32415063 PBO:0111092 Surprisingly, pir2-1 showed a drastic upregulation of pho1 and byr2 genes as compared to wild- type (WT) (Fig. 1b),
PMID:32415063 PBO:0111091 Surprisingly, pir2-1 showed a drastic upregulation of pho1 and byr2 genes as compared to wild- type (WT) (Fig. 1b),
PMID:32415063 PBO:0111090 as was also observed in mmi1Δ and rrp6Δ cells (Fig. 1a and Supplementary Fig. 1a)6
PMID:32415063 PBO:0111090 as was also observed in mmi1Δ and rrp6Δ cells (Fig. 1a and Supplementary Fig. 1a)6
PMID:32415063 PBO:0111089 as was also observed in mmi1Δ and rrp6Δ cells (Fig. 1a and Supplementary Fig. 1a)6
PMID:32415063 PBO:0111089 as was also observed in mmi1Δ and rrp6Δ cells (Fig. 1a and Supplementary Fig. 1a)6
PMID:32415063 PBO:0111090 Loss of the MTREC subunit Red1 resulted in the accumulation of longer readthrough transcripts (referred to as prt-L and nam1-L) (Fig. 1a), as was also observed in mmi1Δ and rrp6Δ cells (Fig. 1a and Supplementary Fig. 1a)6,7,11.
PMID:32415063 PBO:0111089 Loss of the MTREC subunit Red1 resulted in the accumulation of longer readthrough transcripts (referred to as prt-L and nam1-L) (Fig. 1a), as was also observed in mmi1Δ and rrp6Δ cells (Fig. 1a and Supplementary Fig. 1a)6,7,11.
PMID:32415063 GO:0031047 The requirement for Pir2 in mediating the repressive effects of lncRNAs is a highly significant finding.
PMID:32496538 FYPO:0004347 Figure 6 and Supplementary Fig S8
PMID:32496538 PBO:0101605 Supplementary Fig S7
PMID:32496538 FYPO:0002913 Strand-specific RT-qPCR; Figure 4 and Supplementary Fig S5
PMID:32496538 FYPO:0002913 Strand-specific RT-qPCR; Figure 4 and Supplementary Fig S5
PMID:32496538 FYPO:0002913 Strand-specific RT-qPCR; Figure 2
PMID:32496538 FYPO:0002913 Strand-specific RT-qPCR; Figure 2
PMID:32496538 FYPO:0007347 Supplementary Fig S7
PMID:32496538 FYPO:0007347 Supplementary Fig S7
PMID:32496538 FYPO:0007347 Supplementary Fig S7
PMID:32496538 PBO:0101606 Supplementary Fig S7
PMID:32496538 PBO:0101605 Supplementary Fig S7
PMID:32496538 PBO:0095888 Figure 5; rbp1 also Figure 7
PMID:32496538 PBO:0101604 Figure 5; rbp1 also Figure 7
PMID:32496538 PBO:0095888 Figure 5; rbp1 also Figure 7
PMID:32496538 FYPO:0002913 Strand-specific RT-qPCR; Figure 2
PMID:32496538 FYPO:0006996 Strand-specific RT-qPCR; Figure 2
PMID:32496538 FYPO:0002913 Strand-specific RT-qPCR; Figure 2
PMID:32496538 FYPO:0002913 Strand-specific RT-qPCR; Figure 2
PMID:32496538 FYPO:0005518 Supplementary Fig S8
PMID:32496538 FYPO:0005518 Supplementary Fig S8
PMID:32496538 FYPO:0005518 Figure 6 and Supplementary Fig S8
PMID:32496538 FYPO:0005516 Figure 6 and Supplementary Fig S8
PMID:32496538 PBO:0101604 Figure 5; rbp1 also Figure 7
PMID:32496538 PBO:0095888 Figure 5
PMID:32496538 PBO:0101604 Figure 5
PMID:32496538 FYPO:0002913 Strand-specific RT-qPCR; Figure 4 and Supplementary Fig S5
PMID:32496538 FYPO:0002913 Strand-specific RT-qPCR; Figure 4 and Supplementary Fig S5
PMID:32496538 FYPO:0002913 Strand-specific RT-qPCR; Figure 4 and Supplementary Fig S5
PMID:32496538 FYPO:0006996 Strand-specific RT-qPCR; Figure 4 and Supplementary Fig S5
PMID:32496538 FYPO:0006996 Strand-specific RT-qPCR; Figure 4 and Supplementary Fig S5
PMID:32496538 FYPO:0006996 Strand-specific RT-qPCR; Figure 4 and Supplementary Fig S5
PMID:32496538 FYPO:0002913 Strand-specific RT-qPCR; Figure 4 and Supplementary Fig S5
PMID:32496538 FYPO:0005518 Supplementary Fig S8
PMID:32496538 FYPO:0002913 Strand-specific RNA-seq analysis, RT-PCR, Strand-specific RT-qPCR; Figure 1, 2 and 4; Supplementary Fig S1, S3 and S5
PMID:32496538 FYPO:0002913 Strand-specific RNA-seq analysis, RT-PCR, Strand-specific RT-qPCR; Figure 1, 2 and 4; Supplementary Fig S1, S3 and S5
PMID:32496538 FYPO:0002913 Strand-specific RNA-seq analysis, RT-PCR, Strand-specific RT-qPCR; Figure 1, 2 and 4; Supplementary Fig S1, S3 and S5
PMID:32499400 PBO:0101147 100 ug/mL MPA
PMID:32499400 PBO:0101148 EMM -U agar plates, supplemeted with 6AU concentration ranging from 3.6 to 150 ug/mL
PMID:32499400 PBO:0101151 at tgp1 promoter
PMID:32499400 PBO:0101155 at lncRNAs upstream of PHO regulon genes (nc-tgp1, nc-pho1, prt1)
PMID:32499400 PBO:0101156 at lncRNAs upstream of PHO regulon genes (nc-tgp1, nc-pho1, prt1)
PMID:32499400 PBO:0101157 also assayed genome-wide
PMID:32499400 PBO:0101157 also assayed genome-wide
PMID:32499400 FYPO:0007411 at different lncRNA polyadenylation sites
PMID:32499408 PBO:0094688 Figure 1B-E and supplementary Figure S1B
PMID:32499408 PBO:0098592 Figure 7A
PMID:32499408 PBO:0098591 fig 5e
PMID:32499408 PBO:0098590 Figure 3
PMID:32499408 PBO:0098588 It is noteworthy that the amount of Arb1 was also drastically decreased in hsp90-G84C cells at high temperatures (Figure 4E)
PMID:32499408 PBO:0098375 even at 25 °C, Arb1-associated Ago1 in the immunoprecipitates from hsp90-G84C cells was much reduced compared to wild-type samples (Figure 4E),
PMID:32499408 PBO:0098587 We then examined how the altered protein level of Tas3 affects the RITS complex formation in vivo. Notably, the low level of Tas3 in hsp90-G84C cells could only recruit minimal amount of Ago1 detected by co-immunoprecipitation assay at elevated temperatures (Figure 4C). (Figure 4B)
PMID:32499408 PBO:0098586 (Figure 4B)
PMID:32499408 PBO:0098585 that the amount of Tas3 but not Ago1 was significantly reduced once the hsp90-G84C cells were shifted to restrictive temperature of 37 °C for 4 hours (Figure 4B)
PMID:32499408 PBO:0098584 Figure 3
PMID:32499408 PBO:0093562 Figure 2E
PMID:32499408 PBO:0094283 Figure 1B-E and supplementary Figure S1B
PMID:32499408 PBO:0098583 Figure 1B-E and supplementary Figure S1B
PMID:32499408 PBO:0094283 Figure 1B-E and supplementary Figure S1B
PMID:32499408 PBO:0095651 Figure 1B-E and supplementary Figure S1B
PMID:32499408 PBO:0098582 Figure 1B-E and supplementary Figure S1B
PMID:32499408 PBO:0094679 Figure 1B-E and supplementary Figure S1B
PMID:32502403 PBO:0022963 Figure 1A
PMID:32502403 PBO:0106705 A failed mitotic nuclear division is a cell phenotype observed at the end of mitosis during the vegetative life cycle in which the nuclear division does not occur and the two DNA masses remain linked by the internuclear membrane bridge. This can result in the coalescence of both DNA masses into one nucleus.
PMID:32502403 PBO:0106704 A failed mitotic nuclear division is a cell phenotype observed at the end of mitosis during the vegetative life cycle in which the nuclear division does not occur and the two DNA masses remain linked by the internuclear membrane bridge. This can result in the coalescence of both DNA masses into one nucleus.
PMID:32502403 PBO:0106701 We found that, in imp1D cells, NPCs were detected at the MMD and the peripheral NPC component Nup60 was removed from this domain (Figure 4C); however, the removal of structural components such as Nup107 and the membrane nucleoporin Cut11 was not observed (Figures 4C, S3A, and S3B).
PMID:32502403 PBO:0106710 ase1D cells that elongated the spindle, the MMD was not properly formed, and the number of NPCs was variable (Figure S2B
PMID:32502403 PBO:0106709 ase1D cells that elongated the spindle, the MMD was not properly formed, and the number of NPCs was variable (Figure S2B
PMID:32502403 PBO:0106707 A failed mitotic nuclear envelope division is a cell phenotype observed at the end of mitosis during the vegetative life cycle in which the nuclear division does not occur and the two DNA masses remain linked by the internuclear membrane bridge. This can result in the coalescence of both DNA masses into one nucleus. We found that wild-type cells showed timed NE division in the absence of actomyosin ring (Figures 4A and 4B), demon- strating that NE division is independent of cell division. However, 100% of imp1D cells (n = 126) completely failed to undergo NE division, resulting in cells with two nuclei linked by a long NE bridge (Figures 4A and 4B; Video S4). This result demonstrates that Imp1 is required for NE division.
PMID:32502403 PBO:0106713 When these cells were left in this con- dition, daughter nuclei began to move closer to each other until they finally merged into one single nucleus (Figure 4E). This phenotype can be promoted if spindles are forced to disas- semble by treating the cells with 30 mg/mL MBC, resulting in 35% (n = 34) of nuclear coalescence events.
PMID:32502403 PBO:0106713 The coalescence of daughter nuclei was also observed in apq12D cells that failed to undergo nuclear division (Figure 4F).
PMID:32502403 PBO:0106712 Apq12 localized in tubules con- nected to or in close proximity to the MMD and at spindle pole regions, mirroring ER tubules marked with Yop1-GFP, Rtn1- GFP, or the artificial ER luminal marker mCherry-ADEL
PMID:32502403 PBO:0106708 Apq12 localized in tubules con- nected to or in close proximity to the MMD and at spindle pole regions, mirroring ER tubules marked with Yop1-GFP, Rtn1- GFP, or the artificial ER luminal marker mCherry-ADEL
PMID:32502403 GO:0140515 causally upstreasm of?
PMID:32502403 PBO:0106711 Consistently, these cells showed a higher fre- quency of asymmetric NE divisions (Figure S2C)
PMID:32518066 GO:0035613 Lsm1Δ56C–7 can only bind tightly to the RNA with a 5′ stem–loop and single stranded 3′ end (Kd = 70 and 32 nM, respectively) (Fig. 5C).
PMID:32518066 GO:0008266 These data indicate that high affinity binding sites for the Lsm1–7 complex must be at the 3′ termini of RNA. On
PMID:32518066 GO:0035925 We conclude that the carboxy-terminal 12 amino acids of Lsm1 are important for the binding specificity of Lsm1–7.
PMID:32546512 FYPO:0000080 Figure 4
PMID:32546512 FYPO:0000080 Figure 4
PMID:32546512 PBO:0094777 Figure 2 vw changed from decreased to normal (compared to WT)
PMID:32546512 PBO:0094777 Figure 2 vw changed from decreased to normal (compared to WT)
PMID:32546512 PBO:0094771 Figure 4
PMID:32546512 FYPO:0000080 Figure 2A
PMID:32546512 FYPO:0000080 Figure 2A
PMID:32546512 FYPO:0000080 Figure 2
PMID:32546512 FYPO:0000080 Figure 2
PMID:32546512 PBO:0099750 Figure 2C the fivefold de-repression of Pho1 in the aps1Δ strain was enhanced additively to 12- fold in the erh1Δ aps1Δ background
PMID:32546512 PBO:0099750 Figure 2C the fivefold de-repression of Pho1 in the aps1Δ strain was enhanced additively to 12- fold in the erh1Δ aps1Δ background
PMID:32546512 PBO:0099750 Figure 5
PMID:32546512 PBO:0099750 Figure 5
PMID:32546512 PBO:0099750 Figure 5
PMID:32546512 FYPO:0000080 Figure 5
PMID:32546512 FYPO:0000080 Figure 5
PMID:32546512 PBO:0094771 Figure 5
PMID:32546512 PBO:0094771 Figure 5
PMID:32546512 PBO:0094771 Figure 5
PMID:32546512 FYPO:0000080 Figure 5
PMID:32546512 FYPO:0000080 Figure 5
PMID:32546512 PBO:0106694 Northern blotting and primer extension, Figure 6
PMID:32546512 PBO:0094775 Northern blotting, Figure 6
PMID:32546512 FYPO:0001357 Figure 8
PMID:32546512 FYPO:0001357 Figure 8
PMID:32546512 FYPO:0001357 Figure 8
PMID:32546512 FYPO:0001357 Figure 8
PMID:32546512 FYPO:0006821 Figure 8
PMID:32546512 FYPO:0002085 Figure S1
PMID:32546512 FYPO:0000080 Figure S1
PMID:32546512 FYPO:0000080 Figure S1
PMID:32546512 FYPO:0000080 Figure S1
PMID:32546512 FYPO:0000080 Figure S1
PMID:32546512 FYPO:0000080 Figure S1
PMID:32546512 FYPO:0000080 Figure S1
PMID:32546512 FYPO:0000080 Figure S1
PMID:32546512 FYPO:0000080 Figure S1
PMID:32546512 FYPO:0000082 Figure S1
PMID:32546512 FYPO:0004481 Figure S1
PMID:32546512 FYPO:0000082 Figure S1
PMID:32546512 FYPO:0001234 Figure S1
PMID:32546512 FYPO:0001234 Figure S1
PMID:32546512 FYPO:0002061 Figure S1
PMID:32546512 FYPO:0002061 Figure S1
PMID:32546512 PBO:0106693 Figure 2C
PMID:32546512 PBO:0094738 Figure 2B
PMID:32546512 PBO:0094738 Figure 2C
PMID:32546512 PBO:0094738 Figure 5
PMID:32546512 PBO:0094771 Figure 2B
PMID:32546512 PBO:0094771 Figure 4
PMID:32546512 PBO:0094771 Figure 4
PMID:32546512 PBO:0094771 Figure 4
PMID:32546512 PBO:0094771 Figure 4
PMID:32546512 PBO:0094771 Figure 4
PMID:32546512 FYPO:0005369 Figure 2A
PMID:32546512 GO:0043628 a scenario in which Erh1 acts as a brake on Mmi1’s ability to promote CPF-de- pendent termination during prt lncRNA synthesis.
PMID:32546512 GO:0043628 suggest ... Erh1 acts as a brake on Mmi1’s ability to promote CPF-de- pendent termination during prt lncRNA synthesis.
PMID:32546512 PBO:0094771 In addition, using the prt–pho1 reporter plas- mid to gauge Pho1 acid phosphatase expression, we found that Pho1 activity was lower in mmi1Δ cells than in wild-type cells (Fig. 6C)
PMID:32546512 PBO:0106695 Figure 4B
PMID:32546512 PBO:0106695 Figure 4B
PMID:32546512 FYPO:0001045 Figure 4B
PMID:32546512 FYPO:0001045 Figure 4B
PMID:32546512 FYPO:0001045 Figure 4B
PMID:32546512 FYPO:0001045 Figure 4B
PMID:32546512 PBO:0094777 (Normal compared to WT) The instructive findings were that the de-repression of Pho1 by erh1Δ was effaced in rhn1Δ, ssu72-C13S, ctf1Δ, ppn1Δ, and swd22Δ cells and was attenuated in dis2Δ cells (Fig. 4B
PMID:32546512 PBO:0094777 (Normal compared to WT) The instructive findings were that the de-repression of Pho1 by erh1Δ was effaced in rhn1Δ, ssu72-C13S, ctf1Δ, ppn1Δ, and swd22Δ cells and was attenuated in dis2Δ cells (Fig. 4B
PMID:32546512 FYPO:0003267 Figure 4
PMID:32546512 FYPO:0003267 Figure 4
PMID:32546512 FYPO:0001234 Figure 2 We obtained viable erh1Figure 2A Δ asp1-D333A haploids after mating and sporulation; the double- mutant was slow-growing on YES agar and cold-sensitive: he de-re- pression of Pho1 activity by erh1Δ was erased in the asp1-D333A back- ground
PMID:32546512 FYPO:0001234 Figure 2 We obtained viable erh1Figure 2A Δ asp1-D333A haploids after mating and sporulation; the double- mutant was slow-growing on YES agar and cold-sensitive: he de-re- pression of Pho1 activity by erh1Δ was erased in the asp1-D333A back- ground
PMID:32546512 FYPO:0000082 Figure 4
PMID:32546512 FYPO:0000080 Figure 4
PMID:32546512 FYPO:0000080 Figure 4
PMID:32546830 GO:0005515 linker
PMID:32546830 FYPO:0002150 Figure 2E tetrad analysis
PMID:32546830 PBO:0099069 Figure 2
PMID:32571823 PBO:0093785 figure 2
PMID:32571823 PBO:0096345 figure3A (increased cacineurin signalling)
PMID:32571823 FYPO:0001198 figure3B
PMID:32571823 FYPO:0000098 figure3C
PMID:32571823 PBO:0096346 figure3D
PMID:32571823 FYPO:0005253 FIG 4 Ccr1 is a molecular target of TAM.
PMID:32571823 FYPO:0002060 figure 1
PMID:32571823 PBO:0096347 figure 2b
PMID:32571823 PBO:0096347 figure 2b
PMID:32571823 FYPO:0002716 fig5
PMID:32571823 PBO:0093644 figure 2
PMID:32571823 PBO:0096341 figure 2
PMID:32571823 PBO:0093646 figure 2
PMID:32571823 PBO:0093660 figure 2
PMID:32571823 PBO:0096340 figure 2
PMID:32571823 PBO:0096339 figure 2
PMID:32571823 PBO:0093653 figure 1
PMID:32571823 FYPO:0002643 figure 2d
PMID:32571823 PBO:0093653 figure 1
PMID:32571823 FYPO:0002792 figure 2c
PMID:32571823 PBO:0093785 figure 2
PMID:32571823 PBO:0094270 figure 2
PMID:32571823 PBO:0093645 figure 2
PMID:32571823 PBO:0096344 figure 2
PMID:32571823 PBO:0093642 figure 2
PMID:32571823 PBO:0096343 figure 2
PMID:32571823 PBO:0096342 figure 2
PMID:32571823 PBO:0093653 figure 2d
PMID:32571823 FYPO:0005254 figure 2d
PMID:32571823 PBO:0094271 figure 2d
PMID:32571823 FYPO:0002343 figure 2d
PMID:32571823 FYPO:0002328 figure 2d
PMID:32571823 FYPO:0001470 figure 2d
PMID:32571823 FYPO:0000086 figure 2d
PMID:32571823 PBO:0094271 figure 2
PMID:32571823 PBO:0093646 figure 2d
PMID:32571823 PBO:0093642 figure 2d
PMID:32594847 FYPO:0001125 DNS
PMID:32594847 FYPO:0001124 DNS
PMID:32594847 FYPO:0000047 DNS
PMID:32650974 GO:0140497 M-Pol I complex
PMID:32650974 GO:0140497 M-Pol I complex
PMID:32650974 GO:0006487 figures 1,2,4. These results suggested that the elongation of mannan takes place sequentially by the actions of the a-mannosyltransferases in the order of SpOch1p, SpMnn9p and SpAnp1p.
PMID:32650974 GO:0005515 split YFP and affinity capture
PMID:32650974 FYPO:0007436 swollen
PMID:32650974 GO:0006487 figures 1,2,4 These results suggested that the elongation of mannan takes place sequentially by the actions of the a-mannosyltransferases in the order of SpOch1p, SpMnn9p and SpAnp1p.
PMID:32650974 GO:0006487 figure 4. These results suggested that the elongation of mannan takes place sequentially by the actions of the a-mannosyltransferases in the order of SpOch1p, SpMnn9p and SpAnp1p.
PMID:32692737 GO:2000779 regulates pathway choice
PMID:32723864 PBO:0107266 Figure 6
PMID:32723864 GO:0140642 Ase1 is required for promoting spindle elongation during mitotic prophase but synergizes with Klp2 to maintain spindle stability during metaphase I.
PMID:32723864 PBO:0107265 Figure 5
PMID:32723864 FYPO:0007752 Figure 5 Three typical types of plots are shown: (I) WTlike metaphase spindle length (maintenance), (II) spindle regression (regression), and (III) continuous spindle elongation (lacking metaphase).
PMID:32723864 PBO:0107264 Figure 5
PMID:32723864 PBO:0107263 Figure 5
PMID:32723864 FYPO:0007744 Figure S1. In contrast, 50% of the spindles in klp2D cells underwent abrupt collapse during metaphase I (Fig. 2, A, C, and E, 3A)
PMID:32723864 FYPO:0007746 Figure S1.
PMID:32723864 FYPO:0007751 Figure S1. In contrast, 50% of the spindles in klp2D cells underwent abrupt collapse during metaphase I (Fig. 2, A, C, and E, 3A)
PMID:32723864 PBO:0099173 Figure S1.
PMID:32723864 FYPO:0007746 Figure S1.
PMID:32723864 FYPO:0007747 absence of Klp2 did not significantly affect spindle elongation during prophase I and only slightly lengthened the maximal spindle length during metaphase I (Fig. 2G).
PMID:32723864 FYPO:0007748 In both mitotic and meiotic cells, the absence of Klp2 slightly but significantly prolonged the duration of preanaphase (Fig. 2, F and G).
PMID:32723864 PBO:0107261 3F. The results show that the absence of Klp2 affects the localization of Ase1-GFP to the meiotic spindles and leads to a decrease of the Ase1-GFP intensity on the meiotic spindles.
PMID:32723864 FYPO:0001513 Figure 7
PMID:32723864 PBO:0107269 Figure 7
PMID:32723864 FYPO:0007756 Figure 7
PMID:32723864 FYPO:0007756 Figure 7
PMID:32723864 FYPO:0007756 Figure 7
PMID:32723864 GO:0061804 Ase1 is required for promoting spindle elongation during mitotic prophase but synergizes with Klp2 to maintain spindle stability during metaphase I.
PMID:32723864 GO:0140642 Ase1 is required for promoting spindle elongation during mitotic prophase but synergizes with Klp2 to maintain spindle stability during metaphase I.
PMID:32723864 PBO:0107268 Figure 6
PMID:32723864 PBO:0107267 Figure 6
PMID:32735772 PBO:0104091 (Figure 3D) As expected, in cells lacking both Scs2 and Scs22, Epr1 became diffusely distributed in the cytoplasm
PMID:32735772 FYPO:0007449 Figures S3B and S3D Epr1-C showed ER localization in vegetatively growing cells, whereas Epr1-N was diffusely distributed in the cytoplasm and the nucleus
PMID:32735772 FYPO:0006378 Figures S3B and S3D Epr1-C showed ER localization in vegetatively growing cells, whereas Epr1-N was diffusely distributed in the cytoplasm and the nucleus
PMID:32735772 FYPO:0007444 Remarkably, Epr1-C, but not Epr1-N, could completely rescue the defects of epr1D in DTT-induced ER- phagy
PMID:32735772 FYPO:0007444 Mutating the FFAT motif or the AIM abolished the ability of Epr1-C to rescue epr1D (Figures 4A, 4B, and S3D).
PMID:32735772 FYPO:0007444 Mutating the FFAT motif or the AIM abolished the ability of Epr1-C to rescue epr1D (Figures 4A, 4B, and S3D).
PMID:32735772 PBO:0104095 The abilities of Epr1-C to bind Atg8 and VAPs using separate motifs suggest that one Epr1-C molecule may be able to interact with both an Atg8 molecule and a VAP molecule simultaneously and thereby bridge an Atg8-VAP association. To test this possi- bility, we performed an in vitro GST pull-down experiment using three proteins expressed in Escherichia coli: GST-tagged Scs2(1-126) corresponding to the FFAT-binding MSP domain, HA-tagged Atg8, and Smt3-tagged Epr1-C (Figure 4C). GST- Scs2(1-126) alone did not pull down Atg8. However, in the pres- ence of Epr1-C, GST-Scs2(1-126) efficiently pulled down both Epr1-C and Atg8, indicating that Epr1-C can bridge an indirect interaction between Scs2 and Atg8. Together, our results demonstrate that the main role of Epr1 in ER-phagy is to bridge an Atg8- VAP connection.
PMID:32735772 PBO:0093561 Fig. S1B
PMID:32735772 FYPO:0001357 Fig. S1B
PMID:32735772 PBO:0104093 Figure 1C AIM-mutated Epr1- C was pulled down as efficiently as wild-type Epr1-C by Scs2 but did not support the pull-down of Atg8 PLUS more experiments We hypothesized that the main role of Epr1 in ER-phagy is to mediate a connection between Atg8 and VAPs. requirement of Epr1 in ER-phagy can be by- passed by an artificial soluble tether that bridges an Atg8-VAP connection.Figure 4D).
PMID:32735772 FYPO:0007447 (Figure 5A) reduced in scs2D and abolished in scs2D scs22D
PMID:32735772 PBO:0104086 Figure 7B We found that DTT-induced increase of Epr1 was severely diminished in ire1D (Figure 7B), indicating that Epr1 upregulation requires Ire1.
PMID:32735772 FYPO:0006294 Figure S1E
PMID:32735772 FYPO:0006294 Figure S1E nitrogen starvation-induced ER-phagy appeared to be normal in epr1D
PMID:32735772 FYPO:0007446 Figure 2B, 2G, 2H
PMID:32735772 FYPO:0007446 Fig 3
PMID:32735772 FYPO:0007447 (Figure S6B), indicating that Ire1 is dispensable for DTT-induced bulk autophagy but is essential for DTT-induced ER-phagy.
PMID:32735772 FYPO:0005264 fig 6b
PMID:32735772 FYPO:0000843 Figure 6A
PMID:32735772 FYPO:0005264 fig 6b
PMID:32735772 PBO:0104098 Figure 7E the ER-phagy defect of ire1D was largely rescued (Figure 7E).
PMID:32735772 FYPO:0007446 (Figure 5A) reduced in scs2D and abolished in scs2D scs22D
PMID:32735772 GO:0005515 Figure 3C Epr1 interacted with both Scs2 and Scs22 in the Y2H assay
PMID:32735772 GO:0005515 Figures 1B and S1C
PMID:32735772 PBO:0104087 Figures 2G and 2H
PMID:32735772 GO:0005783 Figure 2a
PMID:32735772 GO:0005515 Figures 1B and S1C
PMID:32735772 PBO:0104088 Figure 3C The 42-amino-acid Epr1-C region (residues 339–380), which is capable of Atg8 bind- ing and contains the predicted FFAT motif, is sufficient for inter- acting with VAPs
PMID:32735772 PBO:0104089 Figure 3C The 42-amino-acid Epr1-C region (residues 339–380), which is capable of Atg8 bind- ing and contains the predicted FFAT motif, is sufficient for inter- acting with VAPs
PMID:32735772 PBO:0104091 Figure 3D ******check with DAN, is this an overexpression allele?
PMID:32735772 FYPO:0000843 Figure 6A
PMID:32735772 FYPO:0000843 Figure 6A
PMID:32735772 FYPO:0000843 Figure 6A
PMID:32735772 FYPO:0000843 Figure 6A
PMID:32735772 FYPO:0000843 Figure 6A
PMID:32735772 FYPO:0000843 Figure 6A
PMID:32735772 PBO:0093561 Fig. S1B
PMID:32735772 PBO:0104092 Figure 1C
PMID:32735772 PBO:0104090 Figure 1C
PMID:32735772 PBO:0104090 Figure 1C
PMID:32735772 GO:0000407 Figure 2a
PMID:32735772 GO:0044804 check with Dan **** Thus, Epr1 is an ER-phagy receptor required for ER stress-induced selective autophagy of both the nuclear envelope and the peripheral ER.
PMID:32735772 PBO:0104093 Figure 3C The 42-amino-acid Epr1-C region (residues 339–380), which is capable of Atg8 bind- ing and contains the predicted FFAT motif, is sufficient for inter- acting with VAPs
PMID:32735772 PBO:0104094 Figure 3C The 42-amino-acid Epr1-C region (residues 339–380), which is capable of Atg8 bind- ing and contains the predicted FFAT motif, is sufficient for inter- acting with VAPs
PMID:32735772 FYPO:0007449 figure 3D
PMID:32790622 PBO:0099296 viable spore yield assay; 30% of the surviving spores had inherited the two centromere 3-linked markers suggesting they are aneuploid/diploid.
PMID:32790622 PBO:0099293 viable spore yield assay
PMID:32790622 FYPO:0002052 viable spore yield assay
PMID:32790622 PBO:0099294 viable spore yield assay
PMID:32790622 PBO:0099295 viable spore yield assay; 16% of the surviving spores had inherited two copies of chromosome 3 and were thus aneuploid/diploid.
PMID:32790622 PBO:0099298 viable spore yield assay
PMID:32790622 PBO:0099297 viable spore yield assay; 20% of the surviving spores had inherited the two centromere 3-linked markers suggesting they are aneuploid/diploid.
PMID:32817556 PBO:0097418 Phenotype is greatly enhanced by mutation of the IR-R boundary element
PMID:32841241 PBO:0102884 CCU codon/AGG anticodon tRNA
PMID:32841241 PBO:0102890 UAC codon/GUA anticodon tRNA
PMID:32841241 PBO:0102889 CCU codon/AGG anticodon tRNA
PMID:32841241 PBO:0102890 UAC codon/GUA anticodon tRNA
PMID:32841241 PBO:0102889 CCU codon/AGG anticodon tRNA
PMID:32841241 PBO:0102890 UAC codon/GUA anticodon tRNA
PMID:32841241 PBO:0102889 CCU codon/AGG anticodon tRNA
PMID:32841241 PBO:0102888 UAC codon/GUA anticodon tRNA
PMID:32841241 PBO:0102887 CCU codon/AGG anticodon tRNA
PMID:32841241 PBO:0102888 UAC codon/GUA anticodon tRNA
PMID:32841241 PBO:0102887 CCU codon/AGG anticodon tRNA
PMID:32841241 PBO:0102886 ACU codon/AGU anticodon tRNA
PMID:32841241 PBO:0102885 UAC codon/GUA anticodon tRNA
PMID:32848252 GO:0140512 fig 3b
PMID:32848252 GO:0005637 Extended Data Figure 2 (nucleoplasmic side)
PMID:32848252 PBO:0099376 causally upstream?
PMID:32848252 PBO:0099365 fig 4/6
PMID:32848252 PBO:0099364 extended fig4
PMID:32848252 PBO:0099362 Fig. 4, Extended Data Fig. 7
PMID:32848252 GO:0007084 lem2 (which encodes Lem2, the binding partner of Cmp7) is also SL with les1
PMID:32848252 PBO:0099371 extended data 6 c,d
PMID:32848252 PBO:0099372 Fig. 3a, Extended Data Fig. 4a–c Removed from nuclear basket in bridge midzone during nuclear division
PMID:32848252 PBO:0099372 Fig. 3a, Extended Data Fig. 4a–c Removed from nuclear basket in bridge midzone during nuclear division
PMID:32848252 PBO:0099373 fig 4/6
PMID:32848252 PBO:0099369 Les1 stalks functionally isolate daughter nuclei from the process of Imp1-dependent local NEB at the centre of the bridge prob- ably acts to create a seal by gathering the inner nuclear envelope tightly around the spindle,
PMID:32848252 PBO:0099370 Fig. 4a, b. Daughter nuclei in the les1Δ strain also suffered transient leakages at the time of maximum spindle elongation, as measured by loss of nuclear NLS–GFP (;
PMID:32848252 GO:0140510 Fig. 3a, Extended Data Fig. 4a–c Removed from nuclear basket in bridge midzone during nuclear division
PMID:32848252 GO:0140510 Fig. 3a, Extended Data Fig. 4a–c Removed from nuclear basket in bridge midzone during nuclear division
PMID:32848252 PBO:0099368 fig 3g
PMID:32848252 PBO:0099366 Extended Data Figure 8
PMID:32848252 GO:0007084 nstead, the repair process was associated with recruitment of the ESCRTIII protein Cmp7 (Fig. 4d) to sites of local NEB20 (Fig. 4d, Extended Data Fig. 8b, c).
PMID:32878942 PBO:0099947 Fig. S3A
PMID:32878942 GO:0061245 Fig 3D
PMID:32878942 GO:2000099 Fig 3D
PMID:32878942 GO:2000099 Fig 3D
PMID:32878942 PBO:0099947 Fig. S3A
PMID:32878942 PBO:0099946 Fig. S3A
PMID:32878942 PBO:0099946 Fig. S3A
PMID:32878942 PBO:0099945 fig4
PMID:32878942 PBO:0099943 Fig 4H&I and S3F&G
PMID:32878942 PBO:0099943 Fig 4H&I and S3F&G
PMID:32878942 FYPO:0000674 Fig S3E
PMID:32878942 FYPO:0000674 Fig S3E
PMID:32878942 FYPO:0000674 Fig S3E
PMID:32878942 FYPO:0000674 Fig S3E
PMID:32878942 PBO:0099942 Fig 4D,E&F
PMID:32878942 FYPO:0003532 Fig S3B,C,&D
PMID:32878942 PBO:0099944 Fig S3F&G
PMID:32878942 PBO:0099943 Fig S3F
PMID:32878942 FYPO:0003532 Fig S3B&C
PMID:32878942 FYPO:0003532 Fig S3B&C
PMID:32878942 PBO:0099938 Figure 2I (vw changed tp FYPO:0002559)
PMID:32878942 FYPO:0001396 Figure 2F-H
PMID:32878942 PBO:0099937 Figure 2D&E
PMID:32896087 PBO:0100492 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100492 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100493 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100493 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100492 solid media screen using prototroph deletion library.
PMID:32896087 PBO:0100493 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100494 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100494 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100493 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100492 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100494 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100492 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100492 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100492 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100492 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100493 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100493 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100494 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100492 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100493 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100492 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100492 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100492 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100492 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100493 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0092433 EMM media with arginine
PMID:32896087 PBO:0092433 EMM media with arginine
PMID:32896087 PBO:0092433 EMM media with arginine
PMID:32896087 PBO:0092433 EMM media with arginine
PMID:32896087 PBO:0100496 EMM media with arginine
PMID:32896087 PBO:0100496 EMM media with arginine
PMID:32896087 PBO:0100496 EMM media with arginine
PMID:32896087 PBO:0100496 EMM media with arginine
PMID:32896087 PBO:0100496 EMM media with arginine
PMID:32896087 PBO:0100496 EMM media with arginine
PMID:32896087 PBO:0100496 EMM media with arginine
PMID:32896087 PBO:0100496 EMM media with arginine
PMID:32896087 PBO:0100496 EMM media with arginine
PMID:32896087 PBO:0100496 EMM media with arginine
PMID:32896087 PBO:0100496 EMM media with arginine
PMID:32896087 PBO:0100496 EMM media with arginine
PMID:32896087 PBO:0100496 EMM media with arginine
PMID:32896087 PBO:0100496 EMM media with arginine
PMID:32896087 PBO:0100496 EMM media with arginine
PMID:32896087 PBO:0100496 EMM media with arginine
PMID:32896087 PBO:0100496 EMM media with arginine
PMID:32896087 PBO:0100496 EMM media with arginine
PMID:32896087 PBO:0092433 EMM media with arginine
PMID:32896087 PBO:0100496 EMM media with arginine
PMID:32896087 GO:0005739 arg3-GFP fusion localisation in minimal media (EMM)
PMID:32896087 PBO:0100492 Liquid media growth assay. Mutant isolated from deletion collection.
PMID:32896087 PBO:0100493 Liquid media growth assay. Mutant isolated from deletion collection.
PMID:32896087 PBO:0100493 Liquid media growth assay. Mutant isolated from deletion collection.
PMID:32896087 PBO:0100493 Liquid media growth assay. Mutant isolated from deletion collection.
PMID:32896087 PBO:0100493 Liquid media growth assay. Mutant isolated from deletion collection.
PMID:32896087 PBO:0100495 Data from screening of prototroph deletion library
PMID:32896087 PBO:0100494 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100494 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100494 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100494 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100494 solid media screen using prototrophic deletion library
PMID:32896087 PBO:0100493 solid media screen using prototrophic deletion library
PMID:32908306 GO:0005739 Cup1-GFP immunofluorescence
PMID:32909946 FYPO:0006295 Fig 1a
PMID:32909946 PBO:0096897 in vitro autophosphorylation activity of Atg1 from atg11D mutant was almost undetectable (Figure 1D
PMID:32909946 PBO:0096898 we found that in S. pombe, Atg1 from atg13D, atg17D, or atg101D mutant exhibited autophosphorylation activities simi- lar to that of Atg1 from wild type
PMID:32909946 FYPO:0006295 Fig 1 a
PMID:32909946 PBO:0096897 Figure 1C). Such a band was not observed for D193A and T208A mutants, confirming that they are indeed kinase dead (
PMID:32915139 PBO:0102266 figure 5B
PMID:32915139 PBO:0102262 50%
PMID:32915139 PBO:0102266 fig 5c
PMID:32915139 PBO:0102268 Cells expressing a mutant allele Mcs4(D512N) that does not activate the SAPK pathway upon stimulation with hydro- gen peroxide (Shieh et al., 1997), displayed Sty1 activation during LatA treatment,
PMID:32915139 PBO:0102269 upstream elements of this signaling cascade shared this phenotype... Mcs4, the redundant MAPKKK´s Wak1 and Win1, and MAPKK Wis1 (Figure 1A, Figure 1—figure supplement 1
PMID:32915139 PBO:0102270 Figure 1C
PMID:32915139 PBO:0093570 fig1 SuppF
PMID:32915139 PBO:0093570 fig1 SuppF
PMID:32915139 PBO:0093569 fig 3a
PMID:32915139 PBO:0102263 fig3c
PMID:32915139 PBO:0102271 fig 4d
PMID:32915139 PBO:0102272 We found that total For3 levels also decline in S. pombe wild-type cells in response to stimuli that activate Sty1, like heat shock (40 ̊C), osmotic saline (0.6 M KCl), and oxidative stress (1 mM H2O2) (Pe ́rez and Cansado, 2010) in a MAPK-dependent manner (Figure 5—figure supplement 3).
PMID:32915139 PBO:0092160 We found that total For3 levels also decline in S. pombe wild-type cells in response to stimuli that activate Sty1, like heat shock (40 ̊C), osmotic saline (0.6 M KCl), and oxidative stress (1 mM H2O2) (Pe ́rez and Cansado, 2010) in a MAPK-dependent manner (Figure 5—figure supplement 3).
PMID:32915139 PBO:0102273 We found that total For3 levels also decline in S. pombe wild-type cells in response to stimuli that activate Sty1, like heat shock (40 ̊C), osmotic saline (0.6 M KCl), and oxidative stress (1 mM H2O2) (Pe ́rez and Cansado, 2010) in a MAPK-dependent manner (Figure 5—figure supplement 3).
PMID:32915139 PBO:0102274 Figure 5—figure supplement 4
PMID:32915139 PBO:0102275 Figure 5—figure supplement 4
PMID:32915139 PBO:0102270 Figure 1C
PMID:32915139 PBO:0102270 Figure 1C
PMID:32915139 PBO:0102277 replaces wt annotation
PMID:32915139 FYPO:0004513 Overexpression under the control of B-estradiol promoter (vw: I added an allele synonym, later these will be searchable and visible)
PMID:32915139 PBO:0102263 fig3b
PMID:32915139 PBO:0093569 fig 3a
PMID:32915139 FYPO:0001365 explicit delay in ring constriction and disassembly (21 ± 0.6 min in wild-type cells vs 36 ± 1.6 min in for3D cells; Figure 2—figure supplement 5
PMID:32915139 PBO:0102262 25%
PMID:32915139 PBO:0102260 fig 5b
PMID:32915139 PBO:0102260 fig 5b
PMID:32915139 PBO:0102259 fig2-supp1
PMID:32915139 FYPO:0004513 upstream elements of this signaling cascade shared this phenotype... Mcs4, the redundant MAPKKK´s Wak1 and Win1, and MAPKK Wis1 (Figure 1A, Figure 1—figure supplement 1
PMID:32915139 PBO:0093569 fig1 SuppF
PMID:32915139 PBO:0093569 fi1 supp5
PMID:32915139 PBO:0102254 cells lacking Sty1 grew in these low LatA concentrations (Figure 1B).
PMID:32915139 FYPO:0004513 fig 1F
PMID:32915139 PBO:0102277 replaces wt annotation
PMID:32915139 FYPO:0001368 (Figure 2—figure supplement 5). ngs formed and constricted correctly in >85% of sty1D cells (Figure 2D).
PMID:32915139 FYPO:0007151 Figure 2A and C) check, has synonym increased stability (better than increased length?)
PMID:33010152 FYPO:0002061 Fig. 3
PMID:33010152 FYPO:0000080 Fig. 4
PMID:33010152 FYPO:0000082 Fig. 4
PMID:33010152 PBO:0094738 Fig. 1
PMID:33010152 PBO:0094738 Fig. 1
PMID:33010152 PBO:0094738 Fig. 1
PMID:33010152 PBO:0094738 Fig. 1
PMID:33010152 PBO:0094738 Fig. 1
PMID:33010152 PBO:0094738 Fig. 1
PMID:33010152 PBO:0094738 Fig. 1, Fig. 8
PMID:33010152 PBO:0094738 Fig. 8
PMID:33010152 PBO:0094738 Fig. 8
PMID:33010152 PBO:0094738 Fig. 8
PMID:33010152 PBO:0094738 Fig. 8
PMID:33010152 PBO:0094738 Fig. 4
PMID:33010152 PBO:0094738 Fig. 4
PMID:33010152 PBO:0094738 Fig. 4
PMID:33010152 PBO:0094738 Fig. 4
PMID:33010152 PBO:0094738 Fig. 4
PMID:33010152 PBO:0094738 Fig. 4
PMID:33010152 PBO:0094738 Fig. 6
PMID:33010152 PBO:0094738 Fig. 6
PMID:33010152 PBO:0094738 Fig. 6
PMID:33010152 PBO:0094738 Fig. 6
PMID:33010152 PBO:0094738 Fig. 6
PMID:33010152 PBO:0094738 Fig. 6
PMID:33010152 PBO:0094738 Fig. 6
PMID:33010152 PBO:0094738 Fig. 6
PMID:33010152 PBO:0094738 Fig. 6
PMID:33010152 PBO:0094738 Fig. 1
PMID:33010152 PBO:0094738 Fig. 4
PMID:33010152 PBO:0094738 Fig. 6
PMID:33010152 PBO:0094738 Fig. 6
PMID:33010152 PBO:0094738 Fig. 6
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 PBO:0094738 Fig. 8
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 PBO:0094738 Fig. 8
PMID:33010152 PBO:0094738 Fig. 8
PMID:33010152 PBO:0094738 Fig. 8
PMID:33010152 FYPO:0000080 Fig. 4
PMID:33010152 FYPO:0000082 Fig. 4
PMID:33010152 FYPO:0000080 Fig. 4
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 PBO:0094738 Fig. 1
PMID:33010152 FYPO:0000080 Fig. 5
PMID:33010152 FYPO:0000080 Fig. 5
PMID:33010152 FYPO:0000080 Fig. 5
PMID:33010152 FYPO:0000080 Fig. 5
PMID:33010152 FYPO:0000080 Fig. 5
PMID:33010152 FYPO:0000080 Fig. 5
PMID:33010152 FYPO:0000082 Fig. 5
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 FYPO:0001357 Fig. 5
PMID:33010152 FYPO:0000080 Fig. 5
PMID:33010152 FYPO:0000080 Fig. 5
PMID:33010152 FYPO:0000080 Fig. 8
PMID:33010152 FYPO:0000080 Fig. 8
PMID:33010152 FYPO:0001355 Fig. 4
PMID:33010152 FYPO:0001355 Fig. 4
PMID:33010152 FYPO:0001355 Fig. 4
PMID:33010152 FYPO:0000080 Fig. 4
PMID:33010152 FYPO:0000082 Fig. 4
PMID:33049028 PBO:0100738 The results showed that in the intronless background, the cox1 and cob1 mRNAs were detected at similar levels in WT[i] and ppr10[i] cells (Fig. 1E–G
PMID:33049028 FYPO:0001934 fig4
PMID:33049028 PBO:0104049 Further analysis revealed that the levels of intron-retaining cox1 and cob1 tran- scripts were increased in ppr10 cells in the intron-containing background (Fig. 1A–C)
PMID:33049028 PBO:0104048 Further analysis revealed that the levels of intron-retaining cox1 and cob1 tran- scripts were increased in ppr10 cells in the intron-containing background (Fig. 1A–C)
PMID:33049028 PBO:0100740 The results showed that in the intronless background, the cox1 and cob1 mRNAs were detected at similar levels in WT[i] and ppr10[i] cells (Fig. 1E–G
PMID:33108274 PBO:0107741 The wtf4poison proteins is distributed throughout asci and spores in the absence of the wtf4antidote. The antidote assembles with the poison and then both proteins are localized to the vacuole in spores.
PMID:33108274 PBO:0107741 The wtf4poison proteins is distributed throughout asci and spores in the absence of the wtf4antidote. The antidote assembles with the poison and then both proteins are localized to the vacuole in spores.
PMID:33109728 FYPO:0002061 Fig. 4B
PMID:33109728 FYPO:0001355 Fig. 4B
PMID:33109728 FYPO:0001357 Fig. 4B
PMID:33109728 FYPO:0001357 Fig. 4B
PMID:33109728 FYPO:0002061 Fig. 4B
PMID:33109728 FYPO:0002061 Fig. 4B
PMID:33109728 FYPO:0001357 Fig. 4B
PMID:33109728 FYPO:0001357 Fig. 4B
PMID:33109728 FYPO:0001355 Fig. 4B
PMID:33109728 FYPO:0001355 Fig. 4B
PMID:33125111 FYPO:0002401 (Fig. 1C).
PMID:33125111 FYPO:0007208 (Fig. 1C).
PMID:33125111 FYPO:0000141 (Fig. 3).
PMID:33125111 FYPO:0000056 (Fig. 1A).
PMID:33125111 FYPO:0000177 (Fig. 3).
PMID:33125111 FYPO:0001234 (Fig. 1B). decreasing slows after 6 hours
PMID:33131769 FYPO:0001904 An fragile actomyosin contractile ring is an abnormal actomyosin contractile ring that disassemble by treatment with a low dose of Latrunculin A, an actin depolymerizing agent.
PMID:33131769 PBO:0099617 *****(abnormal distribution in...) inhomogeneous contractile Rng2 ring An inhomogeneous contractile Rng2 ring is an abnormal actomyosin contractile ring that show an uneven distribution of 2mYFP-Rng2-12A over the ring.
PMID:33131769 FYPO:0001904 An fragile actomyosin contractile ring is an abnormal actomyosin contractile ring that disassemble by treatment with a low dose of Latrunculin A, an actin depolymerizing agent.
PMID:33137119 PBO:0105949 Fig3A. affecting substrate Fkh2 in vitro
PMID:33137119 FYPO:0001032 pREP81-gad8-Q298L
PMID:33137119 PBO:0105950 affecting Gad8-S546 phosphorylation
PMID:33137119 PBO:0105950 affecting Gad8-S546 phosphorylation
PMID:33137119 PBO:0093824 pREP81-gad8-Q298L fig 5a
PMID:33137119 PBO:0093824 pREP81-gad8-K263C
PMID:33137119 PBO:0105952 Following release from campthotecin
PMID:33137119 PBO:0105950 affecting Gad8-S546 phosphorylation
PMID:33137119 FYPO:0004765 fig2
PMID:33137119 FYPO:0001021 fig1c
PMID:33137119 FYPO:0000674 fig1c
PMID:33137119 PBO:0093613 fig 6b
PMID:33137119 PBO:0093580 fig 6b
PMID:33137119 PBO:0105955 7B.
PMID:33137119 FYPO:0001021 pREP81-gad8-K263C
PMID:33137119 FYPO:0000674 pREP81-gad8-K263C figure 2
PMID:33137119 FYPO:0001021 pREP81-gad8-T260C. fig1a
PMID:33137119 PBO:0093581 fig 6c dominent negative effect
PMID:33137119 FYPO:0002578 pREP81-gad8-Q298L fig6D
PMID:33137119 FYPO:0000088 The only conditions under which we did not detect phosphorylation of Gad8-K263C were in Δtor1 cells in the presence of hydroxyurea or camptothecin (S3B Fig), a finding that may suggest that the activity of the kinase responsible for Gad8-K263C phosphorylation is inhibited under genotoxic stress conditions.
PMID:33137119 PBO:0105956 Fig3A.Gad8-K263C was also phosphorylated at S546 under conditions that compromise Tor1 activity, such as osmotic or low glucose stress (S3A Fig), further supporting Tor1-independent phosphorylation of Gad8-K263C by an as yet unknown kinase.
PMID:33137119 PBO:0093581 fig 6c L fig6D
PMID:33137119 FYPO:0000088 Additionally, the phosphorylation sites of Gad8 are required for genotoxic stress, since gad8-S527A/S546A mutant alleles are also sensitive to DNA damage and DNA replication stress (S5B Fig).
PMID:33137119 FYPO:0000088 (S5A Fig)
PMID:33137119 PBO:0094345 Fig3C. The wild type Gad8 is not phosphorylated at T387 in the absence of Tor1 and is only weakly phosphorylated under low-glucose conditions (Fig 3C).
PMID:33137119 PBO:0105954 Fig3C. we found that Gad8-K263C is phosphorylated at T387 in Δtor1 cells under normal or low-glucose growth conditions.
PMID:33137119 FYPO:0000082 As previously described [33], mutating both Tor1-dependent phosphorylation sites, S546 and S527, to alanine, abolished the ability of cells to grow at high temperature or in the presence of osmotic stress (Fig 3B)
PMID:33137119 PBO:0105953 Fig3A. affecting substrate Fkh2 in vitro
PMID:33137119 PBO:0093823 pREP81-gad8-T260C fig 2B
PMID:33137119 PBO:0105947 affecting substrate Fkh2 in vitro
PMID:33137119 PBO:0105948 affecting substrate Fkh2 in vitro
PMID:33137119 FYPO:0004765 pREP81-gad8-T260C fig2
PMID:33137119 PBO:0105949 Fig3A. affecting substrate Fkh2 in vitro
PMID:33137119 PBO:0093612 figure 3d. I CHANGED THIS ONE< IS IT CORRECT?
PMID:33137119 PBO:0105954 Fig3C. we found that Gad8-K263C is phosphorylated at T387 in Δtor1 cells under normal or low-glucose growth conditions.
PMID:33137119 PBO:0093558 fig 3b
PMID:33137119 FYPO:0000674 pREP81-gad8-T260C fig1a
PMID:33137119 PBO:0105948 affecting substrate Fkh2 in vitro
PMID:33137119 PBO:0093824 pREP81-gad8-T260C fig 2B
PMID:33137119 FYPO:0004765 pREP81-gad8-K263C
PMID:33137119 PBO:0105954 Fig3A. To our surprise, Gad8-K263C was phosphorylated at S546 in wild type cells, as well as in Δtor1 cells (S546-P, Fig 3A).This finding suggests that the Gad8-K263C mutant is phosphorylated by a kinase that normally does not recognize Gad8 as a substrate.
PMID:33137119 FYPO:0005947 fig 3b
PMID:33137119 FYPO:0000674 fig 3B
PMID:33137119 PBO:0105948 affecting substrate Fkh2 in vitro
PMID:33138913 PBO:0100132 This raises the possibility that the MIM complex assists Atg43 through facilitating its mitochondrial localization.
PMID:33138913 PBO:0100119 fig 2.
PMID:33138913 FYPO:0007448 fig1
PMID:33138913 FYPO:0007448 fig1
PMID:33138913 FYPO:0007596 fig1a
PMID:33138913 FYPO:0007596 Consistent with this, mitophagy was impaired in the mim1D and mim2D mutants (Figure 5D)
PMID:33138913 FYPO:0007596 Consistent with this, mitophagy was impaired in the mim1D and mim2D mutants (Figure 5D)
PMID:33138913 PBO:0100117 In the absence of Mim1 or Mim2, the GFP-Atg43 signal at the mitochondria was severely decreased (Figure 5C
PMID:33138913 FYPO:0001355 Fig- ure 5—figure supplement 1F
PMID:33138913 FYPO:0007592 fig 3H
PMID:33138913 FYPO:0007592 fig 3H
PMID:33138913 FYPO:0001357 figure 3I
PMID:33138913 FYPO:0007594 check genotype. ***********figure 3c
PMID:33138913 FYPO:0007594 fig 3b/4b
PMID:33138913 FYPO:0007592 fig 3b
PMID:33138913 PBO:0100120 figure 3D
PMID:33138913 PBO:0100124 fig 4D
PMID:33138913 FYPO:0007592 figure 4B
PMID:33138913 FYPO:0003768 fig3 supp1b&c
PMID:33138913 FYPO:0007594 whereas Atg43 with a truncation of the 60 C-terminal aa was defective in mitophagy (Figure 4B)
PMID:33138913 PBO:0100125 figure 4B Atg43 lacking the 20 C-terminal aa exhibited only a partial defect in mitophagy,
PMID:33138913 PBO:0093560 fig 4c
PMID:33138913 PBO:0100123 figure 4G
PMID:33138913 PBO:0100122 The interaction between full-length Atg43 and Mim2 was confirmed using reciprocal immunoprecipitation experi- ments (Figure 5A and Figure 5—figure supplement 1B).
PMID:33138913 GO:0140595 MIM complex (requrested)
PMID:33138913 PBO:0100127 This raises the possibility that the MIM complex assists Atg43 through facilitating its mitochondrial localization.
PMID:33138913 PBO:0100127 This raises the possibility that the MIM complex assists Atg43 through facilitating its mitochondrial localization.
PMID:33138913 PBO:0100121 figure 3D
PMID:33138913 PBO:0100128 We confirmed that Mim1 and Mim2 are required for stable localization of Tom70 on mitochondria in fis- sion yeast (Figure 5—figure supplement 1H
PMID:33138913 PBO:0100128 We confirmed that Mim1 and Mim2 are required for stable localization of Tom70 on mitochondria in fis- sion yeast (Figure 5—figure supplement 1H
PMID:33138913 PBO:0100129 Atg43 was observed on mitochondria in the absence of Tom70 (Figure 5E) and vice versa (Figure 5—figure supplement 1I)
PMID:33138913 PBO:0100123 Atg43 was observed on mitochondria in the absence of Tom70 (Figure 5E) and vice versa (Figure 5—figure supplement 1I)
PMID:33138913 PBO:0100130 Atg43 was observed on mitochondria in the absence of Tom70 (Figure 5E) and vice versa (Figure 5—figure supplement 1I)
PMID:33138913 PBO:0100130 Atg43 was observed on mitochondria in the absence of Tom70 (Figure 5E) and vice versa (Figure 5—figure supplement 1I)
PMID:33138913 PBO:0100131 Atg43 was observed on mitochondria in the absence of Tom70 (Figure 5E) and vice versa (Figure 5—figure supplement 1I)
PMID:33138913 PBO:0100131 Atg43 was observed on mitochondria in the absence of Tom70 (Figure 5E) and vice versa (Figure 5—figure supplement 1I)
PMID:33138913 PBO:0100123 Atg43 was observed on mitochondria in the absence of Tom70 (Figure 5E) and vice versa (Figure 5—figure supplement 1I)
PMID:33138913 PBO:0100123 Atg43 was observed on mitochondria in the absence of Tom70 (Figure 5E) and vice versa (Figure 5—figure supplement 1I)
PMID:33138913 PBO:0100132 This raises the possibility that the MIM complex assists Atg43 through facilitating its mitochondrial localization.
PMID:33138913 PBO:0100133 figure 6B,D
PMID:33138913 PBO:0100134 figure 6B
PMID:33138913 PBO:0100133 figure 6B
PMID:33138913 FYPO:0007602 By contrast, the atg7D and atg43DAIM mutants did not exhibit such an increased in superoxide (Figure 7D)
PMID:33138913 PBO:0100120 figure 3D
PMID:33138913 PBO:0093560 fig 3i
PMID:33138913 PBO:0100123 fig 3K
PMID:33138913 PBO:0100123 fig 4D
PMID:33138913 FYPO:0007592 fig 3H
PMID:33138913 PBO:0100116 Therefore, we propose that a major role of Atg43 in the mitophagy process is to tether Atg8 to mitochondria through direct interaction with Atg8 via the AIM region.
PMID:33138913 GO:0005741 figure 2F, 2G, 2H
PMID:33138913 FYPO:0007594 fig1
PMID:33138913 FYPO:0007602 By contrast, the atg7D and atg43DAIM mutants did not exhibit such an increased in superoxide (Figure 7D)
PMID:33138913 FYPO:0007594 fig1D
PMID:33138913 PBO:0092097 2A
PMID:33138913 FYPO:0001355 Fig- ure 5—figure supplement 1F
PMID:33138913 PBO:0100117 In the absence of Mim1 or Mim2, the GFP-Atg43 signal at the mitochondria was severely decreased (Figure 5C
PMID:33153481 FYPO:0007516 Fig.1a,d,e,f,S3; 3D quantification of DAPI stained DNA, G2 arrested cells by cdc2-asM17, Shortened the distance between genomic loci
PMID:33153481 FYPO:0007518 Fig. 6b-d; Rad52 foci quantification, G2 arrested cells by cdc2-asM17, + Thiolutin
PMID:33153481 FYPO:0007328 Fig. 6b-d; Rad52 foci quantification, G2 arrested cells by cdc2-asM17, + Thiolutin
PMID:33153481 FYPO:0000972 Fig. 6b-d; Rad52 foci quantification, G2 arrested cells by cdc2-asM17
PMID:33153481 FYPO:0007519 Fig.6e; 3D quantification of DAPI stained DNA, G2 arrested cells by cdc2-asM17, + Thiolutin
PMID:33153481 FYPO:0007517 Fig.4,S5; G2 arrested cells by cdc2-asM17
PMID:33153481 FYPO:0001352 Fig.2,3,S4; Hi-C, G2 arrested cells by cdc2-asM17
PMID:33153481 FYPO:0001221 Fig.S2; G2 arrested cells by cdc2-asM17
PMID:33159083 FYPO:0007533 also assayed using ChIP to detect Rts1 binding to Npp106
PMID:33159083 FYPO:0007532 also assayed using ChIP to detect Rts1 binding to Npp106
PMID:33159083 FYPO:0007532 also assayed using ChIP to detect Rts1 binding to Npp106
PMID:33159083 FYPO:0007532 also assayed using ChIP to detect Rts1 binding to Npp106
PMID:33159083 PBO:0100676 FISH
PMID:33159083 FYPO:0007532 also assayed using ChIP to detect Rts1 binding to Npp106
PMID:33159083 PBO:0100676 FISH; same as nup132delta alone
PMID:33159083 FYPO:0007532 also assayed using ChIP to detect Rts1 binding to Npp106
PMID:33159083 FYPO:0007532 also assayed using ChIP to detect Rts1 binding to Npp106
PMID:33159083 FYPO:0007532 also assayed using ChIP to detect Rts1 binding to Npp106
PMID:33159083 FYPO:0007532 also assayed using ChIP to detect Rts1 binding to Npp106
PMID:33159083 FYPO:0007533 also assayed using ChIP to detect Rts1 binding to Npp106
PMID:33159083 FYPO:0007533 also assayed using ChIP to detect Rts1 binding to Npp106
PMID:33159083 FYPO:0007533 also assayed using ChIP to detect Rts1 binding to Npp106
PMID:33159083 GO:1990426 pmt3-D81R pmt3-KallR
PMID:33159083 FYPO:0007532 also assayed using ChIP to detect Rts1 binding to Npp106
PMID:33159083 FYPO:0007532 also assayed using ChIP to detect Rts1 binding to Npp106
PMID:33172987 FYPO:0001357 Figure S2
PMID:33172987 GO:1902635 I changed the function annotation to this process annotation because it precisely negates the SGD annotation
PMID:33172987 PBO:0101375 Figure1C (requested normal membrane lipid binding)
PMID:33172987 PBO:0101376 Figure 1C
PMID:33172987 GO:0005515 PH1 domain Fig. 2A, Table S2
PMID:33172987 PBO:0095685 THIS IS A GUESS I COULD NOT ACCESS THE SUPP SO ANNOTATED TO THE Snider ITS3-1 growth phenotype
PMID:33172987 FYPO:0001357 Figure S2
PMID:33172987 FYPO:0001357 Figure S2
PMID:33172987 FYPO:0001357 Figure S2
PMID:33172987 PBO:0101372 (Fig. S2B).
PMID:33172987 PBO:0101373 Figure S2
PMID:33172987 PBO:0101371 Figure S1
PMID:33172987 PBO:0101371 Figure S1
PMID:33172987 FYPO:0001357 Figure S2
PMID:33172987 FYPO:0001357 Figure S2
PMID:33172987 FYPO:0001357 Figure S2
PMID:33172987 FYPO:0001355 Figure S3
PMID:33172987 PBO:0101371 Figure S1
PMID:33172987 PBO:0101371 Figure S1
PMID:33172987 FYPO:0000339 Figure 4E-F
PMID:33172987 PBO:0101372 Figure 3A
PMID:33172987 PBO:0101371 (Fig. 1F-G
PMID:33172987 GO:0005546 Fig. 1D-E
PMID:33172987 FYPO:0001357 Figure S2
PMID:33172987 FYPO:0001357 Figure S2
PMID:33172987 FYPO:0001357 Figure S2
PMID:33172987 PBO:0101374 Figure S3
PMID:33172987 FYPO:0001355 Figure S3
PMID:33172987 GO:0005543 Figure 3
PMID:33172987 GO:0005543 Opy1 PH1 (aa1-128) can directly bind phospholipids in vitro Figure 1
PMID:33176147 FYPO:0005555 figure 2c Figures 3B and S3B Figures 4C and 4D
PMID:33176147 FYPO:0007542 figS2A
PMID:33176147 FYPO:0005555 figure 2c Figures 3B and S3B Figures 4C and 4D
PMID:33176147 PBO:0094949 fig 2A
PMID:33176147 PBO:0100477 Figures 4E and 4F
PMID:33176147 FYPO:0007543 fig1F
PMID:33176147 FYPO:0007542 fig1F/figS2A
PMID:33176147 FYPO:0005018 fig1F
PMID:33176147 FYPO:0005018 fig1F
PMID:33176147 FYPO:0007544 fig1E
PMID:33176147 PBO:0096647 fig 2A
PMID:33176147 FYPO:0007544 fig1E
PMID:33176147 PBO:0100478 Figures 4E and 4F
PMID:33176147 PBO:0100478 Figures 4E and 4F
PMID:33176147 FYPO:0007544 fig1E
PMID:33202882 PBO:0099385 intron 2
PMID:33225241 PBO:0093559 same as mas5delta alone
PMID:33225241 PBO:0093559 same as mas5delta alone
PMID:33225241 FYPO:0007300 background: Pyp1-GFP
PMID:33225241 PBO:0022466 Background Sty1-GFP
PMID:33357436 PBO:0106496 Figure 4F
PMID:33357436 PBO:0108785 These results indicate that the Cdc15 F-BAR domain can position Cdc12 directly at the PM by binding membrane and Cdc12 simultaneously.
PMID:33357436 PBO:0099724 Figure S2E
PMID:33357436 PBO:0106498 moved down from abnormal localization
PMID:33357436 PBO:0106495 In vitro binding assay with Cdc15 F-BAR domain and full length Pxl1
PMID:33357436 PBO:0106491 fig 2B in vitro binding assay with Cdc15 F-BAR domain and Cdc12 peptide aa20-40
PMID:33357436 PBO:0106492 Figure 3A
PMID:33357436 FYPO:0004594 additional cewlll. poles
PMID:33357436 FYPO:0001365 Figures 3C and 3D
PMID:33357436 FYPO:0005221 Figure S2B electron microscopy of purified Cdc15 F-BAR domain
PMID:33357436 PBO:0106497 Figure S2C
PMID:33378674 GO:0006335 at pericentromeric regions
PMID:33378677 PBO:0107727 inferred from abolished interaction between Pof8 and Lsm subunits
PMID:33378677 PBO:0107728 inferred from decreased interaction between Pof8 and Lsm subunits
PMID:33378677 PBO:0107726 inferred from abolished interaction between Pof8 and Lsm subunits
PMID:33386485 PBO:0100250 background Hsp104-GFP and Rho1.C17R-mCherry
PMID:33386485 FYPO:0007301 Background Rho1.C17R-mCherry
PMID:33386485 FYPO:0007301 background Hsp104-GFP and Rho1.C17R-mCherry
PMID:33386485 PBO:0100249 background Hsp104-GFP and Rho1.C17R-mCherry
PMID:33400299 FYPO:0006141 figure 4b
PMID:33400299 PBO:0103212 transcriptional activity was dramatically increased in these 11 mitochondrial mutant strains (Figure 1i,j).
PMID:33400299 PBO:0103212 Figure 1m
PMID:33400299 PBO:0103214 Figure 1m
PMID:33400299 PBO:0103215 To further examine whether ROS and NO mediated increased Rst2 transcriptional activity caused by mitochondrial complex III/IV inhibitors, we examined the effect of antioxidant N-acetyl-L-cysteine (NAC) which aids in ROS detoxification and 2-(4-Carboxyphenyl)-4,4,5,5-tetramethy-limidazo-line-1-oxyl-3- oxide (Carboxy-PTIO), a NO-specific scavenger on the Rst2 transcriptional activity stimulated by mitochondrial complex III/IV inhibitors. The results showed that NAC and Carboxy-PTIO significantly inhibited mitochondrial complex III/IV inhibitors-induced activation of Rst2 in a dose-dependent manner (Figure 2e–j), suggesting that ROS and NO were involved in mitochondrial respiratory chain complex III/IV inhibitors-induced activation of Rst2. To further prove this result, we also examined the effect of a mammalian NO synthesis (NOS) inhibitor, N G-nitro-l-arginine methyl ester (NAME) on the Rst2 transcriptional activity stimulated by mitochondrial complex III/IV inhibitors, since it was reported that NAME treatment can reduce NO formation by more than 60% in yeast cells (Astuti et al., 2016a). As expected, NAME dose-dependently decreased mitochondrial complex III/IV inhibitors- induced Rst2 activation (Figure 2k–m).
PMID:33400299 PBO:0103216 (Figure 2k–m).
PMID:33400299 PBO:0103217 Figure 2n
PMID:33400299 PBO:0103217 Figure 2n
PMID:33400299 PBO:0103220 3a glucose starve
PMID:33400299 PBO:0020037 3a glucose starve
PMID:33400299 PBO:0103219 3a glucose r excess
PMID:33400299 PBO:0103218 Figure 2n
PMID:33400299 FYPO:0007617 Table1
PMID:33400299 FYPO:0000440 Table1
PMID:33400299 PBO:0103212 transcriptional activity was dramatically increased in these 11 mitochondrial mutant strains (Figure 1i,j).
PMID:33400299 PBO:0103212 transcriptional activity was dramatically increased in these 11 mitochondrial mutant strains (Figure 1i,j).
PMID:33400299 PBO:0103212 transcriptional activity was dramatically increased in these 11 mitochondrial mutant strains (Figure 1i,j).
PMID:33400299 PBO:0103212 transcriptional activity was dramatically increased in these 11 mitochondrial mutant strains (Figure 1i,j).
PMID:33400299 PBO:0103212 transcriptional activity was dramatically increased in these 11 mitochondrial mutant strains (Figure 1i,j).
PMID:33400299 PBO:0103212 transcriptional activity was dramatically increased in these 11 mitochondrial mutant strains (Figure 1i,j).
PMID:33400299 PBO:0103212 transcriptional activity was dramatically increased in these 11 mitochondrial mutant strains (Figure 1i,j).
PMID:33400299 PBO:0103212 transcriptional activity was dramatically increased in these 11 mitochondrial mutant strains (Figure 1i,j).
PMID:33400299 PBO:0103212 transcriptional activity was dramatically increased in these 11 mitochondrial mutant strains (Figure 1i,j).
PMID:33400299 PBO:0103212 transcriptional activity was dramatically increased in these 11 mitochondrial mutant strains (Figure 1i,j).
PMID:33400299 FYPO:0006141 figure 4b
PMID:33400299 FYPO:0006141 figure 4b
PMID:33400299 FYPO:0006141 figure 4b
PMID:33400299 FYPO:0006141 figure 4b
PMID:33400299 FYPO:0006141 figure 4b
PMID:33400299 FYPO:0006141 figure 4b
PMID:33400299 FYPO:0006141 figure 4b
PMID:33400299 FYPO:0006141 figure 4b
PMID:33400299 FYPO:0000440 Table1
PMID:33400299 FYPO:0006141 figure 4b
PMID:33400299 FYPO:0006141 figure 4b
PMID:33400299 FYPO:0006141 figure 4b
PMID:33410907 PBO:0097236 6c
PMID:33410907 PBO:0103181 Figure 2c (this replaces the sty1 WT annotation Should this be normal? i.e. normal for the conditions? )
PMID:33410907 PBO:0103180 Figure 2c (this replaces the sty1 WT annotation Should this be normal? i.e. normal for the conditions? )
PMID:33410907 PBO:0111318 ( Figure 5D **I moved this from a WT phenotype)
PMID:33410907 FYPO:0003004 (is thsi |+h2os, check) the intracellular level of ROS was elevated in pin1 and ssu72 mutants (Figure 6H),
PMID:33410907 FYPO:0003004 (is this +H2o2, check) the intracellular level of ROS was elevated in pin1 and ssu72 mutants (Figure 6H),
PMID:33410907 PBO:0111317 Ssu72, but not with the GST control in the pull down experiment. These results suggested that Pin1 directly interacted with and recruited Ssu72 for pSer5 dephosphorylation to facilitate progression of transcription important for cellular response to oxidative stress
PMID:33410907 PBO:0103169 In the absence of Pin1, Ser5 phosphorylated Rpb1 was associated and accumulated at the promoter region following H2O2 stress but was defective in entering elongation to generate transcripts of the corresponding genes (Figure 1C)
PMID:33410907 PBO:0094384 Figure 1C
PMID:33410907 PBO:0103165 2B
PMID:33410907 PBO:0103166 2B
PMID:33410907 PBO:0103167 2B
PMID:33410907 PBO:0103165 As shown in Figure 3C and D, upon H2O2 stress, Rpb1 was recruited to the promoter and extensively phosphorylated at Ser5.
PMID:33410907 PBO:0103178 Figure 4. Sty1 interacted and phosphorylated Rpb1-CTD at Ser5.
PMID:33410907 FYPO:0006819 Figure 1
PMID:33410907 FYPO:0000087 Figure 1
PMID:33410907 FYPO:0005889 Figure 5e
PMID:33410907 FYPO:0000087 Figure 5
PMID:33410907 FYPO:0001103 Figure 5
PMID:33410907 PBO:0103163 Figure 4. Sty1 interacted and phosphorylated Rpb1-CTD at Ser5.
PMID:33410907 PBO:0096825 Figure 4. Sty1 interacted and phosphorylated Rpb1-CTD at Ser5.
PMID:33410907 PBO:0092468 Figure 1
PMID:33410907 PBO:0092468 Figure 1
PMID:33410907 PBO:0092468 Figure 1
PMID:33410907 PBO:0101320 fig2a
PMID:33410907 PBO:0103164 fig? (under calf alkaline phosphatase treated)
PMID:33410907 PBO:0097080 Figure 1C
PMID:33410907 PBO:0103168 As shown in Figure 3C and D, upon H2O2 stress, Rpb1 was recruited to the promoter and extensively phosphorylated at Ser5.
PMID:33410907 PBO:0103170 In line with these results, Ser2 phosphorylation of Rpb1-CTD, which facilitated transcription elongation, was reduced in pin1 mutant as a secondary effect derived from defect in transcription initiation to elongation (Figure 3A and B).
PMID:33410907 PBO:0103177 These results suggested that, in addition to the binding to theRpb1-CTD, the isomerization activity was also required for the fu
PMID:33410907 PBO:0103175 Intriguingly, upon oxidative stress, the association between Rpb1 and Sty1 was decreased in wild type cells and up regulated in the pin1 mutant with reduced phosphorylation of Ser2 (Figure 4B).
PMID:33410907 PBO:0103172 In line with these results, Ser2 phosphorylation of Rpb1-CTD, which facilitated transcription elongation, was reduced in pin1 mutant as a secondary effect derived from defect in transcription initiation to elongation (Figure 3A and B).
PMID:33410907 PBO:0103171 In line with theseresults, Ser2 phosphorylation of Rpb1-CTD, which facilitatedtranscription elongation, was reduced in pin1 mutantas a secondary effect derived from defect in transcription initiation to elongation (Figure 3A and B).
PMID:33410907 PBO:0097079 Figure 1C
PMID:33419777 FYPO:0007474 FigS1. delayed septation, Cellular phenotype where cells initiate growth before septation has taken place, resulting in variable cell size at division.
PMID:33419777 FYPO:0007660 Fig 3A-F same result in Wild type background
PMID:33419777 FYPO:0007660 Fig3A-F same result in wild type background
PMID:33419777 PBO:0107436 Fig5 E,F abnormal protein localisation in multinucleated cells
PMID:33419777 FYPO:0007474 Fig5C Table 3
PMID:33419777 PBO:0107435 Fig5C compare16 and 17 Table 3 I don't quite know how to annotate this or whether I leave it as 'variable size at division and do a genetic interaction and Im not sure that the term I have suggested is right
PMID:33419777 PBO:0107435 increased cell size variability. cellular phenotype of variable cell size at division may be further increased in the absence of another cellular protein Fig5 compare 14 and 15 Table 3 I don't quite know how to annotate this or whether I leave it as 'variable size at division and do a genetic interaction and Im not sure that the term I have suggested is right
PMID:33419777 PBO:0107433 Fig4A
PMID:33419777 PBO:0102590 Fig5A
PMID:33419777 PBO:0102679 Fig5A
PMID:33419777 FYPO:0007474 Fig1B, C Table 1
PMID:33419777 FYPO:0007474 Fig1B, C Table 1
PMID:33419777 FYPO:0007474 Fig1B, C Table 1
PMID:33419777 PBO:0107437 Fig4A.
PMID:33419777 PBO:0104580 Fig5A
PMID:33419777 PBO:0107432 Fig1A
PMID:33419777 FYPO:0007474 Fig1B, C Table 1
PMID:33419777 FYPO:0007474 Fig1B, C Table 1
PMID:33419777 FYPO:0007660 Fig 2, Table 2
PMID:33419777 PBO:0107435 Fig5C compare 7 and 9 When cdc2 is not tyrosine phosphorylation mga2 delta does not increase the cell size variability any further.
PMID:33419777 PBO:0107435 Fig5C compare 4 and 6 the variability of cdc2cdc13 fusion protein is increased in mga2 delta. I don't quite know how to annotate this or whether I leave it as 'variable size at division and do a genetic interaction and Im not sure that the term I have suggested is right
PMID:33419777 FYPO:0007660 Fig 2, Table 2
PMID:33419777 FYPO:0007474 Fig3H same in wild type background
PMID:33419777 PBO:0107434 Fig4 B,C, D. A cellular phenotype found in multinucleated cells where nuclear division is no longer synchronous and cells with an odd number of nuclei are observed
PMID:33419777 FYPO:0007474 Fig 3I same in wild type background
PMID:33434270 PBO:0106087 Figure. 6A
PMID:33434270 PBO:0106086 Figure. 5A
PMID:33468217 FYPO:0003044 inferred from silencing and H3-K9 methylation phenotypes
PMID:33468217 GO:0031445 inferred from silencing and H3-K9 methylation phenotypes
PMID:33483504 FYPO:0001234 fig. 1b n=344
PMID:33483504 FYPO:0001234 fig. 3d
PMID:33483504 FYPO:0007611 fig. 3b
PMID:33483504 PBO:0097070 figure 3b
PMID:33483504 PBO:0097069 figure 3a
PMID:33483504 PBO:0097069 figure 3a
PMID:33483504 GO:0032473 integral 2a,b,c,d
PMID:33483504 PBO:0097068 fig 1d. Despite the multiple types of abnormalities observed in emr1Δ cells, mitochondria of emr1Δ cells were still able to undergo fission and fusion (Fig. 1d), but improperly segregated into daughter cells after mitosis (Fig. 1e). This phenotype of defective mitochondrial segregation is consistent with the previous finding that spherical/giant mitochondria in mutant cells compromise mitochondrial movements, inheritance, and segregation7,8,2
PMID:33483504 GO:0120010 er to mitochondria
PMID:33483504 PBO:0097071 As shown in Fig. 6b, c, Emr1-FL and Emr1-ΔN, but not Emr1-ΔC, restored the normal number of Mdm12 foci, confirming that the C-terminus of Emr1 is required for regulating the number of ERMES foci.
PMID:33483504 PBO:0097073 fig 5
PMID:33483504 PBO:0097072 fig 4d though the expression levels of Mdm12 were comparable in WT and emr1Δ Cells
PMID:33483504 PBO:0097071 fig 4 significantly decreased the number of Mdm12 (a constitutive component of the ERMES complex) foci
PMID:33483504 FYPO:0000895 fig1 (cox4-GFP to label Mt)
PMID:33483504 FYPO:0007611 fig. 1a
PMID:33483504 PBO:0097067 fig. 1b n=344
PMID:33483504 PBO:0095634 fig 1c
PMID:33496728 PBO:0104825 (Fig. 4 C). Cdc12p distributed in a smaller zone in the R-nodes of Δmid1 cells...node dimensions in the R-nodes of constricting contractile rings.....
PMID:33496728 PBO:0104824 Figure 1E, F. VW instead of abnormal, I did increased and decreased rate with low penetrance (i.e the rate is variable within the population, someincreased and some decrreased, although there see to be 2 distinct sub-populations we can't capture this effectively)
PMID:33496728 FYPO:0003946 Figure S3
PMID:33496728 FYPO:0000161 Figure S1
PMID:33496728 FYPO:0001368 Figure S1
PMID:33496728 FYPO:0000161 Figure S1
PMID:33496728 FYPO:0003946 Figure S3
PMID:33496728 PBO:0104819 Figure 1
PMID:33496728 PBO:0104817 Figure 1E, F. The average constriction rate of Δmid1 contractile rings is 0.27 μm/min (Saha and Pollard, 2012a), but the distribution of constriction rates appears bimodal with fast and slow subpopulations. The type of strand that builds the contractile ring strongly correlates with its constriction rate, with contractile rings made from nascent strands constricting faster (0.32 μm/min) and contractile rings made from enduring strands constricting more slowly (0.20 μm/min; Fig. 1 E).
PMID:33496728 FYPO:0007830 Figure 3 Figure 4 Figure S2
PMID:33496728 FYPO:0003946 Figure S3
PMID:33496728 PBO:0104823 Figure 5
PMID:33496728 FYPO:0003946 Figure 5
PMID:33496728 PBO:0104822 Figure 1, Figure 5. +5 min, a 15-min delay compared with wild-type cells
PMID:33496728 FYPO:0007832 Figure 5
PMID:33496728 FYPO:0000161 Figure 5 (VW: changed severity from high to low as this seems to partially rescue mid1-delta?)
PMID:33496728 PBO:0104818 Figure 2 Figure 3 Figure 4 Figure S2
PMID:33496728 FYPO:0000161 Figure 1A, B
PMID:33496728 FYPO:0000161 Figure 6
PMID:33496728 PBO:0104820 Figure 1
PMID:33496728 FYPO:0001364 Figure S1
PMID:33496728 PBO:0104821 Figure 1E, F
PMID:33496728 PBO:0104820 Figure 1E, F. We generated Δmid1 Δmyp2 double-mutant cells and found that the distribution of constriction rates of their contractile rings is still bimodal, albeit with both populations constricting 25–50% more slowly than the Δmid1 populations, consistent with Myp2p being responsible for ∼50% of the constriction rate
PMID:33506191 PBO:0102842 "fig4 If possible, please add the following comment - “The nucleus is retained in the center of the cell during mitosis."""
PMID:33506191 PBO:0102843 Fig7
PMID:33506191 PBO:0102842 fig6
PMID:33506191 PBO:0102842 fig4
PMID:33506191 PBO:0102842 fig4
PMID:33506191 PBO:0102837 fig1
PMID:33506191 PBO:0102841 Fig 7 These results indicate that first, the main reason for lethality of cut7 is derived from the cut phenotype; second, some cells could escape from cut by displacing the nucleus from the middle of the cell axis; and finally, these cut7 survivors could resume cell division as diploid progenies at the permissive temperature.
PMID:33506191 PBO:0102840 fig2 live cell imaging
PMID:33506191 PBO:0102839 fig2 live cell imaging
PMID:33506191 PBO:0102838 fig1
PMID:33506191 PBO:0102838 fig1
PMID:33506191 PBO:0102838 fig1
PMID:33506191 PBO:0102838 fig1
PMID:33506191 PBO:0102838 fig1
PMID:33506191 PBO:0102838 fig1
PMID:33506191 PBO:0102837 fig1
PMID:33506191 PBO:0102837 fig1
PMID:33506191 PBO:0102837 fig1
PMID:33506191 PBO:0102837 fig1
PMID:33506191 PBO:0102837 fig1
PMID:33506191 PBO:0102837 fig1
PMID:33511417 FYPO:0007656 genome-wide average; slightly increased amplitudes of the -2, -1, +1 nucleosome peaks (relative to NDR)
PMID:33511417 FYPO:0004491 genome-wide average
PMID:33526714 PBO:0099413 figure2
PMID:33526714 PBO:0099410 figure 2
PMID:33526714 PBO:0099410 figure 2
PMID:33526714 PBO:0099410 figure2
PMID:33526714 PBO:0099412 figure2
PMID:33526714 PBO:0099411 figure2
PMID:33526714 PBO:0099410 figure2
PMID:33526714 PBO:0099410 figure2
PMID:33526714 PBO:0099410 figure2
PMID:33526714 PBO:0099413 figure2
PMID:33526714 PBO:0099413 figure2
PMID:33526714 PBO:0099413 figure2
PMID:33526714 PBO:0099413 figure2
PMID:33526714 PBO:0099413 figure2
PMID:33529549 PBO:0109245 Importantly, the dam1Δ mutation impaired disjunction of homologous chromosomes (figure 5a), as seen in mad2Δ and ark1-so mutants [25,52].
PMID:33529549 PBO:0109805 Furthermore, the dam1Δ mutation increased equational segregation of sister chromatids in rec12+ cells (figure 5b, left) but it decreased equational segregation in sgo1Δ rec12Δ or haploid meiotic sgo1Δ cells (figure 5b,c)
PMID:33529549 PBO:0109806 Decreased equational segregation in the diploid sgo1∆ rec12∆ background or the haploid sgo1∆ background.
PMID:33529549 FYPO:0008099 Anaphase A chromosome movement is completely abolished and only anaphase B chromosome movement occurs.
PMID:33529549 PBO:0109807 Figure 1. Increased equational segregation in sgo1∆ background.
PMID:33529549 PBO:0109808 Figure 1. Increased equational segregation in sgo1∆ background.
PMID:33529549 PBO:0109803 Figure 1. Increased equational segregation in the sgo1∆ background.
PMID:33529549 FYPO:0005634 ***** increased bi-oriented attachment of sister chromatids in meiosis I*****The frequencies of sister centromere splitting varied (electronic supplementary material, figure S2A), but the mean splitting frequencies per centromere obtained by the bootstrap method were signifi- cantly higher in rec12Δ cells than in rec12+ cells (the difference was also significant in the usual t-test, p < 0.01; figure 2d, +). The elevated frequency of sister centromere splitting in chiasma-lacking cells confirms that chiasmata prevent bi-oriented attachment of sister chromatids.
PMID:33529549 PBO:0109802 FIgure 1. Decreased equational segregation in the sgo1∆ rec12∆ background or the haploid sgo1∆ background.
PMID:33529549 GO:0031619 The elevated frequency of sister centromere splitting in chiasma-lacking cells confirms that chiasmata prevent bi-oriented attachment of sister chromatids.
PMID:33529549 PBO:0109801 FIgure 1. These results indicate that the error correction mechanism decreases bi-oriented attachment of sister chromatids in the presence of chiasmata, but conversely increases bi-oriented attachment (thereby decreasing mono-oriented attachment) in the absence of chiasmata. In our previous study, the equational segregation frequencies of cen1 were somewhat higher in the rec12Δ background [28], although the reason for this is unknown. However, the mad2Δ mutation similarly decreased equational segregation, being consistent with our current results.
PMID:33534698 GO:0061700 Figure 1
PMID:33534698 GO:0035859 Figure 1
PMID:33534698 GO:1990130 Figure 1
PMID:33534698 GO:0005774 Figure 1, Supp 1
PMID:33534698 GO:0005774 Figure 1, Supp 1
PMID:33534698 GO:0005774 Figure 1, Supp 1
PMID:33534698 GO:0005774 Figure 1, Supp 1
PMID:33534698 GO:0005774 Figure 1, Supp 1
PMID:33534698 GO:0005774 Figure 1, Supp 1
PMID:33534698 GO:0005774 Figure 1, Supp 1
PMID:33534698 PBO:0099984 vw I edited to make the response the extension to GCN2 mediated signalling, but I hope to improve these GO terms.
PMID:33534698 PBO:0099986 Gcn2-dependent induction of autoph- agy was also observed in cells treated by 3-amino-1,2,4-triazole (3-AT) or methionine sulfoximine (MSX), inhibitors of histidine and glutamine biosynthesis, respectively (Figure 4—figure supplement 1D,E).
PMID:33534698 GO:0010508 Autophagy in response to leucine starvation was abrogated by the gcn1D, but not gcn20D, mutation (Figure 4D),
PMID:33534698 PBO:0099987 We found that autophagy after leucine starvation was severely impaired in cells lacking Cpc2 and in those overexpressing a fission yeast ortholog of Yih1/IMPACT (Figure 4—figure supplement 1G), confirming the essential role of the Gcn2 activity in autophagy induction upon amino acid starvation.
PMID:33534698 PBO:0099988 fig 4 a Though much less than that in wild-type cells, autophagy was still detectable in the tsc2D iml1D double mutant, indicating that, in addition to the GATOR1 and TSC complexes, there must be an additional mechanism to attenuate TORC1 upon nitrogen starvation for autophagy induction.
PMID:33534698 PBO:0099988 fig4a
PMID:33534698 FYPO:0001357 Figure 2a
PMID:33534698 FYPO:0001357 Figure 2a
PMID:33534698 FYPO:0001357 Figure 2a
PMID:33534698 FYPO:0001357 Figure 2a
PMID:33534698 FYPO:0001357 Figure 2a
PMID:33534698 FYPO:0001357 Figure 2a
PMID:33534698 FYPO:0001357 Figure 2a
PMID:33534698 FYPO:0001355 Figure 2a
PMID:33534698 FYPO:0001355 Figure 2a
PMID:33534698 PBO:0093560 Figure 2b
PMID:33534698 FYPO:0001357 Figure 2b (any1 reescues)
PMID:33534698 FYPO:0001357 Figure 2b (any1 rescues)
PMID:33534698 FYPO:0001357 Figure 2e (sea3 rescued by gtr1 GDP-locked)
PMID:33534698 PBO:0099989 Figure 2f
PMID:33534698 FYPO:0001357 Figure 2e (sea3 rescued by gtr1 GDP-locked)
PMID:33534698 PBO:0099990 Figure 2g
PMID:33534698 PBO:0099991 On the other hand, Iml1 and Sea3 were co-immunoprecipitated even in the absence of Seh1, Sea2, and Sea4 (Figure 3E), implying that Sea3 directly binds to GATOR1 and anchors the other GATOR2 components to GATOR1.
PMID:33534698 PBO:0099992 The binding of Sea3 to GATOR1 is dependent on the integrity of the GATOR1 complex, and the absence of any one of the GATOR1 subunits disrupted the Sea3–GATOR1 association (Figure 3F,G and H).
PMID:33534698 PBO:0099992 The binding of Sea3 to GATOR1 is dependent on the integrity of the GATOR1 complex, and the absence of any one of the GATOR1 subunits disrupted the Sea3–GATOR1 association (Figure 3F,G and H).
PMID:33534698 PBO:0099992 The binding of Sea3 to GATOR1 is dependent on the integrity of the GATOR1 complex, and the absence of any one of the GATOR1 subunits disrupted the Sea3–GATOR1 association (Figure 3F,G and H).
PMID:33534698 PBO:0099993 Consis- tently, in the absence of intact GATOR1, the vacuolar localization of Sea3 (Figure 1E) was lost and the protein diffused throughout the cytosol (Figure 3I, Figure 3—figure supplement 1A),
PMID:33534698 PBO:0099994 Furthermore, consi tent with the essential role of Sea3 in the interaction between GATOR1 and the other GATOR2 sub- units, the vacuolar localization of Sea2, Sea4, and Seh1 ( was abrogated in the sea3D background (Figure 3—figure supplement 1C–E).
PMID:33534698 PBO:0099995 (Figure 3—figure supplement 1C–E).
PMID:33534698 PBO:0099996 (Figure 3—figure supplement 1C–E).
PMID:33534698 PBO:0099997 In the case of the sea3D mutant, Iml1, Npr2, and Npr3 were all detectable on vacuoles (Figure 3—figure supplement 2E,F and G),
PMID:33534698 PBO:0099998 (Figure 3—figure supplement 2E,F and G),
PMID:33534698 PBO:0099999 (Figure 3—figure supplement 2E,F and G),
PMID:33534698 PBO:0100000 On the other hand, immuno- precipitation of the GATOR1 subunit Iml1 found that the physical interaction between GATOR1 and the Gtr1 GTPase was reduced in the sea3D mutant (Figure 3M).
PMID:33534698 FYPO:0001357 (Figure 3—figure supplement 3A), indicating that Arg854 of S. pombe Iml1 is not essential for the GATOR1 function.
PMID:33534698 PBO:0100001 (DIRECTLY INHIBITS) Recently, another conserved arginine residue in mammalian GATOR1, Arg78 of the Nprl2 subunit,was proposed to serve as an arginine finger that promotes GTP hydrolysis by RagA/B (Shen et al.,2019, Figure 3—figure supplement 3B). To assess the role of the equivalent residue in the S.pombe GATOR1, Arg98 in Npr2 was substituted with alanine to construct an npr2R98A mutantstrain. The mutant cells exhibited a compromised growth phenotype that was rescued by rapamycinor the gtr1SN mutation, an indicative of compromised GAP activity of GATOR1 (Figure 3—figuresupplement 3C). Though the npr2R98A phenotype was not as severe as that of the npr2 nullmutant, these observations are in line with the model that the conserved Arg residue in Npr2, butnot the one in Iml1, acts as an arginine finger of GATOR1 also in fission yeast.
PMID:33534698 PBO:0100002 (DIRECTLY INHIBITS) Recently, another conserved arginine residue in mammalian GATOR1, Arg78 of the Nprl2 subunit,was proposed to serve as an arginine finger that promotes GTP hydrolysis by RagA/B (Shen et al.,2019, Figure 3—figure supplement 3B). To assess the role of the equivalent residue in the S.pombe GATOR1, Arg98 in Npr2 was substituted with alanine to construct an npr2R98A mutantstrain. The mutant cells exhibited a compromised growth phenotype that was rescued by rapamycinor the gtr1SN mutation, an indicative of compromised GAP activity of GATOR1 (Figure 3—figuresupplement 3C). Though the npr2R98A phenotype was not as severe as that of the npr2 nullmutant, these observations are in line with the model that the conserved Arg residue in Npr2, butnot the one in Iml1, acts as an arginine finger of GATOR1 also in fission yeast.
PMID:33534698 PBO:0100003 However, no GFP accumulation was detected in gcn2D cells under leucine starvation (Figure 4C), demonstrating that the autophagy induced by leucine starvation is dependent on the Gcn2 kinase.
PMID:33534698 PBO:0100004 (ARginine starvation) Similarly, in cells of arginine auxotrophy, Gcn2-dependent autophagy was detectable after incubation in the growth medium without arginine (Figure 4—figure supplement 1C).
PMID:33534698 PBO:0100006 5A). In contrast, Psk1 remained phosphorylated even after the starvation in the gcn2D, eIF2a-S52A, and fil1D mutant strains (Figure 5A), suggesting that TORC1 inactivation in leucine-starved cells is medi- ated by the Gcn2-eIF2a-Fil1 pathway.
PMID:33534698 FYPO:0007803 Moreover, the autophagy defect of the gcn2D mutant was complemented by TORC1 inactivation by the TORC1 inhibitors, rapamycin and caffeine (Figure 5B).
PMID:33534698 FYPO:0006295 In the gnc2D iml1D tsc2D triple mutant, a trace of released GFP was detected only after 14 hr of nitrogen starvation (Figure 6C), while autophagy takes place within 2 hr in wild-type cells after the starvation (Figure 4B).
PMID:33534698 GO:0061700 Figure 1
PMID:33534698 PBO:0099983 Indeed, we observed that, after leucine starvation, the Fil1 protein increased, which was dependent on Gcn2 and the phosphorylation of eIF2a (Fig- ure 4—figure supplement 1H).
PMID:33534698 FYPO:0007803 Moreover, S. pombe cells lacking Gcn3 (Figure 4D) or Fil1 (Figure 4F) displayed autophagy defects during leucine starvation.
PMID:33534698 FYPO:0007803 fig 4e In order to test whether the Gcn2 kinase induces autophagy through phosphorylation of eIF2a, we constructed a strain that expresses eIF2a with its phosphorylation site Ser52 substituted by ala- nine (eIF2a-S52A).
PMID:33534698 GO:0061700 Figure 1
PMID:33534698 GO:0061700 Figure 1
PMID:33534698 GO:0061700 Figure 1
PMID:33536395 FYPO:0007800 In contrast, gmn2∆ cells missorted and secreted a significant amount of BiP to the cell surface. These re- sults indicate that Gmn2p is required for normal retention of a luminal ER protein in S. pombe cells.
PMID:33536395 GO:0006890 changed from protein retention in ER lumen
PMID:33536395 PBO:0106841 Fig. 3B
PMID:33536395 FYPO:0007288 Fig. 3C
PMID:33536395 GO:0005794 As expected, Och1-EGFP expressed in the wild type strain showed strong fluorescence as a typical Golgi-like dots, but faint fluorescent dots were confirmed in gmn2∆ cells (Fig. 4A).
PMID:33536395 GO:0000139 The Gmn2-EGFP protein was recycled back into the ER just as Gms1-EGFP, indicating that Gmn2-EGFP localized mostly to the Golgi membranes (Fig. 6B).
PMID:33536395 PBO:0106842 As expected, Och1-EGFP expressed in the wild type strain showed strong fluorescence as a typical Golgi-like dots, but faint fluorescent dots were confirmed in gmn2∆ cells (Fig. 4A).
PMID:33536395 FYPO:0007800 In contrast, gmn2∆ cells missorted and secreted a significant amount of BiP to the cell surface. These re- sults indicate that Gmn2p is required for normal retention of a luminal ER protein in S. pombe cells.
PMID:33536395 PBO:0094648 The gmn2∆ cells were found to be viable despite growing slightly slower than the wild type (Fig. 3A MM (leu-)) and exhibited the same phenotypes as those of the original gmn2 mutant.
PMID:33536395 PBO:0095408 The gmn2∆ cells were highly sen- sitive to hygromycin B, being unable to grow on YES plates containing 25 μg/ml of the drug (Fig. 3A)
PMID:33536434 PBO:0108653 GI Redundancy
PMID:33568651 FYPO:0005031 Polymerase usage sequencing
PMID:33568651 FYPO:0007681 Rnh201-RED mutant, based on the S. cerevsiae equivalent, is unable to remove single rNMPs from DNA but, buy genetic analysis, is able to remove runs of rNMPs.
PMID:33568651 FYPO:0004251 Polymerase usage sequencing
PMID:33568651 FYPO:0007679 Polymerase usage sequencing
PMID:33568651 FYPO:0007254 replication dynamic analysis demonstrates that the priming strand is stable in the absence of Ku (previous work has shown resection is increased behind the arrested fork). Replication restart is slightly delayed, confirming previous work. Assayed by polymerase usage sequencing
PMID:33574613 PBO:0105026 Fig 1 b (me2)
PMID:33574613 FYPO:0001355 We indeed observed that pir1∆ cells exhibited a growth defect on minimal medium
PMID:33574613 PBO:0105038 The addition of ubi4∆, cul4∆ or ddb1∆ dramatically reduced Pir1 ubiquitination in tor2-ts6 mts2-1 cells (Fig. 3f).
PMID:33574613 GO:0080008 which?
PMID:33574613 GO:0080008 which?
PMID:33574613 FYPO:0007226 the deletion of ubi4, ddb1 or cul4 restored ade6-DSR silencing (Fig. 3g and Extended Data Fig. 3d).
PMID:33574613 FYPO:0007226 the deletion of ubi4, ddb1 or cul4 restored ade6-DSR silencing (Fig. 3g and Extended Data Fig. 3d).
PMID:33574613 FYPO:0007226 the deletion of ubi4, ddb1 or cul4 restored ade6-DSR silencing (Fig. 3g and Extended Data Fig. 3d).
PMID:33574613 FYPO:0007212 The restoration of silencing required Pir1, as a loss of Ubi4 failed to silence ade6-DSR in pir1∆ cells (Fig. 3g).
PMID:33574613 FYPO:0007212 The restoration of silencing required Pir1, as a loss of Ubi4 failed to silence ade6-DSR in pir1∆ cells (Fig. 3g).
PMID:33574613 PBO:0105040 Remarkably, the loss of Ubi4, Cul4 or Ddb1 in tor2-ts6 cells restored the silencing of gametogenic genes genome-wide (Fig. 3h and Extended Data Fig. 3g).
PMID:33574613 PBO:0105041 Remarkably, the loss of Ubi4, Cul4 or Ddb1 in tor2-ts6 cells restored the silencing of gametogenic genes genome-wide (Fig. 3h and Extended Data Fig. 3g).
PMID:33574613 PBO:0105042 Remarkably, the loss of Ubi4, Cul4 or Ddb1 in tor2-ts6 cells restored the silencing of gametogenic genes genome-wide (Fig. 3h and Extended Data Fig. 3g). and Fig. 4g).
PMID:33574613 PBO:0105043 Remarkably, the loss of Ubi4, Cul4 or Ddb1 in tor2-ts6 cells restored the silencing of gametogenic genes genome-wide (Fig. 3h and Extended Data Fig. 3g). and Fig. 4g).
PMID:33574613 PBO:0105040 Remarkably, the loss of Ubi4, Cul4 or Ddb1 in tor2-ts6 cells restored the silencing of gametogenic genes genome-wide (Fig. 3h and Extended Data Fig. 3g).
PMID:33574613 FYPO:0003066 abnormal asci containing fewer than four, or no, spores were frequently generated (Fig. 7c).
PMID:33574613 FYPO:0000581 Defective chromosome segregation and reduced spore viability were also noted (Fig. 7a and Supplementary Videos 1–3)
PMID:33574613 FYPO:0004159 Defective chromosome segregation and reduced spore viability were also noted (Fig. 7a and Supplementary Videos 1–3)
PMID:33574613 FYPO:0004966 cells showed impaired oscillation of chromosomes and a prolonged horsetail stage (approximately 160min compared with approximately 120min; Fig. 7a,b).
PMID:33574613 PBO:0105051 Compared with the WT, cells expressing Pir1-SD showed a marked decrease in recombination frequency (Fig. 6f).
PMID:33574613 PBO:0105050 Compared with the WT, cells expressing Pir1-SD showed a marked decrease in recombination frequency (Fig. 6f).
PMID:33574613 PBO:0105049 Compared with the WT, cells expressing Pir1-SD showed a marked decrease in recombination frequency (Fig. 6f).
PMID:33574613 PBO:0105048 Figure 6B DSBs; for example, rec25, rec27 and mug20), which are critical for recombination and proper chromosome segregation during meiosis-I4
PMID:33574613 PBO:0105047 Figure 6B DSBs; for example, rec25, rec27 and mug20), which are critical for recombination and proper chromosome segregation during meiosis-I4
PMID:33574613 PBO:0105046 Figure 6B DSBs; for example, rec25, rec27 and mug20), which are critical for recombination and proper chromosome segregation during meiosis-I4
PMID:33574613 PBO:0105045 restores the MTREC and Rrp6 association with Mmi1 and Erh1 during meiosis (Fig. 5d).
PMID:33574613 PBO:0105044 restores the MTREC and Rrp6 association with Mmi1 and Erh1 during meiosis (Fig. 5d).
PMID:33574613 FYPO:0007686 Whereas Pir1-WT disappeared, Pir1-SD per- sisted during meiosis as multiple nuclear foci coinciding with Mmi1 and Erh1 foci (Fig. 5b,c).
PMID:33574613 PBO:0105041 Remarkably, the loss of Ubi4, Cul4 or Ddb1 in tor2-ts6 cells restored the silencing of gametogenic genes genome-wide (Fig. 3h and Extended Data Fig. 3g).
PMID:33574613 FYPO:0007685 Intriguingly, cells expressing Pir1-SD, but not Pir1-WT or Pir1-SA, continued to divide on nutrient-limiting medium at a low temperature (Fig. 4a), suggesting that stabilized Pir1 supports cell proliferation under suboptimal growth conditions.
PMID:33574613 FYPO:0001357 We indeed observed that pir1∆ cells exhibited a growth defect on minimal medium
PMID:33574613 PBO:0093560 Similar to pir1∆, tor2-ts6 cells showed a severe growth defect at a semi-permissive temperature (29°C) on minimal medium but not on rich medium (Fig. 4d).
PMID:33574613 FYPO:0001357 Similar to pir1∆, tor2-ts6 cells showed a severe growth defect at a semi-permissive temperature (29°C) on minimal medium but not on rich medium (Fig. 4d).
PMID:33574613 PBO:0092302 Notably, Pir1 was depleted during early meiosis (Fig. 5a) but gradually recov- ered by middle meiosis.
PMID:33574613 PBO:0105025 Fig 1 b (me2)
PMID:33574613 PBO:0105027 Fig 1 b (1.5x) (me2)
PMID:33574613 FYPO:0003235 Extended data Fig 1 b c (also at MTREC independent islands)
PMID:33574613 PBO:0105028 figure 1c
PMID:33574613 PBO:0105029 figure 1e
PMID:33574613 PBO:0105030 Fig 1 a
PMID:33574613 PBO:0105031 Fig 1 a
PMID:33574613 PBO:0105032 Fig. 1f,g
PMID:33574613 MOD:01148 figure 1h
PMID:33574613 PBO:0105033 Moreover, ubiquitination of Pir1 was detected in tor2-ts6 cells and increased in the tor2-ts6 mts2-1 mutant (Fig. 1h)
PMID:33574613 PBO:0105030 Fig 1 a
PMID:33574613 PBO:0105031 Fig 1 a
PMID:33574613 PBO:0110910 he Tor2-containing TORC1 complex phosphorylated Pir1 in vitro and mutation of the 12 serine residues to alanine attenu- ated Pir1 phosphorylation (Extended Data Fig. 2a,c).
PMID:33574613 FYPO:0002033 Extended Data Fig. 2a,c
PMID:33574613 PBO:0105032 Replacement of the 12 phospho-serine residues with the phospho-mimic aspartic acid residue (Pir1-12SD) indeed conferred stability in tor2-ts6 cells (Extended Data Fig. 2d)
PMID:33574613 PBO:0105032 Replacement of the 12 phospho-serine residues with the phospho-mimic aspartic acid residue (Pir1-12SD) indeed conferred stability in tor2-ts6 cells (Extended Data Fig. 2d); Deletion of ubi4 in tor2-ts6 cells cells indeed stabilized Pir1 (Fig. 3b)
PMID:33574613 PBO:0105038 Consistently, ubiquitination of Pir1-SD in the tor2-ts6 mts2-1 mutant was reduced (Fig. 2e).
PMID:33574613 PBO:0095162 Interestingly, the expression of Pir1-SD in tor2-ts6 cells restored the levels of Red1 (Extended Data Fig. 2e), suggesting that the reduction in Red1 in the tor2 mutant cells (Fig. 1c) is linked to the degradation of its interaction part- ner Pir1
PMID:33574613 PBO:0105039 ubi4 gene, which encodes polyubiquitin implicated in sexual development34, was upregulate in tor2-ts6 cells (Fig. 3a).
PMID:33574613 PBO:0105032 Moreover, loss of the ubiquitin ligase-associated Cullin-RING finger family protein Cul4, a component of ClrC35,36 that interacts with MTREC15, also stabilized Pir1 in both tor2-ts6 and nitrogen-starved cells (Fig. 3c
PMID:33574613 PBO:0105032 Moreover, loss of the ubiquitin ligase-associated Cullin-RING finger family protein Cul4, a component of ClrC35,36 that interacts with MTREC15, also stabilized Pir1 in both tor2-ts6 and nitrogen-starved cells (Fig. 3c
PMID:33574613 PBO:0105038 The addition of ubi4∆, cul4∆ or ddb1∆ dramatically reduced Pir1 ubiquitination in tor2-ts6 mts2-1 cells (Fig. 3f).
PMID:33574613 PBO:0105038 The addition of ubi4∆, cul4∆ or ddb1∆ dramatically reduced Pir1 ubiquitination in tor2-ts6 mts2-1 cells (Fig. 3f).
PMID:33579781 PBO:0096575 Fig. 4A
PMID:33579781 PBO:0094773 Fig. 4A
PMID:33579781 PBO:0096583 Fig. 4A
PMID:33579781 PBO:0096582 Fig. 4A
PMID:33579781 PBO:0096581 Fig. 4A
PMID:33579781 PBO:0096580 Fig. 4A
PMID:33579781 PBO:0096580 Fig. 4A
PMID:33579781 FYPO:0000080 Fig. 2
PMID:33579781 FYPO:0000080 Fig. 2 However, S. pombe is viable when Pro3 or Pro6 is changed to alanine in every other heptad, includ- ing the rump, in the context of the full-length CTD (Fig. 2), signifying that reduced proline content is tolerated and that Pro3 and Pro6 need not be present in consecutive heptads
PMID:33579781 PBO:0096585 Fig. 4A
PMID:33579781 FYPO:0001355 Fig. 5A
PMID:33579781 PBO:0096576 Fig. 4A
PMID:33579781 PBO:0094738 Fig. 5B
PMID:33579781 PBO:0094738 Fig. 5B
PMID:33579781 PBO:0094771 Fig. 5B
PMID:33579781 PBO:0094771 Fig. 5B
PMID:33579781 PBO:0094771 Fig. 5B
PMID:33579781 PBO:0094771 Fig. 5B
PMID:33579781 PBO:0094771 Fig. 5B
PMID:33579781 PBO:0094771 Fig. 5B
PMID:33579781 PBO:0096584 Fig. 4A
PMID:33579781 PBO:0096579 Fig. 4A
PMID:33579781 PBO:0096578 Fig. 4A
PMID:33579781 PBO:0094771 Fig. 5B
PMID:33579781 PBO:0094771 Fig. 5B
PMID:33579781 PBO:0094771 Fig. 5B
PMID:33579781 PBO:0094771 Fig. 5B
PMID:33579781 FYPO:0002141 Fig. 2 However, S. pombe is viable when Pro3 or Pro6 is changed to alanine in every other heptad, includ- ing the rump, in the context of the full-length CTD (Fig. 2), signifying that reduced proline content is tolerated and that Pro3 and Pro6 need not be present in consecutive heptads
PMID:33579781 GO:0006369 Need to add modified version
PMID:33579781 PBO:0096577 Fig. 4A
PMID:33579781 PBO:0096576 Fig. 4A
PMID:33658433 PBO:0103648 vw:added nucleosome assembly
PMID:33670267 FYPO:0007722 ATPase assay
PMID:33670267 FYPO:0004227 TAP co-purification, Western blot for histone H3
PMID:33670267 FYPO:0004227 TAP co-purification, Western blot for histone H3
PMID:33670267 FYPO:0004227 TAP co-purification, Western blot for histone H3
PMID:33670267 FYPO:0007722 ATPase assay
PMID:33670267 FYPO:0007722 ATPase assay
PMID:33670267 FYPO:0004227 TAP co-purification, Western blot for histone H3
PMID:33670267 FYPO:0007722 ATPase assay
PMID:33683349 PBO:0037130 fig3
PMID:33683349 FYPO:0000400 QUESTION ig 5b (I only curated the red line temp inc at tome zero, becase it would be difficult to specify at 60 mins, I could not think of a way to do this). I'm assuming these cells do not enter mitosis, is that correct
PMID:33683349 PBO:0019154 fig 6a
PMID:33683349 PBO:0094949 figure 4
PMID:33683349 FYPO:0000082 High temp - 30 degrees. (VW I changed this from a cell phenotype term to a population phenotype term) fig1 We interpret this suppression to indicate that the lethal mitoses, which occur in the smallest cells, require Cig2/CDK activity instead of, or in addi- tion to, Cdc13/CDK activity.
PMID:33683349 PBO:0107206 "fig1 &2 Nick suggested ""mitotic catastrophe""We would make this a related synonym?"
PMID:33683349 PBO:0094645 fig3
PMID:33683349 PBO:0094949 fig 5a
PMID:33683349 FYPO:0002060 figure 6b
PMID:33683349 PBO:0098712 figure 4
PMID:33683349 FYPO:0002516 fig 5
PMID:33683349 PBO:0095165 fig2 (30 degrees) wee1-50ts mik1D cells divide at a smaller size than wee1-50ts mik1D cig2D cells
PMID:33683349 PBO:0019208 fig3 (i.e wee?)
PMID:33683349 PBO:0037130 fig3
PMID:33711009 FYPO:0005369 20°
PMID:33711009 PBO:0102977 Neither the N-terminal segment from aa 1–496 nor the C-terminal fragment from 578–710 was able to bind to Dis2 or Swd22 in the 2-hybrid format (Fig 11A)
PMID:33711009 FYPO:0005369 20°
PMID:33711009 FYPO:0005369 20°
PMID:33711009 FYPO:0005369 20°
PMID:33711009 FYPO:0005369 20°
PMID:33711009 PBO:0102976 Neither the N-terminal segment from aa 1–496 nor the C-terminal fragment from 578–710 was able to bind to Dis2 or Swd22 in the 2-hybrid format (Fig 11A)
PMID:33723569 PBO:0093629 32ºC
PMID:33723569 FYPO:0000268 32ºC
PMID:33723569 FYPO:0000089 32ºC
PMID:33723569 FYPO:0004709 live-cell imaging, 25ºC
PMID:33723569 FYPO:0004516 live-cell imaging, 25ºC
PMID:33723569 FYPO:0004466 live-cell imaging, 25ºC
PMID:33723569 FYPO:0002573 live-cell imaging, 25ºC
PMID:33723569 FYPO:0007328 live-cell imaging, 25ºC
PMID:33723569 FYPO:0000972 live-cell imaging, 25ºC
PMID:33723569 FYPO:0002573 live-cell imaging, 25ºC
PMID:33723569 FYPO:0006686 live-cell imaging, 25ºC
PMID:33723569 FYPO:0003503 25ºC, live-cell imaging, cell length at septation
PMID:33723569 FYPO:0003503 25ºC, live-cell imaging, cell length at septation
PMID:33723569 FYPO:0003906 25ºC
PMID:33723569 FYPO:0000972 live-cell imaging, 25ºC
PMID:33723569 FYPO:0002573 live-cell imaging, 25ºC
PMID:33723569 FYPO:0002601 25ºC
PMID:33723569 PBO:0093585 25ºC
PMID:33723569 FYPO:0006686 live-cell imaging, 25ºC
PMID:33723569 FYPO:0000085 32ºC
PMID:33723569 FYPO:0000089 32ºC
PMID:33723569 FYPO:0000088 32ºC
PMID:33723569 FYPO:0000268 32ºC
PMID:33723569 FYPO:0001355 32ºC
PMID:33723569 PBO:0093616 32ºC
PMID:33723569 PBO:0093773 25ºC
PMID:33723569 FYPO:0004516 live-cell imaging, 25ºC
PMID:33723569 FYPO:0004516 live-cell imaging, 25ºC
PMID:33723569 FYPO:0004516 live-cell imaging, 25ºC
PMID:33723569 FYPO:0004516 live-cell imaging, 25ºC
PMID:33723569 FYPO:0007328 live-cell imaging, 25ºC
PMID:33723569 FYPO:0007328 live-cell imaging, 25ºC
PMID:33723569 FYPO:0007328 live-cell imaging, 25ºC
PMID:33723569 FYPO:0002573 live-cell imaging, 25ºC
PMID:33723569 FYPO:0002573 live-cell imaging, 25ºC
PMID:33723569 FYPO:0007710 live-cell imaging, 25ºC
PMID:33723569 FYPO:0007711 live-cell imaging, 25ºC
PMID:33723569 FYPO:0007711 live-cell imaging, 25ºC
PMID:33723569 FYPO:0007710 live-cell imaging, 25ºC
PMID:33723569 FYPO:0007710 live-cell imaging, 25ºC
PMID:33723569 FYPO:0007710 live-cell imaging, 25ºC
PMID:33723569 FYPO:0007710 live-cell imaging, 25ºC
PMID:33723569 FYPO:0007711 live-cell imaging, 25ºC
PMID:33723569 PBO:0093585 25ºC
PMID:33723569 PBO:0093585 25ºC
PMID:33723569 PBO:0093585 25ºC
PMID:33723569 FYPO:0006686 live-cell imaging, 25ºC
PMID:33723569 FYPO:0006686 live-cell imaging, 25ºC
PMID:33723569 PBO:0093585 25ºC
PMID:33723569 FYPO:0002553 25ºC
PMID:33723569 FYPO:0006687 live-cell imaging, 25ºC
PMID:33754639 FYPO:0002061 temperature sensitive 37°
PMID:33771877 PBO:0099489 fig 3 At exg1, ecm33, eng1 et gas1, condensin is redistributed throughout the gene body instead of accumulating around transcription termination sites.
PMID:33771877 PBO:0099488 fig 3 At exg1, ecm33, eng1 et gas1, condensin is redistributed throughout the gene body instead of accumulating around transcription termination sites.
PMID:33771877 PBO:0099486 fig 3 At exg1, ecm33, eng1 et gas1, condensin is redistributed throughout the gene body instead of accumulating around transcription termination sites.
PMID:33771877 PBO:0099487 fig 3 At exg1, ecm33, eng1 et gas1, condensin is redistributed throughout the gene body instead of accumulating around transcription termination sites.
PMID:33771877 PBO:0099491 Fig 2b
PMID:33771877 PBO:0099490 fig 2b Importantly, the accumulation of condensin in sen1Δ cells could not be caused by an accumulation of either TFIIIC or Tbp1 because their levels on chromatin remained largely unaffected in the absence of Sen1, as shown by ChIP with a GFP-tagged version of Tbp1 and a myc-tagged version of the TFIIIC component Sfc6 (Figs 2B and S1).
PMID:33771877 PBO:0099498 fig3.
PMID:33771877 PBO:0099497 fig3.
PMID:33771877 PBO:0099496 fig3.
PMID:33771877 PBO:0099495 fig3.
PMID:33771877 PBO:0099494 fig 1
PMID:33771877 FYPO:0007738 fig 1
PMID:33771877 PBO:0099493 Fig 2
PMID:33771877 PBO:0099492 Fig 2
PMID:33775921 FYPO:0001355 highest overexpression level
PMID:33788833 PBO:0095509 The mutant protein is observed at the vacuolar surface
PMID:33788833 PBO:0095503 Affecting Cps1 carboxypeptidase
PMID:33788833 PBO:0095504 Affecting Vps10, Vps27, Vps35, Pep12 and the PI(3)P probe Cherry-FYVE
PMID:33788833 GO:0034058 In the null mutant and the mutant without SNARE domain the fluorescence of prevacuolar endosome markers is reduced, and Cps1 processing is abnormal
PMID:33788833 GO:0031902 co-localization with Vps35 and with Vps27
PMID:33788833 GO:0005802 co-localization with Cfr1
PMID:33788833 PBO:0095501 80 mM MgCl2
PMID:33788833 PBO:0093594 1.0 M KCl
PMID:33788833 PBO:0095512 The mutant protein is observed at the vacuolar surface
PMID:33788833 PBO:0095511 same as vps35delta alone
PMID:33788833 PBO:0095511 same as vps35delta alone
PMID:33788833 PBO:0095510 The mutant protein is observed faintly at the vacuolar surface of a low percentage of cells
PMID:33788833 PBO:0095502 Affecting Cps1 carboxypeptidase
PMID:33788833 PBO:0095509 The mutant protein is observed at the vacuolar surface
PMID:33788833 PBO:0095504 Affecting Vps10 and the PI(3) probe Cherry-FYVE
PMID:33788833 PBO:0095507 Affecting Vps10, Vps27, Vps35, Pep12 and the PI(3)P probe Cherry-FYVE
PMID:33788833 PBO:0095506 Affecting Vps10, Vps27, Vps35, Pep12 and the PI(3)P probe Cherry-FYVE
PMID:33788833 PBO:0095513 The mutant protein is observed faintly at the vacuolar surface of a low percentage of cells
PMID:33788833 PBO:0095509 The mutant protein is observed at the vacuolar surface
PMID:33788833 PBO:0095509 The mutant protein is observed at the vacuolar surface
PMID:33788833 PBO:0095509 The mutant protein is observed at the vacuolar surface
PMID:33788833 PBO:0095530 Affecting Cps1 carboxypeptidase
PMID:33788833 PBO:0095529 Affecting Cps1 carboxypeptidase
PMID:33788833 PBO:0095503 Affecting Cps1 carboxypeptidase
PMID:33788833 PBO:0095526 Affecting Cps1 carboxypeptidase
PMID:33788833 PBO:0095520 same as fsv1delta alone
PMID:33788833 PBO:0095505 Affecting Vps10, Vps27, Vps35, Pep12 and the PI(3)P probe Cherry-FYVE
PMID:33788833 PBO:0095513 The mutant protein is observed faintly at the vacuolar surface of a low percentage of cells
PMID:33788833 PBO:0095512 The mutant protein is observed at the vacuolar surface
PMID:33788833 PBO:0095512 The mutant protein is observed at the vacuolar surface
PMID:33788833 PBO:0095512 The mutant protein is observed at the vacuolar surface
PMID:33788833 PBO:0095512 The mutant protein is observed at the vacuolar surface
PMID:33788833 PBO:0095512 The mutant protein is observed at the vacuolar surface
PMID:33788833 PBO:0095512 The mutant protein is observed at the vacuolar surface
PMID:33788833 PBO:0095512 The mutant protein is observed at the vacuolar surface
PMID:33788833 PBO:0095512 The mutant protein is observed at the vacuolar surface
PMID:33788833 PBO:0095510 The mutant protein is observed faintly at the vacuolar surface of a low percentage of cells
PMID:33788833 PBO:0095509 The mutant protein is observed at the vacuolar surface
PMID:33788833 PBO:0095509 The mutant protein is observed at the vacuolar surface
PMID:33788833 PBO:0095509 The mutant protein is observed at the vacuolar surface
PMID:33823663 PBO:0104295 figure 9 modified form is activated for sexual differentiation
PMID:33823663 PBO:0104294 figure9
PMID:33823663 FYPO:0007963 DNS
PMID:33823663 FYPO:0007963 DNS
PMID:33825974 FYPO:0004602 Figure s2 (c); live cell imaging with 3D structured illumination microscopy (3D-SIM)
PMID:33825974 FYPO:0005914 live cell imaging with 3D structured illumination microscopy (3D-SIM)
PMID:33825974 FYPO:0004665 live cell imaging with 3D structured illumination microscopy (3D-SIM)
PMID:33825974 FYPO:0004665 live cell imaging with 3D structured illumination microscopy (3D-SIM)
PMID:33825974 FYPO:0004665 live cell imaging with 3D structured illumination microscopy (3D-SIM)
PMID:33825974 FYPO:0004665 live cell imaging with 3D structured illumination microscopy (3D-SIM)
PMID:33825974 PBO:0104155 Figure 4d, 4e; Figure s3b; live cell imaging with 3D structured illumination microscopy (3D-SIM)
PMID:33836577 PBO:0093613 figure 3C
PMID:33836577 PBO:0093613 figure 3B
PMID:33836577 PBO:0019133 figure 3D
PMID:33836577 PBO:0019133 figure 3D
PMID:33836577 PBO:0019133 figure 3D
PMID:33836577 PBO:0093613 figure 3C
PMID:33836577 PBO:0093613 figure 3C
PMID:33836577 PBO:0093613 figure 3B
PMID:33836577 PBO:0093613 figure 3B
PMID:33836577 PBO:0093613 figure 3B
PMID:33836577 PBO:0100203 figure 1
PMID:33836577 PBO:0100204 figure 1
PMID:33836577 PBO:0100205 figure 1
PMID:33836577 PBO:0100202 figure 2D
PMID:33836577 PBO:0100206 figure 2D
PMID:33836577 PBO:0100206 figure 2E
PMID:33836577 PBO:0100206 figure 2E
PMID:33836577 PBO:0093613 figure 3B
PMID:33836577 GO:1990238 figure 2
PMID:33836577 GO:0005515 figure 2 requires phosphorylated T89, T154, T155 to bind Nbs1 FHA domain
PMID:33836577 PBO:0100201 figure 2
PMID:33836577 PBO:0019133 figure 3D
PMID:33836577 PBO:0100202 We therefore introduced a synthetic CT15 peptide into an endonuclease assay containing the MR complex, but lacking Nbs1 (Fig. 4A). Strikingly, the CT15 peptide stimulated the endonuclease activity of MR similarly to the unphosphorylated, full-length Ctp1 (Fig. 4B). Moreover, stimulation of MR at higher concentrations of the CT15 peptide (100 μM) was comparable to the maximal levels achieved with the MRN complex and phosphorylated full-length Ctp1 (Ctp1p in Fig. 4C).
PMID:33836577 PBO:0019133 figure 3D
PMID:33836577 PBO:0019133 figure 3D
PMID:33836577 PBO:0093613 figure 3C
PMID:33836577 PBO:0093613 figure 3C
PMID:33888556 PBO:0107033 figure 4 (no rescue by sgo3)
PMID:33888556 FYPO:0006424 Figure 1C
PMID:33888556 PBO:0109714 Figure 1B/C
PMID:33888556 PBO:0107029 Figure (we modelled this increased duration of cohesion in mitotic anaphase, and the ectopic rec8 expression is now part of the genotype,does that sound OK?)
PMID:33888556 PBO:0107030 Figure 2A cohesion protection defect
PMID:33888556 PBO:0107031 Figure 2D
PMID:33888556 FYPO:0007760 Figure 3AB vw repurposed this as it was essentially the same as the other annotation to this genotype (suggesting that Rec8-2A was properly expressed but not protected at centromeres during anaphase I.)
PMID:33888556 FYPO:0007759 Figure 3
PMID:33888556 PBO:0107033 figure 4
PMID:33888556 FYPO:0002219 Figure 3BC Strikingly, the phenotype of rec8-2E was completely suppressed by sgo1Δ indicating that Rec8-2E was protected by Sgo1 not only at centromeres but also along the chromosome arm.
PMID:33888556 FYPO:0005633 Figure 1C
PMID:33888556 FYPO:0006425 Figure 1C
PMID:33888556 FYPO:0006425 Figure 1C
PMID:33888556 PBO:0109715 Figure 1C
PMID:33888556 PBO:0109716 Figure 1C
PMID:33888556 PBO:0109331 refer to model in figure 4. Therefore, consistent with the genetic analyses, this biochemical analysis supports the notion that phosphorylation at Rec8-S450 and the adjacent site plays a role in promoting the PP2A-dependent removal of CK1-dependent phosphorylation of Rec8 (Fig. 4B).
PMID:33888556 FYPO:0006426 Figure 2A
PMID:33888556 FYPO:0002219 Figure 2F
PMID:33888556 FYPO:0002061 Figure 3D. phosphomimetic rec8
PMID:33888556 FYPO:0002060 Figure 3D.
PMID:33888556 FYPO:0002060 Figure 3D.
PMID:33888556 FYPO:0002061 Figure 3D. phosphomimetic rec8
PMID:33888556 PBO:0109332 To further examine this possibility, we reconstituted Rec8 dephosphorylation in vitro using immunoprecipitated Par1-containing PP2A complexes.
PMID:33888556 PBO:0109333 To further examine this possibility, we reconstituted Rec8 dephosphorylation in vitro using immunoprecipitated Par1-containing PP2A complexes.
PMID:33888556 PBO:0107039 figure 4
PMID:33909078 PBO:0105746 alpha-1,3-galactosylation of O-linked glycan
PMID:33909078 PBO:0097089 alpha-1,2-galactosylation of N-linked glycan
PMID:33909078 PBO:0097092 alpha-1,2-galactosylation of O-linked glycan
PMID:33909078 PBO:0105746 alpha-1,3-galactosylation of O-linked glycan
PMID:33909078 PBO:0105746 alpha-1,3-galactosylation of O-linked glycan
PMID:33909078 PBO:0097092 alpha-1,2-galactosylation of O-linked glycan
PMID:33909078 PBO:0097089 alpha-1,2-galactosylation of N-linked glycan
PMID:33909078 PBO:0097089 alpha-1,2-galactosylation of N-linked glycan
PMID:33925026 FYPO:0000903 same as alp14delta alone
PMID:33925026 FYPO:0005681 same as alp14delta alone
PMID:33925026 FYPO:0005682 same as alp14delta alone
PMID:33925026 FYPO:0005682 same as klp6delta alone
PMID:33925026 FYPO:0005681 same as klp6delta alone
PMID:33925026 PBO:0097255 Assays were done in the MDR-sup (multi-drug resistance-suppressed) genetic background together with nda3-TB101
PMID:33925026 FYPO:0001355 same as alp14delta alone
PMID:33925026 PBO:0097257 reduced frequency of microtubule rescue
PMID:33925026 FYPO:0005703 same as alp14delta alone
PMID:33925026 PBO:0097256 reduced frequency of microtubule catastrophe
PMID:33946513 PBO:0097109 Figure 4a
PMID:33946513 FYPO:0002626 Figure 6. We found that the dri1∆ cells acquired tolerance to high temperature, as they could form colonies at 39 ◦C, whereas wild-type cells could not (Figure 6C).
PMID:33946513 FYPO:0002060 fig 1c dri1 supresses cut7
PMID:33946513 FYPO:0002060 fig1a
PMID:33946513 FYPO:0002060 fig1
PMID:33946513 PBO:0107001 Figure 2A,B
PMID:33946513 PBO:0107002 Klp2 levels on spindle microtubules were significantly lower than those in cut7-22 (which are increased compared to WT)
PMID:33946513 PBO:0107004 Figure 2D
PMID:33946513 PBO:0107005 SHOULD THIS BE NORMAL? However, the Mal3 protein levels did not change in the presence or absence of Dri1 (Supplementary Figure S3A). Similarly, the levels of Mal3-GFP on the spindle MTs were almost the same both in wild-type and dri1∆ cells (Supplementary Figure S3B).
PMID:33946513 PBO:0107006 fig S4a
PMID:33946513 PBO:0107007 to pac
PMID:33946513 PBO:0107008 to pac
PMID:33946513 PBO:0018470 Figure 3A
PMID:33946513 PBO:0023225 Figure 3A
PMID:33946513 GO:0005634 Figure 3A
PMID:33946513 PBO:0107002 Klp2 levels on spindle microtubules were significantly lower than those in cut7-22 (which are increased compared to WT)
PMID:33946513 PBO:0107008 to pac
PMID:33946513 PBO:0107007 to pac
PMID:33946513 PBO:0107001 Figure 2A,B
PMID:33946513 PBO:0107004 Figure 2D
PMID:33970532 FYPO:0007792 only amino acid auxotrophic cell
PMID:33970532 PBO:0094358 only amino acid auxotrophic cell
PMID:33970532 FYPO:0007792 only amino acid auxotrophic cell
PMID:33970532 FYPO:0007791 The control strain ED668 expressed ecl1+ when Mg2+ was depleted but not in a strain lacking fil1+ (Figure 2a)
PMID:33970532 PBO:0094360 to capture target of ecl1
PMID:34010645 FYPO:0007597 Figure 2.
PMID:34010645 FYPO:0007597 Figure 2.
PMID:34010645 PBO:0095076 H3K9me3 levels at pericentric dh repeats and dh RNA levels in hht3-K9MK14R cells are similar to those in wild-type cells, comparing with hht3-K9M.
PMID:34010645 FYPO:0007597 Figure 2
PMID:34019809 GO:0000822 structure, fig2
PMID:34019809 FYPO:0007841 fix catalytic activity
PMID:34019809 FYPO:0007841 fix catalytic activity
PMID:34028542 PBO:0092254 fig 5
PMID:34028542 FYPO:0003743 Proliferation defect of gad8ts aly2 mutant in low glucose was similar to that of gad8ts mutant.
PMID:34028542 FYPO:0003743 Proliferation defect of gad8ts aly1 mutant in low glucose was similar to that of gad8ts mutant.
PMID:34028542 PBO:0099304 Fig1 aly3 rescues
PMID:34028542 PBO:0099303 Cytoplasmic Ght5-GFP was observed within the vacuolar membrane stained with FM4-64.
PMID:34028542 PBO:0099302 top panel, Fig. 6A; Fig. S3B,C).
PMID:34028542 PBO:0092077 After cultivation in low glucose MM for 10 h, medium was replaced with low-glucose nitrogen-starved MM, and cells were further cultivated for 4 h.
PMID:34028542 PBO:0099307 fig6
PMID:34028542 PBO:0099309 although not shown directly , genetic interactions are consistent with this activity
PMID:34028542 PBO:0099307 fig6
PMID:34028542 PBO:0099308 fig6 (phenocopies WT)
PMID:34028542 FYPO:0000047 Proliferation defect of gad8ts mutant in low glucose was restored by SPCC584.15c deletion.
PMID:34028542 FYPO:0003743 Proliferation defect of gad8ts rod1 mutant in low glucose was similar to that of gad8ts mutant.
PMID:34080538 FYPO:0007304 Fig. 4
PMID:34080538 FYPO:0005706 Fig. 4
PMID:34080538 FYPO:0005343 Fig. 4
PMID:34080538 PBO:0097991 Fig. 5 -Phosph form (From other publications, we know bona-fide that the localisation observed here is the kinetochore, but here they study how it changes)
PMID:34080538 PBO:0109503 Fig. 5 - Dephosph form
PMID:34080538 PBO:0109502 Fig. 5 - Dephosph form
PMID:34080538 PBO:0109501 Fig. 4
PMID:34080538 PBO:0109500 Fig. 4
PMID:34080538 PBO:0022963 Fig. 4
PMID:34080538 FYPO:0007304 Fig. 4
PMID:34080538 FYPO:0007304 Fig. 4
PMID:34080538 FYPO:0005706 Fig. 4
PMID:34080538 FYPO:0005343 Fig. 4
PMID:34080538 PBO:0109499 Fig. 4
PMID:34080538 FYPO:0005706 Fig. 4
PMID:34080538 FYPO:0005343 Fig. 4
PMID:34080538 PBO:0109507 Fig. 5
PMID:34080538 PBO:0109507 Fig. 5
PMID:34080538 PBO:0109507 Fig. 5
PMID:34080538 PBO:0109507 Fig. 5
PMID:34080538 PBO:0109508 Fig. 5 supp 3
PMID:34080538 PBO:0109507 Fig. 5 supp 3
PMID:34080538 PBO:0109504 Fig. 4
PMID:34086083 GO:0005634 YES, YES (low-glucose)
PMID:34086083 GO:0005737 YES, YES (low-glucose)
PMID:34086083 PBO:0108842 ALERTED FROM A LATER PAPER Rst2 regulates the expression of ste11, which encodes a transcription factor to regulate sexual development (Sugimoto et al. 1991); fbp1, which encodes fructose-1,6-bisphosphatase (Hoffman and Winston 1990); and mug14, which encodes an adducin homolog (Inamura et al. 2021).
PMID:34133210 FYPO:0005543 Constriction took longer in pxl1(9A)
PMID:34133210 FYPO:0001368 Although there was a small difference in CR formation between pxl1(9A) (13.6 +/- 2.5; 33 cells) and pxl1(9D) (12.2 +/- 2.3 min; 41 cells), formation was similar in pxl1(9D) and pxl1+ (12.4 +/- 3.0; 32 cells), and there were no significant differences in the durations of CR maturation.
PMID:34133210 PBO:0092467 fig1
PMID:34133210 FYPO:0007829 Figure 4, A and B
PMID:34133210 PBO:0106246 although not IDA, there is experimental data to support this inference
PMID:34133210 PBO:0106244 Cdk1 phosphorylation of Pxl1 reduced binding to the F-BAR domain of Cdc15 (Figure 5A), but not to Cdc15C (Figure 5B).
PMID:34133210 FYPO:0007828 Although there was a small difference in CR formation between pxl1(9A) (13.6 +/- 2.5; 33 cells) and pxl1(9D) (12.2 +/- 2.3 min; 41 cells), formation was similar in pxl1(9D) and pxl1+ (12.4 +/- 3.0; 32 cells), and there were no significant differences in the durations of CR maturation.
PMID:34147496 GO:0006799 inferred from polyphosphate absent from cell
PMID:34147496 PBO:0112697 These results imply that: (1) Pho84 is multiply ubiquitinated; (2) ubiquitination of Pho84 depends mainly on Pqr1.
PMID:34169534 PBO:0107986 also assayed using Pil1 co-tethering with microscopy
PMID:34169534 PBO:0107987 also assayed using Pil1 co-tethering with microscopy
PMID:34209806 MOD:00047 i added as good to have multiple support.
PMID:34209806 PBO:0100508 The interactions of the Nrl1(NRDE-2) and the Nrl1(C-term) domain constructs with Mtl1 were significantly lower
PMID:34209806 PBO:0100507 We observed similar intensities of interaction of the Nrl1(N-term) and the Nrl1(N-term + NRDE-2) constructs with Mtl1 (1511.2 � 89.4 or 1558.2 � 159.3 Miller units for the N-terminal region and the N-terminus with NRDE2 domain and Mtl1, respectively),
PMID:34209806 PBO:0100507 We observed similar intensities of interaction of the Nrl1(N-term) and the Nrl1(N-term + NRDE-2) constructs with Mtl1 (1511.2 � 89.4 or 1558.2 � 159.3 Miller units for the N-terminal region and the N-terminus with NRDE2 domain and Mtl1, respectively),
PMID:34209806 GO:0005681 Need to curate ref42 for earlier part of this story, but this can be. inferred here from the interactions
PMID:34228709 PBO:0095859 hypermutator
PMID:34228709 FYPO:0003923 DNA combing
PMID:34228709 FYPO:0005032 equivalent substitution to cdc20-P287R
PMID:34228709 FYPO:0000173 Cds1 is partially phosphorylated
PMID:34228709 FYPO:0001707 Chk1 is partially phosphorylated
PMID:34250083 FYPO:0001309 Phenotype determined with robotics-based CFU assay.
PMID:34250083 FYPO:0001309 Phenotype determined with robotics-based CFU assay.
PMID:34250083 FYPO:0000245 Phenotype determined with robotics-based CFU assay.
PMID:34250083 FYPO:0000245 Phenotype determined with robotics-based CFU assay.
PMID:34250083 FYPO:0000245 Phenotype determined with robotics-based CFU assay.
PMID:34250083 FYPO:0000245 Phenotype determined with robotics-based CFU assay.
PMID:34250083 FYPO:0001309 Phenotype determined with robotics-based CFU assay.
PMID:3428262 FYPO:0003095 mitotic G2/M transition delay
PMID:34292936 PBO:0096842 worse than rad51delta alone
PMID:34292936 PBO:0096842 worse than rad51delta alone
PMID:34296454 FYPO:0007877 This result indicates that the immediate decrease in protein synthesis rates upon TOR inhibition is not dependent upon the S6Ks or their downstream targets.
PMID:34296454 PBO:0104158 Please refer to Fig. 5E&F from paper for partial inhibition protein synthesis phenotype
PMID:34296454 GO:2000767 hese observations are consistent with the idea that the essential TORC1 is the major complex responsi- ble for the rapid inhibition of protein synthesis and that changes in phosphorylation levels relevant to regulating protein synthesis should be detectable within 20 min and significant by 40 min of TOR inhibition.
PMID:34296454 PBO:0104159 For the Torin1-resistant mutant, the phosphorylation levels remained constant throughout the time course
PMID:34296454 PBO:0104159 For the Torin1-resistant mutant, the phosphorylation levels remained constant throughout the time course
PMID:34309513 GO:0140588 in vitro (Figure 4A, Video 1).
PMID:34309513 GO:0140588 in vitro (Figure 4A, Video 1).
PMID:34309513 GO:0140588 in vitro (Figure 4A, Video 1).
PMID:34309513 GO:0140588 in vitro (Figure 4A, Video 1).
PMID:34309513 GO:0140588 in vitro (Figure 4A, Video 1).
PMID:34309513 GO:0140588 in vitro (Figure 4A, Video 1).
PMID:34346498 FYPO:0007864 Figure 5 To confirm this, we evaluatedthe behaviour of bqt1Δ sad1.2 alp4-GFP cells harbouring the SPBmarkers Sid4–mCherry and Sad1.2–mCherry, effectively showingthat Alp4–GFP molecules located far from the nucleus wereassociated with the SPBs (Fig. 5C,D)
PMID:34346498 PBO:0099607 Figure 1
PMID:34346498 PBO:0099608 Figure 1 (see above)
PMID:34346498 PBO:0099609 Figure 1 (see above)
PMID:34346498 PBO:0099610 Figure 2E
PMID:34346498 PBO:0099611 Figure 2E
PMID:34346498 FYPO:0007852 Figure 3
PMID:34346498 PBO:0099612 figure7 maximum length of self-assembled spindles increased upon deletion of klp6 (from 7.9±3.8 μm to 12.9±4.7 μm; Fig. 7E).
PMID:34346498 PBO:0099613 Figure 5 To confirm this, we evaluatedthe behaviour of bqt1Δ sad1.2 alp4-GFP cells harbouring the SPBmarkers Sid4–mCherry and Sad1.2–mCherry, effectively showingthat Alp4–GFP molecules located far from the nucleus wereassociated with the SPBs (Fig. 5C,D)
PMID:34346498 FYPO:0007849 Figure 2F
PMID:34346498 PBO:0099614 figure 7C
PMID:34346498 PBO:0099616 figure 7C
PMID:34346498 PBO:0022389 Figure 2
PMID:34346498 PBO:0099592 late spindle elongation (move down /when GO reflect stages of meiotic spindle elongation)
PMID:34346498 PBO:0099601 decreased abnormal SPB-independent meiosis II
PMID:34346498 PBO:0099600 figure7 C
PMID:34346498 PBO:0099599 figure7 maximum length of self-assembled spindles increased upon deletion of klp6 (from 7.9±3.8 μm to 12.9±4.7 μm; Fig. 7E).
PMID:34346498 FYPO:0007849 analysis of bqt1Δ sad1.2 dis1Δ meiocytes showed that the percentage of selfassembled spindles with normal formation and function was similar to that in the bqt1Δ sad1.2 setting (Fig. 6F,H).
PMID:34346498 PBO:0099598 Figure 6 Remarkably, we found that, in the case of bqt1Δ sad1.2 alp14-26 meiocytes, despite clear dysfunction of alp14-26, self-assembled spindles were still able to form and behaved normally (Fig. 6C,D). However, they formed in a smaller percentage of meiocytes (from ∼80% to ∼30%, Fig. 6F), indicating that the contribution of Alp14 to self-assembled spindle formation and behaviour is substantial.
PMID:34346498 FYPO:0007846 Figure 2F
PMID:34346498 PBO:0099596 Figure 7
PMID:34346498 FYPO:0007755 Figure 2F
PMID:34346498 PBO:0099595 Figure 7
PMID:34346498 FYPO:0003614 Figure 6B
PMID:34346498 PBO:0099602 Figure 3A
PMID:34352089 PBO:0104079 Pac1 strain (Pac1-AA) that allowed rapid rapamycin-dependent nuclear exclusion of Pac1 (Figure 1B).
PMID:34352089 PBO:0104069 Figure 3A and Supplementary Fig- ure S5A
PMID:34352089 PBO:0104069 Figure 3A and Supplementary Fig- ure S5A
PMID:34352089 PBO:0104071 figure 1c
PMID:34352089 PBO:0104072 5' extended precursors, C/C box (but not H/ACA box). Pac1 nuclear exclusion specifically led to the accumulation of 5′-extended precursors of Pac1-bound C/D box snoRNAs (Supplementary Figure S3A). This ac- cumulation was confirmed by Northern blot assays on three C/D box snoRNAs (sno16, snoU14 and snr79), whereas a control H/ACA box snoRNA (sno12) was unaffected
PMID:34352089 PBO:0104073 5' extended precursors, C/C box (but not H/ACA box)
PMID:34352089 PBO:0104074 5' extended precursors, C/C box (but not H/ACA box)
PMID:34352089 FYPO:0007883 we observed a sharp decline in RNAPII occupancy inside the gene body, directly downstream of the Pac1- bound region located in the first half of the genes (Fig- ure 2B, blue profile). In contrast, Pac1 nuclear exclusion resulted in extended RNAPII occupancy throughout the entire ORFs (Figure 2B, red profile). Such differences in RNAPII profiles are suggestive of Pac1-dependent prema- ture termination.
PMID:34352089 GO:0000956 waiting for GO:NEW.inferred from association with prremature termination sites
PMID:34352089 PBO:0104076 we observed a sharp decline in RNAPII occupancy inside the gene body, directly downstream of the Pac1- bound region located in the first half of the genes (Fig- ure 2B, blue profile). In contrast, Pac1 nuclear exclusion resulted in extended RNAPII occupancy throughout the entire ORFs (Figure 2B, red profile). Such differences in RNAPII profiles are suggestive of Pac1-dependent prema- ture termination.
PMID:34352089 GO:0000956 waiting for GO:NEW. We show this for only two mRNA: mfs2 and SPBC530.02. Can this be added in the annotation extension ?
PMID:34352089 GO:0030847 NEW TERM REQUESTED CHILD OF BOTH termination of RNA polymerase II transcription, poly(A)-independent We showed pac1-dependent poly(A)-independent RNA polymerase II termination for 2 mRNA genes (mfs2 and SPBC530.02), 4 snRNA genes (snU1, snU2, snU4 and snU5), and 2 snoRNA genes (snU3 and snU32) . Can this be added in the annotation extension ?
PMID:34352089 PBO:0104078 MOVE DOWN
PMID:34352089 PBO:0104077 MOVE DOWN
PMID:34352089 PBO:0093558 Supplementary Figure S5B
PMID:34382912 MOD:00046 fig 5
PMID:34382912 MOD:00046 fig 5
PMID:34382912 PBO:0103459 fig4
PMID:34382912 PBO:0103458 fig4
PMID:34382912 MOD:00046 fig 5
PMID:34382912 PBO:0103460 fig4
PMID:34382912 PBO:0103457 figure 2
PMID:34382912 MOD:00046 fig 5
PMID:34382912 MOD:00046 fig 5
PMID:34382912 MOD:00046 fig 5
PMID:34382996 FYPO:0007876 Interestingly, the reduction in local secretion correlates with a strong loss of the wPM phenotype (Fig. 6, A and B; Fig. S4, E and F; and Fig. S5): only 4% of h+ fus1Δ cells (1/27) showed wPM, whereas 73% (16/22) and 20% (4/20) of h+ WT showed wPM in WT × WT and WT × fus1Δ crosses, respectively
PMID:34382996 FYPO:0004804 no assembly of vesicles by electron microscopy (Because cell fu- sion completely fails when both partner cells lack fus1)
PMID:34382996 FYPO:0000413 Only when gpd1∆ is in h- cell
PMID:34382996 FYPO:0007874 Fig. 6, A–C The density of vesicles was strongly reduced in the fus1Δ cells, whether this was h+ or h−, while WT h+ cells showed slightly higher vesicle density than h− cells, as in previous analysis ()
PMID:34382996 FYPO:0000413 Stronger phenotype in h+ than h- cell
PMID:34382996 PBO:0108245 Fig. 6 E and Fig. S4 D. By LM, Myo52 and Exo84 also showed strong signal reduction in fus1Δ .
PMID:34382996 GO:1990819 figure5
PMID:34382996 GO:1990819 figure5
PMID:34382996 PBO:0108248 Fig. 6, A–C The density of vesicles was strongly reduced in the fus1Δ cells, whether this was h+ or h−, while WT h+ cells showed slightly higher vesicle density than h− cells, as in previous analysis ()
PMID:34389684 FYPO:0000080 Figue 1C
PMID:34389684 PBO:0094777 similar to wt
PMID:34389684 PBO:0099765 this can be inferred from the experiments
PMID:34389684 FYPO:0002061 Random spore analysis
PMID:34389684 FYPO:0002061 The seb1-G476S and aps1Δ alleles were synthetically lethal;
PMID:34389684 PBO:0099764 Here, we found that tgp1 promoter–driven acid phosphatase expression was increased 30-fold in seb1-G476S cells versus seb1-WT cells and that this derepression was effaced by mutating the promoter-proximal nc- tgp1 PAS (Fig. 4D).
PMID:34389684 PBO:0099763 (Fig. 4B), Pho1 expression from the wild-type plasmid was increased sevenfold in seb1-G476S cells versus seb1-WT cells thereby echoing the derepressive effect of seb1-G476S on pho1 expression from the chromosomal prt–pho1 locus.
PMID:34389684 FYPO:0001357 ..... while rhn1Δ rescued the cs growth defect of seb1-G476S at 20 °C
PMID:34389684 FYPO:0002060 Figue 3A Notable findings were that seb1-G476S rescued the ts growth defect of rhn1Δ at 37 °C......
PMID:34389684 FYPO:0002061 Random spore analysis
PMID:34389684 FYPO:0002061 Random spore analysis
PMID:34389684 FYPO:0002061 Random spore analysis
PMID:34389684 FYPO:0002061 Random spore analysis
PMID:34389684 FYPO:0002061 Random spore analysis
PMID:34389684 FYPO:0001355 Figure 1c
PMID:34389684 PBO:0099762 NorthernBlotting
PMID:34389684 PBO:0099761 RNA-seq poly(A) tail reads. (Figs. 3–5 collectively fortify the case for seb1-G476S as a gain-of-function mutation in Seb1 that elicits precocious lncRNA termination dependent on lncRNA PAS and cleavage/polyadenylation factors.)
PMID:34389684 PBO:0099760 RNA-seq poly(A) tail reads. (Figs. 3–5 collectively fortify the case for seb1-G476S as a gain-of-function mutation in Seb1 that elicits precocious lncRNA termination dependent on lncRNA PAS and cleavage/polyadenylation factors.)
PMID:34389684 PBO:0099759 RNA-seq poly(A) tail reads. (Figs. 3–5 collectively fortify the case for seb1-G476S as a gain-of-function mutation in Seb1 that elicits precocious lncRNA termination dependent on lncRNA PAS and cleavage/polyadenylation factors.)
PMID:34389684 PBO:0099758 RNA-seq poly(A) tail reads. (Figs. 3–5 collectively fortify the case for seb1-G476S as a gain-of-function mutation in Seb1 that elicits precocious lncRNA termination dependent on lncRNA PAS and cleavage/polyadenylation factors.)
PMID:34389684 PBO:0099757 RNA-seq poly(A) tail reads. (Figs. 3–5 collectively fortify the case for seb1-G476S as a gain-of-function mutation in Seb1 that elicits precocious lncRNA termination dependent on lncRNA PAS and cleavage/polyadenylation factors.)
PMID:34389684 PBO:0099756 RNA-seq poly(A) tail reads. (Figs. 3–5 collectively fortify the case for seb1-G476S as a gain-of-function mutation in Seb1 that elicits precocious lncRNA termination dependent on lncRNA PAS and cleavage/polyadenylation factors.)
PMID:34389684 PBO:0099755 RNA-seq poly(A) tail reads. (Figs. 3–5 collectively fortify the case for seb1-G476S as a gain-of-function mutation in Seb1 that elicits precocious lncRNA termination dependent on lncRNA PAS and cleavage/polyadenylation factors.)
PMID:34389684 PBO:0099754 RNA-seq poly(A) tail reads. (Figs. 3–5 collectively fortify the case for seb1-G476S as a gain-of-function mutation in Seb1 that elicits precocious lncRNA termination dependent on lncRNA PAS and cleavage/polyadenylation factors.)
PMID:34389684 PBO:0099753 RNA-seq poly(A) tail reads. (Figs. 3–5 collectively fortify the case for seb1-G476S as a gain-of-function mutation in Seb1 that elicits precocious lncRNA termination dependent on lncRNA PAS and cleavage/polyadenylation factors.)
PMID:34389684 PBO:0099752 RNA-seq poly(A) tail reads. (Figs. 3–5 collectively fortify the case for seb1-G476S as a gain-of-function mutation in Seb1 that elicits precocious lncRNA termination dependent on lncRNA PAS and cleavage/polyadenylation factors.)
PMID:34389684 PBO:0099751 RNA-seq poly(A) tail reads. (Figs. 3–5 collectively fortify the case for seb1-G476S as a gain-of-function mutation in Seb1 that elicits precocious lncRNA termination dependent on lncRNA PAS and cleavage/polyadenylation factors.)
PMID:34389684 PBO:0093554 Fig 7A
PMID:34389684 PBO:0093554 Fig 7A
PMID:34389684 FYPO:0000080 Fig 7a
PMID:34389684 PBO:0094771 Fig 7 compared to WT
PMID:34389684 PBO:0099750 Although seb1- G476S asp1-H397A cells grew slowly in liquid medium at 30 °C, an assay of acid phosphatase showed that the double mutant expressed threefold higher levels of Pho1 than the seb1-G476S single mutant (Fig. 6B). (NOTE ABOUT 20 FOLD HIGHE TTHAN WT)
PMID:34389684 FYPO:0002061 Random spore analysis
PMID:34389684 PBO:0094738 compared to WT
PMID:34389684 PBO:0099750 compared to WT
PMID:34389684 PBO:0099749 compared to WT
PMID:34389684 PBO:0099749 Fig 7 compared to WT
PMID:34389684 FYPO:0001489 Random spore analysis (DNS)
PMID:34389684 PBO:0099748 Figure 1A
PMID:34389684 FYPO:0001489 Random spore analysis (DNS)
PMID:34389684 FYPO:0001489 Random spore analysis (DNS)
PMID:34389684 PBO:0099749 Figure 1A (vw changed to increased with low serverity as we compare to WT)
PMID:34402513 FYPO:0007828 Figure 4
PMID:34402513 FYPO:0001368 Figure 4
PMID:34402513 FYPO:0002253 Figure S3B-C
PMID:34402513 FYPO:0001903 Figure S2C
PMID:34402513 PBO:0099825 Figure 1A-C
PMID:34402513 PBO:0099826 Figure 1A-C
PMID:34402513 FYPO:0005289 Figure S3A Interestingly, we noticed during imaging that imp2-17A rlc1-mNG sid4-mNG cells displayed CR sliding events where the CR formed in the middle of the cell but then slid towards one cell tip (6/18 cells) (Fig. S3A).
PMID:34402513 PBO:0099827 Figure 1A-C
PMID:34402513 PBO:0099828 Figure 1A-C
PMID:34402513 PBO:0099812 Figure 1A-C
PMID:34402513 PBO:0099829 Figure 1A-C
PMID:34402513 PBO:0099830 Figure 1A-C
PMID:34402513 PBO:0099831 Figure 1A-C
PMID:34402513 PBO:0099832 Figure 1A-C
PMID:34402513 PBO:0099814 Figure S2F
PMID:34402513 PBO:0099813 Figure S2D-E
PMID:34402513 PBO:0099812 Figure 2G
PMID:34402513 FYPO:0004097 Figure 4A-B
PMID:34402513 FYPO:0007828 Figure 4A-B
PMID:34402513 FYPO:0000316 Figure S4B
PMID:34402513 PBO:0099811 Figure S2D-E
PMID:34402513 FYPO:0001903 Figure S2A and C
PMID:34402513 FYPO:0000339 Figure S3B-C
PMID:34402513 PBO:0099833 Figure 1A-C
PMID:34402513 PBO:0099837 Figure 1A-C
PMID:34402513 PBO:0099841 Imp2 was phosphorylated by Hhp1 in vitro, and mutation of the 15 identified and two more CK1 consensus sites eliminated this phosphorylation (Fig. 2B)
PMID:34402513 PBO:0099840 Together these findings implicate Cdk1 in modulating the timing of Imp2 localization to the CR, and are consistent with the general theme of Cdk1 inhibiting cytokinesis until chromosome segregation is complete
PMID:34402513 FYPO:0001971 Figure S2A-B
PMID:34402513 FYPO:0002062 Figure S4A
PMID:34402513 FYPO:0002062 Figure S4A
PMID:34402513 FYPO:0002062 Figure S4A
PMID:34402513 FYPO:0004085 Figure S4A
PMID:34402513 FYPO:0004085 Figure S4B
PMID:34402513 FYPO:0001368 Figure 4A-B
PMID:34402513 FYPO:0001971 Figure S2A-B there was no detectable defect in morphology or cell division in imp2-11A, imp2-11E, imp2-17E, imp2-28A or imp2-28E cells although some imp2-17A cells failed to separate, forming chains (Fig. S2A and B).
PMID:34402513 FYPO:0001760 Figure S2A-B
PMID:34402513 FYPO:0000316 Figure S4B
PMID:34402513 PBO:0099821 Figure 2E
PMID:34402513 PBO:0099820 Figure 3
PMID:34402513 FYPO:0004097 Figure 4
PMID:34402513 FYPO:0007828 Figure 4
PMID:34402513 FYPO:0001368 Figure 4
PMID:34402513 FYPO:0002253 Figure S3B-C
PMID:34402513 FYPO:0001903 Figure S2A and C
PMID:34402513 PBO:0099818 Figure S2D and F
PMID:34402513 PBO:0099813 Figure S2D-E
PMID:34402513 PBO:0099836 Figure 1A-C
PMID:34402513 PBO:0099838 vw added extensions to link MF to BP & phase
PMID:34402513 PBO:0109289 This phenotype suggests that phosphorylation of the 17 CK1 consensus sites in Imp2 promotes the medial anchoring of the CR on the membrane, possibly by stabilizing an unknown interaction involving the Imp2 IDR.
PMID:34402513 PBO:0099835 Figure 1A-C
PMID:34402513 PBO:0099834 Figure 1A-C
PMID:34402513 FYPO:0001760 Figure S2A-B
PMID:34402513 FYPO:0001760 Figure S2A-B
PMID:34402513 FYPO:0001760 Figure S2A-B
PMID:34402513 FYPO:0001903 Figure S2A and C
PMID:34402513 FYPO:0001903 Figure S2A and C
PMID:34402513 FYPO:0001760 Figure S2A-B
PMID:34402513 FYPO:0001252 Figure S2A-C
PMID:34402513 FYPO:0002253 Figure S3B-C
PMID:34402513 PBO:0099819 Figure S2D-E
PMID:34402513 PBO:0099818 Figure S2D and F
PMID:34402513 FYPO:0001903 Figure SA and C
PMID:34402513 PBO:0099817 Figure 3. Imp2-11A-mNG was recruited to the CR earlier (ca. 4 minutes) than Imp2-mNG (Fig. 3A, B, and C).
PMID:34402513 FYPO:0004097 Figure 4
PMID:34402513 FYPO:0007828 Figure 4
PMID:34402513 FYPO:0001368 Figure 4
PMID:34402513 PBO:0099816 Figure 2F
PMID:34402513 PBO:0099822 Figure 1A-C
PMID:34402513 PBO:0099823 Figure 1A-C
PMID:34402513 PBO:0099824 Figure 1A-C
PMID:34402513 PBO:0099816 Figure 2D
PMID:34402513 PBO:0099816 Figure 2G, H
PMID:34402513 PBO:0099816 Figure 2G However, mutation of 3 additional Cdk1 consensus sites abolished Imp2 phosphorylation by Cdk1 (Imp2-11A, Fig. 2C).
PMID:34402513 PBO:0099815 Figure 3. Imp2-11E-mNG was not recruited to the CR later than Imp2-mNG but its peak accumulation was delayed compared to wildtype (Fig. 3A, B, and C)
PMID:34402513 FYPO:0001365 Figure 4. However, imp2-17E cells exhibited slower CR constriction. In fact, CR remnants remained in 62% of imp2-17E cells for the duration of our observation.
PMID:34460892 PBO:0103878 Evidence was from RNA-seq data
PMID:34460892 PBO:0103878 Evidence was from RNA-seq not from microarray
PMID:34460892 PBO:0103879 Evidence code was RNA-seq
PMID:34460892 PBO:0103880 Evidence from RNA-seq data
PMID:34460892 PBO:0092337 Evidence from RNA-seq data
PMID:34460892 PBO:0103880 Evidence was from RNA-seq data
PMID:34460892 PBO:0103878 Evidence was from RNA-seq data
PMID:34460892 PBO:0103878 Evidence was from RNA-seq data
PMID:34460892 PBO:0092337 Evidence was from RNA-seq data
PMID:34460892 PBO:0103878 Evidence was from RNA-seq data
PMID:34460892 PBO:0103878 Evidence was from RNA-seq data
PMID:34460892 PBO:0103878 Evidence was from RNA-seq data
PMID:34460892 PBO:0103878 Evidence was from RNA-seq data
PMID:34460892 PBO:0103878 Evidence was from RNA-seq data
PMID:34460892 PBO:0103878 Evidence was from RNA-seq data
PMID:34460892 PBO:0103880 Evidence was from RNA-seq data
PMID:34460892 PBO:0103878 Evidence was from RNA-seq data
PMID:34460892 PBO:0103880 Evidence was from RNA-seq data
PMID:34460892 PBO:0103878 Evidence was from RNA-seq data
PMID:34460892 PBO:0103878 Evidence was from RNA-seq data
PMID:34460892 PBO:0103878 Evidence was from RNA-seq data
PMID:34460892 PBO:0103880 Evidence was from RNA-seq data
PMID:34460892 PBO:0092140 Evidence was from RNA-seq data
PMID:34460892 PBO:0103880 Evidence was from RNA-seq data
PMID:34460892 PBO:0103878 Evidence was from RNA-seq data
PMID:34460892 PBO:0103880 Evidence was from RNA-seq data
PMID:34460892 PBO:0103880 Evidence was from RNA-seq data
PMID:34460892 PBO:0092337 Evidence was from RNA-seq data
PMID:34460892 PBO:0103880 Evidence was from RNA-seq data
PMID:34460892 PBO:0103880 Evidence was from RNA-seq data
PMID:34460892 PBO:0103878 Evidence form RNA-seq data
PMID:34460892 PBO:0103880 Evidence form RNA-seq data
PMID:34460892 PBO:0103878 Evidence form RNA-seq data
PMID:34460892 PBO:0103878 Evidence form RNA-seq data
PMID:34460892 PBO:0103878 Evidence form RNA-seq data
PMID:34460892 PBO:0103880 Evidence form RNA-seq data
PMID:34460892 PBO:0092337 Evidence form RNA-seq data
PMID:34460892 PBO:0103880 Evidence form RNA-seq data
PMID:34460892 PBO:0103878 Evidence form RNA-seq data
PMID:34460892 PBO:0103878 Evidence form RNA-seq data
PMID:34460892 PBO:0092337 Evidence form RNA-seq data
PMID:34460892 PBO:0103880 Evidence form RNA-seq data
PMID:34460892 PBO:0103880 Evidence from RNA-seq data
PMID:34460892 PBO:0103878 Evidence from RNA-seq data
PMID:34460892 PBO:0103880 Evidence from RNA-seq data
PMID:34460892 PBO:0103880 Evidence from RNA-seq data
PMID:34460892 PBO:0103880 Evidence from RNA-seq data
PMID:34460892 PBO:0103880 Evidence from RNA-seq data
PMID:34460892 PBO:0103880 Evidence from RNA-seq data
PMID:34460892 PBO:0103878 Evidence from RNA-seq data
PMID:34460892 PBO:0103880 Evidence from RNA-seq data
PMID:34460892 PBO:0103880 Evidence from RNA-seq data
PMID:34460892 PBO:0092337 Evidence from RNA-seq data
PMID:34460892 PBO:0103880 Evidence from RNA-seq data
PMID:34460892 PBO:0103878 Evidence from RNA-seq data
PMID:34460892 PBO:0103880 Evidence from RNA-seq data
PMID:34460892 PBO:0103878 Evidence from RNA-seq data
PMID:34460892 PBO:0103880 Evidence from RNA-seq data
PMID:34464389 FYPO:0007936 Figure S7B The proportion of junctions down- stream of tlh2 was higher in the tlh2 overexpression strain compared to wild-type
PMID:34464389 PBO:0106084 during stationary phase. Figure 6C In fact, the protein levels of Scw1 markedly decreased in ageing cells.
PMID:34464389 PBO:0110916 Figure 4B Accordingly, our smFISH experiment showed that tlh2 was de-repressed in sir2 deletion cells
PMID:34464389 PBO:0103668 Figure 5A Cells lacking Sir2 showed a subtle extension of chronological lifespan compared to wild-type, especially at later timepoints
PMID:34464389 FYPO:0007937 Based on DNA breakpoint junctions in genome sequence data (Fig 5B While wild-type cells showed a substantial increase of indels in aged cells, sir2Δ cells showed only a subtle increase
PMID:34464389 FYPO:0000245 Figure S7C Moreover, the tlh2 overexpression strain was substantially shorter-lived than wild-type cells
PMID:34464389 FYPO:0007936 5B Notably, in aged cells the double mutant showed an ~3-fold increase in chro- mosomal junctions on average, albeit with large variation, but no increase in indels
PMID:34464389 FYPO:0001309 Fig 5A Given the increased lifespan of rnh1Δ rnh201Δ cells
PMID:34464389 PBO:0105656 S7A Fig A re-analysis of RNA-seq data from non-dividing cells [68] revealed a subtle increase in tlh2 expression during chronological ageing
PMID:3448096 FYPO:0000998 cells are longer that wt under N starvation conditions, but not necessarily longer than a wt cell is when not starved for N
PMID:3448096 FYPO:0000998 cells are longer that wt under N starvation conditions, but not necessarily longer than a wt cell is when not starved for N
PMID:3448096 FYPO:0000998 cells are longer that wt under N starvation conditions, but not necessarily longer than a wt cell is when not starved for N
PMID:3448096 FYPO:0000998 cells are longer that wt under N starvation conditions, but not necessarily longer than a wt cell is when not starved for N
PMID:3448096 FYPO:0000998 cells are longer that wt under N starvation conditions, but not necessarily longer than a wt cell is when not starved for N
PMID:3448096 FYPO:0000998 cells are longer that wt under N starvation conditions, but not necessarily longer than a wt cell is when not starved for N
PMID:3448096 FYPO:0000998 cells are longer that wt under N starvation conditions, but not necessarily longer than a wt cell is when not starved for N
PMID:3448096 FYPO:0000998 cells are longer that wt under N starvation conditions, but not necessarily longer than a wt cell is when not starved for N
PMID:34499159 PBO:0105139 Figure 5E
PMID:34499159 PBO:0105136 Figure 5D These observations indicate that the mip1 mutation does not affect the TORC1-dependent phosphorylation of Sck1, Sck2 and Maf1.
PMID:34499159 PBO:0105135 Figure 4B
PMID:34499159 PBO:0105132 Figure 4c
PMID:34499159 PBO:0105131 Figure 3d
PMID:34499159 PBO:0105145 Thus, in addition to Psk1, Atg13 also appears to be phosphorylated by TORC1 in a manner dependent on Mip1 Tyr-533, a residue critical for the TOS motif-mediated recruitment of TORC1 substrates.
PMID:34499159 PBO:0105143 Figure 1
PMID:34499159 FYPO:0002672 Figure 5A
PMID:34499159 FYPO:0000111 Figure 3c
PMID:34499159 PBO:0105133 Figure 4B
PMID:34499159 FYPO:0001147 Figure S2B
PMID:34499159 PBO:0105133 Figure 4b
PMID:34499159 FYPO:0000111 Figure 3c
PMID:34499159 FYPO:0001357 Figure 3C
PMID:34499159 FYPO:0002672 Figure 5A
PMID:34499159 PBO:0105141 Figure 2
PMID:34499159 PBO:0105140 Figure 2
PMID:34499159 PBO:0105131 Figure 2
PMID:34524082 PBO:0111592 Figure 3F /fig1
PMID:34524082 FYPO:0007334 Fig. 4A
PMID:34524082 PBO:0095976 VW REQUESTED ABOLISHED Fig. 4E Both H3K9me2 and H3K9me3 were completely abolished in clr4-GS253 and clr4-3FA strains at centromeric dg/dh repeats, being indistinguishable from clr4Δ
PMID:34524082 PBO:0095977 Fig. 4D (Currently, we cannot explain why the dg transcripts in the 3FA mutant are only slightly elevated while completely losing H3K9me2/3.)
PMID:34524082 PBO:0095978 Fig. 4D
PMID:34524082 PBO:0095979 Fig. 4D
PMID:34524082 FYPO:0007334 Fig. 4A
PMID:34524082 PBO:0095976 Fig. 4E REQUESTED ABOLISHED
PMID:34524082 PBO:0095980 Fig. 4D
PMID:34524082 PBO:0095982 Fig. 4D
PMID:34524082 PBO:0095983 Fig. 4E
PMID:34524082 PBO:0095983 Fig. 4E
PMID:34524082 PBO:0095984 Fig. 4E
PMID:34524082 PBO:0095984 Fig. 4E
PMID:34524082 PBO:0111588 hht-ub14 substrate which both manifest a similar degree of strong stimulation by H3K14ub (Figure 1C, Figure 1—figure supplement 1E–H).
PMID:34524082 PBO:0111591 Figure 3F / fig1 These experiments confirm the observation by Oya et al., 2019 that the H3K14ub substrate triggers a dramatic and specific increase in the methyltransferase activity of Clr4. However, in contrast to the previous study, we observe that the KMT domain is sufficient to mediate this regulatory mechanism.
PMID:34524082 PBO:0111593 Figure 3F /fig1
PMID:34524082 PBO:0111594 consistent with Clr4’s KMT domain mediating the crosstalk between H3K14ub and H3K9me2/3 as an essential step in heterochromatin formation and maintenance.
PMID:34524082 PBO:0095981 Fig. 4D
PMID:34580178 PBO:0093559 figure 1B
PMID:34580178 PBO:0093559 figure 1B
PMID:34580178 PBO:0093559 figure 1B
PMID:34580178 PBO:0093559 figure 1B
PMID:34580178 PBO:0093559 figure 1B
PMID:34580178 PBO:0093559 figure 1B
PMID:34580178 PBO:0093560 figure 1B
PMID:34580178 PBO:0093559 figure 1B
PMID:34580178 PBO:0093559 figure 1B
PMID:34580178 PBO:0093559 figure 1B
PMID:34580178 PBO:0093559 figure 1B
PMID:34580178 PBO:0093559 figure 1B
PMID:34580178 PBO:0093559 figure 1B
PMID:34580178 PBO:0093559 figure 1B
PMID:34580178 PBO:0093559 figure 1B
PMID:34580178 PBO:0093559 figure 1B
PMID:34580178 PBO:0093559 figure 1B
PMID:34580178 PBO:0093559 figure 1B
PMID:34580178 PBO:0093559 figure 1B
PMID:34580178 PBO:0093559 figure 1B
PMID:34580178 PBO:0093559 figure 1B
PMID:34580178 PBO:0093559 figure 1B
PMID:34580178 PBO:0093559 figure 1B
PMID:34608864 PBO:0105479 presence or absence of MMS
PMID:34608864 PBO:0105485 presence or absence of HU
PMID:34608864 PBO:0105486 presence or absence of HU
PMID:34608864 FYPO:0004240 presence or absence of MMS
PMID:34608864 FYPO:0004240 presence or absence of MMS
PMID:34608864 PBO:0105485 presence or absence of HU
PMID:34608864 PBO:0105486 presence or absence of HU
PMID:34608864 MOD:01148 in presence or absence of MMS
PMID:34613787 FYPO:0004854 (Fig. 3C) The number of Cdc12-3GFP molecules in the contractile rings of adf1-M3 mutant cells was on average about twice that of wild-type cells and much more variable
PMID:34613787 FYPO:0004854 (Fig. 3A-B and Table 2). Contractile rings of adf1-M3 mutant cells that were able to constrict had twice as many myosin molecules as the wild-type cells, translating to one myosin motor domain for every 70 nm of filament
PMID:34613787 FYPO:0004854 (Fig. 3A-B and Table 2). Contractile rings of adf1-M3 mutant cells that were able to constrict had twice as many myosin molecules as the wild-type cells, translating to one myosin motor domain for every 70 nm of filament
PMID:34613787 PBO:0098928 Figure 2B
PMID:34613787 FYPO:0003014 Second, the normalized disassembly rate, which took the number of actin molecules in the ring into consideration, was 40% lower in the mutant than wild-type cells.
PMID:34613787 PBO:0098929 In contrast, these myosins persisted at nearly their highest levels for an hour and the time course of the process was much more variable in the adf1-M3 mutant cells (Fig. 4C and D). In a few cofilin mutant cells, the myosins dwelled at the cell division site for more than 10 minutes after the completion of the ring constriction (Fig. 5A).
PMID:34613787 PBO:0098931 Mutations of either type II myosin gene in the myo2-E1 or myp2Δ strains reduced the numbers of actin molecules in contractile rings by more than half compared with wild-type cells at the end of 10 the maturation period and the onset of constriction (Fig. 6A-B and Table 1).
PMID:34613787 FYPO:0002699 Mutations of either type II myosin gene in the myo2-E1 or myp2Δ strains reduced the numbers of actin molecules in contractile rings by more than half compared with wild-type cells at the end of 10 the maturation period and the onset of constriction (Fig. 6A-B and Table 1).
PMID:34613787 FYPO:0001365 WHY ISNNT THIS PART. OF ????FYPO:0000230 abnormal actomyosin contractile ring actin filament organization
PMID:34613787 FYPO:0001365 WHY ISNNT THIS PART. OF ????FYPO:0000230 abnormal actomyosin contractile ring actin filament organization
PMID:34613787 GO:1903475 We conclude that type II myosins contribute to both the assembly and disassembly of actin filaments in contractile rings.
PMID:34613787 GO:1903475 We conclude that type II myosins contribute to both the assembly and disassembly of actin filaments in contractile rings.
PMID:34613787 GO:1902404 We conclude that type II myosins contribute to both the assembly and disassembly of actin filaments in contractile rings.
PMID:34613787 GO:1902404 We conclude that type II myosins contribute to both the assembly and disassembly of actin filaments in contractile rings.
PMID:34613787 PBO:0098926 Figure 2B
PMID:34613787 FYPO:0007898 In prior work the mutant cells appeared to assemble normal contractile rings, but our quantitative measurements revealed that the cdc12-4A mutation reduced by about half both the rate of accumulation and the peak numbers of polymerized actin in the ring (Fig. 2E and Table 1).
PMID:34613787 PBO:0098927 Contractile rings of adf1-M3 mutant cells accumulated actin twice as fast over a similar period of time as wild-type cells (Table 2).
PMID:34613787 FYPO:0004854 Therefore, mature rings of the mutant had on average about 1.9 times as much actin as wild-type cells
PMID:34666001 PBO:0101579 figure 5
PMID:34666001 FYPO:0008012 (vw: 25% cell death)
PMID:34666001 FYPO:0008012 In microchannels, where clusters form at high frequency, due to larger and more frequent compressive mechanical stresses onto the CWs, the survival behavior was markedly different. First, wsc1D cells exhibited a much higher yield of death of $28%. Second, all alleles exhibited a high yield of death around $25% including wsc1DWSC
PMID:34666001 PBO:0101579 figure 5
PMID:34666001 PBO:0101579 figure 5
PMID:34666001 FYPO:0008003 figure 5
PMID:34666001 PBO:0101579 figure 5
PMID:34666001 PBO:0101579 figure 5
PMID:34666001 PBO:0101581 increased lateral diffusion in membrane. Finally, Wsc1DWSC-GFP and Wsc1DSTR-GFP, which are incapable of clustering, exhibited much smaller half-times—closer to that of mCherry-Psy1 (Figures 6A, 6B, and S6A).
PMID:34666001 PBO:0101582 n these videos, we did not detect any lysis in WT red cells, but a high incidence of dying wsc1DCC-GFP of $26%
PMID:34666001 PBO:0101579 figure 5
PMID:34666001 FYPO:0008003 figure 5
PMID:34666001 PBO:0101579 figure 5
PMID:34666001 PBO:0101579 figure 5
PMID:34666001 PBO:0101579 figure 5
PMID:34666001 PBO:0101579 figure 5
PMID:34666001 PBO:0101579 figure 5
PMID:34666001 PBO:0101579 figure 5
PMID:34666001 PBO:0101578 mechanoreceptor. Together, these results indicate that Wsc1 clustering may be triggered by local surface compression, independently of puta- tive ‘‘trans’’ homotypic interactions between extracellular sensors from neighbor cells or general cell-to-cell signaling.
PMID:34666001 PBO:0101579 figure 5
PMID:34666001 PBO:0101579 Remarkably, the Wsc1DCC-GFP lacking a large fraction of the cytoplasmic C-ter- minal tail, and thus presumably defective in downstream signal transduction was dispensable for clustering. This finding rein- forces the notion that Wsc1 clustering occurs independently of downstream CWI signaling.
PMID:34666001 PBO:0101580 In sharp contrast, Wsc1DSTR-GFP, Wsc1DWSC-GFP and Wsc1DSTRDWSC-GFP cells were completely devoid of any clustering phenotype, with an enrichment at con- tacts close to $2 (Figures 5D, 5E, and S2F–S2H).
PMID:34666001 PBO:0101580 In sharp contrast, Wsc1DSTR-GFP, Wsc1DWSC-GFP and Wsc1DSTRDWSC-GFP cells were completely devoid of any clustering phenotype, with an enrichment at con- tacts close to $2 (Figures 5D, 5E, and S2F–S2H).
PMID:34666001 PBO:0101579 figure 5
PMID:34666001 PBO:0101579 figure 5
PMID:34666001 PBO:0101579 figure 5
PMID:34666001 PBO:0101579 figure 5
PMID:34666001 PBO:0101579 figure 5
PMID:34666001 PBO:0101579 figure 5
PMID:34666001 PBO:0101580 In sharp contrast, Wsc1DSTR-GFP, Wsc1DWSC-GFP and Wsc1DSTRDWSC-GFP cells were completely devoid of any clustering phenotype, with an enrichment at con- tacts close to $2 (Figures 5D, 5E, and S2F–S2H).
PMID:34666001 FYPO:0008003 figure 5
PMID:34666001 PBO:0101581 increased lateral diffusion in membrane. Finally, Wsc1DWSC-GFP and Wsc1DSTR-GFP, which are incapable of clustering, exhibited much smaller half-times—closer to that of mCherry-Psy1 (Figures 6A, 6B, and S6A).
PMID:34674264 PBO:0094509 Although this assay is not quantitative, we found that Sid4 was ubiquitinated to similar levels as in wild-type in both dma1-6A and dma1-6D/E but was not ubiquitinated in dma1D (Fig. 2A).
PMID:34674264 MOD:00046 in vivo phosphorylation sites identified by mass spectrometry
PMID:34674264 MOD:00047 in vivo phosphorylation site identified by mass spectrometry
PMID:34674264 PBO:0093475 in vitro kinase assay showed S166 is phosphorylated by Cdk1
PMID:34674264 PBO:0094506 in vitro kinase assay showed S251 is phosphorylated by Plo1
PMID:34674264 PBO:0094507 in vitro kinase assay showed T18, S20, and S266 are phosphorylated by CK2
PMID:34674264 PBO:0094507 in vitro kinase assay showed T18, S20, and S266 are phosphorylated by CK2
PMID:34674264 PBO:0094516 (Fig.3A–C). Reduced contractile ring localization during mitosis. However, we observed that Dma1-6A was significantly more difficult to detect at the first instance of CR localization early in mitosis than either Dma1 or Dma1-6D/E
PMID:34674264 PBO:0094517 Normal localization to medial cortical nodes, SPB, and division septum as wildtype
PMID:34674264 PBO:0094514 (Fig.2B). Dma1-6D/E auto-ubiquitination was modestly but reproducibly reduced relative to wild- type. Specifically, while 82% of wild-type Dma1 became ubiquitinated on at least one site, 71% of Dma1-6D/E did.
PMID:34674264 PBO:0094513 Fig. 2B). Almost abolished Dma1 auto-ubiquitination by in vitro assay
PMID:34674264 PBO:0094512 Decreased Dma1 auto-ubiquitination by in vitro assay
PMID:34674264 PBO:0094511 in vitro assay
PMID:34674264 PBO:0094517 Normal localization to medial cortical nodes, mitotic contractile ring, SPB, and septum as wildtype
PMID:34674264 FYPO:0003762 Fig 4a We observed that nda3-km311, dma1- 6A nda3-km311, and dma1-6D/E nda3-km311 cells delayed septation relative to wild-type cells and that dma1Δ cells did not
PMID:34674264 PBO:0098166 in vitro kinase assay showed T18, S20, and S266 are phosphorylated by CK2
PMID:34674264 PBO:0094520 Normal localization to medial cortical nodes, SPB, and division septum as wildtype
PMID:34674264 FYPO:0000776 CHECK ALLELELS we combined analog-sensitive (cdc2-as, orb5-as) and temperature- sensitive (plo1-1) alleles. Despite these kinases targeting Dma1 in vitro, we found no evidence that inhibiting any of them singly (not shown) or together (Fig. 1G) chan- ged Dma1 phosphostatus as monitored by SDS/PAGE mobility suggesting that these kinases are not responsible for regulating Dma1 phosphostatus in cells.
PMID:34674264 PBO:0094517 Localization to SPBs at the same level as wildtype during spindle stress
PMID:34674264 PBO:0094518 Localization to SPBs at the same level as wildtype during spindle stress
PMID:34674264 FYPO:0003762 Fig 4a
PMID:34686329 PBO:0109878 (Figure S4C)
PMID:34686329 PBO:0102818 (Figures S1E and S1F)
PMID:34686329 PBO:0109888 Surprisingly, despite a strong decrease of Tor2 steady-state levels, its stability appears unaffected, even increasing 6 h after CHX treatment. It is possible that Tor2 is subjected to rapid turnover and compensa- tory mechanisms boosting its synthesis.
PMID:34686329 PBO:0109877 (Figure S4C)
PMID:34686329 PBO:0109878 (Figure 3D)
PMID:34686329 PBO:0109963 We conclude that Tti1, and to a lesser extent Tti2, re- cruits TTT to nascent Tra1 polypeptides
PMID:34686329 PBO:0109963 We conclude that Tti1, and to a lesser extent Tti2, re- cruits TTT to nascent Tra1 polypeptides
PMID:34686329 PBO:0093612 (Figure 6B)
PMID:34686329 PBO:0109890 Figure 2C) Abolished interaction between Tti2 protein and tra1 mRNA
PMID:34686329 PBO:0109878 (Figure 3D)
PMID:34686329 PBO:0109897 (Figure 3E)
PMID:34686329 PBO:0109878 (Figure 3D)
PMID:34686329 PBO:0109880 (Figure 3C)
PMID:34686329 PBO:0109874 (Figures S1E and S1F)
PMID:34686329 PBO:0102818 (Figures S1E and S1F)
PMID:34686329 PBO:0109880 (Figure 3C)
PMID:34686329 PBO:0109881 In contrast, Tti2 and Tti1 interaction with tra1+ does not change in the absence of Tel2 (Figure 2I),
PMID:34686329 PBO:0093580 (Figure 6B)
PMID:34686329 PBO:0109897 (Figure 3E)
PMID:34686329 PBO:0109893 (Figure 3E)
PMID:34686329 PBO:0109908 Tti1 caused a strong decrease of Tti2 and Tel2 binding (Fig- ure 2J).
PMID:34686329 GO:0051083 (Figures 2A and 2B). To determine whether this interaction occurs cotranslationally, we then repeated Tti1 RIPs in cells treated either with puromycin, an inhibitor of translation elongation, or with EDTA, which disso- ciates ribosomes. Both treatments abolished Tti1 binding to tra1+ (Figure 2C).
PMID:34686329 GO:0051083 (Figures 2A and 2B). To determine whether this interaction occurs cotranslationally, we then repeated Tti1 RIPs in cells treated either with puromycin, an inhibitor of translation elongation, or with EDTA, which disso- ciates ribosomes. Both treatments abolished Tti1 binding to tra1+ (Figure 2C).
PMID:34686329 GO:0051083 Conventional and qRT-PCR analyses revealed a specific enrichment of the tra1+ mRNA in RIPs of all three TTT subunits, Tel2, Tti1, and Tti2, compared with several negative controls (Figures 2A and 2B). To determine whether this interaction occurs cotranslationally, we then repeated Tti1 RIPs in cells treated either with puromycin, an inhibitor of translation elongation, or with EDTA, which disso- ciates ribosomes. Both treatments abolished Tti1 binding to tra1+ (Figure 2C).
PMID:34686329 GO:0005634 Tel2 does not localize to the nucleus in standard growth conditions (Figure S2B).
PMID:34686329 GO:0005737 (Figure S2B).
PMID:34686329 PBO:0109907 Finally, our published tran- scriptomic analysis of tti2-CKO mutants showed that PIKK mRNA levels remain unaffected following Tti2 depletion (Fig- ureS1H)
PMID:34686329 PBO:0109906 Finally, our published tran- scriptomic analysis of tti2-CKO mutants showed that PIKK mRNA levels remain unaffected following Tti2 depletion (Fig- ureS1H)
PMID:34686329 PBO:0109905 Finally, our published tran- scriptomic analysis of tti2-CKO mutants showed that PIKK mRNA levels remain unaffected following Tti2 depletion (Fig- ureS1H)
PMID:34686329 PBO:0109904 Finally, our published tran- scriptomic analysis of tti2-CKO mutants showed that PIKK mRNA levels remain unaffected following Tti2 depletion (Fig- ureS1H)
PMID:34686329 GO:0110078 (Figure 1A)
PMID:34686329 GO:0110078 (Figure 1A)
PMID:34686329 GO:0110078 Altogether, our quantitative proteomic analyses indicate that Tti2, Tel2, and Tti1, together with Asa1, form a stable multi- meric complex that interacts with most PIKKs in S. pombe (Figure 1A)
PMID:34686329 FYPO:0000705 Abolished incorporation of Tra1 into SAGA complex
PMID:34686329 FYPO:0000705 Abolished incorporation of Tra1 into SAGA complex
PMID:34686329 PBO:0109866 RNA-seq
PMID:34686329 PBO:0109899 (figure 6F)
PMID:34686329 PBO:0109898 (Figure 6H)
PMID:34686329 PBO:0109898 (Figure 6H)
PMID:34686329 FYPO:0000847 RNA-seq
PMID:34686329 FYPO:0000847 (Figure 6J)
PMID:34686329 PBO:0093580 (Figure 6B)
PMID:34686329 PBO:0093581 (Figure 6B)
PMID:34686329 PBO:0109876 (Figure S1G)
PMID:34686329 PBO:0109875 (Figure S1G)
PMID:34686329 PBO:0109876 (Figure S1G)
PMID:34686329 PBO:0109896 (Figure 3E)
PMID:34686329 FYPO:0000705 Abolished incorporation of Tra1 into SAGA complex
PMID:34686329 FYPO:0000705 Abolished incorporation of Tra1 into SAGA complex
PMID:34686329 FYPO:0000705 Abolished incorporation of Tra1 into SAGA complex
PMID:34686329 PBO:0109900 (Figure 7A)
PMID:34686329 PBO:0109869 (Figure 7A)
PMID:34686329 FYPO:0002430 figure 6I
PMID:34686329 FYPO:0002430 figure 6I
PMID:34686329 PBO:0109871 Western blotting followed by quantification of signal intensities showed that both the steady-state levels and the stability of Tra1, Tra2, and Tor1 decrease following Tti2 depletion (Figures 1C–1F).
PMID:34686329 PBO:0109872 Western blotting followed by quantification of signal intensities showed that both the steady-state levels and the stability of Tra1, Tra2, and Tor1 decrease following Tti2 depletion (Figures 1C–1F).
PMID:34686329 PBO:0109873 Western blotting followed by quantification of signal intensities showed that both the steady-state levels and the stability of Tra1, Tra2, and Tor1 decrease following Tti2 depletion (Figures 1C–1F).
PMID:34686329 FYPO:0001355 Depletion of each protein re- duces S. pombe viability and proliferation compared with control strains and culture conditions (Figures S1C and S1D).
PMID:34686329 FYPO:0001355 (Figures S1C and S1D).
PMID:34686329 FYPO:0001355 (Figures S1C and S1D).
PMID:34686329 PBO:0109874 We used qRT-PCR to deter- mine the effect of TTT depletion on the expression of two sexual differentiation genes, ste11+ and mei2+. We observed that the mRNA levels of both genes increase upon depletion of Tel2, Tti1, and Tti2 compared with control strains and conditions (Figures S1E and S1F)
PMID:34686329 PBO:0109876 Western blotting showed decreased phosphorylation of the ribosomal protein S6, a ca- nonical TORC1 substrate, following Tel2, Tti1, and Tti2 depletion (Figure S1G)
PMID:34686329 PBO:0109875 Western blotting showed decreased phosphorylation of the ribosomal protein S6, a ca- nonical TORC1 substrate, following Tel2, Tti1, and Tti2 depletion (Figure S1G)
PMID:34686329 PBO:0109896 (Figure 3E)
PMID:34686329 PBO:0109875 (Figure S1G)
PMID:34686329 PBO:0102818 We used qRT-PCR to deter- mine the effect of TTT depletion on the expression of two sexual differentiation genes, ste11+ and mei2+. We observed that the mRNA levels of both genes increase upon depletion of Tel2, Tti1, and Tti2 compared with control strains and conditions (Figures S1E and S1F)
PMID:34686329 PBO:0109874 (Figures S1E and S1F)
PMID:34686329 PBO:0109882 (Figure 2H)
PMID:34686329 PBO:0109877 (Figure S4C)
PMID:34686329 PBO:0109878 (Figure 3C)
PMID:34686329 PBO:0109879 (Figure S5)
PMID:34686329 PBO:0109866 RNA-seq
PMID:34686329 PBO:0093580 (Figure 6B)
PMID:34686329 PBO:0100916 (Figure 6B)
PMID:34686329 PBO:0093576 (Figure 6B)
PMID:34731638 FYPO:0002336 To test this more directly, we performed the HSS assay in the double spt16–1epe1Δ mutant. Indeed, heterochromatin spreading was completely restored (Figure 3H, compare with Figure 2D)
PMID:34731638 FYPO:0004742 (Figure S2F)
PMID:34731638 FYPO:0005917 we observed derepression of several subtelomeric genes (Figures 2E and S2G).
PMID:34731638 FYPO:0007480 (Figure 2D) reduced heterochromatin spreading at mating-type and subtelomeric heterochromatin
PMID:34731638 PBO:0094681 (Figure 1B) In contrast, there was a substantial reduction of H3K9me2 at the mating-type locus, in agreement with a previous study (Holla et al., 2020) (Figure S1A), and at the subtelomeres
PMID:34731638 PBO:0101104 (Figures 1B, 1C, S1D) only a subtle change of H3K9me2 at pericentromere
PMID:34731638 PBO:0101105 (Figure 2C) Conversely, in the pob3Δ strain, the orange reporter was also fully derepressed in the majority of cells, yet the green reporter remained silenced or mildly derepressed. This result implies that pob3Δ cells have a heterochromatin spreading defect
PMID:34731638 FYPO:0007892 Nonetheless, the pob3Δ mutant exhibited increased incorporation of H3-T7 at the TEL1L region (Figure 4G), implying that the H3 turnover rate is increased at subtelomeric heterochromatin.
PMID:34731638 FYPO:0004604 Figure 4E
PMID:34731638 FYPO:0003412 Figure 4E
PMID:34731638 FYPO:0004577 ntriguingly, while H3K9me2 levels were unaltered in spt16–1, H3K9me3 levels were reduced at several loci at the TEL1L subtelomeric region (i.e., SPAC212.09c, SPAC212.08c, and SPAC212.06c; compare Figure 4B with 4A)
PMID:34731638 FYPO:0003412 synthetic defect in the silencing of dg and tlh1/2 transcripts (Figure 4C)
PMID:34731638 FYPO:0003412 Figure 4E
PMID:34731638 FYPO:0004604 Figure 4E
PMID:34731638 FYPO:0006299 (figure 1 f)
PMID:34731638 FYPO:0004542 (figure 1 f)
PMID:34731638 FYPO:0002360 vw changed from decreased to normal because look WT?
PMID:34731638 FYPO:0002360 (Figure 1 G)
PMID:34731638 FYPO:0003555 (Figure 1 G)
PMID:34731638 FYPO:0006299 (fig1G) (fig1G ) vw changed to increased (compared to WT)
PMID:34731638 PBO:0101106 (fig1G ) vw changed to increased (compared to WT)
PMID:34731638 FYPO:0002360 Moreover, epe1Δ reduced the expression of several subtelomeric genes in pob3Δ, suggesting that it also counteracts heterochromatin spreading (Figure 3G)
PMID:34731638 FYPO:0004604 Partial suppression of pob3∆ silencing phenotype.
PMID:34731638 FYPO:0007894 (Figures 1E and S1D) we found increased signals of elongating RNAPII (RNAPII Ser2P) and H2B ubiquitination (H2Bub), a histone mark associated with active transcription
PMID:34731638 GO:0000791 (Figure S1E)
PMID:34731638 PBO:0101107 Figures S2C–S2E in chromatin/euchromatin
PMID:34731638 PBO:0101108 Figures S2C–S2E in chromatin/euchromatin
PMID:34731638 FYPO:0002387 Although degradation of Epe1 still occurs in pob3Δ in S phase, we found increased steady-state levels of Epe1 in cycling cells (Figure S3A).
PMID:34731638 PBO:0101110 found reduced Swi6 binding in spt16–1 at subtelomeric genes close to the heterochromatin boundary (SPAC212.12, SPAC212.06c; Figure 4D).
PMID:34731638 PBO:0101111 (Figures S4A–S4C) Histone H3 ChIP-seq revealed a small but reproducible reduction of H3 at subtelomeres in pob3Δ
PMID:34731638 PBO:0101112 (Figures S4A–S4C) Histone H3 ChIP-seq revealed a small but reproducible reduction of H3 at subtelomeres in pob3Δ
PMID:34731638 PBO:0101113 (Figures S4A–S4C) Histone H3 ChIP-seq revealed a small but reproducible reduction of H3 at subtelomeres in pob3Δ
PMID:34731638 FYPO:0007891 (Figure 2D) reduced heterochromatin spreading at mating-type and subtelomeric heterochromatin
PMID:34731638 FYPO:0007895 (Figures 1E and S1D) we found increased signals of elongating RNAPII (RNAPII Ser2P) and H2B ubiquitination (H2Bub), a histone mark associated with active transcription
PMID:34731638 FYPO:0005917 we observed derepression of several subtelomeric genes (Figures 2E and S2G).
PMID:34738170 FYPO:0001357 A serial dilution spotting assay (Fig. 2B) showed that the growth of och1Δ with either pAL-pwp1+ or pAU-pwp1+ was as fast as that of wild-type cells, indicating that the growth defect of och1Δ cells was alleviated by expression of pwp1+.
PMID:34738170 FYPO:0001357 A serial dilution spotting assay (Fig. 2B) showed that the growth of och1Δ with either pAL-pwp1+ or pAU-pwp1+ was as fast as that of wild-type cells, indicating that the growth defect of och1Δ cells was alleviated by expression of pwp1+.
PMID:34738170 FYPO:0001357 A serial dilution spotting assay (Fig. 2B) showed that the growth of och1Δ with either pAL-pwp1+ or pAU-pwp1+ was as fast as that of wild-type cells, indicating that the growth defect of och1Δ cells was alleviated by expression of pwp1+.
PMID:34798057 FYPO:0000708 Both mutants displayed meiosis defects with a reduction in gamete numbers and viability more marked in the nda2noD mutant (Figures 6A, 6B, and 6C).
PMID:34798057 FYPO:0000708 Figure S1 D
PMID:34798057 PBO:0100613 V348A
PMID:34798057 PBO:0093562 (Figure S7A),
PMID:34798057 PBO:0093564 (Figure S7A)
PMID:34798057 PBO:0093564 (weird!) Intriguingly, the double nda2noD nda3noD mutant was less sensitive than the single ones. OK!Therefore, a possible explanation for the lower sensitivity of the double mutant is that defects resulting from the elevated level of one monomer are compensated for by a similar overexpression of the second monomer.
PMID:34798057 FYPO:0005599 Figure 6E When dus3D diploids were induced to enter meiosis, the time needed in prophase for spindle assembly in MI was increased, while a marked in- crease in the duration of metaphase was noted in both MI and MII (Figures 6D–6H).
PMID:34798057 FYPO:0002091 Figures 6I and 6J
PMID:34805795 PBO:0108104 BFC augments TORC1 activation in response to amino acid stimulation
PMID:34805795 PBO:0108102 (Figure S3) Bhd1 and Fnp1 localize to vacuoles in response to amino acid star- vation and that this localization is largely independent of the presence of the other protein.
PMID:34805795 PBO:0108103 during amino acid supplementation. (Figures 2G and S4), demonstrating that the BFC, is required for efficient activation of TORC1 following amino acid supplementation.
PMID:34805795 PBO:0108097 Figure 5
PMID:34805795 PBO:0108097 Figure 5
PMID:34805795 PBO:0108097 Figure S1A
PMID:34805795 PBO:0108103 during amino acid supplementation. (Figures 2G and S4), demonstrating that the BFC, is required for efficient activation of TORC1 following amino acid supplementation.
PMID:34805795 PBO:0108101 (Figure S3) Bhd1 and Fnp1 localize to vacuoles in response to amino acid star- vation and that this localization is largely independent of the presence of the other protein.
PMID:34805795 PBO:0108106 during amino acid starvation
PMID:34805795 PBO:0108106 during amino acid starvation
PMID:34805795 PBO:0108097 Figure S1A
PMID:34805795 PBO:0099985 results in a significant growth advantage of BFC mutant over wild-type strains when equal number of log phase cells are grown on rapamycin-containing EMM plates supplemented with amino acids (Figures S1A and S1B). Moreover, treating cells with 125 or 150 ng/mL of rapamycin for 90 min revealed that the growth advantage of BFC mutants correlates with an increase in P-Rps6 levels compared to wild-type cells (Figure S5C). Together, these data support a model in which BFC participates in TORC1 repression.
PMID:34805795 PBO:0108098 Bhd1 and Fnp1 appear diffusely distributed throughout the cytoplasm in amino acid replete conditions, but localize to vacuoles in response to amino acid starvation evidenced by the strong overlap between Bhd1-/Fnp1-GFP and the FM4-64 dye under amino acid starvation conditions (Figures 2A–2F)
PMID:34805795 FYPO:0007909 (figure 4d) (vw: assayed vacuolar pH as a surrogate for V-ATPase activity)
PMID:34805795 FYPO:0001159 (figure 4d) (vw: assayed vacuolar pH as a surrogate for V-ATPase activity)
PMID:34805795 PBO:0108099 (Figure 4F) (vw: ph9)
PMID:34805795 PBO:0108099 (Figure 4F) (vw: ph9)
PMID:34805795 FYPO:0006266 (Figure S1A)
PMID:34805795 FYPO:0006266 (Figure S1A)
PMID:34810257 FYPO:0000091 We found that cnp20-14A is highly sensitive to TBZ, even more strongly than the cnp20-ΔCIM mutant (Fig. 6D and SI Appendix, Fig. S16),
PMID:34810257 PBO:0112398 fig 3 Our results indicate that the first 55 amino acids of CENP-TCnp20 are the minimal interaction domain with Ccp1, which we named the Ccp1- interacting motif (CIM).
PMID:34810257 FYPO:0000091 (Fig. 4 E and F).
PMID:34810257 PBO:0101612 But GFP-Ccp1 is completely disassociated from centromeric regions in cnp20-ΔCIM at all stages of the cell cycle (Fig. 4 C and D and SI Appendix, Fig. S13).
PMID:34810257 PBO:0101627 during mitotc M-phase. In contrast, we found that GFP-Ccp1 in all cnp20-14A mutant cells remains associated with centromeres during all the stages of the cell cycle (Fig. 6 B and C).
PMID:34810257 FYPO:0000141 But most cnp20-14A cells display mitotic delay, and more than 12% of mutant cells failed to complete chromosome segregation within 30 min (Fig. 6 E and F)
PMID:34810257 PBO:0101628 (ndc80 receptor) These co-IP experiments showed that the interaction between Ndc80 and CENP-TCnp20 is drastically increased during mitosis (Fig. 7C), supporting the idea that the presence of Ccp1 interferes with the interaction between Ndc80 and CENP-TCnp2
PMID:34810257 PBO:0101629 These data demonstrate that CDK1 is capable of phosphorylating the CIM domain of CENP-TCnp20. Various slow migrating bands were observed in the assay with Cnp201-55 (Fig. 7D), indicating that the domain contains multiple phosphorylation sites, consistent with our point mutation analysis. (ASSAYED USING HUMAN CDK1)
PMID:34810257 PBO:0112397 However, we found that Spc25-GFP appeared not to attach to microtubules in ∼20% of cnp20-14A mitotic cells, indicating that dephosphorylation of the CIM domain leads to mislocalization of Ndc80C during mitosis (Fig. 7A). Importantly, our co-IP results indicated that the interaction between Cnp20-14A and Ndc80 is significantly reduced during mitosis (Fig. 7B).
PMID:34810257 PBO:0101615 Cnp20-14A showed a strong interaction with Ccp1 (Fig. 5F)
PMID:34810257 PBO:0101613 Yeast two hybrid To investigate how phosphorylation of the CIM domain affects the interaction between Ccp1 and CENP-TCnp20, we conducted yeast two-hybrid assays with Cnp20-14D and Ccp1. We found that the interaction between Cnp20-14D and Ccp1 was dramatically reduced (Fig. 5F).
PMID:34810257 PBO:0101624 In addition, we found that CENP-ACnp1-GFP partially reduced its centromere localization in cnp20-9 at the restrictive temperature (SI Appendix, Fig. S6).
PMID:34810257 PBO:0101623 whereas the localization of GFP-Ccp1 at centromeres only has a mild reduction in the CENP-A ts mutant, cnp1-1 (SI Appendix, Fig. S4).
PMID:34810257 PBO:0101622 We next checked the distribution of CENP-TCnp20-GFP in ccp1Δ and found that its centromere localization was unaffected in the mutant (Fig. 2 G–I).
PMID:34810257 PBO:0101621 whereas the localization of GFP-Ccp1 at centromeres only has a mild reduction in the CENP-A ts mutant, cnp1-1 (SI Appendix, Fig. S4).
PMID:34810257 PBO:0101612 We found that GFP-Ccp1 was delocalized from centromeres at the restrictive temperature in cnp20-9 at all stages of the cell cycle (Fig. 2 E and F and SI Appendix, Fig. S3)
PMID:34810257 PBO:0101620 Consistent with the key role of CENP-TCnp20 in the assembly of the Ndc80 complex, we found that the association of Ndc80-GFP with centromeres is lost in cnp20-9 at the restrictive temperature (Fig. 2 C and D).
PMID:34810257 PBO:0101625 (These data suggest that phosphorylation of the CIM domain leads to disassociation of Ccp1 from centromeres. CIM domain) Together,our data indicate that CENP-TCnp20 is required for Ccp1 centromere localization
PMID:34810257 PBO:0112401 fig 3 Our results indicate that the first 55 amino acids of CENP-TCnp20 are the minimal interaction domain with Ccp1, which we named the Ccp1- interacting motif (CIM). Yeast two hybrid
PMID:34810257 PBO:0112400 Yeast two hybrid The yeast two-hybrid assays showed that the Ccp1 homodimer mutant, Ccp1-4A, was unable to interact with CENP-TCnp20 (Fig. 3A and SI Appendix, Fig. S8)
PMID:34849791 FYPO:0000082 Supplemental Figure S4B
PMID:34849791 PBO:0094560 Figure 4
PMID:34849791 FYPO:0000964 Supplemental Figure S4B
PMID:34849791 FYPO:0000082 Supplemental Figure S4B
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PMID:34849791 FYPO:0000674 Supplemental Figure S3B
PMID:34849791 FYPO:0000964 Supplemental Figure S3B
PMID:34849791 PBO:0094559 Figure 4
PMID:34849791 FYPO:0000674 Supplemental Figure S3B
PMID:34849791 FYPO:0000964 Supplemental Figure S3B
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PMID:34849791 FYPO:0000674 Supplemental Figure S3B
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PMID:34849791 FYPO:0000674 Supplemental Figure S3B
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PMID:34849791 FYPO:0000964 Supplemental Figure S4B
PMID:34849791 FYPO:0000082 Supplemental Figure S5B
PMID:34849791 FYPO:0000964 Supplemental Figure S5B
PMID:34849791 PBO:0094561 Figure 4
PMID:34849791 PBO:0094562 Figure 4
PMID:34849791 FYPO:0000082 Supplemental Figure S5B
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PMID:34849791 FYPO:0000082 Figure 3A
PMID:34849791 FYPO:0000964 Figure 3B
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PMID:34849791 FYPO:0000674 Supplemental Figure S4B
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PMID:34849791 FYPO:0000674 Supplemental Figure S3B
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PMID:34849791 FYPO:0000082 Figure 3A
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PMID:34849791 FYPO:0000674 Figure 3A
PMID:34849791 FYPO:0000964 Figure 3B
PMID:34849791 FYPO:0001513 Figure 4
PMID:34851403 PBO:0109232 In cells lacking Sgo1 (sgo1Δ), which protects centromeric cohesin during anaphase, no separated kinetochore signals were observed (Fig. 3A,C), although sister chromatids frequently underwent equational segregation in the absence of chiasmata (Fig. S2B).
PMID:34851403 FYPO:0005648 Non-separated signals were found to be significantly or nearly significantly wider than in wild-type cells (Fig. 3E,F;)
PMID:34851403 FYPO:0005648 In mrc1Δ cells, sister kinetochores and centromere cores separated at a low, but significant, level (Fig. 3A–D; Figs S2C and S3A,B), and non-separated signals were significantly wider in shape (Fig. 3E,F; Fig. S3C,D).
PMID:34851403 PBO:0109237 Additionally, the DNA replication checkpoint function of Mrc1 is not required for sister kinetochore association, because deletion of cds1, which encodes an effector kinase functioning downstream of Mrc1 in the DNA replication checkpoint pathway (Alcasabas et al., 2001; Murakami and Okayama, 1995; Tanaka and Russell, 2001), did not affect the kinetochore association state or sister chromatid segregation (Fig. 3C,E; Fig. S2C).
PMID:34910579 PBO:0102300 36 degrees
PMID:34910579 PBO:0102299 36 degrees
PMID:34910579 PBO:0102298 36 degrees
PMID:34910579 FYPO:0005840 see above
PMID:34910579 FYPO:0003890 We confirmed the defects in septa using electron microscopy. In cells with closed septa, the primary septum was uneven (Figure 3, red arrows) and thinner in smi1-1 cells than in WT (Figure 3A).
PMID:34910579 FYPO:0001188 Figure 2A
PMID:34910579 PBO:0102297 recruits glucanases and glucan synthases to division site
PMID:34910579 PBO:0035615 Figure 1, C and D restrictive temperature mutant.
PMID:34910579 PBO:0102306 36 degrees
PMID:34910579 PBO:0102308 36 degrees
PMID:34910579 PBO:0102308 36 degrees
PMID:34910579 PBO:0035615 Supplemental Figure S2, A–D
PMID:34910579 PBO:0102304 36 degrees
PMID:34910579 PBO:0102302 36 degrees
PMID:34910579 PBO:0102301 36 degrees
PMID:34910579 FYPO:0004292 Supplemental Figure S2, A–D
PMID:34910579 FYPO:0000650 38.5% cf WT 11.5% Figure 1F
PMID:34910579 PBO:0102309 recruits glucanases and glucan synthases to division site
PMID:34910579 PBO:0102309 ogether, these results confirmed that Sbg1 is specific to Bgs1, while Smi1 regulates the levels of both Bgs4 and Bgs1 at the division site, with a more important role for Bgs4 (Figure 7, A–C).
PMID:34910579 PBO:0102299 36 degrees
PMID:34951983 GO:0007052 Microtubule dynamics required for spindle repair following laser ablation
PMID:34951983 GO:0007052 required for spindle repair following laser ablation
PMID:34951983 GO:0007052 required for spindle repair following laser ablation
PMID:34951983 GO:0007052 Not required for spindle repair following laser ablation
PMID:34958661 FYPO:0002455 All three double mutants exhibited synthetic defects in cell growth and cytokinesis as judged by tilted and disorganized septa (Fig. 5, C–E; and Fig. S3 M).
PMID:34958661 FYPO:0002455 All three double mutants exhibited synthetic defects in cell growth and cytokinesis as judged by tilted and disorganized septa (Fig. 5, C–E; and Fig. S3 M).
PMID:34958661 FYPO:0002455 All three double mutants exhibited synthetic defects in cell growth and cytokinesis as judged by tilted and disorganized septa (Fig. 5, C–E; and Fig. S3 M).
PMID:34958661 FYPO:0006616 The cell length at division phenotype for arf6Δ was minor, but these cells were wider than wild type (Fig. S1 E).
PMID:34958661 GO:0010971 Figure 1
PMID:34958661 GO:0010971 Figure 1
PMID:34958661 PBO:0096312 Fig S1A; 27 micron
PMID:34958661 PBO:0096312 Fig S1A; 26.6 micron
PMID:34958661 PBO:0096312 Fig S1A; 24.6 micron
PMID:34958661 PBO:0101335 This is from GIs, phenocopy, PLUS If the Arf6 localization defect in syt22Δ is due to loss of the GTP-bound state, then it should be suppressed by arf6(Q75L). Indeed, arf6(Q75L)-mNG localized to nodes even in syt22Δ cells (Fig. 2 G)
PMID:34958661 PBO:0101336 The slower-migrating, hyperphosphorylated form of Wee1 was lost in arf6Δ and syt22Δ, similar to cdr2Δ (Fig. 1 H). We conclude that activated Arf6 functions in the Cdr2 pathway to control cell size at division through inhibition of Wee1.
PMID:34958661 PBO:0101336 The slower-migrating, hyperphosphorylated form of Wee1 was lost in arf6Δ and syt22Δ, similar to cdr2Δ (Fig. 1 H). We conclude that activated Arf6 functions in the Cdr2 pathway to control cell size at division through inhibition of Wee1.
PMID:34958661 PBO:0101336 The slower-migrating, hyperphosphorylated form of Wee1 was lost in arf6Δ and syt22Δ, similar to cdr2Δ (Fig. 1 H). We conclude that activated Arf6 functions in the Cdr2 pathway to control cell size at division through inhibition of Wee1.
PMID:34958661 PBO:0101337 Arf6 localizes stably to Cdr2 nodes during interphase in a manner that depends on nucleotide binding, membrane binding, and Cdr2 itself.; strongly enriched at cortical nodes in the cell middle (Fig. 2 A). Arf6 and Cdr2 colocalized at nodes (Figs. 2 B and S2 A)
PMID:34958661 PBO:0021076 trongly enriched at cortical nodes in the cell middle (Fig. 2 A). Arf6 and Cdr2 colocalized at nodes (Figs. 2 B and S2 A)
PMID:34958661 PBO:0101338 Arf6 node localization required Cdr2 but not other node proteins (Figs. 2 E and S2 B).
PMID:34958661 PBO:0101338 A GDP-locked mutant arf6(T52N)-mNG lost node localization, (Fig. 2 F)
PMID:34958661 PBO:0101339 but the GTP-locked allele arf6(Q75L)-mNG remained at nodes (Fig. 2 F)
PMID:34958661 PBO:0101338 Further, Arf6 localization to nodes was lost upon deletion of its GEF Syt22 (Fig. 2 G
PMID:34958661 PBO:0101339 Indeed, arf6(Q75L)-mNG localized to nodes even in syt22Δ cells (Fig. 2 G)
PMID:34958661 GO:0051285 Ucp3-mNG localized to spots at the cell tips, which likely represent endocytic actin patches due to colocalization with actin patch component Pan1 (Fig. S2, E and F)
PMID:34958661 PBO:0101340 The resulting arf6 alleles reduced node localization and instead enriched at the cytoplasm (Fig. S2, H and I)
PMID:34958661 PBO:0101340 The resulting arf6 alleles reduced node localization and instead enriched at the cytoplasm (Fig. S2, H and I)
PMID:34958661 PBO:0101340 The resulting arf6 alleles reduced node localization and instead enriched at the cytoplasm (Fig. S2, H and I)
PMID:34958661 PBO:0101341 rf6Δ cells had cytoplasmic Cdr2 clusters that were absent in wild-type cells (Figs. 3 A and S2 J), indicating defects in cortical anchoring.
PMID:34958661 PBO:0101342 "Modified form is indirect because GDP bound does not localize to nodes) ""These defects indicate that Arf6 anchors Cdr2 stably at nodes, meaning that Arf6 and Cdr2 reciprocally promote each other’s node localization."""
PMID:34958661 PBO:0101343 o explain this connection, we examined the localization of Wee1 and Cdr1 at cortical nodes in arf6Δ mutants. Wee1 localized to nodes in arf6Δ, but Cdr1 did not (Fig. 3, D and E; and Fig. S3 D)
PMID:34958661 PBO:0101343 We combined arf6Δ with the mid1(400–450Δ) mu- tant that cannot bind Cdr2. In the resulting cells, Cdr2 was ab- sent from the cell cortex and formed large cytoplasmic puncta (Figs. 4 A and S2 J).
PMID:34958661 PBO:0112444 Thus, Arf6 and Mid1 are partially over- lapping anchors for Cdr2 nodes.
PMID:34958661 PBO:0101345 The resulting arf6 alleles reduced node localization and instead enriched at the cytoplasm (Fig. S2, H and I)
PMID:34958661 PBO:0101346 (actually mid1-Nter)
PMID:34959732 FYPO:0001367 (Sub lethal and lethat doese) Figure 5 and Figure S3. Also in the Table 3.
PMID:34959732 FYPO:0002060 Table 5 and Figure S3, and Figure S4C. Vegetative cell lysis caused by lethal and sublethal concentrations of micafungin is suppressed in the pbr1-8
PMID:34959732 FYPO:0001367 (Sub lethal and lethat doese) Figure 5 and Figure S3. Also in the Table 3.
PMID:34959732 FYPO:0001367 Figure 3A and Figure S1A. Table 3. Suppression of the lytic phenotype at cytokinesis
PMID:34959732 FYPO:0000417 Figure 3B and Figure S1B. Also in the Table 3. Cytokinesis is blocked in both wild-type and pbr1-8 strains treated with lethal concentrations of the echinocandin drug anidulafungin, suggesting that this drug affects the function of Bgs4 and Bgs1 and/or Bgs3
PMID:34959732 FYPO:0000005 Figure 4A and Figure S2A Sublethal concentrations of caspofungin
PMID:34959732 FYPO:0002060 Table 5 and Figure S3, and Figure S4C. Vegetative cell lysis caused by lethal and sublethal concentrations of micafungin is suppressed in the pbr1-8
PMID:34959732 FYPO:0001367 Figure 4B and Figure S2B. Also in the Table 3. The pbr1-8 mutation partially suppresses the slowing cytokinesis caused by lethal concentrations of caspofungin, suggesting that besides Bgs4, this drug affects other Bgs subunits (Bgs1 and/or Bgs3)
PMID:34959732 FYPO:0000164 Figure 4B and Figure S2B. Also in the Table 3. The pbr1-8 mutation partially suppresses the slowing cytokinesis caused by lethal concentrations of caspofungin, suggesting that besides Bgs4, this drug affects other Bgs subunits (Bgs1 and/or Bgs3)
PMID:34959732 FYPO:0000005 Figure 4A and Figure S2A Sublethal concentrations of caspofungin
PMID:34967420 PBO:0102818 RNA-Seq
PMID:34967420 PBO:0102817 RNA-Seq
PMID:34967420 PBO:0102816 RNA-Seq
PMID:34967420 PBO:0102815 RNA-Seq
PMID:34967420 PBO:0102814 RNA-Seq
PMID:34967420 PBO:0102813 RNA-Seq
PMID:34967420 PBO:0102812 RNA-Seq
PMID:34967420 PBO:0102811 RNA-Seq
PMID:34967420 PBO:0102810 Northern Blotting, RNA-Seq
PMID:34967420 PBO:0102828 RNA-Seq
PMID:34967420 PBO:0102827 RNA-Seq
PMID:34967420 PBO:0102826 RNA-Seq
PMID:34967420 PBO:0102825 RNA-Seq
PMID:34967420 PBO:0102824 RNA-Seq
PMID:34967420 PBO:0102823 RNA-Seq
PMID:34967420 PBO:0102822 RNA-Seq
PMID:34967420 PBO:0102821 RNA-Seq
PMID:34967420 PBO:0102820 RNA-Seq
PMID:34967420 PBO:0102819 RNA-Seq
PMID:35008733 PBO:0094645 Live cell imaging revealed that GFP-Lac1 and Lag1-GFP remain localized at the ER in the absence of Lag1 or Lac1 respectively, indicating that their ER localizations are not interdependent.
PMID:35008733 PBO:0094646 Fig 3. Live cell imaging revealed that GFP-Lac1 and Lag1-GFP remain localized at the ER in the absence of Lag1 or Lac1 respectively, indicating that their ER localizations are not interdependent.
PMID:35008733 PBO:0094647 Fig 3. Live cell imaging revealed that GFP-Lac1 and Lag1-GFP remain localized at the ER in the absence of Lag1 or Lac1 respectively, indicating that their ER localizations are not interdependent.
PMID:35008733 FYPO:0006133 fig 5 b. (thin-layer chromatography) We detected an accumulation of PHS and sphingoid bases-1-phosphate levels (PHS-1P or DHS-1P)
PMID:35008733 FYPO:0005593 (thin-layer chromatography) Additionally, the pattern of complex sphingolipids in Lac1-depleted cells shows a strong accumulation of IPC and the appearance of new bands that might correspond to different IPC species
PMID:35011726 FYPO:0001355 severe growth defects with smc6-X and nse6∆
PMID:35011726 FYPO:0001355 severe growth defects with smc6-X and nse6∆
PMID:35011726 FYPO:0001355 severe growth defects with smc6-X and nse6∆
PMID:35011726 FYPO:0002061 Nse1- R188E mutant shows synthetic lethality with smc6-74
PMID:35011726 FYPO:0002061 Nse1- R188E mutant shows synthetic lethality with smc6-74
PMID:35011726 PBO:0105578 Among the Nse1-bound factors, we repeatedly ob- served the Ubc13, Mms2, and Uba1 (Data File S1A,B, Data File S2A–C—ProteomeXchange: PXD029573, and Table S3).
PMID:35011726 FYPO:0001913 (Figure 2D
PMID:35011726 PBO:0093616 The Nse1 ubiquitin ligase mutant showed a synthetic relationship with the Nse2 SUMO ligase mutant (C195S, H197A), indicating their separate roles in SMC5/6 function
PMID:35011726 GO:0061631 Figure 1A
PMID:35011726 GO:0061631 Figure 1A
PMID:35011726 PBO:0093618 (Figure 3A) ubiquitin ligase mutant
PMID:35011726 PBO:0093581 (Figure 3A) ubiquitin ligase mutant
PMID:35011726 PBO:0105577 Nse4 ubiquitination at K181 and Nse3 at K195 (Data Files S3 and S4).
PMID:35011726 PBO:0105577 Nse4 ubiquitination at K181 and Nse3 at K195 (Data Files S3 and S4).
PMID:35011726 FYPO:0000957 Interestingly, the addition of nse1- C216S mutation suppressed the R188E phenotypes (Figure 3A), suggesting that it leads to a ubiquitin-ligase-independent outcome.
PMID:35011726 FYPO:0000963 Interestingly, the addition of nse1- C216S mutation suppressed the R188E phenotypes (Figure 3A), suggesting that it leads to a ubiquitin-ligase-independent outcome.
PMID:35011726 FYPO:0001357 These synthetic phenotypes were again suppressed by the nse1-C216S mutation (Figure S5).
PMID:35011726 PBO:0105579 Figure 1A The MS analysis of the Nse1/3/4- and Ubc13/Mms2-containing in vitro ubiquitination assay led to the identification of Nse4 ubiquitination at K181 and Nse3 at K195 (Data Files S3 and S4).
PMID:35011726 FYPO:0001355 severe growth defects with smc6-X and nse6∆
PMID:35011726 PBO:0105580 Figure 1A The MS analysis of the Nse1/3/4- and Ubc13/Mms2-containing in vitro ubiquitination assay led to the identification of Nse4 ubiquitination at K181 and Nse3 at K195 (Data Files S3 and S4).
PMID:35012333 FYPO:0000080 Fig 11A
PMID:35012333 FYPO:0001357 Fig S7
PMID:35012333 FYPO:0001357 Fig S7
PMID:35012333 FYPO:0001357 Fig S7
PMID:35012333 FYPO:0001357 Fig S7
PMID:35012333 FYPO:0001357 Fig S7
PMID:35012333 FYPO:0001357 Fig S7
PMID:35012333 FYPO:0007820 Fig S6
PMID:35012333 PBO:0096728 Fig S6, new term suggested
PMID:35012333 FYPO:0008027 Fig 12B
PMID:35012333 FYPO:0008027 Fig 12B
PMID:35012333 FYPO:0008027 Fig 12B
PMID:35012333 FYPO:0001357 Fig S5A
PMID:35012333 FYPO:0001357 Fig S5A
PMID:35012333 PBO:0094777 Fig S5B
PMID:35012333 PBO:0094777 Fig S5B
PMID:35012333 FYPO:0001357 Fig S4
PMID:35012333 FYPO:0001357 Fig S4
PMID:35012333 FYPO:0000080 Fig S4
PMID:35012333 FYPO:0000080 Fig S4
PMID:35012333 FYPO:0000080 Fig S4
PMID:35012333 FYPO:0000080 Fig S4
PMID:35012333 FYPO:0001357 Fig S3
PMID:35012333 FYPO:0001357 Fig S3
PMID:35012333 FYPO:0001357 Fig S3
PMID:35012333 FYPO:0002085 Fig S3
PMID:35012333 FYPO:0001357 Fig S2
PMID:35012333 FYPO:0007820 Fig 13
PMID:35012333 FYPO:0008028 Fig 12A
PMID:35012333 FYPO:0007820 Fig 13
PMID:35012333 PBO:0096729 Fig 13
PMID:35012333 PBO:0096730 Fig 13
PMID:35012333 PBO:0096731 Fig 13, new term suggested
PMID:35012333 PBO:0096731 Fig 13, new term suggested
PMID:35012333 PBO:0096728 Fig 13, new term suggested
PMID:35012333 PBO:0096731 Fig 13, new term suggested
PMID:35012333 PBO:0096731 Fig 13, new term suggested
PMID:35012333 PBO:0096732 Fig 13
PMID:35012333 PBO:0096729 Fig 13
PMID:35012333 PBO:0096732 Fig 13
PMID:35012333 FYPO:0001357 Fig 11A
PMID:35012333 FYPO:0001357 Fig 11A
PMID:35012333 FYPO:0001357 Fig 11A
PMID:35012333 FYPO:0001357 Fig 11A
PMID:35012333 FYPO:0001357 Fig 11A
PMID:35012333 FYPO:0000080 Fig 11A
PMID:35012333 FYPO:0000080 Fig 11A
PMID:35012333 FYPO:0000080 Fig 11A
PMID:35012333 FYPO:0000080 Fig 11A
PMID:35012333 FYPO:0000080 Fig 11A
PMID:35012333 FYPO:0000080 Fig 11A
PMID:35012333 FYPO:0000080 Fig 11A
PMID:35012333 PBO:0094777 Fig 11B
PMID:35012333 PBO:0094777 Fig 11B
PMID:35012333 PBO:0094738 Fig 11B
PMID:35012333 PBO:0094738 Fig 11B
PMID:35012333 PBO:0094738 Fig 11B
PMID:35012333 PBO:0094738 Fig 11B
PMID:35012333 PBO:0094738 Fig 11B
PMID:35012333 PBO:0094738 Fig 11B
PMID:35012333 FYPO:0002061 Described in Garg et al. (NAR 2020) -PMID: 33010152
PMID:35012333 FYPO:0002061 Described in Garg et al. (NAR 2020) -PMID: 33010152
PMID:35012333 FYPO:0001357 Fig 10A
PMID:35012333 FYPO:0001357 Fig 10A
PMID:35012333 FYPO:0001357 Fig 10A
PMID:35012333 FYPO:0001357 Fig 10A
PMID:35012333 FYPO:0001357 Fig 10A
PMID:35012333 FYPO:0001357 Fig 10A
PMID:35012333 FYPO:0001357 Fig 10A
PMID:35012333 FYPO:0001357 Fig 10A
PMID:35012333 FYPO:0001357 Fig 10A
PMID:35012333 FYPO:0001357 Fig 10A
PMID:35012333 FYPO:0001357 Fig 10A
PMID:35012333 FYPO:0001357 Fig 10A
PMID:35012333 PBO:0094771 Fig 4
PMID:35012333 PBO:0094771 Fig 10B
PMID:35012333 PBO:0094771 Fig 10B
PMID:35012333 PBO:0094771 Fig 10B
PMID:35012333 PBO:0094771 Fig 10B
PMID:35012333 PBO:0094738 Fig 10B
PMID:35012333 PBO:0094738 Fig 10B
PMID:35012333 PBO:0094738 Fig 10B
PMID:35012333 PBO:0094738 Fig 10B
PMID:35012333 PBO:0094738 Fig 10B
PMID:35012333 PBO:0094738 Fig 10B
PMID:35012333 PBO:0094738 Fig 10B
PMID:35012333 PBO:0094738 Fig 10B
PMID:35012333 FYPO:0001357 Fig 4
PMID:35012333 PBO:0093553 Fig 8A
PMID:35012333 PBO:0093555 Fig 8A
PMID:35012333 PBO:0094738 Fig 8B
PMID:35012333 PBO:0094771 Fig 8B
PMID:35012333 PBO:0093557 Fig 7A
PMID:35012333 PBO:0093557 Fig 7A
PMID:35012333 PBO:0093555 Fig 7A
PMID:35012333 PBO:0093555 Fig 7A
PMID:35012333 PBO:0094777 Fig 7B
PMID:35012333 PBO:0094777 Fig 7B
PMID:35012333 PBO:0094777 Fig 7B
PMID:35012333 PBO:0094738 Fig 7B
PMID:35012333 PBO:0094738 Fig 7B
PMID:35012333 PBO:0094738 Fig 7B
PMID:35012333 PBO:0093553 Fig 7A
PMID:35012333 FYPO:0001357 Fig 7A
PMID:35012333 FYPO:0001357 Fig 7A
PMID:35012333 FYPO:0001357 Fig 6A
PMID:35012333 FYPO:0001357 Fig 6A
PMID:35012333 PBO:0094771 Fig 6B
PMID:35012333 PBO:0094771 Fig 6B
PMID:35012333 PBO:0093558 Fig 5A
PMID:35012333 PBO:0093558 Fig 5A
PMID:35012333 PBO:0093558 Fig 5A
PMID:35012333 PBO:0093558 Fig 5A
PMID:35012333 PBO:0093558 Fig 5A
PMID:35012333 PBO:0093558 Fig 5A
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PMID:35012333 PBO:0093558 Fig 5A
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PMID:35012333 PBO:0093557 Fig 5A
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PMID:35012333 PBO:0093554 Fig 5A
PMID:35012333 PBO:0093554 Fig 5A
PMID:35012333 PBO:0094738 Fig 5B
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PMID:35012333 PBO:0094738 Fig 5B
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PMID:35012333 PBO:0094738 Fig 5B
PMID:35012333 PBO:0094738 Fig 5B
PMID:35012333 PBO:0094738 Fig 5B
PMID:35012333 PBO:0094771 Fig 4B
PMID:35012333 PBO:0094777 Fig 4B
PMID:35012333 PBO:0094777 Fig 4B
PMID:35012333 PBO:0094777 Fig 4B
PMID:35012333 PBO:0094738 Fig 5B
PMID:35012333 PBO:0094738 Fig 5B
PMID:35012333 PBO:0094738 Fig 5B
PMID:35012333 FYPO:0001357 Fig 4A
PMID:35012333 FYPO:0001357 Fig 4A
PMID:35012333 FYPO:0001357 Fig 4A
PMID:35012333 FYPO:0001357 Fig 4A
PMID:35012333 FYPO:0001357 Fig 4A
PMID:35012333 FYPO:0001357 Fig 4A
PMID:35012333 PBO:0093558 Fig 4A
PMID:35012333 PBO:0093558 Fig 4A
PMID:35012333 PBO:0093558 Fig 4A
PMID:35012333 FYPO:0001357 Fig 2A
PMID:35012333 PBO:0094771 Fig 2B
PMID:35012333 PBO:0093553 Fig 2A
PMID:35012333 PBO:0093553 Fig 2A
PMID:35012333 PBO:0093553 Fig 2A
PMID:35012333 PBO:0094738 Fig 2B
PMID:35012333 PBO:0094738 Fig 2B
PMID:35012333 PBO:0094738 Fig 2B
PMID:35012333 PBO:0093553 Fig 1A
PMID:35012333 PBO:0093553 Fig 1A
PMID:35012333 PBO:0093561 Fig 1A
PMID:35012333 PBO:0093561 Fig 1A
PMID:35012333 PBO:0093561 Fig 1A
PMID:35012333 FYPO:0001357 Fig 1A
PMID:35012333 FYPO:0001357 Fig 1A
PMID:35012333 FYPO:0001357 Fig 1A
PMID:35012333 GO:0006799 from polyphosphate absent from cell
PMID:35024575 PBO:0098549 Conclusion is dawn by comparing Fig. 1H and Fig. 1I in https://www.micropublication.org/journals/biology/micropub-biology-000508.
PMID:35024575 PBO:0098550 Conclusion is dawn by comparing Fig. 1H and Fig. 1I in https://www.micropublication.org/journals/biology/micropub-biology-000508.
PMID:35058438 PBO:0112402 abolished figure 1E
PMID:35058438 PBO:0112402 abolished figure 1E
PMID:35058438 PBO:0112402 figure 1j
PMID:35075549 PBO:0095255 -ve regulation stat phase
PMID:35075549 PBO:0095252 ****STATIONARY PhASE**** the protein level of Fzo1 is unstable during the stationary phase.
PMID:35075549 PBO:0095254 (Fig. 3). We found that Fzo1 protein was not degraded at late time points in the ∆rsv2 mutant
PMID:35075549 PBO:0095254 (Fig. S1) The results showed that Fzo1 protein was not degraded at late time points only in the Δubc8 mutant (Fig. 4). Fzo1 protein was not degraded in ∆rsv2 and Δubc8 mutants after longer incubation times (60 and 72 h)
PMID:35075549 PBO:0095254 (Fig. 5) We found that when Fzo1 protein was overexpressed, it was no longer degraded at late time points
PMID:35075549 PBO:0095255 -v regulation, stationary phase
PMID:35079912 PBO:0095303 (Figure 3A) 25 µM of iron chelator bathophenanthroline disulfonate (BPS) was added to YES media to create iron-depleted condition.
PMID:35079912 PBO:0105959 (Figure 3A) Fe2(SO4)3 was added to YES media for a final concentration of 2.75 mM.
PMID:35079912 PBO:0105959 (Figure 3A) Fe2(SO4)3 was added to YES media for a final concentration of 2.75 mM.
PMID:35079912 PBO:0105960 We found that only Δfio1 cells were sensitive to Cu2+
PMID:35079912 PBO:0095304 (Figure 3A) 25 µM of iron chelator bathophenanthroline disulfonate (BPS) was added to YES media to create iron-depleted condition.
PMID:35082773 PBO:0093560 Figure 1A
PMID:35082773 PBO:0096833 (Figure 5A). we found that the protein level of Cdr2 in ksg1-208 cells was significantly lower than that in wild-type cells (Figures 4A,B),
PMID:35082773 PBO:0096834 Figure 4c In contrast, a fraction of ksg1-208 cells showed septum or division site localized Cdr2-mEGFP in the dividing cells at 27◦C, indicating the cortex dissociation of Cdr2 was hindered.
PMID:35082773 PBO:0096835 (Figure 5A) Western blot analysis showed that the level of Cdc25 protein was dramatically lower in ksg1-208 cells than that in wild-type cells, indicating that Ksg1 played a crucial role in the accumulation of Cdc25 protein
PMID:35082773 PBO:0096835 (Figure 5A) In addition, the Cdc25 protein level decreased in ppk21 and cdr2 cells as well, indicating the role of Ppk21 and Cdr2 on regulating Cdc25 protein level .
PMID:35082773 PBO:0096835 (Figure 5A). In addition, the Cdc25 protein level decreased in ppk21 and cdr2 cells as well, indicating the role of Ppk21 and Cdr2 on regulating Cdc25 protein level
PMID:35082773 PBO:0096832 (Figures 4A,B) we found that the protein level of Cdr2 in ksg1-208 cells was significantly lower than that in wild-type cells
PMID:35082773 FYPO:0000648 It should be noted that cdr2+ overexpressed wild-type cells showed a shorter cell length at 27◦C, but a longer cell length at 35◦C than cdr2+ non-overexpressed wild-type cells (Figure 3B).
PMID:35082773 PBO:0095096 (Figure 3C). In addition, the cdr2+ overexpressed wild-type cells showed a higher septation index than cdr2+ non-overexpressed wild-type cells at 35◦C
PMID:35082773 FYPO:0003503 (Figures 3A,B) overexpression of cdr2+ also reversed the defects in the cell length and the septation index of ksg1-208 cells
PMID:35082773 FYPO:0000339 (Figure 2D and Supplementary Figure 1) The results showed that the septation ring of the ksg1-208 delta-ppk21 double mutant was off-centered at 33◦C, which was more severe than that of ksg1-208 cells
PMID:35082773 PBO:0096314 (Figures 2D,E) results showed that ksg1-208 ppk21 cells exhibited a longer cell length than either ksg1-208 or ppk21 cells at both 27 and 33◦C
PMID:35082773 PBO:0096830 (Figure 2B) ...which was recovered by the overexpression of ppk21+
PMID:35082773 PBO:0096311 (Figure 2A) significantly longer than that of wild-type cells at 27◦C
PMID:35082773 PBO:0093561 Figure 1A
PMID:35082773 FYPO:0002061 (Figure 2C) 33 degrees
PMID:35082773 PBO:0096831 Figure 2B...which was recovered by the overexpression of ppk21+
PMID:35099006 PBO:0096598 Increased percentage of septated cells at both permissive and restrictive temperature.
PMID:35099006 PBO:0093558 The growth rate of pkd2-B42 at the restrictive temperature of 36C or higher is 80% lower than wild-type cells.
PMID:35099006 GO:0009992 pkd2 mutants show temporary deflation followed by reinflation. pkd2-B42 has 50% lower spring constant as measured by Atomic Force Microscopy implicating reduced cellular stiffness. This indicates a reduced ability of this mutant at maintaining cellular turgor.
PMID:35108037 FYPO:0000674 Figure S2D
PMID:35108037 FYPO:0002177 Figure S2A-C
PMID:35108037 FYPO:0001903 Figure S2A-C
PMID:35108037 FYPO:0001903 Figure S2A-C
PMID:35108037 FYPO:0001903 Figure S2A-C
PMID:35108037 PBO:0104534 Figure 2B - Pxl1(AxxA1-6) reduced binding to Cdc15C(aa441-end) compared to wildtype Pxl1
PMID:35108037 PBO:0104528 Pxl1 (aa177-188 P181A, P184A) abolished binding to Cdc15 SH3 and Cdc15C1(aa600-end), Figure 2D
PMID:35108037 PBO:0104534 Pxl1-AxxA6 reduced binding to full-length Cdc15 (Figure 3A) and Cdc15 C1 (Figure S1A)
PMID:35108037 PBO:0104535 Pxl1-P18A+AxxA6 reduced binding to full-length Cdc15 compared to wild type Pxl1 (Figure 3A)
PMID:35108037 PBO:0104535 Pxl1-P18A reduced binding to full-length Cdc15 compared to wild-type Pxl1 (Figure 3A)
PMID:35108037 PBO:0104536 Pxl1-AxxA1-3 bound Cdc15C1(aa600-end) just as well as wild type Pxl1 (Figure S1A)
PMID:35108037 PBO:0104534 Mutant reduced binding to Cdc15C1(aa600-end) compared to wild type Pxl1 (Figure S1A)
PMID:35108037 PBO:0104534 Mutant reduced binding to Cdc15C1(aa600-end) compared to wild type Pxl1 (Figure S1A)
PMID:35108037 PBO:0104534 Mutant reduced binding to Cdc15C1(aa600-end) compared to wild type Pxl1 (Figure S1A)
PMID:35108037 PBO:0104536 Mutant bound Cdc15C1(aa600-end) as well as wildtype Pxl1 (Figure S1A)
PMID:35108037 FYPO:0006187 Figure S3A (25C)
PMID:35108037 FYPO:0006187 Figure S3A (25C)
PMID:35108037 FYPO:0006187 Figure S3A (25C)
PMID:35108037 FYPO:0007828 Figure S3A (25C)
PMID:35108037 FYPO:0007828 Figure S3A
PMID:35108037 FYPO:0007828 Figure S3A (25C)
PMID:35108037 FYPO:0004895 Figure S3A (25C)
PMID:35108037 FYPO:0001365 Figure S3A (25C)
PMID:35108037 FYPO:0001365 Figure S3A (25C)
PMID:35108037 PBO:0104537 Figure S3B (25C)
PMID:35108037 FYPO:0002060 Figure S2E
PMID:35108037 FYPO:0002060 Figure S2E
PMID:35108037 FYPO:0002060 Figure S2E
PMID:35108037 FYPO:0002060 Figure S2E
PMID:35108037 FYPO:0002060 Figure S2E
PMID:35108037 FYPO:0002060 Figure S2E
PMID:35108037 FYPO:0002060 Figure S2E
PMID:35108037 FYPO:0002060 Figure S2E
PMID:35108037 FYPO:0002060 Figure S2E
PMID:35108037 FYPO:0002060 Figure S2E
PMID:35108037 FYPO:0002060 Figure S2E
PMID:35108037 FYPO:0002060 Figure S2E
PMID:35108037 FYPO:0002060 Figure S2E
PMID:35108037 FYPO:0002060 Figure S2E
PMID:35108037 FYPO:0002060 Figure S2E
PMID:35108037 GO:0005515 Figure 1B, 1D-F, 2B-E, 3A-B, S1A-B
PMID:35108037 PBO:0104527 in vitro binding assay, Figure 3B
PMID:35108037 PBO:0104528 in vitro binding assay with purified Cdc15 F-BAR domain and purified Pxl1 (Fig 1E)
PMID:35108037 PBO:0104529 Figure 4A,C
PMID:35108037 PBO:0104530 Figure 4A,C
PMID:35108037 PBO:0104531 Figure 4B,D
PMID:35108037 PBO:0104532 Figure 4B,D
PMID:35108037 PBO:0104532 Figure 4B,D
PMID:35108037 PBO:0104533 Figure S1D-E
PMID:35108037 FYPO:0002141 Figure S2D (19c)
PMID:35108037 FYPO:0000674 Figure S2D
PMID:35108037 FYPO:0001357 Figure S2D(25,29,32)
PMID:35108037 FYPO:0003809 Figure S2D
PMID:35108037 FYPO:0004675 Fig S2D
PMID:35108037 FYPO:0002141 Figure S2D
PMID:35108037 FYPO:0002141 Figure S2D
PMID:35108037 FYPO:0000674 Figure S2D
PMID:35108037 FYPO:0001357 Figure S2D (25,29,32)
PMID:35108037 FYPO:0001357 Figure S2D (25,29,32)
PMID:35108037 FYPO:0002060 Figure S2E
PMID:35108037 FYPO:0002060 Figure S2E
PMID:35108037 FYPO:0003809 Figure S2D
PMID:35108037 FYPO:0003809 Figure S2D
PMID:35108037 FYPO:0004675 Fig S2D
PMID:35108037 FYPO:0004675 Fig S2D
PMID:35108037 FYPO:0002177 Figure S2A-C
PMID:35108037 FYPO:0002177 Figure S2A-C
PMID:35108037 FYPO:0002060 Figure S2E
PMID:35157728 PBO:0100683 The Δbdf2 muta- tion also suppresses the elevated levels of Gcn5 at the subtelomeric chromatin in Δtor1 cells (Fig 4E).
PMID:35157728 FYPO:0003555 Figure2 A
PMID:35157728 FYPO:0003555 Figure2 A
PMID:35157728 FYPO:0003555 Figure2 A
PMID:35157728 FYPO:0003555 Figure2 A
PMID:35157728 PBO:0100686 Significantly, Δbdf2 restores low levels of Gcn5 binding at MBF promoters in Δtor1 cells under normal growth conditions and also restores the normal pattern of an increased level of Gcn5 in response to HU (Fig 6C).
PMID:35157728 FYPO:0006395 Consistently, we detected higher levels of H3K9Ac at subtelomeric genes in Δtor1 cells compared to wild type cells, and this defect was suppressed by either Δgcn5 or Δbdf2 (Fig 4C)
PMID:35157728 PBO:0100682 Consistently, we detected higher levels of H3K9Ac at subtelomeric genes in Δtor1 cells compared to wild type cells, and this defect was suppressed by either Δgcn5 or Δbdf2 (Fig 4C)
PMID:35157728 FYPO:0006395 Consistently, we detected higher levels of H3K9Ac at subtelomeric genes in Δtor1 cells compared to wild type cells, and this defect was suppressed by either Δgcn5 or Δbdf2 (Fig 4C)
PMID:35157728 FYPO:0006742 Figure2 A
PMID:35157728 PBO:0100681 We detected a markedly higher level of Gcn5 binding at subte- lomeric genes in Δtor1 cells, compared with wild type cells (Fig 4A).
PMID:35157728 FYPO:0006742 Figure2 A
PMID:35157728 FYPO:0006742 Figure2 A
PMID:35157728 FYPO:0003555 Figure2 A
PMID:35157728 PBO:0110918 30 fold. Fig 2
PMID:35157728 PBO:0093824 25%
PMID:35157728 FYPO:0003555 Figure2 A
PMID:35157728 PBO:0093824 24%
PMID:35157728 PBO:0110919 280 fold. Fig 2
PMID:35157728 PBO:0093580 no supression
PMID:35157728 FYPO:0003555 Figure2 A
PMID:35157728 FYPO:0006740 Unexpectedly, although there is no increase in MBF-dependent transcription, we detected an increase in Gcn5 binding at the promoters of cdc22+ or cdc18+ in Δtor1 or Δgad8 cells under normal or replication stress conditions (Fig 5A)
PMID:35157728 FYPO:0003555 Figure2 A
PMID:35157728 FYPO:0003555 Figure2 A
PMID:35157728 PBO:0100686 Significantly, Δbdf2 restores low levels of Gcn5 binding at MBF promoters in Δtor1 cells under normal growth conditions and also restores the normal pattern of an increased level of Gcn5 in response to HU (Fig 6C).
PMID:35157728 PBO:0110920 120 fold. Fig 2
PMID:35157728 GO:0000122 Tor1 inhibits the binding of Gcn5 at sub-telomeric genes and MBF promoters
PMID:35157728 FYPO:0003555 Figure2 A
PMID:35157728 FYPO:0003555 Figure2 A
PMID:35157728 FYPO:0003555 Figure2 A
PMID:35157728 PBO:0100685 Unexpectedly, although there is no increase in MBF-dependent transcription, we detected an increase in Gcn5 binding at the promoters of cdc22+ or cdc18+ in Δtor1 or Δgad8 cells under normal or replication stress conditions (Fig 5A)
PMID:35157728 PBO:0100685 Unexpectedly, although there is no increase in MBF-dependent transcription, we detected an increase in Gcn5 binding at the promoters of cdc22+ or cdc18+ in Δtor1 or Δgad8 cells under normal or replication stress conditions (Fig 5A)
PMID:3516412 GO:0004672 activated_by(CHEBI:18420)
PMID:35171902 PBO:0104711 . Interestingly, although git3Δ nmt41-epe1+ cells form heterochromatin at pericentric repeats,
PMID:35171902 PBO:0104712 polysome profiling
PMID:35171902 PBO:0104712 polysome profiling
PMID:35171902 PBO:0101109 nterestingly, we found that Epe1 protein levels are significantly reduced in git3Δ nmt41-epe1+ and pka1Δ nmt41-epe1+ cells (Fig 2F)
PMID:35171902 FYPO:0003574 H3K9me2 levels at dh repeats are restored close to wild-type levels in git3Δ nmt41-epe1+ cells (Fig 1E).
PMID:35171902 PBO:0104709 Consistent with the results of the genetic screen, serial dilution analyses show that git1Δ, git3Δ, git5Δ, gpa2Δ, pka1Δ, and cyr1Δ all rescue silenc- ing defects of otr::ura4+ caused by Epe1 overexpression, as indicated by better growth on EMM medium containing 5-FOA (Fig 1D)
PMID:35194019 FYPO:0002061 Fig S10 (tetrad analysis)
PMID:35194019 FYPO:0001357 Fig S10 (tetrad analysis)
PMID:35194019 PBO:0093562 TBZ 15ug/ml
PMID:35194019 PBO:0093564 TBZ 15ug/ml
PMID:35194019 PBO:0093562 TBZ 15ug/ml
PMID:35194019 PBO:0093562 TBZ 15ug/ml
PMID:35194019 FYPO:0000964 TBZ 15ug/ml
PMID:35194019 FYPO:0003412 Figur 5C forward strand RT-qPCR (dh repeat)
PMID:35194019 FYPO:0004742 Figur 5C forward strand RT-qPCR (dh repeat)
PMID:35194019 FYPO:0004742 Figure 5C forward strand RT-qPCR (dh repeat)
PMID:35194019 FYPO:0003412 Figure 5C forward strand RT-qPCR (dh repeat)
PMID:35194019 FYPO:0004742 Figure 5C forward strand RT-qPCR (dh repeat)
PMID:35194019 FYPO:0004742 Figure 5C forward strand RT-qPCR (dh repeat)
PMID:35194019 PBO:0096785 Figur 5D
PMID:35194019 PBO:0032778 Figur 5D
PMID:35194019 FYPO:0001357 Fig S10 (tetrad analysis)
PMID:35194019 FYPO:0001357 Fig S10 (tetrad analysis)
PMID:35194019 FYPO:0002061 Fig S10 (tetrad analysis)
PMID:35194019 FYPO:0001357 Fig S10 (tetrad analysis)
PMID:35194019 FYPO:0001357 Fig S10 (tetrad analysis)
PMID:35277511 FYPO:0002239 telomere southern (experiment)
PMID:35277511 FYPO:0002060 growth >48 hrs, growth to exponential phase
PMID:35277511 FYPO:0002239 telomere southern (experiment)
PMID:35286199 PBO:0093561 Fig. 1
PMID:35286199 PBO:0093561 Fig. 1
PMID:35286199 PBO:0093561 Fig. 1
PMID:35286199 PBO:0093561 Fig. 1
PMID:35286199 FYPO:0002058 Fig. 1
PMID:35286199 FYPO:0002058 Fig. 1
PMID:35286199 FYPO:0002058 Fig. 1
PMID:35286199 FYPO:0002058 Fig. 1
PMID:35286199 FYPO:0002058 Fig. 1
PMID:35286199 PBO:0093561 Fig. 1
PMID:35286199 FYPO:0002060 Fig. 1
PMID:35286199 FYPO:0002058 Fig. 1
PMID:35286199 FYPO:0002061 Fig. 1
PMID:35286199 FYPO:0000276 Fig. 2
PMID:35286199 PBO:0107133 Fig. 4
PMID:35286199 FYPO:0000069 Fig. 4
PMID:35286199 FYPO:0003227 Fig. 4
PMID:35286199 PBO:0101442 Fig. 3
PMID:35286199 FYPO:0001357 Fig. 1
PMID:35286199 FYPO:0001357 Fig. 1
PMID:35286199 PBO:0093559 Fig. 1
PMID:35286199 PBO:0107132 Fig. 2
PMID:35286199 FYPO:0001357 Fig. 1
PMID:35286199 PBO:0093559 Fig. 1
PMID:35286199 PBO:0093559 Fig. 1
PMID:35286199 PBO:0093560 Fig. 1
PMID:35286199 PBO:0107138 Fig. 5
PMID:35286199 PBO:0107137 Fig. 5
PMID:35286199 PBO:0107135 Fig. 4
PMID:35286199 PBO:0107134 Fig. 4
PMID:35286199 FYPO:0000339 Fig. 4
PMID:35293864 FYPO:0007974 Fig. 4 - figure supplement 2 We found that in both les1Δ and nem1Δ cells microtubule growth speed inside the nuclear bridge was faster than in wild-type cells
PMID:35293864 PBO:0096311 Note: not sure about the term name and the child. Fig. 3 supp 1 A, C
PMID:35293864 PBO:0106719 Fig. 5E Ase1 is required for normal rescue distribution
PMID:35293864 FYPO:0007974 Fig. 5F,G The decrease in growth speed associated with internalisation of microtubules in the nuclear membrane bridge is reduced upon Ase1 deletion
PMID:35293864 PBO:0106718 Fig. 5 supp 3E
PMID:35293864 PBO:0106716 Fig. 2 - Figure supplement 1 klp5Δklp6Δ cells exhibited slightly longer microtubule growth events
PMID:35293864 FYPO:0007972 mal3Δ cells exhibited lower microtubule growth speed throughout anaphase B Fig. 2G
PMID:35293864 FYPO:0007971 Fig. 5F,G The decrease in growth speed associated with internalisation of microtubules in the nuclear membrane bridge is reduced upon Ase1 deletion
PMID:35293864 FYPO:0007974 Fig. 4 - figure supplement 2 We found that in both les1Δ and nem1Δ cells microtubule growth speed inside the nuclear bridge was faster than in wild-type cells
PMID:35293864 PBO:0106717 Fig. 2 - Figure supplement 2F
PMID:35293864 PBO:0106718 Fig. 2 - Figure supplement 2E
PMID:35300005 FYPO:0001029 100 ug/ml canavanine
PMID:35314193 GO:0016791 Cobalt/nickel-dependent inorganic pyrophosphatase activity, Figure 1
PMID:35314193 FYPO:0002085 Figure 12
PMID:35314193 PBO:0098306 Figures 1 and 3
PMID:35314193 FYPO:0002085 Figure 12
PMID:35314193 PBO:0094738 Figure 12
PMID:35314193 PBO:0094777 Figure 12
PMID:35314193 PBO:0094738 Figure 12
PMID:35314193 PBO:0110566 Cobalt/nickel-dependent inorganic pyrophosphatase activity, Figure 3
PMID:35314193 PBO:0110566 Cobalt/nickel-dependent inorganic pyrophosphatase activity, Figure 4
PMID:35314193 GO:0016791 Cobalt/nickel-dependent inorganic pyrophosphatase activity, Figure 4
PMID:35314193 PBO:0098306 Figures 1 and 3
PMID:35314193 PBO:0098307 Figure 8
PMID:35314193 PBO:0098307 Figure 8
PMID:35314193 PBO:0098307 Figure 8
PMID:35314193 PBO:0098307 Figure 8
PMID:35314193 PBO:0098307 Figure 8
PMID:35314193 PBO:0098307 Figure 10
PMID:35314193 PBO:0098306 Figure 10
PMID:35320724 FYPO:0002060 Figure 4
PMID:35320724 PBO:0107692 Figure S1
PMID:35320724 FYPO:0001491 Figure 2C
PMID:35320724 FYPO:0001491 Figure 2C
PMID:35320724 PBO:0107691 Figure 3, S1
PMID:35320724 PBO:0107690 Figure 3, S1
PMID:35320724 PBO:0107700 Figure 7
PMID:35320724 PBO:0107700 Figure 7
PMID:35320724 PBO:0107702 Figure 4
PMID:35320724 PBO:0107703 Figure 4
PMID:35320724 PBO:0107702 Figure S4
PMID:35320724 PBO:0107704 Figure S5
PMID:35320724 PBO:0096891 Figure 4
PMID:35320724 FYPO:0002061 Figure 4
PMID:35320724 FYPO:0001489 Figure 2A even if securin levels were elevated to only about eight times the wild-type level (Kamenz et al., 2015) (Figure 2A
PMID:35320724 FYPO:0001234 Figure 4
PMID:35320724 FYPO:0002060 Figure 4
PMID:35320724 PBO:0107690 Figure 4
PMID:35320724 PBO:0107693 Figure 4
PMID:35320724 FYPO:0002061 Figure 5
PMID:35320724 FYPO:0002060 Figure 5
PMID:35320724 FYPO:0002061 Figure S6D
PMID:35320724 PBO:0107690 Figure 6
PMID:35320724 PBO:0107690 Figure S6B
PMID:35320724 PBO:0107705 Figure S5
PMID:35320724 PBO:0107692 Figure 1B, 5B
PMID:35320724 PBO:0107691 Figure 1B, 5B
PMID:35320724 PBO:0107690 Figure 1B, 2D, 5B, 6C, 7B, 7C
PMID:35320724 PBO:0107689 Figure S6G
PMID:35320724 PBO:0107707 Figure 3a Similar results were obtained for Cdc13-GFP (Figure S1). Hence securin and Cdc13 are still efficiently targeted for proteasomal degradation in the cdc48-353 mutant.
PMID:35320724 PBO:0107706 figure 3a However, the cellular degradation kinetics of securin-GFP were indistinguishable in cdc48+ and cdc48-353 mutant cells after normalizing for the reduced level (Figure 3A), suggesting that se- curin degradation was unaffected in the cdc48-353 mutant.
PMID:35320724 FYPO:0004705 Consistent with the low levels of separase, we found that sister chromatid separation was delayed in cdc48- 353 mutant cells relative to the decline in CDK1 activity at mitotic exit (Figure 1C).
PMID:35320724 PBO:0107702 Figure 5
PMID:35320724 FYPO:0001489 Figure 6
PMID:35320724 PBO:0107690 Figure S7
PMID:35320724 PBO:0107698 Figure 5
PMID:35320724 PBO:0107697 Figure 5
PMID:35320724 PBO:0107696 Figure 5
PMID:35320724 PBO:0107695 Figure 4
PMID:35320724 FYPO:0002060 Figure 4
PMID:35320724 PBO:0107694 Figure 4
PMID:35320724 FYPO:0001489 Figure 2C
PMID:35320724 FYPO:0002060 Figure 6
PMID:35320724 FYPO:0002061 Figure 6
PMID:35320724 FYPO:0002060 Figure 6
PMID:35320724 FYPO:0002061 Figure 6
PMID:35320724 FYPO:0001489 Figure 6
PMID:35320724 FYPO:0002060 Figure 6
PMID:35320724 PBO:0107699 Figure 7
PMID:35320724 PBO:0107699 Figure 7
PMID:35320724 PBO:0107700 Figure 7
PMID:35320724 PBO:0107701 Figure 7
PMID:35325114 FYPO:0007990 TERM REQUESTED growth auxotrophic for isoleucine
PMID:35325114 FYPO:0007991 TERM REQUESTED growth auxotrophic for valine
PMID:35333350 FYPO:0002485 (Figure 7) rec8-F204S mutant is defective in LinE formation and recombination
PMID:35333350 FYPO:0000900 (Figure 7) rec8-F204S mutant is defective in LinE formation and recombination (Rec10-mCherry forms aberrant dotty or filamentous aggregates within the nucleus, similar to rec8∆.)
PMID:35333350 GO:0007129 These results suggest that Wpl1 plays a role in alignment of homologs through Rec8-dependent formation of axis-loop chromatin structure.
PMID:35333350 FYPO:0007939 (Figures 2A and B) Hi-C analysis for rec10Δ and rec12Δ cells showed X-shaped contacts similar to wild-type cells AND (Figure 3A).... punctate Hi-C interactions observed in the wild-type were mostly lost in rec8Δ
PMID:35333350 FYPO:0007939 (Figures 2A and B) Hi-C analysis for rec10Δ and rec12Δ cells showed X-shaped contacts similar to wild-type cells AND (Figure 3A).... punctate Hi-C interactions observed in the wild-type were mostly lost in rec8Δ
PMID:35333350 FYPO:0000197 Supplementary Figure S4B) wpl1Δ rarely showed torsional turning (Supplementary Figure S4C, Supplemen- tal Movies 1, and 2) during horsetail movements that is important for the alignment of homologs
PMID:35333350 GO:0007129 These results suggest that Wpl1 plays a role in alignment of homologs through Rec8-dependent formation of axis-loop chromatin structure.
PMID:35333350 FYPO:0001357 (Figure S5B)
PMID:35333350 FYPO:0001357 (Figure S5B)
PMID:35333350 FYPO:0003054 during horsetail/ prophase
PMID:35333350 PBO:0102339 These results sugest that in the rec8-F204S mutant, as in rec8Δ, the Rec8- dependent meiosis-specific short chromatin loop structures are lost, resulting in a concomitant loss of the structural property of the chromosome required for proper alignment.
PMID:35333350 FYPO:0002092 rec8-S552P and rec8Δ, which showed the cohesion defect, were used as a control strain (see Supplementary Figure S5C, S5D, and S5E for details of the rec8-S552P mutant)
PMID:35333350 FYPO:0007942 figure 4c,e also supported by (Figure 4A), Fluorescence images of Rec8- GFP showed that axial structures in meiotic chromosomes were more prominent in wpl1Δ than in the wild-type
PMID:35333350 FYPO:0007945 Figure S4B
PMID:35333350 FYPO:0007944 DECREASED NUMBER (figure 6 and figure 5e, S6BC) defective loop formation also supported by increased distance between the telomere-ade8 distance was longer in the rec8-F204S mutant than in the wild-type, suggesting that the chromatin of the rec8-F204S mutant was flexible and was abnormally stretched by the traction of the horsetail movement
PMID:35333350 FYPO:0002890 (Figure 5D, Supplemental Movies 1, and 3) In the rec8-F204S mutant, only the leading edge of the nucleus followed the horsetail movement, while the bulk of chromosomes were left behind, similar to rec8Δ
PMID:35333350 FYPO:0007945 (Figure 6B). The alignment index of chromosome 1 at meiotic prophase (2.5 h) decreased in rec8-F204S (1.6) compared with the wild-type (rec8-wt, 2.6)
PMID:35333350 FYPO:0003179 (Figure 7)
PMID:35333350 FYPO:0003613 (Figure 5C) The rec8-F204S mutant maintained sister chromatid cohesion as assessed at the cut3 gene locus
PMID:35354597 PBO:0112113 Fig. 6D
PMID:35354597 FYPO:0003750 Fig. 2D
PMID:35354597 FYPO:0003750 Fig. 2D
PMID:35354597 FYPO:0003750 Fig. 2C
PMID:35354597 FYPO:0003750 Fig. 2C
PMID:35354597 FYPO:0003750 Fig. 2B
PMID:35354597 FYPO:0003750 Fig. 2C
PMID:35354597 FYPO:0003750 Fig. 2B
PMID:35354597 GO:0044732 Fig. 5F
PMID:35354597 PBO:0112113 Fig. 6D
PMID:35354597 PBO:0112113 Fig. 6D
PMID:35354597 PBO:0112114 Fig. 6B
PMID:35354597 PBO:0112114 Fig. 6B
PMID:35354597 GO:0044732 Fig. 5F
PMID:35354597 PBO:0112113 Fig. 6B
PMID:35354597 GO:0044732 Fig. 5F
PMID:35354597 GO:0044732 Fig. 5F
PMID:35354597 GO:0044732 Fig. 5F
PMID:35354597 GO:0044732 Fig. 5
PMID:35354597 PBO:0112112 NPC clusters in nup132Δ nuclei coalesced into larger clusters that preferentially localized to the SPBs in mitosis. Fig. 3F
PMID:35354597 PBO:0112111 Fig. 3E
PMID:35354597 GO:0044732 Fig. 6A
PMID:35354597 FYPO:0008171 Fig. 3D
PMID:35354597 PBO:0112110 Fig. 3A, B and C
PMID:35354597 GO:0051292 Continued NPC assembly in cdc25.22 arrested cells that have low Cdk1 activity suggests that unlike in metazoans, Cdk1 (SpCdc2) is not required for NPC assembly in S. pombe.
PMID:35354597 PBO:0112115 Fig. 6E
PMID:35354597 PBO:0112114 Fig. 6D
PMID:35416247 PBO:0095654 in presence of tschimganine
PMID:35416247 PBO:0095654 in presence of tschimganine
PMID:35416247 PBO:0095654 in presence of tschimganine
PMID:35416247 PBO:0095654 in presence of tschimganine
PMID:35416247 PBO:0092325 in presence of tschimganine
PMID:35416247 PBO:0092325 in presence of tschimganine
PMID:35416247 PBO:0092325 in presence of tschimganine
PMID:35416247 PBO:0092325 in presence of tschimganine
PMID:35512546 GO:0008266 RRM3
PMID:35536002 PBO:0100391 Fig. 12 (Note how the levels are the same as when the pyrophosphatase is inactivated in the full-length protein)
PMID:35536002 PBO:0100393 Fig. 7
PMID:35536002 PBO:0100390 Fig. 7
PMID:35536002 PBO:0100390 Fig. 7
PMID:35536002 PBO:0100390 Fig. 7
PMID:35536002 PBO:0100394 Fig. 12
PMID:35536002 PBO:0100390 Fig. 7
PMID:35536002 PBO:0100389 Fig. 8 and text
PMID:35536002 PBO:0100394 Fig. 8 & 12
PMID:35536002 PBO:0100396 Fig. 8
PMID:35536002 PBO:0100396 Fig. 8
PMID:35536002 PBO:0100392 Fig. 7
PMID:35536002 PBO:0100391 Fig. 7
PMID:35536002 PBO:0100391 Fig. 7
PMID:35536002 PBO:0100392 Fig. 7
PMID:35536002 PBO:0100395 Fig. 12
PMID:35536002 PBO:0100396 Fig. 8
PMID:35536002 PBO:0100395 Fig. 8
PMID:35536002 PBO:0100394 Fig. 12
PMID:35536002 PBO:0100392 Fig. 7
PMID:35536002 PBO:0100390 Fig. 7
PMID:35536002 PBO:0100393 Fig. 7
PMID:35609605 PBO:0099980 COMPACTION Figures 3A, 3B, and S3A
PMID:35609605 FYPO:0001009 "Figures 3A, 3B, and S3A (no rescue) dan says ""FigS3A (bottom panel) shows that ring compaction completely failed in scs2Δscs22Δmyo2-E1(aaG345R) at 36 degree. In fact, we did not directly show that these cells failed ring contraction similarly as myo2-E1(aaG345R) at high temperature (which is well known) in the paper, as we mainly focused on ring compaction process. But we have implied that in the context."""
PMID:35609605 PBO:0099976 COMPACTION I asked is this the correct genotype? Dan answered Our quantification in FigS3C (bottom panel) shows that ring compaction is slightly faster in scs2Δscs22Δmyo2-E1(aaG345R) than wt at 24 degree, although such a difference is not significant quantitatively. Qualitatively, compaction (in terms of mobility) of individual nodes was indeed faster. So, I felt reluctant to use either “normal” or “abnormal” to describe that.
PMID:35609605 FYPO:0003339 and is already defective in actomyosin � 17 compaction at the permissive temperature of 24 C (Figure S1C, video S2) and (Figures 3A, 3B, and S3A))
PMID:35609605 PBO:0099981 figure 4D
PMID:35609605 PBO:0099982 figure 4D
PMID:35609605 PBO:0099979 COMPACTION Figures 3A, 3B, and S3A (inhibiting exocytosis rescues defect of compaction)
PMID:35609605 PBO:0099978 (partial rescue) Incomplete ring compaction was still observed in myo2- E1pil1D, although such fraction was reduced as compared with myo2-E1 (Figure 3B I don't see the images - this is from the bar chart))
PMID:35609605 PBO:0099977 Figure 3 COMPACTION
PMID:35622906 PBO:0101161 OLD SPB
PMID:35639710 PBO:0097854 Figure1
PMID:35639710 PBO:0104699 Figure 2A
PMID:35639710 FYPO:0001545 Figure 1 (same as WT)
PMID:35639710 PBO:0104696 Fig 1
PMID:35639710 PBO:0097854 Figure3 confirms dominance of can1-1
PMID:35639710 PBO:0104695 Second, Any1R175C does not show an increase but rather a strong decrease in its ubiquiti- nation level.
PMID:35639710 PBO:0104696 Fig 1
PMID:35639710 PBO:0104698 Increased protein ubiquitination.
PMID:35658118 PBO:0110547 Microscopic observa- tion showed that mitochondria were tubular in acb1+ cells but became fragmented in acb1Δ cells (Fig. 1A).
PMID:35658118 PBO:0112557 By con- trast, mitochondria became fragmented/aggregated (74.4%) PLUS This result indicates that mitochondrial mass/biogenesis was reduced by the absence of Acb1 or Dnm1. Note that dnm1-deletion in acb1Δ cells did not restore mitochondrial mass (Fig. 2C)
PMID:35658118 FYPO:0001357 figure 1b a nd 3C
PMID:35658118 PBO:0093797 (phenotypoe seems to be additive on glycerol) Consistently, the growth of acb1Δ and acb1Δdnm1Δ cells on nonfer- mentable medium plates (YE plates plus 0.1% glucose and 3% glycerol) was comparable but was slower than the growth of WT and dnm1Δ cells (Fig. 2D,F).
PMID:35658118 PBO:0093559 Figure 1b and 3c
PMID:35658118 PBO:0093798 As shown in Fig. 1B, acb1Δ grew slightly slower on fermentable med- ium than acb1+ cells and much slower on nonfer- mentable medium.
PMID:35658118 FYPO:0009007 Therefore, increased cell death rather than abnormal cell division was the conse- quence of the impaired cell proliferation caused by the absence of Acb1 (Fig. 3D).
PMID:35658118 PBO:0110553 figure 2c
PMID:35658118 PBO:0110554 figure 2c
PMID:35658118 PBO:0110554 figure 2c
PMID:35658118 PBO:0109726 he expression of Dnm1 was comparable in wild-type and acb1Δ cells (Fig. 2E).
PMID:35658118 FYPO:0008137 Intriguingly, the size of lipid droplets became lar- ger and the number of lipid droplets became less as acb1+ and acb1Δ+acb1 cells grew older in nutrient- rich medium (Fig. 4C,D). By contrast, the size and number of lipid droplets did not change as acb1Δ cells grew older in nutrient-rich medium (Fig. 4C,D).
PMID:35658118 PBO:0107530 Therefore, increased cell death rather than abnormal cell division was the conse- quence of the impaired cell proliferation caused by the absence of Acb1 (Fig. 3D).
PMID:35658118 PBO:0112556 Consistent with the finding reported previously by our group [8], mitochondria formed a highly branch network (47.8%) in dnm1Δ cells (Fig. 2A,B)
PMID:35658118 FYPO:0002009 Three independent experiments consistently showed that the oxygen consumption rate of acb1Δ cells was significantly decreased when the cells were cultured in nutrient-rich medium (i.e. YE) (Fig. 3B).
PMID:35658118 PBO:0110551 Figure 2a, 2b
PMID:35658118 PBO:0110551 Figure 2a, 2b
PMID:35658118 PBO:0110548 We noticed that mito- chondrial fragmentation caused by the absence of Acb1 was more apparent when cells were cultured in nutrient- rich medium than in minimal medium.
PMID:35673994 PBO:0102716 Fig. 4E
PMID:35673994 PBO:0108178 Fig. 6
PMID:35673994 FYPO:0006108 Fig. 6
PMID:35673994 PBO:0102726 Fig. 6
PMID:35673994 FYPO:0006108 Fig. 6
PMID:35673994 PBO:0108178 Fig. 6
PMID:35673994 PBO:0108178 Fig. 5
PMID:35673994 PBO:0108178 Fig. 2B
PMID:35673994 PBO:0102728 Fig. 6
PMID:35673994 PBO:0108175 Fig. 5
PMID:35673994 FYPO:0006108 Fig. 5
PMID:35673994 PBO:0102728 Fig. 5
PMID:35673994 PBO:0102726 Fig. 5
PMID:35673994 FYPO:0006108 Fig. 5
PMID:35673994 PBO:0102727 Fig. 5
PMID:35673994 FYPO:0006108 Fig. 5
PMID:35673994 PBO:0108177 Fig. 5F
PMID:35673994 PBO:0102728 Fig. 5C
PMID:35673994 PBO:0108175 Fig. 5
PMID:35673994 PBO:0108176 Fig. 5
PMID:35673994 PBO:0102728 Fig. 5
PMID:35673994 PBO:0108175 Fig. 4E
PMID:35673994 PBO:0108174 Fig. 4E
PMID:35673994 PBO:0102716 Fig. 4E
PMID:35673994 PBO:0108173 Fig. 2B
PMID:35673994 PBO:0108173 Fig. 2B
PMID:35673994 PBO:0108172 Fig. 2B
PMID:35673994 FYPO:0005989 Fig. 2A
PMID:35673994 PBO:0108171 Fig. 2B
PMID:35673994 PBO:0102728 chimera expressed from the ura4 locus (@ura4) - kept because not assayed from fus1 locus
PMID:35673994 PBO:0102727 Fig. 2H
PMID:35673994 PBO:0102726 Fig. 2C
PMID:35673994 FYPO:0006108 Fig. 6
PMID:35673994 PBO:0108170 Fig. 3
PMID:35673994 FYPO:0007683 Fig. 3
PMID:35673994 PBO:0102720 Fig. 2D
PMID:35781263 PBO:0108273 decreased
PMID:35781263 PBO:0103077 "The Δght5 strain is always in 27 a ""low glucose state"" even when cultured in high glucose medium, and this may be the reason why the 28 lifespan extension phenotype appears."
PMID:35901126 PBO:0111628 Examination by HPLC of the nucleoside composition of purified tRNATyr(GUA) from trm6Δ and trm61Δ mutants revealed that m1A levels were less than 0.03 moles/mole, compared to 0.60 moles/mole in WT cells, whereas levels of C, m5C, and m7G were very similar in the tRNATyr(GUA) from both mutant and WT cells (Fig 1B and 1C)
PMID:35901126 PBO:0111628 Examination by HPLC of the nucleoside composition of purified tRNATyr(GUA) from trm6Δ and trm61Δ mutants revealed that m1A levels were less than 0.03 moles/mole, compared to 0.60 moles/mole in WT cells, whereas levels of C, m5C, and m7G were very similar in the tRNATyr(GUA) from both mutant and WT cells (Fig 1B and 1C)
PMID:35901126 PBO:0111629 Similarly, poison primer extension showed that tRNAiMet(CAU) was nearly completely modified with m1A58 in WT cells (97%), but not visibly modified in trm6Δ and trm61Δ mutants (although quantifica- tion with the high background gave 2.0% for trm6Δ and 2.8% in trm61Δ).
PMID:35901126 PBO:0111630 Similarly, poison primer extension showed that tRNAiMet(CAU) was nearly completely modified with m1A58 in WT cells (97%), but not visibly modified in trm6Δ and trm61Δ mutants (although quantifica- tion with the high background gave 2.0% for trm6Δ and 2.8% in trm61Δ).
PMID:35901126 PBO:0111631 These results show that S. pombe trm6+ and trm61+ are required for all detectable m1A58 modification of cytoplasmic tRNAs.
PMID:35901126 PBO:0111631 These results show that S. pombe trm6+ and trm61+ are required for all detectable m1A58 modification of cytoplasmic tRNAs.
PMID:35901126 PBO:0111632 The northern analysis revealed that tRNAiMet(CAU) levels were substantially reduced in the S. pombe trm6Δ mutants, both at 30 ̊C and 38.5 ̊C. At 30 ̊C, tRNAiMet(CAU) levels were 49% of those in WT cells, whereas each of the other eight tRNAs had levels between 82% and 121% of those in WT cells (Figs 2A, 2B and S3).
PMID:35901126 FYPO:0000674 Similarly, the temperature sensitivity of the S. pombe trm61Δ strain was completely suppressed by expression of the stand-alone imt06+ gene (S5 Fig).
PMID:35901126 FYPO:0000674 Similarly, the temperature sensitivity of the S. pombe trm61Δ strain was completely suppressed by expression of the stand-alone imt06+ gene (S5 Fig).
PMID:35901126 FYPO:0000674 We found that the temperature sensitive growth defect of S. pombe trm6Δ mutants on EMMC-leu media was completely suppressed by expression of the stand-alone imt06+ gene, growing identically to that of an S. pombe trm6Δ [Ptrm6 trm6+] strain at high temperature (Fig 2C),
PMID:35901126 FYPO:0000674 We found that the temperature sensitive growth defect of S. pombe trm6Δ mutants on EMMC-leu media was completely suppressed by expression of the stand-alone imt06+ gene, growing identically to that of an S. pombe trm6Δ [Ptrm6 trm6+] strain at high temperature (Fig 2C),
PMID:35901126 PBO:0093556 Growth analysis on plates showed that the trm6Δ dhp1-5 and trm6Δ dhp1-6 mutants were nearly as healthy at high temperatures as the WT strain on both YES and EMMC-his media, whereas the trm6Δ tol1-1 mutant was slightly less healthy at higher temperatures (Fig 3A).
PMID:35901126 PBO:0093556 Growth analysis on plates showed that the trm6Δ dhp1-5 and trm6Δ dhp1-6 mutants were nearly as healthy at high temperatures as the WT strain on both YES and EMMC-his media, whereas the trm6Δ tol1-1 mutant was slightly less healthy at higher temperatures (Fig 3A).
PMID:35901126 PBO:0093556 Growth analysis on plates showed that the trm6Δ dhp1-5 and trm6Δ dhp1-6 mutants were nearly as healthy at high temperatures as the WT strain on both YES and EMMC-his media, whereas the trm6Δ tol1-1 mutant was slightly less healthy at higher temperatures (Fig 3A).
PMID:35901126 PBO:0093556 Growth analysis on plates showed that the trm6Δ dhp1-5 and trm6Δ dhp1-6 mutants were nearly as healthy at high temperatures as the WT strain on both YES and EMMC-his media, whereas the trm6Δ tol1-1 mutant was slightly less healthy at higher temperatures (Fig 3A).
PMID:35901126 PBO:0111633 Northern analysis of tRNA from strains grown at 30 ̊C and after temperature shift to 38.5 ̊C showed that the dhp1 and tol1 suppressors substantially restored tRNAiMet(CAU) levels at both high and low temperatures, without affecting any of a number of other tRNAs (Fig 3B and 3C).
PMID:35901126 PBO:0111633 Northern analysis of tRNA from strains grown at 30 ̊C and after temperature shift to 38.5 ̊C showed that the dhp1 and tol1 suppressors substantially restored tRNAiMet(CAU) levels at both high and low temperatures, without affecting any of a number of other tRNAs (Fig 3B and 3C).
PMID:35901126 GO:0180037 The discovery of dhp1 and tol1 mutations as suppressors of the S. pombe trm6Δ temperature sensitivity demonstrates the involvement of the RTD pathway in decay of tRNAiMet(CAU) lack- ing m1A58 in S. pombe.
PMID:35901126 GO:0180037 The discovery of dhp1 and tol1 mutations as suppressors of the S. pombe trm6Δ temperature sensitivity demonstrates the involvement of the RTD pathway in decay of tRNAiMet(CAU) lack- ing m1A58 in S. pombe.
PMID:35901126 FYPO:0001357 Similarly, the temperature sensitivity of the S. pombe trm61Δ strain was completely suppressed by expression of the stand-alone imt06+ gene (S5 Fig).
PMID:35901126 FYPO:0001357 Similarly, the temperature sensitivity of the S. pombe trm61Δ strain was completely suppressed by expression of the stand-alone imt06+ gene (S5 Fig).
PMID:35901126 PBO:0093558 As anticipated, the resulting trm6Δ imt06Δ strain grew very poorly at 30 ̊C, and was temperature sensitive at higher tem- peratures, not growing at all at 37 ̊C,
PMID:35901126 PBO:0093558 As anticipated, the resulting trm6Δ imt06Δ strain grew very poorly at 30 ̊C, and was temperature sensitive at higher tem- peratures, not growing at all at 37 ̊C,
PMID:35901126 PBO:0111633 Northern analysis of tRNA from strains grown at 30 ̊C and after temperature shift to 38.5 ̊C showed that the dhp1 and tol1 suppressors substantially restored tRNAiMet(CAU) levels at both high and low temperatures, without affecting any of a number of other tRNAs (Fig 3B and 3C).
PMID:35901126 PBO:0093560 As anticipated, the resulting trm6Δ imt06Δ strain grew very poorly at 30 ̊C, and was temperature sensitive at higher tem- peratures, not growing at all at 37 ̊C, These results show a prominent synthetic growth defect in the S. pombe trm6Δ imt06Δ strain, due only to reduced levels of tRNAiMet(CAU).
PMID:35901126 PBO:0093560 As anticipated, the resulting trm6Δ imt06Δ strain grew very poorly at 30 ̊C, and was temperature sensitive at higher tem- peratures, not growing at all at 37 ̊C, These results show a prominent synthetic growth defect in the S. pombe trm6Δ imt06Δ strain, due only to reduced levels of tRNAiMet(CAU).
PMID:35901126 PBO:0093558 We observed little, if any, suppression of the trm6Δ growth defect in the trm6Δ cid14Δ strains (S13A Fig), and only very minor restoration of tRNAiMet(CAU) levels at high tempera- ture, relative to levels in trm6Δ mutants (21% vs 18%, compared to 39% in the trm6Δ dhp1-5 strain) (S13B and S13C Fig). Thus, we infer that tRNAiMet(CAU) is degraded in S. pombe trm6Δ and trm6Δ imt06Δ mutants primarily by the RTD pathway, and not appreciably by the TRAMP complex of the nuclear surveillance pathway.
PMID:35901126 PBO:0093558 S1
PMID:35901126 PBO:0111633 Northern analysis of tRNA from strains grown at 30 ̊C and after temperature shift to 38.5 ̊C showed that the dhp1 and tol1 suppressors substantially restored tRNAiMet(CAU) levels at both high and low temperatures, without affecting any of a number of other tRNAs (Fig 3B and 3C).
PMID:35901126 PBO:0093558 S1
PMID:35924983 PBO:0093560 Supplemental Figure 6
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PMID:35924983 PBO:0093561 Supplemental Figure 4, Table 1
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PMID:35924983 FYPO:0001355 Supplemental Figure 4
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PMID:35924983 PBO:0093559 Supplemental Figure 4, Table 1
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PMID:35924983 PBO:0093561 Supplemental Figure 4, Table 1
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PMID:35924983 PBO:0093560 Supplemental Figure 4, Table 1
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PMID:35924983 PBO:0093559 Supplemental Figure 4, Table 1
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PMID:35924983 PBO:0109486 Fig. 6
PMID:35924983 PBO:0020040 Fig. 6
PMID:35924983 PBO:0093770 Figure 3
PMID:35924983 PBO:0109485 through nuclear exclusion
PMID:35924983 PBO:0109485 through nuclear exclusion
PMID:35924983 PBO:0109485 through degradation by ubiquitination
PMID:35924983 PBO:0109485 through degradation by ubiquitination
PMID:35924983 PBO:0093767 Supplemental Figure 4, Table 1
PMID:35924983 PBO:0093767 Supplemental Figure 4, Table 1
PMID:35924983 FYPO:0001492 Supplemental Figure 4, Table 1
PMID:35924983 FYPO:0001492 Supplemental Figure 4, Table 1
PMID:35924983 PBO:0093767 Figure 3
PMID:35924983 PBO:0093767 Figure 3
PMID:35924983 PBO:0109483 Figure 6
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PMID:35924983 PBO:0109480 Figure 7
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PMID:35924983 FYPO:0009111 Figure 7
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PMID:35924983 FYPO:0001355 Supplemental Figure 4
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PMID:35940128 FYPO:0003480 Queuosine absent from tRNA when cells are supplied with queuosine nucleoside, but not when supplied with queuine nucleobase
PMID:35940128 PBO:0096360 term requested Queuosine nucleosidase activity
PMID:35970865 PBO:0105694 figure4
PMID:35970865 PBO:0105695 normal CENP-A maintenance
PMID:35970865 PBO:0103733 decreased CENP-A maintenance
PMID:35970865 PBO:0105695 normal CENP-A maintenance
PMID:35970865 PBO:0105695 normal CENP-A maintenance
PMID:35970865 PBO:0105695 normal CENP-A maintenance
PMID:35970865 PBO:0105696 Note that an increase of transcript levels from centromeres has not been demonstrated in the paper. What has been exactly demonstrated is an increased association of RNA polII to the cnt region of centromeres.
PMID:35970865 PBO:0105696 Note that an increase of transcript levels from centromeres has not been demonstrated in the paper. What has been exactly demonstrated is an increased association of RNA polII to the cnt region of centromeres.
PMID:35970865 PBO:0095634 Fig. 2a The resultant mis6-302 cut9-665 double mutant exhibited severe growth defects, even at the semi-restrictive temperature (Fig. 2a). This suggests that the mitotic function of Mis6 is crucial for prolonged metaphase.
PMID:35970865 PBO:0095634 Fig. 2a The resultant mis6-302 cut9-665 double mutant exhibited severe growth defects, even at the semi-restrictive temperature (Fig. 2a). This suggests that the mitotic function of Mis6 is crucial for prolonged metaphase.
PMID:35970865 PBO:0105697 Figure 2a (during M-phase)
PMID:35970865 FYPO:0008025 (during M-phase) Mis15 localises to the inner regions of centromeres as does Mis6, while Mis12 and Nuf2 localise to the outer regions relative to Mis6, and Mis6 localised to centromeres in the mis12 and nuf2 mutants but not in the mis15 mutant (Supplementary Fig. 6)
PMID:35970865 FYPO:0008025 during M-phase Mis15 localises to the inner regions of centromeres as does Mis6, while Mis12 and Nuf2 localise to the outer regions relative to Mis6, and Mis6 localised to centromeres in the mis12 and nuf2 mutants but not in the mis15 mutant (Supplementary Fig. 6)
PMID:35970865 FYPO:0002360 (during M-phase) Supplementary Fig. 9b). These results demonstrate that kinetochore mutants with the intact inner kinetochore architecture retained the ability to silence transcrip- tion at the central core region.
PMID:35970865 FYPO:0002360 (during M-phase) Supplementary Fig. 9b). These results demonstrate that kinetochore mutants with the intact inner kinetochore architecture retained the ability to silence transcrip- tion at the central core region.
PMID:35970865 PBO:0092503 When we followed the temporal kinetics of GFP- Cnp1 intensity during metaphase, the reduction of GFP-Cnp1 intensity seen in mis6-302 and mis15-68 cells was rescued by the additional knockout of Fft3 (mis6-302 fft3Δ, Supplementary Fig. 11a–c; mis15-68 fft3Δ, Supplementary Fig. 11d–f), confirming that Fft3 removes Cnp1 upon transcription at centromeres.
PMID:35970865 PBO:0095634 Fig. 2a
PMID:35970865 PBO:0095634 Fig. 2a
PMID:35970865 PBO:0093558 Fig. 2a
PMID:35970865 PBO:0105691 "Fig. 2c, d).""decreased CENP-A maintenance during M-phase"". defective in CENP-A maintenance during M phase, as well as defective in CENP-A loading during interphase The GFP-Cnp1 intensity at centromeres decayed more rapidly in mis6-302 cells than in WT cells (Fig. 2f, g and Supplementary Figs. 4 and 5a). Taken together, these results suggest that Mis6, but not Scm3, is responsible for the maintenance of Cnp1 at centromeres during metaphase."
PMID:35970865 PBO:0105692 Defective in CENP-A maintenance. Mis15 localises to the inner regions of centromeres as does Mis6, while Mis12 and Nuf2 localise to the outer regions relative to Mis6, and Mis6 localised to centromeres in the mis12 and nuf2 mutants but not in the mis15 mutant (Supplementary Fig. 6)In the mis15-68 mutants, signal intensities of Cnp1 at centromeres during mitotic arrest were decreased like in the mis6-302 mutant, whereas not in the mis12-537 and nuf2-2 mutants (Fig. 2h–j and Supplementary Figs. 5b–d and 7)
PMID:35970865 PBO:0093556 Fig. 2a
PMID:35970865 PBO:0105693 figure4
PMID:36002457 PBO:0110954 However, no significant changes were observed for several meiotic mRNAs and PROMPTs/CUTs MTREC targets (Supplementary Fig. 8b, c)
PMID:36002457 PBO:0110941 While A198E retained the WT level of binding (Fig. 2i, lanes 3 and 7), the L205R and F215R mutants no longer bound Iss10 (Fig. 2i, lanes 4, 5, 8 and 9).
PMID:36002457 PBO:0110942 While A198E retained the WT level of binding (Fig. 2i, lanes 3 and 7), the L205R and F215R mutants no longer bound Iss10 (Fig. 2i, lanes 4, 5, 8 and 9).
PMID:36002457 PBO:0110942 Using these cells, reciprocal co-immunoprecipitation experiments showed that the Red1-L205R mutation also compro- mised Red1 association with Iss10 in S. pombe (Fig. 3a and Supple- mentary Fig. 3a).
PMID:36002457 PBO:0093555 While red1Δ cells showed only a moderate growth defect on solid rich medium at 30°C, this defect was more pronounced at lower temperature of 25 or 18°C (Supplementary Fig. 3b), as published previously1
PMID:36002457 PBO:0093559 While red1Δ cells showed only a moderate growth defect on solid rich medium at 30°C, this defect was more pronounced at lower temperature of 25 or 18°C (Supplementary Fig. 3b), as published previously1
PMID:36002457 PBO:0093555 While red1Δ cells showed only a moderate growth defect on solid rich medium at 30°C, this defect was more pronounced at lower temperature of 25 or 18°C (Supplementary Fig. 3b), as published previously14,34 or when the cells were grown on minimal medium (Supplementary Fig. 3c).
PMID:36002457 PBO:0093555 Importantly, red1-L205R cells showed a simi- lar growth defect, when grown on minimal medium, suggesting that Red1-Iss10 interaction can be important for Red1-dependent cell growth function depending on the environmental conditions (Fig. 3b).
PMID:36002457 PBO:0110943 We observed that the red1-L205R mutation had an effect on both Iss10 and Red1 localization by, respectively, inducing the disappearance of Iss10 nuclear foci and the increase in the number of Red1 foci per nucleus (Fig. 3c–e)
PMID:36002457 PBO:0110944 We observed that the red1-L205R mutation had an effect on both Iss10 and Red1 localization by, respectively, inducing the disappearance of Iss10 nuclear foci and the increase in the number of Red1 foci per nucleus (Fig. 3c–e)
PMID:36002457 PBO:0110945 These findings indicate that the interaction of Iss10 with Red1 is required for Iss10 recruitment to Red1 nuclear foci and suggest that it may promote the clustering of Red1 nuclear foci.
PMID:36002457 PBO:0110946 We observed that the red1-L205R mutation had an effect on both Iss10 and Red1 localization by, respectively, inducing the disappearance of Iss10 nuclear foci and the increase in the number of Red1 foci per nucleus (Fig. 3c–e)
PMID:36002457 PBO:0110947 We observed that the red1-L205R mutation had an effect on both Iss10 and Red1 localization by, respectively, inducing the disappearance of Iss10 nuclear foci and the increase in the number of Red1 foci per nucleus (Fig. 3c–e)
PMID:36002457 PBO:0110948 We observed that the red1-L205R mutation had an effect on both Iss10 and Red1 localization by, respectively, inducing the disappearance of Iss10 nuclear foci and the increase in the number of Red1 foci per nucleus (Fig. 3c–e)
PMID:36002457 PBO:0110949 We observed that the red1-L205R mutation had an effect on both Iss10 and Red1 localization by, respectively, inducing the disappearance of Iss10 nuclear foci and the increase in the number of Red1 foci per nucleus (Fig. 3c–e)
PMID:36002457 PBO:0110948 We observed that the red1-L205R mutation had an effect on both Iss10 and Red1 localization by, respectively, inducing the disappearance of Iss10 nuclear foci and the increase in the number of Red1 foci per nucleus (Fig. 3c–e)
PMID:36002457 PBO:0110947 We observed that the red1-L205R mutation had an effect on both Iss10 and Red1 localization by, respectively, inducing the disappearance of Iss10 nuclear foci and the increase in the number of Red1 foci per nucleus (Fig. 3c–e)
PMID:36002457 PBO:0110950 We observed that the red1-L205R mutation had an effect on both Iss10 and Red1 localization by, respectively, inducing the disappearance of Iss10 nuclear foci and the increase in the number of Red1 foci per nucleus (Fig. 3c–e)
PMID:36002457 PBO:0110951 We observed that the red1-L205R mutation had an effect on both Iss10 and Red1 localization by, respectively, inducing the disappearance of Iss10 nuclear foci and the increase in the number of Red1 foci per nucleus (Fig. 3c–e)
PMID:36002457 PBO:0110952 We observed that the red1-L205R mutation had an effect on both Iss10 and Red1 localization by, respectively, inducing the disappearance of Iss10 nuclear foci and the increase in the number of Red1 foci per nucleus (Fig. 3c–e)
PMID:36002457 PBO:0110953 In Strep-tag pull down assays, both mutations (K483D, F490D) essentially disrupted the Red1 binding (Supplementary Fig. 7d, lanes 3, 4).
PMID:36002457 PBO:0110953 Using Y2H assays, we could show that the Red1 E32R mutation is sufficient to prevent the interaction with Ars2 in the context of full-length proteins (Fig. 5f). mportantly, while Red1-TAP and Ars2-GFP interact, as expected, this interaction was lost in cells expressing Red1-E32R-TAP (Fig. 5g).
PMID:36002457 PBO:0093555 A similar growth defect was visible for the red1-E32R-TAP mutant cells grown on minimal medium, suggesting that Red1-Ars2 interaction, depending on the growth conditions, can be important for the normal growth of the cell population (Fig. 5h).
PMID:36002457 PBO:0108631 However, no significant changes were observed for several meiotic mRNAs and PROMPTs/CUTs MTREC targets (Supplementary Fig. 8b, c)
PMID:36002457 PBO:0110955 However, no significant changes were observed for several meiotic mRNAs and PROMPTs/CUTs MTREC targets (Supplementary Fig. 8b, c)
PMID:36002457 PBO:0112760 However, no significant changes were observed for several meiotic mRNAs and PROMPTs/CUTs MTREC targets (Supplementary Fig. 8b, c)
PMID:36002457 PBO:0110957 We examined the possible effect of red1-E32R mutation on pho1 and byr2 mRNAs. However, no significant changes in pho1 and byr2 mRNA levels were observed between wild-type and red1-E32R mutant cells (Supplementary Fig. 8d).
PMID:36002457 PBO:0110958 We examined the possible effect of red1-E32R mutation on pho1 and byr2 mRNAs. However, no significant changes in pho1 and byr2 mRNA levels were observed between wild-type and red1-E32R mutant cells (Supplementary Fig. 8d).
PMID:36002457 PBO:0110959 Interestingly, quantification of the intensity of the signal within each nucleus showed a reduction of Ars2-GFP nuclear signal in red1-E32R mutant cells compared to wild- type cells, suggesting that some of Ars2-GFP proteins diffuse to the cytoplasm (Supplementary Fig. 8e).
PMID:36006032 FYPO:0005728 figure 1 D
PMID:36006032 PBO:0105585 Overexpression of Par2 suppressed the SAC silencing defects and allowed dis2Δ cells to enter anaphase earlier after arrest-and-release in the nda3-KM311 mutant background.
PMID:36006032 PBO:0105585 Overexpression of Par1 slightly suppressed the SAC silencing defects and allowed dis2Δ cells to enter anaphase earlier after arrest-and-release in the nda3-KM311 mutant background.
PMID:36006032 FYPO:0005727 figure 1 D
PMID:36006032 PBO:0105587 figure 1 D
PMID:36006032 FYPO:0005728 figure 1 D
PMID:36006032 FYPO:0005727 figure 1 D
PMID:36006032 FYPO:0005728 figure 1 D
PMID:36006032 FYPO:0005728 figure 1 D
PMID:36006032 PBO:0105585 Overexpression of Par2 suppressed the SAC silencing defects and allowed dis2Δ cells to enter anaphase earlier after arrest-and-release in the nda3-KM311 mutant background.
PMID:36006032 PBO:0105585 Overexpression of Par1 slightly suppressed the SAC silencing defects and allowed dis2Δ cells to enter anaphase earlier after arrest-and-release in the nda3-KM311 mutant background.
PMID:36006032 PBO:0105585 Overexpression of Ppa2 slightly suppressed the SAC silencing defects and allowed dis2Δ cells to enter anaphase earlier after arrest-and-release in the nda3-KM311 mutant background.
PMID:36006032 PBO:0105585 Overexpression of Ppa2 slightly suppressed the SAC silencing defects and allowed dis2Δ cells to enter anaphase earlier after arrest-and-release in the nda3-KM311 mutant background.
PMID:36006032 PBO:0105586 figure 1 D
PMID:36006032 FYPO:0005728 figure 1 D
PMID:36006032 PBO:0105585 Overexpression of Ppa2 slightly suppressed the SAC silencing defects and allowed dis2Δ cells to enter anaphase earlier after arrest-and-release in the nda3-KM311 mutant background.
PMID:36006032 PBO:0105585 Overexpression of Ppa2 slightly suppressed the SAC silencing defects and allowed dis2Δ cells to enter anaphase earlier after arrest-and-release in the nda3-KM311 mutant background.
PMID:36006032 PBO:0105585 Overexpression of all Ppa1 slightly suppressed the SAC silencing defects and allowed dis2Δ cells to enter anaphase earlier after arrest-and-release in the nda3-KM311 mutant background.
PMID:36006032 PBO:0105585 Overexpression of all Ppa1 slightly suppressed the SAC silencing defects and allowed dis2Δ cells to enter anaphase earlier after arrest-and-release in the nda3-KM311 mutant background.
PMID:36006032 PBO:0105585 Pab1 slightly suppressed the SAC silencing defects and allowed dis2Δ cells to enter anaphase earlier after arrest- and-release in the nda3-KM311 mutant background (Figure 2 and Figure S2).
PMID:36006032 PBO:0105585 Pab1 slightly suppressed the SAC silencing defects and allowed dis2Δ cells to enter anaphase earlier after arrest- and-release in the nda3-KM311 mutant background (Figure 2 and Figure S2).
PMID:36006032 PBO:0105581 Our in vitro dephosphor- ylation assay results demonstrated that individually overexpressing PP2A subunits indeed boosted the over- all phosphatase activity compared to expressing endog- enous subunits alone (Figure 3B).
PMID:36088506 FYPO:0001164 The growth of the mrz1 mutant was almost like WT strain in both glucose- and glycerol-containing media at 30 °C (Fig. 4A).
PMID:36088506 PBO:0110212 Assessment of Mrz1 levels in these strains (Fig. 3) showed that the levels of Mrz1 markedly increased in ubc13 deletion background and no others, apart from the expected increase in the addition of MG132 controls.
PMID:36088506 GO:0005741 As observed, most of Mrz1 was localized in the mitochondrial fraction (Fig. 1B).
PMID:36088506 PBO:0110211 proteasome inhibitor MG132
PMID:36088506 PBO:0110210 As shown in Fig. 2A, Mrz1 expression was decreased during the stationary phase grown on YES.
PMID:36090151 PBO:0093664 1.6 mM
PMID:36090151 PBO:0093664 1.6 mM
PMID:36095128 PBO:0109797 Figure S12.B
PMID:36095128 PBO:0109796 (Supplementary Figures S6 and S7A). mug5 intron 2
PMID:36095128 PBO:0109795 (Supplementary Figures S6 and S7A). rap1 intron 2
PMID:36095128 PBO:0109794 (Supplementary Figures S6 and S7A). ...the disruption of secondary structures by exposure to elevated temperatures could open the fold and increase the distance between the BP and 3′ss.... Indeed, excision of introns with secondary structures such as rap1 intron 2, whi5 intron 1, atg20 intron 2 and mug65 intron 2 was sensitive to 15 min treatment at 42◦C. After lower- ing the temperature to 25◦C, splicing defects of these in- trons recovered in wt cells, but the recovery with whi5 and atg20 introns was slower in Δsde2.
PMID:36095128 PBO:0109793 Semi quantitative RT-PCR followed by gel electrophoresis; Intron retention observed in absence of sde2, cay1 and tls1
PMID:36095128 PBO:0109792 Semi quantitative RT-PCR followed by gel electrophoresis; Intron retention observed in absence of sde2, cay1 and tls1
PMID:36095128 PBO:0109791 A shorter form of the protein translated from intron-retained transcript
PMID:36095128 PBO:0109800 Figure S12.B
PMID:36095128 PBO:0109797 Figure S12.B
PMID:36095128 GO:0045292 Figure S13. C
PMID:36095128 GO:0045292 Figure S13. C
PMID:36095128 GO:0045292 Figure S13. C
PMID:36095128 GO:0045292 Figure S13. C
PMID:36095128 PBO:0109798 Figure S12.B
PMID:36095128 GO:0045292 Figure S13. C
PMID:36095128 GO:0045292 Figure S13. C
PMID:36095128 FYPO:0003619 figure 1 (rap1 intron2 branch site distance decreased)
PMID:36095128 FYPO:0003619 figure 1 (rap1 intron2 branch site distance decreased)
PMID:36095128 FYPO:0008118 figure 1
PMID:36095128 FYPO:0008118 figure 1
PMID:36095128 FYPO:0008118 figure 1
PMID:36095128 PBO:0109800 Figure S12.B
PMID:36095128 PBO:0109799 Figure S12.B
PMID:36095128 GO:0045292 Figure S13. C
PMID:36095128 GO:0045292 Figure S13. C
PMID:36095128 GO:0045292 Figure S13. C
PMID:36095128 GO:0045292 Figure S13. C
PMID:36095128 GO:0045292 Figure S13. C
PMID:36095128 PBO:0109790 figure 1 (rap1 intron2, ftp105 intron 3 and pyp3 intron 1)
PMID:36095128 PBO:0109789 figure 1 (rap1 intron2, ftp105 intron 3 and pyp3 intron 1)
PMID:36095128 PBO:0109798 Figure S12.B
PMID:36095128 PBO:0109797 Figure S12.B
PMID:36095128 PBO:0109800 Figure S12.B
PMID:36095128 PBO:0109799 Figure S12.B
PMID:36095128 PBO:0109798 Figure S12.B
PMID:36095128 PBO:0109791 A shorter form of the protein translated from intron-retained transcript
PMID:36095128 PBO:0109791 A shorter form of the protein translated from intron-retained transcript
PMID:36095128 PBO:0109791 A shorter form of the protein translated from intron-retained transcript
PMID:36095128 PBO:0109791 A shorter form of the protein translated from intron-retained transcript
PMID:36095128 PBO:0109792 Semi quantitative RT-PCR followed by gel electrophoresis; Intron retention observed in absence of sde2, cay1 and tls1
PMID:36095128 PBO:0109791 A shorter form of the protein translated from intron-retained transcript
PMID:36095128 PBO:0109791 A shorter form of the protein translated from intron-retained transcript
PMID:36095128 PBO:0109791 A shorter form of the protein translated from intron-retained transcript
PMID:36095128 PBO:0109793 Semi quantitative RT-PCR followed by gel electrophoresis; Intron retention observed in absence of sde2, cay1 and tls1
PMID:36095128 PBO:0109799 Figure S12.B
PMID:36095128 PBO:0109788 figure 1 (rap1 intron2, ftp105 intron 3 and pyp3 intron 1)
PMID:36095128 FYPO:0008118 Among the mutants studied, Δcay1 and Δtls1 strains also showed splicing defects spe- cific for rap1 intron 2 (Supplementary Figure S10A).
PMID:36095128 FYPO:0008118 Among the mutants studied, Δcay1 and Δtls1 strains also showed splicing defects spe- cific for rap1 intron 2 (Supplementary Figure S10A).
PMID:36095128 PBO:0109791 Figure S13. C A shorter form of the protein translated from intron-retained transcript
PMID:36095128 PBO:0109791 Figure S13. C A shorter form of the protein translated from intron-retained transcript
PMID:36095128 PBO:0109791 A shorter form of the protein translated from intron-retained transcript
PMID:36095128 PBO:0109791 A shorter form of the protein translated from intron-retained transcript
PMID:36095128 PBO:0109791 A shorter form of the protein translated from intron-retained transcript
PMID:36095128 PBO:0109791 A shorter form of the protein translated from intron-retained transcript
PMID:36095128 PBO:0109791 A shorter form of the protein translated from intron-retained transcript
PMID:36108046 PBO:0102944 Consistent with this assumption, we found that dnt1Δ cells lost minichromosomes (Ch16, ade6-M216) at an elevated rate that is almost 100 times higher than that of the wild-type (Fig 1B), and displayed increased frequency of lagging chromosomes and chromosome mis-segre- gation at mitotic anaphase (Fig 1C).
PMID:36108046 FYPO:0005727 inefficient anaphase initiation upon SAC inactivation/ persistent MCC-APC/C binding upon SAC activation The SAC was first robustly activated by the nda3-KM311 mutant then inactivated by shifting mitotically arrested cells back to permissive temperature(30˚C)/ We found that dnt1Δ cells retained high amounts of SPB-localized Cdc13-GFP and nuclear Cut2-GFP for much pro- longed period compared to wild-type cells, almost to the same degree as previously identified SAC-inactivation defective mutant dis2Δ
PMID:36108046 PBO:0093556 I changed to decreased. becasue the phenotype is compared to WT,
PMID:36108046 PBO:0093556 I changed to decreased. becasue the phenotype is compared to WT,
PMID:36108046 PBO:0102945 Surprisingly, Slp1Cdc20 was slightly, but appreciably and reproducibly, less abundant (ranging from roughly 20% to 50% at different time points) in dnt1Δ cells than in wild-type cells (Fig 3B), suggesting Dnt1 may indeed positively regulate the levels of intact Slp1Cdc20. In addition, this regulation of Slp1Cdc20 stability by Dnt1 is Dma1-independent, as the dnt1Δ dma1Δ double mutant has a similar level and degradation profile of Slp1Cdc20 as dnt1Δ single mutant (S5 Fig).
PMID:36108046 FYPO:0008032 but dnt1Δ cells stayed for extended length of time at anaphase B (Fig 1D–1F)
PMID:36108046 PBO:0093563 Consequently, sensitivity of dnt1Δ cells to TBZ was largely but not completely suppressed by excessive Slp1Cdc20 expression achieved by three copies of slp1+ (Fig 3E).
PMID:36108046 FYPO:0005706 but dnt1Δ cells stayed for extended length of time at ana- phase B (Fig 1D–1F)
PMID:36112198 FYPO:0001020 Fig. S2
PMID:36112198 PBO:0093594 fig1 (double mutant with cyr1 is more sensitive)
PMID:36112198 PBO:0093594 figure 2
PMID:36112198 PBO:0093594 figure 2
PMID:36112198 FYPO:0006717 Fig S2
PMID:36112198 PBO:0107560 Fig. S2
PMID:36112198 PBO:0107560 Fig. S2
PMID:36112198 FYPO:0006717 Fig. S2
PMID:36112198 FYPO:0006717 Fig. S2
PMID:36112198 FYPO:0000961 Fig. S2
PMID:36112198 FYPO:0005947 figure 3
PMID:36112198 FYPO:0005947 fig4
PMID:36112198 PBO:0093595 figure 2
PMID:36112198 PBO:0093595 figure 2
PMID:36112198 FYPO:0000098 Fig. S2
PMID:36112198 FYPO:0006717 figure S2
PMID:36112198 FYPO:0000112 figure 2
PMID:36112198 PBO:0093595 figure 2
PMID:36112198 PBO:0093595 figure 2
PMID:36112198 PBO:0093595 figure 2b
PMID:36112198 PBO:0093595 figure 2b
PMID:36112198 FYPO:0001214 cgs1∆ partially rescues plb1∆ on KCl
PMID:36112198 FYPO:0001214 cgs1∆ partially rescues plb1∆ on KCl
PMID:36112198 PBO:0093593 Fig 4 rst2∆ partially rescues plb1∆ on KCl
PMID:36112198 PBO:0093593 Fig 4 rst2∆ partially rescues plb1∆ on KCl
PMID:36112198 PBO:0107570 observed Pka1-GFP
PMID:36112198 PBO:0107569 fig5
PMID:36112198 PBO:0107568 observed Pka1-GFP
PMID:36112198 PBO:0107568 observed Pka1-GFP
PMID:36112198 PBO:0107567 observed Pka1-GFP
PMID:36112198 PBO:0107566 low glucose MM
PMID:36112198 PBO:0107562 glucose MM
PMID:36112198 PBO:0107561 glucose MM
PMID:36112198 FYPO:0000961 rst2∆ rescues pka1∆ plb1∆ on KCl
PMID:36112198 PBO:0093594 rst2∆ partially rescues pka1∆ plb1∆ on KCl
PMID:36112198 PBO:0093595 Fig 1b
PMID:36112198 PBO:0093593 Fig.1 Overexpression of Pka1 restores the KCl-sensitive pheno- type of the plb1∆ strain.
PMID:36112198 PBO:0093593 Fig.1 Overexpression of Pka1 restores the KCl-sensitive pheno- type of the plb1∆ strain.
PMID:36112198 FYPO:0000961 cgs1∆ rescues cyr1∆ plb1∆ on sorbitol
PMID:36112198 PBO:0093593 cgs1∆ partially rescues cyr1∆ plb1∆ on KCl
PMID:36112198 FYPO:0005947 rst2∆ rescues pka1∆ on KCl
PMID:36112198 FYPO:0005947 rst2∆ rescues pka1∆ on KCl
PMID:36138017 PBO:0096651 (Fig. 2d)
PMID:36138017 PBO:0096652 We found that Tip1 was efficiently ubiquitinated in the absence of the calcineurin catalytic subunit Ppb1, with a similar degree of modification to that of wild-type cells (Fig. 6a).
PMID:36138017 FYPO:0004601 though HU treatment caused equally efficient arrest at S phase in both wild-type and dma1Δ cells (Supplementary Fig. 4)
PMID:36138017 PBO:0096648 More interestingly, in the presence of HU, the binding between Tea4 and Tip1 was elevated in dma1Δ cells and in wild-type cells treated with deubiquitinating enzyme USP2 to remove Tip1 ubi- quitination (Fig. 4f), this is consistent with increased polar growth in dma1Δ cells (Fig. 4b).
PMID:36138017 PBO:0096651 Strikingly, Tip1 ubiquitination was abolished in both dma1 mutants (Fig. 2d), demonstrating that both functional FHA and RF domains in Dma1 are required for Tip1 ubiquitination in vivo.
PMID:36138017 PBO:0096644 Dma1 ubiquitinates Tip1
PMID:36138017 FYPO:0002657 (Fig. 4)
PMID:36138017 FYPO:0001017 (Fig. 4)
PMID:36138017 PBO:0020227 figure 1D.
PMID:36174923 PBO:0095015 fig S2
PMID:36174923 PBO:0095016 fig S2
PMID:36174923 FYPO:0001357 Fig. S5.
PMID:36174923 FYPO:0000245 Fig. 5.
PMID:36174923 PBO:0095018 fig 4
PMID:36174923 FYPO:0001357 Fig. S5.
PMID:36174923 FYPO:0000245 Fig. 7b partial rescue - still loses viabiltiy at 48 hours
PMID:36174923 FYPO:0000245 Fig. 7b partial rescue - still loses viabiltiy at 48 hours
PMID:36174923 PBO:0093605 Fig. 5.
PMID:36174923 PBO:0093605 Fig. 5.
PMID:36174923 PBO:0093605 Fig. 5.
PMID:36174923 PBO:0093605 Fig. 5.
PMID:36174923 FYPO:0003095 Microscopic examination revealed that Δsty1Δppr10 cells were highly elongated compared to WT, Δppr10, and Δsty1 cells (Fig. 5B), suggesting that progression from G2 into mitosis was impaired in Δsty1Δppr10 cells.
PMID:36174923 PBO:0095017 fig S2
PMID:36174923 FYPO:0002060 Fig. S5.
PMID:36174923 FYPO:0000245 Fig. 5.
PMID:36174923 FYPO:0000245 Fig 6
PMID:36174923 PBO:0095001 figure1
PMID:36174923 PBO:0095013 fig S2
PMID:36174923 PBO:0095014 fig S2
PMID:36200823 FYPO:0001234 sfh1-13 mutant strain exhibited a slow growth phenotype at 32◦C upon nmt41-cnp1 expression (sfh1-13 at 32◦C in the lower panel of Supplementary Figure S1B
PMID:36200823 PBO:0093562 In addition, a low concentra- tion of TBZ enhanced the chromosome segregation de- fects of the temperature-sensitive sfh1-13 mutant (Supple- mentary Figure S1A).
PMID:36200823 FYPO:0001234 sfh1-13 mutant strain exhibited a slow growth phenotype at 32◦C upon nmt41-cnp1 expression (sfh1-13 at 32◦C in the lower panel of Supplementary Figure S1B
PMID:36200823 FYPO:0008036 Importantly, MNase protection at sites i, iii, and v, which are located between CENP-ACnp1 and heterochro- matin domains, was elevated in sfh1-13 cells (site i: 1.5-fold, P-value = 0.027; site iii: 2.2-fold, P-value = 0.0001; site v: 1.2-fold, P-value = 0.02; left panel of Figure 5B), indicat- ing that Sfh1/RSC contributes to chromatin decompaction at the boundary.
PMID:36200823 PBO:0094598 (Figure 3E). As reported previously, deletion of clr3 increased the loading of Snf21 at pericentromeric repeats; however, we did not observe greater Snf21 occupancy in our sfh1-13 clr3Δ double mutant relative to a sfh1-13 sin- gle mutant, suggesting that sfh1-13 prevents the acetylation- dependent recruitment of Snf21 at pericentromeres, and that the elimination of misloaded CENP-ACnp1 in sfh1-13Δ clr3Δ cells is not due to the increase in Snf21 level.
PMID:36200823 FYPO:0006842 while loss of Clr3 eliminated CENP-ACnp1 accumulation at the pericentromere in a sfh1- 13 mutant background, indicating that Clr3 is required for ectopic deposition of CENP-ACnp1 (Figure 3D).
PMID:36200823 FYPO:0000141 In addition, a low concentra- tion of TBZ enhanced the chromosome segregation de- fects of the temperature-sensitive sfh1-13 mutant (Supple- mentary Figure S1A).
PMID:36200823 PBO:0093564 sfh1-13 clr3Δ cells were faster growing on TBZ-containing plates than sfh1-13 cells, indicating that deletion of clr3 partially rescues the TBZ sensitivity of sfh1-13.
PMID:36200823 PBO:0093564 sfh1-13 clr3Δ cells were faster growing on TBZ-containing plates than sfh1-13 cells, indicating that deletion of clr3 partially rescues the TBZ sensitivity of sfh1-13.
PMID:36200823 PBO:0093564 sfh1-13 clr3Δ cells were faster growing on TBZ-containing plates than sfh1-13 cells, indicating that deletion of clr3 partially rescues the TBZ sensitivity of sfh1-13.
PMID:36200823 PBO:0094597 In sfh1-13 mutant cells, a small but signifi- cant increase in the localization of CENP-CCnp3 and CENP- IMis6 was observed at surrounding pericentromeric repeats (Figure 2B and C);
PMID:36200823 FYPO:0000047 However, deletion strains of two genes encod- ing SWI/SNF core components, snf5 and snf22, did not exhibit sensitivity to CENP-ACnp1 overexpression (Supple- mentary Figure S2A).
PMID:36200823 FYPO:0000047 However, deletion strains of two genes encod- ing SWI/SNF core components, snf5 and snf22, did not exhibit sensitivity to CENP-ACnp1 overexpression (Supple- mentary Figure S2A).
PMID:36200823 PBO:0094593 at pericentromeric heterochromatin When CENP-ACnp1 was expressed at wild- type levels, specific accumulation at pericentromeric heterochromatin domains of all centromeres (Figure 1A), but not at non-centromeric locations
PMID:36200823 PBO:0094594 Importantly, no significant dif- ference in the level of Cnp1 protein or mRNA was seen in sfh1-13 cells (Figure 1E).
PMID:36200823 PBO:0094593 at pericentromeric heterochromatin When CENP-ACnp1 was expressed at wild- type levels, specific accumulation at pericentromeric heterochromatin domains of all centromeres (Figure 1A), but not at non-centromeric locations
PMID:36200823 FYPO:0006842 Furthermore, we observed ectopic CENP-ACnp1 deposition at pericentromeric heterochromatin domains in snf21-36 but not in rsc1 and rsc4 deletion mutants (Figure 1F)
PMID:36200823 PBO:0094595 However, the sfh1-13 mutation had only a mild influence on H3K9me levels (Figure 1C), as we re- ported previously (12).
PMID:36200823 PBO:0094596 In sfh1-13 mutant cells, a small but signifi- cant increase in the localization of CENP-CCnp3 and CENP- IMis6 was observed at surrounding pericentromeric repeats (Figure 2B and C);
PMID:36200871 PBO:0109062 Figure 2, E and F). We concluded that Pkd2 is calcium-permeable under the mechanical stimulus of membrane stretching.
PMID:36200871 FYPO:0008063 The peak amplitude of the cal- cium spikes in pkd2-B42 cells was similarly reduced by 62% (Figure 4D).
PMID:36200871 GO:0005886 Supplemental Figure S5A). We concluded that the calcium-permeable Pkd2 primarily localizes to the plasma membrane.
PMID:36200871 FYPO:0001197 At 36°C, the average calcium level of pkd2-B42 cells was 34% lower than that of wild type cells (Figure 3, C and D).
PMID:36259651 FYPO:0003031 When cells were grown in media containing nitro- gen sources, some of the nc1669 cells underwent mating (followed by meiosis), whereas WT cells never initiated mat- ing (Figure 3B, C)
PMID:36259651 PBO:0094617 When cells were grown in media containing nitro- gen sources, some of the nc1669 cells underwent mating (followed by meiosis), whereas WT cells never initiated mat- ing (Figure 3B, C)
PMID:36302945 FYPO:0001723 data not shown, related data in Figure 2A
PMID:36302945 FYPO:0002988 Figure 1. Cells with leucine auxotrophy (leu1-32 strain) show weak growth on the synthetic medium EMM supplemented with 0.2 mM leucine (Fig. 1B). EMM contains 0.5% NH4Cl
PMID:36302945 FYPO:0002988 Figure 4 In 3.0% NH4Cl medium, the growth speed of both strains became slower after exposure to the high NH4Cl condition for 14 h.
PMID:36302945 FYPO:0002988 Figure 3, this phenotype was observed for cat1_delta leu1-32 double mutant.
PMID:36361590 PBO:0102893 Figure 2
PMID:36361590 PBO:0102895 figure3
PMID:36361590 PBO:0102894 figure3
PMID:36361590 PBO:0102895 figure3
PMID:36361590 PBO:0102896 We detected wdr83 (Figure S1) and performed the Western blot and RT-qPCR analyses. We detected no significant changes in the mRNA levels of gpl1, gih35 or wdr83 in the analyzed mu- no significant changes in the mRNA levels of gpl1, gih35 or wdr83 in the analyzed mutants tants (Figure 5a).
PMID:36361590 PBO:0102893 Figure 2& 4 These results indicated that the Gih35 helicase is part of the Gih35 and Wdr83 on one side, and as an anchoring protein that allows the binding of the Gpl1-Gih35-Wdr83 complex to the spliceosome on the other side. Gpl1- Gih35-Wdr83 complex, but to associate with the spliceosome, it requires the interaction with Gpl1. Altogether, these findings confirmed the above results of the Y2H assay and provided further support for the hypothesis that Gpl1 functions as a bridging protein for
PMID:36361590 GO:0005681 Gpl1-Gih35-Wdr83 complex
PMID:36361590 GO:0005681 Gpl1-Gih35-Wdr83 complex
PMID:36361590 GO:0005681 Gpl1-Gih35-Wdr83 complex
PMID:36361590 PBO:0102894 figure3
PMID:36408846 PBO:0109787 (Fig 3C and D). Indeed, the distribution of the GFP dots revealed aberrant segregation of sister chromatids in MI of clr4F449Y/clr4F449Y cells, with a high frequency of equational segregation that normally occurs during MII (Fig 3D
PMID:36408846 FYPO:0002150 figure 3F
PMID:36408846 PBO:0100295 figure 4a
PMID:36408846 PBO:0100295 figure 4a
PMID:36408846 PBO:0100297 Furthermore, fewer clr4F449Y/clr4F449Y cells displayed lagging DNA upon expression of Swi6Chp1-like-CD (Fig 4C and D).
PMID:36408846 FYPO:0008047 clr4F449Y/clr4F449Y cells displayed strongly ele- vated H3K9me2 levels when in mitosis, while H3K9me3 was absent (Figs 2A and EV3A).
PMID:36408846 FYPO:0008048 This revealed reduced H3K9me2, but increased H3K9me3 levels upon 1-NM-PP1 addition in cdk1-as cells specifi- cally (Fig 6F),
PMID:36408846 PBO:0111081 Indeed, CDK1/Cyclin B phosphorylated recombinant Clr4 specifically at S458 (Fig 6E).
PMID:36408846 FYPO:0005641 (Fig 3C and D). Indeed, the distribution of the GFP dots revealed aberrant segregation of sister chromatids in MI of clr4F449Y/clr4F449Y cells, with a high frequency of equational segregation that normally occurs during MII (Fig 3D
PMID:36408846 FYPO:0008038 clr4F449Y/clr4F449Y cells displayed strongly ele- vated H3K9me2 levels when in mitosis, while H3K9me3 was absent (Figs 2A and EV3A).
PMID:36408846 FYPO:0008052 clr4F449Y/clr4F449Y cells displayed strongly ele- vated H3K9me2 levels when in mitosis, while H3K9me3 was absent (Figs 2A and EV3A).
PMID:36408846 PBO:0100296 Figure 4 A (This obser- vation indicates that highest binding affinity of Swi6 towards H3 is necessary for proper subnuclear localization in meiocytes, for which H3K9 needs to be tri-methylated.
PMID:36408846 PBO:0100299 Upon inhibition of Cdk1-as, Clr4S458 phosphorylation rapidly decreased and was undetectable 3 h postinhibition, whereas Clr4 phosphorylation levels remained unaffected in cdk1+ cells (Figs 6D and EV5D).
PMID:36408846 FYPO:0000278 spores formed colonies again (Fig 4G).
PMID:36408846 FYPO:0008050 (Check tomorrow should this be tri methylation)
PMID:36408846 PBO:0112497 Consistent with earlier findings, we frequently observed spores with two GFP dots in a sin- gle nucleus of a tetrad derived from clr4D/clr4D cells (Fig 3E, green fraction). Such a pattern (i.e., normal segregation during MI but not MII) occurred in < 1% of clr4F449Y/clr4F449Y cells that we have ana- lyzed (Fig 3E)
PMID:36423630 GO:0032040 We isolated nascent 40S (also known as small subunit processome) by pull- ing down fibrillarin (Nop1)-associated particles (Figure S4I; Table S3; Data S1)
PMID:36423630 GO:0032040 We isolated nascent 40S (also known as small subunit processome) by pull- ing down fibrillarin (Nop1)-associated particles (Figure S4I; Table S3; Data S1)
PMID:36423630 GO:0032040 We isolated nascent 40S (also known as small subunit processome) by pull- ing down fibrillarin (Nop1)-associated particles (Figure S4I; Table S3; Data S1)
PMID:36423630 GO:0032040 We isolated nascent 40S (also known as small subunit processome) by pull- ing down fibrillarin (Nop1)-associated particles (Figure S4I; Table S3; Data S1)
PMID:36423630 GO:0032040 We isolated nascent 40S (also known as small subunit processome) by pull- ing down fibrillarin (Nop1)-associated particles (Figure S4I; Table S3; Data S1)
PMID:36423630 GO:0032040 We isolated nascent 40S (also known as small subunit processome) by pull- ing down fibrillarin (Nop1)-associated particles (Figure S4I; Table S3; Data S1)
PMID:36423630 GO:0032040 We isolated nascent 40S (also known as small subunit processome) by pull- ing down fibrillarin (Nop1)-associated particles (Figure S4I; Table S3; Data S1)
PMID:36423630 GO:0032040 We isolated nascent 40S (also known as small subunit processome) by pull- ing down fibrillarin (Nop1)-associated particles (Figure S4I; Table S3; Data S1)
PMID:36423630 GO:0032040 We isolated nascent 40S (also known as small subunit processome) by pull- ing down fibrillarin (Nop1)-associated particles (Figure S4I; Table S3; Data S1)
PMID:36423630 GO:0032040 We isolated nascent 40S (also known as small subunit processome) by pull- ing down fibrillarin (Nop1)-associated particles (Figure S4I; Table S3; Data S1)
PMID:36423630 GO:0032040 We isolated nascent 40S (also known as small subunit processome) by pull- ing down fibrillarin (Nop1)-associated particles (Figure S4I; Table S3; Data S1)
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0032040 We isolated nascent 40S (also known as small subunit processome) by pull- ing down fibrillarin (Nop1)-associated particles (Figure S4I; Table S3; Data S1)
PMID:36423630 GO:0003723 Similarly to human nucleosphosmin,12 Fkbp39 can bind RNA in vitro and phase separate with RNA (Figures S4A and S4B). Fkbp39 robustly forms liquid-like condensates with RNA in sharp contrast to condensates with DNA (Figures S4B and S2D).
PMID:36423630 GO:1902626 State 2 has 24 ribosomal proteins but only 9 biogenesis factors, and ITS2 is cleaved and its associated factors are released (Figures 2A and S3D; Table S2).
PMID:36423630 GO:1902626 State 2 has 24 ribosomal proteins but only 9 biogenesis factors, and ITS2 is cleaved and its associated factors are released (Figures 2A and S3D; Table S2).
PMID:36423630 GO:1902626 State 2 has 24 ribosomal proteins but only 9 biogenesis factors, and ITS2 is cleaved and its associated factors are released (Figures 2A and S3D; Table S2).
PMID:36423630 GO:1902626 State 2 has 24 ribosomal proteins but only 9 biogenesis factors, and ITS2 is cleaved and its associated factors are released (Figures 2A and S3D; Table S2).
PMID:36423630 GO:1902626 In state 3, RNA domain III is folded and the biogenesis complex Ytm1-Erb1-Ppp1 (Ytm1-Erb1-Nop7 in S. cerevisiae) is incorporated32 for a total of 30 ribosomal proteins and 15 biogenesis factors (Figure 2A).
PMID:36423630 GO:1902626 In state 3, RNA domain III is folded and the biogenesis complex Ytm1-Erb1-Ppp1 (Ytm1-Erb1-Nop7 in S. cerevisiae) is incorporated32 for a total of 30 ribosomal proteins and 15 biogenesis factors (Figure 2A).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0000785 By contrast, Fkbp41 is found pri- marily in the insoluble chromatin fraction (Figure S1C).
PMID:36423630 PBO:0111363 We found that chromatin-associated Fkbp39 and Fkbp41 predominately localized to the rDNA locus, similar to previous observations on budding yeast and mammalian nucle- ophosmins,20–23 but our ChIP-seq data also revealed a strong enrichment at the 25S rDNA, which had not been described before (Figures 1A, 1B, and S1D).
PMID:36423630 PBO:0111363 We found that chromatin-associated Fkbp39 and Fkbp41 predominately localized to the rDNA locus, similar to previous observations on budding yeast and mammalian nucle- ophosmins,20–23 but our ChIP-seq data also revealed a strong enrichment at the 25S rDNA, which had not been described before (Figures 1A, 1B, and S1D).
PMID:36423630 GO:0000182 On the other hand, Fkbp39 could bind to DNA and nucleosomes with a 40-bp-long linker DNA (Figures 1C, S1I, and S1J) but not to nucleosomes lacking or with short 10 bp linker DNA (Figure S2A).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0140693 This supports the role of histones in promoting heterotypic LLPS of Fkbp39 with DNA (Figures 1D and S2E). These observations suggest that Fkbp39 could organize the rDNA-containing chromatin into a phase- separated compartment.
PMID:36423630 FYPO:0004227 We mutated the active site of the prolyl isomerase domain of Fkbp39 (F301C/W314C/Y337K)29 and found that it was impaired in the ability to bind nucleosomes but not DNA (Figure S2B).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0031491 On the other hand, Fkbp39 could bind to DNA and nucleosomes with a 40-bp-long linker DNA (Figures 1C, S1I, and S1J) but not to nucleosomes lacking or with short 10 bp linker DNA (Figure S2A).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:1902626 In state 3, RNA domain III is folded and the biogenesis complex Ytm1-Erb1-Ppp1 (Ytm1-Erb1-Nop7 in S. cerevisiae) is incorporated32 for a total of 30 ribosomal proteins and 15 biogenesis factors (Figure 2A).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 PBO:0111364 By contrast, in fkbp39D cells, we de- tected Ytm1 on chromatin, primarily at the 30 end of the rDNA re- peats, specifically enriched at the 30 ETS and the non-tran- scribed spacer (NTS) DNA sites (Figures 4A, S5A, and S5B).
PMID:36423630 GO:0042274 Fkbp39 separates nascent ribosomes from chromatin in cells
PMID:36423630 GO:0042273 Fkbp39 separates nascent ribosomes from chromatin in cells
PMID:36423630 FYPO:0001137 reduced levels of 18S and 25S rRNA and accu- mulation of 50 ETS RNA and unprocessed rRNA in the mutant compared with wild-type cells (Figures S5D and S5E).
PMID:36423630 FYPO:0003694 reduced levels of 18S and 25S rRNA and accu- mulation of 50 ETS RNA and unprocessed rRNA in the mutant compared with wild-type cells (Figures S5D and S5E).
PMID:36423630 GO:0042790 To determine if Fkbp39 is required for transcription or RNA processing, we performed nascent RNA-seq using 4-thiouracil labeling. Immediately after labeling, the levels of nascent rRNA in wild-type or fkbp39D cells were comparable (Figures 4B, S5F, and S5G), indicating that Fkbp39 is not required for rRNA transcription.
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 PBO:0111365 Although the overall Fkbp39 protein levels are slightly reduced in fkbp41D total lysates (Fig- ure S7E), there was a marked reduction of Fkbp39 localization specifically at 25S rDNA in those cells compared with wild- type (Figures 6A, 6B, and S7F).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 The structure of state 1 shows an early assembly intermediate with 23 ribosomal proteins and 19 biogenesis factors (Figure 2A; Table S2).
PMID:36423630 GO:0030685 We identi- fied 4 major states of nascent 60S, and each state could be further classified into multiple substates (Figures 2A and S3; Table 1). The nascent 60S associated with Fkbp39 represents early ribosome biogenesis stages as described below.
PMID:36423630 GO:0000785 In wild-type cells, Ytm1 is not detectable on chromatin, in agreement with our in vitro data showing that Fkbp39 sepa- rates ribosome biogenesis intermediates from chromatin (Figures 4A, S5A, and S5B).
PMID:36423630 GO:0032040 We isolated nascent 40S (also known as small subunit processome) by pull- ing down fibrillarin (Nop1)-associated particles (Figure S4I; Table S3; Data S1)
PMID:36423630 GO:0032040 We isolated nascent 40S (also known as small subunit processome) by pull- ing down fibrillarin (Nop1)-associated particles (Figure S4I; Table S3; Data S1)
PMID:36435910 PBO:0109107 Evidence: in vitro biochemical assays using purified tubulin and recombinant Dis1 protein / New GO term requested: microtubule destabilization activity
PMID:36435910 PBO:0109109 Figure 2a
PMID:36435910 PBO:0109110 Figure 2a
PMID:36435910 PBO:0109110 Figure 2a
PMID:36435910 PBO:0109107 Dis1 uses its TOG domains to induce microtubule catastrophe, in which polymerisation turns into depolymerisation
PMID:36435910 FYPO:0009057 Figure 2a
PMID:36481249 FYPO:0005097 The tor2-287 mutant cells also showed a similar phenotype after shifting at 36 ◦C (Fig. 3C, upper panel), indicating the G1 arrest.
PMID:36481249 FYPO:0005097 having 1C and 2C DNA peak (Fig. 3C, upper panel) with a majority of cells having 1C DNA peak indicating a G1 arrest while only 2C DNA peak was observed in wild type cells grown under similar conditions
PMID:36481249 PBO:0108766 The phosphorylation of Psk1 and Rps602 was completely abolished in wat1Δ, wat1-17, and tor2-287 mutants after shifting the cells at non-permissive temperature (Fig. 4A, upper and middle panel).
PMID:36481249 FYPO:0001029 cells were unable to grow on the plates containing canavanine (Fig. 4C). Interestingly, wat1Δ, wat1-17, and tor2-287 mutant cells exhibited resistance to canavanine (Fig. 4C) suggesting that disruption of wat1 leads to inactivation of the TORC1 pathway resulting in the defect in amino acid uptake
PMID:36481249 PBO:0108768 Real-time quantitative PCR analysis revealed the up-regulation of transcripts of per1 and isp5 genes and down regulation of cat1 gene in wat1Δ, wat1-17, and tor2-287 mutant background at the non-permissive temperature (Fig. 4B),
PMID:36481249 FYPO:0001492 wat1Δ and wat1-17 mutant cells were a little elongated with an average size of 18.5 μm (Fig. 3A and 3B).
PMID:36481249 FYPO:0002151 figure 1a
PMID:36481249 FYPO:0001492 wat1Δ and wat1-17 mutant cells were a little elongated with an average size of 18.5 μm (Fig. 3A and 3B).
PMID:36481249 PBO:0108775 The phosphorylation of Psk1 and Rps602 was completely abolished in wat1Δ, wat1-17, and tor2-287 mutants after shifting the cells at non-permissive temperature (Fig. 4A, upper and middle panel).
PMID:36481249 FYPO:0000648 In contrast, under the same condition, the wat1Δ and wat1-17 mutant cells became shorter in size with a round morphology having an average cell length of 7.7 and 8.3 μm, respectively (Fig. 3A and 3B)
PMID:36481249 FYPO:0000648 Interestingly, the average cell size of tor-287 mutant cells also decreases from 18.2 μm at 25 ◦C to 7.0 μm at 36 ◦C (Fig. 3A and 3B
PMID:36537249 PBO:0108732 abolished Mhf1 localization
PMID:36537249 FYPO:0004318 As shown in Fig. 1A,B, the percentage of mitotic WT cells displaying Plo1–GFP signals increased over time upon incubation at 16°C and, 8 h after cold treatment, ∼90% of WT cells were arrested at preanaphase, presumably due to the activation of the SAC. As Bub1 is a core component of the SAC (Fischer et al., 2021), the absence of Bub1 was expected to abolish the SAC. Consistently, the percentage of mitotic bub1Δ cells remained low (<10%) throughout the period of cold treatment (Fig. 1A,B).
PMID:36537249 PBO:0108788 mitotic prophase
PMID:36537249 GO:0005515 binds to Mhf1
PMID:36537249 GO:0005515 binds to Mhf2
PMID:36537249 PBO:0108746 Intriguingly, similar to the percentage of mitotic WT cells, the percentage of mitotic mhf2Δ cells increased over time upon cold treatment, but to a lesser degree (Fig. 1A,B).
PMID:36574843 PBO:0110788 figure3
PMID:36574843 PBO:0110786 (vw: did not reduce cell size further) EPISTATIC Consistent with this prediction, PTet-cdr2 did not reduce cell J. Biol. Chem. (2023) 299(2) 102831 3 Regulation of cell size and Wee1 by elevated levels of Cdr2 size in the temperature-sensitive wee1-50 mutant grown at 36 C (Fig. 2E).
PMID:36574843 GO:0031569 dosage dependent (We conclude that increased levels of Cdr2 cause hyperphosphorylation of Wee1 leading to reduced cell size at division.)
PMID:36574843 PBO:0110794 HYPERPHOSPHORYLATED WEE1 (get identifier)
PMID:36574843 FYPO:0003481 In contrast, Tet-based overexpression of cdr2(E177A) increased the size of dividing cells, consistent with dominant-negative effects for
PMID:36574843 PBO:0110786 Addition of Tet to PTet-cdr2 cells caused a marked and significant decrease in cell length at division (Fig. 2, A and B)
PMID:36574843 PBO:0110789 figure3
PMID:36574843 FYPO:0000017 neither Cdr2(1–330) nor Cdr2(1–590) truncations reduced cell size or formed cytoplasmic clusters (Fig. 7, B–D) despite expression of all constructs to similar levels (Fig. S3A).
PMID:36574843 FYPO:0000017 neither Cdr2(1–330) nor Cdr2(1–590) truncations reduced cell size or formed cytoplasmic clusters (Fig. 7, B–D) despite expression of all constructs to similar levels (Fig. S3A).
PMID:36574843 FYPO:0000648 However, induction of PTet-cdr2 in cdr1Δ cdr2Δ cells still reduced cell size, whereas PTet-cdr2(E177A) had no effect (Fig. 2, C and D).
PMID:36617881 GO:0010964 These results suggest that Epe1 promotes assembly of the RNAi machinery at constitutive heterochromatin by expressing dg/dh ncRNAs.
PMID:36626373 PBO:0025083 Thus we found that wildtype Cat1-GFP cells growing in nitrogen-starvation conditions is localised to the plasma membrane, particularly at the growing cell ends, as previously reported [12,26].
PMID:36633091 PBO:0107942 Fig. 5C
PMID:36633091 PBO:0107941 Fig. 5C
PMID:36633091 FYPO:0002071 Fig. 3B
PMID:36633091 FYPO:0000056 Fig. 1A, 1B, S1A
PMID:36633091 PBO:0107939 Fig. 1C, 1D and 1E
PMID:36633091 FYPO:0002071 Fig. 3B
PMID:36633091 PBO:0107940 Fig. 2D
PMID:36633091 FYPO:0003190 Fig. 2C
PMID:36633091 FYPO:0003194 Fig. 2C
PMID:36633091 FYPO:0009002 Fig. 1A, 1B, S1A
PMID:36633091 FYPO:0000895 Fig. 1A, 1B, S1A
PMID:36633091 PBO:0107943 Fig. 2A and 2C
PMID:36633091 PBO:0107941 Fig. 5C
PMID:36633091 PBO:0107942 Fig. 5C
PMID:36633091 PBO:0107936 Fig. 1C, ID and 1E
PMID:36633091 FYPO:0002029 Supplementary Fig. S1D and S1E
PMID:36633091 PBO:0107936 Fig. S1D and S1E
PMID:36633091 PBO:0107937 Fig. 2A and 2C
PMID:36633091 FYPO:0002071 Fig. 3B
PMID:36633091 PBO:0107938 Fig. 2A and 2B
PMID:36633091 PBO:0107939 Fig. 1C, Fig. 1D and Fig. 1E
PMID:36650056 FYPO:0000510 Change to: Nuclear congression without nuclear fusion
PMID:36650056 FYPO:0002890 change to: twin horsetail nucleus
PMID:36650056 FYPO:0004795 Was annotated as normal meiosis
PMID:36650056 FYPO:0002890 change to: twin horsetail nucleus
PMID:36650056 PBO:0102161 akr1Δ affecting tht1
PMID:36650056 FYPO:0000510 Change to: Nuclear congression without nuclear fusion
PMID:36650056 PBO:0102168 palmitoylation of tht1D is reduced by akr1D
PMID:36650056 PBO:0102167 Lower levels in the akr1 mutant
PMID:36650056 PBO:0102167 Lower levels in the akr1 mutant
PMID:36650056 FYPO:0000510 Change to: Nuclear congression without nuclear fusion
PMID:36650056 FYPO:0002890 change to: twin horsetail nucleus
PMID:36695178 PBO:0103279 Very high levels of diploidization in minimal medium
PMID:36695178 PBO:0103281 Sub-lethal phenotype, with only 10% of expected double mutants recovered.
PMID:36695178 FYPO:0005584 LC-MS
PMID:36695178 FYPO:0005585 LC-MS
PMID:36695178 FYPO:0005585 LC-MS
PMID:36695178 FYPO:0005585 LC-MS
PMID:36695178 FYPO:0005584 LC-MS
PMID:36695178 FYPO:0005584 LC-MS
PMID:36695178 PBO:0019210 Very prominent in minimal medium due to the lack of the Kennedy pathway precursors
PMID:36695178 FYPO:0006716 Severe buckling of the mitotic spindle was observed in 31% of cells, resulting in bowshaped nuclear intermediates during anaphase (Fig. 4D). It took longer for these nuclei to divide, and they often formed daughter nuclei of unequal sizes (Fig. S4E)
PMID:36695178 PBO:0103284 Severe buckling of the mitotic spindle was observed in 31% of cells, resulting in bowshaped nuclear intermediates during anaphase (Fig. 4D). It took longer for these nuclei to divide, and they often formed daughter nuclei of unequal sizes (Fig. S4E)
PMID:36695178 FYPO:0000229 Very prominent in minimal medium due to the lack of the Kennedy pathway precursors
PMID:36695178 PBO:0103280 Very prominent in minimal medium due to the lack of the Kennedy pathway precursors
PMID:36705602 PBO:0100540 Figure 3 summarizes data
PMID:36705602 PBO:0100540 Figure 3 summarizes data
PMID:36705602 PBO:0100540 Figure 3 summarizes data
PMID:36705602 PBO:0100540 Figure 3 summarizes data
PMID:36705602 PBO:0100540 Figure 3 summarizes data
PMID:36705602 PBO:0100540 Figure 3 summarizes data
PMID:36705602 PBO:0109293 Figure 3 summarizes data
PMID:36705602 PBO:0109293 Figure 3 summarizes data
PMID:36705602 PBO:0109293 Figure 3 summarizes data
PMID:36749320 PBO:0108664 Figure 10
PMID:36749320 PBO:0109286 Figure 10 - Manu: Transfer to FYPO:0008075
PMID:36749320 PBO:0109286 Figure 5A
PMID:36749320 PBO:0109286 Figure 5A
PMID:36749320 PBO:0109288 Figure 5A
PMID:36749320 PBO:0109286 Figure 5A
PMID:36749320 PBO:0109288 Figure 5A
PMID:36749320 PBO:0109287 Figure 5A
PMID:36749320 PBO:0109287 Figure 5A
PMID:36749320 PBO:0109287 Figure 5A
PMID:36749320 PBO:0109286 Figure 5A
PMID:36749320 PBO:0108665 Figure 10
PMID:36749320 PBO:0108667 Fig. 5 S2
PMID:36749320 PBO:0108668 Fig. 5 S2
PMID:36749320 PBO:0108668 Fig. 5 S2
PMID:36749320 PBO:0108669 Fig. 5 S2
PMID:36749320 PBO:0108666 Fig. 5 S2
PMID:36749320 PBO:0109288 Figure 5C
PMID:36749320 PBO:0109288 Figure 5C
PMID:36749320 PBO:0109286 Figure 5A
PMID:36749320 PBO:0109287 Figure 5A
PMID:36749320 PBO:0109288 Figure 5A
PMID:36749320 PBO:0109288 Figure 5A
PMID:36749320 PBO:0109288 Figure 5A
PMID:36749320 PBO:0109288 Figure 5A
PMID:36749320 PBO:0109286 Figure 5A
PMID:36749320 PBO:0109287 Figure 5A
PMID:36749320 PBO:0109286 Figure 5A
PMID:36749320 PBO:0109286 Figure 5A
PMID:36749320 PBO:0103081 Figure 3
PMID:36749320 PBO:0103081 Figure 3
PMID:36749320 PBO:0103081 Figure 3
PMID:36749320 PBO:0109286 Figure 5C
PMID:36749320 PBO:0109287 Figure 5
PMID:36749320 PBO:0108661 Figure 4
PMID:36749320 PBO:0109276 Figure 10
PMID:36749320 PBO:0109275 Figure 10
PMID:36749320 PBO:0108658 Figure 3
PMID:36749320 PBO:0098304 Figure 3
PMID:36749320 PBO:0098304 Figure 3
PMID:36749320 PBO:0098304 Figure 3
PMID:36749320 PBO:0098304 Figure 3
PMID:36749320 PBO:0098304 Figure 3
PMID:36749320 PBO:0098304 Figure 3
PMID:36749320 PBO:0098304 Figure 3
PMID:36749320 PBO:0098304 Figure 3
PMID:36749320 PBO:0098304 Figure 3
PMID:36749320 PBO:0108669 Fig. 5 S2
PMID:36749320 PBO:0108669 Fig. 5 S2
PMID:36749320 PBO:0108670 Fig. 3E
PMID:36749320 PBO:0108669 Fig. 5 S2
PMID:36749320 PBO:0098304 Figure 3
PMID:36749320 PBO:0098304 Figure 3
PMID:36749320 PBO:0103081 Figure 3
PMID:36749320 PBO:0103081 Figure 3
PMID:36749320 PBO:0109287 Figure 5B
PMID:36749320 PBO:0109286 Figure 10 - Manu: transfer to FYPO:0008075
PMID:36779416 PBO:0098000 non detectable Fig. 1. Phosphate starvation induces ecl3+ expression in a pho7+-dependent manner.
PMID:36779416 PBO:0092197 figure 1A,B
PMID:36779416 PBO:0098000 Phosphate starvation did not induce ecl3+ expression in Δckb1 cells, indicating that the induction was dependent on Ckb1 (Fig. 2B)
PMID:36779416 PBO:0098004 phosphate replete. Zfs1 is involved in the repression of the ecl3+ transcript level in a nutrient-rich environment but is not required for the induction by phosphate starvation. Next,
PMID:36779416 PBO:0098002 non detectable Fig. 1. Phosphate starvation induces ecl3+ expression in a pho7+-dependent manner.
PMID:36779416 PBO:0098001 non detectable Fig. 1. Phosphate starvation induces ecl3+ expression in a pho7+-dependent manner.
PMID:36793083 PBO:0093580 Fig. 3
PMID:36793083 PBO:0093616 Fig. 3
PMID:36793083 PBO:0093616 Fig. 3
PMID:36793083 PBO:0093616 Fig. 3
PMID:36793083 PBO:0093616 Fig. 3
PMID:36793083 PBO:0093616 Fig. 3
PMID:36793083 PBO:0093616 Fig. 3
PMID:36793083 PBO:0093616 Fig. 3
PMID:36793083 PBO:0093616 Fig. 3
PMID:36793083 PBO:0100810 Fig. 4D
PMID:36793083 PBO:0100811 Fig. 4D
PMID:36793083 PBO:0100812 Fig. 4D
PMID:36793083 PBO:0100812 Fig. 4D
PMID:36793083 PBO:0100813 Fig. 4D
PMID:36793083 PBO:0093616 Fig. 3
PMID:36793083 PBO:0100813 Fig. 4D
PMID:36793083 PBO:0100816 Fig. 4D
PMID:36793083 PBO:0100814 Fig. 4D
PMID:36793083 PBO:0100815 Fig. 4D
PMID:36793083 PBO:0093581 Fig. 3
PMID:36793083 PBO:0093581 Fig. 3
PMID:36793083 PBO:0093581 Fig. 3
PMID:36793083 PBO:0093581 Fig. 3
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092357 Figure S3
PMID:36794724 PBO:0092357 Figure S3
PMID:36794724 PBO:0092357 Figure S3
PMID:36794724 FYPO:0008102 Figure 8
PMID:36794724 PBO:0109762 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109761 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109760 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109759 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109758 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109757 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109756 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109755 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109754 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109753 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109752 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109751 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109750 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109749 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109748 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109747 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109746 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109745 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109744 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0109763 Figure 6
PMID:36794724 PBO:0109743 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109764 Figure 6
PMID:36794724 PBO:0109765 Figure 6
PMID:36794724 PBO:0109766 Figure 6
PMID:36794724 PBO:0109742 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109741 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109740 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109739 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109738 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109737 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109736 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109735 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109734 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109733 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109732 Figure 6, 7, 9 and 10
PMID:36794724 PBO:0109731 Figure 6, 7, 9 and 10
PMID:36794724 FYPO:0008123 Figure 5B
PMID:36794724 FYPO:0008119 Figure 5D ang G
PMID:36794724 PBO:0101499 Figure 1B
PMID:36794724 PBO:0109974 Figure 3A
PMID:36794724 PBO:0109974 Figure 3B
PMID:36794724 PBO:0109974 Figure 3C
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure 2
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092197 Figure S4
PMID:36794724 PBO:0092197 Figure S4
PMID:36799444 PBO:0109163 We performed an IP–WB experiment on the bqt4� background (‘bqt4�’ in Fig.2A). Deletion of bqt4+ did not affect these interactions, indicating that Cho2, Ole1 and Erg11 interact with Lem2 independent of Bqt4.
PMID:36799444 PBO:0109162 We performed an IP–WB experiment on the bqt4� background (‘bqt4�’ in Fig.2A). Deletion of bqt4+ did not affect these interactions, indicating that Cho2, Ole1 and Erg11 interact with Lem2 independent of Bqt4.
PMID:36799444 PBO:0109161 We performed an IP–WB experiment on the bqt4� background (‘bqt4�’ in Fig.2A). Deletion of bqt4+ did not affect these interactions, indicating that Cho2, Ole1 and Erg11 interact with Lem2 independent of Bqt4.
PMID:36799444 PBO:0109160 Finally, we examined whether Lem2 affected their subcellular localization. GFP-Cho2, GFP-Ole1 and Erg11-GFP were localized in the cortical ER and NE (or perinuclear ER), and deletion of the lem2+ gene did not affect the localization (Fig. 2B), indicating that Lem2 is not necessary for their NE localization
PMID:36799444 PBO:0109159 Finally, we examined whether Lem2 affected their subcellular localization. GFP-Cho2, GFP-Ole1 and Erg11-GFP were localized in the cortical ER and NE (or perinuclear ER), and deletion of the lem2+ gene did not affect the localization (Fig. 2B), indicating that Lem2 is not necessary for their NE localization
PMID:36799444 PBO:0109158 Finally, we examined whether Lem2 affected their subcellular localization. GFP-Cho2, GFP-Ole1 and Erg11-GFP were localized in the cortical ER and NE (or perinuclear ER), and deletion of the lem2+ gene did not affect the localization (Fig. 2B), indicating that Lem2 is not necessary for their NE localization
PMID:36799444 PBO:0109168 Fig.3D
PMID:36820394 PBO:0108812 Table 1
PMID:36820394 PBO:0108811 Table 1
PMID:36820394 PBO:0108810 Table 1
PMID:36820394 PBO:0108809 Table 1
PMID:36820394 PBO:0108808 Table 1
PMID:36820394 PBO:0108807 Table 1
PMID:36820394 PBO:0108806 Table 1
PMID:36820394 PBO:0108805 Table 1
PMID:36820394 PBO:0108804 Table 1
PMID:36820394 PBO:0108803 Table 1
PMID:36820394 PBO:0108802 Table 1
PMID:36820394 PBO:0108801 Table 1
PMID:36820394 PBO:0108800 Table 1
PMID:36820394 PBO:0108820 Table 1
PMID:36820394 PBO:0108818 Table 1
PMID:36820394 PBO:0108817 Table 1
PMID:36820394 PBO:0108816 Table 1
PMID:36820394 PBO:0108815 Table 1
PMID:36820394 PBO:0108814 Table 1
PMID:36820394 PBO:0108813 Table 1
PMID:36820394 PBO:0108821 Table 1
PMID:36820394 PBO:0108819 Table 1
PMID:36820394 PBO:0108799 Table 1
PMID:36820394 PBO:0108828 Table 1
PMID:36820394 PBO:0108829 Table 1
PMID:36820394 PBO:0108830 Table 1
PMID:36820394 PBO:0108831 Table 1
PMID:36820394 PBO:0108832 Table 1
PMID:36820394 PBO:0108798 Table 1
PMID:36820394 PBO:0108797 Table 1
PMID:36820394 PBO:0108796 Table 1
PMID:36820394 PBO:0108795 Table 1
PMID:36820394 PBO:0108791 Table 1
PMID:36820394 PBO:0108794 Table 1
PMID:36820394 PBO:0108793 Table 1
PMID:36820394 PBO:0108792 Table 1
PMID:36820394 PBO:0108793 Fig.1
PMID:36820394 PBO:0108793 Fig.1
PMID:36820394 PBO:0108793 Fig.1
PMID:36820394 PBO:0108792 Fig.1
PMID:36820394 PBO:0108792 Fig.1
PMID:36820394 PBO:0108792 Fig.1
PMID:36820394 PBO:0108791 Fig.1
PMID:36820394 PBO:0108791 Fig.1
PMID:36820394 PBO:0108791 Fig.1
PMID:36820394 PBO:0108827 Table 1
PMID:36820394 PBO:0108826 Table 1
PMID:36820394 PBO:0108825 Table 1
PMID:36820394 PBO:0108824 Table 1
PMID:36820394 PBO:0108823 Table 1
PMID:36820394 PBO:0108822 Table 1
PMID:36854376 FYPO:0008215 ). O1 decreased the average population cell length from 12 µm to 10.3 µm in the wild-type strain after incubation for 6 h at 29°C, whereas no such decrease by O1 was observed in the rho1-A62T strain, where average cell size is 12.3 µm in the DMSO control and 11.8 µm in the presence of O1 (figure 2c).
PMID:36854376 FYPO:0001357 The mutant strain appears to grow normally (figure 2b). O
PMID:36882296 PBO:0094738 Fig. 12B
PMID:36882296 FYPO:0002061 Fig. 1A
PMID:36882296 FYPO:0002061 Fig. 1A
PMID:36882296 FYPO:0002085 Figs. 1A, 5A, 6A, 7A, 8A
PMID:36882296 FYPO:0002085 Fig. 1A
PMID:36882296 PBO:0094738 Figs. 1B, 5B, 6B, 7B, 8B, 9B, 10B
PMID:36882296 FYPO:0000080 Fig. 1A
PMID:36882296 FYPO:0000080 Fig. 1A
PMID:36882296 PBO:0094771 Fig. 1B
PMID:36882296 PBO:0094771 Fig. 1B
PMID:36882296 PBO:0094771 Fig. 1B
PMID:36882296 FYPO:0000080 Fig. 1A
PMID:36882296 PBO:0094771 Fig. 1B
PMID:36882296 PBO:0094771 Fig. 1B
PMID:36882296 PBO:0094771 Fig. 1B
PMID:36882296 FYPO:0002085 Fig. 5A
PMID:36882296 FYPO:0002085 Fig. 5A
PMID:36882296 FYPO:0002061 Fig. 5A
PMID:36882296 FYPO:0002061 Fig. 5A
PMID:36882296 FYPO:0002061 Fig. 5A
PMID:36882296 FYPO:0002061 Fig. 5A
PMID:36882296 FYPO:0002085 Fig. 5A
PMID:36882296 FYPO:0002085 Fig. 5A
PMID:36882296 PBO:0094738 Fig. 5B
PMID:36882296 PBO:0094738 Fig. 5B
PMID:36882296 PBO:0094738 Fig. 5B
PMID:36882296 PBO:0094738 Fig. 5B
PMID:36882296 PBO:0094777 Fig. 5B
PMID:36882296 FYPO:0002085 Fig. 6A
PMID:36882296 FYPO:0002085 Fig. 6A
PMID:36882296 FYPO:0002085 Fig. 6A
PMID:36882296 FYPO:0002085 Fig. 6A
PMID:36882296 PBO:0106693 Fig. 13
PMID:36882296 PBO:0106693 Fig. 13
PMID:36882296 PBO:0106693 Fig. 13
PMID:36882296 PBO:0106693 Fig. 13
PMID:36882296 PBO:0094771 Fig. 13
PMID:36882296 FYPO:0001357 Fig. 9A
PMID:36882296 PBO:0099749 Fig. 4
PMID:36882296 PBO:0099749 Fig. 4
PMID:36882296 PBO:0094771 Fig. 4
PMID:36882296 PBO:0094771 Fig. 4
PMID:36882296 PBO:0108876 Fig. 3
PMID:36882296 PBO:0108864 Fig. 3
PMID:36882296 FYPO:0000080 Fig. 1A. Redundancy with rpb1-T4A
PMID:36882296 FYPO:0001355 Fig. S8
PMID:36882296 FYPO:0001355 Fig. S8
PMID:36882296 FYPO:0001355 Fig. S8
PMID:36882296 FYPO:0001355 Fig. S8
PMID:36882296 FYPO:0001355 Fig. S8
PMID:36882296 FYPO:0001355 Fig. S8
PMID:36882296 FYPO:0001355 Fig. S8
PMID:36882296 FYPO:0001355 Fig. S8
PMID:36882296 FYPO:0002061 Fig. S8
PMID:36882296 FYPO:0002061 Fig. S8
PMID:36882296 FYPO:0002061 Fig. S8
PMID:36882296 FYPO:0002061 Fig. S8
PMID:36882296 PBO:0094738 Fig. S7B
PMID:36882296 PBO:0094738 Fig. S7B
PMID:36882296 PBO:0094738 Fig. S7B
PMID:36882296 FYPO:0002085 Fig. S7A
PMID:36882296 FYPO:0002085 Fig. S7A
PMID:36882296 FYPO:0002085 Fig. S7A
PMID:36882296 PBO:0094771 Fig. S6B
PMID:36882296 PBO:0094771 Fig. S6B
PMID:36882296 FYPO:0002085 Fig. S6A
PMID:36882296 FYPO:0002085 Fig. S6A
PMID:36882296 PBO:0106693 Fig. S5B
PMID:36882296 FYPO:0002085 Fig. S5A
PMID:36882296 PBO:0108875 Fig. S3
PMID:36882296 PBO:0108874 Fig. S3
PMID:36882296 PBO:0108873 Fig. S3
PMID:36882296 PBO:0108872 Fig. S3
PMID:36882296 PBO:0108871 Fig. S3
PMID:36882296 PBO:0108870 Fig. S3
PMID:36882296 PBO:0108869 Fig. S3
PMID:36882296 PBO:0108868 Fig. S3
PMID:36882296 PBO:0108867 Fig. S3
PMID:36882296 PBO:0108866 Fig. S3
PMID:36882296 PBO:0108865 Fig. S3
PMID:36882296 PBO:0108864 Fig. S3
PMID:36882296 PBO:0098004 Fig. S3
PMID:36882296 PBO:0108863 Fig. S3
PMID:36882296 PBO:0096777 Fig. S3
PMID:36882296 PBO:0108862 Fig. S4
PMID:36882296 PBO:0108861 Fig. S4
PMID:36882296 PBO:0108800 Fig. S4
PMID:36882296 PBO:0108860 Fig. S4
PMID:36882296 PBO:0108859 Fig. S4
PMID:36882296 PBO:0108858 Fig. S4
PMID:36882296 PBO:0108857 Fig. S4
PMID:36882296 PBO:0108856 Fig. S4
PMID:36882296 PBO:0108855 Fig. S4
PMID:36882296 PBO:0108801 Fig. S4
PMID:36882296 PBO:0108854 Fig. S4
PMID:36882296 PBO:0108853 Fig. S4
PMID:36882296 PBO:0108822 Fig. S4
PMID:36882296 PBO:0108813 Fig. S4
PMID:36882296 PBO:0108852 Fig. S4
PMID:36882296 PBO:0108810 Fig. S4
PMID:36882296 PBO:0108807 Fig. S4
PMID:36882296 PBO:0108851 Fig. S4
PMID:36882296 PBO:0108804 Fig. S4
PMID:36882296 PBO:0108808 Fig. S4
PMID:36882296 PBO:0108809 Fig. S4
PMID:36882296 PBO:0108850 Fig. S4
PMID:36882296 PBO:0108812 Fig. S4
PMID:36882296 FYPO:0002085 Fig. 12A
PMID:36882296 FYPO:0002085 Fig. 12A
PMID:36882296 PBO:0094777 Fig. 9B
PMID:36882296 PBO:0094777 Fig. 7B
PMID:36882296 PBO:0094777 Fig. 12B
PMID:36882296 FYPO:0002085 Fig. 12A
PMID:36882296 PBO:0094738 Fig. 11B
PMID:36882296 PBO:0094738 Fig. 11B
PMID:36882296 PBO:0094738 Fig. 11B
PMID:36882296 PBO:0094738 Fig. 11B
PMID:36882296 FYPO:0002085 Fig. 11A
PMID:36882296 PBO:0094771 Fig. 10B
PMID:36882296 PBO:0094771 Fig. 10B
PMID:36882296 FYPO:0001355 Fig. 10A
PMID:36882296 FYPO:0001355 Fig. 10A
PMID:36882296 FYPO:0002085 Fig. 10A
PMID:36882296 FYPO:0002085 Fig. 10A
PMID:36882296 PBO:0094771 Fig. 9B
PMID:36882296 PBO:0094771 Fig. 9B
PMID:36882296 PBO:0094771 Fig. 9B
PMID:36882296 PBO:0094771 Fig. 9B
PMID:36882296 PBO:0094738 Fig. 9B
PMID:36882296 PBO:0094738 Fig. 9B
PMID:36882296 PBO:0094738 Fig. 9B
PMID:36882296 FYPO:0000082 Fig. 9A
PMID:36882296 FYPO:0001355 Fig. 9A
PMID:36882296 FYPO:0000080 Fig. 9A
PMID:36882296 FYPO:0000080 Fig. 9A
PMID:36882296 FYPO:0000080 Fig. 9A
PMID:36882296 FYPO:0000080 Fig. 9A
PMID:36882296 FYPO:0000080 Fig. 9A
PMID:36882296 PBO:0094771 Fig. 8B
PMID:36882296 FYPO:0002085 Fig. 8A
PMID:36882296 PBO:0094771 Fig. 8B
PMID:36882296 FYPO:0002085 Fig. 8A
PMID:36882296 PBO:0094738 Fig. 7B
PMID:36882296 PBO:0094738 Fig. 7B
PMID:36882296 PBO:0094738 Fig. 7B
PMID:36882296 PBO:0094738 Fig. 7B
PMID:36882296 PBO:0094738 Fig. 7B
PMID:36882296 PBO:0094738 Fig. 7B
PMID:36882296 FYPO:0002085 Fig. 7A
PMID:36882296 FYPO:0002085 Fig. 7A
PMID:36882296 PBO:0093554 Fig. 7A
PMID:36882296 FYPO:0002085 Fig. 7A
PMID:36882296 FYPO:0002085 Fig. 7A
PMID:36882296 FYPO:0002085 Fig. 7A
PMID:36882296 FYPO:0002085 Fig. 7A
PMID:36882296 PBO:0094738 Fig. 7B, 10B, 12B
PMID:36882296 PBO:0094771 Fig. 6B
PMID:36882296 PBO:0094771 Fig. 6B
PMID:36882296 PBO:0094771 Fig. 6B
PMID:36882296 PBO:0094771 Fig. 6B
PMID:36882296 PBO:0094771 Fig. 6B
PMID:36882296 PBO:0094771 Fig. 6B
PMID:36882296 PBO:0094771 Fig. 6B
PMID:36882296 PBO:0094771 Fig. 6B
PMID:36882296 PBO:0094771 Fig. 6B
PMID:36882296 PBO:0094771 Fig. 6B
PMID:36882296 PBO:0094771 Fig. 6B
PMID:36882296 PBO:0094771 Fig. 6B
PMID:36882296 PBO:0094771 Fig. 6B
PMID:36882296 PBO:0094771 Fig. 6B
PMID:36882296 FYPO:0002085 Fig. 6A
PMID:36882296 FYPO:0002085 Fig. 6A
PMID:36882296 FYPO:0002085 Fig. 6A, 10A
PMID:36951094 PBO:0112658 Fig. 2D
PMID:36951094 PBO:0112660 Fig. 2D
PMID:36951094 PBO:0112660 Fig. 2D
PMID:36951094 PBO:0112660 Fig. 2D
PMID:36951094 PBO:0112660 Fig. 2D
PMID:36951094 PBO:0112660 Fig. 2D
PMID:36951094 PBO:0112659 Fig. 2A
PMID:36951094 PBO:0112658 Fig. 2A
PMID:36951094 PBO:0112308 Fig. 6C
PMID:36951094 PBO:0112657 Fig. 5B and 5C
PMID:36951094 FYPO:0000468 Fig. 5B
PMID:36951094 FYPO:0000468 Fig. 5B
PMID:36951094 PBO:0112307 Fig. 5B and 5C
PMID:36951094 PBO:0112307 Fig. 5C
PMID:36951094 PBO:0112665 the AT-hook motifs were required for the mat3-M donor choice.
PMID:36951094 PBO:0112664 the Swi6-binding site was required for the mat2-P donor choice
PMID:36951094 GO:0007534 Rad54 further stimulates the activation of strand invasion of Rad51 by the Swi2-Swi5 complex.
PMID:36951094 GO:0007534 we demonstrated that the Swi2-Swi5 complex promotes Rad51-driven strand invasion in vitro
PMID:36951094 GO:0007534 we demonstrated that the Swi2-Swi5 complex promotes Rad51-driven strand invasion in vitro
PMID:36951094 PBO:0112307 Fig. 6C
PMID:36951094 PBO:0112657 Fig. 6C
PMID:36951094 PBO:0112663 Fig. 6A
PMID:36951094 PBO:0112663 Fig. 6A
PMID:36951094 PBO:0112308 Fig. 5C
PMID:36951094 PBO:0112308 Fig. 5C
PMID:36951094 PBO:0112657 Fig. 5C
PMID:36951094 PBO:0112662 Fig. 3C
PMID:36951094 PBO:0112661 Fig. 3C
PMID:36951094 PBO:0112308 Fig. 5C
PMID:36951094 GO:0007535 we demonstrated that the Swi2-Swi5 complex promotes Rad51-driven strand invasion in vitro
PMID:36951094 PBO:0112661 Fig. 3C
PMID:36951094 PBO:0112659 Fig. 2D
PMID:36951094 PBO:0112659 Fig. 2D
PMID:36951094 PBO:0112658 Fig. 2D
PMID:36951094 PBO:0112658 Fig. 2D
PMID:37052630 PBO:0097264 Fig. 2b - control is the overexpressed pka1D with overexpressed wild-type (nmt81)
PMID:37052630 PBO:0097264 Fig. 2b - control is the overexpressed pka1D with overexpressed wild-type (nmt81)
PMID:37052630 PBO:0097264 Fig. 2b - control is the overexpressed pka1D with overexpressed wild-type (nmt81)
PMID:37052630 PBO:0109067 Fig. 2b - control is the overexpressed pka1D with overexpressed wild-type (nmt81)
PMID:37052630 PBO:0109067 Fig. 2b - control is the overexpressed pka1D with overexpressed wild-type (nmt81)
PMID:37052630 PBO:0093564 Fig. 2b - control
PMID:37052630 PBO:0093564 Main text Table S1
PMID:37052630 PBO:0093564 Main text Table S1
PMID:37052630 PBO:0093564 Main text Table S1
PMID:37052630 PBO:0093564 Main text Table S1
PMID:37052630 PBO:0093564 Main text Table S1
PMID:37052630 PBO:0093594 Fig. S1
PMID:37052630 PBO:0107560 Fig. S1
PMID:37052630 PBO:0093570 Fig. S1
PMID:37052630 PBO:0097264 Fig. 2b - control is the overexpressed pka1D with overexpressed wild-type (nmt81)
PMID:37076472 GO:0033698 Figure 1.
PMID:37076472 GO:0033698 Figure 1.
PMID:37076472 GO:0033698 Figure 1.
PMID:37076472 GO:0033698 Figure 1.
PMID:37076472 GO:0033698 Figure 1.
PMID:37076472 GO:0033698 Figure 1.
PMID:37076472 GO:0033698 Figure 1.
PMID:37076472 GO:0033698 Figure 1.
PMID:37076472 GO:0032221 Figure 3.
PMID:37076472 GO:0032221 Figure 3.
PMID:37076472 GO:0032221 Figure 3.
PMID:37076472 GO:0032221 Figure 3.
PMID:37076472 GO:0032221 Figure 3.
PMID:37076472 GO:0032221 Figure 3.
PMID:37076472 GO:0033698 Figure 1.
PMID:37099380 FYPO:0009106 Closer to ring
PMID:37099380 FYPO:0006338 Closer to tip
PMID:37099380 FYPO:0006338 Closer to tip
PMID:37120429 FYPO:0001234 The suppressive effect of TA and EK on EA defects in non-essential functions were not specific to S. cerevisiae, as these mutations also rescued SpHsp90-EA mediated temperature sensitivity in Sz. pombe (Fig. 5d).
PMID:37120429 FYPO:0002061 Sz. pombe cells expressing SpHsp90-EA had an osmolyte-remediated temperature sensitivity phenotype, which strongly suggested conservation of EA-specific phenotypes (Fig. 3b).
PMID:37120429 FYPO:0001357 Sz. pombe cells expressing SpHsp90-EA had an osmolyte-remediated temperature sensitivity phenotype, which strongly suggested conservation of EA-specific phenotypes (Fig. 3b).
PMID:37120429 FYPO:0002060 Using this system, we observed that SpHsp90-EA supported viability of Sz. pombe cells (Fig. 1b).
PMID:37120429 FYPO:0001234 The suppressive effect of TA and EK on EA defects in non-essential functions were not specific to S. cerevisiae, as these mutations also rescued SpHsp90-EA mediated temperature sensitivity in Sz. pombe (Fig. 5d).
PMID:37128864 PBO:0109302 Cell length increases during log and stationary phases at 32 degree.
PMID:37128864 GO:0140602 Localization depends on Cdc2 kinase activity but not on Clp1.
PMID:37128864 PBO:0102449 The phenotype can be seen at 32 degree.
PMID:37128864 PBO:0109305 The phenotype can be seen at 32˚C. The phenotype can be seen at 32˚C. Furthermore, the log phase chromosomes more actively fluctuated in cdc2-L7 cells than in WT cells, and despite a repression in chromosome fluctuation, fluctuation was still elevated in the stationary phase, as demonstrated by an upward shift of the cdc2-L7 MSD plot of the ade6 locus and a complete lack of an overlap of their 95% confidence intervals with those of the WT plot (Fig. 5H).
PMID:37128864 PBO:0093606 Loss of viability is evident only when cells are exposed to 32 degree before and upon entry into stationary phase.
PMID:37128864 PBO:0109304 The N/C ratio was also reduced but not significantly different from that of stationary phase cells (Fig. 1E; Fig. S1G), suggesting that the observed nuclear size differences from stationary phase originate from the cell size differences.
PMID:37156397 PBO:0109152 The amount of Coq4 was significantly reduced in ∆coq11 and ∆coq12 single mutants
PMID:37156397 PBO:0109154 The amount of Coq4 was significantly reduced in ∆coq11 and ∆coq12 single mutants
PMID:37156397 GO:0006744 low CoQ10 level
PMID:37156397 GO:0005739 LC-MS analysis
PMID:37156397 PBO:0109151 (Figs. 2A, S1A) Like other mutants lacking CoQ, the ∆coq11 strain showed better growth on cysteine-containing medium.
PMID:37156397 PBO:0105960 Figs. 3, S1C. Similar to the Δcoq2 (ppt1) strain, the Δcoq11 and Δcoq12 strains grew more slowly in the presence of 1 and 2 mM hydrogen peroxide or 0.5 mM CuSO4 than in its absence
PMID:37156397 FYPO:0001413 (Fig. 4) The results revealed higher sulfide levels in both Δcoq11 and Δcoq12 strains
PMID:37156397 GO:0006744 low CoQ10 level
PMID:37156397 GO:0005739 Coq12-GFP fusion (Fig. 8A). The GFP fluorescence pattern was similar to that of Mitotracker Red, a mitochondria stain. Mitochondrial localization of Coq12 was therefore confirmed
PMID:37156397 GO:0005739 LC-MS
PMID:37156397 PBO:0109151 (Fig. 2A) By contrast, the ∆coq12 strain showed almost no growth on PMLU medium containing cysteine.
PMID:37156397 FYPO:0000103 Figs. 3, S1C. Similar to the Δcoq2 (ppt1) strain, the Δcoq11 and Δcoq12 strains grew more slowly in the presence of 1 and 2 mM hydrogen peroxide or 0.5 mM CuSO4 than in its absence
PMID:37156397 PBO:0109153 (Fig. 4) The results revealed higher sulfide levels in both Δcoq11 and Δcoq12 strains
PMID:37156397 FYPO:0002061 Figs. 2B, S1B
PMID:37156397 FYPO:0002061 Figs. 2B, S1B
PMID:37156397 FYPO:0002061 Figs. 2B, S1B
PMID:37156397 FYPO:0002061 Figs. 2B, S1B
PMID:37156397 FYPO:0002061 Figs. 2B, S1B
PMID:37156397 FYPO:0002061 Figs. 2B, S1B
PMID:37156397 FYPO:0002061 Figs. 2B, S1B
PMID:37156397 FYPO:0001355 We first noticed that ∆coq11 and ∆coq12 strains did not grow well on minimal medium, as was observed for CoQ-deficient S. pombe (Fig. 2A, S1A)
PMID:37156397 PBO:0105857 As a result, we obtained 42 strains in which the CoQ10 content was lower than half that of the wild-type (WT) strain. The 10 mutants with the lowest CoQ10 levels are listed in Table 1
PMID:37156397 PBO:0105857 As a result, we obtained 42 strains in which the CoQ10 content was lower than half that of the wild-type (WT) strain. The 10 mutants with the lowest CoQ10 levels are listed in Table 1
PMID:37156397 PBO:0105857 As a result, we obtained 42 strains in which the CoQ10 content was lower than half that of the wild-type (WT) strain. The 10 mutants with the lowest CoQ10 levels are listed in Table 1
PMID:37156397 PBO:0105857 As a result, we obtained 42 strains in which the CoQ10 content was lower than half that of the wild-type (WT) strain. The 10 mutants with the lowest CoQ10 levels are listed in Table 1
PMID:37156397 PBO:0105857 As a result, we obtained 42 strains in which the CoQ10 content was lower than half that of the wild-type (WT) strain. The 10 mutants with the lowest CoQ10 levels are listed in Table 1
PMID:37156397 PBO:0105857 As a result, we obtained 42 strains in which the CoQ10 content was lower than half that of the wild-type (WT) strain. The 10 mutants with the lowest CoQ10 levels are listed in Table 1
PMID:37156397 PBO:0105857 As a result, we obtained 42 strains in which the CoQ10 content was lower than half that of the wild-type (WT) strain. The 10 mutants with the lowest CoQ10 levels are listed in Table 1
PMID:37156397 PBO:0105857 As a result, we obtained 42 strains in which the CoQ10 content was lower than half that of the wild-type (WT) strain. The 10 mutants with the lowest CoQ10 levels are listed in Table 1
PMID:37156397 FYPO:0002061 Figs. 2B, S1B
PMID:37156397 PBO:0109155 Interestingly, NAD+ reduction activity was clearly detected in purified Coq12-8xHis from S. pombe (Fig. 9A)
PMID:37156397 FYPO:0002061 Figs. 2B, S1B
PMID:37156397 FYPO:0002061 Figs. 2B, S1B
PMID:37156397 FYPO:0002061 Figs. 2B, S1B
PMID:37156397 PBO:0093578 Figs. 3, S1C. Similar to the Δcoq2 (ppt1) strain, the Δcoq11 and Δcoq12 strains grew more slowly in the presence of 1 and 2 mM hydrogen peroxide or 0.5 mM CuSO4 than in its absence
PMID:37156397 FYPO:0000087 Figs. 3, S1C. Similar to the Δcoq2 (ppt1) strain, the Δcoq11 and Δcoq12 strains grew more slowly in the presence of 1 and 2 mM hydrogen peroxide or 0.5 mM CuSO4 than in its absence
PMID:37158439 FYPO:0000674 Figure 3C
PMID:37158439 FYPO:0000674 Figure 3B
PMID:37158439 FYPO:0004481 Figure 3B
PMID:37158439 FYPO:0004481 Figure 3B
PMID:37158439 FYPO:0000639 Figure 2 Fig. 2. fic1-2A myo2-E1 cells can achieve membrane ingression and cell separation at myo2-E1’s restrictive temperature
PMID:37158439 FYPO:0008090 Figure 1
PMID:37158439 FYPO:0007774 Figure 4C
PMID:37158439 FYPO:0000674 Figure 4D
PMID:37158439 FYPO:0000080 Figure S1
PMID:37158439 FYPO:0000082 Figure 4D
PMID:37158439 FYPO:0008090 Figure 2
PMID:37158439 FYPO:0008090 Figure 1
PMID:37158439 FYPO:0000674 Figure S2
PMID:37158439 FYPO:0004481 Figure S2
PMID:37158439 FYPO:0000674 Figure S3
PMID:37158439 FYPO:0004481 Figure S3
PMID:37158439 FYPO:0004481 Figure S3
PMID:37158439 FYPO:0000674 Figure S3
PMID:37158439 FYPO:0000674 Figure S3
PMID:37158439 FYPO:0004481 Figure S3
PMID:37158439 FYPO:0000674 Figure S3
PMID:37158439 FYPO:0004557 From this screen we observed one significant interaction: fic1’s phospho-ablating mutant, fic1-2A, suppressed myo2-E1
PMID:37158439 FYPO:0004557 From this screen we observed one significant interaction: fic1’s phospho-ablating mutant, fic1-2A, suppressed myo2-E1
PMID:37158439 FYPO:0008090 Figure 1
PMID:37158439 FYPO:0004481 Figure 3C
PMID:37158439 FYPO:0000674 Figure 3C
PMID:37158439 FYPO:0000202 Figure 1E and G
PMID:37158439 FYPO:0003532 Figure 4A
PMID:37158439 FYPO:0003532 Figure 4A
PMID:37158439 FYPO:0003532 Figure 4A
PMID:37158439 FYPO:0003532 Figure 4A
PMID:37158439 FYPO:0003532 Figure 4A
PMID:37158439 FYPO:0003532 Figure 4A
PMID:37158439 PBO:0109255 Figure 1B
PMID:37158439 FYPO:0003532 Figure 4A
PMID:37158439 FYPO:0007774 Figure 4C
PMID:37158439 FYPO:0007774 Figure 4C
PMID:37158439 FYPO:0007774 Figure 4C
PMID:37158439 FYPO:0007774 Figure 4C
PMID:37158439 FYPO:0007774 Figure 4C
PMID:37158439 FYPO:0004481 Figure 1B. From this screen we observed one significant interaction: fic1’s phospho-ablating mutant, fic1-2A, suppressed myo2-E1
PMID:37158439 FYPO:0004481 Figure 1C
PMID:37158439 FYPO:0004481 Figure 1C
PMID:37158439 FYPO:0000202 Figure 1E and G
PMID:37158439 FYPO:0005905 Figure 1 E and G
PMID:37158439 FYPO:0005905 Figure 1E and G
PMID:37158439 FYPO:0008090 Figure 1
PMID:37158439 FYPO:0000082 Figure 4D
PMID:37158439 FYPO:0004481 Figure 3C We next asked if S. pombe Cyk3 was required for fic1-2A’s suppression of myo2-E1. Indeed, cyk3Δ prevented fic1-2A from suppressing myo2-E1
PMID:37158439 FYPO:0004481 Figure 3C
PMID:37158439 FYPO:0004481 Figure 3C
PMID:37158439 FYPO:0000674 Figure 3C
PMID:37158439 FYPO:0000674 Figure S1
PMID:37158439 FYPO:0000674 Figure S1
PMID:37158439 FYPO:0000639 Figure 2 Fig. 2. fic1-2A myo2-E1 cells can achieve membrane ingression and cell separation at myo2-E1’s restrictive temperature
PMID:37158439 PBO:0109256 Figure 2
PMID:37158439 FYPO:0001760 Figure 2
PMID:37158439 FYPO:0004481 Figure S2
PMID:37158439 FYPO:0000674 Figure S2
PMID:37158439 FYPO:0000082 Figure S1
PMID:37158439 FYPO:0000082 Figure S1
PMID:37158439 FYPO:0000674 Figure S1
PMID:37158439 FYPO:0000674 Figure S1
PMID:37158439 FYPO:0004481 Figure 3C We next asked if S. pombe Cyk3 was required for fic1-2A’s suppression of myo2-E1. Indeed, cyk3Δ prevented fic1-2A from suppressing myo2-E1
PMID:37158439 FYPO:0006879 Figure 2
PMID:37160462 PBO:0109839 Phenotype complementation by human RAD23A
PMID:37162093 FYPO:0000017 Figure 7
PMID:37162093 FYPO:0001420 Figure 4BD, Figure 6BDE
PMID:37162093 FYPO:0002058 Figure S2
PMID:37162093 FYPO:0002058 Figure S2
PMID:37162093 FYPO:0001420 Figure 6BDE, Figure S2
PMID:37162093 PBO:0093560 Figure 3AD, Figure 6ACE
PMID:37162093 FYPO:0002104 Figure 7
PMID:37162093 FYPO:0002104 Figure 7
PMID:37162093 FYPO:0002273 Figure 7
PMID:37162093 FYPO:0002058 Figure 4BD
PMID:37162093 FYPO:0002105 Figure 7
PMID:37162093 FYPO:0002058 Figure 5AB
PMID:37162093 FYPO:0002058 Figure 5AB
PMID:37162093 FYPO:0001420 Figure 5AB, Figure S3
PMID:37162093 FYPO:0002104 Figure 7
PMID:37162093 PBO:0093561 Figure 3BE, Figure 6ACE
PMID:37162093 FYPO:0002058 Figure 4AC
PMID:37162093 FYPO:0002058 Figure 4AC
PMID:37162093 PBO:0093561 Figure 4AC, Figure 6BDE
PMID:37162093 FYPO:0002058 Figure 4BD
PMID:37162093 PBO:0093559 Figure 3CF, Figure 6ACE
PMID:37164017 PBO:0093561 Growth rate improved by addition of either glutamate, glutamine, or arginine
PMID:37164017 FYPO:0001355 Growth rate improved by addition of arginine
PMID:37191320 GO:0090158 The growth defect of the triple mutant strain defective in Spo7, Rtn1, and Yop1 is restored by the overexpression of the budding yeast reticulophagy receptor Atg40, a reticulon- and REEP-like protein that contains an ER-shaping activit
PMID:37191320 PBO:0109199 (Fig. S4F), the ΔC21–60 and ΔN29 mutants exhibited partial and severe defects in reticulophagy, respectively, whereas the both mutant proteins were detectable on the ER (Fig. S4G)
PMID:37191320 PBO:0109200 Fig. S4E revealed that the ER-shaping activities of the ΔC21–60 and ΔN29 mutants were partially and severely impaired, respectively (Fig. S4E)
PMID:37191320 PBO:0109201 (Fig. S4F), the ΔC21–60 and ΔN29 mutants exhibited partial and severe defects in reticulophagy, respectively, whereas the both mutant proteins were detectable on the ER (Fig. S4G)
PMID:37191320 PBO:0109202 Fig. S4E revealed that the ER-shaping activities of the ΔC21–60 and ΔN29 mutants were partially and severely impaired, respectively (Fig. S4E)
PMID:37191320 PBO:0104254 In hva22Δ cells, reticulophagy was abolished, similar to cells lacking the core autophagy protein Atg1 (Figure 1B).
PMID:37191320 GO:0016236 Next, selective types of autophagy, such as mitophagy and pexophagy, were monitored by the processing of the mitochondrial protein Tuf1- RFP or Sdh2-GFP [21] and the peroxisomal protein Pex11- GFP, respectively. We observed that the hva22Δ mutant was partially defective in both mitophagy (Figure 2D and Fig. S2E) and pexophagy (Figure 2E).
PMID:37191320 GO:0044804 We further found that the inner nuclear membrane protein Lem2 [26] was also degraded in a manner dependent on Hva22 (Figure 1H,I), indicating that the nuclear envelope undergoes Hva22- dependent reticulophagy. (vw I think this should be nucleophagy becasue IMN is not comnnected to ER)
PMID:37191320 GO:0005783 Consistently, Hva22 was observed on the ER under both nitrogen-rich and starvation conditions (Figure 3C).
PMID:37192628 FYPO:0003810 Overexpression of Atg44 in both species caused mitochondrial fragmentation not only in wild-type cells but also in Dnm1-deficient cells (Figures 3E and 3F).
PMID:37192628 PBO:0109197 As expected, in S. pombe atg44D cellslacking Mgm1, some of the mitochondria became fragmentedand mitophagy was partially rescued (Figures 4A and S3F).
PMID:37192628 FYPO:0007594 In atg44D cells, mitophagy was completely blocked similarly to cells lacking Atg1, a core autophagy protein (Figures 1A and S1B).
PMID:37192628 GO:0005758 Based on these results, we conclude that Atg44 localizes in the IMS and is not a transmembrane protein.
PMID:37192628 PBO:0109196 Unexpectedly, wenoticed that addition of Sp-Atg44 caused fragmentation of lipid bilayers on the mica (compare Figures 7B and 7C), and the fragmented lipid bilayers abundant with Sp-Atg44 underwent division and fusion (Figure 7D; Video S6). These observations suggest that Sp-Atg44 has the ability to cause membrane fragility through physical interaction.
PMID:37192628 GO:0008289 Atg44 binds to lipid membranes in vitro (Figures 5A and 5E), and the cryo-EM and HS-AFM analyses (Figures 5F–5I) suggest that Atg44 tends to bind to lipid membranes with high curvature.
PMID:37192628 FYPO:0004340 Similarly, loss of Atg44 in S. pombe affected mitochondrial morphology; some of the Sp-atg44D cells showed spherically enlarged mitochondria like Sp-dnm1D cells (Figure 3D)
PMID:37192628 FYPO:0007448 Loss of Atg44 in either S. pombe or S. cerevisiae did not or only marginally affected non-selective macroautophagy, as measured by GFP/RFP processing (Figures S1C, S1D, and S1F) or the Pho8D60 assay (Figure 1E), or other types of selective autophagy including the Cvt pathway that delivers the precursor form of the hydrolase aminopeptidase I to the vacuole (Figure S1G), endoplasmic reticulum-phagy/reticulophagy (Figures S1E and S1H), and pexophagy (Figure S1I), suggesting that Atg44 is specifically required for mitophagy.
PMID:37192628 PBO:0109197 As expected, in S. pombe atg44D cellslacking Mgm1, some of the mitochondria became fragmentedand mitophagy was partially rescued (Figures 4A and S3F).
PMID:37200372 FYPO:0000088 Fig. 1
PMID:37200372 PBO:0093587 Fig. 7
PMID:37200372 PBO:0093587 Fig. 7
PMID:37200372 PBO:0093613 Fig. 7
PMID:37200372 FYPO:0000268 Fig. 7
PMID:37200372 FYPO:0000268 Fig. 7
PMID:37200372 PBO:0093587 Fig. 7
PMID:37200372 PBO:0093587 Fig. 7
PMID:37200372 PBO:0093587 Fig. 7
PMID:37200372 PBO:0093613 Fig. 7
PMID:37200372 FYPO:0000085 Fig. 7
PMID:37200372 FYPO:0000085 Fig. 7
PMID:37200372 FYPO:0000268 Fig. 7
PMID:37200372 PBO:0093629 Fig. 7
PMID:37200372 FYPO:0000268 Fig. 7
PMID:37200372 PBO:0109430 Fig. S12
PMID:37200372 PBO:0109430 Fig. S12
PMID:37200372 PBO:0109429 Fig. S12
PMID:37200372 PBO:0109428 Fig. S12
PMID:37200372 PBO:0100985 Fig. S12
PMID:37200372 PBO:0109421 Fig. 6
PMID:37200372 PBO:0109421 Fig. 6
PMID:37200372 PBO:0109427 Fig. 6
PMID:37200372 PBO:0109427 Fig. 6
PMID:37200372 PBO:0109426 Fig. 6
PMID:37200372 PBO:0109426 Fig. 6
PMID:37200372 PBO:0109419 Fig. 6
PMID:37200372 PBO:0109418 Fig. 6
PMID:37200372 PBO:0109414 Fig. 6
PMID:37200372 PBO:0109414 Fig. 6
PMID:37200372 FYPO:0000088 Fig. 6
PMID:37200372 PBO:0109412 Fig. 6B
PMID:37200372 FYPO:0000089 Fig. 6
PMID:37200372 PBO:0109425 Fig. 6B
PMID:37200372 FYPO:0000089 Fig. 6
PMID:37200372 FYPO:0000088 Fig. 6
PMID:37200372 FYPO:0001355 Fig. S2 and text
PMID:37200372 FYPO:0002060 Fig. S2 and text
PMID:37200372 FYPO:0002061 Fig. S2 and text
PMID:37200372 FYPO:0002061 Fig. S2 and text
PMID:37200372 PBO:0109424 Fig. 2
PMID:37200372 PBO:0109424 Fig. 2
PMID:37200372 PBO:0109424 Fig. 2
PMID:37200372 PBO:0109423 Fig. 2
PMID:37200372 PBO:0109423 Fig. 2
PMID:37200372 PBO:0109422 Fig. 2
PMID:37200372 PBO:0109422 Fig. 2
PMID:37200372 PBO:0109422 Fig. 2
PMID:37200372 PBO:0109421 Fig. 2
PMID:37200372 PBO:0109420 Fig. 2
PMID:37200372 PBO:0109421 Fig. 2
PMID:37200372 PBO:0109420 Fig. 2
PMID:37200372 PBO:0109419 Fig. 1
PMID:37200372 PBO:0109419 Fig. 1
PMID:37200372 PBO:0109418 Fig. 1
PMID:37200372 PBO:0109418 Fig. 1
PMID:37200372 PBO:0109417 Fig. 1
PMID:37200372 PBO:0109416 Fig. 1
PMID:37200372 PBO:0109415 Fig. 1
PMID:37200372 PBO:0109415 Fig. 1
PMID:37200372 PBO:0109414 Fig. 1
PMID:37200372 PBO:0109413 Fig. 1
PMID:37200372 PBO:0109412 Fig. 1
PMID:37200372 PBO:0109411 Fig. 1
PMID:37200372 PBO:0109411 Fig. 1
PMID:37200372 PBO:0109411 Fig. 1
PMID:37200372 FYPO:0000089 Fig. 1
PMID:37200372 FYPO:0000089 Fig. 1
PMID:37200372 FYPO:0000089 Fig. 1
PMID:37200372 FYPO:0000089 Fig. 1
PMID:37200372 FYPO:0000089 Fig. 1
PMID:37200372 FYPO:0000089 Fig. 1
PMID:37200372 FYPO:0000088 Fig. 1
PMID:37200372 FYPO:0000088 Fig. 1
PMID:37200372 FYPO:0000088 Fig. 1
PMID:37200372 FYPO:0000088 Fig. 1
PMID:37200372 FYPO:0000088 Fig. 1
PMID:37200372 FYPO:0000088 Fig. 1
PMID:37237082 PBO:0093579 figure 5e
PMID:37237082 FYPO:0001355 Like srr1Δ cells, srr1-W157R, srr1-D111A,P112A, and srr1-H184A cells produced small colonies (Supplementary Fig. 2b), consistent with the role of the SRR1-like domain even in the absence of exogenous DNA damage.
PMID:37237082 FYPO:0001355 Like srr1Δ cells, srr1-W157R, srr1-D111A,P112A, and srr1-H184A cells produced small colonies (Supplementary Fig. 2b), consistent with the role of the SRR1-like domain even in the absence of exogenous DNA damage.
PMID:37237082 PBO:0096838 The rad52-R45K, rad52Δ, and srr1Δ mutations eliminate ~90% of isochromosomes in rad51Δ cells (Fig. 2c and ref. 32), indicating that both Rad52 and Srr1 are essential for the major pathway of isochromosome formation.
PMID:37237082 PBO:0109251 skb1∆ and srr1∆ additively reduce the rate of gross chromosomal rearrangements in rad51 deletion background.
PMID:37237082 PBO:0109251 skb1∆ and srr1∆ additively reduce the rate of gross chromosomal rearrangements in rad51 deletion background.
PMID:37237082 FYPO:0000957 figure 3a
PMID:37237082 FYPO:0000963 figure 3a
PMID:37237082 FYPO:0001690 figure 3a
PMID:37237082 PBO:0103454 To our surprise, not only srr1Δ but also skb1Δ reduced GCR rates in the rad51Δ background, demonstrating that both Srr1 and Skb1 cause GCRs.
PMID:37237082 PBO:0103454 To our surprise, not only srr1Δ but also skb1Δ reduced GCR rates in the rad51Δ background, demonstrating that both Srr1 and Skb1 cause GCRs.
PMID:37237082 FYPO:0006437 Normal Chk1 phosphorylation and cell cycle arrest
PMID:37237082 PBO:0108250 (Fig. 3e). We found that srr1Δ and srr1-W157R increased the rate of chromosome loss. (In WT and rad51 backgrounds)
PMID:37237082 PBO:0108250 (Fig. 3e). We found that srr1Δ and srr1-W157R increased the rate of chromosome loss. (In WT and rad51 backgrounds)
PMID:37237082 PBO:0096838 srr1-W157R and rad52-R45K or pcn1-K107R additively reduce gross chromosomal rearrangement. srr1-W157R and pcn1-K107R also addi- tively reduced GCR rates in rad51Δ cells (Fig. 4a).
PMID:37237082 GO:0000076 Unlike chk1Δ, in the srr1Δ strain, the septation index declined to the wild-type level by 6 h after MMS addition, suggesting that Srr1 is dispensable for cell cycle arrest.
PMID:37237082 PBO:0096838 srr1-W157R and rad52-R45K or pcn1-K107R additively reduce gross chromosomal rearrangement. srr1-W157R and pcn1-K107R also addi- tively reduced GCR rates in rad51Δ cells (Fig. 4a).
PMID:37237082 PBO:0093618 figure 3a
PMID:37237082 PBO:0093579 figure 3a
PMID:37237082 PBO:0093615 figure 3a
PMID:37237082 PBO:0096838 Both srr1-D111A,P112A and srr1- H148A mutations reduced GCR rates (Fig. 5d).
PMID:37237082 PBO:0096838 Both srr1-D111A,P112A and srr1- H148A mutations reduced GCR rates (Fig. 5d).
PMID:37237082 PBO:0093618 figure 5e
PMID:37237082 FYPO:0001355 Like srr1Δ cells, srr1-W157R, srr1-D111A,P112A, and srr1-H184A cells produced small colonies (Supplementary Fig. 2b), consistent with the role of the SRR1-like domain even in the absence of exogenous DNA damage.
PMID:37237082 FYPO:0006437 Normal Chk1 phosphorylation and cell cycle arrest
PMID:37237082 FYPO:0005371 (Fig. 3e).
PMID:37237082 PBO:0093615 figure 3a
PMID:37237082 PBO:0093579 figure 3a
PMID:37237082 PBO:0093618 figure 3a
PMID:37237082 FYPO:0002150 We crossed srr1Δ and rad52Δ haploid strains and dissected the tetrads but failed to obtain srr1Δ rad52Δ progenies (Fig. 4b),
PMID:37237082 FYPO:0002150 We crossed srr1Δ and rad52Δ haploid strains and dissected the tetrads but failed to obtain srr1Δ rad52Δ progenies (Fig. 4b),
PMID:37237082 PBO:0109253 In the wild-type background, srr1Δ but not skb1Δ slightly reduced GCR rates, showing that Srr1 is required for GCRs even in the presence of Rad51
PMID:37237082 FYPO:0001355 Like srr1Δ cells, srr1-W157R, srr1-D111A,P112A, and srr1-H184A cells produced small colonies (Supplementary Fig. 2b), consistent with the role of the SRR1-like domain even in the absence of exogenous DNA damage.
PMID:37237082 PBO:0093579 figure 5e
PMID:37237082 PBO:0093615 figure 5e
PMID:37237082 PBO:0093618 figure 5e
PMID:37237082 PBO:0096839 (Fig. 6a) In wild-type and rad51 deletion backgrounds
PMID:37237082 PBO:0096839 (Fig. 6a) In wild-type and rad51 deletion backgrounds
PMID:37237082 FYPO:0005371 (Fig. 3e).
PMID:37237082 PBO:0096838 To our surprise, not only srr1Δ but also skb1Δ reduced GCR rates in the rad51Δ background, demonstrating that both Srr1 and Skb1 cause GCRs.
PMID:37237082 PBO:0093615 figure 5e
PMID:37237082 PBO:0096838 To our surprise, not only srr1Δ but also skb1Δ reduced GCR rates in the rad51Δ background, demonstrating that both Srr1 and Skb1 cause GCRs.
PMID:37237082 PBO:0096838 Fig 1e Genome sequencing of one of them identified the srr1/ ber1-W157R and skb1-A377V mutations in their SRR1-like and arginine methyltransferase (RMTase) domains, respectively (Fig. 1b).
PMID:37279920 PBO:0109206 Strikingly, however, silencing at the mating type locus was completely abolished in the 22 absence of Caf1 and Mot2, similar to clr4∆ cells, as revealed by the lack of cell growth on 23 5FOA-containing medium and the marked accumulation of ura4+ transcripts (Fig. 1g-h).
PMID:37279920 PBO:0109208 Figure 2
PMID:37279920 PBO:0109206 Strikingly, however, silencing at the mating type locus was completely abolished in the 22 absence of Caf1 and Mot2, similar to clr4∆ cells, as revealed by the lack of cell growth on 23 5FOA-containing medium and the marked accumulation of ura4+ transcripts (Fig. 1g-h).
PMID:37279920 PBO:0095652 We also detected intermediate phenotypes for the 8 ccr4∆ mutant, pointing to a partial contribution of this RNA deadenylase (Fig. 1g-h; 9 Supplementary Fig. 1b-d).
PMID:37288768 PBO:0019232 Fig 3
PMID:37288768 FYPO:0007664 Notably, the nuclear displacement phenotypewas associated with mid-anaphase spindle bending and/or detachment of one of the daughter chromosome masses from the spindle, and subsequent spindle disassembly and merger of the two daughter chromosome masses into one diploid nucleus (Figs 1B and 2B).
PMID:37288768 PBO:0110059 Fig 4D
PMID:37288768 PBO:0110055 Fig 1B
PMID:37288768 PBO:0110298 Fig 1B
PMID:37288768 PBO:0110056 Fig 4C
PMID:37288768 PBO:0093562 Fig S2A We first validated the previous report of cbf11Δ cells being sensitive to TBZ. When plated on YES medium containing TBZ, the cbf11Δ mutant indeed showed strong sensitivity to the drug (Fig. S2A),
PMID:37288768 PBO:0019232 Fig 3
PMID:37288768 FYPO:0000886 Fig 4A, S3
PMID:37288768 FYPO:0000891 Fig 4A, S2
PMID:37288768 PBO:0019031 Fig 3
PMID:37288768 PBO:0110058 Fig 2E
PMID:37288768 PBO:0110057 Fig 2G
PMID:37288768 PBO:0019031 Fig 3
PMID:37288768 PBO:0019031 Fig 3
PMID:37288768 PBO:0019031 Fig 3
PMID:37400983 PBO:0109933 Interestingly, when amino acid substitutions in the hinge and CSD were combined, the resulting Chp2 mutants (Chp2-mut3 and Chp3-mut5) no longer bound DNA (Fig. 3K and M, and Supplementary Fig. S2F)
PMID:37400983 PBO:0109933 Interestingly, when amino acid substitutions in the hinge and CSD were combined, the resulting Chp2 mutants (Chp2-mut3 and Chp3-mut5) no longer bound DNA (Fig. 3K and M, and Supplementary Fig. S2F)
PMID:37400983 PBO:0109933 Chp2-CSD (Chp2-CSD3A) no longer bound DNA (Fig. 3F and Supplementary Fig. S2B), Chp2 with H5A mutation in the hinge (Chp2-mut1) or with either CSD2A or CSD3A mutation in the CSD (Chp2-mut2 and Chp2- mut4) exhibited weaker DNA-binding activity compared to wild-type Chp2 (Chp2-WT) (Fig. 3H, I, J and L and Sup- plementary Fig. S2C and S2F)
PMID:37400983 PBO:0109934 exhibited only a very weak DNA binding activity compared to wild- type Chp2-CD (Chp2-CSDWT ) (Fig. 3D and E, and Supple- mentary Fig. S2B and S2E)
PMID:37400983 FYPO:0003231 Chp2 mutants lacking DNA-binding activities associated with both the hinge and the N-terminus of CSD (mut 3 and mut 5) exhibited reduced heterochromatin association compared to wild-type Chp2 at representative heterochromatic regions (centromeric dg, the mating-type cenH, telomere and mat3M::ura4+), and the reduction was more severe for Chp2-mut3 compared to Chp2-mut5 (Fig. 6A).
PMID:37400983 FYPO:0002336 mat3M::ura4+ reporter silencing
PMID:37400983 FYPO:0005929 Chp2 mutants lacking DNA-binding activities associated with both the hinge and the N-terminus of CSD (mut 3 and mut 5) exhibited reduced heterochromatin association compared to wild-type Chp2 at representative heterochromatic regions (centromeric dg, the mating-type cenH, telomere and mat3M::ura4+), and the reduction was more severe for Chp2-mut3 compared to Chp2-mut5 (Fig. 6A).
PMID:37400983 FYPO:0002336 mat3M::ura4+ reporter silencing
PMID:37400983 PBO:0109932 Inter- estingly, we found that Chp2-CSD exhibited a robust DNA binding activity (Fig. 2K and M),
PMID:37400983 PBO:0109933 when these were replaced by alanine (Fig. 3A), the resulting Chp2-H mutant (Chp2-H5A) no longer bound to DNA (Fig. 3B and C, and Supplementary Fig. S2A and S2D),
PMID:37400983 PBO:0109927 As previously reported, in wild-type cells, Swi6 was present in both the soluble (S) and chromatin-enriched pellet (P) fractions, with approximately 40% of the total Swi6 protein detected in the pellet fraction, and most of the Swi6 in the pellet fraction was redistributed to the soluble fraction in clr4� cells (Fig. 1A).
PMID:37400983 FYPO:0002827 mat3M::ura4+ reporter silencing | combined mutations of the hinge and one of the mutations in the N-terminus of CSD (mut3 and mut5) showed a silencing defect (Fig. 4C)
PMID:37400983 FYPO:0002336 mat3M::ura4+ reporter silencing
PMID:37400983 PBO:0109928 Interest- ingly, we found that Chp2 in the chromatin-enriched pellet fraction was not affected by the Mit1I11R mutation (Fig. 1B).
PMID:37400983 FYPO:0007336 mat3M::ura4+ reporter silencing | combined mutations of the hinge and one of the mutations in the N-terminus of CSD (mut3 and mut5) showed a silencing defect (Fig. 4C)
PMID:37400983 GO:0003677 Using purified full-length, dimerized Chp2 and Swi6, we performed EMSAs using pericentromeric DNA as a probe. Consistent with previous results, Swi6 bound DNA efficiently, and Chp2 also showed similar DNA binding activity (Fig. 2B and C).
PMID:37400983 GO:0003677 Using purified full-length, dimerized Chp2 and Swi6, we performed EMSAs using pericentromeric DNA as a probe. Consistent with previous results, Swi6 bound DNA efficiently, and Chp2 also showed similar DNA binding activity (Fig. 2B and C).
PMID:37400983 PBO:0109930 ****NEED TO FIX allele description*****. The N-terminal disordered region of Swi6 (Swi6-N) bound weakly to DNA (Fig. 2D and L),
PMID:37400983 PBO:0109931 whereas no DNA binding activity was detected for Swi6-CD or Swi6-CSD (Fig. 2E, G and L).
PMID:37400983 PBO:0109931 whereas no DNA binding activity was detected for Swi6-CD or Swi6-CSD (Fig. 2E, G and L).
PMID:37400983 PBO:0109932 The hinge and the N-terminal disor- dered regions of Chp2 (Chp2-H and Chp2-N) also bound DNA (Fig. 2H, J and M)
PMID:37400983 PBO:0109932 The hinge and the N-terminal disor- dered regions of Chp2 (Chp2-H and Chp2-N) also bound DNA (Fig. 2H, J and M)
PMID:37400983 PBO:0109931 no detectable DNA-binding activity was observed for Chp2-CD (Fig. 2I and M).
PMID:37400983 FYPO:0004984 Chp2 mutants lacking DNA-binding activities associated with both the hinge and the N-terminus of CSD (mut 3 and mut 5) exhibited reduced heterochromatin association compared to wild-type Chp2 at representative heterochromatic regions (centromeric dg, the mating-type cenH, telomere and mat3M::ura4+), and the reduction was more severe for Chp2-mut3 compared to Chp2-mut5 (Fig. 6A).
PMID:37400983 PBO:0109928 In contrast, Chp2 was preferentially present in the chromatin-enriched pellet fraction in wild-type cells, and the Chp2 in this fraction was not altered by the clr4+ depletion (Fig. 1B).
PMID:37400983 FYPO:0002827 mat3M::ura4+ reporter silencing |combined mutations of the hinge and one of the mutations in the N-terminus of CSD (mut3 and mut5) showed a silencing defect (Fig. 4C)
PMID:37403782 PBO:0109444 Deletion of snoZ30 and sno530 resulted in a loss of 2′-O-methylation at A41 and A64, respectively, suggesting that sno530 is indeed the A64 U6-modifying snoRNA (Figure 1C, D, Supplementary Figure S3).
PMID:37403782 PBO:0109442 Deletion of snoZ30 and sno530 resulted in a loss of 2′-O-methylation at A41 and A64, respectively, suggesting that sno530 is indeed the A64 U6-modifying snoRNA (Figure 1C, D, Supplementary Figure S3).
PMID:37403782 GO:0030515 we examined our Bmc1 RIP-Seq dataset (20), which revealed an interaction between Bmc1 and snoZ30, which guides 2′-O-methylation of U6 at position 41 (41) (Supplementary Figures S1A, S2A, B).
PMID:37403782 FYPO:0008112 Importantly, co-migration of Pof8 with U6 was lost upon deletion of Bmc1 (Figure 1B), as well as co-migration of Bmc1 with U6 upon deletion of Pof8 (Supplementary Fig- ure S1C).
PMID:37403782 FYPO:0008110 reproducible decrease in modification at several other sites, most notably A64 (Figure 1C, D, Sup- plementary Figure S3).
PMID:37403782 FYPO:0008110 reproducible decrease in modification at several other sites, most notably A64 (Figure 1C, D, Sup- plementary Figure S3).
PMID:37403782 PBO:0109446 Further support- ing the idea that U6 complex formation is contingent on the presence of all three proteins, we observed a loss of snoZ30 binding to Bmc1 upon knockout of any member of the complex (Supplementary Figure S2A).
PMID:37403782 PBO:0109446 Further support- ing the idea that U6 complex formation is contingent on the presence of all three proteins, we observed a loss of snoZ30 binding to Bmc1 upon knockout of any member of the complex (Supplementary Figure S2A).
PMID:37403782 FYPO:0008110 reproducible decrease in modification at several other sites, most notably A64 (Figure 1C, D, Sup- plementary Figure S3).
PMID:37403782 PBO:0109446 Further support- ing the idea that U6 complex formation is contingent on the presence of all three proteins, we observed a loss of snoZ30 binding to Bmc1 upon knockout of any member of the complex (Supplementary Figure S2A).
PMID:37403782 GO:0030515 We validated the interaction between Bmc1 and sno530 by RNP immunoprecipitation/qPCR and showed that much like snoZ30 and U6, this interaction is dependent on the presence of the assembled Bmc1-Pof8-Thc1 com- plex (Figure 1A).
PMID:37403782 PBO:0109449 Deletion of snoZ30 and sno530 resulted in a loss of 2′-O-methylation at A41 and A64, respectively, suggesting that sno530 is indeed the A64 U6-modifying snoRNA (Figure 1C, D, Supplementary Figure S3).
PMID:37403782 GO:0016180 U6
PMID:37403782 GO:0016180 U6
PMID:37403782 GO:0016180 U6
PMID:37403782 PBO:0109669 Still, as mean intron retention values indeed showed an in- crease upon Bmc1 deletion (Figure 5A), we chose several representative intron retention events to validate with semi- quantitative RT-PCR (one of which, intron 1 of pud1, dis- played a statistically significant increase upon Bmc1 dele- tion at 32 ̊C in our RNA Seq dataset).
PMID:37403782 FYPO:0008113 Still, as mean intron retention values indeed showed an in- crease upon Bmc1 deletion (Figure 5A), we chose several representative intron retention events to validate with semi- quantitative RT-PCR (one of which, intron 1 of pud1, dis- played a statistically significant increase upon Bmc1 dele- tion at 32 ̊C in our RNA Seq dataset).
PMID:37403782 PBO:0112458 Bmc1 5 capping catalytic activity is not required for promoting 2 -O-methylation of U6
PMID:37403782 GO:0005732 we found that all three proteins are neces- sary for an interaction with U6 (Figure 1A, Supplemen- tary Figure S1B).
PMID:37403782 FYPO:0008112 Importantly, co-migration of Pof8 with U6 was lost upon deletion of Bmc1 (Figure 1B), as well as co-migration of Bmc1 with U6 upon deletion of Pof8 (Supplementary Fig- ure S1C).
PMID:37403782 GO:0005732 we found that all three proteins are neces- sary for an interaction with U6 (Figure 1A, Supplemen- tary Figure S1B).
PMID:37403782 GO:0005732 we found that all three proteins are neces- sary for an interaction with U6 (Figure 1A, Supplemen- tary Figure S1B).
PMID:37403782 PBO:0109444 Deletion of snoZ30 and sno530 resulted in a loss of 2′-O-methylation at A41 and A64, respectively, suggesting that sno530 is indeed the A64 U6-modifying snoRNA (Figure 1C, D, Supplementary Figure S3).
PMID:37403782 PBO:0109443 Still, as mean intron retention values indeed showed an in- crease upon Bmc1 deletion (Figure 5A), we chose several representative intron retention events to validate with semi- quantitative RT-PCR (one of which, intron 1 of pud1, dis- played a statistically significant increase upon Bmc1 dele- tion at 32 ̊C in our RNA Seq dataset).
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PMID:37445861 PBO:0093786 Fig. 1
PMID:37445861 PBO:0093786 Fig. 1
PMID:37445861 PBO:0093786 Fig. 1
PMID:37445861 PBO:0093786 Fig. 1
PMID:37445861 PBO:0093786 Fig. 1
PMID:37445861 PBO:0093786 Fig. 1
PMID:37445861 PBO:0093784 Fig. 1
PMID:37445861 PBO:0093786 Fig. 1
PMID:37445861 PBO:0093786 Fig. 1
PMID:37445861 PBO:0093786 Fig. 1
PMID:37445861 PBO:0093786 Fig. 1
PMID:37445861 PBO:0093785 Fig. 1
PMID:37445861 PBO:0093785 Fig. 1
PMID:37445861 PBO:0093786 Fig. 1
PMID:37445861 PBO:0093786 Fig. 1
PMID:37445861 PBO:0093784 Fig. 1
PMID:37445861 PBO:0093786 Fig. 1
PMID:37445861 FYPO:0001986 Fig. 1
PMID:37459529 GO:0032221 Unexpectedly, the structure also reveals two copies of Alp13 (hereafter referred to as Alp13a and Alp13b) (Fig. 2C),
PMID:37459529 GO:0032221 Alp13b is connected to the complex by both Cph1 and Cph2 (Figs. 2C and 3A)
PMID:37459529 GO:0032221 Alp13b is connected to the complex by both Cph1 and Cph2 (Figs. 2C and 3A)
PMID:37459529 GO:0060090 Pst2 evidently serves as a structural platform, bringing together almost all the other subunits of the complex.
PMID:37459529 GO:0180032 assayed complex
PMID:37459529 PBO:0111389 Deletion of the active center loop compromised the HDAC activity of Clr6S (Fig. 6G), consistent with a role of the loop in catalytic activity, although a secondary effect, due to perturbation of the protein structure could not be excluded.,
PMID:37459529 GO:0140937 assayed complex
PMID:37459529 GO:0034739 assayed complex
PMID:37459529 GO:0032221 All six subunits of the Clr6S complex are seen in the map (Fig. 2 B and C and SI Appendix, Table S1). Unexpectedly, the structure also reveals two copies of Alp13 (hereafter referred to as Alp13a and Alp13b) (Fig. 2C)
PMID:37459529 GO:0032221 The structure shows that Pst2, Clr6, and Prw1, a WD40-containing subunit, form a subcomplex, within which Pst2 associates with the catalytic subunit Clr6, as well as interacting with Prw1 (Fig. 2C),
PMID:37459529 GO:0032221 The structure shows that Pst2, Clr6, and Prw1, a WD40-containing subunit, form a subcomplex, within which Pst2 associates with the catalytic subunit Clr6, as well as interacting with Prw1 (Fig. 2C),
PMID:37459529 GO:0060090 Thus, Cph2 interacts with all the other subunits except Prw1, whose association with the complex occurs only through the Pst2–CTD (Fig. 4C).
PMID:37459529 GO:0180033 assayed complex
PMID:37531259 FYPO:0004085 Figure S1D
PMID:37531259 PBO:0109540 Figure 1C
PMID:37531259 FYPO:0004085 Figure S1D
PMID:37531259 PBO:0109538 Figure 1E
PMID:37531259 PBO:0109538 Figure 1E
PMID:37531259 PBO:0109537 Figure 3A
PMID:37531259 PBO:0109536 Figure 3A in myo1-mNG fim1-mCherry cells overproducing Ank1, while Fim1-mCherry was at patches, almost all Myo1-mNG was cytoplasmic (Fig. 3A).
PMID:37531259 PBO:0109535 Figure 3B Furthermore, in cells overproducing ank1+, ~10% of Fim1-mCherry patches internalized compared to ~95% of Fim1-mCherry patches internalized in the control cells (Fig. 3B)
PMID:37531259 PBO:0109534 Figure 3C
PMID:37531259 PBO:0109524 Figure 1D
PMID:37531259 GO:0008289 vw, I think we can conclude this from the EXP, especially as we know that myo1 binds phopshilipids in other species :Addition of Ank1 resulted in a reduction in the amount of co-pelleting of the Myo1(1-964)-FLAG-Cam1-Cam2 complex with liposomes (Fig. 2F). We therefore conclude that Ank1 directly binds and inhibits Myo1 membrane binding, supporting our model.
PMID:37531259 PBO:0109541 Given the AF model and the above results, we hypothesized that Ank1 In contrast, in myo1-mNG fim1-mCherry cells overproducing Ank1, while Fim1-mCherry was at patches, almost all Myo1-mNG was cytoplasmic (Fig. 3A). These data support our model that Ank1 blocks Myo1 membrane association and normally sequesters the bulk of Myo1 in the cytoplasm.precludes Myo1 membrane binding and sequesters the myosin-1 complex in the cytoplasm (Fig. 2F).Addition of Ank1 resulted in a reduction in the amount of co-pelleting of the Myo1(1-964)-FLAG-Cam1-Cam2 complex with liposomes (Fig. 2F). We therefore conclude that Ank1 directly binds and inhibits Myo1 membrane binding, supporting our model.
PMID:37531259 PBO:0109524 Figure 3E
PMID:37531259 PBO:0109528 Figure 1C
PMID:37531259 GO:0051285 Figure 1C
PMID:37531259 GO:0061645 Figure 1C &F
PMID:37531259 PBO:0109532 Fig. 1, Fig. 1B, Fig. 2D
PMID:37531259 GO:0051285 Figure 1C
PMID:37531259 PBO:0109539 Figure 1C
PMID:37531259 GO:0005737 Figure 1F
PMID:37531259 PBO:0109531 Figure S1B
PMID:37531259 PBO:0109530 Figure S1A
PMID:37531259 FYPO:0000744 Figure S1C
PMID:37531259 FYPO:0001357 Figure S1D (vw: same pathway)
PMID:37531259 FYPO:0004085 Figure S1D
PMID:37531259 FYPO:0004085 Figure S1D
PMID:37531259 PBO:0109524 Figure 3E
PMID:37531259 PBO:0109529 Figure S1C
PMID:37531259 FYPO:0001366 Figure 1C
PMID:37531259 PBO:0109527 Figure 1C
PMID:37531259 PBO:0109526 Figure 1C
PMID:37531259 PBO:0109525 Figure 1C
PMID:37531259 PBO:0109533 Figure 3C
PMID:37540145 GO:0000266 Thus, our data indicate that Mdi1 plays a conserved role as a profission factor that is not required for Dnm1 recruitment but is required to facilitate the completion of mitochondrial division. Fig 4
PMID:37540145 PBO:0109587 loss of Mdi1 did not impact Dnm1 recruitment to mitochondria and Dnm1 foci appeared associated with the hyperfused net structures (Fig. 4 F, arrows).
PMID:37540145 PBO:0109593 Figure 4G
PMID:37540145 PBO:0109719 Figure 4F mitochondrial net-like morphology
PMID:37540145 PBO:0109720 Figure 4F mitochondrial net-like morphology
PMID:37540145 PBO:0109596 Figure 4G
PMID:37550452 PBO:0108474 Figure 6
PMID:37550452 PBO:0109824 Extended Data Figure 9e
PMID:37550452 PBO:0109823 Figure 6
PMID:37550452 PBO:0108475 Figure 6
PMID:37550452 PBO:0093561 Figure 5
PMID:37550452 PBO:0108473 Figure 6
PMID:37550452 PBO:0093561 Figure 5
PMID:37550452 FYPO:0002061 Figure 5
PMID:37553386 PBO:0112256 Fig. 1F
PMID:37553386 FYPO:0001357 Fig. 1F
PMID:37553386 FYPO:0001357 Fig. 1F
PMID:37553386 PBO:0112261 Fig. 3G
PMID:37553386 FYPO:0001030 Fig. 5A
PMID:37553386 FYPO:0001030 Fig. 5A
PMID:37553386 PBO:0112248 Assayed using S. japonicus rop1 in vitro. Fig. 4
PMID:37553386 PBO:0112263 Fig. 5B
PMID:37553386 PBO:0112264 Fig. 5B
PMID:37553386 PBO:0112265 Fig. 5B
PMID:37553386 PBO:0112252 Fig. 6
PMID:37553386 FYPO:0001357 Fig. 1F
PMID:37553386 FYPO:0001357 Fig. 1F
PMID:37553386 FYPO:0001357 Fig. 1F
PMID:37553386 FYPO:0007448 Fig. 1B and C
PMID:37553386 PBO:0112254 Fig. 1B and C
PMID:37553386 PBO:0112255 Fig. 1B and C
PMID:37553386 PBO:0112253 Fig. 1B and C
PMID:37553386 PBO:0112254 Fig. 1B and C
PMID:37553386 PBO:0112253 Fig. 1B and C
PMID:37553386 PBO:0112252 Fig. 6
PMID:37553386 PBO:0102947 Fig. 5A
PMID:37553386 PBO:0102947 Fig. 5A
PMID:37553386 PBO:0112258 Fig. S2G and H
PMID:37553386 PBO:0112260 Fig. 2C
PMID:37553386 FYPO:0000381 Fig. 1D and E
PMID:37553386 PBO:0112250 Assayed using S. japonicus yop1 in vitro. Fig. 4
PMID:37553386 FYPO:0001030 Fig. 5A
PMID:37553386 PBO:0112256 Fig. 5A
PMID:37553386 PBO:0112262 Fig. 5A
PMID:37553386 PBO:0112256 Fig. 5A
PMID:37553386 PBO:0112263 Fig. 5B
PMID:37553386 PBO:0112251 Fig. 1B
PMID:37553386 PBO:0112259 Fig. 2C
PMID:37553386 PBO:0112258 Fig. S2G and H
PMID:37553386 PBO:0112257 Fig. 1G
PMID:37553386 PBO:0112257 Fig. 1G
PMID:37553386 FYPO:0000355 Fig. S2D
PMID:37553386 FYPO:0001030 Fig. 1F
PMID:37553386 FYPO:0001030 Fig. 1F
PMID:37553386 PBO:0112256 Fig. 1F
PMID:37553386 PBO:0112256 Fig. 1F
PMID:37572670 PBO:0111035 Figure 3 Sty1-Tpx1 fusion proteins, Wis1 was hyperphosphorylated to less electrophoretically mo- bile forms even in the absence of stress (Figures 3A and 3D).
PMID:37572670 FYPO:0002059 Moreover, when we crossed strains expressing Sty1-Tpx1 fusion and Dpyp1 mutant alleles, we observed a very strong synthetic lethal interaction, with 95% of spores with a sty1-tpx1 Dpyp1 genotype failing to give rise to a colony (Figure 2I and not shown). This strongly suggests that sty1- tpx1 and Dpyp1 alleles act independently to increase Sty1 phosphorylation, thus increasing it to lethal levels when co-ex- pressed. Indeed, analysis of colonies bearing markers of both al- leles revealed that surviving cells had completely eliminated Sty1-Tpx1 expression and activity (Figures 2J and 2K and not shown).
PMID:37572670 FYPO:0003481 Our analysis revealed that Sty15CS- mutant-expressing cells were longer at the point of division than wild-type cells, strongly suggesting that Sty15CS’s pro- mitotic function was compromised (Figures S1D and S1E).
PMID:37572670 FYPO:0001122 Indeed, consistent with the requirement of Wis1-dependent phosphorylation of Sty1 for timely entry into mitosis, cells expressing Wis1M395G or Wis1M395A were elongated (Figure S6B).
PMID:37572670 FYPO:0001122 Indeed, consistent with the requirement of Wis1-dependent phosphorylation of Sty1 for timely entry into mitosis, cells expressing Wis1M395G or Wis1M395A were elongated (Figure S6B).
PMID:37572670 PBO:0111034 Figure 1 Strikingly, Sty1 phosphorylation was increased in cells ex- pressing either Sty1-Tpx1 or Sty1-Tpx1C48S (Figure 1D)
PMID:37572670 FYPO:0006822 This revealed that Sty1- Tpx1- and Sty1-Tpx1C48S-expressing cells both divided at a significantly smaller size than wild-type cells (Figure 1F).
PMID:37572670 FYPO:0003481 Next, we co-expressed the Sty1-Tpx1C48S fusion with a Wis1AA mutant, in which the MAP3K-phosphorylated residues are substituted with alanine. Wis1AA cells are significantly elongated, reflecting the mitotic delay associated with Sty1 hypophosphorylation (Figures 4B, 4C, and S6A).50
PMID:37572670 PBO:0111045 Although expression of Sty-Tpx1C48S stimulated a bigger increase in Sty1 activity in cells expressing wild-type Wis1, expression of Sty1-Tpx1C48S also increased Sty1 phosphorylation and partially rescued the cell-cycle defect of Wis1AA cells (Figures 4B and 4C)
PMID:37572670 PBO:0111044 Although, both Wis1M395G and Wis1M395A were expressed at wild-type levels, Sty1 phosphory- lation was very low and minimally increased even in response to 6 mM H2O2 in these cells (Figure 4D).
PMID:37572670 PBO:0111044 Although, both Wis1M395G and Wis1M395A were expressed at wild-type levels, Sty1 phosphory- lation was very low and minimally increased even in response to 6 mM H2O2 in these cells (Figure 4D).
PMID:37572670 PBO:0111043 Strikingly, the stress- induced phosphorylation of Wis1M395G and Wis1M395A was also compromised, strongly suggesting that Wis1 kinase activity was required for the stress-induced phosphorylation and activation of Wis1 (Figure 4D).
PMID:37572670 PBO:0111043 Strikingly, the stress- induced phosphorylation of Wis1M395G and Wis1M395A was also compromised, strongly suggesting that Wis1 kinase activity was required for the stress-induced phosphorylation and activation of Wis1 (Figure 4D).
PMID:37572670 FYPO:0003481 Dmcs4 mutant cells are delayed in entry to mitosis, reaching a significantly longer size than wild-type cells before dividing (Figure 5A).45,47,48
PMID:37572670 PBO:0111035 Sty1-Tpx1 expression stimulated similar levels of constitutive Wis1 phosphorylation in Dmcs4 mutant as in wild-type (mcs4+) cells (Figure 5B). Accordingly, there were similar levels of Sty1 phosphorylati
PMID:37572670 GO:0005078 Sty1-Tpx1 complexes provide a scaffold for Wis1
PMID:37572670 PBO:0111041 Consistent with Pyp1 oxidation providing a similar mechanism to reversibly inhibit Pyp1 and activate Sty1, there was a much smaller H2O2-induced increase in Sty1 phos- phorylation in Dtrx1 mutant cells, where H2O2-induced Pyp1 disul- fides were not detected (Figures 2D and 2F).
PMID:37572670 PBO:0095350 Tpx1 is required for H2O2-induced activa- tion of Sty1, over a range of concentrations up to 10 mM H2O2.31
PMID:37572670 PBO:0111042 Indeed, our analysis of Dtpx1 mutant cells indicated that Tpx1 was important for maximal Wis1 phosphorylation (pppWis1) in response to 6 mM H2O2 (Figures 3C, S4E, and S4F).
PMID:37572670 PBO:0111041 By contrast, over- expression of Tpx1 increased H2O2-induced Sty1 phosphoryla- tion in wild-type cells and also restored some H2O2-inducibility to Sty1 phosphorylation in Dpyp2 cells (Figures 2A and S3E).
PMID:37572670 PBO:0111040 By contrast, over- expression of Tpx1 increased H2O2-induced Sty1 phosphoryla- tion in wild-type cells and also restored some H2O2-inducibility to Sty1 phosphorylation in Dpyp2 cells (Figures 2A and S3E).
PMID:37572670 PBO:0111039 As expected, Sty1 phosphorylation was increased in Dpyp1 mutant cells, confirming the importance of this phosphatase in maintaining low levels of Sty1 activity (Fig- ure 2A)
PMID:37572670 FYPO:0001122 Indeed, our exam- ination indicated that ‘‘sty1-tpx1 wis1DD’’ strains, which genotyp- ically bore both alleles, had adapted to the deleterious effect of hyperactivated Sty1 by lowering Sty1 expression to such an extent that they exhibited the long cell phenotype associated with its loss (Figures S3A and S3B).
PMID:37572670 PBO:0111043 We observed a small, but reproducible, stress-induced decrease in Wis1DD mobility in these cells, corroborating that Wis1 undergoes a stress- induced phosphorylation on different sites from those phosphor- ylated by the MAP3K (Figures 4A, S5A, S4A, S4B, and S4F).
PMID:37572670 PBO:0111044 Significantly, this stress-induced increase in Wis1DD phosphory- lation was mirrored by stress-induced increases in Sty1 phos- phorylation, strongly suggesting that it increases Wis1 activity (Figure 4A).
PMID:37572670 FYPO:0003481 Next, we co-expressed the Sty1-Tpx1C48S fusion with a Wis1AA mutant, in which the MAP3K-phosphorylated residues are substituted with alanine. Wis1AA cells are significantly elongated, reflecting the mitotic delay associated with Sty1 hypophosphorylation (Figures 4B, 4C, and S6A).50
PMID:37572670 FYPO:0009007 Hence, the lower viability of cells co-expressing sty1-tpx1 and wis1DD suggested a synthetic negative interaction, with both alleles acting independently to increase Sty1 phosphorylation to lethal levels.
PMID:37572670 PBO:0111038 By contrast, cells expressing Sty1-Tpx1C48S con- tained substantially increased levels of lower mobility and phos- phorylated Pyp2 (p-Pyp2), even prior to addition of H2O2. Together these data strongly support the conclusion that the Sty1-Tpx1 and Sty1-Tpx1C48S fusion proteins are constitutively hyperactive compared with wild-type Sty1 (Figures 1F and 1G).
PMID:37572670 FYPO:0006822 This revealed that Sty1- Tpx1- and Sty1-Tpx1C48S-expressing cells both divided at a significantly smaller size than wild-type cells (Figure 1F).
PMID:37572670 PBO:0111034 Figure 1 Strikingly, Sty1 phosphorylation was increased in cells ex- pressing either Sty1-Tpx1 or Sty1-Tpx1C48S (Figure 1D)
PMID:37572670 PBO:0111037 Crucially, both Sty1-Tpx1 fu- sions were expressed at similar levels to wild-type Sty1 and sup- ported growth under stress conditions, confirming retention of Sty1 function (Figures 1B and 1D). By contrast, the oxidative stress sensitivity and lower Pyp1 levels in cells expressing a Sty15CS-Tpx1 fusion protein, provided further evidence that cys- teines in Sty1 are required for Sty1 function independently from forming disulfide-bonded complexes with Tpx1 (Figures 1B and S1F).39
PMID:37572670 FYPO:0005947 Sty15CS-expressing cells were able to adapt to os- motic stress but were less tolerant than wild-type cells to higher levels of H2O2 (Figure 1B).
PMID:37572670 PBO:0093578 Sty15CS-expressing cells were able to adapt to os- motic stress but were less tolerant than wild-type cells to higher levels of H2O2 (Figure 1B).
PMID:37572670 PBO:0111036 Consistent with lower Sty1 activity, Sty15CS-expressing cells contained less Pyp1 than wild-type cells (Figure S1F). This likely explains the slightly elevated phosphorylation of Sty15CS (Figure S1G)
PMID:37572670 FYPO:0000544 Sty1-Tpx1 disulfide formation abrogated (Figure S1C).
PMID:37572670 FYPO:0002059 Moreover, when we crossed strains expressing Sty1-Tpx1 fusion and Dpyp1 mutant alleles, we observed a very strong synthetic lethal interaction, with 95% of spores with a sty1-tpx1 Dpyp1 genotype failing to give rise to a colony (Figure 2I and not shown). This strongly suggests that sty1- tpx1 and Dpyp1 alleles act independently to increase Sty1 phosphorylation, thus increasing it to lethal levels when co-ex- pressed. Indeed, analysis of colonies bearing markers of both al- leles revealed that surviving cells had completely eliminated Sty1-Tpx1 expression and activity (Figures 2J and 2K and not shown).
PMID:37590302 FYPO:0007197 Figure 1F and 1G Analysis by live-cell microscopy further showed that both fission and fusion frequencies increased significantly in cells lacking Yta4
PMID:37590302 FYPO:0008122 Figure 1F and 1G Analysis by live-cell microscopy further showed that both fission and fusion frequencies increased significantly in cells lacking Yta4
PMID:37590302 FYPO:0007197 Figure 1F and 1G Analysis by live-cell microscopy further showed that both fission and fusion frequencies increased significantly in cells lacking Yta4
PMID:37590302 FYPO:0003810 Figure 1
PMID:37590302 FYPO:0007194 Figure 1
PMID:37590302 PBO:0109729 Hence, these results show the character- istic property of Yta4 in reducing the affinity of Dnm1 for GTP and in inhibiting Dnm1 assembly.
PMID:37590302 FYPO:0001531 To reduce the complexity in analyzing Dnm1 GTPase activity, we performed colorimetric assays by using the assembly-defective version of Dnm1 (i.e., Dnm1(G380D), see S6A Fig). Interestingly, Dnm1(G380D) still exhibited a GTPase activ- ity but has a very low rate of GTP hydrolysis (Km = 85.00 μM, Vmax = 1.02 μM/min, versus the control Dnm1(WT): Km = 126.59 μM, Vmax = 4.82 μM/min) (S8 Fig).
PMID:37590302 PBO:0109726 Quantification showed that the expression levels of endogenous Dnm1 were comparable in WT and yta4Δ cells (Fig 3B)
PMID:37590302 FYPO:0000897 the expression of Yta4(WT), Yta4(AA), or Yta4(EQ) from the yta4 promoter restored Dnm1-associated mitochondrial fission to the WT level in yta4∆ cells (S3D Fig)
PMID:37590302 FYPO:0000895 Yta4(EQ) impaired the for- mation of Dnm1 foci on mitochondria but unexpectedly caused mitochondria to aggregate (Figs 4D and S1C)
PMID:37590302 PBO:0109727 As shown in Figs 4D and S1C, overexpression of WT Yta4 impaired the formation of Dnm1 foci on mitochondria but did not change the tubular mito- chondrial morphology.
PMID:37590302 PBO:0109728 showed that the delocalized GFP-Fis1 appeared to be present in the cytoplasm of Yta4-overexpressing cells, while GFP-Fis1 in Yta4(AA)-overexpressing or Yta4 (EQ)-overexpressing cells was still present on mitochondria, which were clearly separated from the ER (S1D and S2 Figs).
PMID:37590302 PBO:0109728 showed that the delocalized GFP-Fis1 appeared to be present in the cytoplasm of Yta4-overexpressing cells, while GFP-Fis1 in Yta4(AA)-overexpressing or Yta4 (EQ)-overexpressing cells was still present on mitochondria, which were clearly separated from the ER (S1D and S2 Figs).
PMID:37590302 FYPO:0000897 the expression of Yta4(WT), Yta4(AA), or Yta4(EQ) from the yta4 promoter restored Dnm1-associated mitochondrial fission to the WT level in yta4∆ cells (S3D Fig)
PMID:37615341 FYPO:0000957 Fig. 2-S1A
PMID:37615341 PBO:0112327 This further suggests that Mud1 is not playing the same role in regulating Rtf2 in S. pombe as has been observed for DDI1/2 in human cells. Fig. 2-S1B
PMID:37615341 FYPO:0001357 Fig. 2-S1A
PMID:37615341 PBO:0112328 Fig. 3C and D
PMID:37615341 FYPO:0001357 Fig. 2-S1A
PMID:37615341 FYPO:0001357 Fig. 2-S1A
PMID:37615341 FYPO:0000963 Fig. 2-S1A
PMID:37615341 FYPO:0006603 Fig. 1
PMID:37615341 FYPO:0005353 Fig. 4
PMID:37615341 FYPO:0005353 Fig. 4
PMID:37615341 FYPO:0005353 Fig. 4
PMID:37615341 FYPO:0000963 Fig. 2-S1A
PMID:37615341 FYPO:0006603 expression of an intron-less rtf1 gene that encodes the same additional 15 amino acids between residues 202–203 (Rtf1 intron2NE) does not provoke increased replication slippage downstream of RTS1 (Figure 4—figure supplement 3), indicating that this protein is indeed dysfunctional.
PMID:37615341 FYPO:0000963 Fig. 2-S1A
PMID:37615341 PBO:0093617 Fig. 2-S1A
PMID:37615341 PBO:0093617 Fig. 2-S1A
PMID:37637271 FYPO:0001355 Figure 1E
PMID:37637271 FYPO:0001355 Figure 1E
PMID:37637271 FYPO:0001355 Figure 1E
PMID:37637271 FYPO:0002061 Figure 1D
PMID:37637271 FYPO:0002061 Figure 1D
PMID:37637271 FYPO:0001355 Figure 1E
PMID:37637271 FYPO:0001235 Figure 1E
PMID:37637271 FYPO:0000964 Figure 1H
PMID:37637271 PBO:0093563 Figure 1H
PMID:37637271 PBO:0093563 Figure 1H
PMID:37637271 FYPO:0001355 Figure 1G
PMID:37637271 FYPO:0001355 Figure 1G
PMID:37637271 FYPO:0000964 Figure 1H
PMID:37637271 FYPO:0001355 Figure 1E
PMID:37637271 FYPO:0001355 Figure 1E
PMID:37637271 FYPO:0001235 Figure 1E
PMID:37694715 PBO:0110252 The TMD alone (Bqt4C414–432) showed even weaker localization at the NE with diffusion to the cytoplasm, but showed the same responses, that is, degradation in the absence of Bqt3 and increased levels upon BZ treatment (Fig. 6A, Bqt4C414–432).
PMID:37694715 PBO:0110254 The TMD alone (Bqt4C414–432) showed even weaker localization at the NE with diffusion to the cytoplasm, but showed the same responses, that is, degradation in the absence of Bqt3 and increased levels upon BZ treatment (Fig. 6A, Bqt4C414–432).
PMID:37694715 PBO:0110252 The fragment Bqt4C369–425 lost its dependency on Bqt3 for degradation and exhibited similar behaviors in the presence or absence of Bqt3 (Fig. 6A, Bqt4C369–425):
PMID:37694715 PBO:0110252 The fragment Bqt4C369–425 lost its dependency on Bqt3 for degradation and exhibited similar behaviors in the presence or absence of Bqt3 (Fig. 6A, Bqt4C369–425):
PMID:37694715 PBO:0110255 The results of the yeast-two-hybrid assay showed that the fragments lacking the last seven residues did not bind to Bqt3 (Fig. 6B).
PMID:37694715 FYPO:0000769 To ascertain whether this abnormal phenotype was caused by an accumulation of Bqt4, we overexpressed GFP–Bqt4 under the nmt1 promoter using the chemical compound YAM2 to control the expression level. YAM2 suppresses nmt1 promoter activity depending on its concentration (Nakamura et al., 2011). Overexpression of GFP–Bqt4 reproduced the nuclear- deformed morphology (Fig. 7B),
PMID:37694715 GO:0005637 These results are consistent with previous studies that showed that Doa10 partially localizes to the INM and is involved in the degradation of certain nuclear and INM substrates, whereas Hrd1 is found exclusively in the ER (Deng and Hochstrasser, 2006; Boban et al., 2014).
PMID:37694715 PBO:0110250 We constructed mutants of E3 ligases and their components that have been suggested to localize to or function in the ER and nucleus, namely ......... The mutants tested showed no detectable increase in fluorescence, except for the hul5Δ mutant (Fig. S2)
PMID:37694715 PBO:0110250 We constructed mutants of E3 ligases and their components that have been suggested to localize to or function in the ER and nucleus, namely ......... The mutants tested showed no detectable increase in fluorescence, except for the hul5Δ mutant (Fig. S2)
PMID:37694715 PBO:0110250 We constructed mutants of E3 ligases and their components that have been suggested to localize to or function in the ER and nucleus, namely ......... The mutants tested showed no detectable increase in fluorescence, except for the hul5Δ mutant (Fig. S2)
PMID:37694715 PBO:0110250 We constructed mutants of E3 ligases and their components that have been suggested to localize to or function in the ER and nucleus, namely ......... The mutants tested showed no detectable increase in fluorescence, except for the hul5Δ mutant (Fig. S2)
PMID:37694715 PBO:0110250 We constructed mutants of E3 ligases and their components that have been suggested to localize to or function in the ER and nucleus, namely ......... The mutants tested showed no detectable increase in fluorescence, except for the hul5Δ mutant (Fig. S2)
PMID:37694715 GO:0016020 Bqt4 is an integral membrane protein
PMID:37694715 PBO:0110251 The Bqt4 fragment containing the helix domain and the adjacent intrinsically disordered sequence (Bqt4C369–432) reproduced the behavior of full-length Bqt4 (Fig. 1A), that is, localization to the NE and responses to BZ, both in the presence and absence of Bqt3 (Fig. 6A, Bqt4C369–432).
PMID:37694715 PBO:0110252 The Bqt4 fragment containing the helix domain and the adjacent intrinsically disordered sequence (Bqt4C369–432) reproduced the behavior of full-length Bqt4 (Fig. 1A), that is, localization to the NE and responses to BZ, both in the presence and absence of Bqt3 (Fig. 6A, Bqt4C369–432).
PMID:37694715 PBO:0110253 The helix domain alone (Bqt4C394–432) showed weaker localization to the NE and was somewhat diffused to the membrane compartments in the cytoplasm; (Fig. 6A, Bqt4C394–432)
PMID:37694715 PBO:0110252 nevertheless, this fragment was degraded in the absence of Bqt3 and its levels increased with BZ treatment (Fig. 6A, Bqt4C394–432) These results indicate that the C-terminal fragment containing residues 369–432 was necessary and sufficient for the NE localization of Bqt4, and its truncation successively reduced NE localization. These results also indicate that the C-terminal TMD of Bqt4 is sufficient for its proteasome-mediated degradation.
PMID:37694715 PBO:0110248 GFP–Bqt4 fluorescence in the nuclei of both bqt3+ and bqt3Δ cells was elevated (Fig. 1A)
PMID:37694715 PBO:0110248 To confirm this result, we measured protein levels by western blotting, which consistently showed an increase in GFP–Bqt4 protein levels in these strains upon proteasomal inhibition by BZ Fig. 1B
PMID:37694715 MOD:01148 Ubiquitinated forms of Bqt4 were detected in bqt3Δ cells and were enriched in both bqt3+ and bqt3Δ cells when proteasomal activity was inhibited (Fig. 1E), suggesting that Bqt4 was targeted to the proteasome by polyubiquitin modification.
PMID:37694715 PBO:0110249 Ubiquitinated forms of Bqt4 were detected in bqt3Δ cells and were enriched in both bqt3+ and bqt3Δ cells when proteasomal activity was inhibited (Fig. 1E), suggesting that Bqt4 was targeted to the proteasome by polyubiquitin modification.
PMID:37694715 PBO:0110250 We constructed mutants of E3 ligases and their components that have been suggested to localize to or function in the ER and nucleus, namely ......... The mutants tested showed no detectable increase in fluorescence, except for the hul5Δ mutant (Fig. S2)
PMID:37694715 PBO:0110250 We constructed mutants of E3 ligases and their components that have been suggested to localize to or function in the ER and nucleus, namely ......... The mutants tested showed no detectable increase in fluorescence, except for the hul5Δ mutant (Fig. S2)
PMID:37694715 PBO:0093554 Fig5B
PMID:37694715 PBO:0110248 We confirmed it by microscopy as well. Fig 3A and B. Deletion of doa10+ partially restored GFP–Bqt4 levels in the absence of Bqt3, whereas deletion of hrd1+ did not (Fig. 3A,B, comparing hrd1Δ to doa10Δ)
PMID:37694715 PBO:0110248 We confirmed it by microscopy as well. Fig 3C and D. We also measured the amount of GFP–Bqt4 in mutants lacking Ubc6 and Ubc7, which are E2 ubiquitin- conjugating enzymes associated with Doa10 (Swanson et al., 2001). We found that GFP–Bqt4 levels increased to some extent in ubc6Δ and ubc7Δ single and ubc6Δ ubc7Δ double mutants (Fig. 3C,D).
PMID:37694715 PBO:0110248 We confirmed it by microscopy as well. Fig 3C and D. We also measured the amount of GFP–Bqt4 in mutants lacking Ubc6 and Ubc7, which are E2 ubiquitin- conjugating enzymes associated with Doa10 (Swanson et al., 2001). We found that GFP–Bqt4 levels increased to some extent in ubc6Δ and ubc7Δ single and ubc6Δ ubc7Δ double mutants (Fig. 3C,D).
PMID:37694715 PBO:0110248 Fig5C and D
PMID:37694715 PBO:0110248 We confirmed it by microscopy as well. Fig 2A and B. We found that GFP–Bqt4 degradation was suppressed in cut8-563 cells shifted to the nonpermissive temperature of 36°C (Fig. 2A,B).
PMID:37694715 PBO:0110248 We confirmed it by microscopy as well. Fig 1C and D.
PMID:37694715 PBO:0110248 Fig S1.
PMID:37723847 PBO:0110120 whereas C-terminus of Pkd2 (Pkd2C) displayed a uniform cytoplasmic pattern (Figures 2b and S2A).
PMID:37723847 FYPO:0002061 Figure 3b, tetrad analysis
PMID:37723847 GO:0031520 localized to the septum and the plasma membrane, especially enriched at cell tips (Figure 2d).
PMID:37723847 GO:0000935 localized to the septum and the plasma membrane, especially enriched at cell tips (Figure 2d).
PMID:37723847 PBO:0110119 N-terminus of Pkd2 (Pkd2N) localized to the cytoplasm and slightly to the ER,
PMID:37723847 PBO:0110118 Localizations of Pkd2ΔN170, Pkd2ΔC577, or Pkd2TM were identical to full length Pkd2 (Figures 2b and S2A).
PMID:37723847 PBO:0110118 Localizations of Pkd2ΔN170, Pkd2ΔC577, or Pkd2TM were identical to full length Pkd2 (Figures 2b and S2A).
PMID:37723847 GO:0005783 full length of Pkd2 (GFP-Pkd2) colocalized with Pmr1, a marker for the ER (Nakazawa et al., 2019),
PMID:37723847 FYPO:0002061 Overexpression of either construct inhibited the growth like full length (Figure 1d), indicating that each of them is capa- ble of inducing cytotoxicity upon overexpression.
PMID:37723847 PBO:0110118 Localizations of Pkd2ΔN170, Pkd2ΔC577, or Pkd2TM were identical to full length Pkd2 (Figures 2b and S2A).
PMID:37723847 FYPO:0002061 Interestingly, the internal transmem- brane region was sufficient to induce both CDRE activa- tion and growth inhibition (Figure 1a,d).
PMID:37723847 FYPO:0002061 Although the CDRE signal is disap- peared (Figure S1B), the cells did not grow in inducible condition in prz1 deletion background (Figure 1b), suggesting that the activation of calcium signaling and the cytotoxicity induced by overexpression of pkd2+ are independent.
PMID:37723847 FYPO:0002061 In accordance with previous observation, the colony did not form under the inducible condition of pkd2+ overexpres- sion (Figure 1b).
PMID:37723847 FYPO:0002061 Overexpression of either construct inhibited the growth like full length (Figure 1d), indicating that each of them is capa- ble of inducing cytotoxicity upon overexpression.
PMID:37723847 FYPO:0001252 Although C-terminal deleted cells (mCh-pkd2ΔC) did not affect to the growth under the normal condition, the strain was hypersensitive to CaCl2 (Figure 3c)
PMID:37723847 PBO:0096587 Although C-terminal deleted cells (mCh-pkd2ΔC) did not affect to the growth under the normal condition, the strain was hypersensitive to CaCl2 (Figure 3c)
PMID:37723847 FYPO:0002060 Figure 3b,tetrad analysis
PMID:37746062 PBO:0110026 Figure1 G-H
PMID:37746062 PBO:0110025 Figure1 G-H
PMID:37746062 PBO:0110026 Figure 1G-H
PMID:37746062 PBO:0110026 Figure1 G-H
PMID:37772819 FYPO:0001357 Fig. 9
PMID:37772819 FYPO:0001357 Fig. 8
PMID:37772819 FYPO:0001357 Fig. 8
PMID:37772819 FYPO:0000080 Fig. 8
PMID:37772819 FYPO:0000080 Fig. 9
PMID:37772819 FYPO:0001357 Fig. 9
PMID:37772819 FYPO:0001357 Fig. 9
PMID:37772819 FYPO:0001357 Fig. 8
PMID:37772819 FYPO:0004469 para-nitrophenylphosphatase activity (Figs. 1B and 2B)
PMID:37772819 FYPO:0004303 Fig. 1B
PMID:37772819 FYPO:0004303 Fig. 1B
PMID:37772819 GO:0052845 Figs. 5 and 6
PMID:37772819 GO:0052843 Figs. 5 and 6
PMID:37772819 GO:0004309 Fig. 4
PMID:37772819 GO:0052846 Siw14 acts on 1,5-IP8, but it has no preference for either the 5 or 1-beta phosphates (Figs.5 and 6)
PMID:37772819 FYPO:0005485 Fig. 5
PMID:37772819 FYPO:0008134 Fig. S1.
PMID:37772819 PBO:0110077 Table S3
PMID:37772819 PBO:0110078 Table S3
PMID:37772819 PBO:0108806 Table S3
PMID:37772819 PBO:0108804 Table S3
PMID:37772819 PBO:0108808 Table S3
PMID:37772819 PBO:0108810 Table S3
PMID:37772819 PBO:0108800 Table S3
PMID:37772819 PBO:0110079 Table S3
PMID:37772819 PBO:0108850 Table S3
PMID:37772819 PBO:0108811 Table S3
PMID:37772819 PBO:0108797 Table S3
PMID:37772819 PBO:0108822 Table S3
PMID:37772819 GO:0004427 Fig. 3
PMID:37772819 GO:0052847 Siw14 acts on 1,5-IP8, but it has no preference for either the 5 or 1-beta phosphates (Figs.5 and 6)
PMID:37772819 FYPO:0002061 Fig. 7
PMID:37772819 FYPO:0002061 Fig. 7
PMID:37772819 FYPO:0001357 Fig. 7
PMID:37772819 FYPO:0001357 Fig. 7
PMID:37772819 FYPO:0001357 Fig. 7
PMID:37772819 FYPO:0001357 Fig. 7
PMID:37772819 FYPO:0001357 Fig. 7
PMID:37772819 FYPO:0001357 Fig. 8
PMID:37772819 FYPO:0001357 Fig. 8
PMID:37772819 FYPO:0001357 Fig. 8
PMID:37783794 FYPO:0001355 Extended Data Fig. 4
PMID:37783794 FYPO:0001355 Extended Data Fig. 4
PMID:37783794 FYPO:0002141 Extended Data Fig. 4
PMID:37783794 FYPO:0001355 Fig. 7B
PMID:37783794 FYPO:0001355 Fig. 7B
PMID:37783794 FYPO:0001355 Fig. 7B
PMID:37783794 FYPO:0001355 Fig. 7B
PMID:37783794 PBO:0110080 Fig. 3C
PMID:37783794 PBO:0110081 Fig. 3C
PMID:37783794 PBO:0110082 Fig. 3C
PMID:37783794 PBO:0110083 Fig. 3C
PMID:37783794 PBO:0110084 Fig. 3E
PMID:37783794 PBO:0110085 Fig. 3D
PMID:37783794 PBO:0110086 Fig. 3D
PMID:37783794 PBO:0110087 Fig. 3D
PMID:37783794 PBO:0110088 Fig. 3D
PMID:37783794 FYPO:0008126 MGM4 reporter | 1 h 5IAA | 2.5% 1,6-HD | Fig. 6B–I
PMID:37783794 PBO:0092114 25 ± 10 molecules at the spindle pole body | Fig. 2
PMID:37783794 PBO:0092114 77 ± 51 molecules at the spindle pole body | Fig. 2
PMID:37783794 PBO:0092114 30 ± 17 molecules at the spindle pole body | Fig. 2
PMID:37783794 PBO:0110098 25 ± 13 molecules at the spindle pole body | Fig. 2
PMID:37783794 PBO:0092114 69 ± 37 molecules at the spindle pole body | Fig. 2
PMID:37783794 PBO:0110098 75 ± 45 molecules at the spindle pole body | Fig. 2
PMID:37783794 PBO:0092114 15 ± 8 molecules at the spindle pole body | Fig. 2
PMID:37783794 PBO:0110098 16 ± 8 molecules at the spindle pole body | Fig. 2
PMID:37783794 PBO:0110095 Fig. 5
PMID:37783794 FYPO:0008125 Fig. 5A–C
PMID:37783794 FYPO:0008125 Fig. 4H
PMID:37783794 PBO:0110096 Fig. 4
PMID:37783794 FYPO:0001355 Extended Data Fig. 4
PMID:37783794 FYPO:0001355 Extended Data Fig. 4
PMID:37783794 PBO:0110089 Fig. 3F,G (vw: into G2)
PMID:37783794 PBO:0110095 Fig. 4
PMID:37783794 GO:0005737 Puncta | Likely endosomes/MVBs | Extended Data Fig. 1A,B
PMID:37783794 PBO:0110439 Fig. 1B–D
PMID:37783794 PBO:0110439 Fig. 1B–D
PMID:37783794 PBO:0110439 Fig. 1B–D
PMID:37783794 PBO:0110439 Fig. 1B–D
PMID:37783794 PBO:0110439 Fig. 1B–D
PMID:37783794 PBO:0110438 Fig. 1B–D
PMID:37783794 PBO:0110438 Fig. 1B–D
PMID:37783794 PBO:0110438 Fig. 1B–D
PMID:37783794 FYPO:0004429 mCherry-Atb2 | 1 h 5IAA | Extended Data Fig. 5H
PMID:37783794 FYPO:0004429 mCherry-Atb2 | 1 h 5IAA | Extended Data Fig. 5H
PMID:37783794 FYPO:0004429 mCherry-Atb2 | 1 h 5IAA | Extended Data Fig. 5G
PMID:37783794 FYPO:0004429 mCherry-Atb2 | 1 h 5IAA | Extended Data Fig. 5G
PMID:37783794 FYPO:0005695 mCherry-Atb2 | Extended Data Fig. 5H
PMID:37783794 PBO:0024258 mCherry-Atb2 | 3 h 5IAA | Extended Data Fig. 5I
PMID:37783794 FYPO:0005695 mCherry-Atb2 | 1 h 5IAA | Extended Data Fig. 5G
PMID:37783794 FYPO:0008126 MGM4 reporter | ±5IAA | Extended Data Fig. 5E,F
PMID:37783794 FYPO:0008126 MGM4 reporter | ±5IAA | Extended Data Fig. 5E,F
PMID:37783794 FYPO:0008126 MGM4 reporter | 1 h 5IAA | Extended Data Fig. 5E,F
PMID:37783794 PBO:0110093 MGM4 reporter | ±5IAA | Extended Data Fig. 5B,C
PMID:37783794 PBO:0110093 MGM4 reporter | ±5IAA | Extended Data Fig. 5B,C
PMID:37783794 FYPO:0008126 MGM4 reporter | 1 h 5IAA | Extended Data Fig. B,C
PMID:37783794 PBO:0110080 1 h 5IAA | Extended Data Fig. 3C
PMID:37783794 FYPO:0008127 Fig. 7G
PMID:37783794 FYPO:0008127 Fig. 7G
PMID:37783794 FYPO:0008126 MGM4 reporter | Fig. 7C–E
PMID:37783794 FYPO:0001355 Extended Data Fig. 4
PMID:37783794 FYPO:0001355 Extended Data Fig. 4
PMID:37783794 FYPO:0001355 Extended Data Fig. 4
PMID:37783794 FYPO:0001355 Extended Data Fig. 4
PMID:37783794 FYPO:0001355 Extended Data Fig. 4
PMID:37783794 FYPO:0001355 Extended Data Fig. 4
PMID:37783794 FYPO:0001357 Extended Data Fig. 4
PMID:37783794 FYPO:0001357 Extended Data Fig. 4
PMID:37783794 FYPO:0001357 Extended Data Fig. 4
PMID:37783794 FYPO:0001355 Extended Data Fig. 4
PMID:37783794 FYPO:0001355 Extended Data Fig. 4
PMID:37783794 FYPO:0001355 Extended Data Fig. 4
PMID:37783794 FYPO:0001355 Extended Data Fig. 4
PMID:37783794 FYPO:0008124 Fig. 4E–H
PMID:37783794 PBO:0110085 Fig. 3A,B
PMID:37783794 PBO:0110092 Fig. 3A,B
PMID:37783794 PBO:0110091 ******** Fig. 3I decreased protein localization to spindle pole body during G1/S
PMID:37783794 PBO:0112754 Fig. 3I
PMID:37783794 PBO:0110089 Fig. 3H–J (vw: into G2)
PMID:37783794 PBO:0110090 *********** Fig. 3G decreased protein localization to spindle pole body during G1/S
PMID:37783794 FYPO:0008126 MGM4 reporter | Fig. 7C–E
PMID:37783794 FYPO:0008126 MGM4 reporter | Fig. 7C,D
PMID:37783794 FYPO:0002061 Lethality determined by tetrad dissection
PMID:37783794 FYPO:0002061 Lethality determined by tetrad dissection
PMID:37783794 FYPO:0001355 Extended Data Fig. 4
PMID:37783794 FYPO:0001355 Extended Data Fig. 4
PMID:37783794 FYPO:0001355 Extended Data Fig. 4
PMID:37783794 FYPO:0001355 Extended Data Fig. 4
PMID:37783794 FYPO:0001355 Extended Data Fig. 4
PMID:37783794 FYPO:0001355 Extended Data Fig. 4
PMID:37783794 FYPO:0001355 Extended Data Fig. 4
PMID:37783794 FYPO:0001355 Extended Data Fig. 4
PMID:37787465 PBO:0112707 Fig. 3C and D
PMID:37787465 PBO:0112708 Fig. 4C and D
PMID:37787465 PBO:0112702 Table 1
PMID:37787465 FYPO:0002780 Fig. 5C and D
PMID:37787465 PBO:0112705 Fig. 5E and F
PMID:37787465 PBO:0112704 Table 1
PMID:37787465 PBO:0112703 Table 1
PMID:37787465 FYPO:0004166 Fig. 5A
PMID:37787465 PBO:0112810 Fig. 5B
PMID:37787465 PBO:0112811 Fig. 5B
PMID:37787465 FYPO:0002780 Fig. 5C and D
PMID:37787465 PBO:0112709 Fig. 4F and G
PMID:37787465 PBO:0112705 Table 1
PMID:37787465 PBO:0112704 Table 1
PMID:37787465 PBO:0112703 Table 1
PMID:37787465 PBO:0112703 Table 1
PMID:37787465 PBO:0112705 Table 1
PMID:37787465 FYPO:0008213 Fig. 2J
PMID:37787465 FYPO:0008213 Fig. 2I
PMID:37787465 PBO:0112772 Fig. 1C and D
PMID:37787465 PBO:0112771 Fig. 1I and J
PMID:37787465 FYPO:0008213 Fig. 2I
PMID:37787465 PBO:0112706 Fig. 3A and B
PMID:37787465 FYPO:0008213 Fig. 2J
PMID:37788281 PBO:0092097 in sam3 mutant
PMID:37788281 GO:0005654 in sam3 mutant
PMID:37788281 PBO:0099115 by expression of rad24-E185K
PMID:37788281 GO:0005654 exclusion from nucleoplasm is delayed in rad24 deletion background
PMID:37788281 FYPO:0001864 dominat negative
PMID:37792890 FYPO:0001357 Indeed, we isolated a cold-sensitive mutant of cut6, cut6-1, as a strong suppressor of css1-3 (S3A Fig).
PMID:37792890 FYPO:0000135 Using GFP-D4H biosensor
PMID:37792890 FYPO:0000135 using GFP-D4H biosensor
PMID:37792890 FYPO:0005803 assayed using FRAP
PMID:37792890 FYPO:0002627 ***In the periplasmic space***** glucans were deposited between the PM and the cell wall at the restrictive temperature (Fig 1B).
PMID:37792890 PBO:0110142 we predicted that the glucan synthases Ags1, Bgs1, Bgs3, and Bgs4 would localize normally and adjacent to the glucan deposits in css1-3 mutant cells. Indeed, all four proteins localized at tips and septa of css1-3, as in wildtype cells
PMID:37792890 FYPO:0001235 (ags1-664, bgs1-191 and/or bgs4-1 of α1,3-glucan synthase, linear β1,3-glucan synthase and 1,6 branched β1,3-glucan synthase, respectively) [18,24,39], improved css1-3 cell growth at semi-permissive temperatures (S1B Fig) while growth in hypoosomotic conditions (sorbitol-containing media) did not (S1C Fig).
PMID:37792890 FYPO:0001235 (ags1-664, bgs1-191 and/or bgs4-1 of α1,3-glucan synthase, linear β1,3-glucan synthase and 1,6 branched β1,3-glucan synthase, respectively) [18,24,39], improved css1-3 cell growth at semi-permissive temperatures (S1B Fig) while growth in hypoosomotic conditions (sorbitol-containing media) did not (S1C Fig).
PMID:37792890 FYPO:0001357 Indeed, we isolated a cold-sensitive mutant of cut6, cut6-1, as a strong suppressor of css1-3 (S3A Fig).
PMID:37805140 PBO:0110224 Trm1 robustly modified nuclear- and mitochondrial-encoded tRNAs, consistent with its proposed localization to the nucleus and mitochondria, while M1 Trm1 only modified mitochondrially- encoded tRNAs Certain nuclear-encoded tRNAs, including tRNA SerUGA and tRNA LeuAAG were robustly modified by endogenous Trm1 (Figure 1D, “wild type”, lane 1) and overexpressed M24 Trm1 (Figure 1D, lane 3)
PMID:37805140 PBO:0110223 Trm1 robustly modified nuclear- and mitochondrial-encoded tRNAs, consistent with its proposed localization to the nucleus and mitochondria, while M1 Trm1 only modified mitochondrially- encoded tRNAs Certain nuclear-encoded tRNAs, including tRNA SerUGA and tRNA LeuAAG were robustly modified by endogenous Trm1 (Figure 1D, “wild type”, lane 1) and overexpressed M24 Trm1 (Figure 1D, lane 3)
PMID:37805140 PBO:0110222 Trm1 robustly modified nuclear- and mitochondrial-encoded tRNAs, consistent with its proposed localization to the nucleus and mitochondria, while M1 Trm1 only modified mitochondrially- encoded tRNAs Certain nuclear-encoded tRNAs, including tRNA SerUGA and tRNA LeuAAG were robustly modified by endogenous Trm1 (Figure 1D, “wild type”, lane 1) and overexpressed M24 Trm1 (Figure 1D, lane 3)
PMID:37805140 PBO:0110215 These northern blots supported the expected subcellular targeting of the Trm1 isoforms: M24 Trm1 robustly modified nuclear- and mitochondrial-encoded tRNAs, consistent with its proposed localization to the nucleus and mitochondria, while M1 Trm1 only modified mitochondrially- encoded tRNAs
PMID:37805140 PBO:0110215 These northern blots supported the expected subcellular targeting of the Trm1 isoforms: M24 Trm1 robustly modified nuclear- and mitochondrial-encoded tRNAs, consistent with its proposed localization to the nucleus and mitochondria, while M1 Trm1 only modified mitochondrially- encoded tRNAs
PMID:37805140 FYPO:0004529 pulse labeling revealed no defects in mitochondrial translation upon Trm1 deletion (Figure S1)
PMID:37805140 FYPO:0007020 figure 4a
PMID:37805140 FYPO:0003957 the D201A mutant showed the same lack of modification of nuclear- and mitochondrial-encoded tRNAs as trm1∆ cells transformed with an empty vector, despite similar levels of protein accumulation as the wild type overexpressed isoform (Figure 1D).
PMID:37805140 FYPO:0008129 figure 4a
PMID:37805140 FYPO:0006253 Wild type and D201A exhibited comparable binding affinity, suggesting that disruption of the putative catalytic site does not impair tRNA binding affinity or binding cooperativity (Figure 2A, B, Figure S2, Table S5).
PMID:37805140 FYPO:0000257 normal stop codon readthrough
PMID:37805140 FYPO:0008130 We found that both wild type and catalytically inactive nuclear-targeted (M24) Trm1 promoted suppression of the tRNA SerUCA allele in a sla1∆ background, suggesting that modification is not strictly required for suppression activity and that Trm1 promotes pre-tRNA maturation even in the absence of catalysis (Figure 3A, B).
PMID:37805140 FYPO:0003957 the D201A mutant showed the same lack of modification of nuclear- and mitochondrial-encoded tRNAs as trm1∆ cells transformed with an empty vector, despite similar levels of protein accumulation as the wild type overexpressed isoform (Figure 1D).
PMID:37805140 PBO:0110227 Trm1 robustly modified nuclear- and mitochondrial-encoded tRNAs, consistent with its proposed localization to the nucleus and mitochondria, while M1 Trm1 only modified mitochondrially- encoded tRNAs Certain nuclear-encoded tRNAs, including tRNA SerUGA and tRNA LeuAAG were robustly modified by endogenous Trm1 (Figure 1D, “wild type”, lane 1) and overexpressed M24 Trm1 (Figure 1D, lane 3)
PMID:37805140 PBO:0110226 Trm1 robustly modified nuclear- and mitochondrial-encoded tRNAs, consistent with its proposed localization to the nucleus and mitochondria, while M1 Trm1 only modified mitochondrially- encoded tRNAs Certain nuclear-encoded tRNAs, including tRNA SerUGA and tRNA LeuAAG were robustly modified by endogenous Trm1 (Figure 1D, “wild type”, lane 1) and overexpressed M24 Trm1 (Figure 1D, lane 3)
PMID:37805140 PBO:0110299 Trm1 robustly modified nuclear- and mitochondrial-encoded tRNAs, consistent with its proposed localization to the nucleus and mitochondria, while M1 Trm1 only modified mitochondrially- encoded tRNAs Certain nuclear-encoded tRNAs, including tRNA SerUGA and tRNA LeuAAG were robustly modified by endogenous Trm1 (Figure 1D, “wild type”, lane 1) and overexpressed M24 Trm1 (Figure 1D, lane 3)
PMID:37805140 PBO:0110225 Trm1 robustly modified nuclear- and mitochondrial-encoded tRNAs, consistent with its proposed localization to the nucleus and mitochondria, while M1 Trm1 only modified mitochondrially- encoded tRNAs Certain nuclear-encoded tRNAs, including tRNA SerUGA and tRNA LeuAAG were robustly modified by endogenous Trm1 (Figure 1D, “wild type”, lane 1) and overexpressed M24 Trm1 (Figure 1D, lane 3)
PMID:37815455 FYPO:0006627 GFP-2xPH(Plc) biosensor
PMID:37815455 PBO:0110109 In contrast, PM Its3-mNG was mildly reduced at 25°C and increased 1.8-fold at 36°C in pik1-11 compared to wildtype cells (Fig. 2E-F and S1E)
PMID:37815455 FYPO:0002150 when we attempted to combine ncs1Δ with pik1-11 we found that they were synthetically lethal (Fig. 4A)
PMID:37815455 FYPO:0002150 when we attempted to combine ncs1Δ with pik1-11 we found that they were synthetically lethal (Fig. 4A)
PMID:37815455 FYPO:0001355 Fig. S2A)
PMID:37815455 FYPO:0001355 Fig. S2A)
PMID:37815455 FYPO:0001355 Fig. S2A)
PMID:37815455 FYPO:0001355 Fig. S2A)
PMID:37815455 FYPO:0007489 We found that Pik1-D450- mNG still localized to the trans-Golgi marked by Sec72-mCherry in ncs1∆ cells (Fig. 4C), Interestingly, there was a high cytoplasmic Pik1 population in ncs1Δ cells that was not observed in wildtype cells; indeed, there was >2- fold more Pik1 overall (Fig. 4D). We currently do not have a mechanistic explanation for this observation.
PMID:37815455 FYPO:0000994 GFP-P4C(SidC) biosensor
PMID:37815455 PBO:0110110 (Fig. S1D)
PMID:37815455 PBO:0110111 (Fig. S1D)
PMID:37815455 PBO:0110112 (Fig. S1D)
PMID:37815455 FYPO:0002060 pik1-11 cells grow similarly to wildtype at 25 ̊C and 29 ̊C but pik1-11 cells do not grow at 32 ̊C or 36 ̊C (Fig. 1C)
PMID:37815455 FYPO:0002061 pik1-11 cells grow similarly to wildtype at 25 ̊C and 29 ̊C but pik1-11 cells do not grow at 32 ̊C or 36 ̊C (Fig. 1C)
PMID:37815455 GO:0098744 To determine whether there was Golgi PI4P in ncs1∆, a proxy for a change in Pik1 activity, we imaged cells expressing GFP-P4CSidC in wildtype and ncs1Δ cells. We observed the persistence of Golgi PI4P puncta as well as increased cytoplasmic and PM PI4P levels in ncs1∆ cells (Fig. 4E-F). Combined with the fact that Pik1 is essential whereas Ncs1 is not (Hamasaki-Katagiri et al., 2004; Park et al., 2009), it seems unlikely that Ncs1 is required for S. pombe Pik1 activity and perhaps even acts as a negative regulator.
PMID:37815455 FYPO:0008040 GFP-P4C(SidC) biosensor
PMID:37815455 FYPO:0008133 GFP-P4C(SidC) biosensor
PMID:37815455 FYPO:0006628 GFP-P4C(SidC) biosensor
PMID:37815455 FYPO:0003736 Figure 1F
PMID:37815455 FYPO:0001903 (Fig. 1D-E).
PMID:37815455 GO:0046854 **********phosphatidylinositol 4-phosphate biosynthetic process We conclude that pik1-11 cells lack a Golgi PI4P pool, and have reduced PM PI4P that does not result in a corresponding decrease in PM PI(4,5)P2.
PMID:37815455 GO:0032588 we observed co-localization of Ncs1-mCherry with Pik1- D450-mNG at the trans-Golgi (Fig. 4B)
PMID:37815455 GO:0032588 found co-localization only with the trans-Golgi marker (Fig. 3B),
PMID:37815455 GO:0046854 **********phosphatidylinositol 4-phosphate biosynthetic process
PMID:37815455 PBO:0110108 We conclude that pik1-11 cells lack a Golgi PI4P pool, and have reduced PM PI4P that does not result in a corresponding decrease in PM PI(4,5)P2.
PMID:37820734 GO:0106260 sequential topological entrapment of two or more DNAs, A DNA tethering activity where a protein complex encircles two or more DNA molecules, one at a time, with its loose fitting ring.
PMID:37820734 GO:0061776 A reaction time course revealed that most dsDNA binding occurred within the first 15 min of incubation, whereas dsDNA binding by Walker A ATPase motif mutant condensin was not stimulated by ATP addition (Figures S1B and S1C). These results show that recombinant fission yeast condensin binds to DNA in an ATP-stimulated, high-salt-resistant manner, characteristic of topological DNA interactions by SMC complexes.
PMID:37820734 GO:0061776 A reaction time course revealed that most dsDNA binding occurred within the first 15 min of incubation, whereas dsDNA binding by Walker A ATPase motif mutant condensin was not stimulated by ATP addition (Figures S1B and S1C). These results show that recombinant fission yeast condensin binds to DNA in an ATP-stimulated, high-salt-resistant manner, characteristic of topological DNA interactions by SMC complexes.
PMID:37820734 GO:0061776 A reaction time course revealed that most dsDNA binding occurred within the first 15 min of incubation, whereas dsDNA binding by Walker A ATPase motif mutant condensin was not stimulated by ATP addition (Figures S1B and S1C). These results show that recombinant fission yeast condensin binds to DNA in an ATP-stimulated, high-salt-resistant manner, characteristic of topological DNA interactions by SMC complexes. Three topologically closed dsDNA sub- strates—supercoiled, relaxed circular, and nicked circular— were all recovered with similar efficiency (Figure 1B). Condensin also bound, albeit less efficiently, circular single-stranded DNA (ssDNA). By contrast, we observed no detectable recovery of linear dsDNA, consistent with a topological condensin-DNA interaction.
PMID:37820734 GO:0003690 author suggested double-stranded DNA gripping or clamping A DNA binding activity, stimulated by the binding of a non-hydrolylsable ATP analogue, where a ATPase protein complex tightly grips a stretch of double-stranded DNA with some or all of its subunits. Such a conformation is usually interpretted as the intermediate state before the ATP hydrolysis by the protein complex.
PMID:37820734 GO:0106260 DNA-DNA tethering activity, sequential topological entrapment: sequential topological entrapment of two or more DNAs, A DNA tethering activity where a protein complex encircles two or more DNA molecules, one at a time, with its loose fitting ring.
PMID:37820734 GO:0061776 A reaction time course revealed that most dsDNA binding occurred within the first 15 min of incubation, whereas dsDNA binding by Walker A ATPase motif mutant condensin was not stimulated by ATP addition (Figures S1B and S1C). These results show that recombinant fission yeast condensin binds to DNA in an ATP-stimulated, high-salt-resistant manner, characteristic of topological DNA interactions by SMC complexes. Although an intact supercoiled plasmid remained stably bound to condensin in the bead fraction, linearized dsDNA was released into the su- pernatant. This experiment confirms that ATP-dependent con- densin loading results in a topological DNA interaction.
PMID:37820734 GO:0106260 sequential topological entrapment of two or more DNAs, A DNA tethering activity where a protein complex encircles two or more DNA molecules, one at a time, with its loose fitting ring.
PMID:37820734 GO:0061776 A reaction time course revealed that most dsDNA binding occurred within the first 15 min of incubation, whereas dsDNA binding by Walker A ATPase motif mutant condensin was not stimulated by ATP addition (Figures S1B and S1C). These results show that recombinant fission yeast condensin binds to DNA in an ATP-stimulated, high-salt-resistant manner, characteristic of topological DNA interactions by SMC complexes.
PMID:37820734 GO:0106260 sequential topological entrapment of two or more DNAs, A DNA tethering activity where a protein complex encircles two or more DNA molecules, one at a time, with its loose fitting ring.
PMID:37820734 GO:0106260 sequential topological entrapment of two or more DNAs, A DNA tethering activity where a protein complex encircles two or more DNA molecules, one at a time, with its loose fitting ring.
PMID:37913773 PBO:0110891 Nevertheless, our analysis revealed that deletion of atf1+ gene (atf1D) did not signif- icantly affect Tor2 accumulation in rDNA (Figures S2A and S2B).
PMID:37913773 FYPO:0001134 Moreover, we found that the diminution of 18S rRNA levels in the tor2-287 mutant could be mitigated by overexpression of Atf1 (atf1 o.p) or disruption of the ago1+ gene (ago1D), which encodes a crucial factor for RNAi-dependent heterochromatinization (Fig- ure 3I).
PMID:37913773 PBO:0110885 nuc1-632 mutant strain, wherein RNA polymerase I function was impaired.33,34 As a result, we found a considerable reduc- tion in Tor2 accumulation in the rDNA region compared with wild-type cells, concomitant with a decrease in rRNA abundance (Figures 2A and 2B).
PMID:37913773 PBO:0110884 We per- formed RT-qPCR and found that transcription of selected ribosome-related genes (rpl102+, rlp7+, and gar2+) was reduced in the tor2-287 mutant (Figure 4A).
PMID:37913773 PBO:0110885 We then examined their accumulation at rDNA using ChIP assays and found a decrease in the rDNA accu- mulation of FLAG-Tor2 lacking the HTH domain (Figure 2G).
PMID:37913773 GO:0042134 In addition, the RNA immunoprecipitation analysis revealed a notable association between FLAG-Tor2 and rDNA transcripts, specifically at the 18S, 5.8S, and 28S regions (Figures 2E and S2D)
PMID:37913773 FYPO:0001134 Moreover, we found that the diminution of 18S rRNA levels in the tor2-287 mutant could be mitigated by overexpression of Atf1 (atf1 o.p) or disruption of the ago1+ gene (ago1D), which encodes a crucial factor for RNAi-dependent heterochromatinization (Fig- ure 3I).
PMID:37913773 PBO:0110883 We per- formed RT-qPCR and found that transcription of selected ribosome-related genes (rpl102+, rlp7+, and gar2+) was reduced in the tor2-287 mutant (Figure 4A).
PMID:37913773 PBO:0110882 We per- formed RT-qPCR and found that transcription of selected ribosome-related genes (rpl102+, rlp7+, and gar2+) was reduced in the tor2-287 mutant (Figure 4A).
PMID:37913773 FYPO:0001134 Although the downstream S6K kinase Psk1 in the TORC1 pathway has been implicated in RP phosphorylation,39 our finding demon- strated that rRNA abundance was unaffected in the psk1D strain (Figure S3A)
PMID:37913773 PBO:0111446 Chromatin immunoprecipitation (ChIP) experiments targeting FLAG-tagged Tor2, Pop3/LST8, Tco89, and Mip1/Raptor, constituents of TORC1,31 exhibited significant TORC1 accumula- tion across the rDNA, predominantly in the 18S and 28S regions (Figures 1A and 1B).
PMID:37913773 PBO:0111445 Chromatin immunoprecipitation (ChIP) experiments targeting FLAG-tagged Tor2, Pop3/LST8, Tco89, and Mip1/Raptor, constituents of TORC1,31 exhibited significant TORC1 accumula- tion across the rDNA, predominantly in the 18S and 28S regions (Figures 1A and 1B).
PMID:37913773 PBO:0110881 we found that the intracellular Atf1 protein levels were significantly reduced in the tor2-287 mutants when detected with an anti-Atf1 antibody (Figures 3G and 3H).
PMID:37913773 PBO:0110880 we conducted ChIP-qPCR targeting Gcn5-HA and found that it diminished from rDNA in the tor2-287 mutant compared with wild-type (Figure S3D).
PMID:37913773 FYPO:0006074 To investigate this, we performed ChIP-qPCR tar- geting H3K9 methylation, a marker of heterochromatin forma- tion, in both wild-type and tor2-287 cells. We found that tor2-287 cells exhibited a marked increase in H3K9me2 levels, accompanied by a slight increase in histone H3 occupancy in the rDNA region (Figures 3C and S3C).
PMID:37913773 PBO:0110878 heterochromatin forma- tion in rDNA is prompted by the dissociation of the stress- responsive transcription factor Atf1 and the accumulation of the histone chaperone FACT, which maintains H3K9 methyl- ation,40 in addition to the RNAi-dependent pathway.14 We there- fore performed ChIP-qPCR targeting Atf1 and FLAG-tagged Pob3 (a component of FACT), and found that Atf1 diminished from the entire rDNA region, while Pob3-FLAG selectively accu- mulated between rDNA repeats (Figures 3D and 3E).
PMID:37913773 PBO:0111445 Chromatin immunoprecipitation (ChIP) experiments targeting FLAG-tagged Tor2, Pop3/LST8, Tco89, and Mip1/Raptor, constituents of TORC1,31 exhibited significant TORC1 accumula- tion across the rDNA, predominantly in the 18S and 28S regions (Figures 1A and 1B).
PMID:37913773 PBO:0111446 Chromatin immunoprecipitation (ChIP) experiments targeting FLAG-tagged Tor2, Pop3/LST8, Tco89, and Mip1/Raptor, constituents of TORC1,31 exhibited significant TORC1 accumula- tion across the rDNA, predominantly in the 18S and 28S regions (Figures 1A and 1B).
PMID:37913773 PBO:0110877 Furthermore, we discovered that this reduction was caused by the dissociation of RNA polymerase I from the rDNA region (Figures 3B and S3B).
PMID:37913773 GO:0060963 Taken together, the transcription of ribosome-associ- ated genes is regulated by TORC1.
PMID:37913773 GO:0061188 We thus conclude that heterochromatinization of rDNA induced by glucose starvation is initiated by TORC1 inactivation (Figure 3F).
PMID:37913773 FYPO:0003694 Our result indicated that the total amount of 18S rRNA transcripts was reduced by half in the tor2-287 mutant, even under nutrient-rich conditions (Figure 3A).
PMID:37949217 PBO:0112798 In the mutants, Xpr1- GFP was similarly localized to the cell periphery, suggesting that accelerated Pi export in these mutants may not be caused by dynamic alteration of the localization of the exporter, Xpr1
PMID:37949217 FYPO:0002060 This time, we obtained Δpqr1Δxpr1Δvtc4 col- onies on PMG with 0.15 mM Pi, which did not grow on either normal PMG (15 mM Pi) or YES.
PMID:37949217 FYPO:0000646 Cells were severely deformed/swollen and many were collapsed and probably dying (Figs. 2D and S2).
PMID:37949217 FYPO:0002060 All double mutants, Δpqr1Δxpr1, Δpqr1Δvtc4, and Δxpr1Δvtc4, were able to form colonies at 100 mM Pi. Δpqr1Δxpr1 showed slow growth at 100 mM Pi and failed to grow at 300 mM Pi (Fig. 2C).
PMID:37949217 FYPO:0001355 All double mutants, Δpqr1Δxpr1, Δpqr1Δvtc4, and Δxpr1Δvtc4, were able to form colonies at 100 mM Pi. Δpqr1Δxpr1 showed slow growth at 100 mM Pi and failed to grow at 300 mM Pi (Fig. 2C).
PMID:37949217 FYPO:0002060 All double mutants, Δpqr1Δxpr1, Δpqr1Δvtc4, and Δxpr1Δvtc4, were able to form colonies at 100 mM Pi. Δpqr1Δxpr1 showed slow growth at 100 mM Pi and failed to grow at 300 mM Pi (Fig. 2C).
PMID:37949217 FYPO:0001330 ************free*************figure 3
PMID:37949217 FYPO:0000364 figure 3
PMID:37949217 FYPO:0008228 Xpr1-dependent Pi export is accelerated by either Δpqr1 or Δvtc4. Importantly, the elevation of Pi export activity in Δpqr1 and Δvtc4 is synergistic. In Δpqr1Δvtc4, exported Pi was far greater than that in the single mutant (Fig. 5D
PMID:37949217 PBO:0112796 Xpr1-dependent Pi export is accelerated by either Δpqr1 or Δvtc4. Importantly, the elevation of Pi export activity in Δpqr1 and Δvtc4 is synergistic. In Δpqr1Δvtc4, exported Pi was far greater than that in the single mutant (Fig. 5D
PMID:37949217 PBO:0112796 Xpr1-dependent Pi export is accelerated by either Δpqr1 or Δvtc4. Importantly, the elevation of Pi export activity in Δpqr1 and Δvtc4 is synergistic. In Δpqr1Δvtc4, exported Pi was far greater than that in the single mutant (Fig. 5D
PMID:37949217 FYPO:0008228 Xpr1-dependent Pi export is accelerated by either Δpqr1 or Δvtc4. Importantly, the elevation of Pi export activity in Δpqr1 and Δvtc4 is synergistic. In Δpqr1Δvtc4, exported Pi was far greater than that in the single mutant (Fig. 5D
PMID:37949217 FYPO:0001357 The Pi hyper-sensitivity of Δpqr1Δxpr1 was suppressed by the double gene deletion of Pho84 and Pho842 (Figs. 6A and S6).
PMID:37949217 PBO:0112798 In the mutants, Xpr1- GFP was similarly localized to the cell periphery, suggesting that accelerated Pi export in these mutants may not be caused by dynamic alteration of the localization of the exporter, Xpr1
PMID:37949217 PBO:0112798 In the mutants, Xpr1- GFP was similarly localized to the cell periphery, suggesting that accelerated Pi export in these mutants may not be caused by dynamic alteration of the localization of the exporter, Xpr1
PMID:37949217 PBO:0112797 We found that Xpr1-GFP did not increase in Δpqr1, Δvtc4, or Δpqr1Δvtc4 (Fig. 5G). Accelerated Pi export in these mutants may not be caused by increased amounts of Xpr1 protein.
PMID:37949217 PBO:0112797 We found that Xpr1-GFP did not increase in Δpqr1, Δvtc4, or Δpqr1Δvtc4 (Fig. 5G). Accelerated Pi export in these mutants may not be caused by increased amounts of Xpr1 protein.
PMID:37949217 PBO:0112797 We found that Xpr1-GFP did not increase in Δpqr1, Δvtc4, or Δpqr1Δvtc4 (Fig. 5G). Accelerated Pi export in these mutants may not be caused by increased amounts of Xpr1 protein.
PMID:37949217 PBO:0112796 Xpr1-dependent Pi export is accelerated by either Δpqr1 or Δvtc4. Importantly, the elevation of Pi export activity in Δpqr1 and Δvtc4 is synergistic. In Δpqr1Δvtc4, exported Pi was far greater than that in the single mutant (Fig. 5D
PMID:37949217 GO:0005886 It was localized mainly in the cell periphery, probably at the plasma membrane (Fig. 1C), consistent with its role in Pi export.
PMID:37949217 PBO:0112824 **************Pi total*****************figure 1a
PMID:37949217 PBO:0096729 ***************total************figure 1a
PMID:37949217 PBO:0112825 ************Pi total ************figure 1A
PMID:37949217 PBO:0112825 ***************total Pi************ figure 1A
PMID:37949217 PBO:0112826 **********Pi total***********figure 1A
PMID:37949217 FYPO:0002061 We found that spores assumed to be Δpqr1Δxpr1Δvtc4 did not form colonies, suggesting synthetic lethality of gene deletions of pqr1+, xpr1+, and vtc4+ on YES.
PMID:37970674 FYPO:0006995 Figure 3D
PMID:37970674 PBO:0112061 However, in nup132Δ cells, whereas wild-type Pli1 was destabilised, Pli1K3R levels remained high (Fig. 1B).
PMID:37970674 PBO:0112060 However, in nup132Δ cells, whereas wild-type Pli1 was destabilised, Pli1K3R levels remained high (Fig. 1B).
PMID:37970674 PBO:0093564 Similarly, both nup132Δ and pli1Δ cells showed sensitivity to the microtubule-stabilising drug thiabendazole (TBZ), consistent with defects in centromere function, and this TBZ sensitivity was also not rescued by the Pli1K3R mutation (Fig. 1C). T
PMID:37970674 PBO:0112070 inhibits
PMID:37970674 PBO:0093564 Similarly, both nup132Δ and pli1Δ cells showed sensitivity to the microtubule-stabilising drug thiabendazole (TBZ), consistent with defects in centromere function, and this TBZ sensitivity was also not rescued by the Pli1K3R mutation (Fig. 1C). T
PMID:37970674 PBO:0096188 , deletion of either nup132+ or pli1+ results in reduced growth in the presence of 5-FOA, indicating increased expression of ura4+ and hence loss of silencing (Fig. 1C).
PMID:37970674 FYPO:0000964 Similarly, both nup132Δ and pli1Δ cells showed sensitivity to the microtubule-stabilising drug thiabendazole (TBZ), consistent with defects in centromere function, and this TBZ sensitivity was also not rescued by the Pli1K3R mutation (Fig. 1C). T
PMID:37970674 GO:0072766 inhibits
PMID:37970674 PBO:0096188 If the silencing defect in nup132Δ cells were due to destabilisation of Pli1, we would expect it to be rescued by expression of the stabilised Pli1K3R mutant. However, this was not the case – nup132Δ cells expressing Pli1K3R–Flag displayed a defect in silencing equivalent to those expressing wild-type Pli1–Flag
PMID:37970674 PBO:0093564 Similarly, both nup132Δ and pli1Δ cells showed sensitivity to the microtubule-stabilising drug thiabendazole (TBZ), consistent with defects in centromere function, and this TBZ sensitivity was also not rescued by the Pli1K3R mutation (Fig. 1C). T
PMID:37970674 PBO:0096188 , deletion of either nup132+ or pli1+ results in reduced growth in the presence of 5-FOA, indicating increased expression of ura4+ and hence loss of silencing (Fig. 1C).
PMID:38048463 PBO:0112025 Fig. 1E
PMID:38048463 PBO:0111621 Fig. 3B
PMID:38048463 PBO:0093618 We found that the rex1BDΔ cells were also sensitive to MMS, but relatively mild compared with apn2Δ (SI Appendix, Fig. S4).
PMID:38048463 GO:0005634 We observed that overexpressed Rex1BD-GFP was enriched within the nucleus, consistent with its role as a heterochromatin factor (SI Appendix, Fig. S3).
PMID:38048463 PBO:0112031 Fig. 5B and C
PMID:38048463 PBO:0112030 Fig. 4E
PMID:38048463 PBO:0112029 Fig. 4E
PMID:38048463 PBO:0112188 Fig. 4D
PMID:38048463 PBO:0112028 Fig. 4C
PMID:38048463 PBO:0112032 Fig. 5D
PMID:38048463 PBO:0111621 Phenotype of rad25 deletion amplified by rex1BD deletion at otr3R10 (Fig. 5B)
PMID:38048463 PBO:0111621 Phenotype of rad25 deletion amplified by rex1BD deletion at otr3R10 (Fig. 5B)
PMID:38048463 PBO:0112033 Fig. 5C
PMID:38048463 PBO:0112027 Fig. 5D
PMID:38048463 PBO:0112027 Fig. 5D
PMID:38048463 GO:0140727 Our genetic assays revealed that Rex1BD acts in an RNAi- independent manner.
PMID:38048463 PBO:0112027 Fig. 2F
PMID:38048463 PBO:0112027 Fig. 2E
PMID:38048463 PBO:0111621 Fig. 1C
PMID:38048463 PBO:0112026 Fig. 1H
PMID:38048463 PBO:0112026 Fig. 1H
PMID:38048463 FYPO:0003555 Fig. 1H
PMID:38048463 PBO:0097417 Fig. 1G
PMID:38048463 PBO:0097417 Fig. 1G
PMID:38048463 FYPO:0002336 Fig. 1G
PMID:38048463 PBO:0098772 Fig. 1F
PMID:38048463 PBO:0096299 Fig. 1E
PMID:38048463 PBO:0111621 Fig. 4B
PMID:38048463 PBO:0111621 Fig. 3C
PMID:38048463 PBO:0112027 Fig. 3B
PMID:38048463 PBO:0112027 Fig. 3B
PMID:38051102 FYPO:0001409 Although the growth defect of the Dsfp1 mutant was observed on glucose medium, it grew normally on medium containing glycerol as the carbon source (Fig. 1H), similar to the situation in budding yeast.27
PMID:38051102 GO:0003713 from
PMID:38051102 GO:0005634 Fhl1 was constitutively found in the nucleus, without being affected by TORC1 inactivation (Fig. 6D) or the loss of Sfp1 (Fig. 6F).
PMID:38051102 PBO:0110573 Moreover, the nuclear signal of Ifh1 was also significantly reduced in the Dsfp1 mutant (Fig. 6F), though neither the protein level nor the mobility shift of Ifh1 was affected by the Dsfp1 mutation (Fig. 6G).
PMID:38051102 PBO:0110702 or the tor2-287 mutation (Fig. 6E), the nuclear accumulation of Ifh1 was largely lost while no change in the Ifh1 protein levels was observed (Fig. 6B), implying that TORC1 promotes the nuclear localization of Ifh
PMID:38051102 GO:0005634 Remarkably, we discovered that Ifh1 accumulates in the nucleus in a TORC1- dependent manner. In wild-type cells expressing Ifh1 with the fluorescent mEGFP tag, Ifh1 appeared to be concentrated in the nucleus, with some cytoplasmic signals (Fig. 6D).
PMID:38051102 PBO:0110701 When TORC1 was inactivated in the tor2-13 or tor2-287 mutants at the restrictive temperature, the electrophoretic mobility of Ifh1 was notably decreased (Fig. 6A). The slow migrating form of Ifh1 was also observed when TORC1 was inactivated in wild-type cells starved of nitrogen (Fig. 6B). Phosphatase treatment experiments confirmed that slow-migrating Ifh1 was its phos- phorylated form (Fig. 6B).
PMID:38051102 PBO:0110701 When TORC1 was inactivated in the tor2-13 or tor2-287 mutants at the restrictive temperature, the electrophoretic mobility of Ifh1 was notably decreased (Fig. 6A). The slow migrating form of Ifh1 was also observed when TORC1 was inactivated in wild-type cells starved of nitrogen (Fig. 6B). Phosphatase treatment experiments confirmed that slow-migrating Ifh1 was its phos- phorylated form (Fig. 6B).
PMID:38051102 PBO:0110700 It was found, however, that the amount of the Ifh1-Fhl1 complex was reduced in the Dsfp1 mutant when compared to that in the wild-type strain.
PMID:38051102 PBO:0110699 The Ifh1-Fhl1 associ- ation was detected both in the presence and absence of Sfp1, suggesting that Sfp1 is not required for their interaction (Fig. 4F).
PMID:38051102 PBO:0110698 The interaction between Fhl1 and Ifh1 was impaired in the mutant expressing Fhl1 without the N-terminal 150 amino acid residues (Fig. 4E), indicating that the Ifh1-FHl1 inter- action depends on the forkhead-associated (FHA) domain of Fhl1.
PMID:38051102 PBO:0094263 Notably, the absence of Sfp1 modestly alleviates the growth defect of the mutants lacking functional GATOR1 (Fig. 1I); the absence of GATOR1 causes a severe growth defect due to deregulated TORC1 activation,28 and therefore, the observed genetic interaction corroborates a functional link between Sfp1 and TORC1.
PMID:38051102 PBO:0094263 Notably, the absence of Sfp1 modestly alleviates the growth defect of the mutants lacking functional GATOR1 (Fig. 1I); the absence of GATOR1 causes a severe growth defect due to deregulated TORC1 activation,28 and therefore, the observed genetic interaction corroborates a functional link between Sfp1 and TORC1.
PMID:38051102 PBO:0094263 Notably, the absence of Sfp1 modestly alleviates the growth defect of the mutants lacking functional GATOR1 (Fig. 1I); the absence of GATOR1 causes a severe growth defect due to deregulated TORC1 activation,28 and therefore, the observed genetic interaction corroborates a functional link between Sfp1 and TORC1.
PMID:38051102 PBO:0094263 Notably, the absence of Sfp1 modestly alleviates the growth defect of the mutants lacking functional GATOR1 (Fig. 1I); the absence of GATOR1 causes a severe growth defect due to deregulated TORC1 activation,28 and therefore, the observed genetic interaction corroborates a functional link between Sfp1 and TORC1.
PMID:38051102 PBO:0094263 Although the growth defect of the Dsfp1 mutant was observed on glucose medium, it grew normally on medium containing glycerol as the carbon source (Fig. 1H), similar to the situation in budding yeast.27. ALSO figure 4B for severity
PMID:38051102 PBO:0094263 Importantly, no significant additive phenotype was observed when the mutations were combined (Fig. 4B), suggesting that Sfp1, Ifh1, and Fhl1 function in the same pathway that regulates cell proliferation. Consistently, like the Dsfp1 mutation (Fig. 1I), the Difh1 and Dfhl1 mutations were also able to ameliorate the growth defect caused by the absence of the functional GATOR1 complex (Fig. 4C).
PMID:38051102 PBO:0110697 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110696 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110695 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110694 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110693 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110692 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110691 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110690 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110689 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110688 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110687 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110686 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110685 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110684 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110683 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110682 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110681 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110680 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110679 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110678 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110677 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110676 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110675 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110674 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110673 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110672 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110671 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110670 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110669 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110668 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110667 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110666 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110665 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110664 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110663 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110662 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110661 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110660 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110659 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110658 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110657 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110656 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110655 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110654 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110653 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110652 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110651 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110650 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110649 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110648 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110647 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110646 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110645 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110644 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110643 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110642 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110641 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110640 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110639 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110638 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110637 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110636 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110635 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110634 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110633 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110632 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110631 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110630 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110629 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110628 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110627 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110626 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110625 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110624 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110623 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110622 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110621 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110620 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110619 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110618 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110617 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110616 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110615 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110614 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110613 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110612 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110611 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110610 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110609 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110608 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110607 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110606 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110605 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110604 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110603 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110602 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110601 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110600 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110599 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110598 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110597 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110596 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110595 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110594 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110593 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110592 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110591 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110590 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110589 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110588 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110587 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110586 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110585 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110584 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110583 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110582 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110581 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110580 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110579 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110578 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110577 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110576 Our RNA-seq data indi- cated that among 141 RP and 292 Ribi genes in fission yeast (Supplementary material, Table S1), 31.9% of the RP genes (45 genes) and 26.4% of the Ribi genes (77 genes) are downregulated in the Dsfp1 mutant (Fig. 3B and C, and Supplementary material, Table S2). Collectively, these results imply that the Sfp1 transcription factor promotes the expression of the genes required for ribosome biosynthesis, a critical process for pro- tein synthesis linked to cell growth.
PMID:38051102 PBO:0110575 An in vitro kinase assay using Sfp1 as a substrate indicated that Sfp1 is a substrate of TORC1 (Fig. 2M).
PMID:38051102 PBO:0110574 (SHOULD I CHANGE THIS TO DELAYED?????) The reduction of the Sfp1 protein upon nitrogen starvation was significantly delayed in the mts3-1 mutant (Fig. 2K), suggesting that the stability of Sfp1 during starvation is regulated by the proteasome.
PMID:38051102 PBO:0110573 In the tor2-287 and tor2-13 mutants, the Sfp1 protein dra- matically decreased within 2h after shifting to the restrictive temperature (Fig. 2A),
PMID:38051102 PBO:0110573 In the tor2-287 and tor2-13 mutants, the Sfp1 protein dra- matically decreased within 2h after shifting to the restrictive temperature (Fig. 2A),
PMID:38051102 PBO:0094263 Notably, the absence of Sfp1 modestly alleviates the growth defect of the mutants lacking functional GATOR1 (Fig. 1I); the absence of GATOR1 causes a severe growth defect due to deregulated TORC1 activation,28 and therefore, the observed genetic interaction corroborates a functional link between Sfp1 and TORC1.
PMID:38051102 PBO:0094263 Notably, the absence of Sfp1 modestly alleviates the growth defect of the mutants lacking functional GATOR1 (Fig. 1I); the absence of GATOR1 causes a severe growth defect due to deregulated TORC1 activation,28 and therefore, the observed genetic interaction corroborates a functional link between Sfp1 and TORC1.
PMID:38051102 PBO:0094264 Notably, the absence of Sfp1 modestly alleviates the growth defect of the mutants lacking functional GATOR1 (Fig. 1I); the absence of GATOR1 causes a severe growth defect due to deregulated TORC1 activation,28 and therefore, the observed genetic interaction corroborates a functional link between Sfp1 and TORC1.
PMID:38051102 PBO:0094264 Notably, the absence of Sfp1 modestly alleviates the growth defect of the mutants lacking functional GATOR1 (Fig. 1I); the absence of GATOR1 causes a severe growth defect due to deregulated TORC1 activation,28 and therefore, the observed genetic interaction corroborates a functional link between Sfp1 and TORC1.
PMID:38051102 PBO:0094263 Notably, the absence of Sfp1 modestly alleviates the growth defect of the mutants lacking functional GATOR1 (Fig. 1I); the absence of GATOR1 causes a severe growth defect due to deregulated TORC1 activation,28 and therefore, the observed genetic interaction corroborates a functional link between Sfp1 and TORC1.
PMID:38051102 PBO:0094264 Notably, the absence of Sfp1 modestly alleviates the growth defect of the mutants lacking functional GATOR1 (Fig. 1I); the absence of GATOR1 causes a severe growth defect due to deregulated TORC1 activation,28 and therefore, the observed genetic interaction corroborates a functional link between Sfp1 and TORC1.
PMID:38051102 PBO:0094263 Although the growth defect of the Dsfp1 mutant was observed on glucose medium, it grew normally on medium containing glycerol as the carbon source (Fig. 1H), similar to the situation in budding yeast.27. ALSO figure 4B for severity
PMID:38051102 PBO:0093779 In contrast, the Dsfp1 mutant exhibited a modest growth defect as well as limited rapamycin sensitivity (Fig. 1G), consistent with the notion that Sfp1 is involved in cell proliferation regulated by TORC1.
PMID:38051102 PBO:0110572 TORC1 activity monitored by the Psk1 phosphorylation was comparable between wild-type and Dsfp1 cells before and after nitrogen starvation (Fig. 1F), further confirming that Sfp1 does not affect TORC1 activity.
PMID:38051102 PBO:0110572 The level of Psk1 phosphorylation was comparable between wild-type and tor2-287 cells growing at 25 � C (Fig. 1E). Upon temperature shift to the restrictive temperature, dephosphorylation of Psk1 was observed with similar kinetics both in the presence and absence of Sfp1 overexpression (Fig. 1E), suggesting that Sfp1 does not affect TORC1 activity.
PMID:38051102 PBO:0093558 Truncation of amino acids 84 to 105 or amino acids 293 to 442 of Sfp1, which removes the N-terminal or C-terminal zinc finger domains, resulted in reduced growth defect suppression in the tor2-287 mutant compared to full-length Sfp1 (Fig. 1D).
PMID:38051102 PBO:0093558 Truncation of amino acids 84 to 105 or amino acids 293 to 442 of Sfp1, which removes the N-terminal or C-terminal zinc finger domains, resulted in reduced growth defect suppression in the tor2-287 mutant compared to full-length Sfp1 (Fig. 1D).
PMID:38051102 PBO:0093558 The screen isolated a plasmid, pALSK53, which suppressed the ts growth phenotype and rapamycin sensitivity of the tor2-13 mutant (Fig. 1A).
PMID:38051102 PBO:0093557 The screen isolated a plasmid, pALSK53, which suppressed the ts growth phenotype and rapamycin sensitivity of the tor2-13 mutant (Fig. 1A).
PMID:38051102 PBO:0093557 The screen isolated a plasmid, pALSK53, which suppressed the ts growth phenotype and rapamycin sensitivity of the tor2-13 mutant (Fig. 1A).
PMID:38133430 FYPO:0004481 Fig. 5A
PMID:38133430 PBO:0094771 Fig. 5B
PMID:38133430 FYPO:0004481 Fig. 5A
PMID:38133430 FYPO:0004481 Fig. 5A
PMID:38133430 PBO:0094738 Fig. 4C, S3B
PMID:38133430 PBO:0094777 Fig. 4C
PMID:38133430 PBO:0094777 Fig. 4C
PMID:38133430 PBO:0094738 Fig. 4C
PMID:38133430 PBO:0094738 Fig. 4C
PMID:38133430 PBO:0094738 Fig. 4C
PMID:38133430 PBO:0094738 Fig. 4C, Fig. S3B
PMID:38133430 FYPO:0001357 Fig. 4A
PMID:38133430 FYPO:0000080 Fig. 4A
PMID:38133430 PBO:0110726 Fig. 3B
PMID:38133430 PBO:0108863 Fig. 3B
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PMID:38133430 PBO:0110725 Fig. 3B
PMID:38133430 FYPO:0001355 Fig. 2, Fig. 4A, Fig. S3A
PMID:38133430 FYPO:0001355 Fig. 2, Fig. 4A, Fig. S3A
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PMID:38133430 FYPO:0001357 Fig. 2, Fig. 4A, Fig. S3A
PMID:38133430 PBO:0110726 Fig. 3B
PMID:38133430 FYPO:0001357 Fig. 2, Fig. 4A, Fig. S3A
PMID:38133430 PBO:0108863 Fig. 3B
PMID:38133430 PBO:0096777 Fig. 3B
PMID:38133430 FYPO:0005369 Fig. 4A, Fig. S3A
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PMID:38133430 FYPO:0000082 Fig. 4A, Fig. S3A
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PMID:38133430 PBO:0110727 Fig. 8B
PMID:38133430 FYPO:0000082 Fig. S3A
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PMID:38133430 FYPO:0001355 Fig. S3A
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PMID:38133430 FYPO:0001357 Fig. 9
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PMID:38133430 FYPO:0001355 Fig. 9
PMID:38133430 PBO:0110729 Fig. 8B
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PMID:38133430 FYPO:0001357 Fig. S5
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PMID:38166399 FYPO:0000730 Importantly, the onset of anaphase was postponed until all the satellite kinetochores merged with the main cluster in the mutant (figure 2a,b).
PMID:38166399 PBO:0094567 s shown in figure 5, the wee1 mutants with no functional spindle check- point indeed failed in accurate chromosome segregation and generated two sister cells with unequal nuclear size.
PMID:38166399 PBO:0110823 s shown in figure 5, the wee1 mutants with no functional spindle check- point indeed failed in accurate chromosome segregation and generated two sister cells with unequal nuclear size.
PMID:38166399 PBO:0094567 s shown in figure 5, the wee1 mutants with no functional spindle check- point indeed failed in accurate chromosome segregation and generated two sister cells with unequal nuclear size.
PMID:38166399 PBO:0037150 s shown in figure 5, the wee1 mutants with no functional spindle check- point indeed failed in accurate chromosome segregation and generated two sister cells with unequal nuclear size.
PMID:38166399 FYPO:0002638 As mitosis progressed, it was faintly found on the entire length of the spindle and SPB in the wild-type cells (figure 3a). By contrast, Mad2 was found as one or two bright speckles in the vicinity of the spindle during mitosis in the wee1 mutant (figure 3b,c). Judged by the length of the spindle, anaphase was initiated soon after Mad2 speckles disappeared (figure 4a,b). In approximately 28% (28 cells out of 101 cells observed) of the wee1 mutants, the Mad2 speckle appeared at least once (figure 4c). The observation thus suggested that the spindle checkpoint was activated in the wee1 mutants.
PMID:38166399 PBO:0110822 Importantly, the onset of anaphase was postponed until all the satellite kinetochores merged with the main cluster in the mutant (figure 2a,b).
PMID:38166399 FYPO:0000324 Importantly, the onset of anaphase was postponed until all the satellite kinetochores merged with the main cluster in the mutant (figure 2a,b).
PMID:38166399 PBO:0110821 Time-lapse imaging analysis revealed abnormal positioning of kinetochores in the wee1 (wee1Δ) mutant. ThBecause the kinetochores, which are captured and bioriented, are clus- tered and found on the spindle, the satellite kinetochores remained unattached, or detached from the spindle during the progression to anaphase in the wee1 mutant (electronic supplementary material, figure S2).e cluster of kinetochores frequently fell apart into a main cluster and a small ‘satellite kinetochore’ during mitosis (figure 1b).
PMID:38166399 PBO:0093556 As shown in electronic supplementary material, figure S1B, introduction of deletion for mad2+ did not cause the lethality in the cdc2-1w and cdc2-3w mutants.
PMID:38166399 PBO:0093556 As shown in electronic supplementary material, figure S1B, introduction of deletion for mad2+ did not cause the lethality in the cdc2-1w and cdc2-3w mutants.
PMID:38166399 FYPO:0002061 As shown in electronic supplementary material, figure S1A, we found that a wee1-50 mad2Δ double mutant is lethal at 36°C.
PMID:38166399 FYPO:0002061 As shown in electronic supplementary material, figure S1A, we found that a wee1-50 mad2Δ double mutant is lethal at 36°C.
PMID:38181050 PBO:0112719 loss of most members of the COMPASS complex, including Set1, Spp1, Swd1, Swd3, Swd2, and Ash2 leads to a significantly decreased amount of Lsd1 protein (Fig 3A)
PMID:38181050 PBO:0112717 that without Clr4, both Lsd1-FTP and Lsd2-FTP show an increase in protein levels, compared to the wild-type cells (Fig 2I).
PMID:38181050 PBO:0112716 Loss of Ddb1 slightly enhances the Lsd1-FTP level, while having no significant effect on the Lsd2-FTP level (Fig 3E).
PMID:38181050 PBO:0112716 The western blot results suggest that the loss of any member of CLRC complex enhances the protein amount of Lsd1 (Fig 3C) or Lsd2 (Fig 3D).
PMID:38181050 PBO:0112716 The western blot results suggest that the loss of any member of CLRC complex enhances the protein amount of Lsd1 (Fig 3C) or Lsd2 (Fig 3D).
PMID:38181050 PBO:0112716 The western blot results suggest that the loss of any member of CLRC complex enhances the protein amount of Lsd1 (Fig 3C) or Lsd2 (Fig 3D).
PMID:38181050 PBO:0112715 Notably, the localizations of Lsd1 and Lsd2 are diminished at the pro- moter regions in the absence of a functional C-terminus (Fig 1C). This result demonstrates that the C-terminal domains of Lsd1 and Lsd2 are involved in their chromatin binding at these regions.
PMID:38181050 PBO:0112716 that without Clr4, both Lsd1-FTP and Lsd2-FTP show an increase in protein levels, compared to the wild-type cells (Fig 2I).
PMID:38181050 FYPO:0002061 lsd1-ΔHMG set1Δ and lsd2-ΔC clr4Δ double mutants resulted in inviable daughter cells, suggesting that Lsd1 has essential overlapping functions with Set1, while Lsd2 has critical overlapping roles with Clr4 (Fig 2A).
PMID:38181050 FYPO:0002061 lsd1-ΔHMG set1Δ and lsd2-ΔC clr4Δ double mutants resulted in inviable daughter cells, suggesting that Lsd1 has essential overlapping functions with Set1, while Lsd2 has critical overlapping roles with Clr4 (Fig 2A).
PMID:38181050 FYPO:0002061 lsd1-ΔHMG set1Δ and lsd2-ΔC clr4Δ double mutants resulted in inviable daughter cells, suggesting that Lsd1 has essential overlapping functions with Set1, while Lsd2 has critical overlapping roles with Clr4 (Fig 2A).
PMID:38181050 FYPO:0002061 lsd1-ΔHMG set1Δ and lsd2-ΔC clr4Δ double mutants resulted in inviable daughter cells, suggesting that Lsd1 has essential overlapping functions with Set1, while Lsd2 has critical overlapping roles with Clr4 (Fig 2A).
PMID:38181050 PBO:0093560 lsd1-ΔHMG clr4Δ cells are viable but sick, which implies a negative genetic interaction between Lsd1 and Clr4 (Figs 2A and S1B).
PMID:38181050 GO:0003713 The Lsd2-BD and Phf1-BD strains could self-activate the reporter genes without Gal4 activating domain, suggesting that Lsd2 and Phf1 alone could recruit basal transcriptional factors to initiate reporter gene transcription (S4 Fig).
PMID:38181050 GO:0003713 The Lsd2-BD and Phf1-BD strains could self-activate the reporter genes without Gal4 activating domain, suggesting that Lsd2 and Phf1 alone could recruit basal transcriptional factors to initiate reporter gene transcription (S4 Fig).
PMID:38181050 PBO:0112727 We also observed that the loss of the C-terminus of Lsd2 does not disrupt the interactions between Lsd2 and Phf1 (Fig 1F) or Phf2 (Fig 1G).
PMID:38181050 PBO:0112726 Additionally, we established that the loss of the HMG-domain of Lsd1 does not affect the interaction between Lsd1 and Phf1 (Fig 1D) or Phf2 (Fig 1E),
PMID:38181050 GO:1990841 Previous studies have shown that Lsd1/2 proteins bind to the promoters of a few hundred genes [70,73,74], suggesting that Lsd1/2 proteins are selectively recruited to those genes. Our ChIP-Seq analysis yields a highly similar set of genomic loci where Lsd1 and Lsd2 are enriched just upstream of the transcriptional start site (TSS) (Fig 1C). This result indicates that Lsd1 and Lsd2 mostly bind to the promoter region of genes and are likely to cooperate with other transcription factors that are involved in regulating gene expression.
PMID:38181050 GO:1990841 Previous studies have shown that Lsd1/2 proteins bind to the promoters of a few hundred genes [70,73,74], suggesting that Lsd1/2 proteins are selectively recruited to those genes. Our ChIP-Seq analysis yields a highly similar set of genomic loci where Lsd1 and Lsd2 are enriched just upstream of the transcriptional start site (TSS) (Fig 1C). This result indicates that Lsd1 and Lsd2 mostly bind to the promoter region of genes and are likely to cooperate with other transcription factors that are involved in regulating gene expression.
PMID:38181050 FYPO:0002061 Notably, deletion of the Lsd2 HMG-domain results in lethality akin to that in the complete loss of Lsd2, which further implies the unknown and important functions of the C-terminus of these two proteins
PMID:38181050 PBO:0112723 figure 6
PMID:38181050 PBO:0112725 At 37 ̊C, only marginal changes in Lsd1 protein levels were observed in H3K4R and H2B-K119R mutants (Fig 6D). However, a significant reduction of Lsd2 was seen in both H3K4R and H2B K119R mutants (Fig 6E),
PMID:38181050 PBO:0112740 Set1 signif- icantly at 37 ̊C compared to that at 30 ̊C, which is due to the temperature sensitive nature of cul4-1.
PMID:38181050 PBO:0112740 Protein levels of Lsd1 and Lsd2 are similar between wild-type and clr4Δ cells at 37 ̊C, indicating that Clr4 is not responsible for Lsd1/2 upregulation in this condition (Fig 4C and 4D)
PMID:38181050 PBO:0112738 Intriguingly, about 72% of downregulated genes in lsd1-ΔHMG, lsd2-ΔC, and set1Δ are antisense non-coding RNAs (S1 Table),
PMID:38181050 PBO:0112739 Intriguingly, about 72% of downregulated genes in lsd1-ΔHMG, lsd2-ΔC, and set1Δ are antisense non-coding RNAs (S1 Table),
PMID:38181050 PBO:0112738 Intriguingly, about 72% of downregulated genes in lsd1-ΔHMG, lsd2-ΔC, and set1Δ are antisense non-coding RNAs (S1 Table),
PMID:38181050 PBO:0112738 Intriguingly, about 72% of downregulated genes in lsd1-ΔHMG, lsd2-ΔC, and set1Δ are antisense non-coding RNAs (S1 Table),
PMID:38181050 PBO:0112737 Under heat stress (37 ̊C), it was consistently found that ubiquitination of Lsd1 and Lsd2 is drastically enhanced in set1Δ cells, even without mts2-1 as a background (Fig 4F)
PMID:38181050 PBO:0112736 Under heat stress (37 ̊C), it was consistently found that ubiquitination of Lsd1 and Lsd2 is drastically enhanced in set1Δ cells, even without mts2-1 as a background (Fig 4F)
PMID:38181050 PBO:0112735 In wild-type cells, we observed a significantly increased amount of Set1 at 37 ̊C (Fig 6A), indicating that Set1 is also stabilized during heat stress.
PMID:38181050 PBO:0112725 At 37 ̊C, only marginal changes in Lsd1 protein levels were observed in H3K4R and H2B-K119R mutants (Fig 6D). However, a significant reduction of Lsd2 was seen in both H3K4R and H2B K119R mutants (Fig 6E),
PMID:38181050 PBO:0112725 figure 6
PMID:38181050 PBO:0112725 figure 6
PMID:38181050 PBO:0112719 loss of most members of the COMPASS complex, including Set1, Spp1, Swd1, Swd3, Swd2, and Ash2 leads to a significantly decreased amount of Lsd1 protein (Fig 3A)
PMID:38181050 PBO:0112719 In contrast, the protein levels of Lsd1-FTP and Lsd2-FTP show a notable decrease in the absence of Set1 (Fig 2I).
PMID:38181050 PBO:0112718 The western blot results suggest that the loss of any member of CLRC complex enhances the protein amount of Lsd1 (Fig 3C) or Lsd2 (Fig 3D).
PMID:38181050 PBO:0112717 The western blot results suggest that the loss of any member of CLRC complex enhances the protein amount of Lsd1 (Fig 3C) or Lsd2 (Fig 3D).
PMID:38181050 PBO:0112717 The western blot results suggest that the loss of any member of CLRC complex enhances the protein amount of Lsd1 (Fig 3C) or Lsd2 (Fig 3D).
PMID:38181050 PBO:0112715 Notably, the localizations of Lsd1 and Lsd2 are diminished at the pro- moter regions in the absence of a functional C-terminus (Fig 1C). This result demonstrates that the C-terminal domains of Lsd1 and Lsd2 are involved in their chromatin binding at these regions.
PMID:38181050 PBO:0112714 We also observed that the loss of the C-terminus of Lsd2 does not disrupt the interactions between Lsd2 and Phf1 (Fig 1F) or Phf2 (Fig 1G).
PMID:38181050 PBO:0112713 Additionally, we established that the loss of the HMG-domain of Lsd1 does not affect the interaction between Lsd1 and Phf1 (Fig 1D) or Phf2 (Fig 1E),
PMID:38181050 PBO:0112719 loss of most members of the COMPASS complex, including Set1, Spp1, Swd1, Swd3, Swd2, and Ash2 leads to a significantly decreased amount of Lsd1 protein (Fig 3A)
PMID:38181050 PBO:0112719 loss of most members of the COMPASS complex, including Set1, Spp1, Swd1, Swd3, Swd2, and Ash2 leads to a significantly decreased amount of Lsd1 protein (Fig 3A)
PMID:38181050 PBO:0112719 loss of most members of the COMPASS complex, including Set1, Spp1, Swd1, Swd3, Swd2, and Ash2 leads to a significantly decreased amount of Lsd1 protein (Fig 3A)
PMID:38181050 PBO:0112720 In contrast, the protein levels of Lsd1-FTP and Lsd2-FTP show a notable decrease in the absence of Set1 (Fig 2I).
PMID:38181050 PBO:0112720 A similar pattern was observed in the Lsd2 samples, although the Lsd2 protein levels also decreased with shg1Δ (Fig 3B).
PMID:38181050 PBO:0112720 A similar pattern was observed in the Lsd2 samples, although the Lsd2 protein levels also decreased with shg1Δ (Fig 3B).
PMID:38181050 PBO:0093560 lsd1-ΔHMG clr4Δ cells are viable but sick, which implies a negative genetic interaction between Lsd1 and Clr4 (Figs 2A and S1B).
PMID:38181050 PBO:0098997 The triple mutants lsd1- ΔHMG set1Δ clr4Δ and lsd2-ΔC set1Δ clr4Δ are lethal (S1D Fig).
PMID:38181050 PBO:0098997 The triple mutants lsd1- ΔHMG set1Δ clr4Δ and lsd2-ΔC set1Δ clr4Δ are lethal (S1D Fig).
PMID:38181050 PBO:0112720 A similar pattern was observed in the Lsd2 samples, although the Lsd2 protein levels also decreased with shg1Δ (Fig 3B).
PMID:38181050 PBO:0112720 A similar pattern was observed in the Lsd2 samples, although the Lsd2 protein levels also decreased with shg1Δ (Fig 3B).
PMID:38181050 PBO:0112720 A similar pattern was observed in the Lsd2 samples, although the Lsd2 protein levels also decreased with shg1Δ (Fig 3B).
PMID:38181050 PBO:0112724 figure 6
PMID:38181050 PBO:0112724 figure 6
PMID:38181050 PBO:0112720 A similar pattern was observed in the Lsd2 samples, although the Lsd2 protein levels also decreased with shg1Δ (Fig 3B).
PMID:38181050 PBO:0112721 Lsd1 (Fig 4A) or Lsd2 (Fig 4B) was detected in the presence of a temperature-sensitive 26S pro- teasome subunit mutant, mts2-1, which inactivates the proteasome at 33 ̊C [111] and thereby stabilizes Lsd1 and Lsd2 (Fig 4A and 4B).
PMID:38181050 PBO:0112722 Lsd1 (Fig 4A) or Lsd2 (Fig 4B) was detected in the presence of a temperature-sensitive 26S pro- teasome subunit mutant, mts2-1, which inactivates the proteasome at 33 ̊C [111] and thereby stabilizes Lsd1 and Lsd2 (Fig 4A and 4B).
PMID:38181050 PBO:0112718 (Fig 5A)
PMID:38181050 PBO:0112718 We found that the loss of any members in CLRC promotes the protein levels of Set1, both at 30 ̊C or 37 ̊C (Fig 5A), indicating that the intact CLRC restricts the amount of Set1.
PMID:38181050 PBO:0112718 We found that the loss of any members in CLRC promotes the protein levels of Set1, both at 30 ̊C or 37 ̊C (Fig 5A), indicating that the intact CLRC restricts the amount of Set1.
PMID:38181050 PBO:0112718 We found that the loss of any members in CLRC promotes the protein levels of Set1, both at 30 ̊C or 37 ̊C (Fig 5A), indicating that the intact CLRC restricts the amount of Set1.
PMID:38181050 PBO:0112728 To our surprise, clr4Δ increases the enrichments of Lsd1/2 while set1Δ decreases the enrichments of Lsd1 at its enriched genomic loci (Figs 2G, 2H, S6 and S7).
PMID:38181050 PBO:0112729 To our surprise, clr4Δ increases the enrichments of Lsd1/2 while set1Δ decreases the enrichments of Lsd1 at its enriched genomic loci (Figs 2G, 2H, S6 and S7).
PMID:38181050 PBO:0112730 To our surprise, clr4Δ increases the enrichments of Lsd1/2 while set1Δ decreases the enrichments of Lsd1 at its enriched genomic loci (Figs 2G, 2H, S6 and S7).
PMID:38181050 PBO:0112731 However, the loss of Shg1 and Sdc1 seems to have little or no effect on Lsd1 protein levels.
PMID:38181050 PBO:0112732 However, the loss of Shg1 and Sdc1 seems to have little or no effect on Lsd1 protein levels.
PMID:38181050 PomGeneEx:0000018 Both Lsd1 (Fig 4C) and Lsd2 (Fig 4D) protein levels drastically increase after heat treatment, although the mRNA levels of Lsd1 and Lsd2 were not significantly altered between wild-type and set1Δ cells (S10 Fig), suggesting that enhanced Lsd1/2 proteins are required for cell survival under heat stress [61].
PMID:38181050 PomGeneEx:0000018 Both Lsd1 (Fig 4C) and Lsd2 (Fig 4D) protein levels drastically increase after heat treatment, although the mRNA levels of Lsd1 and Lsd2 were not significantly altered between wild-type and set1Δ cells (S10 Fig), suggesting that enhanced Lsd1/2 proteins are required for cell survival under heat stress [61].
PMID:38181050 PBO:0112733 Protein levels of Lsd1 and Lsd2 are similar between wild-type and clr4Δ cells at 37 ̊C, indicating that Clr4 is not responsible for Lsd1/2 upregulation in this condition (Fig 4C and 4D)
PMID:38181050 PBO:0112734 Protein levels of Lsd1 and Lsd2 are similar between wild-type and clr4Δ cells at 37 ̊C, indicating that Clr4 is not responsible for Lsd1/2 upregulation in this condition (Fig 4C and 4D)
PMID:38181050 PBO:0112725 However, without Set1, Lsd1/2 protein levels are no longer upregulated during heat stress (Fig 4C and 4D), which implies that Set1 is required to elevate the protein levels of Lsd1 and Lsd2 under heat stress.
PMID:38181050 PBO:0112718 Both cul4-1 or ddb1Δ enhanced the amount of Set1 protein, indicating that both CLRC and CRL4 complexes modulate Set1 levels (Fig 5C)
PMID:38181050 PBO:0112723 Although no significant alterations were detected for Flag-Set1 protein levels between wild-type and clr4W31G cells at 30 ̊C, the elevated Flag-Set1 is less pronounced in clr4W31G compared to clr4Δ at 37 ̊C (Fig 5B),
PMID:38181050 PBO:0112724 However, without Set1, Lsd1/2 protein levels are no longer upregulated during heat stress (Fig 4C and 4D), which implies that Set1 is required to elevate the protein levels of Lsd1 and Lsd2 under heat stress.
PMID:38181050 PBO:0112723 figure 6
PMID:38269097 PBO:0112487 Table S3
PMID:38269097 FYPO:0000674 Figure 2
PMID:38269097 PBO:0093556 Figure 2
PMID:38269097 PBO:0093556 Figure 2
PMID:38269097 FYPO:0000674 Figure 2
PMID:38269097 FYPO:0002672 Figure 1
PMID:38269097 PBO:0093558 We serendipitously discovered that fission yeast cells exhibit significant proliferation even at 38°C and 39°C, but not at 40°C, on agar medium supplemented with rapamycin, a TORC1-specific inhibitor [...] the fkh1 null mutant failed to grow at 39°C even in the presence of rapamycin. Figure 1
PMID:38269097 PBO:0112336 Figure 1
PMID:38269097 PBO:0112338 Figure 1
PMID:38269097 PBO:0112337 Figure 1
PMID:38269097 PBO:0112336 Figure 2 and 3
PMID:38269097 PBO:0112337 Figure 3
PMID:38269097 PBO:0112336 Figure 3
PMID:38269097 PBO:0112337 Figure 3
PMID:38269097 FYPO:0000674 Figure 2 and 3
PMID:38269097 PBO:0112336 Figure 2
PMID:38269097 PBO:0092185 Figure 2
PMID:38269097 PBO:0112338 Figure 3
PMID:38269097 PBO:0093561 Figure 3
PMID:38269097 PBO:0112336 Figure 4
PMID:38269097 PBO:0112337 Figure 4
PMID:38269097 PBO:0112486 Figure 5
PMID:38269097 PBO:0092105 Figure 5
PMID:38269097 PBO:0112339 Figure 5
PMID:38269097 PBO:0112336 Figure 6
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PMID:38269097 PBO:0112338 Figure 6
PMID:38269097 PBO:0112336 Figure 6
PMID:38269097 PBO:0112336 Figure 6
PMID:38269097 FYPO:0001357 Figure 2 and 3
PMID:38269097 FYPO:0002141 Figure S3
PMID:38269097 FYPO:0001357 Figure 3
PMID:38269097 FYPO:0001357 Figure 2
PMID:38269097 FYPO:0001357 Figure 2
PMID:38269097 FYPO:0001357 Figure 2
PMID:38269097 FYPO:0001357 Figure 2
PMID:38269097 PBO:0093559 Figure 4
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PMID:38269097 PBO:0093556 Figure 4
PMID:38269097 FYPO:0001357 Figure 4
PMID:38269097 FYPO:0001357 Figure 4
PMID:38269097 FYPO:0000674 Figure 4
PMID:38269097 FYPO:0000674 Figure 4
PMID:38269097 MOD:00696 Figure S3
PMID:38269097 FYPO:0002141 Figure S3
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PMID:38269097 FYPO:0002141 Figure S3
PMID:38269097 PBO:0112336 Figure 6
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PMID:38269097 PBO:0112336 Figure 6
PMID:38269097 PBO:0092185 Figure S2
PMID:38269097 PBO:0112340 Fig. S7
PMID:38269097 PBO:0112340 Fig. 6A
PMID:38269097 PBO:0112341 Fig. 6A
PMID:38269097 PBO:0112340 Fig. 6A
PMID:38269097 PBO:0112340 Fig. 6A
PMID:38269097 PBO:0112340 Fig. 6A
PMID:38269097 PBO:0112340 Fig. S7
PMID:38269097 PBO:0112340 Fig. S7
PMID:38269097 PBO:0112340 Fig. S7
PMID:38269097 PBO:0112340 Fig. S7
PMID:38269097 PBO:0112340 Fig. S7
PMID:38269097 PBO:0112340 Fig. S7
PMID:38269097 PBO:0112340 Fig. S7
PMID:38269097 PBO:0112340 Fig. S7
PMID:38269097 PBO:0112340 Fig. S7
PMID:38269097 PBO:0112340 Fig. S7
PMID:38269097 PBO:0112342 Fig. 6A
PMID:38269097 PBO:0112343 Figure 5
PMID:38269097 PBO:0112344 Figure 5
PMID:38269097 PBO:0112345 Figure S3
PMID:38269097 PBO:0112345 Figure S3
PMID:38269097 PBO:0112346 Figure S6
PMID:38269097 PBO:0112346 Figure S6
PMID:38269097 PBO:0112337 Figure 3
PMID:38269097 PBO:0112336 Figure S4
PMID:38269097 PBO:0112336 Figure S4
PMID:38269097 PBO:0112336 Figure S4
PMID:38269097 PBO:0112336 Figure S4
PMID:38269097 PBO:0112336 Figure 3
PMID:38269097 PBO:0112347 Table S4
PMID:38269097 PBO:0112348 Table S4
PMID:38269097 PBO:0112349 Table S4
PMID:38269097 PBO:0112350 Table S4
PMID:38269097 PBO:0112351 Table S2
PMID:38269097 PBO:0112352 Table S2
PMID:38269097 PBO:0112353 Tabls S2
PMID:38269097 PBO:0112354 Table S2
PMID:38269097 PBO:0112355 Table S2
PMID:38269097 PBO:0112356 Table S2
PMID:38269097 PBO:0112357 Table S2
PMID:38269097 PBO:0112358 Table S2
PMID:38269097 PBO:0112359 Table S2
PMID:38269097 PBO:0112360 Table S2
PMID:38269097 PBO:0112361 Table S2
PMID:38269097 PBO:0112362 Table S2
PMID:38269097 PBO:0112363 Table S2
PMID:38269097 PBO:0112364 Table S2
PMID:38269097 PBO:0112365 Table S2
PMID:38269097 PBO:0112366 Table S2
PMID:38269097 PBO:0112367 Table S2
PMID:38269097 PBO:0112368 Table S2
PMID:38269097 PBO:0112369 Table S2
PMID:38269097 PBO:0112370 Table S2
PMID:38269097 PBO:0112371 Table S2
PMID:38269097 PBO:0112372 Table S2
PMID:38269097 PBO:0112373 Table S2
PMID:38269097 PBO:0112374 Table S2
PMID:38269097 PBO:0112375 Table S2
PMID:38269097 PBO:0112376 Table S2
PMID:38269097 PBO:0112377 Table S2
PMID:38269097 PBO:0112378 Table S2
PMID:38269097 PBO:0112379 Table S2
PMID:38269097 PBO:0112380 Table S2
PMID:38269097 PBO:0112381 Table S2
PMID:38269097 PBO:0112382 Table S2
PMID:38269097 PBO:0112383 Table S2
PMID:38269097 PBO:0112384 Table S2
PMID:38269097 PBO:0112385 Table S2
PMID:38269097 PBO:0112386 Table S2
PMID:38269097 PBO:0112387 Table S2
PMID:38269097 PBO:0112388 Table S2
PMID:38269097 PBO:0112389 Table S2
PMID:38269097 PBO:0112390 Table S2
PMID:38269097 PBO:0112391 Table S2
PMID:38269097 PBO:0112392 Table S2
PMID:38269097 PBO:0112393 Fig. 2C
PMID:38269097 PBO:0093556 Figure 2
PMID:38269097 FYPO:0001357 Figure 1
PMID:38269097 PBO:0112393 Fig. 2C
PMID:38269097 FYPO:0001357 Figure 1
PMID:38269097 FYPO:0001357 Figure 1
PMID:38269097 FYPO:0001357 Figure 1
PMID:38269097 PBO:0093561 Figure 3
PMID:38269097 PBO:0112394 Fig. 4C
PMID:38269097 PBO:0112487 Table S3
PMID:38269097 PBO:0112487 Table S3
PMID:38269097 PBO:0112487 Table S3
PMID:38269097 PBO:0112487 Table S3
PMID:38269097 PBO:0112487 Table S3
PMID:38269097 PBO:0112487 Table S3
PMID:38269097 PBO:0112487 Table S3
PMID:38269097 PBO:0112487 Table S3
PMID:38269097 PBO:0112487 Table S3
PMID:38269097 PBO:0112487 Table S3
PMID:38269097 PBO:0112487 Table S3
PMID:38269097 PBO:0112487 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
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PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
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PMID:38269097 PBO:0112488 Table S3
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PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 PBO:0112488 Table S3
PMID:38269097 FYPO:0000674 Figure 1
PMID:38269097 FYPO:0001357 Figure 2 and 3
PMID:38269097 FYPO:0000674 Figure 2
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PMID:38269097 FYPO:0001357 Fig. 6B
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PMID:38269097 FYPO:0002141 Figure S3
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PMID:38269097 FYPO:0001357 Figure S4
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PMID:38269097 FYPO:0001357 Figure S4
PMID:38285941 FYPO:0002827 The other two mutants showed defective silencing of the mat2P::ura4+ reporter and haploid meiosis (Fig. 4C), as well as detectable levels of the mat2P transcript (Fig. 4D).
PMID:38285941 PBO:0112223 , mcm2-1 and mcl1-4 cells failed to maintain heterochromatin, as indicated by white colony color and loss of the H3K9me3 mark (SI Appendix, Fig. S7). Thus, both Mcl1 and Mcm2 are required for propagation of heterochromatin at an ectopic site.
PMID:38285941 FYPO:0002827 The other two mutants showed defective silencing of the mat2P::ura4+ reporter and haploid meiosis (Fig. 4C), as well as detectable levels of the mat2P transcript (Fig. 4D).
PMID:38285941 PBO:0112223 , mcm2-1 and mcl1-4 cells failed to maintain heterochromatin, as indicated by white colony color and loss of the H3K9me3 mark (SI Appendix, Fig. S7). Thus, both Mcl1 and Mcm2 are required for propagation of heterochromatin at an ectopic site.
PMID:38285941 FYPO:0003247 (Fig. 4 E and F).
PMID:38285941 FYPO:0008187 (Fig. 4 E and F).
PMID:38285941 PBO:0111391 (Fig. 4 E and F).
PMID:38285941 FYPO:0007159 (Fig. 4 E and F).
PMID:38285941 PBO:0095652 Fig. S1. Genetic screen for mutants defective in heterochromatin propagation.
PMID:38285941 PBO:0095653 Fig. S1. Genetic screen for mutants defective in heterochromatin propagation.
PMID:38285941 PBO:0095651 Fig. S1. Genetic screen for mutants defective in heterochromatin propagation.
PMID:38285941 PBO:0095651 Fig. S1. Genetic screen for mutants defective in heterochromatin propagation.
PMID:38285941 PBO:0095653 Fig. S1. Genetic screen for mutants defective in heterochromatin propagation.
PMID:38285941 PBO:0095651 Fig. S1. Genetic screen for mutants defective in heterochromatin propagation.
PMID:38285941 PBO:0112227 Mcl1 localized to heterochromatic loci in S phase, like Mcm2 (Fig. 2B).
PMID:38285941 PBO:0112227 Mcl1 localized to heterochromatic loci in S phase, like Mcm2 (Fig. 2B).
PMID:38285941 FYPO:0003246 (Fig. 2 D and E and SI Appendix, Figs. S2 A–D and S3). Mcm2 mapping was performed 60 min after release from the cdc25-22 block. A similar septation index for WT and swi6Δ cells indicated normal progression of swi6Δ cells through S phase (SI Appendix, Fig. S2B).
PMID:38285941 FYPO:0000217 Compared to WT, swi6Δ cells showed a considerable decrease in BrdU incorporation across mat, which persisted through the time course (Fig. 2D and SI Appendix, Fig. S3). Mcm2 was still detected, although with more defined peaks, likely reflecting licensed, but not activated, replication ori gins across the domain (Fig. 2D)
PMID:38285941 FYPO:0000088 The mcm2-6 mutant showed sensitivity to hydroxyurea (HU) (SI Appendix, Fig. S5C), indicating defective replication, and was not further analyzed.
PMID:38285941 PBO:0112228 Notably, the addition of the WT Mcm2 HBD during the purification of the H3 and H4 histones promoted their solubili zation, highlighting its role as a histone chaperone (SI Appendix, Fig. S5D).
PMID:38285941 PBO:0112226 Thus, although both mutants affect the retention of parental histones, Mcl1 plays a more critical role in the process.
PMID:38285941 PBO:0112229 FACT associates with subunits of MCM (Mcm2) and GINS (Psf3) when Mcl1 is present, but these interactions are lost in cells lacking Mcl1 (Fig. 6A),
PMID:38285941 PBO:0112230 FACT associates with subunits of MCM (Mcm2) and GINS (Psf3) when Mcl1 is present, but these interactions are lost in cells lacking Mcl1 (Fig. 6A),
PMID:38285941 PBO:0095653 Fig. S1. Genetic screen for mutants defective in heterochromatin propagation.
PMID:38289024 FYPO:0002336 demonstrating that tethering Swi6HP1 to the mat locus was sufficient to rescue heat stress-induced defective epigenetic mainte- nance of heterochromatin.
PMID:38289024 FYPO:0002827 Figure 5B; Notably, cells expressing two copies, but not one copy, of wis1-DD showed severe gene silencing defects (Figure 5B and Figure 5—figure supplement 1B), and consistently the mRNA levels of the kΔ::ade6+ increased dramatically in these cells (Figure 5C and Figure 5—figure supplement 1C).
PMID:38289024 FYPO:0004376 Figure 6B; endogenous atf1+ was deleted
PMID:38289024 FYPO:0002336 Figure 8A
PMID:38289024 FYPO:0002336 Figure 6B; endogenous atf1+ was deleted
PMID:38289024 FYPO:0002336 Figure 6B; endogenous atf1+ was deleted
PMID:38289024 FYPO:0002336 Figure 6B; endogenous atf1+ was deleted
PMID:38289024 FYPO:0002336 Figure 6B; endogenous atf1 was deleted
PMID:38289024 PBO:0093558 Figure 6B, Figure 3-S1; endogenous atf1+ was deleted
PMID:38289024 PBO:0095652 Figure 3-S2A B More strikingly, Patf1-atf1(10D/E) also visibly compromised epigenetic silencing even at 30°C (Figure 3—figure supplement 2A, B).
PMID:38289024 FYPO:0002827 cells at 37°C restored gene silencing rapidly at normal temperature 30°C after being re-plated on medium containing limited adenine (Figure 2A and B). However, when this re-plating assay was applied to dcr1Δ, one of the RNAi mutants, a considerable proportion of cells still emerged as variegated colonies (designated as dcr1ΔV), which was in sharp contrast to wild type cells (Figure 2B).
PMID:38289024 PBO:0112213 Binding affinity between Atf1 and Swi6HP1 is maintained for non- phosphorylatable Atf1(10A/I) at 37°C, but disrupted for phosphomimetic Atf1(10D/E) even at 30°C.
PMID:38289024 PBO:0112214 Binding affinity between Atf1 and Swi6HP1 is maintained for non- phosphorylatable Atf1(10A/I) at 37°C, but disrupted for phosphomimetic Atf1(10D/E) even at 30°C.
PMID:38289024 PBO:0112214 Furthermore, in vitro pull-down assays demonstrated that the interaction between Atf1 and Swi6HP1 was also largely disrupted in wis1-DD mutants (Figure 5E and Figure 5—figure supplement 1E).
PMID:38289024 PBO:0111016 Consistently, ChIP- qPCR analyses showed that the abundance of both H3K9me3 and Swi6HP1 bound at the mat locus but not at pericentromere decreased dramatically in cells with two copies of wis1-DD (Figure 5F and Figure 5—figure supplement 1F).
PMID:38289024 PBO:0112215 Consistently, ChIP- qPCR analyses showed that the abundance of both H3K9me3 and Swi6HP1 bound at the mat locus but not at pericentromere decreased dramatically in cells with two copies of wis1-DD (Figure 5F and Figure 5—figure supplement 1F).
PMID:38289024 FYPO:0002336 Intriguingly, removal of Sty1 kinase activity by introducing either sty1 deletion mutant (sty1Δ) or ATP analogue-sensitive mutant of sty1 (sty1-T97A, i.e. sty1-as2) (Zuin et al., 2010) into wis1-DD mutant background could relieve the negative effect of constitutive activation of MAPK Sty1 on kΔ::ade6+ reporter gene silencing, binding affinity between Atf1 and Swi6HP1 and heterochromatin stability at the mat locus (Figure 5 and Figure 5—figure supplement 2).
PMID:38289024 PBO:0112216 Intriguingly, removal of Sty1 kinase activity by introducing either sty1 deletion mutant (sty1Δ) or ATP analogue-sensitive mutant of sty1 (sty1-T97A, i.e. sty1-as2) (Zuin et al., 2010) into wis1-DD mutant background could relieve the negative effect of constitutive activation of MAPK Sty1 on kΔ::ade6+ reporter gene silencing, binding affinity between Atf1 and Swi6HP1 and heterochromatin stability at the mat locus (Figure 5 and Figure 5—figure supplement 2).
PMID:38289024 FYPO:0002336 Intriguingly, removal of Sty1 kinase activity by introducing either sty1 deletion mutant (sty1Δ) or ATP analogue-sensitive mutant of sty1 (sty1-T97A, i.e. sty1-as2) (Zuin et al., 2010) into wis1-DD mutant background could relieve the negative effect of constitutive activation of MAPK Sty1 on kΔ::ade6+ reporter gene silencing, binding affinity between Atf1 and Swi6HP1 and heterochromatin stability at the mat locus (Figure 5 and Figure 5—figure supplement 2).
PMID:38289024 FYPO:0002336 Intriguingly, removal of Sty1 kinase activity by introducing either sty1 deletion mutant (sty1Δ) or ATP analogue-sensitive mutant of sty1 (sty1-T97A, i.e. sty1-as2) (Zuin et al., 2010) into wis1-DD mutant background could relieve the negative effect of constitutive activation of MAPK Sty1 on kΔ::ade6+ reporter gene silencing, binding affinity between Atf1 and Swi6HP1 and heterochromatin stability at the mat locus (Figure 5 and Figure 5—figure supplement 2).
PMID:38289024 PBO:0112216 Intriguingly, removal of Sty1 kinase activity by introducing either sty1 deletion mutant (sty1Δ) or ATP analogue-sensitive mutant of sty1 (sty1-T97A, i.e. sty1-as2) (Zuin et al., 2010) into wis1-DD mutant background could relieve the negative effect of constitutive activation of MAPK Sty1 on kΔ::ade6+ reporter gene silencing, binding affinity between Atf1 and Swi6HP1 and heterochromatin stability at the mat locus (Figure 5 and Figure 5—figure supplement 2).
PMID:38289024 PBO:0112216 Intriguingly, removal of Sty1 kinase activity by introducing either sty1 deletion mutant (sty1Δ) or ATP analogue-sensitive mutant of sty1 (sty1-T97A, i.e. sty1-as2) (Zuin et al., 2010) into wis1-DD mutant background could relieve the negative effect of constitutive activation of MAPK Sty1 on kΔ::ade6+ reporter gene silencing, binding affinity between Atf1 and Swi6HP1 and heterochromatin stability at the mat locus (Figure 5 and Figure 5—figure supplement 2).
PMID:38289024 PBO:0112216 Intriguingly, removal of Sty1 kinase activity by introducing either sty1 deletion mutant (sty1Δ) or ATP analogue-sensitive mutant of sty1 (sty1-T97A, i.e. sty1-as2) (Zuin et al., 2010) into wis1-DD mutant background could relieve the negative effect of constitutive activation of MAPK Sty1 on kΔ::ade6+ reporter gene silencing, binding affinity between Atf1 and Swi6HP1 and heterochromatin stability at the mat locus (Figure 5 and Figure 5—figure supplement 2).
PMID:38289024 FYPO:0002336 indicating full rescue of silencing defects at the mat locus under heat stress.
PMID:38289024 FYPO:0002336 Figure 3- S2A B
PMID:38289024 FYPO:0002336 Figure 3D; endogenous atf1+ was deleted
PMID:38359013 FYPO:0002061 erratum corrected previous annotation
PMID:38360270 PBO:0112127 Fig. 4
PMID:38360270 PBO:0112126 Fig. 4
PMID:38360270 PBO:0112126 Fig. 4
PMID:38360270 PBO:0112203 Fig. 4
PMID:38360270 PBO:0112202 Fig. 4
PMID:38360270 FYPO:0001457 Fig. 5Cells defective in UPR are sensitive to tunicamycin (32). Consistently, ire1Δ cells failed to grow on EMM plates containing tunicamycin (Fig. 2B)
PMID:38360270 PBO:0112129 Fig. 4
PMID:38360270 PBO:0112129 Fig. 4
PMID:38360270 PBO:0112128 Fig. 4
PMID:38360270 PBO:0112131 Fig. 4
PMID:38360270 PBO:0112132 Fig. 4
PMID:38360270 PBO:0112132 Fig. 4
PMID:38360270 PBO:0112133 Fig. 4
PMID:38360270 PBO:0112133 Fig. 4
PMID:38360270 FYPO:0003118 Fig. 3
PMID:38360270 PBO:0112204 Fig. 4
PMID:38360270 PBO:0112205 Fig. 4
PMID:38360270 PBO:0112201 Fig. 4
PMID:38360270 PBO:0112200 Fig. 4
PMID:38360270 PBO:0112125 Fig. 4
PMID:38360270 PBO:0112199 Fig. 4
PMID:38360270 PBO:0112198 Fig. 4
PMID:38360270 PBO:0112124 Fig. 4
PMID:38360270 FYPO:0003118 Fig. 3
PMID:38360270 PBO:0112117 Fig. 1 Intriguingly, we observed that the absence of erd2 caused mitochondrial fragmentation (Fig. 1, A and B)
PMID:38360270 FYPO:0004166 Fig. 1C Moreover, the oxygen consumption rate of erd2Δ cells was higher than that of WT cells (Figs. 1C and S1A), suggesting that mitochondrial respi- ration was increased in erd2Δ cells.
PMID:38360270 FYPO:0003004 Fig. 1 As shown in Figure 1, D and E, mitochondrial ROS was higher in erd2Δ cells than in WT cells.
PMID:38360270 PBO:0112118 Fig. 2A
PMID:38360270 PBO:0112119 Fig. 2A
PMID:38360270 PBO:0112119 Fig. 2A
PMID:38360270 PBO:0112120 Fig. 2A
PMID:38360270 PBO:0112121 Fig. 2A
PMID:38360270 PBO:0112121 Fig. 2A
PMID:38360270 PBO:0093559 Fig. 2B Under unstressed conditions, that is, when cells were grown on EMM plates, ire1Δ and erd2Δ had no noticeable effect on cell growth, but ire1Δerd2Δ impaired cell growth (Fig. 2B).
PMID:38360270 PBO:0093561 Fig. 2B
PMID:38360270 PBO:0093560 Fig. 2B
PMID:38360270 PBO:0112122 Fig. 2B
PMID:38360270 FYPO:0003896 Fig. 3 mitochondria were fragmented in erd2Δ cells but not in WT, ire1Δ, or erd2Δire1Δ cells
PMID:38360270 FYPO:0003896 Fig. 3 mitochondria were fragmented in erd2Δ cells but not in WT, ire1Δ, or erd2Δire1Δ cells
PMID:38360270 PBO:0112123 DID WE NEED TO CHANGE THIS TO LOW. Fig. 3 The results showed that the oxygen consumption rate of erd2Δ cells, but not ire1Δ or erd2Δire1Δ cells, was increased.
PMID:38360270 PBO:0112206 Fig. 4
PMID:38360270 PBO:0112207 Fig. 4
PMID:38360270 PBO:0112126 Fig. 4
PMID:38360270 PBO:0112127 Fig. 4
PMID:38360270 PBO:0112128 Fig. 4
PMID:38360270 PBO:0112129 Fig. 4
PMID:38360270 PBO:0112134 Fig. 5
PMID:38360270 PBO:0112123 DID WE NEED TO CHANGE THIS TO LOW. Fig. 3 The results showed that the oxygen consumption rate of erd2Δ cells, but not ire1Δ or erd2Δire1Δ cells, was increased.
PMID:38360270 PBO:0112208 Fig. 5
PMID:38360270 PBO:0112127 Fig. 4
PMID:38360270 FYPO:0001457 Paradoxically, erd2Δ cells, in which UPR was activated (Fig. 2A), also grew poorly on EMM plates con- taining tunicamycin.
PMID:38360270 PBO:0112131 Fig. 4
PMID:38360270 PBO:0112130 Fig. 4
PMID:38360270 PBO:0112130 Fig. 4
PMID:38360270 PBO:0112128 Fig. 4
PMID:38399762 FYPO:0000387 The extent of biofilm formed in SPBPJ4664.02∆ decreased by 40% as compared to WT (p < 0.05), indicating that SPBPJ4664.02 is required for biofilm formation.
PMID:38448160 PBO:0112146 Fig. 3D
PMID:38448160 PBO:0095113 Furthermore, we examined the in vitro phosphorylation by Plo1 using recombinant Mis4 protein and found that the N terminus of Mis4 is preferentially phosphorylated by Plo1 (Fig S2A–C).
PMID:38448160 FYPO:0003176 Fig. 2B
PMID:38448160 PBO:0095113 We examined if Psm3 is phosphorylated by Plo1 in vitro and found phosphorylation of T182 in the N terminus and S1001 in the C terminus (Fig. S3)
PMID:38448160 PBO:0112245 Figure 2D
PMID:38448160 FYPO:0003176 Fig. 4D
PMID:38448160 PBO:0095113 We identified 11 polo-kinase consensus N/Q/E/D-X-S/T sites and four non-consensus S/T in this domain, which were phosphorylated by Plo1 in vitro and some of them were detected also in vivo (Fig S1A–C).
PMID:38448160 PBO:0095113 We identified 11 polo-kinase consensus N/Q/E/D-X-S/T sites and four non-consensus S/T in this domain, which were phosphorylated by Plo1 in vitro and some of them were detected also in vivo (Fig S1A–C).
PMID:38448160 PBO:0095113 We identified 11 polo-kinase consensus N/Q/E/D-X-S/T sites and four non-consensus S/T in this domain, which were phosphorylated by Plo1 in vitro and some of them were detected also in vivo (Fig S1A–C).
PMID:38448160 PBO:0095113 We identified 11 polo-kinase consensus N/Q/E/D-X-S/T sites and four non-consensus S/T in this domain, which were phosphorylated by Plo1 in vitro and some of them were detected also in vivo (Fig S1A–C).
PMID:38448160 PBO:0095113 We identified 11 polo-kinase consensus N/Q/E/D-X-S/T sites and four non-consensus S/T in this domain, which were phosphorylated by Plo1 in vitro and some of them were detected also in vivo (Fig S1A–C).
PMID:38448160 PBO:0095113 We identified 11 polo-kinase consensus N/Q/E/D-X-S/T sites and four non-consensus S/T in this domain, which were phosphorylated by Plo1 in vitro and some of them were detected also in vivo (Fig S1A–C).
PMID:38448160 PBO:0095113 We identified 11 polo-kinase consensus N/Q/E/D-X-S/T sites and four non-consensus S/T in this domain, which were phosphorylated by Plo1 in vitro and some of them were detected also in vivo (Fig S1A–C).
PMID:38448160 PBO:0095113 We identified 11 polo-kinase consensus N/Q/E/D-X-S/T sites and four non-consensus S/T in this domain, which were phosphorylated by Plo1 in vitro and some of them were detected also in vivo (Fig S1A–C).
PMID:38448160 PBO:0095113 We identified 11 polo-kinase consensus N/Q/E/D-X-S/T sites and four non-consensus S/T in this domain, which were phosphorylated by Plo1 in vitro and some of them were detected also in vivo (Fig S1A–C).
PMID:38448160 PBO:0095113 We identified 11 polo-kinase consensus N/Q/E/D-X-S/T sites and four non-consensus S/T in this domain, which were phosphorylated by Plo1 in vitro and some of them were detected also in vivo (Fig S1A–C).
PMID:38448160 PBO:0095113 We identified 11 polo-kinase consensus N/Q/E/D-X-S/T sites and four non-consensus S/T in this domain, which were phosphorylated by Plo1 in vitro and some of them were detected also in vivo (Fig S1A–C).
PMID:38448160 PBO:0095113 We identified 11 polo-kinase consensus N/Q/E/D-X-S/T sites and four non-consensus S/T in this domain, which were phosphorylated by Plo1 in vitro and some of them were detected also in vivo (Fig S1A–C).
PMID:38448160 PBO:0112136 Fig. 3C
PMID:38448160 PBO:0112137 Figure 3D
PMID:38448160 PBO:0112138 Figure 4B
PMID:38448160 PBO:0112138 Figure 4B
PMID:38448160 PBO:0112138 Figure 4E
PMID:38448160 PBO:0095113 We identified 11 polo-kinase consensus N/Q/E/D-X-S/T sites and four non-consensus S/T in this domain, which were phosphorylated by Plo1 in vitro and some of them were detected also in vivo (Fig S1A–C).
PMID:38448160 PBO:0112141 Fig. 1B
PMID:38448160 PBO:0095113 We examined if Psm3 is phosphorylated by Plo1 in vitro and found phosphorylation of T182 in the N terminus and S1001 in the C terminus (Fig. S3)
PMID:38448160 GO:0031619 In moa1Δ cells, a mi- nority population (11%) of cells underwent equational segregation at meiosis I (because of defects in mono-orientation), whereas the majority underwent reductional segregation due to the presence of chiasmata and tension exerted across homologs, as reported previously (Miyazaki et al, 2017) (Fig 2B)
PMID:38448160 PBO:0095113 We identified 11 polo-kinase consensus N/Q/E/D-X-S/T sites and four non-consensus S/T in this domain, which were phosphorylated by Plo1 in vitro and some of them were detected also in vivo (Fig S1A–C).
PMID:38448160 PBO:0112154 Fig. 1B In moa1Δ cells, Rec8 cohesin localization increases at the core centromere although sister chromatid cohesion is abol- ished at this sit
PMID:38448160 PBO:0095113 Furthermore, we examined the in vitro phosphorylation by Plo1 using recombinant Mis4 protein and found that the N terminus of Mis4 is preferentially phosphorylated by Plo1 (Fig S2A–C).
PMID:38448160 PBO:0109676 Figure 4E
PMID:38448160 PBO:0112247 Figure 4E
PMID:38448160 PBO:0112137 Figure 4E
PMID:38448160 PBO:0112153 segregation defects in psm3-3A in achiasmatic meiosis I suppressed by wpl1 deletion. Figure 4E
PMID:38448160 FYPO:0003176 Fig. 4D
PMID:38448160 FYPO:0003176 Fig. 3D
PMID:38448160 PBO:0112151 Fig. 3F
PMID:38448160 PBO:0112150 Fig. 3E
PMID:38448160 PBO:0112149 Fig. 3E
PMID:38448160 PBO:0112510 Unequal sister chromatid segregation in meiosis II after reductional segregation in meiosis I. Fig. 3D
PMID:38448160 PBO:0109783 Figure 3D
PMID:38448160 PBO:0112510 Unequal sister chromatid segregation in meiosis II after reductional segregation in meiosis I. Fig. 3D
PMID:38448160 PBO:0095113 We examined if Psm3 is phosphorylated by Plo1 in vitro and found phosphorylation of T182 in the N terminus and S1001 in the C terminus (Fig. S3)
PMID:38448160 PBO:0095113 Furthermore, we examined the in vitro phosphorylation by Plo1 using recombinant Mis4 protein and found that the N terminus of Mis4 is preferentially phosphorylated by Plo1 (Fig S2A–C).
PMID:38448160 PBO:0095113 Furthermore, we examined the in vitro phosphorylation by Plo1 using recombinant Mis4 protein and found that the N terminus of Mis4 is preferentially phosphorylated by Plo1 (Fig S2A–C).
PMID:38448160 PBO:0095113 Furthermore, we examined the in vitro phosphorylation by Plo1 using recombinant Mis4 protein and found that the N terminus of Mis4 is preferentially phosphorylated by Plo1 (Fig S2A–C).
PMID:38448160 PBO:0095113 Furthermore, we examined the in vitro phosphorylation by Plo1 using recombinant Mis4 protein and found that the N terminus of Mis4 is preferentially phosphorylated by Plo1 (Fig S2A–C).
PMID:38448160 GO:1990813 suggesting that 40% of the reductional population underwent random segregation at meiosis II which is originated from loss of cohesion (a defect in cohesion protection) in anaphase I.
PMID:38448160 PBO:0112148 Measured in two-hybrid assay using only the N-terminal 245aa part of Rec8 (Fig. 2F)
PMID:38448160 MOD:00696 Furthermore, we examined the in vitro phosphorylation by Plo1 using recombinant Mis4 protein and found that the N terminus of Mis4 is preferentially phosphorylated by Plo1 (Fig S2A–C).
PMID:38448160 PBO:0095113 Furthermore, we examined the in vitro phosphorylation by Plo1 using recombinant Mis4 protein and found that the N terminus of Mis4 is preferentially phosphorylated by Plo1 (Fig S2A–C).
PMID:38448160 GO:0031619 Indeed, cells expressing Psm3-2A (alanine substitution at T182 and S1001) showed mono-orientation defects (20%) albeit mildly, compared with WT (12%) (Fig 3C), suggesting that phosphorylation of these sites might contribute to establishing cohesion at the core cen- tromeres.....We speculate that the Psm3 phosphorylation at the gate may play a role in transiently loosening Rec8-Psm3 gate to facilitate establishment of cohesion at the core centromere.
PMID:38448160 PBO:0112155 (Figs 3A and S3A–E) We examined if Psm3 is phosphorylated by Plo1 in vitro and found phosphorylation of T182 in the N terminus and S1001 in the C terminus, both locate in the coiled-coil region of the DNA exit gate (Figs 3A and S3A–E), These results suggest that the phosphorylation at Psm3-S110 specifically regulates Rec8 cohesin at centromeres most likely depending on Moa1-Plo1.
PMID:38448160 PBO:0112142 Fig. 1B
PMID:38448160 PBO:0112143 Fig. 2B In moa1Δ cells, a mi- nority population (11%) of cells underwent equational segregation at meiosis I (because of defects in mono-orientation), whereas the majority underwent reductional segregation due to the presence of chiasmata and tension exerted across homologs, as reported previously (Miyazaki et al, 2017) (Fig 2B).
PMID:38448160 PBO:0112497 Unequal sister chromatid segregation in meiosis II after reductional segregation in meiosis I. Fig. 2B
PMID:38448160 PBO:0112502 Fig. 2B
PMID:38448160 PBO:0112246 Figure 2D
PMID:38448160 PBO:0112146 Figure 2D
PMID:38448160 PBO:0112147 Figure 2D emarkably, introducing the rec8-15A mutation into rec12Δ rec8-2A cells increased equational segrega- tion to 36% (Fig 2D), suggesting that phosphorylation at some or all 15S/T sites in Rec8 is contributing at least partly to establishing mono-orientation, most likely by promoting cohesion at the core centromeres.
PMID:38448160 PBO:0095113 We identified 11 polo-kinase consensus N/Q/E/D-X-S/T sites and four non-consensus S/T in this domain, which were phosphorylated by Plo1 in vitro and some of them were detected also in vivo (Fig S1A–C).
PMID:38448160 GO:0031619 Indeed, cells expressing Psm3-2A (alanine substitution at T182 and S1001) showed mono-orientation defects (20%) albeit mildly, compared with WT (12%) (Fig 3C), suggesting that phosphorylation of these sites might contribute to establishing cohesion at the core cen- tromeres.
PMID:38448160 PBO:0095113 Furthermore, we examined the in vitro phosphorylation by Plo1 using recombinant Mis4 protein and found that the N terminus of Mis4 is preferentially phosphorylated by Plo1 (Fig S2A–C).
PMID:38448160 PBO:0095113 Furthermore, we examined the in vitro phosphorylation by Plo1 using recombinant Mis4 protein and found that the N terminus of Mis4 is preferentially phosphorylated by Plo1 (Fig S2A–C).
PMID:38448160 PBO:0112153 segregation defects in psm3-3A in achiasmatic meiosis I suppressed by wpl1 deletion. Figure 4E
PMID:38448160 PBO:0112153 Figure 4E
PMID:38448160 PBO:0109676 Figure 4E
PMID:38448160 GO:0031619 Accordingly, rec8-15A psm3-3A double mutant showed more defects in mono-orientation than either rec8-15A or psm3-3A mutant (Fig 4E), suggesting that the phosphorylation on Rec8 and Psm3 cooperatively act to establish cohesion at the core centro- meres.
PMID:38479839 PBO:0112335 Fig. 5D
PMID:38479839 PBO:0112329 Work with Dpb4 for parental histone H3-H4 transfer on the leading strand
PMID:38479839 PBO:0112329 Work with Dpb3 for parental histone H3-H4 transfer on the leading strand
PMID:38479839 PBO:0112329 Transfers parental histone H3-H4 on the lagging strand.
PMID:38479839 PBO:0112329 Deposits parental histone H3-H4 on both daughter strands during DNA replication.
PMID:38479839 PBO:0094679 Fig. 3
PMID:38479839 PBO:0096191 Fig. 1
PMID:38479839 PBO:0096191 Fig. 1
PMID:38479839 PBO:0096191 Fig. 1
PMID:38479839 PBO:0112330 Fig. 1E
PMID:38479839 FYPO:0008186 Fig. 1E
PMID:38479839 FYPO:0008186 Fig. 1E
PMID:38479839 FYPO:0008186 Fig. 1E
PMID:38479839 PBO:0112331 Fig. 2
PMID:38479839 PBO:0112766 Fig. 2
PMID:38479839 PBO:0112766 Fig. 2
PMID:38479839 PBO:0096192 Fig. 1
PMID:38479839 FYPO:0004742 Fig. 3
PMID:38479839 PBO:0112332 Fig. 3
PMID:38479839 PBO:0103245 Fig. 3D
PMID:38479839 PBO:0103245 Fig. 3D
PMID:38479839 FYPO:0008199 Fig. 3D
PMID:38479839 PBO:0112318 Fig. 3E
PMID:38479839 PBO:0095977 Fig. 3E
PMID:38479839 PBO:0095977 Fig. 3E
PMID:38479839 PBO:0095977 Fig. 3E
PMID:38479839 PBO:0095977 Fig. 3E
PMID:38479839 PBO:0103246 Fig. 3F
PMID:38479839 PBO:0103247 Fig. 3F
PMID:38479839 PBO:0103247 Fig. 3F
PMID:38479839 PBO:0103247 Fig. 3F
PMID:38479839 PBO:0103247 Fig. 3F
PMID:38479839 PBO:0112333 Fig. 5D
PMID:38479839 PBO:0112334 Fig. 6A
PMID:38479839 PBO:0112330 Fig. 6A
PMID:38479839 PBO:0096192 Fig. 6A
PMID:38479839 PBO:0096192 Fig. 6A
PMID:38479839 PBO:0112767 Fig. 6B, C and D
PMID:38479839 PBO:0112331 Fig. 6B, C and D
PMID:38479839 PBO:0096191 Fig. S2
PMID:38479839 PBO:0096191 Fig. S2
PMID:38479839 PBO:0112766 Fig. S2
PMID:38479839 PBO:0112766 Fig. S2
PMID:38479839 FYPO:0004742 Fig. S2
PMID:38479839 FYPO:0004742 Fig. S2
PMID:38479839 PBO:0112331 Fig. S5
PMID:38479839 GO:0006335 Deposits parental histone H3-H4 on both daughter strands during DNA replication
PMID:38479839 GO:0006335 Works with Dpb3 for parental histone H3-H4 transfer on the leading strand
PMID:38479839 GO:0006335 Transfers parental histone H3-H4 on the lagging strand.
PMID:38598031 FYPO:0005947 Figure 3c
PMID:38598031 FYPO:0001020 Figure 3c
PMID:38598031 PBO:0093594 Figure 3c
PMID:38598031 PBO:0107560 Figure 3c
PMID:38598031 PBO:0093595 Figure 3c, rst2∆ partially rescues the pps1∆ pka1∆ strain on KCl
PMID:38598031 PBO:0107560 Figure 3c, rst2∆ partially rescues the pps1∆ pka1∆ strain on CaCl2
PMID:38598031 GO:0005783 Figure 4
PMID:38598031 PBO:0107562 Figure 4
PMID:38598031 PBO:0112567 Figure 4a
PMID:38598031 PBO:0112566 Figure 4
PMID:38598031 GO:0005886 Figure 4
PMID:38598031 PBO:0096587 Figure 2
PMID:38598031 PBO:0112574 Figure 6
PMID:38598031 PBO:0112570 Figure 6
PMID:38598031 PBO:0112571 Figure 6
PMID:38598031 PBO:0112570 Figure 6
PMID:38598031 PBO:0112574 Figure 6
PMID:38598031 PBO:0112574 Figure 6
PMID:38598031 PBO:0112574 Figure 6
PMID:38598031 PBO:0112573 Figure 6
PMID:38598031 PBO:0112573 Figure 6
PMID:38598031 PBO:0107568 Figure 5
PMID:38598031 PBO:0107568 Figure 5
PMID:38598031 PBO:0096587 Figure 2
PMID:38598031 PBO:0093594 Figure 3a
PMID:38598031 PBO:0107560 Figure 3a
PMID:38598031 PBO:0112568 Figure 5
PMID:38598031 PBO:0093595 Figure 3a
PMID:38598031 PBO:0112569 Figure 5
PMID:38598031 PBO:0112572 Figure 4a
PMID:38598031 PBO:0112570 Figure 6
PMID:38598031 PBO:0107570 Figure 6
PMID:38598031 PBO:0112571 Figure 6
PMID:38598031 PBO:0112570 Figure 6
PMID:38598031 PBO:0107569 Figure 6
PMID:38598031 PBO:0107570 Figure 6
PMID:38598031 PBO:0112569 Figure 5
PMID:38598031 PBO:0107568 Figure 5
PMID:38598031 PBO:0107568 Figure 5
PMID:38598031 PBO:0093595 Figure 2
PMID:38598031 PBO:0093595 Figure 2
PMID:38598031 PBO:0112568 Figure 5
PMID:38598031 PBO:0037579 Figure 5
PMID:38598031 PBO:0107565 Figure 5
PMID:38598031 GO:0005737 Figure 5
PMID:38598031 PBO:0107560 Figure 2
PMID:38598031 PBO:0093594 Figure 2
PMID:38598031 PBO:0107560 Figure 2
PMID:38598031 PBO:0093594 Figure 2
PMID:38598031 FYPO:0001020 Figure 2
PMID:38598031 FYPO:0005947 Figure 2
PMID:38598031 PBO:0107560 Figure 1b
PMID:38598031 PBO:0093594 Figure 1a
PMID:38598031 GO:0005634 Figure 5
PMID:38598031 PBO:0093595 Figure 3a
PMID:38598031 PBO:0096587 Figure 3a
PMID:38598031 PBO:0096587 Figure 3a
PMID:38598031 PBO:0093594 Figure 3b
PMID:38598031 FYPO:0001020 Figure 3b
PMID:38598031 PBO:0093594 Figure 3b
PMID:38598031 PBO:0107560 Figure 3b
PMID:3870979 FYPO:0002044 homozygous diploid
PMID:3870979 FYPO:0000583 homozygous diploid
PMID:3870979 FYPO:0002043 homozygous diploid
PMID:3870979 FYPO:0002043 homozygous diploid
PMID:3870979 FYPO:0000583 homozygous diploid
PMID:3870979 FYPO:0002043 at 33.5 degrees, which is restrictive for cdc10-129 but allows sporulation
PMID:3870979 FYPO:0002043 at 33.5 degrees, which is restrictive for cdc2-33 but allows sporulation
PMID:3870979 FYPO:0001886 Saccharomyces LEU2 used for disruption
PMID:3870979 FYPO:0001886 done in h- cells kinetics depend on medium composition (see fig 6B)
PMID:3870979 FYPO:0000583 at 33.5 degrees, which is restrictive for cdc10129 but allows sporulation
PMID:3870979 FYPO:0000681 at 33.5 degrees, which is restrictive for cdc2-33 but allows sporulation
PMID:4154968 GO:0004354 "well this is a slight fudge. The activity was assayed and present. We know this is glutamate dehydrogenase...so sone and will make ""published"""
PMID:4309177 GO:0003938 activated by ATP
PMID:4698209 GO:0004794 inhibited_by CHEBI:17191
PMID:4698210 GO:0003984 inhibited_by CHEBI:27266
PMID:4708672 GO:0019002 The enzyme is strongly inhibited by AMP and GMP. Whereas GMP seems to act by a direct competition for the GTP binding site, AMP appears as an allosteric effector, showing at non-saturating substrate concentrations a homotropic effect as well as a heterotropic effect upon the GTP and aspartate binding
PMID:4708672 GO:0004019 The enzyme is strongly inhibited by AMP and GMP. Whereas GMP seems to act by a direct competition for the GTP binding site, AMP appears as an allosteric effector, showing at non-saturating substrate concentrations a homotropic effect as well as a heterotropic effect upon the GTP and aspartate binding
PMID:4708672 GO:0016208 The enzyme is strongly inhibited by AMP and GMP. Whereas GMP seems to act by a direct competition for the GTP binding site, AMP appears as an allosteric effector, showing at non-saturating substrate concentrations a homotropic effect as well as a heterotropic effect upon the GTP and aspartate binding
PMID:4821071 GO:0003984 activated_by FAD , inhibited_by L-valine
PMID:6094012 FYPO:0001972 parent child relationship with term above requested
PMID:6094012 FYPO:0000134 actually this only occurs in 30% of cells.. I don't know if it is viable or inviable
PMID:6526818 GO:0003961 inhibited by methionine
PMID:6828164 FYPO:0000400 fig1A Table 1 cdc13 transition point is 0.69 using a cdc13-117 mutant
PMID:6828164 FYPO:0000400 fig1A Table 1 cdc13 transition point (0.78) is not advanced in a cdc13-117 wee1.6 mutant
PMID:6828164 FYPO:0000400 fig1A The transition point for cdc2 (0.74) is not advanced using a cdc2.M35 wee1.6 mutant
PMID:6828164 PBO:0095711 cell size at septation is 9.5µm in cdc2-1w (9.7µm in cdc2-2w)
PMID:6828164 FYPO:0000400 fig1A The transition point for cdc2 is 0.70 using cdc2.M63
PMID:6828164 FYPO:0000400 fig1A The transition point for cdc2 is 0.65 using cdc2.M26
PMID:6828164 FYPO:0000400 fig1A The transition point for cdc2 is 0.66 using cdc2.M35
PMID:6828164 FYPO:0000400 fig1A The transition point for cdc2 is 0.65 using cdc2.M55
PMID:6828164 FYPO:0003449 fig1A The transition point for cdc2 is advanced from 0.69 to 0.48 using a cdc2.33 wee1 [more...]
PMID:6828164 FYPO:0003449 The transition point for cdc2 is advanced from 0.68 to 0.47 using a cdc2.L7 wee1.6 mutant
PMID:6828164 FYPO:0003449 The transition point for cdc2 is advanced from 0.65 to 0.53 using a cdc2.M26 wee1.6 mutant
PMID:6828164 FYPO:0000400 fig1A
PMID:6828164 FYPO:0000400 fig1A The transition point for cdc2 (0.68) is not advanced using a cdc2.M63 wee1.6 mutant
PMID:6828164 FYPO:0003449 The transition point for cdc1 is advanced in a cdc1.P13 wee1.6 mutant from 0.62 to 0.33. An asynchronous population of a cdc1-P13 wee1.6 mutant was shifted from 25°C to the restrictive temperature of 36°C to inactivate the cdc1 gene and the number of cells that went on to divide was increased compared to a cdc1-7 mutant
PMID:6828164 FYPO:0000400 fig1A TTable 1 cdc27 transition point is 0.62 using a cdc27.K3 mutant
PMID:6828164 FYPO:0000400 "fig1A EXP The transition point for cdc1 is not advanced in a cdc1.7 cdc2-1w mutant (0.64). An asynchronous population of a cdc1-7cdc2-1w mutant was shifted from 25°C to the restrictive temperature of 36°C to inactivate the cdc1 gene and the number of cells that went on to divide was similar to a cdc1-7 mutant. The transition point for cdc1 (0.58) is not advanced in a cdc1.7 cdc2-2w mutant (cdc2-2w is the same change as cdc2-1w, but also consider comment transferred from duplicate annotation: ""I think this allele cdc2-2w maybe a typo or a changed annotation since this paper was published and is actually cdc2-3w"")."
PMID:6828164 FYPO:0003449 fig1A The transition point s advanced from 0.68 to 0.29 in a cdc1.7 wee1.6 mutant. An asynchronous population of a cdc1-7 wee1.6 mutant was shifted from 25°C to the restrictive temperature of 36°C to inactivate the cdc1 gene and the number of cells that went on to divide was increased compared to a cdc1-7 mutant
PMID:6828164 FYPO:0002516 TP. 0.33
PMID:6828164 FYPO:0000400 fig1A The cdc1 gene has a execution point of ~0.62 which means its function is completed just before entry into mitosis. An asynchronous population of the cdc1-7 mutant was shifted from 25°C to the restrictive temperature of 36°C to inactivate the gene and the number of cells that went on to divide was measured
PMID:6828164 FYPO:0002516 ???
PMID:6828164 FYPO:0000400 fig1A The cdc1 gene has a execution point of ~0.65 which means its function is completed just before entry into mitosis. An asynchronous population of the cdc1-7 mutant was shifted from 25°C to the restrictive temperature of 36°C to inactivate the gene and the number of cells that went on to divide was measured
PMID:6828164 PBO:0095711 cell size at septation is 8.7µm
PMID:6828164 PBO:0095711 cell size at septation is 8.9µm
PMID:6828164 PBO:0095711 cell size at septation is 8.5µm
PMID:6828164 PBO:0095711 cell size at septation is 8.9µm
PMID:6828164 PBO:0095711 cell size at septation is 8.4µm
PMID:6828164 PBO:0095711 cell size at septation is 10.3µm
PMID:6828164 PBO:0095711 cell size at septation is 9.6µm
PMID:6828164 PBO:0094266 cell size at separation is 22.4µm compared to 12.8µm for wild type
PMID:6828164 PBO:0093767 cell size at separation is 16.7µm compared to 12.8µm for wild type
PMID:6828164 FYPO:0000400 fig1A The transition point for cdc2 is 0.68 using cdc2.L7
PMID:6828164 FYPO:0000400 fig1A The transition point for cdc2 is 0.65 using cdc2.33
PMID:6828164 FYPO:0003449 fig1A The transition point for cdc27 is advanced from 0.63 to 0.22 in a cdc27-K3 wee1.6 mutant. An asynchronous population of a cdc1-7 wee1.6 mutant was shifted from 25°C to the restrictive temperature of 36°C to inactivate the cdc27 gene and the number of cells that went on to divide was increased compared to a cdc27-K3 mutant
PMID:689088 FYPO:0006822 at division
PMID:6943408 FYPO:0003485 After release from HU block, cells can undergo one round of division without DNA replication
PMID:6943408 FYPO:0003485 DNA synthesis and cell number increase were rapidly inhibited (data not given but similar to the mitotic mutant cdc 2 in Fig. 5 of Nurse et al. 1976)
PMID:6943408 FYPO:0003485 DNA synthesis and cell number increase were rapidly inhibited (data not given but similar to the mitotic mutant cdc 2 in Fig. 5 of Nurse et al. 1976)
PMID:6943408 FYPO:0003485 DNA synthesis and cell number increase were rapidly inhibited (data not given but similar to the mitotic mutant cdc 2 in Fig. 5 of Nurse et al. 1976)
PMID:6943408 FYPO:0003485 DNA synthesis and cell number increase were rapidly inhibited (data not given but similar to the mitotic mutant cdc 2 in Fig. 5 of Nurse et al. 1976)
PMID:6943408 FYPO:0003485 After release from HU block, cells can undergo one round of division without DNA replication
PMID:6943408 FYPO:0001982 Cells unable to divide, even after DNA replication is completed
PMID:6943408 FYPO:0001982 Cells unable to divide, even after DNA replication is completed
PMID:6943408 FYPO:0000608 Cells able to undergo normal DNA replication and enter cell division, but fail to divide.
PMID:6943408 FYPO:0000608 Cells able to undergo normal DNA replication and enter cell division, but fail to divide.
PMID:6943408 FYPO:0003738 All nuclei took on a granular appearance and in some nuclei this granularity was clearly resolvable into three densely staining bodies resembling condensed chromosomes (Fig. 3)
PMID:6943408 FYPO:0001248 abolished
PMID:6943408 FYPO:0003485 After release from HU block, cells can undergo one round of division without DNA replication
PMID:6943408 FYPO:0003485 After release from HU block, cells can undergo one round of division without DNA replication
PMID:6961452 GO:0004070 This was really IGI complemetnation of E-coli pyrB
PMID:7262540 PBO:0101531 cells septate at 58% of wild type diploid length
PMID:7262540 PBO:0101531 cells divide at 75% of wild type diploid cell length at division at 25°C
PMID:7262540 PBO:0101536 cells divide at 9% longer than wild diploid cells at division
PMID:7262540 PBO:0101536 cells divide at 8% longer than wild diploid cells at division
PMID:7262540 PBO:0101534 cells divide at 10% longer than wild diploid cells at division
PMID:7262540 PBO:0101536 cells divide at 6% longer than wild diploid cells at division
PMID:7262540 PBO:0101534 cells divide at 11% longer than wild diploid cells at division
PMID:7262540 PBO:0101534 cells divide at 11% longer than wild diploid cells at division
PMID:7262540 PBO:0101534 cells divide at 10% longer than wild diploid cells at division
PMID:7262540 PBO:0101534 cells divide at 12% longer than wild diploid cells at division
PMID:7262540 PBO:0101535 cells divide at 7% longer than wild diploid cells at division
PMID:7262540 PBO:0101531 cells divide at 82% of wild diploid size at division
PMID:7262540 PBO:0101531 cells divide at 56% of the size at division of wild type diploids
PMID:7262540 PBO:0101531 Cells divide at 65% of wild type diploid cell length
PMID:7262540 PBO:0101534 cells divide at 16.7µm at 25°C
PMID:7262540 PBO:0101533 This mutation is probably allelic with cdc2-56. Cells divide at 10.0 µm. I think it is useful to have it annotated as it is in old literature and people may wonder what it is
PMID:7262540 PBO:0101531 cells divide at 10.2µm at 25°C
PMID:7262540 PBO:0101532 cells divide at 22.4µm at 25°C
PMID:7262540 PBO:0101531 cdc2-1w was previously called wee2-1
PMID:7262540 PBO:0101531 cells septate at 56% of wild type diploid length
PMID:7262540 PBO:0101531 cells septate at 54% of wild type diploid length
PMID:7262540 PBO:0101531 cells septate at 58% of wild type diploid length
PMID:7262540 PBO:0101531 cells septate at 52% of wild type diploid length
PMID:7262540 PBO:0101531 cells septate at 81% of wild type diploid length
PMID:7262540 PBO:0101531 cells septate at 82% of wild type diploid length
PMID:7262540 PBO:0101531 cells septate at 85% of wild type diploid length
PMID:7262540 PBO:0101531 cells septate at 77% of wild type diploid length
PMID:7262540 PBO:0101531 cells septate at 87% of wild type diploid length
PMID:7262540 FYPO:0002176 small cell size at division is partially suppressed in the presence of sup3-5 an opal nonsense suppressor mutation in the sup3 tRNA gene. Cells divide at 89% of control cell length at division so are not really normal size
PMID:7262540 PBO:0101531 cells divide at 51% of control cell length at division
PMID:7498507 GO:0004725 activated_by(CHEBI:16356)
PMID:7501024 FYPO:0001490 salt stress
PMID:7501024 FYPO:0001490 non-ionic osmotic stress
PMID:7501024 FYPO:0001490 salt stress
PMID:7501454 MOD:00046 hyperphosphorylated in late S phase; phosphorylated on different sites in S versus G2/M
PMID:7501454 GO:0003887 constant throughout cell cycle
PMID:7501454 GO:0003697 higher affinity during S phase than G2/M
PMID:7559598 FYPO:0000280 not shown
PMID:7559598 PBO:0097547 not shown
PMID:7588609 PBO:0021177 heterozygous diploid
PMID:7596817 FYPO:0003695 polysome profile
PMID:7596817 FYPO:0003696 polysome profile
PMID:7622618 FYPO:0000280 evidence is essentially IC, as I inferred sterility from the lack of shmoo formation (h- cells)
PMID:7626804 PBO:0093767 Fig 4A right panel cells average size 16.6µm This strain is a gene replacement of cdc2+
PMID:7626804 PBO:0099203 Fig 4B absence of peptide 3 This strain is a gene replacement of cdc2+
PMID:7626804 PBO:0099204 Fig 4B middle right panel presence of peptide 3 This strain is a gene replacement of cdc2+
PMID:7626804 PBO:0099205 Fig 4B absence of peptide 3 Overexpression of wee1 does not phosphorylate T14A residue. This strain is a gene replacement of cdc2+
PMID:7626804 PBO:0099206 Fig 4B increased peptide 3 compared to when wee1 is not overexpressed . This strain is a gene replacement of cdc2+
PMID:7626804 PBO:0099207 Fig5 B wee1 is necessary for T14 phosphorylation no peptide 3 is observed when wee1 is deleted
PMID:7626804 PBO:0099208 Fig7A,B At restrictive temperature T14 is not phosphorylated (no peptide when cells blocked at RT.)
PMID:7626804 PBO:0099209 Fig7A, B At shift to permissive temperature T14 becomes phosphorylated. Peptide 3 is only present at low stoichiometry
PMID:7626804 FYPO:0001706 Fig8
PMID:7626804 PBO:0099202 Fig 4A middle panel cells average size 11.6µm This strain is a gene replacement of cdc2+
PMID:7626804 FYPO:0002176 Table 2 cdc2-T14A is present on multicopy plasmid cells are viable and have a normal cell size phenotype
PMID:7626804 FYPO:0000648 Table 2 cdc2-T14A is present on multicopy plasmid cells are viable but have a semi wee phenotype
PMID:7626804 FYPO:0002102 Fig8
PMID:7626804 PBO:0099210 data not shown
PMID:7626804 PBO:0094619 Fig1B, C and D x = a small phospho peptide of T14Y15. T14 phosphorylation only occurs when wee1 is overexpressed
PMID:7626804 PBO:0094620 Fig3 chk1 1 is not required for T14 phosphorylation by wee1
PMID:7626804 MOD:00047 Fig1D peptide 2
PMID:7626804 PBO:0099201 Fig1D peptide 3 and peptide1
PMID:7626804 MOD:00047 Fig1D peptide 3
PMID:7626804 PBO:0099200 Fig1A
PMID:7651412 FYPO:0003735 switches specificity from direct repeats to inverted repeats
PMID:7651414 PBO:0105935 matmi and matpi
PMID:7651414 PBO:0105934 matmi and matpi
PMID:7651414 PBO:0105935 matmi and matpi
PMID:7651414 PBO:0105934 matmi and matpi
PMID:7651414 PBO:0105936 matmi and matpi
PMID:7657164 PBO:0094488 residue not determined, but probably Y173
PMID:7687541 GO:0005737 fig4
PMID:7706287 FYPO:0000400 arrest point determined by H1 kinase activity peak
PMID:7706287 FYPO:0000911 assayed for bulk poly(A)+ RNA
PMID:7706287 FYPO:0002522 assayed for bulk poly(A)+ RNA
PMID:7739540 FYPO:0001430 (Figure 3b)
PMID:7739540 FYPO:0001430 (Figure 3b)
PMID:7739540 FYPO:0001430 (Figure 3b)
PMID:7773104 FYPO:0005472 NADP-GDH-defective
PMID:7774573 PBO:0037510 abnormal mitotic arrest with 4C DNA content Cells undergo an extra round of DNA replication without undergoing cytokinesis pREP5cdc2-DL41 is integrated. cdc2-DL45 has same phenotype but it is not clear if it is under the same conditions
PMID:7774573 PBO:0037509 pREP5cdc2-DL41 is integrated. cdc2-DL45 has same phenotype but it is not clear if it is under the same conditions
PMID:7774573 PBO:0106642 pREP5cdc2-DL41 is integrated.cdc2-DL45 has same phenotype but it is not clear if it is under the same conditions. Abnormal septum phenotype include misplace septum, multi septa and partially formed septa
PMID:7774573 PBO:0037507 pREP5cdc2-DL41 is integrated. cdc2-DL45 has same phenotype but it is not clear if it is under the same conditions
PMID:7774573 PBO:0037506 pREP5cdc2-DL41 is integrated. cdc2-DL45 has same phenotype but it is not clear if it is under the same conditions
PMID:7774573 PBO:0037519 pREP41-DL50 is integrated
PMID:7774573 PBO:0037522 pREP5-DL45 is integrated. cdc2+ is expressed from its own promoter on a multi copy plasmid
PMID:7774573 PBO:0037522 pREP5-DL41 is integrated. cdc2+ is expressed from its own promoter on a multi copy plasmid
PMID:7774573 PBO:0106643 pREP41cdc2-DL50 is integrated
PMID:7774573 PBO:0037520 pREP5cdc2+ is integrated. 24% cells enter mitosis compared to 2% when cdc2+ is not over expressed but they did not say that it was a cut phenotype
PMID:7774573 PBO:0037519 pREP41cdc2-DL50 is integrated
PMID:7774573 PBO:0037518 pREP41cdc2-DL50 is integrated
PMID:7774573 PBO:0093712 pREP41cdc2-DL50 is integrated
PMID:7774573 PBO:0095634 pIRT2suc1 multi copy plasmid partially rescues the pREP5cdc2-DL41 integrant mitotic arrest phenotype and allows formation of micro colonies. cdc2-DL45 is also partially rescued but it is not clear whether this is under the same conditions
PMID:7774573 PBO:0096052 pRIP45cdc2-DL41 is integrated
PMID:7774573 PBO:0096053 pRIP45cdc2+ is integrated
PMID:7774573 PBO:0096052 pRIP45cdc2-DL45 is integrated
PMID:7774573 PBO:0037515 pREP41cdc2-DL45 is a multi copy plasmid . No data shown
PMID:7774573 PBO:0037516 pREP41cdc2-DL45 is a multi copy plasmid. No data shown
PMID:7774573 PBO:0037516 pREP41cdc2-DL41 is a multi copy plasmid . No data shown
PMID:7774573 PBO:0037515 pREP41cdc2-DL41 is a multi copy plasmid . No data shown
PMID:7774573 PBO:0097954 pRIP45DL45 is integrated. cdc2-DL41 has same phenotype but it is not clear if it is under the same conditions. Figure 6B the 20% of cells that are in mitosis are probably cells that were in mitosis when the culture was shifted to the restrictive temperature
PMID:7774573 PBO:0037513 About 75% of cells do not enter mitosis in presence of HU Figure 6A, showing that this mutant does not disrupt normal controls regulating entry into mitosis. pRIP45cdc2-DL45 is integrated cdc2-DL41 has same phenotype but it is not clear if it is under the same conditions
PMID:7774573 PBO:0037512 pREP5cdc2-DL41 is integrated. cdc2-DL45 has same phenotype but it is not clear if it is under the same conditions
PMID:7774573 PBO:0037511 child term of abnormal regulation of mitotic metaphase/anaphase transition. pREP5cdc2-DL41 is integrated. cdc2-DL45 has same phenotype but it is not clear if it is under the same conditions
PMID:7796804 PBO:0097659 Fig 6 middle panels Fig7B panel 4 cells examined 7 hour after refeeding with nitrogen
PMID:7796804 PBO:0097558 Fig 6 bottom panels Fig7B panel 5 cells nitrogen starved and examined 7 hour after refeeding with nitrogen
PMID:7796804 PBO:0097659 Fig 6 bottom panels Fig7B panel 6 cells examined 7 hour after refeeding with nitrogen
PMID:7796804 PBO:0104265 fypo/issues/3164 Fig 5C the cyclin cdc13 cdc2 complex are detected when cells are blocked at G1/S with cdc20-M10 mutant, complex precipitated with p13 beads
PMID:7796804 PBO:0104265 fypo/issues/3164 Fig 5C the cyclin cdc13 cdc2 complex are detected when cells are blocked at G1/S with cdc20-M45 mutant, complex precipitated with p13 beads
PMID:7796804 PBO:0097659 Fig 6, Fig7B panel 8,
PMID:7796804 PBO:0104261 Fig7A panel 2
PMID:7796804 PBO:0104266 Fig7A panel 1
PMID:7796804 PBO:0104261 Fig7A panel 4
PMID:7796804 PBO:0104261 Fig7A panel 6
PMID:7796804 PBO:0102115 Fig7A panel 3
PMID:7796804 PBO:0102115 Fig7A panel 5
PMID:7796804 PBO:0104267 Fig5B cdc10-129 cells blocked in G1
PMID:7796804 PBO:0037896 Fig 7C
PMID:7796804 PBO:0037896 Fig 7C
PMID:7796804 PBO:0104268 Fig7B. It is the soluble form (upper panel) that disappears not the insoluble form (lower panel) which has implications for which form is allowing replication. I don't know whether to leave this annotation out
PMID:7796804 PBO:0104269 Fig7C
PMID:7796804 PBO:0104270 Figure 1, 4,5
PMID:7796804 PBO:0100985 Fig 6 top panels, Fig7B panel 1 cells examined 7 hour after refeeding with nitrogen
PMID:7796804 PBO:0097659 Fig 6 top panels , Fig7B panel 2 cells examined 7 hour after refeeding with nitrogen After 7 hour the cdc10-V50 cells start to leak through and this allows the mik1D wee1-50 cells to start entering mitosis
PMID:7796804 PBO:0104261 Fig7A 8,
PMID:7796804 PBO:0104264 Fig 5B cdc22-M45 blocks in G1/S
PMID:7796804 PBO:0104264 Fig 5B cdc22-M45 blocked in G1/S
PMID:7796804 PBO:0104263 Fig 5C cyclin cdc13 cdc2 complex are not detected when cells are blocked in G1 with cdc10-129 mutant complex precipitated with p13 beads
PMID:7796804 PBO:0104262 Fig 5A
PMID:7796804 PBO:0104262 Fig 5A
PMID:7796804 PBO:0099447 Figure 1, 4,5
PMID:7796804 PBO:0099448 Figure 1, 4,5
PMID:7796804 PBO:0023774 Figure 1, 4,5
PMID:7796804 PBO:0104261 Fig5A
PMID:7796804 PBO:0097558 Fig 6 middle panels Fig7B panel 3 cells examined 7 hour after refeeding with nitrogen
PMID:7798319 FYPO:0003166 Consistently, the phenotype of cut9-T98 was indistinguishable from that of cut9-665
PMID:7798319 FYPO:0002303 Consistently, the phenotype of cut9-T98 was indistinguishable from that of cut9-665
PMID:7798319 FYPO:0003165 Consistently, the phenotype of cut9-T98 was indistinguishable from that of cut9-665
PMID:7813446 FYPO:0001355 not arrested like wee1-50 overexp alone
PMID:7813446 FYPO:0001355 not arrested like wee1-50 overexp alone
PMID:7813446 PBO:0094967 higher than wee1 not overexp, but lower than wee1-50 overexp in wt bkg
PMID:7813446 FYPO:0001355 not arrested like wee1+ overexp alone
PMID:7859738 FYPO:0002060 Figure 4
PMID:7859738 FYPO:0002060 Figure 4
PMID:7859738 FYPO:0002060 Figure 4
PMID:7859738 FYPO:0002060 Figure 4
PMID:7859738 FYPO:0002060 Figure 4
PMID:7859738 FYPO:0002060 Figure 4
PMID:7859738 FYPO:0002060 Figure 4
PMID:7876257 MOD:00006 endoglycosidase-H cleaves N-linked glycosylation
PMID:7883794 PBO:0023560 Figure 3A
PMID:7883794 PBO:0106434 Figure 3B
PMID:7883794 FYPO:0005773 Data not shown
PMID:7883794 PBO:0102251 Table 1, Figure 1B appearance of IC peak at early timepoint
PMID:7883794 PBO:0106431 Figure 2B
PMID:7883794 PBO:0106432 Figure 2C
PMID:7883794 PBO:0106429 Fig1 B
PMID:7883794 PBO:0106433 Table 1, Figure 2C
PMID:7883794 PBO:0106430 Figure 1A
PMID:7889932 GO:0000287 crystal structure
PMID:7903653 FYPO:0000249 ABOLISHED
PMID:7903653 FYPO:0000249 ABOLISHED
PMID:7903653 FYPO:0000249 ABOLISHED
PMID:7909513 PBO:0106921 3 kb transcript
PMID:7909513 PBO:0106920 the basal level of the 3.2 kb transcript was lower than that in h90 wild type cells, but the 3 kb transcript was properly induced upon nitrogen starvation
PMID:7916653 FYPO:0001490 deletion with expressed plasmid, after plasmid loss
PMID:7916658 PBO:0105614 inferred from combination of phenotype shown in this paper with background knowledge
PMID:7916658 FYPO:0000012 constitutive cdc18+ expression
PMID:7916658 FYPO:0001492 constitutive cdc18+ expression
PMID:7916658 FYPO:0001355 constitutive cdc18+ expression
PMID:7923372 PBO:0103991 they interacted in the Y2H experiment, so inferring this relationship
PMID:7957097 FYPO:0004922 no mitotic spindle
PMID:7957097 PBO:0099590 inhibits
PMID:7957098 FYPO:0001916 same as cdc13-117 alone
PMID:7957098 FYPO:0001933 same as rad4 cut5 allele alone
PMID:7957098 FYPO:0001933 same as rad4 cut5 allele alone
PMID:7957098 FYPO:0001933 same as rad4 cut5 allele alone
PMID:7957098 FYPO:0001933 same as rad4 cut5 allele alone
PMID:7957098 FYPO:0001933 same as rad4 cut5 allele alone
PMID:7957098 FYPO:0001933 same as rad4 cut5 allele alone
PMID:7957098 FYPO:0001916 same as cdc25-22 alone
PMID:7957098 FYPO:0001933 same as rad4 cut5 allele alone
PMID:7957098 FYPO:0001933 same as rad4 cut5 allele alone
PMID:7957098 FYPO:0001933 same as rad4 cut5 allele alone
PMID:7957098 FYPO:0001916 same as cdc2-33 alone
PMID:7957098 PBO:0097701 same as cdc10-129 alone
PMID:7975894 PBO:0107866 increased transcriptional response to nitrogen starvation
PMID:7975894 PBO:0107866 increased transcriptional response to nitrogen starvation
PMID:7975894 PBO:0107869 increased transcription from TR box SO:0001858
PMID:7983142 FYPO:0001253 33 degrees (may be standard for them)
PMID:7983142 FYPO:0001253 33 degrees (may be standard for them)
PMID:7983142 FYPO:0000280 33 degrees (may be standard for them)
PMID:7983142 PBO:0026157 33 degrees (may be standard for them)
PMID:7983142 PBO:0104310 33 degrees (may be standard for them)
PMID:7983142 FYPO:0001357 33 degrees (may be standard for them)
PMID:7983142 FYPO:0000021 33 degrees (may be standard for them); morphology same as ppe1delta alone
PMID:8006074 FYPO:0000477 fig8
PMID:8006074 FYPO:0001043 fig8
PMID:8006074 FYPO:0000479 fig8
PMID:8006074 FYPO:0000477 fig8
PMID:8026462 FYPO:0001384 assayed using casein
PMID:8039497 GO:0140281 also some genetic interactions that cannot be described with biogrid
PMID:8039497 GO:0031028 also some genetic interactions that cannot be described with biogrid
PMID:8039497 FYPO:0002024 unstable plasmid loss experiment
PMID:8087848 PBO:0037895 cells are induced to increase their ploidy by a specific treatment e.g. heat shock or drug treatment
PMID:8087848 PBO:0037895 cells are induced to increase their ploidy by a specific treatment e.g. heat shock or drug treatment
PMID:8087848 PBO:0037896 cdc13delete cells were kept alive by episomal pSM2 cdc13. Cell phenotype was observed after plasmid loss. Figure 2C
PMID:8087848 PBO:0037893 cells are induced to increase their ploidy by a specific treatment e.g. heat shock or drug treatment
PMID:8087848 PBO:0037892 FACS analysis of germinating haploid cdc13delta spores. Up to 32C DNA content was observed by 19 hour after referring spores to allow germination Figure 2
PMID:8087848 PBO:0026408 germinating haploid cdc13delta spores, observed by 14 hour after spores allowed to germination (Figure 2b). cdc13delete cells kept alive by a multicopy plasmid, pSM2-cdc13. Cell phenotype was observed after plasmid loss same phenotype as in Figure 2b
PMID:8087848 FYPO:0005711 p34cdc2 cdc13-9 complex was pulled down using p13suc1 beads and then western blotted using anti cdc13 antibody SP4 to show reduced levels of Cdc13 complexed with cdc2 compared to the wild type control
PMID:8087848 PBO:0099432 cdc10-129 cells blocked in G1 over expressing cdc2 from integrated pREP5cdc2 and cdc13 from episomal pREP41-cdc13. The nmt1 promoter is derepressed Figure 4
PMID:8087848 PBO:0099433 cdc10-129 cells blocked in G1 over expressing cdc2 from integrated pREP5cdc2 and cdc13 from episomal pREP41-cdc13. The nmt1 promoter is derepressed Figure 4
PMID:8121488 PBO:0037896 (transient expression) most surviving cells generated diploid or tetraploid clones/ if rum was derepressed for only a short period, most surviving cells generated diploid or tetraploid clones, as would be expected if there were complete rounds of DNA replication. Fig1b
PMID:8121488 PBO:0112244 Fig 4E G. In cdc10-129 rum1 delta strain cells at 36 fail to activate the DNA replication checkpoint in the absence of rum1 and cells proceed into mitosis in the presence of HU and enter mitosis with reduced DNA content
PMID:8121488 PBO:0112244 Fig 4d, f. In cdc10-129 rum1 delta strain cells fail to activate the DNA replication checkpoint in the absence of rum1 and cells proceed into mitosis in the absence of DNA replication and enter mitosis with reduced DNA content proce of DNA replication and
PMID:8121488 PBO:0112243 xpression results in a small delay of S phase onset until cells attain a higher mass, suggesting the rumr gene product may act as a transient inhibitor of progres- sion through GI into S phase. The appearance of a small popu- lation of IC cells at 16 h is consistent with this interpretation (Fig. lb).
PMID:8121488 PBO:0112243 xpression results in a small delay of S phase onset until cells attain a higher mass, suggesting the rumr gene product may act as a transient inhibitor of progres- sion through GI into S phase. The appearance of a small popu- lation of IC cells at 16 h is consistent with this interpretation (Fig. lb).
PMID:8121488 FYPO:0005097 4a elongated cell, cells do not replicate DNA (never enter S phase), but keep growing
PMID:8121488 PBO:0112242 Fig3a
PMID:8121488 FYPO:0001425 At both temperatures the DNA content per cell continued to increase, demonstrating that the G2-arrested cells were able to undergo further rounds of S phase (Fig. 2c and d, right) .
PMID:8121488 FYPO:0001425 Fig1B they give a pulse of rum1
PMID:8121488 PBO:0112241 negative regulation/(I now think this is the same as G1 checkpoint). expression results in a small delay of S phase onset until cells attain a higher mass, suggesting the rumr gene product may act as a transient inhibitor of progres- sion through GI into S phase. The appearance of a small popu- lation of IC cells at 16 h is consistent with this interpretation (Fig. lb).
PMID:8121488 PBO:0112240 Fig 4A, B. In cdc10-129 rum1 delta strain cells fail to activate the DNA replication checkpoint in the absence of DNA replication and
PMID:8121488 FYPO:0007476 data not shown cells become arrest in G2
PMID:8121488 PBO:0112239 Table 1
PMID:8121488 PBO:0112238 Fig2B. prestart
PMID:8121488 PBO:0112237 in vitro assay data not shown
PMID:8121488 PBO:0112236 Table 1 increased cell size required for the G1/S transition.
PMID:8121488 PBO:0026408 Fig1A Overreplicating haploid cells become highly enlarged (Fig. la, left),
PMID:8163505 GO:0004674 based on phenotype this annotation is possible
PMID:8187760 FYPO:0001382 assayed in vitro using casein
PMID:8187760 FYPO:0000839 same as cdc25-22 alone
PMID:8187760 FYPO:0000839 same as cdc2-33 alone
PMID:8187760 FYPO:0004105 grows in three dimensions instead of just at cell ends
PMID:8196631 GO:0043409 NEG REG OF PHEROMONE RESPONSE MAPK
PMID:8223442 FYPO:0007564 fig 1
PMID:8223442 FYPO:0007565 fig 1
PMID:8227198 FYPO:0001665 response curve differs from wt and other git mutants
PMID:8264625 GO:0004674 casein substrate
PMID:8264625 GO:0043539 casein substrate (vw changed from GO:0004674 with contributes to)
PMID:8292390 PBO:0096647 same as cps8-185 alone
PMID:8299169 FYPO:0002068 C868T (nt)
PMID:8319772 MOD:00046 present throughout cell cycle
PMID:8334988 FYPO:0002987 binucleate fypo/issues/#2400 fypo/issues/#2401
PMID:8346915 GO:0004019 inhibiyted by CHEBI:43040
PMID:8413241 PBO:0105255 tyrosine; residue not determined
PMID:8413241 PBO:0105255 tyrosine; residue not determined
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has dominant negative phenotype
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 does not supress the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 does not supress the ts phenotype
PMID:8437586 PBO:0038194 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2 supresses the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 does not supress the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 does not supress the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2 supresses the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0093712 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 Table1 mutant gene expressed from multicopy plasmid pIRT2 does not suppress the ts phenotype
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0000082 Table 1 mutant gene expressed from multicopy plasmid pIRT2 partially supresses the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2 surpresses the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0099234 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0001234 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2 suppresses the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0093712 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 does not suppress the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2 suppresses the ts phenotype
PMID:8437586 PBO:0038194 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0001234 Table 1 mutant gene expressed from multicopy plasmid pIRT2 partially suppresses the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0093712 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 does not suppress the ts phenotype
PMID:8437586 PBO:0037209 Table 1 Fig 2 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0093712 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 does not suppress the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0000082 Table 1 mutant gene expressed from multicopy plasmid pIRT2 partially supresses the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2 suppresses the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2 does not suppress the ts phenotype
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2 suppresses the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2 suppresses the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has dominant negative phenotype
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has dominant negative phenotype
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has dominant negative phenotype
PMID:8437586 PBO:0019154 mutant gene expressed from multicopy plasmid pIRT2 has dominant negative phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2 does not supress the ts phenotype
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 does not supress the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant expressed from multi copy plasmid pIRT2
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2 does not supress the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0107596 Table 1, Fig2 mutant gene expressed from multicopy plasmid pIRT2 partially suppresses the ts phenotype
PMID:8437586 PBO:0093712 Table 1 Fig 2 mutant gene expressed from multicopy plasmid pIRT2 suppresses the ts phenotype
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0107595 Fig 5 increased duration of G1 phase
PMID:8437586 FYPO:0002061 Cdc2 is only mildly over expressed as it is expressed from a multi copy plasmid pIRT2. This is much lower over expression than from the nmt1 promoter and for all the other annotations were the cdc2 mutant is expressed from pIRT2 I have said 'unknown' for expression level
PMID:8437586 PBO:0019154 Cdc2 is only mildly over expressed as it is expressed from a multi copy plasmid pIRT2. This is much lower over expression than from the nmt1 promoter and for all the other annotations were the cdc2 mutant is expressed from pIRT2 I have said 'unknown' for expression level
PMID:8437586 PBO:0100985 Table 1 Fig 4 nmt1 ON
PMID:8437586 PBO:0097954 Fig 5 nmt1 promoter ON
PMID:8437586 PBO:0097954 Fig 5 nmt1 promoter ON
PMID:8437586 PBO:0097954 Fig 5 nmt1 promoter ON
PMID:8437586 FYPO:0002061 Table 1 nmt1 promoter ON
PMID:8437586 PBO:0019154 Table 1 nmt1 promoter ON
PMID:8437586 FYPO:0002061 Table 1 nmt1 promoter ON
PMID:8437586 PBO:0019154 Table 1 nmt1 promoter ON
PMID:8437586 FYPO:0002061 Table 1 nmt1 promoter ON
PMID:8437586 PBO:0019154 Table 1 nmt1 promoter ON
PMID:8437586 FYPO:0002061 Table 1 Fig 4 nmt1 promoter ON
PMID:8437586 PBO:0019154 Table 1 Fig 4 nmt1 promoter ON
PMID:8437586 FYPO:0002061 Fig 4 Table 1 nmt1 promoter ON
PMID:8437586 PBO:0019154 Fig 4 Table 1 nmt1 promoter ON
PMID:8437586 FYPO:0002061 Table 1 nmt1 promoter ON
PMID:8437586 PBO:0019154 Table 1 nmt1 promoter ON
PMID:8437586 FYPO:0002061 Fig 4 nmt1 promoter ON
PMID:8437586 PBO:0019154 Fig 4 nmt1 promoter ON
PMID:8437586 FYPO:0002061 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0001490 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002085 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0001490 Table 1 mutant gene expressed from multicopy plasmid pIRT2 no suppression
PMID:8437586 FYPO:0002085 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0001490 Table 1 mutant gene expressed from multicopy plasmid pIRT2 no suppression
PMID:8437586 FYPO:0002085 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0001490 Table 1 mutant gene expressed from multicopy plasmid pIRT2 no suppression
PMID:8437586 FYPO:0002085 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0001490 Table 1 mutant gene expressed from multicopy plasmid pIRT2 no suppression
PMID:8437586 FYPO:0002085 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002085 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0001490 Table 1 mutant gene expressed from multicopy plasmid pIRT2 does not supress the ts phenotype
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0001490 Table 1 mutant gene expressed from multicopy plasmid pIRT2 no suppression
PMID:8437586 FYPO:0002085 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0001490 Table 1 mutant gene expressed from multicopy plasmid pIRT2 supresses the ts phenotype
PMID:8437586 FYPO:0002085 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 FYPO:0002061 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 PBO:0019154 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 FYPO:0002061 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 PBO:0019154 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 FYPO:0002061 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 PBO:0019154 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has dominant negative phenotype
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has dominant negative phenotype
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has dominant negative phenotype
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has dominant negative phenotype
PMID:8437586 FYPO:0002061 mutant gene expressed from multicopy plasmid pIRT2 has dominant negative phenotype
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 does not supress the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0020446 Table 1 mutant gene expressed from multicopy plasmid pIRT2 does not suppress the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2 supresses the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002060 Table 1 mutant gene expressed from multicopy plasmid pIRT2 give partial suppression
PMID:8437586 FYPO:0000082 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0019143 Table 1 mutant gene expressed from multicopy plasmid pIRT2 partially supresses the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2 supresses the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 does not supress the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 does not supress the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2 supresses the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 does not supress the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0019154 Table 1 mutant gene expressed from multicopy plasmid pIRT2 does not supress the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2 supresses the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 mutant expressed from multi copy plasmid has dominant negative phenotype Table 1
PMID:8437586 PBO:0019154 mutant expressed from multi copy plasmid has dominant negative phenotype Table 1
PMID:8437586 FYPO:0002061 mutant expressed from multi copy plasmid has dominant negative phenotype Table 1
PMID:8437586 PBO:0019154 mutant expressed from multi copy plasmid has dominant negative phenotype Table 1
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 FYPO:0002061 Table 1 mutant expressed from multi copy plasmid has dominant negative phenotype Table 1
PMID:8437586 PBO:0019154 Table 1 mutant expressed from multi copy plasmid has dominant negative phenotype Table 1
PMID:8437586 FYPO:0002061 mutant expressed from multi copy plasmid has dominant negative phenotype Table 1
PMID:8437586 PBO:0019154 mutant expressed from multi copy plasmid has dominant negative phenotype Table 1
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2 has a dominant negative phenotype
PMID:8437586 FYPO:0002061 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0020446 Table 1 mutant gene expressed from multicopy plasmid pIRT2 supresses the ts phenotype
PMID:8437586 FYPO:0000082 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2 supresses the ts phenotype
PMID:8437586 PBO:0038194 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8437586 FYPO:0002061 Table 1 mutant gene expressed from multicopy plasmid pIRT2
PMID:8463273 GO:0004699 kinase assay, and hybridization with S. cerevisiae PKC
PMID:8485317 FYPO:0002060 like dis1-288 alone
PMID:8485317 FYPO:0002061 like dis1-288 alone
PMID:8496185 GO:0004017 inhibited by P(1),P(5)-bis(5'-adenosyl) pentaphosphate(5-)?
PMID:8497322 PBO:0094949 fig 2 c
PMID:8497322 FYPO:0002061 data not shown
PMID:8497322 PBO:0093631 partial rescue of chk1, fig 2 b
PMID:8497322 PBO:0094950 fig 2a DROPS TO ZERO
PMID:8497322 PBO:0094952 fig 2 c
PMID:8497322 PBO:0093581 fig 4
PMID:8497322 FYPO:0001046 fig 3 fypo/issues/2818
PMID:8497322 FYPO:0006822 fig 3 fypo/issues/2818
PMID:8497322 PBO:0093629 fig 2 c
PMID:8497322 FYPO:0002061 fig 3
PMID:8497322 PBO:0093630 fig 2 c
PMID:8497322 FYPO:0001971 fig 3 cells fail to separate and are clupmed together, multiple rounds of nuclear division
PMID:8497322 PBO:0093630 fig 2a
PMID:8497322 FYPO:0002060 fig 3 a
PMID:8515818 PBO:0097559 Fig2a lane1
PMID:8515818 PBO:0097558 Fig1b bottom R panel , bottom R K41A is predicted to be catalytically inactive. cdc25 is constituitively OP behind ADH promoter and nim1 is behind thiamine repressible promotor
PMID:8515818 FYPO:0002061 Fig1b bottom R panel, bottom L
PMID:8515818 FYPO:0002061 Fig1b top R panel bottom L cdc25 is constituitively OP behind ADH promoter and nim1 is behind thiamine repressible promotor
PMID:8515818 FYPO:0002061 Fig1b top R panel, top cdc25 is constituitively OP behind ADH promoter and nim1 is behind thiamine repressible promotor
PMID:8515818 FYPO:0002061 Fig1b bottom R panel, top
PMID:8515818 PBO:0019218 Fig1b bottom R panel, bottom L
PMID:8515818 MOD:00046 Fig2b 2x serine phos to T phos
PMID:8515818 PBO:0097560 Fig2a lane 3
PMID:8515818 FYPO:0002060 Fig1b bottom R panel , bottom R K41A is predicted to be catalytically inactive. cdc25 is constituitively OP behind ADH promoter and nim1 is behind thiamine repressible promotor
PMID:8515818 MOD:00047 Fig 2b
PMID:8515818 PBO:0097561 (directly inhibits) Fig4a,b together with data from fig 2,3
PMID:8515818 MOD:00047 Fig2b
PMID:8515818 FYPO:0006822 data not shown ref16
PMID:8515818 PBO:0019218 Fig1b top R panel bottom L cdc25 is constituitively OP behind ADH promoter and nim1 is behind thiamine repressible promotor
PMID:8515818 PBO:0019218 Fig1b top R panel, top cdc25 is constituitively OP behind ADH promoter and nim1 is behind thiamine repressible promotor
PMID:8515818 PBO:0097558 Fig1b top R panel bottom R K41A is predicted to be catalytically inactive. cdc25 is constituitively OP behind ADH promoter and nim1 is behind thiamine repressible promotor
PMID:8515818 FYPO:0002060 Fig1b top R panel bottom R. K41A is predicted to be catalytically inactive ref 18. cdc25 is constituitively OP behind ADH promoter and nim1 is behind thiamine repressible promotor
PMID:8515818 PBO:0019218 Fig1b bottom R panel, top
PMID:8515818 MOD:00046 Fig2b,
PMID:8521469 FYPO:0001425 same as cdc18+ oe alone
PMID:8521469 FYPO:0001425 same as cdc18+ oe alone
PMID:8521500 PBO:0101294 Fig 3C
PMID:8521500 PBO:0101284 Fig1 Histone H1 used as substrate
PMID:8521500 PBO:0096558 Fig 1 Histone H1 used as substrate
PMID:8521500 PBO:0101285 [MOVE 'occurs at' TO M-PHASE CYCLIN] Fig1 and 2B 0.26nM pRum1 inhibits in vitro cdc2-cdc13 kinase activity by ~80%, Fig3C ig5B,C, D addition of 2.6nM rum1 reduces cdc2 associated kinase activity
PMID:8521500 PBO:0101286 Fig2C rum1+ driven by nmt1 promoter in pREP6X is integrated
PMID:8521500 PBO:0101287 Fig3A
PMID:8521500 PBO:0101288 Fig3A
PMID:8521500 PBO:0101289 Fig3A
PMID:8521500 PBO:0101289 Fig3A
PMID:8521500 PBO:0101290 Fig3A
PMID:8521500 PBO:0101291 Fig3B
PMID:8521500 PBO:0101292 Fig3B
PMID:8521500 PBO:0101293 Fig4 rum1HA pulldown brings down both cdc13 and cdc2 to form rum1-cdc13-cdc2 complex. so I really need to add 3 proteins not two in the annotation extensions
PMID:8521500 PBO:0101295 Fig 3C
PMID:8521500 PBO:0101296 Fig5A
PMID:8521500 PBO:0101297 Fig5A
PMID:8521500 PBO:0101298 FigB over expression reduces cdc2 kinase activity even in absence of added rum1 protein
PMID:8521500 PBO:0101299 Fig5B over expression abolishes cdc13 associated kinase activity even in absence of added rum1 protein
PMID:8521500 PBO:0101300 [ move to specific cyclin] Fig6 2.6nM rum1 inhibits cig2 associated cdc2 kinase activity by ~50%
PMID:8521500 PBO:0101301 Fig 6 cdc2-cig1 complex is insensitive to inhibition by rum1. There is ~100% activity in the presence of 26nM rum
PMID:8522609 FYPO:0000839 same as cdc2-33 alone
PMID:8522609 FYPO:0001418 same as orb3-167 alone
PMID:8522609 FYPO:0000647 same as orb3-167 alone
PMID:8522609 FYPO:0001018 same as orb2-34 alone
PMID:8522609 FYPO:0001018 same as orb2-34 alone
PMID:8522609 FYPO:0002021 same as orb3-167 alone
PMID:8552670 PBO:0104786 , activated_by(CHEBI:18420)
PMID:8557036 GO:0008353 assayed in S. cerevisiae cell extracts, with S.c. CTD substrate
PMID:8557036 GO:0004693 assayed in S. cerevisiae cell extracts, with S.c. CDK2 substrate
PMID:8557037 GO:0004693 activated_by(CHEBI:63041)
PMID:8569679 FYPO:0002061 fig2
PMID:8569679 FYPO:0002061 fig2
PMID:8569679 FYPO:0002061 fig2
PMID:8569679 FYPO:0002061 fig2
PMID:8569679 FYPO:0002061 fig2
PMID:8569679 FYPO:0002061 fig2
PMID:8569679 FYPO:0002061 fig2
PMID:8569679 FYPO:0002061 fig2
PMID:8590464 GO:0004043 inhibited_by L-lysine
PMID:8590465 GO:0004151 cryptic dihydroorotase domain
PMID:8590474 PBO:0095685 partial rescuie
PMID:8618924 GO:1902969 also inferred from orthology to all other Orc1s in the world
PMID:8621436 FYPO:0000158 they show it is not abnormal regulation of rereplication in cdc25 double mutant expts
PMID:8621436 FYPO:0000620 transient phenotype, they then attempt to divide without segregation
PMID:8621436 FYPO:0002303 transient phenotype, they then attempt to divide without segregation
PMID:8621436 FYPO:0000620 transient phenotype, they then attempt to divide without segregation
PMID:8621436 FYPO:0002303 transient phenotype, they then attempt to divide without segregation
PMID:8621436 FYPO:0000158 they show it is not abnormal regulation of rereplication in cdc25 double mutant expts
PMID:8649397 FYPO:0001122 Can't say if they are viable vegetative because it is in a pyp2+ background
PMID:8654750 PBO:0099148 PHEROMONE
PMID:8668131 GO:0006744 func comps S cer ABC1
PMID:8688826 GO:0034399 Val: changed from nuclear lumen to nuclear periphery
PMID:872890 PBO:0103505 Fig6, Table 2 cell size measure by protein content per cell, cells need to reach ~7pg/cell. This measurement is also the same for wild type cells which are small after nitrogen starvation (Fig5)
PMID:872890 FYPO:0006031 Table 1, Fig1
PMID:872890 PBO:0103506 Fig4, Table 2 cell size measure by protein content per cell, cells need to reach ~7pg/cell. This measurement is also the same for wild type cells which are small after spore germination (Fig3)
PMID:872890 FYPO:0006906 Fig 2 This shows that wee1-50 has a direct effect on the G2-M transition because cells now at the permissive temperature (active wee1) detect that they are too small to enter mitosis and the G2/M transition is inhibited
PMID:872890 FYPO:0006905 Fig 2 This suggests that wee1-50 only has an indirect effect on the G1-S transition because when wee1-50 is shifted to the permissive temperature cells are still small, this is not affected by the presence of active wee1 and cells enter S-phase at the same size as they did at the restrictive temperature
PMID:872890 FYPO:0006909 Table 1
PMID:872890 FYPO:0006909 Table 1, DNA replication initiated at low protein content
PMID:872890 PBO:0102251 Table 1, Fig1
PMID:872890 PBO:0093712 Fig1, data not shown cdc2-1w is called wee 2-1 in this paper. Wee cells enter mitosis at a small cell size compared to wild type cells and thus daughter cells are born smaller than wild type cells. Wee cells have similar cell cycle timing (doubling time) to wild type cells
PMID:8799335 PBO:0092041 present with ammonium, allantoin, or proline nitrogen source
PMID:8799851 PBO:0101513 Fig 9
PMID:8799851 PBO:0101512 Uses elutriation synchrony. Fig5 cdc13 protein level in synchronous culture of wee1-50 cells at restrictive temperature is absent during longer G1 phase
PMID:8799851 PBO:0101514 Fig10
PMID:8799851 PBO:0101511 Data not shown cdc13 protein level in asynchronous culture of wee1-50 cells at restrictive temperature is reduced by 40% compared to asynchronous culture of WT cells
PMID:8811082 GO:0140078 The capacity of Nth-Spo to generate strand breaks in a variety of damaged plasmid DNA substrates was investigated. Figure 4shows the activity of Nth-Spo and Nth-Eco in incising super- coiled damaged DNA. None of the proteins caused breaks in undamaged DNA.
PMID:8811082 GO:0000703 thymine glycols, urea
PMID:8824588 PBO:0105349 also has AP1 binding site
PMID:8834798 FYPO:0000117 abnormal septum forms on the surface from one side of the cell and then extends in a disor- ganized manner into the interior
PMID:8876193 PBO:0099353 Fig2
PMID:8876193 PBO:0099352 data not shown, cells blocked at G2/M, cells need to complete cell cycle to observe asymmetry
PMID:8876193 PBO:0099352 data not shown, cells blocked in absence of septation, cells need to complete cell cycle to observe asymmetry
PMID:8876193 PBO:0099354 Fig2 1% of cells still have a short mitotic spindle after 5h at restrictive temperature
PMID:8876193 PBO:0099355 Fig3
PMID:8876193 PBO:0099356 Fig3
PMID:8876193 GO:0048311 Fig4
PMID:8876193 PBO:0099352 data not shown, cells blocked in S phase, cells need to complete cell cycle to observe asymmetry
PMID:8876193 PBO:0099352 data not shown, cells blocked at G1/S, cells need to complete cell cycle to observe asymmetry
PMID:8876193 PBO:0099351 data not shown
PMID:8876193 PBO:0099350 73% asymmetric distribution at old end by 5 hours asymmetric mitochondrial aggregation at old cell end
PMID:8876193 PBO:0099349 Fig 1 77% asymmetric distribution by 5 hours, aggregation observed after 1 hour
PMID:8879048 GO:0043409 NEG REG PHEROMONE MAPK
PMID:8918598 FYPO:0005112 ubiquitin conjugate
PMID:8918598 FYPO:0005112 ubiquitin conjugate
PMID:8918880 FYPO:0002060 fig 1
PMID:8918880 FYPO:0002060 fig 1
PMID:8918880 GO:0005680 fig 5
PMID:8918880 FYPO:0002060 fig 1
PMID:8918880 FYPO:0002061 fig 1
PMID:8943330 PBO:0095167 tyrosine; position(s) not determined
PMID:8943330 GO:0000196 not sure this annotation is 100% supported, can revise later if needed.
PMID:8946912 FYPO:0002070 fig 2a
PMID:8946912 FYPO:0001234 fig 3
PMID:8946912 FYPO:0003210 fig 2a
PMID:8946912 FYPO:0001007 fig 2a
PMID:8978670 FYPO:0002023 figure 1
PMID:8978670 FYPO:0000417 figure 1
PMID:8978670 FYPO:0002024 figure 1
PMID:8978670 FYPO:0001008 figure 1
PMID:8978687 FYPO:0002060 figure 2
PMID:8978687 FYPO:0002060 figure 1a
PMID:8978687 FYPO:0001368 fig 4 b
PMID:8978687 FYPO:0002018 figure 5
PMID:8978687 FYPO:0002018 figure 5
PMID:8978687 FYPO:0001705 figure 5
PMID:8978687 FYPO:0004474 figure 5
PMID:8978687 FYPO:0005371 figure 6
PMID:8978687 PBO:0104407 fig 6 c
PMID:8978687 FYPO:0004648 fig 6 a
PMID:8978687 FYPO:0000729 fig 6 a
PMID:8978687 FYPO:0003758 fig 6 a
PMID:8978687 FYPO:0005393 fig 7
PMID:8978687 FYPO:0002049 fig 7
PMID:9024682 PBO:0024080 sporulation of homozygous diploid
PMID:9024682 PBO:0024081 sporulation of homozygous diploid
PMID:9024682 PBO:0096483 severe when both cells are cpb1delta
PMID:9034337 FYPO:0001974 Fig 3C wee cell phenotype cell cycle distribution FACS profile of vegetatively growing wee cells show a cell cycle distribution with increased number of cells with a 1C DNA content compared to wild type cells. Note the increase in the G1 peak depends on the size of the cell and semi-wee cells do not always shown an increased G1 peak
PMID:9034337 PBO:0099201 Fig 6 GST wee1 has been phosphorylated in vitro by chk1. This assay shows that phosphorylation of wee1 by chk1 does not affect wee1 kinase activity
PMID:9034337 PBO:0108717 Fig 5, Fig6
PMID:9034337 PBO:0106846 Fig 4,
PMID:9034337 FYPO:0002085 Data not shown chk1+ over expression phenotype is suppressed by over expressing cdc25+ independently of cdr1
PMID:9034337 PBO:0095634 Fig 3B
PMID:9034337 PBO:0095685 Fig 3B
PMID:9034337 FYPO:0002060 Fig 3A
PMID:9034337 PBO:0093712 Fig 3C cell elongation as a result of chk1 over expression is dependent on wee1+
PMID:9034337 FYPO:0005773 Fig 2 D
PMID:9034337 FYPO:0000444 Fig 2 D
PMID:9034337 FYPO:0001575 Fig 2 A
PMID:9034337 PBO:0106845 Fig 2C
PMID:9034337 PBO:0096052 Fig 2B Histone H1 used as cdc2 substrate Chk2 expressed from nmt1 promoter
PMID:9034337 PBO:0108716 Fig1
PMID:9042863 PBO:0108718 dephosphorylation of Cdc2 Y15 by Cdc25 delayed in response to ionising radiation
PMID:9042863 GO:0072435 Activity inhibited in response to mitotic G2 DNA damage checkpoint
PMID:9042863 FYPO:0001046 temperature permissive for wee1-50; unirradiated
PMID:9042863 FYPO:0007248 temperature restrictive for wee1-50
PMID:9062192 GO:0051728 mei2 promotes g1 arrest, premeiotic dna replication and meiosis I
PMID:9078365 FYPO:0000583 homozygous diploid
PMID:9078390 PBO:0096202 fig 2 C
PMID:9078390 PBO:0037209 fig 3a
PMID:9078390 PBO:0096204 fig 2 C
PMID:9078390 PBO:0037209 fig 3a
PMID:9078390 PBO:0096205 fig 2 C
PMID:9078390 FYPO:0002061 fig 3a
PMID:9078390 PBO:0096202 fig 2 C
PMID:9078390 PBO:0096205 fig 2 C
PMID:9078390 FYPO:0002061 fig 3a
PMID:9078390 FYPO:0002061 fig 3a
PMID:9078390 PBO:0096203 fig 2 C
PMID:9090050 PBO:0094574 inhibition by CCCP and DCCD
PMID:9092661 PBO:0110293 We found that the double mutant uvded rad2d was more resistant than a rad2d single mutant (Fig. 3).
PMID:9092661 PBO:0106872 Cell survival assay
PMID:9092661 PBO:0106872 Cell survival assay
PMID:9092661 PBO:0109839 Cell survival assay
PMID:9092661 PBO:0110294 Figure 4
PMID:9092661 PBO:0109839 Cell survival assay
PMID:9092661 PBO:0110293 Figure 2...The uvde gene disruption made cells only mildly sensitive to UV, even after high doses.
PMID:9092661 PBO:0110293 We found that the double mutant uvded rad2d was more resistant than a rad2d single mutant (Fig. 3).
PMID:9092661 PBO:0110294 Figure 4
PMID:9092661 PBO:0110295 Figure 4. The rad13d uvded double mutant cells were unable to remove either type of damage, even during 3 h post-UV incubation.
PMID:9092661 GO:0070914 We found that the double mutant uvded rad2d was more resistant than a rad2d single mutant (Fig. 3). This implies that the Rad2 protein is very important for processing nicks introduced by UVDE..........These results show that the Rad2 protein is involved only in the UVDE-mediated second pathway and that there are both rad2-dependent and rad2-independent components of the UVDE-mediated repair pathway.
PMID:9092661 PBO:0110295 Furthermore, a rad13d uvded rad2d triple disruptant had the same UV sensitivity as the rad13d uvded double disruptant.
PMID:9092661 PBO:0110294 Figure 5
PMID:9105045 PBO:0105900 cdc12 froms a cortical spot
PMID:9111307 FYPO:0003241 not sure if this is the right term, sent a question
PMID:9125114 PBO:0096500 also increased (WT overexppression) normal (WT)
PMID:9135147 PBO:0095167 tyrosine; residue not determined
PMID:9135148 PBO:0094619 inferring that residue is Y15, though not shown experimentally
PMID:9136929 PBO:0094396 not annotated to other stresses as subsequent papers show it is critical for assembly of signaling MAPKKK-MAPKKmodule
PMID:9153313 PBO:0093629 same as rad26delta alone
PMID:9153313 PBO:0093629 same as rad3delta alone
PMID:9153313 PBO:0093629 same as crb2delta alone
PMID:9154834 PBO:0105229 residue not determined, but probably Y173
PMID:9154834 FYPO:0004254 doesn't resume normally
PMID:9154834 PBO:0095824 residue not determined, but probably Y173
PMID:9154838 PBO:0032853 has condensed chromosomes
PMID:9177184 PBO:0098824 as cyclin-CDK complex with Cdc13 or Cig2
PMID:9182664 FYPO:0002845 this might be dumbbell ask Jacky
PMID:9182664 FYPO:0003413 swollen
PMID:9182664 FYPO:0002462 swollen
PMID:9191273 PBO:0099148 PHEROMONE MAPK
PMID:9200612 PBO:0097438 Fig2B C
PMID:9200612 FYPO:0001587 Fig 2C protein localised to both cell tips
PMID:9200612 FYPO:0001587 Fig 2C Protein localised to both cell tips during monopolar growth
PMID:9200612 FYPO:0001587 Fig 2D Protein localised to both cell tips during monopolar growth
PMID:9200612 PBO:0097440 Fig3A
PMID:9200612 PBO:0097449 Fig1C iii
PMID:9200612 PBO:0097448 Fig1C ii
PMID:9200612 PBO:0097436 data not shown
PMID:9200612 PBO:0097437 data not shown. 95% of cells re bent or T shaped but don't say the different percentages so I've left it as bent
PMID:9200612 FYPO:0002177 data not shown. tea1 on multi copy plasmid -R2 suppresses the cell shape defect of tea1 delta
PMID:9200612 PBO:0097439 Fig 2B,C
PMID:9200612 PBO:0096501 Fig6D
PMID:9200612 PBO:0097447 Fig 6D
PMID:9200612 PBO:0097445 Fig5C cells blocked in mitosis so have no interphase MTs
PMID:9200612 PBO:0097446 Fig5C
PMID:9200612 PBO:0097445 Fig5C
PMID:9200612 PBO:0097444 Fig5C
PMID:9200612 PBO:0037217 Fig5 shown using TBZ treatment and wash out and by cold shock and relocalization
PMID:9200612 PBO:0097442 Fig4 A
PMID:9200612 PBO:0097443 Fig4 A
PMID:9200612 PBO:0097443 Fig4 A
PMID:9200612 PBO:0097442 Fig4 A
PMID:9200612 PBO:0097441 Fig3A
PMID:9200612 PBO:0097433 Fig1C ii
PMID:9200612 PBO:0097434 Fig1C iii
PMID:9200612 PBO:0097435 Fig1C iii
PMID:9201720 PBO:0098805 physically interacts with and IMP evidence
PMID:9201720 PBO:0103195 not shown that it is ser/thr kinase activity, just that it is kinase activity
PMID:9201720 PBO:0103194 physically interacts with and IMP evidence
PMID:9211982 FYPO:0003698 truncated Gar2 accumulates in this dense body
PMID:9252327 PBO:0093560 This allele removes motif B' through E in reverse transcriptase domain of telomerase catalytic subunit. This allele showed similar delayed grow defect phenotype as trt1∆::his3+ allele that remove 99% of ORF.
PMID:9252327 PBO:0098712 Cells look normal in early generation, but show many elongated cells in later generation due to telomere shortening.
PMID:9252327 PBO:0093560 Cell growth rate is reduced in later generation due to telomere shortening. In early generation, cells growth rate is not distingushiable from trt1+ cells.
PMID:9252327 PBO:0093637 Cells show progressive telomere shortening.
PMID:9252327 PBO:0093637 This allele removes motif B' through E in reverse transcriptase domain of telomerase catalytic subunit. This allele showed similar rate of telomere shortening as trt1∆::his3+ allele that remove 99% of ORF.
PMID:9252327 PBO:0098712 This allele removes motif B' through E in reverse transcriptase domain of telomerase catalytic subunit. This allele showed similar extent of delayed cell elongation phenotype as trt1∆::his3+ allele that remove 99% of ORF.
PMID:9278510 PBO:0037311 fig 2 b
PMID:9278510 PBO:0037311 fig 2 b
PMID:9278510 FYPO:0004259 fig 1
PMID:9285594 GO:0000796 Fig 1
PMID:9285594 GO:0000796 Fig 1
PMID:9285594 PBO:0101680 in vitro
PMID:9287302 GO:0036245 vw: I deleted accidintally , then readded
PMID:9287302 GO:0036245 vw: I deleted accidintally , then readded
PMID:9301023 FYPO:0002519 (Figure 2b)
PMID:9301023 PBO:0098600 (Figure 2a)
PMID:9301025 FYPO:0002060 just getting the allele in the database (they used it in the exp)
PMID:9303310 PBO:0096937 Fig2
PMID:9303310 PBO:0096939 Fig2, Fig3
PMID:9303310 PBO:0096940 Fig2, Fig3
PMID:9303310 PBO:0096941 Fig5 (vw, I edited the extensions)
PMID:9303310 PBO:0096942 Fig 8 added by cig1 associated CDK1
PMID:9303310 PBO:0096943 Fig7B
PMID:9303310 FYPO:0000333 Fig7A
PMID:9303310 PBO:0096936 Fig 1 exponentially growing cells mainly in G2
PMID:9303310 PBO:0096936 Fig 1 cells blocked in G1 at the restrictive temp
PMID:9303310 PBO:0096938 Fig2
PMID:9303312 PBO:0105913 Fig7 res2 on multi copy pREP3X ON
PMID:9303312 PBO:0105902 Fig 1A and C cdc18 transcription is not dependent on cdc2 function
PMID:9303312 PBO:0105903 Fig 1 B cdc2-M26 has no detectable kinase activity in G1 at restrictive temperature
PMID:9303312 PBO:0105904 Fig 1D cdc2-M26 does not enter S phase even though cdc18 transcription is presence
PMID:9303312 PBO:0037892 Fig2 B
PMID:9303312 PBO:0101286 Fig2 B
PMID:9303312 PBO:0101286 Fig2 B cells do not undergo re replication at restrictive temperature
PMID:9303312 PBO:0105905 Fig2A cells do not undergo re replication at restrictive temperature but cdc18 transcript increases
PMID:9303312 PBO:0105902 Fig2 B
PMID:9303312 PBO:0105906 Fig3A cdc18 transcript accumulates in absence of cig1, cig2 and cdc13
PMID:9303312 PBO:0105906 Fig3A cdc18 transcript accumulates in absence of cdc13
PMID:9303312 PBO:0105907 Fig3B cdc18 protein accumulates in absence of cig1, cig2 and cdc13
PMID:9303312 PBO:0105908 Fig3C no DNA replication in absence of all 3 cyclins
PMID:9303312 PBO:0105909 Fig3C DNA replication in presence of cig1 and cig2
PMID:9303312 PBO:0105910 Fig3C Abnormal DNA replication with cut DNA replication in absence cig1, cig2 and cdc13 promoter ON some cells have a cut phenotype. NOT sure the data warrants an annotation
PMID:9303312 PBO:0105911 Fig3C, D Absence of cdc2 kinase activity in absence cig1, cig2 and cdc13
PMID:9303312 PBO:0105912 Fig3C, D cdc13 promoter ON cdc2 kinase activity acts after the accumulation of cdc18 protein to bring about the G1/S transition
PMID:9303312 PBO:0105913 Fig4B decreased cdc18 transcript level as cells proceed through S phase and G2 and increases as cell go though G1
PMID:9303312 PBO:0105906 Fig 4C Cdc2 not required for active cdc10 dependent transcription during S phase
PMID:9303312 PBO:0105913 Fig 4C Cdc18 transcript is low during G2
PMID:9303312 PBO:0105913 Fig 4C Cdc18 transcript is low during G2
PMID:9303312 PBO:0105914 Cdc2 kinase activity is low during G2 data not shown
PMID:9303312 FYPO:0003246 Fig 4D
PMID:9303312 FYPO:0003246 Fig 4D
PMID:9303312 PBO:0094078 Fig3C Abnormal DNA replication with cut DNA replication in absence cig1, cig2 and cdc13 promoter ON some cells have a cut phenotype. NOT sure the data warrants an annotation
PMID:9303312 PBO:0105923 Fig2 B
PMID:9303312 PBO:0105922 Fig8 C
PMID:9303312 PBO:0105922 Fig8 C
PMID:9303312 PBO:0105921 Fig8 Presence of MBF is correlated with cdc10 dependent transcription repression during G2
PMID:9303312 PBO:0105921 Fig8 Presence of MBF is correlated with cdc10 dependent transcription repression during G2
PMID:9303312 PBO:0105921 Fig8 Presence of MBF is correlated with cdc10 dependent transcription repression during G2
PMID:9303312 PBO:0105921 Fig8 Presence of MBF is correlated with cdc10 dependent transcription repression during G2
PMID:9303312 PBO:0105920 Fig 5, 6, 7,
PMID:9303312 PBO:0105919 Fig 5, 6, 7,
PMID:9303312 PBO:0105918 Fig8B DSC1 is now called MBF
PMID:9303312 PBO:0105918 Fig8 DSC1 is now called MBF
PMID:9303312 PBO:0105918 Fig8B DSC1 is now called MBF
PMID:9303312 PBO:0105918 Fig8 DSC1 is now called MBF
PMID:9303312 PBO:0105913 Fig7 res2 on multi copy pREP3X ON
PMID:9303312 PBO:0105917 Fig7
PMID:9303312 PBO:0098713 Fig7 res1 on multi copy pREP3X ON
PMID:9303312 PBO:0105915 Fig7 res1 on multi copy pREP3X ON
PMID:9303312 PBO:0105916 Fig7 res1 on multi copy pREP3X ON
PMID:9303312 PBO:0105913 Data not shown
PMID:9303312 PBO:0105915 Fig6B
PMID:9303312 PBO:0098716 Fig6B
PMID:9303312 PBO:0105915 Fig6D
PMID:9303312 PBO:0098716 Fig6D
PMID:9303312 PBO:0098713 Fig6C
PMID:9303312 PBO:0105915 Fig6C
PMID:9303312 PBO:0105913 Fig6A cdc18 transcript maximal around peak of septation
PMID:9303312 PBO:0105905 Fig5C rep2delta has no effect on cdc18 transcript levels in the absence of res2
PMID:9303312 FYPO:0004235 Fig 5C
PMID:9303312 PBO:0105905 Fig5A, B level of cdc18 transcript does not decreased after release from HU block
PMID:9303312 PBO:0098715 Fig5A, B decreased cdc18 transcript in HU block and on release
PMID:9303312 PBO:0098715 Fig5A decreased cdc18 transcript in HU block and on release
PMID:9303312 PBO:0098715 Fig5A, B decreased cdc18 transcript in HU block and on release
PMID:9312055 PBO:0102750 fig 4 b-d
PMID:9312055 FYPO:0001946 fig 1c
PMID:9312055 FYPO:0002061 fig 3b
PMID:9312055 FYPO:0002061 fig 3b
PMID:9312055 PBO:0102752 fig9
PMID:9312055 MOD:01148 poly...
PMID:9312055 PBO:0020076 fig7
PMID:9312055 PBO:0096939 fig 6
PMID:9312055 PBO:0102751 fig 6
PMID:9312055 PBO:0102749 fig 4a
PMID:9312055 PBO:0099779 fig 4
PMID:9312055 FYPO:0003165 fig 1c
PMID:9312055 PBO:0102748 fig 4
PMID:9312055 FYPO:0002060 fig 3b (rescue)
PMID:9312055 FYPO:0002061 fig 3b (rescue)
PMID:9312055 FYPO:0002061 fig 3b
PMID:9312055 PBO:0095634 fig 1b
PMID:9312055 FYPO:0002060 fig 2 (synthetic rescue)
PMID:9312055 FYPO:0002060 fig 2 (synthetic rescue)
PMID:9312055 FYPO:0002061 fig 2
PMID:9312055 FYPO:0002061 fig 1b
PMID:9312055 FYPO:0003165 fig 1c
PMID:9312055 FYPO:0002061 fig 1b
PMID:9312055 FYPO:0002061 fig 1b
PMID:9312055 FYPO:0003165 fig 1c
PMID:9312055 FYPO:0001946 fig 1c
PMID:9312055 FYPO:0002060 fig 1b
PMID:9312055 FYPO:0001946 fig 1c
PMID:9312055 PBO:0102753 fig9
PMID:9315645 GO:0062038 "This one comes in ""from the side"", see Ladds, Bond post 2010 publication summary"
PMID:9315645 PBO:0102572 fig7, sort of indirect - kinase dead mutant doesn't activate
PMID:9321395 PBO:0097481 data not shown
PMID:9321395 FYPO:0001492 (Figure 4)
PMID:9321395 PBO:0097481 (Figure 5)
PMID:9321395 PBO:0097481 (Figure 5)
PMID:9321395 PBO:0097481 (Figure 5)
PMID:9321395 FYPO:0000082 (Figure 4)
PMID:9321395 GO:0038066 An increased level of phosphotyrosine was detected on Spc1 in wis1 cells overexpressing Wis4∆N, but not in wis1∆ cells, indicating that the action of Wis4 is Wis1- dependent.
PMID:9321395 FYPO:0002177 not shown
PMID:9321395 PBO:0097481 (Figure 5)
PMID:9321395 FYPO:0001492 (Figure 4)
PMID:9321395 FYPO:0000271 (Figure 4)
PMID:9325108 GO:0008821 activated_by(CHEBI:18420)| activated_by(CHEBI:29035)
PMID:9325304 FYPO:0000620 3B
PMID:9325304 FYPO:0006477 3B
PMID:9325304 GO:0010498 via purification assay
PMID:9325304 GO:0010498 via purification assay
PMID:9325316 GO:0001055 author intent
PMID:9325316 GO:0006366 author intent
PMID:9325316 GO:0001055 author intent
PMID:9325316 GO:0003677 binds DNA in complex (2,3,11)
PMID:9325316 GO:0003677 binds DNA in complex (2,3,11)
PMID:9325316 GO:0003677 binds DNA in complex (2,3,11)
PMID:9325316 GO:0003677 binds DNA on its own
PMID:9325316 GO:0001055 author intent
PMID:9325316 GO:0001055 author intent
PMID:9325316 GO:0006366 author intent
PMID:9325316 GO:0006366 author intent
PMID:9325316 GO:0006366 author intent
PMID:9371883 PBO:0107553 two-hybrid assay
PMID:9371883 PBO:0107554 two-hybrid assay
PMID:9371883 PBO:0107553 two-hybrid assay
PMID:9371883 PBO:0107554 two-hybrid assay
PMID:9372936 FYPO:0000838 assayed using SV40 NLS-GFP-LacZ reporter protein
PMID:9372936 FYPO:0001355 same as rae1-167 single mutant
PMID:9372936 FYPO:0000838 assayed using SV40 NLS-GFP-LacZ reporter protein
PMID:9372936 FYPO:0001355 same as rae1-167 single mutant
PMID:9398669 FYPO:0000303 add penetrance?
PMID:9398669 PBO:0033959 fig 5c switched from conjugtion freqeuncy to sterility as can only capture penetance on cell phenotypes
PMID:9398669 PBO:0095554 nitrogen induced arrest
PMID:9398669 PBO:0095551 because slp1 can bypass wee1 it must independently inhibit cd2
PMID:9398669 PBO:0095555 G1 phase nitrogen induced arrest
PMID:9398669 PBO:0095551 because slp1 can bypass wee1 it must independently inhibit cd2
PMID:9398669 FYPO:0001425 fig 5a
PMID:9420333 PBO:0103702 (IN gthis paper we don't actually know that it's the new one, that comes later, but ...)cdc7 is associated with both SPBs when a short spindle is present
PMID:9420333 PBO:0103703 (GTP bound)
PMID:9420333 PBO:0110201 (GTP bound)
PMID:9420333 PBO:0110202 (GTP bound)
PMID:9420333 PBO:0018634 Fig3A,C spg1-HA observed at SPB throughout the mitotic cell cycle
PMID:9420333 PBO:0023023 Fig3A,C spg1-HA observed at SPB throughout the mitotic cell cycle
PMID:9420333 PBO:0103697 Fig5A
PMID:9420333 PBO:0103697 Fig5A
PMID:9420333 PBO:0103701 cdc7 is associated with both SPBs when a short spindle is present
PMID:9420333 PBO:0103698 Fig5B
PMID:9420333 PBO:0103699 Fig 6A in late anaphase cdc7 is normally localized only one SPB
PMID:9420333 PBO:0103694 "Fig 1 vw interpretation for ""active form"""
PMID:9420333 PBO:0103700 Fig 6C in late anaphase cdc7 is normally localized only one SPB
PMID:9420333 PBO:0103695 Fig2A loss of cdc16 function does not affect cdc7 kinase activity
PMID:9420333 PBO:0103695 Fig2A loss of spg1 function does not affect cdc7 kinase activity
PMID:9428701 GO:0004722 MBP substrate, activated_by(CHEBI:29035)
PMID:9430640 PBO:0096366 Fig 4B inhibitory for cdc2/cdc13 and cdc2/cig2 but not cdc2/cig1. Both Rum1+ and Rum1-A58A62 can inhibit cdk1 activity
PMID:9430640 MOD:00047 Fig3C
PMID:9430640 PBO:0096367 Fig5B
PMID:9430640 PBO:0096368 Fig6
PMID:9430640 PBO:0096369 Fig7, Fig8 cdc2-cig1 complex efficiently phosphorylates rum1 T58T62 residues in vivo . Phosphorylation by cdc2-cig2 or cdc2-cdc13 only observed after a very long exposure
PMID:9430640 PBO:0096370 Fig 10
PMID:9430640 PBO:0096369 Fig7, Fig8 cdc2-cig1 complex efficiently phosphorylates rum1 T58T62 residues in vivo . Phosphorylation by cdc2-cig2 or cdc2-cdc13 only observed after a very long exposure
PMID:9430640 PBO:0096377 this isn't quite the right way to capture this target, still thinking
PMID:9430640 PBO:0096377 this isn't quite the right way to capture this target, still thinking
PMID:9430640 PBO:0096361 Fig5
PMID:9430640 PBO:0092114 Fig1B
PMID:9430640 PBO:0096372 Fig 4B inhibitory for cdc2/cdc13 and cdc2/cig2 but not cdc2/cig1. Both Rum1+ and Rum1-A58A62 can inhibit cdk1 activity
PMID:9430640 PBO:0092211 Fig1B
PMID:9430640 PBO:0096371 Fig7B rum1 A58A62 mutant protein is unable to be phosphorylated by cdc2/cig1
PMID:9430640 PBO:0096362 Fig1C Peaks at the end of G2 40 min before peak of rum1 protein
PMID:9430640 PBO:0092393 Fig1B
PMID:9430640 PBO:0096363 Fig2
PMID:9430640 MOD:01148 Fig2
PMID:9430640 PBO:0094205 Fig3, data not shown phenotype similar to rum+OP
PMID:9430640 PBO:0095634 Fig3B, similar to rum1+OP more severe than either single mutant. expressed from muliticopy plasmid. Colonies were integrants
PMID:9430640 PBO:0096365 Fig3C integrated copy
PMID:9450991 FYPO:0000016 figure 1A
PMID:9450991 FYPO:0001418 30x figure 4B
PMID:9450991 FYPO:0001490 figure 4B
PMID:9450991 FYPO:0002061 fig 4A
PMID:9450991 FYPO:0004702 figure 2A/B
PMID:9450991 FYPO:0003166 figure 1A
PMID:9450991 FYPO:0003166 figure 1A
PMID:9450991 PBO:0033643 figure 1A
PMID:9450991 PBO:0103183 figure 1A
PMID:9459302 PBO:0035607 is this OK? its aseptate?
PMID:9468529 GO:0008444 inhibited_by CHEBI:29035
PMID:9488736 PBO:0096790 looks very likely it is a ser/thr kinase, but if anything comes up that contradicts it this annotation can be made less specific
PMID:9491802 FYPO:0002061 expressed Clostridium botulinum C3 protein to ADP-ribosylate Rho proteins including Rho1
PMID:9524127 PBO:0106211 (Fig. 3a)
PMID:9524127 PBO:0106211 (Fig. 3a)
PMID:9524127 PBO:0106211 (Fig. 3a)
PMID:9524127 PBO:0106211 (Fig. 3a)
PMID:9524127 PBO:0106211 (Fig. 3a)
PMID:9524127 PBO:0105150 (Fig. 3a)
PMID:9524127 PBO:0106211 (Fig. 3a)
PMID:9524127 PBO:0105150 (Fig. 3)
PMID:9524127 PBO:0106212 (Fig. 3a)
PMID:9531532 FYPO:0002061 over 35
PMID:9531532 FYPO:0000276 over 25
PMID:9531532 FYPO:0002060 over 25
PMID:9531532 FYPO:0002061 over 25
PMID:9531532 FYPO:0002061 over 25
PMID:9535817 FYPO:0005288 inferred from FYPO:0000825, FYPO:0001117, FYPO:0005743, FYPO:0007674 phenotypes (including conditions)
PMID:9552380 GO:0000307 cig2-cdc2
PMID:9560390 FYPO:0001122 osmotic stress
PMID:9560390 FYPO:0001122 osmotic stress
PMID:9571240 FYPO:0000398 fig3
PMID:9571240 FYPO:0001054 4e
PMID:9571240 FYPO:0003012 4e
PMID:9571240 GO:2000134 Ste9 was indispensable for the growth of the wee1 cells, which had to lengthen the pre-Start G1 period to restrain DNA synthesis until the critical size to override Start control was attained....Ste9 might be required for main- tenance of the Cdc2 kinase in a pre-Start form, suggested by the fact that overexpression of Ste9 in- duced rereplication of the genome due to reduction of the mitotic kinase activity of the Cdc13/Cdc2 com- plex, and rereplication in the cdc2ts strain was pre- vented by the ste9 mutation.
PMID:9572736 FYPO:0001492 Fig. 4
PMID:9572736 FYPO:0000963 Fig. 5B
PMID:9572736 PBO:0093580 Fig. 5B
PMID:9572736 PBO:0093580 Fig. 5B
PMID:9572736 PBO:0093581 Fig. 5B
PMID:9572736 FYPO:0005189 Fig. 5A
PMID:9572736 FYPO:0005189 Fig. 5A
PMID:9572736 FYPO:0005189 Fig. 5A
PMID:9572736 FYPO:0003503 Fig. 4
PMID:9572736 FYPO:0003503 Fig. 4
PMID:9572736 FYPO:0001492 Fig. 4
PMID:9572736 FYPO:0001492 Fig. 4
PMID:9572736 FYPO:0003503 Fig. 4
PMID:9572736 FYPO:0003503 Fig. 4
PMID:9572736 FYPO:0003503 Fig. 4
PMID:9572736 FYPO:0003503 Fig. 4
PMID:9572736 FYPO:0000088 Fig. 3D
PMID:9572736 PBO:0112273 Fig. 3C
PMID:9572736 PBO:0112273 Fig. 3C
PMID:9572736 PBO:0092345 Fig. 3C
PMID:9572736 PBO:0112272 Fig. 3B
PMID:9572736 PBO:0112271 Fig. 2B
PMID:9572736 PBO:0112270 Fig. 2A
PMID:9572736 PBO:0112270 Fig. 2A
PMID:9572736 PBO:0112270 Fig. 2A
PMID:9572736 PBO:0112269 Fig. 1C
PMID:9572736 PBO:0112268 Fig. 1C
PMID:9572736 PBO:0112267 Fig. 1C
PMID:9585506 GO:0005515 western but we know this happens and I wanted to capture the extension
PMID:9585506 FYPO:0001490 salt stress
PMID:9585506 GO:0005515 western but we know this happens and I wanted to capture the extension
PMID:9585506 FYPO:0001490 salt stress
PMID:9585506 FYPO:0001490 salt stress
PMID:9585506 FYPO:0001490 salt stress
PMID:9599405 PBO:0099148 PEHROMONE
PMID:9601094 FYPO:0001357 figure 6
PMID:9601094 PBO:0102021 Fig 3C at metaphase/anaphase transiton
PMID:9601094 PBO:0102020 (Fig. 4D
PMID:9601094 FYPO:0000964 dph1∆ cells were not hypersensitive to TBZ, compared to wild-type cells (Fig. 6C)
PMID:9601094 PBO:0102019 fig 4B
PMID:9601094 PBO:0102018 fig 4B
PMID:9601094 FYPO:0003903 fig 4B
PMID:9601094 PBO:0093562 Figure 4A
PMID:9601094 FYPO:0001357 medium level of mph1 OEX (high is lethal)
PMID:9601094 PBO:0102017 fig 2D
PMID:9601094 FYPO:0000620 Fig 3C at metaphase/anaphase transiton
PMID:9601094 FYPO:0001399 figure 6
PMID:9601094 FYPO:0001399 figure 6
PMID:9606213 PBO:0099406 (slightly increased- In fact, more cells had staining at their tips than wild-type cells, probably indicating a prolonged attempt to conjugate, after which the protein delocalizes)
PMID:9606213 GO:0043332 By immunofluorescence, these antibod- ies stained a single dot at the very tip of each cell in wild- type pre-zygotes (Fig. 2, C and D).
PMID:9606213 PBO:0107899 Therefore, in a h90 mam2 strain, the P cells will attempt mating, but the M cells will be unable to respond due to the lack of the P-factor receptor, and so the cells will fail to initiate fusion
PMID:9606213 PBO:0107897 polarization, in shmoo DNS
PMID:9606213 FYPO:0000573 fig1
PMID:9606213 FYPO:0000573 fig1
PMID:9606213 PBO:0107897 polarization, during conjugation, in shmoo fig1. We interpret the data as indicating that F-actin is first cor- rectly localized to the tip in all fus1 mutants, but is then re- distributed after a defective attempt to fuse. Thus, it is likely that Fus1 is required for the correct organization and stabilization of polarized F-actin at the tip, but is no
PMID:9606213 PBO:0107898 DNS actin distributed in cytoplasm
PMID:9606213 FYPO:0000573 fig1
PMID:9606213 PBO:0099406 In fact, more cells had staining at their tips than wild-type cells, probably indicating a prolonged attempt to conjugate, after which the protein delocalizes
PMID:9606213 PBO:0107900 fig7
PMID:9606213 PBO:0099406 (slightly increased- In fact, more cells had staining at their tips than wild-type cells, probably indicating a prolonged attempt to conjugate, after which the protein delocalizes)
PMID:9614176 PBO:0099121 Fig1 A
PMID:9614176 PBO:0099123 Fig4 - sows proteasome involvment as well
PMID:9614176 PBO:0099121 Fig3D loss of cig2 does not restore P factor induced G1 arrest
PMID:9614176 PBO:0099122 Fig3 A In absence of rum1 cdc2-cdc13 kinase activity remains high in presence of P factor
PMID:9614176 PBO:0099124 Fig5A
PMID:9614176 PBO:0099126 Fig5C
PMID:9614176 PBO:0099125 Fig5B
PMID:9614176 PBO:0099127 Fig5C
PMID:9614176 PBO:0099128 Fig5C
PMID:9614176 PBO:0099127 Fig5C
PMID:9614176 PBO:0099129 Fig6A transcript assayed was Mat1-Mm
PMID:9614176 PBO:0099130 Fig4
PMID:9614176 GO:0031568 Fig2B after addition of P factor to nitrogen starved G1 arrested cells P factor does not further increase rum1 protein level. It is inferred that rum1 is required to maintain G1 arrest rather than bring it about.
PMID:9614178 PBO:0106874 residue not determined experimentally, but probably Y173
PMID:9614178 PBO:0100943 residue not determined experimentally, but probably Y173
PMID:9614178 PBO:0103795 residue not determined experimentally, but probably Y173
PMID:9614178 PBO:0103795 residue not determined experimentally, but probably Y173
PMID:9614178 PBO:0095827 residue not determined experimentally, but probably Y173
PMID:9614178 PBO:0100943 residue not determined experimentally, but probably Y173
PMID:9622480 PBO:0097034 very mild as shown in xp
PMID:9635188 PBO:0018634 independent of F-actin (assayed using Latrunculin A)
PMID:9635188 PBO:0019716 independent of F-actin (assayed using Latrunculin A)
PMID:9635188 FYPO:0002061 29 degrees; permissive for either single mutant
PMID:9635188 GO:0110085 dependent on F-actin (assayed using Latrunculin A)
PMID:9635188 PBO:0018346 independent of F-actin (assayed using Latrunculin A)
PMID:9635188 FYPO:0002060 24 degrees
PMID:9635190 FYPO:0005000 fig 5 during interphase
PMID:9635190 FYPO:0004754 fig 5 during mitotic M-phase
PMID:9635190 FYPO:0000783 fig 5 during mitotic M-phase
PMID:9635190 FYPO:0000783 fig 5 during mitotic M-phase
PMID:9635190 FYPO:0000783 fig 5 during mitotic M-phase
PMID:9635190 FYPO:0000783 fig 5 during mitotic M-phase
PMID:9635190 FYPO:0000783 fig 5 during mitotic M-phase
PMID:9635190 PBO:0033730 Figure 4b
PMID:9635190 FYPO:0001179 cytoplasm in interphase (Figure 4a, I)
PMID:9635190 PBO:0095293 Figure 2c
PMID:9635190 PBO:0095292 Figure 2b
PMID:9635190 PBO:0095291 (Fig 1i)
PMID:9635190 PBO:0095288 (Fig 1i)
PMID:9635190 PBO:0095290 Figure 2a
PMID:9635190 FYPO:0000783 fig 5 during mitosis
PMID:9635190 FYPO:0001179 cytoplasm during interphase (with nuclear localization)
PMID:9636183 PBO:0095711 same severity as wee1-50 alone
PMID:9658208 FYPO:0002060 just to get the allele details of -P in the database
PMID:9660817 FYPO:0001147 data not shown
PMID:9660817 PBO:0093824 data not shown
PMID:9660817 FYPO:0000708 data not shown
PMID:9660818 GO:0016020 including plasma membrane (GO:0005886)
PMID:9660818 PBO:0100579 assayed using myelin basic protein; interaction shown in separate experiment
PMID:9660818 PBO:0093824 same severity when crossed with wild type or shk1delta
PMID:9660818 PBO:0093825 when crossed with partner overexpressing shk1-deltaN; normal in cross with wild type
PMID:9660818 PBO:0093825 when crossed with shk1delta overexpressing shk2+ or wild type
PMID:9660818 GO:0004674 assayed using myelin basic protein
PMID:9671458 PBO:0103267 h90 background
PMID:9671458 PBO:0103268 h- background
PMID:9671458 PBO:0097017 assayed in both h- and h90 backgrounds
PMID:9679144 PBO:0019143 Fig 3A-C pre NETO blocked cells do not branch if TBZ is added at shift down
PMID:9679144 FYPO:0000672 Fig2C arrest released cells have NETO defect and do not branch.
PMID:9679144 PBO:0038218 Fig2C arrest released cells are pre NETO but only branch at low level.
PMID:9679144 PBO:0095940 Fig2C cells were pre NETO after temperature block about 5% cells are already branched at release
PMID:9679144 PBO:0095940 Fig2C cells were pre NETO after temperature block about 5% cells are already branched at release
PMID:9679144 PBO:0095939 Fig2B cells were pre NETO after temperature block
PMID:9679144 PBO:0095938 Fig2B cells were pre NETO after temperature block
PMID:9679144 PBO:0095936 Fig2 B cells were pre NETO after temperature block
PMID:9679144 PBO:0095937 Fig2A cdc25-22 arrest released cells ie post NETO do not branch
PMID:9679144 PBO:0095936 Fig1 F, H cells were pre NETO after temperature block
PMID:9679144 PBO:0095944 Fig 9 tea1 can relocalise to cell ends in absence of microtubules
PMID:9679144 PBO:0019143 Fig 3C cell length does not affect branching showing its not because cells are longer at high temp
PMID:9679144 PBO:0095941 Fig 4 Short interphase microtubules located in the cell centre
PMID:9679144 PBO:0095945 Fig 11 absence of microtubules
PMID:9679144 PBO:0095945 Fig 11 in the absence of microtubules and actin
PMID:9679144 PBO:0095946 Fig5 C,D Fig 12 Normal protein localisation in presence of TBZ
PMID:9679144 PBO:0095942 Fig5 C,D
PMID:9679144 PBO:0095943 Fig 8A-D Actin relocalisation to old or new cell end after microtubule disruption
PMID:9679144 FYPO:0007379 Fig 6 abnormal septum in branched cell
PMID:9679144 PBO:0095181 Fig 6 F-actin localised to branch site in presence of TBZ
PMID:9693363 FYPO:0003694 increased 25S/18S ration
PMID:9693384 PBO:0095827 probably Y173, but not determined experimentally
PMID:9693384 PBO:0097481 probably Y173, but not determined experimentally
PMID:9693384 PBO:0097481 probably Y173, but not determined experimentally
PMID:9718372 PBO:0100943 probably Y173, but not determined experimentally
PMID:9718372 PBO:0095349 probably Y173, but not determined experimentally
PMID:9718372 PBO:0100951 probably Y173, but not determined experimentally
PMID:9722643 FYPO:0000091 fig5
PMID:9722643 GO:0005634 fig4
PMID:9722643 PBO:0103534 fig3
PMID:9722643 FYPO:0001840 table2
PMID:9722643 FYPO:0000472 fig2
PMID:9722643 FYPO:0002060 fig1
PMID:9739083 PBO:0104512 Fig 6. cdc18 expressed from nmt1 promoter on multi copy plasmid
PMID:9739083 FYPO:0000402 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0000402 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0000402 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0000402 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0001052 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0005773 Fig 2A cdc18 expressed from pREP3X and assayed after 20 hours after removal of thiamine at 32°C
PMID:9739083 FYPO:0000402 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0000402 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0000402 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0000402 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0001052 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0001122 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0005773 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0005773 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0005773 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0002519 Data not shown Cdc18 expressed from nmt1 promoter on multi copy plasmid
PMID:9739083 FYPO:0005773 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0005773 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0005773 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0005773 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0005773 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0001122 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0001122 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0005773 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0005773 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0005773 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 FYPO:0002995 Data not shown Cdc18 expressed from nmt1 promoter on multi copy plasmid
PMID:9739083 FYPO:0002061 cdc18-1-141 when expressed on multi copy plasmid does not rescue cdc18-K46
PMID:9739083 FYPO:0002061 cdc18-150-577 when expressed on multi copy plasmid does not rescue cdc18-K46
PMID:9739083 FYPO:0002061 cdc18-150-577(T374A) when expressed on multi copy plasmid does not rescue cdc18-K46
PMID:9739083 FYPO:0002061 cdc1-577 (NTP) when expressed on multi copy plasmid does not rescue cdc18-K46
PMID:9739083 PBO:0097659 Fig 2A cdc18 expressed from pREP3X and assayed after 20 hours after removal of thiamine at 32°C
PMID:9739083 PBO:0097659 Fig 2A cdc18 expressed from pREP3X and assayed after 20 hours after removal of thiamine at 32°C
PMID:9739083 PBO:0097659 Fig 2A cdc18 expressed from pREP3X and assayed after 20 hours after removal of thiamine at 32°C
PMID:9739083 PBO:0104509 Fig 5 cdc18 expressed from nmt1 promoter on multi copy plasmid. Cells grown in absence of thiamine for 20 hours then shifted to 25°C or 36°C and followed for 3 generations
PMID:9739083 PBO:0097659 Fig 2A cdc18 expressed from pREP3X and assayed after 20 hours after removal of thiamine at 32°C
PMID:9739083 PBO:0102340 Fig 2B cdc18 expressed from pREP3X and assayed after 20 hours after removal of thiamine at 32°C
PMID:9739083 PBO:0104505 Fig2B cdc18 expressed from pREP3X and assayed after 20 hours after removal of thiamine at 32°C
PMID:9739083 PBO:0096052 Fig 3 the kinase assay substrate used is Histone H1
PMID:9739083 PBO:0096053 Fig 3 the kinase assay substrate used is Histone H1
PMID:9739083 PBO:0096053 data not shown the kinase assay substrate used is Histone H1
PMID:9739083 PBO:0104510 Fig 5 cdc18 expressed from nmt1 promoter on multi copy plasmid. Cells grown in absence of thiamine for 20 hours then shifted to 25°C or 36°C and followed for 3 generations
PMID:9739083 PBO:0104511 Fig 5 cdc18 expressed from nmt1 promoter on multi copy plasmid. Cells grown in absence of thiamine for 20 hours then shifted to 25°C or 36°C and followed for 3 generations
PMID:9739083 PBO:0100985 Fig 6. cdc18 expressed from nmt1 promoter on multi copy plasmid
PMID:9739083 PBO:0104511 Fig 5 cdc18 expressed from nmt1 promoter on multi copy plasmid. Cells grown in absence of thiamine for 20 hours then shifted to 25°C or 36°C and followed for 3 generations
PMID:9739083 PBO:0104512 Fig 5 cdc18 expressed from nmt1 promoter on multi copy plasmid. Cells grown in absence of thiamine for 20 hours then shifted to 25°C or 36°C and followed for 3 generations
PMID:9739083 PBO:0104513 Fig 5 cdc18 expressed from nmt1 promoter on multi copy plasmid. Cells grown in absence of thiamine for 20 hours then shifted to 25°C or 36°C and followed for 3 generations
PMID:9739083 PBO:0104514 Fig 5 cdc18 expressed from nmt1 promoter on multi copy plasmid. Cells grown in absence of thiamine for 20 hours then shifted to 25°C or 36°C and followed for 3 generations
PMID:9739083 FYPO:0005773 Fig 4 cdc18 expressed from nmt1 on multi copy plasmid
PMID:9739083 PBO:0104508 Fig 3 not strictly a co-immunoprecitation experiment as they used suc1 beads to pull down cdc2 then a western blot
PMID:9739083 PBO:0104507 Fig 3 not strictly a co-immunoprecitation experiment as they used suc1 beads to pull down cdc2 then a western blot
PMID:9739083 PBO:0104506 Fig 3 cdc18 expressed from pREP3X and assayed for 20 hours after removal of thiamine at 32°C
PMID:9739083 PBO:0096363 Fig 3 cdc18 expressed from pREP3X and assayed for 20 hours after removal of thiamine at 32°C
PMID:9739083 PBO:0096363 Fig 3 cdc18 expressed from pREP3X and assayed for 20 hours after removal of thiamine at 32°C
PMID:9739083 PBO:0104513 Fig 5 cdc18 expressed from nmt1 promoter on multi copy plasmid. Cells grown in absence of thiamine for 20 hours then shifted to 25°C or 36°C and followed for 3 generations
PMID:9739083 PBO:0104515 Fig 5 cdc18 expressed from nmt1 promoter on multi copy plasmid. Cells grown in absence of thiamine for 20 hours then shifted to 25°C or 36°C and followed for 3 generations
PMID:9739083 PBO:0104511 Fig 5 cdc18 expressed from nmt1 promoter on multi copy plasmid. Cells grown in absence of thiamine for 20 hours then shifted to 25°C or 36°C and followed for 3 generations
PMID:9739083 PBO:0104509 Fig 6 cdc18 expressed from nmt1 promoter on multi copy plasmid. cells examined after 20 h after thiamine removal.
PMID:9739083 PBO:0104511 Fig 6 cdc18 expressed from nmt1 promoter on multi copy plasmid. cells examined after 20 h after thiamine removal.
PMID:9739083 PBO:0104510 Fig 6. cdc18 expressed from nmt1 promoter on multi copy plasmid
PMID:9739083 PBO:0104511 Fig 6. cdc18 expressed from nmt1 promoter on multi copy plasmid
PMID:9739083 PBO:0099432 Fig 6 and cell phenotype data not shown. cdc18 expressed from nmt1 promoter on multi copy plasmid
PMID:9739083 PBO:0104518 Fig 6. cdc18 expressed from nmt1 promoter on multi copy plasmid
PMID:9739083 PBO:0104512 Fig 6. cdc18 expressed from nmt1 promoter on multi copy plasmid
PMID:9739083 PBO:0104512 Fig 6. cdc18 expressed from nmt1 promoter on multi copy plasmid
PMID:9739083 PBO:0104514 Fig 6 cdc18 expressed from nmt1 promoter on multi copy plasmid. cells examined after 20 h after thiamine removal.
PMID:9739083 PBO:0104515 Fig 6 cdc18 expressed from nmt1 promoter on multi copy plasmid. cells examined after 20 h after thiamine removal.
PMID:9739083 PBO:0104509 Fig 6 cdc18 expressed from nmt1 promoter on multi copy plasmid. cells examined after 20 h after thiamine removal.
PMID:9739083 PBO:0104516 Fig 6. cdc18 expressed from nmt1 promoter on multi copy plasmid
PMID:9739083 PBO:0104517 Fig 6. cdc18 expressed from nmt1 promoter on multi copy plasmid
PMID:9740803 GO:0061608 actually combination of in vitro assay, interactions, and sequence similarity
PMID:9740803 PBO:0103363 also assayed with GFP-NLS construct
PMID:9740803 GO:0008139 can't use IPI because we don't have identifiers for human importin alpha or the GST-NLS construct
PMID:9745017 PBO:0095902 inferred from decreased nda3 mRNA level
PMID:9745017 PBO:0095902 inferred from decreased nda3 mRNA level
PMID:9755169 PBO:0107539 Fig 2C, cdc10 dependent transcription occurs during mitotic exit
PMID:9755169 PBO:0107540 Fig 2C, cdc10 dependent transcription occurs during mitotic exit
PMID:9755169 PBO:0107542 Fig4C cd18 N term deletion can accumulate in a metaphase arrest
PMID:9755169 PBO:0107542 Fig5D
PMID:9755169 PBO:0107542 Fig5C
PMID:9755169 PBO:0096440 Fig5B
PMID:9755169 PBO:0107542 Fig4C cd18 N term deletion can accumulate in a metaphase arrest
PMID:9755169 PBO:0107542 Fig4E cdc18 lacking cdc2 phosphorylation sites accumulates immediately as cells progress into mitosis
PMID:9755169 PBO:0107541 Fig3B
PMID:9755169 PBO:0107541 Fig3B cdc10 is a cdc18 transcriptional regulator see Fig2C
PMID:9755169 PBO:0107541 Fig3A cdc10 is a cdc18 transcriptional regulator see Fig2C
PMID:9755169 PBO:0107538 Fig 2C, cdc10 dependent transcription occurs during mitotic exit
PMID:9755190 PBO:0096190 requested chromatin silencing term but advised to use this one
PMID:9755190 PBO:0096191 requested chromatin silencing term but advised to use this one
PMID:9755190 PBO:0096190 requested chromatin silencing term but advised to use this one
PMID:9755190 PBO:0096193 requested chromatin silencing term but advised to use this one
PMID:9755190 PBO:0096192 requested chromatin silencing term but advised to use this one
PMID:9771717 FYPO:0000678 not shown
PMID:9774107 PBO:0108169 fig 4a
PMID:9774107 PBO:0108165 fig 2 e
PMID:9774107 PBO:0108165 data not shown
PMID:9774107 PBO:0094001 fig2e
PMID:9774107 PBO:0094001 fig2e
PMID:9774107 PBO:0095532 fig2
PMID:9774107 PBO:0095532 fig2
PMID:9774107 PBO:0108166 fig2
PMID:9774107 PBO:0108166 fig2
PMID:9774107 PBO:0108168 fig 4a
PMID:9778252 PBO:0021058 Precise observation revealed that Mei2p dots could be visible in conjugating cells that completed cell fusion but did not undergo karyogamy yet.
PMID:9786952 PBO:0102009 4de
PMID:9786952 FYPO:0005870 fig 2b
PMID:9786952 FYPO:0006802 fig 2e
PMID:9786952 FYPO:0003500 4a
PMID:9786952 FYPO:0001254 4a
PMID:9786952 PBO:0032815 4ab
PMID:9786952 PBO:0102010 fig6
PMID:9786952 PBO:0102008 fig 2a
PMID:9786952 FYPO:0001406 fig 2b
PMID:9790887 GO:0004743 activated_by(CHEBI:18420), activated_by(CHEBI:29103)
PMID:9794798 PBO:0098699 mutant Cdc6 is not positively regulated by PCNA to the same extent as Cdc6+
PMID:9794798 PBO:0098699 mutant Cdc6 is not positively regulated by PCNA to the same extent as Cdc6+
PMID:9802907 PBO:0018634 (included because different/new method) To observe the SPB in living cells, GFP-tagged Sad1 (designated hereafter Sad1âGFP) was expressed and found to be bound to the SPB throughout the cell cycle (Figure 1A), identical to immunolocalization data (Ha- gan and Yanagida, 1995)
PMID:9802907 FYPO:0002639 ADVANCED I hope I got this right?A striking feature in dis1 mutant cells was that the back-and-forth cen1 DNA movements seen in phase 2 of wild-type cells were entirely absent. After spindle elongation (the SPB distance, ô°8 ô°m), the cen1 signals were fused again and moved to one of the SPBs. Such prolonged centromere splitting while the spindle was elongating was never seen in wild-type or any of the other mutant cells examined so far.
PMID:9802907 PBO:0018346 (included because different/new method) To observe the SPB in living cells, GFP-tagged Sad1 (designated hereafter Sad1–GFP) was expressed and found to be bound to the SPB throughout the cell cycle (Figure 1A), identical to immunolocalization data (Ha- gan and Yanagida, 1995)
PMID:9808627 FYPO:0003241 G1 block
PMID:9808627 PBO:0033703 (Fig. 2D)
PMID:9808627 PBO:0033704 G2 block
PMID:9832516 PBO:0093579 severity estimated because wt (i.e. not overexpressing cdc25) not shown
PMID:9832516 PBO:0093579 severity estimated because wt (i.e. not overexpressing cdc25) not shown
PMID:9832516 PBO:0093579 severity estimated because wt (i.e. not overexpressing cdc25) not shown
PMID:9832516 PBO:0093579 severity estimated because wt (i.e. not overexpressing cdc25) not shown
PMID:9839953 PBO:0097089 at the second po- sition (Gal-Man-O)
PMID:9839953 PBO:0097092 at the second po- sition (Gal-Man-O)
PMID:9839953 PBO:0097089 low activity
PMID:9843572 FYPO:0000712 figure 3 A&B
PMID:9843572 PBO:0103076 Figure 9A
PMID:9843572 PBO:0103075 Figure 8
PMID:9843572 PBO:0103075 Figure 8
PMID:9843572 PBO:0103074 figure 3 B (additive)
PMID:9843572 PBO:0094266 Figure 7A
PMID:9843572 FYPO:0000711 figure 3 A&B
PMID:9843572 FYPO:0003481 (Figure 3B)
PMID:9843572 FYPO:0003481 (Figure 3B)
PMID:9843572 FYPO:0003481 (Figure 3B)
PMID:9843572 FYPO:0001124 Figure 6A
PMID:9843572 PBO:0098712 (Figure 1
PMID:9843572 FYPO:0003481 (Figure 3B)
PMID:9843572 FYPO:0001491 Figure 6B
PMID:9843577 FYPO:0007136 single micrograph, so can't tell if they're viable
PMID:9843577 FYPO:0007137 single micrograph, so can't tell if they're viable
PMID:9843966 PBO:0026234 neutral wrt viability because data not shown, so don't know if aseptate mononucleate cells are the same ones that manage to survive and eventually divide
PMID:9857040 GO:0000403 biologically relevant? it can also cut these
PMID:9857040 GO:0070336 biologically relevant? it can also cut these
PMID:9862966 PBO:0101179 Fig3 CD
PMID:9862966 PBO:0101180 https://github.com/pombase/fypo/issues/3931
PMID:9864354 FYPO:0007125 Fig. 2 E
PMID:9864354 FYPO:0000620 indicated by high level of H1 kinase activity
PMID:9864354 FYPO:0007125 Fig. 2 E
PMID:9864354 FYPO:0000229 Fig. 2 D
PMID:9872416 PBO:0103888 figure 2.
PMID:9872416 PBO:0103891 figure 2.
PMID:9872416 PBO:0103890 figure 2.
PMID:9872416 PBO:0103889 figure 2.
PMID:9872416 PBO:0103893 figure 2.
PMID:9872416 PBO:0103892 figure 2.
PMID:9872416 PBO:0103887 figure 2.
PMID:9891039 FYPO:0001355 worse than cdc24-M38 alone (wt not shown)
PMID:9891039 FYPO:0001355 worse than cdc24-M38 alone (wt not shown)
PMID:9891039 FYPO:0001355 worse than cdc24-M38 alone (wt not shown)
PMID:9891039 FYPO:0001355 worse than cdc24-M38 alone (wt not shown)
PMID:9891047 FYPO:0002061 temperature permissive for single mutant without rad26delta
PMID:9891047 FYPO:0002061 temperature permissive for single mutant without rad26delta
PMID:9891047 FYPO:0002061 temperature permissive for single mutant without rad26delta
PMID:9891047 FYPO:0002061 temperature permissive for single mutant without rad26delta
PMID:9891047 FYPO:0002061 temperature permissive for single mutant without rad26delta
PMID:9891047 PBO:0093560 temperature permissive for single mutant without rad26delta
PMID:9891047 PBO:0095859 temperature permissive for single mutant without rad2delta
PMID:9891047 PBO:0095859 temperature permissive for single mutant without rad2delta
PMID:9891047 PBO:0095857 temperature permissive for single mutant without rad2delta
PMID:9891047 FYPO:0002061 temperature permissive for single mutant without cds1delta
PMID:9891047 FYPO:0002061 temperature permissive for single mutant without rad26delta
PMID:9891047 PBO:0095859 temperature permissive for single mutant without rad2delta
PMID:9891047 PBO:0093561 temperature permissive for single mutant without cds1delta
PMID:9891047 PBO:0093561 temperature permissive for single mutant without cds1delta
PMID:9891047 PBO:0095859 temperature permissive for single mutant without cds1delta
PMID:9891047 PBO:0093561 temperature permissive for single mutant without cds1delta
PMID:9891047 PBO:0095859 temperature permissive for single mutant without cds1delta
PMID:9891047 PBO:0093561 temperature permissive for single mutant without cds1delta
PMID:9891047 PBO:0095857 temperature permissive for single mutant without cds1delta
PMID:9891047 PBO:0093560 temperature permissive for single mutant without cds1delta
PMID:9891047 PBO:0095857 temperature permissive for single mutant without cds1delta
PMID:9891047 PBO:0095859 temperature permissive for single mutant without rad2delta
PMID:9891047 PBO:0095859 temperature permissive for single mutant without rad2delta
PMID:9891047 PBO:0093560 temperature permissive for single mutant without cds1delta
PMID:9891047 PBO:0095859 temperature permissive for single mutant without rad2delta
PMID:9891047 PBO:0093560 temperature permissive for single mutant without cds1delta
PMID:9891047 PBO:0095859 temperature permissive for single mutant without rad2delta
PMID:9891047 FYPO:0002061 temperature permissive for single mutant without rad26delta
PMID:9891047 PBO:0093560 temperature permissive for single mutant without rad26delta
PMID:9891047 PBO:0093560 temperature permissive for single mutant without rad26delta
PMID:9891047 PBO:0095857 temperature permissive for single mutant without rad2delta
PMID:9891047 PBO:0095859 temperature permissive for single mutant without rad2delta
PMID:9950674 FYPO:0002061 fig 9
PMID:9950674 FYPO:0003165 fig 9
PMID:9973368 GO:0036349 galactose specific flocculation should have cell-cell ahdesion parentage
PMID:9973368 FYPO:0001357 non-flocculating cells