EC:2.7.11.22 - FACTA Search

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Query: EC:2.7.11.22 (cdc2)
8,319 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Budding yeast strains have three CLN genes, which have limited cyclin homology. At least one of the three is required for cell cycle START. Four B cyclins are known in yeast; two have been shown to function in mitosis. We have discovered a fifth B-cyclin gene, called CLB5, which when cloned on a CEN plasmid can rescue strains deleted for all three CLN genes. CLB5 transcript abundance peaks in G1, coincident with the CLN2 transcript but earlier than the CLB2 transcript. CLB5 deletion does not cause lethality, either alone or in combination with other CLN or CLB deletions. However, strains deleted for CLB5 require more time to complete S phase, suggesting that CLB5 promotes some step in DNA synthesis. CLB5 is the only yeast cyclin whose deletion lengthens S phase. CLB5 may also have some role in promoting the G1/S transition, because cln1 cln2 strains require both CLN3 and CLB5 for viability on glycerol media and cln1,2,3- strains require CLB5 for rescue by the Drosophila melanogaster cdc2 gene. In conjunction with cln1,2,3- rescue by CLB5 overexpression and the coincident transcriptional regulation of CLB5 and CLN2, these observations are suggestive of partial functional redundancy between CLB5 and CLN genes.
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PMID:CLB5: a novel B cyclin from budding yeast with a role in S phase. 138 26

The GPA1 gene of S. cerevisiae encodes a G alpha subunit that plays a positive role in the transduction of signals stimulating recovery from pheromone-induced cell cycle arrest. The GPA1Val50 mutation, in which Gly-50 is replaced by valine, causes hyperadaptation to pheromone. However, GPA1Val50 cells do not recover from division arrest in the absence of both CLN1 and CLN3, which encode G1 cyclins, indicating that the recovery-promoting activity of GPA1Val50 requires the function of G1 cyclins. An sgv1 mutation suppresses the hyperadaptive response caused by GPA1Val50 and also confers cold- and temperature-sensitive growth. The SGV1 gene encodes an apparent protein kinase homologous to CDC28/cdc2 kinase: SGV1 is 42% identical to CDC28. The activated mutation, CLN3-2, partially suppresses the growth defect of sgv1, suggesting that the SGV1 and CLN3 proteins may act in the same growth control pathway.
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PMID:SGV1 encodes a CDC28/cdc2-related kinase required for a G alpha subunit-mediated adaptive response to pheromone in S. cerevisiae. 182 90

Transcriptional induction by the mating pheromone alpha-factor was monitored at different stages of the yeast cell cycle. G2/M-phase and pre-Start cells showed strong FUS1 mRNA induction, whereas in post-Start cells the signaling was reduced significantly. This reduction in signaling activity in post-Start cells was correlated with the presence of CLN1 or CLN2 transcripts and was not observed in synchronized cells lacking functional CLN1 and CLN2 genes. Activation of the Cln-Cdc28p kinase by overexpression of CLN2 from the GAL1 promoter strongly reduced FUS1 mRNA induction. CLN1 overexpression had a similar effect when the FAR1 gene, encoding a negative regulator of CLN1/2 function, was deleted. This reduction of pheromone signaling was specific for CLN1 and CLN2, as it was not observed when CLN3 was overexpressed. Inactivation of the Cln-Cdc28p kinase complex by thermal inactivation of temperature-sensitive Cdc28p prevented repression of FUS1 signaling. CLN2 overexpression suppressed the constitutive signaling and division-arrest phenotypes of cells with a disrupted gpa1 gene, indicating that the site of action for repression is downstream of the alpha-subunit (Gpa1p) of the heterotrimeric G protein. The repression at Start of pheromone signaling by Cln1-Cdc28p or Cln2-Cdc28p kinase complexes may contribute to the acquisition of pheromone resistance as cells execute Start.
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PMID:G1 cyclins CLN1 and CLN2 repress the mating factor response pathway at Start in the yeast cell cycle. 792 87

The CLN1, CLN2 and CLN3 gene family of G1-acting cyclin homologs of Saccharomyces cerevisiae is functionally redundant: any one of the three Cln proteins is sufficient for activation of Cdc28p protein kinase activity for cell cycle START. The START event leads to multiple processes (including DNA replication and bud emergence); how Cln/Cdc28 activity activates these processes remains unclear. CLN3 is substantially different in structure and regulation from CLN1 and CLN2, so its functional redundancy with CLN1 and CLN2 is also poorly understood. We have isolated mutations that alter this redundancy, making CLN3 insufficient for cell viability in the absence of CLN1 and CLN2 expression. Mutations causing phenotypes specific for the cell division cycle were analyzed in detail. Mutations in one gene result in complete failure of bud formation, leading to depolarized cell growth. This gene was identified as BUD2, previously described as a non-essential gene required for proper bud site selection but not required for budding and viability. Bud2p is probably the GTPase-activating protein for Rsr1p/Bud1p [Park, H., Chant, I. and Herskowitz, I. (1993) Nature, 365, 269-274]; we find that Rsr1p is required for the bud2 lethal phenotype. Mutations in two other genes (ERC10 and ERC19) result in a different morphogenetic defect: failure of cytokinesis resulting in the formation of long multinucleate tubes. These results suggest direct regulation of diverse aspects of bud morphogenesis by Cln/Cdc28p activity.
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PMID:Genetic analysis of Cln/Cdc28 regulation of cell morphogenesis in budding yeast. 826 69

In Saccharomyces cerevisiae, mating pheromones activate two MAP kinases (MAPKs), Fus3p and Kss1p, to induce G1 arrest prior to mating. Fus3p is known to promote G1 arrest by activating Far1p, which inhibits three Clnp/Cdc28p kinases. To analyze the contribution of Fus3p and Kss1p to G1 arrest that is independent of Far1p, we constructed far1 CLN strains that undergo G1 arrest from increased activation of the mating MAP kinase pathway. We find that Fus3p and Kss1p both control G1 arrest through multiple functions that operate in parallel with Far1p. Fus3p and Kss1p together promote G1 arrest by repressing transcription of G1/S cyclin genes (CLN1, CLN2, CLB5) by a mechanism that blocks their activation by Cln3p/Cdc28p kinase. In addition, Fus3p and Kss1p counteract G1 arrest through overlapping and distinct functions. Fus3p and Kss1p together increase the expression of CLN3 and PCL2 genes that promote budding, and Kss1p inhibits the MAP kinase cascade. Strikingly, Fus3p promotes proliferation by a novel function that is not linked to reduced Ste12p activity or increased levels of Cln2p/Cdc28p kinase. Genetic analysis suggests that Fus3p promotes proliferation through activation of Mcm1p transcription factor that upregulates numerous genes in G1 phase. Thus, Fus3p and Kss1p control G1 arrest through a balance of arrest functions that inhibit the Cdc28p machinery and proliferative functions that bypass this inhibition.
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PMID:Fus3p and Kss1p control G1 arrest in Saccharomyces cerevisiae through a balance of distinct arrest and proliferative functions that operate in parallel with Far1p. 1004 17

In the budding yeast, Saccharomyces cerevisiae, control of cell proliferation is exerted primarily during G(1) phase. The G(1)-specific transcription of several hundred genes, many with roles in early cell cycle events, requires the transcription factors SBF and MBF, each composed of Swi6 and a DNA-binding protein, Swi4 or Mbp1, respectively. Binding of these factors to promoters is essential but insufficient for robust transcription. Timely transcriptional activation requires Cln3/CDK activity. To identify potential targets for Cln3/CDK, we identified multicopy suppressors of the temperature sensitivity of new conditional alleles of SWI6. A bck2Delta background was used to render SWI6 essential. Seven multicopy suppressors of bck2Delta swi6-ts mutants were identified. Three genes, SWI4, RME1, and CLN2, were identified previously in related screens and shown to activate G(1)-specific expression of genes independent of CLN3 and SWI6. The other four genes, FBA1, RPL40a/UBI1, GIN4, and PAB1, act via apparently unrelated pathways downstream of SBF and MBF. Each depends upon CLN2, but not CLN1, for its suppressing activity. Together with additional characterization these findings indicate that multiple independent pathways are sufficient for proliferation in the absence of G(1)-specific transcriptional activators.
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PMID:Multiple pathways for suppression of mutants affecting G1-specific transcription in Saccharomyces cerevisiae. 1567 47

Cip1, a newly identified yeast analog of p21, is a Cln3-CDK inhibitor that negatively regulates cell-cycle START. However, its function remains poorly understood. In this study, we found that deletion of CLN3 did not result in bypass of G1-phase arrest caused by Cip1 overexpression. Cip1 depletion in cln3-null mutants significantly advanced the timing of Cln2 expression, supporting the idea that Cip1 represses START in a Cln3-independent manner. We set to search for novel Cip1 interacting proteins and found that Ccr4, a known START regulator, and its associated factor Caf120, interact with Cip1. Ccr4-Caf120 acts redundantly with Cdk1-Cln3 to inhibit Whi5-mediated regulation of START. This interaction was conserved between human Ccr4 and p21. In addition, deletion of WHI5 robustly suppressed G1-phase arrest caused by Cip1 overexpression. We conclude that Cip1 negatively regulates START by acting as a dual repressor of Ccr4 in parallel with Cln3.
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PMID:Dual Repressive Function by Cip1, a Budding Yeast Analog of p21, in Cell-Cycle START Regulation. 3273 30