Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: EC:2.7.11.1 (protein kinase)
81,284 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The cell cycle in Saccharomyces cerevisiae is controlled by regulation of START in late G1. The CLN1, CLN2 and CLN3 family of cyclin homologues is required for cells to pass START. They probably act by activating the CDC28 protein kinase. Expression of CLN1 or CLN3 under the control of an inducible promoter shows that transcription of either gene is sufficient for cyclin-deficient strains arrested in G1 to traverse START. A model of START regulation involves activation of CDC28 kinase by any CLN protein, leading to activation of CLN1 and CLN2 transcription in a positive feedback loop and passage through START. The cell cycle-dependent transcriptional regulators SWI4 and SWI6 may be components of the feedback loop. Cell cycle commitment entails resistance to the inhibitory action of mating factor, which correlates with peak levels of CLN1 and CLN2 mRNAs. FAR1 encodes an alpha-factor-dependent inhibitor of CLN function whose expression is markedly reduced at the time of START. The interplay of all these factors may sharpen the START transition such that it is close to an all-or-nothing switch event. This may be important for several START-dependent events to be activated at the same time, leading to coordinated cell cycle progression.
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PMID:Is START a switch? 148 46

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

In rapidly growing cells of the budding yeast Saccharomyces cerevisiae, the cell cycle is regulated chiefly at Start, just before the G1-S boundary, whereas in the fission yeast Schizosaccharomyces pombe, the cycle is predominantly regulated at G2-M. Both control points are present in both yeasts, and both require the p34cdc2 protein kinase. At G2-M, p34cdc2 kinase activity in S. pombe requires a B-type cyclin in a complex with p34cdc2; this complex is the same as MPF (maturation promoting factor). The p34cdc2 activity at the G1-S transition in S. cerevisiae may be regulated by a similar cyclin complex, using one of the products of a new class of cyclin genes (CLN1, CLN2 and WHI1 (DAF1/CLN3)). At least one is required for progression through the G1-S phase, and deletion of all three leads to G1 arrest. WHI1 was isolated as a dominant allele causing budding yeast cells to divide at a reduced size and was later independently identified as DAF1, a dominant allele of which rendered the cells refractory to the G1-arrest induced by the mating pheromone alpha-factor. The dominant alleles are truncations thought to yield proteins of increased stability, and the cells are accelerated through G1. Without WHI1 function, the cells are hypersensitive to alpha-factor, enlarged and delayed in G1. Heretofore, this G1-class of cyclins has not been identified in other organisms. We have isolated a G1-type cyclin gene called puc1+ from S. pombe, using a functional assay in S. cerevisiae. Expression of puc1+ in S. pombe indicates that it has a cyclin-like role in the fission yeast distinct from the role of the B-type mitotic cyclin.
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PMID:Identification of a G1-type cyclin puc1+ in the fission yeast Schizosaccharomyces pombe. 182 91

Yeast cells become committed to the mitotic cell cycle at a stage during G1 called Start. To enter Start, cells must grow to a critical size. They also require the CDC28 protein kinase and at least one of three G1-specific cyclins encoded by CLN1, 2, and 3. It is thought that Start is triggered by the accumulation of G1 cyclins that bind to the CDC28 kinase and activate it. So what determines the accumulation of G1 cyclins? For CLN1 and CLN2, transcriptional activation could be involved because their RNAs appear transiently during the cell cycle as cells undergo Start. Here we report that the appearance of CLN1 and CLN2 RNAs depends on an active CDC28 kinase and is stimulated by CLN3 activity. We propose that CDC28 kinase activity due to CLN1 and CLN2 proteins arises through a positive feedback loop which allows CLN proteins to promote their own synthesis.
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PMID:Positive feedback in the activation of G1 cyclins in yeast. 182 7

Entry into the mitotic cycle (START) requires a protein kinase encoded by the CDC28 gene and one of three redundant G1-specific cyclins encoded by CLN1, -2, and -3. SWI4 and SWI6 are transcription factors required for the START-dependent activation of the HO endonuclease gene. They also fulfill an overlapping but essential role for cell division since cells deleted for both genes are inviable. We show that the essential role of SWI4 and SWI6 is to ensure the activity of G1-specific cyclin genes. SWI4 and SWI6 appear necessary for the transcription of CLN1 and CLN2, but not for that of CLN3. CLN3 function is, however, also dependent on SWI4 and SWI6.
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PMID:The role of SWI4 and SWI6 in the activity of G1 cyclins in yeast. 183 38

FUS3 is functionally redundant with KSS1, a homologous yeast protein kinase, for a step(s) in signal transduction between the beta subunit of the guanine nucleotide binding protein (G protein), STE4, and the mating type-specific transcriptional activator, STE12. Either FUS3 or KSS1 can execute this function; when neither gene encoding these protein kinases is present, signal transduction is blocked, causing sterility. This functional redundancy is strain dependent; some standard laboratory strains (S288C) are kss1-. FUS3 has additional functions required for cell cycle arrest and vegetative growth that do not overlap with KSS1 functions. FUS3 mediates cell cycle arrest during mating through transcriptional repression of two G1 cyclins (CLN1 and CLN2) and through posttranscriptional inhibition of a third G1 cyclin (CLN3). FUS3 is also required for vegetative growth in haploid strains dependent upon CLN3 for cell cycle progression but is not required in strains dependent upon either CLN1 or CLN2, suggesting a functional divergence among the three G1 cyclins. The diverse roles for FUS3 suggest that the FUS3 protein kinase has multiple substrates, some of which may be shared with KSS1.
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PMID:FUS3 represses CLN1 and CLN2 and in concert with KSS1 promotes signal transduction. 194 50

Cyclins were discovered in marine invertebrates based on their dramatic cell cycle periodicity. Recently, the products of three genes associated with cell cycle progression in S. cerevisiae were found to share limited homology with cyclins. Mutational elimination of the CLN1, CLN2, and DAF1/WHI1 products leads to cell cycle arrest independent of cell type, while expression of any one of the genes allows cell proliferation. Using strains where CLN1 was expressed conditionally, the essential function of Cln proteins was found to be limited to the G1 phase. Furthermore, the ability of the Cln proteins to carry out this function was found to decay rapidly upon cessation of Cln biosynthesis. The data are consistent with the hypothesis that Cln proteins activate the Cdc28 protein kinase, shown to be essential for the G1 to S phase transition in S. cerevisiae. Because of the apparent functional redundancy of these genes, DAF1/WHI1 has been renamed CLN3.
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PMID:An essential G1 function for cyclin-like proteins in yeast. 257 33

Saccharomyces cerevisiae FUS3/DAC2 protein kinase, a homolog of mammalian mitogen-activated protein (MAP) kinase, inactivates a G1 cyclin encoded by the CLN3 gene to arrest cell division in the G1 phase and activates a transcriptional factor STE12 in response to mating pheromone during sexual conjugation. To elucidate the role of the FUS3/DAC2 gene product in the mating process, I constructed and characterized dac2 cln3 double mutants. Here, I show that FUS3/DAC2 is required for completion of cell fusion even in the dac2 cln3 double mutants in which the pheromone response is restored, suggesting that FUS3/DAC2 plays a positive role in cell fusion during conjugation. In addition, the cdc dac2 and cdc37 ste double mutants were constructed and investigated for their phenotypes to clarify the relationship between FUS3/DAC2, STE7 or STE11 and CDC gene products (CDC28, 36, 37 and 39). The results indicate that FUS3/DAC2 may act upstream of CDC28 and provide evidence that the G1 arrest and morphological changes conferred by the cdc37 mutation may require FUS3/DAC2 (MAP kinase), STE7(MEK) and STE11 (MEK kinase).
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PMID:Yeast homolog of mammalian mitogen-activated protein kinase, FUS3/DAC2 kinase, is required both for cell fusion and for G1 arrest of the cell cycle and morphological changes by the cdc37 mutation. 784 75

The events of the eukaryotic cell cycle are governed by cyclin-dependent kinases (cdk's), whose activation requires association with cyclin regulatory subunits expressed at specific cell cycle stages. In the budding yeast Saccharomyces cerevisiae, the cell cycle is thought to be controlled by a single cdk, CDC28. Passage through the G1 phase of the cell cycle is regulated by complexes of CDC28 and G1 cyclins (CLN1, CLN2, and CLN3). A putative G1 cyclin, HCS26, has recently been identified. In a/alpha diploid cells lacking CLN1 and CLN2, HCS26 is required for passage through G1. HCS26 does not associate with CDC28, but instead associates with PHO85, a closely related protein kinase. Thus, budding yeast, like higher eukaryotes, use multiple cdk's in the regulation of cell cycle progression.
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PMID:Cell cycle control by a complex of the cyclin HCS26 (PCL1) and the kinase PHO85. 797 30

In the budding yeast Saccharomyces cerevisiae, passage through START, which commits cells to a new round of cell division, requires growth to a critical size. To examine the effect of hyperactivation of the cAMP pathway on cell size at START, a strain was constructed that is able to respond to exogenously added cAMP. In the presence of cAMP, this strain showed increased cell volume at bud emergence, suggesting that the critical cell size necessary for START is increased. In addition, a mutation that results in unregulated cAMP-dependent protein kinase (bcy1) caused increased cell size at START. These results indicate that hyperactivation of the cAMP pathway causes increases in cell size through cAMP-dependent protein kinase. Cells carrying a hyperactive allele of CLN3 (CLN3-2) also showed increased size at START in the presence of cAMP. These cells retained resistance to alpha factor, however, suggesting that increases in cell size by cAMP are not due to a reduction of Cln3 activity. The observed increases in cell size due to hyperactivation of the cAMP pathway suggest that cell size modulation by nutrient conditions may be associated with a change of the activity of the cAMP pathway.
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PMID:Increases in cell size at START caused by hyperactivation of the cAMP pathway in Saccharomyces cerevisiae. 817 12


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