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)

Cell division in eukaryotes is mediated by the action of the mitosis promoting factor, which is composed of the CDC2 protein kinase and one of the various mitotic cyclins. We have recently isolated a cdc2 gene from alfalfa. Here, we report the isolation of two cyclin genes, cycMs1 and cycMs2, from alfalfa. The cycMs2 gene shows highest similarity to type B cyclins. In contrast, the predicted amino acid sequence of the cycMs1 gene shows similar homology scores to cyclins of all types (25 to 35%). Both genes are expressed in dividing suspension cultured cells but cease to be expressed when the cells enter stationary phase. In synchronized alfalfa suspension cultured cells, the mRNAs of cycMs1 and cycMs2 show maximal expression in the G2 and M phases. Transcripts of cycMs2 are found only in late G2 and M phase cells, an expression pattern typical for cyclin B genes, whereas cycMs1 appears with the onset of G2. This pattern indicates that alfalfa cycMs1 and cycMs2 belong to different classes of cyclins. In young leaves, expression of both genes is high, whereas in mature leaves no transcripts can be detected, indicating that the two cyclin genes are true cell division markers at the mRNA level. In other organs, a more complex expression pattern of the two cyclin genes was found.
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PMID:Alfalfa cyclins: differential expression during the cell cycle and in plant organs. 130 38

We have examined the role of phosphorylation in the regulation of human cyclin-dependent kinase-2 (CDK2), a protein closely related to the cell cycle regulatory kinase CDC2. We find that CDK2 from HeLa cells contains three major tryptic phosphopeptides. Analysis of site-directed mutant proteins, expressed by transient transfection of COS cells, demonstrates that the two major phosphorylation sites are Tyr15 (Y15) and Thr160 (T160). Additional phosphorylation probably occurs on Thr14 (T14). Replacement of T160 with alanine abolishes the kinase activity of CDK2, indicating that phosphorylation at this site (as in CDC2) is required for kinase activity. Mutation of Y15 and T14 stimulates kinase activity, demonstrating that phosphorylation at these sites (as in CDC2) is inhibitory. Similarly, CDK2 is activated in vitro by dephosphorylation of Y15 and T14 by the phosphatase CDC25. Analysis of HeLa cells synchronized at various cell cycle stages indicates that CDK2 phosphorylation on T160 increases during S phase and G2, when CDK2 is most active. Phosphorylation on the inhibitory sites T14 and Y15 is also maximal during S phase and G2. Thus, the activity of a subpopulation of CDK2 molecules is inhibited at a time in the cell cycle when overall CDK2 activity is increased.
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PMID:Cell cycle regulation of CDK2 activity by phosphorylation of Thr160 and Tyr15. 139 89

We have previously shown by cDNA cloning that a higher plant, Arabidopsis thaliana, possesses at least two CDC2 genes (CDC2a and CDC2b) similar to the cell-cycle-controlling cdc2 gene of Schizosaccharomyces pombe. To understand the exon-intron organization of these genes, genomic clones were isolated and their nucleotide sequences determined. The coding and 5'-untranslated regions of CDC2a were interrupted by seven and one introns, respectively, whilst CDC2b contained three introns within the coding portion. These intron positions partly overlapped with each other and with those of the yeast cdc2 gene, nevertheless the lengths and sequences of the corresponding introns were diverse.
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PMID:Exon-intron organization of the Arabidopsis thaliana protein kinase genes CDC2a and CDC2b. 161 2

DNA polymerase III of the yeast Saccharomyces cerevisiae has been reported to be encoded at the CDC2 locus based on two observations. First, the CDC2 gene has homology to known DNA polymerase genes [Boulet et al. (1989) EMBO J. 8, 1849-1854], and second, the mutants cdc2-1 and cdc2-2 yield little or no DNA polymerase III activity in vitro [Boulet et al. (1989); Sitney et al. (1989) Cell 56, 599-605]. We describe here the isolation of temperature-sensitive DNA polymerase III from cdc2-2 strains. Our results provide direct experimental confirmation of the previously inferred gene/enzyme relationship and verify the conclusion that DNA polymerase III is required to replicate the genome. We isolated DNA polymerase III from two cdc2-2 strains, one containing the wild-type allele for DNA polymerase I (CDC17) and the other a mutant DNA polymerase I allele (cdc17-1). Yields from cdc2-2 cells of both DNA polymerase III activity and an associated 3'-5'-exonuclease activity [exonuclease III; Bauer et al. (1988) J. Biol. Chem. 263, 917-924] were decreased relative to yields from CDC2 cells. DNA polymerase III activity from cdc2-2 strains is thermolabile, displaying at least a 4-fold reduction in half-life at 44 degrees C. The activity is also labile at 37 degrees C, a temperature which is restrictive for growth of cdc2-2 but not CDC2 strains. At 23 degrees C, a temperature which is permissive for growth of both cdc2-2 and CDC2 strains, the mutant and wild-type DNA polymerase III activities display equal stability. These observations provide a demonstrable biochemical basis for the thermosensitive phenotype of cdc2-2 cells.
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PMID:Isolation of temperature-sensitive DNA polymerase III from Saccharomyces cerevisiae cdc2-2. 167 79

The onset of S-phase and M-phase in both Schizosaccharomyces pombe and Saccharomyces cerevisiae requires the function of the cdc2/CDC28 gene product, p34, a serine-threonine protein kinase. A human homolog, p34cdc2, was identified by functional complementation of the S.pombe cdc2 mutation (Lee and Nurse, 1987). Using a human cDNA expression library to search for suppressors of cdc28 mutations in S. cerevisiae, we have identified a second functional p34 homolog, CDK2 cell division kinase). This gene is expressed as a 2.1 kb transcript encoding a polypeptide of 298 amino acids. This protein retains nearly all of the amino acids highly conserved among previously identified p34 homologs from other species, but is considerably divergent from all previous p34cdc2 homologs, approximately 65% identity. This gene encodes the human homolog of the Xenopus Eg1 gene, sharing 89% amino acid identity, and defines a second sub-family of CDC2 homologs. A second chromosomal mutation which arose spontaneously was required to allow complementation of the cdc28-4 mutation by CDK2. This mutation blocked the ability of this strain to mate. These results suggest that the machinery controlling the human cell cycle is more complex than that for fission and budding yeast.
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PMID:A new human p34 protein kinase, CDK2, identified by complementation of a cdc28 mutation in Saccharomyces cerevisiae, is a homolog of Xenopus Eg1. 171 86

We have cloned two different human cDNAs that can complement cdc28 mutations of budding yeast Saccharomyces cerevisiae. One corresponds to a gene encoding human p34CDC2 kinase, and the other to a gene (CDK2; cell division kinase) that has not been characterized previously. The CDK2 protein is highly homologous to p34CDC2 kinase (65% identical) and more significantly is homologous to Xenopus Eg1 kinase (89% identical), suggesting that CDK2 is the human homolog of Eg1. The human CDC2 and CDK2 genes were both able to complement the inviability of a null allele of S. cerevisiae CDC28. This result indicates that the CDK2 protein has a biological activity closely related to the CDC28 and p34CDC2 kinases. However, CDK2 was unable to complement cdc2 mutants in fission yeast Schizosaccharomyces pombe under the condition where the human CDC2 gene could complement them. CDK2 mRNA appeared late in G1 or in early S phase, slightly before CDC2 mRNA, after growth stimulation in normal human fibroblast cells. These results suggest that in human cells, two different CDC2-like kinases may regulate the cell cycle at distinct stages.
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PMID:Cloning of a human cDNA encoding a CDC2-related kinase by complementation of a budding yeast cdc28 mutation. 171 94

Senescent cells fail to respond to serum-induced signals for DNA synthesis. Because a central role for the p34cdc2 protein kinase is postulated in control of the cell cycle, we examined the status of this kinase in senescent cells and other growth-arrested cells. In growing human and Syrian hamster fibroblasts, three 35S-labeled proteins of 34-36 kDa were immunoprecipitated with p34cdc2 antiserum. Only the two slower migrating forms were phosphorylated as determined by 32P labelling. In senescent cells, which failed to incorporate [3H]thymidine, no p34cdc2 protein was synthesized and very little or no cdc2 mRNA was observed. When maintained for 48 h in 0.5% serum, young cells also retained only marginal cdc2 expression. After stimulation of low serum-arrested cells by addition of 10% serum, a time-dependent increase of cdc2 mRNA was observed, whereas serum stimulation of senescent cells did not increase cdc2 mRNA. In contrast to senescent and low serum-arrested cells, cdc2 mRNA was expressed at normal levels in cells partially growth arrested by isoleucine deficiency in G1, by aphidicolin at G1-S, by etoposide in G2, or by Colcemid in the M phase of the cell cycle, indicating that cdc2 down-regulation does not always occur upon growth arrest. Following transfection of a plasmid containing the human CDC2 gene into hamster cells, expression of human cdc2 failed to overcome the block to DNA synthesis in senescent cells. Although p34cdc2 was synthesized in the transfected cells, the multiple phosphorylated forms of the proteins were not observed. Taken together, these data support the concept that a chain of events leads to senescence. While p34cdc2 kinase may be one of the critical elements, other cell cycle controls are also involved.
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PMID:Down-regulation of cdc2 in senescent human and hamster cells. 193 64

The cdc2 gene product (p34cdc2) has been thought to play a central role in control of the mitotic cell cycle of yeasts and animals. To approach an understanding of the cell-cycle-control system in higher plants, we isolated, from an Arabidopsis thaliana cDNA library, two clones (CDC2a and CDC2b) similar to the Schizosaccharomyces pombe cdc2 gene. Genomic Southern-blot analysis with the CDC2a and CDC2b cDNA probes suggested that the A. thaliana genome contains several additional cdc2-like genes, which together with the CDC2a and CDC2b genes may constitute a CDC2 gene family. The CDC2a cDNA expressed in Sc. pombe corrected the elongated morphology, caused by the temperature-sensitive cdc2-33 mutation, to the normal shapes, indicating that the A. thaliana CDC2a gene product resembles Sc. pombe p34cdc2 functionally as well as structurally. These results support the view that the cell cycle of higher plants is controlled by an analogue of a p34cdc2-centered regulatory system like that of yeasts and animals.
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PMID:Identification of two cell-cycle-controlling cdc2 gene homologs in Arabidopsis thaliana. 193 13

In Saccharomyces cerevisiae, three different DNA polymerase complexes, POLI, POLII and POLIII, are known to be involved in DNA replication. The catalytic subunit of POLIII is encoded by the essential CDC2 gene. The existence of different thermosensitive noncomplementing mutants of CDC2 offers the possibility of using a genetic approach to investigate the involvement of POLIII in induced gene conversion. When cdc2 heteroallelic cells were irradiated and incubated under restrictive conditions, almost no induction of thermoresistant cells could be detected, suggesting an essential role for POLIII in mitotic gene conversion events.
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PMID:Possible involvement of the yeast POLIII DNA polymerase in induced gene conversion. 194 22

The cdc2 cell cycle control genes of yeast and man encode 34 kDa protein kinases. Using the human CDC2 gene as a DNA probe we have isolated cDNA clones corresponding to the mouse cdc2 gene. Sequencing of the mouse clones show 96% identity at the amino acid level to the human CDC2 gene and detects a 2 kb RNA product indistinguishable to that seen in human cells. The mouse gene should be useful in studying the functional control of the cell cycle in mouse cells.
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PMID:Cloning of the mouse homologue of the yeast cell cycle control gene cdc2. 213 58

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