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)

The mammalian D-type cyclins promote progression through a G1 checkpoint by phosphorylating the retinoblastoma protein (pRB), and can contribute to oncogenesis via their deregulated expression achieved through gene amplification, chromosomal rearrangement, or retroviral integration. We now report a novel mechanism of tumour-associated D-cyclin over-abundance, resulting from enhanced protein stability. In two human cell lines established from a single uterine sarcoma biopsy, pRB-positive SK-UT-1B and pRB-deficient SK-UT-1, aberrant accumulation of functional cyclins D1, and D2 and D3 occurred in the absence of gene amplification and/or elevated mRNA expression. The abundance of D-cyclin proteins remained elevated throughout the cell cycle, and pulse-chase experiments revealed six to 10-fold prolongation of their protein half-lives as compared with either diploid fibroblasts or control U-2-OS sarcoma cells. These results point to a critical regulatory role of D-type cyclin turnover, and contribute to refinement of current views of the role played by the cyclin D-CDK-p16-pRB pathway in cell cycle control and tumorigenesis.
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PMID:Enhanced protein stability: a novel mechanism of D-type cyclin over-abundance identified in human sarcoma cells. 871 Mar 82

Cyclin-dependent kinases (Cdks) are required for cell cycle progression. Two potentially significant Cdk substrates in human cells are the human single-stranded binding protein (HSSB or RPA), which plays an essential role in DNA replication, repair, and recombination, and the tumor suppressor p107 which acts to negatively regulate cell growth. In this report we describe the in vitro phosphorylation of these two proteins by Cdks in an attempt to understand how cyclin-substrate interactions direct phosphorylation efficiencies. We show that cyclin A-Cdk2 efficiently phosphorylates the p34 subunit of HSSB (HSSB-p34) alone or as a part of the heterotrimeric complex. In contrast, cyclin E-Cdk2 that is active in phosphorylating histone H1, does not support the phosphorylation of the p34 subunit of HSSB. We provide evidence that this differential phosphorylation results from a specific interaction between HSSB-p34 and cyclin A, but not cyclin E. Thus the observed cell cycle-dependent phosphorylation of HSSB-p34 at the G1 to S transition is most likely catalyzed by cyclin A-Cdk2 initiated by the direct interaction between cyclin A and the HSSB-p34 subunit. These studies are consistent with our previous observation that p107, which directly binds cyclin A, is efficiently phosphorylated by cyclin A-Cdk2 but not cyclin B-associated kinases. Here we further demonstrate that cyclin A only complexes with p107 in its unphosphorylated form. These data suggest a catalytic mechanism by which Cdk acts: substrate targeting by a cyclin-substrate interaction followed by dissociation of the Cdk upon phosphate incorporation allowing the Cdk to become available for the next cycle of phosphorylation.
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PMID:Studies on the in vitro phosphorylation of HSSB-p34 and -p107 by cyclin-dependent kinases. Cyclin-substrate interactions dictate the efficiency of phosphorylation. 879 63

HIV-1 Rev transactivator is readily phosphorylated at separate regions by protein kinase CK2 and MAP kinase. Protein kinase CK1 cannot replace CK2 as phosphorylating agent and cdc2 only slowly phosphorylates Rev at one of the two sites affected by MAP kinase. Mutational analysis shows that Ser-8 and, to a lesser extent, Ser-5 are phosphorylated by CK2. In contrast, a mutation (R14TV-->EED) which suppresses Rev activity dramatically enhances Rev phosphorylation either in vitro by CK2 or in vivo, suggesting that phosphorylation by CK2 could play a role in Rev down-regulation.
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PMID:Phosphorylation of HIV-1 Rev protein: implication of protein kinase CK2 and pro-directed kinases. 880 71

We studied the subcellular distribution of cdk2 in synchronized, PDGF-stimulated human fibroblasts (FH109). After contact inhibition and serum depletion, more than 95% of FH109 cells were arrested in G0/G1-phase. PDGF-AB led to a 16-fold increase in proliferation compared with untreated cells. Cell cycle progression was studied by flow cytometric analysis, [3H]thymidine incorporation, and phosphorylation of the retinoblastoma gene product, pRB. Using Western blot analysis after subcellular fractionation, we revealed that after PDGF stimulation the phosphorylated (Thr 160), i.e., activated, form of cdk2 (33 kDa) first appeared in the nucleus at late G1-phase and persisted throughout until to the end of S-phase. Since cdk2 was not synthesized de novo, and the amount of inactive cdk2 (35 kDa) remained constant in the nucleus, we suggested a translocation from the cytosol to the nucleus in late G1. Using immunofluorescence techniques, we detected a diffuse staining in quiescent cells. Starting at late G1-phase, cdk2 immunoreactivity was concentrated to the nucleus while immunoreactivity in the cytosol disappeared. We therefore draw the conclusion that cdk2 is translocated from the cytosol into the nucleus in late G1-phase. Since protein levels and activity of cdk7, which is the catalytic subunit of cdk-activating kinase (CAK) phosphorylating cdk2, remained constant throughout the cell cycle, CAK activity might therefore be regulated by the availability of its substrate cdk2.
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PMID:Translocation of cdk2 to the nucleus during G1-phase in PDGF-stimulated human fibroblasts. 914 23

Kaposi's sarcoma-associated herpesvirus (KSHV or human herpesvirus 8) is a novel gammaherpesvirus implicated in the cause of Kaposi's sarcoma and certain malignancies of lymphatic origin. One of the candidate genes possibly involved in promoting tumor development is an open reading frame (ORF) with sequence similarity to human type D cyclin genes. This cyclin-like gene, when expressed in tissue culture cells, promotes phosphorylation and inactivation of the retinoblastoma tumor suppressor protein and thereby may result in deregulation of cell division control. We report here the biochemical characterization of this cyclin (KSHV-cyc) and the kinase activity that it elicits upon expression in tissue culture cells. We demonstrate that the kinase activity associated with KSHV-cyc is sensitive to the cdk inhibitor p27 (KIP) and due to activation of cdk6. However, in contrast to cdk6 activated by cellular type D cyclins, the cdk6 activated by KSHV-cyc is capable of phosphorylating not only the retinoblastoma protein but also histone H1. This finding implies that activation by KSHV-cyc alters the substrate preference of this cdk. This may have important physiological consequences in that the kinase activity triggered by this viral cyclin may abrogate cell cycle checkpoints in addition to those targeted by cellular cyclin D-cdk6 kinase.
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PMID:The cyclin encoded by Kaposi's sarcoma-associated herpesvirus stimulates cdk6 to phosphorylate the retinoblastoma protein and histone H1. 915 5

The fission yeast gene cdc18(+) is required for entry into S phase and for coupling mitosis to the successful completion of S phase. Cdc18 is a highly unstable protein that is expressed only once per cell cycle at the G1/S boundary. Overexpression of Cdc18 causes a mitotic delay and reinitiation of DNA replication, suggesting that the inactivation of Cdc18 plays a role in preventing rereplication within a given cell cycle. In this paper, we present evidence that Cdc18 is associated with active cyclin-dependent kinase in vivo. We have expressed Cdc18 as a glutathione S-transferase fusion in fission yeast and demonstrated that the fusion protein is functional in vivo. We find that the Cdc18 fusion protein copurifies with a kinase activity capable of phosphorylating histone H1 and Cdc18. The activity was identified by a variety of methods as the cyclin-dependent kinase containing the product of the cdc2(+) gene. The amino terminus of Cdc18 is required for association with cyclin-dependent kinase, but the association does not require the consensus cyclin-dependent kinase phosphorylation sites in this region. Additionally, both G1/S and mitotic forms of cyclin-dependent kinase phosphorylate and interact with Cdc18. These interactions between Cdc18 and cyclin-dependent kinases suggest mechanisms by which cyclin-dependent kinases could activate the initiation of DNA replication and could prevent rereplication.
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PMID:Interaction of the S phase regulator cdc18 with cyclin-dependent kinase in fission yeast. 917 84

In cells of higher eukaryotes, cyclin D-dependent kinases Cdk4 and Cdk6 and, possibly, cyclin E-dependent Cdk2 positively regulate the G1- to S-phase transition, by phosphorylating the retinoblastoma protein (pRb), thereby releasing E2F transcription factors that control S-phase genes. Here we performed microinjection and transfection experiments using rat R12 fibroblasts, their derivatives conditionally overexpressing cyclins D1 or E, and human U-2-OS cells, to explore the action of G1 cyclins and the relationship of E2F and cyclin E in S-phase induction. We demonstrate that ectopic expression of cyclin E, but not cyclin D1, can override G1 arrest imposed by either the p16INK4a Cdk inhibitor specific for Cdk4 and Cdk6 or a novel phosphorylation-deficient mutant pRb. Several complementary approaches to assess E2F activation, including quantitative reporter assays in live cells, showed that the cyclin E-induced S phase and completion of the cell division cycle can occur in the absence of E2F-mediated transactivation. Together with the ability of cyclin E to overcome a G1 block induced by expression of dominant-negative mutant DP-1, a heterodimeric partner of E2Fs, these results provide evidence for a cyclin E-controlled S phase-promoting event in somatic cells downstream of or parallel to phosphorylation of pRb and independent of E2F activation. They furthermore indicate that a lack of E2F-mediated transactivation can be compensated by hyperactivation of this cyclin E-controlled event.
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PMID:Cyclin E-induced S phase without activation of the pRb/E2F pathway. 919 74

Mammalian D-type cyclins are differentially expressed during the first gap phase (G1) of the cell cycle in various cell types, and function as regulatory subunits of cyclin-dependent kinases (cdks), cdk4 and cdk6, to form holoenzymes whose activities are both necessary and rate limiting for G1 progression. Mitogenic signals induce the expression of cyclin D and cdk4 proteins, and facilitate their assembly into holoenzymes and their post-translational modification, while anti-proliferative stimuli extinguish the activity of cyclin D-dependent kinases by inducing cdk inhibitors which directly interfere with their catalytic functions and/or inhibit the post-translational activation of cyclin-bound cdks. Therefore, a variety of extracellular signals target and regulate the cyclin D/cdk4 serine/threonine kinases, which execute their critical functions during middle to late G1 phase by phosphorylating key substrates, including the retinoblastoma tumor suppressor gene products (pRb). Although overexpression of cyclin D, or inactivation of Rb or cdk inhibitor gene alone is not sufficient for cell transformation, high frequency of alterations of these genes in cancers suggests that inactivation of this particular pathway is involved in tumor development.
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PMID:Control of G1 progression by D-type cyclins: key event for cell proliferation. 920 86

Activation of the Cdc2.cyclin B kinase is a pivotal step of mitotic initiation. This step is mediated principally by the dephosphorylation of residues threonine 14 (Thr14) and tyrosine 15 (Tyr15) on the Cdc2 catalytic subunit. In several organisms homologs of the Wee1 kinase have been shown to be the major activity responsible for phosphorylating the Tyr15 inhibitory site. A membrane-bound kinase capable of phosphorylating residue Thr14, the Myt1 kinase, has been identified in the frog Xenopus laevis and more recently in human. In this study, we have examined the substrate specificity and cell cycle regulation of the human Myt1 kinase. We find that human Myt1 phosphorylates and inactivates Cdc2-containing cyclin complexes but not complexes containing Cdk2 or Cdk4. Analysis of endogenous Myt1 demonstrates that it remains membrane-bound throughout the cell cycle, but its kinase activity decreased during M phase arrest, when Myt1 became hyperphosphorylated. Further, Cdc2. cyclin B1 was capable of phosphorylating Myt1 in vitro, but this phosphorylation did not affect Myt1 kinase activity. These findings suggest that human Myt1 is negatively regulated by an M phase-activated kinase and that Myt1 inhibits mitosis due to its specificity for Cdc2.cyclin complexes.
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PMID:Human Myt1 is a cell cycle-regulated kinase that inhibits Cdc2 but not Cdk2 activity. 926 80

We have found that ectopic expression of cyclin A increases hormone-dependent and hormone-independent transcriptional activation by the estrogen receptor in vivo in a number of cell lines, including HeLa cells, U-2 OS osteosarcoma cells and Hs 578Bst breast epithelial cells. This effect can be further enhanced in HeLa cells by the concurrent expression of the cyclin-dependent kinase activator, cyclin H, and cdk7, and abolished by expression of the cdk inhibitor, p27(KIP1), or by the expression of a dominant negative catalytically inactive cdk2 mutant. ER is phosphorylated between amino acids 82 and 121 in vitro by the cyclin A/cdk2 complex and incorporation of phosphate into ER is stimulated by ectopic expression of cyclin A in vivo. Together, these results strongly suggest a direct role for the cyclin A/cdk2 complex in phosphorylating ER and regulating its transcriptional activity.
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PMID:Regulation of estrogen receptor transcriptional enhancement by the cyclin A/Cdk2 complex. 929 75

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