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

The state of cellular senescence is characterised by an irreversible arrest in the G1 phase of the cell cycle. It has previously been shown that three cell cycle genes, cyclin A, cyclin B and cdc2, are not expressed in senescent human fibroblasts. All three gene products have functions after S-phase entry, so that their suppression cannot explain the irreversible G1 arrest. Here, we report that the abundance of transcripts from two other cell cycle genes, cdk2 and cdk4, thought to act during G1-->S progression, is significantly diminished in senescent cells of the diploid human fibroblast line WI-38. Surprisingly, two other cyclins, D1 and E, behave in a completely different way, in that their expression is elevated in senescent cells, especially under conditions of serum starvation. Both the synthesis and the steady-state level of cyclin D1 protein were also found to be markedly higher in senescent cells (3- to 6-fold). Cyclins D1 and E are thus the first genes shown to be overexpressed or deregulated in senescent cells. It is tempting to speculate that this deregulation may be due to the absence, in senescent cells, of a regulatory loop that would normally control their expression. This is supported by our finding that cyclin E-associated kinase activity in senescent cells is reduced approx. 14-fold. Our data also suggest that the deregulated expression of cyclin D1 and E is not sufficient to drive senescent cells into DNA replication.
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PMID:Deregulation of cyclins D1 and E and suppression of cdk2 and cdk4 in senescent human fibroblasts. 836 Feb 68

The differential activation of cyclin and cyclin-dependent kinase genes by the adenovirus E1A gene product (E1A) or serum factors was studied with a rat 3Y1 derivative cell line, g12-21, in which the E1A12S cDNA can be expressed in response to dexamethasone (dex). The induction of DNA synthesis in quiescent g12-21 cells occurred within 12 h after serum stimulation, while it occurred within 8 h after treatment with dex. The expression of cyclin D1 and E genes in the serum-stimulated cells was induced in mid G1 and mid to late G1, respectively, while that of the cyclin D1 gene was not induced and the induction of the cyclin E gene was shifted to the G1/S boundary in the dex-treated cells. The cdk2 gene was induced in late G1 and cdc2 and cyclin A genes at the G1/S boundary in both serum-stimulated and dex-treated cells. These results suggest that E1A skips cell cycle events which normally occur in early to mid G1 and may directly activate late-response genes. Analysis of the transcription factor E2F complexes formed in the promoter regions of cdc2 and dihydrofolate reductase genes showed that the amount of complexes formed is maximal at the G1/S boundary, but decreases in S phase when these genes are transcribed extensively.
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PMID:Differential activation of cyclin and cyclin-dependent kinase genes by adenovirus E1A12S cDNA product. 837 70

We have investigated the effects of deregulated expression of the human c-MYC protooncogene on cyclin gene expression and on the transcription factor E2F. We found that constitutive expression of MYC or activation of conditional MycER chimeras led to higher levels of cyclin A and cyclin E mRNA. Activation of cyclin A expression by MYC led to a growth factor-independent association of cyclin A and cdk2 with the transcription factor E2F and correlated with an increase in E2F transcriptional activity. In contrast, expression of the G1 phase cyclin D1 was strongly reduced in MYC-transformed cells. In synchronized cells, repression of cyclin D1 by MYC occurred very early in the G1 phase of the cell cycle.
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PMID:Differential modulation of cyclin gene expression by MYC. 838 81

In the cell cycle of fission and budding yeast, the p34cdc2/CDC28 kinase is required for both the G1-to-S and G2-to-M phase transitions. In vertebrates, the homologous p34cdc2 kinase is required for G2-to-M phase transitions but appears to be dispensable for DNA synthesis. We have investigated the function of a related kinase, p33cdk2, using serum-stimulated quiescent human fibroblasts. While the p33cdk2 protein was expressed at constant levels throughout the cell cycle, p33cdk2 kinase activity was first detected a few hours prior to the onset of DNA synthesis. Microinjection of anti-p33cdk2 antibodies blocked cells from entering S phase. Pre-adsorption of these antibodies with cdk2 protein abrogated their blocking effect suggesting that the G1 arrest caused by these antibodies is cdk2-specific. These results indicate that p33cdk2 is required for the G1-to-S phase transition in mammalian cells. We also show evidence to suggest that the cyclin E/p33cdk2 complex is likely to be required for entry into S phase since the timing of the cyclin E-associated kinase activity was coincident with that of p33cdk2 and preclearing of either component abolished the majority of the histone H1 kinase activity present in the lysates harvested from the late G1.
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PMID:The cdk2 kinase is required for the G1-to-S transition in mammalian cells. 850 82

The APC gene is mutated in familial adenomatous polyposis (FAP) as well as in sporadic colorectal tumours. The product of the APC gene is a 300 kDa cytoplasmic protein associated with the adherence junction protein catenin. Here we show that overexpression of APC blocks serum-induced cell cycle progression from G0/G1 to the S phase. Mutant APCs identified in FAP and/or colorectal tumours were less inhibitory and partially obstructed the activity of the normal APC. The cell-cycle blocking activity of APC was alleviated by the overexpression of cyclin E/CDK2 or cyclin D1/CDK4. Consistent with this result, kinase activity of CDK2 was significantly down-regulated in cells overexpressing APC although its synthesis remained unchanged, while CDK4 activity was barely affected. These results suggest that APC may play a role in the regulation of the cell cycle by negatively modulating the activity of cyclin-CDK complexes.
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PMID:The tumour suppressor gene product APC blocks cell cycle progression from G0/G1 to S phase. 852 19

Mammalian cultures primarily regulate cell cycle traverse during G1. For progression through G1 and commitment to DNA synthesis, the activity of a family of proteins, the cyclin-dependent kinases (cdks), is required. There are two primary regulatory portions of G1: (a) the G0-G1 transition, which allows entry into G1; and (b) the G1-S transition, promoting entry to DNA synthesis and commitment to cell division. In the present manuscript, we provide evidence for cross-talk between these two cell cycle transitions. Extracts prepared from quiescent mouse mammary epithelial cells are shown to act in a dominant manner to specifically inhibit the histone H1 kinase activity of preformed/active cdk2, cdk4, cyclin A, or cyclin E complexes from G1-S cell extracts. The inhibitory activity arises as cells enter quiescence and decreases once cultures are stimulated to begin G1 traverse and endogenous cdk activity becomes evident. This activity is associated with the regulated binding of the cdk inhibitor p27Kip1 to cyclin A/cdk2 kinase complexes upon mixing of the extracts. Removal of p27Kip1 from the quiescent cell extract specifically abolishes the inhibitory effect. The inhibitory activity and p27Kip1 binding in vitro depend on incubation of the extracts at physiological temperature or the presence of a reducing agent. The results suggest an interplay between the acquisition of quiescence, cdk activity, and G1 traverse.
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PMID:Conditional binding to and cell cycle-regulated inhibition of cyclin-dependent kinase complexes by p27Kip1. 854 20

The E6 and E7 proteins of the high-risk human papillomaviruses (HPVs) act coordinately to immortalize human keratinocytes. These viral oncoproteins function by binding and altering the activity of cellular proteins which regulate cell cycle progression. Among the proteins bound by E7 are the retinoblastoma protein, Rb, as well as the related p107 and p130 proteins. In addition, E7 binds cyclin A, which regulates transit through the S and G2/M phases of the cell cycle. In this study, we demonstrate that HPV 18 E7 also associates with cyclin E which controls the G1/S transition. E7/cyclin E complexes were immunoprecipitated from E7-expressing cells as well as from cell extracts using GST-E7 fusion proteins. E7 was found to complex with a single form of cyclin E, and the binding was mediated through p107. Both E7/cyclin E and E7/cyclin A complexes exhibit kinase activity through associated cdk2 proteins which can contribute to phosphorylation of p107. The association of E7 with proteins which regulate transit through the cell cycle may provide an additional mechanism by which infection with human papillomaviruses results in cellular hyperproliferation.
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PMID:Human papillomavirus E7 oncoproteins bind a single form of cyclin E in a complex with cdk2 and p107. 855 88

Rapamycin (Sirolimus, Rapamune), a potent immunosuppressive agent, has been demonstrated to have remarkable activity in inhibiting allograft rejection in animal models of transplantation. It is currently in phase II clinical trials. Rapamycin belongs to the class of macrocyclic immunosuppressive drugs that are bioactive only when bound to immunophilins. Cyclosporin A and FK506, two other members of this class, selectively block the transcriptional activation of several cytokine genes, thereby inhibiting cytokine production. Although rapamycin and its structural analog FK506 bind to the same immunophilin (FKBP), rapamycin acts at a later stage in T-cell cycle progression by blocking cytokine-mediated signal transduction pathways. This inhibition is the consequence of modulation of activity of a target protein by the rapamycin: FKBP complex [sirolimus effector protein (SEP)]. Although the identification of SEP has recently been reported, its function in cell-cycle progression is not known. The biochemical events that rapamycin has been shown to inhibit are (a) activation of p70S6 kinase, (b) activation of cdk2/cyclin E complex, (c) phosphorylation of retinoblastoma protein, and (d) suppression of cdc2 and cyclin A transcription.
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PMID:Rapamune (Sirolimus, rapamycin): an overview and mechanism of action. 858 37

Rapamycin has potent immunosuppressive properties reflecting its ability to disrupt cytokine signaling that promotes lymphocyte growth and differentiation. In IL-2-stimulated T cells, rapamycin impedes progression through the G1/S transition of the proliferation cycle, resulting in a mid-to-late G1 arrest. Two major biochemical alterations underlie this mode of action. The first one affects the phosphorylation/activation of the p70 S6 kinase (p70s6k), an early event of cytokine-induced mitogenic response. By inhibiting this enzyme, whose major substrate is the 40S ribosomal subunit S6 protein, rapamycin reduces the translation of certain mRNA encoding for ribosomal proteins and elongation factors, thereby decreasing protein synthesis. A second, later effect of rapamycin in IL-2-stimulated T cells is an inhibition of the enzymatic activity of the cyclin-dependent kinase cdk2-cyclin E complex, which functions as a crucial regulator of G1/S transition. This inhibition results from a prevention of the decline of the p27 cdk inhibitor, that normally follows IL-2 stimulation. To mediate these biochemical alterations, rapamycin needs to bind to intracellular proteins, termed FKBP, thereby forming a unique effector molecular complex. However, neither(p70s6k) inhibition, nor p27-induced cdk2-cyclin E inhibition are directly caused by the FKBP-rapamycin complex. Instead, this complex physically interacts with a novel protein, designated "mammalian target of rapamycin" (mTOR), which has sequence homology with the catalytic domain of phosphatidylinositol kinases and may therefore be itself a kinase. mTOR may act upstream of (p70s6K) and cdk2-cyclin E in a linear or bifurcated pathway of growth regulation. Molecular dissection of this pathway should further unravel cytokine-mediated signaling processes and help devise new immunosuppressants.
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PMID:Mechanism of action of the immunosuppressant rapamycin. 859 3

We report here the first extensive in vivo study of cell cycle regulation in the Xenopus embryo. Cyclin A1, B1, B2, and E1 levels, Cdc2 and Cdk2 kinase activity, and Cdc25C phosphorylation states were monitored during early Xenopus embryonic cell cycles. Cyclin B1 and B2 protein levels were high in the unfertilized egg, declined upon fertilization, and reaccumulated to the same level during the first cell cycle, a pattern repeated during each of the following 11 divisions. Cyclin A1 showed a similar pattern, except that its level was lower in the egg than in the cell cycles after fertilization. Cyclin B1/Cdc2 kinase activity oscillated, peaking before each cleavage, and Cdc25C alternated between a highly phosphorylated and a less phosphorylated form that correlated with high and low cyclin B1/Cdc2 kinase activity, respectively. Unlike the mitotic cyclins, the level of cyclin E1 did not oscillate during embryogenesis, although its associated Cdk2 kinase activity cycled twice for each oscillation of cyclin B1/Cdc2 activity, consistent with a role for cyclin E1 in both S-phase and mitosis. Although the length of the first embryonic cycle is regulated by both the level of cyclin B and the phosphorylation state of Cdc2, cyclin accumulation alone was rate-limiting for later cycles, since overexpression of a mitotic cyclin after the first cycle caused cell cycle acceleration. The activity of Cdc2 closely paralleled the accumulation of cyclin B2, but cell cycle acceleration caused by cyclin B overexpression was not associated with elevation of Cdc2 activity to higher than metaphase levels. Tyrosine phosphorylation of Cdc2, absent during cycles 2-12, reappeared at the midblastula transition coincident with the disappearance of cyclin E1. Cyclin A1 disappeared later, at the beginning of gastrulation. Our results suggest that the timing of the cell cycle in the Xenopus embryo evolves from regulation by accumulation of mitotic cyclins to mechanisms involving periodic G1 cyclin expression and inhibitory tyrosine phosphorylation of Cdc2.
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PMID:In vivo regulation of the early embryonic cell cycle in Xenopus. 860 1


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