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)

Cyclins are regulatory molecules that undergo periodic accumulation and destruction during each cell cycle. By activating p34cdc2 and related kinase subunits they control important events required for normal cell cycle progression. Cyclin A, for example, regulates at least two distinct kinase subunits, the mitotic kinase subunit p34cdc2 and related subunit p33cdk2, and is widely believed to be necessary for progression through S phase. However, cyclin A also forms a stable complex with the cellular transcription factor DRTF1 and thus may perform other functions during S phase. DRTF1, in addition, associates with the tumour suppressor retinoblastoma (Rb) gene product and the Rb-related protein p107. We now show, using biologically active fusion proteins, that cyclin A can direct the binding of the cdc2-like kinase subunit, p33cdk2, to complexed DRTF1, containing either Rb or p107, as well as activate its histone H1 kinase activity. Cyclin A cannot, however, direct p34cdc2 to the DRTF1 complex and we present evidence suggesting that the stability of the cyclin A-p33cdk2 complex is influenced by DRTF1 or an associated protein. Cyclin A, therefore, serves as an activating and targeting subunit of p33cdk2. The ability of cyclin A to activate and recruit p33cdk2 to DRTF1 may play an important role in regulating cell cycle progression and moreover defines a mechanism for coupling cell-cycle events to transcriptional initiation.
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PMID:Cyclin A recruits p33cdk2 to the cellular transcription factor DRTF1. 129 52

RPA is a single-stranded DNA binding protein complex purified from human cells and is essential for the initiation and elongation stages of SV40 DNA replication in vitro. In both human and yeast cells, the 34 kDa polypeptide subunit of RPA is phosphorylated in the S and G2 phases of the cell cycle and not in G1. One of the major RPA kinases present in extracts of human cells was purified and shown to be the cyclin B-cdc2 complex. This purified kinase, and a closely related cyclin A associated cdc2-like kinase, phosphorylated RPA p34 on a subset of the chymotryptic peptides that were phosphorylated in vivo at the G1-S transition. Two serines near the N-terminus of RPA p34 were identified as possible sites of phosphorylation by cdc2 kinase. These same serines were necessary for RPA phosphorylation in vivo. The purified cdc2 kinase stimulated SV40 DNA replication in vitro when added to G1 cell extracts. The kinase also stimulated unwinding at the origin of replication, one of the earliest steps in DNA replication requiring RPA, but only in the presence of an additional factor present in G1 cell extracts. Thus, one or more members of the cyclin-cdc2 kinase family may be required for the initiation and maintenance of S phase, in part due to their ability to phosphorylate and activate a cellular DNA replication factor, RPA.
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PMID:cdc2 family kinases phosphorylate a human cell DNA replication factor, RPA, and activate DNA replication. 131 95

The growth-suppressive activity of the retinoblastoma (RB) protein is suggested to be regulated by phosphorylation. In studies on the kinase that phosphorylates the RB proteins, we have previously found that RB proteins can be phosphorylated by purified cdc2 kinase. In this study, we noted that RB proteins immunoprecipitated from human cell lysates are weakly phosphorylated in the absence of purified cdc2 kinase. Immunoblot analysis showed the presence of p34cdc2 in the immunoprecipitates with anti-RB monoclonal antibody. In addition, the coprecipitated kinase was found to have the same substrate specificity as cdc2 kinase. The associated kinase activity was particularly high in cells arrested in G1/S and S phase by aphidicolin. Furthermore, RB proteins were shown to be phosphorylated in nuclear extracts by some endogenous cdc2-like kinase(s). These results suggest that cdc2-like kinase is the main kinase for phosphorylation of RB proteins in vivo.
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PMID:cdc2-like kinase is associated with the retinoblastoma protein. 159 40

Human myeloid leukemia cells (i.e., HL-60, U937, THP-1) which are induced to differentiate along the monocytic pathway by 12-O-tetradecanoylphorbol-13-acetate (TPA), revert back to the undifferentiated phenotype after 3 to 4 weeks. During this differentiation and retrodifferentiation process the cells obviously establish a distinct sequence of biological processes which is integrally regulated to simultaneously control differentiation and cell growth. Thus, induction of monocytic markers by TPA is associated with a down-regulation of cell cycle genes and cessation of proliferation. In particular, crosstalk between the TPA-induced translocation of protein kinase C (PKC) and the activation of transcription factors, especially AP-1, enhances the expression of genes associated with the monocytic phenotype. This is accompanied by induction of intermediate filament proteins, surface glycoproteins, changes in membrane properties and intracellular metabolism. In parallel, the cells cease to divide, and genes associated with cell cycle progression including cdc2, cyclins, cdc25, and histones are down-regulated. Although signals responsible for arrested cell growth remain unclear, there are several control mechanisms regarding cell cycle genes and differentiation parameters (for a review, see Nigg, E. A., Seminars in Cell Biol., 2, 262-270, 1991). For example, activated p34cdc2 kinase is involved in lamina disassembly by direct phosphorylation of lamin proteins which may contribute to nuclear envelope breakdown during mitosis (Enoch, T., M. Peter, P. Nurse, J. Cell Biol. 112, 797-807 (1991)). Moreover, endomembrane traffic is arrested by a cdc2-like kinase probably via phosphorylation of members of the rab protein family which contributes to vesiculation and membrane transport by hydrolyzing GTP (Tuomikoski, T., et al., Nature 342, 942-945 (1989)). Although there are several reports on a possible feedback control between differentiation and cell cycle, including phosphorylation of cyclins and activation of a ubiquitin-dependent proteolytic degradation, signaling pathways and possible mechanisms for retrodifferentiation and reentry into the cell cycle remain unclear. While some terminally differentiated cells are committed to die, the major part of the differentiated monocytic population undergoes retrodifferentiation. All cellular signals characterized so far are reverted during retrodifferentiation: Redistribution of PKC and down-regulation of c-fos and c-jun contribute to an interruption of the differentiation-associated transsignaling cascade. Thus, down-regulation of markers associated with monocytic differentiation in combination with metabolic changes restore the original cell phenotype. At the same time cell cycle genes are up-regulated, and the cells regain proliferative capacity. Finally, retrodifferentiated and untreated control cells demonstrate indistinguishable properties.
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PMID:Retrodifferentiation--an alternative biological pathway in human leukemia cells. 164 56

A homology probing approach was utilized to isolate a new human protein kinase. Deoxyoligonucleotide probes recognizing a conserved subdomain in the COOH-terminal portion of protein kinases identified a cDNA clone encoding a putative kinase with predicted serine/threonine phosphorylation specificity. The full-length, 1.7-kilobase pair cDNA hybridizes to 1.7- and 3.4-kilobase mRNA transcripts in a number of tissues. The size of the encoded protein is 454 amino acids and consists of an NH2-terminal 130-residue segment, which may represent a regulatory region, followed by a 324-residue catalytic domain. Comparisons and alignments of the primary sequence and predicted secondary structure of the catalytic region to other known kinases reveal that the new kinase, denoted "CLK" (for CDC-like kinase), represents a prototype for a new family of human protein kinases bearing significant homology to the yeast cdc2/CDC28 kinases that regulate the cell cycle.
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PMID:Molecular cloning of a novel human cdc2/CDC28-like protein kinase. 170 89

In a screen of mouse erythroleukemia cDNA expression libraries with anti-phosphotyrosine antibodies, designed to isolate tyrosine kinase coding sequences, we identified several cDNAs encoding proteins identical or very similar to known protein-tyrosine kinases. However, two frequently isolated cDNAs, clk and nek, encode proteins which are most closely related to protein kinases involved in regulating progression through the cell cycle, and contain motifs generally considered diagnostic of protein-serine/threonine kinases. The clk gene product contains a C-terminal cdc2-like kinase domain, most similar to the FUS3 catalytic domain. The Clk protein, expressed in bacteria, becomes efficiently phosphorylated in vitro on tyrosine as well as serine/threonine, and phosphorylates the exogenous substrate poly(glu, tyr) on tyrosine. Direct biochemical evidence indicates that both protein-tyrosine and protein-serine/threonine kinase activities are intrinsic to the Clk catalytic domain. These results suggest the existence of a novel class of protein kinases, with an unusual substrate specificity, which may be involved in cell cycle control.
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PMID:A mammalian protein kinase with potential for serine/threonine and tyrosine phosphorylation is related to cell cycle regulators. 182 55

The cdc2/cdk2 protein kinases play key roles in the cell cycle at two control points: the G1/S transition and the entry into mitosis. Olomoucine, a specific inhibitor of these kinases, was tested in two plant cell systems: Petunia mesophyll protoplasts induced to divide and Arabidopsis thaliana cell suspension cultures. The cell cycle status was analysed from DNA histograms or through continuous labelling of cells with 5-bromodeoxyuridine (BrdUrd) followed by double staining with bis-benzimide (Hoechst 33258) and propidium iodide (PI). Such analyses resolve cells from several generations according to the extent of their DNA replication. Olomoucine was shown to reversibly arrest differentiated Petunia cells induced to divide at G1 phase and cycling Arabidopsis cells in late G1 and G2. A comparison of the effects of aphidicolin, oryzalin and olomoucine suggests that in the Arabidopsis cell suspension culture, a cdc2/cdk2-like kinase is activated at a restriction point in late G1.
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PMID:Olomoucine, an inhibitor of the cdc2/cdk2 kinases activity, blocks plant cells at the G1 to S and G2 to M cell cycle transitions. 752 94

The major kinase capable of phosphorylating tau in a porcine brain extract was suggested to be a brain cdc2-like kinase, called cdk5. Tau protein components of microtubules assembled in the brain extract using ATP were phosphorylated to a higher level, and showed a slower electrophoretic mobility than those assembled with GTP. Most of this phosphorylation and electrophoretic mobility shift, that occurred in the brain extract incubated with ATP, were inhibited by butyrolactone I, a specific inhibitor of cdc2 kinase and cdk5. Further, butyrolactone I inhibited phosphorylation of tau exogenously added to the brain extract by approximately 70%. cdk5 purified from porcine brain decreased the electrophoretic mobility of dephosphorylated tau by in vitro phosphorylation of tau to the level present in microtubules polymerized with ATP. cdc2 kinase purified from starfish oocytes also phosphorylated tau and shifted its electrophoretic mobility to an extent greater than that obtained with cdk5. Western blot analysis showed that cdc2 kinase phosphorylated epitopes recognized by SMI31, 33, 34, and tau 1 antibodies in tau proteins , while cdk5 phosphorylated the site recognized by SMI33 (corresponding to phosphorylation at Ser235 in the longest human tau isoform) and partially phosphorylated the tau 1 site. Phosphorylation experiments performed on tau in brain extracts, in the presence of okadaic acid, suggested the presence of both okadaic acid-sensitive and -insensitive phosphatases acting on phosphorylated Ser235. Rat tau that was prepared immediately after decapitation showed a similar phosphorylation state to tau in microtubules polymerized with ATP, suggesting that tau is relatively phosphorylated in vivo.
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PMID:Evidence for cdk5 as a major activity phosphorylating tau protein in porcine brain extract. 759 34

P13suc1 sepharose-conjugated beads were used to extract the kinases that phosphorylate neurofilaments in the squid giant axon. Using Western blots and in vitro kinase assays, we demonstrated the presence of an active cdc2-like kinase and its putative regulators such as cyclin E, p13, and p67 in axoplasm and a P13-axoplasm complex (P13-Ax). Protein kinase A (PKA) and casein kinase (CK) I and II were also found in the P13-Ax. Western blot analysis of the P13-Ax also demonstrated several axonal cytoskeletal components; e.g., neurofilaments (NFs; NF 60, 70, and 220), tubulin, actin, and microtubule-associated proteins. NF 220 and tubulin were phosphorylated by the kinases in the P13-Ax. To determine whether NFs bound directly to the P13 beads, or bound indirectly by association with cdc2 kinase, a washed, axon-derived neurofilament preparation that contained NFs, PKA, CKl, and tubulin, but no cdc2-like kinase, yielded no bound proteins after incubation with P13suc1. The wash supernatant from the neurofilament preparation, however, containing the cdc2-like kinase, did yield cytoskeletal components that bound to P13suc1. Moreover, a bacterial-expressed cdk5 associated with P13 beads was able to complex with selected cytoskeletal components in the washed neurofilament preparation. These data indicate that direct binding of P13 beads with a cdc2-like kinase could extract active multimeric complexes composed of axonal cytoskeletal proteins and kinases. Application of P13 chromatography may be useful in characterizing the network of functional interactions among cytoskeletal elements and protein kinases in neurons.
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PMID:P13suc1 associates with a cdc2-like kinase in a multimeric cytoskeletal complex in squid axoplasm. 766 4

Transformation of cells in culture by polyomavirus is mediated by one of its early gene products, middle-sized tumor antigen (MTAg). This protein forms multiple complexes with cellular enzymes such as tyrosine kinases (pp60c-src), a phosphatidylinositol 3-kinase, and phosphatase 2A. Association with MTAg leads to the activation of pp60c-src through interference with phosphorylation at Tyr-527, a site negatively regulating src kinase activity. MTAg abrogates mitosis-specific activation of pp60c-src, resulting in constitutive high kinase activity of the enzyme throughout all phases of the cell cycle. Here we report that MTAg is transiently modified during mitosis, resulting in an increase in its apparent molecular size on SDS/acrylamide gels. Similarly, MTAg isolated from interphase cells and phosphorylated by the cell cycle-regulated serine/threonine kinase p34cdc2 in vitro has increased molecular mass. The large molecular mass form of the protein can be converted to the authentic 56-kDa form upon dephosphorylation by potato acid phosphatase. Two putative phosphorylation sites for a cdc2-like kinase were identified as Thr-160 and -291, respectively. Conversion of Thr-160 to Ala resulted in a transformation-defective mutant protein that was still capable of associating with pp60c-src, phosphatidylinositol 3-kinase, and phosphatase 2A, while the corresponding mutant in position 291 was wild type with respect to all parameters measured so far. These data suggest that phosphorylation by p34cdc2 or a related cell cycle-regulated kinase modulates the interaction of MTAg with cellular targets that are crucial for cell transformation.
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PMID:Mitosis-specific phosphorylation of polyomavirus middle-sized tumor antigen and its role during cell transformation. 769 Jan 42


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