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)

We show that the fission yeast dis2 protein phosphatase, which is highly similar to mammalian type 1 phosphatase, is a phosphoprotein containing phosphoserine (phospho-S) and threonine (phospho-T). It has several phosphorylation sites, two of which locate in the C-terminus. Phospho-T was abolished in the alanine substitution mutant at the C-terminal T316, which is conserved as a residue in the cdc2 consensus, TPPR, in a number of type 1-like phosphatases. In G2-arrested cdc2-L7 cells, the degree of T316 phosphorylation was reduced, whereas it was enhanced in metaphase-arrested nuc2-663 mutant cells. Phospho-T was produced in dis2 by fission yeast cdc2 kinase, but not in the substitution mutant A316, indicating that the T316 residue was the site for cdc2 kinase in vitro. Phosphatase activity of wild type dis2 was reduced by incubation with cdc2 kinase, but that of mutant dis2-A316 was not. Phosphorylation of T316 hence has a potential significance in cell cycle control in conjunction with cdc2 kinase activation and inactivation. Overexpression phenotypes of wild type dis2+, sds21+ and mutant dis2-A316, sds21-TPPR genes were consistent with negative regulation of dis2 by phosphorylation. This type of regulation would explain why cells harboring the dis2-11 mutation enter mitosis but fail to exit from it.
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PMID:Phosphorylation of dis2 protein phosphatase at the C-terminal cdc2 consensus and its potential role in cell cycle regulation. 795 97

Protein phosphatase 1 and protein phosphatase 2A contain potential phosphorylation sites for cyclin-dependent kinases. In the present study we found that rabbit skeletal muscle protein phosphatase 1, as well as recombinant protein phosphatase 1 alpha and protein phosphatase 1 gamma 1, but not protein phosphatase 2A, was phosphorylated and inhibited by cdc2/cyclin A and cdc2/cyclin B. Phosphopeptide mapping and phospho amino acid analysis suggested that the phosphorylation site was located at a C-terminal threonine. Neither cdc2/cyclin A nor cdc2/cyclin B phosphorylated an active form of protein phosphatase 1 alpha in which Thr-320 had been mutated to alanine, indicating that the phosphorylation occurred at this threonine residue. Furthermore, protein phosphatase 1, but not protein phosphatase 2A, activity was found to change during the cell cycle of human MG-63 osteosarcoma cells. The observed oscillations in protein phosphatase 1 activity during the cell cycle may be due, at least in part, to phosphorylation of protein phosphatase 1 by cyclin-dependent kinases. Together, the results suggest a mechanism for direct regulation of protein phosphatase 1 activity.
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PMID:Phosphorylation and inactivation of protein phosphatase 1 by cyclin-dependent kinases. 802 97

The cyclin-dependent kinases are key cell cycle regulators whose activation is required for passage from one cell cycle phase to the next. In mammalian cells, CDK2 has been implicated in control of the G1 and S phases. We have used a two-hybrid protein interaction screen to identify cDNAs encoding proteins that can interact with CDK2. Among those identified was a protein (KAP), which contained the HCXX-XXGR motif characteristic of protein tyrosine phosphatases. KAP showed phosphatase activity toward substrates containing either phosphotyrosine or phosphoserine residues. Since KAP is not significantly similar to known phosphatases beyond the catalytic core motif, it represents an additional class of dual specificity phosphatase. KAP interacted with cdc2 and CDK2 in yeast. In mammalian cells, KAP also associated with cdc2 and CDK2 but showed a preference for cdc2. The ability of KAP to bind multiple cyclin-dependent kinases suggests that it may play a role in cell cycle regulation.
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PMID:KAP: a dual specificity phosphatase that interacts with cyclin-dependent kinases. 812 73

The cdc25+ tyrosine phosphatase is a key mitotic inducer of the fission yeast Schizosaccharomyces pombe, controlling the timing of the initiation of mitosis. Mammals contain at least three cdc25+ homologues called cdc25A, cdc25B and cdc25C. In this study we investigate the biological function of cdc25A. Although very potent in rescuing the S.pombe cdc25 mutant, cdc25A is less structurally related to the S.pombe enzyme. Northern and Western blotting detection reveals that unlike cdc25B, cdc25C and cdc2, cdc25A is predominantly expressed in late G1. Moreover, immunodepletion of cdc25A in rat cells by microinjection of a specific antibody effectively blocks their cell cycle progression from G1 into the S phase, as determined by laser scanning single cell cytometry. These results indicate that cdc25A is not a mitotic regulator but a novel phosphatase that plays a crucial role in the start of the cell cycle. In view of its strong ability to activate cdc2 kinase and its specific expression in late G1, cdc2-related kinases functioning early in the cell cycle may be targets for this phosphatase.
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PMID:Cdc25A is a novel phosphatase functioning early in the cell cycle. 815 93

The majority of signal transduction studies have focused on events induced by mitogen stimulation. However, little is known about the negative control signals that cause or maintain growth arrest and must be overcome for mitogenesis to occur. We investigated the possible role of protein phosphatases in this negative regulatory process. Treatment of quiescent hamster and human fibroblasts with low doses of the phosphatase inhibitors sodium o-vanadate or okadaic acid allowed 30-40% of cells to progress from G0-G1 arrest to S phase. This was accompanied by phosphorylation of the retinoblastoma and MAP-kinase proteins, as well as induction of the cdc2 protein. Furthermore, we observed that protein phosphatase inhibitor treatment could override the block to DNA synthesis in senescent cells, which are normally nonresponsive to mitogens. These data suggest that protein phosphatases may play a role in the negative regulation of cell growth and maintenance of growth arrest.
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PMID:Disruption of G0-G1 arrest in quiescent and senescent cells treated with phosphatase inhibitors. 816 73

We used the interaction trap, a yeast genetic selection for interacting proteins, to isolate human cyclin-dependent kinase interactor 1 (Cdi1). In yeast, Cdi1 interacts with cyclin-dependent kinases, including human Cdc2, Cdk2, and Cdk3, but not with Ckd4. In HeLa cells, Cdi1 is expressed at the G1 to S transition, and the protein forms stable complexes with Cdk2. Cdi1 bears weak sequence similarity to known tyrosine and dual specificity phosphatases. In vitro, Cdi1 removes phosphate from tyrosine residues in model substrates, but a mutant protein that bears a lesion in the putative active site cysteine does not. Overexpression of wild-type Cdi1 delays progression through the cell cycle in yeast and HeLa cells; delay is dependent on Cdi1 phosphatase activity. These experiments identify Cdi1 as a novel type of protein phosphatase that forms complexes with cyclin-dependent kinases.
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PMID:Cdi1, a human G1 and S phase protein phosphatase that associates with Cdk2. 824 50

Decreased affinity of the retinoblastoma protein (RB) for the nuclear compartment has been correlated with cell cycle-dependent phosphorylation of the RB protein during the G1/S phase of the cell cycle. We examined the effects of microinjected protein-serine/threonine phosphatases types 1 (PP1) and 2A (PP2A) on nuclear association of RB monitored as the resistance of RB to extraction at the G1/S transition. Microinjection of PP1 into either the nucleus or the cytoplasm of cells synchronized in G1 increased the amount of RB that was resistant to extraction from the nucleus. Microinjection of PP2A, however, required direct injection into the nucleus to generate this effect. In addition, we found that nuclear injection of only the PP2A catalytic subunit (PP2AC) and not the complex containing the A and C subunits inhibited RB extraction. Microinjection of either PP1 or PP2A and the resultant increased affinity of RB for the nucleus corresponded with the inhibition of cell cycle progression into S phase. Injection of either phosphatase into cells that had entered S phase did not block DNA synthesis, suggesting that the effect of the injected phosphatases on cell cycle arrest was specific. In vitro biochemical studies with purified PP1 and PP2A showed that intact RB protein phosphorylated by cdc2 kinase served as a substrate for both protein phosphatases. Our results suggest that protein phosphatases may be important regulators of RB function and support the idea that cell cycle progression is regulated by the phosphorylation state of the RB protein.
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PMID:Regulation of cell cycle progression and nuclear affinity of the retinoblastoma protein by protein phosphatases. 838 Jun 37

The yeast Cdc7 function is required for the G1/S transition and is dependent on passage through START, a point controlled by the Cdc28/cdc2/p34 protein kinase. CDC7 encodes a protein kinase activity, and we now show that this kinase activity varies in the cell cycle but that protein levels appear to remain constant. We present several lines of evidence that periodic activation of CDC7 kinase is at least in part through phosphorylation. First, the kinase activity of the Cdc7 protein is destroyed by dephosphorylation of the protein in vitro with phosphatase. Second, Cdc7 protein is hypophosphorylated and inactive as a kinase in extracts of cells arrested at START but becomes active and maximally phosphorylated subsequent to passage through START. The phosphorylation pattern of Cdc7 protein is complex. Phosphopeptide mapping reveals four phosphopeptides in Cdc7 prepared from asynchronous yeast cells. Both autophosphorylation and phosphorylation in trans appear to contribute to this pattern. Autophosphorylation is shown to occur by using a thermolabile Cdc7 protein. A protein in yeast extracts can phosphorylate and activate Cdc7 protein made in Escherichia coli, and phosphorylation is thermolabile in cdc28 mutant extracts. Cdc7 protein carrying a serine to alanine change in the consensus recognition site for Cdc28 kinase shows an altered phosphopeptide map, suggesting that this site is important in determining the overall Cdc7 phosphorylation pattern.
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PMID:Regulation of Saccharomyces cerevisiae CDC7 function during the cell cycle. 838 76

To understand the role of the type 2A-like protein phosphatase in the cell division cycle, we investigated the mutant phenotypes obtained when the fission yeast ppa1+ and ppa2+ phosphatase genes (which encode polypeptides with approximately 80% identity to mammalian type 2A phosphatases) were either deleted or overexpressed. We also investigated the in vivo effect of okadaic acid, an inhibitor of protein serine/threonine phosphatases, on cell division. We show that ppa2+ interacts genetically with the cell cell regulators cdc25+ and wee1+, as a ppa2 deletion is lethal when combined with wee1-50 but partially suppresses the conditional lethality of cdc25-22 mutation. Evidence that ppa2+ negatively controls the entry into mitosis, possibly through the regulation of cdc2 tyrosine phosphorylation, is presented. ppa2 phosphatase is abundant in the cytoplasm, in contrast to the type 1-like phosphatase dis2, which is enriched in the nucleus. Overproduced ppa1 or ppa2 proteins accumulate in the cytoplasm near the nuclear periphery, and cells arrest in interphase. Okadaic acid-treated cells, like a ppa2 deletion, are short in length and display protein hyperphosphorylation. Cytokinesis is also inhibited, producing binucleated cells. We show that ppa2 is the genetic locus controlling okadaic acid sensitivity. The ppa2 deletion reveals the same hyperphosphorylated proteins as okadaic acid. When a strain deleted for ppa2 is treated with okadaic acid, cell size is reduced further to that of wee1-50 mutant strain or overexpressing the cdc25+ gene product, suggesting functional relationship of ppa2 with the cdc25 tyrosine phosphatase and/or the wee1 kinase in cell cycle control.
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PMID:Negative regulation of mitosis by the fission yeast protein phosphatase ppa2. 838 6

Caldesmon phosphatase was identified in chicken gizzard smooth muscle by using as substrates caldesmon phosphorylated at different sites by protein kinase C, Ca2+/calmodulin-dependent protein kinase II and cdc2 kinase. Most (approximately 90%) of the phosphatase activity was recovered in the cytosolic fraction. Gel filtration after (NH4)2SO4 fractionation of the cytosolic fraction revealed a single major peak of phosphatase activity which coeluted with calponin phosphatase [Winder, Pato and Walsh (1992) Biochem. J. 286, 197-203] and myosin LC20 phosphatase. Further purification of caldesmon phosphatase was achieved by sequential chromatography on columns of DEAE-Sephacel, omega-amino-octyl-agarose, aminopropyl-agarose and thiophosphorylated myosin LC20-Sepharose. A single peak of caldesmon phosphatase activity was detected at each step of the purification. The purified phosphatase was identified as SMP-I [Pato and Adelstein (1980) J. Biol. Chem. 255, 6535-6538] by subunit composition (three subunits, of 60, 55 and 38 kDa) and Western blotting using antibodies against the holoenzyme which recognize all three subunits and antibodies specific for the 38 kDa catalytic subunit. SMP-I is a type 2A protein phosphatase [Pato, Adelstein, Crouch, Safer, Ingebritsen and Cohen (1983) Eur. J. Biochem. 132, 283-287; Winder et al. (1992), cited above]. Consistent with the conclusion that SMP-I is the major caldesmon phosphatase of smooth muscle, purified SMP-I from turkey gizzard dephosphorylated all three phosphorylated forms of caldesmon, whereas SMP-II, -III and -IV were relatively ineffective. Kinetic analysis of dephosphorylation by chicken gizzard SMP-I of the three phosphorylated caldesmon species and calponin phosphorylated by protein kinase C indicates that calponin is a significantly better substrate of SMP-I than are any of the three phosphorylated forms of caldesmon. We therefore suggest that caldesmon phosphorylation in vivo can be maintained after kinase inactivation due to slow dephosphorylation by SMP-I, whereas calponin and myosin are rapidly dephosphorylated by SMP-I and SMP-III/SMP-IV respectively. This may have important functional consequences in terms of the contractile properties of smooth muscle.
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PMID:Smooth-muscle caldesmon phosphatase is SMP-I, a type 2A protein phosphatase. 839 39

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