EC:2.7.11.1 - FACTA Search

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Query: EC:2.7.11.1 (protein kinase)
81,284 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In eucaryotes, M-phase promoting factor (MPF) triggers meiosis in germ cells and mitosis in somatic cells. MPF is composed of two proteins of which one is homologous with the protein kinase encoded by gene cdc2 of Schizosaccharomyces pombe (p34cdc2) and the other is a cyclin whose concentration oscillates during the cell cycle. Inactivation of p34cdc2 (MPF) requires cyclin degradation, which occurs during the metaphase-anaphase transition of the M-phase. Cyclin degradation is not only associated with cell cycle progression, but is also required for this event. At the G2/M transition, p34cdc2 protein kinase is activated and catalyzes phosphorylation of numerous key proteins, thus enabling cell changes to occur. p34cdc2 undergoes multiple-site phosphorylation in a cell cycle-dependent manner. At onset of mitosis, the protein phosphatase cdc25 catalyzes dephosphorylation of the p34cdc2 kinase at the threonine 14 and tyrosine 15 sites. This event may be the rate-limiting step controlling onset of mitosis in cells of vertebrates. A second protein kinase, encoded by the proto-oncogene c-mos, acts as a cytostatic factor preventing cyclin degradation and keeping unfertilized eggs from progressing beyond the second meiotic metaphase.
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PMID:[Control of cell division in eucaryotes]. 839 83

Unfertilized frog eggs arrest at the second meiotic metaphase, due to cytostatic activity of the c-mos proto-oncogene (CSF). MAP kinase has been proposed to mediate CSF activity in suppressing cyclin degradation. Using an in vitro assay to generate CSF activity, and recombinant CL 100 phosphatase to inactivate MAP kinase, we confirm that the c-mos proto-oncogene blocks cyclin degradation through MAP kinase activation. We further show that for MAP kinase to suppress cyclin degradation, it must be activated before cyclin B-cdc2 kinase has effectively promoted cyclin degradation. Thus MAP kinase does not inactivate, but rather prevents the cyclin degradation pathway from being turned on. Using a constitutively active mutant of Ca2+/calmodulin dependent protein kinase II, which mediates the effects of Ca2+ at fertilization, we further show that the kinase can activate cyclin degradation in the presence of both MPF and the c-mos proto-oncogene without inactivating MAP kinase.
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PMID:MAP kinase does not inactivate, but rather prevents the cyclin degradation pathway from being turned on in Xenopus egg extracts. 883 8

The product of the c-mos proto-oncogene is a protein kinase that is normally expressed in germ cells and functions during oocyte maturation. It has been shown, however, that inappropriate expression of either the viral or cellular mos gene can induce neoplastic progression in somatic cells. Furthermore, v-mos-transformed NIH3T3 cells will undergo arrest of proliferation in early G1 upon serum withdrawal but are unable to appropriately down-regulate cell cycle regulatory proteins, such as cyclin and cdc2 proteins, that normally are down-regulated in quiescent, untransformed NIH3T3 cells. Since the levels of these proteins are partially transcriptionally controlled, we investigated whether there were alterations in the expression of E2F and AP-1 transcription factor complexes. Indeed, the putative G0/G1-specific p130-E2F complex that is normally observed during low serum-induced cell cycle arrest in NIH3T3 cells is not present in serum starved v-mos-transformed cells. Instead, G1-phase arrested v-mos-transformed cells stably express two E2F protein complexes that are normally observed only during S-phase in untransformed cells. The elevation of these complexes in arrested v-mos-transformed cells may be the cause of the transcriptional activation of the E2F-regulated genes cdc2, DHFR, cyclin A, and E2F1 seen in serum starved v-mos-transformed cells. In addition, there are high levels of AP-1 DNA binding activity in serum starved v-mos-transformed cells compared to very low amounts in nontransformed cells. This altered regulation of transcription factor complexes and cell cycle control proteins upon serum withdrawal may provide a mechanism for the uncontrolled cell growth associated with neoplastic transformation induced by certain proto-oncogenes.
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PMID:Deregulation of specific E2F complexes by the v-mos oncogene. 922 66

During oocyte maturation and early development, mRNAs receive poly(A) in the cytoplasm at distinct times relative to one another and to the cell cycle. These cytoplasmic polyadenylation reactions do not occur during oogenesis, but begin during oocyte maturation and continue throughout early development. In this report, we focus on the link between cytoplasmic polyadenylation and control of the cell cycle during meiotic maturation. Activation of maturation promoting factor, a complex of CDK1 and cyclin, is required for maturation and dependent on c-mos protein kinase. We demonstrate here that two classes of polyadenylation exist during oocyte maturation, defined by their dependence of c-mos and CDK1 protein kinases. Polyadenylation of the first class of mRNAs (class I) is independent of c-mos and CDK1 kinase activities, whereas polyadenylation of the second class (class II) requires both of these activities. Class I polyadenylation, through its effects on c-mos mRNA, is required for class II polyadenylation. cis-acting elements responsible for this distinction reside in the 3'-untranslated region, upstream of the polyadenylation signal AAUAAA. Cytoplasmic polyadenylation elements (CPEs) are sufficient to specify class I polyadenylation, and subtle changes in the CPE can substantially, though not entirely, shift an RNA from class I to class II. Activation of class I polyadenylation events is independent of hyperphosphorylation of CPE-binding protein or poly(A) polymerase, and requires cellular protein synthesis. The two classes of polyadenylation and of mRNA define a dependent pathway, in which polyadenylation of certain mRNAs requires the prior polyadenylation of another. We propose that this provides one method of regulating the temporal order of polyadenylation events, and links polyadenylation to the control of the meiotic cell cycle.
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PMID:A dependent pathway of cytoplasmic polyadenylation reactions linked to cell cycle control by c-mos and CDK1 activation. 928 30

Cytoplasmic polyadenylation controls the translation of several maternal mRNAs during Xenopus oocyte maturation and requires two sequences in the 3' untranslated region (UTR), the U-rich cytoplasmic polyadenylation element (CPE), and the hexanucleotide AAUAAA. c-mos mRNA is polyadenylated and translated soon after the induction of maturation, and this protein kinase is necessary for a kinase cascade culminating in cdc2 kinase (MPF) activation. Other mRNAs are polyadenylated later, around the time of cdc2 kinase activation. To determine whether there is a hierarchy in the cytoplasmic polyadenylation of maternal mRNAs, we ablated c-mos mRNA with an antisense oligonucleotide. This prevented histone B4 and cyclin A1 and B1 mRNA polyadenylation, indicating that the polyadenylation of these mRNAs is Mos dependent. To investigate a possible role of cdc2 kinase in this process, cyclin B was injected into oocytes lacking c-mos mRNA. cdc2 kinase was activated, but mitogen-activated protein kinase was not. However, polyadenylation of cyclin B1 and histone B4 mRNA was still observed. This demonstrates that cdc2 kinase can induce cytoplasmic polyadenylation in the absence of Mos. Our data further indicate that although phosphorylation of the CPE binding protein may be involved in the induction of Mos-dependent polyadenylation, it is not required for Mos-independent polyadenylation. We characterized the elements conferring Mos dependence (Mos response elements) in the histone B4 and cyclin B1 mRNAs by mutational analysis. For histone B4 mRNA, the Mos response elements were in the coding region or 5' UTR. For cyclin B1 mRNA, the main Mos response element was a CPE that overlaps with the AAUAAA hexanucleotide. This indicates that the position of the CPE can have a profound influence on the timing of cytoplasmic polyadenylation.
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PMID:The Mos pathway regulates cytoplasmic polyadenylation in Xenopus oocytes. 934 4

Mitogen-activated protein kinase kinases (MKKs or MEKs) are dual specificity tyrosine/threonine protein kinases that are activated by phosphorylation at two closely spaced serine residues (serines-218 and -222) by the c-mos and raf proto-oncogenes. This double phosphorylation is both necessary and sufficient for MEKs to activate the MAP kinase enzymes in vitro. The specificity or regulation of in vivo signaling to the mammalian MEKs (MEK1 and MEK2) was recently reported also to involve the differential phosphorylation of a proline-rich peptide located between the MEK kinase-subdomains IX and X. Here we report the purification and characterization of an auto-activating protein kinase from bovine brain that phosphorylates serine-298 of the MEK1 and MEK2 proline-rich insert peptides. The auto-activation of the MEK-S298 peptide kinase is the result of an intermolecular phosphorylation event that can be prevented by the peptide substrates. The inactive kinase migrates on gel filtration as a 90 kDa protein, and after activation as a 43 kDa phosphoprotein. Incorporation of 32P[phosphate] into 40-42 kDa proteins on SDS-PAGE parallels the activation of the enzyme, and dephosphorylation by protein phosphatase 2Ac reverses the activation. SDS-PAGE renaturation assays show that the 40 kDa protein has the capacity to autophosphorylate, and exhibits kinase activity towards myelin basic protein after activation. Phosphorylation of purified bovine brain MEK or recombinant MEK1 by the auto-activated kinase does not activate the enzyme, and does not interfere with the in vitro raf-mediated MEK activation. We conclude that still unknown kinases may control the MAP kinase pathway by targeting MEK.
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PMID:Identification and characterization of an auto-activating MEK kinase from bovine brain: phosphorylation of serine-298 in the proline-rich domain of the mammalian MEKs. 941 3

Mos is a germ cell-specific serine/threonine protein kinase that plays an important role during meiotic divisions of oocytes. Upon expression in somatic cells, Mos causes cell cycle perturbations leading to neoplastic transformation. Mos activates the MAP kinase pathway in both oocytes and transformed somatic cells. To determine the mechanism of cell cycle perturbation in mos-transformed cells, we examined the status of some key regulators of G1 phase. We provide evidence that Mos causes an elevation in the level of cyclin D1 in NIH/3T3 cells. As expected from the increased cyclin D1 level, mos transformation of NIH/3T3 cells caused an increase in the protein kinase activities of cyclin D1-Cdk4 and cyclin E-Cdk2 and induced hyperphosphorylation of the retinoblastoma protein. Of importance, the level of cyclin D1 was also elevated in eye lens of the c-mos-transgenic mice compared to normal mice. Our results indicate that the mechanism of cellular transformation by Mos involves an elevation in the level of cyclin D1 in somatic cells.
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PMID:Elevated level of cyclin D1 in mos-transformed cells. 953 50

Cytoplasmic polyadenylation of specific mRNAs commonly is correlated with their translational activation during development. Here, we focus on links between cytoplasmic polyadenylation, translational activation and the control of meiotic maturation in Xenopus oocytes. We manipulate endogenous c-mos mRNA, which encodes a protein kinase that regulates meiotic maturation. We determined that translational activation of endogenous c-mos mRNA requires a long poly(A) tail per se, rather than the process of polyadenylation. For this, we injected 'prosthetic' poly(A)_synthetic poly(A) tails designed to attach by base pairing to endogenous c-mos mRNA that has had its own polyadenylation signals removed. This prosthetic poly(A) tail activates c-mos translation and restores meiotic maturation in response to progesterone. Thus the role of polyadenylation in activating c-mos mRNA differs from its role in activating certain other mRNAs, for which the act of polyadenylation is required. In the absence of progesterone, prosthetic poly(A) does not stimulate c-mos expression, implying that progesterone acts at additional steps to elevate c-Mos protein. By using a general inhibitor of polyadenylation together with prosthetic poly(A), we demonstrate that these additional steps include polyadenylation of at least one other mRNA, in addition to that of c-mos mRNA. These other mRNAs, encoding regulators of meiotic maturation, act upstream of c-Mos in the meiotic maturation pathway.
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PMID:Meiotic maturation in Xenopus requires polyadenylation of multiple mRNAs. 960 98

The purpose of the present review is to outline the current understanding on the molecular mechanisms governing various stages of oocyte maturation, transition from maternal to embryonic control and the initial steps of pre-embryo development. The cytoplasmic and nuclear maturation of the oocyte during pre-ovulatory development can be viewed as separate entities. Cytoplasmic maturation and the acquisition of stores of RNA and protein dominates oocyte development between the premordial and pre-ovulatory stages of development. Initiation of nuclear maturation is marked by the breakdown of the nuclear envelope, or germinal vesicle and is triggered by the midcycle luteinizing hormone peak. In vitro, this is associated with a decrease in the intracellular concentrations of cAMP. This and several subsequent steps of meiosis are controlled by the M-phase promoting factor (MPF). While the constituents of MPF, p34cdc2 kinase and B-type cyclin, are also present in mitotically dividing cells, in meiotically dividing oocytes the regulation of MPF activity differs. An oocyte-specific protein kinase, c-mos, plays an important role in up-regulating the activity of MPF at various stages of final oocyte maturation. Several lines of evidence suggest that the proper function of the c-mos-MPF system is associated with important features of the last stages of oocyte maturation such as the resumption of meiotic maturation, inhibition of DNA replication between meiosis I and II, and the maintenance of the oocyte at metaphase II arrest until it is fertilized. Eventually the destruction of c-mos and active MPF following fertilization allows the initiation of mitotic cell division in the pre-embryo. The very first cell divisions of the human pre-embryo are still under the control of maternally inherited mRNA and protein. Several lines of evidence suggest that in humans, zygotic gene expression is initiated between the 4- and 8-cell stages, after which the pre-embryo begins to utilize its own genes. Some of the first genes to be expressed in the human pre-embryo encode proteins that are associated with cell division, extracellular growth modulatory signals as well as factors associated with implantation. We acknowledge that most of the data presented comes from species other than human, therefore at present the full biological role of the proposed regulatory pathways and control mechanisms for human biology remains speculative.
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PMID:The molecular mechanisms of oocyte maturation and early embryonic development are unveiling new insights into reproductive medicine. 973 31

It has been shown previously that protein kinase A (PKA) maintains Xenopus oocytes arrested at G2, at least in part by preventing c-mos translation, but how PKA controls c-mos translation is not known. Using microinjection of recombinant c-mos, which still activates MAP kinase in the presence of active PKA, we have found that PKA does not exert any effect on translation of endogenous c-mos if MAP kinase is first activated. Even though they accumulate c-mos and contain MAP kinase activity as high as control oocytes, oocytes do not exit G2 in the presence of active PKA. These results are discussed in connection with recent findings on regulation of c-raf activity.
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PMID:Inactivation of protein kinase A is not required for c-mos translation during meiotic maturation of Xenopus oocytes. 977 64

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