EC:2.7.12.2 - FACTA Search

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Query: EC:2.7.12.2 (MEK)
18,161 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Serpentine receptors coupled to the heterotrimeric G protein, Gi2, are capable of stimulating DNA synthesis in a variety of cell types. A common feature of the Gi2-coupled stimulation of DNA synthesis is the activation of the mitogen-activated protein kinases (MAPKs). The regulation of MAPK activation by the Gi2-coupled thrombin and acetylcholine muscarinic M2 receptors occurs by a sequential activation of a network of protein kinases. The MAPK kinase (MEK) which phosphorylates and activates MAPK is also activated by phosphorylation. MEK is phosphorylated and activated by either Raf or MEK kinase (MEKK). Thus, Raf and MEKK converge at MEK to regulate MAPK. Gi2-coupled receptors are capable of activating MEK and MAPK by Raf-dependent and Raf-independent mechanisms. Pertussis toxin catalyzed ADP-ribosylation of alpha i2 inhibits both the Raf-dependent and -independent pathways activated by Gi2-coupled receptors. The Raf-dependent pathway involves Ras activation, while the Raf-independent activation of MEK and MAPK does not involve Ras. The Raf-independent activation of MEK and MAPK most likely involves the activation of MEKK. The vertebrate MEKK is homologous to the Ste11 and Byr2 protein kinases in the yeast Saccharomyces cerevisiae and Schizosaccharomyces pombe, respectively. The yeast Ste11 and Byr2 protein kinases are involved in signal transduction cascades initiated by pheromone receptors having a 7 membrane spanning serpentine structure coupled to G proteins. MEKK appears to be conserved in the regulation of G protein-coupled signal pathways in yeast and vertebrates. Raf represents a divergence in vertebrates from the yeast pheromone-responsive protein kinase system.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:How does the G protein, Gi2, transduce mitogenic signals? 801 90

Expression of the GTPase-deficient G alpha 16 polypeptide G alpha 16Q212L, a member of the Gq family of heterotrimeric G proteins, constitutively activated phospholipase C beta activity in Swiss 3T3 cells. Expression of G alpha 16Q212L appears to persistently stimulte a low level of protein kinase C activity which also increases protein kinase A activity in Swiss 3T3 cells. Growth of G alpha 16Q212L expressing cells was significantly inhibited relative to wild-type Swiss 3T3 cells. Bombesin-stimulated DNA synthesis was completely inhibited in G alpha 16Q212L expressing clones, whereas the growth responses to platelet-derived growth factor (PDGF) and serum were inhibited 50-80% relative to wild-type cells. In addition to the inhibition of cell growth, G alpha 16Q212L expression significantly inhibited the stimulation of protein kinase C, Raf-1, MEK, mitogen-activated protein kinase, phospholipase A2 activity, and Ca2+ mobilization in response to PDGF. In contrast, PDGF receptor activation of phospholipase C gamma, phosphatidylinositol 3-kinase, and Ras GTP loading was similar in wild-type and G alpha 16Q212L expressing clones. PDGF regulation of membrane ruffling and actin fiber assembly, responses mediated in part by phosphatidylinositol 3-kinase, were unaffected in G alpha 16Q212L expressing clones. The growth inhibitory action of G alpha 16Q212L expression in Swiss 3T3 cells is downstream of the initial SH2 domain-encoded signal transduction proteins regulated in response to PDGF receptor autophosphorylation. The findings demonstrate that constitutively activated G alpha 16Q212L persistently activates phospholipase C activity and effectively inhibits a subset of cytoplasmic signal transduction pathways involved in growth factor tyrosine kinase receptor stimulation of cell growth. G16/Gq-regulated signal transduction can acutely stimulate specific response pathways involved in mitogenesis; but persistent activation of G16/Gq-regulated effectors, including phospholipase C beta, inhibit tyrosine kinase-initiated mitogenesis. One role for G16/Gq response systems may be to modulate growth factor receptor signaling.
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PMID:Expression of GTPase-deficient G alpha 16 inhibits Swiss 3T3 cell growth. 802 Dec 43

We have studied the role of Raf-1 in mitogenesis and cellular transformation induced by G protein-coupled receptors in NIH 3T3 cells transfected with the human m1 muscarinic receptor. We have observed that in m1-expressing NIH 3T3 cells, the cholinergic agonist carbachol induces a dose- and time-dependent shift in the electrophoretic mobility of p72Raf-1, equivalent to that observed when using phorbol esters or platelet-derived growth factor as stimulants. Phosphoamino acid analysis of slower mobility forms of p72Raf-1 revealed both phosphoserine and phosphothreonine. Carbachol potently induced c-Raf activity as judged by its in vitro phosphorylating activity using MEK as a substrate. However, induction of Raf-1 kinase activity by carbachol occurred much earlier than changes in its electrophoretic mobility. Raf-1 kinase activation followed a kinetic similar to that exhibited by an epitope-tagged ERK2 protein when coexpressed in the same cells. Conventional protein kinase C (PKC) inactivation by means of sustained phorbol ester treatment or by a new nontoxic PKC-specific inhibitor, GF 109203X, abolished p72Raf-1 mobility shift induced by carbachol or by phorbol esters. However, c-Raf and ERK2 enzymatic activity in response to carbachol was at least 50-80% PKC-independent. Furthermore, inhibition of PKC failed to affect DNA synthesis or focus formation induced by carbachol in cells expressing m1 receptors. In contrast, cotransfection of NIH 3T3 cells with the Raf-1 dominant negative mutant Raf-301 (K375W) drastically decreased the transforming ability of m1 receptors. Thus, our findings implicate Raf-1 activation in transformation by G protein-coupled receptors. In addition, our data suggest that activation of p72Raf-1 and ERK2 by G protein-coupled receptors involves PKC-independent pathways.
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PMID:Signaling through transforming G protein-coupled receptors in NIH 3T3 cells involves c-Raf activation. Evidence for a protein kinase C-independent pathway. 806 29

Mitogen activated protein kinases (MAP) or extracellular signal regulated protein kinases (ERK) are a family of protein serine/threonine kinases that are activated very rapidly in response to many extracellular stimuli. elk-1, an ets related gene codes for two transcriptional factors elk-1, which regulates c-fos transcription and delta elk-1, both of which are substrates for MAP kinases. A part of the C-terminal transcriptional activation domain (ETA-2) which is common to both the proteins was previously shown to function as an activator of MAP kinases. In this report, in an attempt to investigate the mechanism of activation of MAP kinases, purified preparations of recombinant elk-1 and P44mpk/ERK-1/ERK-2 proteins were used to show the association of elk-1 proteins with MAP kinases. The specific interactions of elk-1 proteins with MAP kinases were confirmed by co-immunoprecipitation studies. Thus elk-1 proteins appear to regulate the activity of MAP kinases by interacting with them ensuring a conformational change and stimulating their autophosphorylation and activation property. The activation was dependent on the presence of ATP and Mg2+. In vitro phosphorylation of elk-1 protein was not regulatory for autonomous DNA binding activity of elk-1 protein. Cells which were exposed to EGF showed a rapid stimulation of an elk-1 specific kinase activity, probably MAP kinase which phosphorylated MBP and was found to be associated with immobilized GST-elk-1. Furthermore, dephosphorylation studies indicate that elk-1 proteins can activate only tyrosine phosphorylated MAP kinase. These results demonstrate the presence of an alternative pathway/mechanism (other than MAP kinase kinase, MAPKK/Mek) for the activation of MAP kinases with tyrosine phosphorylation occurring before serine/threonine autophosphorylation and activation by elk-1 proteins.
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PMID:elk-1 proteins interact with MAP kinases. 820 31

MEK1 is a dual specificity kinase that phosphorylates and activates the Erk/MAP kinases Erk-1 and Erk-2 by phosphorylating them on threonine and tyrosine. We report the cloning of a second MEK-like complementary DNA, Mek2, which predicts a protein of a molecular weight of 44,500. The MEK2 protein bears substantial sequence homology to MEK1, except at its amino terminus, and at a proline-rich region insert between the conserved kinase subdomains 9 and 10. MEK1 and MEK2 are shown to be encoded by different genes and are located on murine chromosomes 9 and 10, respectively. Northern analysis indicates that Mek2 is expressed at low levels in adult mouse brain and heart tissue, and at higher levels in other tissues examined. Low expression levels of Mek2 in brain tissue are in contrast to the high levels of Mek1 expressed in brain. Mek2 is expressed at high levels in neonatal brain, however. Recombinant MEK2 produced in bacteria phosphorylates a kinase-inactive Erk-1 on tyrosine and threonine, whereas a kinase-inactive mutant MEK2 does not. These findings suggest that MEK2 is a member of a multigene family.
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PMID:MEK2 is a kinase related to MEK1 and is differentially expressed in murine tissues. 829 98

Mitogen-activated protein kinases (MAPKs) are rapidly phosphorylated and activated in response to various extracellular stimuli in many different cell types. Such regulation of MAPK results from sequential activation of a series of protein kinases. The kinases that phosphorylate MAPKs, the MAP kinase kinases (MEKs) are also activated by phosphorylation. MEKs are related in sequence to the yeast protein kinases Byr1 (from Schizosaccharomyces pombe) and Ste7 (from Saccharomyces cerevisiae), which function in the pheromone-induced signaling pathway that results in mating. Byr1 and Ste7 are in turn regulated by the protein kinases Byr2 and Ste11. The amino acid sequence of the mouse homolog of Byr2 and Ste11, denoted MEKK (MEK kinase), was elucidated from a complementary DNA sequence encoding a protein of 672 amino acid residues (73 kilodaltons). MEKK was expressed in all mouse tissues tested, and it phosphorylated and activated MEK. Phosphorylation and activation of MEK by MEKK was independent of Raf, a growth factor-regulated protein kinase that also phosphorylates MEK. Thus, MEKK and Raf converge at MEK in the protein kinase network mediating the activation of MAPKs by hormones, growth factors, and neurotransmitters.
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PMID:A divergence in the MAP kinase regulatory network defined by MEK kinase and Raf. 838 2

Plasma membrane-enriched fractions were prepared from human embryonic retinal cells transformed with either adenovirus E1A and oncogenic ras DNA, or E1A and E1B DNA. Ras comprised 5-10% of the membrane protein from the E1A/ras transformed cells, whereas the membranes from E1A/E1B transformed cells did not overexpress Ras. The membranes from E1A/ras cells contained MAP kinase kinase kinase (MAPKKK) activity, even after washing in 0.5 M NaCl, whereas the membranes from E1A/E1B cells did not. Neither membrane fraction contained MAP kinase kinase or MAP kinase activity after washing with 0.5M NaCl. Immunoblotting experiments revealed about 10-fold more c-Raf in the membranes from E1A/ras cells than from E1A/E1B cells, and 50-60% of the MAPKKK activity in Triton X100-solubilised membranes from E1A/ras cells was immunoprecipitated with anti-Raf antibodies. A striking enrichment of c-Raf in the plasma membranes of E1A/ras cells was also demonstrated by immunocytochemistry, where it was co-localized with Ras. The MAPKKK activity in E1A/ras membranes was unaffected by incubation with protein phosphatases or by inclusion of protein phosphatase inhibitors during isolation, nor was it activated by GTP-Ras or inhibited by GDP-Ras. The results support the view that Ras and c-Raf interact with one another, but that neither c-Raf phosphorylation nor its interaction with GTP-Ras are alone sufficient for activation. The identification of MAPKKK activity in the membranes of ras-transformed cells may prove useful in elucidating the mechanism by which Raf is activated by Ras.
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PMID:Specific association of activated MAP kinase kinase kinase (Raf) with the plasma membranes of ras-transformed retinal cells. 841 21

Mutants defective in meiotic recombination were isolated from a disomic haploid strain of Saccharomyces cerevisiae by examining recombination within the leu2 and his4 heteroalleles located on chromosome III. The mutants were classified into two new complementation groups (MRE2 and MRE11) and eight previously identified groups, which include SPO11, HOP1, REC114, MRE4/MEK1 and genes in the RAD52 epistasis group. All of the mutants, in which the mutations in the new complementation groups are homozygous and diploid, can undergo premeiotic DNA synthesis and produce spores. The spores are, however, not viable. The mre2 and mre11 mutants produce viable spores in a spo13 background, in which meiosis I is bypassed, suggesting that these mutants are blocked at an early step in meiotic recombination. The mre2 mutant does not exhibit any unusual phenotype during mitosis and it is, thus, considered to have a mutation in a meiosis-specific gene. By contrast, the mre11 mutant is sensitive to damage to DNA by methyl methanesulfonate and exhibits a hyperrecombination phenotype in mitosis. Among six alleles of HOP1 that were isolated, an unusual pattern of intragenic complementation was observed.
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PMID:Identification of new genes required for meiotic recombination in Saccharomyces cerevisiae. 841 89

Previous studies of Saccharomyces cerevisiae have identified several meiosis-specific genes whose products are required for wild-type levels of meiotic recombination and for normal synaptonemal complex (SC) formation. Several of these mutants were examined in a physical assay designed to detect heteroduplex DNA (hDNA) intermediates in meiotic recombination. hDNA was not detected in the rec102, mei4 and hop1 mutants; it was observed at reduced levels in red1, mek1 and mer1 strains and at greater than the wild-type level in zip1. These results indicate that the REC102, MEI4, HOP1, RED1, MEK1 and MER1 gene products act before hDNA formation in the meiotic recombination pathway, whereas ZIP1 acts later. The same mutants assayed for hDNA formation were monitored for meiotic chromosome pairing by in situ hybridization of chromosome-specific DNA probes to spread meiotic nuclei. Homolog pairing occurs at wild-type levels in the zip1 and mek1 mutants, but is substantially reduced in mei4, rec102, hop1, red1 and mer1 strains. Even mutants that fail to recombine or to make any SC or SC precursors undergo a significant amount of meiotic chromosome pairing. The in situ hybridization procedure revealed defects in meiotic chromatin condensation in mer1, red1 and hop1 strains.
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PMID:Heteroduplex DNA formation and homolog pairing in yeast meiotic mutants. 853 92

Rap1 small GTP-binding protein has the same amino acid sequence at its effector domain as that of Ras. Rap1 has been shown to antagonize the Ras functions, such as the Ras-induced transformation of NIH 3T3 cells and the Ras-induced activation of the c-Raf-1 protein kinase-dependent mitogen-activated protein (MAP) kinase cascade in Rat-1 cells, whereas we have shown that Rap1 as well as Ras stimulates DNA synthesis in Swiss 3T3 cells. We have established a cell-free assay system in which Ras activates bovine brain B-Raf protein kinase. Here we have used this assay system and examined the effect of Rap1 on the B-Raf activity to phosphorylate recombinant MAP kinase kinase (MEK). Recombinant Rap1B stimulated the activity of B-Raf, which was partially purified from bovine brain and immunoprecipitated by an anti-B-Raf antibody. The GTP-bound form was active, but the GDP-bound form was inactive. The fully post-translationally lipid-modified form was active, but the unmodified form was nearly inactive. The maximum B-Raf activity stimulated by Rap1B was nearly the same as that stimulated by Ki-Ras. Rap1B enhanced the Ki-Ras-stimulated B-Raf activity in an additive manner. These results indicate that not only Ras but also Rap1 is involved in the activation of the B-Raf-dependent MAP kinase cascade.
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PMID:Activation of brain B-Raf protein kinase by Rap1B small GTP-binding protein. 857 7

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