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)

The involvement of pertussis toxin (PTX)-sensitive and -insensitive pathways in the activation of the mitogen-activated protein kinase (MAPK) cascade was examined in ventricular cardiomyocytes cultured from neonatal rats. A number of agonists that activate heterotrimeric G-protein-coupled receptors stimulated MAPK activity after exposure for 5 min. These included foetal calf serum (FCS), endothelin-1 (these two being the most effective of the agonists examined), phenylephrine, endothelin-3, lysophosphatidic acid, carbachol, isoprenaline and angiotensin II. Activation of MAPK and MAPK kinase (MEK) by carbachol returned to control levels within 30-60 min, whereas activation by FCS was more sustained. FPLC on Mono Q showed that carbachol and FCS activated two peaks of MEK and two peaks of MAPK (p42MAPK and p44MAPK). Pretreatment of cells with PTX for 24 h inhibited the activation of MAPK by carbachol, FCS and lysophosphatidic acid, but not that by endothelin-1, phenylephrine or isoprenaline. Involvement of G-proteins in the activation of the cardiac MAPK cascade was demonstrated by the sustained (PTX-insensitive) activation of MAPK (and MEK) after exposure of cells to AlF4-. AlF4- activated PtdIns hydrolysis, as did endothelin-1, endothelin-3, phenylephrine and FCS. In contrast, the effect of lysophosphatidic acid on PtdIns hydrolysis was small and carbachol was without significant effect even after prolonged exposure. We conclude that PTX-sensitive (i.e. Gi/G(o)-linked) and PTX-insensitive (i.e. Gq/Gs-linked) pathways of MAPK activation exist in neonatal ventricular myocytes. FCS may stimulate the MAPK cascade through both pathways.
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PMID:Activation of the mitogen-activated protein kinase cascade by pertussis toxin-sensitive and -insensitive pathways in cultured ventricular cardiomyocytes. 762 7

PHAS-I levels increased 8-fold as 3T3-L1 fibroblasts differentiated into adipocytes and acquired sensitivity to insulin. Insulin increased PHAS-I protein (3.3-fold after 2 days), the rate of PHAS-I synthesis (3-fold after 1 h), and the half-life of the protein (from 1.5 to 2.5 days). Insulin also increased the phosphorylation of PHAS-I and promoted dissociation of the PHAS-I eukaryotic initiation factor-4E (eIF-4E) complex, effects that were maximal within 10 min. With recombinant [H6]PHAS-I as substrate, mitogen-activated protein (MAP) kinase was the only insulin-stimulated PHAS-I kinase detected after fractionation of extracts by Mono Q chromatography; however, MAP kinase did not readily phosphorylate [H6]PHAS-I when the [H6]PHAS-I.eIF-4E complex was the substrate. Thus, while MAP kinase may phosphorylate free PHAS-I, it is not sufficient to dissociate the complex. Moreover, rapamycin attenuated the stimulation of PHAS-I phosphorylation by insulin and markedly inhibited dissociation of PHAS-I.eIF-4E, without decreasing MAP kinase activity. Rapamycin abolished the effects of insulin on increasing phosphorylation of ribosomal protein S6 and on activating p70S6K. The MAP kinase kinase inhibitor, PD 098059, markedly decreased MAP kinase activation by insulin, but it did not change PHAS-I phosphorylation or the association of PHAS-I with eIF-4E. In summary, insulin increases the expression of PHAS-I and promotes phosphorylation of multiple sites in the protein via multiple transduction pathways, one of which is rapamycin-sensitive and independent of MAP kinase. Rapamycin may inhibit translation initiation by increasing PHAS-I binding to eIF-4E.
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PMID:Control of PHAS-I by insulin in 3T3-L1 adipocytes. Synthesis, degradation, and phosphorylation by a rapamycin-sensitive and mitogen-activated protein kinase-independent pathway. 762 82

Ras proteins function through the formation of specific complexes with Raf-1, B-raf, PI-3 kinase and RalGDS. These interactions all require Ras-GTP with an intact effector binding domain (Switch I region). We have examined the requirements of the Switch II region (amino acids 60-72) for the production of stable interactions between Ras and its downstream effectors. A point mutation at position 65 or 64 combined with additional mutations at either position 65 or 71 rendered nucleotide-free Ras protein unable to stably interact with Ras specific guanine nucleotide exchange factors. Ha-Ras containing point mutations at positions 65 and 71 possessed a twofold higher affinity for B-raf and consequently MEK1. The point mutation at 64, in combination with additional point mutations at either position 65 or 71, resulted in a protein which failed to interact with either PI-3 kinase or neurofibromin, though these Ras mutants effectively bound both Raf-1 and B-raf. An activated form of Ras, Q61L-Ras, associated with all effector proteins independent of the bound guanine nucleotide. Q61L-Ras-GDP was almost as effective as wild type Ras-GMPPNP in the in vitro activation of MEK1 and MAP kinase. Competitive studies with the catalytic domain if neurofibromin, NF1-GRD, demonstrated that its interaction with Ras-GMPPNP is mutually exclusive with both Raf-1 and B-raf. These data suggest that rasGAP and neurofibromin are unable to downregulate Ras-GTP complexed to Raf-1 or B-raf.
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PMID:Different structural requirements within the switch II region of the Ras protein for interactions with specific downstream targets. 763 Jun 28

A kinase cascade highly conserved throughout evolution, Raf/MAP kinase kinase kinase (MAPKKK)-->MAP kinase kinase (MAPKK)-->MAP kinase (MAPK)-->ribosomal S6 kinase (p90 RSK), is thought to play a crucial role in signal transduction from the membrane to the nucleus. In mammalian cells, this cascade is connected both to tyrosine kinase receptors and G protein-coupled receptors. Although the mode of activation at the receptor level differs, all mitogens activate the ubiquitously expressed isoforms of MAPK, p42 and p44. We have cloned, epitope tagged and expressed in fibroblasts, the Hamster MAPKK and p44 MAPK in order to analyze their time-course of activation, their subcellular localization, their regulatory phosphorylation sites and their role in cell cycle entry. We have demonstrated that MAPK activation was rapid, biphasic and persistent. The sustained phase of activation is only obtained with potent mitogenic agents, correlating with their ability to elicit cell cycle entry. Activation of MAPKK is also rapid and persistent but does not distinguish between mitogenic and non mitogenic factors, indicating that a distinction occurs at the MAPK level, probably by the action of specific phosphatases such as MAPK phosphatase MKP-1. Both isoforms of MAPK are translocated into the nucleus upon growth factor addition whereas the upstream activators (MAPKKK, Raf and MAPKK) remain cytoplasmic. MAPK translocation, together with the ability of MAPK to phosphorylate transcription factors, indicates that MAPK might constitute a relay between cytoplasmic and nuclear events. Finally we show that interfering with the MAP kinase cascade, by expressing either MAPK antisense, a MAPK dominant negative mutant or the MAPK specific phosphatase, MKP-1, suppresses the growth factor induced G0 to G1 transition. In addition, permanently activated versions of MAPKK reduce growth factor requirement, allow autonomous cell growth and induce tumor formation in nude mice. We therefore conclude that MAP kinase activation is both necessary and sufficient to trigger cell cycle entry.
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PMID:[MAP kinase module: role in the control of cell proliferation]. 764 66

The c-Rmil/B-raf proto-oncogene belongs to the mil/raf family encoding serine/threonine protein kinases shown to be involved in signal transduction from the membrane to the nucleus. We previously showed that the avian c-Rmil gene encodes two proteins of 94 and 95 kDa resulting from the alternative splicing of a 120 bp exon encoding 40 aminoacids (exon 10). We isolated from a mouse brain library B-raf cDNAs containing this exon 10 and a previously unidentified 36 bp insert which constitutes an additional alternatively spliced exon designated exon 8b. These two exons are located between the CR2 region and the catalytic domain of the protein. By using specific sera generated against different regions of the B-Raf protein, we identified 10 B-Raf isoforms and we defined their structure and their expression pattern in adult mouse tissues. The B-Raf proteins are mainly expressed in neural tissues and, interestingly, isoforms containing aminoacids encoded by exon 10 are specifically expressed in these tissues. We also show that several B-Raf isoforms interact with the Mek-1 protein (MAP kinase kinase) and phosphorylate this protein on serine residues 218 and 222.
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PMID:[B-raf gene encodes for multiple isoforms with Mek-1 kinase activity]. 764 69

A mutant rat cell clone that suppresses the transformation defects of RAS effector loop substitutions is heterozygous for mutations in c-raf1 and MEK1. The mutant cells can be transformed by many otherwise defective RAS effector mutants, including RAS genes with the effector regions of distantly related GTPases, even though the encoded RAS proteins do not interact with either the mutant or wild-type RAF in Saccharomyces cerevisiae. While the significance of the c-raf1 mutation is unclear, the MEK1 mutation increases MEK1 activity and leads to activation of mitogen-activated protein kinase. The mutant MEK1 is coupled to the epidermal growth factor pathway but exhibits decreased physical interaction with RAF. When overexpressed, the MEK1 mutation is transforming and causes hyperphosphorylation of RAF. Signalling from RAS to MEK1 may be mediated by something other than RAF alone, but signalling through MEK1 is probably sufficient for RAS transformation.
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PMID:RAS signalling is abnormal in a c-raf1 MEK1 double mutant. 765 28

Members of the Rho family of small guanosine triphosphatases (GTPases) regulate the organization of the actin cytoskeleton; Rho controls the assembly of actin stress fibers and focal adhesion complexes, Rac regulates actin filament accumulation at the plasma membrane to produce lamellipodia and membrane ruffles, and Cdc42 stimulates the formation of filopodia. When microinjected into quiescent fibroblasts, Rho, Rac, and Cdc42 stimulated cell cycle progression through G1 and subsequent DNA synthesis. Furthermore, microinjection of dominant negative forms of Rac and Cdc42 or of the Rho inhibitor C3 transferase blocked serum-induced DNA synthesis. Unlike Ras, none of the Rho GTPases activated the mitogen-activated protein kinase (MAPK) cascade that contains the protein kinases c-Raf1, MEK (MAPK or ERK kinase), and ERK (extracellular signal-regulated kinase). Instead, Rac and Cdc42, but not Rho, stimulated a distinct MAP kinase, the c-Jun kinase JNK/SAPK (Jun NH2-terminal kinase or stress-activated protein kinase). Rho, Rac, and Cdc42 control signal transduction pathways that are essential for cell growth.
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PMID:An essential role for Rho, Rac, and Cdc42 GTPases in cell cycle progression through G1. 765 75

Simultaneous inactivation of pyp1 and pyp2 PTPases in fission yeast leads to aberrant cell morphology and growth arrest. Spontaneous recessive mutations that bypass the requirement for pyp1 and pyp2 and reside in two complementation groups were isolated, sty1 and sty2. sty1- and sty2- mutant cells are substantially delayed in the timing of mitotic initiation. We have isolated the sty1 gene, which encodes a MAP kinase that is closely related to a subfamily of MAP kinases regulated by osmotic stress including Saccharomyces cervisiae HOG1 and human CSBP1. We find that sty2 is allelic to the wis1 MAP kinase kinase and that delta sty1 and delta wis1 cells are unable to grow in high osmolarity medium. Osmotic stress induces both tyrosine phosphorylation of Sty1 and a reduction in cell size at division. Pyp2 associates with and tyrosine dephosphorylates Sty1 in vitro. We find that wis1-dependent induction of pyp2 mRNA is responsible for tyrosine dephosphorylation of Sty1 in vivo on prolonged exposure to osmotic stress. We conclude that Pyp1 and Pyp2 are tyrosine-specific MAP kinase phosphatases that inactivate an osmoregulated MAP kinase, Sty1, which acts downstream of the Wis1 MAP kinase kinase to control cell size at division in fission yeast.
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PMID:Pyp1 and Pyp2 PTPases dephosphorylate an osmosensing MAP kinase controlling cell size at division in fission yeast. 765 64

Insulin stimulates the activity of mitogen-activated protein kinase (MAPK) via its upstream activator, MAPK kinase (MEK), a dual specificity kinase that phosphorylates MAPK on threonine and tyrosine. The potential role of MAPK activation in insulin action was investigated with the specific MEK inhibitor PD98059. Insulin stimulation of MAPK activity in 3T3-L1 adipocytes (2.7-fold) and L6 myotubes (1.4-fold) was completely abolished by pretreatment of cells with the MEK inhibitor, as was the phosphorylation of MAPK and pp90Rsk, and the transcriptional activation of c-fos. Insulin receptor autophosphorylation on tyrosine residues and activation of phosphatidylinositol 3'-kinase were unaffected. Pretreatment of cells with PD98059 had no effect on basal and insulin-stimulated glucose uptake, lipogenesis, and glycogen synthesis. Glycogen synthase activity in extracts from 3T3-L1 adipocytes and L6 myotubes was increased 3-fold and 1.7-fold, respectively, by insulin. Pretreatment with 10 microM PD98059 was without effect. Similarly, the 2-fold activation of protein phosphatase 1 by insulin was insensitive to PD98059. These results indicate that stimulation of the MAPK pathway by insulin is not required for many of the metabolic activities of the hormone in cultured fat and muscle cells.
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PMID:Mitogen-activated protein kinase kinase inhibition does not block the stimulation of glucose utilization by insulin. 765 64

Mitogen-activated protein kinases (MAPKs) play a pivotal role in the mitogenic signal transduction pathway and are essential components of the MAPK cascade, which includes MEK (also known as MAP kinase kinase), Raf-1, and Ras. In this study, we examined whether constitutive activation of the MAPK cascade was associated with the carcinogenesis of human renal cell carcinomas in a series of 25 tumors and in corresponding normal kidneys. Constitutive activation of MAPKs in tumor tissue, as determined by the appearance of phosphorylated forms, was found in 12 cases (48%), and this activation was confirmed by a direct in vitro kinase assay of immunoprecipitate using myelin basic protein as the substrate. The phosphorylation of MEK and of Raf-1, as monitored by a mobility shift in SDS-PAGE, which is reportedly associated with the activation of these kinases, occurred in 9 of 18 cases (50%) and in 6 of 11 cases (55%) respectively. The activation of MAPKs was correlated with MEK activation (P = 0.0045) and with Raf-1 activation (P = 0.067). Furthermore, overexpression of MEK was found in 13 of 25 cases (52%) by Western blot analysis, and this overexpression was associated significantly with MAPK activation (P = 0.034). No mutations were noted in H-,K-, or N-ras genes by PCR direct sequencing in any of the 25 tumor samples. Of the patients studied, 8 of 18 (44%) stage pT2 patients and four of six (67%) stage pT3 patients showed MAPK activation. The single stage pT1 patient did not evidence MAPK activation. Furthermore, one of seven (14%) grade 1 patients, 9 of 13 (69%) grade 2 patients, and two of five (40%) grade 3 patients showed MAPK activation (grade 1 versus grades 2 and 3, P = 0.046). Our results suggest that constitutive activation of MAPKs may be associated with the carcinogenesis of human RCCs.
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PMID:Constitutive activation of mitogen-activated protein (MAP) kinases in human renal cell carcinoma. 766 95

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