UNIPROT:P51532 - FACTA Search

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Query: UNIPROT:P51532 (transcriptional activator)
6,546 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

MEF, a recently identified member of the E74 family of ETS-related transcription factors, is a strong transcriptional activator of cytokine gene expression. Using a green fluorescent protein gene reporter plasmid regulated by an MEF-responsive promoter, we determined that the transcriptional activity of MEF is largely restricted to the G1 phase of the cell cycle. MEF-dependent transcription was suppressed by the expression of cyclin A but not by cyclin D or cyclin E. This effect was due to the kinase activity generated by cyclin A expression, as co-expression of the cyclin-dependent kinase inhibitors p21 or p27, or a dominant negative form of CDK2 (DNK2), abrogated the reduction of MEF transcriptional activity by cyclin A. Cyclin A-CDK2 phosphorylated MEF protein in vitro more efficiently than cyclin D-CDK4 or cyclin E-CDK2, and phosphorylation of MEF by cyclin A-CDK2 reduced its ability to bind DNA. We determined one site of phosphorylation by cyclin A-CDK2 at the C terminus of MEF, using mass-spectrometry; mutation of three serine or threonine residues in this region significantly reduced phosphorylation of MEF by cyclin A and reduced cyclin A-mediated suppression of its transactivating activity. These amino acid substitutions also reduced the restriction of MEF activity to G1. Phosphorylation of MEF by the cyclin A-CDK2 complex controls its transcriptional activity during the cell cycle, establishing a novel link between the ETS family of proteins and the cell cycle machinery.
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PMID:Cyclin A-dependent phosphorylation of the ETS-related protein, MEF, restricts its activity to the G1 phase of the cell cycle. 1150 16

The zinc finger protein early growth response 1 (Egr-1) is a transcriptional activator involved in the regulation of growth and differentiation. We show here that a constitutive active mutant of mitogen-activated kinase kinase-1 (MAPKK-1) strongly stimulates the activity of the Egr-1 promoter, thus explaining the effects of mitogens upon Egr-1 mRNA and protein levels. Moreover, we show that a constitutive active MAPKK-1 leads to an increase in the biological activity of Egr-1 to activate transcription. We conclude that the signaling pathway involving mitogen-activated protein kinase/extracellular signal-regulated protein kinase has a dual impact on the biology of Egr-1 by controlling the transcription of the Egr-1 gene and the transcriptional activity of the Egr-1 protein.
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PMID:The extracellular signal-regulated protein kinases Erk1/Erk2 stimulate expression and biological activity of the transcriptional regulator Egr-1. 1153 Sep 39

The nonstructural protein NS1 of the autonomous parvovirus minute virus of mice (MVMp) is cytolytic when expressed in transformed cells. Before causing extensive cell lysis, NS1 induces a multistep cell cycle arrest in G(1), S, and G(2), well reproducing the arrest in S and G(2) observed upon MVMp infection. In this work we investigated the molecular mechanisms of growth inhibition mediated by NS1 and MVMp. We show that NS1-mediated cell cycle arrest correlates with the accumulation of the cyclin-dependent kinase (Cdk) inhibitor p21(cip1) associated with both the cyclin A/Cdk and cyclin E/Cdk2 complexes but in the absence of accumulation of p53, a potent transcriptional activator of p21(cip1). By comparison, MVMp infection induced the accumulation of both p53 and p21(cip1). We demonstrate that p53 plays an essential role in the MVMp-induced cell cycle arrest in both S and G(2) by using p53 wild-type (+/+) and null (-/-) cells. Furthermore, only the G(2) arrest was abrogated in p21(cip1) null (-/-) cells. Together these results show that the MVMp-induced cell cycle arrest in S is p53 dependent but p21(cip1) independent, whereas the arrest in G(2) depends on both p53 and its downstream effector p21(cip1). They also suggest that induction of p21(cip1) by the viral protein NS1 arrests cells in G(2) through inhibition of cyclin A-dependent kinase activity.
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PMID:NS1- and minute virus of mice-induced cell cycle arrest: involvement of p53 and p21(cip1). 1160 46

We observed that the transcription of Saccharomyces cerevisiae cytoplasmic thiol peroxidase type II (cTPx II) (YDR453C) is regulated in response to various stresses (e.g. oxidative stress, carbon starvation, and heat-shock). It has been suggested that both transcription-activating proteins, Yap1p and Skn7p, regulate the transcription of cTPx II upon exposure to oxidative stress. However, a dramatic loss of transcriptional response to various stresses in yeast mutant strains lacking both Msn2p and Msn4p suggests that the transcription factors act as a principal transcriptional activator. In addition to two Yap1p response elements (YREs), TTACTAA and TTAGTAA, the presence of two stress response elements (STREs) (CCCCT) in the upstream sequence of cTPx II also suggests that Msn2p/Msn4p could control stress-induced expression of cTPx II. Analysis of the transcriptional activity of site-directed mutagenesis of the putative STREs (STRE1 and STRE2) and YREs (TRE1 and YRE2) in terms of the activity of a lacZ reporter gene under control of the cTPx II promoter indicates that STRE2 acts as a principal binding element essential for transactivation of the cTPx II promoter. The transcriptional activity of the cTPx II promoter was exponentially increased after postdiauxic growth. The transcriptional activity of the cTPx II promoter is greatly increased by rapamycin. Deletion of Tor1, Tor2, Ras1, and Ras2 resulted in a considerable induction when compared with their parent strains, suggesting that the transcription of cTPx II is under negative control of the Ras/cAMP and target of rapamycin signaling pathways. Taken together, these results suggest that cTPx II is a target of Msn2p/Msn4p transcription factors under negative control of the Ras-protein kinase A and target of rapamycin signaling pathways. Furthermore, the accumulation of cTPx II upon exposure to oxidative stress and during the postdiauxic shift suggests an important antioxidant role in stationary phase yeast cells.
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PMID:Msn2p/Msn4p act as a key transcriptional activator of yeast cytoplasmic thiol peroxidase II. 1182 10

In the budding yeast Saccharomyces cerevisiae, entry into meiosis and its successful completion depend on two positive regulators, Ime1 and Ime2. Ime1 is a transcriptional activator that is required for transcription of IME2, a serine/threonine protein kinase. We show that in vivo Ime2 associates with Ime1, that in vitro Ime2 phosphorylates Ime1, and that in living cells the stability of Ime1 depends on Ime2. Diploid cells with IME2 deleted show an increase in the level of Ime1, whereas haploid cells overexpressing IME2 show a decrease in the stability of Ime1. Furthermore, the level of Ime1 depends on the kinase activity of Ime2. Using a mutation in one of the ATPase subunits of the proteasome, RPT2, we demonstrate that Ime1, amino acids 270 to 360, is degraded by the 26S proteasome. We also show that Ime2 itself is an extremely unstable protein whose expression in vegetative cultures is toxic. We propose that a negative-feedback loop ensures that the activity of Ime1 will be restricted to a narrow window.
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PMID:Ime2, a meiosis-specific kinase in yeast, is required for destabilization of its transcriptional activator, Ime1. 1188 93

Mirk/Dyrk1B is an arginine-directed serine/threonine protein kinase that is expressed at low levels in most normal tissues but at elevated levels in many tumor cell lines and in normal skeletal muscle. Colon carcinoma cell lines stably overexpressing Mirk proliferated in serum-free medium, but the mechanism of Mirk action is unknown. DCoHm (dimerization cofactor of hepatocyte nuclear factor 1alpha ( HNF1alpha) from muscle), a novel gene of the DCoH family with 78% amino acid identity to DCoH, was identified as a Mirk-binding protein by yeast two-hybrid analysis and cloned. Mirk co-immunoprecipitated with DCoHm and bound to DCoHm in glutathione S-transferase pull-down assays. DCoH stabilizes HNF1alpha as a dimer and enhances its transcriptional activity on the beta-fibrinogen promoter reporter, and DCoHm had similar activity. Mirk enhanced HNF1alpha transcriptional activity in a dose-dependent manner, whereas two kinase-inactive Mirk mutants and a Mirk N-terminal deletion mutant did not. Mirk, DCoHm, and HNF1alpha formed a complex. Mirk bound to a specific region within the CREB-binding protein-binding region of HNF1alpha and phosphorylated HNF1alpha at a site adjacent to the Mirk-binding region. Conversely, the HNF1alpha binding domain was located within the first five conserved kinase subdomains of Mirk. Mirk co-immunoprecipitated with the MAPK kinase MKK3, an upstream activator of p38. MKK3 enhanced Mirk kinase activity and the transcriptional activation of HNF1alpha by Mirk, suggesting that Mirk, like p38, is activated by certain environmental stress agents. The Mirk-binding protein DCoH has been shown to be selectively expressed in colon carcinomas but not in normal tissue. Mirk may function as an HNF1alpha transcriptional activator in response to an MKK3-mediated stress signal, and the selective expression of DCoH could restrict the Mirk response to carcinoma cells.
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PMID:Mirk protein kinase is activated by MKK3 and functions as a transcriptional activator of HNF1alpha. 1198 Sep 10

Chicken ovalbumin upstream promoter transcription factor I (COUP-TFI) is an orphan member of the nuclear hormone receptor superfamily that comprises key regulators of many biological functions, such as embryonic development, metabolism, homeostasis, and reproduction. Although COUP-TFI can both actively silence gene transcription and antagonize the functions of various other nuclear receptors, the COUP-TFI orphan receptor also acts as a transcriptional activator in certain contexts. Moreover, COUP-TFI has recently been shown to serve as an accessory factor for some ligand-bound nuclear receptors, suggesting that it may modulate, both negatively and positively, a wide range of hormonal responses. In the absence of any identified cognate ligand, the mechanisms involved in the regulation of COUP-TFI activity remain unclear. The elucidation of several putative phosphorylation sites for MAPKs, PKC, and casein kinase II within the sequence of this orphan receptor led us to investigate phosphorylation events regulating the various COUP-TFI functions. After showing that COUP-TFI is phosphorylated in vivo, we provide evidence that in vivo inhibition of either MAPK or PKC signaling pathway leads to a specific and pronounced decrease in COUP-TFI-dependent transcriptional activation of the vitronectin gene promoter. Focusing on the molecular mechanisms underlying the MAPK- and PKC-mediated regulation of COUP-TFI activity, we show that COUP-TFI can be directly targeted by PKC and MAPK. These phosphorylation events differentially modulate COUP-TFI functions: PKC-mediated phosphorylation enhances COUP-TFI affinity for DNA and MAPK-mediated phosphorylation positively regulates the transactivation function of COUP-TFI, possibly through enhancing specific coactivator recruitment. These data provide evidence that COUP-TFI is likely to integrate distinct signaling pathways and raise the possibility that multiple extracellular signals influence biological processes controlled by COUP-TFI.
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PMID:Multiple phosphorylation events control chicken ovalbumin upstream promoter transcription factor I orphan nuclear receptor activity. 1204 19

The subcellular localization of Msn2, a transcriptional activator of STRE (stress response element)-regulated genes, is modulated by carbon source availability. In cells growing in glucose, Msn2 is located mainly in the cytosol, whereas in carbon source-starved cells, Msn2 is located largely inside the nucleus. However, in cells lacking Reg1 (the regulatory subunit of the Reg1/Glc7 protein phosphatase complex), the regulation of subcellular distribution is absent, Msn2 being constitutively present in the cytosol. The localization defect in these mutants is specific for carbon starvation stress, and it is because of the presence of an abnormally active Snf1 protein kinase that inhibits the nuclear localization of Msn2 upon carbon starvation. Active Snf1 kinase is also able to avoid the effects of rapamycin, a drug that by inhibiting the TOR kinase pathway leads to a nuclear localization of Msn2 in wild type cells. Therefore, active Snf1 and the TOR kinase pathway may affect similar cytosolic steps in the regulation of the subcellular localization of Msn2.
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PMID:Convergence of the target of rapamycin and the Snf1 protein kinase pathways in the regulation of the subcellular localization of Msn2, a transcriptional activator of STRE (Stress Response Element)-regulated genes. 1209 9

Beta-catenin is a transcriptional activator that is regulated by glycogen synthase kinase-3 (GSK-3). GSK-3 is constitutively active in unstimulated cells where it phosphorylates beta-catenin, targeting beta-catenin for rapid degradation. Receptor-induced inhibition of GSK-3 allows beta-catenin to accumulate in the cytoplasm and then translocate to the nucleus where it promotes the transcription of genes such as c-myc and cyclin D1. Wnt hormones, the best known regulators of beta-catenin, inhibit GSK-3 via the Disheveled protein. However, GSK-3 is also inhibited when it is phosphorylated by Akt, a downstream target of phosphatidylinositol 3-kinase (PI3K). We have previously shown that B cell Ag receptor (BCR) signaling leads to activation of PI3K and Akt as well as inhibition of GSK-3. Therefore, we hypothesized that BCR engagement would induce the accumulation of beta-catenin via a PI3K/Akt/GSK-3 pathway. We now show that BCR ligation causes an increase in the level of beta-catenin in the nuclear fraction of B cells as well as an increase in beta-catenin-dependent transcription. Direct inhibition of GSK-3 by LiCl also increased beta-catenin levels in B cells. This suggests that GSK-3 keeps beta-catenin levels low in unstimulated B cells and that BCR-induced inhibition of GSK-3 allows the accumulation of beta-catenin. Surprisingly, we found that the BCR-induced phosphorylation of GSK-3 on its negative regulatory sites, as well as the subsequent up-regulation of beta-catenin, was not mediated by Akt but by the phospholipase C-dependent activation of protein kinase C. Thus, the BCR regulates beta-catenin levels via a phospholipase C/protein kinase C/GSK-3 pathway.
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PMID:The B cell antigen receptor regulates the transcriptional activator beta-catenin via protein kinase C-mediated inhibition of glycogen synthase kinase-3. 1209 78

Mirk/Dyrk1B protein kinase was shown in an earlier study to function as a transcriptional activator of HNF1alpha, which Mirk phosphorylates at Ser(249) within its CREB (cAMP-response element-binding protein)-binding protein (CBP) binding domain (). The MAPK kinase MKK3 was also shown to activate Mirk as a protein kinase, implicating Mirk in the biological response to certain stress agents. Another MKK3 substrate, p38MAPK, is now shown to inhibit the function of Mirk as a transcriptional activator in a kinase-independent manner. Co-immunoprecipitation experiments demonstrated that kinase-inactive p38AF, as well as wild-type p38, sequestered Mirk and prevented its association with MKK3. Only the p38alpha and p38beta isoforms, but not the gamma or delta isoforms, complexed with Mirk. p38alphaMAPK blocked Mirk activation of HNF1alpha in a dose-dependent manner, with high levels of kinase-inactive p38alphaAF completely suppressing the activity of Mirk. Size fractionation by fast protein liquid chromatography on Superdex 200 demonstrated that Mirk is not found as a monomer in vivo, but is found within 150-700 kDa subnuclear complexes, which co-migrate with the nuclear body scaffolding protein PML. Endogenous Mirk, p38, and MKK3 co-migrate within 500-700-kDa protein complexes, which accumulate when nuclear export is blocked by leptomycin B. Stable overexpression of Mirk increases the fraction of Mirk protein and p38 protein within these 500-700 kDa complexes, suggesting that the complexes act as nuclear depots for Mirk and p38. Sequestration of Mirk by p38 may occur within these subnuclear complexes. Synchronization experiments demonstrated that Mirk levels fluctuate about 10-fold within the cell cycle, while p38 levels do not, leading to the speculation that endogenous p38 could only block Mirk function when Mirk levels were low in S phase and not when Mirk levels were elevated in G(0)/G(1). These data suggest a novel cell cycle-dependent function for p38, suppression of the function of Mirk as a transcriptional activator only when cells are proliferating, and thus limiting Mirk function to growth-arrested cells.
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PMID:The transcriptional activator Mirk/Dyrk1B is sequestered by p38alpha/beta MAP kinase. 1238 4

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