UNIPROT:P05412 - FACTA Search

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Query: UNIPROT:P05412 (c-Jun)
11,453 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A direct comparison of the relative DNA-binding capabilities of in vivo Jun-containing complexes derived from overexpression of the highly transforming viral Jun (VJ-1 CEF), the weakly transforming chicken cellular Jun (CJ-3 CEF) or background endogenous Jun (RCAS CEF) was assessed by gel mobility-shift assays using a synthetic oligonucleotide containing the consensus sequence TGACTCA (consensus AP-1). Chicken embryo fibroblasts (CEFs) expressing background c-Jun levels (RCAS CEF) contain almost undetectable levels of c-Jun but retain significant DNA-binding activity with two distinct complexes capable of binding specifically to the consensus AP-1 site. CEFs overexpressing either v-Jun or c-Jun contain these same two complexes and, while showing marked increases in Jun protein levels, do not exhibit any increase in DNA binding or transcriptional activation activity, suggesting that much of the overexpressed protein is inactive. Gel-shift assays performed in the presence of a Jun-specific antibody revealed a reduction in binding by both complexes, suggesting that each contains Jun or a Jun cross-reactive protein. Antibodies specific for Jun B, c-Fos, Fos B and CREB failed to interact with either complex. However, antibody specific for Fra-2 caused a slight supershift, suggesting that one or both complexes may contain Fra-2. Gel-shift competition assays with 16 'AP-1- and CREB-like' target sequences revealed that, within each cell type, the two protein complexes varied in their ability to recognize the mutant target sequences. These results clearly indicate differences in potential target recognition by each specific in vivo complex, and suggest that each may preferentially bind its own subset of target DNAs. In addition, a comparison of binding by individual complexes derived from CEFs overexpressing v-Jun and c-Jun also revealed differences in target recognition. Thus, in vivo complexes formed by overexpression of v-Jun and c-Jun vary in their ability to recognize and bind to a number of 'AP-1- and CREB-like' target sequences. This has important implications with regard to the mechanisms involved in cell transformation by v-Jun.
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PMID:In vivo viral and cellular Jun complexes exhibit differential interaction with a number of in vitro generated 'AP-1- and CREB-like' target sequences. 851 Sep 33

The transcription factors controlling the complex genetic response to ischemia and their modes of regulation are poorly understood. We found that ATF-2 and c-Jun DNA binding activity is markedly enhanced in post-ischemic kidney or in LLC-PK1 renal tubular epithelial cells exposed to reversible ATP depletion. After 40 min of renal ischemia followed by reperfusion for as little as 5 min, binding of ATF-2 and c-Jun, but not ATF-3 or CREB (cAMP response element binding protein), to oligonucleotides containing either an ATF/cAMP response element (ATF/CRE) or the jun2TRE from the c-jun promoter, was significantly increased. Binding to jun2TRE and ATF/CRE oligonucleotides occurred with an identical time course. In contrast, nuclear protein binding to an oligonucleotide containing a canonical AP-1 element was not detected until 40 min of reperfusion, and although c-Jun was present in the complex, ATF-2 was not. Incubating nuclear extracts from reperfused kidney with protein phosphatase 2A markedly reduced binding to both the ATF/CRE and jun2TRE oligonucleotides, compatible with regulation by an ATF-2 kinase. An ATF-2 kinase, which phosphorylated both the transactivation and DNA binding domains of ATF-2, was activated by reversible ATP depletion. This kinase coeluted on Mono Q column chromatography with a c-Jun amino-terminal kinase and with the peak of stress-activated protein kinase, but not p38, immunoreactivity. In conclusion, DNA binding activity of ATF-2 directed at both ATF/CRE and jun2TRE motifs is modulated in response to the extreme cellular stress of ischemia and reperfusion or reversible ATP depletion. Phosphorylation-dependent activation of the DNA binding activity of ATF-2, which appears to be regulated by the stress-activated protein kinases, may play an important role in the earliest stages of the genetic response to ischemia/reperfusion by targeting ATF-2 and c-Jun to specific promoters, including the c-jun promoter and those containing ATF/CREs.
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PMID:Ischemia and reperfusion enhance ATF-2 and c-Jun binding to cAMP response elements and to an AP-1 binding site from the c-jun promoter. 853 Apr 13

The CBP protein mediates PKA induced transcription by binding to the PKA phosphorylated activation domain of CREB. Here we show that CBP also stimulates the activity of both c-Jun and v-Jun in vivo. The CREB binding domain of CBP is sufficient to contact to c-Jun in vitro. When this domain of CBP is linked to the activation domain of VP16 and expressed in vivo it stimulates c-Jun dependent transcription. Deletion analysis of c-Jun indicate that the CBP binding site is within the N-terminal activation domain. Loss of binding to CBP in vitro correlates with severely reduced transactivation capacity in vivo. Mutation of Ser63/73 in c-Jun, or the corresponding position in v-Jun (Ser36/46) leads to reduced binding to CBP in vitro and abolishes augmentation of transcription in vivo. These data are consistent with a mechanism by which CBP acts as a co-activator protein for Jun dependent transcription by interacting with the Jun N-terminal activation domain.
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PMID:Stimulation of c-Jun activity by CBP: c-Jun residues Ser63/73 are required for CBP induced stimulation in vivo and CBP binding in vitro. 854 7

A new member of the ATF/CREB family of transcription factors, called B-ATF, has been isolated from a cDNA library prepared from Epstein-Barr virus stimulated human B cells. B-ATF is a 125 amino acid nuclear protein possessing a basic leucine zipper domain that is most similar to the basic leucine zipper of ATF-3. Northern blot analysis of polyadenylated mRNA isolated from a variety of human tissues and established cell lines indicates that the 1.0 kilobase B-ATF mRNA is expressed differentially, with the strongest hybridization detected in lung and in Raji Burkitt's lymphoma. Efficient homodimerization of the B-ATF protein cannot be detected using the yeast two hybrid system or using in vitro binding assays with glutathione-s-transferase-B-ATF and maltose binding protein-B-ATF fusion proteins produced in E. coli. However, a yeast two hybrid library screen has identified the human oncoprotein JunB as a specific binding partner for B-ATF. Glutathione-s-transferase-B-ATF heterodimerizes efficiently with in vitro translated JunB, c-Jun, and JunD, but only weakly associates with c-Fos. In addition, electrophoretic mobility shift assays demonstrate that a B-ATF/c-Jun protein complex can interact with DNA containing a consensus binding site for AP-1, suggesting that B-ATF functions as a tissue-specific modulator of the AP-1 transcription complex in human cells.
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PMID:B-ATF: a novel human bZIP protein that associates with members of the AP-1 transcription factor family. 857 Jan 75

ATF3 gene, which encodes a member of the activating transcription factor/cAMP responsive element binding protein (ATF/CREB) family of transcription factors, is induced by many physiological stresses. As a step toward understanding the induction mechanisms, we isolated the human ATF3 gene and analyzed its genome organization and 5'-flanking region. We found that the human ATF3 mRNA is derived from four exons distributed over 15 kilobases. Sequence analysis of the 5'-flanking region revealed a consensus TATA box and a number of transcription factor binding sites including the AP-1, ATF/CRE, NF-kappa B, E2F, and Myc/Max binding sites. As another approach to understanding the mechanisms by which the ATF3 gene is induced by stress signals, we studied the regulation of the ATF3 gene in tissue culture cells by anisomycin, an approach that has been used to study the stress responses in tissue culture cells. We showed that anisomycin at a low concentration activates the ATF3 promoter and stabilizes the ATF3 mRNA. Significantly, co-transfection of DNAs expressing ATF2 and c-Jun activates the ATF3 promoter. A possible mechanism implicating the C-Jun NH2-terminal kinase/stress-activated protein kinase (JNK/SAPK) stress-inducible signaling pathway in the induction of the ATF3 gene is discussed.
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PMID:ATF3 gene. Genomic organization, promoter, and regulation. 857 71

We studied the effects of bile acids on inducibility of the transcription factor AP-1 in human colon carcinoma LoVo cells. Firstly, cells were treated with chenodeoxycholic acid and the nuclear extracts from those cells were processed by electrophoretic mobility shift assays to analyze nuclear AP-1 DNA-binding activity. We demonstrated that chenodeoxycholic acid induced AP-1 DNA-binding activity in a dose- and time-dependent fashion. Antibody supershift experiments clearly revealed that the majority of protein components in induced AP-1 DNA-binding activity were the products of oncogenes c-fos and c-jun. On the other hand, DNA-binding activity in the nuclear extracts for either NF kappa B, Sp1, or ATF/CREB was not affected by bile acids, suggesting that the effect of bile acids was rather specific for AP-1. Transient transfection experiments supported this notion: expression of the AP-1-luciferase reporter construct was induced by bile acids in a dose-dependent manner, and expression of either reporter construct for NF kappa B, Sp1, or ATF/CREB was not influenced by treatment of the cells with bile acids. We also demonstrated that those bile acids efficiently activated AP-1-dependent promoter in DLD-1 cells, which (as well as LoVo cells), are derived from colon adenocarcinoma, but not in COLO320DM cells which are from colon carcinoid tumor. Thus, we may indicate that bile acids exclusively induce nuclear AP-1 activity in colon adenocarcinoma cells.
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PMID:Induction of the transcription factor AP-1 in cultured human colon adenocarcinoma cells following exposure to bile acids. 863 Nov 27

The CREB-binding protein (CBP) plays a central role in the regulation of gene expression by several different second messenger pathways including serum growth factors, cAMP and phorbol esters. CBP specifically binds to the phosphorylated forms of CREB and c-Jun and is thought to activate transcription through a C-terminal activation domain. In this report, we demonstrate that the C terminus of CBP is dispensable for its ability to stimulate phospho-CREB activity, and, further, that the deletion of this domain produces highly active, mutant forms of CBP. The novel N-terminal activation identified by this deletional analysis consists of the first 714 amino acids of CBP and is sufficient for high levels of transcriptional activity. This domain is also capable of stimulating the activity of a second cAMP-regulated factor, ATF-1. Surprisingly, ATF-1 activity is not significantly stimulated by full-length CBP suggesting that the C-terminal domain of CBP may also serve to regulate ATF-1/CBP activity. Additionally, the demonstration that one of our hyperactive CBP mutants is able to activate a nonphosphorylatable mutant of CREB (M1 CREB) provides the first evidence that CBP may play a role in regulating the basal transcriptional activity of CREB.
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PMID:Identification and characterization of a novel transcriptional activation domain in the CREB-binding protein. 866 3

Glucocorticoid hormones convert the glucocorticoid receptor (GR) from an inactive cytosolic complex to a nuclear form that regulates transcription. Binding of GR to palindromic DNA-recognition sites (hormone response elements) leads to activated target gene transcription. GR also exerts negative actions on transcription, e.g., by interfering with the function of several other transcription factors such as AP-1, NK-kappa B, CREB, and Oct-1. Physical interactions of GR with AP-1 subunits are readily detectable but do not seem sufficient since nonrepressing GR mutants still interact in vitro, so that specific conformational changes and/or interactions with additional partner proteins may be required for negative action. In an attempt to find such partner proteins, we defined regions of c-Jun and GR essential for mutual interference and used in those a yeast two-hybrid screen for interacting proteins. Repeatedly we isolated overlapping cDNA sequences of one protein interaction with both c-Jun and GR. This protein does not interact with c-Fos or a non-repressing GR mutant and expressed in mammalian cells does not substantially affect AP-1 or GR activity. Interestingly, however, the protein rescues yeast cells from the toxic effects of the GR fragment used for screening. The protein represents the human homologue of the yeast E2 ubiquitin-conjugating enzyme, Ubc9; its specific interactions with both GR and c-Jun, but not mutant GR, suggest that it may exert physiologic regulatory functions.
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PMID:Interaction of the Ubc9 human homologue with c-Jun and with the glucocorticoid receptor. 873 11

CREB-binding protein (CBP) functions as a coactivator molecule for a number of transcription factors including CREB, c-Fos, c-Jun, c-Myb, and several nuclear receptors. Although binding sites for these factors within CBP have been identified, the regions of CBP responsible for transcriptional activation are unknown. In this report, we show that the N-terminal half of CBP is sufficient for activation of CREB-mediated transcription and that this region contains a strong transcriptional activation domain (TAD). Both deletion of this TAD or sequestering of factors that the TAD binds using a squelching assay were found to greatly decrease the ability of CBP to activate CREB-mediated transcription. In vivo studies by others have shown that p300/CBP associates with TBP; using an in vitro approach, we show the N-terminal TAD binds TBP. We also examined the ability of the C terminus of CBP to activate transcription using GAL-CBP chimeras. With this approach, we identified two C-terminal TADs located adjacent to the c-Fos binding site. In previous studies, cAMP-dependent protein kinase A (PKA) increased the transcriptional activity of a GAL full-length CBP chimera in F9 cells, and of the C terminus in PC-12 cells. Here, we demonstrate that PKA also increased the ability of the N-terminal TADs of CBP to activate transcription in PC-12 but not F9 or COS-7 cells, suggesting that this PKA-responsiveness is cell type-specific.
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PMID:CREB-binding protein activates transcription through multiple domains. 891 Apr 28

Chromaffin cells of the adrenal medulla are neural crest-derived neuroendocrine cells that express neuropeptide genes in vivo and in vitro. As such these cells are useful for examining tissue- and cell-specific regulation of the enkephalin gene. We previously demonstrated that the chromatin configuration of the enkephalin gene correlated with its tissue-specific expression in the adrenal medulla and primary chromaffin cell cultures. In this study we examine and characterize binding of transcription factors to the enkephalin promoter/enhancer region. Gel shift analyses of this region with extracts from chromaffin cells and PC12 cells (a pheochromocytoma cell line that does not express the enkephalin gene) demonstrate that all detectable binding is to ENKCRE-2, a cyclic AMP response-like element, and that the binding is cell specific. Gel shift and supershift analyses show that, unlike reports demonstrating that binding activity in the CNS is composed of the cyclic AMP response element binding protein, CREB, the majority of protein binding in chromaffin cells is from the AP-1 family of transcription factors. This binding is composed of c-Jun, JunD, and possibly a novel Fos-related protein(s). These data suggest enkephalin gene expression in the adrenal gland is controlled by cell-specific binding of transcription factors from the Fos/Jun families to the enkephalin CRE-2 element. Furthermore, these data suggest at least two different modes of enkephalin gene regulation exist between endocrine and neuronal tissues.
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PMID:AP-1-related proteins bind to the enkephalin CRE-2 element in adrenal chromaffin cells. 893 56

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