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)

The simian virus 40 (SV40) transcriptional enhancer is composed of multiple cis-acting DNA sequence motifs, each individually having a two- to fourfold effect on the efficiency of transcription. When various distinct cis-elements act in combination, however, a dramatic enhancement of transcription initiation often results. SV40-enhancer A-domain sequences were previously shown to be important for early and late transcription in vivo. Here we report the isolation of the enhancer binding factor AP-4, which recognizes a motif in this domain. Purified AP-4 activates SV40 late transcription in vitro, and this stimulation is augmented by the addition of transcription factor AP-1 which binds to adjacent sequences in the A-domain, suggesting coordinate action of the two factors for transcriptional enhancement. AP-1 also represses late transcription from a major in vitro start site which is poorly used in vivo, indicating that AP-1 can act as both a positive and negative regulator of SV40 late transcription. Thus by manipulating the levels of different trans-acting factors in vitro, we can recreate the pattern of SV40 late initiation observed during the viral lytic cycle in vivo.
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PMID:Enhancer binding factors AP-4 and AP-1 act in concert to activate SV40 late transcription in vitro. 283 4

The consensus recognition element for the mammalian transcription factor AP-1 is very similar to that of the transcriptional activator GCN4. Here, we show that the AP-1 recognition element (ARE) found in the SV40 enhancer can activate transcription from a heterologous promoter in S. cerevisiae. This activation, however, is not dependent on the presence of GCN4 as evidenced by ARE-dependent transcription in a gcn4 yeast strain. A previously unknown yeast transcription factor that is probably responsible for this activation was identified and highly purified. The yeast factor, designated yAP-1, shares remarkably similar biochemical and DNA-binding characteristics with mammalian AP-1. These data suggest that the yeast and mammalian AP-1 are evolutionarily conserved and perhaps functionally related. Also note-worthy is that GCN4 can bind to a GCN4 recognition element (GCRE) and to the ARE with approximately equal affinities; yAP-1, however, has a much lower affinity for the GCRE than the ARE, suggesting that yAP-1 can discriminate between these elements in vivo.
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PMID:Transcriptional activation by the SV40 AP-1 recognition element in yeast is mediated by a factor similar to AP-1 that is distinct from GCN4. 283 68

The human papovavirus BK has a noncoding regulatory region located between the divergently transcribed early and late coding regions. Many strains of BK virus (BKV) have direct DNA sequence repeats in the regulatory region, although the number and extent of these repeats varies widely between independent isolates. Until recently, little was known about the individual functional elements within the BKV regulatory region, and the biological significance of the variable repeat structure has been unclear. To characterize the interaction between sequences in the BKV regulatory region and host cell transcription factors, we have carried out DNase I footprinting and competitive binding experiments on three strains of BKV, including one strain that does not contain direct sequence repeats. We have used relatively crude fractions from HeLa cell nuclear extracts, as well as DNA affinity-purified preparations of proteins. Our results demonstrate that BK(Dunlop), BK(WW), and BK(MM) each contain multiple binding sites for a factor, NF-BK, that is a member of the nuclear factor 1 family of transcription factors. We predict the presence of three to eight binding sites for NF-BK in the other strains of BKV for which a DNA sequence is available. This suggests that the binding of this protein is likely to be required for biological activity of the virus. In addition to NF-BK sites, BK(WW) and BK(MM) each contain a single binding site for transcription factor Sp1, and BK(Dunlop) contains two binding sites for transcription factor AP-1. The AP-1 sites in BK(Dunlop) span the junction of adjacent direct repeats, suggesting that repeat formation may be an important mechanism for de novo formation of binding sites not present in a parental strain.
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PMID:Binding of cellular proteins to the regulatory region of BK virus DNA. 284 92

The adenovirus early region 3 (E3) promoter is an early viral promoter which is strongly induced by the adenovirus transactivator protein E1A. DNase I footprinting with HeLa cell extracts has identified four factor-binding domains which appear to be involved in basal and E1A-induced transcriptional regulation. These binding domains may bind TATA region-binding factors (site I), the CREB/ATF protein (site II), the AP-1 protein (site III), and nuclear factor I/CTF (site IV). Recently, it has been shown that the DNA-binding domain of transcription factor AP-1 has homology with the yeast transcription factor GCN4 and that the yeast transactivator protein GAL4 is able to stimulate transcription in HeLa cells from promoters containing GAL4-binding sites. These results suggest an evolutionary conservation of both transcription factors and the mechanisms responsible for transcriptional activation in Saccharomyces cerevisiae and higher eucaryotic organisms. To determine whether similar patterns of transcriptional regulation were seen with the E3 promoter in HeLa and yeast cells, the E3 promoter fused to the chloramphenicol acetyltransferase (cat) gene was cloned into a high-copy-number plasmid and stably introduced into yeast cells. S1 analysis revealed that similar E3 promoter mRNA start sites were found in yeast and HeLa cells. DNase I footprinting with partially purified yeast extracts revealed that four regions of the E3 promoter were protected. Several of these regions were similar to binding sites determined by using HeLa cell extracts. Oligonucleotide mutagenesis of these binding domains indicated their importance in the transcriptional regulation of the E3 promoter in yeast cells. These results suggest that similar cellular transcription factor-binding sites may be involved in the regulation of promoters in both yeast and mammalian cells.
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PMID:Adenovirus transcriptional regulatory regions are conserved in mammalian cells and Saccharomyces cerevisiae. 297 53

The promoter regions of several phorbol diester-(TPA-) inducible genes (collagenase, stromelysin, hMT IIA, and SV40) share a conserved 9 bp motif. Synthetic copies of these closely related sequences conferred TPA inducibility upon heterologous promoters. Footprinting analysis indicated that these TPA-responsive elements (TREs) are recognized by a common cellular protein: the previously described transcription factor AP-1. A point mutation that eliminated the basal and induced activity of the TRE also interfered with its ability to bind AP-1. Treatment of cultured cells with TPA led to a rapid 3- to 4-fold increase in TRE binding activity, by a posttranslational mechanism. These results strongly suggest that AP-1 is at the receiving end of a complex pathway responsible for transmitting the effects of phorbol ester tumor promoters from the plasma membrane to the transcriptional machinery.
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PMID:Phorbol ester-inducible genes contain a common cis element recognized by a TPA-modulated trans-acting factor. 303 32

The Fos protein complex and several Fos-related antigens (FRA) bind specifically to a sequence element referred to as the HeLa cell activator protein 1 (AP-1) binding site. A combination of structural and immunological comparisons has identified the Fos-associated protein (p39) as the protein product of the jun proto-oncogene (c-Jun). The p39/Jun protein is one of the major polypeptides identified in AP-1 oligonucleotide affinity chromatography extracts of cellular proteins. These preparations of AP-1 also contain Fos and several FRA's. Some of these proteins bind to the AP-1 site directly whereas others, like Fos, appear to bind indirectly via protein-protein interactions. Cell-surface stimulation results in an increase in c-fos and c-jun products. Thus, the products of two protooncogenes (and several related proteins), induced by extracellular stimuli, form a complex that associates with transcriptional control elements containing AP-1 sites, thereby potentially mediating the long-term responses to signals that regulate growth control and development.
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PMID:Fos-associated protein p39 is the product of the jun proto-oncogene. 313 Jun 60

Cell lines stably transfected with metal inducible, MT-fos chimeric genes were used to study the ability of the c-fos gene product, Fos, to act as a transcriptional trans-activator. In 3T3MTfos cells, induction of Fos expression led to specific trans-activation of an AP-1 responsive reporter gene. Induction of Fos expression in F9MTfos cells, however, did not lead to trans-activation. Since, unlike NIH3T3 cells, F9 cells do not contain detectable levels of AP-1, we examined whether a c-Jun/AP-1 expression vector can restore the trans-activating effect of Fos in F9MTfos cells. Transfection with a functional c-Jun/AP-1 vector restored the specific trans-activating effect of Fos on AP-1 responsive constructs. When incubated with nondenatured cell extracts, anti-cFos antisera precipitated a protein complex composed of Fos and several Fos associated proteins (FAP). One of these, FAP p39, is structurally identical to c-Jun/AP-1. These results suggest that Fos is a trans-acting factor that is capable of stimulating gene expression not by direct binding to DNA but by interaction with the sequence-specific transcription factor AP-1. Therefore recognition of specific cis-elements by AP-1 is a prerequisite for Fos-mediated stimulation of gene expression.
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PMID:The c-Fos protein interacts with c-Jun/AP-1 to stimulate transcription of AP-1 responsive genes. 313 40

Three members of the Jun/AP-1 family have been identified in mouse cDNA libraries: c-Jun, Jun-B, and Jun-D. We have compared the DNA binding properties of the Jun proteins by using in vitro translation products in gel retardation assays. Each protein was able to bind to the consensus AP-1 site (TGACTCA) and, with lower affinity, to related sequences, including the cyclic AMP response element TGACGTCA. The relative binding to the oligonucleotides tested was similar for the different proteins. The Jun proteins formed homodimers and heterodimers with other members of the family, and they were bound to the AP-1 site as dimers. When Fos translation product was present, DNA binding by Jun increased markedly, and the DNA complex contained Fos. The C-terminal homology region of Jun was sufficient for DNA binding, dimer formation, and interaction with Fos. Our general conclusion is that c-Jun, Jun-B, and Jun-D are similar in their DNA binding properties and in their interaction with Fos. If there are functional differences between them, they are likely to involve other activities of the Jun proteins.
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PMID:DNA binding activities of three murine Jun proteins: stimulation by Fos. 314 91

The c-Jun and c-fos proto-oncogenes encode proteins that form a complex which regulates transcription from promoters containing AP-1 activation elements. c-Jun has specific DNA binding activity, while c-Fos has homology to the putative DNA binding domain of c-Jun. Following in vitro translation, c-Jun binds as a homodimer to the AP-1 DNA site, while c-Fos fails to dimerize and displays no apparent affinity for the AP-1 element. Cotranslated c-Jun and c-Fos proteins bind 25 times more efficiently to the AP-1 DNA site as a heterodimer than does the c-Jun homodimer. These experiments suggest that in growth factor-stimulated cells c-Jun binds DNA as a dimer with c-Fos as its natural partner. However, overexpression of c-Jun protein in the absence of c-Fos may result in formation of aberrant homodimeric transcription complexes, which could abrogate the normal mechanisms controlling gene expression.
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PMID:c-Jun dimerizes with itself and with c-Fos, forming complexes of different DNA binding affinities. 314 92

ATF is a cellular transcription factor involved in the regulation of multiple adenovirus E1A- and cellular cAMP-inducible promoters. Using DNA affinity chromatography, we have purified ATF and found that a series of polypeptides copurify in a sequence-specific manner. We demonstrate that these polypeptides represent a family of proteins that are related by DNA-binding specificity and by immunological cross-reactivity. This family includes the transcription factor AP-1, whose recognition sequence, GTGAGTCAA, differs from the ATF consensus, GTGACGTCAA, by the absence of a cytosine residue. Our results further indicate that there are multiple forms of both ATF and AP-1. The immunological cross-reactivity and related DNA-binding specificities suggest that ATF and AP-1 contain similar amino acid sequences and may have originated from a common gene.
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PMID:A family of immunologically related transcription factors that includes multiple forms of ATF and AP-1. 314 78

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