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)

Nuclear levels of c-Jun, JunB, c-Fos, and LRF-1 (liver regeneration factor) are high for a large fraction of the G1 phase in regenerating liver and mitogen-stimulated hepatic cells. Previously, JunB was regarded as a less potent transcriptional activator than c-Jun that could also function as a repressor. However, we found that, like c-Jun, JunB alone or LRF-1/JunB strongly transactivates a cAMP-responsive promoter. Unlike c-Jun, JunB represses several AP-1 or activator of transcription factor site-containing promoters, and this inhibition is greatly enhanced in the presence of LRF-1. Here, we identify separate regions of JunB required for trans-activation and repression of these promoters. Deletion analysis shows that the region involved in trans-activation function is highly conserved among all Jun family members and corresponds to activator domain (A1) of c-Jun. In contrast, repression is maximal in the presence of both the DNA-binding domain and a region proximal to the basic region that is highly divergent among Jun proteins. Functional distinctions between Jun proteins during induction of the growth response and tumorigenesis may be accounted for by promoter-specific activation and repression mediated by regional differences in Jun family proteins.
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PMID:Promoter-specific trans-activation and inhibition mediated by JunB. 833 92

The X-ray structure of the DNA binding domain of the yeast transcriptional activator protein GCN4 bound to a DNA fragment containing the sequence of the perfectly symmetrical ATF/CREB site has been solved to 3.0 A resolution. The architecture of this specific recognition complex supports the current model for bZIP proteins: a homodimer of parallel alpha-helices form an interhelix coiled-coil region via the leucine zipper, and the two N-terminal basic regions fit into the major groove of half sites on opposite sides of the DNA double helix. The structure shows that DNA flexibility plays the predominant role in the preservation of protein contacts with the symmetric ATF/CREB site (ATGACGTCAT) as compared to the pseudo-symmetric AP-1 target site (ATGACTCAT), overcoming the positional displacement of functional groups introduced by the additional G.C base-pair at the center of the ATF/CREB sequence.
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PMID:The X-ray structure of the GCN4-bZIP bound to ATF/CREB site DNA shows the complex depends on DNA flexibility. 837 81

oriLyt, the lytic origin of DNA replication of Epstein-Barr virus (EBV), ensures viral DNA amplification during the productive or lytic phase of the virus' life cycle. To understand the contribution of cis- and transacting elements involved in DNA replication of oriLyt, a detailed mutational analysis was undertaken which defined BZLF1, a viral transcriptional activator, as an essential replication factor. The BZLF1 protein belongs to the extended fos/jun family of transcription factors and binds to specific BZLF1 binding motifs within oriLyt, as well as to consensus AP-1 sites. Recombinant, chimeric transcription factors identified the transcriptional activation domain of BZLF1 as being necessary to mediate DNA replication, a function which could not be substituted by any other transcription factor tested, including jun, E2, myc or VP16.
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PMID:A transcription factor with homology to the AP-1 family links RNA transcription and DNA replication in the lytic cycle of Epstein-Barr virus. 840 60

Nuclear factor of activated T cells (NF-AT) is a transcriptional activator involved in the induction of IL-2 gene expression. The response element for NF-AT is a sequence localized between -285/-254 in the IL-2 regulatory region. The composition of NF-AT protein is still not fully elucidated. We demonstrate that, in normal human T cells, an AP-1 protein is a component of the NF-AT protein complex. This was evidenced by the ability of the AP-1 site to compete with the NF-AT site for binding to NF-AT and by the capacity of immobilized anti-Jun and anti-Fos antibodies to deplete NF-AT-binding activity from nuclear extracts of activated T cells. There was no detectable binding of in vitro translated Jun/Fos heterodimer (AP-1) to the NF-AT sequence, and the NF-AT sequence was unable to inhibit the binding of Jun/Fos to the AP-1 sequence. The presence of an AP-1 protein in the NF-AT protein complex may regulate NF-AT-binding activity through protein-protein interaction.
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PMID:A protein of the AP-1 family is a component of nuclear factor of activated T cells. 846 70

The transcription factor c-Fos is a short-lived cellular protein. The levels of the protein fluctuate significantly and abruptly during changing pathophysiological conditions. Thus, it is clear that degradation of the protein plays an important role in its tightly regulated activity. We examined the involvement of the ubiquitin pathway in c-Fos breakdown. Using a mutant cell line, ts20, that harbors a thermolabile ubiquitin-activating enzyme, E1, we demonstrate that impaired function of the ubiquitin system stabilizes c-Fos in vivo. In vitro, we reconstituted a cell-free system and demonstrated that the protein is multiply ubiquitinated. The adducts serve as essential intermediates for degradation by the 26S proteasome. We show that both conjugation and degradation are significantly stimulated by c-Jun, with which c-Fos forms the active heterodimeric transcriptional activator AP-1. Analysis of the enzymatic cascade involved in the conjugation process reveals that the ubiquitin-carrier protein E2-F1 and its human homolog UbcH5, which target the tumor suppressor p53 for degradation, are also involved in c-Fos recognition. The E2 enzyme acts along with a novel species of ubiquitin-protein ligase, E3. This enzyme is distinct from other known E3s, including E3 alpha/UBR1, E3 beta, and E6-AP. We have purified the novel enzyme approximately 350-fold and demonstrated that it is a homodimer with an apparent molecular mass of approximately 280 kDa. It contains a sulfhydryl group that is essential for its activity, presumably for anchoring activated ubiquitin as an intermediate thioester prior to its transfer to the substrate. Taken together, our in vivo and in vitro studies strongly suggest that c-Fos is degraded in the cell by the ubiquitin-proteasome proteolytic pathway in a process that requires a novel recognition enzyme.
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PMID:Degradation of the proto-oncogene product c-Fos by the ubiquitin proteolytic system in vivo and in vitro: identification and characterization of the conjugating enzymes. 852 78

The lytic cycle of Epstein-Barr virus (EBV) can be activated by transfection of the gene for ZEBRA, a viral basic-zipper (bZip) transcriptional activator. ZEBRA and cellular AP-1 bZip activators, such as c-Fos, have homologous DNA-binding domains, and their DNA-binding specificities overlap. Moreover, EBV latency can also be disrupted by phorbol esters, which act, in part, through AP-1 activators. It is not known whether ZEBRA and AP-1 factors play equivalent roles in the initial stages of reactivation. Here the contribution of ZEBRA's basic DNA recognition domain to disruption of latency was analyzed by comparing ZEBRA with chimeric mutants in which the DNA recognition domain of ZEBRA was replaced with the analogous domain of c-Fos. Chimeric ZEBRA/c-Fos proteins overexpressed in Escherichia coli bound DNA with the specificity of c-Fos; they bound a heptamer AP-1 site and an octamer TPA response element (TRE). ZEBRA bound the AP-1 site and an array of ZEBRA response elements (ZREs). In assays with reporter genes, both ZEBRA and ZEBRA/c-Fos chimeric mutants activated transcription from Zp, a promoter of the ZEBRA gene (BZLF1) that contains the TRE and multiple ZREs. However, despite their capacity to activate reporters bearing Zp, neither ZEBRA nor the c-Fos chimeras activated transcription from Zp in the context of the intact latent viral genome. In contrast, ZEBRA but not ZEBRA/c-Fos chimeras activated Rp, a second viral promoter that controls ZEBRA expression. Hence, transcriptional autostimulation by transfected ZEBRA occurred preferentially at Rp. Both ZEBRA and the ZEBRA/c-Fos chimeras activated transcription from reporters with multimerized AP-1 sites. However, in the context of the virus, only ZEBRA activated the promoters of two early lytic cycle genes, BMRF1 and BMLF1, that contain an AP-1 site. Thus, overexpression of an activator that recognized AP-1 and TRE sites was not sufficient to activate EBV early lytic cycle genes.
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PMID:Comparing transcriptional activation and autostimulation by ZEBRA and ZEBRA/c-Fos chimeras. 862 67

The visna virus Tat protein is a strong transcriptional activator and is necessary for efficient viral replication. The Tat protein regulates transcription through an AP-1 site proximal to the TATA box within the viral long terminal repeat (LTR). Previous studies from our laboratory using Tat-Gal4 chimeric proteins showed that Tat has a potent acidic activation domain. Furthermore, a region adjacent to the Tat activation domain contains a highly conserved leucine-rich domain which, in the context of the full-length protein, suppressed the activity of the activation domain. To further elucidate the role of this region, four leucine residues within this region of Tat were mutated. In transient-transfection assays using visna virus LTR-CAT as a reporter construct, the activity of this leucine mutant was dramatically reduced. Additionally, domain-swapping experiments using the N-terminal activation domain of VP16 showed that the leucine-rich domain of Tat confers AP-1 responsiveness to the chimeric VP16-Tat protein. A chimeric VP16-Tat construct containing the leucine mutations showed no increased AP-1 responsiveness in comparison with that of the VP16 activation domain alone. Furthermore, in competition experiments, a Gal4-Tat protein containing only the leucine region of Tat (amino acids 34 to 62) was able to inhibit by competition the activity of full-length Tat. These studies strongly suggest that this leucine-rich domain is responsible for targeting the Tat protein to AP-1 sites in the viral LTR. In addition, examination of the amino acid sequence of this region of Tat revealed a highly helical secondary structure and a pattern of residues similar to that in the leucine zippers in the bZIP family of DNA-binding proteins. This has important implications for the interaction of Tat with cellular proteins, specifically Fos and Jun, that contain bZIP domains.
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PMID:The leucine domain of the visna virus Tat protein mediates targeting to an AP-1 site in the viral long terminal repeat. 867 56

Transcription factors/activators are a group of proteins that bind to specific consensus sequences (cis elements) in the promoter regions of downstream target/effector genes and transactivate or repress effector gene expression. The up- or downregulation of effector genes will ultimately lead to many biological changes such as proliferation, growth suppression, differentiation, or senescence. Transcription factors are subject to transcriptional and posttranslational regulation. This review will focus on the redox (reduction/oxidation) regulation of transcription factors/activators with emphasis on p53, AP-1, and NF-kappa B. The redox regulation of transcriptional activators occurs through highly conserved cysteine residues in the DNA binding domains of these proteins. In vitro studies have shown that reducing environments increase, while oxidizing conditions inhibit sequence-specific DNA binding of these transcriptional activators. When intact cells have been used for study, a more complex regulation has been observed. Reduction/oxidation can either up- or downregulate DNA binding and/or transactivation activities in transcriptional activator-dependent as well as cell type-dependent manners. In general, reductants decrease p53 and NF-kappa B activities but dramatically activate AP-1 activity. Oxidants, on the other hand, greatly activate NF-kappa B activity. Furthermore, redox-induced biochemical alterations sometimes lead to change in the biological functions of these proteins. Therefore, differential regulation of these transcriptional activators, which in turn, regulate many target/effector genes, may provide an additional mechanism by which small antioxidant molecules play protective roles in anticancer and antiaging processes. Better understanding of the mechanism of redox regulation, particularly in vivo, will have an important impact on drug discovery for chemoprevention and therapy of human disease such as cancer.
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PMID:Redox regulation of transcriptional activators. 885 44

The hepatitis B virus (HBV) genome encodes a 154 amino acid protein termed X (HBx, hepatitis B x protein), which is a promiscuous transcriptional activator of polymerase II and III promoters. HBx upregulates a wide range of cellular and viral genes and is thought to facilitate viral pregenome and mRNA transcription; however, its precise role in the viral replication cycle remains to be elucidated. The functional mechanisms of HBx appear very complex. It was shown to activate transcription factors AP-1 and NF-kappa B vis cytoplasmic pathways including ras-MAP kinase. In contrast, nuclear HBx is thought to activate the transcriptional machinery directly. A second transcriptional activator protein (Mst, middle s transactivator) is encoded by 3'-truncated preS2/S sequences of integrated HBV DNA, but not by the intact viral gene. HBx and Mst may contribute to the pathogenicity of chronic hepatitis B and are suggested to promote hepatocyte transformation via upregulation of cellular proto-oncogenes. Further, HBx may enhance HBV related carcinogenesis by inactivation of the tumour suppressor gene product p53.
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PMID:Hepatitis B virus transcriptional activators: mechanisms and possible role in oncogenesis. 887 69

It has been shown that a C-terminally truncated form of the middle-sized hepatitis B virus (HBV) surface protein (MHBst) functions as a transcriptional activator. This function is dependent on the cytosolic orientation of the N-terminal PreS2 domain of MHBst, but in the case of wild-type MHBs, the PreS2 domain is contranslationally translocated into the ER lumen. Recent reports demonstrated that the PreS2 domain of the large HBV surface protein (LHBs) initially remains on the cytosolic side of the ER membrane after translation. Therefore, the question arose as to whether the LHBs protein exhibits the same transcriptional activator function as MHBst. We show that LHBs, like MHBst, is indeed able to activate a variety of promoter elements. There is evidence for a PKC-dependent activation of AP-1 and NF-kappa B by LHBs. Downstream of the PKC the functionality of c-Raf-1 kinase is a prerequisite for LHBs-dependent activation of AP-1 and NF-kappa B since inhibition of c-Raf-1 kinase abolishes LHBs-dependent transcriptional activation of AP-1 and NF-kappa B.
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PMID:The hepatitis B virus large surface protein (LHBs) is a transcriptional activator. 891 53

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