UNIPROT:P05412 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Target Concepts:

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

The product of the jun proto-oncogene has been identified as one form of the transcription factor AP-1. The p55fos protein associates with jun/AP-1 by means of a heterodimer which requires intact 'leucine zipper' domains of both proteins. The fos/jun heterodimer binds to and activates transcription from TPA-responsive promoter elements (TGACTCA), which represent one final target of the protein kinase C pathway. The other main signal transduction pathway, initiated by the activation of the adenylate cyclase, involves the transcription factor CREB. The promoter element recognized by CREB, a cyclic AMP responsive element (CRE), consist of a palyndromic sequence similar to a TRE (TGACGTCA). We show that jun efficiently trans-activates CRE sequences and that fos and jun efficiently bind and cooperate in activating CRE promoter elements. The similarity between TRE and CRE sequences may involve an interplay in transcriptional regulation and 'cross-talk' between components of the two major signal transduction pathways.
...
PMID:Cross-talk in signal transduction: TPA-inducible factor jun/AP-1 activates cAMP-responsive enhancer elements. 210 94

Mutational analyses of Jun show that the leucine zipper mediates dimerization with other Jun molecules or with the Fos protein and determines the three-dimensional orientation of the adjacent basic region, facilitating interaction with DNA. The basic region of Jun is the DNA contact surface. Substitution of certain basic residues in this region leads to loss of DNA binding. Some basic region mutants also act as transdominant lethals: they are able to tie up wild type protein in inactive complexes. The definition of transactivator domains with deletion mutants of Jun appears to depend on the assay for transcriptional activation. CAT assays suggest multiple transactivator regions in the N-terminal third of Jun, while in vitro transcription assays detect a negative regulator of transcription in this region. Another transactivator domain appears to be located close to the basic region in both c-Jun and JunD. The genetics of Jun supports a hierarchical order of Jun functions in which dimerization is a prerequisite for both DNA binding and transcriptional activation, and DNA binding is needed for transcriptional activation.
...
PMID:The genetics of jun. 213 8

Proto-oncogene products c-Fos and c-Jun form a complex which binds with high affinity to the 12-O-tetradecanoylphorbol-13-acetate (TPA) response DNA element and which stimulates transcription of phorbol ester- inducible genes. We have previously identified, by screening a lambda gt11 expression library, murine protein mXBP, which binds to a sequence which overlaps the 3' end of the murine class II major histocompatibility complex A alpha gene X box, a conserved transcription element found upstream of all class II genes. Here, we demonstrate that the target sequence for mXBP is a consensus cyclic AMP response element (CRE). mXBP is a member of the leucine zipper family of DNA-binding proteins and has significant homology to oncoproteins c-Fos and c-Jun. The inferred amino acid sequence of mXBP shows near identity to human CRE-BP1, except it does not contain an internal proline-rich domain. Immunoprecipitation and glutaraldehyde cross-linking studies show that mXBP/CRE-BP2 can form a complex with c-Jun. Complex formation is dependent on intact leucine zipper domains in both proteins. mXBP-c-Jun complexes can coexist with c-Fos-c-Jun complexes and can bind with high affinity to CRE, but not to TPA response DNA element, sequences. These results suggest that changes in the expression of mXBP/CRE-BP2, c-Fos, and c-Jun, which alter the ratio of mXBP-c-Jun to c-Fos-c-Jun complexes, would affect the relative expression of cyclic AMP and phorbol ester-responsive genes. This provides support for a combinatorial model of gene regulation, whereby protein-protein interactions which alter the DNA binding specificity of protein complexes can expand the flexibility of cellular transcriptional responses.
...
PMID:mXBP/CRE-BP2 and c-Jun form a complex which binds to the cyclic AMP, but not to the 12-O-tetradecanoylphorbol-13-acetate, response element. 213 7

Introduction of the zta gene of Epstein-Barr virus into latently infected B cells leads to induction of the entire lytic cycle program of the virus. The Zta gene product is a sequence-specific DNA-binding protein of 35 kilodaltons that behaves as a specific transcriptional transactivator in transient cotransfection assays. All known Zta-responsive target promoters contain one or more members of a family of consensus-binding sites known as ZREs. On the basis of the presence of limited amino acid similarity within a basic carboxy-terminal domain, Zta has been proposed to be a highly divergent member of the c-Jun/c-Fos/GCN4 family of AP-1-binding proteins. We show here that in vitro-translated Zta and the Jun:Fos proteins have overlapping but distinct target DNA-binding specificies; both recognize canonical AP-1 sites, but only Zta recognizes ZRE sites and only Jun:Fos recognizes CRE sites. The relative binding affinity of Zta for oligonucleotides containing the 7-base-pair c-Fos AP-1 site TGAGTCA was twofold greater than that for the ZRE core motifs TGAGCAA, TG TGCAA, and TGAGTAA, but 10-fold greater than that for TGTGTCA, as measured by gel mobility retardation and competition DNA-binding assays. Cross-linking and cotranslational heterodimerization assays showed that like GCN4, Zta forms a stable homodimer in both its DNA-bound and unbound forms. Furthermore, we show that a potential coiled-coil helical domain adjacent to the basic domain of Zta can substitute for the leucine zipper of c-Fos to produce a DNA-binding protein that has a very stringent target DNA specificity and can only recognize symmetric 9-base-pair AP-1 sites (ATGAGTCAT). Therefore, despite the absence of the repeated heptad leucine zipper motifs, the Zta protein retains the characteristic features of a juxtaposed basic region and an exactly aligned coiled-coil alpha-helical dimerization domain of the bZIP class of transcriptional regulatory factors.
...
PMID:The Epstein-Barr virus Zta transactivator: a member of the bZIP family with unique DNA-binding specificity and a dimerization domain that lacks the characteristic heptad leucine zipper motif. 216 45

We present evidence that the glucocorticoid receptor (GR) and transcription factor Jun/AP-1 can reciprocally repress one another's transcriptional activation by a novel mechanism that is independent of DNA binding. Overexpression of c-Jun prevents the glucocorticoid-induced activation of genes carrying a functional glucocorticoid response element (GRE). Conversely, GR is able to repress AP-1-mediated transcriptional activation. Mutant analysis reveals that the ligand binding and DNA binding domains of GR and the region including the leucine zipper of c-Jun are required for repression. Gel retardation analysis demonstrates that bacterially expressed c-Jun disrupts GR-GRE complexes. These data indicate that members of two distinct classes of transcription factors can oppose one another's activity through a mechanism likely involving protein-protein interactions.
...
PMID:Functional antagonism between oncoprotein c-Jun and the glucocorticoid receptor. 216 53

The leucine zipper motif has been observed in a number of proteins thought to function as eucaryotic transcription factors. Mutation of the leucine zipper interferes with protein dimerization and DNA binding. We examined the effect of point mutations in the leucine zipper of c-Myc on its ability to dimerize in vitro and to inhibit Friend murine erythroleukemia (F-MEL) differentiation. Glutaraldehyde cross-linking studies failed to provide evidence for homodimerization of in vitro-synthesized c-Myc protein, although it was readily demonstrated for c-Jun. Nevertheless, whereas transfected wild-type c-myc sequences strongly inhibited F-MEL differentiation, those with single or multiple mutations in the leucine zipper were only partially effective in this regard. Since the leucine zipper domain of c-Myc is essential for its cooperative effect in ras oncogene-mediated transformation, this study emphasizes the close relationship that exists between transformation and hematopoietic commitment and differentiation. c-Myc may produce its effects on F-MEL differentiation through leucine zipper-mediated heterodimeric associations rather than homodimeric ones.
...
PMID:The leucine zipper of c-Myc is required for full inhibition of erythroleukemia differentiation. 220 13

A newly recognized class of eukaryotic transcription factors is characterized by a bipartite sequence motif, consisting of a C-terminal dimerization region (the leucine zipper) and an N-terminal basic region (which mediates DNA binding). In studies of isolated leucine zipper peptides, the dimerization region has been characterized as a coiled coil of parallel alpha-helices. To extend these studies to a functional DNA-binding domain, we describe CD studies of the thermal unfolding and refolding of a 58-residue fragment of GCN4, the yeast homologue of the c-Jun protooncoprotein. This fragment, which contains the complete leucine zipper and basic region, retains the DNA-binding properties of the intact protein. The GCN4 DNA-binding domain exhibits two independent helix-coil unfolding transitions. The major transition (midpoint 65 degrees C) is due to dissociation of the dimer in accord with previous studies of an isolated leucine zipper. A novel pretransition in the temperature range 0-40 degrees C is also observed, which reflects partial stabilization of the nascent helix in the basic region. Remarkably, complete folding of the basic region as an alpha-helix requires specific DNA binding, and the protein-DNA complex exhibits a single cooperative unfolding transition. These results support a major feature of the recently proposed "scissor's grip" model of DNA recognition, in which the basic regions extend from the leucine zipper as bifurcating alpha-helical arms.
...
PMID:Thermal unfolding studies of a leucine zipper domain and its specific DNA complex: implications for scissor's grip recognition. 226 59

The cyclic AMP response element (CRE) is found in many cellular genes regulated by cyclic AMP, and similar elements are present in the early genes of adenovirus that are activated by E1A. The transcription factor CREB has previously been shown to bind this site, and cDNAs for CREB have recently been characterized. We report here the isolation of a cDNA encoding a human DNA-binding protein that also recognizes this motif in cellular and viral promoters. This protein, HB16, displays structural similarity to CREB and to c-Jun and c-Fos, which bind the related 12-O-tetradecanoylphorbol-13-acetate response element (TRE). HB16 contains a highly basic, putative DNA-binding domain and a leucine zipper structure thought to be involved in dimerization. Deletional analysis of HB16 demonstrated that the leucine zipper is required for its interaction with DNA. In addition, HB16 could form a complex with c-Jun but not with c-Fos. Despite its structural similarity to c-Jun and c-Fos and its interaction with c-Jun, HB16 had approximately a 10-fold-lower affinity for the TRE sequence than for the CRE sequence. Although HB16 and CREB both recognized the CRE motif, an extensive binding analysis of HB16 revealed differences in the fine specificity of binding of the two proteins. HB16 mRNA was found at various levels in many human tissues but was most abundant in brain, where its expression was widespread. The existence of more than one CRE-binding protein suggests that the CRE motif could serve multiple regulatory functions.
...
PMID:A cDNA for a human cyclic AMP response element-binding protein which is distinct from CREB and expressed preferentially in brain. 232 2

fra-1 encodes a serum-inducible protein (Fra-1) that is antigenically related to Fos. We have characterized Fra-1 expression in serum-stimulated cells using antibodies raised against several regions of this protein. Fra-1, expressed transiently in COS cells or in serum-stimulated rat fibroblasts, undergoes extensive post-translational modification, primarily by phosphorylation of serine residues. It is present in both the nucleus and the cytoplasm and participates in a protein complex with Jun. Using proteins synthesized in reticulocyte lysates, we have shown that Fra-1, like Fos, binds to the AP-1 recognition element cooperatively with Jun. A truncated Fra-1 protein that contains the leucine zipper region but not an adjacent basic amino acid domain, complexes with Jun in vitro but fails to bind AP-1 oligonucleotides. These results demonstrate that Fra-1 contributes to the DNA-binding activity ascribed to transcription factor AP-1.
...
PMID:The product of a fos-related gene, fra-1, binds cooperatively to the AP-1 site with Jun: transcription factor AP-1 is comprised of multiple protein complexes. 249 53

Fos protein can trans-activate AP-1-dependent gene expression and trans-repress the c-fos promoter. Although we find that trans-repression is enhanced by coexpression of c-Jun, it does not require any of the AP-1 or ATF sites in the mouse c-fos promoter. A major target for repression is the serum response element (SRE). Fos mutants with an impaired leucine zipper are defective in trans-repression and transformation, suggesting that these functions involve the formation of Fos protein complexes. In contrast, mutations that abolish DNA binding of Fos enhance trans-repression but destroy the transforming potential of Fos. In addition, v-Fos protein efficiently transforms but is unable to trans-repress. These findings point to different mechanisms involved in trans-activation and trans-repression and suggest that trans-repression of the type described here is neither sufficient nor required for Fos-induced transformation.
...
PMID:trans-repression of the mouse c-fos promoter: a novel mechanism of Fos-mediated trans-regulation. 251 30

<< Previous 1 2 3 4 5 6 7 8 9 10 Next >>