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

---

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

In regenerating liver, a physiologically normal model of cell growth, LRF-1, JunB, c-Jun, and c-Fos among Jun/Fos/LRF-1 family members are induced posthepatectomy. In liver cells, high levels of c-Fos/c-Jun, c-Fos/JunB, LRF-1/c-Jun, and LRF-1/JunB complexes are present for several hours after the G0/G1 transition, and the relative level of LRF-1/JunB complexes increases during G1. We provide evidence for dramatic differences in promoter-specific activation by LRF-1- and c-Fos-containing complexes. LRF-1 in combination with either Jun protein strongly activates a cyclic AMP response element-containing promoter which c-Fos/Jun does not activate. LRF-1/c-Jun, c-Fos/c-Jun, and c-Fos/JunB activate specific AP-1 and ATF site-containing promoters, and in contrast, LRF-1/JunB potently represses c-Fos- and c-Jun-mediated activation of these promoters. Repression is dependent on a region in LRF-1 that includes amino acids 40 to 84 (domain R) and the basic/leucine zipper domain. As the relative level of LRF-1/JunB complexes increases posthepatectomy, c-Fos/Jun-mediated ATF and AP-1 site activation is likely to decrease with simultaneous transcriptional activation of the many liver-specific genes whose promoters contain cyclic AMP response element sites. Thus, through complex interactions among LRF-1, JunB, c-Jun, and c-Fos, control of delayed gene expression may be established for extended times during the G1 phase of hepatic growth.
...
PMID:Interactions among LRF-1, JunB, c-Jun, and c-Fos define a regulatory program in the G1 phase of liver regeneration. 140 55

c-Jun belongs to a family of proteins that require dimerization for activity. Dimerization occurs through a leucine-rich region near the carboxy terminus called the leucine zipper. Jun can form dimeric complexes with other Jun family as well as Fos family members. The relative proportion of these different dimeric complexes is determined by the relative abundance of each family member at a particular time. Overexpression of v-Jun or c-Jun alone will lead to cell transformation of chicken embryo fibroblasts, albeit with varying efficiencies. Upon overexpression, v-Jun or c-Jun presumably becomes the predominant AP-1 component in the cell. Theoretically, this should lead to a larger proportion of homodimers than heterodimers. It is not clear what role, if any, the other Jun and Fos family proteins play during cell transformation. We have examined the ability of Jun to induce cell transformation in chicken embryo fibroblasts in the absence of interaction with other Jun or Fos family proteins. To this end, we have constructed a chicken v-Jun mutant that is incapable of heterodimerization. This was accomplished by replacing the leucine zipper region of Jun with that of the yeast transcription factor GCN4. This chimeric protein, VJ-GLZ, retains all of the DNA binding and transcriptional activation domains of v-Jun. As expected, in vitro translated VJ-GLZ was found to be incapable of forming heterodimers with c-Fos, FosB, and JunD.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Heterodimerization with c-Fos is not required for cell transformation of chicken embryo fibroblasts by Jun. 147 69

c-Jun is a typical member of the bZIP (basic zipper) family of dimeric transcriptional activators. These proteins contain a basic region responsible for DNA sequence recognition and a leucine zipper that mediates dimerization. bZIP proteins regulate a large number of important physiological functions and, therefore, present an interesting target for molecular interference and mimicry. As a step toward the development of peptide and nonpeptide analogs of such proteins, we constructed a derivative of c-Jun that binds DNA as a monomer. This construction was done by connecting a second basic region to the natural basic region of c-Jun by means of a short peptide loop. Although the polypeptide backbone of the second basic region has an inverted polarity relative to that of the natural basic region, the monomeric c-Jun protein binds DNA with reasonably high affinity and indistinguishable specificity from the wild-type, dimeric c-Jun protein. Furthermore, the monomeric c-Jun protein can activate transcription in vivo. These findings indicate that the polypeptide backbone of the basic region contributes little to sequence recognition and that the leucine zipper is not directly involved in transcriptional activation.
...
PMID:Construction and expression of a monomeric c-Jun protein that binds and activates transcription of AP-1-responsive genes. 152 63

Transcription factor c-Jun appears to be a nuclear target of the Ras-induced signal transduction pathway. In fact, some experiments show that transforming forms of the Ras protein cooperate with Jun in transcriptional activation mediated by an AP-1 site and others indicate that the two oncoproteins cooperate in cellular transformation. Although it is likely that intracellular signaling systems activated by Ras might act directly on c-Jun by inducing specific phosphorylation, it is unclear how c-Jun participates in the transformation process. Here, we present results obtained with a LexA-Jun zipper fusion that lacks both the transcriptional activation domains and the basic region of the DNA-binding domain of c-Jun and contains only the intact leucine-zipper domain. This fusion product has a dominant negative effect on the transcriptional activation elicited by phorbol esters, c-Jun, c-Fos, Ras and E1A on an AP-1-responsive site. An analogous LexA-Fos zipper fusion has similar effects on transcriptional induction. The LexA-Jun zipper fusion acts further as a transformation suppressor, since it causes the generation of nontransformed revertants of ras-transformed cells. This effect is likely to be elicited by the dimerization potential of the Jun leucine zipper trapping cellular Jun and/or Fos in a protein complex unable to bind to DNA. These data implicate further that Ras-mediated transformation involves functional transcription factor AP-1 and that it is possible to interfere with cell transformation by interfering simply with the dimerization of transcription factors involved in the transformation process.
...
PMID:Transformation and transactivation suppressor activity of the c-Jun leucine zipper fused to a bacterial repressor. 158 58

A panel of epitope-specific antibodies, directed against c-Fos, c-Jun, and FosB derived oligopeptide sequences, was generated and used to study the interaction of Fos and Jun proteins and the binding of the Fos/Jun complex to the AP1-binding site (TRE). Our results strongly support results previously obtained by site-directed mutagenesis experiments. The leucine zipper is the major site of interaction between Fos and Jun. Antibodies directed against this domain of Fos bound free Fos protein efficiently, but were unable to recognize Fos within the Fos/Jun complex. In contrast, all other Fos epitope-specific antibodies showed similar reactivity with both free and complexed Fos. Antibodies directed against sequences adjacent to the leucine zipper inhibited formation of the complex. This may suggest that amino acids in the vicinity of the leucine zipper may also play some role in the formation of the protein complex. Binding of Fos/Jun to the TRE was inhibited only by antibodies directed against the basic regions in Fos or Jun previously suggested to represent the DNA binding sites. The fact that very similar results were obtained by two totally different strategies, i.e., mutagenesis experiments and domain mapping using epitope-specific antibodies, lends strong support to the proposed domain structure of Fos and Jun family members.
...
PMID:Mapping of functional domains in Fos and Jun proteins using epitope-specific antibodies. 169 78

We present evidence that CRE-BP1 binding to the cyclic AMP (cAMP) response element (CRE) is a transcriptional activator. Transcriptional activation was assayed by cotransfection into CV-1 cells of a CRE-BP1 expression plasmid together with a reporter plasmid in which the thymidine kinase promoter and four tandem repeats of CRE were linked to the chloramphenicol acetyltransferase (CAT) gene. Cotransfection with the CRE-BP1 expression plasmid caused an 8-fold stimulation of CAT activity, while cotransfection with the plasmids to express CRE-BP1 and c-Jun induced a 32-fold stimulation of CAT activity, suggesting that a heterodimer of CRE-BP1 with c-Jun is a stronger trans-activator than a homodimer of CRE-BP1. By using a series of deletion and point mutants of CRE-BP1 in this cotransfection assay, two functional domains of CRE-BP1 were identified: the putative metal finger structure in the amino-terminal region and the leucine zipper motif linked to a cluster of basic amino acids in the carboxyl-terminal region. The former was a transcriptional activation domain in the absence of c-Jun. The latter was a DNA-binding domain, and was essential in both the presence and absence of c-Jun.
...
PMID:Identification of the functional domains of the transcriptional regulator CRE-BP1. 183 93

The adenovirus E1A protein stimulates transcription of various genes. Recent experiments using a fusion protein have shown that E1A can function through a specific CRE (cyclic AMP response element)-binding protein, CRE-BP1 (also designated ATF-2), which stimulates the transcription from a CRE-containing promoter by homodimer formation or heterodimer formation with c-Jun. In this paper, the functional domains required for mediation of the E1A-induced trans-activation were analyzed using deletion and point mutants of CRE-BP1. The mutation in the putative metal finger structure or leucine zipper structure completely abolished the ability of CRE-BP1 to mediate the E1A-induced trans-activation. Furthermore, overexpression of CRE-BP1 or c-Jun interfered with the E1A-induced trans-activation. These results suggest that the complete putative metal finger structure in the N-terminal region of CRE-BP1 plays an important role for the E1A-induced trans-activation, and the heterodimer of CRE-BP1 with the unidentified protein participates in the interaction with E1A.
...
PMID:Complete putative metal finger and leucine zipper structures of CRE-BP1 are required for the E1A-induced trans-activation. 183 14

We investigated the effect of c-Fos and/or c-Jun co-expression on transcription activation by the progesterone (PR), glucocorticoid (GR) or androgen (AR) receptors using three different reporter genes and four different cell lines. We found that c-Fos could only inhibit, while c-Jun could either inhibit or further stimulate receptor-induced transcription. All these effects were receptor, promoter, and cell type specific, and, importantly, the steroid receptors had non-reciprocal effects on the transactivation ability of c-Jun in the presence or absence of c-Fos. Collectively, these results argue against heterodimer formation as a mechanism to explain the phenomena. Transactivation by the endogenous PR in T47D cells could be inhibited by increasing the intracellular c-Fos level with forskolin as well as by co-expressing c-Fos; no such effect was seen in MCF-7 cells. The inhibition by c-Fos of PR-induced transcription involves a competitive mechanism, which requires the presence of the intact c-Fos leucine zipper and is directed mainly at the transcription activation function (TAF) located in the PR and GR hormone binding domains (TAF-2). However, the co-expression of c-Fos did not alter the 'squelching/transcriptional interference' by the PR of estrogen receptor (ER)-induced transcription. Multiple mechanisms are discussed which may be involved in the crosstalk between the two signal transduction pathways.
...
PMID:Cell-specific inhibitory and stimulatory effects of Fos and Jun on transcription activation by nuclear receptors. 193 3

The nuclear phosphoprotein c-Jun, encoded by the proto-oncogene c-jun, is a major component of the AP-1 complex. A potent transcriptional regulator, c-jun is also able to transform normal rat embryo cells in cooperation with an activated c-Ha-ras gene. By deletion analysis, we identified the regions of c-Jun encoding transformation and transactivation functions. Our studies indicate that there is a direct correlation between the ability of the c-Jun protein to activate transcription and cotransform rat embryo cells. The regions involved in these functions include the conserved leucine zipper/DNA binding domain and an effector domain near its N terminus. This N-terminal region spans amino acids 61 to 146 of the c-Jun protein and is highly conserved among all Jun family members. These results support the hypothesis that c-Jun transforms cells by stimulating the expression of transformation-mediating genes.
...
PMID:The transactivating domain of the c-Jun proto-oncoprotein is required for cotransformation of rat embryo cells. 194 89

The physiological significance of in vitro leucine zipper interactions was studied by the use of two strategies which detect specific protein-protein interactions in mammalian cells. Fusion genes were constructed which produce chimeric proteins containing leucine zipper domains from several proteins fused either to the DNA-binding domain of the Saccharomyces cerevisiae GAL4 protein or to the transcriptional activation domain of the herpes simplex virus VP16 protein. Previous studies in mammalian cells have demonstrated that a single chimeric polypeptide containing these two domains will activate transcription of a reporter gene present downstream of the GAL4 DNA-binding site. Similarly, if the GAL4 DNA-binding domain of a chimeric protein could be complexed through leucine zipper interactions with the VP16 activation domain of another chimeric protein, then transcriptional activation of the reporter gene would be detected. Using this strategy for detecting leucine zipper interactions, we observed homo-oligomerization between leucine zipper domains of the yeast protein GCN4 and hetero-oligomerization between leucine zipper regions from the mammalian transcriptional regulating proteins c-Jun and c-Fos. In contrast, homo-oligomerization of the leucine zipper domain from c-Myc was not detectable in cells. The inability of the c-Myc leucine zipper to homo-oligomerize strongly in cells was confirmed independently. The second strategy to detect leucine zipper interactions takes advantage of the observation that the addition of nuclear localization sequences to a cytoplasmic protein will allow the cytoplasmic protein to be transported to and retained in the nucleus. Chimeric genes encoding proteins with sequences from a cytoplasmic protein fused either to the GCN4 or c-Myc leucine zipper domains were constructed. Experiments with the c-Myc chimeric protein failed to demonstrate transport of the cytoplasmic marker protein to the nucleus in cells expressing the wild-type c-Myc protein. In contrast, the cytoplasmic marker was translocated into the nucleus when the GCN4 leucine zippers were present on both the cytoplasmic marker and a nuclear protein, presumably as a result of leucine zipper interaction. These results suggest that c-Myc function requires hetero-oligomerization to an as yet undefined factor.
...
PMID:Intracellular leucine zipper interactions suggest c-Myc hetero-oligomerization. 199 Feb 93


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

---