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

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

Basal expression of a chimeric gene (pMHO4CAT) consisting of approximately 7 kilobase pairs (kbp) of the 5'-flanking region of the mouse heme oxygenase-1 (HO-1) gene fused to the bacterial chloramphenicol acetyltransferase gene is 2- to 10-fold greater than that of an analogous construct containing only 1287 bp of the 5'-flanking region (pMHO1CAT) in transiently transfected cultured cells. The enhancer activity has been localized to a 268-base pair (bp) fragment positioned approximately 4 kilobase pairs upstream of the transcription initiation site. This fragment contains two high affinity protein binding sites, regions A and B, as determined by DNase I protection assays using nuclear protein extracts from rat C6 glioma cells. Both sites include core sequence elements, TGAGTCA (region A) and TGTGTCA (region B), that resemble the consensus binding site, TGA(G/C)TCA, of the Jun/Fos (AP-1) family of transcription factors. Purified, bacterially expressed AP-1 (c-Jun homodimer) specifically binds to both elements, exhibiting greater affinity for the region A motif. The expression of pMHO4CAT, but not of pMHO1CAT, is stimulated by the phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA), and the 268-bp enhancer fragment confers TPA inducibility and c-Jun/c-Fos transactivation to the heterologous SV40 promoter. These functions are mediated by the AP-1 binding sites as multiple copies of the region A motif also confer TPA induction and c-Jun/c-Fos transactivation upon a heterologous promoter.
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PMID:Distal AP-1 binding sites mediate basal level enhancement and TPA induction of the mouse heme oxygenase-1 gene. 140 Apr 99

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.
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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.
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PMID:Complete putative metal finger and leucine zipper structures of CRE-BP1 are required for the E1A-induced trans-activation. 183 14

The nuclear oncoproteins fos and jun are associated as a heterodimer which binds to TPA (PMA or TPA: phorbol 12-myristate 13-acetate)- responsive promoter elements (TRE), the recognition site for the transcription factor AP-1. The fos/jun heterodimer has a higher affinity to the TRE and stimulates transcription of responsive genes more than the jun homodimer. The association of these two oncoproteins may play a central role in signal transduction and regulation of cell proliferation and differentiation. We further defined the regulation of fos and jun by studying their inducibility by second messengers in cells of hematopoietic origin. In THP-1 monocytic leukemia cells fos and jun mRNA levels are regulated in a coupled manner by second messengers activated after membrane phospholipid turnover. Addition of phospholipase C to cells, as well as stimulation of protein kinase C and release of intracellular Ca2+, caused a rapid induction of fos and jun mRNA levels, but the induction of jun mRNA showed a more persistant and less transient pattern than fos. In contrast to the phosphoinositol system, stimulation of the adenylate cyclase pathway in THP-1 cells induced only fos transcription whereas jun mRNA levels remained unchanged. A similar uncoupling of fos and jun inducibility was found after phorbol ester addition to the human erythroleukemia cell line HEL and the human promyelocytic cell line HL-60. The uncoupling of fos and jun levels might predispose cells to the formation of combinatorial transcription complexes of a different composition and activity than the fos/jun heterodimer. Indeed, nuclear extracts from THP-1 cells before or after activation of the phosphinositol or adenylate cyclase second messenger pathways revealed a correlation in fos and jun expression and specific binding of the heterocomplex to a TRE sequence.
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PMID:Coupled and uncoupled induction of fos and jun transcription by different second messengers in cells of hematopoietic origin. 215 73

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.
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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

Mutations between the leucines of the "leucine zipper" domain of Jun D can either decrease (Asn 301 to Ala) or increase (Thr 307, Ala 308, to Glu, Val) homodimer formation and specific binding to DNA even though such changes do not modify the predicted alpha-helical structure of this region. As shown previously, addition of Fos strongly increases the affinity of Jun for DNA by forming a heterodimer. The jun down mutation (Asn 301 to Ala) also diminishes DNA binding by the Fos-Jun D heterodimer. These data strongly support the coiled coil conformation of this region where residues adjacent to the leucines are also important for dimer formation. Ultraviolet cross-linking experiments have shown that both Fos and Jun directly contact the TGACTCA palindromic sequence defined as a TPA (12-O-tetradecanoyl phorbol-13-acetate) response element or TRE. Both Jun homodimers and Jun-Fos heterodimers bind this TRE as well as the cAMP responsive element (CRE or TGACGTCA) with comparable affinities. While strong c-Jun or Jun D binding requires a perfect palindrome, Jun-Fos complexes can also efficiently recognize sequences where the right half of the palindrome is less conserved (TGACTAA or TGACGCA).
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PMID:Jun DNA-binding is modulated by mutations between the leucines or by direct interaction of fos with the TGACTCA sequence. 256 20

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

Leucine zippers constitute a widely observed structural motif which serves to promote both homo- and heterodimerization in a number of DNA-binding proteins. As part of our ongoing efforts to characterize both the structure and the dynamical properties of this dimerization domain as they relate to biological function, we report here the secondary structure in solution of a recombinant dimeric peptide (rJunLZ) comprising residues Arg276-Asn314 of the leucine zipper domain of c-Jun. Two- and three-dimensional homo- and heteronuclear NMR experiments have allowed definition of the secondary structure of rJunLZ and have provided a total of approximately 1500 interproton distance and 62 phi dihedral angle constraints for tertiary structure calculations. Amide proton protection factors, calculated from hydrogen-deuterium exchange experiments, have identified 62 hydrogen bonds in the rJunLZ dimer. We have also examined the role of Asn22, the only polar residue situated at the hydrophobic dimer interface. Virtually all leucine zipper sequences contain such a polar residue (usually Asn) near the center of the motif. X-ray crystallographic studies showed that, in the case of the GCN4 homodimer, the polar residue (Asn) adopts an asymmetric conformation in an otherwise essentially symmetric structure. In contrast, all NMR studies of leucine zipper homodimers to date have suggested that the dimers are completely symmetric in solution. We present evidence that the side-chain amide protons of Asn22 are hydrogen-bonded in solution and that this side chain exchanges rapidly between two distinct conformations. On the basis of these observations, we propose a dynamic model which can explain the apparent differences in symmetry observed in NMR and X-ray crystallographic studies of leucine zipper homodimers. We show that mutation of Asn22 to a hydrophobic Leu residue markedly increases the thermal stability of the rJunLZ homodimer, consistent with a destabilizing role for this residue. However, at temperatures below 30 degrees C, the Asn22-->Leu mutant rearranges to form oligomers larger than the dimer, as was previously observed for the corresponding Asn-->Val mutation in the GCN4 leucine zipper. These results are consistent with the hypothesis that the polar Asn residue commonly observed at the interface of leucine zippers imposes specificity for the dimer structure at the expense of stability [Harbury, P.B., Zhang, T., Kim, P.S., & Alber, T. (1993) Science 262, 1401-1407].
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PMID:Nuclear magnetic resonance characterization of the Jun leucine zipper domain: unusual properties of coiled-coil interfacial polar residues. 774 21

fra-2 (fos-related antigen-2) expression is detected at a basal level even in growth-arrested chicken embryo fibroblasts (CEF), but upon serum-stimulation high levels of its transcripts are transiently observed. This induction is delayed and prolonged compared to that of c-fos. Transient expression experiments in CEF using a series of constructs of chicken fra-2 promoter region linked to the CAT reporter gene indicated previously that serum response element (SRE) is not required for full serum inducibility. In this report, we show that constructs in which the CRE-like sequence and both AP-1 binding sites are disrupted lack serum inducibility, suggesting that either of these enhancers is important in serum induction of fra-2. In growth-arrested CEF, small amounts of Fra-2/c-Jun complex bind to the AP-1 consensus sequences in fra-2 promoter, while a significant part of the enhanced AP-1 binding activity after 60-120 min of serum stimulation is attributable to c-Fos/c-Jun heterodimer. At later times Fra-2/c-Jun again becomes the main complex. Transient expression assays in F9 cells indicated that c-Fos/c-Jun heterodimers have strong stimulatory effects on fra-2 promoter activity, while Fra-2/c-Jun complex has lower transcriptional activity than that of c-Jun homodimer. These results suggest that c-Fos (induced at earlier times) and c-Jun proteins are at least partly responsible for serum-induced expression of fra-2.
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PMID:fra-2 promoter can respond to serum-stimulation through AP-1 complexes. 786 46

The AP-1 transcriptional activating complex, made up of Jun and Fos protein, is involved in controlling many cellular processes such as cell proliferation, differentiation and transformation. We have previously characterized a dominant-negative mutant of c-Jun called TAM-67 which forms dimers with c-Jun and c-Fos, and binds DNA as a homodimer or heterodimer with c-Jun or c-Fos. This dominant-negative mutant is a potent inhibitor of AP-1 mediated transactivation, as well as c-jun/ras and TPA/ras-induced transformation. The present report describes experiments designed to elucidate the exact molecular mechanism of this dominant-negative inhibitor. The DNA binding kinetics of both TAM-67:TAM-67 homodimers as well as TAM-67:Fos heterodimers were studied and compared to those of c-Jun and other transactivation-deficient mutants of c-Jun. These studies demonstrated that the TAM-67 proteins have similar DNA binding kinetics to c-Jun and other Jun mutant proteins. Thus, the deletion of the amino-terminal end of the Jun protein does not significantly alter the protein's affinity for DNA. In addition, to determine whether TAM-67 functions through the formation of homodimers, or through interactions with endogenous c-Jun or c-Fos, we constructed a pair of chimeric proteins made by replacing the leucine zipper of TAM-67 with the leucine zippers of GCN4 and c-Fos. These chimeric proteins, termed TAM/GCN4 and TAM/Fos, were then tested for their ability to bind DNA, inhibit c-Jun-induced transactivation, and inhibit TPA/ras-mediated transformation. The results of these studies show that while both chimeric proteins bind equally well to DNA, only the TAM/Fos protein, and not the TAM/GCN4 protein, inhibits AP-1-induced transactivation and TPA/ras-induced transformation. When compared to the TAM-67 protein, the TAM/Fos protein is an equally potent inhibitor of transactivation and transformation. These results suggest that TAM-67 inhibits AP-1-mediated processes through a 'quenching' mechanism by inhibiting the function of endogenous Jun and/or Fos proteins. The implications of these mechanistic findings on the development of potent inhibitors of signal transduction pathways are discussed.
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PMID:Mechanism of action of a dominant-negative mutant of c-Jun. 810 21


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