Nuclear hormone receptors comprise a superfamily of ligand-modulated transcription factors that mediate the transcriptional activities of steroids, retinoids, and thyroid hormones. A growing number of related proteins have been identified that possess the structural features of hormone receptors, but that lack known ligands. Known as orphan receptors, these proteins represent targets for novel signaling molecules. We have isolated a mammalian orphan receptor that forms a heterodimeric complex with the retinoid X receptor. A screen of candidate ligands identified farnesol and related metabolites as effective activators of this complex. Farnesol metabolites are generated intracellularly and are required for the synthesis of cholesterol, bile acids, steroids, retinoids, and farnesylated proteins. Intermediary metabolites have been recognized as transcriptional regulators in bacteria and yeast. Our results now suggest that metabolite-controlled intracellular signaling systems are utilized by higher organisms.
The response of a cell to mitogens and differentiation agents involves the transcriptional induction of several cellular genes. Prominent among these so-called 'immediate early' or 'competence' genes are the nuclear oncogenes fos and myc. Although the precise function of these early response genes in growth control is not understood, it is likely that many of them are involved in the transition from G0 to G1 in the cell cycle. The findings that the products of nuclear proto-oncogenes jun and erbA are transcriptional factors supports the notion of the role of the nuclear oncoproteins in the regulation of gene expression. Recently, it has been reported that the FOS protein is associated in transcriptional complexes with the product of the jun oncogene, the transcription factor AP-1. As the fos gene is induced in response to mitogens during initiation of cell growth, we investigated whether expression of the nuclear transcription factor AP-1 is also inducible. We report that mouse c-jun gene transcription is rapidly induced by serum and phorbol-ester 12-o-tetradecanoyl phorbol 13-acetate (TPA). Furthermore, induction is transient and the mRNA is superinduced by inhibitors of protein synthesis.
As2O3 induces apoptosis without differentiation in retinoic acid-sensitive and retinoic acid-resistant APL cells at concentrations that are achievable in patients. As2O3 induces loss of the PML/RAR alpha fusion protein in NB4 cells, in retinoic-acid resistant cells derived from them, in fresh APL cells from patients, and in non-APL cells transfected to express this protein. As2O3 and retinoic acid induce different patterns of gene regulation, and they inhibit the phenotypes induced by each other. Understanding the molecular basis of these differences in the effects of As2O3 and retinoic acid may guide the clinical use of arsenic compounds and provide insights into the management of leukemias that do not respond to retinoic acid.
Gene expression is modulated by the specific interactions of nuclear proteins with unique regulatory sequences in the genome. Proteins involved in transcriptional regulation seem to be either transcription factors or transcription modulators and their interactions are crucial in determining whether the expression of a specific gene is activated or repressed. Recently, the product of the proto-oncogene jun has been identified as the transcription factor AP-1, whereas nuclear oncoproteins fos and myc have been implicated in transcriptional transregulation of several promoters. Furthermore, the products of the fos and jun proto-oncogenes are associated in some transcription complexes. Although the nature of the association is unclear, the two proteins co-immunoprecipitate with fos antibodies in nuclear extracts. Here, we report studies that demonstrate that the fos protein directly modulates jun function by means of a heterodimer of fos and jun proteins. The fos 'leucine zipper' domain is necessary for the DNA binding of the heterodimer; a distinct domain, localized in the C-terminal region of the fos protein, is responsible for transcriptional regulation.
Retinoids induce myeloblastic leukemia (HL-60) cells to differentiate into granulocytes, which subsequently die by apoptosis. Retinoid action is mediated through at least two classes of nuclear receptors: retinoic acid receptors, which bind both all-trans retinoic acid and 9-cis retinoic acid, and retinoid X receptors, which bind only 9-cis retinoic acid. Using receptor-selective synthetic retinoids and HL-60 cell sublines with different retinoid responsiveness, we have investigated the contribution that each class of receptors makes to the processes of cellular differentiation and death. Our results demonstrate that ligand activation of retinoic acid receptors is sufficient to induce differentiation, whereas ligand activation of retinoid X receptors is essential for the induction of apoptosis in HL-60 cell lines.
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 Xgtll expression library, murine protein mXBP, which binds to a sequence which overlaps the 3' end of the murine class II major histocompatibility complex Ae 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.
Expression of the nuclear proto-oncogene cjun is rapidly and transiently induced by many growth factors, serum, and tumor promoters. The sequence elements in the c-jun promoter involved in serum or growth factor induction have not been identified. The c-jun promoter region between -117 and -72 contains binding sites for the transcription factors Spl, CTF, and AP-1. An additional sequence element has been noted at position -59.This A+T-rich sequence, formerly proposed as a TFIID-binding site, conforms to the consensus binding sequence of a recentl identified factor, RSRF (related to serum response factor). In this study, we mapped the sequences in the c-jun promoter responsible for epidermal growth factor (EGF), serum, and 12-0-tetradecanoylphorbol-13-acetate (TPA) induction by deletion and point mutational analysis. We found that the c-jun RSRF site is an important element for EGF and serum induction of the promoter and that there are several factors in HeLa nuclear extracts which specifically bind to this site. The RSRF site was also sufficient for EGF, serum, and TPA induction when assayed on a heterologous promoter. The c-jun AP-1 site was not required for EGF, serum, or TPA induction but was sufficient to mediate a weak response to these agents when assayed on a heterologous promoter. Double mutation of the RSRF and AP-1 sites suggests that there is an additional TPA-responsive element between -80 and +150 in the c-jun promoter.Treatment of cultured cells with serum or growth factors induces expression of a set of genes known as immediateearly genes (reviewed in reference 10). Induction of expression of these genes is rapid and independent of new protein synthesis, suggesting that the induction is a direct consequence of a limited number of posttranslational steps. The signal transduction pathways by which serum or growth factors activate immediate-early genes are not well understood. One approach to this question is to study the regulation of promoter elements in immediate-early genes that mediate their response to growth factors. The factors which bind to these elements can then be identified and the regulation of these factors can be studied to trace their control back to cell surface receptors.One such control element is the serum response element
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