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Browsing by Subject "retinoic acid receptors"
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Item Multiple parameters determine the specificity of transcriptional response by nuclear receptors HNF-4, ARP-1, PPAR, RAR and RXR through common response elements.(Oxford University Press, 1998-05-15) Nakshatri, H; Bhat-Nakshatri, PA number of nuclear receptors, including retinoic acid receptors (RARs), retinoid-X receptors (RXRs), hepatocyte nuclear factor 4 (HNF-4), chicken ovalbumin upstream promoter transcription factor I (COUP-TFI), apolipoprotein regulatory protein 1 (ARP-1) and peroxisome proliferator-activated receptor (PPAR), bind to response elements comprised of two core motifs, 5'-RG(G/T)TCA, or a closely related sequence separated by 1 nt (DR1 elements). The potential role of the precise sequence of the core motif as well as the spacer nucleotide in determining specificity and promiscuity of receptor-response element interactions was investigated. We show here that nucleotides at base positions 1, 2 and 4 of the core motif as well as the spacer nucleotide determine the binding preference of HNF-4 and ARP-1 homodimers and RAR:RXR and PPAR:RXR heterodimers. In transfection experiments transcriptional activation by HNF-4 and PPAR:RXR and repression by ARP-1 correlated with the relative in vitro binding affinity provided the element was located within the proper promoter context. Furthermore, promoter context also determined whether an element that binds to HNF-4 and PPAR:RXR with equal affinity functions as an HNF-4 response element or PPAR response element. Thus, apart from the element-specific differences in affinity for the receptors, additional promoter-specific transcription factors that interact with HNF-4 and PPAR:RXR determine the specificity of transcriptional response through DR1-type elements.Item A retinoic acid response element is present in the mouse cellular retinol binding protein I (mCRBPI) promoter.(EMBO Press, 1991-08) Smith, W C; Nakshatri, H; Leroy, P; Rees, J; Chambon, PGenomic and cDNA sequences for the mouse cellular retinol binding protein I (mCRBPI) are presented. A specific cis-acting element responsible for retinoic acid (RA) inducibility of the mCRBPI promoter was identified and characterized. Deletion mapping of a CRBPI promoter--chloramphenicol acetyltransferase reporter gene construct localized this element to a 259 bp restriction fragment located approximately 1 kb upstream from the transcription start-site. A sequence closely resembling the previously characterized RA response element (RARE) of the RA receptor beta 2 (RAR-beta 2) promoter, and consisting of a direct repeat of the motif 5'-GGTCA-3' separated by three nucleotides, was found within this restriction fragment. Mutation of these 5'-GGTCA-3' motifs to GGAGC and GGGGC abolished RA-inducible transcription whereas a mutation to a direct repeat of the GTTCA motif found in the RARE of the RAR-beta 2 promoter resulted in enhanced inducibility. Oligonucleotides containing the direct repeat of the GGTCA motif were able to confer RA-dependent transcriptional enhancement to the herpes simplex thymidine kinase promoter, as well as to bind directly all three retinoic acid receptors (RARs) alpha, beta and gamma, as determined by gel retardation/shift assays. The control of CRBPI gene transcription by RA-RAR complexes interacting with the RARE characterized here may correspond to a feedback mechanism important in regulating retinoid metabolism and action.Item Retinoid receptors and binding proteins(Company of Biologists, 1992-01-01) Lohnes, David; Dierich, Andrée; Ghyselinck, Norbert; Kastner, Phillipe; Lampron, Carmen; LeMEUR, Marianne; Lufkin, Thomas; Mendelsohn, Cathy; Nakshatri, Hari; Chambon, PierreSkip to Next Section Retinoids, in particular all-trans retinoic acid (T-RA), are essential for normal development and homeostasis of vertebrates. Although many effects of retinoids, particularily with regard to teratogenicity, have been described in the literature, the mechanisms by which these simple signalling molecules work has only recently begun to be elucidated. We now recognize at least two classes of retinoid-binding proteins and two families of retinoid receptors. The ultimate interpretation of the retinoid signal within a given cell is probably the result of a complex series of interactions between these proteins, yet little is understood concerning the role each member of this signalling pathway plays. It is therefore imperative to dissect the molecular mechanisms which transduce the effects of these ligands, both in vivo and in isolated systems. One approach we are employing is gene targeting of retinoic acid receptors (RARs) and cellular retinoid-binding proteins to generate mice in which one or more of these genes has been functionally inactivated.