Peroxisome proliferator-activated receptors and retinoic acid receptors differentially control the interactions of retinoid X receptor heterodimers with ligands, coactivators, and corepressors.

As the obligate member of most nuclear receptor heterodimers, retinoid X receptors (RXRs) can potentially perform two functions: cooperative binding to hormone response elements and coordinate regulation of target genes by RXR ligands. In this paper we describe allosteric interactions between RXR and two heterodimeric partners, retinoic acid receptors (RARs) and peroxisome proliferator-activated receptors (PPARs); RARs and PPARs prevent and permit activation by RXR-specific ligands, respectively. By competing for dimerization with RXR on response elements consisting of direct-repeat half-sites spaced by 1 bp (DR1 elements), the relative abundance of RAR and PPAR determines whether the RXR signaling pathway will be functional. In contrast to RAR, which prevents the binding of RXR ligands and recruits the nuclear receptor corepressor N-CoR, PPAR permits the binding of SRC-1 in response to both RXR and PPAR ligands. Overexpression of SRC-1 markedly potentiates ligand-dependent transcription by PPARgamma, suggesting that SRC-1 serves as a coactivator in vivo. Remarkably, the ability of RAR to both block the binding of ligands to RXR and interact with corepressors requires the CoR box, a structural motif residing in the N-terminal region of the RAR ligand binding domain. Mutations in the CoR box convert RAR from a nonpermissive to a permissive partner of RXR signaling on DR1 elements. We suggest that the differential recruitment of coactivators and corepressors by RAR-RXR and PPAR-RXR heterodimers provides the basis for a transcriptional switch that may be important in controlling complex programs of gene expression, such as adipocyte differentiation.

A nuclear hormone receptor corepressor mediates transcriptional silencing by receptors with distinct repression domains.

Ligand-independent transcriptional repression is an important function of nuclear hormone receptors. An interaction screen with the repression domain of the orphan receptor RevErb identified N-CoR, the corepressor for thyroid hormone receptor (TR) and retinoic acid receptor (RAR). N-CoR is likely to be a bona fide transcriptional corepressor for RevErb because (i) RevErb interacts with endogenous N-CoR, (ii) ectopic N-CoR potentiates RevErb-mediated repression, and (iii) transcriptional repression by RevErb correlates with its ability to bind N-CoR. Remarkably, a region homologous to the CoR box which is necessary for TR and RAR to interact with N-CoR is not required for RevErb. Rather, two short regions of RevErb separated by approximately 200 amino acids are required for interaction with N-CoR. The primary amino acid sequence of the N-terminal region of RevErb essential for N-CoR interaction is not homologous to that of TR or RAR, whereas similarities exist among the C-terminal domains of the receptors. N-CoR contains two adjacent but distinct interaction domains, one of which binds tightly to both RevErb and TR whereas the other binds more weakly and differentially interacts with the nuclear receptors. These results indicate that multiple nuclear receptors, utilizing different primary amino acid sequences, repress transcription by interacting with N-CoR.

Ligand-independent repression by the thyroid hormone receptor mediated by a nuclear receptor co-repressor.

Thyroid-hormone and retinoic-acid receptors exert their regulatory functions by acting as both activators and repressors of gene expression. A nuclear receptor co-repressor (N-CoR) of relative molecular mass 270K has been identified which mediates ligand-independent inhibition of gene transcription by these receptors, suggesting that the molecular mechanisms of repression by thyroid-hormone and retinoic-acid receptors are analogous to the co-repressor-dependent transcriptional inhibitory mechanisms of yeast and Drosophila.

Polarity-specific activities of retinoic acid receptors determined by a co-repressor.

Retinoic acid receptors (RARs) and retinoid-X receptors (RXRs) activate or repress transcription by binding as heterodimers to DNA-response elements that generally consist of two direct repeat half-sites of consensus sequence AGGTCA. On response elements consisting of direct repeats spaced by five base pairs (DR + 5 elements), RAR/RXR heterodimers activate transcription in response to RAR-specific ligands, such as all-trans-retinoic acid (RA). In contrast, on elements consisting of direct repeats spaced by one base pair (DR + 1 elements), RAR/RXR heterodimers exhibit little or no response to activating ligands and repress RXR-dependent transcription. Here we show that ligand-dependent transactivation by RAR on DR + 5 elements requires the dissociation of a new nuclear receptor co-repressor, N-CoR, and recruitment of the putative co-activators p140 and p160. Surprisingly, on DR + 1 elements, N-CoR remains associated with RAR/RXR heterodimers even in the presence of RAR ligands, resulting in constitutive repression. These observations indicate that DNA-response elements can allosterically regulate RAR-co-repressor interactions to determine positive or negative regulation of gene expression.

Genomic structure of the POU-related hepatic transcription factor HNF-1 alpha.

Hepatocyte Nuclear Factor-1 alpha (HNF-1 alpha) is a vertebrate transcriptional regulatory protein which plays a prominent role in the activation of a large family of hepatocyte-specific genes. It is the prototype of a new subfamily of POU-related proteins important in embryogenesis and cell-type specification. Here we report on the genomic structure and DNA sequence of HNF-1 alpha of the hen. Functional domains are non-uniformly conserved between hen and mammals consistent with the notion of functions in the hen oviduct that were lost in mammals after avian mammalian separation. The unusual homeo-related DNA-binding domain is well preserved between birds and mammals. The exon/intron pattern of the gene changed during evolution. The rat gene consists of 9 exons, the chicken gene of 10. In mammals one intron was eliminated that in hens subdivides the serine-rich transactivation domain. Comparison of the sequences at this junction indicates the involvement of elements of the V(D)J recombination system in the process of intron elimination.

Hepatic nuclear factor 1 alpha (HNF-1 alpha) is expressed in the oviduct of hens and interacts with regulatory elements of the lysozyme gene.

HNF-1 alpha is a nuclear transcriptional regulatory protein required for the expression of a variety of liver-specific genes. This factor was previously considered liver-specific but later shown to be expressed also in a few other mammalian tissues. Here we report on the occurrence of HNF-1 alpha in the avian oviduct. This finding is of particular interest because HNF-1 alpha is not expressed in female reproductive organs of mammals. The avian oviduct is the site of assembly for the avian egg and the site of tissue-specific synthesis of the major egg white proteins, such as lysozyme. We also demonstrate that the chicken lysozyme gene contains HNF-1 recognition sites within two of its important upstream regulatory elements. The presence of HNF-1 recognition elements in functionally significant regulatory sites of the lysozyme gene and high levels of HNF-1 alpha in the oviduct is a strong indication for the involvement of HNF-1 alpha in the control of the lysozyme gene and possibly other egg white protein genes in the chicken oviduct. Apparently, HNF-1 alpha performs functions in the avian oviduct that were lost upon development from birds to mammals.