Differential capacity of wild type promoter elements for binding and trans-activation by retinoic acid and thyroid hormone receptors.

Retinoic acid receptor (RAR) and thyroid hormone receptor (T3R) are structurally similar and can bind as homodimers or T3R-RAR heterodimers to a single synthetic DNA response element. The interaction of these two types of receptors with wild type elements, however, has not been systematically investigated. Promoter elements from genes regulated by retinoic acid (RA) or thyroid hormone (T3) were tested for response to T3 and RA in transient transfections in both JEG and COS cells. The elements were classified as primarily responsive to RA or to T3 or responsive to both ligands. Binding of highly purified RAR alpha and T3R alpha to the various elements was assessed using the gel shift assay. Those elements predominantly responsive to one ligand showed preferential binding to the appropriate receptor. A series of point mutations were introduced into the rat GH T3 response element to further define sequence requirements for response to both RA and T3. Down-mutations in any of the three hexamers (previously demonstrated to be required for full response to T3 and full binding of T3R) also decreased RA induction and RAR binding. However, only one of two sets of up-mutations for T3 response also increased RA induction, demonstrating differences in hexamer preference between RAR and T3R. Variation in spacing of the three hexamers did not influence RA vs. T3 induction or RAR vs. T3R binding according to the predictions of a simple hexamer spacing model. There was a strong correlation between the extent of T3R dimer binding and strength of T3 induction for a subset of elements studied in JEG cells (r = 0.97, P < 0.01) and a weaker but significant correlation in COS cells (r = 0.65, P < 0.05)). In contrast, RAR dimer binding by the wild type elements did not quantitatively correlate with RA induction in either JEG (r = 0.13, P > 0.05) or COS cells (r = 0.21, P > 0.05). These results suggests that RAR interacts with a heterodimer partner(s) which influences binding site specificity, whereas T3R heterodimer partner(s) is less likely to alter binding site recognition. The observed difference in COS and JEG cells as well as the weak T3R binding-function relationship of the malic enzyme element, however, suggest that the influence of T3R heterodimer partner(s) on binding site specificity is likely to vary with cell type and the specific element tested.     

Half-site spacing and orientation determines whether thyroid hormone and retinoic acid receptors and related factors bind to DNA response elements as monomers, homodimers, or heterodimers.

The receptors for thyroid hormone (T3R) and retinoic acid (RAR) are members of a nuclear receptor subfamily that are capable of recognizing similar DNA sequences. Native response elements for T3R and RAR consist of two or more putative half-site binding motifs organized as imperfect direct or inverted repeats separated by different sized nucleotide gaps. To clarify how T3R, RAR, and related factors recognize DNA response elements, we analyzed the interaction of purified receptors with a series of inverted and direct repeats of an idealized AGGTCA half-site separated by different sized nucleotide gaps. Our results indicate that RAR and T3R can bind to half-sites as monomers and, depending on the orientation and distance between half-sites, also bind as homodimers or T3R-RAR heterodimers. T3R also binds to certain DNA elements as a heterodimer with one or more nuclear factors from eucaryotic cells. Thus, the orientation and spacing of half-sites play a central role in determining which configuration of receptors and nuclear factors will interact with a specific DNA element. This along with the ability of these factors to participate in reversible protein-protein interactions serve to broaden and diversify the responses mediated by T3R, RAR, and related members of this nuclear receptor subfamily.     

RXR alpha, a promiscuous partner of retinoic acid and thyroid hormone receptors.

Retinoic acid receptor (RAR), thyroid hormone receptor (T3R) and vitamin D3 receptor (VD3R) differ from steroid hormone receptors in that they bind and transactivate through responsive elements organized as direct rather than inverted repeats. We now show that recombinant RAR and T3R are monomers in solution and cannot form stable homodimeric complexes on their responsive elements. Stable binding of the receptors to their responsive elements requires heterodimerization with a nuclear factor. This auxiliary factor is tightly associated with RAR and T3R in the absence of DNA and co-purifies with both receptors. As demonstrated by extensive purification, the same auxiliary factor is required for stable DNA binding of RAR as for that of T3R; the factor also facilitates the formation of a stable VD3R-DNA complex. The auxiliary factor is identical to the retinoid X receptor alpha (RXR alpha) by biochemical and functional criteria. The identification of RXR alpha as a dimerization partner for the RARs, T3Rs and VD3R has important implications as to the function of these receptors and their ligands in development, homeostasis and neoplasia.     

H-2RIIBP expressed from a baculovirus vector binds to multiple hormone response elements.

H-2RIIBP is a member of the nuclear hormone receptor superfamily that binds to the region II enhancer of major histocompatibility complex class I genes. Based on its homology with Drosophila XR2C/CF1, H-2RIIBP may play a role in development. By using a baculovirus expression system, a large amount of recombinant H-2RIIBP was produced. The recombinant protein accumulated in the nucleus of insect cells. A series of monoclonal antibodies reacting with the recombinant H-2RIIBP was then generated. A DNA-protein immunoprecipitation assay was developed with these antibodies, enabling the DNA-binding specificity of H-2RIIBP to be distinguished from that of an endogenous region II binding factor expressed in uninfected insect cells. We show that H-2RIIBP binds to estrogen response elements with an affinity comparable to that for the region II enhancer. H-2RIIBP also bound to some, but not all, thyroid hormone response elements and retinoic acid response elements, albeit at a lower affinity. Binding to these elements was demonstrated without exogenous addition of a ligand. The H-2RIIBP binding specificity determined by this assay was in agreement with the specificity assessed by Southwestern and gel mobility shift assays. Furthermore, methylation interference assays indicated that H-2RIIBP recognizes the conserved hormone response motif GG(T/A)CA. Taken together, these data demonstrate that H-2RIIBP is capable of binding to hormone response elements of a variety of genes. They suggest that H-2RIIBP may exert a pleiotropic function.