Sctructural studies of the human thyroid hormone receptor isoform β e do ácido retinóico 9-cis isoforma α

In eukaryotes, nuclear receptors are of major importance for intercellular signaling because they join different intra and extracellular signals during regulation of genetic programs. The great majority of these proteins function as ligand activated transcription factors providing a direct link between signaling molecules and the transcriptional responses elicited by them. The genetic programs that these receptors establish or modify affect virtually all aspects of the multicellular organisms? life, such as embryogenesis, homeostasis, reproduction, cell growth, and death. Their gene-regulatory power and selectivity has prompted intense research which is now starting to decipher the complex network of molecular events involved in transcription regulation. The future challenge will be to uncover the molecular rules that define spatial and temporal control of gene expression. Such knowledge would be essential to the development of more efficient drugs with better therapeutic values. Therefore, the main purpose in this study was to extend the understanding on the behavior and the structure of human thyroid receptor, isoform ?1 (hTRβ1), and human retinoic acid X receptor, isoform ? (hRXRα). It was applied the small angle X-ray scattering technique to determine, in solution, the envelop of both receptors containing DNA and ligand binding domains. Beside this, several crystallization conditions were tried for both receptors. The results made possible to define the spatial localization of the domains and the quaternary structure of the homodimers and homotetramers. Consequently, we were able to propose the first structural models for nuclear receptors containing the DNA and ligand binding domains. The oligomeric behavior of the hTRβ1, in solution, was also analyzed qualitatively. We verified that it was influenced by the presence of T3 hormone, the protein concentration, the presence of both DNA and ligand binding domains, and by specific mutations. Based on these results, we were able to hypothesize that the hTRβ1 has the capacity of autorepression. Up to now, only the hRXRα, in the whole nuclear receptor superfamily, had been described to behave similarly. Finally, we crystallized the ligand binding domain of the hTRβ1 in the presence of the ligands T3, Triac, and GC-1. The objective was to solve crystallographic structures essential for the future development of tiromimetics with isoform-selective action. (AU)