Artículos de revistas
Analysis of agonist and antagonist effects on thyroid hormone receptor conformation by hydrogen/deuterium exchange
Fecha
2011-01Registro en:
Molecular Endocrinology, Chevy Chase : Endocrine Society, v. 25, n. 1, p. 15-31, Jan. 2011
0888-8809
10.1210/me.2010-0202
Autor
Figueira, A. C. M.
Saidemberg, D. M.
Souza, P. C. T.
Martínez, L.
Scanlan, T. S.
Baxter, J. D.
Skaf, M. S.
Palma, M. S.
Webb, P.
Polikarpov, Igor
Institución
Resumen
Thyroid hormone receptors (TRs) are ligand-gated transcription factors with critical roles in development and metabolism. Although x-ray structures of TR ligand-binding domains (LBDs) with agonists are available, comparable structures without ligand (apo-TR) or with antagonists are not. It remains important to understand apo-LBD conformation and the way that it rearranges with ligands to develop better TR pharmaceuticals. In this study, we conducted hydrogen/deuterium exchange on TR LBDs with or without agonist (T3) or antagonist (NH3). Both ligands reduce deuterium incorporation into LBD amide hydrogens, implying tighter overall folding of the domain. As predicted, mass spectroscopic analysis of individual proteolytic peptides after hydrogen/deuterium exchange reveals that ligand increases the degree of solvent protection of regions close to the buried ligand-binding pocket. However, there is also extensive ligand protection of other regions, including the dimer surface at H10–H11, providing evidence for allosteric communication between the ligand-binding pocket and distant interaction surfaces. Surprisingly, C-terminal activation helix H12, which is known to alter position with ligand, remains relatively protected from solvent in all conditions suggesting that it is packed against the LBD irrespective of the presence or type of ligand. T3, but not NH3, increases accessibility of the upper part of H3–H5 to solvent, and we propose that TR H12 interacts with this region in apo-TR and that this interaction is blocked by T3 but not NH3. We present data from site-directed mutagenesis experiments and molecular dynamics simulations that lend support to this structural model of apo-TR and its ligand-dependent conformational changes.