Your search keyword '"Hormone receptors -- Influence"' showing total 2 results

1. SMRT repression of nuclear receptors controls the adipogenic set point and metabolic homeostasis

Author

Nofsinger, Russell R., Li, Pingping, Hong, Suk-Hyun, Jonker, Johan W., Barish, Grant D., Ying, Hao, Cheng, Sheue-yann, LeBlanc, Mathias, Xu, Wei, Pei, Liming, Kang, Yeon-Joo, Nelson, Michael, Downes, Michael, Yu, Ruth T., Olefsky, Jerrold M., Lee, Chih-Hao, and Evans, Ronald M.

Subjects

Glucose metabolism -- Research, Homeostasis -- Research, Thyroid hormones -- Properties, Retinoids -- Properties, Hormone receptors -- Properties, Hormone receptors -- Influence, Genetic transcription -- Research, Science and technology

Abstract

The nuclear receptor corepressor, silencing mediator of retinoid and thyroid hormone receptors (SMRT), is recruited by a plethora of transcription factors to mediate lineage and signal-dependent transcriptional repression. We generated a knockin mutation in the receptor interaction domain (RID) of SMRT ([SMRT.sup.mRID]) that solely disrupts its interaction with nuclear hormone receptors (NHRs). [SMRT.sup.mRID] mice are viable and exhibit no gross developmental abnormalities, demonstrating that the reported lethality of SMRT knockouts is determined by non-NHR transcription factors. However, [SMRT.sup.mRID] mice exhibit widespread metabolic defects including reduced respiration, altered insulin sensitivity, and 70% increased adiposity. The latter phenotype is illustrated by the observation that [SMRT.sup.mRID]-derived MEFs display a dramatically increased adipogenic capacity and accelerated differentiation rate. Collectively, our results demonstrate that SMRT-RID-dependent repression is a key determinant of the adipogenic set point as well as an integrator of glucose metabolism and whole-body metabolic homeostasis. adipogenesis | corepressor | PPAR | TR | glucose regulation

Published

2008

2. Dimerization of the thyrotropin-releasing hormone receptor potentiates hormone-dependent receptor phosphorylation

Author

Song, Gyun Jee, Jones, Brian W., and Hinkle, Patricia M.

Subjects

G proteins -- Properties, Thyrotropin releasing factor -- Properties, Hormone receptors -- Influence, Hormone receptors -- Properties, Phosphorylation -- Research, Science and technology

Abstract

The G protein-coupled thyrotropin (TSH)-releasing hormone (TRH) receptor forms homodimers. Regulated receptor dimerization increases TRH-induced receptor endocytosis. These studies test whether dimerization increases receptor phosphorylation, which could potentiate internalization. Phosphorylation at residues 355-365, which is critical for internalization, was measured with a highly selective phospho-site-specific antibody. Two strategies were used to drive receptor dimerization. Dimerization of a TRH receptor-FK506-binding protein (FKBP) fusion protein was stimulated by a dimeric FKBP ligand. The chemical dimerizer caused a large increase in TRH-dependent phosphorylation within 1 min, whereas a monomeric FKBP ligand had no effect. The dimerizer did not alter phoshorylation of receptors lacking the FKBP domain. Dimerization of receptors containing an N-terminal HA epitope also was induced with anti-HA antibody. Anti-HA IgG strongly increased TRH-induced phosphorylation, whereas monomeric Fab fragments had no effect. Anti-HA antibody did not alter phosphorylation in receptors lacking an HA tag. Furthermore, two phosphorylation-defective TRH receptors functionally complemented one another and permitted phosphorylation. Receptors with a D71A mutation in the second transmembrane domain do not signal, whereas receptors with four Ala mutations in the 355-365 region signal normally but lack phosphorylation sites. When D71A- and 4A1a-TRH receptors were expressed alone, neither underwent TRH-dependent phosphorylation. When they were expressed together, D71A receptor was phosphorylated by G protein-coupled receptor kinases in response to TRH. These results suggest that the TRH receptor is phosphorylated preferentially when it is in dimers or when preexisting receptor dimers are driven into microaggregates. Increased receptor phosphorylation may amplify desensitization. G protein | desensitization | G protein-coupled receptor | G protein-coupled receptor kinase | PKC

Published

2007