Thyroid Hormone Regulation of Transmembrane Signalling in Neonatal Rat Ventricular Myocytes by Selective Alteration of the Expression and Coupling of G-protein Alpha-subunits

Overview

Journal Biochem J

Specialty Biochemistry

Date 1995 May 1

PMID 7741715

Citations 4

Authors

S W Bahouth

Affiliations

Soon will be listed here.

Abstract

Thyroid hormone exerts profound effects on the activity of the hormone-sensitive adenylate cyclase system in the heart. Distinct guanine nucleotide-binding regulatory proteins (G-proteins) mediate stimulatory and inhibitory influences on adenylate cyclase activity. To examine whether the effects of thyroid hormone on adenylate cyclase involve specific changes in G-protein subunit expression, the influence of tri-iodothyronine (T3) on the biosynthesis and activity of G-proteins in neonatal rat ventricular myocytes was determined. In myocytes challenged with T3 for 5 days, Gs alpha levels increased by 4 +/- 0.5-fold, whereas Gi2 alpha levels declined by more than 80%. T3 down-regulated Gi2 alpha mRNA by 60% within 3 days, but had no effect on Gs alpha mRNA. The basis for the decline in Gi2 alpha mRNA was the T3-mediated suppression of Gi2 alpha gene transcription by 80 +/- 9% within 4 h. The decline in Gi2 alpha mRNA in response to T3 produced a 2-fold decrease in relative rate of synthesis of Gi2 alpha but not in its half-life (46 +/- 7 h). Gs alpha synthesis was not altered by T3, but the half-life of Gs alpha increased from 50 +/- 6 h in control cells to 72 +/- 8 h in T3-treated cells. In addition, T3 provoked the translocation of Gs alpha from the cytoplasmic to the membranous compartment. Membranous Gs alpha increased from 30 +/- 6% to 61 +/- 7% of total cellular Gs alpha, whereas cytoplasmic Gs alpha declined from 68 +/- 6% to 33 +/- 8% within 1 day of exposure to T3. T3-mediated up-regulation of Gs alpha enhanced the activation of myocardial adenylate cyclase by the stimulatory pathway whereas the down-regulation of Gi2 alpha attenuated the deactivation of myocardial adenylate cyclase by the inhibitory pathway.

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