The anabolic actions of growth hormone and thyroxine on protein metabolism in Snell dwarf and normal mice

Abstract

The individual effects of GH and thyroxine (T₄) on protein metabolism were determined in dwarf and normal mice in vivo. The hormone deficiencies of dwarf mice (low serum concentrations of GH and T₄) resulted in decreased protein synthesis rates in skeletal muscle and liver, but no difference in synthesis rates in heart. The efficiency of synthesis (g protein/g RNA per day; K_RNA) was lower in all three tissues in dwarf compared with normal mice, but effects on RNA concentration were not consistent; there was no change in muscle, a decrease in liver and an increase in heart. Treatment of dwarf mice for 9 days with either human GH or T₄ caused increases in body weight and length. Protein synthesis rates were increased in muscle, liver and heart by either hormone, though much more so with T₄ than GH. In muscle and liver both GH and T₄ treatment resulted in an increased RNA concentration, but T₄ treatment also increased K_RNA. In heart, both GH and T₄ increased K_RNA with no change in RNA concentration. GH caused no significant changes in protein degradation rates so that growth rates were increased. T₄ increased degradation rates so that there was no increased net growth in muscle or liver; in heart, T₄ did induce increased growth despite the large increase in degradation rate. Tibial length was increased by both hormones; GH treatment of dwarf mice also increased cartilage sulphate incorporation on day 9, but T₄ treatment did not, suggesting that bone growth is transient with T₄ treatment. Normal mice showed no changes in growth or tissue protein metabolism in response to GH, but following T₄ treatment there was increased protein turnover due to higher tissue RNA concentrations, although only heart growth was increased. Thus normal mice showed almost no net response to GH or T₄, but dwarf mice showed a large response to both hormones. The response was different, however, in that GH caused concomitant increases in growth rates whereas T₄ altered body tissue proportions. J. Endocr. (1988) 119, 31–41