Synthesis, subcellular distribution and turnover of dopamine beta-hydroxylase in organ cultures of sympathetic ganglia and adrenal medullae.

The synthesis, subcellular distribution and turnover of dopamine beta-hydroxylase was studied in organ cultures of rat adrenal medullae and superior cervical ganglia. After exposure to [3H]leucine for 1 or 3 h, the tissues were homogenized at various time intervals and the amount of labelled dopamine beta-hydroxylase in different subcellular fractions (cytosol, soluble and membrane-bound fraction of catecholamine storage vesicles) was determined by immunoprecipitation and subsequent electrophoresis. In cultured adrenal medullae, induction of dopamine beta-hydroxylase initiated in vivo by administration of reserpine affected both soluble and membrane-bound pools of dopamine beta-hydroxylase to a similar extent after pulse-labelling for 1 or 3 h. The half-lives of dopamine beta-hydroxylase, which amounted to 6 h for the cytosol, 7.5 h for the soluble vesicular and 32 h for the membrane-bound vesicular pools were not altered by pretreatment with reserpine. In superior cervical ganglia the half-lives of the soluble pools were 2-3 times longer than in the adrenal medulla, whereas the half-life of the membrane-bound fraction was the same as in the adrenal medulla. In both organs the most heavily labelled fraction (both after a pulse of 1 or 3 h) was always that of the vesicular membrane, suggesting that newly-synthesized dopamine beta-hydroxylase is immediately incorporated into the storage vesicles and not via release into the cytosol from the site of synthesis. The fact that the half-life of membrane-bound dopamine beta-hydroxylase is markedly longer than that of the two soluble pools suggests that the single pools are not only independently supplied by newly-synthesized DBH but there is also no appreciable subsequent exchange between soluble and membrane-bound pools.