In vitro study of frog (Rana ridibunda Pallas) interrenal function by use of a simplified perifusion system. IV. Influence of metyrapone and aminoglutethimide upon aldosterone production

Effect of the intermediate filament inhibitor IDPN on steroid secretion by frog adrenal glands

In order to determine the role of intermediate filaments in adrenal steroidogenesis, we have studied the effect of IDPN (beta-beta'iminodipropionitrile), an intermediate filaments perturbing agent, on corticosteroid secretion by frog interrenal glands in vitro. A 6-h administration of IDPN (10(-3) M) did not affect the spontaneous release of corticosterone and aldosterone. While IDPN did not alter the response of adrenal fragments to ACTH, the drug caused a marked decrease in angiotensin II-induced stimulation of corticosterone and aldosterone production. These results indicate that, in contrast to microfilaments, which play an important role in spontaneous steroidogenesis, intermediate filaments are not required for basal corticosteroid secretion but are involved in the mechanism of action of angiotensin in frog adrenocortical cells.

Interrenal function in larval Ambystoma tigrinum. II. Control of aldosterone secretion and electrolyte balance by ACTH

Renal clearance techniques were used to assess the role of ACTH on renal electrolyte transport in larval Ambystoma tigrinum. Radioimmunoassay was employed to evaluate changes in circulating aldosterone in these animals. Larvae were hypophysectomized and maintained for 1 week on either ACTH replacement therapy (50 ng/g) or sham injections prior to clearance measurements. Hypophysectomy significantly lowered plasma [Na+] (from 96 to 90 mM), plasma [K+] (from 6 to 4 mM), plasma aldosterone titer (from 157 to 36 pg/ml), fractional Na+ reabsorption (from 97 to 94%), and fractional K+ reabsorption (from 68 to 50%). ACTH replacement restored plasma [Na+] to 96 mM, aldosterone titer to 157 pg/ml, fractional Na+ reabsorption to 96%, and fractional K+ reabsorption to 75%. When steroid synthesis was blocked in a separate set of larvae; ACTH was unable to reverse the sodium depletion which results from adaptation to distilled water. This suggests that ACTH is not acting directly on Na+ transport but acts through a steroid like aldosterone. When larvae were injected intravenously with antialdosterone antibodies their fractional Na+ reabsorption decreased from 95 to 87%. We conclude, therefore, the ACTH works via interrenal steroids, such as aldosterone, to control renal electrolyte transport in this species.

Relative inhibitory potency of five mineralocorticoid antagonists on aldosterone biosynthesis in vitro

Spirolactones are mineralocorticoid antagonists which bind to aldosterone receptors in the distal nephron. During the last decade, several antimineralocorticoids, which are more potent than spironolactone in competing for mineralocorticoid receptors have been developed. In the present study, we have compared the direct activity of spironolactone and four related compounds: prorénone (SC 23133), SC 19886, SC 26304 and its carboxylic analog SC 27169, on aldosterone biosynthesis. Two of them (SC 26304 and its carboxylic analog SC 27169) had no effect on adrenal steroidogenesis, even at concentrations up to 10(-3)M. Spironolactone and prorenone (SC 23133) induced a marked but reversible inhibition of aldosterone biosynthesis. SC 19886 totally inhibited aldosterone production and the activity of this compound lasted for more than 7 hours. In addition, SC 19886 and prorenone (SC 23133) totally suppressed ACTH and angiotensin II-induced stimulation of aldosterone biosynthesis whereas SC 27169 was unable to block adrenal response to these corticotropic hormones. Our results suggest that compounds such as prorenone (SC 23133), SC 19886 and spironolactone, which are potent inhibitors of aldosterone biosynthesis could be more active in the treatment of primary aldosteronism than those antimineralocorticoids which are devoid of action on aldosterone biosynthesis.

The effects of aldosterone on sodium and potassium metabolism in larval Ambystoma tigrinum

Electrolyte depletion resulting from 14 days in distilled water, which was changed daily, lowered plasma Na concentration from 108 to 92 mM. Aminoglutethimide was administered on each of the final 3 days of the depletion period in doses of 3 mg/animal. This further depressed Na to 75 mM. Both aldosterone (25 micrograms/animal) and corticosterone (200 micrograms/animal) returned plasma Na to 92 mM. Cortisone (200 micrograms/animal) was ineffective. There were no consistent patterns in plasma K. Renal clearance experiments showed that the same dose of aminoglutethimide decreased fractional tubular Na reabsorption and increased fractional tubular K reabsorption. Aldosterone reversed these trends suggesting that this hormone may play a role in controlling renal electrolyte excretion.