Renal receptor-binding activity of reduced metabolites of aldosterone: evidence for a mineralocorticoid effect outside of the classic aldosterone receptor system.

Reduced metabolites of aldosterone have been shown to have antinatriuretic and kaliuretic effects. We have studied the ability of four reduced metabolites of aldosterone to compete with [3H]aldosterone and [3H]dexamethasone for binding to the mineralocorticoid and glucocorticoid receptors of the kidney using adrenalectomized rat renal slices and cytosol, respectively, as sources of the binding proteins. 5 alpha-Dihydroaldosterone had 18.9% the ability to compete with [3H]aldosterone for binding to the cytoplasmic receptor of adrenalectomized rat renal slices in comparison to unlabeled aldosterone. Its antinatriuretic potency varied between 7-17%. Its ability to compete with [3H]dexamethasone for binding to the renal glucocorticoid receptor was only 1.9% in comparison to unlabeled dexamethasone. The relative competitive activities of 3 beta,5 alpha-tetrahydroaldosterone and 3 beta,5 beta-tetrahydroaldosterone with [3H]aldosterone to adrenalectomized rat renal slices cytosol were 1.26% and 0.05%, respectively, in comparison to unlabeled aldosterone. Their reported mineralocorticoid activities using the adrenalectomized rat bioassay (antinatriuresis) were 0.1-0.4% and 0.15%, respectively, in comparison to aldosterone. The most important aldosterone metabolite 3 alpha,5 beta-tetrahydroaldosterone showed negligible competitive activity with [3H]aldosterone or [3H]dexamethasone for the renal corticoid type I or type II receptors, respectively. However, this compound has been reported and confirmed to have weak but clear-cut mineralocorticoid activity (approximately 1/100th that of aldosterone). The mineralocorticoid activity of 3 alpha,5 beta-tetrahydroaldosterone cannot be explained by a mechanism involving the classic renal mineralocorticoid receptor. The mechanism could involve an alternative receptor system, a nonreceptor-mediated renal mechanism, or the conversion to a metabolite that would interact with classic receptors.