Physico-chemical characterization of cytosol and nuclear mineralocorticoid receptors in rat kidney

Effect of various 6-dehydro-corticosteroids, 9, 11-dehydro-DOCA and 9 alpha-fluoro-DOCA on the fluxes of sodium and potassium

The introduction of a double bond at carbons 6 and 7 (6-dehydro-derivatives) of deoxycorticosterone acetate (DOCA), cortisol-21-acetate, 9 alpha-fluorocortisol-21-acetate (9 alpha-F-C-ac) and aldosterone-21-acetate substantially reduces affinity for Type II receptors but not for Type I receptors. Such a modification changes the effect of these steroids on urinary excretion of Na+ and K+. 6-Dehydro-derivatives will thus bind preferentially to receptor Type I inducing the retention of sodium and compete with mineralocorticoids for such receptors. The increase in both natriuresis and kaliuresis when corticosteroids and their 6-dehydro-derivatives are administered together may be interpreted as evidence for a Type II receptor mediation of those ion fluxes. The ionic changes are not mediated by the (Na+ + K+)-ATPase system. The fluoration at 9 and the dehydrogenation at C9C11 of DOCA result in a strong increase of binding to Type I receptor and of sodium retention.

Analysis of renal and hippocampal type I and type II receptors by fast protein liquid chromatography

Type I and Type II adrenal steroid receptors from rat renal and hippocampal cytosols were studied by the technique of Fast Protein Liquid Chromatography. Type I receptors were labelled with [3H]aldosterone plus excess RU26988, and Type II receptors with [3H]dexamethasone. On a Mono Q anion exchange column the molybdate-stabilized renal and hippocampal Type I receptors both eluted as single symmetrical peaks at 0.27 M NaCl, with a recovery of approximately 90% and 60-fold purification (renal) and 10-15-fold (hippocampal). Molybdate-stabilized Type II binding sites from both hippocampal and renal cytosols co-eluted with the Type I sites. On Superose gel filtration renal Type I receptor-steroid complexes consistently eluted two fractions later than hippocampal Type I complexes, suggesting that the renal complexes are smaller; Type II receptor-steroid complexes from both cytosols co-eluted, consistently one fraction behind hippocampal Type I sites. Sequential gel filtration and anion exchange chromatography achieved a 1000-fold purification of renal Type I binding sites, with an overall recovery of 10%.

Effect of 6-dehydro-DOCA and 6-dehydro-9 alpha-fluorocortisol acetate on the excretion of sodium and potassium in the rat

Deoxycorticosterone acetate (DOCA) and 9 alpha-fluorocortisol acetate (9 alpha-F-Cac) can be modified by the introduction of a double bond at carbons 6 and 7 (6-dehydro-derivatives). Such a modification markedly changes the effect of the steroids on urinary excretion of Na+ and K+. Since 6-7 reduction of DOCA and 9 alpha-F-Cac substantially reduces affinity for Type II receptors but not Type I receptors, 6-dehydro-derivatives will thus bind preferentially to receptors influencing the retention of sodium (the "mineralocorticoid" or Type I receptor), and compete with mineralocorticoids for such receptors. We interpret the increase in both natriuresis and kaliuresis when mineralocorticoids and their dehydro-derivatives are administered together as evidence for a Type II receptor mediation of these ion fluxes.

Activation of cytosol aldosterone receptors in rat kidney

Cytosolic aldosterone-protein complexes are isolated from rat kidney slices after incubation with [3H]aldosterone and dexamethasone. Activated and unactivated forms of the complex are characterized by gel electrophoresis and hydroxyapatite chromatography after incubation at 4 degrees C and 25 degrees C respectively. It is found that the activated form reaches a maximum after 30 min at 25 degrees C and can be separated as an homogeneous peak by electrophoresis. Intermediate forms can also be identified. In the presence of 10 mM ATP, activation immediately occurs at 4 degrees C and is almost complete. In the presence of 10 mM molybdate, the activation is strongly enhanced and the increase in activated form may be about fifteen-fold whether molybdate is added during kidney homogenization or just before incubation at 25 degrees C. On the other hand molybdate reduces to one third the binding of the aldosterone-receptor complexes to nuclei. In the presence of the steroid RU 26988 which is a pure glucocorticoid, experiments done on aldosterone-receptors complexes and their binding to nuclei are confirmed. This proves that aldosterone is specific for mineralocorticoid sites. The general pattern of the mineralocorticoid receptor activation is discussed and its resemblance to the case of other steroid hormones is emphasized.