Synthesis of 3 alpha, 5 alpha-tetrahydroaldosterone

Enzymatic synthesis of 3H-labeled Ring-A reduced metabolites of aldosterone and their separation by high pressure liquid chromatography

Specific methods are described for the enzymatic synthesis of each of the six possible 3H-labeled Ring-A reduced metabolites of aldosterone (5 alpha- and 5 beta-DHAldo; 3 alpha,5 alpha-THAldo; 3 beta,5 alpha-THAldo; 3 alpha,5 beta-THAldo; and 3 beta,5 beta-THAldo; see footnote 1 for full names). Use of heated jacketed columns (C8-reverse phase) and two HPLC solvent systems, with isocratic aqueous methanol or acetonitrile, respectively, have been developed which resolve all six Ring-A reduced metabolites of aldosterone. The relative retention times and elution order of each reduced metabolite are different with each solvent system and hence help confirm the identities of Ring-A reduced metabolites made in vivo from physiological quantities of [3H]aldosterone. The use of an on-line beta-radioactivity detector (Berthold LB-504) enhanced the sensitivity of detection and markedly improved the resolution of these metabolites, compared with that obtained by off-line scintillation counting. Thus, the use of increased temperature with these two solvent systems, together with an on-line radioactivity detector, provide a useful and efficient analytical tool for the separation and identification of each reduced metabolite of aldosterone.

Synthesis of 19-noraldosterone, a potent mineralocorticoid

19-Noraldosterone has been prepared for biological re-evaluation through an extension of a recent synthesis of 19-hydroxyaldosterone: 21-hydroxy-6 beta,19-epoxy-4-pregnene-3,20-dion-20-ethylene ketal-18,11 beta-lactone (1a) was acetylated and then reduced with zinc-acetic acid-isopropanol to the 19-ol 2b. Treatment with sodium acetate transposed the double bond into conjugation, and 2a thus obtained was oxidized with pyridinium chlorochromate to the 19-oxo compound 3. Decarbonylation to the 19-nor lactone 4 was effected by heating with alkali. Protection of the C-3 carbonyl was achieved by ketalization and the resulting mixture of the 5-ene and 5(10)-ene ketals 5 was reduced with DIBAH to the corresponding mixture of the hemiacetals 6. Acid hydrolysis of the latter afforded 19-noraldosterone (7), accompanied by the 18,21-anhydro ketal 8. 19-Noraldosterone in the solid state exists in the cyclic form 7b, which appears to be also the predominant isomer present under conditions of mass spectrometry. [1H]NMR indicates that in chloroform 19-noraldosterone exists mostly as an equilibrium mixture of structures 7a and 7b. Sodium periodate oxidation furnished the gamma-etiolactone 9, confirming the 17 beta configuration in 7.

A highly lipophilic form of aldosterone. Isolation and characterization of an aldosterone dimer

A highly lipophilic form of aldosterone obtained both from incubations of 18-hydroxycorticosterone with quartered rat adrenals and by treatment of aldosterone with acid, was identified as an aldosterone dimer based on its 1H, 13C NMR and mass spectra.

Synthesis of 19-hydroxyaldosterone and the 3 beta-hydroxy-5-ene analog of aldosterone, active mineralocorticoids

19-Hydroxyaldosterone (20) and the 3 beta-hydroxy-5-ene analog of aldosterone (HAA) (8) were synthesized from 21-acetoxy-4-pregnene-3,20-dion-20-ethylene ketal-18, 11 beta-lactone (2) as follows: the double bond was transposed from the 4,5 to the 5,6-position by enol acetylation to 3, followed by sodium borohydride reduction. Further reduction of the resulting lactone 4a with diisobutylaluminum hydride (DIBAH) furnished the 20-ketal of HAA 6, from which free HAA (8) and the 18,21-anhydro compound 7 were obtained by acid treatment. The [1H]NMR spectrum of 8 in CDCl3 showed it to be a mixture of two isomeric forms. Correlation with the known aldosterone-gamma-etiolactone (10) was established by periodate oxidation of HAA to the corresponding etiolactone 9 followed by chromic acid oxidation. The preparation of 20 was next effected in the following manner: the diacetate 4b was converted into the 6 beta, 19-oxido compound 13b by addition of hypobromous acid followed by the hypoiodite reaction of the bromohydrin 11. Mild saponification of 13b lead to the corresponding diol 13a, and was followed by selective oxidation to the 3-one 14, readily dehydrobrominated to 15a. Reductive ring opening furnished a mixture of the 19,21-diol 16a and its 5-ene isomer 16b, which was directly converted to the diketal 17. Reduction with DIBAH gave the hemiacetal 18, and hydrolysis of the latter 19-hydroxyaldosterone (20) as a water-soluble solid, accompanied by the 18,21-anhydro compound 19. 19-Hydroxyaldosterone exists in CHCl3 and water as a mixture of mainly two isomers. Periodate oxidation furnished the etiolactone 21. Preliminary results indicate that HAA and 19-hydroxyaldosterone are active mineralocorticoids in the Kagawa bioassay and short-circuit current measurements.