Article: The stereospecific removal of a C-19 hydrogen atom in oestrogen biosynthesis

1. The synthesis of a number of 19-substituted androgens is described. 2. A method for the partially stereospecific introduction of a tritium label at C-19 in 19-hydroxyandrost-5-ene-3beta,17beta-diol was developed. The 19-(3)H-labelled triol produced by reduction of 19-oxoandrost-5-ene-3beta,17beta-diol with tritiated sodium borohydride is tentatively formulated as 19-hydroxy[(19-R)-19-(3)H]androst-5-ene-3beta,17beta-diol and the 19-(3)H-labelled triol produced by reduction of 19-oxo[19-(3)H]-androst-5-ene-3beta,17beta-diol with sodium borohydride as 19-hydroxy[(19-S)-19-(3)H]-androst-5-ene-3beta,17beta-diol. 3. In the conversion of the (19-R)-19-(3)H-labelled compound into oestrogen by a microsomal preparation from human term placenta more radioactivity was liberated in formic acid (61.6%) than in water (38.4%). In a parallel experiment with the (19-S)-19-(3)H-labelled compound the order of radioactivity was reversed: formic acid (23.4%), water (76.2%). 4. These observations are interpreted in terms of the removal of the 19-S-hydrogen atom in the conversion of a 19-hydroxy androgen into a 19-oxo androgen during oestrogen biosynthesis. 5. It is suggested that the removal of C-19 in oestrogen biosynthesis occurs compulsorily at the oxidation state of a 19-aldehyde with the liberation of formic acid.

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The Stereospecific Removal of a C-19 Hydrogen Atom in Oestrogen Biosynthesis