M. Akhtar

The impact of aromatase mechanism on other P450s

Experimental findings from a number of laboratories have converged to show that the conversion of androgens into oestrogen, catalysed by aromatase, involves three distinct reactions which occur at a single active site. That each one of these reactions belongs to a different generic type was revealed by chemical consideration, together with our (18)O-experiments. In particular, these findings highlighted the fact that the third reaction in the sequence occurs by a novel process for which a number of plausible mechanisms have been considered. The scrutiny of these mechanisms has involved either studies on aromatase itself, or on related enzymes which catalyse the aromatase type of cleavage reaction as generalized in equation 1: [equation: see text]. The acyl-carbon cleavage reaction of equation 1 is catalysed by sterol 14alpha-demethylases, accounts for several side-chain fission products formed by CYP17 (17alpha-hydroxylase-17,20-lyase), and constitutes a weak property of certain drug metabolizing P450s, when given aliphatic aldehydes as substrates. From cumulative studies on these enzymes, consensus is beginning to emerge that the acyl-carbon fission may be promoted by the FeIII-OOH intermediate, formed during the catalytic cycles of P450s. The precedent for the direct involvement of the FeIII-OOH species in the reaction of equation 1 is influencing our thinking regarding the mechanism of the conventional hydroxylation reaction. The status of knowledge surrounding the current debate on these issues will be reviewed.

The pathway for the removal of the 15α-methyl group of lanosterol: The role of Lanost-8-ene-3β,32-diol in cholesterol biosynthesis

Abstract [19α- 3 H]Lanost-7-ene-3β-ol is synthesized and is shown to be demethylated by a rat liver homogenate to give 4,4′-dimethylcholesta-7,14-dien-3β-ol. [32- 3 H]Lanost-8-ene-3β,32-diol is synthesized and is shown to be demethylated by a rat liver microsomal preparation to give 4,4′-dimethylcholesta-8,14-dien-3β-ol with the release of C-32 as formic acid.

The cationic charges on Arg347, Arg358 and Arg449 of human cytochrome P450c17 (CYP17) are essential for the enzyme's cytochrome b5-dependent acyl-carbon cleavage activities.

CYP17 (17alpha-hydroxylase-17,20-lyase; also P450c17 or P450(17alpha)) catalyses the17alpha-hydroxylation of progestogens and the subsequent acyl-carbon cleavage of the 17alpha-hydroxylated products (lyase activity) in the biosynthesis of androgens. The enzyme also catalyses another type of acyl-carbon cleavage (direct cleavage activity) in which the 17alpha-hydroxylation reaction is by-passed. Human CYP17 is heavily dependent on the presence of the membrane form of cytochrome b(5) for both its lyase and direct cleavage activities. In the present study it was found that substitution of human CYP17 amino acids, Arg(347), Arg(358) and Arg(449), with non-cationic residues, yielded variants that were impaired in the two acyl-carbon bond cleavage activities, quantitatively to the same extent and these were reduced to between 3 and 4% of the wild-type protein. When the arginines were replaced by lysines, the sensitivity to cytochrome b(5) was restored and the acyl-carbon cleavage activities were recovered. All of the human mutant CYP17 proteins displayed wild-type hydroxylase activity, in the absence of cytochrome b(5). The results suggest that the bifurcated cationic charges at Arg(347), Arg(358) and Arg(449) make important contributions to the formation of catalytically competent CYP17.cytochrome b(5) complex. The results support our original proposal that the main role of cytochrome b(5) is to promote protein conformational changes which allow the iron-peroxo anion to form a tetrahedral adduct that fragments to produce the acyl-carbon cleavage products.

Adolf Friedrich Johann Butenandt. 24 March 1903–18 January 1995

In the period up to the outbreak of the Second World War, Germany had dominated most branches of natural sciences, and in particular chemistry. Of the 39 Nobel Prizes in Chemistry awarded between 1901 and 1939, 18 were won for discoveries in which German chemists had made exclusive or substantial contributions. Adolf Butenandt belongs to that era of Germany when its scientists were at the forefront in confronting technically challenging problems, in the solution of which their traditional Teutonic thoroughness and determination played as important a role as flair and inventiveness.