PT  - JOURNAL ARTICLE
AU  - T J Monks
AU  - S S Lau
AU  - L R Pohl
AU  - J R Gillette
TI  - The mechanism of formation of o-bromophenol from bromobenzene.
DP  - 1984 Mar 01
TA  - Drug Metabolism and Disposition
PG  - 193--198
VI  - 12
IP  - 2
4099  - http://dmd.aspetjournals.org/content/12/2/193.short
4100  - http://dmd.aspetjournals.org/content/12/2/193.full
SO  - Drug Metab Dispos1984 Mar 01; 12
AB  - Both o-bromophenol and p-bromophenol are formed from bromobenzene in rat liver microsomes. It has been established that p-bromophenol is formed via bromobenzene-3,4-oxide, but o-bromophenol could conceivably arise via either the 2,3-epoxide or the 1,2-epoxide or by direct insertion of oxygen. As described in the present article, we have isolated and identified bromobenzene 2,3-dihydrodiol as a microsomal metabolite of bromobenzene. Identification of the dihydrodiol therefore indicates the formation of its obligatory precursor, bromobenzene-2,3-oxide. Moreover, using bromo(2,4,6-2H3)benzene, we have clarified the mechanism of formation of o-bromophenol from bromobenzene. The rate of formation of o-bromophenol from bromobenzene and bromo(2,4,6-2H3)benzene in liver microsomes from 3-methylcholanthrene-treated rats was 0.72 +/- 0.02 and 0.74 +/- 0.06 nmol/mg/min (kH/kD = 0.99), respectively. The lack of a significant isotope effect indicates that the hydroxylation of bromobenzene to o-bromophenol is not by a direct insertion mechanism. Furthermore, the mass spectrum of o-bromophenol isolated from a microsomal incubation with bromo(2,4,6-2H3)benzene indicated that 70% of the product retained all three deuterium atoms. These results are consistent with the view that o-bromophenol is formed from the 2,3-epoxide intermediate but do not preclude formation by the addition of oxygen to the 2-position carbons followed by an NIH shift and rearrangement before an epoxide is formed.