Metabolism of dichlorobiphenyls by hepatic microsomal cytochrome P-450

In vitro rat hepatic microsomal metabolism of ten individual dichlorobiphenyls (DCBs) has been investigated as part of a major study of the role of metabolism in the toxicity of polychlorinated biphenyl (PCB) pollutant mixtures. The DCBs were metabolized to monohydroxy and dihydrodiol metabolites and unstable metabolites of intermediate polarity. DCBs with both chloro substituents on the same ring, one or both of which were ortho substituents, were susceptible to the same regioselectivities for hydroxylation by control, phénobarbital (PB)- or β-naphthoflavone (BNF)-induced cytochromes P-450 (principally in the 4-position), with the greatest rates of hydroxylation arising with PB-induced cytochrome P-450. In contrast, DCBs with no ortho chlorosubstituents had regioselectivities for hydroxylation by control and PB-induced cytochrome P-450 which differed from that of BNF-induced cytochromes P-450; the greatest rates of hydroxylation were with BNF-induced systems. DCBs with one chloro substituent on each ring were metabolized, with the site of hydroxylation being under the electronic influence of the chloro substituent. With 4,4'-DCB, 60 per cent of the hydroxylated DCB metabolite underwent an NIH shift [G. Guroff, J. W. Daly, D. M. Jerina, J. Renson, B. Witkop and S. Udenfriend, Science157, 1524 (1967)]. The BNF-induced system produced the highest rates of dihydrodiol fomation that were eliminated by an epoxide hydratase inhibitor. The results indirectly prove that arene oxides are intermediates in DCB metabolism and are possibly the source of DCB mutagenicity. The PCBs 2,4,2'4'- and 3,4,3',4'-tetrachlorobiphenyl induced the same effects as PB and BNF respectively. Thus, PCBs differentially affect the metabolism of their individual components and are, possibly, responsible for enhancing their own toxicity by inducing enhanced rates of formation of arene oxide intermediates.