Effects of microsomal enzyme inducers in vivo and inhibitors in vitro on the covalent binding of benzo[a]pyrene metabolites to DNA catalyzed by liver microsomes from genetically responsive and nonresponsive mice.

The in vitro DNA binding of benzo[a]pyrene metabolites generated by mouse liver microsomes can be resolved into at least nine distinct peaks by elution of a Sephadex LH20 column with a water-methanol gradient. These peaks, representing metabolite-nucleoside complexes, are named A (most polar) through I (least polar). 3-Methylcholanthrene, 2,3,7,8-tetrachlorodibenzo-p-dioxin, phenobarbital, Aroclor 1254, pregnenolone-16α-carbonitrile, or ethanol was administered in vivo to genetically “responsive” C57BL/6N or “nonresponsive” DBA/2N mice, in an attempt to understand and identify increases or decreases in reactive BP intermediates that bind to DNA. Rises or falls in these peaks are also noted when liver microsomes from control or 3-methylcholanthrene-treated C57BL/6N or DBA/2N mice were incubated in vitro with [³H]benzo[a]pyrene and microsomal enzyme inhibitors such as α-naphthoflavone, metyrapone or cyclohexene oxide. All of our interpretations concerning the binding of metabolites to DNA are consistent with non-K-region oxygenation of benzo[a]pyrene being mediated predominantly by cytochrome(s) P₁-450 and K-region oxygenation of benzo[a]pyrene being catalysed predominantly by form(s) of P-450 other than P₁-450. All of the biological perturbations are consistent with the following assignments. The major reactive intermediate of benzo[a]pyrene contributing to each peak is suggested to be: peaks A and C, an unknown dihydrodiol oxide; peaks B, D, F and I, quinones oxygenated further (or quinone-derived free radicals); peak E, both cis- and tans-7,8-diol-9,10-epoxides; peak F′, the 7.8-oxide; peak G, the 4.5-oxide; and peak H, an unknown phenol oxide. The DNA nucleosides are not identified in this study. Of the ten peaks listed here, it is of interest that the major metabolite(s) contributing to eight of the peaks (all except peaks F' and G) involve(s) more than a single mono-oxygenation by forms of cytochrome P-450. All peaks, with the exception of peak G, appear to be predominantly associated with benzo[a]pyrene metabolism mediated by P₁-450 and, therefore, controlled by the Ah locus. The use of these microsomal enzyme inducers or inhibitors—combined with the underlying genetic predisposition of the individual, tissue, or cell culture system under study—demonstrates that the balance between P-450 and epoxide hydrase, and the ratio of each form of P-450 to the other forms of P-450, can influence markedly the quantity and quality of reactive intermediates of benzo[a]pyrene that bind to DNA.