| Abstract: | The mutagenic and carcinogenic metabolite of benzoa]pyrene, (7R,8S)-dihydroxy-(9R,10R)-epoxy-7,8, 9,10-tetrahydrobenzoa]pyrene, undergoes two major reactions in the presence of DNA: (i) hydrolysis and (ii) covalent binding. We report that hydrolysis and covalent binding are specific and general acid-catalyzed reactions with the same or similar rate-determining steps. To account for the similarity of rate-determining steps in covalent binding and hydrolysis we propose and test two models. In each model, the rate-determining step results in formation of a carbonium ion, which serves as a precursor for both tetrol and adduct. In model A the carbonium ion is partitioned between two domains (1 and 2), while in model B there is only one domain. Measurements of pseudo-first-order rate constants, product ratios, and rate ratios support model A, while kinetic results are inconsistent with model B. Domain 1 most likely represents activated benzoa]pyrenes that are intercalated into DNA, while domain 2 hydrocarbons are physically bound to the outside of the DNA helix. |
