Covalent DNA adducts formed by benzo[c]chrysene in mouse epidermis and by benzo[c]chrysene fjord-region diol epoxides reacted with DNA and polynucleotides.

Abstract

The metabolic activation in mouse skin of benzo[c]chrysene (B[c]C), a weakly carcinogenic polycyclic aromatic hydrocarbon (PAH) present in coal tar and crude oil, was investigated. Male Parkes mice were treated topically with 0.5 mumol of B[c]C, and DNA was isolated from the treated areas of skin at various times after treatment and analyzed by 32P-postlabeling. Seven adduct spots were detected, at a maximum level of 0.89 fmol of adducts/microgram of DNA. Four B[c]C-DNA adducts persisted in skin for at least 3 weeks. Treatment of mice with 0.5 mumol of the optically pure putative proximate carcinogens (+)- and (-)-trans-benzo[c]chrysene-9,10-dihydrodiols [(+)- and (-)-B[c]C-diols] led to the formation of adducts which comigrated on TLC and HPLC with some of those formed in B[c]C-treated mice. The major adduct formed in mouse skin treated with B[c]C coeluted on TLC and HPLC with an adduct formed in mouse skin treated with (-)-B[c]C-diol. These results suggested that the detected adducts were formed by the fjord-region B[c]C-9,10-dihydrodiol 11,12-epoxides (B[c]CDEs). To test this, the four optically pure synthetic B[c]CDEs were reacted in vitro with DNA and with synthetic polynucleotides and these samples were 32P-postlabeled. Cochromatography, both on TLC and HPLC, of in vitro and in vivo adducts indicated that B[c]C is activated in mouse skin through formation of the (-)-anti- and (+)-syn-B[c]CDE with 9R,10S,11S,12R- and 9S,10R,11S,12R- absolute configuration, respectively, both of which formed two DNA adducts in vivo. However, the major adduct present in the B[c]C-treated skin DNA was not a fjord-region B[c]CDE adduct but was possibly derived from a bay region B[c]CDE at the 1,2,3,4-position. The extent of DNA adduct formation by B[c]C in mouse skin DNA was lower than that of moderately carcinogenic PAHs previously studied by this method, suggesting a correlation between extent of DNA adduct formation and carcinogenic potential.