Mutagenicity of reactive derivatives of carcinogenic hydrocarbons: evidence of DNA repair

The ability of cellular DNA repair enzymes, which are active on ultraviolet light-induced lesions in DNA, to recognize and repair damage induced in DNA by exposure to carcinogenic polycylic hydrocarbons was investigated and the effect of such repair processes on the mutagenicity of the hydrocarbons determined. The carcinogenic hydrocarbos, 7-bromomethylbenza]anthracene (7-BrMeBA) and 7-bromomethyl-12-methylbenza]anthracene (7-BrMe-12-MeBA), chosen for this study because they form well characterized, stable products with DNA, were dissolved at various concentrations in acetone, added under mild conditions to biologically active DNA isolated from Bacillus subtilis, and the reaction stopped by ethanol precipitation. The hydrocarbons were determined by specific radioactivity to be covalently linked to DNA at a frequency of from 1–5 per 1000 nucleotides. An increased frequency of bound hydrocarbon molecules was directly correlated with a decrease in the buoyant density of the DNA as measured in analytical CsCl centrifugation studies. The samples of hydrocarbon-bound DNA were tested for survival of biological activity and for the frequency of induced forward mutations in two recipient strains (hcr⁺ and hcr^?) of Bacillus subtilis which differ in their ability to repair ultraviolet light-induced lesions in DNA. The survival of the biological activity was significantly higher in the repairing strain (hcr⁺). A higher frequency of mutations was detected in the repairing strain as well. The loss of transforming activity and the increase in the frequency of mutations (up to 20-fold) was directly proportional to the amount of hydrocarbon bound to the DNA samples. The majority of these mutations proved unable to revert spontaneously. Finally, the ability of highly purified rat liver endonuclease, shown to recognize lesions in UV-irradiated DNA, to recognize such hydrocarbon lesions was investigated. Tritiated 7-BrMeBA-treated DNAs exposed to the enzyme were found to sustain single-strand nicks in proportion to the amount of hydrocarbon bound while untreated DNA remained substantially intact. The action of the endonuclease appeared to result in an increase in the biological activity of DNA containing hydrocarbon residues when this was assayed in the hcr^? mutant.