The rates of formation and disappearance of benzo[a]pyrene (B[a]P) DNA-adducts were analyzed in the epidermis of SENCAR mice over a 21-day time course. Mice were treated topically with 200 nmol/mouse of [3H]B[a]P at various times prior to sacrifice. The formation and disappearance of total adducts as well as individual adducts was determined and in addition, the rate of DNA turnover was monitored concurrently so that adduct disappearance could be expressed as a function of epidermal cell turnover. Under these experimental conditions, covalent binding of B[a]P to epidermal DNA reached a peak 24 h after treatment. Interestingly, between 24-48 h after application of the hydrocarbon there was a very rapid drop in the level of bound B[a]P to value approximately 50% of the maximum level at 24 h. Thereafter, the level of bound B[a]P disappeared at a much slower rate. In dual-label experiments, where the epidermal DNA was pre-labeled with [14C]thymidine, [3H]B[a]P DNA-adduct disappearance between 24-48 h was clearly more rapid than could be explained on the basis of epidermal DNA turnover. By 72 h and beyond, however, [3H]B[a]P DNA-adduct disappearance approximately paralleled DNA turnover. Examination of the rate of formation and disappearance of individual B[a]P DNA-adducts (nine individual adducts) suggested that some deoxyadenosine adducts were removed more rapidly than deoxyguanosine adducts. The results indicate that at least some epidermal cells have the capacity to repair B[a]P DNA-adducts. The data are discussed in relation to the process of tumor initiation in mouse skin.