Evidence for an adaptive DNA repair pathway in CHO and human skin fibroblast cell lines.

When Escherichia coli is chronically exposed to very low, nontoxic doses of a monofunctional alkylating agent (notably N-methyl-N'-nitro-nitrosoguanidine, MNNG), the adaptive DNA repair pathway is induced which enables the bacteria to resist the killing and mutagenic effects of further alkylation damage. Mutation resistance in adapted bacteria is achieved, at least partly, by a greatly increased capacity of the cells to eliminate the minor DNA alkylation product O6-methyl-guanine, which has been strongly implicated as premutagenic and precarcinogenic. We now show that the chronic treatment of a Chinese hamster ovary (CHO) and a SV40-transformed human skin fibroblast (GM637) cell line with non-toxic levels of MNNG renders the cells resistant to the induction of sister chromatid exchange (SCE) by further alkylation damage. CHO cells also become resistant to killing (GM637 cells have not yet been tested). Having ruled out explanations such as changes in cell cycle distribution, mutagen permeability and mutagen detoxification, we conclude that resistance is probably achieved by the cells becoming more efficient at repairing alkylation damage, analogous to the adaptive response of E. coli.