Enhanced DNA cross-link removal: the apparent mechanism of resistance in a clinically relevant melphalan-resistant human breast cancer cell line.

Resistance to the cytotoxic effects of alkylating agents is a major limitation to their clinical efficacy. Although a number of animal and human tumor cell models have been developed to study this problem, it has proven difficult to achieve very high levels of resistance to alkylating agents in vitro. This is consistent with the recent clinical evidence that alkylator resistance can be overcome by dose escalations of less than 10-fold. A number of mechanisms of alkylator resistance have been described, more than one of which may occur in the same model. This paper describes a human breast cancer cell subline selected for 3-fold resistance to melphalan and cross-resistant to other alkylators in which only one of the previously described mechanisms of resistance, enhanced removal of DNA interstrand cross-linking, is demonstrable. Northern blot analysis using the human incisional repair gene ERCC-1 cDNA demonstrated that this particular gene product is not the altered function in these cells, so the molecular characterization of the observed enhanced repair is pending. Because these cells are also cross-resistant to radiation and to adriamycin and epipodophyllotoxin, they may represent a clinically relevant model in which to examine the role of DNA repair of lesions resulting from alkylators and other cytotoxic agents.