Mechanism of Action of Fotemustine, a New Chloroethylnitrosourea Anticancer Agent: Evidence for the Formation of Two DNA-Reactive Intermediates Contributing to Cytotoxicity

Abstract

Methyl excision repair deficient human tumor cells (Mer^-) were found to be hypersusceptible to killing by the antimelanoma agent fotemustine (FM) implicating alkylation of O⁶ guanine as the major contributor to toxicity. Preincubation of the drug in aqueous solution for 5 min resulted in an immediate reduction in cytotoxicity (35−50%), in vitro DNA alkylation (31%), and DNA interstrand cross-linking (40%) followed by a second reaction with considerably slower kinetics. Electrospray ionisation mass spectrometry (ESI-MS) showed that in aqueous solution FM rearranged rapidly to form either a metastable tautomer or decomposed to form a highly reactive diazohydroxide (t_1/2 < 2 min). These results suggest the presence of two DNA-reactive species relevant to biological activity. Coincubation of ellagic acid (an inhibitor of O⁶-guanine alkylation) with FM inhibited in vitro ISC, suggesting that the O⁶-chloroethyl lesion is the predominant cause of the cross-link. On the basis of these findings, we propose that FM breaks down to form a short-lived intermediate, 2-chloroethyldiazohydroxide, which rapidly generates O⁶-guanine lesions responsible for the drug's initial activity and a long lived iminol tautomer responsible for the remaining O⁶ guanine alkylation and cytotoxicity.