IDENTIFICATION OF THE MAJOR LESION FROM THE REACTION OF AN ACRIDINE-TARGETED ANILINE MUSTARD WITH DNA AS AN ADENINE N1 ADDUCT

DNA adducts of two acridine-linked aniline half-mustards have been isolated and identified. The compound where the half-mustard is attached to the DNA-targeting acridine moiety by a short linker chain alkylates both double- and single-stranded DNA exclusively at guanine N7, as do the majority of known aromatic and aliphatic nitrogen mustards. The longer-chain analogue, also containing a more reactive half-mustard, shows a strikingly different pattern, alkylating double-stranded DNA to yield primarily (>90 %) the adenine N1 adduct, together with <10% of the adenine N3 adduct and only trace amounts of the guanine N7 adduct. In the presence of MgCl2 (which is known not to inhibit the interaction of drugs at minor groove sites), the adenine N3 adduct is the major product. The latter compound is the first known aniline mustard (and apparently the first known alkylating agent of any type) to preferentially alkylate adenine at the N1 position in duplex DNA. These results are consistent with previous work [Prakash et al. (1990) Biochemistry 29, 9799-9807], which showed that the preferred site of DNA alkylation by the corresponding long-chain acridine-linked aniline bis-mustards in general was at major groove sites of adenines and identifies the major site of alkylation as adenine N1 and not N7. This selectivity for adenine N1 alkylation is suggested to result from a preference for the acridine mustard side chain of these compounds to project into the major groove following intercalation of the acridine, coupled with structural distortion of the DNA helix to make the N1 positions of adenines adjacent to the intercalation sites more accessible.