Nitrogen mustards such as mechlorethamine have previously been shown to covalently cross-link DNA through the N7 position of the two guanine bases of a d[GXC].d[GYC] duplex sequence, a so-called 1,3 G-G-cross-link, when X-Y = C-G or T-A. Here, we report the formation of a new mechlorethamine cross-link with the d[GXC].d[GYC] fragment when X-Y is a C-C mismatch pair. Mechlorethamine cross-links this fragment preferentially between the two mismatched cytosine bases, rather than between the guanine bases. The cross-link also forms when one or both of the guanine bases of the d[GCC].d[GCC] fragment are replaced by N7-deazaguanine, and, more generally, forms with any C-C mismatch, regardless of the flanking base pairs. Piperidine cleavage of the cross-link species containing the d[GCC].d[GCC] sequence gives DNA fragments consistent with alkylation at the mismatched cytosine bases. We also provide evidence that the cross-link reaction occurs between the N3 atoms of the two cytosine bases by showing that the formation of the C-C cross-link is pH dependent for both mechlorethamine and chlorambucil. Dimethyl sulfate (DMS) probing of the cross-linked d[GCC].d[GCC] fragment showed that the major groove of the guanine adjacent to the C-C mismatch is still accessible to DMS. In contrast, the known minor groove binder Hoechst 33258 inhibits the cross-link formation with a C-C mismatch pair flanked by A-T base pairs. These results suggest that the C-C mismatch is cross-linked by mechlorethamine in the minor groove. Since C-C pairs may be involved in unusual secondary structures formed by the trinucleotide repeat sequence d[CCG]n, and associated with triplet repeat expansion diseases, mechlorethamine may serve as a useful probe for these structures.