MISMATCH-INDUCED SWITCH OF NEOCARZINOSTATIN ATTACK SITES IN THE DNA MINOR GROOVE

Based on the finding that the wobble G.T mismatch 5' to the C of AGC.GCT results in switching of the attack chemistry by neocarzinostatin chromophore (NCS-Chrom) on the deoxyribose moiety of C from C-1' to C-4' [Kappen, L. S. & Goldberg, I. H. (1992) Proc. Natl. Acad. Sci. U.S.A. 89, 6706-6710], a series of mismatches has been explored for their effect on the chemistry of damage at the T of AG T.ACT in oligodeoxynucleotides, a site at which 4'-chemistry ordinarily occurs. Placement of a G-T mispair 5' to the T results in a marked increase in 4'-chemistry, as measured by the formation of breaks with 3'-phosphoglycolate ends and abasic sites due to 4'-hydroxylation. Strikingly, 4'-chemistry is induced at the T on the complementary strand, a site ordinarily restricted to 5'-chemistry. Substitution of dioxygen by the radiation sensitizer misonidazole exerts a pronounced effect on the partitioning of the 4'-chemistry in favor of the 3'-phosphoglycolate product. Both stable T-G and unstable T.C mismatches at the attack site itself are associated with marked inhibition of damage at this site. Whereas placement of the relatively stable G.A mismatch on the 5'-side of the T residue (AGT) results in substantial inhibition of damage at the T without shifting of chemistry, the same mismatch at the 3'-side of the attack site decreases damage only slightly but is associated with the appearance of significant 1'-chemistry. By contrast, no shift in chemistry is found with bleomycin, which attacks at C-4'. These findings provide further support for the role of minor groove microstructure in determining the chemical mechanisms of DNA damage and underscore the usefulness of NCS-Chrom as a probe of DNA microheterogeneity.