Solution structure studies of the cobalt complex of a bleomycin functional model bound to d(CGCAATTGCG)2 by two-dimensional nuclear magnetic resonance methods and restrained molecular dynamics simulation.

The interaction between the cobalt(III) complex of a bleomycin functional model (AMPHIS-NET) and the oligonucleotide d(CGCAATTGCG)2 and the structural features of the 1:1 ligand-DNA complex have been determined by high-resolution two-dimensional nuclear magnetic resonance methods and restrained molecular dynamics calculations. The intermolecular nuclear Overhauser effect (NOE) cross-peaks between ligand protons and the DNA minor groove protons suggest that the cobalt(III) complex of AMPHIS-NET binds in the minor groove of DNA at the central AATT site. The NOE connectivities also clearly indicate that the H8 pyridine proton and the H2 imidazole proton in the metal-binding domain interact with the H4' sugar proton of C19 and the H4' sugar proton of A5, respectively, which defines a structure where the metal binding moiety of Co(III).AMPHIS-NET participates in binding to the DNA and extends into the region two base pairs beyond the central AATT site in the minor groove. This binding model is in accord with the consistently observed nondiffusion DNA cleavage in locations two to three residues beyond the end of AT-rich binding sites induced by the corresponding iron(II) complexes of AMPHIS-NET and other AMPHIS-lexitropsin hybrids of the bleomycin functional model compounds.