Abstract: The complex between the rationally designed synthetic DNA cleaving agent netropsin-diazene and the double-stranded DNA oligomer 5'-CGCAAAGGC-3'.5'-GCCTTTTGCG-3' was characterized by two-dimensional NMR spectroscopy in solution. Photolysis of netropsin-diazene bound to DNA generates a trimethylenemethane diradical intermediate that induces single-strand breaks in the DNA. The pi-diyl trimethylenemethane based compounds are a new class of DNA nucleases. We tested the following design criteria: (i) binding of the diazene and subsequent reactive diyl to the DNA, (ii) sequence selectivity in the ligand binding and (iii) prevention of diyl dimerization. Sixteen NOE derived ligand-DNA distance restraints were used to obtain the energy minimized model of the complex. The ligand is bound to the minor groove of the oligomer with the diazene at the 5' end of the A-tract in the predominant conformation of the complex. This form of the complex exchanges with a minor conformation in which the ligand is in the opposite orientation. The DNA maintains a B-form structure. Netropsin-diazene has fulfilled all of the design criteria, binding to the DNA duplex studied in the minor groove of the central AAAA tract in a 1:1 mode, preventing diyl dimerization and other side reactions from occurring.

Space-filling model showing the DNA binding mode of the netropsin diazene. The DNA is magenta, netropsin red, diazene moiety cyan, diradical sites, yellow, and the nearby DNA H1', H4' and H5' atos that are potential targets for the radicals, green.