DNA-mediated charge transport for DNA repair

Fluorescent analogs of adenine that selectively oxidize guanine were used to investigate photoinduced electron transfer through the DNA pi-stack as a function of reactant stacking and energetics. Small variations in these factors led to profound changes in the kinetics and distance dependences of DNA-mediated electron-transfer reactions. Values of beta, a parameter reflecting the dependence of electron transfer on distance, ranged from 0.1 to 1.0 per angstrom. Strong stacking interactions result in the fastest electron-transfer kinetics. Electrons are thus transported preferentially through an intrastrand rather than interstrand pathway. Reactant energetics also modulate the distance dependence of DNA-mediated charge transport. These studies may resolve the range of disparate results previously reported, and paradigms must now be developed to describe these properties of the DNA pi-stack, which can range from insulator- to "wire"-like.

The possibility has been considered for almost forty years that the DNA double helix, which contains a pi-stacked array of heterocyclic base pairs, could be a suitable medium for the migration of charge over long molecular distances. This notion of high charge mobility is a critical consideration with respect to DNA damage. We have previously found that the DNA double helix can serve as a molecular bridge for photo-induced electron transfer between metallointercalators, with fast rates (> or = 10(10)s-1) and with quenching over a long distance (>40 A). Here we use a metallointercalator to introduce a photoexcited hole into the DNA pi-stack at a specific site in order to evaluate oxidative damage to DNA from a distance. Oligomeric DNA duplexes were prepared with a rhodium intercalator covalently attached to one end and separated spatially from 5'-GG-3' doublet sites of oxidation. Rhodium-induced photo-oxidation occurs specifically at the 5'-G in the 5'-GG-3' doublets and is observed up to 37 A away from the site of rhodium intercalation. We find that the yield of oxidative damage depends sensitively upon oxidation potential and pi-stacking, but not on distance. These results demonstrate directly that oxidative damage to DNA may be promoted from a remote site as a result of hole migration through the DNA pi-stack.