Maintaining the integrity of the genome is fundamental to living organisms. To this end, nature developed several mechanisms to find and promptly repair DNA lesions. Among them, base excision repair (BER) enzymes evolved to efficiently carry out this task. Notably, the mechanisms allowing these proteins to search for, detect, and fix DNA damage on a biologically relevant time scale still remain partially unclear. By taking MutY, a BER enzyme implied in the repair of the 8-oxoguanine-adenine mismatches, as a model system, we shed some light on the repair mechanism through a theoretical-computational approach. First, we estimated the effect of the oxidation state of the MutY iron-sulfur cluster on the protein-DNA binding. Then, the redox thermodynamics of both the protein cluster and DNA nucleobases are calculated. Finally, the charge migration kinetics along the double strand bound to the enzyme has been evaluated. The rationalization of our results indicates that the search for DNA lesions is essentially dictated by the redox chemistry of the species involved, i.e., the iron-sulfur redox cofactor and the DNA bound to the enzyme.
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