Lesion specificity in the base excision repair enzyme hNeil1: Modeling and dynamics studies

Base excision repair (BER) is the major pathway employed to excise oxidized DNA lesions. Human Neil1, a versatile glycosylase in the BER pathway, repairs a diverse array of oxidative lesions; however, the most prevalent, 8-oxo-7,8-dihydroguanine (8-oxoG), is only weakly excised. The structural origin of hNeill's ability to repair a variety of lesions but not 8-oxoG is a model system for connecting enzyme structure and lesion-recognition specificity. To elucidate structural properties determining hNeill's substrate specificities, we have investigated it in complex with two pairs of representative well-repaired substrates: the R- and S-spiroiminodihydantoin (Sp) stereoisomers, nonplanar further oxidation products of guanine, and the 5R,6S- and 5S,6R-thymine glycol (Tg) stereoisomers, the most prevalent oxidative lesions of thymine. We also investigate the poorly repaired 8-oxoG. We employed molecular modeling and 10 ns molecular dynamics (MD) simulations. The results of our investigations provide structural explanations for the ability of hNeill to excise a variety of oxidative lesions: they possess common chemical features, namely, a pyrimidine-like ring and shared hydrogen bond donor-acceptor properties, which allow the lesions to fit well in the binding pocket, which is somewhat flexible. However, the planar 8-oxoG is not as well accommodated in the shallow and comparatively cramped recognition pocket; it has fewer hydrogen bonding interactions with the enzyme and a solvent exposed six-membered ring, consistent with its poor repair susceptibility by this enzyme.