posted on 2019-07-18, 15:11authored byEli Naydenova, Sven Roßbach, Christian Ochsenfeld
Uracil DNA glycosylase
catalyzes the N-glycosidic
bond cleavage of uracil, thereby initiating the base excision repair
mechanism for this DNA lesion. Here we employ hybrid quantum mechanics/molecular
mechanics calculations to investigate the exact mechanism of the nucleophile
attack and the role of the conserved His148 residue. Our calculations
suggest that the C1′–N1 bond dissociation proceeds by
a migration of the electrophilic sugar in the direction of the water
nucleophile, resulting in a planar, oxocarbenium-like transition state.
The subsequent nucleophile addition and proton transfer to a nearby
base occur without a barrier. We assign the role of a proton acceptor
to His148 and elucidate why mutations of this residue curtail the
enzymatic activity but do not fully suppress it.