AI Article Synopsis
- Base flipping is a crucial mechanism used by enzymes like uracil DNA glycosylase (UDG) to access and remove uracil bases from DNA, which are usually hidden in the DNA structure.
- Previous research indicated that this process starts with the DNA undergoing slight movements before strong interactions with uracil occur later in the reaction.
- The study revealed that UDG has a significant preference for recognizing uracil when it is paired with a modified adenine that doesn't form standard hydrogen bonds, suggesting that both the lack of hydrogen bonding and increased flexibility of the DNA help facilitate the base flipping process.
Article Abstract
Base flipping is a highly conserved strategy used by enzymes to gain catalytic access to DNA bases that would otherwise be sequestered in the duplex structure. A classic example is the DNA repair enzyme uracil DNA glycosylase (UDG) which recognizes and excises unwanted uracil bases from DNA using a flipping mechanism. Previous work has suggested that enzymatic base flipping begins with dynamic breathing motions of the enzyme-bound DNA substrate, and then, only very late during the reaction trajectory do strong specific interactions with the extrahelical uracil occur. Here we report that UDG kinetically and thermodynamically prefers substrate sites where the uracil is paired with an unnatural adenine analogue that lacks any Watson-Crick hydrogen-bonding groups. The magnitude of the preference is a striking 43000-fold as compared to an adenine analogue that forms three H-bonds. Transient kinetic and fluorescence measurements suggest that preferential recognition of uracil in the context of a series of incrementally destabilized base pairs arises from two distinct effects: weak or absent hydrogen bonding, which thermodynamically assists extrusion, and, most importantly, increased flexibility of the site which facilitates DNA bending during base flipping. A coupled, stepwise reaction coordinate is implicated in which DNA bending precedes base pair rupture and flipping.
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