Abstract
Eukaryotic DNA polymerase β (Pol β) plays an important role in cellular DNA repair, as it fills short gaps in dsDNA that result from removal of damaged bases. Since defects in DNA repair may lead to cancer and genetic instabilities, Pol β has been extensively studied, especially its mechanisms for substrate binding and a fidelity-related conformational change referred to as "fingers closing." Here, we applied single-molecule FRET to measure distance changes associated with DNA binding and prechemistry fingers movement of human Pol β. First, using a doubly labeled DNA construct, we show that Pol β bends the gapped DNA substrate less than indicated by previously reported crystal structures. Second, using acceptor-labeled Pol β and donor-labeled DNA, we visualized dynamic fingers closing in single Pol β-DNA complexes upon addition of complementary nucleotides and derived rates of conformational changes. We further found that, while incorrect nucleotides are quickly rejected, they nonetheless stabilize the polymerase-DNA complex, suggesting that Pol β, when bound to a lesion, has a strong commitment to nucleotide incorporation and thus repair. In summary, the observation and quantification of fingers movement in human Pol β reported here provide new insights into the delicate mechanisms of prechemistry nucleotide selection.
Highlights
DNA repair is pivotal for maintaining genome integrity [1]
Our distance measurements on the bending sensor, revealed that DNA bending upon polymerase binding occurs to a smaller extent than predicted by various structures resolved with X-ray crystallography
The inter-fluorophore distances that we calculated for the fingers conformational change are consistent with crystal structures 1BPX and 1BPY, implying that it is the flexible positioning of the downstream strand that determines the bend
Summary
DNA repair is pivotal for maintaining genome integrity [1]. Among the most common damages of DNA are base lesions, in which the chemical structure of a single base has been altered [2, 3]. The labeling position on the DNA was chosen such that open and closed conformations of the fingers exhibit different FRET efficiencies (E) when Pol b is bound to the surface-immobilized DNA substrate.
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