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Abstract Altered DNA dynamics at lesion sites are implicated in how DNA repair proteins sense damage within genomic DNA. Using laser temperature-jump (T-jump) spectroscopy combined with cytosine-analog Förster Resonance Energy Transfer (FRET) probes that sense local DNA conformations, we measured the intrinsic dynamics of DNA containing 3 base-pair mismatches recognized in vitro by Rad4 (yeast ortholog of XPC). Rad4/XPC recognizes diverse lesions from environmental mutagens and initiates nucleotide excision repair. T-jump measurements, together with a novel and rigorous comparison with equilibrium FRET, uncovered conformational dynamics spanning multiple timescales and revealed key differences between Rad4-specific and non-specific DNA. AT-rich non-specific sites (matched or mismatched) exhibited dynamics primarily within the T-jump observation window, albeit with some amplitude in ‘missing’ fast (<20 μs) kinetics. These fast-kinetics amplitudes were dramatically larger for specific sites (CCC/CCC and TTT/TTT), which also exhibited ‘missing’ slow (>50 ms) kinetics at elevated temperatures, unseen in non-specific sites. We posit that the rapid (μs–ms) intrinsic DNA fluctuations help stall a diffusing protein at AT-rich/damaged sites and that the >50-ms kinetics in specific DNA reflect a propensity to adopt unwound/bent conformations resembling Rad4-bound DNA structures. These studies provide compelling evidence for sequence/structure-dependent intrinsic DNA dynamics and deformability that likely govern damage sensing by Rad4. 

Xeroderma pigmentosum C (XPC) is a key initiator in the global genome nucleotide excision repair pathway in mammalian cells. Inherited mutations in the XPC gene can cause xeroderma pigmentosum (XP) cancer predisposition syndrome that dramatically increases the susceptibility to sunlight-induced cancers. Various genetic variants and mutations of the protein have been reported in cancer databases and literature. The current lack of a high-resolution 3-D structure of human XPC makes it difficult to assess the structural impact of the mutations/genetic variations. Using the available high-resolution crystal structure of its yeast ortholog, Rad4, we built a homology model of human XPC protein and compared it with a model generated by AlphaFold. The two models are largely consistent with each other in the structured domains. We have also assessed the degree of conservation for each residue using 966 sequences of XPC orthologs. Our structure- and sequence conservation-based assessments largely agree with the variant’s impact on the protein’s structural stability, computed by FoldX and SDM. Known XP missense mutations such as Y585C, W690S, and C771Y are consistently predicted to destabilize the protein’s structure. Our analyses also reveal several highly conserved hydrophobic regions that are surface-exposed, which may indicate novel intermolecular interfaces that are yet to be characterized.