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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. 

Abstract DNA in cells is organized in negatively supercoiled loops. The resulting torsional and bending strain allows DNA to adopt a surprisingly wide variety of 3-D shapes. This interplay between negative supercoiling, looping, and shape influences how DNA is stored, replicated, transcribed, repaired, and likely every other aspect of DNA activity. To understand the consequences of negative supercoiling and curvature on the hydrodynamic properties of DNA, we submitted 336 bp and 672 bp DNA minicircles to analytical ultracentrifugation (AUC). We found that the diffusion coefficient, sedimentation coefficient, and the DNA hydrodynamic radius strongly depended on circularity, loop length, and degree of negative supercoiling. Because AUC cannot ascertain shape beyond degree of non-globularity, we applied linear elasticity theory to predict DNA shapes, and combined these with hydrodynamic calculations to interpret the AUC data, with reasonable agreement between theory and experiment. These complementary approaches, together with earlier electron cryotomography data, provide a framework for understanding and predicting the effects of supercoiling on the shape and hydrodynamic properties of DNA. 

Altered DNA dynamics at lesion sites are implicated in how DNA repair proteins pause and identify damage within genomic DNA. We examined DNA dynamics in the context of damage recognition by Rad4 (yeast ortholog of XPC), which recognizes diverse lesions from environmental mutagens and initiates nucleotide excision repair. Previous studies with a cytosine-analog FRET pair placed on either side of 3 base-pair (bp) mismatched sites – recognized specifically by Rad4 in vitro – unveiled severely deformed DNA even without Rad4 (Chakraborty et al. (2018) Nucleic Acid Res. 46: 1240-1255). Here, using laser T-jump, we revealed the timescales of these spontaneous deformations. 3-bp AT-rich nonspecific sites, whether matched or mismatched, exhibited conformational dynamics primarily within the T-jump observation window (~20 µs – <100 ms), albeit with some amplitude in unresolved (<20 µs) kinetics. The amplitudes of the “missing” fast kinetics increased dramatically for mismatched specific sites, which were further distinguished by additional “missing” amplitude in slow (>100 ms) kinetics at elevated temperatures. We posit that the rapid (µs-ms) fluctuations help stall a diffusing protein at AT-rich/damaged sites and that the >100-ms kinetics reflect a propensity for specific DNA to adopt unwound/bent conformations that may resemble Rad4-bound structures. These studies provide compelling evidence for unusual DNA dynamics and deformability that likely govern how Rad4 senses DNA damage.