Abstract
XPD helicase is a DNA unwinding enzyme involved in multiple cellular processes. As part of TFIIH, XPD opens a repair bubble in DNA for access by proteins in the nucleotide excision repair pathway. XPD uses the energy from ATP hydrolysis to translocate in the 5-prime to 3-prime direction on one strand of duplex DNA, displacing the opposite strand in the process. We used magnetic tweezers assays to measure the double-stranded DNA (dsDNA) unwinding and single-stranded DNA (ssDNA) translocation activities of human XPD by itself. In our experimental setup, hXPD exhibits low unwinding processivity of ~14 bp and slow overall unwinding rate of ~0.3 bp/s. Individual unwinding and translocation events were composed of fast and slow runs and pauses. Analysis of these events gave similar mean run sizes and rates for unwinding and translocation, suggesting that unwinding is a reflection of translocation. The analysis also revealed that hXPD spent similar time stalling and unwinding. hXPD translocated on ssDNA at a similar overall rate as that of unwinding, pointing to an active helicase. However, we observed modest effects of DNA sequence on stalling and unwinding initiation position. Considering the slow unwinding rate, high probability of base pair separation at the ssDNA/dsDNA fork, and the observed DNA sequence dependences, we propose that hXPD is most likely a partially active helicase. Our results provide detailed information on the basal activity of hXPD which enhances our mechanistic understanding of hXPD activity.
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