Honda M, Park J, Pugh RA, Ha T, Spies M
Single-molecule analysis reveals differential effect of ssDNA-binding proteins on DNA translocation by XPD helicase. [Journal Article, Research Support, N.I.H., Extramural, Research Support, U.S. Gov't, Non-P.H.S.]
Mol Cell 2009 Sep 11; 35(5):694-703.
An encounter between a DNA-translocating enzyme and a DNA-bound protein must occur frequently in the cell, but little is known about its outcome. Here we developed a multicolor single-molecule fluorescence approach to simultaneously monitor single-stranded DNA (ssDNA) translocation by a helicase and the fate of another protein bound to the same DNA. Distance-dependent fluorescence quenching by the iron-sulfur cluster of the archaeal XPD (Rad3) helicase was used as a calibrated proximity signal. Despite the similar equilibrium DNA-binding properties, the two cognate ssDNA-binding proteins RPA1 and RPA2 differentially affected XPD translocation. RPA1 competed with XPD for ssDNA access. In contrast, RPA2 did not interfere with XPD-ssDNA binding but markedly slowed down XPD translocation. Mechanistic models of bypassing DNA-bound proteins by the Rad3 family helicases and their biological implications are discussed.
More from this journalRelated subjects (MeSH) |
