The single-stranded DNA-binding protein replication protein A (RPA) interacts with several human RecQ DNA helicases that have important roles in maintaining genomic stability; however, the mechanism for RPA stimulation of DNA unwinding is not well understood. To map regions of Werner syndrome helicase (WRN) that interact with RPA, yeast two-hybrid studies, WRN affinity pull-down experiments and enzyme-linked immunosorbent assays with purified recombinant WRN protein fragments were performed. The results indicated that WRN has two RPA binding sites, a high affinity N-terminal site, and a lower affinity C-terminal site. Based on results from mapping studies, we sought to determine if the WRN N-terminal region harboring the high affinity RPA interaction site was important for RPA stimulation of WRN helicase activity. To accomplish this, we tested a catalytically active WRN helicase domain fragment (WRN H-R ) that lacked the N-terminal RPA interaction site for its ability to unwind long DNA duplex substrates, which the wild-type enzyme can efficiently unwind only in the presence of RPA. WRN H-R helicase activity was significantly reduced on RPAdependent partial duplex substrates compared with full-length WRN despite the presence of RPA. These results clearly demonstrate that, although WRN H-R had comparable helicase activity to full-length WRN on short duplex substrates, its ability to unwind RPAdependent WRN helicase substrates was significantly impaired. Similarly, a Bloom syndrome helicase (BLM) domain fragment, BLM 642-1290 , that lacked its N-terminal RPA interaction site also unwound short DNA duplex substrates similar to wild-type BLM, but was severely compromised in its ability to unwind long DNA substrates that full-length BLM helicase could unwind in the presence of RPA. These results suggest that the physical interaction between RPA and WRN or BLM helicases plays an important role in the mechanism for RPA stimulation of helicase-catalyzed DNA unwinding.Within the last decade, several genetic disorders with premature aging and/or cancer have been identified in which a gene member of the RecQ helicase family is mutated (1, 2). RecQ helicases share a centrally located domain of ϳ450 residues that contains the seven conserved helicase motifs (for review, see Ref.3). The founding member of the RecQ family, Escherichia coli RecQ helicase, has been extensively studied biochemically and has been genetically implicated in DNA recombination. A single yeast RecQ helicase, Sgs1 or Rqh1, is found in the budding yeast Saccharomyces cerevisiae and fission yeast Schizosaccharomyces pombe, respectively, and these helicases are thought to be important in the cellular response to DNA-damaging agents and maintenance of genome stability. RecQ helicases have also been identified in a number of higher eukaryotes, including Xenopus laevis (focus forming activity 1 (FFA-1) 1 ), Drosophila melanogaster (DmBLM and DmRecQ5), and Caenorhabditis elegans (WRN-1, Ce-RCQ5, HIM-6, and RECQL/Q1). These helicases have proposed functions in ...
