Abstract
Several proteins have been shown to catalyze branch migration (BM) of the Holliday junction, a key intermediate in DNA repair and recombination. Here, using joint molecules made by human RAD51 or Escherichia coli RecA, we find that the polarity of the displaced ssDNA strand of the joint molecules defines the polarity of BM of RAD54, BLM, RECQ1, and RuvAB. Our results demonstrate that RAD54, BLM, and RECQ1 promote BM preferentially in the 3'→5' direction, whereas RuvAB drives it in the 5'→3' direction relative to the displaced ssDNA strand. Our data indicate that the helicase activity of BM proteins does not play a role in the heterology bypass. Thus, RAD54 that lacks helicase activity is more efficient in DNA heterology bypass than BLM or REQ1 helicases. Furthermore, we demonstrate that the BLM helicase and BM activities require different protein stoichiometries, indicating that different complexes, monomers and multimers, respectively, are responsible for these two activities. These results define BM as a mechanistically distinct activity of DNA translocating proteins, which may serve an important function in DNA repair and recombination.
Highlights
Several proteins catalyze branch migration (BM) of the Holliday junction
Using joint molecules made by human RAD51 or Escherichia coli RecA, we find that the polarity of the displaced ssDNA strand of the joint molecules defines the polarity of BM of RAD54, BLM, RECQ1, and RuvAB
RAD54 and RuvAB Show Opposite Polarities of Branch Migration—Here, we examined the polarity of BM promoted by human RAD54 using plasmid-length DNA joint molecules (JMs) that contain displaced ssDNA strand with either 3Ј35Ј (3Ј-JMs) or 5Ј33Ј (5Ј-JMs) polarity (Fig. 1A)
Summary
Several proteins catalyze branch migration (BM) of the Holliday junction. Results: RAD54 is a robust BM protein capable of bypassing extensive regions of DNA heterology. Our results demonstrate that RAD54, BLM, and RECQ1 promote BM, both four-stranded and three-stranded, preferentially in the 3Ј35Ј direction, whereas RuvAB drives the reactions in the 5Ј33Ј direction relative to the displaced ssDNA strand of JMs. Our data indicate that the helicase activity of BM proteins does not play a role in the heterology bypass during BM of Holliday junctions. We demonstrate that the BLM helicase and BM activities require different protein stoichiometries and reaction conditions, indicating that different protein complexes, monomers and multimers, respectively, are responsible for these two activities These results define BM and DNA helicase as two mechanistically distinct activities of DNA translocating proteins and suggest that these two activities may serve different functions in DNA repair and recombination
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