Cells must continuously repair inevitable DNA damage while avoiding the deleterious consequences of imprecise repair. Distinction between legitimate and illegitimate repair processes is thought to be achieved in part through differential recognition and processing of specific noncanonical DNA structures, although the mechanistic basis of discrimination remains poorly defined. Here, we show that Escherichia coli RecQ, a central DNA recombination and repair enzyme, exhibits differential processing of DNA substrates based on their geometry and structure. Through single-molecule and ensemble biophysical experiments, we elucidate how the conserved domain architecture of RecQ supports geometry-dependent shuttling and directed processing of recombination-intermediate [displacement loop (D-loop)] substrates. Our study shows that these activities together suppress illegitimate recombination in vivo, whereas unregulated duplex unwinding is detrimental for recombination precision. Based on these results, we propose a mechanism through which RecQ helicases achieve recombination precision and efficiency.RecQ | helicase | magnetic tweezers | single molecule | DNA unwinding
BLM, one of the human RecQ helicases, plays a fundamental role in homologous recombination-based error-free DNA repair pathways, which require its translocation and DNA unwinding activities. Although translocation is essential in vivo during DNA repair processes and it provides a framework for more complex activities of helicases, including strand separation and nucleoprotein displacement, its mechanism has not been resolved for any human DNA helicase. Here, we present a quantitative model for the translocation of a monomeric form of BLM along ssDNA. We show that BLM performs translocation at a low adenosine triphosphate (ATP) coupling ratio (1 ATP consumed/1 nucleotide traveled) and moderate processivity (with a mean number of 50 nucleotides traveled in a single run). We also show that the rate-limiting step of the translocation cycle is a transition between two ADP-bound enzyme states. Via opening of the helicase core, this structural change may drive the stepping of BLM along the DNA track by a directed inchworm mechanism. The data also support the conclusion that BLM performs double-stranded DNA unwinding by fully active duplex destabilization.
The conserved switch 1 loop of P-loop NTPases is implicated as a central element that transmits information between the nucleotide-binding pocket and the binding site of the partner proteins. Recent structural studies have identified two states of switch 1 in G-proteins and myosin, but their role in the transduction mechanism has yet to be clarified. Single tryptophan residues were introduced into the switch 1 region of myosin II motor domain and studied by rapid reaction methods. We found that in the presence of MgADP, two states of switch 1 exist in dynamic equilibrium. Actin binding shifts the equilibrium towards one of the MgADP states, whereas ATP strongly favors the other. In the light of electron cryo-microscopic and X-ray crystallographic results, these findings lead to a specific structural model in which the equilibrium constant between the two states of switch 1 is coupled to the strength of the actin-myosin interaction. This has implications for the enzymatic mechanism of G-proteins and possibly P-loop NTPases in general.
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