Single-molecule study of RuvAB-mediated Holliday-junction migration

AUTOR(ES)

Dawid, A.

FONTE

National Academy of Sciences

RESUMO

Branch migration of Holliday junctions is an important step of genetic recombination and DNA repair. In Escherichia coli, this process is driven by the RuvAB complex acting as a molecular motor. Using magnetic tweezers, we studied the RuvAB-directed migration of individual Holliday junctions formed between two ≈6-kb DNA molecules of identical sequence, and we measured the migration rate at 37°C and 1 mM ATP. We directly demonstrate that RuvAB is a highly processive DNA motor protein that is able to drive continuous and unidirectional branch migration of Holliday junctions at a well defined average speed over several kilobases through homologous sequences. We observed directional inversions of the migration at the DNA molecule boundaries leading to forth-and-back migration of the branch point and allowing us to measure the migration rate in the presence of negative or positive loads. The average migration rate at zero load was found to be ≈43 bp/sec. Furthermore, the load dependence of the migration rate is small, within the force range of –3.4 pN (hindering force) to +3.4 pN (assisting force).

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