Single-molecule analysis reveals the molecular bearing mechanism of DNA strand exchange by a serine recombinase.

Structural and topological data suggest that serine site-specific DNA recombinases exchange duplex DNAs by rigid-body relative rotation of the two halves of the synapse, mediated by a flat protein-protein interaction surface. We present evidence for this rotational motion for a simple serine recombinase, the Bxb1 phage integrase, from a single-DNA-based supercoil-release assay that allows us to follow crossover site cleavage, rotation, religation, and product release in real time. We have also used a two-DNA braiding-relaxation experiment to observe the effect of synapse rotation in reactions on two long molecules. Relaxation and unbraiding are rapid (averaging 54 and 70 turns/s, respectively) and complete, with no discernible pauses. Nevertheless, the molecular friction associated with rotation is larger than that of type-I topoisomerases in a similar assay. Surprisingly we find that the synapse can stay rotationally "open" for many minutes.