Abstract
The site-specific recombination pathway by which the bacteriophage lambda chromosome is excised from its Escherichia coli host chromosome is a tightly regulated, highly directional, multistep reaction that is executed by a series of multiprotein complexes. Until now, it has been difficult to study the individual steps of such reactions in the context of the entire pathway. Using single-molecule light microscopy, we have examined this process from start to finish. Stable bent-DNA complexes containing integrase and the accessory proteins IHF (integration host factor) and Xis form rapidly on attL and attR recombination partners, and synapsis of partner complexes follows rapidly after their formation. Integrase-mediated DNA cleavage before or immediately after synapsis is required to stabilize the synaptic assemblies. Those complexes that synapsed (approximately 50% of the total) yield recombinant product with a remarkable approximately 100% efficiency. The rate-limiting step of excision occurs after synapsis, but closely precedes or is concomitant with the appearance of a stable Holliday junction. Our kinetic analysis shows that directionality of this recombination reaction is conferred by the irreversibility of multiple reaction steps.