Abstract
A reciprocal strand exchange between two DNA helices generates the crossed-strand intermediate, or Holliday junction, which is common to many pathways of homologous and site-specific recombination. The Int family of recombinases are unique in their ability to both make and resolve Holliday junctions. Previous experiments utilizing 'synthetic' att site Holliday junctions to study the mechanisms associated with the cleavage, transfer and ligation of DNA strands have been confined to studying reciprocal strand exchanges (a pair of temporally overlapping strand cleavages). To circumvent this limitation, we have designed synthetic suicide Holliday junctions that make it possible to monitor individual DNA strand cleavage events. These substrates contain a pre-existing nick in the vicinity of the Int binding site; when Int introduces a second nick into these substrates, the 5'OH nucleophile required for ligation (in either the forward or reverse reaction) is lost by diffusion, thus trapping the covalent protein-DNA intermediate. The results indicate that resolution (involving two partner Ints) is stimulated by additional 'cross-core' Ints as a result of enhanced cleavage rates, and not as a result of enhanced co-ordination of cleavage. Several models for the role of the 'cross-core' Ints during resolution are discussed, as well as the usefulness of these substrates for studying additional aspects of the Holliday junction resolution reaction.