Isolation and characterization of the Tn3 resolvase synaptic intermediate.

Abstract

We have isolated in quantitative yield the synaptic intermediate formed during site-specific recombination by Tn3 resolvase and characterized it by restriction endonuclease mapping, electron microscopy and topological methods. The intermediate accumulates at low reaction temperatures and is stabilized by crosslinking of the resolvase protomers with glutaraldehyde. The DNA-resolvase complex that maintains the structure of the intermediate (the synaptosome) is approximately 100 A in diameter, forms specifically at resolution (res) sites, and requires two res sites in a supercoiled DNA molecule. Resolvase bound to individual res sites protects approximately -0.5 supercoil per site from relaxation by a topoisomerase, whereas the formation of the synaptosome protects -3 supercoils and condenses the associated DNA to a supercoil density 2.5 times that of the non-complexed substrate. Although recombination requires two directly repeated res sites, both direct and inverted sites form synaptosomes. We conclude that the specificity of recombination is achieved by a three-stage recognition system: binding of resolvase to separate sites, formation of the synaptosome and determination of site orientation from within the complex.