1. Structure of a Synaptic γδ Resolvase Tetramer Covalently Linked to Two Cleaved DNAs
- Author
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Gary J. Sarkis, Weikai Li, Satwik Kamtekar, Nigel D. F. Grindley, Yong Xiong, and Thomas A. Steitz
- Subjects
Models, Molecular ,Tn3 transposon ,Stereochemistry ,Dimer ,Biology ,Crystallography, X-Ray ,Cleavage (embryo) ,Protein Structure, Secondary ,chemistry.chemical_compound ,Tetramer ,Catalytic Domain ,Recombinase ,Computer Simulation ,Site-specific recombination ,Protein Structure, Quaternary ,Recombination, Genetic ,Binding Sites ,Multidisciplinary ,DNA ,Protein Structure, Tertiary ,Crystallography ,Amino Acid Substitution ,chemistry ,Duplex (building) ,Mutation ,Transposon Resolvases ,Dimerization - Abstract
The structure of a synaptic intermediate of the site-specific recombinase γδ resolvase covalently linked through Ser 10 to two cleaved duplex DNAs has been determined at 3.4 angstrom resolution. This resolvase, activated for recombination by mutations, forms a tetramer whose structure is substantially changed from that of a presynaptic complex between dimeric resolvase and the cleavage site DNA. Because the two cleaved DNA duplexes that are to be recombined lie on opposite sides of the core tetramer, large movements of both protein and DNA are required to achieve strand exchange. The two dimers linked to the DNAs that are to be recombined are held together by a flat interface. This may allow a 180° rotation of one dimer relative to the other in order to reposition the DNA duplexes for strand exchange.
- Published
- 2005