INTERMOLECULAR DISINTEGRATION AND INTRAMOLECULAR STRAND TRANSFER ACTIVITIES OF WILD-TYPE AND MUTANT HIV-1 INTEGRASE

We report the activities of HIV integrase protein on a novel DNA substrate, consisting of a pair of gapped duplex molecules. Integrase catalyzed an intermolecular disintegration reaction that requires positioning of a pair of the gapped duplexes in a configuration that resembles the integration intermediate. However, the major reaction resulted from an intramolecular reaction involving a single gapped duplex, giving rise to a hairpin. Surprisingly, a deletion mutant of integrase that lacks both the amino and carboxyl terminal regions still catalyzed the intermolecular disintegration reaction, but supported only a very low level of the intramolecular reaction. The central core region of integrase is therefore sufficient to both bind the gapped duplex DNA and juxtapose a pair of such molecules through protein-protein interactions. We suggest that the branched DNA structures of the previously reported disintegration substrate, and the intermolecular disintegration substrate described here, assist in stabilizing protein-protein interactions that otherwise require the amino and carboxyl terminal regions of integrase.