Recombination directionality factor gp3 binds ϕC31 integrase via the zinc domain, potentially affecting the trajectory of the coiled-coil motif.

To establish a prophage state, the genomic DNA of temperate bacteriophages normally becomes integrated into the genome of their host bacterium by integrase-mediated, site-specific DNA recombination. Serine integrases catalyse a single crossover between an attachment site in the host (attB) and a phage attachment site (attP) on the circularized phage genome to generate the integrated prophage DNA flanked by recombinant attachment sites, attL and attR. Exiting the prophage state and entry into the lytic growth cycle requires an additional phage-encoded protein, the recombination directionality factor or RDF, to mediate recombination between attL and attR and excision of the phage genome. The RDF is known to bind integrase and switch its activity from integration (attP x attB) to excision (attL x attR) but its precise mechanism is unclear. Here, we identify amino acid residues in the RDF, gp3, encoded by the Streptomyces phage ϕC31 and within the ϕC31 integrase itself that affect the gp3:Int interaction. We show that residue substitutions in integrase that reduce gp3 binding adversely affect both excision and integration reactions. The mutant integrase phenotypes are consistent with a model in which the RDF binds to a hinge region at the base of the coiled-coil motif in ϕC31 integrase.

A phage protein that binds φC31 integrase to switch its directionality.

The serine integrase, Int, from the Streptomyces phage φC31 mediates the integration and excision of the phage genome into and out of the host chromosome. Integrases usually require a recombination directionality factor (RDF) or Xis to control integration and excision and, as φC31 Int only mediates integration in the absence of other phage proteins, we sought to identify a φC31 RDF. Here we report that the φC31 early protein, gp3 activated attL x attR recombination and inhibited attP x attB recombination. Gp3 binds to Int in solution and when Int is bound to the attachment sites. Kinetic analysis of the excision reaction suggested that gp3 modifies the interactions between Int and the substrates to form an active recombinase. In the presence of gp3, Int assembles an excision synaptic complex and the accumulation of the integration complex is inhibited. The structure of the excision synaptic complex, like that of the hyperactive mutant of Int, IntE449K, appeared to be biased towards one that favours the production of correctly joined products. The functional properties of φC31 gp3 resemble those of the evolutionarily unrelated RDF from phage Bxb1, suggesting that these two RDFs have arisen through convergent evolution.