The protein that activates site-specific excision of the HP1 genome from the Hemophilus influenzae chromosome, HP1 Cox, was purified. Native Cox consists of four 8.9-kDa protomers. Tetrameric Cox self-associates to octamers; the apparent dissociation constant was 8 microM protomer, suggesting that under reaction conditions Cox is largely tetrameric. Cox binding sites consist of two direct repeats of the consensus motif 5'-GGTMAWWWWA; one Cox tetramer binds to each motif. Cox binding interfered with the interaction of HP1 integrase with one of its binding sites, IBS5. This competition is central to directional control, as shown by studies on mutated sites. Both Cox binding sites were necessary for Cox to fully inhibit integration and activate excision, although Cox continued to affect recombination when the single binding site proximal to IBS5 remained intact. Eliminating the IBS5 site completely prevented integration but greatly enhanced excision. Excisive recombination continued to require Cox even when IBS5 was inactivated. Cox must therefore play a positive role in assembling the nucleoprotein complexes producing excisive recombination, by inducing the formation of a critical conformation in those complexes.