The biochemical reaction of a site-specific recombinase such as Hin invertase or gammadelta resolvase starts with binding of the recombinase to its recombination site and cleavage of the DNA in the center of the site. This is followed by strand exchange and finally ligation of the ends of the recombined strands. Previous biochemical studies have shown that Hin invertase and gammadelta resolvase cannot proceed beyond DNA cleavage in the absence of Mg++ ion, indicating that these recombinases require Mg++ ion in the strand exchange process. We have observed that the intercalating agent, ethidium bromide (2 microM), does not interfere with DNA cleavage, but slows strand exchange in a concentration-dependent manner. Levels of Mg++ ion below 5 mM also slow strand exchange substantially. We infer that random intercalation of ethidium bromide inhibits unwinding of the double helix at the recombination site in the negatively supercoiled DNA and propose that Mg+ may be required for Hin to deform the secondary structure of B-DNA prior to strand exchange.