Highly mismatched molecules resembling recombination intermediates efficiently transform mismatch repair proficient Escherichia coli.

The ability of related DNAs to undergo recombination decreases with increased sequence divergence. Mismatch repair has been proposed to be a key factor in preventing homeologous recombination; however, the contribution of mismatch repair is not universal. Although mismatch repair has been proposed to act by preventing strand exchange and/or inactivating multiply mismatched heteroduplexes, there has been no systematic study to determine at what step(s) in recombination mismatch repair acts in vivo. Since heteroduplex is a commonly proposed intermediate in many models of recombination, we have investigated the consequences of mismatch repair on plasmids that are multiply mismatched in heteroduplex structures that are similar to those that might arise during recombination. Plasmids containing multiply mismatched regions were transformed into wild-type and Mut+ Escherichia coli mutants. There was only a 30-40% reduction in transformation of Mut+ as compared to mutS and mutL strains for DNAs containing an 18% mismatched heteroduplex. The products obtained from mutS hosts differed from those obtained from Mut+ hosts in that there were many more colonies containing mixtures of two plasmids, due to survival of both strands of the heteroduplex. There were nearly 10 times more recombinants obtained from the mutS as compared to the wild-type host. Based on these results and those from other studies with E. coli and yeast, we propose that the prevention of recombination between highly diverged DNAs may be at a step earlier than heteroduplex formation.