Nonreplicating lambda phage DNA in homoimmune Escherichia coli lysogens provides a useful model system for study of processes that activate DNA for homologous recombination. We measured recombination by extracting phage DNA from infected cells, using it to transfect recA recipient cells, and scoring the frequency of recombinant infective centers. With unirradiated phage, recombinant frequencies were less than 0.1%. However, recombination could be increased over 300-fold by prior UV irradiation of the phages. The dependence of recombination on UvrA function varied greatly with UV dose. With phage irradiated to 20 J/m2, recombinant frequencies in repressed infections of uvr+ bacteria were one-fifth those in uvrA infections; with phages irradiated to 100 J/m2, frequencies in uvr+ infections were thirty times higher than in uvrA infections. Most UV-stimulated recombination in uvrA infections appeared to depend on the bacterial methyl-directed mismatch-repair system: frequencies were depressed 5-20-fold in uvrA bacteria also lacking MutH, MutL or MutS functions, and recombinant frequencies decreased with increasing GATC-adenine methylation of phage stocks. The biological activity of nonreplicating UV-irradiated phage DNA declined with time after infection of uvrA cells; this decline was photoproduct-dependent, more marked for undermethylated than overmethylated phage DNA, and depended on host MutHLS functions. In uvr+ bacteria, where the UvrABC system provided an alternative, apparently less efficient, route to recombinagenic DNA, UV-stimulated recombinant frequencies were about twice as high in mutH or mutLS as in mut+ cells, in agreement with hyper-rec mut effects previously described by others.
During infection of homoimmune Escherichia coli lysogens ("repressed infections"), undamaged nonreplicating lambda phage DNA circles undergo very little recombination. Prior UV irradiation of phages dramatically elevates recombinant frequencies, even in bacteria deficient in UvrABC-mediated excision repair. We previously reported that 80-90% of this UvrABC-independent recombination required MutHLS function and unmethylated d(GATC) sites, two hallmarks of methyl-directed mismatch repair. We now find that deficiencies in other mismatch-repair activities--UvrD helicase, exonuclease I, exonuclease VII, RecJ exonuclease--drastically reduce recombination. These effects of exonuclease deficiencies on recombination are greater than previously observed effects on mispair-provoked excision in vitro. This suggests that the exonucleases also play other roles in generation and processing of recombinagenic DNA structures. Even though dsDNA breaks are thought to be highly recombinagenic, 60% of intracellular UV-irradiated phage DNA extracted from bacteria in which recombination is low--UvrD-, ExoI-, ExoVII-, or Rec(J-)--displays (near-)blunt-ended dsDNA ends (RecBCD-sensitive when deproteinized). In contrast, only bacteria showing high recombination (Mut+ UvrD+ Exo+) generate single-stranded regions in nonreplicating UV-irradiated DNA. Both recF and recB recC mutations strikingly reduce recombination (almost as much as a recF recB recC triple mutation), suggesting critical requirements for both RecF and RecBCD activity. The mismatch repair system may thus process UV-irradiated DNA so as to initiate more than one recombination pathway.
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