Crossing Over Between Regions of Limited Homology in Escherichia coli: RecA-Dependent and RecA-Independent Pathways

Crossing Over Between Regions of Limited Homology in Escherichia coli: RecA-Dependent and RecA-Independent Pathways

Susan T. Lovett^a, Rebecca L. Hurley^a, Vincent A. Sutera, Jr.^a, Rachel H. Aubuchon^a, and Maria A. Lebedeva^a
^a Rosenstiel Basic Medical Sciences Research Center and the Department of Biology, Brandeis University, Waltham, Massachusetts 02454-9110

Corresponding author: Susan T. Lovett, Brandeis University, Waltham, MA 02454-9110., lovett{at}brandeis.edu (E-mail)

Communicating editor: L. S. SYMINGTON

We have developed an assay for intermolecular crossing overbetween circular plasmids carrying variable amounts of homology.Screens of Escherichia coli mutants demonstrated that knownrecombination functions can only partially account for the observedrecombination. Recombination rates increased three to four ordersof magnitude as homology rose from 25 to 411 bp. Loss of recAblocked most recombination; however, RecA-independent crossingover predominated at 25 bp and could be detected at all homologylengths. Products of recA-independent recombination were reciprocalin nature. This suggests that RecA-independent recombinationmay involve a true break-and-join mechanism, but the geneticbasis for this mechanism remains unknown. RecA-dependent crossingover occurred primarily by the RecF pathway but considerablerecombination occurred independent of both RecF and RecBCD.In many respects, the genetic dependence of RecA-dependent crossingover resembled that reported for single-strand gap repair. Surprisingly,ruvC mutants, in both recA⁺ and recA mutant backgrounds, scoredas hyperrecombinational. This may occur because RuvC preferentiallyresolves Holliday junction intermediates, critical to both RecA-dependentand RecA-independent mechanisms, to the noncrossover configuration.Levels of crossing over were increased by defects in DnaB helicaseand by oxidative damage, showing that damaged DNA or stalledreplication can initiate genetic recombination.

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