Enrichment and Elimination of mutY Mutators in Escherichia coli Populations

Enrichment and Elimination of mutY Mutators in Escherichia coli Populations

Lucinda Notley-McRobb^a, Shona Seeto^a, and Thomas Ferenci^a
^a School of Molecular and Microbial Biosciences, University of Sydney, Sydney, New South Wales 2006, Australia

Corresponding author: Thomas Ferenci, G08, University of Sydney, Sydney, NSW 2006, Australia., tferenci{at}mail.usyd.edu.au (E-mail)

Communicating editor: H. OCHMAN

The kinetics of mutator sweeps was followed in two independentpopulations of Escherichia coli grown for up to 350 generationsin glucose-limited continuous culture. A rapid elevation ofmutation rates was observed in both populations within 120–150generations, as was apparent from major increases in the proportionof the populations with unselected mutations in fhuA. The increasein mutation rates was due to sweeps by mutY mutators. In bothcultures, the enrichment of mutators resulted from hitchhikingwith identified beneficial mutations increasing fitness underglucose limitation; mutY hitchhiked with mgl mutations in oneculture and ptsG in the other. In both cases, mutators wereenriched to constitute close to 100% of the population beforea periodic selection event reduced the frequency of unselectedmutations and mutators in the cultures. The high proportionof mutators persisted for 150 generations in one populationbut began to be eliminated within 50 generations in the other.The persistence of mutator, as well as experimental data showingthat mutY bacteria were as fit as near-isogenic mutY⁺ bacteriain competition experiments, suggest that mutator load by deleteriousmutations did not explain the rapidly diminishing proportionof mutators in the populations. The nonmutators sweeping outmutators were also unlikely to have arisen by reversion or antimutatormutations; the mutY mutations were major deletions in each caseand the bacteria sweeping out mutators contained intact mutY.By following mgl allele frequencies in one population, we discoveredthat mutators were outcompeted by bacteria that had rare mglmutations previously as well as additional beneficial mutation(s).The pattern of appearance of mutY, but not its elimination,conforms to current models of mutator sweeps in bacterial populations.A mutator with a narrow mutational spectrum like mutY may belost if the requirement for beneficial mutations is for changesother than GC $->$ TA transversions. Alternatively, epistatic interactionsbetween mutator mutation and beneficial mutations need to bepostulated to explain mutator elimination.

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