Horizontal Acquisition of Divergent Chromosomal DNA in Bacteria: Effects of Mutator Phenotypes

Horizontal Acquisition of Divergent Chromosomal DNA in Bacteria: Effects of Mutator Phenotypes

Jeffrey P. Townsend^a, Kaare M. Nielsen^a, Daniel S. Fisher^b, and Daniel L. Hartl^a
^a Department of Organismic and Evolutionary Biology, Harvard University, Cambridge, Massachusetts 02138
^b Department of Physics, Harvard University, Cambridge, Massachusetts 02138

Corresponding author: Jeffrey P. Townsend, 321 Koshland Hall, University of California, Berkeley, CA 94720., townsend{at}nature.berkeley.edu (E-mail)

Communicating editor: M. VEUILLE

We examine the potential beneficial effects of the expandedaccess to environmental DNA offered by mutators on the adaptivepotential of bacterial populations. Using parameters from publishedstudies of recombination in E. coli, we find that the presenceof mutators has the potential to greatly enhance bacterial populationadaptation when compared to populations without mutators. Inone specific example, for which three specific amino acid substitutionsare required for adaptation to occur in a 300-amino-acid protein,we found a 3500-fold increase in the rate of adaptation. Theprobability of a beneficial acquisition decreased if more aminoacid changes, or integration of longer DNA fragments, were requiredfor adaptation. The model also predicts that mutators are morelikely than nonmutator phenotypes to acquire genetic variabilityfrom a more diverged set of donor bacteria. Bacterial populationsharboring mutators in a sequence heterogeneous environment arepredicted to acquire most of their DNA conferring adaptationin the range of 13–30% divergence, whereas nonmutatorphenotypes become adapted after recombining with more homogeneoussequences of 7–21% divergence. We conclude that mutatorscan accelerate bacterial adaptation when desired genetic variabilityis present within DNA fragments of up to $~$ 30% divergence.

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