Genetic Exchange Across a Species Boundary in the Archaeal Genus Ferroplasma

John M. Eppley^*^,1^,2, Gene W. Tyson^,1^,3, Wayne M. Getz and Jillian F. Banfield^,^,4

^* Department of Bioengineering, Department of Environmental Science, Policy and Management and Department of Earth and Planetary Sciences, University of California, Berkeley, California 94720

^⁴ Corresponding author: Department of Earth and Planetary Sciences, University of California, Berkeley, CA 94720.
E-mail: jill{at}eps.berkeley.edu

Speciation as the result of barriers to genetic exchange isthe foundation for the general biological species concept. However,the relevance of genetic exchange for defining microbial speciesis uncertain. In fact, the extent to which microbial populationscomprise discrete clusters of evolutionarily related organismsis generally unclear. Metagenomic data from an acidophilic microbialcommunity enabled a genomewide, comprehensive investigationof variation in individuals from two coexisting natural archaealpopulations. Individuals are clustered into species-like groupsin which cohesion appears to be maintained by homologous recombination.We quantified the dependence of recombination frequency on sequencesimilarity genomewide and found a decline in recombination withincreasing evolutionary distance. Both inter- and intralineagerecombination frequencies have a log-linear dependence on sequencedivergence. In the declining phase of interspecies genetic exchange,recombination events cluster near the origin of replicationand are localized by tRNAs and short regions of unusually highsequence similarity. The breakdown of genetic exchange withincreasing sequence divergence could contribute to, or explain,the establishment and preservation of the observed populationclusters in a manner consistent with the biological speciesconcept.

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ISSUE HIGHLIGHTS: Genetics 2007 177: NP. [Full Text]