Abstract
ABSTRACTDue to their universal presence and high sequence conservation, rRNA sequences are used widely in phylogenetics for inferring evolutionary relationships between microbes and in metagenomics for analyzing the composition of microbial communities. Most microbial genomes encode multiple copies of ribosomal RNA (rRNA) genes to supply cells with sufficient capacity for protein synthesis. These copies typically undergo concerted evolution that keeps their sequences identical, or nearly so, due to gene conversion, a type of intragenomic recombination that changes one copy of a homologous sequence to exactly match another. Widely varying rates of rRNA gene conversion have previously been estimated by comparative genomics methods and using genetic reporter assays. To more directly measure rates of rRNA intragenomic recombination, we sequenced the sevenEscherichia colirRNA operons in 15 lineages of cells that were evolved for ~13,750 generations with frequent single-cell bottlenecks that reduce the effects of selection. We identified 34 gene conversion events and estimate an overall rate of intragenomic recombination events between rRNA copies of 3.2 × 10−4per generation or 5.3 × 10−5per potential donor sequence. This rate varied only slightly from random expectations between different portions of the rRNA genes and between rRNA operons located at different locations in the genome. This accurate estimate of the rate of rRNA gene conversions fills a gap in our quantitative understanding of how ribosomal sequences and other multicopy elements diversify and homogenize during microbial genome evolution.
Publisher
Cold Spring Harbor Laboratory