Adaptive evolution of hybrid bacteria by horizontal gene transfer

Abstract: 9Horizontal gene transfer is an important factor in bacterial evolution that can act across 10 species boundaries. Yet, we know little about rate and genomic targets of cross-lineage 11 gene transfer, and about its effects on the recipient organism's physiology and fitness. 12Here, we address these questions in a parallel evolution experiment with two Bacillus 13 subtilis lineages of 7% sequence divergence. We observe rapid evolution of hybrid 14 organisms: gene transfer swaps ~12% of the core genome in just 2… Show more

“…Just natural selection acts on mutations and thereby shapes the observed patterns of substitutions, selection also undoubtedly strongly acts on recombination events and shapes the recombination patterns that we detect in the core genome alignments. Indeed, strong selection on horizontal transfer events between two B. subtilis strains was recently observed in a laboratory evolution experiment ( Power et al, 2020 ). However, it is currently not clear to what extent the differences in observed recombination rates are shaped mainly by natural selection, for example that due to epistatic interactions only recombinant segments from other strains with similar ‘ecotypes’ are not removed by purifying selection, as suggested by some previous works ( Shapiro et al, 2012 ; Cadillo-Quiroz et al, 2012 ), or that recombination rates may be set mostly by which lineages co-occur at the same geographical location.…”

“…Just natural selection acts on mutations and thereby shapes the observed patterns of substitutions, selection also undoubtedly strongly acts on recombination events and shapes the recombination patterns that we detect in the core genome alignments. Indeed, strong selection on horizontal transfer events between two B. subtilis strains was recently observed in a laboratory evolution experiment (Power et al, 2020). However, it is currently not clear to what extent the differences in observed recombination rates are shaped mainly by natural selection, e.g.…”

Whole genome phylogenies reflect the distributions of recombination rates for many bacterial species

“…Just natural selection acts on mutations and thereby shapes the observed patterns of substitutions, selection also undoubtedly strongly acts on recombination events and shapes the recombination patterns that we detect in the core genome alignments. Indeed, strong selection on horizontal transfer events between two B. subtilis strains was recently observed in a laboratory evolution experiment ( Power et al, 2020 ). However, it is currently not clear to what extent the differences in observed recombination rates are shaped mainly by natural selection, for example that due to epistatic interactions only recombinant segments from other strains with similar ‘ecotypes’ are not removed by purifying selection, as suggested by some previous works ( Shapiro et al, 2012 ; Cadillo-Quiroz et al, 2012 ), or that recombination rates may be set mostly by which lineages co-occur at the same geographical location.…”

“…Just natural selection acts on mutations and thereby shapes the observed patterns of substitutions, selection also undoubtedly strongly acts on recombination events and shapes the recombination patterns that we detect in the core genome alignments. Indeed, strong selection on horizontal transfer events between two B. subtilis strains was recently observed in a laboratory evolution experiment (Power et al, 2020). However, it is currently not clear to what extent the differences in observed recombination rates are shaped mainly by natural selection, e.g.…”

Whole genome phylogenies reflect the distributions of recombination rates for many bacterial species

“…Transformation allows bacteria to acquire adaptively useful genes, to operate a distributed gene pool, and to remove parasitic mobile genetic elements from their genomes (Carvalho et al, 2020;Croucher et al, 2016;Power et al, 2021). In pathogenic bacteria, natural transformation is important for the spread of virulence traits including capsule variation and antibiotic resistance (Chi et al, 2007;Croucher et al, 2011;Domingues et al, 2012;Griffith, 1928).…”

The DNA transporter ComEC has metal‐dependent nuclease activity that is important for natural transformation