Bursts of reproduction can create genetic structure in frequently recombining bacterial population

In many bacterial species, strong genetic structure is present, where individuals are clustered into genetically distinct groupings within the species. However, high rates of homologous recombination have also been observed in many of these species, high enough that simple models of evolution predict that such genetic structure should be eliminated. One proposed resolution to this contradiction is the presence of recurrent bursts of reproduction caused by rapid adaptation or microepidemics. We investigate this hypothesis using coalescent simulations with recombination, focusing on the distribution of pairwise genetic distances. We show that bursty reproduction can indeed create genetic structure even when recombination is so frequent that all structure would be eliminated in the absence of bursts. However, we find that this may require some fine-tuning, as it is only possible when there is a burst of reproduction that is sufficiently large and recent in the population's history. In addition, we find that for other statistics beyond the pairwise distribution, the simplest model of bursty reproduction does not produce distributions similar to those observed in nature. Interestingly, genetic structure from bursts of reproduction can appear among pairs of samples which do not share any clonally inherited genes, a feature which cannot be observed in populations whose structure is just a consequence of limited recombination.