The Maintenance of Sex in Bacteria Is Ensured by Its Potential to Reload Genes

Gergely J. Szöll $o$ si^*, Imre Derényi^*^,1 and Tibor Vellai

^* Department of Biological Physics and Department of Genetics, Eötvös University, H-1117 Budapest, Hungary

^¹ Corresponding author: Department of Biological Physics, Eötvös University, Pázmány P. stny. 1A, H-1117 Budapest, Hungary.
E-mail: derenyi{at}angel.elte.hu

Why sex is maintained in nature is a fundamental question inbiology. Natural genetic transformation (NGT) is a sexual processby which bacteria actively take up exogenous DNA and use itto replace homologous chromosomal sequences. As it has beendemonstrated, the role of NGT in repairing deleterious mutationsunder constant selection is insufficient for its survival, andthe lack of other viable explanations have left no alternativeexcept that DNA uptake provides nucleotides for food. Here wedevelop a novel simulation approach for the long-term dynamicsof genome organization (involving the loss and acquisition ofgenes) in a bacterial species consisting of a large number ofspatially distinct populations subject to independently fluctuatingecological conditions. Our results show that in the presenceof weak interpopulation migration NGT is able to subsist asa mechanism to reload locally lost, intermittently selectedgenes from the collective gene pool of the species through DNAuptake from migrants. Reloading genes and combining them withthose in locally adapted genomes allow individual cells to readaptfaster to environmental changes. The machinery of transformationsurvives under a wide range of model parameters readily encompassingreal-world biological conditions. These findings imply thatthe primary role of NGT is not to serve the cell with food,but to provide homologous sequences for restoring genes thathave disappeared from or become degraded in the local population.