Genetic mixing and demixing on expanding spherical frontiers

Abstract

ABSTRACTGenetic fluctuation during range expansion is a key process driving evolution. When a bacterial population is expanding on a 2D surface, random fluctuations in the growth of the pioneers at the front line cause a strong de-mixing of genotypes. Even when there is no selective advantage, sectors of low genetic diversity are formed. Experimental studies of range expansions in surface-attached colonies of fluorescently-labeled microorganisms have contributed significantly to our understanding of fundamental evolutionary dynamics. However, experimental studies on genetic fluctuations in 3D range expansions have been sparse, despite their importance for tumour or biofilm development. We encapsulated populations of two fluorescentEscherichia colistrains in inoculation droplets (volumes ∼0.1 nl). The confined ensemble of cells grew when embedded in a hydrogel – with nutrients – and developed 3D colonies with well-defined, sector-like regions. Using a confocal laser scanning microscope (CLSM), we imaged the development of 3D colonies and the emergence of sectors. We characterised how cell concentration in the inoculation droplet controls sectors, growth rate, and the transition from branched colonies to quasi-spherical colonies. We further analysed how sectors on the surface change over time. We complement these experimental results with a modified 3D Eden growth model. The model in 3D spherical growth predicts a phase, where sectors are merging, followed by a steady increase (constant rate), and the experimentally analysed sectors were consistent with this prediction. Ergo, our results demonstrate qualitative differences between radial (2D) and spherical (3D) range expansions and their importance in gene fixation processes.