Dynamics of pattern formation and emergence of swarming in C. elegans

Abstract

Many animals in their natural habitat exhibit collective motion and form complex patterns to tackle environmental difficulties. Several physical and biological factors, such as animal motility, population densities, and chemical cues, play significant roles in this process. However, very little is known about how sensory information interplays with all these factors and controls the dynamics of collective response and pattern formation. Here, we use a model organism, Caenorhabditis elegans, to study the direct relation between oxygen sensing, pattern formation, and the emergence of swarming in active worm aggregates. We find that when thousands of animals gather on food, bacteria-mediated decrease in oxygen levels slowed down the animals and triggers motility-induced phase separation. Three coupled factors bacterial accumulation, aerotaxis, and population density act together and control the dynamics of pattern formation. Through several intermediate stages, aggregates converge to a large scale swarming phase and collectively move across the bacterial lawn. Additionally, our theoretical model captures behavioral differences resulting from the genetic variations and oxygen sensitivity. Altogether, our study provides many physical insights and a new platform for investigating the complex relationship between neural sensitivity, collective dynamics, and pattern formation.