Phase transitions during fruiting body formation in Myxococcus xanthus

TL;DR

This study investigates the phase transitions in Myxococcus xanthus during fruiting body formation, revealing a shift from flocking to stream formation driven by contact and timing, modeled as active liquid crystals.

Contribution

It introduces a high-resolution tracking approach and a liquid crystal model to describe the dynamic phase transitions in bacterial collective behavior.

Findings

Transition from flocking to streaming behavior.

Cell-contact and internal timing regulate phase change.

Active liquid crystal model explains development cycle.

Abstract

The formation of a collectively moving group benefits individuals within a population in a variety of ways such as ultra-sensitivity to perturbation, collective modes of feeding, and protection from environmental stress. While some collective groups use a single organizing principle, others can dynamically shift the behavior of the group by modifying the interaction rules at the individual level. The surface-dwelling bacterium Myxococcus xanthus forms dynamic collective groups both to feed on prey and to aggregate during times of starvation. The latter behavior, termed fruiting-body formation, involves a complex, coordinated series of density changes that ultimately lead to three-dimensional aggregates comprising hundreds of thousands of cells and spores. This multi-step developmental process most likely involves several different single-celled behaviors as the population condenses from a loose, two-dimensional sheet to a three-dimensional mound. Here, we use high-resolution microscopy and computer vision software to spatiotemporally track the motion of thousands of individuals during the initial stages of fruiting body formation. We find that a combination of cell-contact-mediated alignment and internal timing mechanisms drive a phase transition from exploratory flocking, in which cell groups move rapidly and coherently over long distances, to a reversal-mediated localization into streams, which act as slow-spreading, quasi-one-dimensional nematic fluids. These observations lead us to an active liquid crystal description of the myxobacterial development cycle.