Confinement inhibits surficial attachment and induces collective behaviors in bacterial colonies

TL;DR

This study investigates how confinement to two dimensions affects bacterial colony behaviors, revealing that confinement inhibits attachment, induces motility, and promotes diverse collective phenomena relevant to bacterial colonization.

Contribution

It introduces novel imaging and analysis methods to show how confinement alters bacterial collective behaviors, including motility and structural organization, independent of material or medium.

Findings

Confinement inhibits permanent bacterial attachment.

Confinement induces twitching motility and collective motion.

Confinement leads to formation of ordered 3D structures.

Abstract

Bacterial colonies are a well-known example of living active matter, exhibiting collective behaviors such as nematic alignment and collective motion that play an important role in the spread of microbial infections. While the underlying mechanics of these behaviors have been described in model systems, many open questions remain about how microbial self-organization adapts to the variety of different environments bacteria encounter in natural and clinical settings. Here, using novel imaging and computational analysis techniques, the effects of confinement to 2D on the collective behaviors of pathogenic bacteria are described. Biofilm-forming Pseudomonas aeruginosa are grown on different substrates, either open to the surrounding fluid or confined to a single monolayer between two surfaces. Orientational ordering in the colony, cell morphologies, and trajectories are measured using single-cell segmentation and tracking. Surprisingly, confinement inhibits permanent attachment and induces twitching motility, giving rise to multiple coexisting collective behaviors. This effect is shown to be independent of the confining material and the presence of liquid medium. The nematic alignment and degree of correlation in the cells' trajectories determines how effectively bacteria can invade the space between two surfaces and the 3D structure of the colony after several days. Confinement causes the formation of dynamic cell layers driven by collective motion as well as collective verticalization leading to the formation of densely packed crystalline structures exhibiting long-range order. These results demonstrate the remarkable breadth of collective behaviors exhibited by bacteria in different environments, which must be considered to better understand bacterial colonization of surfaces.