A dynamic fluid landscape mediates the spread of bacteria

TL;DR

This study reveals how the physical environment, specifically fluid pools created by yeast, enhances bacterial motility and spread, emphasizing the importance of environmental dynamics in microbial interactions.

Contribution

It demonstrates that physical factors like fluid pools around yeast cells significantly influence bacterial motility and spreading, a novel insight into microbial ecology.

Findings

Yeast presence increases bacterial spread on substratum.

Fluid pools around yeast facilitate bacterial motility.

Physical environment dynamics affect bacterial spreading patterns.

Abstract

Microbial interactions regulate their spread and survival in competitive environments. It is not clear if the physical parameters of the environment regulate the outcome of these interactions. In this work, we show that the opportunistic pathogen Pseudomonas aeruginosa occupies a larger area on the substratum in the presence of yeast such as Cryptococcus neoformans , than without it. At the microscopic level, bacterial cells show an enhanced activity in the vicinity of yeast cells. We observe this behaviour even when the live yeast cells are replaced with heat-killed cells or with spherical glass beads of similar morphology, which suggests that the observed behaviour is not specific to the biology of microbes. Upon careful investigation, we find that a fluid pool is formed around yeast cells which facilitates the swimming of the flagellated P. aeruginosa , causing their enhanced motility. Using mathematical modeling we demonstrate how this local enhancement of bacterial motility leads to the enhanced spread observed at the level of the plate. We find that the dynamics of the fluid landscape around the bacteria, mediated by the growing yeast lawn, affects the spreading. For instance, when the yeast lawn grows faster, a bacterial colony prefers a lower initial loading of yeast cells for optimum enhancement in the spread. We confirm our predictions using Candida albicans and C. neoformans, at different initial compositions. In summary, our work shows the importance of considering the dynamically changing physical environment while studying bacterial motility in complex environments.