📝 SummarXiv

Abstract

Bacteria are often required to navigate across confined spaces to reach desired destinations in biological and environmental systems, allowing critical functions in host-microbe symbiosis, infection, drug delivery, soil ecology, and soil bioremediation. While the canonical run-and-tumble motility is effective in finding targets under confinement, it may not represent the most ideal strategy due to the continuous monitoring of environmental cues and stochastic recorrection of their paths. Here, we show that salt gradients can be exploited to improve the run-and-tumble motility of flagellated soil bacteria, Pseudomonas putida, by biasing the cells' motion toward salt. Salt gradients impact bacterial swimming by straightening their runs toward salt, which we attribute to diffusiophoresis acting asymmetrically around the cell. This action imposes an effective torque on the cell body that is strong enough to overcome Brownian rotation, thereby stabilizing the motion and guiding the cells toward salt with straighter runs. We further demonstrate that imposing salt gradients in the presence of toxic organic contaminants enhances their chemotactic dispersion toward the contaminants via diffusiophoresis, suggesting its potential utility in bioremediation. Our findings reveal a previously unrecognized mechanism by which salt gradients can bias bacterial motility, offering new opportunities to control microbial transport in complex environments.