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Autores principales: Zbinden, Matti, Huisman, Jana S., Blitvic, Natasha, Stocker, Roman, Słomka, Jonasz
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2410.07012
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author Zbinden, Matti
Huisman, Jana S.
Blitvic, Natasha
Stocker, Roman
Słomka, Jonasz
author_facet Zbinden, Matti
Huisman, Jana S.
Blitvic, Natasha
Stocker, Roman
Słomka, Jonasz
contents Conjugation accelerates bacterial evolution by enabling bacteria to acquire genes horizontally from their neighbors. Plasmid donors must physically encounter and connect with recipients to allow plasmid transfer, and different environments are characterized by vastly different encounter rates between cells, based on mechanisms ranging from simple diffusion to fluid flow. However, how the environment affects the conjugation rate by setting the encounter rate has been largely neglected, mostly because existing experimental setups do not allow direct control over cell encounters. Here, we describe the results of conjugation experiments in E. coli in which we systematically varied the magnitude of shear flow using a cone-and-plate rheometer to control the encounter rate. We discovered that the conjugation rate increases with shear until it peaks at an optimal shear rate (100 1/s), reaching a conjugation rate five-fold higher than the baseline set by diffusion-driven encounters. This optimum marks the transition from a regime in which shear promotes conjugation by increasing the rate of cell-cell encounters to a regime in which shear disrupts conjugation. Regions of high fluid shear are widespread in aquatic systems, in the gut of host organisms, and in soil, and our results indicate that these regions could be hotspots of bacterial conjugation in the environment.
format Preprint
id arxiv_https___arxiv_org_abs_2410_07012
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Fluid flow generates bacterial conjugation hotspots by increasing the rate of shear-driven cell-cell encounters
Zbinden, Matti
Huisman, Jana S.
Blitvic, Natasha
Stocker, Roman
Słomka, Jonasz
Biological Physics
Conjugation accelerates bacterial evolution by enabling bacteria to acquire genes horizontally from their neighbors. Plasmid donors must physically encounter and connect with recipients to allow plasmid transfer, and different environments are characterized by vastly different encounter rates between cells, based on mechanisms ranging from simple diffusion to fluid flow. However, how the environment affects the conjugation rate by setting the encounter rate has been largely neglected, mostly because existing experimental setups do not allow direct control over cell encounters. Here, we describe the results of conjugation experiments in E. coli in which we systematically varied the magnitude of shear flow using a cone-and-plate rheometer to control the encounter rate. We discovered that the conjugation rate increases with shear until it peaks at an optimal shear rate (100 1/s), reaching a conjugation rate five-fold higher than the baseline set by diffusion-driven encounters. This optimum marks the transition from a regime in which shear promotes conjugation by increasing the rate of cell-cell encounters to a regime in which shear disrupts conjugation. Regions of high fluid shear are widespread in aquatic systems, in the gut of host organisms, and in soil, and our results indicate that these regions could be hotspots of bacterial conjugation in the environment.
title Fluid flow generates bacterial conjugation hotspots by increasing the rate of shear-driven cell-cell encounters
topic Biological Physics
url https://arxiv.org/abs/2410.07012