Breakdown of Vibrio Cholerae Biofilm Architecture Induced by Antibiotics Disrupts Community Barrier Function

Overview

Journal Nat Microbiol

Specialties Microbiology
Parasitology

Date 2019 Oct 30

PMID 31659297

Citations 35

Authors

Francisco Diaz-Pascual

Raimo Hartmann

Martin Lempp

Lucia Vidakovic

Boya Song

Hannah Jeckel

Kai M Thormann

Fitnat H Yildiz

Jorn Dunkel

Hannes Link

Carey D Nadell

Knut Drescher

Affiliations

Soon will be listed here.

Abstract

Bacterial cells in nature are frequently exposed to changes in their chemical environment. The response mechanisms of isolated cells to such stimuli have been investigated in great detail. By contrast, little is known about the emergent multicellular responses to environmental changes, such as antibiotic exposure, which may hold the key to understanding the structure and functions of the most common type of bacterial communities: biofilms. Here, by monitoring all individual cells in Vibrio cholerae biofilms during exposure to antibiotics that are commonly administered for cholera infections, we found that translational inhibitors cause strong effects on cell size and shape, as well as biofilm architectural properties. We identified that single-cell-level responses result from the metabolic consequences of inhibition of protein synthesis and that the community-level responses result from an interplay of matrix composition, matrix dissociation and mechanical interactions between cells. We further observed that the antibiotic-induced changes in biofilm architecture have substantial effects on biofilm population dynamics and community assembly by enabling invasion of biofilms by bacteriophages and intruder cells of different species. These mechanistic causes and ecological consequences of biofilm exposure to antibiotics are an important step towards understanding collective bacterial responses to environmental changes, with implications for the effects of antimicrobial therapy on the ecological succession of biofilm communities.

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