Adaptations in Gut Bacteroidales Facilitate Stable Co-existence with Their Lytic Bacteriophages

Overview

Journal bioRxiv

Date 2024 Nov 28

PMID 39605433

Authors

Adrian Cortes-Martin

Colin Buttimer

Jessie L Maier

Ciara A Tobin

Lorraine A Draper

R Paul Ross

Manuel Kleiner

Colin Hill

Andrey N Shkoporov

Affiliations

Soon will be listed here.

Abstract

Background: Bacteriophages (phages) and bacteria within the gut microbiome persist in long-term stable coexistence. These interactions are driven by eco-evolutionary dynamics, where bacteria employ a variety of mechanisms to evade phage infection, while phages rely on counterstrategies to overcome these defences. Among the most abundant phages in the gut are the crAss-like phages that infect members of the Bacteroidales, in particular In this study, we explored some of the mechanisms enabling the co-existence of four phage-Bacteroidales host pairs using a multi-omics approach (transcriptomics, proteomics and metabolomics). These included three species paired with three crAss-like phages ( and ϕcrAss001, and ϕcrAss002, and an acapsular mutant of with DAC15), and paired with the siphovirus ϕPDS1.

Results: We show that phase variation of individual capsular polysaccharides (CPSs) is the primary mechanism promoting phage co-existence in Bacteroidales, but this is not the only strategy. Alternative resistance mechanisms, while potentially less efficient than CPS phase variation, can be activated to support bacterial survival by regulating gene expression and resulting in metabolic adaptations, particularly in amino acid degradation pathways. These mechanisms, also likely regulated by phase variation, enable bacterial populations to persist in the presence of phages, and An acapsular variant of demonstrated broader transcriptomic, proteomic, and metabolomic changes, supporting the involvement of additional resistance mechanisms beyond CPS variation.

Conclusions: This study advances our understanding of long-term phage-host interaction, offering insights into the long-term persistence of crAss-like phages and extending these observations to other phages, such as ϕPDS1. Knowledge of the complexities of phage-bacteria interactions is essential for designing effective phage therapies and improving human health through targeted microbiome interventions.

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