Surface-mediated Bacteriophage Defense Incurs Fitness Tradeoffs for Interbacterial Antagonism

Overview

Journal EMBO J

Specialties Biotechnology
Molecular Biology

Date 2025 Mar 11

PMID 40065098

Authors

Chia-En Tsai

Feng-Qi Wang

Chih-Wen Yang

Ling-Li Yang

Thao Vp Nguyen

Yung-Chih Chen

Po-Yin Chen

Ing-Shouh Hwang

See-Yeun Ting

Affiliations

Soon will be listed here.

Abstract

Bacteria in polymicrobial habitats are constantly exposed to biotic threats from bacteriophages (or "phages"), antagonistic bacteria, and predatory eukaryotes. These antagonistic interactions play crucial roles in shaping the evolution and physiology of bacteria. To survive, bacteria have evolved mechanisms to protect themselves from such attacks, but the fitness costs of resisting one threat and rendering bacteria susceptible to others remain unappreciated. Here, we examined the fitness consequences of phage resistance in Salmonella enterica, revealing that phage-resistant variants exhibited significant fitness loss upon co-culture with competitor bacteria. These phage-resistant strains display varying degrees of lipopolysaccharide (LPS) deficiency and increased susceptibility to contact-dependent interbacterial antagonism, such as the type VI secretion system (T6SS). Utilizing mutational analyses and atomic force microscopy, we show that the long-modal length O-antigen of LPS serves as a protective barrier against T6SS-mediated intoxication. Notably, this competitive disadvantage can also be triggered independently by phages possessing LPS-targeting endoglycosidase in their tail spike proteins, which actively cleave the O-antigen upon infection. Our findings reveal two distinct mechanisms of phage-mediated LPS modifications that modulate interbacterial competition, shedding light on the dynamic microbial interplay within mixed populations.

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