Polymyxin B lethality requires energy-dependent outer membrane disruption.

IF 19.4 1区生物学 Q1 MICROBIOLOGY

Nature Microbiology Pub Date : 2025-09-29 DOI:10.1038/s41564-025-02133-1

Carolina Borrelli, Edward J A Douglas, Sophia M A Riley, Aikaterini Ellas Lemonidi, Gerald Larrouy-Maumus, Wen-Jung Lu, Boyan B Bonev, Andrew M Edwards, Bart W Hoogenboom

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Abstract

Polymyxin antibiotics target lipopolysaccharides (LPSs) in both membranes of the bacterial cell envelope, leading to bacterial killing through a poorly defined mechanism. Here we demonstrate that metabolic activity is essential for the lethality of clinically relevant doses of polymyxin B (PmB) and leverage this insight to determine its mode of action. PmB killed exponential-phase Escherichia coli but did not eliminate stationary-phase cells unless a carbon source was available. Antibiotic lethality correlated with surface protrusions visible by atomic force microscopy and LPS loss from the outer membrane via processes that required LPS synthesis and transport but that were blocked by the MCR-1 polymyxin resistance determinant. While energy-dependent outer-membrane disruption was not directly lethal, it facilitated PmB access to the inner membrane, which the antibiotic permeabilized in an energy-independent manner, leading to cell death. This work reveals how metabolic inactivity confers tolerance of an important, membrane-targeting antibiotic.

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多粘菌素B的致死率需要能量依赖性外膜破坏。

多粘菌素抗生素靶向细菌细胞膜上的脂多糖（lps），通过一种尚不明确的机制导致细菌死亡。在这里，我们证明了代谢活性对临床相关剂量的多粘菌素B （PmB）的致死率至关重要，并利用这一见解来确定其作用模式。PmB杀死指数相大肠杆菌，但不能消除固定相细胞，除非有碳源可用。抗生素致死率与原子力显微镜下可见的表面突起和外膜上脂多糖的损失相关，这些过程需要脂多糖的合成和运输，但被MCR-1多粘菌素耐药决定因素阻断。虽然能量依赖的外膜破坏不是直接致命的，但它促进了PmB进入内膜，抗生素以能量独立的方式渗透内膜，导致细胞死亡。这项工作揭示了代谢不活动如何赋予一种重要的膜靶向抗生素的耐受性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Nature Microbiology Immunology and Microbiology-Microbiology

CiteScore

44.40

自引率

1.10%

发文量

226

期刊介绍： Nature Microbiology aims to cover a comprehensive range of topics related to microorganisms. This includes: Evolution: The journal is interested in exploring the evolutionary aspects of microorganisms. This may include research on their genetic diversity, adaptation, and speciation over time. Physiology and cell biology: Nature Microbiology seeks to understand the functions and characteristics of microorganisms at the cellular and physiological levels. This may involve studying their metabolism, growth patterns, and cellular processes. Interactions: The journal focuses on the interactions microorganisms have with each other, as well as their interactions with hosts or the environment. This encompasses investigations into microbial communities, symbiotic relationships, and microbial responses to different environments. Societal significance: Nature Microbiology recognizes the societal impact of microorganisms and welcomes studies that explore their practical applications. This may include research on microbial diseases, biotechnology, or environmental remediation. In summary, Nature Microbiology is interested in research related to the evolution, physiology and cell biology of microorganisms, their interactions, and their societal relevance.