Exploiting cooperative pathogen behaviour for enhanced antibiotic potency: A Trojan horse approach.

IF 2.6 4区生物学 Q3 MICROBIOLOGY

Microbiology-Sgm Pub Date : 2024-04-01 DOI:10.1099/mic.0.001454

Alper Mutlu, Emily J Vanderpool, Kendra P Rumbaugh, Stephen P Diggle, Ashleigh S Griffin

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引用次数: 0

Abstract

Antimicrobial resistance poses an escalating global threat, rendering traditional drug development approaches increasingly ineffective. Thus, novel alternatives to antibiotic-based therapies are needed. Exploiting pathogen cooperation as a strategy for combating resistant infections has been proposed but lacks experimental validation. Empirical findings demonstrate the successful invasion of cooperating populations by non-cooperating cheats, effectively reducing virulence in vitro and in vivo. The idea of harnessing cooperative behaviours for therapeutic benefit involves exploitation of the invasive capabilities of cheats to drive medically beneficial traits into infecting populations of cells. In this study, we employed Pseudomonas aeruginosa quorum sensing cheats to drive antibiotic sensitivity into both in vitro and in vivo resistant populations. We demonstrated the successful invasion of cheats, followed by increased antibiotic effectiveness against cheat-invaded populations, thereby establishing an experimental proof of principle for the potential application of the Trojan strategy in fighting resistant infections.

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利用病原体的合作行为提高抗生素效力：特洛伊木马方法

抗生素耐药性对全球构成的威胁不断升级，使得传统的药物开发方法越来越无效。因此，我们需要新的疗法来替代以抗生素为基础的疗法。有人提出利用病原体合作作为对抗耐药性感染的策略，但缺乏实验验证。实证研究结果表明，不合作的 "骗子 "会成功入侵合作的种群，从而有效降低体外和体内的致病力。利用合作行为达到治疗效果的想法涉及利用骗子的入侵能力，将对医学有益的特性引入感染细胞群。在这项研究中，我们利用铜绿假单胞菌的法定量感应作弊器将抗生素敏感性引入体外和体内耐药菌群。我们证明了骗子的成功入侵，以及随后对骗子入侵种群的抗生素有效性的提高，从而为特洛伊木马策略在抗耐药性感染中的潜在应用建立了实验性原理证明。

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

Microbiology-Sgm 生物-微生物学

CiteScore

4.60

自引率

7.10%

发文量

132

审稿时长

3.0 months

期刊介绍： We publish high-quality original research on bacteria, fungi, protists, archaea, algae, parasites and other microscopic life forms. Topics include but are not limited to: Antimicrobials and antimicrobial resistance Bacteriology and parasitology Biochemistry and biophysics Biofilms and biological systems Biotechnology and bioremediation Cell biology and signalling Chemical biology Cross-disciplinary work Ecology and environmental microbiology Food microbiology Genetics Host–microbe interactions Microbial methods and techniques Microscopy and imaging Omics, including genomics, proteomics and metabolomics Physiology and metabolism Systems biology and synthetic biology The microbiome.