Structural and functional analyses of STM14_5441-STM14_5442: A potential mechanism for persister formation against aminoglycosides

IF 15.8 1区医学 Q1 PHARMACOLOGY & PHARMACY Drug Resistance Updates Pub Date : 2025-01-29 DOI:10.1016/j.drup.2025.101210

Hyun-Jong Eun , Seok-Won Jang , Ju-Hyun Park , Jooyeon Lee , Ki-Young Lee , Eun-Jin Lee , Bong-Jin Lee

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引用次数: 0

Abstract

Aims

The ability to eliminate bacterial persister cells is still a medical challenge that has yet to be overcome. These cells represent a unique subpopulation within bacterial communities and are characterized by a reduced susceptibility to antibiotics with growth retardation. In this study, we investigated the molecular basis of persister formation in Salmonella Typhimurium 14028 s under aminoglycoside stress.

Methods

We analyzed the crystal structure of the STM14_5441–STM14_5442 complex, which belongs to the type II toxin-antitoxin system, and identified key ribosome-binding residues in STM14_5441. Changes in the antibiotic susceptibility of Salmonella caused by the loss of the ribosome-binding property of STM14_5441 were assessed. We conducted intracellular ATP assays under aminoglycoside stress and RNA-seq analysis following STM14_5441 induction.

Results

Our studies demonstrated the critical role of STM14_5441 in the formation of persister cells in Salmonella, particularly those under aminoglycoside stress. We observed that a loss of ribosome binding in STM14_5441 resulted in increased antibiotic susceptibility. Additionally, intracellular ATP assays revealed increased ATP levels in STM14_5441 induced group, and RNA-seq analysis identified several genes that play a role in this phenomenon.

Conclusions

The present data suggest that persister forms under aminoglycoside stress through the following mechanisms: i) inhibition of membrane hyperpolarization by impeding F₁Fo ATP synthase activity and ii) enhanced poststress recovery by ATP storage and increased protein synthesis capacity. Based on this suggestion, we reannotated the STM14_5441-STM14_5442 TA pair as the ResTA (RNA cleavage-induced energy storage toxin-antitoxin) system. Furthermore, new insights into the function of TA systems may lay the groundwork for developing novel strategies to target bacterial persister cells, thereby preventing the accelerated emergence of antibiotic resistance in bacterial populations.

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来源期刊

Drug Resistance Updates 医学-药学

CiteScore

26.20

自引率

11.90%

发文量

审稿时长

29 days

期刊介绍： Drug Resistance Updates serves as a platform for publishing original research, commentary, and expert reviews on significant advancements in drug resistance related to infectious diseases and cancer. It encompasses diverse disciplines such as molecular biology, biochemistry, cell biology, pharmacology, microbiology, preclinical therapeutics, oncology, and clinical medicine. The journal addresses both basic research and clinical aspects of drug resistance, providing insights into novel drugs and strategies to overcome resistance. Original research articles are welcomed, and review articles are authored by leaders in the field by invitation. Articles are written by leaders in the field, in response to an invitation from the Editors, and are peer-reviewed prior to publication. Articles are clear, readable, and up-to-date, suitable for a multidisciplinary readership and include schematic diagrams and other illustrations conveying the major points of the article. The goal is to highlight recent areas of growth and put them in perspective. *Expert reviews in clinical and basic drug resistance research in oncology and infectious disease *Describes emerging technologies and therapies, particularly those that overcome drug resistance *Emphasises common themes in microbial and cancer research