Niclosamide nanoparticles as a novel adjuvant reverse colistin resistance via multiple mechanisms against multidrug-resistant Salmonella infections.

IF 3.8 2区生物学 Q2 MICROBIOLOGY

Microbiology spectrum Pub Date : 2025-10-20 DOI:10.1128/spectrum.02252-25

Kaifang Yi, Peiyi Liu, Mengyao Zhang, Qiange Liu, Mengjing Feng, Zibo Li, Dandan He, Li Yuan, Xiaoyuan Ma, Gongzheng Hu

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Abstract

The mobile colistin resistance (mcr) mechanism enables rapid horizontal transfer of resistance genes across food, animals, and humans, driving significant resistance in mcr-carrying bacteria. While numerous adjuvants can reverse colistin resistance, research on their dose-response relationships remains limited, and most suffer from poor solubility, low bioavailability, and safety issues, hindering clinical use. The dose-response analysis showed that niclosamide could achieve a high reversal efficiency within a relatively low concentration range. However, as the concentration of niclosamide increased, the ability to reverse colistin resistance remained unchanged, and the reversal efficiency gradually decreased. Mechanistic analyses reveal that its synergistic antibacterial effect with colistin involves disrupting bacterial membrane permeability, dissipating proton motive force, and inhibiting efflux pumps, leading to membrane damage, cytoplasmic leakage, ATP depletion, and accelerated reactive oxygen species-mediated oxidative damage, ultimately resulting in the death of bacterial cells. A niclosamide nanodelivery system (niclosamide-loaded mPEG-PLGA nanoparticles [NCL@mPEG-PLGA-NPs]) was developed to enhance bioavailability, significantly boosting colistin's efficacy against Salmonella in vitro and in vivo. The in-depth study of the dose-response relationship of adjuvants in reversing colistin resistance and the establishment of the niclosamide nanodrug delivery system will lay a scientific foundation for the clinical application of colistin adjuvants and the development of suitable drug delivery systems.

Importance: Colistin is used as a last resort for many infections caused by multidrug-resistant gram-negative bacteria, but colistin-resistant strains are on the rise. Studies have found that the combination of niclosamide and colistin exhibits significant synergistic antibacterial effects. Dose-response analysis shows that niclosamide has extremely high resistance reversal efficiency within a relatively low concentration range. The development of the new dosage form of NCL@mPEG-PLGA-NPs will lay a scientific foundation for the clinical application of colistin adjuvants and the development of drug delivery systems.

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奈洛沙胺纳米颗粒作为一种新型佐剂，通过多种机制逆转粘菌素耐药性，对抗多重耐药沙门氏菌感染。

移动粘菌素耐药性（mcr）机制使耐药基因能够在食物、动物和人类之间快速水平转移，从而在携带mcr的细菌中产生显著的耐药性。虽然许多佐剂可以逆转粘菌素耐药性，但对其剂量-反应关系的研究仍然有限，而且大多数佐剂存在溶解度差、生物利用度低和安全性问题，阻碍了临床应用。剂量效应分析表明，氯硝柳胺在较低的浓度范围内具有较高的逆转效率。但随着氯硝柳胺浓度的增加，逆转粘菌素耐药性的能力保持不变，逆转效率逐渐降低。机理分析表明，其与粘菌素的协同抑菌作用包括破坏细菌膜通透性、耗散质子动力、抑制外排泵，导致膜损伤、胞质渗漏、ATP耗竭和活性氧介导的氧化损伤加速，最终导致细菌细胞死亡。为了提高生物利用度，开发了一种奈洛沙胺纳米递送系统（奈洛沙胺负载mPEG-PLGA纳米颗粒[NCL@mPEG-PLGA-NPs]），在体外和体内显著提高了粘菌素抗沙门氏菌的功效。深入研究佐剂在逆转粘菌素耐药中的量效关系，建立奈洛沙胺纳米给药系统，将为粘菌素佐剂的临床应用和开发合适的给药系统奠定科学基础。重要性：粘菌素被用作由多重耐药革兰氏阴性菌引起的许多感染的最后手段，但粘菌素耐药菌株正在上升。研究发现，氯硝柳胺与粘菌素联合使用具有显著的协同抗菌作用。剂量效应分析表明，在相对较低的浓度范围内，氯硝柳胺具有极高的抗逆转效率。NCL@mPEG-PLGA-NPs新剂型的开发将为粘菌素佐剂的临床应用和给药系统的开发奠定科学基础。

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 spectrum Biochemistry, Genetics and Molecular Biology-Genetics

CiteScore

3.20

自引率

5.40%

发文量

1800

期刊介绍： Microbiology Spectrum publishes commissioned review articles on topics in microbiology representing ten content areas: Archaea; Food Microbiology; Bacterial Genetics, Cell Biology, and Physiology; Clinical Microbiology; Environmental Microbiology and Ecology; Eukaryotic Microbes; Genomics, Computational, and Synthetic Microbiology; Immunology; Pathogenesis; and Virology. Reviews are interrelated, with each review linking to other related content. A large board of Microbiology Spectrum editors aids in the development of topics for potential reviews and in the identification of an editor, or editors, who shepherd each collection.