Structure-based targeting of the lipid A-modifying enzyme PmrC to contrast colistin resistance in Acinetobacter baumannii.

IF 4 2区 生物学 Q2 MICROBIOLOGY
Frontiers in Microbiology Pub Date : 2024-11-28 eCollection Date: 2024-01-01 DOI:10.3389/fmicb.2024.1501051
Maria Romano, Federico Falchi, Eliana De Gregorio, Maria Stabile, Antonella Migliaccio, Alessia Ruggiero, Valeria Napolitano, Ida Autiero, Flavia Squeglia, Rita Berisio
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引用次数: 0

Abstract

Introduction: Antimicrobial-resistant pathogens are an ongoing threat to human and animal health. According to the World Health Organization (WHO), colistin is considered the last resort antibiotic against human infections due to multidrug-resistant Gram-negative organisms-including Acinetobacter baumanni, a priority-1 pathogen. Despite colistin being considered a last resort antibiotic, transferable bacterial resistance to this drug has been reported in humans and animals. This makes addressing colistin resistance a critical priority in public health efforts. The large PetN transferase membrane protein PmrC is responsible for colistin resistance due to its catalysed modification of lipid A of the external membrane. Despite its importance, this potential drug target was never characterised at a molecular level.

Methods: The recombinant production of large membrane proteins in their native forms is a bottleneck in modern molecular biology. In this study, we recombinantly produced PmrC and biophysically characterised it in solution. We employed in silico approaches, including virtual screening and molecular modelling, to identify PmrC ligands. The binding of these ligands to PmrC was measured using Microscale Thermophoresis (MST). The best ligand was tested for its ability to hamper colistin resistance in Acinetobacter baumannii clinical isolates. Finally, we checked that the identified compound was not cytotoxic at the used concentrations by haemolysis assays.

Results: We successfully produced PmrC PetN transferase membrane protein in high yields and showed that PmrC is a stable α-β protein, with melting temperature Tm = 60°C. Based on the PmrC structural model, we identified a promising druggable cavity. Therefore, we used a structure-based virtual screening to identify potential inhibitors. A small molecule, here denominated as s-Phen, was proved to bind PmrC with μM affinity. Microbiological assays confirmed that the s-Phen can drastically reduce colistin minimum inhibitory concentration (MIC) in two A. baumannii-resistant isolates and that it is not cytotoxic. Importantly, PmrC binding pocket to s-Phen is highly conserved in all homologues of PmrC, regardless of the location of genes encoding for them and of their operons.

Discussion: Our study provides a molecular characterisation of PmrC and demonstrates the importance of PmrC as a drug target and the strong potential of PmrC binding molecules to act as colistin adjuvants, operating as synergistic tools to combat multiresistant nosocomial pathogens.

导言:耐药性病原体对人类和动物健康构成持续威胁。据世界卫生组织(WHO)称,可乐定被认为是应对人类感染的最后一种抗生素,这种感染是由对多种药物产生耐药性的革兰氏阴性菌引起的,其中包括鲍曼不动杆菌(Acinetobacter baumanni),这是一种优先级为 1 的病原体。尽管秋水仙素被认为是最后一种抗生素,但在人类和动物中仍有细菌对这种药物产生耐药性的报道。因此,解决可乐定耐药性问题成为公共卫生工作的重中之重。大型 PetN 转移酶膜蛋白 PmrC 通过催化修饰外膜的脂质 A 而产生了对秋水仙素的耐药性。尽管它很重要,但这个潜在的药物靶点从未在分子水平上得到表征:方法:以原生形式重组生产大型膜蛋白是现代分子生物学的一个瓶颈。在这项研究中,我们重组生产了 PmrC,并在溶液中对其进行了生物物理表征。我们采用了包括虚拟筛选和分子建模在内的硅学方法来鉴定 PmrC 配体。这些配体与 PmrC 的结合是通过微尺度热电泳(MST)测量的。我们测试了最佳配体对鲍曼不动杆菌临床分离株的可乐定耐药性的抑制能力。最后,我们通过溶血试验检验了所鉴定的化合物在所用浓度下是否具有细胞毒性:结果:我们成功地高产制备出了 PmrC PetN 转移酶膜蛋白,并证明 PmrC 是一种稳定的 α-β 蛋白,熔点温度 Tm = 60°C。根据 PmrC 的结构模型,我们发现了一个很有前景的可药用空腔。因此,我们利用基于结构的虚拟筛选来确定潜在的抑制剂。结果证明,一种小分子(在此称为 s-Phen)能以 μM 的亲和力与 PmrC 结合。微生物学实验证实,s-Phen 能大幅降低两种耐鲍曼尼氏菌分离物的可乐定最低抑菌浓度(MIC),而且没有细胞毒性。重要的是,PmrC 与 s-Phen 的结合口袋在 PmrC 的所有同源物中都是高度保守的,与编码它们的基因的位置及其操作子的位置无关:我们的研究提供了 PmrC 的分子特征,证明了 PmrC 作为药物靶点的重要性,以及 PmrC 结合分子作为可乐定佐剂的强大潜力,可作为抗多重耐药性医院病原体的协同工具。
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
CiteScore
7.70
自引率
9.60%
发文量
4837
审稿时长
14 weeks
期刊介绍: Frontiers in Microbiology is a leading journal in its field, publishing rigorously peer-reviewed research across the entire spectrum of microbiology. Field Chief Editor Martin G. Klotz at Washington State University is supported by an outstanding Editorial Board of international researchers. This multidisciplinary open-access journal is at the forefront of disseminating and communicating scientific knowledge and impactful discoveries to researchers, academics, clinicians and the public worldwide.
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