Pse-T2-Based Short Peptides with Broad-Spectrum Antimicrobial Activity, Stability, and Safety Combat MDR Staphylococcus aureus In Vitro and in Mouse Infection Model.

IF 4 2区医学 Q2 CHEMISTRY, MEDICINAL

ACS Infectious Diseases Pub Date : 2025-07-17 DOI:10.1021/acsinfecdis.4c01034

Hee Kyoung Kang, Yoonkyung Park

引用次数: 0

Abstract

Infections caused by MDR pathogens are on the rise worldwide, and relying on conventional antibiotics can be life-threatening for patients. To address this issue, we used a functional truncated peptide, Pse-T2-C12, which exhibited excellent antibacterial, antibiofilm, and antipersister activities, along with a rapid killing rate against all tested pathogens. Pse-T2-C12 kills bacterial cells via pore formation, permeabilization, and disruption of bacterial membranes. Pse-T2-C12 did not induce resistance development, remained stable over pH, temperature, and serum conditions, and showed no detectable toxicity in vitro and in vivo. Moreover, in vivo data showed that Pse-T2-C12 reduced MDR Staphylococcus aureus infection, resulting in a reduced inflammatory response, decreased coagulation, and pain reduction. These findings highlight Pse-T2-C12 as a promising antibiotic candidate owing to its easy synthesis, economic benefits, and ability to treat MDR bacterial infections.

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具有广谱抗菌活性、稳定性和安全性的pse - t2短肽在体外和小鼠感染模型中对抗MDR金黄色葡萄球菌。

由耐多药病原体引起的感染在世界范围内呈上升趋势，依赖传统抗生素可能危及患者生命。为了解决这个问题，我们使用了一种功能性截断肽Pse-T2-C12，它具有出色的抗菌、抗生物膜和抗持久性活性，并且对所有测试的病原体具有快速的杀伤速度。Pse-T2-C12通过形成孔、渗透和破坏细菌膜来杀死细菌细胞。Pse-T2-C12不诱导耐药，在pH、温度和血清条件下保持稳定，体外和体内均未显示出可检测到的毒性。此外，体内数据显示Pse-T2-C12减少了MDR金黄色葡萄球菌感染，导致炎症反应减少，凝血减少，疼痛减轻。这些发现突出了Pse-T2-C12作为一种有希望的候选抗生素，因为它易于合成，经济效益好，并且能够治疗耐多药细菌感染。

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

ACS Infectious Diseases CHEMISTRY, MEDICINALINFECTIOUS DISEASES&nb-INFECTIOUS DISEASES

CiteScore

9.70

自引率

3.80%

发文量

213

期刊介绍： ACS Infectious Diseases will be the first journal to highlight chemistry and its role in this multidisciplinary and collaborative research area. The journal will cover a diverse array of topics including, but not limited to: * Discovery and development of new antimicrobial agents — identified through target- or phenotypic-based approaches as well as compounds that induce synergy with antimicrobials. * Characterization and validation of drug target or pathways — use of single target and genome-wide knockdown and knockouts, biochemical studies, structural biology, new technologies to facilitate characterization and prioritization of potential drug targets. * Mechanism of drug resistance — fundamental research that advances our understanding of resistance; strategies to prevent resistance. * Mechanisms of action — use of genetic, metabolomic, and activity- and affinity-based protein profiling to elucidate the mechanism of action of clinical and experimental antimicrobial agents. * Host-pathogen interactions — tools for studying host-pathogen interactions, cellular biochemistry of hosts and pathogens, and molecular interactions of pathogens with host microbiota. * Small molecule vaccine adjuvants for infectious disease. * Viral and bacterial biochemistry and molecular biology.