铜绿假单胞菌
结合
肽
抗菌活性
微生物学
化学
组合化学
抗菌肽
细菌
生物
生物化学
数学分析
遗传学
数学
作者
Yanxi Yang,Shelby Vexler,Maria C. Jordan,Serena Abbondante,Alison R. Yung,Huan Peng,Michaela Marshall,Bita V. Naini,Saumya Jain,Yei‐Chen Lai,Nasim Annabi,Kenneth P. Roos,Eric Pearlman,Irene A. Chen
标识
DOI:10.1021/acscentsci.5c00562
摘要
Antibiotic resistance among Gram-negative organisms is a major challenge. Some molecules, including antimicrobial peptides such as polymyxin B (PMB), are antibacterial but toxic due to low specificity, causing poor clinical utility. Drug delivery to bacterial cells using a biocompatible nanomaterial is a possible approach to securing such drugs. We engineered a nonlytic phage to recognize the lipopolysaccharide of Gram-negative bacteria and cross-linked thousands of peptides per virion, making "PMB-M13αLPS". PMB-M13αLPS reduced the minimum inhibitory concentration in vitro by ∼2 orders of magnitude across multiple pathogen strains. Immunocompetent mice with multidrug-resistant P. aeruginosa pneumonia or corneal infection were effectively treated by PMB-M13αLPS, which showed potency ∼2 orders of magnitude greater in vivo compared to that of PMB. PMB-M13αLPS was well-tolerated, with no toxic effects. Conjugates of antimicrobial peptides and synthetic phages combine engineerable targeting with large payload capacity, improving potency and therapeutic index for otherwise toxic molecules.
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