化学
肽
生物信息学
抗菌剂
抗菌肽
蛋白质组
糖基化
组合化学
两亲性
生物膜
抗生素
计算生物学
生物化学
合理设计
磷脂酰甘油
蛋白质水解
细菌
蛋白质组学
化学改性
化学生物学
糖肽
药物发现
环肽
抗生素耐药性
肽序列
抗菌剂
膜蛋白
选择性
作者
Huayang Liu,Ziheng Xu,Yu Zhang,Dinghao Chen,Liheng Lu,Shichao Xu,Jianjun Cheng,Huaimin Wang
摘要
Proteolytic processing of precursor proteins liberates bioactive fragments, yet the systematic discovery of such peptides remains challenging. Here, we establish a fragment-mining strategy that combines in silico prediction with chemical tailoring to generate self-assembling antimicrobial peptides directly from protein sequences, including previously unannotated proteins. Self-assembly proved integral to activity: amphiphilic modification promoted nanonet formation and efficient bacterial membrane disruption, while rational glycosylation reprogrammed physicochemical properties to confer selectivity for bacterial phosphatidylglycerol over mammalian phosphatidylcholine, thereby broadening the therapeutic window. The optimized peptide, C16-KA6-Glc, displayed broad-spectrum bactericidal activity, superior biofilm eradication, and negligible resistance development. In murine models of thigh and pneumonia infection, C16-KA6-Glc achieved therapeutic efficacy comparable to that of conventional antibiotics while also attenuating inflammatory responses. These findings demonstrate a generalizable approach to translating latent proteome fragments into de novo self-assembling peptide therapeutics with clinical potential.
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