Natural antimicrobial peptides (AMPs) and enzymes (AMEs) are promising non-antibiotic candidates against antimicrobial resistance but suffer from low efficiency and poor stability. Here, we develop peptide nanozymes which mimic the mode of action of AMPs and AMEs through de novo design and peptide assembly. Through modelling a minimal building block of IHIHICI is proposed by combining critical amino acids in AMPs and AMEs and hydrophobic isoleucine to conduct assembly. Experimental validations reveal that IHIHICI assemble into helical β-sheet nanotubes with acetate modulation and perform phospholipase C-like and peroxidase-like activities with Ni coordination, demonstrating high thermostability and resistance to enzymatic degradation. The assembled nanotubes demonstrate cascade antifungal actions including outer mannan docking, wall disruption, lipid peroxidation and subsequent ferroptotic death, synergistically killing >90% Candida albicans within 10?min on disinfection pad. These findings demonstrate an effective de novo design strategy for developing materials with multi-antimicrobial mode of actions.
最新重要论文
Stable peptide-assembled nanozyme mimicking dual antifungal actions, Nat Commun, 5 Jul 2024
Nature Communications, 5 July,2024,DOI:https://doi.org/10.1038/s41467-024-50094-6
Stable peptide-assembled nanozyme mimicking dual antifungal actions
Ye Yuan, Lei Chen, Kexu Song, Miaomiao Cheng, Ling Fang, Lingfei Kong, Lanlan Yu, Ruonan Wang, Zhendong Fu, Minmin Sun, Qian Wang, Chengjun Cui, Haojue Wang, Jiuyang He, Xiaonan Wang, Yuan Liu, Bing Jiang, Jing Jiang, Chenxuan Wang, Xiyun Yan, Xinzheng Zhang & Lizeng Gao
Abstract
Natural antimicrobial peptides (AMPs) and enzymes (AMEs) are promising non-antibiotic candidates against antimicrobial resistance but suffer from low efficiency and poor stability. Here, we develop peptide nanozymes which mimic the mode of action of AMPs and AMEs through de novo design and peptide assembly. Through modelling a minimal building block of IHIHICI is proposed by combining critical amino acids in AMPs and AMEs and hydrophobic isoleucine to conduct assembly. Experimental validations reveal that IHIHICI assemble into helical β-sheet nanotubes with acetate modulation and perform phospholipase C-like and peroxidase-like activities with Ni coordination, demonstrating high thermostability and resistance to enzymatic degradation. The assembled nanotubes demonstrate cascade antifungal actions including outer mannan docking, wall disruption, lipid peroxidation and subsequent ferroptotic death, synergistically killing >90% Candida albicans within 10?min on disinfection pad. These findings demonstrate an effective de novo design strategy for developing materials with multi-antimicrobial mode of actions.
文章链接:https://www.nature.com/articles/s41467-024-50094-6
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