Formation Mechanism and Biomedical Applications of Protease-Manipulated Peptide Assemblies

Tianyue Jiang; Chendan Liu; Xiao Xu; Bingfang He; Ran Mo

doi:10.3389/fbioe.2021.598050

Formation Mechanism and Biomedical Applications of Protease-Manipulated Peptide Assemblies

Tianyue Jiang, Chendan Liu, Xiao Xu, Bingfang He, Ran Mo

School of Pharmaceutical Sciences

Research output: Contribution to journal › Review article › peer-review

8 Scopus citations

Abstract

Exploiting enzyme-catalyzed reactions to manipulate molecular assembly has been considered as an attractive bottom-up nanofabrication approach to developing a variety of nano-, micro-, and macroscale structures. Upon enzymatic catalysis, peptides and their derivatives transform to assemblable building blocks that form ordered architecture by non-covalent interactions. The peptide assemblies with unique characteristics have great potential for applications in bionanotechnology and biomedicine. In this mini review, we describe typical mechanisms of the protease-instructed peptide assembly via bond-cleaving or bond-forming reactions, and outline biomedical applications of the peptide assemblies, such as drug depot, sustained release, controlled release, gelation-regulated cytotoxicity, and matrix construction.

Original language	English
Article number	598050
Journal	Frontiers in Bioengineering and Biotechnology
Volume	9
DOIs	https://doi.org/10.3389/fbioe.2021.598050
State	Published - 26 Feb 2021

Keywords

biomedical application
mechanism
peptide assemblies
protease
self-assembly

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abstract = "Exploiting enzyme-catalyzed reactions to manipulate molecular assembly has been considered as an attractive bottom-up nanofabrication approach to developing a variety of nano-, micro-, and macroscale structures. Upon enzymatic catalysis, peptides and their derivatives transform to assemblable building blocks that form ordered architecture by non-covalent interactions. The peptide assemblies with unique characteristics have great potential for applications in bionanotechnology and biomedicine. In this mini review, we describe typical mechanisms of the protease-instructed peptide assembly via bond-cleaving or bond-forming reactions, and outline biomedical applications of the peptide assemblies, such as drug depot, sustained release, controlled release, gelation-regulated cytotoxicity, and matrix construction.",

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AU - Jiang, Tianyue

AU - Liu, Chendan

AU - Xu, Xiao

AU - He, Bingfang

AU - Mo, Ran

PY - 2021/2/26

Y1 - 2021/2/26

N2 - Exploiting enzyme-catalyzed reactions to manipulate molecular assembly has been considered as an attractive bottom-up nanofabrication approach to developing a variety of nano-, micro-, and macroscale structures. Upon enzymatic catalysis, peptides and their derivatives transform to assemblable building blocks that form ordered architecture by non-covalent interactions. The peptide assemblies with unique characteristics have great potential for applications in bionanotechnology and biomedicine. In this mini review, we describe typical mechanisms of the protease-instructed peptide assembly via bond-cleaving or bond-forming reactions, and outline biomedical applications of the peptide assemblies, such as drug depot, sustained release, controlled release, gelation-regulated cytotoxicity, and matrix construction.

AB - Exploiting enzyme-catalyzed reactions to manipulate molecular assembly has been considered as an attractive bottom-up nanofabrication approach to developing a variety of nano-, micro-, and macroscale structures. Upon enzymatic catalysis, peptides and their derivatives transform to assemblable building blocks that form ordered architecture by non-covalent interactions. The peptide assemblies with unique characteristics have great potential for applications in bionanotechnology and biomedicine. In this mini review, we describe typical mechanisms of the protease-instructed peptide assembly via bond-cleaving or bond-forming reactions, and outline biomedical applications of the peptide assemblies, such as drug depot, sustained release, controlled release, gelation-regulated cytotoxicity, and matrix construction.

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KW - mechanism

KW - peptide assemblies

KW - protease

KW - self-assembly

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M3 - 文献综述

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SN - 2296-4185

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JO - Frontiers in Bioengineering and Biotechnology

JF - Frontiers in Bioengineering and Biotechnology

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Formation Mechanism and Biomedical Applications of Protease-Manipulated Peptide Assemblies

Abstract

Keywords

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