Strong Protein Adhesives through Lanthanide-enhanced Structure Folding and Stack Density

Jing Chen; Weiwei Shi; Yubin Ren; Kelu Zhao; Yangyi Liu; Bo Jia; Lai Zhao; Ming Li; Yawei Liu; Juanjuan Su; Chao Ma; Fan Wang; Jing Sun; Yang Tian; Jingjing Li; Hongjie Zhang; Kai Liu

doi:10.1002/anie.202304483

Strong Protein Adhesives through Lanthanide-enhanced Structure Folding and Stack Density

Jing Chen, Weiwei Shi, Yubin Ren, Kelu Zhao, Yangyi Liu, Bo Jia, Lai Zhao, Ming Li, Yawei Liu, Juanjuan Su, Chao Ma, Fan Wang, Jing Sun, Yang Tian, Jingjing Li^*, Hongjie Zhang, Kai Liu

^*Corresponding author for this work

School of Chemistry and Molecular Engineering

Research output: Contribution to journal › Article › peer-review

22 Scopus citations

Abstract

Generating strong adhesion by engineered proteins has the potential for high technical applications. Current studies of adhesive proteins are primarily limited to marine organisms, e.g., mussel adhesive proteins. Here, we present a modular engineering strategy to generate a type of exotic protein adhesives with super strong adhesion behaviors. In the protein complexes, the lanmodulin (LanM) underwent α-helical conformational transition induced by lanthanides, thereby enhancing the stacking density and molecular interactions of adhesive protein. The resulting adhesives exhibited outstanding lap-shear strength of ≈31.7 MPa, surpassing many supramolecular and polymer adhesives. The extreme temperature (−196 to 200 °C) resistance capacity and underwater adhesion performance can significantly broaden their practical application scenarios. Ex vivo and in vivo experiments further demonstrated the persistent adhesion performance for surgical sealing and healing applications.

Original language	English
Article number	e202304483
Journal	Angewandte Chemie - International Edition
Volume	62
Issue number	43
DOIs	https://doi.org/10.1002/anie.202304483
State	Published - 23 Oct 2023

Keywords

Biomedical Applications
Coacervate Adhesives
Modular Protein Engineering
Molecular Interactions
Structural Proteins

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10.1002/anie.202304483

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title = "Strong Protein Adhesives through Lanthanide-enhanced Structure Folding and Stack Density",

abstract = "Generating strong adhesion by engineered proteins has the potential for high technical applications. Current studies of adhesive proteins are primarily limited to marine organisms, e.g., mussel adhesive proteins. Here, we present a modular engineering strategy to generate a type of exotic protein adhesives with super strong adhesion behaviors. In the protein complexes, the lanmodulin (LanM) underwent α-helical conformational transition induced by lanthanides, thereby enhancing the stacking density and molecular interactions of adhesive protein. The resulting adhesives exhibited outstanding lap-shear strength of ≈31.7 MPa, surpassing many supramolecular and polymer adhesives. The extreme temperature (−196 to 200 °C) resistance capacity and underwater adhesion performance can significantly broaden their practical application scenarios. Ex vivo and in vivo experiments further demonstrated the persistent adhesion performance for surgical sealing and healing applications.",

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doi = "10.1002/anie.202304483",

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T1 - Strong Protein Adhesives through Lanthanide-enhanced Structure Folding and Stack Density

AU - Chen, Jing

AU - Shi, Weiwei

AU - Ren, Yubin

AU - Zhao, Kelu

AU - Liu, Yangyi

AU - Jia, Bo

AU - Zhao, Lai

AU - Li, Ming

AU - Liu, Yawei

AU - Su, Juanjuan

AU - Ma, Chao

AU - Wang, Fan

AU - Sun, Jing

AU - Tian, Yang

AU - Li, Jingjing

AU - Zhang, Hongjie

AU - Liu, Kai

PY - 2023/10/23

Y1 - 2023/10/23

N2 - Generating strong adhesion by engineered proteins has the potential for high technical applications. Current studies of adhesive proteins are primarily limited to marine organisms, e.g., mussel adhesive proteins. Here, we present a modular engineering strategy to generate a type of exotic protein adhesives with super strong adhesion behaviors. In the protein complexes, the lanmodulin (LanM) underwent α-helical conformational transition induced by lanthanides, thereby enhancing the stacking density and molecular interactions of adhesive protein. The resulting adhesives exhibited outstanding lap-shear strength of ≈31.7 MPa, surpassing many supramolecular and polymer adhesives. The extreme temperature (−196 to 200 °C) resistance capacity and underwater adhesion performance can significantly broaden their practical application scenarios. Ex vivo and in vivo experiments further demonstrated the persistent adhesion performance for surgical sealing and healing applications.

AB - Generating strong adhesion by engineered proteins has the potential for high technical applications. Current studies of adhesive proteins are primarily limited to marine organisms, e.g., mussel adhesive proteins. Here, we present a modular engineering strategy to generate a type of exotic protein adhesives with super strong adhesion behaviors. In the protein complexes, the lanmodulin (LanM) underwent α-helical conformational transition induced by lanthanides, thereby enhancing the stacking density and molecular interactions of adhesive protein. The resulting adhesives exhibited outstanding lap-shear strength of ≈31.7 MPa, surpassing many supramolecular and polymer adhesives. The extreme temperature (−196 to 200 °C) resistance capacity and underwater adhesion performance can significantly broaden their practical application scenarios. Ex vivo and in vivo experiments further demonstrated the persistent adhesion performance for surgical sealing and healing applications.

KW - Biomedical Applications

KW - Coacervate Adhesives

KW - Modular Protein Engineering

KW - Molecular Interactions

KW - Structural Proteins

UR - https://www.scopus.com/pages/publications/85171347844

U2 - 10.1002/anie.202304483

DO - 10.1002/anie.202304483

M3 - 文章

AN - SCOPUS:85171347844

SN - 1433-7851

VL - 62

JO - Angewandte Chemie - International Edition

JF - Angewandte Chemie - International Edition

IS - 43

M1 - e202304483

ER -

Strong Protein Adhesives through Lanthanide-enhanced Structure Folding and Stack Density

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Keywords

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