Lasso Proteins: Modular Design, Cellular Synthesis, and Topological Transformation

Entangled proteins have attracted significant research interest. Herein, we report the first rationally designed lasso proteins, or protein [1]rotaxanes, by using a p53dim‐entwined dimer for intramolecular entanglement and a SpyTag‐SpyCatcher reaction for side‐chain ring closure. The lasso structure...

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Published in:Angewandte Chemie 2020-10, Vol.132 (43), p.19315-19323
Main Authors: Liu, Yajie, Wu, Wen‐Hao, Hong, Sumin, Fang, Jing, Zhang, Fan, Liu, Geng‐Xin, Seo, Jongcheol, Zhang, Wen‐Bin
Format: Article
Language:English
Subjects:
Biomaterials
Biomedical materials
catenanes
Chemistry
Digestion
Dimers
Entanglement
Genetic code
lasso proteins
Magnetic resonance spectroscopy
Modular design
Mutation
NMR
Nuclear magnetic resonance
p53
Proteins
Proteolysis
Rotaxanes
slide-ring gels
Spectrometry
Topology
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container_end_page 19323
container_issue 43
container_start_page 19315
container_title Angewandte Chemie
container_volume 132
creator Liu, Yajie
Wu, Wen‐Hao
Hong, Sumin
Fang, Jing
Zhang, Fan
Liu, Geng‐Xin
Seo, Jongcheol
Zhang, Wen‐Bin
description Entangled proteins have attracted significant research interest. Herein, we report the first rationally designed lasso proteins, or protein [1]rotaxanes, by using a p53dim‐entwined dimer for intramolecular entanglement and a SpyTag‐SpyCatcher reaction for side‐chain ring closure. The lasso structures were confirmed by proteolytic digestion, mutation, NMR spectrometry, and controlled ligation. Their dynamic properties were probed by experiments such as end‐capping, proteolytic digestion, and heating/cooling. As a versatile topological intermediate, a lasso protein could be converted to a rotaxane, a heterocatenane, and a “slide‐ring” network. Being entirely genetically encoded, this robust and modular lasso‐protein motif is a valuable addition to the topological protein repertoire and a promising candidate for protein‐based biomaterials. Artificially designed lasso proteins were modularly synthesized in cellulo based on assembly–reaction synergy. This enables the synthesis of protein (pseudo)rotaxanes, protein heterocatenanes, and protein‐based „slide‐ring“ hydrogels via topological transformation.
doi_str_mv 10.1002/ange.202006727
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subjects Biomaterials
Biomedical materials
catenanes
Chemistry
Digestion
Dimers
Entanglement
Genetic code
lasso proteins
Magnetic resonance spectroscopy
Modular design
Mutation
NMR
Nuclear magnetic resonance
p53
Proteins
Proteolysis
Rotaxanes
slide-ring gels
Spectrometry
Topology
title Lasso Proteins: Modular Design, Cellular Synthesis, and Topological Transformation
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