Issue 19, 2023

A covalent crosslinking strategy to construct a robust peptide-based artificial esterase

Abstract

Peptide-based artificial enzymes derived from the supramolecular assembly of short peptides have attracted growing attention in recent years. However, the stability of these artificial enzymes is still a problem since their noncovalent supramolecular structure is quite sensitive and frail under environmental conditions. In this study, we reported a covalent crosslinking strategy for the fabrication of a robust peptide-based artificial esterase. Inspired by the di-tyrosine bonds in many natural structural proteins, multi-tyrosines were designed into a peptide sequence with histidine as the catalytic residue for the ester hydrolysis reaction. Upon the photo-induced oxidation reaction, the short peptide YYHYY rapidly transferred into nanoparticle-shaped aggregates (CL-YYHYY) and displayed improved esterase-like catalytic activity than some previously reported noncovalent-based artificial esterases. Impressively, CL-YYHYY showed outstanding reusability and superior stability under high temperature, strong acid and alkaline and organic solvent conditions. This study provides a promising approach to improving the catalytic activity and stability of peptide-based artificial enzymes.

Graphical abstract: A covalent crosslinking strategy to construct a robust peptide-based artificial esterase

Supplementary files

Article information

Article type
Paper
Submitted
06 Mar 2023
Accepted
13 Apr 2023
First published
13 Apr 2023

Soft Matter, 2023,19, 3458-3463

A covalent crosslinking strategy to construct a robust peptide-based artificial esterase

Y. Tian, L. Yang, X. Peng, W. Qi and M. Wang, Soft Matter, 2023, 19, 3458 DOI: 10.1039/D3SM00284E

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