Improving the catalytic ability of a peptide-based artificial glycosidase through a tyrosine strategy

Abstract

Recently, peptide-based artificial enzymes have attracted growing interest due to the similar composition of peptide assemblies to natural enzymes. However, low catalytic activity and stability are still the main challenges for these enzyme-like catalysts. In this study, a tyrosine strategy was developed to construct a peptide-based artificial glycosidase through engaging the Tyr residue into the peptide sequence. We found that the appropriate substitution of Tyr produced an enhanced catalytic ability, because the proximal Tyr residue around catalytic sites acts as a nucleophile, playing an important role in the substrate orientation and proton transfer. Moreover, inspired by the biological function of dityrosine bonds in structural proteins, a photo-crosslinking reaction between the phenolic side chains of Tyr was also employed to form intermolecular covalent bonds in peptide assemblies, which further improved the activity and stability of the artificial glycosidase. This work provides a simple avenue for the designing and construction of efficient glycosidase-like catalysts based on a peptide-based material platform.