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Repurposing a bacterial prolidase for organophosphorus hydrolysis: Reshaped catalytic cavity switches substrate selectivity

Jian Yang, Yunzhu Xiao, Ru Li, Yu Liu, Lijuan Long

2020Biotechnology and Bioengineering15 citationsDOI

Abstract

Enzyme promiscuity is critical to the acquisition of evolutionary plasticity in cells and can be recruited for high-value chemical synthesis or xenobiotic degradation. The molecular determinants of substrate ambiguity are essential to this activity; however, these details remain unknown. Here, we performed the directed evolution of a prolidase to enhance its initially weak paraoxonase activity. The in vitro evolution led to an unexpected 1,000,000-fold switch in substrate selectivity, with a 30-fold increase in paraoxon hydrolysis and 40,000-fold decrease in peptide hydrolysis. Structural and in silico analyses revealed enlarged catalytic cavities and substrate repositioning as responsible for rapid catalytic transitions between distinct chemical reactions.

Topics & Concepts

ParaoxonSelectivityChemistrySubstrate (aquarium)CatalysisHydrolysisAdaptive evolutionIn silicoPeptideDirected evolutionBiophysicsBiochemistryEnzymeCombinatorial chemistryStereochemistryBiologyGeneMutantAcetylcholinesteraseEcologyPeptidase Inhibition and AnalysisSignaling Pathways in DiseaseBiochemical and Structural Characterization
Repurposing a bacterial prolidase for organophosphorus hydrolysis: Reshaped catalytic cavity switches substrate selectivity | Litcius