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Evolutionary Engineering of a Cp*Rh(III) Complex-Linked Artificial Metalloenzyme with a Chimeric β-Barrel Protein Scaffold

Shunsuke Kato, Akira Onoda, Ulrich Schwaneberg, Takashi Hayashi

2023Journal of the American Chemical Society28 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Evolutionary engineering of our previously reported Cp*Rh(III)-linked artificial metalloenzyme was performed based on a DNA recombination strategy to improve its catalytic activity toward C(sp 2 )–H bond functionalization. Improved scaffold design was achieved with α-helical cap domains of fatty acid binding protein (FABP) embedded within the β-barrel structure of nitrobindin (NB) as a chimeric protein scaffold for the artificial metalloenzyme. After optimization of the amino acid sequence by directed evolution methodology, an engineered variant, designated NB HLH1 (Y119A/G149P) with enhanced performance and enhanced stability was obtained. Additional rounds of metalloenzyme evolution provided a Cp*Rh(III)-linked NB HLH1 (Y119A/G149P) variant with a >35-fold increase in catalytic efficiency ( k cat / K M ) for cycloaddition of oxime and alkyne. Kinetic studies and MD simulations revealed that aromatic amino acid residues in the confined active-site form a hydrophobic core which binds to aromatic substrates adjacent to the Cp*Rh(III) complex. The metalloenzyme engineering process based on this DNA recombination strategy will serve as a powerful method for extensive optimization of the active-sites of artificial metalloenzymes.

Topics & Concepts

ChemistryProtein engineeringDirected evolutionStereochemistryActive siteEnzyme kineticsCatalysisCombinatorial chemistryDNAEnzymeBiochemistryMutantGeneCyclopropane Reaction MechanismsAdvanced biosensing and bioanalysis techniquesChemical Synthesis and Analysis