Litcius/Paper detail

Substrate Channeling by a Rationally Designed Fusion Protein in a Biocatalytic Cascade

Matthew J. Kummer, Yoo Seok Lee, Mengwei Yuan, Bassam Alkotaini, Cong‐Gui Zhao, Emmy Blumenthal, Shelley D. Minteer

2021JACS Au64 citationsDOIOpen Access PDF

Abstract

Substrate channeling, where an intermediate in a multistep reaction is directed toward a reaction center rather than freely diffusing, offers several advantages when employed in catalytic cascades. Here we present a fusion enzyme comprised of an alcohol and aldehyde dehydrogenase, that is computationally designed to facilitate electrostatic substrate channeling using a cationic linker bridging the two structures. Rosetta protein folding software was utilized to determine an optimal linker placement, added to the truncated termini of the proteins, which is as close as possible to the active sites of the enzymes without disrupting critical catalytic residues. With improvements in stability, product selectivity (90%), and catalyst turnover frequency, representing 500-fold increased activity compared to the unbound enzymes and nearly 140-fold for a neutral-linked fusion enzyme, this design strategy holds promise for making other multistep catalytic processes more sustainable and efficient.

Topics & Concepts

LinkerChemistryFusionCombinatorial chemistryCatalysisProtein engineeringEnzymeSubstrate (aquarium)Alcohol dehydrogenaseCascadeBiocatalysisCationic polymerizationCatalytic efficiencyActive siteFusion proteinFolding (DSP implementation)BiophysicsBiochemistryReaction mechanismOrganic chemistryComputer scienceRecombinant DNABiologyChromatographyLinguisticsEcologyGeneEngineeringOperating systemElectrical engineeringPhilosophyProtein purification and stabilityProtein Structure and DynamicsMonoclonal and Polyclonal Antibodies Research