Controlled Orientation of Active Sites in a Nanostructured Multienzyme Complex

Overview

Journal Sci Rep

Specialty Science

Date 2016 Dec 23

PMID 28004799

Citations 3

Authors

Sung In Lim

Byungseop Yang

Younghan Jung

Jaehyun Cha

Jinhwan Cho

Eun-Sil Choi

Yong Hwan Kim

Inchan Kwon

Affiliations

Soon will be listed here.

Abstract

Multistep cascade reactions in nature maximize reaction efficiency by co-assembling related enzymes. Such organization facilitates the processing of intermediates by downstream enzymes. Previously, the studies on multienzyme nanocomplexes assembled on DNA scaffolds demonstrated that closer interenzyme distance enhances the overall reaction efficiency. However, it remains unknown how the active site orientation controlled at nanoscale can have an effect on multienzyme reaction. Here, we show that controlled alignment of active sites promotes the multienzyme reaction efficiency. By genetic incorporation of a non-natural amino acid and two compatible bioorthogonal chemistries, we conjugated mannitol dehydrogenase to formate dehydrogenase with the defined active site arrangement with the residue-level accuracy. The study revealed that the multienzyme complex with the active sites directed towards each other exhibits four-fold higher relative efficiency enhancement in the cascade reaction and produces 60% more D-mannitol than the other complex with active sites directed away from each other.

Citing Articles

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Noncanonical Amino Acids in Biocatalysis.

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Enzyme Fusions in Biocatalysis: Coupling Reactions by Pairing Enzymes.

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