Efficient Lewis acid catalysis of an abiological reaction in a de novo protein scaffold

New enzyme catalysts are usually engineered by repurposing the active sites of natural proteins. Here we show that design and directed evolution can be used to transform a non-natural, functionally naive zinc-binding protein into a highly active catalyst for an abiological hetero-Diels–Alder reactio...

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Bibliographic Details
Published in:Nature chemistry 2021-03, Vol.13 (3), p.231-235
Main Authors: Basler, Sophie, Studer, Sabine, Zou, Yike, Mori, Takahiro, Ota, Yusuke, Camus, Anna, Bunzel, H. Adrian, Helgeson, Roger C., Houk, K. N., Jiménez-Osés, Gonzalo, Hilvert, Donald
Format: Article
Language:English
Subjects:
631/92/469
639/638/77/603
639/638/92/607
Active control
Analytical Chemistry
Biochemistry
Catalysis
Catalysts
Catalytic Domain
Chemical reactions
Chemistry
Chemistry and Materials Science
Chemistry/Food Science
Cycloaddition Reaction
Density Functional Theory
Design
Directed evolution
Directed Molecular Evolution
Enzymes
Evolution
Hydrogen Bonding
Inorganic Chemistry
Kinetics
Lewis acid
Lewis Acids - chemistry
Metal ions
Metalloproteins - chemistry
Metalloproteins - metabolism
Molecular Docking Simulation
Organic Chemistry
Physical Chemistry
Proteins
Scaffolds
Stereochemistry
Stereoselectivity
Substrate Specificity
Zinc
Zinc-binding protein
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Summary:New enzyme catalysts are usually engineered by repurposing the active sites of natural proteins. Here we show that design and directed evolution can be used to transform a non-natural, functionally naive zinc-binding protein into a highly active catalyst for an abiological hetero-Diels–Alder reaction. The artificial metalloenzyme achieves >10 4 turnovers per active site, exerts absolute control over reaction pathway and product stereochemistry, and displays a catalytic proficiency (1/ K TS  = 2.9 × 10 10  M −1 ) that exceeds all previously characterized Diels–Alderases. These properties capitalize on effective Lewis acid catalysis, a chemical strategy for accelerating Diels–Alder reactions common in the laboratory but so far unknown in nature. Extension of this approach to other metal ions and other de novo scaffolds may propel the design field in exciting new directions. A de novo designed zinc-binding protein has been converted into a highly active, stereoselective catalyst for a hetero-Diels–Alder reaction. Design and directed evolution were used to effectively harness Lewis acid catalysis and create an enzyme more proficient than other reported Diels–Alderases.
ISSN:1755-4330
1755-4349
DOI:10.1038/s41557-020-00628-4