Ashleigh J. Burke scite author profile

The combination of computational design and directed evolution could offer a general strategy to create enzymes with new functions. To date, this approach has delivered enzymes for a handful of model reactions. Here we show that new catalytic mechanisms can be engineered into proteins to accelerate more challenging chemical transformations. Evolutionary optimization of a primitive design afforded an efficient and enantioselective enzyme (BH32.14) for the Morita-Baylis-Hillman (MBH) reaction. BH32.14 is suitable for preparative scale transformations, accepts a broad range of aldehyde and enone coupling partners, and is able to promote selective mono-functionalizations of dialdehydes. Crystallographic, biochemical and computational studies reveal that BH32.14 operates via a sophisticated catalytic mechanism comprising a His23 nucleophile paired with a judiciously positioned Arg124. This catalytic arginine shuttles between conformational states to stabilize multiple oxyanion intermediates and serves as a genetically encoded surrogate of privileged bidentate hydrogen bonding catalysts (e.g. thioureas). This study demonstrates that elaborate catalytic devices can be built from scratch to promote demanding multi-step processes not observed in Nature.

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An Engineered Cytidine Deaminase for Biocatalytic Production of a Key Intermediate of the Covid-19 Antiviral Molnupiravir

Burke

Birmingham

Zhuo

et al. 2022

J. Am. Chem. Soc.

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The Covid-19 pandemic highlights the urgent need for cost-effective processes to rapidly manufacture antiviral drugs at scale. Here we report a concise biocatalytic process for Molnupiravir, a nucleoside analogue recently approved as an orally available treatment for SARS-CoV-2. Key to the success of this process was the development of an efficient biocatalyst for the production of N -hydroxy-cytidine through evolutionary adaption of the hydrolytic enzyme cytidine deaminase. This engineered biocatalyst performs >85 000 turnovers in less than 3 h, operates at 180 g/L substrate loading, and benefits from in situ crystallization of the N -hydroxy-cytidine product (85% yield), which can be converted to Molnupiravir by a selective 5′-acylation using Novozym 435.

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Enzymes with noncanonical amino acids

Zhao

Burke

Green

2020

Current Opinion in Chemical Biology

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Engineering a Cytidine Aminotransferase for Biocatalytic Production of the Antiviral Molnupiravir

Burke¹,

Birmingham²,

Zhuo³

et al. 2021

Preprint

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The COVID-19 pandemic highlights the urgent need for cost-effective processes to rapidly manufacture antiviral drugs at scale. Here we report a concise biocatalytic process for Molnupiravir, a nucleoside analogue currently in phase 3 clinical trials as an orally available treatment for SARS-CoV-2. Key to the success of this process was the development of a cytidine aminotransferase for the production of N-hydroxy-cytidine through evolutionary adaption of the hydrolytic enzyme cytidine deaminase. This engineered biocatalyst performs >100,000 turnovers in less than 30 minutes, operates at 180 g/L substrate loading and benefits from in situ crystallization of the N-hydroxy-cytidine product (>90% yield), which can be converted to Molnupiravir by a selective 5'-acylation using Novozym® 435.

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Ashleigh J. Burke

Design and evolution of an enzyme with a non-canonical organocatalytic mechanism

Engineering an efficient and enantioselective enzyme for the Morita–Baylis–Hillman reaction

An Engineered Cytidine Deaminase for Biocatalytic Production of a Key Intermediate of the Covid-19 Antiviral Molnupiravir

Enzymes with noncanonical amino acids

Engineering a Cytidine Aminotransferase for Biocatalytic Production of the Antiviral Molnupiravir

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