Development of a Highly Selective NAD<sup>+</sup>‐Dependent Glyceraldehyde Dehydrogenase and its Application in Minimal Cell‐Free Enzyme Cascades-Reference-Cited by-同舟云学术

Development of a Highly Selective NAD⁺‐Dependent Glyceraldehyde Dehydrogenase and its Application in Minimal Cell‐Free Enzyme Cascades

Published:2023-11-16 Issue: Volume: Page:
ISSN:1864-5631
Container-title:ChemSusChem
language:en
Short-container-title:ChemSusChem

Author:

Teshima Mariko¹,Sutiono Samuel¹²,Döring Manuel¹,Beer Barbara¹³,Boden Mikael⁴,Schenk Gerhard⁴⁵⁶,Sieber Volker¹⁴⁷⁸^ORCID

Affiliation:

1. Chair of Chemistry of Biogenic Resources Technical University of Munich Campus Straubing for Biotechnology and Sustainability, Schulgasse 16 94315 Straubing Germany

2. Current address: CarboCode Germany GmbH Byk-Gulden-Straße 2 78467 Constance Germany

3. Current address: CASCAT GmbH Europaring 4 94315 Straubing Germany

4. School of Chemistry and Molecular Biosciences The University of Queensland 68 Cooper Rd, St. Lucia 4072 Brisbane Australia

5. Australian Institute for Bioengineering and Nanotechnology The University of Queensland Corner of College and Cooper Rds, St. Lucia 4072 Brisbane Australia

6. Sustainable Minerals Institute The University of Queensland Corner of College and Staff House Rds, St. Lucia 4072 Brisbane Australia

7. SynBioFoundry@TUM Technical University of Munich Schulgasse 22 94315 Straubing Germany

8. Catalytic Research Center Technical University of Munich Ernst-Otto-Fischer Straße 1 85748 Garching Germany

Abstract

AbstractAnthropogenic climate change has been caused by over‐exploitation of fossil fuels and CO2 emissions. To counteract this, the chemical industry has shifted its focus to sustainable chemical production and the valorization of renewable resources. However, the biggest challenges in biomanufacturing are technical efficiency and profitability. In our minimal cell‐free enzyme cascade generating pyruvate as the central intermediate, the NAD+‐dependent, selective oxidation of D‐glyceraldehyde was identified as a key reaction step to improve the overall cascade flux. Successive genome mining identified one candidate enzyme with 24‐fold enhanced activity and another whose stability is unaffected in 10 % (v/v) ethanol, the final product of our model cascade. Semi‐rational engineering improved the substrate selectivity of the enzyme up to 21‐fold, thus minimizing side reactions in the one‐pot enzyme cascade. The final biotransformation of D‐glucose showed a continuous linear production of ethanol (via pyruvate) to a final titer of 4.9 % (v/v) with a molar product yield of 98.7 %. Due to the central role of pyruvate in diverse biotransformations, the optimized production module has great potential for broad biomanufacturing applications.

Publisher

Wiley

Subject

General Energy,General Materials Science,General Chemical Engineering,Environmental Chemistry

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