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Metabolic Engineering of <i>Clostridium cellulovorans</i> to Improve Butanol Production by Consolidated Bioprocessing

Zhiqiang Wen, Rodrigo Ledesma‐Amaro, Minrui Lu, Mingjie Jin, Sheng Yang

2020ACS Synthetic Biology54 citationsDOI

Abstract

Clostridium cellulovorans DSM 743B can produce butyrate when grown on lignocellulose, but it can hardly synthesize butanol. In a previous study, C. cellulovorans was successfully engineered to switch the metabolism from butyryl-CoA to butanol by overexpressing an alcohol aldehyde dehydrogenase gene adhE1 from Clostridium acetobutylicum ATCC 824; however, its full potential in butanol production is still unexplored. In the study, a metabolic engineering approach based on a push–pull strategy was developed to further enhance cellulosic butanol production. In order to accomplish this, the carbon flux from acetyl-CoA to butyryl-CoA was pulled by overexpressing a trans-enoyl-coenzyme A reductase gene (ter), which can irreversibly catalyze crotonyl-CoA to butyryl-CoA. Then an acid reassimilation pathway uncoupled with acetone production was introduced to redirect the carbon flow from butyrate and acetate toward butyryl-CoA. Finally, xylose metabolism engineering was implemented by inactivating xylR (Clocel_0594) and araR (Clocel_1253), as well as overexpressing xylT (CA_C1345), which is expected to supply additional carbon and reducing power for CoA and butanol synthesis pathways. The final engineered strain produced 4.96 g/L of n-butanol from alkali extracted corn cobs (AECC), increasing by 235-fold compared to that of the wild type. It serves as a promising butanol producer by consolidated bioprocessing.

Topics & Concepts

Clostridium acetobutylicumButanolMetabolic engineeringBioprocessChemistryBiochemistryCellulosic ethanolClostridiumAlcohol dehydrogenaseBioprocess engineeringBiologyEnzymeBiotechnologyBacteriaEthanolGeneticsCellulosePaleontologyBiofuel production and bioconversionMicrobial Metabolic Engineering and BioproductionCatalysis for Biomass Conversion
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