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Metabolic engineering of <i>Vibrio natriegens</i> for anaerobic succinate production

Felix Thoma, Clarissa Schulze, Carolina Gutierrez‐Coto, Maurice Hädrich, Janine Huber, Christoph Gunkel, Rebecca Thoma, Bastian Blombach

2021Microbial Biotechnology42 citationsDOIOpen Access PDF

Abstract

Summary The biotechnological production of succinate bears serious potential to fully replace existing petrochemical approaches in the future. In order to establish an economically viable bioprocess, obtaining high titre, yield and productivity is of central importance. In this study, we present a straightforward engineering approach for anaerobic succinate production with Vibrio natriegens , consisting of essential metabolic engineering and optimization of process conditions. The final producer strain V. natriegens Δ lldh Δ dldh Δ pfl Δ ald Δ dns :: pyc Cg (Succ1) yielded 1.46 mol of succinate per mol of glucose under anaerobic conditions (85% of the theoretical maximum) and revealed a particularly high biomass‐specific succinate production rate of 1.33 g Succ g CDW −1 h −1 compared with well‐established production systems. By applying carbon and redox balancing, we determined the intracellular flux distribution and show that under the tested conditions the reductive TCA as well as the oxidative TCA/glyoxylate pathway contributed to succinate formation. In a zero‐growth bioprocess using minimal medium devoid of complex additives and expensive supplements, we obtained a final titre of 60.4 g Succ l −1 with a maximum productivity of 20.8 g Succ l −1 h −1 and an overall volumetric productivity of 8.6 g Succ l −1 h −1 during the 7 h fermentation. The key performance indicators (titre, yield and productivity) of this first engineering approach in V. natriegens are encouraging and compete with costly tailored microbial production systems.

Topics & Concepts

BioprocessMetabolic engineeringGlyoxylate cycleFermentationBiomass (ecology)Bioprocess engineeringFood scienceBiochemical engineeringProductivityChemistryPulp and paper industryBiochemistryBiologyBiotechnologyMetabolismAgronomyEnzymePaleontologyEconomicsEngineeringMacroeconomicsMicrobial Metabolic Engineering and BioproductionBiofuel production and bioconversionEnzyme Catalysis and Immobilization