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High-throughput enrichment of temperature-sensitive argininosuccinate synthetase for two-stage citrulline production in E. coli

Thorben Schramm, Martin Lempp, Dominik Beuter, Silvia González Sierra, Timo Glatter, Hannes Link

2020Metabolic Engineering20 citationsDOIOpen Access PDF

Abstract

Controlling metabolism of engineered microbes is important to modulate cell growth and production during a bioprocess. For example, external parameters such as light, chemical inducers, or temperature can act on metabolism of production strains by changing the abundance or activity of enzymes. Here, we created temperature-sensitive variants of an essential enzyme in arginine biosynthesis of Escherichia coli (argininosuccinate synthetase, ArgG) and used them to dynamically control citrulline overproduction and growth of E. coli. We show a method for high-throughput enrichment of temperature-sensitive ArgG variants with a fluorescent TIMER protein and flow cytometry. With 90 of the thus derived ArgG variants, we complemented an ArgG deletion strain showing that 90% of the strains exhibit temperature-sensitive growth and 69% of the strains are auxotrophic for arginine at 42 °C and prototrophic at 30 °C. The best temperature-sensitive ArgG variant enabled precise and tunable control of cell growth by temperature changes. Expressing this variant in a feedback-dysregulated E. coli strain allowed us to realize a two-stage bioprocess: a 33 °C growth-phase for biomass accumulation and a 39 °C stationary-phase for citrulline production. With this two-stage strategy, we produced 3 g/L citrulline during 45 h cultivation in a 1-L bioreactor. These results show that temperature-sensitive enzymes can be created en masse and that they may function as metabolic valves in engineered bacteria.

Topics & Concepts

AuxotrophyArgininosuccinate synthaseEscherichia coliBioprocessBiochemistryMetabolic engineeringBiologyOverproductionMetabolomeStrain (injury)CitrullineEnzymeBacteriaArginineGeneticsAmino acidGeneMetabolitePaleontologyAnatomyCancer Research and TreatmentsBacteriophages and microbial interactionsBacterial Genetics and Biotechnology