Abstract
BackgroundPropionic acid is used primarily as a food preservative with smaller applications as a chemical building block for the production of many products including fabrics, cosmetics, drugs, and plastics. Biological production using propionibacteria would be competitive against chemical production through hydrocarboxylation of ethylene if native producers could be engineered to reach near-theoretical yield and good productivity. Unfortunately, engineering propionibacteria has proven very challenging. It has been suggested that activation of the sleeping beauty operon in Escherichia coli is sufficient to achieve propionic acid production. Optimising E. coli production should be much easier than engineering propionibacteria if tolerance issues can be addressed.ResultsPropionic acid is produced in E. coli via the sleeping beauty mutase operon under anaerobic conditions in rich medium via amino acid degradation. We observed that the sbm operon enhances amino acids degradation to propionic acid and allows E. coli to degrade isoleucine. However, we show here that the operon lacks an epimerase reaction that enables propionic acid production in minimal medium containing glucose as the sole carbon source. Production from glucose can be restored by engineering the system with a methylmalonyl-CoA epimerase from Propionibacterium acidipropionici (0.23 ± 0.02 mM). 1-Propanol production was also detected from the promiscuous activity of the native alcohol dehydrogenase (AdhE). We also show that aerobic conditions are favourable for propionic acid production. Finally, we increase titre 65 times using a combination of promoter engineering and process optimisation.ConclusionsThe native sbm operon encodes an incomplete pathway. Production of propionic acid from glucose as sole carbon source is possible when the pathway is complemented with a methylmalonyl-CoA epimerase. Although propionic acid via the restored succinate dissimilation pathway is considered a fermentative process, the engineered pathway was shown to be functional under anaerobic and aerobic conditions.
Highlights
Propionic acid is used primarily as a food preservative with smaller applications as a chemical build‐ ing block for the production of many products including fabrics, cosmetics, drugs, and plastics
Traces of succinate were produced as a result of lysine and methionine biosynthesis
Since propionic acid (PA) is permeable to the E. coli membrane [32], we added an export mechanism
Summary
Propionic acid is used primarily as a food preservative with smaller applications as a chemical build‐ ing block for the production of many products including fabrics, cosmetics, drugs, and plastics. Native PA producers, such as propionibacteria, can produce PA as their primary fermentation product achieving high yields. These organisms exhibit slow growth, require fastidious nutrient media for growth and lack reliable tools for metabolic engineering. A few examples exist in the literature and these typically result in modest improvements and occur in lower producing native producers that are easier to engineer, such as P. shermanii [7, 8]. These improved strains are still inferior to the best native producers. Heterologous production of PA represents an attractive alternative to overcome limitations in metabolic engineering of native producers and offers a valuable tool to test rational hypotheses that cannot be tested in native producers due to our inability to engineer them [6]
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