Escherichia coli is the best-established microbial host strain for production of proteins and chemicals, but has a weakness for not secreting high amounts of active heterologous proteins to the extracellular culture medium, of which origins belong to whether prokaryotes or eukaryotes. In this study, Candida antarctica lipase B (CalB), a popular eukaryotic enzyme which catalyzes a number of biochemical reactions and barely secreted extracellularly, was expressed functionally at a gram scale in culture medium by using a simple amino acid-tag system of E. coli. New fusion tag systems consisting of a pelB signal sequence and various anion amino acid tags facilitated both intracellular expression and extracellular secretion of CalB. Among them, the N-terminal five aspartate tag changed the quaternary structure of the dimeric CalB and allowed production of 1.9 g/L active CalB with 65 U/mL activity in culture medium, which exhibited the same enzymatic properties as the commercial CalB. This PelB-anion amino acid tag-based expression system for CalB can be extended to production of other industrial proteins hardly expressed and exported from E. coli, thereby increasing target protein concentrations and minimizing purification steps.
Acetic acid is an abundant material that can be used as a carbon source by microorganisms. Despite its abundance, its toxicity and low energy content make it hard to utilize as a sole carbon source for biochemical production. To increase acetate utilization and isobutanol production with engineered Escherichia coli, the feasibility of utilizing acetate and metabolic engineering was investigated. The expression of acs, pckA, and maeB increased isobutanol production by up to 26%, and the addition of TCA cycle intermediates indicated that the intermediates can enhance isobutanol production. For isobutanol production from acetate, acetate uptake rates and the NADPH pool were not limiting factors compared to glucose as a carbon source. This work represents the first approach to produce isobutanol from acetate with pyruvate flux optimization to extend the applicability of acetate. This technique suggests a strategy for biochemical production utilizing acetate as the sole carbon source.
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