In vitro production of n-butanol from glucose.

The heat treatment of recombinant mesophiles having heterologous thermotolerant enzymes results in the one-step preparation of highly selective biocatalytic modules. The assembly of these modules enables us to readily construct an artificial metabolic pathway in vitro. In this work, we constructed a non-natural, cofactor-balanced, and oxygen-insensitive pathway for n-butanol production using 16 thermotolerant enzymes. The whole pathway was divided into 7 parts, in each of which NAD(H)-dependent enzymes were assigned to be the last step, and the fluxes through each part were spectrophotometrically determined. This real-time monitoring technique enabled the experimental optimization of enzyme level to achieve a desired production rate. Through the optimized pathway, n-butanol could be produced from glucose with a molar yield of 82% at a rate of 8.2 µmol l(-1) min(-1). Our approach would be widely applicable to the rational optimization of artificial metabolic pathways as well as to the in vitro production of value-added biomolecules.