Metabolic and Process Engineering of Clostridium beijerinckii for Butyl Acetate Production in One Step.

n-Butyl acetate is an important food additive commonly produced via concentrated sulfuric acid catalysis or immobilized lipase catalysis of butanol and acetic acid. Compared with chemical methods, an enzymatic approach is more environmentally friendly; however, it incurs a higher cost due to lipase production. In vivo biosynthesis via metabolic engineering offers an alternative to produce n-butyl acetate. This alternative combines substrate production (butanol and acetyl-coenzyme A (acetyl-CoA)), alcohol acyltransferase expression, and esterification reaction in one reactor. The alcohol acyltransferase gene ATF1 from Saccharomyces cerevisiae was introduced into Clostridium beijerinckii NCIMB 8052, enabling it to directly produce n-butyl acetate from glucose without lipase addition. Extractants were compared and adapted to realize glucose fermentation with in situ n-butyl acetate extraction. Finally, 5.57 g/L of butyl acetate was produced from 38.2 g/L of glucose within 48 h, which is 665-fold higher than that reported previously. This demonstrated the potential of such a metabolic approach to produce n-butyl acetate from biomass.

Developing Clostridium diolis as a biorefinery chassis by genetic manipulation.

Clostridium diolis can efficiently utilize various inexpensive, renewable resources such as crude glycerol and lignocellulosic biomass hydrolysate to produce bulk chemicals and fuels. However, its study has been impeded by the lack of efficient plasmids electro-transformation techniques. In this study, an efficient electroporation protocol for C. diolis was developed and two replicons functional in C. diolis were identified. After optimizing parameters, the electro-transformation efficiency was enhanced from 5 to 692 transformants/ug DNA. Moreover, metabolic engineering of C. diolis was performed as proof of concept for the first time. By simply overexpressing heterologous genes based on the replicable plasmids, the strain was engineered to improve productions of diol (1,3-propanediol) and n-alcohol (butanol), and to enable butyl acetate synthesis in vivo, respectively under different culture conditions. This work represented a milestone of breeding C. diolis using metabolic engineering, and paved the way for studying C. diolis on the molecular level.

Facile synthesis of Pt-decorated Ir black as a bifunctional oxygen catalyst for oxygen reduction and evolution reactions.

Pt-Decorated Ir black (Pt@Ir) nanoparticles with two varying Pt mass fractions (Pt4@Ir96 and Pt16@Ir84) were generated by a facile method in water with the aid of Ir black. The Pt@Ir nanoparticles were investigated as a bifunctional oxygen catalysts for both the oxygen reduction reaction (ORR) and oxygen evolution reaction (OER) in acidic medium. Benefiting from the good dispersion of ultrafine Pt nanodots on the Ir black surface and the synergistic effect between the Pt and underlying Ir atoms, Pt@Ir nanoparticles have exhibited outstanding ORR activity and comparable OER performance in comparison with commercial Ir black. In particular, Pt16@Ir84 shows an ORR mass activity of 2.6 times that of commercial Pt black and exhibits much better bifunctional performances than a mixture of Pt black and Ir black with a Ir/Pt mass ratio of 50/50 (Pt50Ir50). Our work highlights the effectiveness of decorating Ir black with Pt nanodots to fabricate bifunctional oxygen catalysts.