Ammam Fariza, Tremblay Pier-Luc, Lizak Dawid M, Zhang Tian
The Novo Nordisk Foundation Center for Biosustainability, Technical University of Denmark, 2970 Hørsholm, Denmark.
The Novo Nordisk Foundation Center for Biosustainability, Technical University of Denmark, 2970 Hørsholm, Denmark ; School of Chemistry, Chemical Engineering and Life Science, Wuhan University of Technology, Wuhan, 430070 People's Republic of China.
Biotechnol Biofuels. 2016 Aug 4;9:163. doi: 10.1186/s13068-016-0576-0. eCollection 2016.
Microbial electrosynthesis (MES) and gas fermentation are bioenergy technologies in which a microbial catalyst reduces CO2 into organic carbon molecules with electrons from the cathode of a bioelectrochemical system or from gases such as H2. The acetogen Sporomusa ovata has the capacity of reducing CO2 into commodity chemicals by both gas fermentation and MES. Acetate is often the only product generated by S. ovata during autotrophic growth.
In this study, trace elements in S. ovata growth medium were optimized to improve MES and gas fermentation productivity. Augmenting tungstate concentration resulted in a 2.9-fold increase in ethanol production by S. ovata during H2:CO2-dependent growth. It also promoted electrosynthesis of ethanol in a S. ovata-driven MES reactor and increased acetate production 4.4-fold compared to unmodified medium. Furthermore, fatty acids propionate and butyrate were successfully converted to their corresponding alcohols 1-propanol and 1-butanol by S. ovata during gas fermentation. Increasing tungstate concentration enhanced conversion efficiency for both propionate and butyrate. Gene expression analysis suggested that tungsten-containing aldehyde ferredoxin oxidoreductases (AORs) and a tungsten-containing formate dehydrogenase (FDH) were involved in the improved biosynthesis of acetate, ethanol, 1-propanol, and 1-butanol. AORs and FDH contribute to the fatty acids re-assimilation pathway and the Wood-Ljungdahl pathway, respectively.
This study presented here shows that optimization of microbial catalyst growth medium can improve productivity and lead to the biosynthesis of different products by gas fermentation and MES. It also provides insights on the metabolism of biofuels production in acetogens and demonstrates that S. ovata has an important untapped metabolic potential for the production of other chemicals than acetate via CO2-converting bioprocesses including MES.
微生物电合成(MES)和气体发酵是生物能源技术,其中微生物催化剂利用来自生物电化学系统阴极或诸如氢气等气体的电子将二氧化碳还原为有机碳分子。产乙酸菌卵形芽孢八叠球菌具有通过气体发酵和MES将二氧化碳还原为商品化学品的能力。在自养生长过程中,乙酸通常是卵形芽孢八叠球菌产生的唯一产物。
在本研究中,对卵形芽孢八叠球菌生长培养基中的微量元素进行了优化,以提高MES和气体发酵的生产力。增加钨酸盐浓度导致卵形芽孢八叠球菌在依赖氢气:二氧化碳的生长过程中乙醇产量增加2.9倍。它还促进了卵形芽孢八叠球菌驱动的MES反应器中乙醇的电合成,与未改良培养基相比,乙酸产量增加了4.4倍。此外,在气体发酵过程中,卵形芽孢八叠球菌成功地将丙酸和丁酸脂肪酸转化为相应的醇1-丙醇和1-丁醇。增加钨酸盐浓度提高了丙酸和丁酸的转化效率。基因表达分析表明,含钨的醛铁氧还蛋白氧化还原酶(AORs)和含钨的甲酸脱氢酶(FDH)参与了乙酸、乙醇、1-丙醇和1-丁醇生物合成的改善。AORs和FDH分别有助于脂肪酸重新同化途径和伍德-Ljungdahl途径。
本研究表明,优化微生物催化剂生长培养基可以提高生产力,并通过气体发酵和MES导致不同产物的生物合成。它还提供了关于产乙酸菌中生物燃料生产代谢的见解,并证明卵形芽孢八叠球菌在通过包括MES在内的二氧化碳转化生物过程生产除乙酸以外的其他化学品方面具有重要的未开发代谢潜力。
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