He Pinjing, Han Wenhao, Shao Liming, Lü Fan
State Key Laboratory of Pollution Control and Resource Reuse, Tongji University, Shanghai, 200092 People's Republic of China.
Institute of Waste Treatment and Reclamation, Tongji University, Shanghai, 200092 People's Republic of China.
Biotechnol Biofuels. 2018 Jan 9;11:4. doi: 10.1186/s13068-017-1005-8. eCollection 2018.
This study aimed at producing C6-C8 medium-chain carboxylates (MCCAs) directly from gaseous CO using mixed culture. The yield and C2-C8 product composition were investigated when CO was continuously fed with gradually increasing partial pressure.
The maximal concentrations of -caproate, -heptylate, and -caprylate were 1.892, 1.635, and 1.033 mmol L, which were achieved at the maximal production rates of 0.276, 0.442, and 0.112 mmol L day, respectively. Microbial analysis revealed that long-term acclimation and high CO partial pressure were important to establish a CO-tolerant and CO-utilizing chain-elongating microbiome, rich in , and Rhodobacteraceae and capable of forming MCCAs solely from CO.
These results demonstrated that carboxylate and syngas platform could be integrated in a shared growth vessel, and could be a promising one-step technique to convert gaseous syngas to preferable liquid biochemicals, thereby avoiding the necessity to coordinate syngas fermentation to short-chain carboxylates and short-to-medium-chain elongation. Thus, this method could provide an alternative solution for the utilization of waste-derived syngas and expand the resource of promising biofuels.
本研究旨在利用混合培养物直接从气态一氧化碳生产C6 - C8中链羧酸盐(MCCAs)。当以逐渐增加的分压连续供给一氧化碳时,研究了其产量和C2 - C8产物组成。
己酸盐、庚酸盐和辛酸盐的最大浓度分别为1.892、1.635和1.033 mmol/L,分别在最大生产率0.276、0.442和0.112 mmol/L·天达到。微生物分析表明,长期驯化和高一氧化碳分压对于建立一个耐一氧化碳且利用一氧化碳的链延长微生物群落很重要,该群落富含梭菌属、芽孢杆菌属和红杆菌科,并且能够仅从一氧化碳形成MCCAs。
这些结果表明,羧酸盐和合成气平台可以整合在一个共享的生长容器中,并且可能是一种将气态合成气转化为更优质液体生化物质的有前景的一步技术,从而避免了协调合成气发酵为短链羧酸盐以及短链到中链延长的必要性。因此,该方法可以为利用废弃物衍生的合成气提供一种替代解决方案,并扩大有前景的生物燃料资源。
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