Microbial co-culturing systems: butanol production from organic wastes through consolidated bioprocessing

被引:25
作者
Jiang, Yujia [1 ]
Zhang, Ting [1 ]
Lu, Jiasheng [1 ]
Duerre, Peter [3 ]
Zhang, Wenming [1 ,2 ]
Dong, Weiliang [1 ,2 ]
Zhou, Jie [1 ,2 ]
Jiang, Min [1 ,2 ]
Xin, Fengxue [1 ,2 ]
机构
[1] Nanjing Tech Univ, Coll Biotechnol & Pharmaceut Engn, State Key Lab Mat Oriented Chem Engn, Puzhu South Rd 30, Nanjing 211800, Jiangsu, Peoples R China
[2] Nanjing Tech Univ, Jiangsu Natl Synerget Innovat Ctr Adv Mat SICAM, Nanjing 211800, Jiangsu, Peoples R China
[3] Univ Ulm, Inst Microbiol & Biotechnol, D-89069 Ulm, Germany
来源
APPLIED MICROBIOLOGY AND BIOTECHNOLOGY | 2018年 / 102卷 / 13期
基金
中国国家自然科学基金;
关键词
Biobutanol; Microbial co-culture; Starch; Lignocellulose; Syngas; Consolidated bioprocessing; BUTYRIC-ACID PRODUCTION; FIBROUS-BED BIOREACTOR; CLOSTRIDIUM-TYROBUTYRICUM; CRYSTALLINE CELLULOSE; N-BUTANOL; FERMENTATION; THERMOCELLUM; SACCHAROPERBUTYLACETONICUM; CELLULOVORANS; BACTERIA;
D O I
10.1007/s00253-018-8970-0
中图分类号
Q81 [生物工程学(生物技术)]; Q93 [微生物学];
学科分类号
071005 ; 0836 ; 090102 ; 100705 ;
摘要
Biobutanol can be indigenously synthesized by solventogenic Clostridium species; however, these microorganisms possess inferior capability of utilizing abundant and renewable organic wastes, such as starch, lignocellulose, and even syngas. The common strategy to achieve direct butanol production from these organic wastes is through genetic modification of wild-type strains. However, due to the complex of butanol synthetic and hydrolytic enzymes expression systems, the recombinants show unsatisfactory results. Recently, setting up microbial co-culturing systems became more attractive, as they could not only perform more complicated tasks, but also endure changeable environments. Hence, this mini-review comprehensively summarized the state-of-the-art biobutanol production from different substrates by using microbial co-culturing systems. Furthermore, strategies regarding establishment principles of microbial co-culturing systems were also analyzed and compared.
引用
收藏
页码:5419 / 5425
页数:7
相关论文
共 32 条
  • [21] Microbial co-culturing strategies for the production high value compounds, a reliable framework towards sustainable biorefinery implementation - an overview
    Rosero-Chasoy, Gilver
    Rodriguez-Jasso, Rosa M.
    Aguilar, Cristobal N.
    Buitron, German
    Chairez, Isaac
    Ruiz, Hector A.
    [J]. BIORESOURCE TECHNOLOGY, 2021, 321
  • [22] High-efficient n-butanol production by co-culturing Clostridium acetobutylicum and Saccharomyces cerevisiae integrated with butyrate fermentative supernatant addition
    Luo, Hongzhen
    Zeng, Qingwei
    Han, Shuo
    Wang, Zhaoyu
    Dong, Qing
    Bi, Yanhong
    Zhao, Yuping
    [J]. WORLD JOURNAL OF MICROBIOLOGY & BIOTECHNOLOGY, 2017, 33 (04)
  • [23] Co-culturing of probiotics influences the microbial and physico-chemical properties but not sensory quality of fermented dairy drink made from goats' milk
    Ranadheera, C. Senaka
    Evans, Craig A.
    Adams, Michelle
    Baines, Surinder K.
    [J]. SMALL RUMINANT RESEARCH, 2016, 136 : 104 - 108
  • [24] Consolidated Bioprocessing Using Clostridium thermocellum and Thermoanaerobacterium thermosaccharolyticum Co-culture for Enhancing Ethanol Production from Corn Straw
    Pang, Jian
    Hao, Min
    Li, Yongli
    Liu, Jianguo
    Lan, Hui
    Zhang, Yongfeng
    Zhang, Qiancheng
    Liu, Zhanying
    [J]. BIORESOURCES, 2018, 13 (04): : 8209 - 8221
  • [25] Understanding the Dynamics of the Saccharomyces cerevisiae and Scheffersomyces stipitis Abundance in Co-culturing Process for Bioethanol Production from Corn Stover
    Wu, Yilu
    Wen, Jieyi
    Wang, Kang
    Su, Changsheng
    Chen, Changjing
    Cui, Ziheng
    Cai, Di
    Cheng, Shikun
    Cao, Hui
    Qin, Peiyong
    [J]. WASTE AND BIOMASS VALORIZATION, 2023, 14 (01) : 43 - 55
  • [26] Enhanced of High Level of β-xylosidase with β-xylanase Production by Co-culturing of Bacillus Strains from Rice Straw using Response Surface Methodology
    Trakunjae, Chanaporn
    Sukkhum, Sukhumaporn
    Kitpreechavanich, Vichien
    [J]. CHIANG MAI JOURNAL OF SCIENCE, 2015, 42 (04): : 822 - 839
  • [27] Enhanced butanol production from dough and okara waste through co-fermentation
    Su, Guandong
    Wang, Chuansheng
    Tan, Jin Kai
    Zhang, Chen
    He, Jianzhong
    [J]. RENEWABLE ENERGY, 2024, 234
  • [28] Feasibility of biohydrogen production from industrial wastes using defined microbial co-culture
    Chen, Peng
    Wang, Yuxia
    Yan, Lei
    Wang, Yiqing
    Li, Suyue
    Yan, Xiaojuan
    Wang, Ningbo
    Liang, Ning
    Li, Hongyu
    [J]. BIOLOGICAL RESEARCH, 2015, 48 : 1 - 8
  • [29] Consolidated microbial production of four-, five-, and six-carbon organic acids from crop residues: Current status and perspectives
    Son, Jina
    Joo, Jeong Chan
    Baritugo, Kei-Anne
    Jeong, Seona
    Lee, Ji Yeon
    Lim, Hye Jin
    Lim, Seo Hyun
    Yoo, Jee In
    Park, Si Jae
    [J]. BIORESOURCE TECHNOLOGY, 2022, 351
  • [30] The potential of biodiesel production from grasses in Thailand through consolidated bioprocessing using a cellulolytic oleaginous yeast, Cyberlindnera rhodanensis CU-CV7
    Chuengcharoenphanich, Nuttha
    Watsuntorn, Wannapawn
    Qi, Wei
    Wang, Zhongming
    Hu, Yunzi
    Chulalaksananukul, Warawut
    [J]. ENERGY, 2023, 263
1234