Metabolic engineering of clostridia for the production of chemicals

Cho, Changhee; Jang, Yu‐Sin; Moon, Hyeon Gi; Lee, Joungmin; Lee, Sang Yup

doi:10.1002/bbb.1531

Cited by 47 publications

(33 citation statements)

References 177 publications

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“…Each microorganism can be optimized for its purpose, for example, through genetic engineering, without the need to consider additional tradeoffs imposed by the other process, and there are numerous efforts to engineer homoacetogenic microorganisms to produce, for example, ethanol, butanol and isobutanol (Köpke et al, 2010;Leang et al, 2013;Banerjee et al, 2014;Cho et al, 2015); (2) Only the electron uptaking strain has to contact the cathode while end product formation can proceed in the bulk liquid, which allows better use of the volume of the cathode compartment; (3) two microbial organisms adapt to each other's metabolic capabilities via a thermodynamic-kinetic feedback loop resulting in an optimized metabolic flux without accumulation of intermediates. In addition, mixed communities are often reported to show higher electron transfer rates or higher current efficiencies than pure cultures (Dinh et al, 2004;Nevin et al, 2008;Call et al, 2009;Fast and Papoutsakis, 2012;Ganigue et al, 2015).…”

Section: Efficient Interspecies Hydrogen Transfer In Mixed Electrosynmentioning

confidence: 99%

Enhanced microbial electrosynthesis by using defined co-cultures

2016

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Microbial uptake of free cathodic electrons presents a poorly understood aspect of microbial physiology. Uptake of cathodic electrons is particularly important in microbial electrosynthesis of sustainable fuel and chemical precursors using only CO 2 and electricity as carbon, electron and energy source. Typically, large overpotentials (200 to 400 mV) were reported to be required for cathodic electron uptake during electrosynthesis of, for example, methane and acetate, or low electrosynthesis rates were observed. To address these limitations and to explore conceptual alternatives, we studied defined co-cultures metabolizing cathodic electrons. The Fe(0)-corroding strain IS4 was used to catalyze the electron uptake reaction from the cathode forming molecular hydrogen as intermediate, and Methanococcus maripaludis and Acetobacterium woodii were used as model microorganisms for hydrogenotrophic synthesis of methane and acetate, respectively. The IS4-M. maripaludis co-cultures achieved electromethanogenesis rates of 0.1-0.14 μmol cm − 2 h − 1 at − 400 mV vs standard hydrogen electrode and 0.6-0.9 μmol cm − 2 h − 1 at − 500 mV. Co-cultures of strain IS4 and A. woodii formed acetate at rates of 0.21-0.23 μmol cm − 2 h − 1 at − 400 mV and 0.57-0.74 μmol cm − 2 h − 1 at − 500 mV. These data show that defined co-cultures coupling cathodic electron uptake with synthesis reactions via interspecies hydrogen transfer may lay the foundation for an engineering strategy for microbial electrosynthesis.

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Section: Efficient Interspecies Hydrogen Transfer In Mixed Electrosynmentioning

confidence: 99%

Enhanced microbial electrosynthesis by using defined co-cultures

2016

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“…C. acetobutylicum is a promising platform strain for the production of important chemicals and biofuels (Cho et al, ; Tracy, ; Tracy et al, ). Recent studies have focused on metabolic engineering of C. acetobutylicum using mobile group II introns to knock out genes of interest in strain development (Jang et al, , ; Lehmann and Lutke‐Eversloh, ).…”

Section: Discussionmentioning

confidence: 99%

Efficient gene knockdown in Clostridium acetobutylicum by synthetic small regulatory RNAs

Cho

Lee

2016

Biotech & Bioengineering

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Clostridium is considered a promising microbial host for the production of valuable industrial chemicals. However, Clostridium is notorious for the difficulty of genetic manipulations, and consequently metabolic engineering. Thus, much effort has been exerted to develop novel tools for genetic and metabolic engineering of Clostridium strains. Here, we report the development of a synthetic small regulatory RNA (sRNA)-based system for controlled gene expression in Clostridium acetobutylicum, consisting of a target recognition site, MicC sRNA scaffold, and an RNA chaperone Hfq. To examine the functional operation of sRNA system in C. acetobutylicum, expression control was first examined with the Evoglow fluorescent protein as a model protein. Initially, a C. acetobutylicum protein annotated as Hfq was combined with the synthetic sRNA based on the Escherichia coli MicC scaffold to knockdown Evoglow expression. However, C. acetobutylicum Hfq did not bind to E. coli MicC, while MicC scaffold-based synthetic sRNA itself was able to knockdown the expression of Evoglow. When E. coli hfq gene was introduced, the knockdown efficiency assessed by measuring fluorescence intensity, could be much enhanced. Then, this E. coli MicC scaffold-Hfq system was used to knock down adhE1 gene expression in C. acetobutylicum. Knocking down the adhE1 gene expression using the synthetic sRNA led to a 40% decrease in butanol production (2.5 g/L), compared to that (4.5 g/L) produced by the wild-type strain harboring an empty vector. The sRNA system was further extended to knock down the pta gene expression in the buk mutant C. acetobutylicum strain PJC4BK for enhanced butanol production. The PJC4BK (pPta-Hfq ) strain, which has the pta gene expression knocked down, was able to produce 16.9 g/L of butanol, which is higher than that (14.9 g/L) produced by the PJC4BK strain, mainly due to reduced acetic acid production. Fed-batch culture of PJC4BK (pPta-Hfq ) strain coupled with in situ gas stripping produced 105.5 g of total solvents (70.7 g butanol, 20.5 g acetone, and 14.3 g ethanol), demonstrating that the sRNA-based engineered C. acetobutylicum strain can be cultured without instability. The synthetic sRNA system reported in this study will be useful for more efficient development of engineered C. acetobutylicum strains capable of producing valuable chemicals and fuels. Biotechnol. Bioeng. 2017;114: 374-383. © 2016 Wiley Periodicals, Inc.

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“…In the biotechnology sector, progress has been exploited by Tetravitae Biosciences using an extremely stable and robust mutant strain of C. beijerinckii with high selectivity for the butanol production, reduced product inhibition and the ability to effectively use low-cost cellulosic feedstocks (Barnard et al, 2010;Lee, Kweon, Park & Jin, 2009b). A number of reviews on this topic have recently been published, evidencing the renewed interest in this long neglected subject (Cho et al, 2015;Lütke-Eversloh, 2014;Lütke-Eversloh & Bahl, 2011;Shao et al, 2011).…”

Section: Genetic and Metabolic Engineering Approachesmentioning

confidence: 99%

“…Due to difficulties in genetic manipulation and complex metabolic regulations, metabolic engineering of Clostridia has been poorly developed and only recently made significant advances (Cho, Jang, Moon, Lee, & Lee, 2015). The regulatory mechanisms controlling solventogenesis began to emerge with the analysis of C. acetobutylicum (Nölling et al, 2001).…”

Section: Genetic and Metabolic Engineering Approachesmentioning

confidence: 99%

An integrated approach: advances in the use ofClostridiumfor biofuel

Kök

2015

Biotechnology and Genetic Engineering Reviews

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Almost 90% of our energy comes from fossil fuels, which are both limited and polluting, hence the need to find alternative sources. Biofuels can provide a sustainable and renewable source of energy for the future. Recent significant advances in genetic engineering and fermentation technology have made microbial bio-based production of chemicals from renewable resources more viable. Clostridium species are considered as promising micro-organisms for the production of a wide range of chemicals for industrial use. However, a number of scientific challenges still need to be overcome to facilitate an economically viable production system. These include the use of cheap non-food-based substrates, a better understanding of the metabolic processes involved, improvement of strains through genetic engineering and innovation in process technology. This paper reviews recent developments in these areas, advancing the use of Clostridium within an industrial context especially for the production of biofuels.

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Metabolic engineering of clostridia for the production of chemicals

Cited by 47 publications

References 177 publications

Enhanced microbial electrosynthesis by using defined co-cultures

Enhanced microbial electrosynthesis by using defined co-cultures

Efficient gene knockdown in Clostridium acetobutylicum by synthetic small regulatory RNAs

An integrated approach: advances in the use ofClostridiumfor biofuel

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