Quantitative analysis of an engineered CO2-fixing Escherichia coli reveals great potential of heterotrophic CO2 fixation

Gong, Fuyu; Liu, Guoxia; Zhai, Xiaoyun; Zhou, Jie; Zhang, Cai; Yin, Lei

doi:10.1186/s13068-015-0268-1

Cited by 73 publications

(50 citation statements)

References 58 publications

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“…In order to increase the intracellular CO 2 concentration for PCK‐catalyzed carboxylation reaction, carbonic anhydrase (CA) gene from Synechococcus sp. PCC7002 was amplified from pET‐RBC‐PRK‐BT‐CA and cloned into pTrc99A‐M‐M1‐46 to obtain plasmid pCA. This plasmid was then transformed into Suc‐T110, resulting in strain Suc‐T110(pCA) (Table S2, Supporting Information).…”

Section: Resultsmentioning

confidence: 99%

“…Plasmid backbone was amplified using primer set CPEC‐99AM46‐F/CPEC‐99AM46‐R and was further digested with DpnI to exclude original plasmid DNA of pTrc99A‐M‐M1‐46. Carbonic anhydrase (CA) gene and bicarbonate transporter (BT) gene were both amplified from the plasmid of pET‐RBC‐PRK‐BT‐CA, a gift from Professor Yin Li (Institute of Microbiology, Chinese Academy of Sciences), using primer pairs CPEC‐CA‐F/CPEC‐CA‐R and CPEC‐BT‐F/CPEC‐BT‐R. These two amplified DNA fragments were individually ligated with pTrc99A‐M‐M1‐46 backbone using CPEC, and correct clones were designated as pCA and pBT.…”

Section: Methodsmentioning

confidence: 99%

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Improving Succinate Productivity by Engineering a Cyanobacterial CO₂ Concentrating System (CCM) in Escherichia coli

Xiao

Zhu

et al. 2017

Biotechnology Journal

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Biologically fixation of CO has great potential as a significant carbon source for biosynthesis, which is also a major way to reduce CO accumulation in atmosphere. Phosphoenolpyruvate (PEP) carboxylation is the key step of anaerobic succinate production in Escherichia coli. In this reaction, one mole CO is assimilated with PEP to form oxaloacetate by PEP carboxykinase (PCK). The preferred substrate of PCK is CO , which is very limited in cytoplasm. In this study, the carbon concentration mechanism (CCM) of cyanobacteria was introduced into Escherichia coli to enhance the intracellular inorganic carbon concentration for improving carboxylation velocity. Overexpression of the bicarbonate transporter (BT) or carbonic anhydrase (CA) gene from Synechococcus sp. PCC7002 led to a 22 or 35% increase in succinate titer at 36 h, respectively. The carboxylation rate of PCK increased from 2.46 to 3.92 µmol min mg protein by overexpression of the CA gene. In addition, co-overexpression of BT and CA genes had a synergetic effect, leading to a 44% increase in succinate titer at 36 h. This work is the first attempt to increase carbon fixation involved in microbial biosynthesis by engineering a biological CO delivery system, which provides new direction and strategies for improving industrial fermentations based on biological CO assimilation pathways.

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Improving Succinate Productivity by Engineering a Cyanobacterial CO₂ Concentrating System (CCM) in Escherichia coli

Xiao

Zhu

et al. 2017

Biotechnology Journal

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“…However, these studies were unable to determine the amount of CO2 that had been fixed by the central metabolic pathways. Recently, we have developed a relative quantification method to calculate the ratio of carbon flux from the CO2-fixation pathway and the central metabolic pathway by LC/MS/MS detection of 13 C and unlabeled metabolites (Gong et al, 2015).…”

Section: Design and Relocation Of Co2-fixation Pathwaymentioning

confidence: 99%

“…We recently introduced cyanobacterial carbonic anhydrase, a key enzyme in the cyanobacterial CCM, into E. coli. Improved CO2-fixation efficiency was found in the engineered CO2-fixing E. coli, demonstrating that the CCM can also be transplanted into heterotrophic microbes (Gong et al, 2015). Ideas on introducing the CCM from cyanobacteria or C4 plants into C3 crops to improve the photosynthetic efficiency of the latter (Covshoff and Hibberd, 2012;Price et al, 2011;Price et al, 2013) have been reported, but much research is still needed on the topic.…”

Section: Engineering Of Co2-fixation Pathways Via Increase In Co2 Supplymentioning

confidence: 99%

Synthetic biology for CO2 fixation

Gong

Zhang

2016

Sci. China Life Sci.

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Recycling of carbon dioxide (CO2) into fuels and chemicals is a potential approach to reduce CO2 emission and fossil-fuel consumption. Autotrophic microbes can utilize energy from light, hydrogen, or sulfur to assimilate atmospheric CO2 into organic compounds at ambient temperature and pressure. This provides a feasible way for biological production of fuels and chemicals from CO2 under normal conditions. Recently great progress has been made in this research area, and dozens of CO2-derived fuels and chemicals have been reported to be synthesized by autotrophic microbes. This is accompanied by investigations into natural CO2-fixation pathways and the rapid development of new technologies in synthetic biology. This review first summarizes the six natural CO2-fixation pathways reported to date, followed by an overview of recent progress in the design and engineering of CO2-fixation pathways as well as energy supply patterns using the concept and tools of synthetic biology. Finally, we will discuss future prospects in biological fixation of CO2.carbon dioxide fixation, synthetic biology, CO2-fixation pathway, energy supply Citation:

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“…However, a major limitation of biological C1 conversion is the inefficiency of the natural C1 assimilation pathway such as the Calvin-Benson-Bassham (CBB) cycle (4). To address this problem, extensive studies have been performed to enhance biological C1 assimilation by developing de novo pathways using efficient carboxylases (5)(6)(7)(8)(9), introducing the CBB cycle into Escherichia coli (10)(11)(12)(13), or by integration with an electrochemical method of reducing CO 2 to formic acid (FA) (14,15). FA can be easily and efficiently synthesized from CO 2 by various chemical processes employing metal catalysts (16) or electricity (17).…”

mentioning

confidence: 99%

Assimilation of formic acid and CO ₂ by engineered Escherichia coli equipped with reconstructed one-carbon assimilation pathways

Junho

Lee

2018

Proc. Natl. Acad. Sci. U.S.A.

109

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Gaseous one-carbon (C1) compounds or formic acid (FA) converted from CO can be an attractive raw material for bio-based chemicals. Here, we report the development of strains assimilating FA and CO through the reconstructed tetrahydrofolate (THF) cycle and reverse glycine cleavage (gcv) pathway. The formate-THF ligase, methenyl-THF cyclohydrolase, and methylene-THF dehydrogenase genes were expressed to allow FA assimilation. The gcv reaction was reversed by knocking out the repressor gene () and overexpressing the genes. This engineered strain synthesized 96% and 86% of proteinogenic glycine and serine, respectively, from FA and CO in a glucose-containing medium. Native serine deaminase converted serine to pyruvate, showing 4.5% of pyruvate-forming flux comes from FA and CO The pyruvate-forming flux from FA and CO could be increased to 14.9% by knocking out ,, and , chromosomally expressing under , and overexpressing the reconstructed THF cycle,, and genes in one vector. To reduce glucose usage required for energy and redox generation, the formate dehydrogenase (Fdh) gene was expressed. The resulting strain showed specific glucose, FA, and CO consumption rates of 370.2, 145.6, and 14.9 mg⋅g dry cell weight (DCW)⋅h, respectively. The C1 assimilation pathway consumed 21.3 wt% of FA. Furthermore, cells sustained slight growth using only FA and CO after glucose depletion, suggesting that combined use of the C1 assimilation pathway and Fdh will be useful for eventually developing a strain capable of utilizing FA and CO without an additional carbon source such as glucose.

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Quantitative analysis of an engineered CO2-fixing Escherichia coli reveals great potential of heterotrophic CO2 fixation

Cited by 73 publications

References 58 publications

Improving Succinate Productivity by Engineering a Cyanobacterial CO₂ Concentrating System (CCM) in Escherichia coli

Improving Succinate Productivity by Engineering a Cyanobacterial CO₂ Concentrating System (CCM) in Escherichia coli

Synthetic biology for CO2 fixation

Assimilation of formic acid and CO ₂ by engineered Escherichia coli equipped with reconstructed one-carbon assimilation pathways

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Quantitative analysis of an engineered CO2-fixing Escherichia coli reveals great potential of heterotrophic CO2 fixation

Cited by 73 publications

References 58 publications

Improving Succinate Productivity by Engineering a Cyanobacterial CO2 Concentrating System (CCM) in Escherichia coli

Improving Succinate Productivity by Engineering a Cyanobacterial CO2 Concentrating System (CCM) in Escherichia coli

Synthetic biology for CO2 fixation

Assimilation of formic acid and CO 2 by engineered Escherichia coli equipped with reconstructed one-carbon assimilation pathways

Contact Info

Product

Resources

About

Improving Succinate Productivity by Engineering a Cyanobacterial CO₂ Concentrating System (CCM) in Escherichia coli

Improving Succinate Productivity by Engineering a Cyanobacterial CO₂ Concentrating System (CCM) in Escherichia coli

Assimilation of formic acid and CO ₂ by engineered Escherichia coli equipped with reconstructed one-carbon assimilation pathways