Metabolic engineering of<i>Saccharomyces cerevisiae</i>âfor production of carboxylic acids: current status and challenges

Abbott, Derek A.; Zelle, Rintze M.; Pronk, Jack T.; Maris, Antonius J. A. van

doi:10.1111/j.1567-1364.2009.00537.x

Cited by 145 publications

(118 citation statements)

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“…Equilibrium ratios were calculated on the assumption that all three compounds are exported via monoanion proton symport, on a proton motive force across the yeast plasma membrane of Ϫ150 mV and an intracellular pH of 7 and on the following acid dissociation (pK a ) constants: malate, 3.46 and 5.10; pyruvate, 2.39; succinate, 4.16 and 5.61. Calculations were performed as described earlier (1,43 Not only does the culture pH impact the thermodynamics of product export, but also it has been reported that a low extracellular pH, combined with the presence of organic acids, can decrease the cytosolic pH (11,28). With a pK a of 6.35, the equilibrium between carbon dioxide and bicarbonate would be strongly influenced by changes in the intracellular pH.…”

Section: Discussionmentioning

confidence: 99%

Key Process Conditions for Production of C ₄ Dicarboxylic Acids in Bioreactor Batch Cultures of an Engineered Saccharomyces cerevisiae Strain

Zelle

Hulster

Kloezen

et al. 2010

Appl Environ Microbiol

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A recent effort to improve malic acid production by Saccharomyces cerevisiae by means of metabolic engineering resulted in a strain that produced up to 59 g liter ؊1 of malate at a yield of 0.42 mol (mol glucose) ؊1 in calcium carbonate-buffered shake flask cultures. With shake flasks, process parameters that are important for scaling up this process cannot be controlled independently. In this study, growth and product formation by the engineered strain were studied in bioreactors in order to separately analyze the effects of pH, calcium, and carbon dioxide and oxygen availability. A near-neutral pH, which in shake flasks was achieved by adding CaCO 3 , was required for efficient C 4 dicarboxylic acid production. Increased calcium concentrations, a side effect of CaCO 3 dissolution, had a small positive effect on malate formation. Carbon dioxide enrichment of the sparging gas (up to 15% [vol/vol]) improved production of both malate and succinate. At higher concentrations, succinate titers further increased, reaching 0.29 mol (mol glucose) ؊1, whereas malate formation strongly decreased. Although fully aerobic conditions could be achieved, it was found that moderate oxygen limitation benefitted malate production. In conclusion, malic acid production with the engineered S. cerevisiae strain could be successfully transferred from shake flasks to 1-liter batch bioreactors by simultaneous optimization of four process parameters (pH and concentrations of CO 2 , calcium, and O 2 ). Under optimized conditions, a malate yield of 0.48 ؎ 0.01 mol (mol glucose) ؊1 was obtained in bioreactors, a 19% increase over yields in shake flask experiments.

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Section: Discussionmentioning

confidence: 99%

Key Process Conditions for Production of C ₄ Dicarboxylic Acids in Bioreactor Batch Cultures of an Engineered Saccharomyces cerevisiae Strain

Zelle

Hulster

Kloezen

et al. 2010

Appl Environ Microbiol

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“…Escherichia coli and yeasts have proven to be excellent biocatalysts for metabolic engineering (11,12). However, both are inhibited by furan aldehydes (7,8,(13)(14)(15) and both contain NADPH-dependent oxidoreductases that convert furfural and hydroxymethylfurfural (dehydration product of hexose sugars) into less toxic alcohols (15)(16)(17).…”

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confidence: 99%

Engineering furfural tolerance in Escherichia coli improves the fermentation of lignocellulosic sugars into renewable chemicals

Wang

Yomano

Lee

et al. 2013

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

170

130

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Pretreatments such as dilute acid at elevated temperature are effective for the hydrolysis of pentose polymers in hemicellulose and also increase the access of enzymes to cellulose fibers. However, the fermentation of resulting syrups is hindered by minor reaction products such as furfural from pentose dehydration. To mitigate this problem, four genetic traits have been identified that increase furfural tolerance in ethanol-producing Escherichia coli LY180 (strain W derivative): increased expression of fucO, ucpA, or pntAB and deletion of yqhD. Plasmids and integrated strains were used to characterize epistatic interactions among traits and to identify the most effective combinations. Furfural resistance traits were subsequently integrated into the chromosome of LY180 to construct strain XW129 (LY180 ΔyqhD ackA::P yadC′ fucO-ucpA) for ethanol. This same combination of traits was also constructed in succinate biocatalysts (Escherichia coli strain C derivatives) and found to increase furfural tolerance. Strains engineered for resistance to furfural were also more resistant to the mixture of inhibitors in hemicellulose hydrolysates, confirming the importance of furfural as an inhibitory component. With resistant biocatalysts, product yields (ethanol and succinate) from hemicellulose syrups were equal to control fermentations in laboratory media without inhibitors. The combination of genetic traits identified for the production of ethanol (strain W derivative) and succinate (strain C derivative) may prove useful for other renewable chemicals from lignocellulosic sugars.lignocellulose | metabolic engineering

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“…Additional advantages of this organism are that its genome has been fully sequenced and that it is considered by the American Food and Drug Administration (FDA) as an organism generally regarded as safe (GRAS) (6). In addition, in several recent studies, the yeast S. cerevisiae has been proposed as a cell factory for the production of bulk chemicals, such as malic, lactic, and citric acid from renewable substrates (1,30,36,42,43).…”

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pH-Dependent Uptake of Fumaric Acid in Saccharomyces cerevisiae under Anaerobic Conditions

Jamalzadeh

Verheijen

Heijnen

et al. 2012

Appl Environ Microbiol

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Microbial production of C 4 dicarboxylic acids from renewable resources has gained renewed interest. The yeast Saccharomyces cerevisiae is known as a robust microorganism and is able to grow at low pH, which makes it a suitable candidate for biological production of organic acids. However, a successful metabolic engineering approach for overproduction of organic acids requires an incorporation of a proper exporter to increase the productivity. Moreover, low-pH fermentations, which are desirable for facilitating the downstream processing, may cause back diffusion of the undissociated acid into the cells with simultaneous active export, thereby creating an ATP-dissipating futile cycle. In this work, we have studied the uptake of fumaric acid in S. cerevisiae in carbon-limited chemostat cultures under anaerobic conditions. The effect of the presence of fumaric acid at different pH values (3 to 5) has been investigated in order to obtain more knowledge about possible uptake mechanisms. The experimental results showed that at a cultivation pH of 5.0 and an external fumaric acid concentration of approximately 0.8 mmol · liter ؊1 , the fumaric acid uptake rate was unexpectedly high and could not be explained by diffusion of the undissociated form across the plasma membrane alone. This could indicate the presence of protein-mediated import. At decreasing pH levels, the fumaric acid uptake rate was found to increase asymptotically to a maximum level. Although this observation is in accordance with proteinmediated import, the presence of a metabolic bottleneck for fumaric acid conversion under anaerobic conditions could not be excluded.

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Metabolic engineering ofSaccharomyces cerevisiaeâfor production of carboxylic acids: current status and challenges

Cited by 145 publications

References 121 publications

Key Process Conditions for Production of C ₄ Dicarboxylic Acids in Bioreactor Batch Cultures of an Engineered Saccharomyces cerevisiae Strain

Key Process Conditions for Production of C ₄ Dicarboxylic Acids in Bioreactor Batch Cultures of an Engineered Saccharomyces cerevisiae Strain

Engineering furfural tolerance in Escherichia coli improves the fermentation of lignocellulosic sugars into renewable chemicals

pH-Dependent Uptake of Fumaric Acid in Saccharomyces cerevisiae under Anaerobic Conditions

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Metabolic engineering ofSaccharomyces cerevisiaeâfor production of carboxylic acids: current status and challenges

Cited by 145 publications

References 121 publications

Key Process Conditions for Production of C 4 Dicarboxylic Acids in Bioreactor Batch Cultures of an Engineered Saccharomyces cerevisiae Strain

Key Process Conditions for Production of C 4 Dicarboxylic Acids in Bioreactor Batch Cultures of an Engineered Saccharomyces cerevisiae Strain

Engineering furfural tolerance in Escherichia coli improves the fermentation of lignocellulosic sugars into renewable chemicals

pH-Dependent Uptake of Fumaric Acid in Saccharomyces cerevisiae under Anaerobic Conditions

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Metabolic engineering ofSaccharomyces cerevisiaeâfor production of carboxylic acids: current status and challenges

Key Process Conditions for Production of C ₄ Dicarboxylic Acids in Bioreactor Batch Cultures of an Engineered Saccharomyces cerevisiae Strain

Key Process Conditions for Production of C ₄ Dicarboxylic Acids in Bioreactor Batch Cultures of an Engineered Saccharomyces cerevisiae Strain