Metabolic Engineering of Ammonium Assimilation in Xylose-Fermenting
            <i>Saccharomyces cerevisiae</i>
            Improves Ethanol Production

Roca, Christophe; Nielsen, Jens; Olsson, Lisbeth

doi:10.1128/aem.69.8.4732-4736.2003

Cited by 93 publications

(58 citation statements)

References 20 publications

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“…Nevertheless, the principal stoichiometric redox problem was not solved (Bruinenberg et al, 1984;Hahn-Hägerdal et al, 2001), and thus xylitol formation will likely remain an inherent property of strains engineered with xylose reductase and xylitol dehydrogenase. Instead, conceptually new metabolic engineering strategies will be necessary such as the use of xylose isomerase (Kuyper et al, 2003;Walfridsson et al, 1996) or new biochemical routes to NADH reoxidation (Roca et al, 2003;Verho et al, 2003). Methods of mutagenesis and selection or more elaborate evolutionary engineering (Sauer, 2001) appear to be the most promising for initial introduction of a novel (Sonderegger and Sauer, 2003) or for improvement of a weak property (Steiner and Sauer, 2003).…”

Section: Discussionmentioning

confidence: 99%

Fermentation performance of engineered and evolved xylose‐fermenting Saccharomyces cerevisiae strains

Sonderegger

Jeppsson

Larsson

et al. 2004

Biotech & Bioengineering

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129

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Lignocellulose hydrolysate is an abundant substrate for bioethanol production. The ideal microorganism for such a fermentation process should combine rapid and efficient conversion of the available carbon sources to ethanol with high tolerance to ethanol and to inhibitory components in the hydrolysate. A particular biological problem are the pentoses, which are not naturally metabolized by the main industrial ethanol producer Saccharomyces cerevisiae. Several recombinant, mutated, and evolved xylose fermenting S. cerevisiae strains have been developed recently. We compare here the fermentation performance and robustness of eight recombinant strains and two evolved populations on glucose/xylose mixtures in defined and lignocellulose hydrolysate-containing medium. Generally, the polyploid industrial strains depleted xylose faster and were more resistant to the hydrolysate than the laboratory strains. The industrial strains accumulated, however, up to 30% more xylitol and therefore produced less ethanol than the haploid strains. The three most attractive strains were the mutated and selected, extremely rapid xylose consumer TMB3400, the evolved C5 strain with the highest achieved ethanol titer, and the engineered industrial F12 strain with by far the highest robustness to the lignocellulosic hydrolysate. B

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Section: Discussionmentioning

confidence: 99%

Fermentation performance of engineered and evolved xylose‐fermenting Saccharomyces cerevisiae strains

Sonderegger

Jeppsson

Larsson

et al. 2004

Biotech & Bioengineering

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129

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“…Only very few manuscripts looking over the engineering of the central nitrogen metabolism of S. cerevisiae have been published [25,27,32,38]. In all these works, the redox intracellular status was unbalanced to decrease glycerol levels and to increase the ethanol production in aerobic or anaerobic batch, using ammonium sulfate as a sole nitrogen source.…”

Section: Discussionmentioning

confidence: 99%

Physiological Effects of GLT1 Modulation in Saccharomyces cerevisiae Strains Growing on Different Nitrogen Sources

Brambilla¹,

Adamo²,

Frascotti³

et al. 2016

Journal of Microbiology and Biotechnology

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“…Expression of XR, XDH, and XK lead to highly inefficient xylose utilization due to a co-factor imbalance, where excess NADH must be regenerated via xylitol production resulting in reduced ethanol yield. Therefore, metabolic engineering of the ammonium assimilation through deletion of the NADPHdependent glutamate dehydrogenase (GDH1) and overexpression of the NADH-dependent glutamate dehydrogenase (GDH2) resulted in a 16% higher ethanol yield due to a 44% xylitol reduction (Grotkjaer et al, 2005;Roca et al, 2003). Using a reverse metabolic engineering approach, metabolic flux analysis (MFA) was used to characterize the intracellular fluxes for both strains based on experimental data of anaerobic continuous cultivations using a growth limited feed of 13 C-labeled glucose, confirming that XR activity shifted from being mostly NADPH to partly NADH dependent in the CPB.CR4 strain.…”

Section: Mature and Developed: Bioethanolmentioning

confidence: 99%

Industrial systems biology

Otero

Nielsen

2009

Biotech & Bioengineering

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134

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ABSTRACT:The chemical industry is currently undergoing a dramatic change driven by demand for developing more sustainable processes for the production of fuels, chemicals, and materials. In biotechnological processes different microorganisms can be exploited, and the large diversity of metabolic reactions represents a rich repository for the design of chemical conversion processes that lead to efficient production of desirable products. However, often microorganisms that produce a desirable product, either naturally or because they have been engineered through insertion of heterologous pathways, have low yields and productivities, and in order to establish an economically viable process it is necessary to improve the performance of the microorganism. Here metabolic engineering is the enabling technology. Through metabolic engineering the metabolic landscape of the microorganism is engineered such that there is an efficient conversion of the raw material, typically glucose, to the product of interest. This process may involve both insertion of new enzymes activities, deletion of existing enzyme activities, but often also deregulation of existing regulatory structures operating in the cell. In order to rapidly identify the optimal metabolic engineering strategy the industry is to an increasing extent looking into the use of tools from systems biology. This involves both x-ome technologies such as transcriptome, proteome, metabolome, and fluxome analysis, and advanced mathematical modeling tools such as genome-scale metabolic modeling. Here we look into the history of these different techniques and review how they find application in industrial biotechnology, which will lead to what we here define as industrial systems biology.

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Metabolic Engineering of Ammonium Assimilation in Xylose-Fermenting Saccharomyces cerevisiae Improves Ethanol Production

Cited by 93 publications

References 20 publications

Fermentation performance of engineered and evolved xylose‐fermenting Saccharomyces cerevisiae strains

Fermentation performance of engineered and evolved xylose‐fermenting Saccharomyces cerevisiae strains

Physiological Effects of GLT1 Modulation in Saccharomyces cerevisiae Strains Growing on Different Nitrogen Sources

Industrial systems biology

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