Metabolic Impact of Increased NADH Availability in
            <i>Saccharomyces cerevisiae</i>

Hou, Jin; Scalcinati, Gionata; Oldiges, Marco; Vemuri, Goutham N.

doi:10.1128/aem.02040-09

Cited by 46 publications

(37 citation statements)

References 40 publications

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“…Thus, the NAD ϩ level and the NADH/NAD ϩ ratio determine the metabolic fluxes of many pathways as well as the transcriptional level of many genes in vivo (13,14). For example, a high NADH/ NAD ϩ ratio triggers overflow metabolism (33), and a low NADH/NAD ϩ ratio enhances the glycolytic flux (38).…”

Section: Nad (Nadmentioning

confidence: 99%

Determining the Extremes of the Cellular NAD(H) Level by Using an Escherichia coli NAD ⁺ -Auxotrophic Mutant

Zhou

Wang

Yang

et al. 2011

Appl Environ Microbiol

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NAD (NAD؉ ) and its reduced form (NADH) are omnipresent cofactors in biological systems. However, it is difficult to determine the extremes of the cellular NAD(H) level in live cells because the NAD ؉ level is tightly controlled by a biosynthesis regulation mechanism. Here, we developed a strategy to determine the extreme NAD(H) levels in Escherichia coli cells that were genetically engineered to be NAD ؉ auxotrophic. First, we expressed the ntt4 gene encoding the NAD(H) transporter in the E. coli mutant YJE001, which had a deletion of the nadC gene responsible for NAD ؉ de novo biosynthesis, and we showed NTT4 conferred on the mutant strain better growth in the presence of exogenous NAD ؉ . We then constructed the NAD ؉ -auxotrophic mutant YJE003 by disrupting the essential gene nadE, which is responsible for the last step of NAD ؉ biosynthesis in cells harboring the ntt4 gene. The minimal NAD ؉ level was determined in M9 medium in proliferating YJE003 cells that were preloaded with NAD ؉ , while the maximal NAD(H) level was determined by exposing the cells to high concentrations of exogenous NAD(H). Compared with supplementation of NADH, cells grew faster and had a higher intracellular NAD(H) level when NAD ؉ was fed. The intracellular NAD(H) level increased with the increase of exogenous NAD ؉ concentration, until it reached a plateau. Thus, a minimal NAD(H) level of 0.039 mM and a maximum of 8.49 mM were determined, which were 0.044؋ and 9.6؋ those of wild-type cells, respectively. Finally, the potential application of this strategy in biotechnology is briefly discussed.

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Section: Nad (Nadmentioning

confidence: 99%

Determining the Extremes of the Cellular NAD(H) Level by Using an Escherichia coli NAD ⁺ -Auxotrophic Mutant

Zhou

Wang

Yang

et al. 2011

Appl Environ Microbiol

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“…Many studies have reported to change the intracellular redox level with cofactor engineering for redistribution of metabolic flux and increase of product yield. [29][30][31][32] These progresses provided an insight into the development of ORP control strategies at genetic engineering levels for increasing the yield of desired products. In this study, from the standpoint of process engineering, genetically encoded NADH biosensor implied that intracellular redox conditions would be significantly influenced by extracellular ORP environment, as well as cell growth and metabolism were dependent on different optimal ORP levels in the production of microaerobic L-lactic acid by L. paracasei.…”

Section: Effects Of Redox Environment On L-lactic Acid Production Dirmentioning

confidence: 98%

The effect of redox environment on l -lactic acid production by Lactobacillus paracasei —A proof by genetically encoded in vivo NADH biosensor

Tian

Zhang

Yang

et al. 2015

Process Biochemistry

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“…It has also been demonstrated that the ethanol overflow in Sacch. cerevisiae is related to a redox imbalance in the mitochondria (Hou et al, 2009;Hou et al, 2010). Deken (1966a) observed that under critical values, an exponentially growing yeast could proceed the degradation of carbohydrate through fermentation and respiration simultaneously.…”

Section: Introductionmentioning

confidence: 99%

Production of functional killer protein in batch cultures upon a shift from aerobic to anaerobic conditions

Silva

Poli

Poletto

et al. 2011

Braz. arch. biol. technol.

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Metabolic Impact of Increased NADH Availability in Saccharomyces cerevisiae

Cited by 46 publications

References 40 publications

Determining the Extremes of the Cellular NAD(H) Level by Using an Escherichia coli NAD ⁺ -Auxotrophic Mutant

Determining the Extremes of the Cellular NAD(H) Level by Using an Escherichia coli NAD ⁺ -Auxotrophic Mutant

The effect of redox environment on l -lactic acid production by Lactobacillus paracasei —A proof by genetically encoded in vivo NADH biosensor

Production of functional killer protein in batch cultures upon a shift from aerobic to anaerobic conditions

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Metabolic Impact of Increased NADH Availability in Saccharomyces cerevisiae

Cited by 46 publications

References 40 publications

Determining the Extremes of the Cellular NAD(H) Level by Using an Escherichia coli NAD + -Auxotrophic Mutant

Determining the Extremes of the Cellular NAD(H) Level by Using an Escherichia coli NAD + -Auxotrophic Mutant

The effect of redox environment on l -lactic acid production by Lactobacillus paracasei —A proof by genetically encoded in vivo NADH biosensor

Production of functional killer protein in batch cultures upon a shift from aerobic to anaerobic conditions

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Determining the Extremes of the Cellular NAD(H) Level by Using an Escherichia coli NAD ⁺ -Auxotrophic Mutant

Determining the Extremes of the Cellular NAD(H) Level by Using an Escherichia coli NAD ⁺ -Auxotrophic Mutant