Specific features of changes in levels of endogenous respiration substrates in Saccharomyces cerevisiae cells at low temperature

Aliverdieva, D. A.; Mamaev, D. V.; Lagutina, L S; Sholtz, K. F.

doi:10.1134/s0006297906010056

Cited by 8 publications

(5 citation statements)

References 35 publications

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“…With this strategy, glycine and serine biomass requirements are directly coupled to succinate formation via the glyoxylate cycle. Substantial succinate accumulation (defined as >0.1 g L − 1 ) in the culture broth is not observed in wild-type S. cerevisiae , and deletion of sdh3 has not resulted in appreciable succinate accumulation [17]; a conclusion also found by chemical inhibition of the succinate dehydrogenase complex with titration of malonate (Figure S1), a chemical inhibtor of this complex [18].…”

Section: Resultsmentioning

confidence: 86%

Industrial Systems Biology of Saccharomyces cerevisiae Enables Novel Succinic Acid Cell Factory

et al. 2013

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Saccharomyces cerevisiae is the most well characterized eukaryote, the preferred microbial cell factory for the largest industrial biotechnology product (bioethanol), and a robust commerically compatible scaffold to be exploitted for diverse chemical production. Succinic acid is a highly sought after added-value chemical for which there is no native pre-disposition for production and accmulation in S. cerevisiae. The genome-scale metabolic network reconstruction of S. cerevisiae enabled in silico gene deletion predictions using an evolutionary programming method to couple biomass and succinate production. Glycine and serine, both essential amino acids required for biomass formation, are formed from both glycolytic and TCA cycle intermediates. Succinate formation results from the isocitrate lyase catalyzed conversion of isocitrate, and from the α-keto-glutarate dehydrogenase catalyzed conversion of α-keto-glutarate. Succinate is subsequently depleted by the succinate dehydrogenase complex. The metabolic engineering strategy identified included deletion of the primary succinate consuming reaction, Sdh3p, and interruption of glycolysis derived serine by deletion of 3-phosphoglycerate dehydrogenase, Ser3p/Ser33p. Pursuing these targets, a multi-gene deletion strain was constructed, and directed evolution with selection used to identify a succinate producing mutant. Physiological characterization coupled with integrated data analysis of transcriptome data in the metabolically engineered strain were used to identify 2nd-round metabolic engineering targets. The resulting strain represents a 30-fold improvement in succinate titer, and a 43-fold improvement in succinate yield on biomass, with only a 2.8-fold decrease in the specific growth rate compared to the reference strain. Intuitive genetic targets for either over-expression or interruption of succinate producing or consuming pathways, respectively, do not lead to increased succinate. Rather, we demonstrate how systems biology tools coupled with directed evolution and selection allows non-intuitive, rapid and substantial re-direction of carbon fluxes in S. cerevisiae, and hence show proof of concept that this is a potentially attractive cell factory for over-producing different platform chemicals.

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Section: Resultsmentioning

confidence: 86%

Industrial Systems Biology of Saccharomyces cerevisiae Enables Novel Succinic Acid Cell Factory

et al. 2013

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“…A newly discovered lactate dehydrogenase inhibitor, malonate, a known competitive inhibitor of succinate dehydrogenase, has been shown to inhibit the conversion of lactate to pyruvate by Saad et al (2006). This succinate analog is transported into neurons, astrocytes, and mitochondria via the succinate transporter (Aliverdieva et al, 2006; Yodoya et al, 2006). We used malonate in a set of experiments to test the hypothesis that lactate is the end-product of aerobic glycolysis in cerebral tissue (Schurr and Payne, 2007).…”

Section: Resultsmentioning

confidence: 99%

Aerobic production and utilization of lactate satisfy increased energy demands upon neuronal activation in hippocampal slices and provide neuroprotection against oxidative stress

Schurr

Gozal

2011

fphar

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Ever since it was shown for the first time that lactate can support neuronal function in vitro as a sole oxidative energy substrate, investigators in the field of neuroenergetics have been debating the role, if any, of this glycolytic product in cerebral energy metabolism. Our experiments employed the rat hippocampal slice preparation with electrophysiological and biochemical methodologies. The data generated by these experiments (a) support the hypothesis that lactate, not pyruvate, is the end-product of cerebral aerobic glycolysis; (b) indicate that lactate plays a major and crucial role in affording neural tissue to respond adequately to glutamate excitation and to recover unscathed post-excitation; (c) suggest that neural tissue activation is accompanied by aerobic lactate and NADH production, the latter being produced when the former is converted to pyruvate by mitochondrial lactate dehydrogenase (mLDH); (d) imply that NADH can be utilized as an endogenous scavenger of reactive oxygen species (ROS) to provide neuroprotection against ROS-induced neuronal damage.

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“…The other physiological role of AOX is to prevent the excess generation of reactive oxygen species, which can damage a wide range of macromolecules, leading to cell death (Vanlerberghe et al 2009;Dinakar et al 2010a;Wang et al 2011). Moreover, several studies have demonstrated the existence of a close relationship between the AOX pathway and pyruvate (Pastore et al 2001;Dinakar et al 2010b), which is a key metabolite and can ensure the functioning of the TCA cycle in mitochondria (Aliverdieva et al 2006). Increases in AOX activity correlates well with the increase in intracellular pyruvate levels, and decreased pyruvate levels also lead to decreased AOX protein levels, signifying the importance of pyruvate in activating AOX (Oliver et al 2008;Dinakar et al 2010b).…”

Section: Introductionmentioning

confidence: 99%

“…2010 b ), which is a key metabolite and can ensure the functioning of the TCA cycle in mitochondria (Aliverdieva et al . 2006). Increases in AOX activity correlates well with the increase in intracellular pyruvate levels, and decreased pyruvate levels also lead to decreased AOX protein levels, signifying the importance of pyruvate in activating AOX (Oliver et al .…”

Section: Introductionmentioning

confidence: 99%

Different respiration metabolism between mycorrhizal and non-mycorrhizal rice under low-temperature stress: a cry for help from the host

Liu

Wang

et al. 2014

J. Agric. Sci.

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SUMMARYLow-temperature stress is an important environmental factor that severely disrupts plant respiration but can be alleviated by symbiotic arbuscular mycorrhizal fungi (AMF). In the current study, a pot experiment was performed to determine changes in the respiratory metabolic capacity of mycorrhizal rice (Oryza sativa) under low-temperature stress. The results demonstrated that low temperature might accelerate the biosynthesis of strigolactone in mycorrhizal rice roots by triggering the expression of genes for the synthesis of strigolactone, which acted as a host stress response signal. In addition, AMF prompted the host tricarboxylic acid (TCA) cycle by enhancing pyruvate metabolism, up-regulating the expression of genes of the TCA cycle under low-temperature stress and affecting the electron transport chain. The alternative oxidase pathway might be the main electron transport pathway in non-mycorrhizal rice under stress, while the cytochrome c oxidase (COX) pathway might be the predominant pathway in arbuscular mycorrhizal symbiosis. Mycorrhizal rice also had higher adenosine triphosphate production to maintain the natural status of respiration under stress conditions, which resulted in improved root growth status and alleviated low-temperature stress.

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Specific features of changes in levels of endogenous respiration substrates in Saccharomyces cerevisiae cells at low temperature

Cited by 8 publications

References 35 publications

Industrial Systems Biology of Saccharomyces cerevisiae Enables Novel Succinic Acid Cell Factory

Industrial Systems Biology of Saccharomyces cerevisiae Enables Novel Succinic Acid Cell Factory

Aerobic production and utilization of lactate satisfy increased energy demands upon neuronal activation in hippocampal slices and provide neuroprotection against oxidative stress

Different respiration metabolism between mycorrhizal and non-mycorrhizal rice under low-temperature stress: a cry for help from the host

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