Effect of reversible reactions on isotope label redistribution

Follstad, Brian D.; Stephanopoulos, Gregory

doi:10.1046/j.1432-1327.1998.2520360.x

Cited by 65 publications

(63 citation statements)

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“…In the network formed by glycolysis and OPPP, cyclic fluxes and reversible reactions cause the redistribution of label among different intermediates in ways that are not easily understood by inspection of labeling patterns (30,65). Computer-aided modeling is needed if 13 C label at multiple carbon positions is to be quantitatively interpreted (37,66).…”

Section: Modeling the Metabolic Networkmentioning

confidence: 99%

A Flux Model of Glycolysis and the Oxidative Pentosephosphate Pathway in Developing Brassica napus Embryos

Schwender

Ohlrogge

Shachar‐Hill

2003

Journal of Biological Chemistry

240

252

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Computer simulation of the steady state distribution of isotopomers in intermediates of the glycolysis/OPPP network was used to fit metabolic flux parameters to the experimental data. The observed distribution of label in cytosolic and plastidic metabolites indicated that key intermediates of glycolysis and OPPP have similar labeling in these two compartments, suggesting rapid exchange of metabolites between these compartments compared with net fluxes into end products. Cycling between hexose phosphate and triose phosphate and reversible transketolase velocity were similar to net glycolytic flux, whereas reversible transaldolase velocity was minimal. Flux parameters were overdetermined by analyzing labeling in different metabolites and by using data from different labeling experiments, which increased the reliability of the findings. Net flux of glucose through the OPPP accounts for close to 10% of the total hexose influx into the embryo. Therefore, the reductant produced by the OPPP accounts for at most 44% of the NADPH and 22% of total reductant needed for fatty acid synthesis.Brassica napus (rapeseed, canola) is one of the world's major oilseed crops and is also a well studied model for oilseed metabolism (1-21). The main storage compounds in seeds of B. napus are oil (triacylglycerols) and storage proteins, which are derived from sugars and amino acids taken up from the surrounding endosperm liquid (11,12,22,23). Because of its high oil content and ease of genetic transformation, B. napus has also been a target for metabolic engineering of oil metabolism. However, some attempts to engineer plant oils have had limited success (for a review, see Ref. 24). In order to make advances in improving oil yield and quality, a more detailed understanding of metabolism during seed development is needed. In particular, a number of fundamental metabolic issues remain unresolved. These include the source(s) of reductant and ATP for fatty acid synthesis; the degree to which cytosolic, plastidial, and mitochondrial metabolic fluxes are integrated; and the chief metabolic and transport route(s) by which carbon flows from maternal sources to seed storage products.

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Section: Modeling the Metabolic Networkmentioning

confidence: 99%

A Flux Model of Glycolysis and the Oxidative Pentosephosphate Pathway in Developing Brassica napus Embryos

Schwender

Ohlrogge

Shachar‐Hill

2003

Journal of Biological Chemistry

240

252

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“…In addition, reduced levels of TAL result in increased G6PD and 6PGD activities, and increased GSH levels, with inhibition of apoptosis. The impact of TAL on apoptotic signaling (23) may be related to an overwhelming influence of TALcatalyzed dihydroxyacetone transfer reactions on the distribution of flux between the PPP and nucleotide metabolism which determines overall propagation of biochemical signals in the context of a metabolic network (43,65). TAL activity has a dominant influence on the balance between the two branches of PPP (23) and, therefore controls intracellular NADPH levels and neutralization of ROIs (43).…”

Section: Regulation Of the Ppp And Apoptosis By Talmentioning

confidence: 99%

The pathogenesis of transaldolase deficiency

Perl¹

2007

IUBMB Life

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SummaryThe signaling networks that mediate cell growth, differentiation, and survival are dependent on complex metabolic and redox pathways. Metabolism of glucose through the pentose phosphate pathway (PPP) fulfills two unique functions: formation of ribose 5-phosphate for the synthesis of nucleotides, RNA, and DNA in support cell growth and formation of NADPH for biosynthetic reactions and neutralization of reactive oxygen intermediates (ROI). Balancing of NADPH and ROI levels by the PPP enzyme transaldolase (TAL) regulates the mitochondrial trans-membrane potential (Dw m ), a critical checkpoint of ATP synthesis and cell survival. While complete deficiency of glucose 6-phosphate dehydrogenase (G6PD) or transketolase (TK) is lethal, TAL-deficient mice developed normally with the exception of male sterility due to structural and functional damage of sperm cell mitochondria. Recently, two cases of complete TAL deficiency have been reported in patients with liver cirrhosis which results from increased cell death of hepatocytes. Delineation of the cell type-specific role that TAL plays in the PPP and cell death signal processing will be critical for understanding the pathogenesis of TAL deficiency.

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“…This reduction is often applied to the hexose 6-phosphate pools (g6p and f6p) in the glycolysis and the pentose 5-phosphate pools (ru5p, x5p, r5p) in the pentose phosphate pathway (e.g. Schmidt et al, 1997;Follstad and Stephanopoulos, 1998). Lumping g6p and f6p and lumping ru5p, x5p and r5p further simplifies the metabolic reaction network of Fig.2 to the reduced version shown in Fig.3.…”

Section: Lumping Equilibrium Poolsmentioning

confidence: 99%

“…Bondomers of a given compound are denoted by an abbreviation of the compound and a binary subscript. Whereas in isotopomer notation the binary subscript '0' denotes a 12 C-atom and a '1' a 13 C-atom (Schmidt et al, 1997), in bondomer notation '0' denotes a C-C bond that has been formed in one of the metabolic reactions and '1' denotes a C-C bond that was already present in the medium substrate molecule. A linear or branched molecule that has a backbone of n carbon atoms has n-1 C-C bonds.…”

Section: Bondomer Balancingmentioning

confidence: 99%

“…Metabolic reaction rates are subsequently determined by fitting the labeling measurements with a model of the metabolic reaction network wherein the reaction rates are the free variables. A mathematical model for this system traditionally consists of a set of balances for all isotopomers of each metabolite in the reaction network (Schmidt et al, 1997). Isotopomers are chemically identical molecules that only vary with respect to their 12 C and 13 C-distribution.…”

Section: Introductionmentioning

confidence: 99%

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Efficient modeling of 13C-labeling distributions in microorganisms

Winden

Verheijen

Heijnen

2003

Computer Aided Chemical Engineering

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Metabolic networks can be analysed using 2D [ 13 C, 1 H] COSY (NMR) measurements of 13 C-labeled metabolites. A framework is presented whereby the steady state reaction rates are deduced from conventional isotopomer balances. This model is reduced by removing redundant nodes and lumping equilibrium pools. Conversion of the balances to the recently introduced bondomer notation further reduces the complexity. When the reduction approaches are applied to the glycolysis and pentose phosphate pathway, the number of equations is reduced by a factor of three without loss of information.

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Effect of reversible reactions on isotope label redistribution

Cited by 65 publications

References 5 publications

A Flux Model of Glycolysis and the Oxidative Pentosephosphate Pathway in Developing Brassica napus Embryos

A Flux Model of Glycolysis and the Oxidative Pentosephosphate Pathway in Developing Brassica napus Embryos

The pathogenesis of transaldolase deficiency

Efficient modeling of 13C-labeling distributions in microorganisms

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