Exchange reactions catalyzed by group‐transferring enzymes oppose the quantitation and the unravelling of the identity of the pentose pathway

Flanigan, Ian L.; Collins, J. Grant; Arora, Krishan; MacLeod, John K.; Williams, John F.

doi:10.1111/j.1432-1033.1993.tb17784.x

Cited by 20 publications

(33 citation statements)

References 36 publications

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“…Supporting evidence from the literature was presented, indicating that six additional reactions can take place [16][17][18][19]. Furthermore, van Winden et al [5] demonstrated that the incorporation of these reactions in the metabolic network model of Penicillium chrysogenum significantly increased the goodness-of-fit to measured 13 C-label distribution data and also resulted in a changed flux distribution.…”

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confidence: 78%

Revisiting the ¹³C‐label distribution of the non‐oxidative branch of the pentose phosphate pathway based upon kinetic and genetic evidence

et al. 2005

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During the past decade, 13 C-labeling based metabolic flux analysis (MFA) has increasingly been used to understand the effect of genetic alterations [1,2], changes in external conditions [3,4] and different nutritional regimes [5,6] on the metabolism of micro-organisms. 13 C-labeling based MFA relies on the feeding of 13 C-labeled substrate to a biological system, allowing the labeled carbon atoms to distribute over the metabolic network, and subsequently measuring the 13 C-label distributions of intracellular and ⁄ or secreted The currently applied reaction structure in stoichiometric flux balance models for the nonoxidative branch of the pentose phosphate pathway is not in accordance with the established ping-pong kinetic mechanism of the enzymes transketolase (EC 2.2.1.1) and transaldolase (EC 2.2.1.2). Based upon the ping-pong mechanism, the traditional reactions of the nonoxidative branch of the pentose phosphate pathway are replaced by metabolite specific, reversible, glycolaldehyde moiety (C 2 ) and dihydroxyacetone moiety (C 3 ) fragments producing and consuming half-reactions. It is shown that a stoichiometric model based upon these half-reactions is fundamentally different from the currently applied stoichiometric models with respect to the number of independent C 2 and C 3 fragment pools in the pentose phosphate pathway and can lead to different label distributions for 13 C-tracer experiments. To investigate the actual impact of the new reaction structure on the estimated flux patterns within a cell, mass isotopomer measurements from a previously published 13 C-based metabolic flux analysis of Saccharomyces cerevisiae were used. Different flux patterns were found. From a genetic point of view, it is well known that several microorganisms, including Escherichia coli and S. cerevisiae, contain multiple genes encoding isoenzymes of transketolase and transaldolase. However, the extent to which these gene products are also actively expressed remains unknown. 7It is shown that the newly proposed stoichiometric model allows study of the effect of isoenzymes on the 13 C-label distribution in the nonoxidative branch of the pentose phosphate pathway by extending the halfreaction based stoichiometric model with two distinct transketolase enzymes instead of one. Results show that the inclusion of isoenzymes affects the ensuing flux estimates.Abbreviations C 2 , glycolaldehyde moiety; C 3 , dihydroxyacetone moiety; e4p, erythrose 4-phosphate; f6p, fructose 6-phosphate; fbp, fructose 1,6-bisphosphate 3;4;5 ; g1p, glucose 1-phosphate; g6p, glucose 6-phosphate; g3p, glyceraldehyde 3-phosphate; MFA, metabolic flux analysis; p5p, pentose pool consisting of ribulose 5-phosphate, ribose 5-phosphate and xylulose 5-phosphate; PPP, pentose phosphate pathway; r5p, ribose 5-phosphate; s7p, sedoheptulose 7-phosphate; SS res , sum of squared residuals; S 2 res , estimated error variance; TA, transaldolase; TK, transketolase; TPP, thiamine pyrophosphate; x5p, xylulose 5-phosphate.

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Revisiting the ¹³C‐label distribution of the non‐oxidative branch of the pentose phosphate pathway based upon kinetic and genetic evidence

et al. 2005

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“…4 [40, 64, 180]. One reason for those discrepancies might be that TK appears to catalyse exchange reactions much faster than the non-oxidative PPP¯ux rates [35].…”

Section: Sequence and Evolutionary Analysismentioning

confidence: 99%

Properties and functions of the thiamin diphosphate dependent enzyme transketolase

Schenk

Duggleby

Nixon

1998

The International Journal of Biochemistry & Cell Biology

226

164

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This review highlights recent research on the properties and functions of the enzyme transketolase, which requires thiamin diphosphate and a divalent metal ion for its activity. The transketolase-catalysed reaction is part of the pentose phosphate pathway, where transketolase appears to control the non-oxidative branch of this pathway, although the overall¯ux of labelled substrates remains controversial. Yeast transketolase is one of several thiamin diphosphate dependent enzymes whose three-dimensional structures have been determined. Together with mutational analysis these structural data have led to detailed understanding of thiamin diphosphate catalysed reactions. In the homodimer transketolase the two catalytic sites, where dihydroxyethyl groups are transferred from ketose donors to aldose acceptors, are formed at the interface between the two subunits, where the thiazole and pyrimidine rings of thiamin diphosphate are bound. Transketolase is ubiquitous and more than 30 full-length sequences are known. The encoded protein sequences contain two motifs of high homology; one common to all thiamin diphosphate-dependent enzymes and the other a unique transketolase motif. All characterised transketolases have similar kinetic and physical properties, but the mammalian enzymes are more selective in substrate utilisation than the nonmammalian representatives. Since products of the transketolase-catalysed reaction serve as precursors for a number of synthetic compounds this enzyme has been exploited for industrial applications. Putative mutant forms of transketolase, once believed to predispose to disease, have not stood up to scrutiny. However, a modi®cation of transketolase is a marker for Alzheimer's disease, and transketolase activity in erythrocytes is a measure of thiamin nutrition. The cornea contains a particularly high transketolase concentration, consistent with the proposal that pentose phosphate pathway activity has a role in the removal of light-generated radicals. #

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“…Earlier studies attempted to assess OPPP activity by measurement of the reduction of label from [1-13 C]Glc in metabolic products by Glc 6-phosphate dehydrogenase reaction relative to the label from [6-13 C]Glc. However, refixation of the 13 CO 2 released and/or redistribution of label due to exchange reactions make such experiments difficult to interpret (Flanigan et al, 1993;Roscher et al, 2000).…”

Section: Glycolytic Breakdown Of Glc Dominates In Plastidic Acetyl-comentioning

confidence: 99%

Probing in Vivo Metabolism by Stable Isotope Labeling of Storage Lipids and Proteins in Developing Brassica napusEmbryos

2002

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Developing embryos of Brassica napus accumulate both triacylglycerols and proteins as major storage reserves. To evaluate metabolic fluxes during embryo development, we have established conditions for stable isotope labeling of cultured embryos under steady-state conditions. Sucrose supplied via the endosperm is considered to be the main carbon and energy source for seed metabolism. However, in addition to 220 to 270 mm carbohydrates (sucrose, glucose, and fructose), analysis of endosperm liquid revealed up to 70 mm amino acids as well as 6 to 15 mm malic acid. Therefore, a labeling approach with multiple carbon sources is a precondition to quantitatively reflect fluxes of central carbon metabolism in developing embryos. Mid-cotyledon stage B. napus embryos were dissected from plants and cultured for 15 d on a complex liquid medium containing 13 C-labeled carbohydrates. The 13 C enrichment of fatty acids and amino acids (after hydrolysis of the seed proteins) was determined by gas chromatography/mass spectrometry. Analysis of 13 C isotope isomers of labeled fatty acids and plastid-derived amino acids indicated that direct glycolysis provides at least 90% of precursors of plastid acetyl-coenzyme A (CoA). Unlabeled amino acids, when added to the growth medium, did not reduce incorporation of 13 C label into plastid-formed fatty acids, but substantially diluted 13 C label in seed protein. Approximately 30% of carbon in seed protein was derived from exogenous amino acids and as a consequence, the use of amino acids as a carbon source may have significant influence on the total carbon and energy balance in seed metabolism. 13 C label in the terminal acetate units of C 20 and C 22 fatty acids that derive from cytosolic acetyl-CoA was also significantly diluted by unlabeled amino acids. We conclude that cytosolic acetyl-CoA has a more complex biogenetic origin than plastidic acetyl-CoA. Malic acid in the growth medium did not dilute 13 C label incorporation into fatty acids or proteins and can be ruled out as a source of carbon for the major storage components of B. napus embryos.Plant oils represent the largest renewable resource of highly reduced carbon chains and there is interest in increasing their production by oilseed crops. Brassica napus (canola, oilseed rape) is a major oil crop and a multitude of literature focuses on the biochemistry and physiology of oil accumulation in developing seeds of B. napus (see Singal et al., 1987;Murphy and Cummis, 1989;Kang and Rawsthorne, 1994;Eastmond and Rawsthorne, 1998;King et al., 1998). Although the biochemical pathways leading from Suc to oil storage are largely understood, a number of questions remain regarding, for example, the subcellular organization of reactions, and the origin of acetyl-CoA, reducing power, and ATP for fatty acid synthesis. These questions are particularly difficult to address using standard in vitro or organellar biochemical analyses that often result in loss of key activities. In addition, due to several reasons including dilution of isotopes by ...

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Exchange reactions catalyzed by group‐transferring enzymes oppose the quantitation and the unravelling of the identity of the pentose pathway

Cited by 20 publications

References 36 publications

Revisiting the ¹³C‐label distribution of the non‐oxidative branch of the pentose phosphate pathway based upon kinetic and genetic evidence

Revisiting the ¹³C‐label distribution of the non‐oxidative branch of the pentose phosphate pathway based upon kinetic and genetic evidence

Properties and functions of the thiamin diphosphate dependent enzyme transketolase

Probing in Vivo Metabolism by Stable Isotope Labeling of Storage Lipids and Proteins in Developing Brassica napusEmbryos

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Exchange reactions catalyzed by group‐transferring enzymes oppose the quantitation and the unravelling of the identity of the pentose pathway

Cited by 20 publications

References 36 publications

Revisiting the 13C‐label distribution of the non‐oxidative branch of the pentose phosphate pathway based upon kinetic and genetic evidence

Revisiting the 13C‐label distribution of the non‐oxidative branch of the pentose phosphate pathway based upon kinetic and genetic evidence

Properties and functions of the thiamin diphosphate dependent enzyme transketolase

Probing in Vivo Metabolism by Stable Isotope Labeling of Storage Lipids and Proteins in Developing Brassica napusEmbryos

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Revisiting the ¹³C‐label distribution of the non‐oxidative branch of the pentose phosphate pathway based upon kinetic and genetic evidence

Revisiting the ¹³C‐label distribution of the non‐oxidative branch of the pentose phosphate pathway based upon kinetic and genetic evidence