MIRACLE: mass isotopomer ratio analysis of U‐<sup>13</sup>C‐labeled extracts. A new method for accurate quantification of changes in concentrations of intracellular metabolites

Mashego, Mlawule R.; Wu, Liang; Dam, Jan C. van; Ras, Cor; Vinke, J. L.; Winden, Wouter A. van; Gulik, Walter M. van; Heijnen, Joseph J.

doi:10.1002/bit.10907

Cited by 239 publications

(226 citation statements)

References 30 publications

(38 reference statements)

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“…Similar conclusions were also achieved for filamentous fungi (Hajjaj et al, 1998) and bacterial cells (Maharjan and Ferenci, 2003). The recent methodologies developed to acquire accurate information on microbial metabolite levels (Buchholz et al, 2002;Soga et al, 2002;van Dam et al, 2002;Mashego et al, 2004;Villas-Bôas et al, 2005; and others) urgently need an extraction protocol that is able to trap a higher diversity of intracellular metabolites of yeasts. However, the yeast metabolome comprises a variety of compounds with a wide range of physical and chemical properties that make this task virtually impossible.…”

Section: Discussionmentioning

confidence: 99%

“…Therefore, it is important to determine the intracellular levels of metabolites accurately, which requires efficient and reliable methods for sample preparation. There have been considerable efforts to develop sensitive and accurate methods for detection of metabolites (Buchholz et al, 2002;Soga et al, 2002;van Dam et al, 2002;Mashego et al, 2004;Villas-Bôas et al, 2005;and others) and to improve the efficiency of data mining and data analysis (Goodacre et al, 2004;Kell, 2004;van der Greef et al, 2004) but relative little attention has been given to sample preparation procedures. Figure 1 summarizes the main steps in sample preparation for metabolome analysis.…”

Section: Introductionmentioning

confidence: 99%

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Global metabolite analysis of yeast: evaluation of sample preparation methods

Villas‐Bôas

Højer-Pedersen

Åkesson

et al. 2005

Yeast

362

352

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Sample preparation is considered one of the limiting steps in microbial metabolome analysis. Eukaryotes and prokaryotes behave very differently during the several steps of classical sample preparation methods for analysis of metabolites. Even within the eukaryote kingdom there is a vast diversity of cell structures that make it imprudent to blindly adopt protocols that were designed for a specific group of microorganisms. We have therefore reviewed and evaluated the whole sample preparation procedures for analysis of yeast metabolites. Our focus has been on the current needs in metabolome analysis, which is the analysis of a large number of metabolites with very diverse chemical and physical properties. This work reports the leakage of intracellular metabolites observed during quenching yeast cells with cold methanol solution, the efficacy of six different methods for the extraction of intracellular metabolites, and the losses noticed during sample concentration by lyophilization and solvent evaporation. A more reliable procedure is suggested for quenching yeast cells with cold methanol solution, followed by extraction of intracellular metabolites by pure methanol. The method can be combined with reduced pressure solvent evaporation and therefore represents an attractive sample preparation procedure for high-throughput metabolome analysis of yeasts.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Global metabolite analysis of yeast: evaluation of sample preparation methods

Villas‐Bôas

Højer-Pedersen

Åkesson

et al. 2005

Yeast

362

352

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“…In vivo kinetic studies rely partly on rapid dynamic perturbation experiments during which a steady-state chemostat culture is perturbed and the subsequent response in both extracellular and intracellular metabolites is monitored (Theobald et al, 1997;Chassagnole et al, 2002;Visser et al, 2002;Mashego et al, 2004;Wu et al, 2005). Taking into account the high turnover rate of most intracellular metabolites, proper measurement of their concentrations requires rapid broth sampling and instantaneous quenching of enzyme activity.…”

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confidence: 99%

“…For application of LC-MS/MS especially the rigorous use of stable isotope (e.g. 13 C) labeled internal standards is a prerequisite to obtain reproducible and reliable results (Mashego et al, 2004;Wu et al, 2005). The aim of the present study was to obtain a fast and reliable method for sampling and quenching of E. coli K12 cells, which would also be applicable to highly dynamic pulse response studies, carried out in chemostat cultures.…”

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confidence: 99%

Development and application of a differential method for reliable metabolome analysis in Escherichia coli

Taymaz-Nikerel

Mey

Ras

et al. 2009

Analytical Biochemistry

145

120

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“…The concentrations and fluxes of metabolites depend on the interactions among this conserved network structure, the cellular environment, and species-specific factors, such as the location, activities, and regulation of metabolic enzymes. Except for a few classic examples, e.g., central carbon metabolism in E. coli and yeast (3)(4)(5) and nitrogen assimilation in bacteria (6-8) the effect of environmental nutrient perturbations on the cellular metabolome have not been directly measured.…”

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confidence: 99%

Conservation of the metabolomic response to starvation across two divergent microbes

Brauer

Yuan

Bennett

et al. 2006

Proc. Natl. Acad. Sci. U.S.A.

238

204

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We followed 68 cellular metabolites after carbon or nitrogen starvation of Escherichia coli and Saccharomyces cerevisiae, using a filter-culture methodology that allows exponential growth, nondisruptive nutrient removal, and fast quenching of metabolism. Dynamic concentration changes were measured by liquid chromatography-tandem mass spectrometry and viewed in clustered heat-map format. The major metabolic responses anticipated from metabolite-specific experiments in the literature were observed as well as a number of novel responses. When the data were analyzed by singular value decomposition, two dominant characteristic vectors were found, one corresponding to a generic starvation response and another to a nutrient-specific starvation response that is similar in both organisms. Together these captured a remarkable 72% of the metabolite concentration changes in the full data set. The responses described by the generic starvation response vector (42%) included, for example, depletion of most biosynthetic intermediates. The nutrient-specific vector (30%) included key responses such as increased phosphoenolpyruvate signaling glucose deprivation and increased ␣-ketoglutarate signaling ammonia deprivation. Metabolic similarity across organisms extends from the covalent reaction network of metabolism to include many elements of metabolome response to nutrient deprivation as well.Escherichia coli ͉ metabolomics ͉ nitrogen/carbon metabolism ͉ Saccharomyces cerevisiae ͉ starvation response T he pathways of cellular metabolism are close to identical across widely divergent organisms (1). The prokaryote Escherichia coli and the eukaryote Saccharomyces cerevisiae share essentially the same metabolic network (2) despite radically different compartmentation. The concentrations and fluxes of metabolites depend on the interactions among this conserved network structure, the cellular environment, and species-specific factors, such as the location, activities, and regulation of metabolic enzymes. Except for a few classic examples, e.g., central carbon metabolism in E. coli and yeast (3-5) and nitrogen assimilation in bacteria (6-8) the effect of environmental nutrient perturbations on the cellular metabolome have not been directly measured.We explored exponentially growing E. coli and S. cerevisiae cultures suddenly deprived of their carbon or nitrogen sources. Metabolic composition can change in as little as a few seconds (9, 10). To get accurate snapshots of the metabolome, we devised a method of growing cells directly on filters to avoid time-consuming procedures (e.g., centrifugation or filtration) before quenching of biochemical activity (11). Transfer of a filter from a plate containing growth medium into cold organic solvent quickly quenches metabolism; transfer to a plate with a different medium composition allows a quick change of the nutrient environment (Fig. 1).For measurement of a number of metabolites simultaneously, we used a liquid chromatography-electrospray ionization-triple quadrupole mass spectrometry (LC-MS/...

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MIRACLE: mass isotopomer ratio analysis of U‐¹³C‐labeled extracts. A new method for accurate quantification of changes in concentrations of intracellular metabolites

Cited by 239 publications

References 30 publications

Global metabolite analysis of yeast: evaluation of sample preparation methods

Global metabolite analysis of yeast: evaluation of sample preparation methods

Development and application of a differential method for reliable metabolome analysis in Escherichia coli

Conservation of the metabolomic response to starvation across two divergent microbes

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MIRACLE: mass isotopomer ratio analysis of U‐13C‐labeled extracts. A new method for accurate quantification of changes in concentrations of intracellular metabolites

Cited by 239 publications

References 30 publications

Global metabolite analysis of yeast: evaluation of sample preparation methods

Global metabolite analysis of yeast: evaluation of sample preparation methods

Development and application of a differential method for reliable metabolome analysis in Escherichia coli

Conservation of the metabolomic response to starvation across two divergent microbes

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MIRACLE: mass isotopomer ratio analysis of U‐¹³C‐labeled extracts. A new method for accurate quantification of changes in concentrations of intracellular metabolites