Multiple High-Throughput Analyses Monitor the Response of
            <i>E. coli</i>
            to Perturbations

Ishii, Nobuyoshi; Nakahigashi, Kenji; Baba, Tomoya; Robert, Martin; Soga, Tomoyoshi; Kanai, Akio; Hirasawa, Takashi; Naba, Miki; Hirai, Kenta; Hoque, Azizul; Ho, Pei Yee; Kakazu, Yuji; Sugawara, Kenji; Igarashi, Saori; Harada, Satoshi; Masuda, Takeshi; Sugiyama, Naoyuki; Togashi, Takashi; Hasegawa, Miki; Takai, Yuki; Yugi, Katsuyuki; Arakawa, Kazuharu; Iwata, Nayuta; Toya, Yoshihiro; Nakayama, Yoichi; Nishi­oka, Takaaki; Shimizu, Kazuyuki; Mori, Hirotada; Tomita, Masaru

doi:10.1126/science.1132067

Cited by 646 publications

(763 citation statements)

References 19 publications

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“…Experimentally, this idea is supported by large scale surveys of the Saccharomyces cerevisiae and Escherichia coli metabolomes [16,17]. In yeast, 75% of enzyme disruptions have no detectable effect on the overall metabolic flux [18].…”

Section: Glossarymentioning

confidence: 99%

“…Although this figure is biased, because of the large number of paralogous enzymes [18] and varied experimental conditions [19] it nonetheless indicates the remarkable robustness of the metabolic network. The deletion of most paralogue-free enzyme-encoding genes indeed causes changes in the metabolic flux [16,18], but at least in bacteria and yeast, most perturbations are only detected within a surprisingly narrow part of the network [17,18]. A low number of enzyme disruptions, however, cause a system-wide response.…”

Section: Glossarymentioning

confidence: 99%

“…Bacteria, for example, counteract perturbations via changes in their overall mRNA levels, protein content and growth rate; however, they maintain the concentration of central metabolites. Perturbations cause very specific and precise adaptations of the cellular enzyme content, indicating that monitoring of the network occurs at multiple nodes [17]. Balancing the perturbation is then manifold; consequences range from fine-tuning of a few enzymes up to adjusting the overall growth rate [17,[20][21][22][23].…”

Section: Glossarymentioning

confidence: 99%

“…Perturbations cause very specific and precise adaptations of the cellular enzyme content, indicating that monitoring of the network occurs at multiple nodes [17]. Balancing the perturbation is then manifold; consequences range from fine-tuning of a few enzymes up to adjusting the overall growth rate [17,[20][21][22][23]. The latter is energetically expensive; a change in the growth rate requires numerous metabolic transitions, and the entire transcriptome, proteome and metabolome must be adapted [23].…”

Section: Glossarymentioning

confidence: 99%

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Regulatory crosstalk of the metabolic network

Grüning

Lehrach

Ralser

2010

Trends in Biochemical Sciences

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The metabolic network has a modular architecture, is robust to perturbations, and responds to biological stimuli and environmental conditions. Through monitoring by metabolite responsive macromolecules, metabolic pathways interact with the transcriptome and proteome. Whereas pathway interconnecting cofactors and substrates report on the overall state of the network, specialised intermediates measure the activity of individual functional units. Transitions in the network affect many of these regulatory metabolites, facilitating the parallel regulation of the timing and control of diverse biological processes. The metabolic network controls its own balance, chromatin structure and the biosynthesis of molecular cofactors; moreover, metabolic shifts are crucial in the response to oxidative stress and play a regulatory role in cancer.Evolution of the metabolic network and its structure Life probably began with the formation of compartmentalised autocatalytic chemical cycles. With the appearance of complex catalysts (ribonucleic acid-or protein-based enzymes), these cycles gained complexity, and evolved in their effectiveness and robustness [1]. These metabolic pathways now form the basis for life.As was the case for the first primitive life forms, the survival of today's complex organisms depends on the robustness and functionality of the metabolic framework [2]. To prevent and counteract perturbations in the flux, many biological control and sensor systems have evolved around the metabolic network. Metabolic pathways provide the cell with energy and supply macromolecular synthesis pathways with their required intermediates. They also balance metabolic systems under a variety of physiological conditions, and act as transducers and sensor systems for environmental conditions and stimuli. In addition, metabolic pathways are essential for crosstalk between metabolic regulatory components and the cellular transcriptome and proteome.As early as the 1960s, the principle that cells alter their gene expression in response to metabolic requirements has been known. The seminal work of Jacob and Monod, investigating the lac operon, uncovered one of the first examples of chemical-genetic regulation, by which bacterial cells adjust their enzyme production to the nutrient supply [3]. However, only recently have the broader implications of this principle emerged. Indeed, changes in the metabolic network not only control the metabolome, but they also have wide-ranging regulatory functions throughout biology.Most of the biochemical mechanisms that link the metabolic network to the transcriptome and proteome are incompletely understood. However, one type of regulation appears to be common: representative network intermediates bind to and modulate sensor function and activity of transcription factors, translational regulators, chromatin, enzymes, RNA molecules, and ion channels. Significant transcriptional changes around these intermediates identified them as reporter metabolites [4,5]. The use of intermediates as activity reporters ne...

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Section: Glossarymentioning

confidence: 99%

Section: Glossarymentioning

confidence: 99%

Section: Glossarymentioning

confidence: 99%

Section: Glossarymentioning

confidence: 99%

See 2 more Smart Citations

Regulatory crosstalk of the metabolic network

Grüning

Lehrach

Ralser

2010

Trends in Biochemical Sciences

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show abstract

“…An important aspect of experimental systems biology is the use of diVerent experimental data sources that can be integrated by the methods of computational systems biology. For instance, Ishii et al used system wide data on transcriptional, protein and metabolite levels to study the central carbon metabolism of Escherichia coli (Ishii et al 2007). Such data sets provide the starting point for computational approaches that can be used to understand fundamental physiological processes.…”

Section: Systems Biologymentioning

confidence: 99%

Quantitative microscopy and systems biology: seeing the whole picture

Verveer

Bastiaens

2008

Histochem Cell Biol

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Understanding cellular function requires studying the spatially resolved dynamics of protein networks. From the isolated proteins we can only learn about their individual properties, but by investigating their behavior in their natural environment, the cell, we obtain information about the overall response properties of the network module in which they operate. Fluorescence microscopy methods provide currently the only tools to study the dynamics of molecular processes in living cells with high temporal and spatial resolution. Combined with computational approaches they allow us to obtain insights in the reactiondiVusion processes that determine biological function on the scale of cells.

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LC‐MS Data Processing with MAVEN: A Metabolomic Analysis and Visualization Engine

Clasquin¹,

Melamud

Rabinowitz³

2012

CP in Bioinformatics

419

360

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MAVEN is an open‐source software program for interactive processing of LC‐MS‐based metabolomics data. MAVEN enables rapid and reliable metabolite quantitation from multiple reaction monitoring data or high‐resolution full‐scan mass spectrometry data. It automatically detects and reports peak intensities for isotope‐labeled metabolites. Menu‐driven, click‐based navigation allows visualization of raw and analyzed data. Here we provide a User Guide for MAVEN. Step‐by‐step instructions are provided for data import, peak alignment across samples, identification of metabolites that differ strongly between biological conditions, quantitation and visualization of isotope‐labeling patterns, and export of tables of metabolite‐specific peak intensities. Together, these instructions describe a workflow that allows efficient processing of raw LC‐MS data into a form ready for biological analysis. Curr. Protoc. Bioinform. 37:14.11.1‐14.11.23. © 2012 by John Wiley & Sons, Inc.

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Multiple High-Throughput Analyses Monitor the Response of E. coli to Perturbations

Cited by 646 publications

References 19 publications

Regulatory crosstalk of the metabolic network

Regulatory crosstalk of the metabolic network

Quantitative microscopy and systems biology: seeing the whole picture

LC‐MS Data Processing with MAVEN: A Metabolomic Analysis and Visualization Engine

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