Critical assessment of genome-scale metabolic models of Arabidopsis thaliana

AbstractThe human gut harbors an enormous number of symbiotic microbes, which is vital for human health. However, interactions within the complex microbiota community and between the microbiota and its host are challenging to elucidate, limiting development in the treatment for a variety of diseases associated with microbiota dysbiosis. Using in silico simulation methods based on flux balance analysis, those interactions can be better investigated. Flux balance analysis uses an annotated genome-scale reconstruction of a metabolic network to determine the distribution of metabolic fluxes that represent the complete metabolism of a bacterium in a certain metabolic environment such as the gut. Simulation of a set of bacterial species in a shared metabolic environment can enable the study of the effect of numerous perturbations, such as dietary changes or addition of a probiotic species in a personalized manner. This review aims to introduce to experimental biologists the possible applications of flux balance analysis in the host-microbiota interaction field and discusses its potential use to improve human health.

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Why does yeast ferment? A flux balance analysis study

Biochemical Society Transactions ◽

10.1042/bst0381225 ◽

2010 ◽

Vol 38 (5) ◽

pp. 1225-1229 ◽

Cited By ~ 23

Author(s):

Evangelos Simeonidis ◽

Ettore Murabito ◽

Kieran Smallbone ◽

Hans V. Westerhoff

Keyword(s):

Flux Balance Analysis ◽

Energy Cost ◽

Yeast Fermentation ◽

Minimal Amount ◽

Aerobic Growth ◽

Analysis Study ◽

Flux Balance ◽

Balance Analysis ◽

Genome Scale ◽

Excess Glucose

Advances in biological techniques have led to the availability of genome-scale metabolic reconstructions for yeast. The size and complexity of such networks impose limits on what types of analyses one can perform. Constraint-based modelling overcomes some of these restrictions by using physicochemical constraints to describe the potential behaviour of an organism. FBA (flux balance analysis) highlights flux patterns through a network that serves to achieve a particular objective and requires a minimal amount of data to make quantitative inferences about network behaviour. Even though FBA is a powerful tool for system predictions, its general formulation sometimes results in unrealistic flux patterns. A typical example is fermentation in yeast: ethanol is produced during aerobic growth in excess glucose, but this pattern is not present in a typical FBA solution. In the present paper, we examine the issue of yeast fermentation against respiration during growth. We have studied a number of hypotheses from the modelling perspective, and novel formulations of the FBA approach have been tested. By making the observation that more respiration requires the synthesis of more mitochondria, an energy cost related to mitochondrial synthesis is added to the FBA formulation. Results, although still approximate, are closer to experimental observations than earlier FBA analyses, at least on the issue of fermentation.

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Semi-automated Curation of Metabolic Models via Flux Balance Analysis: A Case Study with Mycoplasma gallisepticum

PLoS Computational Biology ◽

10.1371/journal.pcbi.1003208 ◽

2013 ◽

Vol 9 (9) ◽

pp. e1003208 ◽

Cited By ~ 10

Author(s):

Eddy J. Bautista ◽

Joseph Zinski ◽

Steven M. Szczepanek ◽

Erik L. Johnson ◽

Edan R. Tulman ◽

...

Keyword(s):

Flux Balance Analysis ◽

Mycoplasma Gallisepticum ◽

Flux Balance ◽

Balance Analysis ◽

Metabolic Models

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Predicting the accumulation of storage compounds by Rhodococcus jostii RHA1 in the feast-famine growth cycles using genome-scale flux balance analysis

PLoS ONE ◽

10.1371/journal.pone.0191835 ◽

2018 ◽

Vol 13 (3) ◽

pp. e0191835 ◽

Cited By ~ 4

Author(s):

Mohammad Tajparast ◽

Dominic Frigon

Keyword(s):

Flux Balance Analysis ◽

Growth Cycles ◽

Storage Compounds ◽

Flux Balance ◽

Balance Analysis ◽

Rhodococcus Jostii Rha1 ◽

Genome Scale ◽

Rhodococcus Jostii

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The ModelSEED Database for the integration of metabolic annotations and the reconstruction, comparison, and analysis of metabolic models for plants, fungi, and microbes

10.1101/2020.03.31.018663 ◽

2020 ◽

Cited By ~ 1

Author(s):

Samuel M. D. Seaver ◽

Filipe Liu ◽

Qizhi Zhang ◽

James Jeffryes ◽

José P. Faria ◽

...

Keyword(s):

Metabolic Pathways ◽

Draft Genome ◽

Biochemical Network ◽

Plant Genomes ◽

Flux Balance ◽

Rosetta Stone ◽

Balance Analysis ◽

Comparison And Analysis ◽

Metabolic Models ◽

Genome Scale

ABSTRACTFor over ten years, ModelSEED has been a primary resource for the construction of draft genome-scale metabolic models based on annotated microbial or plant genomes. Now being released, the biochemistry database serves as the foundation of biochemical data underlying ModelSEED and KBase. The biochemistry database embodies several properties that, taken together, distinguish it from other published biochemistry resources by: (i) including compartmentalization, transport reactions, charged molecules and proton balancing on reactions;; (ii) being extensible by the user community, with all data stored in GitHub; and (iii) design as a biochemical “Rosetta Stone” to facilitate comparison and integration of annotations from many different tools and databases. The database was constructed by combining chemical data from many resources, applying standard transformations, identifying redundancies, and computing thermodynamic properties. The ModelSEED biochemistry is continually tested using flux balance analysis to ensure the biochemical network is modeling-ready and capable of simulating diverse phenotypes. Ontologies can be designed to aid in comparing and reconciling metabolic reconstructions that differ in how they represent various metabolic pathways. ModelSEED now includes 33,978 compounds and 36,645 reactions, available as a set of extensible files on GitHub, and available to search at https://modelseed.org and KBase.

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Simulating serial-target antibacterial drug synergies using flux balance analysis

10.1101/030791 ◽

2015 ◽

Author(s):

Andrew S Krueger ◽

Christian Munck ◽

Gautam Dantas ◽

George M Church ◽

James Galagan ◽

...

Keyword(s):

Flux Balance Analysis ◽

Enzyme Inhibitors ◽

Metabolic Inhibitors ◽

Metabolic Enzyme ◽

Antibacterial Drug ◽

Flux Balance ◽

Single Target ◽

Metabolic Systems ◽

Balance Analysis ◽

Genome Scale

Flux balance analysis (FBA) is an increasingly useful approach for modeling the behavior of metabolic systems. However, standard FBA modeling of genetic knockouts can not predict drug combination synergies observed between serial metabolic targets, even though such synergies give rise to some of the most widely used antibiotic treatments. Here we extend FBA modeling to simulate responses to chemical inhibitors at varying concentrations, by diverting enzymatic flux to a waste reaction. This flux diversion yields very similar qualitative predictions to prior methods for single target activity. However, we find very different predictions for combinations, where flux diversion, which mimics the kinetics of competitive metabolic inhibitors, can explain serial target synergies between metabolic enzyme inhibitors that we confirmed in Escherichia coli cultures. FBA flux diversion opens the possibility for more accurate genome-scale predictions of drug synergies, which can be used to suggest treatments for infections and other diseases.

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Modeling the Differences in Biochemical Capabilities ofPseudomonasSpecies by Flux Balance Analysis: How Good Are Genome-Scale Metabolic Networks at Predicting the Differences?

The Scientific World JOURNAL ◽

10.1155/2014/416289 ◽

2014 ◽

Vol 2014 ◽

pp. 1-11 ◽

Cited By ~ 6

Author(s):

Parizad Babaei ◽

Tahereh Ghasemi-Kahrizsangi ◽

Sayed-Amir Marashi

Keyword(s):

In Silico ◽

Metabolic Networks ◽

Closely Related Species ◽

Systematic Analysis ◽

Reconstruction Process ◽

Flux Balance ◽

Wide Range ◽

Balance Analysis ◽

Metabolic Models ◽

Genome Scale

To date, several genome-scale metabolic networks have been reconstructed. These models cover a wide range of organisms, from bacteria to human. Such models have provided us with a framework for systematic analysis of metabolism. However, little effort has been put towards comparing biochemical capabilities of closely related species using their metabolic models. The accuracy of a model is highly dependent on the reconstruction process, as some errors may be included in the model during reconstruction. In this study, we investigated the ability of threePseudomonasmetabolic models to predict the biochemical differences, namely, iMO1086, iJP962, and iSB1139, which are related toP. aeruginosaPAO1,P. putidaKT2440, andP. fluorescensSBW25, respectively. We did a comprehensive literature search for previous works containing biochemically distinguishable traits over these species. Amongst more than 1700 articles, we chose a subset of them which included experimental results suitable forin silicosimulation. By simulating the conditions provided in the actual biological experiment, we performed case-dependent tests to compare thein silicoresults to the biological ones. We found out that iMO1086 and iJP962 were able to predict the experimental data and were much more accurate than iSB1139.

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