scholarly journals Observing metabolic functions at the genome scale

2007 ◽  
Vol 8 (6) ◽  
pp. R123 ◽  
Author(s):  
Jean-Marc Schwartz ◽  
Claire Gaugain ◽  
Jose C Nacher ◽  
Antoine de Daruvar ◽  
Minoru Kanehisa
Keyword(s):  
Metabolic Functions ◽  
Genome Scale

scholarly journals Identifying functional metabolic shifts in heart failure with the integration of omics data and a cardiomyocyte-specific, genome-scale model

2020 ◽  
Author(s):  
Bonnie V. Dougherty ◽  
Kristopher D. Rawls ◽  
Glynis L. Kolling ◽  
Kalyan C. Vinnakota ◽  
Anders Wallqvist ◽  
...  
Keyword(s):  
Gene Expression ◽  
Heart Failure ◽  
Specific Model ◽  
Metabolic Phenotype ◽  
Scale Model ◽  
Metabolic Markers ◽  
Metabolic Functions ◽  
Carbon Substrates ◽  
End Stage ◽  
Genome Scale

SummaryThe heart is a metabolic omnivore, known to consume many different carbon substrates in order to maintain function. In diseased states, the heart’s metabolism can shift between different carbon substrates; however, there is some disagreement in the field as to the metabolic shifts seen in end-stage heart failure and whether all heart failure converges to a common metabolic phenotype. Here, we present a new, validated cardiomyocyte-specific GEnome-scale metabolic Network REconstruction (GENRE), iCardio, and use the model to identify common shifts in metabolic functions across heart failure omics datasets. We demonstrate the utility of iCardio in interpreting heart failure gene expression data by identifying Tasks Inferred from Differential Expression (TIDEs) which represent metabolic functions associated with changes in gene expression. We identify decreased NO and Neu5Ac synthesis as common metabolic markers of heart failure across datasets. Further, we highlight the differences in metabolic functions seen across studies, further highlighting the complexity of heart failure. The methods presented for constructing a tissue-specific model and identifying TIDEs can be extended to multiple tissue and diseases of interest.

FCDECOMP: Decomposition of metabolic networks based on flux coupling relations

2014 ◽  
Vol 12 (05) ◽  
pp. 1450028 ◽  
Author(s):  
Abolfazl Rezvan ◽  
Sayed-Amir Marashi ◽  
Changiz Eslahchi
Keyword(s):  
Metabolic Networks ◽  
System Level ◽  
Computational Framework ◽  
Flux Coupling ◽  
Metabolic Functions ◽  
Original Genome ◽  
A Cell ◽  
Scale Network ◽  
Genome Scale

A metabolic network model provides a computational framework to study the metabolism of a cell at the system level. Due to their large sizes and complexity, rational decomposition of these networks into subsystems is a strategy to obtain better insight into the metabolic functions. Additionally, decomposing metabolic networks paves the way to use computational methods that will be otherwise very slow when run on the original genome-scale network. In the present study, we propose FCDECOMP decomposition method based on flux coupling relations (FCRs) between pairs of reaction fluxes. This approach utilizes a genetic algorithm (GA) to obtain subsystems that can be analyzed in isolation, i.e. without considering the reactions of the original network in the analysis. Therefore, we propose that our method is useful for discovering biologically meaningful modules in metabolic networks. As a case study, we show that when this method is applied to the metabolic networks of barley seeds and yeast, the modules are in good agreement with the biological compartments of these networks.

scholarly journals Nature lessons: the whitefly bacterial endosymbiont is a minimal amino acid factory with unusual energetics

2016 ◽  
Author(s):  
Jorge Calle-Espinosa ◽  
Miguel Ponce-de-Leon ◽  
Diego Santos-Garcia ◽  
Francisco J. Silva ◽  
Francisco Montero ◽  
...  
Keyword(s):  
Amino Acid ◽  
Energy Production ◽  
Metabolic Networks ◽  
Metabolic Model ◽  
Atp Production ◽  
Symbiotic Associations ◽  
Bacterial Endosymbiont ◽  
Metabolic Functions ◽  
A Genome ◽  
Genome Scale

Bacterial lineages that establish obligate symbiotic associations with insect hosts are known to possess highly reduced genomes with streamlined metabolic functions that are commonly focused on amino acid and vitamin synthesis. We constructed a genome-scale metabolic model of the whitefly bacterial endosymbiont Candidatus Portiera aleyrodidarum to study the energy production capabilities using stoichiometric analysis. Strikingly, the results suggest that the energetic metabolism of the bacterial endosymbiont relies on the use of pathways related to the synthesis of amino acids and carotenoids. A deeper insight showed that the ATP production via carotenoid synthesis may also have a potential role in the regulation of amino acid production. The coupling of energy production to anabolism suggest that minimization of metabolic networks as a consequence of genome size reduction does not necessarily limit the biosynthetic potential of obligate endosymbionts.

scholarly journals Model-driven discovery of underground metabolic functions inEscherichia coli

2015 ◽  
Vol 112 (3) ◽  
pp. 929-934 ◽  
Author(s):  
Gabriela I. Guzmán ◽  
José Utrilla ◽  
Sergey Nurk ◽  
Elizabeth Brunk ◽  
Jonathan M. Monk ◽  
...  
Keyword(s):  
Strain Analysis ◽  
Cross Reactivity ◽  
Enzyme Promiscuity ◽  
Adaptive Laboratory Evolution ◽  
Model Driven ◽  
Bioinformatic Tools ◽  
Metabolic Functions ◽  
Biological Discovery ◽  
Constraint Based Modeling ◽  
Genome Scale

Enzyme promiscuity toward substrates has been discussed in evolutionary terms as providing the flexibility to adapt to novel environments. In the present work, we describe an approach toward exploring such enzyme promiscuity in the space of a metabolic network. This approach leverages genome-scale models, which have been widely used for predicting growth phenotypes in various environments or following a genetic perturbation; however, these predictions occasionally fail. Failed predictions of gene essentiality offer an opportunity for targeting biological discovery, suggesting the presence of unknown underground pathways stemming from enzymatic cross-reactivity. We demonstrate a workflow that couples constraint-based modeling and bioinformatic tools with KO strain analysis and adaptive laboratory evolution for the purpose of predicting promiscuity at the genome scale. Three cases of genes that are incorrectly predicted as essential inEscherichia coli—aspC,argD, andgltA—are examined, and isozyme functions are uncovered for each to a different extent. Seven isozyme functions based on genetic and transcriptional evidence are suggested between the genesaspCandtyrB,argDandastC,gabTandpuuE, andgltAandprpC. This study demonstrates how a targeted model-driven approach to discovery can systematically fill knowledge gaps, characterize underground metabolism, and elucidate regulatory mechanisms of adaptation in response to gene KO perturbations.

scholarly journals Exploring the metabolic landscape of pancreatic ductal adenocarcinoma cells using genome-scale metabolic modeling

2021 ◽  
Author(s):  
Mohammad Mazharul Islam ◽  
Andrea Goertzen ◽  
Pankaj Kumar Singh ◽  
Rajib Saha
Keyword(s):  
Pancreatic Ductal Adenocarcinoma ◽  
Therapy Response ◽  
Metabolic Model ◽  
Ductal Adenocarcinoma ◽  
Patient Specific ◽  
Beta Oxidation ◽  
Metabolic Functions ◽  
Dismal Prognosis ◽  
Fatty Acid Beta Oxidation ◽  
Genome Scale

Pancreatic ductal adenocarcinoma (PDAC) is a major research focus due to its poor therapy response and dismal prognosis. PDAC cells adapt their metabolism efficiently to the environment to which they are exposed, often relying on diverse fuel sources depending on availability. Since traditional experimental techniques appear exhaustive in the search for a viable therapeutic strategy against PDAC, in this study, a highly curated and omics-informed genome-scale metabolic model of PDAC was reconstructed using patient-specific transcriptomic data. From the analysis of the model-predicted metabolic changes, several new metabolic functions were explored as potential therapeutic targets against PDAC in addition to the already known metabolic hallmarks of pancreatic cancer. Significant downregulation in the peroxisomal fatty acid beta oxidation pathway reactions, flux modulation in the carnitine shuttle system, and upregulation in the reactive oxygen species detoxification pathway reactions were observed. These unique metabolic traits of PDAC were then correlated with potential drug combinations that can be repurposed for targeting genes with poor prognosis in PDAC. Overall, these studies provide a better understanding of the metabolic vulnerabilities in PDAC and will lead to novel effective therapeutic strategies.

scholarly journals Metage2Metabo: metabolic complementarity applied to genomes of large-scale microbiotas for the identification of keystone species

2019 ◽  
Author(s):  
Arnaud Belcour ◽  
Clémence Frioux ◽  
Méziane Aite ◽  
Anthony Bretaudeau ◽  
Anne Siegel
Keyword(s):  
Large Scale ◽  
Metabolic Networks ◽  
Keystone Species ◽  
Large Family ◽  
Functional Screening ◽  
Metabolic Cooperation ◽  
Metabolic Functions ◽  
Genome Scale ◽  
Equivalent Properties ◽  
Processing Solution

AbstractCapturing the functional diversity of microbiotas entails identifying metabolic functions and species of interest within hundreds or thousands. Starting from genomes, a way to functionally analyse genetic information is to build metabolic networks. Yet, no method enables a functional screening of such a large number of metabolic networks nor the identification of critical species with respect to metabolic cooperation.Metage2Metabo (M2M) addresses scalability issues raised by metagenomics datasets to identify keystone, essential and alternative symbionts in large microbiotas communities with respect to individual metabolism and collective metabolic complementarity. Genome-scale metabolic networks for the community can be either provided by the user or very efficiently reconstructed from a large family of genomes thanks to a multi-processing solution to run the Pathway Tools software. The pipeline was applied to 1,520 genomes from the gut microbiota and 913 metagenome-assembled genomes of the rumen microbiota. Reconstruction of metabolic networks and subsequent metabolic analyses were performed in a reasonable time.M2M identifies keystone, essential and alternative organisms by reducing the complexity of a large-scale microbiota into minimal communities with equivalent properties, suitable for further analyses.

scholarly journals Metage2Metabo, microbiota-scale metabolic complementarity for the identication of key species

eLife ◽  
2020 ◽  
Vol 9 ◽  
Author(s):  
Arnaud Belcour ◽  
Clémence Frioux ◽  
Méziane Aite ◽  
Anthony Bretaudeau ◽  
Falk Hildebrand ◽  
...  
Keyword(s):  
Functional Diversity ◽  
Large Scale ◽  
Metabolic Networks ◽  
De Novo ◽  
Functional Screening ◽  
Metabolic Cooperation ◽  
Metabolic Functions ◽  
Key Species ◽  
Genome Scale ◽  
Equivalent Properties

To capture the functional diversity of microbiota, one must identify metabolic functions and species of interest within hundreds or thousands of microorganisms. We present Metage2Metabo (M2M) a resource that meets the need for de-novo functional screening of genome-scale metabolic networks (GSMNs) at the scale of a metagenome, and the identification of critical species with respect to metabolic cooperation. M2M comprises a flexible pipeline for the characterisation of individual metabolisms and collective metabolic complementarity. In addition, M2M identifies key species, that are meaningful members of the community for functions of interest. We demonstrate that M2M is applicable to collections of genomes as well as metagenome-assembled genomes, permits an efficient GSMN reconstruction with Pathway Tools, and assesses the cooperation potential between species. M2M identifies key organisms by reducing the complexity of a large-scale microbiota into minimal communities with equivalent properties, suitable for further analyses.

scholarly journals What does your cell really do? Model-based assessment of mammalian cells metabolic functionalities using omics data

2020 ◽  
Author(s):  
Anne Richelle ◽  
Benjamin P. Kellman ◽  
Alexander T. Wenzel ◽  
Austin W.T. Chiang ◽  
Tyler Reagan ◽  
...  
Keyword(s):  
Mammalian Cells ◽  
Large Scale ◽  
Metabolic Networks ◽  
Omics Data ◽  
Web Based ◽  
Cell Functions ◽  
Metabolic Functions ◽  
Biological Studies ◽  
Biological Entities ◽  
Genome Scale

AbstractLarge-scale omics experiments have become standard in biological studies, leading to a deluge of data. However, researchers still face the challenge of connecting changes in the omics data to changes in cell functions, due to the complex interdependencies between genes, proteins and metabolites. Here we present a novel framework that begins to overcome this problem by allowing users to infer how metabolic functions change, based on omics data. To enable this, we curated and standardized lists of metabolic tasks that mammalian cells can accomplish. We then used genome-scale metabolic networks to define gene modules responsible for each specific metabolic task. We further developed a framework to overlay omics data on these modules to predict pathway usage for each metabolic task. The proposed approach allows one to directly predict how changes in omics experiments change cell or tissue function. We further demonstrated how this new approach can be used to leverage the metabolic functions of biological entities from the single cell to their organization in tissues and organs using multiple transcriptomic datasets (human and mouse). Finally, we created a web-based CellFie module that has been integrated into the list of tools available in GenePattern (www.genepattern.org) to enable adoption of the approach.

scholarly journals Adapting to the Airways: Metabolic Requirements of Pseudomonas aeruginosa during the Infection of Cystic Fibrosis Patients

Metabolites ◽  
2019 ◽  
Vol 9 (10) ◽  
pp. 234 ◽  
Author(s):  
La Rosa ◽  
Johansen ◽  
Molin
Keyword(s):  
Cystic Fibrosis ◽  
Pseudomonas Aeruginosa ◽  
Physiological Changes ◽  
Metabolic Evolution ◽  
Physiological Conditions ◽  
Metabolic Functions ◽  
Lung Infections ◽  
Genome Scale

Pseudomonas aeruginosa is one of the major causes of morbidity and mortality of cystic fibrosis patients. During the infection, the bacteria colonize the nutritional rich lung mucus, which is present in the airway secretions in the patients, and they adapt their phenotype accordingly to the lung environment. In the airways, P. aeruginosa undergoes a broad metabolic rewiring as a consequence of the nutritional and stressful complexity of the lungs. However, the role of such metabolic rewiring on the infection outcome is poorly understood. Here, we review the metabolic evolution of clinical strains of P. aeruginosa during a cystic fibrosis lung infection and the metabolic functions operating in vivo under patho-physiological conditions. Finally, we discuss the perspective of modeling the cystic fibrosis environment using genome scale metabolic models of P. aeruginosa. Understanding the physiological changes occurring during the infection may pave the way to a more effective treatment for P. aeruginosa lung infections.

scholarly journals Systems biology analysis of the Clostridioides difficile core-genome contextualizes microenvironmental evolutionary pressures leading to genotypic and phenotypic divergence

2020 ◽  
Vol 6 (1) ◽  
Author(s):  
Charles J. Norsigian ◽  
Heather A. Danhof ◽  
Colleen K. Brand ◽  
Numan Oezguen ◽  
Firas S. Midani ◽  
...  
Keyword(s):  
Large Scale ◽  
Core Genome ◽  
Iron Acquisition ◽  
Carbon Sources ◽  
Growth Dynamics ◽  
Scale Model ◽  
Clostridioides Difficile ◽  
Metabolic Functions ◽  
Genes Encoding ◽  
Genome Scale

Abstract Hospital acquired Clostridioides (Clostridium) difficile infection is exacerbated by the continued evolution of C. difficile strains, a phenomenon studied by multiple laboratories using stock cultures specific to each laboratory. Intralaboratory evolution of strains contributes to interlaboratory variation in experimental results adding to the challenges of scientific rigor and reproducibility. To explore how microevolution of C. difficile within laboratories influences the metabolic capacity of an organism, three different laboratory stock isolates of the C. difficile 630 reference strain were whole-genome sequenced and profiled in over 180 nutrient environments using phenotypic microarrays. The results identified differences in growth dynamics for 32 carbon sources including trehalose, fructose, and mannose. An updated genome-scale model for C. difficile 630 was constructed and used to contextualize the 28 unique mutations observed between the stock cultures. The integration of phenotypic screens with model predictions identified pathways enabling catabolism of ethanolamine, salicin, arbutin, and N-acetyl-galactosamine that differentiated individual C. difficile 630 laboratory isolates. The reconstruction was used as a framework to analyze the core-genome of 415 publicly available C. difficile genomes and identify areas of metabolism prone to evolution within the species. Genes encoding enzymes and transporters involved in starch metabolism and iron acquisition were more variable while C. difficile distinct metabolic functions like Stickland fermentation were more consistent. A substitution in the trehalose PTS system was identified with potential implications in strain virulence. Thus, pairing genome-scale models with large-scale physiological and genomic data enables a mechanistic framework for studying the evolution of pathogens within microenvironments and will lead to predictive modeling to combat pathogen emergence.

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