Using bioconductor package BiGGR for metabolic flux estimation based on gene expression changes in brain.

Predicting the distribution of metabolic fluxes in biochemical networks is of major interest in systems biology. Several databases provide metabolic reconstructions for different organisms. Software to analyze flux distributions exists, among others for the proprietary MATLAB environment. Given the...

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Main Authors: Anand K Gavai, Farahaniza Supandi, Hannes Hettling, Paul Murrell, Jack A M Leunissen, Johannes H G M van Beek
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2015-01-01
Series:PLoS ONE
Online Access:https://doi.org/10.1371/journal.pone.0119016
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spelling doaj-b2a0e450f3474a0a9df7e85fd2c626642021-03-03T20:07:35ZengPublic Library of Science (PLoS)PLoS ONE1932-62032015-01-01103e011901610.1371/journal.pone.0119016Using bioconductor package BiGGR for metabolic flux estimation based on gene expression changes in brain.Anand K GavaiFarahaniza SupandiHannes HettlingPaul MurrellJack A M LeunissenJohannes H G M van BeekPredicting the distribution of metabolic fluxes in biochemical networks is of major interest in systems biology. Several databases provide metabolic reconstructions for different organisms. Software to analyze flux distributions exists, among others for the proprietary MATLAB environment. Given the large user community for the R computing environment, a simple implementation of flux analysis in R appears desirable and will facilitate easy interaction with computational tools to handle gene expression data. We extended the R software package BiGGR, an implementation of metabolic flux analysis in R. BiGGR makes use of public metabolic reconstruction databases, and contains the BiGG database and the reconstruction of human metabolism Recon2 as Systems Biology Markup Language (SBML) objects. Models can be assembled by querying the databases for pathways, genes or reactions of interest. Fluxes can then be estimated by maximization or minimization of an objective function using linear inverse modeling algorithms. Furthermore, BiGGR provides functionality to quantify the uncertainty in flux estimates by sampling the constrained multidimensional flux space. As a result, ensembles of possible flux configurations are constructed that agree with measured data within precision limits. BiGGR also features automatic visualization of selected parts of metabolic networks using hypergraphs, with hyperedge widths proportional to estimated flux values. BiGGR supports import and export of models encoded in SBML and is therefore interoperable with different modeling and analysis tools. As an application example, we calculated the flux distribution in healthy human brain using a model of central carbon metabolism. We introduce a new algorithm termed Least-squares with equalities and inequalities Flux Balance Analysis (Lsei-FBA) to predict flux changes from gene expression changes, for instance during disease. Our estimates of brain metabolic flux pattern with Lsei-FBA for Alzheimer's disease agree with independent measurements of cerebral metabolism in patients. This second version of BiGGR is available from Bioconductor.https://doi.org/10.1371/journal.pone.0119016
collection DOAJ
language English
format Article
sources DOAJ
author Anand K Gavai
Farahaniza Supandi
Hannes Hettling
Paul Murrell
Jack A M Leunissen
Johannes H G M van Beek
spellingShingle Anand K Gavai
Farahaniza Supandi
Hannes Hettling
Paul Murrell
Jack A M Leunissen
Johannes H G M van Beek
Using bioconductor package BiGGR for metabolic flux estimation based on gene expression changes in brain.
PLoS ONE
author_facet Anand K Gavai
Farahaniza Supandi
Hannes Hettling
Paul Murrell
Jack A M Leunissen
Johannes H G M van Beek
author_sort Anand K Gavai
title Using bioconductor package BiGGR for metabolic flux estimation based on gene expression changes in brain.
title_short Using bioconductor package BiGGR for metabolic flux estimation based on gene expression changes in brain.
title_full Using bioconductor package BiGGR for metabolic flux estimation based on gene expression changes in brain.
title_fullStr Using bioconductor package BiGGR for metabolic flux estimation based on gene expression changes in brain.
title_full_unstemmed Using bioconductor package BiGGR for metabolic flux estimation based on gene expression changes in brain.
title_sort using bioconductor package biggr for metabolic flux estimation based on gene expression changes in brain.
publisher Public Library of Science (PLoS)
series PLoS ONE
issn 1932-6203
publishDate 2015-01-01
description Predicting the distribution of metabolic fluxes in biochemical networks is of major interest in systems biology. Several databases provide metabolic reconstructions for different organisms. Software to analyze flux distributions exists, among others for the proprietary MATLAB environment. Given the large user community for the R computing environment, a simple implementation of flux analysis in R appears desirable and will facilitate easy interaction with computational tools to handle gene expression data. We extended the R software package BiGGR, an implementation of metabolic flux analysis in R. BiGGR makes use of public metabolic reconstruction databases, and contains the BiGG database and the reconstruction of human metabolism Recon2 as Systems Biology Markup Language (SBML) objects. Models can be assembled by querying the databases for pathways, genes or reactions of interest. Fluxes can then be estimated by maximization or minimization of an objective function using linear inverse modeling algorithms. Furthermore, BiGGR provides functionality to quantify the uncertainty in flux estimates by sampling the constrained multidimensional flux space. As a result, ensembles of possible flux configurations are constructed that agree with measured data within precision limits. BiGGR also features automatic visualization of selected parts of metabolic networks using hypergraphs, with hyperedge widths proportional to estimated flux values. BiGGR supports import and export of models encoded in SBML and is therefore interoperable with different modeling and analysis tools. As an application example, we calculated the flux distribution in healthy human brain using a model of central carbon metabolism. We introduce a new algorithm termed Least-squares with equalities and inequalities Flux Balance Analysis (Lsei-FBA) to predict flux changes from gene expression changes, for instance during disease. Our estimates of brain metabolic flux pattern with Lsei-FBA for Alzheimer's disease agree with independent measurements of cerebral metabolism in patients. This second version of BiGGR is available from Bioconductor.
url https://doi.org/10.1371/journal.pone.0119016
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