TY - JOUR
T1 - Systematic construction of kinetic models from genome-scale metabolic networks
AU - Stanford, Natalie J.
AU - Lubitz, Timo
AU - Smallbone, Kieran
AU - Klipp, Edda
AU - Mendes, Pedro
AU - Liebermeister, Wolfram
N1 - The authors thank the EPSRC and BBSRC for financial support of this work through the Manchester Doctoral Training Centre ISBML (grant EP/F500009/1 supported NJS) and the Manchester Centre for Integrative Systems Biology (grant BB/C0082191 supported KS and PM), the EU FP7 programme: UniCellSys (supported PM, TL, EK, and WL), BaSysBio (supported TL, EK, and WL), BioPreDyn (grant 289434, supported PM and KS), the German Research Foundation (supported WL), the OncoPath project (supported TL and EK), and the USAâs NIGMS (grant GM080219) supported PM. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.all data is supplied as supplementary files published with the article
PY - 2013/11/14
Y1 - 2013/11/14
N2 - The quantitative effects of environmental and genetic perturbations on metabolism can be studied in silico using kinetic models. We present a strategy for large-scale model construction based on a logical layering of data such as reaction fluxes, metabolite concentrations, and kinetic constants. The resulting models contain realistic standard rate laws and plausible parameters, adhere to the laws of thermodynamics, and reproduce a predefined steady state. These features have not been simultaneously achieved by previous workflows. We demonstrate the advantages and limitations of the workflow by translating the yeast consensus metabolic network into a kinetic model. Despite crudely selected data, the model shows realistic control behaviour, a stable dynamic, and realistic response to perturbations in extracellular glucose concentrations. The paper concludes by outlining how new data can continuously be fed into the workflow and how iterative model building can assist in directing experiments. © 2013 Stanford et al.
AB - The quantitative effects of environmental and genetic perturbations on metabolism can be studied in silico using kinetic models. We present a strategy for large-scale model construction based on a logical layering of data such as reaction fluxes, metabolite concentrations, and kinetic constants. The resulting models contain realistic standard rate laws and plausible parameters, adhere to the laws of thermodynamics, and reproduce a predefined steady state. These features have not been simultaneously achieved by previous workflows. We demonstrate the advantages and limitations of the workflow by translating the yeast consensus metabolic network into a kinetic model. Despite crudely selected data, the model shows realistic control behaviour, a stable dynamic, and realistic response to perturbations in extracellular glucose concentrations. The paper concludes by outlining how new data can continuously be fed into the workflow and how iterative model building can assist in directing experiments. © 2013 Stanford et al.
U2 - 10.1371/journal.pone.0079195
DO - 10.1371/journal.pone.0079195
M3 - Article
VL - 8
JO - PLoS ONE
JF - PLoS ONE
IS - 11
M1 - e79195
ER -