TY - JOUR
T1 - Reconstruction of Arabidopsis metabolic network models accounting for subcellular compartmentalization and tissue-specificity
AU - Mintz-Oron, Shira
AU - Meir, Sagit
AU - Malitsky, Sergey
AU - Ruppin, Eytan
AU - Aharoni, Asaph
AU - Shlomi, Tomer
N1 - Ministry of Science and Technology; Minerva Foundation; European Research Council; Science Foundation; Ministry of Science and Technologies for an integrated study of plant metabolismWe thank Nathan Lewis, Gad Galili, Arren Bar-Even, Keren Yizhak, and Raphy Zarecki for their help and fruitful comments. Work in the A.A. laboratory was supported by the Minerva Foundation and the European Research Council project Systems Analysis of Plant Metabolism through the Integration of Heterogeneous Data from Genetics, Informatics and Metabolomics (FP7 program). T.S. is supported by a grant from the Israel Science Foundation; A.A, E.R, and T.S are supported by a joint grant from the Ministry of Science and Technologies for an integrated study of plant metabolism; and S.M.-O. is supported by the Ministry of Science and Technology. A.A. is the incumbent of the Adolpho and Evelyn Blum Career Development Chair of Cancer Research.
PY - 2012/1/3
Y1 - 2012/1/3
N2 - Plant metabolic engineering is commonly used in the production of functional foods and quality trait improvement. However, to date, computational model-based approaches have only been scarcely used in this important endeavor, in marked contrast to their prominent success in microbial metabolic engineering. In this study we present a computational pipeline for the reconstruction of fully compartmentalized tissue-specific models of Arabidopsis thaliana on a genome scale. This reconstruction involves automatic extraction of known biochemical reactions in Arabidopsis for both primary and secondary metabolism, automatic gap-filling, and the implementation of methods for determining subcellular localization and tissue assignment of enzymes. The reconstructed tissue models are amenable for constraint-based modeling analysis, and significantly extend upon previous model reconstructions. A set of computational validations (i.e., cross-validation tests, simulations of known metabolic functionalities) and experimental validations (comparison with experimental metabolomics datasets under various compartments and tissues) strongly testify to the predictive ability of the models. The utility of the derived models was demonstrated in the prediction of measured fluxes in metabolically engineered seed strains and the design of genetic manipulations that are expected to increase vitamin E content, a significant nutrient for human health. Overall, the reconstructed tissue models are expected to lay down the foundations for computational-based rational design of plant metabolic engineering. The reconstructed compartmentalized Arabidopsis tissue models are MIRIAM-compliant and are available upon request.
AB - Plant metabolic engineering is commonly used in the production of functional foods and quality trait improvement. However, to date, computational model-based approaches have only been scarcely used in this important endeavor, in marked contrast to their prominent success in microbial metabolic engineering. In this study we present a computational pipeline for the reconstruction of fully compartmentalized tissue-specific models of Arabidopsis thaliana on a genome scale. This reconstruction involves automatic extraction of known biochemical reactions in Arabidopsis for both primary and secondary metabolism, automatic gap-filling, and the implementation of methods for determining subcellular localization and tissue assignment of enzymes. The reconstructed tissue models are amenable for constraint-based modeling analysis, and significantly extend upon previous model reconstructions. A set of computational validations (i.e., cross-validation tests, simulations of known metabolic functionalities) and experimental validations (comparison with experimental metabolomics datasets under various compartments and tissues) strongly testify to the predictive ability of the models. The utility of the derived models was demonstrated in the prediction of measured fluxes in metabolically engineered seed strains and the design of genetic manipulations that are expected to increase vitamin E content, a significant nutrient for human health. Overall, the reconstructed tissue models are expected to lay down the foundations for computational-based rational design of plant metabolic engineering. The reconstructed compartmentalized Arabidopsis tissue models are MIRIAM-compliant and are available upon request.
UR - http://www.scopus.com/inward/record.url?scp=84856015478&partnerID=8YFLogxK
U2 - https://doi.org/10.1073/pnas.1100358109
DO - https://doi.org/10.1073/pnas.1100358109
M3 - مقالة
SN - 0027-8424
VL - 109
SP - 339
EP - 344
JO - Proceedings of the National Academy of Sciences of the United States of America
JF - Proceedings of the National Academy of Sciences of the United States of America
IS - 1
ER -