Your search keyword '"Weichart D"' showing total 5 results

1. A community-driven global reconstruction of human metabolism.

Author

Luxembourg Centre for Systems Biomedicine (LCSB): Experimental Neurobiology (Balling Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Molecular Systems Physiology (Thiele Group) [research center], Thiele, Ines(*), Swainston, N.(*), Fleming, Ronan MT, Hoppe, A., Sahoo, Swagatika, Aurich, Maike Kathrin, Haraldsdottir, Hulda, Mo, M. L., Rolfsson, O., Stobbe, M. D., Thorleifsson, S. G., Agren, R., Bölling, C., Bordel, S., Chavali, A. K., Dobson, P., Dunn, W. B., Endler, L., Hala, D., Hucka, M., Hull, D., Jameson, D., Jamshidi, N., Jonsson, J. J., Juty, N., Keating, S., Nookaew, I., Le Novère, N., Malys, N., Mazein, A., Papin, J. A., Price, N. D., Selkov, E. Sr, Sigurdsson, M. I., Simeonidis, Evangelos, Sonnenschein, N., Smallbone, K., Sorokin, A., van Beek, J. H., Weichart, D., Goryanin, I., Nielsen, J., Westerhoff, H. V., Kell, D. B., Mendes, P., Palsson, B. O., Luxembourg Centre for Systems Biomedicine (LCSB): Experimental Neurobiology (Balling Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Molecular Systems Physiology (Thiele Group) [research center], Thiele, Ines(*), Swainston, N.(*), Fleming, Ronan MT, Hoppe, A., Sahoo, Swagatika, Aurich, Maike Kathrin, Haraldsdottir, Hulda, Mo, M. L., Rolfsson, O., Stobbe, M. D., Thorleifsson, S. G., Agren, R., Bölling, C., Bordel, S., Chavali, A. K., Dobson, P., Dunn, W. B., Endler, L., Hala, D., Hucka, M., Hull, D., Jameson, D., Jamshidi, N., Jonsson, J. J., Juty, N., Keating, S., Nookaew, I., Le Novère, N., Malys, N., Mazein, A., Papin, J. A., Price, N. D., Selkov, E. Sr, Sigurdsson, M. I., Simeonidis, Evangelos, Sonnenschein, N., Smallbone, K., Sorokin, A., van Beek, J. H., Weichart, D., Goryanin, I., Nielsen, J., Westerhoff, H. V., Kell, D. B., Mendes, P., and Palsson, B. O.

Abstract

Multiple models of human metabolism have been reconstructed, but each represents only a subset of our knowledge. Here we describe Recon 2, a community-driven, consensus ‘metabolic reconstruction’, which is the most comprehensive representation of human metabolism that is applicable to computational modeling. Compared with its predecessors, the reconstruction has improved topological and functional features, including ~2× more reactions and ~1.7× more unique metabolites. Using Recon 2 we predicted changes in metabolite biomarkers for 49 inborn errors of metabolism with 77% accuracy when compared to experimental data. Mapping metabolomic data and drug information onto Recon 2 demonstrates its potential for integrating and analyzing diverse data types. Using protein expression data, we automatically generated a compendium of 65 cell type–specific models, providing a basis for manual curation or investigation of cell-specific metabolic properties. Recon 2 will facilitate many future biomedical studies and is freely available at http://humanmetabolism.org/.

Published

2013

2. A community-driven global reconstruction of human metabolism.

Author

Luxembourg Centre for Systems Biomedicine (LCSB): Experimental Neurobiology (Balling Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Molecular Systems Physiology (Thiele Group) [research center], Thiele, Ines(*), Swainston, N.(*), Fleming, Ronan MT, Hoppe, A., Sahoo, Swagatika, Aurich, Maike Kathrin, Haraldsdottir, Hulda, Mo, M. L., Rolfsson, O., Stobbe, M. D., Thorleifsson, S. G., Agren, R., Bölling, C., Bordel, S., Chavali, A. K., Dobson, P., Dunn, W. B., Endler, L., Hala, D., Hucka, M., Hull, D., Jameson, D., Jamshidi, N., Jonsson, J. J., Juty, N., Keating, S., Nookaew, I., Le Novère, N., Malys, N., Mazein, A., Papin, J. A., Price, N. D., Selkov, E. Sr, Sigurdsson, M. I., Simeonidis, Evangelos, Sonnenschein, N., Smallbone, K., Sorokin, A., van Beek, J. H., Weichart, D., Goryanin, I., Nielsen, J., Westerhoff, H. V., Kell, D. B., Mendes, P., Palsson, B. O., Luxembourg Centre for Systems Biomedicine (LCSB): Experimental Neurobiology (Balling Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Molecular Systems Physiology (Thiele Group) [research center], Thiele, Ines(*), Swainston, N.(*), Fleming, Ronan MT, Hoppe, A., Sahoo, Swagatika, Aurich, Maike Kathrin, Haraldsdottir, Hulda, Mo, M. L., Rolfsson, O., Stobbe, M. D., Thorleifsson, S. G., Agren, R., Bölling, C., Bordel, S., Chavali, A. K., Dobson, P., Dunn, W. B., Endler, L., Hala, D., Hucka, M., Hull, D., Jameson, D., Jamshidi, N., Jonsson, J. J., Juty, N., Keating, S., Nookaew, I., Le Novère, N., Malys, N., Mazein, A., Papin, J. A., Price, N. D., Selkov, E. Sr, Sigurdsson, M. I., Simeonidis, Evangelos, Sonnenschein, N., Smallbone, K., Sorokin, A., van Beek, J. H., Weichart, D., Goryanin, I., Nielsen, J., Westerhoff, H. V., Kell, D. B., Mendes, P., and Palsson, B. O.

Abstract

Multiple models of human metabolism have been reconstructed, but each represents only a subset of our knowledge. Here we describe Recon 2, a community-driven, consensus ‘metabolic reconstruction’, which is the most comprehensive representation of human metabolism that is applicable to computational modeling. Compared with its predecessors, the reconstruction has improved topological and functional features, including ~2× more reactions and ~1.7× more unique metabolites. Using Recon 2 we predicted changes in metabolite biomarkers for 49 inborn errors of metabolism with 77% accuracy when compared to experimental data. Mapping metabolomic data and drug information onto Recon 2 demonstrates its potential for integrating and analyzing diverse data types. Using protein expression data, we automatically generated a compendium of 65 cell type–specific models, providing a basis for manual curation or investigation of cell-specific metabolic properties. Recon 2 will facilitate many future biomedical studies and is freely available at http://humanmetabolism.org/.

Published

2013

3. Systematic integration of experimental data and models in systems biology.

Author

Li, P., Dada, J.O., Jameson, D., Spasic, I., Swainston, N., Carroll, K., Dunn, W., Khan, F., Messiha, E., Simeonides, E., Weichart, D., Winder, C., Broomhead, D.S., Goble, C.A., Gaskell, S.J., Kell, D.B., Westerhoff, H.V., Mendes, P., Paton, N.W., Li, P., Dada, J.O., Jameson, D., Spasic, I., Swainston, N., Carroll, K., Dunn, W., Khan, F., Messiha, E., Simeonides, E., Weichart, D., Winder, C., Broomhead, D.S., Goble, C.A., Gaskell, S.J., Kell, D.B., Westerhoff, H.V., Mendes, P., and Paton, N.W.

Abstract

Background: The behaviour of biological systems can be deduced from their mathematical models. However, multiple sources of data in diverse forms are required in the construction of a model in order to define its components and their biochemical reactions, and corresponding parameters. Automating the assembly and use of systems biology models is dependent upon data integration processes involving the interoperation of data and analytical resources.Results: Taverna workflows have been developed for the automated assembly of quantitative parameterised metabolic networks in the Systems Biology Markup Language (SBML). A SBML model is built in a systematic fashion by the workflows which starts with the construction of a qualitative network using data from a MIRIAM-compliant genome-scale model of yeast metabolism. This is followed by parameterisation of the SBML model with experimental data from two repositories, the SABIO-RK enzyme kinetics database and a database of quantitative experimental results. The models are then calibrated and simulated in workflows that call out to COPASIWS, the web service interface to the COPASI software application for analysing biochemical networks. These systems biology workflows were evaluated for their ability to construct a parameterised model of yeast glycolysis.Conclusions: Distributed information about metabolic reactions that have been described to MIRIAM standards enables the automated assembly of quantitative systems biology models of metabolic networks based on user-defined criteria. Such data integration processes can be implemented as Taverna workflows to provide a rapid overview of the components and their relationships within a biochemical system. © 2010 Li et al; licensee BioMed Central Ltd.

Published

2010

4. Systematic integration of experimental data and models in systems biology.

Author

Li, P., Dada, J.O., Jameson, D., Spasic, I., Swainston, N., Carroll, K., Dunn, W., Khan, F., Messiha, E., Simeonides, E., Weichart, D., Winder, C., Broomhead, D.S., Goble, C.A., Gaskell, S.J., Kell, D.B., Westerhoff, H.V., Mendes, P., Paton, N.W., Li, P., Dada, J.O., Jameson, D., Spasic, I., Swainston, N., Carroll, K., Dunn, W., Khan, F., Messiha, E., Simeonides, E., Weichart, D., Winder, C., Broomhead, D.S., Goble, C.A., Gaskell, S.J., Kell, D.B., Westerhoff, H.V., Mendes, P., and Paton, N.W.

Abstract

Background: The behaviour of biological systems can be deduced from their mathematical models. However, multiple sources of data in diverse forms are required in the construction of a model in order to define its components and their biochemical reactions, and corresponding parameters. Automating the assembly and use of systems biology models is dependent upon data integration processes involving the interoperation of data and analytical resources.Results: Taverna workflows have been developed for the automated assembly of quantitative parameterised metabolic networks in the Systems Biology Markup Language (SBML). A SBML model is built in a systematic fashion by the workflows which starts with the construction of a qualitative network using data from a MIRIAM-compliant genome-scale model of yeast metabolism. This is followed by parameterisation of the SBML model with experimental data from two repositories, the SABIO-RK enzyme kinetics database and a database of quantitative experimental results. The models are then calibrated and simulated in workflows that call out to COPASIWS, the web service interface to the COPASI software application for analysing biochemical networks. These systems biology workflows were evaluated for their ability to construct a parameterised model of yeast glycolysis.Conclusions: Distributed information about metabolic reactions that have been described to MIRIAM standards enables the automated assembly of quantitative systems biology models of metabolic networks based on user-defined criteria. Such data integration processes can be implemented as Taverna workflows to provide a rapid overview of the components and their relationships within a biochemical system. © 2010 Li et al; licensee BioMed Central Ltd.

Published

2010

5. A consensus yeast metabolic network reconstruction obtained from a community approach to systems biology

Author

Herrgård, M.J., Swainston, N., Dobson, P., Dunn, W.B., Arga, K.Y., Arvas, M., Blüthgen, N., Borger, S., Costenoble, R., Heinemann, M., Hucka, M., Le Novère, N., Li, P, Liebermeister, W., Mo, M.L., Oliveira, A.P., Petranovic, D., Pettifer, S., Simeonidis, E., Smallbone, K., Spasić, I., Weichart, D., Brent, R., Broomhead, D.S., Westerhoff, H.V., Kırdar, B.I., Penttilä, M., Klipp, E., Palsson, B.Ø., Sauer, U., Oliver, S.G., Mendes, P., Nielsen, J., Kell, D.B., Herrgård, M.J., Swainston, N., Dobson, P., Dunn, W.B., Arga, K.Y., Arvas, M., Blüthgen, N., Borger, S., Costenoble, R., Heinemann, M., Hucka, M., Le Novère, N., Li, P, Liebermeister, W., Mo, M.L., Oliveira, A.P., Petranovic, D., Pettifer, S., Simeonidis, E., Smallbone, K., Spasić, I., Weichart, D., Brent, R., Broomhead, D.S., Westerhoff, H.V., Kırdar, B.I., Penttilä, M., Klipp, E., Palsson, B.Ø., Sauer, U., Oliver, S.G., Mendes, P., Nielsen, J., and Kell, D.B.

Abstract

Genomic data allow the large-scale manual or semi-automated assembly of metabolic network reconstructions, which provide highly curated organism-specific knowledge bases. Although several genome-scale network reconstructions describe Saccharomyces cerevisiae metabolism, they differ in scope and content, and use different terminologies to describe the same chemical entities. This makes comparisons between them difficult and underscores the desirability of a consolidated metabolic network that collects and formalizes the 'community knowledge' of yeast metabolism. We describe how we have produced a consensus metabolic network reconstruction for S. cerevisiae. In drafting it, we placed special emphasis on referencing molecules to persistent databases or using database-independent forms, such as SMILES or InChI strings, as this permits their chemical structure to be represented unambiguously and in a manner that permits automated reasoning. The reconstruction is readily available via a publicly accessible database and in the Systems Biology Markup Language (http://www.comp-sys-bio.org/yeastnet). It can be maintained as a resource that serves as a common denominator for studying the systems biology of yeast. Similar strategies should benefit communities studying genome-scale metabolic networks of other organisms.