Your search keyword '"Centler, Florian"' showing total 3 results

1. Computing chemical organizations in biological networks.

Author

Centler F, Kaleta C, di Fenizio PS, and Dittrich P

Subjects

Algorithms, Animals, Biology methods, Computer Simulation, Escherichia coli genetics, Escherichia coli metabolism, Genome, Genome, Bacterial, Humans, Models, Biological, Models, Chemical, Software, Software Design, Computational Biology methods, Systems Biology

Abstract

Motivation: Novel techniques are required to analyze computational models of intracellular processes as they increase steadily in size and complexity. The theory of chemical organizations has recently been introduced as such a technique that links the topology of biochemical reaction network models to their dynamical repertoire. The network is decomposed into algebraically closed and self-maintaining subnetworks called organizations. They form a hierarchy representing all feasible system states including all steady states., Results: We present three algorithms to compute the hierarchy of organizations for network models provided in SBML format. Two of them compute the complete organization hierarchy, while the third one uses heuristics to obtain a subset of all organizations for large models. While the constructive approach computes the hierarchy starting from the smallest organization in a bottom-up fashion, the flux-based approach employs self-maintaining flux distributions to determine organizations. A runtime comparison on 16 different network models of natural systems showed that none of the two exhaustive algorithms is superior in all cases. Studying a 'genome-scale' network model with 762 species and 1193 reactions, we demonstrate how the organization hierarchy helps to uncover the model structure and allows to evaluate the model's quality, for example by detecting components and subsystems of the model whose maintenance is not explained by the model., Availability: All data and a Java implementation that plugs into the Systems Biology Workbench is available from http://www.minet.uni-jena.de/csb/prj/ot/tools.

Published

2008

2. Phenotype prediction in regulated metabolic networks.

Author

Kaleta C, Centler F, di Fenizio PS, and Dittrich P

Subjects

Catalysis, Chemistry, Organic methods, Culture Media, Energy Transfer physiology, Escherichia coli Proteins genetics, Escherichia coli Proteins metabolism, Models, Biological, Predictive Value of Tests, Protein Interaction Mapping methods, Signal Transduction, Escherichia coli genetics, Escherichia coli metabolism, Gene Expression Regulation, Bacterial physiology, Metabolic Networks and Pathways genetics, Phenotype, Systems Biology methods

Abstract

Background: Due to the growing amount of biological knowledge that is incorporated into metabolic network models, their analysis has become more and more challenging. Here, we examine the capabilities of the recently introduced chemical organization theory (OT) to ease this task. Considering only network stoichiometry, the theory allows the prediction of all potentially persistent species sets and therewith rigorously relates the structure of a network to its potential dynamics. By this, the phenotypes implied by a metabolic network can be predicted without the need for explicit knowledge of the detailed reaction kinetics., Results: We propose an approach to deal with regulation - and especially inhibitory interactions - in chemical organization theory. One advantage of this approach is that the metabolic network and its regulation are represented in an integrated way as one reaction network. To demonstrate the feasibility of this approach we examine a model by Covert and Palsson (J Biol Chem, 277(31), 2002) of the central metabolism of E. coli that incorporates the regulation of all involved genes. Our method correctly predicts the known growth phenotypes on 16 different substrates. Without specific assumptions, organization theory correctly predicts the lethality of knockout experiments in 101 out of 116 cases. Taking into account the same model specific assumptions as in the regulatory flux balance analysis (rFBA) by Covert and Palsson, the same performance is achieved (106 correctly predicted cases). Two model specific assumptions had to be considered: first, we have to assume that secreted molecules do not influence the regulatory system, and second, that metabolites with increasing concentrations indicate a lethal state., Conclusion: The introduced approach to model a metabolic network and its regulation in an integrated way as one reaction network makes organization analysis a universal technique to study the potential behavior of biological network models. Applying multiple methods like OT and rFBA is shown to be valuable to uncover critical assumptions and helps to improve model coherence.

Published

2008

3. Chemical Organizations in the Central Sugar Metabolism of Escherichia coli

Author

Centler, Florian, Fenizio, Pietro Speroni di, Matsumaru, Naoki, Dittrich, Peter, Belloma, Nicola, editor, Deutsch, Andreas, editor, Brusch, Lutz, editor, Byrne, Helen, editor, Vries, Gerda de, editor, and Herzel, Hanspeter, editor

Published

2007