Metabolic network discovery through reverse engineering of metabolome data

Reverse engineering of high-throughput omics data to infer underlying biological networks is one of the challenges in systems biology. However, applications in the field of metabolomics are rather limited. We have focused on a systematic analysis of metabolic network inference from in silico metabol...

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Veröffentlicht in:	Metabolomics 2009-09, Vol.5 (3), p.318-329
Hauptverfasser:	Çakır, Tunahan, Hendriks, Margriet M. W. B, Westerhuis, Johan A, Smilde, Age K
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Schlagworte:	Biochemistry Biomedical and Life Sciences Biomedicine Cell Biology Developmental Biology Life Sciences Metabolites Molecular Medicine Original Original Article Studies
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container_title	Metabolomics
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creator	Çakır, Tunahan Hendriks, Margriet M. W. B Westerhuis, Johan A Smilde, Age K
description	Reverse engineering of high-throughput omics data to infer underlying biological networks is one of the challenges in systems biology. However, applications in the field of metabolomics are rather limited. We have focused on a systematic analysis of metabolic network inference from in silico metabolome data based on statistical similarity measures. Three different data types based on biological/environmental variability around steady state were analyzed to compare the relative information content of the data types for inferring the network. Comparing the inference power of different similarity scores indicated the clear superiority of conditioning or pruning based scores as they have the ability to eliminate indirect interactions. We also show that a mathematical measure based on the Fisher information matrix gives clues on the information quality of different data types to better represent the underlying metabolic network topology. Results on several datasets of increasing complexity consistently show that metabolic variations observed at steady state, the simplest experimental analysis, are already informative to reveal the connectivity of the underlying metabolic network with a low false-positive rate when proper similarity-score approaches are employed. For experimental situations this implies that a single organism under slightly varying conditions may already generate more than enough information to rightly infer networks. Detailed examination of the strengths of interactions of the underlying metabolic networks demonstrates that the edges that cannot be captured by similarity scores mainly belong to metabolites connected with weak interaction strength.
doi_str_mv	10.1007/s11306-009-0156-4
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title	Metabolic network discovery through reverse engineering of metabolome data
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