Metabolite coupling in genome-scale metabolic networks

BackgroundBiochemically detailed stoichiometric matrices have now been reconstructed for various bacteria, yeast, and for the human cardiac mitochondrion based on genomic and proteomic data. These networks have been manually curated based on legacy data and elementally and charge balanced. Comparative analysis of these well curated networks is now possible. Pairs of metabolites often appear together in several network reactions, linking them topologically. This co-occurrence of pairs of metabolites in metabolic reactions is termed herein "metabolite coupling." These metabolite pairs can be directly computed from the stoichiometric matrix, S. Metabolite coupling is derived from the matrix ŜŜT, whose off-diagonal elements indicate the number of reactions in which any two metabolites participate together, where Ŝ is the binary form of S.ResultsMetabolite coupling in the studied networks was found to be dominated by a relatively small group of highly interacting pairs of metabolites. As would be expected, metabolites with high individual metabolite connectivity also tended to be those with the highest metabolite coupling, as the most connected metabolites couple more often. For metabolite pairs that are not highly coupled, we show that the number of reactions a pair of metabolites shares across a metabolic network closely approximates a line on a log-log scale. We also show that the preferential coupling of two metabolites with each other is spread across the spectrum of metabolites and is not unique to the most connected metabolites. We provide a measure for determining which metabolite pairs couple more often than would be expected based on their individual connectivity in the network and show that these metabolites often derive their principal biological functions from existing in pairs. Thus, analysis of metabolite coupling provides information beyond that which is found from studying the individual connectivity of individual metabolites.ConclusionThe coupling of metabolites is an important topological property of metabolic networks. By computing coupling quantitatively for the first time in genome-scale metabolic networks, we provide insight into the basic structure of these networks.

[1]  A. Barabasi,et al.  Global organization of metabolic fluxes in the bacterium Escherichia coli , 2004, Nature.

[2]  Pierre N. Robillard,et al.  Modeling and Simulation of Molecular Biology Systems Using Petri Nets: Modeling Goals of Various Approaches , 2004, J. Bioinform. Comput. Biol..

[3]  D. Fell,et al.  The small world of metabolism , 2000, Nature Biotechnology.

[4]  R. Tanaka,et al.  Scale-rich metabolic networks. , 2005, Physical review letters.

[5]  B. Palsson,et al.  Assessment of the metabolic capabilities of Haemophilus influenzae Rd through a genome-scale pathway analysis. , 2000, Journal of theoretical biology.

[6]  A. Telser Molecular Biology of the Cell, 4th Edition , 2002 .

[7]  Gong-Xin Yu,et al.  Ruleminer: a Knowledge System for Supporting High-throughput Protein Function Annotations , 2004, J. Bioinform. Comput. Biol..

[8]  S. Wuchty Scale-free behavior in protein domain networks. , 2001, Molecular biology and evolution.

[9]  R. Albert,et al.  The large-scale organization of metabolic networks , 2000, Nature.

[10]  Costas D Maranas,et al.  Elucidation and structural analysis of conserved pools for genome-scale metabolic reconstructions. , 2005, Biophysical journal.

[11]  Bernhard Palsson,et al.  Two-dimensional annotation of genomes , 2004, Nature Biotechnology.

[12]  B. Palsson,et al.  An expanded genome-scale model of Escherichia coli K-12 (iJR904 GSM/GPR) , 2003, Genome Biology.

[13]  A. Barabasi,et al.  Network biology: understanding the cell's functional organization , 2004, Nature Reviews Genetics.

[14]  Markus J. Herrgård,et al.  Reconstruction and validation of Saccharomyces cerevisiae iND750, a fully compartmentalized genome-scale metabolic model. , 2004, Genome research.

[15]  Stephen S Fong,et al.  Metabolic gene–deletion strains of Escherichia coli evolve to computationally predicted growth phenotypes , 2004, Nature Genetics.

[16]  Harvey J. Greenberg,et al.  Reconstruction and Functional Characterization of the Human Mitochondrial Metabolic Network Based on Proteomic and Biochemical Data* , 2004, Journal of Biological Chemistry.

[17]  J. Nielsen,et al.  Genome-scale analysis of Streptomyces coelicolor A3(2) metabolism. , 2005, Genome research.

[18]  Michael I. Jordan,et al.  Protein Molecular Function Prediction by Bayesian Phylogenomics , 2005, PLoS Comput. Biol..

[19]  G. Church,et al.  Analysis of optimality in natural and perturbed metabolic networks , 2002 .

[20]  B. Palsson,et al.  Genome-scale reconstruction of the metabolic network in Staphylococcus aureus N315: an initial draft to the two-dimensional annotation , 2005, BMC Microbiology.

[21]  B. Palsson,et al.  Expanded Metabolic Reconstruction of Helicobacter pylori (iIT341 GSM/GPR): an In Silico Genome-Scale Characterization of Single- and Double-Deletion Mutants , 2005, Journal of bacteriology.

[22]  A. Lehninger Principles of Biochemistry , 1984 .

[23]  B O Palsson,et al.  Metabolic modeling of microbial strains in silico. , 2001, Trends in biochemical sciences.

[24]  B. Alberts,et al.  Molecular Biology of the Cell 4th edition , 2007 .

[25]  A. Barabasi,et al.  Hierarchical Organization of Modularity in Metabolic Networks , 2002, Science.

[26]  Adam M. Feist,et al.  Modeling methanogenesis with a genome‐scale metabolic reconstruction of Methanosarcina barkeri , 2006 .