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/.
Genomic data now allow the large-scale manual or semi-automated reconstruction of metabolic networks. A network reconstruction represents a highly curated organism-specific knowledge base. A few genome-scale network reconstructions have appeared for metabolism in the baker’s yeast Saccharomyces cerevisiae. These alternative network reconstructions differ in scope and content, and further have used different terminologies to describe the same chemical entities, thus making comparisons between them difficult. The formulation of a ‘community consensus’ network that collects and formalizes the ‘community knowledge’ of yeast metabolism is thus highly desirable. We describe how we have produced a consensus metabolic network reconstruction for S. cerevisiae. Special emphasis is laid on referencing molecules to persistent databases or using database-independent forms such as SMILES or InChI strings, since 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, and we describe the manner in which it can be maintained as a community resource. It should serve as a common denominator for system biology studies of yeast. Similar strategies will be of benefit to communities studying genome-scale metabolic networks of other organisms.
We present an experimental and computational pipeline for the generation of kinetic models of metabolism, and demonstrate its application to glycolysis in Saccharomyces cerevisiae. Starting from an approximate mathematical model, we employ a “cycle of knowledge” strategy, identifying the steps with most control over flux. Kinetic parameters of the individual isoenzymes within these steps are measured experimentally under a standardised set of conditions. Experimental strategies are applied to establish a set of in vivo concentrations for isoenzymes and metabolites. The data are integrated into a mathematical model that is used to predict a new set of metabolite concentrations and reevaluate the control properties of the system. This bottom-up modelling study reveals that control over the metabolic network most directly involved in yeast glycolysis is more widely distributed than previously thought.
During transition into stationary phase a large set of proteins is induced in Escherichia coli. Only a minority of the corresponding genes has been identified so far. Using the lambda placMu system and a plate screen for carbon starvation-induced fusion activity, a series of chromosomal lacZ fusions (csi::lacZ) was isolated. In complex medium these fusions were induced either during late exponential phase or during entry into stationary phase. csi::lacZ expression in minimal media in response to starvation for carbon, nitrogen and phosphate sources and the roles of global regulators such as the alternative sigma factor sigma s (encoded by rpoS), cAMP/CRP and the relA gene product were investigated. The results show that almost every fusion exhibits its own characteristic pattern of expression, suggesting a complex control of stationary phase-inducible genes that involves various combinations of regulatory mechanisms for different genes. All fusions were mapped to the E. coli chromosome. Using fine mapping by Southern hybridization, cloning, sequencing and/or phenotypic analysis, csi-5, csi-17, and csi-18 could be localized in osmY (encoding a periplasmic protein), glpD (aerobic glycerol-3-phosphate dehydrogenase) and glgA (glycogen synthase), respectively. The other fusions seem to specify novel genes now designated csiA through to csiF. csi-17(glpD)::lacZ was shown to produce its own glucose-starvation induction, thus illustrating the intricacies of gene-fusion technology when applied to the study of gene regulation.
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