Abstract
Reconstructions of cellular metabolism are publicly available for a variety of different microorganisms and some mammalian genomes. To date, these reconstructions are “genome-scale” and strive to include all reactions implied by the genome annotation, as well as those with direct experimental evidence. Clearly, many of the reactions in a genome-scale reconstruction will not be active under particular conditions or in a particular cell type. Methods to tailor these comprehensive genome-scale reconstructions into context-specific networks will aid predictive in silico modeling for a particular situation. We present a method called Gene Inactivity Moderated by Metabolism and Expression (GIMME) to achieve this goal. The GIMME algorithm uses quantitative gene expression data and one or more presupposed metabolic objectives to produce the context-specific reconstruction that is most consistent with the available data. Furthermore, the algorithm provides a quantitative inconsistency score indicating how consistent a set of gene expression data is with a particular metabolic objective. We show that this algorithm produces results consistent with biological experiments and intuition for adaptive evolution of bacteria, rational design of metabolic engineering strains, and human skeletal muscle cells. This work represents progress towards producing constraint-based models of metabolism that are specific to the conditions where the expression profiling data is available.
Highlights
Genome-scale metabolic networks are reconstructed to contain all known metabolic genes and reactions in a particular organism [1]
We have demonstrated the functionality of this Gene Inactivity Moderated by Metabolism and Expression (GIMME) method with gene expression data from E. coli and human skeletal muscle cells
We have shown that (1) the computed consistency between gene expression data for different conditions and Required Metabolic Functionalities (RMF) agrees with physiological data, (2) the most consistent networks depend on the metabolic objective and media conditions, and (3) the most consistent networks for human skeletal muscle cells contain significantly fewer reactions than the global human model
Summary
Genome-scale metabolic networks are reconstructed to contain all known metabolic genes and reactions in a particular organism [1]. From the top down, gene expression data provides a picture of what genes are being transcribed at a particular time, and which enzymes are probably active in the cell [3]. Both of these types of knowledge can be used to refine metabolic networks under given conditions. Metabolic network reconstructions can be combined with gene expression data from different states to identify regulatory principles in organisms [9]. Due to the noise, it is impossible to define a comprehensive set of present mRNA transcripts without a large
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