Abstract
Genome-scale network reconstructions are useful tools for understanding cellular metabolism, and comparisons of such reconstructions can provide insight into metabolic differences between organisms. Recent efforts toward comparing genome-scale models have focused primarily on aligning metabolic networks at the reaction level and then looking at differences and similarities in reaction and gene content. However, these reaction comparison approaches are time-consuming and do not identify the effect network differences have on the functional states of the network. We have developed a bilevel mixed-integer programming approach, CONGA, to identify functional differences between metabolic networks by comparing network reconstructions aligned at the gene level. We first identify orthologous genes across two reconstructions and then use CONGA to identify conditions under which differences in gene content give rise to differences in metabolic capabilities. By seeking genes whose deletion in one or both models disproportionately changes flux through a selected reaction (e.g., growth or by-product secretion) in one model over another, we are able to identify structural metabolic network differences enabling unique metabolic capabilities. Using CONGA, we explore functional differences between two metabolic reconstructions of Escherichia coli and identify a set of reactions responsible for chemical production differences between the two models. We also use this approach to aid in the development of a genome-scale model of Synechococcus sp. PCC 7002. Finally, we propose potential antimicrobial targets in Mycobacterium tuberculosis and Staphylococcus aureus based on differences in their metabolic capabilities. Through these examples, we demonstrate that a gene-centric approach to comparing metabolic networks allows for a rapid comparison of metabolic models at a functional level. Using CONGA, we can identify differences in reaction and gene content which give rise to different functional predictions. Because CONGA provides a general framework, it can be applied to find functional differences across models and biological systems beyond those presented here.
Highlights
Advances in genome sequencing and computational modeling techniques have sparked the construction of genome-scale network reconstructions (GENREs) [1] for over 100 prokaryotic and eukaryotic organisms [2]
We have developed a bilevel mixed-integer linear programming (MILP) approach to identify functional differences between models by comparing network reconstructions aligned at the gene level, bypassing the need for a time-consuming reaction-level alignment
We have developed a bilevel mixed-integer linear programming (MILP) approach, called CONGA, to identify functional differences between two networks by comparing network reconstructions aligned at the gene level
Summary
Advances in genome sequencing and computational modeling techniques have sparked the construction of genome-scale network reconstructions (GENREs) [1] for over 100 prokaryotic and eukaryotic organisms [2]. These reconstructions describe the functions of hundreds of metabolic genes, and enable a concise mathematical representation of an organism’s biochemical capabilities via genome-scale models. Existing network comparison approaches such as reconstruction jamborees [7,8] or metabolic network reconciliation [9] compare models of the same or closelyrelated organisms with the aim of identifying and reconciling differences between models. Reaction alignment approaches can be time-consuming, since biochemical databases (such as BiGG, BioCyc, KEGG or SEED [10,11,12,13]) and model construction platforms (such as Pathway Tools [14] or the Model SEED [6]) may use different nomenclatures or abbreviations to describe metabolites and reactions
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