Identification of Conserved Moieties in Metabolic Networks by Graph Theoretical Analysis of Atom Transition Networks.

Hulda S Haraldsdóttir,Ronan M T Fleming,Costas D Maranas

doi:10.1371/journal.pcbi.1004999

Hulda S Haraldsdóttir, Ronan M T Fleming + Show 1 more

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https://doi.org/10.1371/journal.pcbi.1004999

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Journal: PLoS computational biology	Publication Date: Nov 21, 2016
Citations: 49	License type: CC BY 4.0

Affiliation: University of Luxembourg

Abstract

Conserved moieties are groups of atoms that remain intact in all reactions of a metabolic network. Identification of conserved moieties gives insight into the structure and function of metabolic networks and facilitates metabolic modelling. All moiety conservation relations can be represented as nonnegative integer vectors in the left null space of the stoichiometric matrix corresponding to a biochemical network. Algorithms exist to compute such vectors based only on reaction stoichiometry but their computational complexity has limited their application to relatively small metabolic networks. Moreover, the vectors returned by existing algorithms do not, in general, represent conservation of a specific moiety with a defined atomic structure. Here, we show that identification of conserved moieties requires data on reaction atom mappings in addition to stoichiometry. We present a novel method to identify conserved moieties in metabolic networks by graph theoretical analysis of their underlying atom transition networks. Our method returns the exact group of atoms belonging to each conserved moiety as well as the corresponding vector in the left null space of the stoichiometric matrix. It can be implemented as a pipeline of polynomial time algorithms. Our implementation completes in under five minutes on a metabolic network with more than 4,000 mass balanced reactions. The scalability of the method enables extension of existing applications for moiety conservation relations to genome-scale metabolic networks. We also give examples of new applications made possible by elucidating the atomic structure of conserved moieties.

Highlights

Conserved moieties give rise to pools of metabolites with constant total concentration and dependent individual concentrations
Conserved moieties are transferred between metabolites in internal reactions of a metabolic network but are not synthesised, degraded or exchanged with the environment
The total amount of a conserved moiety in the metabolic network is constant over time

Summary

Introduction

Conserved moieties give rise to pools of metabolites with constant total concentration and dependent individual concentrations. These constant metabolite pools often consist of highly connected cofactors that are distributed throughout a metabolic network. Moiety conservation imposes a purely physicochemical form of regulation on metabolism that is mediated through changes in concentration ratios within constant metabolite pools. Reich and Sel’kov likened conserved moieties to turning wheels that are “geared into a clockwork” [2]. They described the thermodynamic state of energy metabolism as “open flow through a system closed by moiety conservation”. It has been shown to be relevant for drug development [4, 5]

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