Sage Journals: Discover world-class research

Abstract

Flux balance analysis (FBA) is one of the most often applied methods on genome-scale metabolic networks. Although FBA uniquely determines the optimal yield, the pathway that achieves this is usually not unique. The analysis of the optimal-yield flux space has been an open challenge. Flux variability analysis is only capturing some properties of the flux space, while elementary mode analysis is intractable due to the enormous number of elementary modes. However, it has been found by Kelk et al. (2012) that the space of optimal-yield fluxes decomposes into flux modules. These decompositions allow a much easier but still comprehensive analysis of the optimal-yield flux space.

Using the mathematical definition of module introduced by Müller and Bockmayr (2013b), we discovered useful connections to matroid theory, through which efficient algorithms enable us to compute the decomposition into modules in a few seconds for genome-scale networks. Using that every module can be represented by one reaction that represents its function, in this article, we also present a method that uses this decomposition to visualize the interplay of modules. We expect the new method to replace flux variability analysis in the pipelines for metabolic networks.

Get full access to this article

View all access options for this article.

References

Beard

D.A.

, Babson

, Curtis

, and Qian

2004. Thermodynamic constraints for biochemical networks. J. Theor. Biol., 228, 327–333.

Burgard

A.P.

, Vaidyaraman

, and Maranas

C.D.

2001. Minimal reaction sets for escherichia coli metabolism under different growth requirements and uptake environments. Biotechnology Progress, 17, 791–797.

Cunningham

W.H.

1973. A combinatorial decomposition theory [Ph.D. thesis]. University of Waterloo, Ontario, Canada.

Feist

A.M.

, and Palsson

B.O.

2010. The biomass objective function. Current Opinion in Microbiology, 13, 344–349.

Gansner

E.R.

, Koutsofios

, North

S.C.

, and Vo

K.-p.

1993. A technique for drawing directed graphs. IEEE Transactions on Software Engineering, 19, 214–230.

Gansner

E.R.

, and North

S.C.

2000. An open graph visualization system and its applications to software engineering. Software - Practice and Experience, 30, 1203–1233.

Kelk

S.M.

, Olivier

B.G.

, Stougie

, and Bruggeman

F.J.

2012. Optimal flux spaces of genome-scale stoichiometric models are determined by a few subnetworks. Scientific Reports, 2, 580.

Khannapho

, Zhao

, Bonde

B.L.

, et al. 2008. Selection of objective function in genome scale flux balance analysis for process feed development in antibiotic production. Metabolic Engineering, 10, 227–233.

Krogdahl

1977. The dependence graph for bases in matroids. Discrete Mathematics, 19, 47–59.

10.

Mahadevan

, and Schilling

2003. The effects of alternate optimal solutions in constraint-based genome-scale metabolic models. Metabolic Engineering, 5, 264–276.

11.

Müller

A.C.

, and Bockmayr

2013a. Fast thermodynamically constrainted flux variability analysis. Bioinformatics, 29, 903–909.

12.

Müller

A.C.

, and Bockmayr

2013b. Flux modules in metabolic networks. Journal of Mathematical Biology, 69, 1151–1179.

13.

Oliveira

J.S.

, Bailey

C.G.

, Jones-Oliveira

J.B.

, and Dixon

D.A.

2001. An algebraic-combinatorial model for the identification and mapping of biochemical pathways. Bulletin of Mathematical Biology, 63, 1163–1196.

14.

Orth

J.D.

, Thiele

, and Palsson

B.O.

2010. What is flux balance analysis. Nat. Biotechnol., 28, 245248.

15.

Oxley

2011. Matroid Theory. Oxford Graduate Texts in Mathematics, 2nd ed. Oxford University Press, New York.

16.

Papin

A.J.

, Stelling

, Price

N.D.

, et al. 2004. Comparison of network-based pathway analysis methods. TRENDS in Biotechnology, 22, 400–405.

17.

Price

N.D.

, Reed

J.L.

, and Palsson

B.Ø.

2004. Genome-scale models of microbial cells: evaluating the consequences of constraints. Nature Reviews Microbiology, 2, 886–897.

18.

Santos

, Boele

, and Teusink

2011. A practical guide to genome-scale metabolic models and their analysis. Methods in Enzymology, 500, 509.

19.

Schuster

, and Hilgetag

1994. On elementary flux modes in biochemical systems at steady state. J. Biol. Systems, 2, 165–182.

20.

Schuster

, and Schuster

1991. Detecting strictly detailed balanced subnetworks in open chemical reaction networks. J. Math. Chem., 6, 17–40.

21.

Truemper

1984. Partial matroid representations. European Journal of Combinatorics, 5, 377–394.

22.

Varma

, and Palsson

B.O.

1994. Metabolic flux balancing: Basic concepts, scientific and practical use. Nat. Biotechnol., 12, 994–998.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.08 MB

Fast Flux Module Detection Using Matroid Theory

Abstract

Abstract

Get full access to this article

References

Supplementary Material