Fluxomers: a new approach for 13 C metabolic flux

Background: The ability to perform quantitative studies using isotope tracers and metabolic flux analysis (MFA) is critical for detecting pathway bottlenecks and elucidating network regulation in biological systems, especially those that have been engineered to alter their native metabolic capacities. Mathematically, MFA models are traditionally formulated using separate state variables for reaction fluxes and isotopomer abundances. Analysis of isotope labeling experiments using this set of variables results in a non-convex optimization problem that suffers from both implementation complexity and convergence problems. Results: This article addresses the mathematical and computational formulation of 13 C MFA models using a new set of variables referred to as fluxomers. These composite variables combine both fluxes and isotopomer abundances, which results in a simply-posed formulation and an improved error model that is insensitive to isotopomer measurement normalization. A powerful fluxomer iterative algorithm (FIA) is developed and applied to solve the MFA optimization problem. For moderate-sized networks, the algorithm is shown to outperform the commonly used 13CFLUX cumomer-based algorithm and the more recently introduced OpenFLUX software that relies upon an elementary metabolite unit (EMU) network decomposition, both in terms of convergence time and output variability. Conclusions: Substantial improvements in convergence time and statistical quality of results can be achieved by applying fluxomer variables and the FIA algorithm to compute best-fit solutions to MFA models. We expect that the fluxomer formulation will provide a more suitable basis for future algorithms that analyze very large scale networks and design optimal isotope labeling experiments.

[1]  W. Wiechert,et al.  Bidirectional reaction steps in metabolic networks: III. Explicit solution and analysis of isotopomer labeling systems. , 1999, Biotechnology and bioengineering.

[2]  H Sahm,et al.  Determination of the fluxes in the central metabolism of Corynebacterium glutamicum by nuclear magnetic resonance spectroscopy combined with metabolite balancing , 1996, Biotechnology and bioengineering.

[3]  W Wiechert,et al.  A universal framework for 13C metabolic flux analysis. , 2001, Metabolic engineering.

[4]  K. Jittorntrum An implicit function theorem , 1978 .

[5]  W Wiechert,et al.  Bidirectional reaction steps in metabolic networks: IV. Optimal design of isotopomer labeling experiments. , 1999, Biotechnology and bioengineering.

[6]  Christoph Wittmann,et al.  Theoretical aspects of 13C metabolic flux analysis with sole quantification of carbon dioxide labeling , 2005, Comput. Biol. Chem..

[7]  Michael A. Saunders,et al.  SNOPT: An SQP Algorithm for Large-Scale Constrained Optimization , 2002, SIAM J. Optim..

[8]  J Villadsen,et al.  Quantification of intracellular metabolic fluxes from fractional enrichment and 13C-13C coupling constraints on the isotopomer distribution in labeled biomass components. , 1999, Metabolic engineering.

[9]  James M. Ortega,et al.  Iterative solution of nonlinear equations in several variables , 2014, Computer science and applied mathematics.

[10]  L. Quek,et al.  OpenFLUX: efficient modelling software for 13C-based metabolic flux analysis , 2009, Microbial cell factories.

[11]  Ralf Steuer,et al.  Review: On the analysis and interpretation of correlations in metabolomic data , 2006, Briefings Bioinform..

[12]  W. Wiechert,et al.  Bidirectional reaction steps in metabolic networks: I. Modeling and simulation of carbon isotope labeling experiments. , 1997, Biotechnology and bioengineering.

[13]  Gregory Stephanopoulos,et al.  Determination of confidence intervals of metabolic fluxes estimated from stable isotope measurements. , 2006, Metabolic engineering.

[14]  Christoph Wittmann,et al.  Amplified Expression of Fructose 1,6-Bisphosphatase in Corynebacterium glutamicum Increases In Vivo Flux through the Pentose Phosphate Pathway and Lysine Production on Different Carbon Sources , 2005, Applied and Environmental Microbiology.

[15]  J. Nielsen,et al.  Quantitative analysis of metabolic fluxes in Escherichia coli, using two-dimensional NMR spectroscopy and complete isotopomer models. , 1999, Journal of biotechnology.

[16]  W. Wiechert,et al.  Bidirectional reaction steps in metabolic networks: II. Flux estimation and statistical analysis. , 1997, Biotechnology and bioengineering.

[17]  Tjalling J. Ypma,et al.  Historical Development of the Newton-Raphson Method , 1995, SIAM Rev..

[18]  Dieter Kraft,et al.  Algorithm 733: TOMP–Fortran modules for optimal control calculations , 1994, TOMS.

[19]  G. Stephanopoulos,et al.  Elementary metabolite units (EMU): a novel framework for modeling isotopic distributions. , 2007, Metabolic engineering.