Combining Flux and Energy Balance Analysis to Model Large-scale Biochemical Networks

Stoichiometric Network Theory is a constraints-based, optimization approach for quantitative analysis of the phenotypes of large-scale biochemical networks that avoids the use of detailed kinetics. This approach uses the reaction stoichiometric matrix in conjunction with constraints provided by flux balance and energy balance to guarantee mass conserved and thermodynamically allowable predictions. However, the flux and energy balance constraints have not been effectively applied simultaneously on the genome scale because optimization under the combined constraints is non-linear. In this paper, a sequential quadratic programming algorithm that solves the non-linear optimization problem is introduced. A simple example and the system of fermentation in Saccharomyces cerevisiae are used to illustrate the new method. The algorithm allows the use of non-linear objective functions. As a result, we suggest a novel optimization with respect to the heat dissipation rate of a system. We also emphasize the importance of incorporating interactions between a model network and its surroundings.

[1]  B. Palsson,et al.  The Escherichia coli MG1655 in silico metabolic genotype: its definition, characteristics, and capabilities. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[2]  Patrick Van Dijck,et al.  Expression of Escherichia coli otsA in a Saccharomyces cerevisiae tps1 mutant restores trehalose 6-phosphate levels and partly restores growth and fermentation with glucose and control of glucose influx into glycolysis , 2000 .

[3]  H. Qian,et al.  Thermodynamics of stoichiometric biochemical networks in living systems far from equilibrium. , 2005, Biophysical chemistry.

[4]  Hong Qian,et al.  Ab initio prediction of thermodynamically feasible reaction directions from biochemical network stoichiometry. , 2005, Metabolic engineering.

[5]  H. Qian,et al.  Thermodynamic constraints for biochemical networks. , 2004, Journal of theoretical biology.

[6]  B. Palsson,et al.  The evolution of molecular biology into systems biology , 2004, Nature Biotechnology.

[7]  B. Palsson,et al.  Towards multidimensional genome annotation , 2006, Nature Reviews Genetics.

[8]  Reinhart Heinrich,et al.  Temperature dependency and temperature compensation in a model of yeast glycolytic oscillations. , 2003, Biophysical chemistry.

[9]  H. Qian,et al.  Energy balance for analysis of complex metabolic networks. , 2002, Biophysical journal.

[10]  Barbara M. Bakker,et al.  Can yeast glycolysis be understood in terms of in vitro kinetics of the constituent enzymes? Testing biochemistry. , 2000, European journal of biochemistry.

[11]  David A. Dixon,et al.  Hyperdigraph-Theoretic Analysis of the EGFR Signaling Network: Initial Steps Leading to GTP: Ras Complex Formation , 2004, J. Comput. Biol..

[12]  J. Edwards,et al.  Systems Properties of the Haemophilus influenzaeRd Metabolic Genotype* , 1999, The Journal of Biological Chemistry.

[13]  H. Qian,et al.  Stoichiometric network theory for nonequilibrium biochemical systems. , 2003, European journal of biochemistry.

[14]  B O Palsson,et al.  Flux-balance analysis of mitochondrial energy metabolism: consequences of systemic stoichiometric constraints. , 2001, American journal of physiology. Regulatory, integrative and comparative physiology.

[15]  Hong Qian,et al.  Open-system nonequilibrium steady state: statistical thermodynamics, fluctuations, and chemical oscillations. , 2006, The journal of physical chemistry. B.