Title :
Modeling the Glycolysis: An Inverse Problem Approach
Author :
Demongeot, Jacques ; Doncescu, Andrei
Author_Institution :
Fac. of Med., Univ. J. Fourier Grenoble, La Tranche
Abstract :
We show in this paper that the metabolic chain can be supposed a potential-Hamiltonian system in which the dynamical flow can be shared between gradient dissipative and periodic conservative parts. If the chain is branched and if we know the fluxes at the extremities of each branch we can deduce information about the internal kinetics (e.g. place of allosteric and Michaelian step with respect to those of branching paths, cooperatively) from minimal additional measurements inside the black box constituted by the system. We will treat as example the glycolysis with the pentose pathway whose fluxes measurements are done at the pyruvate and pentose levels.
Keywords :
biochemistry; cellular biophysics; inverse problems; reaction kinetics theory; dynamical flow; glycolysis modeling; gradient dissipative parts; inverse problem; metabolic chain; pentose pathway; periodic conservative parts; potential Hamiltonian system; pyruvate; Biochemistry; Biological systems; Differential equations; Evolution (biology); Extremities; Humans; Inverse problems; Kinetic theory; Mathematical model; Nonlinear dynamical systems; enzymatic kinetics; generalized control strength coefficients; inverse problem; metabolic networks; potential-Hamiltonian decomposition;
Conference_Titel :
Advanced Information Networking and Applications Workshops, 2009. WAINA '09. International Conference on
Conference_Location :
Bradford
Print_ISBN :
978-1-4244-3999-7
Electronic_ISBN :
978-0-7695-3639-2
DOI :
10.1109/WAINA.2009.135
