Investigating the robustness of the classical enzyme kinetic equations in small intracellular compartments Export

@article{citeulike:6009599, abstract = {Classical descriptions of enzyme kinetics ignore the physical nature of the intracellular environment. Main implicit assumptions behind such approaches are that reactions occur in compartment volumes which are large enough so that molecular discreteness can be ignored and that molecular transport occurs via diffusion. Starting from a master equation description of enzyme reaction kinetics and assuming metabolic steady-state conditions, we derive novel mesoscopic rate equations which take into account (i) the intrinsic molecular noise due to the low copy number of molecules in intracellular compartments (ii) the physical nature of the substrate transport process, i.e. diffusion or vesicle-mediated transport. These equations replace the conventional macroscopic and deterministic equations in the context of intracellular kinetics. The latter are recovered in the limit of infinite compartment volumes. We find that deviations from the predictions of classical kinetics are pronounced (hundreds of percent in the estimate for the reaction velocity) for enzyme reactions occurring in compartments which are smaller than approximately 200nm, for the case of substrate transport to the compartment being mediated principally by vesicle or granule transport and in the presence of competitive enzyme inhibitors. This has implications for the common approach of modelling large intracellular reaction networks using ordinary differential equations and also for the calculation of the effective dosage of competitive inhibitor drugs.}, archivePrefix = {arXiv}, author = {Grima, Ramon}, citeulike-article-id = {6009599}, citeulike-linkout-0 = {http://arxiv.org/abs/0910.4469}, citeulike-linkout-1 = {http://arxiv.org/pdf/0910.4469}, day = {23}, eprint = {0910.4469}, keywords = {biophysics, enzyme, intracellular, kinetics, noise, robustness, stochastic}, month = {Oct}, posted-at = {2009-10-26 23:46:26}, priority = {2}, title = {Investigating the robustness of the classical enzyme kinetic equations in small intracellular compartments}, url = {http://arxiv.org/abs/0910.4469}, year = {2009} }

TY - JOUR ID - citeulike:6009599 L3 - citeulike-article-id:6009599 N2 - Classical descriptions of enzyme kinetics ignore the physical nature of the intracellular environment. Main implicit assumptions behind such approaches are that reactions occur in compartment volumes which are large enough so that molecular discreteness can be ignored and that molecular transport occurs via diffusion. Starting from a master equation description of enzyme reaction kinetics and assuming metabolic steady-state conditions, we derive novel mesoscopic rate equations which take into account (i) the intrinsic molecular noise due to the low copy number of molecules in intracellular compartments (ii) the physical nature of the substrate transport process, i.e. diffusion or vesicle-mediated transport. These equations replace the conventional macroscopic and deterministic equations in the context of intracellular kinetics. The latter are recovered in the limit of infinite compartment volumes. We find that deviations from the predictions of classical kinetics are pronounced (hundreds of percent in the estimate for the reaction velocity) for enzyme reactions occurring in compartments which are smaller than approximately 200nm, for the case of substrate transport to the compartment being mediated principally by vesicle or granule transport and in the presence of competitive enzyme inhibitors. This has implications for the common approach of modelling large intracellular reaction networks using ordinary differential equations and also for the calculation of the effective dosage of competitive inhibitor drugs. TI - Investigating the robustness of the classical enzyme kinetic equations in small intracellular compartments KW - biophysics KW - enzyme KW - intracellular KW - kinetics KW - noise KW - robustness KW - stochastic AU - Grima, Ramon PY - 2009/Oct/23/ UR - http://arxiv.org/abs/0910.4469 ER -