%0 Journal Article %1 Morelli:2008:J-Chem-Phys:18698893 %A Morelli, M J %A ten Wolde, P R %D 2008 %J J Chem Phys %K brownian network_analysis %N 5 %P 054112-054112 %R 10.1063/1.2958287 %T Reaction Brownian dynamics and the effect of spatial fluctuations on the gain of a push-pull network %U http://www.ncbi.nlm.nih.gov/pubmed/18698893?dopt=Abstract %V 129 %X Brownian Dynamics algorithms have been widely used for simulating systems in soft-condensed matter physics. In recent times, their application has been extended to the simulation of coarse-grained models of biochemical networks. In these models, components move by diffusion and interact with one another upon contact. However, when reactions are incorporated into a Brownian dynamics algorithm, care must be taken to avoid violations of the detailed-balance rule, which would introduce systematic errors in the simulation. We present a Brownian dynamics algorithm for simulating reaction-diffusion systems that rigorously obeys detailed balance for equilibrium reactions. By comparing the simulation results to exact analytical results for a bimolecular reaction, we show that the algorithm correctly reproduces both equilibrium and dynamical quantities. We apply our scheme to a "push-pull" network in which two antagonistic enzymes covalently modify a substrate. Our results highlight that spatial fluctuations of the network components can strongly reduce the gain of the response of a biochemical network.

@article{Morelli:2008:J-Chem-Phys:18698893, abstract = {Brownian Dynamics algorithms have been widely used for simulating systems in soft-condensed matter physics. In recent times, their application has been extended to the simulation of coarse-grained models of biochemical networks. In these models, components move by diffusion and interact with one another upon contact. However, when reactions are incorporated into a Brownian dynamics algorithm, care must be taken to avoid violations of the detailed-balance rule, which would introduce systematic errors in the simulation. We present a Brownian dynamics algorithm for simulating reaction-diffusion systems that rigorously obeys detailed balance for equilibrium reactions. By comparing the simulation results to exact analytical results for a bimolecular reaction, we show that the algorithm correctly reproduces both equilibrium and dynamical quantities. We apply our scheme to a "push-pull" network in which two antagonistic enzymes covalently modify a substrate. Our results highlight that spatial fluctuations of the network components can strongly reduce the gain of the response of a biochemical network.}, added-at = {2009-12-10T03:41:41.000+0100}, author = {Morelli, M J and ten Wolde, P R}, biburl = {https://www.bibsonomy.org/bibtex/23c5bc984ec79d455f257dda661944d34/penkib}, description = {Reaction Brownian dynamics and the effect of spati... [J Chem Phys. 2008] - PubMed result}, doi = {10.1063/1.2958287}, interhash = {0cff1472c39fdc8a8d6eb9d0ebc0ddca}, intrahash = {3c5bc984ec79d455f257dda661944d34}, journal = {J Chem Phys}, keywords = {brownian network_analysis}, month = Aug, number = 5, pages = {054112-054112}, pmid = {18698893}, timestamp = {2009-12-10T03:41:41.000+0100}, title = {Reaction Brownian dynamics and the effect of spatial fluctuations on the gain of a push-pull network}, url = {http://www.ncbi.nlm.nih.gov/pubmed/18698893?dopt=Abstract}, volume = 129, year = 2008 }