Steady-state kinetic modeling constrains cellular resting states and dynamic behavior.

A defining characteristic of living cells is the ability to respond dynamically to external stimuli while maintaining homeostasis under resting conditions. Capturing both of these features in a single kinetic model is difficult because the model must be able to reproduce both behaviors using the sam...

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Main Authors: Jeremy E Purvis, Ravi Radhakrishnan, Scott L Diamond
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2009-03-01
Series:PLoS Computational Biology
Online Access:http://europepmc.org/articles/PMC2637974?pdf=render
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spelling doaj-728e13fac510443a95fa4237ae9d9cd42020-11-25T01:46:02ZengPublic Library of Science (PLoS)PLoS Computational Biology1553-734X1553-73582009-03-0153e100029810.1371/journal.pcbi.1000298Steady-state kinetic modeling constrains cellular resting states and dynamic behavior.Jeremy E PurvisRavi RadhakrishnanScott L DiamondA defining characteristic of living cells is the ability to respond dynamically to external stimuli while maintaining homeostasis under resting conditions. Capturing both of these features in a single kinetic model is difficult because the model must be able to reproduce both behaviors using the same set of molecular components. Here, we show how combining small, well-defined steady-state networks provides an efficient means of constructing large-scale kinetic models that exhibit realistic resting and dynamic behaviors. By requiring each kinetic module to be homeostatic (at steady state under resting conditions), the method proceeds by (i) computing steady-state solutions to a system of ordinary differential equations for each module, (ii) applying principal component analysis to each set of solutions to capture the steady-state solution space of each module network, and (iii) combining optimal search directions from all modules to form a global steady-state space that is searched for accurate simulation of the time-dependent behavior of the whole system upon perturbation. Importantly, this stepwise approach retains the nonlinear rate expressions that govern each reaction in the system and enforces constraints on the range of allowable concentration states for the full-scale model. These constraints not only reduce the computational cost of fitting experimental time-series data but can also provide insight into limitations on system concentrations and architecture. To demonstrate application of the method, we show how small kinetic perturbations in a modular model of platelet P2Y(1) signaling can cause widespread compensatory effects on cellular resting states.http://europepmc.org/articles/PMC2637974?pdf=render
collection DOAJ
language English
format Article
sources DOAJ
author Jeremy E Purvis
Ravi Radhakrishnan
Scott L Diamond
spellingShingle Jeremy E Purvis
Ravi Radhakrishnan
Scott L Diamond
Steady-state kinetic modeling constrains cellular resting states and dynamic behavior.
PLoS Computational Biology
author_facet Jeremy E Purvis
Ravi Radhakrishnan
Scott L Diamond
author_sort Jeremy E Purvis
title Steady-state kinetic modeling constrains cellular resting states and dynamic behavior.
title_short Steady-state kinetic modeling constrains cellular resting states and dynamic behavior.
title_full Steady-state kinetic modeling constrains cellular resting states and dynamic behavior.
title_fullStr Steady-state kinetic modeling constrains cellular resting states and dynamic behavior.
title_full_unstemmed Steady-state kinetic modeling constrains cellular resting states and dynamic behavior.
title_sort steady-state kinetic modeling constrains cellular resting states and dynamic behavior.
publisher Public Library of Science (PLoS)
series PLoS Computational Biology
issn 1553-734X
1553-7358
publishDate 2009-03-01
description A defining characteristic of living cells is the ability to respond dynamically to external stimuli while maintaining homeostasis under resting conditions. Capturing both of these features in a single kinetic model is difficult because the model must be able to reproduce both behaviors using the same set of molecular components. Here, we show how combining small, well-defined steady-state networks provides an efficient means of constructing large-scale kinetic models that exhibit realistic resting and dynamic behaviors. By requiring each kinetic module to be homeostatic (at steady state under resting conditions), the method proceeds by (i) computing steady-state solutions to a system of ordinary differential equations for each module, (ii) applying principal component analysis to each set of solutions to capture the steady-state solution space of each module network, and (iii) combining optimal search directions from all modules to form a global steady-state space that is searched for accurate simulation of the time-dependent behavior of the whole system upon perturbation. Importantly, this stepwise approach retains the nonlinear rate expressions that govern each reaction in the system and enforces constraints on the range of allowable concentration states for the full-scale model. These constraints not only reduce the computational cost of fitting experimental time-series data but can also provide insight into limitations on system concentrations and architecture. To demonstrate application of the method, we show how small kinetic perturbations in a modular model of platelet P2Y(1) signaling can cause widespread compensatory effects on cellular resting states.
url http://europepmc.org/articles/PMC2637974?pdf=render
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AT scottldiamond steadystatekineticmodelingconstrainscellularrestingstatesanddynamicbehavior
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