Literature DB >> 24086102

SIMULATING BIOCHEMICAL SIGNALING NETWORKS IN COMPLEX MOVING GEOMETRIES.

Wanda Strychalski1, David Adalsteinsson, Timothy C Elston.   

Abstract

Signaling networks regulate cellular responses to environmental stimuli through cascades of protein interactions. External signals can trigger cells to polarize and move in a specific direction. During migration, spatially localized activity of proteins is maintained. To investigate the effects of morphological changes on intracellular signaling, we developed a numerical scheme consisting of a cut cell finite volume spatial discretization coupled with level set methods to simulate the resulting advection-reaction-diffusion system. We then apply the method to several biochemical reaction networks in changing geometries. We found that a Turing instability can develop exclusively by cell deformations that maintain constant area. For a Turing system with a geometry-dependent single or double peak solution, simulations in a dynamically changing geometry suggest that a single peak solution is the only stable one, independent of the oscillation frequency. The method is also applied to a model of a signaling network in a migrating fibroblast.

Entities:  

Keywords:  Advection-reaction-diffusion equation; Level set methods; Numerical methods; Systems biology

Year:  2010        PMID: 24086102      PMCID: PMC3786195          DOI: 10.1137/090779693

Source DB:  PubMed          Journal:  SIAM J Sci Comput        ISSN: 1064-8275            Impact factor:   2.373


  23 in total

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