Computational methodologies for modelling, analysis and simulation of signalling networks

doi:10.1093/bib/bbl043

Briefings in Bioinformatics Advance Access originally published online on November 20, 2006
Briefings in Bioinformatics 2006 7(4):339-353; doi:10.1093/bib/bbl043

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Computational methodologies for modelling, analysis and simulation of signalling networks

David Gilbert, Hendrik Fuß, Xu Gu, Richard Orton, Steve Robinson, Vladislav Vyshemirsky, Mary Jo Kurth, C. Stephen Downes and Werner Dubitzky

Corresponding author. Prof. David Gilbert, Bioinformatics Research Centre, A416, Davidson Building University of Glasgow, Glasgow G12 8QQ, Scotland, UK. Tel: +44 141 330 2563; Fax: +44 141 330 8627; E-mail: drg{at}dcs.gla.ac.uk

This article is a critical review of computational techniquesused to model, analyse and simulate signalling networks. Wepropose a conceptual framework, and discuss the role of signallingnetworks in three major areas: signal transduction, cellularrhythms and cell-to-cell communication. In order to avoid anoverly abstract and general discussion, we focus on three casestudies in the areas of receptor signalling and kinase cascades,cell-cycle regulation and wound healing. We report on a varietyof modelling techniques and associated tools, in addition tothe traditional approach based on ordinary differential equations(ODEs), which provide a range of descriptive and analyticalpowers. As the field matures, we expect a wider uptake of thesealternative approaches for several reasons, including the needto take into account low protein copy numbers and noise andthe great complexity of cellular organisation. An advantageoffered by many of these alternative techniques, which havetheir origins in computing science, is the ability to performsophisticated model analysis which can better relate predictedbehaviour and observations.

Keywords: biochemical signalling networks, modelling, analysis, simulation

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