Dynamics of unperturbed and noisy generalized Boolean networks

For years, we have been building models of gene regulatory networks, where recent advances in molecular biology shed some light on new structural and dynamical properties of such highly complex systems. In this work, we propose a novel timing of updates in random and scale-free Boolean networks, ins...

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Veröffentlicht in:	Journal of theoretical biology 2009-10, Vol.260 (4), p.531-544
Hauptverfasser:	Darabos, Ch, Tomassini, M., Giacobini, M.
Format:	Artikel
Sprache:	eng
Schlagworte:	Animals Boolean dynamics Complex networks Computer Simulation Gene Expression Regulation Gene Regulatory Networks Genetic regulatory networks Models, Genetic Perturbations Random Boolean networks Scale-free networks Systems Biology - methods
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container_title	Journal of theoretical biology
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creator	Darabos, Ch Tomassini, M. Giacobini, M.
description	For years, we have been building models of gene regulatory networks, where recent advances in molecular biology shed some light on new structural and dynamical properties of such highly complex systems. In this work, we propose a novel timing of updates in random and scale-free Boolean networks, inspired by recent findings in molecular biology. This update sequence is neither fully synchronous nor asynchronous, but rather takes into account the sequence in which genes affect each other. We have used both Kauffman's original model and Aldana's extension, which takes into account the structural properties about known parts of actual GRNs, where the degree distribution is right-skewed and long-tailed. The computer simulations of the dynamics of the new model compare favorably to the original ones and show biologically plausible results both in terms of attractors number and length. We have complemented this study with a complete analysis of our systems’ stability under transient perturbations, which is one of biological networks defining attribute. Results are encouraging, as our model shows comparable and usually even better behavior than preceding ones without loosing Boolean networks attractive simplicity.
doi_str_mv	10.1016/j.jtbi.2009.06.027
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subjects	Animals Boolean dynamics Complex networks Computer Simulation Gene Expression Regulation Gene Regulatory Networks Genetic regulatory networks Models, Genetic Perturbations Random Boolean networks Scale-free networks Systems Biology - methods
title	Dynamics of unperturbed and noisy generalized Boolean networks
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