A self-organized model for cell-differentiation based on variations of molecular decay rates

Systemic properties of living cells are the result of molecular dynamics governed by so-called genetic regulatory networks (GRN). These networks capture all possible features of cells and are responsible for the immense levels of adaptation characteristic to living systems. At any point in time only...

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Veröffentlicht in:	PloS one 2012-05, Vol.7 (5), p.e36679-e36679
Hauptverfasser:	Hanel, Rudolf, Pöchacker, Manfred, Schölling, Manuel, Thurner, Stefan
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Sprache:	eng
Schlagworte:	Analysis Bioinformatics Biology Catalysis Cell differentiation Cell Differentiation - genetics Decay Decay rate Differentiation (biology) Dynamic stability E coli Enzymes Escherichia coli Gene expression Gene Regulatory Networks Homeostasis Kinetics Mathematics Models, Biological Molecular dynamics mRNA turnover Networks Nonlinear Dynamics Periodicity Proteins Pseudomonas aeruginosa RNA Science Simulation Transcription Transcription (Genetics) Transcription factors
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creator	Hanel, Rudolf Pöchacker, Manfred Schölling, Manuel Thurner, Stefan
description	Systemic properties of living cells are the result of molecular dynamics governed by so-called genetic regulatory networks (GRN). These networks capture all possible features of cells and are responsible for the immense levels of adaptation characteristic to living systems. At any point in time only small subsets of these networks are active. Any active subset of the GRN leads to the expression of particular sets of molecules (expression modes). The subsets of active networks change over time, leading to the observed complex dynamics of expression patterns. Understanding of these dynamics becomes increasingly important in systems biology and medicine. While the importance of transcription rates and catalytic interactions has been widely recognized in modeling genetic regulatory systems, the understanding of the role of degradation of biochemical agents (mRNA, protein) in regulatory dynamics remains limited. Recent experimental data suggests that there exists a functional relation between mRNA and protein decay rates and expression modes. In this paper we propose a model for the dynamics of successions of sequences of active subnetworks of the GRN. The model is able to reproduce key characteristics of molecular dynamics, including homeostasis, multi-stability, periodic dynamics, alternating activity, differentiability, and self-organized critical dynamics. Moreover the model allows to naturally understand the mechanism behind the relation between decay rates and expression modes. The model explains recent experimental observations that decay-rates (or turnovers) vary between differentiated tissue-classes at a general systemic level and highlights the role of intracellular decay rate control mechanisms in cell differentiation.
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subjects	Analysis Bioinformatics Biology Catalysis Cell differentiation Cell Differentiation - genetics Decay Decay rate Differentiation (biology) Dynamic stability E coli Enzymes Escherichia coli Gene expression Gene Regulatory Networks Homeostasis Kinetics Mathematics Models, Biological Molecular dynamics mRNA turnover Networks Nonlinear Dynamics Periodicity Proteins Pseudomonas aeruginosa RNA Science Simulation Transcription Transcription (Genetics) Transcription factors
title	A self-organized model for cell-differentiation based on variations of molecular decay rates
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