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Exploring the effect of network topology, mRNA and protein dynamics on gene regulatory network stability

Yipei Guo, Ariel Amir

2021Nature Communications37 citationsDOIOpen Access PDF

Abstract

Homeostasis of protein concentrations in cells is crucial for their proper functioning, requiring steady-state concentrations to be stable to fluctuations. Since gene expression is regulated by proteins such as transcription factors (TFs), the full set of proteins within the cell constitutes a large system of interacting components, which can become unstable. We explore factors affecting stability by coupling the dynamics of mRNAs and proteins in a growing cell. We find that mRNA degradation rate does not affect stability, contrary to previous claims. However, global structural features of the network can dramatically enhance stability. Importantly, a network resembling a bipartite graph with a lower fraction of interactions that target TFs has a higher chance of being stable. Scrambling the E. coli transcription network, we find that the biological network is significantly more stable than its randomized counterpart, suggesting that stability constraints may have shaped network structure during the course of evolution.

Topics & Concepts

Gene regulatory networkBipartite graphGeneTranscription factorInteraction networkBiologyMessenger RNARegulation of gene expressionStability (learning theory)Gene expressionTopology (electrical circuits)Protein stabilityNetwork dynamicsGraphComputational biologyCell biologyGeneticsComputer scienceMathematicsTheoretical computer scienceDiscrete mathematicsMachine learningCombinatoricsGene Regulatory Network AnalysisBioinformatics and Genomic NetworksEvolution and Genetic Dynamics
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