Stability Depends on Positive Autoregulation in Boolean Gene Regulatory Networks

Network motifs have been identified as building blocks of regulatory networks, including gene regulatory networks (GRNs). The most basic motif, autoregulation, has been associated with bistability (when positive) and with homeostasis and robustness to noise (when negative), but its general importance in network behavior is poorly understood. Moreover, how specific autoregulatory motifs are selected during evolution and how this relates to robustness is largely unknown. Here, we used a class of GRN models, Boolean networks, to investigate the relationship between autoregulation and network stability and robustness under various conditions. We ran evolutionary simulation experiments for different models of selection, including mutation and recombination. Each generation simulated the development of a population of organisms modeled by GRNs. We found that stability and robustness positively correlate with autoregulation; in all investigated scenarios, stable networks had mostly positive autoregulation. Assuming biological networks correspond to stable networks, these results suggest that biological networks should often be dominated by positive autoregulatory loops. This seems to be the case for most studied eukaryotic transcription factor networks, including those in yeast, flies and mammals.

• Publication year

  2014

• Venue

  PLoS Comput. Biol.

• Publication date

  2014-11-01

• Fields of study

  Biology, Medicine, Computer Science

• Identifiers
  DOI 10.1371/journal.pcbi.1003916PMID 25375153PMCID 4222607
• External record

  Open on Semantic Scholar

• Source metadata

  Semantic Scholar, PubMed

• Assuming biological networks correspond to stable networks, the results suggest that biological networks should often be dominated by positive autoregulatory loops.

  Confidence 0.90

  박진우 (dztg5apj7m) extractionB (s683577b42) reviewAK (4715169a40) review
• Across all investigated scenarios, stable networks were mostly characterized by positive autoregulation.

  Confidence 0.96

  박진우 (dztg5apj7m) extractionB (s683577b42) reviewAK (4715169a40) review
• In the tested Boolean network models, network stability and network robustness positively correlate with autoregulation.

  Confidence 0.97

  박진우 (dztg5apj7m) extractionB (s683577b42) reviewAK (4715169a40) review

• autoregulation

  network motif

  A network motif in which a gene or node regulates its own activity or expression.

  박진우 (dztg5apj7m) extractionB (s683577b42) reviewAK (4715169a40) review
• biological networks

  network

  Regulatory networks in living organisms that serve as the biological context for interpreting the model results.

  Aliases: biological network

  박진우 (dztg5apj7m) extractionB (s683577b42) reviewAK (4715169a40) review
• boolean network

  network model

  A discrete gene regulatory network model in which each node is updated by Boolean logic rules.

  Aliases: Boolean networks

  박진우 (dztg5apj7m) extractionB (s683577b42) reviewAK (4715169a40) review
• network robustness

  network property

  The ability of a gene regulatory network to preserve its behavior under perturbations.

  Aliases: robustness

  박진우 (dztg5apj7m) extractionB (s683577b42) reviewAK (4715169a40) review
• network stability

  network property

  The tendency of a gene regulatory network to remain in or return to a stable dynamical state.

  Aliases: stability

  박진우 (dztg5apj7m) extractionB (s683577b42) reviewAK (4715169a40) review
• positive autoregulation

  network motif

  A self-regulatory motif in which a gene or node enhances its own activity.

  Aliases: positive autoregulatory loop, positive autoregulatory loops

  박진우 (dztg5apj7m) extractionB (s683577b42) reviewAK (4715169a40) review

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