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Network Class Superposition Analyses

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  • Carl A B Pearson
  • Chen Zeng
  • Rahul Simha

Abstract

Networks are often used to understand a whole system by modeling the interactions among its pieces. Examples include biomolecules in a cell interacting to provide some primary function, or species in an environment forming a stable community. However, these interactions are often unknown; instead, the pieces' dynamic states are known, and network structure must be inferred. Because observed function may be explained by many different networks (e.g., for the yeast cell cycle process [1]), considering dynamics beyond this primary function means picking a single network or suitable sample: measuring over all networks exhibiting the primary function is computationally infeasible. We circumvent that obstacle by calculating the network class ensemble. We represent the ensemble by a stochastic matrix , which is a transition-by-transition superposition of the system dynamics for each member of the class. We present concrete results for derived from Boolean time series dynamics on networks obeying the Strong Inhibition rule, by applying to several traditional questions about network dynamics. We show that the distribution of the number of point attractors can be accurately estimated with . We show how to generate Derrida plots based on . We show that -based Shannon entropy outperforms other methods at selecting experiments to further narrow the network structure. We also outline an experimental test of predictions based on . We motivate all of these results in terms of a popular molecular biology Boolean network model for the yeast cell cycle, but the methods and analyses we introduce are general. We conclude with open questions for , for example, application to other models, computational considerations when scaling up to larger systems, and other potential analyses.

Suggested Citation

  • Carl A B Pearson & Chen Zeng & Rahul Simha, 2013. "Network Class Superposition Analyses," PLOS ONE, Public Library of Science, vol. 8(4), pages 1-10, April.
  • Handle: RePEc:plo:pone00:0059046
    DOI: 10.1371/journal.pone.0059046
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    References listed on IDEAS

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    1. Guanyu Wang & Yongwu Rong & Hao Chen & Carl Pearson & Chenghang Du & Rahul Simha & Chen Zeng, 2012. "Process-Driven Inference of Biological Network Structure: Feasibility, Minimality, and Multiplicity," PLOS ONE, Public Library of Science, vol. 7(7), pages 1-9, July.
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    Cited by:

    1. Alan A Cohen & Emmanuel Milot & Qing Li & Patrick Bergeron & Roxane Poirier & Francis Dusseault-Bélanger & Tamàs Fülöp & Maxime Leroux & Véronique Legault & E Jeffrey Metter & Linda P Fried & Luigi Fe, 2015. "Detection of a Novel, Integrative Aging Process Suggests Complex Physiological Integration," PLOS ONE, Public Library of Science, vol. 10(3), pages 1-26, March.

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