ASP-based method for the enumeration of attractors in non-deterministic synchronous and asynchronous multi-valued networks

Emna Ben Abdallah; Maxime Folschette; Olivier Roux; Morgan Magnin

doi:10.1186/s13015-017-0111-2

ASP-based method for the enumeration of attractors in non-deterministic synchronous and asynchronous multi-valued networks

Algorithms Mol Biol. 2017 Aug 15:12:20. doi: 10.1186/s13015-017-0111-2. eCollection 2017.

Authors

Emna Ben Abdallah¹, Maxime Folschette^{2

3}, Olivier Roux¹, Morgan Magnin^{1

4}

Affiliations

¹ École Centrale de Nantes, LS2N UMR CNRS 6004, 1 rue de la Noë, 44321 Nantes, France.
² Université de Nantes, LS2N UMR CNRS 6004, 1 rue de la Noë, 44321 Nantes, France.
³ Université Nice Sophia Antipolis, I3S UMR CNRS 7271, 2000, route des Lucioles, 06900 Nice, France.
⁴ National Institute of Informatics, 2-1-2, Hitotsubashi, Chiyoda-ku, Tokyo, 101-8430 Japan.

Abstract

Background: This paper addresses the problem of finding attractors in biological regulatory networks. We focus here on non-deterministic synchronous and asynchronous multi-valued networks, modeled using automata networks (AN). AN is a general and well-suited formalism to study complex interactions between different components (genes, proteins,...). An attractor is a minimal trap domain, that is, a part of the state-transition graph that cannot be escaped. Such structures are terminal components of the dynamics and take the form of steady states (singleton) or complex compositions of cycles (non-singleton). Studying the effect of a disease or a mutation on an organism requires finding the attractors in the model to understand the long-term behaviors.

Results: We present a computational logical method based on answer set programming (ASP) to identify all attractors. Performed without any network reduction, the method can be applied on any dynamical semantics. In this paper, we present the two most widespread non-deterministic semantics: the asynchronous and the synchronous updating modes. The logical approach goes through a complete enumeration of the states of the network in order to find the attractors without the necessity to construct the whole state-transition graph. We realize extensive computational experiments which show good performance and fit the expected theoretical results in the literature.

Conclusion: The originality of our approach lies on the exhaustive enumeration of all possible (sets of) states verifying the properties of an attractor thanks to the use of ASP. Our method is applied to non-deterministic semantics in two different schemes (asynchronous and synchronous). The merits of our methods are illustrated by applying them to biological examples of various sizes and comparing the results with some existing approaches. It turns out that our approach succeeds to exhaustively enumerate on a desktop computer, in a large model (100 components), all existing attractors up to a given size (20 states). This size is only limited by memory and computation time.

Keywords: Answer set programming; Attractors; Biological regulatory network; Cycles; Multiple-valued networks; Steady states.