Abstract
BackgroundBoolean network modeling has been widely used to model large-scale biomolecular regulatory networks as it can describe the essential dynamical characteristics of complicated networks in a relatively simple way. When we analyze such Boolean network models, we often need to find out attractor states to investigate the converging state features that represent particular cell phenotypes. This is, however, very difficult (often impossible) for a large network due to computational complexity.ResultsThere have been some attempts to resolve this problem by partitioning the original network into smaller subnetworks and reconstructing the attractor states by integrating the local attractors obtained from each subnetwork. But, in many cases, the partitioned subnetworks are still too large and such an approach is no longer useful. So, we have investigated the fundamental reason underlying this problem and proposed a novel efficient way of hierarchically partitioning a given large network into smaller subnetworks by focusing on some attractors corresponding to a particular phenotype of interest instead of considering all attractors at the same time. Using the definition of attractors, we can have a simplified update rule with fixed state values for some nodes. The resulting subnetworks were small enough to find out the corresponding local attractors which can be integrated for reconstruction of the global attractor states of the original large network.ConclusionsThe proposed approach can substantially extend the current limit of Boolean network modeling for converging state analysis of biological networks.Electronic supplementary materialThe online version of this article (doi:10.1186/s12918-016-0338-4) contains supplementary material, which is available to authorized users.
Highlights
Boolean network modeling has been widely used to model large-scale biomolecular regulatory networks as it can describe the essential dynamical characteristics of complicated networks in a relatively simple way
To demonstrate the effectiveness of our framework in practice, we applied our method to three biological network models for finding attractors responsible for proliferation or apoptosis phenotypes: the first was a Mitogen-activated protein kinase (MAPK) model [6] with 53 nodes and 88 links, the second was a colitisassociated colon cancer (CACC) model [10] with 70 nodes and 152 links and the last was the simplified cancer pathways (SCP) model [9] with 96 nodes and 265 links
Boolean network modeling is becoming popular in modeling large-scale biological regulatory networks, looking for attractors for converging state analysis is still challenging for large networks due to computational complexity
Summary
Boolean network modeling has been widely used to model large-scale biomolecular regulatory networks as it can describe the essential dynamical characteristics of complicated networks in a relatively simple way When we analyze such Boolean network models, we often need to find out attractor states to investigate the converging state features that represent particular cell phenotypes. Once a Boolean network model is obtained, the converging state characteristics of the modeled network can be investigated by identifying attractor states which were known corresponding to cell To tackle such a problem, there have been several attempts to reduce the original Boolean network model by eliminating some nodes or logically simplifying Boolean functions [17,18,19,20,21,22,23,24,25,26,27], or focusing only on point attractors [28, 29]. Even if the reduced network is small enough to search the full state
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