AI Article Synopsis
- Recent methods for analyzing the structure of networks, especially in genetic regulatory networks (GRNs), focus on motifs—repeated subgraph patterns.
- The study found that differences in motif distributions within groups of evolved networks were greater than those between groups, suggesting that evolutionary pressures do not strictly determine network structure.
- Analysis of motifs’ functional roles indicated they may not be more crucial than other subgraph patterns, especially in larger networks, where the complexity may obscure the significance of specific motifs.
Article Abstract
Methods that analyse the topological structure of networks have recently become quite popular. Whether motifs (subgraph patterns that occur more often than in randomized networks) have specific functions as elementary computational circuits has been cause for debate. As the question is difficult to resolve with currently available biological data, we approach the issue using networks that abstractly model natural genetic regulatory networks (GRNs) which are evolved to show dynamical behaviors. Specifically one group of networks was evolved to be capable of exhibiting two different behaviors ("differentiation") in contrast to a group with a single target behavior. In both groups we find motif distribution differences within the groups to be larger than differences between them, indicating that evolutionary niches (target functions) do not necessarily mold network structure uniquely. These results show that variability operators can have a stronger influence on network topologies than selection pressures, especially when many topologies can create similar dynamics. Moreover, analysis of motif functional relevance by lesioning did not suggest that motifs were of greater importance to the functioning of the network than arbitrary subgraph patterns. Only when drastically restricting network size, so that one motif corresponds to a whole functionally evolved network, was preference for particular connection patterns found. This suggests that in non-restricted, bigger networks, entanglement with the rest of the network hinders topological subgraph analysis.
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| http://dx.doi.org/10.1016/j.biosystems.2008.05.012 | DOI Listing |
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