Abstract
BackgroundOne of the most important projects in the post-genome-era is the systemic identification of biological network. The almost of studies for network identification focused on the improvement of computational efficiency in large-scale network inference of complex system with cyclic relations and few attempted have been done for answering practical problem occurred in real biological systems. In this study, we focused to evaluate inferring performance of our previously proposed method for inferring biological network on simple network motifs.ResultsWe evaluated the network inferring accuracy and efficiency of our previously proposed network inferring algorithm, by using 6 kinds of repeated appearance of highly significant network motifs in the regulatory network of E. coli proposed by Shen-Orr et al and Herrgård et al, and 2 kinds of network motif in S. cerevisiae proposed by Lee et. al. As a result, our method could reconstruct about 40% of interactions in network motif from time-series data set. Moreover the introduction of time-series data of one-factor disrupted model could remarkably improved the performance of network inference.ConclusionsThe results of network inference examination of E. coli network motif shows that our network inferring algorithm was able to apply to typical topology of biological network. A continuous examination of inferring well established network motif in biology would strengthen the applicability of our algorithm to the realistic biological network.
Highlights
One of the most important projects in the post-genome-era is the systemic identification of biological network
We previously proposed efficient procedures for inferring biological network based on experimentally observed time-series data of mRNA or metabolites [7,8,9,10] using S-system and real-coded genetic algorithms (RCGAs) [11] with a combination of uni-modal normal distribution crossover(UNDX) [12] and minimal generation gap(MGG) [13]
In the case of network inferences for Dense Overlapping Regulation (DOR)(Dense overlapping regulation), FF(Feed-forward), RM(Regulator Module) and TM(Target Module) networks, the value of recall becomes around 0.4, which indicates about 40% of interactions in the network model are properly reconstructed by our algorithm
Summary
One of the most important projects in the post-genome-era is the systemic identification of biological network. The almost of studies for network identification focused on the improvement of computational efficiency in large-scale network inference of complex system with cyclic relations and few attempted have been done for answering practical problem occurred in real biological systems. We focused to evaluate inferring performance of our previously proposed method for inferring biological network on simple network motifs. Time-series with dynamic behavior are one of such data involving enormous amount of information regarding the regulation of biological network in vivo. As such information is entirely implicit, it requires the development of adequate analytic. S-system requires a large number of parameters that must be estimated to identify dynamical biological networks; the number of estimated parameters is 2n(n + 1) (where n is the number of system components)
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