Abstract
BackgroundCross-species analysis of protein-protein interaction (PPI) networks provides an effective means of detecting conserved interaction patterns. Identifying such conserved substructures between PPI networks of different species increases our understanding of the principles deriving evolution of cellular organizations and their functions in a system level. In recent years, network alignment techniques have been applied to genome-scale PPI networks to predict evolutionary conserved modules. Although a wide variety of network alignment algorithms have been introduced, developing a scalable local network alignment algorithm with high accuracy is still challenging.ResultsWe present a novel pairwise local network alignment algorithm, called LePrimAlign, to predict conserved modules between PPI networks of three different species. The proposed algorithm exploits the results of a pairwise global alignment algorithm with many-to-many node mapping. It also applies the concept of graph entropy to detect initial cluster pairs from two networks. Finally, the initial clusters are expanded to increase the local alignment score that is formulated by a combination of intra-network and inter-network scores. The performance comparison with state-of-the-art approaches demonstrates that the proposed algorithm outperforms in terms of accuracy of identified protein complexes and quality of alignments.ConclusionThe proposed method produces local network alignment of higher accuracy in predicting conserved modules even with large biological networks at a reduced computational cost.
Highlights
Cross-species analysis of protein-protein interaction (PPI) networks provides an effective means of detecting conserved interaction patterns
Our experiments have demonstrated that the proposed LePrimAlign algorithm predicts conserved protein complexes more accurately and generates higher-quality alignment for any PPI network pairs than three prevalent local network alignment algorithms
Since network alignment identifies a comprehensive functional mapping of proteins between species, it provides an efficient way of predicting functions of unknown proteins and completing functional annotations especially in less-studied species
Summary
Cross-species analysis of protein-protein interaction (PPI) networks provides an effective means of detecting conserved interaction patterns Identifying such conserved substructures between PPI networks of different species increases our understanding of the principles deriving evolution of cellular organizations and their functions in a system level. A wide variety of network alignment algorithms have been introduced, developing a scalable local network alignment algorithm with high accuracy is still challenging Recent research in this area has focused on systematic. The network alignment problem includes finding the entire mapping of nodes and conserved edges between the mapped node pairs within two or more networks This problem can be applied to PPI networks because representing proteins and E is a set of edges representing interactions between proteins
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