Previous studies indicated that many overlapping structures exist among the modular structures in protein-protein interaction (PPI) networks, which may reflect common functional components shared by different biological processes. In this paper, a Markov clustering based Link Clustering (MLC) method for the identification of overlapping modular structures in PPI networks is proposed. Firstly, MLC method calculates the extended link similarity and derives a similarity matrix to represent the relevance among the protein interactions. Then it employs markov clustering to partition the link similarity matrix and obtains overlapping network modules with significantly less parameters and threshold constraints compared to most current methodologies. Experiments on two networks with known reference classes and two biological PPI networks of Escherichia coli, Saccharomyces cerevisiae, respectively, show that MLC outperforms the original Link Clustering and the classical Clique Percolation Method in terms of accurate identification of the core modules in each test network. Therefore, we consider the MLC method is high promisingly in identifying important pathways through studying the interplay between functional processes in different organism. © 2016 Bentham Science Publishers
A markov clustering based link clustering method to identify overlapping modules in protein-protein interaction networks
Blanzieri, Enrico;
2016-01-01
Abstract
Previous studies indicated that many overlapping structures exist among the modular structures in protein-protein interaction (PPI) networks, which may reflect common functional components shared by different biological processes. In this paper, a Markov clustering based Link Clustering (MLC) method for the identification of overlapping modular structures in PPI networks is proposed. Firstly, MLC method calculates the extended link similarity and derives a similarity matrix to represent the relevance among the protein interactions. Then it employs markov clustering to partition the link similarity matrix and obtains overlapping network modules with significantly less parameters and threshold constraints compared to most current methodologies. Experiments on two networks with known reference classes and two biological PPI networks of Escherichia coli, Saccharomyces cerevisiae, respectively, show that MLC outperforms the original Link Clustering and the classical Clique Percolation Method in terms of accurate identification of the core modules in each test network. Therefore, we consider the MLC method is high promisingly in identifying important pathways through studying the interplay between functional processes in different organism. © 2016 Bentham Science PublishersI documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione