IEEE Transactions on Knowledge and Data Engineering
Quasi-bicliques: Complexity and Binding Pairs
COCOON '08 Proceedings of the 14th annual international conference on Computing and Combinatorics
Modeling Protein Interacting Groups by Quasi-Bicliques: Complexity, Algorithm, and Application
IEEE/ACM Transactions on Computational Biology and Bioinformatics (TCBB)
Near optimal solutions for maximum quasi-bicliques
COCOON'10 Proceedings of the 16th annual international conference on Computing and combinatorics
Computing the protein binding sites
ISBRA'11 Proceedings of the 7th international conference on Bioinformatics research and applications
Mining biological interaction networks using weighted quasi-bicliques
ISBRA'11 Proceedings of the 7th international conference on Bioinformatics research and applications
IEEE/ACM Transactions on Computational Biology and Bioinformatics (TCBB)
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Motivation: Protein--protein interaction, mediated by protein interaction sites, is intrinsic to many functional processes in the cell. In this paper, we propose a novel method to discover patterns in protein interaction sites. We observed from protein interaction networks that there exist a kind of significant substructures called interacting protein group pairs, which exhibit an all-versus-all interaction between the two protein-sets in such a pair. The full-interaction between the pair indicates a common interaction mechanism shared by the proteins in the pair, which can be referred as an interaction type. Motif pairs at the interaction sites of the protein group pairs can be used to represent such interaction type, with each motif derived from the sequences of a protein group by standard motif discovery algorithms. The systematic discovery of all pairs of interacting protein groups from large protein interaction networks is a computationally challenging problem. By a careful and sophisticated problem transformation, the problem is solved using efficient algorithms for mining frequent patterns, a problem extensively studied in data mining. Results: We found 5349 pairs of interacting protein groups from a yeast interaction dataset. The expected value of sequence identity within the groups is only 7.48%, indicating non-homology within these protein groups. We derived 5343 motif pairs from these group pairs, represented in the form of blocks. Comparing our motifs with domains in the BLOCKS and PRINTS databases, we found that our blocks could be mapped to an average of 3.08 correlated blocks in these two databases. The mapped blocks occur 4221 out of total 6794 domains (protein groups) in these two databases. Comparing our motif pairs with iPfam consisting of 3045 interacting domain pairs derived from PDB, we found 47 matches occurring in 105 distinct PDB complexes. Comparing with another putative domain interaction database InterDom, we found 203 matches. Availability: http://research.i2r.a-star.edu.sg/BindingMotifPairs/resources Contact: jinyan@i2r.a-star.edu.sg Supplementary information:http://research.i2r.a-star.edu.sg/BindingMotifPairs and Bioinformatics online.