Identification of protein complexes by integrating multiple alignment of protein interaction networks

Cheng Yu Ma, Yi Ping Phoebe Chen, Bonnie Berger*, Chung Shou Liao

*Corresponding author for this work

Research output: Contribution to journalJournal Article peer-review

48 Scopus citations

Abstract

Motivation: Protein complexes are one of the keys to studying the behavior of a cell system. Many biological functions are carried out by protein complexes. During the past decade, the main strategy used to identify protein complexes from high-throughput network data has been to extract near-cliques or highly dense subgraphs from a single protein-protein interaction (PPI) network. Although experimental PPI data have increased significantly over recent years, most PPI networks still have many false positive interactions and false negative edge loss due to the limitations of high-throughput experiments. In particular, the false negative errors restrict the search space of such conventional protein complex identification approaches. Thus, it has become one of the most challenging tasks in systems biology to automatically identify protein complexes. Results: In this study, we propose a new algorithm, NEOComplex (NECC- and Ortholog-based Complex identification by multiple network alignment), which integrates functional orthology information that can be obtained from different types of multiple network alignment (MNA) approaches to expand the search space of protein complex detection. As part of our approach, we also define a new edge clustering coefficient (NECC) to assign weights to interaction edges in PPI networks so that protein complexes can be identified more accurately. The NECC is based on the intuition that there is functional information captured in the common neighbors of the common neighbors as well. Our results show that our algorithm outperforms well-known protein complex identification tools in a balance between precision and recall on three eukaryotic species: human, yeast, and fly. As a result of MNAs of the species, the proposed approach can tolerate edge loss in PPI networks and even discover sparse protein complexes which have traditionally been a challenge to predict.

Original languageEnglish
Pages (from-to)1681-1688
Number of pages8
JournalBioinformatics
Volume33
Issue number11
DOIs
StatePublished - 01 06 2017
Externally publishedYes

Bibliographical note

Publisher Copyright:
© The Author 2017.

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