Abstract
BackgroundSemantic similarity measures are useful to assess the physiological relevance of protein-protein interactions (PPIs). They quantify similarity between proteins based on their function using annotation systems like the Gene Ontology (GO). Proteins that interact in the cell are likely to be in similar locations or involved in similar biological processes compared to proteins that do not interact. Thus the more semantically similar the gene function annotations are among the interacting proteins, more likely the interaction is physiologically relevant. However, most semantic similarity measures used for PPI confidence assessment do not consider the unequal depth of term hierarchies in different classes of cellular location, molecular function, and biological process ontologies of GO and thus may over-or under-estimate similarity.ResultsWe describe an improved algorithm, Topological Clustering Semantic Similarity (TCSS), to compute semantic similarity between GO terms annotated to proteins in interaction datasets. Our algorithm, considers unequal depth of biological knowledge representation in different branches of the GO graph. The central idea is to divide the GO graph into sub-graphs and score PPIs higher if participating proteins belong to the same sub-graph as compared to if they belong to different sub-graphs.ConclusionsThe TCSS algorithm performs better than other semantic similarity measurement techniques that we evaluated in terms of their performance on distinguishing true from false protein interactions, and correlation with gene expression and protein families. We show an average improvement of 4.6 times the F1 score over Resnik, the next best method, on our Saccharomyces cerevisiae PPI dataset and 2 times on our Homo sapiens PPI dataset using cellular component, biological process and molecular function GO annotations.
Highlights
Semantic similarity measures are useful to assess the physiological relevance of protein-protein interactions (PPIs)
Algorithm The goal of Topological Clustering Semantic Similarity (TCSS) is to find subsets of Gene Ontology (GO) terms defining similar concepts and score gene products belonging to a similar subset higher than if they belong to different sets
In an effort to normalize the depth of the GO directed acyclic graph (DAG) across the ontology, the algorithm first defines mutually exclusive sub-graphs rooted at major nodes
Summary
Semantic similarity measures are useful to assess the physiological relevance of protein-protein interactions (PPIs). They quantify similarity between proteins based on their function using annotation systems like the Gene Ontology (GO). Most semantic similarity measures used for PPI confidence assessment do not consider the unequal depth of term hierarchies in different classes of cellular location, molecular function, and biological process ontologies of GO and may over-or under-estimate similarity. GO organizes knowledge about gene function in a directed acyclic graph (DAG) of terms and their relationships It is organized in three orthogonal ontologies capturing knowledge about cellular location, biological process and molecular function [1]. The GO DAG is a complex network of over 31,000 terms and 46,900 relations
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