Abstract
BackgroundThe identification of genes responsible for human inherited diseases is one of the most challenging tasks in human genetics. Recent studies based on phenotype similarity and gene proximity have demonstrated great success in prioritizing candidate genes for human diseases. However, most of these methods rely on a single protein-protein interaction (PPI) network to calculate similarities between genes, and thus greatly restrict the scope of application of such methods. Meanwhile, independently constructed and maintained PPI networks are usually quite diverse in coverage and quality, making the selection of a suitable PPI network inevitable but difficult.MethodsWe adopt a linear model to explain similarities between disease phenotypes using gene proximities that are quantified by diffusion kernels of one or more PPI networks. We solve this model via a Bayesian approach, and we derive an analytic form for Bayes factor that naturally measures the strength of association between a query disease and a candidate gene and thus can be used as a score to prioritize candidate genes. This method is intrinsically capable of integrating multiple PPI networks.ResultsWe show that gene proximities calculated from PPI networks imply phenotype similarities. We demonstrate the effectiveness of the Bayesian regression approach on five PPI networks via large scale leave-one-out cross-validation experiments and summarize the results in terms of the mean rank ratio of known disease genes and the area under the receiver operating characteristic curve (AUC). We further show the capability of our approach in integrating multiple PPI networks.ConclusionsThe Bayesian regression approach can achieve much higher performance than the existing CIPHER approach and the ordinary linear regression method. The integration of multiple PPI networks can greatly improve the scope of application of the proposed method in the inference of disease genes.
Highlights
The identification of genes responsible for human inherited diseases is one of the most challenging tasks in human genetics
We further show the capability of our approach in integrating multiple protein-protein interaction (PPI) networks
Data sources We propose to infer disease genes using gene proximity profiles derived from protein-protein interaction (PPI) networks, a phenotype similarity profile calculated using text mining technique, and known associations between disease phenotypes and genes extracted from the Online Mendelian Inheritance in Man (OMIM) database
Summary
The identification of genes responsible for human inherited diseases is one of the most challenging tasks in human genetics. Recent studies based on phenotype similarity and gene proximity have demonstrated great success in prioritizing candidate genes for human diseases Most of these methods rely on a single protein-protein interaction (PPI) network to calculate similarities between genes, and greatly restrict the scope of application of such methods. Recent studies have shown the modular nature of human genetic diseases [15,16,17,18,19,20,21,22,23], which suggests that diseases share common clinic characteristics are often caused by functionally related genes [24] With this understanding, various methods have been proposed to utilize phenotype similarity and gene proximity for the inference of causative genes for human inherited diseases [14,25,26,27]. The naïve thinking of combining all available protein interactions into a single large network is straightforward, performance of methods based on such a combined network is questionable [25]
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