Abstract
Comprehensive understanding of human cancer mechanisms requires the identification of a thorough list of cancer-associated genes, which could serve as biomarkers for diagnoses and therapies in various types of cancer. Although substantial progress has been made in functional studies to uncover genes involved in cancer, these efforts are often time-consuming and costly. Therefore, it remains challenging to comprehensively identify cancer candidate genes. Network-based methods have accelerated this process through the analysis of complex molecular interactions in the cell. However, the extent to which various interactome networks can contribute to prediction of candidate genes responsible for cancer is still enigmatic. In this study, we evaluated different human protein-protein interactome networks and compared their application to cancer gene prioritization. Our results indicate that network analyses can increase the power to identify novel cancer genes. In particular, such predictive power can be enhanced with the use of unbiased systematic protein interaction maps for cancer gene prioritization. Functional analysis reveals that the top ranked genes from network predictions co-occur often with cancer-related terms in literature, and further, these candidate genes are indeed frequently mutated across cancers. Finally, our study suggests that integrating interactome networks with other omics datasets could provide novel insights into cancer-associated genes and underlying molecular mechanisms.
Highlights
Over the past few decades, cancer related genes have generally been identified using genome wide association studies [1,2,3]
We evaluated different human protein-protein interactome networks and compared their application to cancer gene prioritization
Using the genes obtained from Sanger Cancer Gene Census (CGC) as gold standard for known cancer genes, we found that the literature-based network (Lit-BM) exhibited the highest power to recover known cancer genes when genes were ranked by degree (Figure 1A and 1B)
Summary
Over the past few decades, cancer related genes have generally been identified using genome wide association studies [1,2,3]. With the release of large-scale protein-protein interaction (PPI) networks in human, the emerging of network medicine offers a platform to explore the molecular mechanisms in cancer [7,8,9,10]. It has been demonstrated that genes encoding hubs are often conserved and essential [11]. These results have led to the hypothesis that, in humans, hub genes could be associated with cancer [12]. Based on this hypothesis, an increasing number of studies have begun to use interactome networks to prioritize cancer related genes [13,14,15,16]. Using a phenomic ranking of protein complexes linked to human disease, Lage et al (2007) have developed a Bayesian predictor to identify disease related genes by pooling human interaction data from several large databases [18]
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