Abstract
BackgroundThe diversity of genomic alterations in cancer poses challenges to fully understanding the etiologies of the disease. Recent interest in infrequent mutations, in genes that reside in the “long tail” of the mutational distribution, uncovered new genes with significant implications in cancer development. The study of cancer-relevant genes often requires integrative approaches pooling together multiple types of biological data. Network propagation methods demonstrate high efficacy in achieving this integration. Yet, the majority of these methods focus their assessment on detecting known cancer genes or identifying altered subnetworks. In this paper, we introduce a network propagation approach that entirely focuses on prioritizing long tail genes with potential functional impact on cancer development.ResultsWe identify sets of often overlooked, rarely to moderately mutated genes whose biological interactions significantly propel their mutation-frequency-based rank upwards during propagation in 17 cancer types. We call these sets “upward mobility genes” and hypothesize that their significant rank improvement indicates functional importance. We report new cancer-pathway associations based on upward mobility genes that are not previously identified using driver genes alone, validate their role in cancer cell survival in vitro using extensive genome-wide RNAi and CRISPR data repositories, and further conduct in vitro functional screenings resulting in the validation of 18 previously unreported genes.ConclusionOur analysis extends the spectrum of cancer-relevant genes and identifies novel potential therapeutic targets.
Highlights
The diversity of genomic alterations in cancer poses challenges to fully understanding the etiologies of the disease
Recent studies indicate that some cancers do not Mohsen et al Genome Biology (2021) 22:287 harbor any known cancer driver mutations, and all cancers carry a large number of rarely recurrent mutations in unique combinations in hundreds of potentially cancerrelevant genes [1,2,3,4,5,6,7]
We efficiently identify a considerable number of upward mobility genes (UMGs) (n = 28–83 per cancer type) and demonstrate their functional importance in cancer on multiple levels
Summary
The diversity of genomic alterations in cancer poses challenges to fully understanding the etiologies of the disease. Recent studies indicate that some cancers do not Mohsen et al Genome Biology (2021) 22:287 harbor any known cancer driver mutations, and all cancers carry a large number of rarely recurrent mutations in unique combinations in hundreds of potentially cancerrelevant genes [1,2,3,4,5,6,7]. These genes are part of a long tail in mutation frequency distributions and referred to as “long tail” genes. We rely on a framework that iteratively propagates information signals (i.e., mutation scores or other quantitative metrics) between each network node (i.e., gene product) and its neighbors
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