Litcius/Paper detail

Discovery of driver non-coding splice-site-creating mutations in cancer

Song Cao, Daniel Cui Zhou, Clara Oh, Reyka G. Jayasinghe, Yanyan Zhao, Christopher J. Yoon, Matthew A. Wyczalkowski, Matthew H. Bailey, Terrence Tsou, Qingsong Gao, Andrew F. Malone, Sheila M. Reynolds, Ilya Shmulevich, Michael C. Wendl, Feng Chen, Li Ding

2020Nature Communications40 citationsDOIOpen Access PDF

Abstract

Non-coding mutations can create splice sites, however the true extent of how such somatic non-coding mutations affect RNA splicing are largely unexplored. Here we use the MiSplice pipeline to analyze 783 cancer cases with WGS data and 9494 cases with WES data, discovering 562 non-coding mutations that lead to splicing alterations. Notably, most of these mutations create new exons. Introns associated with new exon creation are significantly larger than the genome-wide average intron size. We find that some mutation-induced splicing alterations are located in genes important in tumorigenesis (ATRX, BCOR, CDKN2B, MAP3K1, MAP3K4, MDM2, SMAD4, STK11, TP53 etc.), often leading to truncated proteins and affecting gene expression. The pattern emerging from these exon-creating mutations suggests that splice sites created by non-coding mutations interact with pre-existing potential splice sites that originally lacked a suitable splicing pair to induce new exon formation. Our study suggests the importance of investigating biological and clinical consequences of noncoding splice-inducing mutations that were previously neglected by conventional annotation pipelines. MiSplice will be useful for automatically annotating the splicing impact of coding and non-coding mutations in future large-scale analyses.

Topics & Concepts

RNA splicingExonGeneticsBiologyIntronGeneComputational biologyExon skippingCoding regionspliceSplice site mutationAlternative splicingRNARNA Research and SplicingRNA modifications and cancerRNA and protein synthesis mechanisms