Tumour mutations in long noncoding RNAs enhance cell fitness

Abstract

AbstractTumour DNA contains thousands of single nucleotide variants (SNVs) in non-protein-coding elements, yet their functional significance remains poorly understood. Amongst the most highly mutated elements are long noncoding RNAs (lncRNAs), functional transcripts known to play key roles in carcinogenesis. Here, we investigate whether mutations in lncRNAs can act as “drivers” that promote cancer cell fitness. We develop an integrative driver lncRNA discovery algorithm and apply it to single nucleotide variants (SNVs) from 2583 primary tumours and 3527 metastases to reveal 54 potential “driver lncRNAs”. Their relevance is supported by enrichment for previously-reported cancer genes, and by clinical and genomic features. Using knockdown and transgene overexpression experiments, we find that tumour SNVs in two novel lncRNAs can boost cell fitness. Driver analysis confirms a particularly high mutation rate in the iconic cancer lncRNA, NEAT1, whose functional significance has been debated in previous studies. We apply in cellulo mutagenesis to identify discrete regions of NEAT1 where SNVs reproducibly increase cell proliferation in both cancerous and normal backgrounds. We show that mutations in the 5’ region of NEAT1 alter ribonucleoprotein assembly and boost the population of subnuclear paraspeckles, thus linking genetic mutations to cellular fitness. In summary, this work establishes function-altering somatic mutations in vulnerable lncRNA sites as a route by which cells acquire fitness during tumorigenesis. Such mutations may act by altering the composition of lncRNA-containing ribonucleoproteins.