Discovery of Cancer Driver Long Noncoding RNAs across 1112 Tumour Genomes: New Candidates and Distinguishing Features

Lanzós, Andrés; Carlevaro-Fita, Joana; Mularoni, Loris; Reverter, Ferrán; Palumbo, Emilio; Guigó, Roderic; Johnson, Rory

doi:10.1038/srep41544

Cited by 99 publications

(108 citation statements)

References 54 publications

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“…Two recent efforts attempted to identify driver lncRNA mutations that were positively selected in human cancers (Juul et al 2017;Lanzós et al 2017). In some form, each method identified non-coding loci or non-coding genes that were mutated at a frequency significantly greater than the background rate across all non-coding loci or across samples, respectively.…”

Section: Lncrnas Augment Drug Response Predictions From Known Pcgs Bimentioning

confidence: 99%

“…However, these methods, by definition, cannot infer somatic mutations in the non-coding genome. Recent efforts have been directed toward identifying somatic drivers that are specifically located in the lncRNA genome (Li et al 2015;Lanzos et al 2017). To identify lncRNA genes with positively selected somatic mutations in the cancer cell lines, we adopt a two-step approach that first selects lncRNA genes with variation frequency higher than the noncoding genome background across all available cell lines, and second, scores lncRNA genes based on mutation frequency per cell line.…”

Section: Lncrna-specific Somatic Mutationsmentioning

confidence: 99%

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Discovering novel long non-coding RNA predictors of anticancer drug sensitivity beyond protein-coding genes

Nath

Lau

Lee

et al. 2019

Preprint

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Large-scale cancer cell line screens have identified thousands of protein-coding genes (PCGs) as biomarkers of anticancer drug response. However, systematic evaluation of long non-coding RNAs (lncRNAs) as pharmacogenomic biomarkers has so far proven challenging. Here, we study the contribution of lncRNAs as drug response predictors beyond spurious associations driven by correlations with proximal PCGs, tissue-lineage or established biomarkers. We show that, as a whole, the lncRNA transcriptome is equally potent as the PCG transcriptome at predicting response to hundreds of anticancer drugs. Analysis of individual lncRNAs transcripts associated with drug response reveals nearly half of the significant associations are in fact attributable to proximal cis-PCGs. However, adjusting for effects of cis-PCGs revealed significant lncRNAs that augment drug response predictions for most drugs, including those with well-established clinical biomarkers. In addition, we identify lncRNA-specific somatic alterations associated with drug response by adopting a statistical approach to determine lncRNAs carrying somatic mutations that undergo positive selection in cancer cells. Lastly, we experimentally demonstrate that two novel lncRNA, EGFR-AS1 and MIR205HG, are functionally relevant predictors of anti-EGFR drug response.3

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Section: Lncrnas Augment Drug Response Predictions From Known Pcgs Bimentioning

confidence: 99%

Section: Lncrna-specific Somatic Mutationsmentioning

confidence: 99%

Discovering novel long non-coding RNA predictors of anticancer drug sensitivity beyond protein-coding genes

Nath

Lau

Lee

et al. 2019

Preprint

View full text Add to dashboard Cite

show abstract

“…To exclude potential confounders induced by proximal known cancer drivers, we extracted 235 candidate driver lncRNAs with any transcripts overlapping proteincoding genes on the opposite strand, or within 10 kb at their closest point on the same strand (Lanzos et al, 2017). In addition, their overlapped (or proximal) PCGs were also extracted.…”

Section: Exclusion Of Potential Confoundersmentioning

confidence: 99%

“…To address this challenge, several methods have been proposed. ExInAtor employed a parametric statistical test to identify lncRNAs with excess of exonic mutations, accounting for individual mutational signatures (Lanzos et al, 2017). Onco-driveFML integrated several functional impact scoring metrics to identify driver regions with functional mutation bias (Mularoni et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

A pan‐cancer atlas of cancer hallmark‐associated candidate driver lncRNAs

et al. 2018

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Substantial cancer genome sequencing efforts have discovered many important driver genes contributing to tumorigenesis. However, very little is known about the genetic alterations of long non‐coding RNAs (lncRNAs) in cancer. Thus, there is a need for systematic surveys of driver lncRNAs. Through integrative analysis of 5918 tumors across 11 cancer types, we revealed that lncRNAs have undergone dramatic genomic alterations, many of which are mutually exclusive with well‐known cancer genes. Using the hypothesis of functional redundancy of mutual exclusivity, we developed a computational framework to identify driver lncRNAs associated with different cancer hallmarks. Applying it to pan‐cancer data, we identified 378 candidate driver lncRNAs whose genomic features highly resemble the known cancer driver genes (e.g. high conservation and early replication). We further validated the candidate driver lncRNAs involved in ‘Tissue Invasion and Metastasis’ in lung adenocarcinoma and breast cancer, and also highlighted their potential roles in improving clinical outcomes. In summary, we have generated a comprehensive landscape of cancer candidate driver lncRNAs that could act as a starting point for future functional explorations, as well as the identification of biomarkers and lncRNA‐based target therapy.

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“…The expression of thousands of lincRNAs are deregulated in cancer, and many lincRNAs have been proposed as biomarkers for tumor tissues and patient prognosis [1]–[3]. There is also strong evidence that lincRNAs may serve as drivers of tumorigenesis, cause drug resistance or cause metastasis [4]–[7]. Mutations in cancer driver genes lead to a series of downstream events, including gene expression changes [8], [9].…”

Section: Introductionmentioning

confidence: 99%

Pan-cancer analysis of expressed somatic nucleotide variants in long intergenic non-coding RNA

Ching

Garmire

2017

Biocomputing 2018

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Long intergenic non-coding RNAs have been shown to play important roles in cancer. However, because lincRNAs are a relatively new class of RNAs compared to protein-coding mRNAs, the mutational landscape of lincRNAs has not been as extensively studied. Here we characterize expressed somatic nucleotide variants within lincRNAs using 12 cancer RNA-Seq datasets in TCGA. We build machine-learning models to discriminate somatic variants from germline variants within lincRNA regions (AUC 0.987). We build another model to differentiate lincRNA somatic mutations from background regions (AUC 0.72) and find several molecular features that are strongly associated with lincRNA mutations, including copy number variation, conservation, substitution type and histone marker features.

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Discovery of Cancer Driver Long Noncoding RNAs across 1112 Tumour Genomes: New Candidates and Distinguishing Features

Cited by 99 publications

References 54 publications

Discovering novel long non-coding RNA predictors of anticancer drug sensitivity beyond protein-coding genes

Discovering novel long non-coding RNA predictors of anticancer drug sensitivity beyond protein-coding genes

A pan‐cancer atlas of cancer hallmark‐associated candidate driver lncRNAs

Pan-cancer analysis of expressed somatic nucleotide variants in long intergenic non-coding RNA

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