The landscape of somatic copy-number alteration across human cancers

Beroukhim, Rameen; Mermel, Craig H.; Porter, Dale; Wei, Guo; Raychaudhuri, Soumya; Donovan, Jerry; Barretina, Jordi; Boehm, Jesse S.; Dobson, Jennifer; Urashima, Mitsuyoshi; Henry, Kevin T. Mc; Pinchback, Reid M.; Ligon, Azra H.; Cho, Yoon-Jae; Haery, Leila; Greulich, Heidi; Reich, Michael; Winckler, Wendy; Lawrence, Michael S.; Weir, Barbara A.; Tanaka, Kumiko; Chiang, Derek Y.; Bass, Adam J.; Loo, Alice; Hoffman, Carter; Prensner, John R.; Liefeld, Ted; Gao, Qing; Yecies, Derek; Signoretti, Sabina; Maher, Elizabeth A.; Kaye, Frederic J.; Sasaki, Hidefumi; Tepper, Joel E.; Fletcher, Jonathan A.; Tabernero, Josep; Baselga, José; Tsao, Ming‐Sound; Demichelis, Francesca; Rubin, Mark A.; Jänne, Pasi A.; Daly, Mark J.; Nucera, Carmelo; Levine, Ross L.; Ebert, Benjamin L.; Gabriel, Stacey; Rustgi, Anil K.; Antonescu, Cristina R.; Ladanyi, Marc; Letaï, Anthony; Garraway, Levi A.; Loda, Massimo; Beer, David G.; True, Lawrence D.; Okamoto, Aikou; Pomeroy, Scott L.; Singer, Samuel; Golub, Todd R.; Lander, Eric S.; Getz, Gad; Sellers, William R.; Meyerson, Matthew

doi:10.1038/nature08822

Cited by 3,296 publications

(3,320 citation statements)

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“…Applied to study colon cancer, the first step employs a straightforward genomic analysis of the Cancer Genome Atlas (TCGA) database (Beroukhim et al , 2010; Barretina et al , 2012) to identify metabolic genes that are downregulated in colorectal cancer (Fig 1A). Subsequently, we performed a novel metabolic modeling analysis to identify, among the genes identified as associated with tumorigenesis in the first step, those whose downregulation is indeed most likely to result in the metabolic alterations observed in colorectal tumors and thus are more likely to play an actual causal role in the transformation of normal to cancerous tissues (Fig 1B).…”

Section: Resultsmentioning

confidence: 99%

“…This step consists of three sub‐steps that are applied sequentially, analyzing gene expression, copy number (CN), and survival data from 272 colorectal cancer samples and 42 matching healthy colon tissues samples in the TCGA (Beroukhim et al , 2010; Barretina et al , 2012): (i) First, analyzing the transcriptomic data of these samples, we identified 4593 genes that are significantly downregulated in colon cancer (one‐sided Wilcoxon rank‐sum test with multiple hypothesis correction (α = 0.001), Table EV1). (ii) Second, 328 of these downregulated genes have significantly lower copy number in the tumors compared to the healthy samples ( Q ‐values < 0.25, Table EV2).…”

Section: Resultsmentioning

confidence: 99%

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An integrated computational and experimental study uncovers FUT 9 as a metabolic driver of colorectal cancer

Auslander

Cunningham

Toosi

et al. 2017

Molecular Systems Biology

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Metabolic alterations play an important role in cancer and yet, few metabolic cancer driver genes are known. Here we perform a combined genomic and metabolic modeling analysis searching for metabolic drivers of colorectal cancer. Our analysis predicts FUT9, which catalyzes the biosynthesis of Ley glycolipids, as a driver of advanced‐stage colon cancer. Experimental testing reveals FUT9's complex dual role; while its knockdown enhances proliferation and migration in monolayers, it suppresses colon cancer cells expansion in tumorspheres and inhibits tumor development in a mouse xenograft models. These results suggest that FUT9's inhibition may attenuate tumor‐initiating cells (TICs) that are known to dominate tumorspheres and early tumor growth, but promote bulk tumor cells. In agreement, we find that FUT9 silencing decreases the expression of the colorectal cancer TIC marker CD44 and the level of the OCT4 transcription factor, which is known to support cancer stemness. Beyond its current application, this work presents a novel genomic and metabolic modeling computational approach that can facilitate the systematic discovery of metabolic driver genes in other types of cancer.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

An integrated computational and experimental study uncovers FUT 9 as a metabolic driver of colorectal cancer

Auslander

Cunningham

Toosi

et al. 2017

Molecular Systems Biology

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“…One of the important genetic lesions that plays a pivotal role in tumorigenesis is the somatic copy number alterations (SCNAs). SCNAs encompass sequences that have different copy numbers in an individual's germline DNA and in the DNA of a clonal subpopulation of cells, which happen to be malignant (Beroukhim et al ., 2010). In other words, the SCNAs involve genomic gains (amplifications, duplications) or losses (deletions) that alter the diploid status of a particular locus, thereby disrupting the balanced genome.…”

Section: Introductionmentioning

confidence: 99%

“…SCNAs in particular are the most intriguing form of genetic variations to study in cancer, as they alter the dosage of a gene product independent of the transcription factors and other controls. Analyses of cancer genome by cytogenetic studies and more recently by array hybridization profiling‐based methodologies have assisted in the identification of recurrent alterations unique to various cancers as well as some common alterations (Beroukhim et al ., 2010; Zack et al ., 2013). In understanding the role of CNAs, it becomes imperative to characterize the CNAs as the driver events in a particular malignancy and distinguish them from the passenger CNAs that would have been imbued into the genome during cancer evolution and possibly do not contribute towards it (Zack et al ., 2013).…”

Section: Introductionmentioning

confidence: 99%

Impact of somatic copy number alterations on the glioblastoma miRNome: miR‐4484 is a genomically deleted tumour suppressor

et al. 2017

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Glioblastoma (GBM) is the most frequent and most malignant primary brain tumour in adults. GBMs have a unique landscape of somatic copy number alterations (SCNAs), with the concomitant appearance of numerous driver amplifications and deletions. Here, we examined the genomic regions harbouring SCNAs and their impact on the GBM miRNome. We found that 40% of SCNA events covering 70–88% of the genomically altered regions, as identified by GISTIC and RAE algorithms, carried miRNA genes. Of 1426 annotated mature miRNAs analysed, ~ 14% (n = 198) were mapped to such fragile loci. Further, we identified an intragenic miRNA, miR‐4484 located on chromosome‐10, as a deleted and downregulated miRNA in GBM. miR‐4484 exhibited a strong positive correlation with the expression of its host gene uroporphyrinogen III synthase (UROS), thereby indicating that the loss of miR‐4484 is a codeletion event in GBM. Overexpression of miR‐4484 reduced the colony‐forming ability and suppressed the migratory capacity of glioma cells. Analysis of the RNA‐seq‐derived transcriptome upon exogenous miR‐4484 overexpression in conjunction with an integrative bioinformatics approach revealed several putative targets of miR‐4484. Unbiased functional enrichment of these targets through DAVID identified a cohort of important gene ontology terms, which possibly explain the functional role of miR‐4484 in gliomagenesis. Selected targets were validated and, importantly, were found to be upregulated in GBM. In brief, our study identified a panel of miRNAs that are likely to be regulated by genomic deletions and amplifications. Further, miR‐4484 was found to be deleted and acts as a tumour suppressor miRNA in GBM.

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“…Cancers can also be divided into clinically meaningful subtypes based on their gene expression patterns that may be indicative of response to a treatment, like Her2 positive breast cancers [4] or KIT positive gastro-intestinal tumours [5], for example. Many cancers have characteristic sets of somatic mutations that can be used to identify and classify the tumours [6]; few studies have even compared these across cancer types [7]. However, cancers are not commonly classified or studied based on the acquired traits or alterations to the pathways because of the added complexity.…”

Section: Introductionmentioning

confidence: 99%

Characterization of aberrant pathways across human cancers

et al. 2013

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Background Cancer is a broad group of genetic diseases which account for millions of deaths worldwide each year. Cancers are classified by various clinical, pathological and molecular methods, but even within a well-characterized disease, there is a significant inter-patient variability in survival, response to treatment, and other parameters. Especially in molecular level, tumours of the same category can appear significantly dissimilar due to complex combinations of genetic aberrations leading to a similar malignancy. We extended the current classification methods by studying tumour heterogeneity at pathway level. Methods We computed the rate of alterations in 1994 pathways and 2210 tumours consisting of eight different cancers. Using gene set enrichment analysis, each sample was computed a pathway aberration profile that reflected its molecular state. The profiles were analysed together to infer the characteristic aberration rates for each pathway within each cancer. Subgroups of tumours defined by similar pathway aberrations were identified using clustering analyses. The pathway aberration and gene expression profiles of the subgroups were consecutively compared across all eight cancer types to search for similar tumours crossing the standard classification. Results We identified pathways and processes that were common to all cancers as well as traits that are unique to a cancer type or closely related cancers. Studying the gene expression patterns within the pathway context suggested potential alteration mechanisms. Clustering analysis revealed five clinically relevant subgroups of tumours in four cancers that exhibited significant differences in survival compared to others. The cross-cancer analysis of the subgroups resulted in the identification of tumours that shared potentially significant alterations. Conclusions This study represents the first effort to extend the molecular characterizations towards pathway level descriptions across the family of cancers. In addition to providing a proof-of-concept for single sample pathway aberration analysis in this context, we present a comprehensive pathway aberration dataset that can be used to study pathway aberration patterns within or across cancers. Significant similarities between subgroups of different cancers on pathway and gene expression levels provide interesting hypotheses for understanding variable drug response, or transferring treatments across diseases by identifying common druggable pathways or genes, for example.

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The landscape of somatic copy-number alteration across human cancers

Cited by 3,296 publications

References 45 publications

An integrated computational and experimental study uncovers FUT 9 as a metabolic driver of colorectal cancer

An integrated computational and experimental study uncovers FUT 9 as a metabolic driver of colorectal cancer

Impact of somatic copy number alterations on the glioblastoma miRNome: miR‐4484 is a genomically deleted tumour suppressor

Characterization of aberrant pathways across human cancers

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