Pan-cancer patterns of somatic copy number alteration

Zack, Travis I.; Schumacher, Steven E.; Carter, Scott L.; Cherniack, Andrew D.; Saksena, Gordon; Tabak, Barbara; Lawrence, Michael S.; Chen, Ken; Wala, Jeremiah A.; Mermel, Craig H.; Sougnez, Carrie; Gabriel, Stacey; Hernandez, Bryan; Shen, Hui; Laird, Peter W.; Getz, Gad; Meyerson, Matthew; Beroukhim, Rameen

doi:10.1038/ng.2760

Cited by 1,612 publications

(1,664 citation statements)

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“…Alternatively, repetitive copy number alterations co‐occurring with mutations in driver genes could reduce BRAF and PIK3CA adjMAFs counts. However, the published literature does not support this hypothesis: BRAF and PIK3CA mutations rarely co‐occur with copy number gains in wild‐type alleles (The Cancer Genome Atlas, 2012; Zack et al ., 2013). Arm‐level 7q gains ( BRAF locus) have been described in up to 40% of CRC samples, mainly chromosomally instable tumors lacking BRAF mutations (The Cancer Genome Atlas, 2012).…”

Section: Discussionmentioning

confidence: 99%

Analysis of mutant allele fractions in driver genes in colorectal cancer – biological and clinical insights

Dienstmann¹,

Élez

Argilés

et al. 2017

Molecular Oncology

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Sequencing of tumors is now routine and guides personalized cancer therapy. Mutant allele fractions (MAFs, or the ‘mutation dose’) of a driver gene may reveal the genomic structure of tumors and influence response to targeted therapies. We performed a comprehensive analysis of MAFs of driver alterations in unpaired primary and metastatic colorectal cancer (CRC) at our institution from 2010 to 2015 and studied their potential clinical relevance. Of 763 CRC samples, 622 had detailed annotation on overall survival in the metastatic setting (OSmet) and 89 received targeted agents matched to KRAS (MEK inhibitors), BRAF (BRAF inhibitors), or PIK3CA mutations (PI3K pathway inhibitors). MAFs of each variant were normalized for tumor purity in the sample (adjMAFs). We found lower adjMAFs for BRAFV 600E and PIK3CA than for KRAS,NRAS, and BRAF non‐V600 variants. TP53 and BRAFV 600E adjMAFs were higher in metastases as compared to primary tumors, and high KRAS adjMAFs were found in CRC metastases of patients with KRAS wild‐type primary tumors previously exposed to EGFR antibodies. Patients with RAS‐ or BRAFV 600E‐mutated tumors, irrespective of adjMAFs, had worse OSmet. There was no significant association between adjMAFs and time to progression on targeted therapies matched to KRAS,BRAF, or PIK3CA mutations, potentially related to the limited antitumor activity of the employed drugs (overall response rate of 4.5%). In conclusion, the lower BRAFV 600E and PIK3CA adjMAFs in subsets of primary CRC tumors indicate subclonality of these driver genes. Differences in adjMAFs between metastases and primary tumors suggest that approved therapies may result in selection of BRAFV 600E‐ and KRAS‐resistant clones and an increase in genomic heterogeneity with acquired TP53 alterations. Despite significant differences in prognosis according to mutations in driver oncogenes, adjMAFs levels did not impact on survival and did not help predict benefit with matched targeted agents in the metastatic setting.

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Section: Discussionmentioning

confidence: 99%

Analysis of mutant allele fractions in driver genes in colorectal cancer – biological and clinical insights

Dienstmann¹,

Élez

Argilés

et al. 2017

Molecular Oncology

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“…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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“…It has been previously reported that CGRs are found in 5%-9% of all cancers (Malhotra et al 2013;Zack et al 2013) and ∼25% of bone tumors (Stephens et al 2011). However, these estimates depend on three factors: first, the type of data utilized (array or sequencing); second, the computational method implemented; and third, the specific types of cancer samples analyzed.…”

Section: Identification and Characterization Of Cgrs From Tcga Samplesmentioning

confidence: 97%

“…More recently, certain types of large-scale complex genomic rearrangements (CGRs), such as chromothripsis, breakage-fusion-bridges, and double minutes, have been discovered within tumor genomes and implicated in tumorigenesis ). CGRs involve three or more distant regions of the genome abnormally joining together and have been implicated in 5%-9% of all cancers (Malhotra et al 2013;Zack et al 2013) and ∼25% of bone tumors (Stephens et al 2011). These rearrangements can form distinct highly amplified contigs that harbor oncogenes, resulting in 10-to 100-fold increases in oncogene copy count, which may potentially drive tumorigenesis (Korbel and Campbell 2013).…”

Section: [Supplemental Materials Is Available For This Article]mentioning

confidence: 99%

“…These were filtered based on their likelihood to contain amplified CGRs. Since multiple amplifications in SNP array data are a good indicator of samples with CGRs (Zack et al 2013), we used the SNP data to build a simple discriminator with three parameters: the length of amplification l, the number of amplifications of at least such length n, and the threshold amplification value t. We then apply this discriminator by considering candidate samples to be those with at least n regions with log ratio of amplification greater than t and length at least l. Applying this discriminator with n = 2, t = 1.4, and l = 15 kb identified 482 candidate samples Table S9), and additionally, we removed one more sample (TCGA-50-5055; likely to be a sample mix up-female patient, male tumor). We therefore have 467 samples in total and present our analysis on these (Table 2).…”

Section: Preprocessing and Data Filtrationmentioning

confidence: 99%

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Identification of complex genomic rearrangements in cancers using CouGaR

et al. 2016

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The genomic alterations associated with cancers are numerous and varied, involving both isolated and large-scale complex genomic rearrangements (CGRs). Although the underlying mechanisms are not well understood, CGRs have been implicated in tumorigenesis. Here, we introduce CouGaR, a novel method for characterizing the genomic structure of amplified CGRs, leveraging both depth of coverage (DOC) and discordant pair-end mapping techniques. We applied our method to whole-genome sequencing (WGS) samples from The Cancer Genome Atlas and identify amplified CGRs in at least 5.2% (10+ copies) to 17.8% (6+ copies) of the samples. Furthermore, ∼95% of these amplified CGRs contain genes previously implicated in tumorigenesis, indicating the importance and widespread occurrence of CGRs in cancers. Additionally, CouGaR identified the occurrence of ‘chromoplexy’ in nearly 63% of all prostate cancer samples and 30% of all bladder cancer samples. To further validate the accuracy of our method, we experimentally tested 17 predicted fusions in two pediatric glioma samples and validated 15 of these (88%) with precise resolution of the breakpoints via qPCR experiments and Sanger sequencing, with nearly perfect copy count concordance. Additionally, to further help display and understand the structure of CGRs, we have implemented CouGaR-viz, a generic stand-alone tool for visualization of the copy count of regions, breakpoints, and relevant genes.

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Pan-cancer patterns of somatic copy number alteration

Cited by 1,612 publications

References 80 publications

Analysis of mutant allele fractions in driver genes in colorectal cancer – biological and clinical insights

Analysis of mutant allele fractions in driver genes in colorectal cancer – biological and clinical insights

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

Identification of complex genomic rearrangements in cancers using CouGaR

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