Breakpoint profiling of 64 cancer genomes reveals numerous complex rearrangements spawned by homology-independent mechanisms

Malhotra, Ankit; Lindberg, Michael; Faust, Gregory G.; Leibowitz, Mitchell L.; Clark, Royden A.; Layer, Ryan M.; Quinlan, Aaron R.; Hall, Ira M.

doi:10.1101/gr.143677.112

Cited by 166 publications

(201 citation statements)

References 50 publications

(56 reference statements)

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“…CouGaR identified at least one contig (≥3 copies) in 443 of the 467 samples analyzed, and on average we found 6.25 contigs per sample. Interestingly, the 6.25 contigs per sample is nearly twice as many as previously reported (Malhotra et al 2013). The lower number reported earlier could be attributed to both lack of methods that were capable of identifying these CGRs accurately and to the smaller number of samples analyzed.…”

Section: Identification and Characterization Of Cgrs From Tcga Samplessupporting

confidence: 70%

“…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: 96%

“…We also compared CouGaR with two published methods, BAMBAM (Sanborn et al 2013) and nFuse (Malhotra et al 2013), on DIPG29. On this sample, CouGaR reported 16 breakpoints, while BAMBAM reported 157 and nFuse reported 25 breakpoints.…”

Section: Comparison Of Cougar To Prior Methodsmentioning

confidence: 99%

“…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%

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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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Section: Identification and Characterization Of Cgrs From Tcga Samplessupporting

confidence: 70%

Section: Identification and Characterization Of Cgrs From Tcga Samplesmentioning

confidence: 96%

Section: Comparison Of Cougar To Prior Methodsmentioning

confidence: 99%

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

confidence: 99%

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Identification of complex genomic rearrangements in cancers using CouGaR

et al. 2016

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“…Except for small insertions, SMASH consistently detected breakpoints with allelic frequencies >1.7%. To see if SMASH produces results comparable to other SV algorithms, we compared its breakpoint detection to HYDRA (Quinlan et al 2010;Malhotra et al 2013) on a set of simulated breakpoints (Supplemental Material; Supplemental Table T3). Overall, SMASH breakpoint detection rates were similar to HYDRA, with SMASH more accurately resolving breakpoint coordinates and HYDRA more consistently detecting short insertions.…”

Section: Resultsmentioning

confidence: 99%

Discovery of recurrent structural variants in nasopharyngeal carcinoma

et al. 2013

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We present the discovery of genes recurrently involved in structural variation in nasopharyngeal carcinoma (NPC) and the identification of a novel type of somatic structural variant. We identified the variants with high complexity mate-pair libraries and a novel computational algorithm specifically designed for tumor-normal comparisons, SMASH. SMASH combines signals from split reads and mate-pair discordance to detect somatic structural variants. We demonstrate a >90% validation rate and a breakpoint reconstruction accuracy of 3 bp by Sanger sequencing. Our approach identified three in-frame gene fusions (YAP1-MAML2, PTPLB-RSRC1, and SP3-PTK2) that had strong levels of expression in corresponding NPC tissues. We found two cases of a novel type of structural variant, which we call ''coupled inversion,'' one of which produced the YAP1-MAML2 fusion. To investigate whether the identified fusion genes are recurrent, we performed fluorescent in situ hybridization (FISH) to screen 196 independent NPC cases. We observed recurrent rearrangements of MAML2 (three cases), PTK2 (six cases), and SP3 (two cases), corresponding to a combined rate of structural variation recurrence of 6% among tested NPC tissues.

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Chromothripsis and Human Genetic Disease

Nazaryan‐Petersen

Tommerup

2016

Encyclopedia of Life Sciences

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Chromothripsis (CTH) is a newly discovered mutational mechanism, which in a single catastrophic event results in localised complex structural rearrangements confined to one or a few chromosomes. After an initial shattering or clustered fragmentation of a chromosomal region, the fragments join together in random order and orientation. During this process some of the generated fragments may be lost. It is not entirely clear which factors trigger the localised fragmentation; however, several mechanisms have been proposed, such as ionising radiation, aborted apoptosis, isolation of chromosome(s) in micronuclei, LINE1‐endonucleases, etc. CTH may disrupt multiple genes and/or regulatory regions. When it is incompatible with cell survival, the result should be apoptosis. However, if a cell escapes apoptosis, the extensive genomic rearrangements may have different phenotypic outcomes: cancer (somatic), congenital and developmental disorders (germline), neutral or even beneficial effects. Key Concepts Chromothripsis is a phenomenon where multiple localised double‐stranded DNA breaks result in complex genomic rearrangements. Chromothripsis occurs within a single cell cycle. Ionising radiation, aborted apoptosis, isolation of chromosome(s) in micronuclei and LINE1‐endonucleases are proposed to have a role in chromothripsis. Chromothripsis in somatic cells may trigger cancer development. Chromothripsis in the germline may result in congenital and developmental disorders.

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Breakpoint profiling of 64 cancer genomes reveals numerous complex rearrangements spawned by homology-independent mechanisms

Cited by 166 publications

References 50 publications

Identification of complex genomic rearrangements in cancers using CouGaR

Identification of complex genomic rearrangements in cancers using CouGaR

Discovery of recurrent structural variants in nasopharyngeal carcinoma

Chromothripsis and Human Genetic Disease

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