Intergenically Spliced Chimeric RNAs in Cancer

Jia, Yuemeng; Xie, Zhongqiu; Li, Hui

doi:10.1016/j.trecan.2016.07.006

Cited by 83 publications

(85 citation statements)

References 81 publications

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“…Surprisingly, we found DNA support for only 6 of 242 fusions for which genomic data was available (Table 3). Fusions specific to RNA are increasingly reported in cancers and normal cell lines (Babiceanu et al 2016;Grosso et al 2015;Jia et al 2016;Li et al 2008;Qin et al 2015;Yun et al 2014). Similarly, in our study we have not been able to identify DNA support for most fusion events, suggesting they appear exclusively in the transcriptome.…”

Section: Discussioncontrasting

confidence: 66%

“…ReadThroughs form via cis-splicing, while trans-splicing of two separately transcribed pre-mRNA molecules can drive RNA-specific formation of fusions typically thought to be caused by genomic restructuring, such as CodingFusions (Gingeras 2009;Li et al 2008). Cissplicing, trans-splicing and splicing to produce truncated-and NoHeadGene-like fusions have all been previously reported in various cancers (Bartonicek et al 2017;Li et al 2008;Jia et al 2016;Qin et al 2015).…”

Section: Discussionmentioning

confidence: 97%

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Found in Transcription: Gene fusions arise through defects in RNA processing in the absence of chromosomal rearrangements

Jiang

Apostolides

Husić

et al. 2019

Preprint

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Recent advancements in high throughput sequencing analysis have enabled the characterization of cancerdriving fusions, improving our understanding of cancer development. Most fusion calling methods, however, examine either RNA or DNA information alone and are limited to a rigid definition of what constitutes a fusion. For this study we developed a pipeline that incorporates several fusion calling methods and considers both RNA and DNA to capture a more complete representation of the tumour fusion landscape. Interestingly, most of the fusions we identified were specific to RNA, with no evidence of corresponding genomic restructuring. Further, while the average total number of fusions in tumour and normal brain tissue samples is comparable, their overall fusion profiles vary significantly. Tumours have an over-representation of fusions occurring between coding genes, whereas fusions involving intergenic or non-coding regions comprised the vast majority of those in normals. Tumours were also more abundant in unique, samplespecific fusions compared to normals, though several fusions exhibited strong recurrence in the tumour type examined (diffuse intrinsic pontine glioma; DIPG) and were absent from both normal tissues and other cancers. Intriguingly, tumours also show broad up-or down-regulation of spliceosomal gene expression, which significantly correlates with fusion number (p=0.007). Our results show that RNA-specific fusions are abundant in both tumour and normal tissue and are associated with spliceosomal gene dysregulation.RNA-specific fusions should be considered as a potential mechanism that may contribute to cancer formation initiation and maintenance alongside more traditional structural events.

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Section: Discussioncontrasting

confidence: 66%

Section: Discussionmentioning

confidence: 97%

Found in Transcription: Gene fusions arise through defects in RNA processing in the absence of chromosomal rearrangements

Jiang

Apostolides

Husić

et al. 2019

Preprint

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“…4A). The genomic proximity of identified transcripts suggests that these fusions could be a result of cis-splicing (7,12). Inspection of nucleotide sequences located 5' and 3' of the fusion junctions for canonical splicing donors (GT) and acceptors (AG) revealed that 81.9% carried GT and AG at the 5' and 3' fusion sites (GT*AG) (Fig.…”

Section: Fusion Transcripts With Splicing Motifs Are Enriched In Neurmentioning

confidence: 98%

“…Besides a fusion resulting from small interstitial genomic deletions at 11q generating either a MLL-FOXR1 or a PAFAH1B2-FOXR2 fusion (11) no intra-chromosomal chimeric transcripts have been described in neuroblastoma. However, they have been shown to be present in other tumor types as well as in non-transformed tissues and be promoted by different types of cellular stress such as infections or mutations (12)(13)(14)(15)(16).…”

Section: Introductionmentioning

confidence: 99%

Alternative splicing in neuroblastoma generates RNA-fusion transcripts and is associated with vulnerability to spliceosome inhibitors

Shi

Rraklli

Maxymovitz

et al. 2019

Preprint

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28The paucity of recurrent mutations has hampered efforts to understand the pathogenesis of 29 neuroblastoma. Through analysis of RNA-sequenced neuroblastoma, we identified >900 primarily 30 intrachromosomal fusion transcripts generated by genes in close proximity. Fusions were enriched 31 in chromosomal regions gained or lost in neuroblastoma and included well-known neuroblastoma 32 oncogenes. The majority of fusions contained canonical splicing sites and a subset exhibited 33 increased sensitivity to spliceosome inhibition. As a proof-of-principle that a gene product with 34 altered properties can be produced by these fusions, we characterized the ZNF451-BAG2 fusion 35 which generates a truncated BAG2-protein capable of inhibiting retinoic acid-induced 36 differentiation. Our findings elucidate a mechanism through which altered gene products, relevant 37 for neuroblastoma pathogenesis and representing possible novel drug targets, can be generated. 38 39 413

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“…The ETV6-NTRK3 fusion was present in a head and neck thyroid carcinoma sample, linking exon 4 of ETV6 to exon 12 of NTRK3. We found three separate SVs in the same sample: i) a translocation of ETV6 (chr12:12,099,706) to chromosome 6 (chr6:125,106,892); ii) a translocation of NTRK3 (chr15:88,694,049) also to chromosome 6 (chr6:125,062,387); and iii) an additional copy number loss (chr12:12,032,501 -chr12:12,099,705) spanning from ETV6 intron 5 to the exact SV breakpoints (chr12:12,099,706), jointly bringing ETV6 within 45 kb upstream of NTRK3, a distance that would allow transcriptional read-through 71 or splicing 72 to yield the ETV6-NTRK3 fusion 73 (Figure 5d). Thus, the short chromosome 6 segment appeared to function as a bridge, linking two other genomic locations to facilitate a gene fusion.…”

Section: Bridged Fusions and Evidence-based Gene Fusion Classificationmentioning

confidence: 99%

Genomic basis for RNA alterations revealed by whole-genome analyses of 27 cancer types

Calabrese¹,

Davidson

Fonseca³

et al. 2017

Preprint

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We present the most comprehensive catalogue of cancer-associated gene alterations through characterization of tumor transcriptomes from 1,188 donors of the Pan-Cancer Analysis of Whole Genomes project. Using matched whole-genome sequencing data, we attributed RNA alterations to germline and somatic DNA alterations, revealing likely genetic mechanisms. We identified 444 associations of gene expression with somatic non-coding single-nucleotide variants. We found 1,872 splicing alterations associated with somatic mutation in intronic regions, including novel exonization events associated with Alu elements. Somatic copy number alterations were the major driver of total gene and allele-specific expression (ASE) variation. Additionally, 82% of gene fusions had structural variant support, including 75 of a novel class called “bridged” fusions, in which a third genomic location bridged two different genes. Globally, we observe transcriptomic alteration signatures that differ between cancer types and have associations with DNA mutational signatures. Given this unique dataset of RNA alterations, we also identified 1,012 genes significantly altered through both DNA and RNA mechanisms. Our study represents an extensive catalog of RNA alterations and reveals new insights into the heterogeneous molecular mechanisms of cancer gene alterations.

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Intergenically Spliced Chimeric RNAs in Cancer

Cited by 83 publications

References 81 publications

Found in Transcription: Gene fusions arise through defects in RNA processing in the absence of chromosomal rearrangements

Found in Transcription: Gene fusions arise through defects in RNA processing in the absence of chromosomal rearrangements

Alternative splicing in neuroblastoma generates RNA-fusion transcripts and is associated with vulnerability to spliceosome inhibitors

Genomic basis for RNA alterations revealed by whole-genome analyses of 27 cancer types

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