A germline chromothripsis event stably segregating in 11 individuals through three generations

Bertelsen, Birgitte; Nazaryan‐Petersen, Lusine; Sun, Wei; Mehrjouy, Mana M.; Xie, Gangcai; Chen, Wei; Hjermind, Lena E.; Taschner, Peter E.M.; Tümer, Zeynep

doi:10.1038/gim.2015.112

Cited by 53 publications

(58 citation statements)

References 41 publications

(49 reference statements)

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“…Remarkably, chromothripsis was detected in a wide range of cancer entities and recognized to be the hallmarks of those with a poor prognosis (Notta et al, ; Rode, Maass, Willmund, Lichter, & Ernst, ). Thereafter its discovery in cancerous tissues, a very similar pattern was also observed in germline chromosomal rearrangements both at the balanced and at the unbalanced state although, in general, with a minor number of chromosomal breaks than observed in cancers (Bertelsen et al, ; Chiang et al, ; Kloosterman et al, ; Kloosterman, Guryev, et al, ; Kloosterman, Hoogstraat, et al, ).…”

Section: Introductionmentioning

confidence: 77%

“…In the recent years, a few cases had been reported of balanced chromothripsis in healthy or mildly affected persons whose children, more severely affected, were with recombinant genomic imbalances or even with apparently the same rearrangement present in the parent. In some of these cases, the parental karyotype was initially interpreted as a balanced two‐way simple translocation (Bertelsen et al, ; de Pagter et al, ). In this study, we illustrate two cases in which we demonstrated that the genomic imbalance present in the index case was derived by parental recombination events between the chromothriptic chromosomes and their normal homologs, although the presence of the parental complex rearrangement was far from predictable in both of them.…”

Section: Introductionmentioning

confidence: 99%

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Insertional translocation involving an additional nonchromothriptic chromosome in constitutional chromothripsis: Rule or exception?

Kurtas

Xumerle

Giussani

et al. 2018

Molec Gen & Gen Med

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Background Chromothripsis, which is the local massive shattering of one or more chromosomes and their reassembly in a disordered array with frequent loss of some fragments, has been mainly reported in association with abnormal phenotypes. We report three unrelated healthy persons, two of which parenting a child with some degree of intellectual disability, carrying a chromothripsis involving respectively one, two, and three chromosomes, which was detected only after whole‐genome sequencing. Unexpectedly, in all three cases a fragment from one of the chromothripsed chromosomes resulted to be inserted within a nonchromothripsed one. Methods Conventional cytogenetic techniques, paired‐end whole‐genome sequencing, polymerase chain reaction, and Sanger sequencing were used to characterize complex rearrangements, copy‐number variations, and breakpoint sequences in all three families. Results In two families, one parent was carrier of a balanced chromothripsis causing in the index case a deletion and a noncontiguous duplication at 3q in case 1, and a t(6;14) translocation associated with interstitial 14q deletion in case 2. In the third family, an unbalanced chromothripsis involving chromosomes 6, 7, and 15 was inherited to the proband by the mosaic parent. In all three parents, the chromothripsis was concurrent with an insertional translocation of a portion of one of the chromothriptic chromosomes within a further chromosome that was not involved in the chromothripsis event. Conclusion Our findings show that (a) both simple and complex unbalanced rearrangements may result by the recombination of a cryptic parental balanced chromothripsis and that (b) insertional translocations are the spy of more complex rearrangements and not simply a three‐breakpoint event.

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Section: Introductionmentioning

confidence: 77%

Section: Introductionmentioning

confidence: 99%

Insertional translocation involving an additional nonchromothriptic chromosome in constitutional chromothripsis: Rule or exception?

Kurtas

Xumerle

Giussani

et al. 2018

Molec Gen & Gen Med

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“…To summarize existing knowledge of chromoanagenesis and contextualize the findings from this study, we conducted a literature review of published reports of germline chromoanagenesis at sequence resolution, almost all of which arose de novo in affected individuals. The results of this review are consolidated in Table 1 and Additional file 2: Table S6 [9, 10, 13, 17–23, 76–78]. Based on this knowledge, and separate from the genome-wide SV analysis of the 686 SSC participants described above, we performed liWGS on an additional three unrelated participants (participants TL010, UTR22, and TL009) with developmental anomalies and large de novo translocational insertions identified by clinical karyotyping, which we suspected may represent more complex rearrangements.…”

Section: Resultsmentioning

confidence: 99%

“…While still rare, our data confirm that non-tumorigenic chromoanagenesis exists as both constitutional and somatic variation and that cytogenetically detected de novo interchromosomal insertions may hallmark such extreme rearrangements, though larger collections of samples are warranted to further investigate this phenomenon. The review of chromoanagenesis literature performed herein [10, 13, 17–23, 76–78] (Table 1 and Additional file 2: Table S6) supports three conclusions: (1) constitutional chromoanagenesis is frequently balanced, possibly due to embryonic selection against loss of genes intolerant to haploinsufficiency [79–81]; (2) extreme genomic rearrangements can be tolerated in the developing germline [77, 78], although cases of unbalanced extreme chromoanagenesis have mostly been reported in cancer; and (3) at least 2/55 of these rearrangements appeared to be the product of multiple compounding mutational events [23] and another 4/55 rearrangements were observed to acquire additional rearrangements de novo upon unstable transmission from parent to child [23, 77], suggesting it is unlikely that such catastrophic rearrangements always arise in a single mutational event. This latter conclusion draws a key parallel between the two prevailing proposed mechanisms of cancer chromoanagenesis, wherein some rearrangements likely arise from DNA shattering in missegregated micronuclei during mitosis [12, 54, 82–85], yet others acquire additional breakpoints over punctuated tumor evolution [14, 79, 86], not unlike the six constitutional rearrangements with some degree of evidence against a singular mutational event [23, 77].…”

Section: Discussionmentioning

confidence: 99%

Defining the diverse spectrum of inversions, complex structural variation, and chromothripsis in the morbid human genome

et al. 2017

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BackgroundStructural variation (SV) influences genome organization and contributes to human disease. However, the complete mutational spectrum of SV has not been routinely captured in disease association studies.ResultsWe sequenced 689 participants with autism spectrum disorder (ASD) and other developmental abnormalities to construct a genome-wide map of large SV. Using long-insert jumping libraries at 105X mean physical coverage and linked-read whole-genome sequencing from 10X Genomics, we document seven major SV classes at ~5 kb SV resolution. Our results encompass 11,735 distinct large SV sites, 38.1% of which are novel and 16.8% of which are balanced or complex. We characterize 16 recurrent subclasses of complex SV (cxSV), revealing that: (1) cxSV are larger and rarer than canonical SV; (2) each genome harbors 14 large cxSV on average; (3) 84.4% of large cxSVs involve inversion; and (4) most large cxSV (93.8%) have not been delineated in previous studies. Rare SVs are more likely to disrupt coding and regulatory non-coding loci, particularly when truncating constrained and disease-associated genes. We also identify multiple cases of catastrophic chromosomal rearrangements known as chromoanagenesis, including somatic chromoanasynthesis, and extreme balanced germline chromothripsis events involving up to 65 breakpoints and 60.6 Mb across four chromosomes, further defining rare categories of extreme cxSV.ConclusionsThese data provide a foundational map of large SV in the morbid human genome and demonstrate a previously underappreciated abundance and diversity of cxSV that should be considered in genomic studies of human disease.Electronic supplementary materialThe online version of this article (doi:10.1186/s13059-017-1158-6) contains supplementary material, which is available to authorized users.

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“…Chromothripsis is characterized by small-scale DNA copy number changes and extensive intrachromosomal rearrangements confined to single chromosome or chromosome arm and has been featured in human cancers (Crasta et al 2012, Zhang et al 2015. Germline chromothripsis is associated with congenital abnormalities as well as developmental disorders (de Pagter et al 2015, Anderson et al 2016, Bertelsen et al 2016. Parent-to-child transmission of chromothripsis has been associated with de novo complex copy number changes and severe congenital abnormalities in the child (de Pagter et al 2015), suggesting that germline chromothripsis may lead to further CIN and potentially, predisposition to cancers.…”

Section: Germline Mutations Affecting Kinetochore-microtubule Dynamicsmentioning

confidence: 99%

Germline mutation contribution to chromosomal instability

Chan

Ngeow

2017

Endocrine-Related Cancer

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Genomic instability is a feature of cancer that fuels oncogenesis through increased frequency of genetic disruption, leading to loss of genomic integrity and promoting clonal evolution as well as tumor transformation. A form of genomic instability prevalent across cancer types is chromosomal instability, which involves karyotypic changes including chromosome copy number alterations as well as gross structural abnormalities such as transversions and translocations. Defects in cellular mechanisms that are in place to govern fidelity of chromosomal segregation, DNA repair and ultimately genomic integrity are known to contribute to chromosomal instability. In this review, we discuss the association of germline mutations in these pathways with chromosomal instability in the background of related cancer predisposition syndromes. We will also reflect on the impact of genetic predisposition to clinical management of patients and how we can exploit this vulnerability to promote catastrophic genomic instability as a therapeutic strategy.

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A germline chromothripsis event stably segregating in 11 individuals through three generations

Cited by 53 publications

References 41 publications

Insertional translocation involving an additional nonchromothriptic chromosome in constitutional chromothripsis: Rule or exception?

Insertional translocation involving an additional nonchromothriptic chromosome in constitutional chromothripsis: Rule or exception?

Defining the diverse spectrum of inversions, complex structural variation, and chromothripsis in the morbid human genome

Germline mutation contribution to chromosomal instability

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