Copy-number signatures and mutational processes in ovarian carcinoma

Macintyre, Geoff; Goranova, Teodora; Silva, Dilrini De; Ennis, Darren; Piskorz, Anna; Eldridge, Matthew; Sie, Daoud; Lewsley, Liz-Anne; Hanif, Aishah; Wilson, Cheryl A.; Dowson, Suzanne; Glasspool, Rosalind; Lockley, Michelle; Brockbank, Elly; Montes, Ana; Walther, Axel; Sundar, Sudha; Edmondson, Richard J.; Hall, Geoff; Gourley, Charlie; Hall, Marcia; Fotopoulou, Christina; Gabra, Hani; Paul, James; Supernat, Anna; Millan, David; Hoyle, Aoisha; Bryson, Gareth; Nourse, Craig; Mincarelli, Laura; Sánchez, Luis Navarro; Ylstra, Bauke; Jimenez-Liñan, Mercedes; Moore, Luiza; Hofmann, Oliver; Markowetz, Florian; McNeish, Iain A.; Brenton, James D.

doi:10.1101/174201

Cited by 56 publications

(92 citation statements)

References 56 publications

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“…No data were available for region γ. As TCGA only includes ovary biopsies taken at the time of diagnosis, we used another independent data set including both spatial and temporal biopsies 6 to confirm our results. Analysis of recurrent alterations on this dataset with GISTIC (Supporting Information Methods, Section 5) confirmed that regions α and β show gain respectively in almost 74 and 85% of the samples (Supporting Information Results Section 6, Fig.…”

Section: Fmcr Of Amplification As a Feature Of Hgs-eocmentioning

confidence: 72%

“…2 From the 591 samples of serous ovarian cancer in the repository, were selected samples from patients with HGS-EOC stage III and IV tumors and with copy number alteration data available (Supporting Information Methods, Section 5). The second cohort was a selection of 91 temporal and spatial biopsies with high data quality from a previously published data set 6 where segmented copy number data were available (see Supporting Information Methods, Section 5).…”

Section: In Silico Data Validationmentioning

confidence: 99%

“…The few concordant data so far suggest that: (i) the branching pattern of HGS-EOC evolution sustains the marked genomic heterogeneity of single nucleotide variants (SNVs) among synchronous lesions. [3][4][5][6] Most of these genomic abnormalities arise in a random fashion and are lesion-specific; (ii) relapsed-molecular features are largely derived from selective pressure of already distinct genetic events present in the primary tumor rather than acquired de novo. 4,7 These findings imply that a single tumor lesion-the ovary for example-cannot any longer be considered representative of the entire disease, nor it is informative on the genomic features of relapsed disease.…”

Section: Introductionmentioning

confidence: 99%

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Multisite analysis of high‐grade serous epithelial ovarian cancers identifies genomic regions of focal and recurrent copy number alteration in 3q26.2 and 8q24.3

Ballabio

Craparotta

Paracchini

et al. 2019

Intl Journal of Cancer

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High‐grade serous epithelial ovarian cancer (HGS‐EOC) is a systemic disease, with marked intra and interpatient tumor heterogeneity. The issue of spatial and temporal heterogeneity has long been overlooked, hampering the possibility to identify those genomic alterations that persist, before and after therapy, in the genome of all tumor cells across the different anatomical districts. This knowledge is the first step to clarify those molecular determinants that characterize the tumor biology of HGS‐EOC and their route toward malignancy. In our study, ‐omics data were generated from 79 snap frozen matched tumor biopsies, withdrawn before and after chemotherapy from 24 HGS‐EOC patients, gathered together from independent cohorts. The landscape of somatic copy number alterations depicts a more homogenous and stable genomic portrait than the single nucleotide variant profile. Genomic identification of significant targets in cancer analysis identified two focal and minimal common regions (FMCRs) of amplification in the cytoband 3q26.2 (region α, 193 kb long) and 8q24.3 (region β, 495 kb long). Analysis in two external databases confirmed regions α and β are features of HGS‐EOC. The MECOM gene is located in region α, and 15 genes are in region β. No functional data are yet available for the genes in the β region. In conclusion, we have identified for the first time two FMCRs of amplification in HGS‐EOC, opening up a potential biological role in its etiopathogenesis.

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Section: Fmcr Of Amplification As a Feature Of Hgs-eocmentioning

confidence: 72%

Section: In Silico Data Validationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Multisite analysis of high‐grade serous epithelial ovarian cancers identifies genomic regions of focal and recurrent copy number alteration in 3q26.2 and 8q24.3

Ballabio

Craparotta

Paracchini

et al. 2019

Intl Journal of Cancer

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“…Copy number signatures can also be used to combine agents that are likely to be more effective. 20 HGSOC cell lines appear to depend on "quality control" pathways that sense and destroy damaged transcripts and proteins. Nonsense-mediated decay (NMD) is highly active in HGSOC cell lines.…”

Section: Do Ovarian Cancers Have Distinctive Metabolic Vulnerabilities?mentioning

confidence: 99%

Critical questions in ovarian cancer research and treatment: Report of an American Association for Cancer Research Special Conference

Bast

Matulonis

Sood

et al. 2019

Cancer

Self Cite

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Substantial progress has been made in understanding ovarian cancer at the molecular and cellular level. Significant improvement in 5‐year survival has been achieved through cytoreductive surgery, combination platinum‐based chemotherapy, and more effective treatment of recurrent cancer, and there are now more than 280,000 ovarian cancer survivors in the United States. Despite these advances, long‐term survival in late‐stage disease has improved little over the last 4 decades. Poor outcomes relate, in part, to late stage at initial diagnosis, intrinsic drug resistance, and the persistence of dormant drug‐resistant cancer cells after primary surgery and chemotherapy. Our ability to accelerate progress in the clinic will depend on the ability to answer several critical questions regarding this disease. To assess current answers, an American Association for Cancer Research Special Conference on “Critical Questions in Ovarian Cancer Research and Treatment” was held in Pittsburgh, Pennsylvania, on October 1‐3, 2017. Although clinical, translational, and basic investigators conducted much of the discussion, advocates participated in the meeting, and many presentations were directly relevant to patient care, including treatment with poly adenosine diphosphate ribose polymerase (PARP) inhibitors, attempts to improve immunotherapy by overcoming the immune suppressive effects of the microenvironment, and a better understanding of the heterogeneity of the disease.

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“…Recently, we have used low-cost shallow WGS (sWGS) to identify CN signatures in the genomes of HGSC [88]. We used biopsy samples from the BriTROC-1 study (the first study of the UK Translational Research in Ovarian Cancer Consortium -detailed in [89]) of relapsed HGSC, and combined relative CN data from sWGS (mean ×0.1) and TP53 mutant allele frequency from deep tagged-amplicon sequencing [90] to generate absolute CN profiles.…”

Section: Complex Genomic Algorithms Including Sv and Cn Signaturesmentioning

confidence: 99%

Targeting DNA repair: the genome as a potential biomarker

Nesic

Wakefield

Kondrashova

et al. 2018

The Journal of Pathology

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Genomic instability and mutations are fundamental aspects of human malignancies, leading to progressive accumulation of the hallmarks of cancer. For some time, it has been clear that key mutations may be used as both prognostic and predictive biomarkers, the best-known examples being the presence of germline BRCA1 or BRCA2 mutations, which are not only associated with improved prognosis in ovarian cancer, but are also predictive of response to poly(ADP-ribose) polymerase (PARP) inhibitors. Although biomarkers as specific and powerful as these are rare in human malignancies, next-generation sequencing and improved bioinformatic analyses are revealing mutational signatures, i.e. broader patterns of alterations in the cancer genome that have the power to reveal information about underlying driver mutational processes. Thus, the cancer genome can act as a stratification factor in clinical trials and, ultimately, will be used to drive personalized treatment decisions. In this review, we use ovarian high-grade serous carcinoma (HGSC) as an example of a disease of extreme genomic complexity that is marked by widespread copy number alterations, but that lacks powerful driver oncogene mutations. Understanding of the genomics of HGSC has led to the routine introduction of germline and somatic BRCA1/2 testing, as well as testing of mutations in other homologous recombination genes, widening the range of patients who may benefit from PARP inhibitors. We will discuss how whole genome-wide analyses, including loss of heterozygosity quantification and whole genome sequencing, may extend this paradigm to allow all patients to benefit from effective targeted therapies. Copyright © 2017 Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd.

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Copy-number signatures and mutational processes in ovarian carcinoma

Cited by 56 publications

References 56 publications

Multisite analysis of high‐grade serous epithelial ovarian cancers identifies genomic regions of focal and recurrent copy number alteration in 3q26.2 and 8q24.3

Multisite analysis of high‐grade serous epithelial ovarian cancers identifies genomic regions of focal and recurrent copy number alteration in 3q26.2 and 8q24.3

Critical questions in ovarian cancer research and treatment: Report of an American Association for Cancer Research Special Conference

Targeting DNA repair: the genome as a potential biomarker

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