Integrative Analysis Identifies Four Molecular and Clinical Subsets in Uveal Melanoma

Robertson, A. Gordon; Shih, Juliann; Yau, Christina; Gibb, Ewan A.; Oba, Junna; Mungall, Karen; Hess, Julian M.; Uzunangelov, Vladislav; Walter, Vonn; Danilova, Ludmila; Lichtenberg, Tara M.; Kucherlapati, Melanie; Kimes, Patrick K.; Tang, Ming; Penson, A.; Babur, Özgün; Akbani, Rehan; Bristow, Christopher A.; Hoadley, Katherine A.; Iype, Lisa; Chang, Matthew T.; Abdel‐Rahman, Mohamed H.; Ally, Adrian; Auman, J. Todd; Balasundaram, Miruna; Balu, Saianand; Benz, Christopher C.; Beroukhim, Rameen; Birol, İnanç; Bodenheimer, Tom; Bowen, Jay; Bowlby, Reanne; Brooks, Denise; Carlsen, Rebecca; Cebulla, Colleen M.; Cherniack, Andrew D.; Chin, Lynda; Cho, Juok; Chuah, Eric; Chudamani, Sudha; Cibulskis, Carrie; Cibulskis, Kristian; Cope, Leslie; Coupland, Sarah E.; DeFreitas, Timothy; Demchok, John A.; Desjardins, Laurence; Dhalla, Noreen; Esmaeli, Bita; Felau, Ina; Ferguson, Martin L.; Frazer, Scott; Gabriel, Stacey; Gastier‐Foster, Julie M.; Gehlenborg, Nils; Gerken, Mark; Gershenwald, Jeffrey E.; Getz, Gad; Griewank, Klaus G.; Grimm, Elizabeth A.; Hayes, D. Neil; Hegde, Apurva M.; Heiman, David I.; Helsel, Carmen; Hobensack, Shital; Holt, Robert A.; Hoyle, Alan P.; Hu, Xin; Hutter, Carolyn M.; Jager, Martine J.; Jefferys, Stuart R.; Jones, Corbin D.; Jones, Steven J.M.; Kandoth, Cyriac; Kasaian, Katayoon; Kim, Jaegil; Kucherlapati, Raju; Lander, Eric S.; Lawrence, Michael S.; Lazar, Alexander J.; Lee, Semin; Leraas, Kristen; Lin, Pei; Liu, Jia; Liu, Wenbin; Lolla, Laxmi; Lu, Yiling; Ma, Yussanne; Mahadeshwar, Harshad S.; Mariani, Odette; Marra, Marco A.; Mayo, Michael; Meier, Sam; Meng, Shaowu; Meyerson, Matthew; Mieczkowski, Piotr A.; Mills, Gordon B.; Moore, Richard A.; Mose, Lisle E.; Mungall, Andrew J.; Murray, Bradley A.; Naresh, Rashi; Noble, Michael S.; Pantazi, Angeliki; Parfenov, Michael; Park, Peter J.; Parker, Joel S.; Perou, Charles M.; Pihl, Todd; Pilarski, Robert; Protopopov, Alexei; Radenbaugh, Amie; Rai, Karan; Ramirez, Nilsa C.; Ren, Xiaojia; Reynolds, Sheila M.; Roach, Jeffrey; Roman‐Roman, Sergio; Roszik, Jason; Sadeghi, Sara; Saksena, Gordon; Sastre, Xavier; Schadendorf, Dirk; Schein, Jacqueline E.; Schoenfield, Lynn; Schumacher, Steven E.; Seidman, Jonathan G.; Seth, Sahil; Sethi, Geetika; Sheth, Margi; Shi, Yan; Shields, Carol L.; Shmulevich, Ilya; Simons, Janae V.; Singh, Arun D.; Sipahimalani, Payal; Skelly, Tara; Sofia, Heidi J.; Soloway, Matthew G.; Song, Xingzhi; Stern, Marc‐Henri; Stuart, Joshua M.; Sun, Qiang; Sun, Huandong; Tam, Angela; Tan, Donghui; Tang, Jiabin; Tarnuzzer, Roy; Taylor, Barry S.; Thiessen, Nina; Thórsson, Vésteinn; Tse, Kane; Veluvolu, Umadevi; Verhaak, Roel G.W.; Voet, Doug; Wan, Yunhu; Wang, Zhining; Weinstein, John N.; Wilkerson, Matthew D.; Williams, Michelle D.; Wise, Lisa; Woodman, Scott E.; Wong, Tina; Wu, Ye; Yang, Liming; Yang, Lixing; Zenklusen, Jean C.; Zhang, Jiashan; Zhang, Hailei; Zmuda, Erik

doi:10.1016/j.ccell.2017.07.003

Cited by 660 publications

(711 citation statements)

References 140 publications

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“…WGS profiling and SV calling was carried for individual TCGA projects as previously described (Cancer Genome Atlas Network, 2012, 2015a, 2015b; Cancer Genome Atlas Research Network, 2014a, 2014b, 2015a, 2015b, 2017a, 2017b; Cancer Genome Atlas Research Network et al, 2013a; Chen et al, 2016; Davis et al, 2014; Robertson et al, 2017), as well as detailed in the Supplemental Experimental Procedures. Previous studies show that on the order of 96%–98% of high-confidence SVs from high-pass WGS data detected by the Meerkat algorithm are able to be validated by PCR (Davis et al, 2014; Yang et al, 2013).…”

Section: Methodsmentioning

confidence: 99%

“…With TCGA gene expression data, large-scale integration between WGS and expression data is possible. TCGA WGS data were generated with either low-depth-of-coverage (low pass) or high-depth-of-coverage (high pass), with both types of WGS being used effectively to identify SVs in previous TCGA consortium-led studies focusing on a specific cancer type (Cancer Genome Atlas Network, 2012, 2015a, 2015b; Cancer Genome Atlas Research Network, 2013, 2014a, 2014b, 2015b, 2017a, 2017b; Davis et al, 2014; Robertson et al, 2017). While low-pass WGS may involve decreased sensitivity of detection, >1,200 cases in TCGA have low-pass data, representing a rich resource, with no pan-cancer study to date using these data.…”

Section: Introductionmentioning

confidence: 99%

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A Pan-Cancer Compendium of Genes Deregulated by Somatic Genomic Rearrangement across More Than 1,400 Cases

et al. 2018

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SUMMARY A systematic cataloging of genes affected by genomic rearrangement, using multiple patient co-horts and cancer types, can provide insight into cancer-relevant alterations outside of exomes. By integrative analysis of whole-genome sequencing (predominantly low pass) and gene expression data from 1,448 cancers involving 18 histopathological types in The Cancer Genome Atlas, we identified hundreds of genes for which the nearby presence (within 100 kb) of a somatic structural variant (SV) breakpoint is associated with altered expression. While genomic rearrangements are associated with widespread copy-number alteration (CNA) patterns, approximately 1,100 genes—including overexpressed cancer driver genes (e.g., TERT, ERBB2, CDK12, CDK4) and underexpressed tumor suppressors (e.g., TP53, RB1, PTEN, STK11)—show SV-associated deregulation independent of CNA. SVs associated with the disruption of topologically associated domains, enhancer hijacking, or fusion transcripts are implicated in gene upregulation. For cancer-relevant pathways, SVs considerably expand our understanding of how genes are affected beyond point mutation or CNA.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A Pan-Cancer Compendium of Genes Deregulated by Somatic Genomic Rearrangement across More Than 1,400 Cases

et al. 2018

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“…UM is characterized by distinct gross chromosomal abnormalities that are associated with patient outcome, the most common being monosomy 3 (M3), which corresponds with a significantly worse prognosis 8, 9, 10, 11, 12. M3 is frequently accompanied by polysomy 8q, and increasing copies of 8q significantly correlate with reduced survival, in a dose‐dependent fashion 8, 10, 13, 14.…”

Section: Introductionmentioning

confidence: 99%

“…Further abnormalities described in UM include loss of 1p, which is associated with poor prognosis in the context of M3 15, and gains on 6p, which, in the absence of additional chromosomal abnormalities, correspond with a good prognosis 16, 17. More recently, mutations occurring in UM have been identified in several genes, including GNAQ , GNA11 , BAP1 , SF3B1 , EIF1AX , PLCB4 , and CYSLTR2 11, 18, 19, 20, 21, 22. In particular, inactivating BAP1 mutations are associated with a poor outcome, being present in ∼84% of all UMs that went on to produce metastases 19, 23, 24.…”

Section: Introductionmentioning

confidence: 99%

Patterns of BAP1 protein expression provide insights into prognostic significance and the biology of uveal melanoma

Farquhar

Thornton

Coupland

et al. 2017

The Journal of Pathology CR

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Uveal melanoma (UM) is a rare aggressive intraocular tumour with a propensity for liver metastases, occurring in ∼50% of patients. The tumour suppressor BAP1 is considered to be key in UM progression. Herein, we present the largest study to date investigating cellular expression patterns of BAP1 protein in 165 UMs, correlating these patterns to prognosis. Full clinical, histological, genetic, and follow‐up data were available for all patients. BAP1 gene sequencing was performed on a subset of 26 cases. An independent cohort of 14 UMs was examined for comparison. Loss of nuclear BAP1 (nBAP1) protein expression was observed in 54% (88/165) UMs. nBAP1 expression proved to be a significant independent prognostic parameter: it identified two subgroups within monosomy 3 (M3) UM, which are known to have a high risk of metastasis. Strikingly, nBAP1‐positiveM3 UMs were associated with prolonged survival compared to nBAP1‐negative M3 UMs (Log rank, p = 0.014). nBAP1 protein loss did not correlate with a BAP1 mutation in 23% (6/26) of the UMs analysed. Cytoplasmic BAP1 protein (cBAP1) expression was also observed in UM: although appearing ‘predominantly diffuse’ in most nBAP1‐negative UM, a distinct ‘focal perinuclear’ expression pattern – localized immediately adjacent to the cis Golgi – was seen in 31% (18/59). These tumours tended to carry loss‐of‐function BAP1 mutations. Our study demonstrates loss of nBAP1 expression to be the strongest prognostic marker in UM, confirming its importance in UM progression. Our data suggest that non‐genetic mechanisms account for nBAP1 loss in a small number of UMs. In addition, we describe a subset of nBAP1‐negative UM, in which BAP1 is sequestered in perinuclear bodies, most likely within Golgi, warranting further mechanistic investigation.

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“…Uveal melanoma is the most common primary intraocular malignancy in adults and is both clinically and genomically distinct from cutaneous melanoma. 1 Despite successful local therapy, almost half of all patients develop metastases, with the majority relapsing in the liver. 2 Unlike cutaneous melanoma, there are no effective systemic treatments for metastatic uveal melanoma, and indeed, there is no defined standard of care.…”

Section: Introductionmentioning

confidence: 99%

A pilot study of intrahepatic yttrium‐90 microsphere radioembolization in combination with intravenous cisplatin for uveal melanoma liver‐only metastases

et al. 2019

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Background Metastatic uveal melanoma is a highly aggressive disease with no standard of care treatment option. A large proportion of patients have liver‐only metastatic disease which raises the question if liver‐directed therapy can be efficacious in this subpopulation. Aims The study aims to evaluate the safety and efficacy of radiosensitizing chemotherapy in combination with yttrium‐90 microspheres in patients with uveal melanoma with liver‐only metastases. Methods and results This single arm, open labeled, non‐randomized study enrolled 10 patients with liver‐only metastatic uveal melanoma between November 2012 and January 2018. Eligible patients received intrahepatic yttrium‐90 microspheres followed by intravenous cisplatin (20 mg/m2) for 5 days. Ten patients were enrolled, but nine patients received treatment who were included in the final analysis with a median follow‐up of 30 months (range 7 to 44). Five (50%) were female, five (50%) had an elevated lactate dehydrogenase (LDH), and one (10%) had prior anti‐PD‐1 therapy. The combination was well tolerated with no greater than or equal to grade 3 toxicity observed. The liver objective response rate (ORR) was 33% (3/9), the median progression‐free survival (PFS) in the liver was 3 months (95% CI, 3‐NA), and the extrahepatic PFS was 3 months (95% CI, 3‐NA). Seventy‐eight percent (7/9) received an immune checkpoint inhibitor on disease progression, with no responses seen. The median overall survival (OS) was 10 months (95% CI, 7‐NA). Conclusion The combination of cisplatin with yttrium‐90 microspheres was well tolerated; however, it was associated with intrahepatic disease control of relatively short duration. No responses were seen in patients treated with immune checkpoint inhibitors post radioembolization.

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Integrative Analysis Identifies Four Molecular and Clinical Subsets in Uveal Melanoma

Cited by 660 publications

References 140 publications

A Pan-Cancer Compendium of Genes Deregulated by Somatic Genomic Rearrangement across More Than 1,400 Cases

A Pan-Cancer Compendium of Genes Deregulated by Somatic Genomic Rearrangement across More Than 1,400 Cases

Patterns of BAP1 protein expression provide insights into prognostic significance and the biology of uveal melanoma

A pilot study of intrahepatic yttrium‐90 microsphere radioembolization in combination with intravenous cisplatin for uveal melanoma liver‐only metastases

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