TY - JOUR
T1 - Spectrum and prevalence of genetic predisposition in medulloblastoma
T2 - a retrospective genetic study and prospective validation in a clinical trial cohort
AU - Waszak, Sebastian M.
AU - Northcott, Paul A.
AU - Buchhalter, Ivo
AU - Robinson, Giles W.
AU - Sutter, Christian
AU - Groebner, Susanne
AU - Grund, Kerstin B.
AU - Brugières, Laurence
AU - Jones, David T.W.
AU - Pajtler, Kristian W.
AU - Morrissy, A. Sorana
AU - Kool, Marcel
AU - Sturm, Dominik
AU - Chavez, Lukas
AU - Ernst, Aurelie
AU - Brabetz, Sebastian
AU - Hain, Michael
AU - Zichner, Thomas
AU - Segura-Wang, Maia
AU - Weischenfeldt, Joachim
AU - Rausch, Tobias
AU - Mardin, Balca R.
AU - Zhou, Xin
AU - Baciu, Cristina
AU - Lawerenz, Christian
AU - Chan, Jennifer A.
AU - Varlet, Pascale
AU - Guerrini-Rousseau, Lea
AU - Fults, Daniel W.
AU - Grajkowska, Wiesława
AU - Hauser, Peter
AU - Jabado, Nada
AU - Ra, Young Shin
AU - Zitterbart, Karel
AU - Shringarpure, Suyash S.
AU - De La Vega, Francisco M.
AU - Bustamante, Carlos D.
AU - Ng, Ho Keung
AU - Perry, Arie
AU - MacDonald, Tobey J.
AU - Hernáiz Driever, Pablo
AU - Bendel, Anne E.
AU - Bowers, Daniel C.
AU - McCowage, Geoffrey
AU - Chintagumpala, Murali M.
AU - Cohn, Richard
AU - Hassall, Timothy
AU - Fleischhack, Gudrun
AU - Eggen, Tone
AU - Wesenberg, Finn
AU - Feychting, Maria
AU - Lannering, Birgitta
AU - Schüz, Joachim
AU - Johansen, Christoffer
AU - Andersen, Tina V.
AU - Röösli, Martin
AU - Kuehni, Claudia E.
AU - Grotzer, Michael
AU - Kjaerheim, Kristina
AU - Monoranu, Camelia M.
AU - Archer, Tenley C.
AU - Duke, Elizabeth
AU - Pomeroy, Scott L.
AU - Shelagh, Redmond
AU - Frank, Stephan
AU - Sumerauer, David
AU - Scheurlen, Wolfram
AU - Ryzhova, Marina V.
AU - Milde, Till
AU - Kratz, Christian P.
AU - Samuel, David
AU - Zhang, Jinghui
AU - Solomon, David A.
AU - Marra, Marco
AU - Eils, Roland
AU - Bartram, Claus R.
AU - von Hoff, Katja
AU - Rutkowski, Stefan
AU - Ramaswamy, Vijay
AU - Gilbertson, Richard J.
AU - Korshunov, Andrey
AU - Taylor, Michael D.
AU - Lichter, Peter
AU - Malkin, David
AU - Gajjar, Amar
AU - Korbel, Jan O.
AU - Pfister, Stefan M.
N1 - Funding Information:
This project was supported by the PedBrain Tumor Project contributing to the ICGC, funded by German Cancer Aid (109252), the German Federal Ministry of Education and Research (BMBF; 01KU1201A and 01KU1201C), and additionally through BMBF grants BioTop (01EK1502A and 01EK1502B), ICGC-Data Mining (01KU1505F), MedSys (0315416C) and NGFNplus (01GS0883). Additional support came from the German Cancer Research Center-Heidelberg Center for Personalized Oncology (German Cancer Research Centre [DKFZ]-HIPO), the St Jude Comprehensive Cancer Center Core Grant (CA 21765), the American Lebanese Syrian Associated Charities, German Cancer Aid (111234), and the German Childhood Cancer Foundation (Deutsche Kinderkrebsstiftung; A2013/46 DKS2014.12). JOK was supported by a European Research Council Starting Grant (336045) and EurocanPlatform (260791) funding from the European Commission. DM was supported by the Canadian Institutes for Health Research (143234). PAN is the recipient of a Roman-Herzog Postdoctoral Fellowship (Hertie Foundation), V Foundation V Scholar Award, Sontag Foundation Distinguished Scientist Award, and is a Pew-Stewart Scholar for Cancer Research (Alexander and Margaret Stewart Trust). AG acknowledges funding from Musicians Against Childhood Cancer. MM acknowledges support from the BC Cancer Foundation and Canadian Institutes for Health Research (FDN 143288). MDT is supported by the Garron Family Chair in Childhood Cancer Research, and grants from the Cure Search Foundation, the National Institutes of Health (R01CA148699 and R01CA159859), the Pediatric Brain Tumor Foundation, the Terry Fox Research Institute, and Brainchild. This study was done with the support of the Ontario Institute for Cancer Research through funding provided by the Government of Ontario. SMW was supported by a Swiss National Science Foundation Early Postdoc.Mobility Fellowship (P2ELP3_155365) and an EMBO Long-Term Fellowship (ALTF 755-2014). SLP was supported by the NIH (2R01 CA109467, U01 CA184898, and U54 HD090255). TCA was supported by the NIH (T32 HL007901). RJG was supported by the Cancer Research UK (A17197) and the NIH (P01CA96832 and R0CA1129541). Tissue banking was supported by funds from the Faculty of Medicine, Masaryk University (Brno, Czech Republic) and KZ was supported by the project AZV 15-30657A from the Ministry of Health of the Czech Republic. CEFALO was supported by grants from the Swedish Council for Health, Working Life and Welfare (2004-0504, 2007-0224), the Swedish Research Council (K2008-70X-15366-04-3), the Swedish Cancer Society (09 0666), the Swedish Childhood Cancer Foundation (PROJ06/050, PROJ09/086), the Swedish Radiation Protection Authority (SSI P 1572), the Danish Strategic Research Council (2103-05-0006, 2064-04-0010), the Swiss Federal Office of Public Health (05.001626), the Swiss Research Foundation on Mobile Communication (A2006.18), the Swiss National Science Foundation (PDFMP3_122873), and the Research Council of Norway (175163/V40). The Medulloblastoma Advanced Genomics International Consortium (or MAGIC) project is financially supported by Genome Canada, Genome BC, Terry Fox Research Institute, Ontario Institute for Cancer Research, Pediatric Oncology Group Ontario, Funds from The Family of Kathleen Lorette and the Clark H Smith Brain Tumour Centre, Montreal Children's Hospital Foundation, Hospital for Sick Children: Sonia and Arthur Labatt Brain Tumour Research Centre, Chief of Research Fund, Cancer Genetics Program, Garron Family Cancer Centre, BRAIN Child, MDT's Garron Family Endowment, and BC Childhood Cancer Parents Association. We thank the DKFZ Genomics and Proteomics Core Facility, Andrea Wittmann (Pediatric Glioma Research Group, DKFZ, Heidelberg, Germany), Laura Sieber (Division of Pediatric Neurooncology, DKFZ), Rolf Kabbe (Division of Theoretical Bioinformatics, DKFZ; Department for Bioinformatics and Functional Genomics, Institute for Pharmacy and Molecular Biotechnology, and BioQuant, Heidelberg University, Heidelberg, Germany), Matthias Bieg (Division of Theoretical Bioinformatics, Heidelberg Center for Personalised Oncology, DKFZ), Matthias Schlesner (Bioinformatics and Omics Data Analytics, DKFZ), and Bernd Klaus (Genome Biology Unit, European Molecular Biology Laboratory [EMBL], Heidelberg, Germany) for technical support. We also acknowledge the IT facilities at EMBL and DKFZ for invaluable support. We thank Brandon Stelter (Biomedical Communications, St Jude Children's Research Hospital, Memphis, TN, USA) for assistance with artwork. This work is dedicated to Prof Dr Enno Kleihauer, who introduced molecular genetics to the field of neuro-oncology in the early 1980s, and who was one of the most influential paediatric haematologist-oncologists in Germany and beyond.
Funding Information:
SMW reports grants from the European Molecular Biology Organization (EMBO) and from the Swiss National Science Foundation, during the conduct of the study. GM reports grants from the St Jude Children's Research Hospital, during the conduct of the study. KvH reports grants from the German Childhood Cancer Foundation, during the conduct of the study. MF reports grants from the Swedish Research Council, the Swedish Council for Health, Working Life and Welfare, the Swedish Cancer Society, the Swedish Childhood Cancer Foundation, and the Swedish Radiation Protection Authority, during the conduct of the study. SLP reports grants from the National Institutes of Health, during the conduct of the study. FMDLV reports financial activities from Annai Systems Inc and financial activities from TOMA Biosciences Inc, outside the submitted work. CDB reports grants from the National Institutes of Health (NIH), during the conduct of the study; grants from the University of Miami, financial activities from the University of Chicago; University of California, Los Angeles; HUGO; New York Genome Center; University of Iowa; Rockefeller University; Alexandria; FH Foundation; Concert Genetics; National Autonomous University of Mexico; Mexican Institute of Social Security; Colorado State University; MacArthur Foundation; and Gordon Conference; and personal fees from CDB Consulting Ltd, Personalis, Inc, 23andme “Roots into the Future Project”, Ancestry.com , Liberty Biosecurity, Med-Tek, IdentifyGenomics LLC, Mars Inc, Etalon Inc, Fish & Richardson PC, Eden Roc, Hypatia, the Nicklaus Children's Hospital Research Institute, Knox Medical, Arc Bio LLC, Embark Veterinary, Digitalis Ventures, Humancode, Web Shield, and Luna DNA, outside the submitted work. All other authors declare no competing interests.
Publisher Copyright:
© 2018 The Author(s). Published by Elsevier Ltd. This is an Open Access article under the CC BY-NC-ND 4.0 license
PY - 2018/6
Y1 - 2018/6
N2 - Background: Medulloblastoma is associated with rare hereditary cancer predisposition syndromes; however, consensus medulloblastoma predisposition genes have not been defined and screening guidelines for genetic counselling and testing for paediatric patients are not available. We aimed to assess and define these genes to provide evidence for future screening guidelines. Methods: In this international, multicentre study, we analysed patients with medulloblastoma from retrospective cohorts (International Cancer Genome Consortium [ICGC] PedBrain, Medulloblastoma Advanced Genomics International Consortium [MAGIC], and the CEFALO series) and from prospective cohorts from four clinical studies (SJMB03, SJMB12, SJYC07, and I-HIT-MED). Whole-genome sequences and exome sequences from blood and tumour samples were analysed for rare damaging germline mutations in cancer predisposition genes. DNA methylation profiling was done to determine consensus molecular subgroups: WNT (MB WNT ), SHH (MB SHH ), group 3 (MB Group3 ), and group 4 (MB Group4 ). Medulloblastoma predisposition genes were predicted on the basis of rare variant burden tests against controls without a cancer diagnosis from the Exome Aggregation Consortium (ExAC). Previously defined somatic mutational signatures were used to further classify medulloblastoma genomes into two groups, a clock-like group (signatures 1 and 5) and a homologous recombination repair deficiency-like group (signatures 3 and 8), and chromothripsis was investigated using previously established criteria. Progression-free survival and overall survival were modelled for patients with a genetic predisposition to medulloblastoma. Findings: We included a total of 1022 patients with medulloblastoma from the retrospective cohorts (n=673) and the four prospective studies (n=349), from whom blood samples (n=1022) and tumour samples (n=800) were analysed for germline mutations in 110 cancer predisposition genes. In our rare variant burden analysis, we compared these against 53 105 sequenced controls from ExAC and identified APC, BRCA2, PALB2, PTCH1, SUFU, and TP53 as consensus medulloblastoma predisposition genes according to our rare variant burden analysis and estimated that germline mutations accounted for 6% of medulloblastoma diagnoses in the retrospective cohort. The prevalence of genetic predispositions differed between molecular subgroups in the retrospective cohort and was highest for patients in the MB SHH subgroup (20% in the retrospective cohort). These estimates were replicated in the prospective clinical cohort (germline mutations accounted for 5% of medulloblastoma diagnoses, with the highest prevalence [14%] in the MB SHH subgroup). Patients with germline APC mutations developed MB WNT and accounted for most (five [71%] of seven) cases of MB WNT that had no somatic CTNNB1 exon 3 mutations. Patients with germline mutations in SUFU and PTCH1 mostly developed infant MB SHH . Germline TP53 mutations presented only in childhood patients in the MB SHH subgroup and explained more than half (eight [57%] of 14) of all chromothripsis events in this subgroup. Germline mutations in PALB2 and BRCA2 were observed across the MB SHH , MB Group3 , and MB Group4 molecular subgroups and were associated with mutational signatures typical of homologous recombination repair deficiency. In patients with a genetic predisposition to medulloblastoma, 5-year progression-free survival was 52% (95% CI 40–69) and 5-year overall survival was 65% (95% CI 52–81); these survival estimates differed significantly across patients with germline mutations in different medulloblastoma predisposition genes. Interpretation: Genetic counselling and testing should be used as a standard-of-care procedure in patients with MB WNT and MB SHH because these patients have the highest prevalence of damaging germline mutations in known cancer predisposition genes. We propose criteria for routine genetic screening for patients with medulloblastoma based on clinical and molecular tumour characteristics. Funding: German Cancer Aid; German Federal Ministry of Education and Research; German Childhood Cancer Foundation (Deutsche Kinderkrebsstiftung); European Research Council; National Institutes of Health; Canadian Institutes for Health Research; German Cancer Research Center; St Jude Comprehensive Cancer Center; American Lebanese Syrian Associated Charities; Swiss National Science Foundation; European Molecular Biology Organization; Cancer Research UK; Hertie Foundation; Alexander and Margaret Stewart Trust; V Foundation for Cancer Research; Sontag Foundation; Musicians Against Childhood Cancer; BC Cancer Foundation; Swedish Council for Health, Working Life and Welfare; Swedish Research Council; Swedish Cancer Society; the Swedish Radiation Protection Authority; Danish Strategic Research Council; Swiss Federal Office of Public Health; Swiss Research Foundation on Mobile Communication; Masaryk University; Ministry of Health of the Czech Republic; Research Council of Norway; Genome Canada; Genome BC; Terry Fox Research Institute; Ontario Institute for Cancer Research; Pediatric Oncology Group of Ontario; The Family of Kathleen Lorette and the Clark H Smith Brain Tumour Centre; Montreal Children's Hospital Foundation; The Hospital for Sick Children: Sonia and Arthur Labatt Brain Tumour Research Centre, Chief of Research Fund, Cancer Genetics Program, Garron Family Cancer Centre, MDT's Garron Family Endowment; BC Childhood Cancer Parents Association; Cure Search Foundation; Pediatric Brain Tumor Foundation; Brainchild; and the Government of Ontario.
AB - Background: Medulloblastoma is associated with rare hereditary cancer predisposition syndromes; however, consensus medulloblastoma predisposition genes have not been defined and screening guidelines for genetic counselling and testing for paediatric patients are not available. We aimed to assess and define these genes to provide evidence for future screening guidelines. Methods: In this international, multicentre study, we analysed patients with medulloblastoma from retrospective cohorts (International Cancer Genome Consortium [ICGC] PedBrain, Medulloblastoma Advanced Genomics International Consortium [MAGIC], and the CEFALO series) and from prospective cohorts from four clinical studies (SJMB03, SJMB12, SJYC07, and I-HIT-MED). Whole-genome sequences and exome sequences from blood and tumour samples were analysed for rare damaging germline mutations in cancer predisposition genes. DNA methylation profiling was done to determine consensus molecular subgroups: WNT (MB WNT ), SHH (MB SHH ), group 3 (MB Group3 ), and group 4 (MB Group4 ). Medulloblastoma predisposition genes were predicted on the basis of rare variant burden tests against controls without a cancer diagnosis from the Exome Aggregation Consortium (ExAC). Previously defined somatic mutational signatures were used to further classify medulloblastoma genomes into two groups, a clock-like group (signatures 1 and 5) and a homologous recombination repair deficiency-like group (signatures 3 and 8), and chromothripsis was investigated using previously established criteria. Progression-free survival and overall survival were modelled for patients with a genetic predisposition to medulloblastoma. Findings: We included a total of 1022 patients with medulloblastoma from the retrospective cohorts (n=673) and the four prospective studies (n=349), from whom blood samples (n=1022) and tumour samples (n=800) were analysed for germline mutations in 110 cancer predisposition genes. In our rare variant burden analysis, we compared these against 53 105 sequenced controls from ExAC and identified APC, BRCA2, PALB2, PTCH1, SUFU, and TP53 as consensus medulloblastoma predisposition genes according to our rare variant burden analysis and estimated that germline mutations accounted for 6% of medulloblastoma diagnoses in the retrospective cohort. The prevalence of genetic predispositions differed between molecular subgroups in the retrospective cohort and was highest for patients in the MB SHH subgroup (20% in the retrospective cohort). These estimates were replicated in the prospective clinical cohort (germline mutations accounted for 5% of medulloblastoma diagnoses, with the highest prevalence [14%] in the MB SHH subgroup). Patients with germline APC mutations developed MB WNT and accounted for most (five [71%] of seven) cases of MB WNT that had no somatic CTNNB1 exon 3 mutations. Patients with germline mutations in SUFU and PTCH1 mostly developed infant MB SHH . Germline TP53 mutations presented only in childhood patients in the MB SHH subgroup and explained more than half (eight [57%] of 14) of all chromothripsis events in this subgroup. Germline mutations in PALB2 and BRCA2 were observed across the MB SHH , MB Group3 , and MB Group4 molecular subgroups and were associated with mutational signatures typical of homologous recombination repair deficiency. In patients with a genetic predisposition to medulloblastoma, 5-year progression-free survival was 52% (95% CI 40–69) and 5-year overall survival was 65% (95% CI 52–81); these survival estimates differed significantly across patients with germline mutations in different medulloblastoma predisposition genes. Interpretation: Genetic counselling and testing should be used as a standard-of-care procedure in patients with MB WNT and MB SHH because these patients have the highest prevalence of damaging germline mutations in known cancer predisposition genes. We propose criteria for routine genetic screening for patients with medulloblastoma based on clinical and molecular tumour characteristics. Funding: German Cancer Aid; German Federal Ministry of Education and Research; German Childhood Cancer Foundation (Deutsche Kinderkrebsstiftung); European Research Council; National Institutes of Health; Canadian Institutes for Health Research; German Cancer Research Center; St Jude Comprehensive Cancer Center; American Lebanese Syrian Associated Charities; Swiss National Science Foundation; European Molecular Biology Organization; Cancer Research UK; Hertie Foundation; Alexander and Margaret Stewart Trust; V Foundation for Cancer Research; Sontag Foundation; Musicians Against Childhood Cancer; BC Cancer Foundation; Swedish Council for Health, Working Life and Welfare; Swedish Research Council; Swedish Cancer Society; the Swedish Radiation Protection Authority; Danish Strategic Research Council; Swiss Federal Office of Public Health; Swiss Research Foundation on Mobile Communication; Masaryk University; Ministry of Health of the Czech Republic; Research Council of Norway; Genome Canada; Genome BC; Terry Fox Research Institute; Ontario Institute for Cancer Research; Pediatric Oncology Group of Ontario; The Family of Kathleen Lorette and the Clark H Smith Brain Tumour Centre; Montreal Children's Hospital Foundation; The Hospital for Sick Children: Sonia and Arthur Labatt Brain Tumour Research Centre, Chief of Research Fund, Cancer Genetics Program, Garron Family Cancer Centre, MDT's Garron Family Endowment; BC Childhood Cancer Parents Association; Cure Search Foundation; Pediatric Brain Tumor Foundation; Brainchild; and the Government of Ontario.
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U2 - 10.1016/S1470-2045(18)30242-0
DO - 10.1016/S1470-2045(18)30242-0
M3 - Article
C2 - 29753700
AN - SCOPUS:85046742636
SN - 1470-2045
VL - 19
SP - 785
EP - 798
JO - The Lancet Oncology
JF - The Lancet Oncology
IS - 6
ER -