Comprehensive, Integrative Genomic Analysis of Diffuse Lower-Grade Gliomas

Brat, Daniel J.; Verhaak, Roel G.W.; Aldape, Kenneth; Yung, W. K. Alfred; Salama, Sofie R.; Cooper, Lee; Rheinbay, Esther; Miller, C. Ryan; Vitucci, Mark; Morozova, Olena; Robertson, A. Gordon; Noushmehr, Houtan; Laird, Peter W.; Cherniack, Andrew D.; Akbani, Rehan; Huse, Jason T.; Ciriello, Giovanni; Poisson, Laila; Barnholtz‐Sloan, Jill S.; Berger, Mitchel S.; Brennan, Cameron; Colen, Rivka R.; Colman, Howard; Flanders, Adam E.; Giannini, Caterina; Grifford, Mia; Iavarone, Antonio; Jain, Rajan; Joseph, Isaac; Kim, Jaegil; Kasaian, Katayoon; Mikkelsen, Tom; Murray, Bradley A.; O’Neill, Brian Patrick; Pachter, Lior; Parsons, D. Williams; Sougnez, Carrie; Sulman, Erik P.; VandenBerg, Scott R.; Meir, Erwin G. Van; Deimling, Andreas von; Zhang, Hailei; Crain, Daniel; Lau, Kevin; Mallery, David; Morris, Scott; Paulauskis, Joseph; Penny, Robert; Shelton, Troy; Sherman, Mark E.; Yena, Peggy; Black, Aaron; Bowen, Jay; Dicostanzo, Katie; Gastier-Foster, Julie M.; Leraas, Kristen; Lichtenberg, Tara M.; Pierson, Christopher R.; Ramirez, Nilsa C.; Taylor, Cynthia; Weaver, Stephanie; Wise, Lisa; Zmuda, Erik; Davidsen, Tanja M.; Demchok, John A.; Eley, Greg; Ferguson, Martin L.; Hutter, Carolyn M.; Shaw, Kenna; Ozenberger, Bradley A.; Sheth, Margi; Sofia, Heidi J.; Tarnuzzer, Roy; Wang, Zhining; Yang, Liming; Zenklusen, Jean C.; Ayala, Brenda; Baboud, Julien; Chudamani, Sudha; Jensen, Mark A.; Liu, Jia; Pihl, Todd; Raman, Rohini; Wan, Yunhu; Wu, Ye; Ally, Adrian; Auman, J. Todd; Balasundaram, Miruna; Balu, Saianand; Baylin, Stephen B.; Beroukhim, Rameen; Bootwalla, Moiz S.; Bowlby, Reanne; Bristow, Christopher A.; Brooks, Denise; Butterfield, Yaron S.N.; Carlsen, Rebecca; Carter, Scott L.; Chin, Lynda; Chu, Andy; Chuah, Eric; Cibulskis, Kristian; Clarke, Amanda; Coetzee, Simon G.; Dhalla, Noreen; Fennell, Tim; Fisher, Sheila; Gabriel, Stacey; Getz, Gad; Gibbs, Richard A.; Guin, Ranabir; Hadjipanayis, Angela; Hayes, D. Neil; Hinoue, Toshinori; Hoadley, Katherine A.; Holt, Robert A.; Hoyle, Alan P.; Jefferys, Stuart R.; Jones, Steven J.M.; Jones, Corbin D.; Kucherlapati, Raju; Lai, Phillip H.; Lander, Eric S.; Lee, Semin; Lichtenstein, Lee; Ma, Yussanne; Maglinte, Dennis T.; Mahadeshwar, Harshad S.; Marra, Marco A.; Mayo, Michael; Meng, Shaowu; Meyerson, Matthew; Mieczkowski, Piotr A.; Moore, Richard A.; Mose, Lisle E.; Mungall, Andrew J.; Pantazi, Angeliki; Parfenov, Michael; Park, Peter J.; Parker, Joel S.; Perou, Charles M.; Protopopov, Alexei; Ren, Xiaojia; Roach, Jeffrey; Sabedot, Thaís; Schein, Jacqueline E.; Schumacher, Steven E.; Seidman, Jonathan G.; Seth, Sahil; Shen, Hui; Simons, Janae V.; Sipahimalani, Payal; Soloway, Matthew G.; Song, Xingzhi; Sun, Huandong; Tabak, Barbara; Tam, Angela; Tan, Donghui; Tang, Jiabin; Thiessen, Nina; Triche, Tim; Berg, David J. Van Den; Veluvolu, Umadevi; Waring, Scot; Weisenberger, Daniel J.; Wilkerson, Matthew D.; Wong, Tina; Wu, Junyuan; Liu, Xi; Xu, Andrew Wei; Yang, Lixing; Zack, Travis I.; Zhang, Jianhua; Aksoy, Bülent Arman; Arachchi, Harindra; Benz, Chris; Bernard, Brady; Carlin, Daniel E.; Cho, Juok; DiCara, Daniel; Frazer, Scott; Fuller, Gregory N.; Gao, Jian; Gehlenborg, Nils; Haussler, David; Heiman, David I.; Iype, Lisa; Jacobsen, Anders; Zhang, Ju; Katzman, Sol; Kim, Hoon; Knijnenburg, Theo; Kreisberg, Richard; Lawrence, Michael S.; Lee, William; Leinonen, Kalle; Lin, Pei; Ling, Shiyun; Liu, Wenbin; Liu, Yingchun; Liu, Yuexin; Lu, Yiling; Mills, Gordon B.; Ng, Sam; Noble, Michael S.; Paull, Evan O.; Rao, Arvind; Reynolds, Sheila M.; Saksena, Gordon; Sanborn, Zack; Sander, Chris; Schultz, Nikolaus; Şenbabaoğlu, Yasin; Shen, Ronglai; Shmulevich, Ilya; Sinha, Rileen; Stuart, Josh; Sumer, S. Onur; Sun, Yichao; Tasman, Natalie; Taylor, Barry S.; Voet, Doug; Weinhold, Nils; Weinstein, John N.; Yang, Da; Yoshihara, Kosuke; Zheng, Siyuan; Zhang, Wei; Zou, Lihua; Abel, Ty W.; Sadeghi, Sara; Cohen, Mark L.; Eschbacher, Jenny; Hattab, Eyas M.; Raghunathan, Aditya; Schniederjan, Matthew; Aziz, Dina; Barnett, Gene H.; Barrett, Wendi; Bigner, Darell D.; Boice, Lori; Brewer, Cathy; Calatozzolo, Chiara; Campos, Benito; Carlotti, Carlos Gilberto; Chan, Timothy A.; Cuppini, Lucia; Curley, Erin; Cuzzubbo, Stefania; Devine, Karen; DiMeco, Francesco; Duell, Rebecca; Elder, J. Bradley; Fehrenbach, Ashley; Finocchiaro, Gaetano; Friedman, William A.; Fulop, Jordonna; Gardner, Johanna; Hermes, Beth; Herold‐Mende, Christel; Jungk, Christine; Kendler, Ady; Lehman, Norman L.; Lipp, Eric; Liu, Ouida; Mandt, Randy; McGraw, Mary; McLendon, Roger E.; McPherson, Christopher; Neder, Luciano; Nguyen, Phuong; Noss, Ardene; Nunziata, Raffaele; Ostrom, Quinn T.; Palmer, Cheryl A.; Perin, Alessandro; Pollo, Bianca; Потапов, А. А.; Potapova, Olga; Rathmell, W. Kimryn; Ротин, Д Л; Scarpace, Lisa; Schilero, Cathy; Senecal, Kelly; Shimmel, Kristen; Shurkhay, Vsevolod; Sifri, Suzanne; Singh, Rosy; Sloan, Andrew E.; Smolenski, Kathy; Staugaitis, Susan M.; Steele, Ruth; Thorne, Leigh B.; Tirapelli, Daniela P.C.; Unterberg, Andreas; Vallurupalli, Mahitha; Wang, Yun; Warnick, Ronald E.; Williams, Cecilia; Wolinsky, Yingli; Bell, Sue; Rosenberg, Mara; Stewart, Chip; Huang, Franklin W.; Grimsby, Jonna; Radenbaugh, Amie; Zhang, Jianan

doi:10.1056/nejmoa1402121

Cited by 2,473 publications

(1,429 citation statements)

References 54 publications

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“…In another series of 457 WHO grade II/III gliomas, 80.7% of the patients were found to harbor an IDH mutation (20). The Cancer Genome Atlas Research Network found an IDH mutation in 226 (80.1%) of 282 WHO grade II/III gliomas (21). Based on these results, the WHO now recognizes IDH mutation as a critical biomarker in the classification of gliomas (4).…”

Section: Idh and Glioma Initiationmentioning

confidence: 98%

“…Conversely, it can be argued that all GBMs harboring a WT IDH are biologically primary GBMs: cases of secondary GBM without an IDH mutation likely represent a progression from an undergraded, lower grade, or anaplastic glioma (8). These assumptions are borne out by recent data that show that gliomas lacking mutation in IDH or having chromosomal loss at 1p and 19q cluster by expression analysis and DNA copy-number profiling (21) and portend a severe prognosis (17). With an increased understanding of molecular markers and their incorporation into clinical trials, the disparity between molecular markers and histopathology-based diagnostics methods becomes more evident.…”

Section: Atrx Tp53 and 1p/19qmentioning

confidence: 99%

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Molecular Genetics of Secondary Glioblastoma

2017

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Glioblastoma (GBM, WHO grade IV astrocytoma) is among the most common adult brain tumors and one that is invariably fatal. GBM is classified as either primary (de novo) or secondary in origin. Secondary GBMs are derived from previously lower grade (WHO grades II or III) gliomas. While secondary GBMs present with similar clinical characteristics as their primary counterparts, the molecular pathways involved in their pathogenesis distinguish the two and have functional consequences for their behavior. Although a large number of histologic markers are routinely utilized to distinguish primary from secondary GBM, advances in genomic and bioinformatics techniques have drastically improved classification of high-grade gliomas and our understanding of the molecular pathways that influence tumor behavior and response to treatment. The significant influence of molecular identity on tumor behavior has been recognized by the most recent WHO classification of CNS tumors, wherein specific molecular markers have been integrated as part of tumor subtype identification process, as a supplement to traditional histological analysis. Indeed, the change heralds a new era for neuro-oncology, one that is moving toward targeted Genetics of Secondary Glioblastoma 28 therapeutics as part of the standard of care. Thus, a comprehensive grasp of this diverse landscape is necessary. In this chapter, we provide an overview of our latest understanding of the molecular diversity of GBM, specifically as it pertains to primary and secondary GBMs, and how it influences prognostication and therapeutic decision-making.

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Section: Idh and Glioma Initiationmentioning

confidence: 98%

Section: Atrx Tp53 and 1p/19qmentioning

confidence: 99%

Molecular Genetics of Secondary Glioblastoma

2017

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“…[4][5][6][7][8][9][10] Their potential to aid the choice of better treatment options is a step forward toward precision medicine.…”

Section: Figure 4: Representative Immunohistochemical Sections For Thmentioning

confidence: 99%

“…GBM has been one of the most molecularly profiled tumors by several groups, including The Cancer Genome Atlas (TCGA) Networks. [4][5][6][7][8][9][10] These studies have singled out specific determinant mutations within the newly identified subtypes: proneural, neural, classical and mesenchymal. Proneural tumors present alterations customized panel included genes such as NF1, RB1, EGFR, TP53, PTEN, IDH1 and PDGFRA, whose alterations have all been previously associated with the three main GBM subtypes: proneural, classical and mesenchymal.…”

mentioning

confidence: 99%

Correlation between molecular features and genetic subtypes of Glioblastoma: critical analysis in 109 cases

et al. 2017

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OBJECTIVE: Glioblastoma, the most common and lethal brain tumor, is also one of the most defying forms of malignancies in terms of treatment. Integrated genomic analysis has searched deeper into the molecular architecture of GBM, revealing a new sub-classification and promising precision in the care for patients with specific alterations. METHOD: Here, we present the classification of a Brazilian glioblastoma cohort into its main molecular subtypes. Using a high-throughput DNA sequencing procedure, we have classified this cohort into proneural, classical and mesenchymal sub-types. Next, we tested the possible use of the overexpression of the EGFR and CHI3L1 genes, detected through immunohistochemistry, for the identification of the classical and mesenchymal subtypes, respectively. RESULTS: Our results demonstrate that genetic identification of the glioblastoma subtypes is not possible using single targeted mutations alone, particularly in the case of the Mesenchymal subtype. We also show that it is not possible to single out the mesenchymal cases through CHI3L1 expression. CONCLUSION: Our data indicate that the Mesenchymal subtype, the most malignant of the glioblastomas, needs further and more thorough research to be ensure adequate identification.

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“…Despite widespread use, this time-honored method of histologic classification and grading suffers from well-documented inter-and intraobserver variability and does not adequately predict clinical outcomes or response to therapies. 3,4 In the Lower Grade Gliomas (LGG) project of The Cancer Genome Atlas (TCGA), 5 we attempted to determine whether biologic classes of disease with clinically distinct behaviors could be captured more cohesively and reliably by the integration of genomic profiling using multiple advanced molecular platforms. We collected nearly 300 diffuse low-grade and intermediate-grade gliomas (oligodendroglioma, astrocytoma, and oligoastrocytoma, WHO grades II and III) and analyzed them for mutations by whole-exome sequencing, DNA copy number alterations, DNA methylation, microRNA expression, and mRNA expression.…”

Section: Commentarymentioning

confidence: 99%