The Genetic Basis of Hepatosplenic T-cell Lymphoma

Matthew McKinney; Andrea B. Moffitt; Philippe Gaulard; Marion Travert; Laurence de Leval; Alina Nicolae; Mark Raffeld; Elaine S. Jaffe; Stefania Pittaluga; Liqiang Xi; Tayla B. Heavican; Javeed Iqbal; Karim Belhadj; Marie‐Hélène Delfau‐Larue; Virginie Fataccioli; Magdalena Czader; Izidore S. Lossos; Jennifer R. Chapman‐Fredricks; Kristy L. Richards; Yuri Fedoriw; Sarah L. Ondrejka; Eric D. Hsi; Lawrence K. Low; Dennis D. Weisenburger; Wing C. Chan; Neha Mehta–Shah; Steven M. Horwitz; Leon Bernal‐Mizrachi; Christopher R. Flowers; Anne Beaven; Mayur Parihar; Lucile Baseggio; Marie Parrens; Anne Moreau; Pierre Sujobert; Monika Pilichowska; Andrew M. Evens; Amy Chadburn; Rex Au-Yeung; Gopesh Srivastava; William W.L. Choi; John R. Goodlad; Igor Aurer; Sandra Bašić‐Kinda; Randy D. Gascoyne; Nicholas S. Davis; Guojie Li; Jenny Zhang; Deepthi Rajagopalan; Anupama Reddy; Cassandra Love; Shawn Levy; Yuan Zhuang; Jyotishka Datta; David B. Dunson; Sandeep S. Davé

doi:10.1158/2159-8290.cd-16-0330

The Genetic Basis of Hepatosplenic T-cell Lymphoma

Matthew McKinney(Duke Medical Center), Andrea B. Moffitt(Duke University), Philippe Gaulard(Inserm), Marion Travert(Inserm), Laurence de Leval(University Hospital of Lausanne), Alina Nicolae(National Institutes of Health), Mark Raffeld(National Institutes of Health), Elaine S. Jaffe(National Institutes of Health), Stefania Pittaluga(National Institutes of Health), Liqiang Xi(National Institutes of Health), Tayla B. Heavican(University of Nebraska at Omaha), Javeed Iqbal(University of Nebraska at Omaha), Karim Belhadj(Inserm), Marie‐Hélène Delfau‐Larue(Inserm), Virginie Fataccioli(Inserm), Magdalena Czader(Indiana University Health), Izidore S. Lossos(University of Miami), Jennifer R. Chapman‐Fredricks(University of Miami), Kristy L. Richards(University of North Carolina at Chapel Hill), Yuri Fedoriw(University of North Carolina at Chapel Hill), Sarah L. Ondrejka(Cleveland Clinic), Eric D. Hsi(Cleveland Clinic), Lawrence K. Low(City Of Hope National Medical Center), Dennis D. Weisenburger(City Of Hope National Medical Center), Wing C. Chan(City Of Hope National Medical Center), Neha Mehta–Shah(Memorial Sloan Kettering Cancer Center), Steven M. Horwitz(Memorial Sloan Kettering Cancer Center), Leon Bernal‐Mizrachi(Emory University), Christopher R. Flowers(Emory University), Anne Beaven(Duke Medical Center), Mayur Parihar(Tata Medical Center), Lucile Baseggio(Hôpital Lyon Sud), Marie Parrens(Institut Polytechnique de Bordeaux), Anne Moreau(Hotel Dieu Hospital), Pierre Sujobert(Université Claude Bernard Lyon 1), Monika Pilichowska(Tufts Medical Center), Andrew M. Evens(Tufts Medical Center), Amy Chadburn(NewYork–Presbyterian Hospital), Rex Au-Yeung(Queen Mary Hospital), Gopesh Srivastava(Queen Mary Hospital), William W.L. Choi(Queen Mary Hospital), John R. Goodlad(Western General Hospital), Igor Aurer(University Hospital Centre Zagreb), Sandra Bašić‐Kinda(University Hospital Centre Zagreb), Randy D. Gascoyne(BC Cancer Agency), Nicholas S. Davis(Duke Medical Center), Guojie Li(Duke Medical Center), Jenny Zhang(Duke Medical Center), Deepthi Rajagopalan(Duke Medical Center), Anupama Reddy(Duke Medical Center), Cassandra Love(Duke Medical Center), Shawn Levy(HudsonAlpha Institute for Biotechnology), Yuan Zhuang(Duke Medical Center), Jyotishka Datta(Statistical and Applied Mathematical Sciences Institute), David B. Dunson(Statistical and Applied Mathematical Sciences Institute), Sandeep S. Davé(Duke University)

Cancer Discovery

January 25, 2017

10.1158/2159-8290.cd-16-0330

Cited by 202Open Access

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Abstract

Abstract Hepatosplenic T-cell lymphoma (HSTL) is a rare and lethal lymphoma; the genetic drivers of this disease are unknown. Through whole-exome sequencing of 68 HSTLs, we define recurrently mutated driver genes and copy-number alterations in the disease. Chromatin-modifying genes, including SETD2, INO80, and ARID1B, were commonly mutated in HSTL, affecting 62% of cases. HSTLs manifest frequent mutations in STAT5B (31%), STAT3 (9%), and PIK3CD (9%), for which there currently exist potential targeted therapies. In addition, we noted less frequent events in EZH2, KRAS, and TP53. SETD2 was the most frequently silenced gene in HSTL. We experimentally demonstrated that SETD2 acts as a tumor suppressor gene. In addition, we found that mutations in STAT5B and PIK3CD activate critical signaling pathways important to cell survival in HSTL. Our work thus defines the genetic landscape of HSTL and implicates gene mutations linked to HSTL pathogenesis and potential treatment targets. Significance: We report the first systematic application of whole-exome sequencing to define the genetic basis of HSTL, a rare but lethal disease. Our work defines SETD2 as a tumor suppressor gene in HSTL and implicates genes including INO80 and PIK3CD in the disease. Cancer Discov; 7(4); 369–79. ©2017 AACR. See related commentary by Yoshida and Weinstock, p. 352. This article is highlighted in the In This Issue feature, p. 339

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