Literature DB >> 29187379

Mutant JAK3 signaling is increased by loss of wild-type JAK3 or by acquisition of secondary JAK3 mutations in T-ALL.

Sandrine Degryse1,2, Simon Bornschein1,2, Charles E de Bock1,2, Emilie Leroy3,4, Marlies Vanden Bempt1,2, Sofie Demeyer1,2, Kris Jacobs1,2, Ellen Geerdens1,2, Olga Gielen1,2, Jean Soulier5, Christine J Harrison6, Stefan N Constantinescu3,4, Jan Cools1,2.   

Abstract

The Janus kinase 3 (JAK3) tyrosine kinase is mutated in 10% to 16% of T-cell acute lymphoblastic leukemia (T-ALL) cases. JAK3 mutants induce constitutive JAK/STAT signaling and cause leukemia when expressed in the bone marrow cells of mice. Surprisingly, we observed that one third of JAK3-mutant T-ALL cases harbor 2 JAK3 mutations, some of which are monoallelic and others that are biallelic. Our data suggest that wild-type JAK3 competes with mutant JAK3 (M511I) for binding to the common γ chain and thereby suppresses its oncogenic potential. We demonstrate that JAK3 (M511I) can increase its limited oncogenic potential through the acquisition of an additional mutation in the mutant JAK3 allele. These double JAK3 mutants show increased STAT5 activation and increased potential to transform primary mouse pro-T cells to interleukin-7-independent growth and were not affected by wild-type JAK3 expression. These data extend our insight into the oncogenic properties of JAK3 mutations and provide an explanation of why progression of JAK3-mutant T-ALL cases can be associated with the accumulation of additional JAK3 mutations.
© 2018 by The American Society of Hematology.

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Year:  2017        PMID: 29187379      PMCID: PMC5796683          DOI: 10.1182/blood-2017-07-797597

Source DB:  PubMed          Journal:  Blood        ISSN: 0006-4971            Impact factor:   22.113


  22 in total

1.  Recurrent JAK1 and JAK3 somatic mutations in T-cell prolymphocytic leukemia.

Authors:  D Bellanger; V Jacquemin; M Chopin; G Pierron; O A Bernard; J Ghysdael; M-H Stern
Journal:  Leukemia       Date:  2013-09-19       Impact factor: 11.528

2.  Structure of the pseudokinase-kinase domains from protein kinase TYK2 reveals a mechanism for Janus kinase (JAK) autoinhibition.

Authors:  Patrick J Lupardus; Mark Ultsch; Heidi Wallweber; Pawan Bir Kohli; Adam R Johnson; Charles Eigenbrot
Journal:  Proc Natl Acad Sci U S A       Date:  2014-05-19       Impact factor: 11.205

3.  Mutation of the receptor tyrosine phosphatase PTPRC (CD45) in T-cell acute lymphoblastic leukemia.

Authors:  Michaël Porcu; Maria Kleppe; Valentina Gianfelici; Ellen Geerdens; Kim De Keersmaecker; Marco Tartaglia; Robin Foà; Jean Soulier; Barbara Cauwelier; Anne Uyttebroeck; Elizabeth Macintyre; Peter Vandenberghe; Vahid Asnafi; Jan Cools
Journal:  Blood       Date:  2012-03-21       Impact factor: 22.113

4.  PTPN2 negatively regulates oncogenic JAK1 in T-cell acute lymphoblastic leukemia.

Authors:  Maria Kleppe; Jean Soulier; Vahid Asnafi; Nicole Mentens; Tekla Hornakova; Laurent Knoops; Stefan Constantinescu; François Sigaux; Jules P Meijerink; Peter Vandenberghe; Marco Tartaglia; Robin Foa; Elizabeth Macintyre; Torsten Haferlach; Jan Cools
Journal:  Blood       Date:  2011-05-06       Impact factor: 22.113

5.  Distinct Acute Lymphoblastic Leukemia (ALL)-associated Janus Kinase 3 (JAK3) Mutants Exhibit Different Cytokine-Receptor Requirements and JAK Inhibitor Specificities.

Authors:  Elisabeth Losdyck; Tekla Hornakova; Lorraine Springuel; Sandrine Degryse; Olga Gielen; Jan Cools; Stefan N Constantinescu; Elisabetta Flex; Marco Tartaglia; Jean-Christophe Renauld; Laurent Knoops
Journal:  J Biol Chem       Date:  2015-10-07       Impact factor: 5.157

6.  JAK3 mutants transform hematopoietic cells through JAK1 activation, causing T-cell acute lymphoblastic leukemia in a mouse model.

Authors:  Sandrine Degryse; Charles E de Bock; Luk Cox; Sofie Demeyer; Olga Gielen; Nicole Mentens; Kris Jacobs; Ellen Geerdens; Valentina Gianfelici; Gert Hulselmans; Mark Fiers; Stein Aerts; Jules P Meijerink; Thomas Tousseyn; Jan Cools
Journal:  Blood       Date:  2014-09-05       Impact factor: 22.113

7.  Recurrent SPI1 (PU.1) fusions in high-risk pediatric T cell acute lymphoblastic leukemia.

Authors:  Masafumi Seki; Shunsuke Kimura; Tomoya Isobe; Kenichi Yoshida; Hiroo Ueno; Yaeko Nakajima-Takagi; Changshan Wang; Lin Lin; Ayana Kon; Hiromichi Suzuki; Yusuke Shiozawa; Keisuke Kataoka; Yoichi Fujii; Yuichi Shiraishi; Kenichi Chiba; Hiroko Tanaka; Teppei Shimamura; Kyoko Masuda; Hiroshi Kawamoto; Kentaro Ohki; Motohiro Kato; Yuki Arakawa; Katsuyoshi Koh; Ryoji Hanada; Hiroshi Moritake; Masaharu Akiyama; Ryoji Kobayashi; Takao Deguchi; Yoshiko Hashii; Toshihiko Imamura; Atsushi Sato; Nobutaka Kiyokawa; Akira Oka; Yasuhide Hayashi; Masatoshi Takagi; Atsushi Manabe; Akira Ohara; Keizo Horibe; Masashi Sanada; Atsushi Iwama; Hiroyuki Mano; Satoru Miyano; Seishi Ogawa; Junko Takita
Journal:  Nat Genet       Date:  2017-07-03       Impact factor: 38.330

Review 8.  The genetics and molecular biology of T-ALL.

Authors:  Tiziana Girardi; Carmen Vicente; Jan Cools; Kim De Keersmaecker
Journal:  Blood       Date:  2017-01-23       Impact factor: 22.113

9.  IL-7 Receptor Mutations and Steroid Resistance in Pediatric T cell Acute Lymphoblastic Leukemia: A Genome Sequencing Study.

Authors:  Yunlei Li; Jessica G C A M Buijs-Gladdines; Kirsten Canté-Barrett; Andrew P Stubbs; Eric M Vroegindeweij; Willem K Smits; Ronald van Marion; Winand N M Dinjens; Martin Horstmann; Roland P Kuiper; Rogier C Buijsman; Guido J R Zaman; Peter J van der Spek; Rob Pieters; Jules P P Meijerink
Journal:  PLoS Med       Date:  2016-12-20       Impact factor: 11.069

10.  Comprehensive analysis of transcriptome variation uncovers known and novel driver events in T-cell acute lymphoblastic leukemia.

Authors:  Zeynep Kalender Atak; Valentina Gianfelici; Gert Hulselmans; Kim De Keersmaecker; Arun George Devasia; Ellen Geerdens; Nicole Mentens; Sabina Chiaretti; Kaat Durinck; Anne Uyttebroeck; Peter Vandenberghe; Iwona Wlodarska; Jacqueline Cloos; Robin Foà; Frank Speleman; Jan Cools; Stein Aerts
Journal:  PLoS Genet       Date:  2013-12-19       Impact factor: 5.917
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  16 in total

Review 1.  Can one target T-cell ALL?

Authors:  Adolfo Ferrando
Journal:  Best Pract Res Clin Haematol       Date:  2018-10-17       Impact factor: 3.020

2.  Partial trisomy 21 contributes to T-cell malignancies induced by JAK3-activating mutations in murine models.

Authors:  Paola Rivera-Munoz; Anouchka P Laurent; Aurelie Siret; Cecile K Lopez; Cathy Ignacimouttou; Melanie G Cornejo; Olivia Bawa; Philippe Rameau; Olivier A Bernard; Philippe Dessen; Gary D Gilliland; Thomas Mercher; Sébastien Malinge
Journal:  Blood Adv       Date:  2018-07-10

3.  Suz12 inactivation cooperates with JAK3 mutant signaling in the development of T-cell acute lymphoblastic leukemia.

Authors:  Michael Broux; Cristina Prieto; Sofie Demeyer; Marlies Vanden Bempt; Llucia Alberti-Servera; Inge Lodewijckx; Roel Vandepoel; Nicole Mentens; Olga Gielen; Kris Jacobs; Ellen Geerdens; Carmen Vicente; Charles E de Bock; Jan Cools
Journal:  Blood       Date:  2019-10-17       Impact factor: 22.113

Review 4.  The Genetics and Mechanisms of T-Cell Acute Lymphoblastic Leukemia.

Authors:  Francesca Gianni; Laura Belver; Adolfo Ferrando
Journal:  Cold Spring Harb Perspect Med       Date:  2020-03-02       Impact factor: 6.915

5.  A Targeted Quantitative Proteomic Method Revealed a Substantial Reprogramming of Kinome during Melanoma Metastasis.

Authors:  Weili Miao; Lin Li; Xiaochuan Liu; Tianyu F Qi; Lei Guo; Ming Huang; Yinsheng Wang
Journal:  Sci Rep       Date:  2020-02-12       Impact factor: 4.379

6.  [Prognostic analysis of patients with mutations in the JAK/STAT signaling pathway in adult acute lymphoblastic leukemia].

Authors:  W J Fan; T T Xu; J J Guo; Y F Li; Z X Jiang
Journal:  Zhonghua Xue Ye Xue Za Zhi       Date:  2021-07-14

Review 7.  The Emerging Role of Suppressors of Cytokine Signaling (SOCS) in the Development and Progression of Leukemia.

Authors:  Esra'a Keewan; Ksenia Matlawska-Wasowska
Journal:  Cancers (Basel)       Date:  2021-08-08       Impact factor: 6.639

8.  Failure of tofacitinib to achieve an objective response in a DDX3X-MLLT10 T-lymphoblastic leukemia with activating JAK3 mutations.

Authors:  Jonathan Wong; Meaghan Wall; Gregory Philip Corboy; Nadine Taubenheim; Gareth Peter Gregory; Stephen Opat; Jake Shortt
Journal:  Cold Spring Harb Mol Case Stud       Date:  2020-08-25

Review 9.  Deregulation of the Interleukin-7 Signaling Pathway in Lymphoid Malignancies.

Authors:  Inge Lodewijckx; Jan Cools
Journal:  Pharmaceuticals (Basel)       Date:  2021-05-08

10.  Overexpression of wild-type IL-7Rα promotes T-cell acute lymphoblastic leukemia/lymphoma.

Authors:  Ana Silva; Afonso R M Almeida; Ana Cachucho; João L Neto; Sofie Demeyer; Mafalda de Matos; Thea Hogan; Yunlei Li; Jules Meijerink; Jan Cools; Ana Rita Grosso; Benedict Seddon; João T Barata
Journal:  Blood       Date:  2021-09-23       Impact factor: 22.113
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