Literature DB >> 25572172

JAK-STAT pathway activation in malignant and nonmalignant cells contributes to MPN pathogenesis and therapeutic response.

Maria Kleppe1, Minsuk Kwak2, Priya Koppikar1, Markus Riester3, Matthew Keller1, Lennart Bastian1, Todd Hricik1, Neha Bhagwat4, Anna Sophia McKenney5, Efthymia Papalexi1, Omar Abdel-Wahab6, Raajit Rampal6, Sachie Marubayashi1, Jonathan J Chen2, Vincent Romanet7, Jordan S Fridman8, Jacqueline Bromberg9, Julie Teruya-Feldstein10, Masato Murakami7, Thomas Radimerski7, Franziska Michor3, Rong Fan11, Ross L Levine12.   

Abstract

UNLABELLED: The identification of JAK2/MPL mutations in patients with myeloproliferative neoplasms (MPN) has led to the clinical development of JAK kinase inhibitors, including ruxolitinib. Ruxolitinib reduces splenomegaly and systemic symptoms in myelofibrosis and improves overall survival; however, the mechanism by which JAK inhibitors achieve efficacy has not been delineated. Patients with MPN present with increased levels of circulating proinflammatory cytokines, which are mitigated by JAK inhibitor therapy. We sought to elucidate mechanisms by which JAK inhibitors attenuate cytokine-mediated pathophysiology. Single-cell profiling demonstrated that hematopoietic cells from myelofibrosis models and patient samples aberrantly secrete inflammatory cytokines. Pan-hematopoietic Stat3 deletion reduced disease severity and attenuated cytokine secretion, with similar efficacy as observed with ruxolitinib therapy. In contrast, Stat3 deletion restricted to MPN cells did not reduce disease severity or cytokine production. Consistent with these observations, we found that malignant and nonmalignant cells aberrantly secrete cytokines and JAK inhibition reduces cytokine production from both populations. SIGNIFICANCE: Our results demonstrate that JAK-STAT3-mediated cytokine production from malignant and nonmalignant cells contributes to MPN pathogenesis and that JAK inhibition in both populations is required for therapeutic efficacy. These findings provide novel insight into the mechanisms by which JAK kinase inhibition achieves therapeutic efficacy in MPNs. ©2015 American Association for Cancer Research.

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Year:  2015        PMID: 25572172      PMCID: PMC4355105          DOI: 10.1158/2159-8290.CD-14-0736

Source DB:  PubMed          Journal:  Cancer Discov        ISSN: 2159-8274            Impact factor:   39.397


  34 in total

Review 1.  Molecular aspects of myeloproliferative neoplasms.

Authors:  François Delhommeau; Dorota Jeziorowska; Christophe Marzac; Nicole Casadevall
Journal:  Int J Hematol       Date:  2010-02-27       Impact factor: 2.490

2.  Conversion of danger signals into cytokine signals by hematopoietic stem and progenitor cells for regulation of stress-induced hematopoiesis.

Authors:  Jimmy L Zhao; Chao Ma; Ryan M O'Connell; Arnav Mehta; Race DiLoreto; James R Heath; David Baltimore
Journal:  Cell Stem Cell       Date:  2014-02-20       Impact factor: 24.633

3.  Neuropathy of haematopoietic stem cell niche is essential for myeloproliferative neoplasms.

Authors:  Lorena Arranz; Abel Sánchez-Aguilera; Daniel Martín-Pérez; Joan Isern; Xavier Langa; Alexandar Tzankov; Pontus Lundberg; Sandra Muntión; Yi-Shiuan Tzeng; Dar-Ming Lai; Jürg Schwaller; Radek C Skoda; Simón Méndez-Ferrer
Journal:  Nature       Date:  2014-06-22       Impact factor: 49.962

4.  Myeloproliferative neoplasia remodels the endosteal bone marrow niche into a self-reinforcing leukemic niche.

Authors:  Koen Schepers; Eric M Pietras; Damien Reynaud; Johanna Flach; Mikhail Binnewies; Trit Garg; Amy J Wagers; Edward C Hsiao; Emmanuelle Passegué
Journal:  Cell Stem Cell       Date:  2013-07-11       Impact factor: 24.633

5.  Safety and efficacy of INCB018424, a JAK1 and JAK2 inhibitor, in myelofibrosis.

Authors:  Srdan Verstovsek; Hagop Kantarjian; Ruben A Mesa; Animesh D Pardanani; Jorge Cortes-Franco; Deborah A Thomas; Zeev Estrov; Jordan S Fridman; Edward C Bradley; Susan Erickson-Viitanen; Kris Vaddi; Richard Levy; Ayalew Tefferi
Journal:  N Engl J Med       Date:  2010-09-16       Impact factor: 91.245

6.  Preclinical characterization of the selective JAK1/2 inhibitor INCB018424: therapeutic implications for the treatment of myeloproliferative neoplasms.

Authors:  Alfonso Quintás-Cardama; Kris Vaddi; Phillip Liu; Taghi Manshouri; Jun Li; Peggy A Scherle; Eian Caulder; Xiaoming Wen; Yanlong Li; Paul Waeltz; Mark Rupar; Timothy Burn; Yvonne Lo; Jennifer Kelley; Maryanne Covington; Stacey Shepard; James D Rodgers; Patrick Haley; Hagop Kantarjian; Jordan S Fridman; Srdan Verstovsek
Journal:  Blood       Date:  2010-02-03       Impact factor: 22.113

7.  Somatic mutations of calreticulin in myeloproliferative neoplasms.

Authors:  Thorsten Klampfl; Heinz Gisslinger; Ashot S Harutyunyan; Harini Nivarthi; Elisa Rumi; Jelena D Milosevic; Nicole C C Them; Tiina Berg; Bettina Gisslinger; Daniela Pietra; Doris Chen; Gregory I Vladimer; Klaudia Bagienski; Chiara Milanesi; Ilaria Carola Casetti; Emanuela Sant'Antonio; Virginia Ferretti; Chiara Elena; Fiorella Schischlik; Ciara Cleary; Melanie Six; Martin Schalling; Andreas Schönegger; Christoph Bock; Luca Malcovati; Cristiana Pascutto; Giulio Superti-Furga; Mario Cazzola; Robert Kralovics
Journal:  N Engl J Med       Date:  2013-12-10       Impact factor: 91.245

8.  Acute myelogenous leukemia-induced sympathetic neuropathy promotes malignancy in an altered hematopoietic stem cell niche.

Authors:  Maher Hanoun; Dachuan Zhang; Toshihide Mizoguchi; Sandra Pinho; Halley Pierce; Yuya Kunisaki; Julie Lacombe; Scott A Armstrong; Ulrich Dührsen; Paul S Frenette
Journal:  Cell Stem Cell       Date:  2014-07-10       Impact factor: 24.633

9.  Physiological Jak2V617F expression causes a lethal myeloproliferative neoplasm with differential effects on hematopoietic stem and progenitor cells.

Authors:  Ann Mullally; Steven W Lane; Brian Ball; Christine Megerdichian; Rachel Okabe; Fatima Al-Shahrour; Mahnaz Paktinat; J Erika Haydu; Elizabeth Housman; Allegra M Lord; Gerlinde Wernig; Michael G Kharas; Thomas Mercher; Jeffery L Kutok; D Gary Gilliland; Benjamin L Ebert
Journal:  Cancer Cell       Date:  2010-06-15       Impact factor: 31.743

10.  Somatic CALR mutations in myeloproliferative neoplasms with nonmutated JAK2.

Authors:  J Nangalia; C E Massie; E J Baxter; F L Nice; G Gundem; D C Wedge; E Avezov; J Li; K Kollmann; D G Kent; A Aziz; A L Godfrey; J Hinton; I Martincorena; P Van Loo; A V Jones; P Guglielmelli; P Tarpey; H P Harding; J D Fitzpatrick; C T Goudie; C A Ortmann; S J Loughran; K Raine; D R Jones; A P Butler; J W Teague; S O'Meara; S McLaren; M Bianchi; Y Silber; D Dimitropoulou; D Bloxham; L Mudie; M Maddison; B Robinson; C Keohane; C Maclean; K Hill; K Orchard; S Tauro; M-Q Du; M Greaves; D Bowen; B J P Huntly; C N Harrison; N C P Cross; D Ron; A M Vannucchi; E Papaemmanuil; P J Campbell; A R Green
Journal:  N Engl J Med       Date:  2013-12-10       Impact factor: 91.245
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  139 in total

Review 1.  A hostel for the hostile: the bone marrow niche in hematologic neoplasms.

Authors:  Daniela S Krause; David T Scadden
Journal:  Haematologica       Date:  2015-11       Impact factor: 9.941

2.  Targeting a regulator of protein homeostasis in myeloproliferative neoplasms.

Authors:  Lindsay M LaFave; Ross L Levine
Journal:  Nat Med       Date:  2016-01       Impact factor: 53.440

3.  Recombinant interferon-α in myelofibrosis reduces bone marrow fibrosis, improves its morphology and is associated with clinical response.

Authors:  Marco Pizzi; Richard T Silver; Ariella Barel; Attilio Orazi
Journal:  Mod Pathol       Date:  2015-08-14       Impact factor: 7.842

Review 4.  Novel and combination therapies for polycythemia vera and essential thrombocythemia: the dawn of a new era.

Authors:  Jan Philipp Bewersdorf; Amer M Zeidan
Journal:  Expert Rev Hematol       Date:  2020-11-01       Impact factor: 2.929

Review 5.  The Rationale for Immunotherapy in Myeloproliferative Neoplasms.

Authors:  Lucia Masarova; Prithviraj Bose; Srdan Verstovsek
Journal:  Curr Hematol Malig Rep       Date:  2019-08       Impact factor: 3.952

Review 6.  Thrombosis in Philadelphia negative classical myeloproliferative neoplasms: a narrative review on epidemiology, risk assessment, and pathophysiologic mechanisms.

Authors:  Somedeb Ball; Kyaw Zin Thein; Abhishek Maiti; Kenneth Nugent
Journal:  J Thromb Thrombolysis       Date:  2018-05       Impact factor: 2.300

7.  Bone marrow-specific loss of ABI1 induces myeloproliferative neoplasm with features resembling human myelofibrosis.

Authors:  Anna Chorzalska; John Morgan; Nagib Ahsan; Diana O Treaba; Adam J Olszewski; Max Petersen; Nathan Kingston; Yan Cheng; Kara Lombardo; Christoph Schorl; Xiaoqing Yu; Roberta Zini; Annalisa Pacilli; Alexander Tepper; Jillian Coburn; Anita Hryniewicz-Jankowska; Ting C Zhao; Elena Oancea; John L Reagan; Olin Liang; Leszek Kotula; Peter J Quesenberry; Philip A Gruppuso; Rossella Manfredini; Alessandro Maria Vannucchi; Patrycja M Dubielecka
Journal:  Blood       Date:  2018-09-13       Impact factor: 22.113

8.  Targeting nuclear β-catenin as therapy for post-myeloproliferative neoplasm secondary AML.

Authors:  Dyana T Saenz; Warren Fiskus; Taghi Manshouri; Christopher P Mill; Yimin Qian; Kanak Raina; Kimal Rajapakshe; Cristian Coarfa; Raffaella Soldi; Prithviraj Bose; Gautam Borthakur; Tapan M Kadia; Joseph D Khoury; Lucia Masarova; Agnieszka J Nowak; Baohua Sun; David N Saenz; Steven M Kornblau; Steve Horrigan; Sunil Sharma; Peng Qiu; Craig M Crews; Srdan Verstovsek; Kapil N Bhalla
Journal:  Leukemia       Date:  2018-12-21       Impact factor: 11.528

Review 9.  Kinase signaling and targeted therapy for primary myelofibrosis.

Authors:  Qiong Yang; John D Crispino; Qiang Jeremy Wen
Journal:  Exp Hematol       Date:  2016-12-30       Impact factor: 3.084

10.  Defective negative regulation of Toll-like receptor signaling leads to excessive TNF-α in myeloproliferative neoplasm.

Authors:  Hew Yeng Lai; Stefan A Brooks; Brianna M Craver; Sarah J Morse; Thanh Kim Nguyen; Nahideh Haghighi; Michael R Garbati; Angela G Fleischman
Journal:  Blood Adv       Date:  2019-01-22
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