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Pacritinib Effectively Inhibits Pro-Survival Signaling and Overcomes BTKCys481Ser-Mediated Resistance in MYD88-Mutated B-Cell Malignancies

Background: Somatic mutations in MYD88 are prevalent in various B-cell malignancies, including Waldenström Macroglobulinemia (WM; 95-97%), primary CNS lymphoma (70-80%), ABC DLBCL (40%), marginal zone lymphoma (5-10%), and CLL (5-15%). These mutations drive oncogenic pro-survival signaling through c...

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Published in:Blood 2024-11, Vol.144, p.5830-5830
Main Authors: Liu, Shirong, Kofides, Amanda, Liu, Xia, Sun, Hao, Canning, Alexa G, Tsakmaklis, Nickolas, Guerrera, Maria Luisa, Patterson, Christopher J, Hunter, Zachary R, Meid, Kirsten, Gokhale, Prafulla C., Hatcher, John M, Castillo, Jorge J., Sarosiek, Shayna R, Treon, Steven P.
Format: Article
Language:English
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Summary:Background: Somatic mutations in MYD88 are prevalent in various B-cell malignancies, including Waldenström Macroglobulinemia (WM; 95-97%), primary CNS lymphoma (70-80%), ABC DLBCL (40%), marginal zone lymphoma (5-10%), and CLL (5-15%). These mutations drive oncogenic pro-survival signaling through cascades involving HCK-directed BTK, ERK, SYK, and IRAK1/IRAK4 activation. HCK, an SRC family member, is transcriptionally upregulated by mutated MYD88 and activated via IL-6/IL-6R/gp130/JAK2 signaling. Although BTK-inhibitors are effective against MYD88-mutated B-cell malignancies, complete responses are rare and resistance often arises due to mutations in BTKCys481. Pacritinib, an FDA-approved kinase inhibitor for myelofibrosis, targets crucial signaling pathways associated with mutated MYD88, including IRAK1, JAK2, and SRC (a homolog of HCK), potentially offering a new therapeutic option for MYD88-mutated malignancies. Methods: We conducted comparative studies to evaluate the effects of pacritinib versus the covalent BTK-inhibitors ibrutinib and zanubrutinib on pro-survival signaling, proliferation, and survival in MYD88-mutated cell lines and primary MYD88-mutated WM cells. Additionally, we assessed pacritinib impact on BTKCys481Ser-expressing, covalent BTK-inhibitor-resistant WM and ABC DLBCL lymphoma cell models. Efficacy was also evaluated in a BTKCys481Ser TMD8 cell xenografted murine model. Results: Pacritinib induced higher levels of apoptosis in MYD88-mutated WM (BCWM.1) and ABC DLBCL (TMD8) cells, as well as in primary (CD19+) MYD88-mutated WM cells versus either ibrutinib or zanubrutinib. The apoptosis-inducing activity was dose-dependent, with significant apoptosis observed at 0.5 µM, which was well within pharmacologically achievable concentrations of pacritinib. Pacritinib suppressed JAK2 and IRAK1 activation and robustly inhibited p-HCK (Y411) and its downstream partner p-BTK (Y223) in MYD88-mutated BCWM.1 and TMD8 cells. Additionally, synergy in inhibiting cell growth was observed between pacritinib and covalent BTK inhibitors, and the BCL-2 inhibitor venetoclax in MYD88-mutated cell lines and primary WM cells. Pacritinib, alone or combined with venetoclax, induced high levels of apoptosis in BTKCys481Ser-expressing, BTK inhibitor-resistant MYD88-mutated WM and ABC DLBCL lymphoma cells. In a BTKCys481Ser TMD8 cell xenograft murine model, pacritinib treatment significantly suppressed tumor growth versus vehicle control or ibrutinib. Conclusions:
ISSN:0006-4971
DOI:10.1182/blood-2024-211285