Pharmacoproteomics identifies combinatorial therapy targets for diffuse large B cell lymphoma
Rebecca L. Goldstein, … , Leandro Cerchietti, Ari Melnick
Rebecca L. Goldstein, … , Leandro Cerchietti, Ari Melnick
Published November 3, 2015
Citation Information: J Clin Invest. 2015;125(12):4559-4571. https://doi.org/10.1172/JCI80714.
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Research Article Oncology

Pharmacoproteomics identifies combinatorial therapy targets for diffuse large B cell lymphoma

Abstract

Rationally designed combinations of targeted therapies for refractory cancers, such as activated B cell–like diffuse large B cell lymphoma (ABC DLBCL), are likely required to achieve potent, durable responses. Here, we used a pharmacoproteomics approach to map the interactome of a tumor-enriched isoform of HSP90 (teHSP90). Specifically, we chemically precipitated teHSP90-client complexes from DLBCL cell lines with the small molecule PU-H71 and found that components of the proximal B cell receptor (BCR) signalosome were enriched within teHSP90 complexes. Functional assays revealed that teHSP90 facilitates BCR signaling dynamics by enabling phosphorylation of key BCR signalosome components, including the kinases SYK and BTK. Consequently, treatment of BCR-dependent ABC DLBCL cells with PU-H71 attenuated BCR signaling, calcium flux, and NF-κB signaling, ultimately leading to growth arrest. Combined exposure of ABC DLBCL cell lines to PU-H71 and ibrutinib, a BCR pathway inhibitor, more potently suppressed BCR signaling than either drug alone. Correspondingly, PU-H71 combined with ibrutinib induced synergistic killing of lymphoma cell lines, primary human lymphoma specimens ex vivo, and lymphoma xenografts in vivo, without notable toxicity. Together, our results demonstrate that a pharmacoproteome-driven rational combination therapy has potential to provide more potent BCR-directed therapy for ABC DLCBL patients.

Authors

Rebecca L. Goldstein, Shao Ning Yang, Tony Taldone, Betty Chang, John Gerecitano, Kojo Elenitoba-Johnson, Rita Shaknovich, Wayne Tam, John P. Leonard, Gabriela Chiosis, Leandro Cerchietti, Ari Melnick

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Figure 6

PU-H71 potentiates response to ibrutinib in ABC DLBCL in vivo.

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PU-H71 potentiates response to ibrutinib in ABC DLBCL in vivo. (A) NOD-S...
(A) NOD-SCID mice were s.c. injected with 106 HBL-1 or TMD8 cells. When tumors were palpable, daily treatment began. (B and C) Tumor growth plots of TMD8 (B) and HBL-1 (C) xenografted mice treated with vehicle (saline), ibrutinib (Ibr; 12.5 mg/kg in chow, ad libidum), PU-H71 (PU; 75 mg/kg i.p. injection) or the combination (purple triangles). Right panels: Growth of each tumor was measured as area under the curve. Average tumor growth is represented on the y axis, which represents tumor volume (mm3)/time (days). Mean ± SEM, Mann-Whitney U test. (D) NOD-SCID mice were xenografted and treated as described above for 24 hours. (E) Lysates of tumors harvested from experiments in D were subjected to immunoblot with indicated antibodies. Relative abundance of phospho-BTK to total BTK was quantified using densitometry. Mean ± SD, unpaired t test. (F) Human non–GCB DLBCL patient samples cultured on an irradiated HK cell feeder layer were exposed to control, ibrutinib (2 nM every 24 hours), PU-H71 (1 μM), or the combination for 48 hours. Cell viability (represented as percentage of vehicle-treated cells) measured using flow cytometry is plotted on the y axis. Live cells are defined as CD20+/CD3 cells that are Annexin V/DAPI double negative. Sample 6128 was tested in 2 biological replicates, unpaired t test. Other samples were tested in 2 technical replicates. Data are presented as mean ± SEM. *P < 0.05; **P < 0.01; ***P < 0.0005.