BRAF inhibitor–associated ERK activation drives development of chronic lymphocytic leukemia
Niuscha Yaktapour, … , Tilman Brummer, Robert Zeiser
Niuscha Yaktapour, … , Tilman Brummer, Robert Zeiser
Published October 20, 2014
Citation Information: J Clin Invest. 2014;124(11):5074-5084. https://doi.org/10.1172/JCI76539.
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Research Article

BRAF inhibitor–associated ERK activation drives development of chronic lymphocytic leukemia

Abstract

Patients with BRAFV600E/K-driven melanoma respond to the BRAF inhibitor vemurafenib due to subsequent deactivation of the proliferative RAS/RAF/MEK/ERK pathway. In BRAF WT cells and those with mutations that activate or result in high levels of the BRAF activator RAS, BRAF inhibition can lead to ERK activation, resulting in tumorigenic transformation. We describe a patient with malignant melanoma who developed chronic lymphocytic leukemia (CLL) in the absence of RAS mutations during vemurafenib treatment. BRAF inhibition promoted patient CLL proliferation in culture and in murine xenografts and activated MEK/ERK in primary CLL cells from additional patients. BRAF inhibitor–driven ERK activity and CLL proliferation required B cell antigen receptor (BCR) activation, as inhibition of the BCR-proximal spleen tyrosine kinase (SYK) reversed ERK hyperactivation and proliferation of CLL cells from multiple patients, while inhibition of the BCR-distal Bruton tyrosine kinase had no effect. Additionally, the RAS-GTP/RAS ratio in primary CLL cells exposed to vemurafenib was reduced upon SYK inhibition. BRAF inhibition increased mortality and CLL expansion in mice harboring CLL xenografts; however, SYK or MEK inhibition prevented CLL proliferation and increased animal survival. Together, these results suggest that BRAF inhibitors promote B cell malignancies in the absence of obvious mutations in RAS or other receptor tyrosine kinases and provide a rationale for combined BRAF/MEK or BRAF/SYK inhibition.

Authors

Niuscha Yaktapour, Frank Meiss, Justin Mastroianni, Thorsten Zenz, Hana Andrlova, Nimitha R. Mathew, Rainer Claus, Barbara Hutter, Stefan Fröhling, Benedikt Brors, Dietmar Pfeifer, Milena Pantic, Ingrid Bartsch, Timo S. Spehl, Philipp T. Meyer, Justus Duyster, Katja Zirlik, Tilman Brummer, Robert Zeiser

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Figure 2

Impact of BRAF and MEK inhibitor treatment on signaling and survival of CLL cells.

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Impact of BRAF and MEK inhibitor treatment on signaling and survival of ...
Highly purified (>97%) CD19+CD5+ cells or CD14+ myeloid cells obtained from the patient were cultured in the presence of the BRAF inhibitors (vemurafenib, dabrafenib), the MEK inhibitor trametinib, BRAF inhibitor combined with MEK inhibitor, or DMSO only at the indicated concentrations. (A) OD as an indicator for viability and metabolic activity of CLL cells under different vemurafenib concentrations in an MTT assay. The experiment was performed twice using in dependent samples from the patient with similar results. Levels of pERK and tERK in the CLL cells (B) or CD14+ cells (C) derived from PBMC were measured by Western blot. We used vemurafenib, dabrafenib, and trametinib (0.07 μM) as indicated. One of 3 independent experiments with similar results is shown. (D) Western blot analysis for pERK and tERK of the protein lysate of highly purified (>97%) patient-derived CD19+CD5+ cells at the indicated concentrations of dabrafenib (Dab; 6 μM) and trametinib (MEK-i; 0.03, 0.07, 0.14 μM). Quantification of the protein amount of the described groups shown as a bar diagram. The experiment was performed 3 times with similar results. (E) The amount of CLL cells in the peripheral blood of Rag2–/–γC–/– mice relative to start of treatment with vehicle or vemurafenib (24 mg/kg/d). (F) The survival of the Rag2–/–γC–/– mice treated as described in panel E is shown (P = 0.0004). Data from 3 independent experiments were pooled.