Functional Apoptosis Profiling Reveals Vulnerabilities in T-cell Large Granular Lymphocytic Leukemia

Overview

Journal Ann Hematol

Date 2025 Feb 6

PMID 39912943

Authors

Evgenii Shumilov

Paolo Mazzeo

Marcel Trautmann

Lena Levien

Kerstin Menck

Katharina Richter

Katharina Markus

Lena Ries

Detlef Haase

Elena Oberle

Philipp Berning

Wolfgang Hartmann

Philipp Strobel

Andrea Kerkhoff

Georg Lenz

Gerald Wulf

Raphael Koch

Affiliations

Soon will be listed here.

Abstract

T-cell large granular lymphocytic leukemia (T-LGLL) is a rare hematologic neoplasm characterized by clonal expansion of CD3 + cytotoxic T lymphocytes and a highly heterogeneous clinical course. Conventional therapy primarily includes immunosuppressive regimen. However, optimal front-line approaches still need to be defined and refractory disease remains a clinical challenge. Thus, we here aimed to explore functional dependencies of T-LGLL as a basis for personalized therapeutic strategies. We performed functional apoptosis profiling and ex vivo drug treatment in a series of 8 clinically and genetically characterized T-LGLL patients from two German University hospitals. Our series of patients underscored the clinical and genetic heterogeneity of the disease. Genetically, only 2 patients harbored a STAT3 mutation. To identify targetable anti-apoptotic mechanisms, we performed selective functional BH3 profiling on the patients' CD8 + T-cells harboring the malignant T-LGLL cells versus the same patients' normal CD4 + T-cells. CD8 + cells in 50% of the patients (4/8) demonstrated a dominant functional dependence on MCL-1 as compared to the same patients' normal T-cells. Accordingly, CD8 + T-LGLL cells from patients with enhanced MCL1 dependence significantly responded to AZD-5991 ex vivo while no response was observed in the remaining samples lacking enhanced MCL-1 dependence. Across clinically and genetically heterogeneous cases of T-LGLL, functional apoptosis profiling identified patients with CD8 + T-LGLL cells harboring a dominant dependence on MCL-1 as a potential therapeutic target.

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