Recombinant human CD19L-sTRAIL effectively targets B cell precursor acute lymphoblastic leukemia
Fatih M. Uckun, … , Osmond J. D’Cruz, Hong Ma
Fatih M. Uckun, … , Osmond J. D’Cruz, Hong Ma
Published January 26, 2015
Citation Information: J Clin Invest. 2015;125(3):1006-1018. https://doi.org/10.1172/JCI76610.
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Research Article Oncology

Recombinant human CD19L-sTRAIL effectively targets B cell precursor acute lymphoblastic leukemia

Abstract

Patients with B cell precursor acute lymphoblastic leukemia (BPL) respond well to chemotherapy at initial diagnosis; however, therapeutic options are limited for individuals with BPL who relapse. Almost all BPL cells express CD19, and we recently cloned the gene encoding a natural ligand of the human CD19 receptor (CD19L). We hypothesized that fusion of CD19L to the soluble extracellular domain of proapoptotic TNF-related apoptosis-inducing ligand (sTRAIL) would markedly enhance the potency of sTRAIL and specifically induce BPL cell apoptosis due to membrane anchoring of sTRAIL and simultaneous activation of the CD19 and TRAIL receptor (TRAIL-R) apoptosis signaling pathways. Here, we demonstrate that recombinant human CD19L-sTRAIL was substantially more potent than sTRAIL and induced apoptosis in primary leukemia cells taken directly from BPL patients. CD19L-sTRAIL effectively targeted and eliminated in vivo clonogenic BPL xenograft cells, even at femtomolar-picomolar concentrations. In mice, CD19L-sTRAIL exhibited a more favorable pharmacokinetic (PK) profile than sTRAIL and was nontoxic at doses ranging from 32 fmol/kg to 3.2 pmol/kg. CD19L-sTRAIL showed potent in vivo antileukemic activity in NOD/SCID mouse xenograft models of relapsed and chemotherapy-resistant BPL at nontoxic fmol/kg dose levels. Together, these results suggest that recombinant human CD19L-sTRAIL has clinical potential as a biotherapeutic agent against BPL.

Authors

Fatih M. Uckun, Dorothea E. Myers, Sanjive Qazi, Zahide Ozer, Rebecca Rose, Osmond J. D’Cruz, Hong Ma

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Figure 2

Recombinant CD19L-sTRAIL selectively binds to and kills leukemia cells in a CD19-dependent manner.

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Recombinant CD19L-sTRAIL selectively binds to and kills leukemia cells i...
(A) Two-color fluorescence dot plots showing the immunoreactivity of CD19L-sTRAIL-NHSF (10 pM) with CD19+ ALL-1 cells and its lack of binding to the CD19 HEK-293T negative control cell line. (B) Confocal microscopy images of ALL-1 cells stained with 10 pM NHSF-labeled CD19L-sTRAIL without blocking (upper panels) and with blocking (lower panels) using a 100-fold molar excess of a hIgG1-Fc fusion protein of CD19L (1 nM). (C) ALL-1 cells were treated for 48 hours at 37°C with 210 fM CD19L-sTRAIL (n = 4), 210 fM CD19L-sTRAIL plus 4.2 pM (n = 4) CD19ICD, or 210 fM CD19L-sTRAIL plus 4.2 pM (n = 4) CD19ECD. Depicted are bar graphs showing the mean ± SEM values for the percentage of apoptotic leukemia cells for each treatment group and P values for planned linear contrasts comparing CD19L-sTRAIL + CD19ECD versus each of the other treatments. *P < 0.001 vs. other treatments. (D) Depicted are Western blots documenting the TRAIL-R–linked death pathway activation in CD19L-sTRAIL–treated (abbreviated as CD19LsT) (2.1 pM) ALL-1 cells. Controls (CON) included Western blots using anti–α/β-actin and anti–α-tubulin antibodies. (E) Depicted are anticleaved PARP Western blots demonstrating the effects of the selective caspase 8 (CASP8) inhibitor Z-IETD-FMK (25 μM) and caspase 9 inhibitor Z-LEHD-FMK (20 μM) on TRAIL-R–linked death pathway activation in ALL-1 cells treated with 840 fM CD19L-sTRAIL for 2 hours. The inhibitors were added to the cultures 15 minutes prior to addition of CD19L-sTRAIL. Also shown is the anti–α-tubulin Western blot of the same samples.