Loss of epigenetic regulator TET2 and oncogenic KIT regulate myeloid cell transformation via PI3K pathway
Lakshmi Reddy Palam, Raghuveer Singh Mali, Baskar Ramdas, Sridhar Nonavinkere Srivatsan, Valeria Visconte, Ramon V. Tiu, Bart Vanhaesebroeck, Axel Roers, Alexander Gerbaulet, Mingjiang Xu, Sarath Chandra Janga, Clifford M. Takemoto, Sophie Paczesny, Reuben Kapur
Lakshmi Reddy Palam, Raghuveer Singh Mali, Baskar Ramdas, Sridhar Nonavinkere Srivatsan, Valeria Visconte, Ramon V. Tiu, Bart Vanhaesebroeck, Axel Roers, Alexander Gerbaulet, Mingjiang Xu, Sarath Chandra Janga, Clifford M. Takemoto, Sophie Paczesny, Reuben Kapur
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Research Article Hematology

Loss of epigenetic regulator TET2 and oncogenic KIT regulate myeloid cell transformation via PI3K pathway

Abstract

Mutations in KIT and TET2 are associated with myeloid malignancies. We show that loss of TET2-induced PI3K activation and -increased proliferation is rescued by targeting the p110α/δ subunits of PI3K. RNA-Seq revealed a hyperactive c-Myc signature in Tet2–/– cells, which is normalized by inhibiting PI3K signaling. Loss of TET2 impairs the maturation of myeloid lineage–derived mast cells by dysregulating the expression of Mitf and Cebpa, which is restored by low-dose ascorbic acid and 5-azacytidine. Utilizing a mouse model in which the loss of TET2 precedes the expression of oncogenic Kit, similar to the human disease, results in the development of a non–mast cell lineage neoplasm (AHNMD), which is responsive to PI3K inhibition. Thus, therapeutic approaches involving hypomethylating agents, ascorbic acid, and isoform-specific PI3K inhibitors are likely to be useful for treating patients with TET2 and KIT mutations.

Authors

Lakshmi Reddy Palam, Raghuveer Singh Mali, Baskar Ramdas, Sridhar Nonavinkere Srivatsan, Valeria Visconte, Ramon V. Tiu, Bart Vanhaesebroeck, Axel Roers, Alexander Gerbaulet, Mingjiang Xu, Sarath Chandra Janga, Clifford M. Takemoto, Sophie Paczesny, Reuben Kapur

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Figure 4

Deficiency of TET2 in BMMCs results in PI3K activation.

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Deficiency of TET2 in BMMCs results in PI3K activation. (A) AKT (ser473)...
(A) AKT (ser473), phosphorylated ERK1/2, and total ERK1/2 levels in WT and Tet2–/– BMMCs. Representative data from 3 independent experiments are shown. (B) Western blots for S6 kinase and phosphor S6 kinase protein levels in WT and Tet2–/– BMMCs are shown. Representative data from 3 independent experiments are shown. (C) Western blots for PTEN and β-actin protein levels in WT and Tet2–/– BMMCs are shown. Data from 2 experiments from a total 3 independent experiments are shown. Quantification of PTEN and β-actin protein band densities is shown. n = 3, mean ± SD, *P < 0.05. (D) Pten mRNA levels in WT and Tet2–/– BMMCs were measured using QRT-PCR. n = 3, *P < 0.05, mean ± SD. (E) WT and Tet2–/– BMMCs were treated with 0.5 μM 5-azacytidine for 24 hours and subjected to Western blot analysis. PTEN and β-actin protein levels are shown. (F) Bisulfite-converted genomic DNA from WT and Tet2–/– BMMCs was used for Pten promoter methylation analysis. Percentage methylation change in GC-rich Pten promoter region is shown. BMMCs from mice with indicated genotypes (G–I) were starved for 6 hours and cultured in the presence or absence of IL-3. After 48 hours, cell proliferation was evaluated by [3H] thymidine incorporation. Counts per minute (CPM) are shown. n = 3, mean ± SD,*P < 0.05. mRNA levels were assessed relative to β-actin mRNA by QRT-PCR assay (C and D). Unpaired, 2-tailed Student’s t test (C and D) and 1-way ANOVA (G–I) were used for statistical analysis.