MEF2C opposes Notch in lymphoid lineage decision and drives leukemia in the thymus
Kirsten Canté-Barrett, … , Steven Goossens, Jules P.P. Meijerink
Kirsten Canté-Barrett, … , Steven Goossens, Jules P.P. Meijerink
Published May 10, 2022
Citation Information: JCI Insight. 2022;7(13):e150363. https://doi.org/10.1172/jci.insight.150363.
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Research Article Hematology Oncology

MEF2C opposes Notch in lymphoid lineage decision and drives leukemia in the thymus

Abstract

Rearrangements that drive ectopic MEF2C expression have recurrently been found in patients with human early thymocyte progenitor acute lymphoblastic leukemia (ETP-ALL). Here, we show high levels of MEF2C expression in patients with ETP-ALL. Using both in vivo and in vitro models of ETP-ALL, we demonstrate that elevated MEF2C expression blocks NOTCH-induced T cell differentiation while promoting a B-lineage program. MEF2C activates a B cell transcriptional program in addition to RUNX1, GATA3, and LMO2; upregulates the IL-7R; and boosts cell survival by upregulation of BCL2. MEF2C and the Notch pathway, therefore, demarcate opposite regulators of B- or T-lineage choices, respectively. Enforced MEF2C expression in mouse or human progenitor cells effectively blocks early T cell differentiation and promotes the development of biphenotypic lymphoid tumors that coexpress CD3 and CD19, resembling human mixed phenotype acute leukemia. Salt-inducible kinase (SIK) inhibitors impair MEF2C activity and alleviate the T cell developmental block. Importantly, this sensitizes cells to prednisolone treatment. Therefore, SIK-inhibiting compounds such as dasatinib are potentially valuable additions to standard chemotherapy for human ETP-ALL.

Authors

Kirsten Canté-Barrett, Mariska T. Meijer, Valentina Cordo’, Rico Hagelaar, Wentao Yang, Jiyang Yu, Willem K. Smits, Marloes E. Nulle, Joris P. Jansen, Rob Pieters, Jun J. Yang, Jody J. Haigh, Steven Goossens, Jules P.P. Meijerink

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Figure 5

MEF2C blocks T cell development.

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MEF2C blocks T cell development. (A) MEF2C-eGFP transgenic mice: loxP-fl...
(A) MEF2C-eGFP transgenic mice: loxP-flanked stop cassette followed by MEF2C cDNA, IRES, and eGFP following exon 1 of the Rosa26 locus (top). Cre recombinase activity removes the stop cassette and activates expression of MEF2C and eGFP from the Rosa26 promoter (bottom). SA, splice acceptor site; arrows, genotyping primers. (B) Genotype of spleens of mice with WT or MEF2C-eGFP transgene (tg) alleles, in the absence or the presence of Lck-Cre. (C) Western blot of endogenous or induced MEF2C and α-tubulin protein levels in total thymocytes from mice of different genotypes. (D) Flow cytometry histograms of eGFP expression in lymph node or thymus cells from duplicate MEF2C-eGFP hetero- or homozygous mice with or without Lck-Cre as indicated by the gray, light green, and dark green histograms. (E) Absolute cell numbers (mean ± SD) for cells from MEF2C-eGFP control (no Cre, open circles) and MEF2C-eGFP/Lck-Cre mice (blue filled circles) at 10–16 and 20–34 weeks of age. Populations are CD4/CD8 DN, DP, CD4 SP, and CD8 SP. DN are also gated on lineage (CD3, B220, CD11b, Ly6G/C, Ter-119) cells to further divide the immature thymocyte populations into DN1-DN4. DN1, CD44+CD25; DN2, CD44+CD25+; DN3, CD44CD25+; DN4, CD44CD25. (F) Total CD45+ cell numbers (mean ± SD) as in E in the thymus (left panel) or inguinal lymph nodes (right panel). (G) Total CD19+ cell numbers (mean ± SD) as in E in the BM (left panel) or thymus (right panel). *P < 0.05, **P < 0.01 by Mann-Whitney U test.