• Precise engineering of the ETO2::GLIS2 fusion in iPSC reproduces leukemogenesis in a developmentally-relevant human cell context

  • The temporal orchestration of chromatin changes by ETO2::GLIS2 reveals hijacking of the essential osteoblastic homeobox DLX3 factor

Pediatric acute myeloid leukemia frequently harbor fusion oncogenes associated with poor prognosis, including KMT2A, NUP98 and GLIS2 rearrangements. While murine models have demonstrated their leukemogenic activities, the steps from a normal human cell to leukemic blasts remain unclear. Here, we precisely reproduced the inversion of chromosome 16 resulting in ETO2::GLIS2 fusion in human induced pluripotent stem cells (iPSC). IPSC-derived ETO2::GLIS2-expressing hematopoietic cells showed differentiation alterations in vitro and efficiently induced in vivo development of leukemia that closely phenocopied human acute megakaryoblastic leukemia (AMKL) reflected by flow cytometry and single cell transcriptomes. Comparison of iPS-derived cells with patient-derived cells revealed altered chromatin accessibility at early and later bona fide leukemia stages with aberrantly higher accessibility and expression of the osteogenic homeobox factor DLX3 that preceded increased accessibility to ETS factors. DLX3 overexpression in normal CD34+ cells increased accessibility to ETS motifs and reduced accessibility to GATA motifs. A DLX3 transcriptional module was globally enriched in both ETO2::GLIS2 AMKL and some aggressive pediatric osteosarcoma. Importantly, DLX3 knock-out abrogated leukemia initiation in this ETO2::GLIS2 iPSC model. Collectively, characterization of a novel human iPSC-derived AMKL model revealed hijacking of the osteogenic homeobox transcription factor DLX3 as an essential early step in chromatin changes and leukemogenesis driven by the ETO2::GLIS2 fusion oncogene.

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