BPDCN MYB Fusions Bind Cell Cycle Gene Promoters, Reactivate Self-Renewal in Progenitor Cells and Induce Myeloid/Dendritic Leukemia

Abstract

Blastic plasmacytoid dendritic cell neoplasm (BPDCN) is a rare acute leukemia with poor prognosis arising from the plasmacytoid dendritic cell (pDC) lineage. MYB is a hematopoietic transcription factor overexpressed in many leukemias. Genomic rearrangements of MYB were identified in a significant fraction of BPDCNs, including in cases without any other clear driver mutations, and result in its fusion to one of several partner genes (Suzuki et al., Leukemia 2017). These fusions are rare or absent in other acute leukemias and the mechanisms by which they contribute to BPDCN oncogenesis are not understood. To examine the impact of Myb fusions on hematopoietic differentiation and leukemogenesis, we used mouse bone marrow progenitors immortalized by estradiol (E2)-dependent activation of HoxB8 and culture with Flt3 ligand (HoxB8-FL cells). We used HoxB8-FL cells deficient in Cdkn2a, since CDKN2A deletion is present in up to ~67% of BPDCNs (Lucioni et al., Blood 2011) but is rare in other myeloid leukemias. HoxB8-FL cells differentiate into myeloid, lymphoid and dendritic cells in vitro upon withdrawal of E2, or in vivo upon transplantation. They therefore represent lymphoid-primed multipotent progenitor (LMPP)-like cells that are unable to self-renew in the absence of E2. We co-expressed a dTom reporter with V5-tagged Myb constructs in HoxB8-FL cells: wild-type full-length Myb (Myb-FL), truncated Myb (Myb-TR) or Myb-PLEKHO1. MYB-PLEKHO1 is the most frequent fusion in BPDCN patients, while truncated Myb is analogous to recurrent BPDCN MYB fusions in which the partner is out-of-frame. Empty vector was used as a control. HoxB8-FL cells expressing Myb-FL, Myb-TR or Myb-PLEKHO1 displayed arrested differentiation upon withdrawal of E2 in vitro (Figure 1). While all empty vector-transduced cells had upregulated CD11b and/or CD11c at day 7 post-E2 withdrawal, Myb overexpression caused an accumulation of CD11b-CD11c- undifferentiated cells. In vivo, a similar effect was observed at day 7 post-transplantation: dTom+ CD11b-CD11c-CD19-B220- undifferentiated cells were still present in the bone marrow of Myb-FL, Myb-TR and Myb-PLEKHO1 recipient mice, while in empty vector recipients all dTom+ cells expressed at least one of these differentiation markers. Surprisingly, we observed long-term persistence of dTom+ cells in the peripheral blood of Myb-TR and Myb-PLEKHO1, but not Myb-FL, recipients. This developed into lethal malignancy in 100% of Myb-TR and Myb-PLEKHO1 recipients by 28 weeks (Figure 2). Malignant cells showed blast-like morphology of acute leukemia and expressed markers of a myeloid/dendritic progenitor (Kit+CD11b+Cx3cr1+). dTom+ disease was never observed in Myb-FL or empty vector recipients (log-rank P<0.001). Together, while expression of either full-length Myb or Myb fusions impaired myeloid/dendritic differentiation, only Myb rearrangements associated with BPDCN generated a fully penetrant leukemia. To investigate chromatin-level differences between physiologically expressed wild-type MYB and MYB fusions, we performed Cut&Run in K562 cells with V5-tagged MYB-FL, MYB-TR or MYB-PLEKHO1 knocked in to the endogenous MYB locus using CRISPR/Cas9 and homology-directed repair. We observed increased binding of MYB-TR and MYB-PLEKHO1 relative to MYB-FL at promoters of cell cycle genes that function at the G2/M checkpoint, including CDC20, CDCA3 and CKS2. These binding sites contained canonical MYB binding motifs, indicating that MYB fusions increase direct DNA binding at chromatin involved in control of specific cell cycle genes. Cut&Run for V5-Myb-PLEKHO1 in mouse leukemias revealed similar direct DNA binding at cell cycle gene promoters. Moreover, expression of G2/M cell cycle genes was enriched in patient BPDCNs relative to normal pDCs. Our data suggest that BPDCN MYB fusions exert distinct oncogenic effects to overexpression of wild-type MYB. In addition to arresting differentiation, BPDCN MYB fusions can reactivate self-renewal in progenitor cells, which may occur through increased direct DNA binding at cell cycle gene promoters. This may explain the simple genetics of MYB-rearranged BPDCN, which lack other recurrent myeloid-type mutations, if the fusions are sufficient to generate leukemia via these dual roles. These data also indicate that therapeutic strategies targeting MYB and/or specific cell cycle checkpoints may be active in BPDCN. Figure 1View largeDownload PPTFigure 1View largeDownload PPT Close modal