Project description:Leukaemogenic mutations commonly disrupt cellular differentiation and/or enhance proliferation, thus perturbing the regulatory programs that control self-renewal and differentiation of stem and progenitor cells. Translocations involving the Mll1 (Kmt2a) gene generate powerful oncogenic fusion proteins, predominantly affecting infant and paediatric AML and ALL patients. The early stages of leukaemogenic transformation are typically inaccessible from human patients and conventional mouse models. Here, we took advantage of cells conditionally blocked at the multipotent haematopoietic progenitor stage to develop a new MLL-r model capturing the early cellular and molecular consequences of MLL-ENL expression based on a clear clonal relationship between the parental and leukaemic cells. Through a combination of scRNA-seq, ATAC-seq and genome-scale CRISPR-Cas9 screening, we identified pathways and genes likely to drive the early phases of leukaemogenesis. Finally, we demonstrated the broad utility of using matched parental and transformed cells for small molecule inhibitor studies by validating both known and new potential therapeutic targets.

Project description:As MLL-rearranged infant leukaemia is known to initiate in utero, we sought to identify developemntal genes expressed in foetal cells that may aid leukaemogenesis. Bulk RNA-Seq was therefore carried out on mouse and human foetal liver blood progenitors (lymphoid-primed multipotent progenitors [LMPPs] and haematopoietic stem cells/ multipotent progenitor cells [HSC/MPPs]) and compared with the same cell types isolated from developmentally later human cord blood and mouse adult bone marrow.

Project description:Malignant transformation in a multipotential precursor has recently been shown to underlie mixed phenotype acute leukaemias. In contrast, and despite the conclusive demonstration that MLL-AF4 infant ALL arises in utero. In order to address this we purified haematopoietic stem/progenitor cell (HSPC) populations from four non-lineage switching presentation infant ALL cases and one ALL presentation which went on to lineage switch at relapse. The specific MLL-AF4 fusion event was determined in unsorted samples by LDI-PCR and identified in purified populations by nested PCR. In three cases where non-lineage restricted populations were able to be purified, MLL-AF4 was identified in the CD34+CD38-CD45RA+ population (LK228, LK230, LS01), the CD34+CD38-CD45RA-CD90- multipotential progenitor population (MPP, LS01) and even a candidate CD34+CD38-CD45RA-CD90+ haematopoietic stem cell (HSC) population (LK228) Interestingly, in a single non-switched MLL-AF9 case analysed for external comparison, the fusion was only identified in CD19+ blast/B cell populations, not in any HSPC population. Unexpectedly, we were also able to identify the presence of the MLL-AF4 fusion in apparently normally differentiated CD34-CD19/3-HLA-DR+CD14/11c+ monocytes/dendritic cells from the peripheral blood/bone marrow of 4/5 cases examined. This finding was further supported by single cell analysis of LS01PALL which identified the fusion in 2/22 CD34-CD19/3-HLA-DR+CD14/11c+ monocytes/dendritic cells analysed. Furthermore, the matched AML sample (LS01RAML) also contained MLL-AF4 positive mature T lymphoid cells. These data imply that MLL-AF4 does not impose a complete block on normal haematopoietic differentiation, and raise the question of what additional factors contribute to leukaemic lineage determination in the setting of the MLL-AF4 translocation. To examine the functional capacity of MLL-AF4 transformed precursor cells we generated a patient-derived xenograft model using NOD-scid/IL2Rγ-/- (NSG) mice. Serial xenotransplantation identified an MLL-AF4 positive clone persisting within the human CD34+CD38-CD45RA-CD90+ compartment across four generations of mice, confirming self-renewal of this population. Together these data identify an early multipotent progenitor or HSC as the putative cell of origin for MLL-AF4 ALL. Furthermore, they demonstrate that MLL-AF4, uniquely amongst MLL fusion genes, imposes a profound lymphoid bias on the developing leukemia but without completely abolishing broader, non-malignant, haematopoietic differentiation.

Project description:Malignant transformation in a multipotential precursor has recently been shown to underlie mixed phenotype acute leukaemias. In contrast, and despite the conclusive demonstration that MLL-AF4 infant ALL arises in utero. In order to address this we purified haematopoietic stem/progenitor cell (HSPC) populations from four non-lineage switching presentation infant ALL cases and one ALL presentation which went on to lineage switch at relapse. The specific MLL-AF4 fusion event was determined in unsorted samples by LDI-PCR and identified in purified populations by nested PCR. In three cases where non-lineage restricted populations were able to be purified, MLL-AF4 was identified in the CD34+CD38-CD45RA+ population (LK228, LK230, LS01), the CD34+CD38-CD45RA-CD90- multipotential progenitor population (MPP, LS01) and even a candidate CD34+CD38-CD45RA-CD90+ haematopoietic stem cell (HSC) population (LK228) Interestingly, in a single non-switched MLL-AF9 case analysed for external comparison, the fusion was only identified in CD19+ blast/B cell populations, not in any HSPC population. Unexpectedly, we were also able to identify the presence of the MLL-AF4 fusion in apparently normally differentiated CD34-CD19/3-HLA-DR+CD14/11c+ monocytes/dendritic cells from the peripheral blood/bone marrow of 4/5 cases examined. This finding was further supported by single cell analysis of LS01PALL which identified the fusion in 2/22 CD34-CD19/3-HLA-DR+CD14/11c+ monocytes/dendritic cells analysed. Furthermore, the matched AML sample (LS01RAML) also contained MLL-AF4 positive mature T lymphoid cells. These data imply that MLL-AF4 does not impose a complete block on normal haematopoietic differentiation, and raise the question of what additional factors contribute to leukaemic lineage determination in the setting of the MLL-AF4 translocation. To examine the functional capacity of MLL-AF4 transformed precursor cells we generated a patient-derived xenograft model using NOD-scid/IL2Rγ-/- (NSG) mice. Serial xenotransplantation identified an MLL-AF4 positive clone persisting within the human CD34+CD38-CD45RA-CD90+ compartment across four generations of mice, confirming self-renewal of this population. Together these data identify an early multipotent progenitor or HSC as the putative cell of origin for MLL-AF4 ALL. Furthermore, they demonstrate that MLL-AF4, uniquely amongst MLL fusion genes, imposes a profound lymphoid bias on the developing leukemia but without completely abolishing broader, non-malignant, haematopoietic differentiation.

Project description:MicroRNAs (miRNAs) have emerged as novel cancer genes. In particular, the 17~92 cluster of miRNAs is highly expressed in haematopoietic cancers and promotes lymphomagenesis in vivo1,2. Clinical use of these findings hinges on isolating the oncogenic activity within the 17~92 cluster and defining its relevant target genes. Here we show that miR-19 is sufficient to promote leukaemogenesis in Notch1 induced T-cell lymphoblastic leukaemia (T-ALL) in vivo. Consistent with the pathogenic importance of this interaction, we report a novel translocation targeting the 17~92 miRNA cluster coinciding with a second rearrangement that activates Notch1 in T-ALL. To identify the miR-19 targets responsible for its oncogenic action, we conducted a large-scale short-hairpin RNA (shRNA) screen for genes whose knockdown could phenocopy miR-19. Strikingly, the results of this screen were enriched for miR-19 target genes, and included Bim (Bcl2L11)1,3, AMP-activated kinase (Prkaa1), and the tumour suppressor phosphatases Pten and PP2A (Ppp2r5e). Hence, an unbiased, functional genomics approach reveals a coordinate clamp down on several regulators of PI3K-related survival signals by the leukaemogenic miR-19. Gene expression data revealing differences in gene expression between parental FL5-12 cells transduced with Vector and miR-19 expressing FL5-12 cells

Project description:Dissecting the early steps of MLL induced leukaemogenic transformation using a new mouse model of AML

Project description:Bromodomain and Extra Terminal protein (BET) inhibitors are first-in-class targeted therapies that deliver a new therapeutic paradigm by directly targeting epigenetic readers1,2. Early clinical trials have shown significant promise especially in acute myeloid leukaemia (AML)3; therefore the evaluation of resistance mechanisms, an inevitable consequence of cancer therapies, is of utmost importance to optimise the clinical efficacy of these drugs. Using primary murine stem and progenitor cells immortalised with MLL-AF9, we have used an innovative approach to generate 20 cell lines derived from single cell clones demonstrating stable resistance, in vitro and in vivo, to the prototypical BET inhibitor, I-BET. Resistance to I-BET confers cross-resistance to chemically distinct BET inhibitors such as JQ1, as well as resistance to genetic knockdown of BET proteins. Resistance is not mediated through increased drug efflux or metabolism but is demonstrated to emerge from leukaemia stem cells (LSC). Resistant clones display a leukaemic granulocyte-macrophage progenitor (L-GMP) phenotype (Lin-, Sca-, cKit+, CD34+, Fc³RII/RIII+) and functionally exhibit increased clonogenic capacity in vitro and markedly shorter leukaemia latency in vivo. Chromatin bound BRD4 is globally reduced in resistant cells, however expression of key target genes such as MYC remains unaltered, highlighting the existence of alternative mechanisms to regulate transcription. We demonstrate that resistance to BET inhibitors is in part a consequence of increased Wnt/²-catenin signaling. Negative regulation of this pathway results in differentiation of resistant cells into mature leukaemic blasts, inhibition of MYC expression and restoration of sensitivity to I-BET in vitro and in vivo. Finally, we show that the sensitivity of primary human AML cells to I-BET correlates with the baseline expression of Wnt/²-catenin target genes. Together these findings provide novel insights into the biology of AML, highlight the potential therapeutic limitations of BET inhibitors and identify strategies that may overcome resistance and enhance the clinical utility of these unique targeted therapies. Comparison of iBET resistant and sensitive cell lines

Project description:Bromodomain and Extra Terminal protein (BET) inhibitors are first-in-class targeted therapies that deliver a new therapeutic paradigm by directly targeting epigenetic readers1,2. Early clinical trials have shown significant promise especially in acute myeloid leukaemia (AML)3; therefore the evaluation of resistance mechanisms, an inevitable consequence of cancer therapies, is of utmost importance to optimise the clinical efficacy of these drugs. Using primary murine stem and progenitor cells immortalised with MLL-AF9, we have used an innovative approach to generate 20 cell lines derived from single cell clones demonstrating stable resistance, in vitro and in vivo, to the prototypical BET inhibitor, I-BET. Resistance to I-BET confers cross-resistance to chemically distinct BET inhibitors such as JQ1, as well as resistance to genetic knockdown of BET proteins. Resistance is not mediated through increased drug efflux or metabolism but is demonstrated to emerge from leukaemia stem cells (LSC). Resistant clones display a leukaemic granulocyte-macrophage progenitor (L-GMP) phenotype (Lin-, Sca-, cKit+, CD34+, Fc³RII/RIII+) and functionally exhibit increased clonogenic capacity in vitro and markedly shorter leukaemia latency in vivo. Chromatin bound BRD4 is globally reduced in resistant cells, however expression of key target genes such as MYC remains unaltered, highlighting the existence of alternative mechanisms to regulate transcription. We demonstrate that resistance to BET inhibitors is in part a consequence of increased Wnt/²-catenin signaling. Negative regulation of this pathway results in differentiation of resistant cells into mature leukaemic blasts, inhibition of MYC expression and restoration of sensitivity to I-BET in vitro and in vivo. Finally, we show that the sensitivity of primary human AML cells to I-BET correlates with the baseline expression of Wnt/²-catenin target genes. Together these findings provide novel insights into the biology of AML, highlight the potential therapeutic limitations of BET inhibitors and identify strategies that may overcome resistance and enhance the clinical utility of these unique targeted therapies. Comparison of iBET resistant and sensitive cell lines

Project description:Bromodomain and Extra Terminal protein (BET) inhibitors are first-in-class targeted therapies that deliver a new therapeutic paradigm by directly targeting epigenetic readers. Early clinical trials have shown significant promise especially in acute myeloid leukaemia (AML)3; therefore the evaluation of resistance mechanisms, an inevitable consequence of cancer therapies, is of utmost importance to optimise the clinical efficacy of these drugs. Using primary murine stem and progenitor cells immortalised with MLL-AF9, we have used an innovative approach to generate 20 cell lines derived from single cell clones demonstrating stable resistance, in vitro and in vivo, to the prototypical BET inhibitor, I-BET. Resistance to I-BET confers cross-resistance to chemically distinct BET inhibitors such as JQ1, as well as resistance to genetic knockdown of BET proteins. Resistance is not mediated through increased drug efflux or metabolism but is demonstrated to emerge from leukaemia stem cells (LSC). Resistant clones display a leukaemic granulocyte-macrophage progenitor (L-GMP) phenotype (Lin-, Sca-, cKit+, CD34+, FcγRII/RIII+) and functionally exhibit increased clonogenic capacity in vitro and markedly shorter leukaemia latency in vivo. Chromatin bound BRD4 is globally reduced in resistant cells, however expression of key target genes such as MYC remains unaltered, highlighting the existence of alternative mechanisms to regulate transcription. We demonstrate that resistance to BET inhibitors is in part a consequence of increased Wnt/β-catenin signaling. Negative regulation of this pathway results in differentiation of resistant cells into mature leukaemic blasts, inhibition of MYC expression and restoration of sensitivity to I-BET in vitro and in vivo. Finally, we show that the sensitivity of primary human AML cells to I-BET correlates with the baseline expression of Wnt/β-catenin target genes. Together these findings provide novel insights into the biology of AML, highlight the potential therapeutic limitations of BET inhibitors and identify strategies that may overcome resistance and enhance the clinical utility of these unique targeted therapies. Total RNA obtained from iBET resistant and sensitive cells

Project description:Dissecting the early steps of MLL induced leukaemogenic transformation using a new mouse model of AML [ATAC-seq]