Project description:Aberrant regulation of chromatin modifiers is a common occurrence across many cancer types, and a key priority is to determine how specific alteration of these proteins, often enzymes, can be targeted therapeutically. MOZ, a histone acyltransferase, is recurrently fused to coactivators CBP, p300, and TIF2 in cases of Acute Myeloid Leukemia (AML). Using either pharmacological inhibition or targeted protein degradation in a mouse model for MOZ-TIF2-driven leukemia, we show that KAT6 (MOZ/MORF) enzymatic activity and the MOZ-TIF2 protein are necessary for indefinite proliferation in cell culture. Interestingly, MOZ enzymatic activity is selectively required in MOZ-TIF2 cells, as murine MLL-AF9 leukemic cells show no sensitivity to the WM-1119 MOZ inhibitor. MOZ-TIF2 directly regulates a small subset of genes encoding developmental transcription factors, augmenting their high expression. Transcription levels of these genes positively correlate with enrichment of histone H3 propionylation at lysine 23 (H3K23pr), a recently appreciated histone acylation associated with gene activation. Unexpectedly, we also show that MOZ-TIF2 and MLL-AF9 regulate transcription of largely non-overlapping gene sets, and their cellular models exhibit distinct sensitivities to multiple small molecule inhibitors directed against AML pathways. This is despite the shared genetic pathways of wild-type MOZ and MLL. Overall, our data provide insight into how aberrant regulation of MOZ contributes to leukemogenesis. We anticipate these experiments will inform future work identifying targeted therapies in the treatment of AML and other diseases involving MOZ-induced transcriptional dysregulation.

Project description:Aberrant regulation of chromatin modifiers is a common occurrence across many cancer types, and a key priority is to determine how specific alteration of these proteins, often enzymes, can be targeted therapeutically. MOZ, a histone acyltransferase, is recurrently fused to coactivators CBP, p300, and TIF2 in cases of Acute Myeloid Leukemia (AML). Using either pharmacological inhibition or targeted protein degradation in a mouse model for MOZ-TIF2-driven leukemia, we show that KAT6 (MOZ/MORF) enzymatic activity and the MOZ-TIF2 protein are necessary for indefinite proliferation in cell culture. Interestingly, MOZ enzymatic activity is selectively required in MOZ-TIF2 cells, as murine MLL-AF9 leukemic cells show no sensitivity to the WM-1119 MOZ inhibitor. MOZ-TIF2 directly regulates a small subset of genes encoding developmental transcription factors, augmenting their high expression. Transcription levels of these genes positively correlate with enrichment of histone H3 propionylation at lysine 23 (H3K23pr), a recently appreciated histone acylation associated with gene activation. Unexpectedly, we also show that MOZ-TIF2 and MLL-AF9 regulate transcription of largely non-overlapping gene sets, and their cellular models exhibit distinct sensitivities to multiple small molecule inhibitors directed against AML pathways. This is despite the shared genetic pathways of wild-type MOZ and MLL. Overall, our data provide insight into how aberrant regulation of MOZ contributes to leukemogenesis. We anticipate these experiments will inform future work identifying targeted therapies in the treatment of AML and other diseases involving MOZ-induced transcriptional dysregulation.

Project description:Aberrant regulation of chromatin modifiers is a common occurrence across many cancer types, and a key priority is to determine how specific alteration of these proteins, often enzymes, can be targeted therapeutically. MOZ, a histone acyltransferase, is recurrently fused to coactivators CBP, p300, and TIF2 in cases of Acute Myeloid Leukemia (AML). Using either pharmacological inhibition or targeted protein degradation in a mouse model for MOZ-TIF2-driven leukemia, we show that KAT6 (MOZ/MORF) enzymatic activity and the MOZ-TIF2 protein are necessary for indefinite proliferation in cell culture. Interestingly, MOZ enzymatic activity is selectively required in MOZ-TIF2 cells, as murine MLL-AF9 leukemic cells show no sensitivity to the WM-1119 MOZ inhibitor. MOZ-TIF2 directly regulates a small subset of genes encoding developmental transcription factors, augmenting their high expression. Transcription levels of these genes positively correlate with enrichment of histone H3 propionylation at lysine 23 (H3K23pr), a recently appreciated histone acylation associated with gene activation. Unexpectedly, we also show that MOZ-TIF2 and MLL-AF9 regulate transcription of largely non-overlapping gene sets, and their cellular models exhibit distinct sensitivities to multiple small molecule inhibitors directed against AML pathways. This is despite the shared genetic pathways of wild-type MOZ and MLL. Overall, our data provide insight into how aberrant regulation of MOZ contributes to leukemogenesis. We anticipate these experiments will inform future work identifying targeted therapies in the treatment of AML and other diseases involving MOZ-induced transcriptional dysregulation.

Project description:Chromosomal translocations encoding the MLL-AF9 and MLL-ENL fusion transcription factors are prevalent in infant acute leukaemia and therapy-related leukaemia. In order to conditionally express the MLL-fusion oncogene in primary haematopoietic progenitor cells (HPC), retroviral delivery of the Tet-off expression system was used (Horton et al., Cancer Res, 2005). Treatment of the conditional cells with Doxycycline caused a decrease in MLL-AF9/ENL mRNA and protein expression, and resulted in terminal differentiation of the cells. By analysing global changes in gene expression after treatment of cells with Doxycycline we were able to identify a number of potential transcriptional target genes of the MLL-AF9 and MLL-ENL fusion oncogenes.

Project description:Monocytic leukemia Zinc finger protein (MOZ) is a MYST-type acetyltransferase involved in chromosomal translocation in acute myelogenous leukemia (AML) and myelodysplastic syndrome. MOZ is established as essential for hematopoiesis; however, the role of MOZ in AML has not been addressed. We propose that MOZ is critical for AML development induced by MOZ-TIF2 fusions. Moz-deficient hematopoietic stem/progenitor cells (HSPCs) expressing MOZ-TIF2 could form colonies in vitro but could not induce AML in mice. By contrast, Moz was dispensable for colony formation by HOXA9-transduced cells and AML development caused by HOXA9 and MEIS1, suggesting a specific requirement for MOZ in AML induced by MOZ/MLL-fusions. Expression of the of Meis1, but not Hoxa9, was reduced in Moz-deficient MOZ-TIF2 AML cells. AML development induced by MOZ-TIF2 was rescued by introducing Meis1 into Moz-deficient cells carrying MOZ-TIF2. Meis1 deletion impaired MOZ-TIF2­-mediated AML development. Active histone modifications were also severely reduced at the Meis1 locus in Moz-deficient MOZ-TIF2 AML cells. These results suggest that endogenous MOZ is critical for MOZ-fusion-induced AML development and maintains active chromatin signatures at target gene loci.

Project description:Transcriptional deregulation plays a major role in acute myeloid leukemia, identification of epigenetic modifying enzymes essential for the maintenance of oncogenic transcription programs holds the key to better understanding the biology and designing effective therapeutic strategies for the disease. Here we provide experimental evidence showing the functional involvement and therapeutic potentials of targeting PRMT1 with H4R3 methyltransferase activity in various MLL and non-MLL leukemias. PRMT1 is necessary but not sufficient for leukemic transformation, which requires co-recruitment of KDM4C with H3K9 demethylase activity by chimeric transcription factors to mediate epigenetic reprogramming. Inhibition of KDM4C/PRMT1 suppresses transcription and transformation ability of MLL fusions and MOZ-TIF2, revealing a novel and targetable epigenetic circuitry mediated by PRMT1 and KDM4C in acute leukemia.

Project description:Acute Myeloid Leukaemia (AML) is a highly heterogeneous disease characterised by an abnormal transcriptional landscape that results in a block in normal blood cell differentiation and aberrant self-renewal. Dysregulation of Homeobox A9 (HOXA9) expression is a hallmark of multiple AML subsets. Although HOXA9 is critical for maintaining leukaemic transformation, it has proven to be a challenging druggable target, and the underpinning molecular mechanisms through which it promotes leukaemogenesis remain elusive. Here, we report the existence of a tripartite complex between eyes absent 1 (EYA1), sine oculis homeobox 1 (SIX1) and HOXA9 in monocytic zinc finger (MOZ) and mixed-lineage leukaemia (MLL) rearranged AMLs. We employed ChIP-seq, together with RNA-seq, to identify regions bound and transcriptionally upregulated in a MOZ-TIF2 driven model of AML. Using RNA-seq, we demonstrated that EYA1 potentiates the transforming capacity of HOXA9 to confer a greater level of differentiation block via upregulation of Wnt and epithelial to mesenchymal transition (EMT) signalling cascades and suppression of myelo-monocytic programmes. We next sought to define the impact of pharmacologically destabilising the EYA1/SIX1/HOXA9 complex using Benzarone. Through a single cell RNA-Seq timecourse following treatment of MOZ-TIF2 cells with Benzarone, we provide evidence that disruption of EYA1 and its interactions results in differentiation of these cells. To prove the specificity of Benzarone towards EYA1, we also conducted RNA-Seq on cells expressing EYA1 and HOXA9 or HOXA9 alone.

Project description:Acute leukaemias are commonly caused by mutations that corrupt the transcriptional circuitry of haematopoietic stem/progenitor cells. However, the mechanisms underlying large-scale transcriptional reprogramming remain largely unknown. Here we investigated transcriptional reprogramming at genome-scale in mouse retroviral transplant models of acute myeloid leukaemia (AML) using both gene-expression profiling and ChIP-sequencing. We identified several thousand candidate regulatory regions with altered levels of histone acetylation which were characterised by differential distribution of consensus motifs for key haematopoietic transcription factors. The integrated genome-scale analysis applied in this study represents a valuable and widely applicable approach to study the transcriptional control of both normal and aberrant haematopoiesis and to identify critical factors responsible for transcriptional reprogramming in human cancer.

Project description:Eradication of chemotherapy-resistant leukemia stem cells is expected to improve treatment outcomes in patients with acute myelogenous leukemia (AML). In a mouse model of AML expressing the MOZ-TIF2 fusion, we found that Ring1A and Ring1B, components of Polycomb repressive complex 1, play crucial roles in maintaining AML stem cells. Deletion of Ring1A and Ring1B (Ring1A/B) from MOZ-TIF2 AML cells diminished self-renewal capacity and induced the expression of numerous genes including Gli-similar 2 (Glis2). Overexpression of Glis2 caused MOZ-TIF2 AML cells to differentiate into mature cells, whereas Glis2 knockdown in Ring1A/B-deficient MOZ-TIF2 cells inhibited differentiation. Thus, Ring1A/B regulates and maintains AML stem cells in part by repressing Glis2 expression, which promotes their differentiation. These findings provide new insights into the mechanism of AML stem cell homeostasis and reveal novel targets for cancer stem cell therapy.

Project description:Haematopoietic stem cells (HSC) reside in locations within the bone marrow microenvironment (BMM) featuring a slightly higher extracellular calcium ion concentration [eCa2+]. HSC respond to [eCa2+] via the G-protein coupled calcium-sensing receptor (CaSR), but the role of CaSR for leukaemia and leukaemia stem cells (LSC), the malignant counterpart to HSC, is poorly defined. Here we performed a proteomic analysis on Lin- MLL AF9+ cells, comparing WT cells to cells lacking CaSR using TMT-based proteomics.