Project description:A differentiation block is the cardinal pathologic feature of acute myeloid leukaemia (AML) but the underlying mechanisms are incompletely understood. Despite absent expression in normal hematopoietic lineages, the Forkhead family transcription factor FOXC1, which is a critical regulator of normal mesenchymal and mesodermal differentiation, is highly expressed in ~20% of cases of AML where it confers a block to monocyte/macrophage lineage differentiation. Through integrated proteomics and bioinformatics approaches, we discovered that FOXC1 interacts with RUNX1 through its Forkhead DNA binding domain and that the two factors co-occupy a discrete set of primed or active enhancers distributed close to monocyte/macrophage differentiation genes. FOXC1 stabilises association of RUNX1, HDAC1 and the Groucho family repressor protein TLE3 at these sites. FOXC1 knockdown induced loss of these repressor proteins and gain of CEBPA binding, with localised increase in enhancer acetylation; nearby genes, including KLF2, were up regulated. A genome-wide redistribution of RUNX1 and TLE3 binding from enhancers to promoters was triggered by FOXC1 knockdown leading to repression of self-renewal genes including MYC and MYB. Thus, FOXC1 misexpression confers a differentiation block in AML by stabilising recruitment of a RUNX1/HDAC1/TLE3 repressor complex at primed or active enhancers close to genes which control monocyte/macrophage lineage differentiation.

Project description:A differentiation block is the cardinal pathologic feature of acute myeloid leukaemia (AML) but the underlying mechanisms are incompletely understood. Despite absent expression in normal hematopoietic lineages, the Forkhead family transcription factor FOXC1, which is a critical regulator of normal mesenchymal and mesodermal differentiation, is highly expressed in ~20% of cases of AML where it confers a block to monocyte/macrophage lineage differentiation. Through integrated proteomics and bioinformatics approaches, we discovered that FOXC1 interacts with RUNX1 through its Forkhead DNA binding domain and that the two factors co-occupy a discrete set of primed or active enhancers distributed close to monocyte/macrophage differentiation genes. FOXC1 stabilises association of RUNX1, HDAC1 and the Groucho family repressor protein TLE3 at these sites. FOXC1 knockdown induced loss of these repressor proteins and gain of CEBPA binding, with localised increase in enhancer acetylation; nearby genes, including KLF2, were up regulated. A genome-wide redistribution of RUNX1 and TLE3 binding from enhancers to promoters was triggered by FOXC1 knockdown leading to repression of self-renewal genes including MYC and MYB. Thus, FOXC1 misexpression confers a differentiation block in AML by stabilising recruitment of a RUNX1/HDAC1/TLE3 repressor complex at primed or active enhancers close to genes which control monocyte/macrophage lineage differentiation.

Project description:Pharmacologic inhibition of LSD1 induces molecular and morphologic differentiation of blast cells in acute myeloid leukaemia (AML) patients harboring MLL gene translocations. In addition to its demethylase activity, LSD1 has a critical scaffolding function at genomic sites occupied by the SNAG domain transcription repressor GFI1. Importantly, inhibitors block both enzymatic and scaffolding activities, in the latter case by disrupting the protein:protein interaction of GFI1 with LSD1. To explore the wider consequences of LSD1 inhibition on the LSD1 protein complex we made use of mass spectrometry approaches. We discovered that the interaction of the HMG-box protein HMG20B with LSD1 was also disrupted by LSD1 inhibition. Downstream investigations revealed that HMG20B is colocated on chromatin genome-wide with GFI1 and LSD1; the strongest HMG20B binding colocates with the strongest GFI1 and LSD1 binding. Functional assays demonstrated that HMG20B depletion induces leukaemia cell differentiation and further revealed that HMG20B is required for the transcription repressor activity of GFI1 through stabilizing the interaction on chromatin of LSD1 with GFI1. Interaction of HMG20B with LSD1 is through its coiled-coil domain. Thus, HMG20B is a critical component of the GFI1:LSD1 transcription repressor complex which contributes to leukaemia cell differentiation block.

Project description:Despite absent expression in normal hematopoiesis, the Forkhead factor FOXC1, a critical mesenchymal differentiation regulator, is highly expressed in ~30% of HOXAhigh AML to confer blocked monocyte/macrophage differentiation. Through integrated proteomics and bioinformatics, we discovered that FOXC1 and RUNX1 interact through Forkhead and Runt domains respectively and cooccupy primed and active enhancers distributed close to differentiation genes. FOXC1 stabilises association of RUNX1, HDAC1 and Groucho repressor TLE3 to limit enhancer activity: FOXC1 knockdown induced loss of repressor proteins, gain of CEBPA binding, enhancer acetylation and upregulation of nearby genes, including KLF2. Furthermore, it triggered genome-wide redistribution of RUNX1, TLE3 and HDAC1 from enhancers to promoters leading to repression of self-renewal genes including MYC and MYB. Our studies highlight RUNX1 and CEBPA transcription factor swapping as a feature of leukemia cell differentiation, and reveal that FOXC1 prevents this by stabilising enhancer binding of a RUNX1/HDAC1/TLE3 transcription repressor complex, to oncogenic effect.

Project description:RUNX1 gene chromosomal translocations and mutations are frequent in acute myeloid leukaemia, sometimes resulting in the aberrant expression of C-terminal-truncated RUNX1 proteins lacking the transactivation domain (TAD). Some AML patients anomalously over-express a RUNX1a splice variant with the same TAD deficit. We performed an in-depth in vitro study of the role of TAD-defective RUNX1 proteins in AML development in human hematopoietic/progenitor stem cells. Transformation ability, maturation phenotype and differentiation/proliferation effects were assessed. Short RUNX1 protein expression seemed to increase both proliferation and self-renewal capacity, disrupting the differentiation program and interfering with wild-type RUNX1b protein, in a dominant-negative, dose-dependent manner. Expression microarray analysis showed short RUNX1 and RUNX1/ETO models had similar aberrant expression patterns. Genes known to be broadly involved in self-renewal and leukemogenesis were found to be altered; specifically observed were overexpression of homeobox genes, downregulation of primitive erythroid genes and alterations in leukemogenic transcription factors. The Wnt/b-catenin and RhoA pathways were also observed to be altered, whereas short RUNX1 proteins appeared not to affect the Notch1 pathway, which is altered in the RUNX1/ETO model. Therefore, we propose that TAD-defective RUNX1 proteins may contribute to leukemogenesis and could form the basis of a new genetic category of AML. Comparative experiment: Human CD34+ hematopoietic cells gene expression was measured after TAD defective RUNX1 cDNA transfection vs empty vector transfection. Two independent experiments were performed for each protein model, using different cord blood donors for each experiment.

Project description:Mutation or epigenetic silencing of the transcription factor C/EBPa is observed in ~10% of patients with acute myeloid leukemia (AML). In both cases, a common global gene expression profile is observed, but down-stream targets relevant for leukemogenesis are not known. Here we identify Sox4 as a direct target of C/EBPa whereby its expression is inversely correlated with C/EBPa activity. Downregulation of Sox4 abrogated increased self-renewal of leukemic cells and restored their differentiation. Gene expression profiles of leukemia initiating cells (LICs) from both Sox4 overexpression and murine mutant C/EBPa AML models clustered together, but differed from other types of AML. Our data demonstrate that Sox4 overexpression resulting from C/EBPa inactivation contributes to the development of leukemias with a distinct LIC phenotype. A ChIP-seq sample of C/EBPa in Macrophages is used in this study

Project description:Mutation or epigenetic silencing of the transcription factor C/EBP? is observed in ~10% of patients with acute myeloid leukemia (AML). In both cases, a common global gene expression profile is observed, but down-stream targets relevant for leukemogenesis are not known. Here we identify Sox4 as a direct target of C/EBP? whereby its expression is inversely correlated with C/EBP? activity. Downregulation of Sox4 abrogated increased self-renewal of leukemic cells and restored their differentiation. Gene expression profiles of leukemia initiating cells (LICs) from both Sox4 overexpression and murine mutant C/EBP? AML models clustered together, but differed from other types of AML. Our data demonstrate that Sox4 overexpression resulting from C/EBP? inactivation contributes to the development of leukemias with a distinct LIC phenotype. K/L (bi-allelic Cebpa mutations) leukemic mice and Sox4 overexprssing leukemic mice were used for RNA extraction and hybridization on Affymetrix microarrays. We compared these microarray samples with the C57/BL6 wild type mice.

Project description:Pharmacologic inhibition of LSD1 induces molecular and morphologic differentiation of blast cells in acute myeloid leukaemia (AML) patients harboring MLL gene translocations. In addition to its demethylase activity, LSD1 has a critical scaffolding function at genomic sites occupied by the SNAG domain transcription repressor GFI1. Importantly, inhibitors block both enzymatic and scaffolding activities, in the latter case by disrupting the protein:protein interaction of GFI1 with LSD1. To explore the wider consequences of LSD1 inhibition on the LSD1 protein complex we made use of mass spectrometry approaches. We discovered that the interaction of the HMG-box protein HMG20B with LSD1 was also disrupted by LSD1 inhibition. Downstream investigations revealed that HMG20B is colocated on chromatin genome-wide with GFI1 and LSD1; the strongest HMG20B binding colocates with the strongest GFI1 and LSD1 binding. Functional assays demonstrated that HMG20B depletion induces leukaemia cell differentiation and further revealed that HMG20B is required for the transcription repressor activity of GFI1 through stabilizing the interaction on chromatin of LSD1 with GFI1. Interaction of HMG20B with LSD1 is through its coiled-coil domain. Thus, HMG20B is a critical component of the GFI1:LSD1 transcription repressor complex which contributes to leukaemia cell differentiation block.

Project description:Pharmacologic inhibition of LSD1 induces molecular and morphologic differentiation of blast cells in acute myeloid leukaemia (AML) patients harboring MLL gene translocations. In addition to its demethylase activity, LSD1 has a critical scaffolding function at genomic sites occupied by the SNAG domain transcription repressor GFI1. Importantly, inhibitors block both enzymatic and scaffolding activities, in the latter case by disrupting the protein:protein interaction of GFI1 with LSD1. To explore the wider consequences of LSD1 inhibition on the LSD1 protein complex we made use of mass spectrometry approaches. We discovered that the interaction of the HMG-box protein HMG20B with LSD1 was also disrupted by LSD1 inhibition. Downstream investigations revealed that HMG20B is colocated on chromatin genome-wide with GFI1 and LSD1; the strongest HMG20B binding colocates with the strongest GFI1 and LSD1 binding. Functional assays demonstrated that HMG20B depletion induces leukaemia cell differentiation and further revealed that HMG20B is required for the transcription repressor activity of GFI1 through stabilizing the interaction on chromatin of LSD1 with GFI1. Interaction of HMG20B with LSD1 is through its coiled-coil domain. Thus, HMG20B is a critical component of the GFI1:LSD1 transcription repressor complex which contributes to leukaemia cell differentiation block.

Project description:Pharmacologic inhibition of LSD1 induces molecular and morphologic differentiation of blast cells in acute myeloid leukaemia (AML) patients harboring MLL gene translocations. In addition to its demethylase activity, LSD1 has a critical scaffolding function at genomic sites occupied by the SNAG domain transcription repressor GFI1. Importantly, inhibitors block both enzymatic and scaffolding activities, in the latter case by disrupting the protein:protein interaction of GFI1 with LSD1. To explore the wider consequences of LSD1 inhibition on the LSD1 protein complex we made use of mass spectrometry approaches. We discovered that the interaction of the HMG-box protein HMG20B with LSD1 was also disrupted by LSD1 inhibition. Downstream investigations revealed that HMG20B is colocated on chromatin genome-wide with GFI1 and LSD1; the strongest HMG20B binding colocates with the strongest GFI1 and LSD1 binding. Functional assays demonstrated that HMG20B depletion induces leukaemia cell differentiation and further revealed that HMG20B is required for the transcription repressor activity of GFI1 through stabilizing the interaction on chromatin of LSD1 with GFI1. Interaction of HMG20B with LSD1 is through its coiled-coil domain. Thus, HMG20B is a critical component of the GFI1:LSD1 transcription repressor complex which contributes to leukaemia cell differentiation block.