Project description:Mutations of the hematopoietic master regulator RUNX1 cause acute myeloid leukaemia, familial platelet disorder and other haematological malignancies whose phenotypes and prognoses depend on the class of RUNX1 mutation. The biochemical behaviour of these oncoproteins and their ability to cause unique diseases has been well studied but the genomic basis of their differential action is unknown. To address this question we compared integrated phenotypic, transcriptomic and genomic data from cells expressing four types of RUNX1 oncoproteins in an inducible fashion during blood development from embryonic stem cells. We show that each class of RUNX1 mutation rapidly deregulates endogenous RUNX1 function by different mechanisms, leading to specific alterations in developmentally controlled transcription factor binding and chromatin programming. The result are distinct perturbations in the trajectories of gene regulatory network changes underlying blood cell development that are consistent with the nature of the final disease phenotype. The development of novel treatments for RUNX1-driven diseases will therefore require consideration beyond RUNX1 haploinsufficiency.

Project description:Mutations of the hematopoietic master regulator RUNX1 cause acute myeloid leukaemia, familial platelet disorder and other haematological malignancies whose phenotypes and prognoses depend on the class of RUNX1 mutation. The biochemical behaviour of these oncoproteins and their ability to cause unique diseases has been well studied but the genomic basis of their differential action is unknown. To address this question we compared integrated phenotypic, transcriptomic and genomic data from cells expressing four types of RUNX1 oncoproteins in an inducible fashion during blood development from embryonic stem cells. We show that each class of RUNX1 mutation rapidly deregulates endogenous RUNX1 function by different mechanisms, leading to specific alterations in developmentally controlled transcription factor binding and chromatin programming. The result are distinct perturbations in the trajectories of gene regulatory network changes underlying blood cell development that are consistent with the nature of the final disease phenotype. The development of novel treatments for RUNX1-driven diseases will therefore require consideration beyond RUNX1 haploinsufficiency.

Project description:Mutations of the hematopoietic master regulator RUNX1 cause acute myeloid leukaemia, familial platelet disorder and other haematological malignancies whose phenotypes and prognoses depend on the class of RUNX1 mutation. The biochemical behavior of these oncoproteins and their ability to cause unique diseases has been well studied but the genomic basis of their differential action is unknown. To address this question we compared integrated phenotypic, transcriptomic and genomic data from cells expressing four types of RUNX1 oncoproteins in an inducible fashion during blood development from embryonic stem cells. We show that each class of RUNX1 mutation rapidly deregulates endogenous RUNX1 function by different mechanisms, leading to specific alterations in developmentally controlled transcription factor binding and chromatin programming. The result are distinct perturbations in the trajectories of gene regulatory network changes underlying blood cell development that are consistent with the nature of the final disease phenotype. The development of novel treatments for RUNX1-driven diseases will therefore require consideration beyond RUNX1 haploinsufficiency.

Project description:RUNX1 is crucial for multiple stages of hematopoiesis and its mutation can cause familial platelet disorder with predisposition to acute myeloid leukemia (FPD/AML). We aim to study the role of RUNX1 in megakaryocyte-biased HSCs differentiation to megakaryocytes.

Project description:RUNX1 is crucial for multiple stages of hematopoiesis and its mutation can cause familial platelet disorder with predisposition to acute myeloid leukemia (FPD/AML). We aim to study the role of RUNX1 in megakaryocyte-biased HSCs differentiation to megakaryocytes.

Project description:Different mutant RUNX1 oncoprotein classes program alternate hematopoietic differentiation trajectories

Project description:RUNX1 is crucial for multiple stages of hematopoiesis and its mutation can cause familial platelet disorder with predisposition to acute myeloid leukemia (FPD/AML). We aim to study the role of RUNX1 in megakaryocyte-biased HSCs differentiation to megakaryocytes. Here, by using Runx1F/FMx1-Cre mouse model ,we sorted CD41pos HSCs and CD41neg HSCs in both RUNX1 WT and KO, and tested the RUNX1 direct binding targets in these cells genome.

Project description:STAG2 encodes a cohesin component and is frequently mutated in myeloid neoplasms, showing highly significant co-mutation patterns with other drivers, including RUNX1. However, the molecular basis of cohesin-mutated leukemogenesis remains poorly understood. Here we show a critical role of an interplay between Stag2 and Runx1 in the regulation of enhancer-promoter looping and transcription in hematopoiesis. Combined loss of Stag2 and Runx1, which co-localize at enhancer-rich, Ctcf-deficient sites, synergistically attenuates enhancer-promoter loops, particularly at sites enriched for RNA polymerase II and Mediator, and deregulates gene expression, leading to myeloid-skewed expansion of hematopoietic stem/progenitor cells (HSPCs) and myelodysplastic syndromes (MDS). Attenuated enhancer-promoter loops in Stag2/Runx1-deficient cells are associated with downregulation of genes with high basal transcriptional pausing, which are important for the regulation of HSPCs.　Down-regulation of high-pausing genes is also confirmed in STAG2/cohesin-mutated primary AML/MDS samples. Our results highlight a unique STAG2/RUNX1 interplay in gene regulation and provide insights into cohesin-mutated leukemogenesis.

Project description:STAG2 encodes a cohesin component and is frequently mutated in myeloid neoplasms, showing highly significant co-mutation patterns with other drivers, including RUNX1. However, the molecular basis of cohesin-mutated leukemogenesis remains poorly understood. Here we show a critical role of an interplay between Stag2 and Runx1 in the regulation of enhancer-promoter looping and transcription in hematopoiesis. Combined loss of Stag2 and Runx1, which co-localize at enhancer-rich, Ctcf-deficient sites, synergistically attenuates enhancer-promoter loops, particularly at sites enriched for RNA polymerase II and Mediator, and deregulates gene expression, leading to myeloid-skewed expansion of hematopoietic stem/progenitor cells (HSPCs) and myelodysplastic syndromes (MDS). Attenuated enhancer-promoter loops in Stag2/Runx1-deficient cells are associated with downregulation of genes with high basal transcriptional pausing, which are important for the regulation of HSPCs.　Down-regulation of high-pausing genes is also confirmed in STAG2/cohesin-mutated primary AML/MDS samples. Our results highlight a unique STAG2/RUNX1 interplay in gene regulation and provide insights into cohesin-mutated leukemogenesis.

Project description:STAG2 encodes a cohesin component and is frequently mutated in myeloid neoplasms, showing highly significant co-mutation patterns with other drivers, including RUNX1. However, the molecular basis of cohesin-mutated leukemogenesis remains poorly understood. Here we show a critical role of an interplay between Stag2 and Runx1 in the regulation of enhancer-promoter looping and transcription in hematopoiesis. Combined loss of Stag2 and Runx1, which co-localize at enhancer-rich, Ctcf-deficient sites, synergistically attenuates enhancer-promoter loops, particularly at sites enriched for RNA polymerase II and Mediator, and deregulates gene expression, leading to myeloid-skewed expansion of hematopoietic stem/progenitor cells (HSPCs) and myelodysplastic syndromes (MDS). Attenuated enhancer-promoter loops in Stag2/Runx1-deficient cells are associated with downregulation of genes with high basal transcriptional pausing, which are important for the regulation of HSPCs.　Down-regulation of high-pausing genes is also confirmed in STAG2/cohesin-mutated primary AML/MDS samples. Our results highlight a unique STAG2/RUNX1 interplay in gene regulation and provide insights into cohesin-mutated leukemogenesis.