Project description:The regulation of the switch from fetal (HBG) to adult (HBB and HBD) beta-globin gene expression has served as a paradigm for clinically relevant developmental transcriptional control. Mechanistic studies of this switch have focused overwhelmingly on HBG repressors with comparatively little attention paid to potential HBG activators. We found that in adult type HUDEP2 erythroid cells, the ATP-dependent chromatin remodeler BRG1 preferentially activates the HBG genes as well as the minor adult HBD gene. BRG1 is a core catalytic subunit of three BAF complexes, canonical BAF, polybromo BAF, and non-canonical BAF (ncBAF) that regulate chromatin accessibility in distinct gene- and cell-type contexts. Using comprehensive CRISPR mediated dissection of these complexes in HUDEP2 and primary adult erythroid cells, we pinpointed the HBG and HBD selective activation function of BRG1 to the ncBAF complex. Loss of the ncBAF complex subunits BRD9 and BAF60A preferentially decreased HBG and HBD transcription while accelerating erythroid differentiation and hemoglobinization. Pharmacologic depletion of BRD9 acutely decreased chromatin accessibility at the HBD and HBG promoters and reduced their transcriptional activities. This surprising demonstration of BAF complex selectivity within a multi-gene cluster extends our understanding of BAF complex functions and identifies a potential target for therapeutic manipulation of beta-like globin genes.

Project description:The regulation of beta-like globin genes, including the switch from fetal (HBG) to adult (HBB and HBD) genes has served as a paradigm of developmental transcriptional control. While HBG repressors such as BCL11A and LRF have been well characterized, recent discoveries of HIF1a and BGLT3 as HBG-specific activators have raised interest in finding new activators as potential therapeutic targets. The ATP-dependent chromosome remodeler BRG1 has previously been demonstrated as necessary for hemoglobin gene transcription. In loss of function studies in adult-like HUDEP2 cells, we found that BRG1 depletion preferentially decreased fetal HBG and the minor adult HBD. BRG1 forms multisubunit complexes with combinations of 27 subunits in 3 families - canonical BAF, polybromo BAF, and non-canonical BAF (ncBAF) - to regulate chromatin accessibility and gene transcription in a cell and condition-specific manner. Using CRISPR loss of function studies in HUDEP2 cells and primary adult erythroid cells, we identified the non-canonical BAF complex as a positive regulator of HBG and HBD. Loss of the non-canonical BAF complex subunits BRD9 and BAF60A/SMARCD1 preferentially decreased HBG and HBD in HUDEP2 cells and primary adult erythroid cultures, while accelerating erythroid differentiation and hemoglobinization. Pharmacological depletion of BRD9 led to acute decreases in chromatin accessibility at HBD and HBG promoters and reduced their primary transcripts, while longer treatment recapitulated genetic ablation effects. This surprising demonstration of BAF complex selectivity within a multi-gene cluster extends our understanding of globin gene transcriptional regulation and identifies a potential target for therapeutic manipulation of beta-like globins.

Project description:The regulation of beta-like globin genes, including the switch from fetal (HBG) to adult (HBB and HBD) genes has served as a paradigm of developmental transcriptional control. While HBG repressors such as BCL11A and LRF have been well characterized, recent discoveries of HIF1a and BGLT3 as HBG-specific activators have raised interest in finding new activators as potential therapeutic targets. The ATP-dependent chromosome remodeler BRG1 has previously been demonstrated as necessary for hemoglobin gene transcription. In loss of function studies in adult-like HUDEP2 cells, we found that BRG1 depletion preferentially decreased fetal HBG and the minor adult HBD. BRG1 forms multisubunit complexes with combinations of 27 subunits in 3 families - canonical BAF, polybromo BAF, and non-canonical BAF (ncBAF) - to regulate chromatin accessibility and gene transcription in a cell and condition-specific manner. Using CRISPR loss of function studies in HUDEP2 cells and primary adult erythroid cells, we identified the non-canonical BAF complex as a positive regulator of HBG and HBD. Loss of the non-canonical BAF complex subunits BRD9 and BAF60A/SMARCD1 preferentially decreased HBG and HBD in HUDEP2 cells and primary adult erythroid cultures, while accelerating erythroid differentiation and hemoglobinization. Pharmacological depletion of BRD9 led to acute decreases in chromatin accessibility at HBD and HBG promoters and reduced their primary transcripts, while longer treatment recapitulated genetic ablation effects. This surprising demonstration of BAF complex selectivity within a multi-gene cluster extends our understanding of globin gene transcriptional regulation and identifies a potential target for therapeutic manipulation of beta-like globins.

Project description:The regulation of beta-like globin genes, including the switch from fetal (HBG) to adult (HBB and HBD) genes has served as a paradigm of developmental transcriptional control. While HBG repressors such as BCL11A and LRF have been well characterized, recent discoveries of HIF1a and BGLT3 as HBG-specific activators have raised interest in finding new activators as potential therapeutic targets. The ATP-dependent chromosome remodeler BRG1 has previously been demonstrated as necessary for hemoglobin gene transcription. In loss of function studies in adult-like HUDEP2 cells, we found that BRG1 depletion preferentially decreased fetal HBG and the minor adult HBD. BRG1 forms multisubunit complexes with combinations of 27 subunits in 3 families - canonical BAF, polybromo BAF, and non-canonical BAF (ncBAF) - to regulate chromatin accessibility and gene transcription in a cell and condition-specific manner. Using CRISPR loss of function studies in HUDEP2 cells and primary adult erythroid cells, we identified the non-canonical BAF complex as a positive regulator of HBG and HBD. Loss of the non-canonical BAF complex subunits BRD9 and BAF60A/SMARCD1 preferentially decreased HBG and HBD in HUDEP2 cells and primary adult erythroid cultures, while accelerating erythroid differentiation and hemoglobinization. Pharmacological depletion of BRD9 led to acute decreases in chromatin accessibility at HBD and HBG promoters and reduced their primary transcripts, while longer treatment recapitulated genetic ablation effects. This surprising demonstration of BAF complex selectivity within a multi-gene cluster extends our understanding of globin gene transcriptional regulation and identifies a potential target for therapeutic manipulation of beta-like globins.

Project description:The regulation of beta-like globin genes, including the switch from fetal (HBG) to adult (HBB and HBD) genes has served as a paradigm of developmental transcriptional control. While HBG repressors such as BCL11A and LRF have been well characterized, recent discoveries of HIF1a and BGLT3 as HBG-specific activators have raised interest in finding new activators as potential therapeutic targets. The ATP-dependent chromosome remodeler BRG1 has previously been demonstrated as necessary for hemoglobin gene transcription. In loss of function studies in adult-like HUDEP2 cells, we found that BRG1 depletion preferentially decreased fetal HBG and the minor adult HBD. BRG1 forms multisubunit complexes with combinations of 27 subunits in 3 families - canonical BAF, polybromo BAF, and non-canonical BAF (ncBAF) - to regulate chromatin accessibility and gene transcription in a cell and condition-specific manner. Using CRISPR loss of function studies in HUDEP2 cells and primary adult erythroid cells, we identified the non-canonical BAF complex as a positive regulator of HBG and HBD. Loss of the non-canonical BAF complex subunits BRD9 and BAF60A/SMARCD1 preferentially decreased HBG and HBD in HUDEP2 cells and primary adult erythroid cultures, while accelerating erythroid differentiation and hemoglobinization. Pharmacological depletion of BRD9 led to acute decreases in chromatin accessibility at HBD and HBG promoters and reduced their primary transcripts, while longer treatment recapitulated genetic ablation effects. This surprising demonstration of BAF complex selectivity within a multi-gene cluster extends our understanding of globin gene transcriptional regulation and identifies a potential target for therapeutic manipulation of beta-like globins.

Project description:The hierarchical organization of hematopoietic stem cells (HSCs) governing adult hematopoiesis has been extensively investigated. However, the dynamic epigenomic transition from fetal to adult hematopoiesis remains incompletely understood, particularly regarding the involvement of epigenetic factors. In this study, we investigate the roles of BRD9, an essential component of the non-canonical BAF (ncBAF) complex known to govern the fate of adult HSCs, in fetal hematopoiesis. Consistent with observations in adult hematopoiesis, BRD9 loss impairs fetal HSC stemness and disturbs erythroid maturation. Intriguingly, the impact on myeloid lineage was discrepant: BRD9 loss inhibited and promoted myeloid differentiation in fetal and adult models, respectively. Through comprehensive transcriptomic and epigenomic analyses, we elucidate the differential roles of BRD9 in a context- and lineage-dependent manner. Our data uncover how BRD9/ncBAF complex modulates transcription in a stage-specific manner, providing deeper insights into the epigenetic regulation underlying the transition from fetal to adult hematopoiesis.

Project description:The hierarchical organization of hematopoietic stem cells (HSCs) governing adult hematopoiesis has been extensively investigated. However, the dynamic epigenomic transition from fetal to adult hematopoiesis remains incompletely understood, particularly regarding the involvement of epigenetic factors. In this study, we investigate the roles of BRD9, an essential component of the non-canonical BAF (ncBAF) complex known to govern the fate of adult HSCs, in fetal hematopoiesis. Consistent with observations in adult hematopoiesis, BRD9 loss impairs fetal HSC stemness and disturbs erythroid maturation. Intriguingly, the impact on myeloid lineage was discrepant: BRD9 loss inhibited and promoted myeloid differentiation in fetal and adult models, respectively. Through comprehensive transcriptomic and epigenomic analyses, we elucidate the differential roles of BRD9 in a context- and lineage-dependent manner. Our data uncover how BRD9/ncBAF complex modulates transcription in a stage-specific manner, providing deeper insights into the epigenetic regulation underlying the transition from fetal to adult hematopoiesis.

Project description:The hierarchical organization of hematopoietic stem cells (HSCs) governing adult hematopoiesis has been extensively investigated. However, the dynamic epigenomic transition from fetal to adult hematopoiesis remains incompletely understood, particularly regarding the involvement of epigenetic factors. In this study, we investigate the roles of BRD9, an essential component of the non-canonical BAF (ncBAF) complex known to govern the fate of adult HSCs, in fetal hematopoiesis. Consistent with observations in adult hematopoiesis, BRD9 loss impairs fetal HSC stemness and disturbs erythroid maturation. Intriguingly, the impact on myeloid lineage was discrepant: BRD9 loss inhibited and promoted myeloid differentiation in fetal and adult models, respectively. Through comprehensive transcriptomic and epigenomic analyses, we elucidate the differential roles of BRD9 in a context- and lineage-dependent manner. Our data uncover how BRD9/ncBAF complex modulates transcription in a stage-specific manner, providing deeper insights into the epigenetic regulation underlying the transition from fetal to adult hematopoiesis.

Project description:The hierarchical organization of hematopoietic stem cells (HSCs) governing adult hematopoiesis has been extensively investigated. However, the dynamic epigenomic transition from fetal to adult hematopoiesis remains incompletely understood, particularly regarding the involvement of epigenetic factors. In this study, we investigate the roles of BRD9, an essential component of the non-canonical BAF (ncBAF) complex known to govern the fate of adult HSCs, in fetal hematopoiesis. Consistent with observations in adult hematopoiesis, BRD9 loss impairs fetal HSC stemness and disturbs erythroid maturation. Intriguingly, the impact on myeloid lineage was discrepant: BRD9 loss inhibited and promoted myeloid differentiation in fetal and adult models, respectively. Through comprehensive transcriptomic and epigenomic analyses, we elucidate the differential roles of BRD9 in a context- and lineage-dependent manner. Our data uncover how BRD9/ncBAF complex modulates transcription in a stage-specific manner, providing deeper insights into the epigenetic regulation underlying the transition from fetal to adult hematopoiesis.

Project description:Transcriptional enhancers can be in physical proximity with their target genes via chromatin looping. The enhancer at the beta-globin locus (LCR) contacts the fetal (HBG) and adult (HBB) type beta-globin genes during corresponding developmental stages. We previously demonstrated that forcing proximity between the LCR and HBG genes in cultured adult-stage erythroid cells can activate HBG transcription. Activation of HBG expression in erythroid cells is of benefit to patients with sickle cell disease. Here, using the beta-globin locus as a model we provide proof-of-concept at the organismal level that forced enhancer re-wiring might present a strategy to alter gene expression for therapeutic purposes. Hematopoietic stem and progenitor cells (HSPC) from mice bearing human beta-globin genes were transduced with lentiviral vectors expressing a synthetic transcription factor (ZF-Ldb1) that fosters LCR-HBG contacts. When engrafted into host animals, HSPCs gave rise to adult-type erythroid cells with elevated HBG expression. Vectors containing ZF-Ldb1 were optimized for activity in cultured human and rhesus erythroid cells. Upon transplantation into rhesus macaques, erythroid cells from HSPCs expressing ZF-Ldb1 displayed elevated HBG production. These findings in two animal models suggest that forced redirection of gene regulatory elements may be used to alter gene expression to treat disease.