Project description:Longstanding observations that fetal hemoglobin (HbF, a2g2) expression is reactivated in postnatal red blood cells (RBCs) during hypoxia or recovery from anemia remain unexplained. We identified the hypoxia inducible factor (HIF) signaling pathway as a direct regulator of HbF expression in a CRISPR/Cas9 genetic screen. In RBC precursors, depletion of the von Hippel–Lindau (VHL) E3 ligase stabilized its ubiquitination target HIF1a to induce g-globin gene transcription. Mechanistically, HIF1a-HIF1bheterodimers bound cognate DNA elements in BGLT3, a long-noncoding RNA gene located 2.7 kb downstream of the tandem g-globin genes. This was followed by recruitment of transcriptional activators, chromatin opening, and increased long-range interactions between the g-globin genes and their upstream enhancer. These effects were recapitulated by hypoxia or inhibition of prolyl hydroxylase domain (PHD) enzymes that target HIF1a for ubiquitination. Our findings link globin gene regulation with canonical hypoxia adaptation, elucidate a mechanism for HbF induction during stress erythropoiesis, and identify a novel therapeutic approach for β-hemoglobinopathies.

Project description:Longstanding observations that fetal hemoglobin (HbF, a2g2) expression is reactivated in postnatal red blood cells (RBCs) during hypoxia or recovery from anemia remain unexplained. We identified the hypoxia inducible factor (HIF) signaling pathway as a direct regulator of HbF expression in a CRISPR/Cas9 genetic screen. In RBC precursors, depletion of the von Hippel–Lindau (VHL) E3 ligase stabilized its ubiquitination target HIF1a to induce g-globin gene transcription. Mechanistically, HIF1a-HIF1bheterodimers bound cognate DNA elements in BGLT3, a long-noncoding RNA gene located 2.7 kb downstream of the tandem g-globin genes. This was followed by recruitment of transcriptional activators, chromatin opening, and increased long-range interactions between the g-globin genes and their upstream enhancer. These effects were recapitulated by hypoxia or inhibition of prolyl hydroxylase domain (PHD) enzymes that target HIF1a for ubiquitination. Our findings link globin gene regulation with canonical hypoxia adaptation, elucidate a mechanism for HbF induction during stress erythropoiesis, and identify a novel therapeutic approach for β-hemoglobinopathies.

Project description:Longstanding observations that fetal hemoglobin (HbF, a2g2) expression is reactivated in postnatal red blood cells (RBCs) during hypoxia or recovery from anemia remain unexplained. We identified the hypoxia inducible factor (HIF) signaling pathway as a direct regulator of HbF expression in a CRISPR/Cas9 genetic screen. In RBC precursors, depletion of the von Hippel–Lindau (VHL) E3 ligase stabilized its ubiquitination target HIF1a to induce g-globin gene transcription. Mechanistically, HIF1a-HIF1bheterodimers bound cognate DNA elements in BGLT3, a long-noncoding RNA gene located 2.7 kb downstream of the tandem g-globin genes. This was followed by recruitment of transcriptional activators, chromatin opening, and increased long-range interactions between the g-globin genes and their upstream enhancer. These effects were recapitulated by hypoxia or inhibition of prolyl hydroxylase domain (PHD) enzymes that target HIF1a for ubiquitination. Our findings link globin gene regulation with canonical hypoxia adaptation, elucidate a mechanism for HbF induction during stress erythropoiesis, and identify a novel therapeutic approach for β-hemoglobinopathies.

Project description:Hemoglobinopathies, including sickle cell disease and _-thalassemia, are global public health concerns. Induction of fetal-type hemoglobin (HbF) is a promising means to treat these disorders; however, precisely how HbF expression is silenced in adult erythroid cells is not fully understood. Here, we show that the LRF/ZBTB7A transcription factor is a potent repressor of HbF production. LRF inactivation derepresses embryonic/fetal _-globin expression in mouse and human adult erythroid cells. We employed genome-wide analysis of the transcriptome, chromatin accessibility and LRF occupancy sites, and demonstrate that LRF occupies the _-globin loci and maintains nucleosome density necessary for _-globin silencing. LRF confers its repressive activity through a unique NuRD repressor complex independent of BCL11A. Strikingly, human erythroid lines lacking both LRF and BCL11A exhibited almost a complete switch in expression from adult- to fetal-type globin, suggesting that these two factors cumulatively represent the near entirety of _-globin repressive activity in adult erythroid cells. RNA-seq, LRF ChIP-seq and ATAC-seq assays were used to investigtae LRF binding, effect of LRF depletion on transcription and chromatin landscape in mouse and human cells.

Project description:Chromatin structure is tightly intertwined with transcription regulation. Here we compared the chromosomal architectures of fetal and adult human erythroblasts and find that globally, chromatin structures and compartments A/B are highly similar at both developmental stages. At a finer scale, we detect distinct folding patterns at the developmentally controlled b-globin locus. Specifically, new fetal stage-specific contacts are uncovered between a region separating the fetal (g-) and adult (b-) globin genes (encompassing the HBBP1 and BGLT3 non-coding genes) and two distal chromosomal sites (HS5 and 3'HS1) that flank the locus. In contrast, in adult cells the HBBP1-BGLT3 region contacts the embryonic e-globin gene, physically separating the fetal globin genes from the enhancer (LCR). Removal of the HBBP1 gene strongly reactivates g-globin expression, accompanied by increased LCR-g-globin and decreased BGLT3-e-globin interactions, mimicking the effects of deleting the fetal globin repressor BCL11A. Our results uncover a new critical regulatory region as a potential target for therapeutic genome editing for hemoglobinopathies and highlight the power of chromosome conformation analysis in discovering new cis control elements.

Project description:Chromatin structure is tightly intertwined with transcription regulation. Here we compared the chromosomal architectures of fetal and adult human erythroblasts and find that globally, chromatin structures and compartments A/B are highly similar at both developmental stages. At a finer scale, we detect distinct folding patterns at the developmentally controlled b-globin locus. Specifically, new fetal stage-specific contacts are uncovered between a region separating the fetal (g-) and adult (b-) globin genes (encompassing the HBBP1 and BGLT3 non-coding genes) and two distal chromosomal sites (HS5 and 3'HS1) that flank the locus. In contrast, in adult cells the HBBP1-BGLT3 region contacts the embryonic e-globin gene, physically separating the fetal globin genes from the enhancer (LCR). Removal of the HBBP1 gene strongly reactivates g-globin expression, accompanied by increased LCR-g-globin and decreased BGLT3-e-globin interactions, mimicking the effects of deleting the fetal globin repressor BCL11A. Our results uncover a new critical regulatory region as a potential target for therapeutic genome editing for hemoglobinopathies and highlight the power of chromosome conformation analysis in discovering new cis control elements.

Project description:Chromatin structure is tightly intertwined with transcription regulation. Here we compared the chromosomal architectures of fetal and adult human erythroblasts and find that globally, chromatin structures and compartments A/B are highly similar at both developmental stages. At a finer scale, we detect distinct folding patterns at the developmentally controlled b-globin locus. Specifically, new fetal stage-specific contacts are uncovered between a region separating the fetal (g-) and adult (b-) globin genes (encompassing the HBBP1 and BGLT3 non-coding genes) and two distal chromosomal sites (HS5 and 3'HS1) that flank the locus. In contrast, in adult cells the HBBP1-BGLT3 region contacts the embryonic e-globin gene, physically separating the fetal globin genes from the enhancer (LCR). Removal of the HBBP1 gene strongly reactivates g-globin expression, accompanied by increased LCR-g-globin and decreased BGLT3-e-globin interactions, mimicking the effects of deleting the fetal globin repressor BCL11A. Our results uncover a new critical regulatory region as a potential target for therapeutic genome editing for hemoglobinopathies and highlight the power of chromosome conformation analysis in discovering new cis control elements.

Project description:Chromatin structure is tightly intertwined with transcription regulation. Here we compared the chromosomal architectures of fetal and adult human erythroblasts and find that globally, chromatin structures and compartments A/B are highly similar at both developmental stages. At a finer scale, we detect distinct folding patterns at the developmentally controlled b-globin locus. Specifically, new fetal stage-specific contacts are uncovered between a region separating the fetal (g-) and adult (b-) globin genes (encompassing the HBBP1 and BGLT3 non-coding genes) and two distal chromosomal sites (HS5 and 3'HS1) that flank the locus. In contrast, in adult cells the HBBP1-BGLT3 region contacts the embryonic e-globin gene, physically separating the fetal globin genes from the enhancer (LCR). Removal of the HBBP1 gene strongly reactivates g-globin expression, accompanied by increased LCR-g-globin and decreased BGLT3-e-globin interactions, mimicking the effects of deleting the fetal globin repressor BCL11A. Our results uncover a new critical regulatory region as a potential target for therapeutic genome editing for hemoglobinopathies and highlight the power of chromosome conformation analysis in discovering new cis control elements.

Project description:The fetal-to-adult hemoglobin switch is regulated in a developmental stage-specific manner and reactivation of fetal hemoglobin (HbF) has therapeutic potential for β-hemoglobinopathies. Although BCL11A and ZBTB7A interact with their coregulators, reportedly mediating most γ-globin transcriptional silencing in erythroid in trans, and in cis, the molecular mechanism underlying the epigenetic dysregulation of the switch remains largely unclear. Here we showed that epigenetic inactivation of an ETS2 repressor factor (ERF) reactivates γ-globin expression during stress erythropoiesis, and ERF depletion elevates γ-globin in erythroid cells and in erythroid progenies from the edited HSPCs engrafted into immunodeficient mice. ERF represses γ-globin by directly binding to two motifs regulating HBG expression, independently of the major HbF repressors BCL11A and ZBTB7A. We further uncovered that an lncRNA, RP11-196G18.23 mediates ERF promoter hypermethylation resulting in reactivation of g-globin. Herein, the epigenetic alterations were identified as novel modulators ameliorating the severity of b-thalassemia, thus providing novel therapeutic targets for β-hemoglobinopathies.

Project description:The fetal-to-adult hemoglobin switch is regulated in a developmental stage-specific manner and reactivation of fetal hemoglobin (HbF) has therapeutic potential for β-hemoglobinopathies. Although BCL11A and ZBTB7A interact with their coregulators, reportedly mediating most γ-globin transcriptional silencing in erythroid in trans, and in cis, the molecular mechanism underlying the epigenetic dysregulation of the switch remains largely unclear. Here we showed that epigenetic inactivation of an ETS2 repressor factor (ERF) reactivates γ-globin expression during stress erythropoiesis, and ERF depletion elevates γ-globin in erythroid cells and in erythroid progenies from the edited HSPCs engrafted into immunodeficient mice. ERF represses γ-globin by directly binding to two motifs regulating HBG expression, independently of the major HbF repressors BCL11A and ZBTB7A. We further uncovered that an lncRNA, RP11-196G18.23 mediates ERF promoter hypermethylation resulting in reactivation of g-globin. Herein, the epigenetic alterations were identified as novel modulators ameliorating the severity of b-thalassemia, thus providing novel therapeutic targets for β-hemoglobinopathies.