Project description:BCL11A, the major regulator of HbF(α2γ2) level, represses γ-globin expression through direct promoter binding in adult erythroid cells in a switch to adult adult-type HbA (α2β2) production. Yet, the mechanism remains unclear. To uncover how BCL11A initiates repression, we used CRISPR/Cas9 and dCas9 screens to dissect the γ-globin promoters and identified an apparent activator element near the BCL11A binding region. Using CUT&RUN and base editing approaches, we demonstrate that this element, the proximal CCAAT box, is the binding site of transcription activator NF-Y. BCL11A competes with NF-Y binding through steric hindrance to initiate γ-globin repression, and the distance between the two motifs is critical for direct competition. Occupancy of NF-Y is rapidly established upon BCL11A depletion, and precedes γ-globin derepression and LCR-globin loop formation. Our findings reveal that the critical fetal-to-adult hemoglobin switch is initiated by the competition between transcription factors within a discrete region in the γ-globin promoters.

Project description:BCL11A, the major regulator of HbF(α2γ2) level, represses γ-globin expression through direct promoter binding in adult erythroid cells in a switch to adult adult-type HbA (α2β2) production. Yet, the mechanism remains unclear. To uncover how BCL11A initiates repression, we used CRISPR/Cas9 and dCas9 screens to dissect the γ-globin promoters and identified an apparent activator element near the BCL11A binding region. Using CUT&RUN and base editing approaches, we demonstrate that this element, the proximal CCAAT box, is the binding site of transcription activator NF-Y. BCL11A competes with NF-Y binding through steric hindrance to initiate γ-globin repression, and the distance between the two motifs is critical for direct competition. Occupancy of NF-Y is rapidly established upon BCL11A depletion, and precedes γ-globin derepression and LCR-globin loop formation. Our findings reveal that the critical fetal-to-adult hemoglobin switch is initiated by the competition between transcription factors within a discrete region in the γ-globin promoters.

Project description:BCL11A, the major regulator of HbF(α2γ2) level, represses γ-globin expression through direct promoter binding in adult erythroid cells in a switch to adult adult-type HbA (α2β2) production. Yet, the mechanism remains unclear. To uncover how BCL11A initiates repression, we used CRISPR/Cas9 and dCas9 screens to dissect the γ-globin promoters and identified an apparent activator element near the BCL11A binding region. Using CUT&RUN and base editing approaches, we demonstrate that this element, the proximal CCAAT box, is the binding site of transcription activator NF-Y. BCL11A competes with NF-Y binding through steric hindrance to initiate γ-globin repression, and the distance between the two motifs is critical for direct competition. Occupancy of NF-Y is rapidly established upon BCL11A depletion, and precedes γ-globin derepression and LCR-globin loop formation. Our findings reveal that the critical fetal-to-adult hemoglobin switch is initiated by the competition between transcription factors within a discrete region in the γ-globin promoters.

Project description:BCL11A, the major regulator of HbF(α2γ2) level, represses γ-globin expression through direct promoter binding in adult erythroid cells in a switch to adult adult-type HbA (α2β2) production. Yet, the mechanism remains unclear. To uncover how BCL11A initiates repression, we used CRISPR/Cas9 and dCas9 screens to dissect the γ-globin promoters and identified an apparent activator element near the BCL11A binding region. Using CUT&RUN and base editing approaches, we demonstrate that this element, the proximal CCAAT box, is the binding site of transcription activator NF-Y. BCL11A competes with NF-Y binding through steric hindrance to initiate γ-globin repression, and the distance between the two motifs is critical for direct competition. Occupancy of NF-Y is rapidly established upon BCL11A depletion, and precedes γ-globin derepression and LCR-globin loop formation. Our findings reveal that the critical fetal-to-adult hemoglobin switch is initiated by the competition between transcription factors within a discrete region in the γ-globin promoters.

Project description:The switch from fetal to adult hemoglobin production has been studied in great depth in part because of its relevance to the treatment of hemolobinopathies. Transcription factor BCL11A, which is essential for repression of the fetal beta-type globin (γ-globin) genes after birth, is largely controlled at the level of transcription but the mechanism of BCL11A developmental control is unknown. Here, using a CRISPR-Cas9 screen in human erythroblasts, we identify transcription factor HIC2 as a repressor of BCL11A transcription. HIC2 and BCL11A expression are anti-correlated in fetal and adult erythroblasts. Forced expression of HIC2 in adult erythroblasts silences BCL11A transcription and markedly induces γ-globin expression. HIC2 binds selectively to constituent erythroid developmental BCL11A enhancer to reduce chromatin accessibility and impair access by transcription factor GATA1, resulting in loss of enhancer activity and enhancer-promoter contacts. Conversely, loss of HIC2 in fetal erythroblasts increases enhancer accessibility, enables GATA1 binding and induces BCL11A transcription. HIC2 is unveiled as a critical evolutionarily conserved regulator of globin gene switching by imposing developmental control on the BCL11A gene.

Project description:The switch from fetal to adult hemoglobin production has been studied in great depth in part because of its relevance to the treatment of hemolobinopathies. Transcription factor BCL11A, which is essential for repression of the fetal beta-type globin (γ-globin) genes after birth, is largely controlled at the level of transcription but the mechanism of BCL11A developmental control is unknown. Here, using a CRISPR-Cas9 screen in human erythroblasts, we identify transcription factor HIC2 as a repressor of BCL11A transcription. HIC2 and BCL11A expression are anti-correlated in fetal and adult erythroblasts. Forced expression of HIC2 in adult erythroblasts silences BCL11A transcription and markedly induces γ-globin expression. HIC2 binds selectively to constituent erythroid developmental BCL11A enhancer to reduce chromatin accessibility and impair access by transcription factor GATA1, resulting in loss of enhancer activity and enhancer-promoter contacts. Conversely, loss of HIC2 in fetal erythroblasts increases enhancer accessibility, enables GATA1 binding and induces BCL11A transcription. HIC2 is unveiled as a critical evolutionarily conserved regulator of globin gene switching by imposing developmental control on the BCL11A gene.

Project description:The switch from fetal to adult hemoglobin production has been studied in great depth in part because of its relevance to the treatment of hemolobinopathies. Transcription factor BCL11A, which is essential for repression of the fetal beta-type globin (γ-globin) genes after birth, is largely controlled at the level of transcription but the mechanism of BCL11A developmental control is unknown. Here, using a CRISPR-Cas9 screen in human erythroblasts, we identify transcription factor HIC2 as a repressor of BCL11A transcription. HIC2 and BCL11A expression are anti-correlated in fetal and adult erythroblasts. Forced expression of HIC2 in adult erythroblasts silences BCL11A transcription and markedly induces γ-globin expression. HIC2 binds selectively to constituent erythroid developmental BCL11A enhancer to reduce chromatin accessibility and impair access by transcription factor GATA1, resulting in loss of enhancer activity and enhancer-promoter contacts. Conversely, loss of HIC2 in fetal erythroblasts increases enhancer accessibility, enables GATA1 binding and induces BCL11A transcription. HIC2 is unveiled as a critical evolutionarily conserved regulator of globin gene switching by imposing developmental control on the BCL11A gene.

Project description:The switch from fetal to adult hemoglobin production has been studied in great depth in part because of its relevance to the treatment of hemolobinopathies. Transcription factor BCL11A, which is essential for repression of the fetal beta-type globin (γ-globin) genes after birth, is largely controlled at the level of transcription but the mechanism of BCL11A developmental control is unknown. Here, using a CRISPR-Cas9 screen in human erythroblasts, we identify transcription factor HIC2 as a repressor of BCL11A transcription. HIC2 and BCL11A expression are anti-correlated in fetal and adult erythroblasts. Forced expression of HIC2 in adult erythroblasts silences BCL11A transcription and markedly induces γ-globin expression. HIC2 binds selectively to constituent erythroid developmental BCL11A enhancer to reduce chromatin accessibility and impair access by transcription factor GATA1, resulting in loss of enhancer activity and enhancer-promoter contacts. Conversely, loss of HIC2 in fetal erythroblasts increases enhancer accessibility, enables GATA1 binding and induces BCL11A transcription. HIC2 is unveiled as a critical evolutionarily conserved regulator of globin gene switching by imposing developmental control on the BCL11A gene.

Project description:The switch from fetal to adult hemoglobin production has been studied in great depth in part because of its relevance to the treatment of hemolobinopathies. Transcription factor BCL11A, which is essential for repression of the fetal beta-type globin (γ-globin) genes after birth, is largely controlled at the level of transcription but the mechanism of BCL11A developmental control is unknown. Here, using a CRISPR-Cas9 screen in human erythroblasts, we identify transcription factor HIC2 as a repressor of BCL11A transcription. HIC2 and BCL11A expression are anti-correlated in fetal and adult erythroblasts. Forced expression of HIC2 in adult erythroblasts silences BCL11A transcription and markedly induces γ-globin expression. HIC2 binds selectively to constituent erythroid developmental BCL11A enhancer to reduce chromatin accessibility and impair access by transcription factor GATA1, resulting in loss of enhancer activity and enhancer-promoter contacts. Conversely, loss of HIC2 in fetal erythroblasts increases enhancer accessibility, enables GATA1 binding and induces BCL11A transcription. HIC2 is unveiled as a critical evolutionarily conserved regulator of globin gene switching by imposing developmental control on the BCL11A gene.

Project description:During human development, there is a switch in the erythroid compartment at birth that results in silencing of expression of fetal hemoglobin (HbF). Reversal of this silencing has been shown to be effective in overcoming the pathophysiologic defect in sickle cell anemia. Among the many transcription factors and epigenetic effectors that are known to mediate HbF silencing, two of the most potent are BCL11A and MBD2-NuRD. In this report we present direct evidence that MBD2- NuRD occupies the γ-globin gene promoter in adult erythroid cells and positions a nucleosome there that results in a closed chromatin conformation that prevents binding of the transcriptional activator, NF-Y. We show that the specific isoform, MBD2a, is required for the formation and stable occupancy of this repressor complex that includes BCL11A, MBD2a-NuRD and the arginine methyltransferase, PRMT5. The methyl cytosine binding preference and the arginine rich (GR) domain of MBD2a are required for high affinity binding to methylated γ-globin gene proximal promoter DNA sequences. Mutation of the methyl cytosine binding domain of MBD2 results in a variable but consistent loss of γ-globin gene silencing, in support of the importance of promoter methylation. The GR domain of MBD2a is also required for recruitment of PRMT5, which in turn results in placement of the repressive chromatin mark H3K8me2s at the promoter. These findings 2 support a unified model that integrates the respective roles of BCL11A, MBD2a-NuRD, PRMT5 and DNA methylation in HbF silencing.