Project description:In order to elucidate the molecular mechanism giving rise to the rare In(Lu) type of Lu(a-b-) blood group phenotype we compared the transcriptome of normal and In(Lu) erythroblasts at different stages of maturation. Many erythroid-specific genes had reduced transcript levels suggesting the phenotype resulted from a transcription factor abnormality. A search for mutations in erythroid transcription factors revealed mutations in the promoter or coding sequence of EKLF in 21 of 24 individuals with the In(Lu) phenotype. In all cases the mutant EKLF allele occurred in the presence of a normal EKLF allele. Individuals with the In(Lu) phenotype have no reported pathology indicating that one functional EKLF allele is sufficient to sustain human erythropoiesis. These data provide the first description of inactivating mutations in human EKLF and the first demonstration of a blood group phenotype resulting from mutations in a transcription factor. Keywords: Time course and cell type comparison.

Project description:Erythropoiesis is dependent on the activity of transcription factors, including the erythroid-specific erythroid Kruppel-like factor (EKLF). ChIP followed by massively parallel sequencing (ChIP-Seq) is a powerful, unbiased method to map transfactor occupancy. We used ChIP-Seq to study the interactome of EKLF in mouse erythroid progenitor cells and more differentiated erythroblasts. We correlated these results with the nuclear distribution of EKLF, RNA-Seq analysis of the transcriptome, and the occupancy of other erythroid transcription factors. In progenitor cells, EKLF is found predominantly at the periphery of the nucleus, where EKLF primarily occupies the promoter regions of genes and acts as a transcriptional activator. In erythroblasts, EKLF is distributed throughout the nucleus, and erythroblast-specific EKLF occupancy is predominantly in intragenic regions. In progenitor cells, EKLF modulates general cell growth and cell cycle regulatory pathways, whereas in erythroblasts EKLF is associated with repression of these pathways. The EKLF interactome shows very little overlap with the interactomes of GATA1, GATA2, or TAL1, leading to a model in which EKLF directs programs that are independent of those regulated by the GATA factors or TAL1. (Blood.2011;118(17):e139-e148) We used ChIP-Seq to study the interactome of EKLF in mouse erythroid progenitor cells and more differentiated erythroblasts and RNA-Seq analysis of the transcriptome.

Project description:Erythropoiesis is dependent on the activity of transcription factors, including the erythroid-specific erythroid Kruppel-like factor (EKLF). ChIP followed by massively parallel sequencing (ChIP-Seq) is a powerful, unbiased method to map transfactor occupancy. We used ChIP-Seq to study the interactome of EKLF in mouse erythroid progenitor cells and more differentiated erythroblasts. We correlated these results with the nuclear distribution of EKLF, RNA-Seq analysis of the transcriptome, and the occupancy of other erythroid transcription factors. In progenitor cells, EKLF is found predominantly at the periphery of the nucleus, where EKLF primarily occupies the promoter regions of genes and acts as a transcriptional activator. In erythroblasts, EKLF is distributed throughout the nucleus, and erythroblast-specific EKLF occupancy is predominantly in intragenic regions. In progenitor cells, EKLF modulates general cell growth and cell cycle regulatory pathways, whereas in erythroblasts EKLF is associated with repression of these pathways. The EKLF interactome shows very little overlap with the interactomes of GATA1, GATA2, or TAL1, leading to a model in which EKLF directs programs that are independent of those regulated by the GATA factors or TAL1. (Blood.2011;118(17):e139-e148)

Project description:Transcriptome analysis of total RNA samples from FACS sorted erythroblasts To further verify the role of cytokine triggered inflammation signaling in erythropoiesis, we decided to follow the profile of gene expression in erythroblasts using DNA microarrays. To elucidated the gene expression pattern in cytokine, especially IL-6, challenged erythroblasts, in vitro IL-6 treated erythroblasts in EPO containing medium both at day 1 and day 2 were collected. We also sorted the erythroblasts at different stages (Proerythroblasts(I),Basophilic(II) and polychromatic(III) erythroblasts,Orthochromatic(IV) erythroblasts) from both DWT and DKO bone marrow cells through fluorescence activated cell sorting. Total RNA were extracted and processed to hybridize with Affymetrix mouse Clariom S microarrays.

Project description:In absence of selenium, proerythroblasts exhibited delay in differentation into basophilic erythroblasts during phenylhydrazine induced stress erythropoiesis. This microarray project was aiming to explore gene expression patterns in erythroblasts in the function of selenium status.

Project description:Erythroblasts

Project description:Erythropoietic homeostasis is coordinated by erythroblast development and challenged by a number of genetic diseases including polycythemia vera. Erythroblasts and central macrophages form erythroblastic islands to provide a specific environment for erythropoiesis. However, how central macrophages interplay with erythroblasts during erythropoiesis remains to be further clarified. In this study, we found that erythroid-specific TFPI knockout decreased the number of erythroblasts under both steady-state and stress conditions, and the function of TFPI in erythropoiesis was mediated by macrophages. TFPI affects the downstream heme synthesis pathway of central macrophages, as shown by RNA sequencing analysis, and the deletion of TFPI reduced the heme content of macrophages by inhibiting ferrochelatase (Fech) expression. Our results show that TFPI plays an important role in the regulation of erythropoiesis and reveal a new mechanism of interplay between erythroblasts and macrophages. TFPI will also provide a new potential treatment strategy for polycythemia vera.

Project description:In humans, fetal erythropoiesis takes place in the liver whereas adult erythropoiesis occurs in the bone marrow. Fetal and adult erythroid cells are not only produced at different sites, but are also distinguished by their respective transcriptional program. In particular, whereas fetal erythroid cells express γ-globin chains to produce fetal hemoglobin (HbF), adult cells express β-globin chains to generate adult hemoglobin. Understanding the transcriptional regulation of the fetal-to-adult hemoglobin switch is clinically important as re-activation of HbF production in adult erythroid cells would represent a promising therapy for the hemoglobin disorders sickle cell disease and β-thalassemia. We used RNA-sequencing to measure global gene and microRNA (miRNA) expression in human erythroblasts derived ex vivo from fetal liver (N = 12 donors) and bone marrow (N = 12 donors) hematopoietic stem/progenitor cells. We identified 7,829 transcripts and 402 miRNA that were differentially expressed (false discovery rate (FDR) <5%). The miRNA expression patterns were replicated in an independent collection of human erythroblasts using a different technology. By combining gene and miRNA expression data, we developed transcriptional networks which show substantial differences between fetal and adult human erythroblasts. Our analyses highlighted the miRNAs at the imprinted 14q32 locus in fetal erythroblasts and the let-7 miRNA family in adult erythroblasts as key regulators of stage-specific erythroid transcriptional programs. Altogether, our results provide a comprehensive resource to prioritize genes that may modify clinical severity in red blood cell (RBC) disorders, or genes that might be implicated in erythropoiesis by genome-wide association studies of RBC traits.

Project description:Erythroblasts from human cord blood

Project description:Anemia is a significant cause of morbidity and mortality in myeloid malignances. Cytogenetic changes are recurrent within malignant hematopoietic stem and progenitor cells, yet their role in anemia pathogenesis remains unknown. One recurrent karyotypic abnormality in myeloid neoplasms is the deletion of part or all of chromosome 7 [-7/del(7q)], which harbors the transcription factor and tumor suppressor gene, CUX1. CUX1 knockdown mouse models develop myeloid disease similar to that seen in humans, including a spontaneous, cell intrinsic, and lethal anemia that develops with age. Here, we elucidate the cellular and molecular mechanisms by which CUX1 regulates erythropoiesis. We demonstrate CUX1 knockdown mice have an aberrant stress erythropoiesis response and decreased survival after acute anemia induction. CUX1 insufficient erythroblasts undergo accelerated cell cycling and increased apoptosis. In line with these phenotypes, transcriptome profiling indicates that CUX1-knockdown elicits increased proliferation and decreased erythroid differentiation gene signatures. ATAC-sequencing demonstrated dramatic, global chromatin opening in CUX1-knockdown erythroblasts. As measured by fluorescence lifetime imaging, this increased chromatin accessibility is concomitant with a disruption in nuclear condensation, which is normally requisite in mammalian erythroblasts for nuclear eviction and terminal differentiation. Finally, we show that CUX1 mediates chromatin compaction by promoting histone deacetylation. Thus, rather than a transcriptional role, our data implicate in an epigenetic regulatory role for CUX1 in erythropoiesis. Furthermore, these results suggest therapeutic targeting of epigenetic regulators, such as histone acetyl transferases, may have clinical benefit for the anemias associated with loss of CUX1.