Project description:CTCF and cohesinSA-1 are regulatory proteins involved in a number of critical cellular processes including transcription, maintenance of chromatin domain architecture, and insulator function. To assess changes in the CTCF and cohesinSA-1 interactomes during erythropoiesis, chromatin immunoprecipitation coupled with high throughput sequencing and mRNA transcriptome analyses via RNA-seq were performed in primary human HSPC hematopoietic stem and progenitor cells (HSPC) and primary human erythroid cells from single donors. Sites of CTCF and cohesinSA-1 co-occupancy were enriched in gene promoters in HSPC and erythroid cells compared to single CTCF or cohesin sites. Cell type-specific CTCF sites in erythroid cells were linked to highly expressed genes, with the opposite pattern observed in HSPCs. Chromatin domains were identified by ChIP-seq with antibodies against trimethylated lysine 27 histone 3, a modification associated with repressive chromatin. Repressive chromatin domains increased in both number and size during hematopoiesis, with many more repressive domains in erythroid cells than HSPCs. CTCF and cohesinSA-1 marked the boundaries of these repressive chromatin domains in a cell-type specific manner. These genomic data support the hypothesis that CTCF and cohesinSA-1 have multiple roles in the regulation of gene expression during erythropoiesis including transcriptional regulation at gene promoters and maintenance of chromatin architecture. CD34+-selected stem and progenitor cells were expanded for three days in the absence of EPO. The cells were further cultured in the presence of EPO, and cells differentiated into R3/R4 nucleated erythroid cells. RNA was isolated from three biological replicates of each cell type and sequencing libraries were prepared from poly A selected RNA.

Project description:CTCF and cohesinSA-1 are regulatory proteins involved in a number of critical cellular processes including transcription, maintenance of chromatin domain architecture, and insulator function. To assess changes in the CTCF and cohesinSA-1 interactomes during erythropoiesis, chromatin immunoprecipitation coupled with high throughput sequencing and mRNA transcriptome analyses via RNA-seq were performed in primary human HSPC hematopoietic stem and progenitor cells (HSPC) and primary human erythroid cells from single donors. Sites of CTCF and cohesinSA-1 co-occupancy were enriched in gene promoters in HSPC and erythroid cells compared to single CTCF or cohesin sites. Cell type-specific CTCF sites in erythroid cells were linked to highly expressed genes, with the opposite pattern observed in HSPCs. Chromatin domains were identified by ChIP-seq with antibodies against trimethylated lysine 27 histone 3, a modification associated with repressive chromatin. Repressive chromatin domains increased in both number and size during hematopoiesis, with many more repressive domains in erythroid cells than HSPCs. CTCF and cohesinSA-1 marked the boundaries of these repressive chromatin domains in a cell-type specific manner. These genomic data support the hypothesis that CTCF and cohesinSA-1 have multiple roles in the regulation of gene expression during erythropoiesis including transcriptional regulation at gene promoters and maintenance of chromatin architecture. CD34+-selected stem and progenitor cells were expanded for three days in the absence of EPO. The cells were further cultured in the presence of EPO, and formaldehyde crosslinked chromatin was isolated after cells differentiated into R3/R4 nucleated erythroid cells. Chromatin Immunoprecipitation followed by sequencing (chIP-seq) was performed using antibodies against CTCF, Cohesin SA1 and H3K27me3, along with a total input control. Two replicates for CTCF and Cohesin SA1 were obtained.

Project description:CTCF and cohesinSA-1 are regulatory proteins involved in a number of critical cellular processes including transcription, maintenance of chromatin domain architecture, and insulator function. To assess changes in the CTCF and cohesinSA-1 interactomes during erythropoiesis, chromatin immunoprecipitation coupled with high throughput sequencing and mRNA transcriptome analyses via RNA-seq were performed in primary human HSPC hematopoietic stem and progenitor cells (HSPC) and primary human erythroid cells from single donors. Sites of CTCF and cohesinSA-1 co-occupancy were enriched in gene promoters in HSPC and erythroid cells compared to single CTCF or cohesin sites. Cell type-specific CTCF sites in erythroid cells were linked to highly expressed genes, with the opposite pattern observed in HSPCs. Chromatin domains were identified by ChIP-seq with antibodies against trimethylated lysine 27 histone 3, a modification associated with repressive chromatin. Repressive chromatin domains increased in both number and size during hematopoiesis, with many more repressive domains in erythroid cells than HSPCs. CTCF and cohesinSA-1 marked the boundaries of these repressive chromatin domains in a cell-type specific manner. These genomic data support the hypothesis that CTCF and cohesinSA-1 have multiple roles in the regulation of gene expression during erythropoiesis including transcriptional regulation at gene promoters and maintenance of chromatin architecture.

Project description:Preeclampsia (PE) has been associated with placental dysfunction, resulting in foetal hypoxia, accelerated erythropoiesis and increased erythroblast count in the umbilical cord blood (UCB). Although the detailed effects remain unknown, placental dysfunction can also cause inflammation, nutritional and oxidative stress in the fetus that can affect erythropoiesis. Here, we compared the expression of surface adhesion molecules and erythroid differentiation capacity of UCB hematopoietic stem/ progenitor cells (HSPCs), UCB erythroid profiles along with transcriptome and proteome of these cells between male and female foetuses from PE and normotensive pregnancies. While no significant differences were observed in UCB HSPC migration/ homing and in vitro erythroid colony differentiation, the UCB HSPC transcriptome and the proteomic profile of the in vitro differentiated erythroid cells differed between PE vs normotensive samples. Accordingly, despite absence of significant differences in the UCB erythroid populations in male or female foetuses from PE or normotensive pregnancies, transcriptional changes were observed during erythropoiesis, particularly affecting male foetuses. Pathway analysis suggested deregulation in mTORC1/AMPK signaling pathways controlling cell cycle, differentiation and protein synthesis. These results associate PE with transcriptional and proteomic changes in foetal HSPCs and erythroid cells that may underlie the higher erythroblast count in the UCB in PE.

Project description:The ubiquitously expressed transcription factor CTCF maintains higher-order chromatin structure in multiple cell types and species through well-established common mechanisms. Here we define a new role for CTCF in tissue-specific gene regulation revealed by serial examinations of genome-wide CTCF occupancy during red blood cell (RBC) differentiation of human CD34+ hematopoietic stem/progenitor cells (HSPCs). We identified 1753 dynamic, erythroid developmental stage-specific CTCF chromatin occupancy sites that occur through both direct DNA binding and indirectly via interactions with lineage-specific transcription factors. These dynamic sites display features of transcriptional enhancers, function as hubs of cis-regulatory elements (CREs) interactome, and are enriched for single nucleotide polymorphisms (SNPs) associated with RBC traits. Precise deletion of CTCF binding motifs from those dynamically bound sites alternated local CRE-interactions and disrupted erythropoiesis.  Our study highlights novel, lineage-specific functions for CTCF and provides new insights into how genetic variation regulates erythropoiesis

Project description:The ubiquitously expressed transcription factor CTCF maintains higher-order chromatin structure in multiple cell types and species through well-established common mechanisms. Here we define a new role for CTCF in tissue-specific gene regulation revealed by serial examinations of genome-wide CTCF occupancy during red blood cell (RBC) differentiation of human CD34+ hematopoietic stem/progenitor cells (HSPCs). We identified 1753 dynamic, erythroid developmental stage-specific CTCF chromatin occupancy sites that occur through both direct DNA binding and indirectly via interactions with lineage-specific transcription factors. These dynamic sites display features of transcriptional enhancers, function as hubs of cis-regulatory elements (CREs) interactome, and are enriched for single nucleotide polymorphisms (SNPs) associated with RBC traits. Precise deletion of CTCF binding motifs from those dynamically bound sites alternated local CRE-interactions and disrupted erythropoiesis.  Our study highlights novel, lineage-specific functions for CTCF and provides new insights into how genetic variation regulates erythropoiesis

Project description:The ubiquitously expressed transcription factor CTCF maintains higher-order chromatin structure in multiple cell types and species through well-established common mechanisms. Here we define a new role for CTCF in tissue-specific gene regulation revealed by serial examinations of genome-wide CTCF occupancy during red blood cell (RBC) differentiation of human CD34+ hematopoietic stem/progenitor cells (HSPCs). We identified 1753 dynamic, erythroid developmental stage-specific CTCF chromatin occupancy sites that occur through both direct DNA binding and indirectly via interactions with lineage-specific transcription factors. These dynamic sites display features of transcriptional enhancers, function as hubs of cis-regulatory elements (CREs) interactome, and are enriched for single nucleotide polymorphisms (SNPs) associated with RBC traits. Precise deletion of CTCF binding motifs from those dynamically bound sites alternated local CRE-interactions and disrupted erythropoiesis.  Our study highlights novel, lineage-specific functions for CTCF and provides new insights into how genetic variation regulates erythropoiesis

Project description:The ubiquitously expressed transcription factor CTCF maintains higher-order chromatin structure in multiple cell types and species through well-established common mechanisms. Here we define a new role for CTCF in tissue-specific gene regulation revealed by serial examinations of genome-wide CTCF occupancy during red blood cell (RBC) differentiation of human CD34+ hematopoietic stem/progenitor cells (HSPCs). We identified 1753 dynamic, erythroid developmental stage-specific CTCF chromatin occupancy sites that occur through both direct DNA binding and indirectly via interactions with lineage-specific transcription factors. These dynamic sites display features of transcriptional enhancers, function as hubs of cis-regulatory elements (CREs) interactome, and are enriched for single nucleotide polymorphisms (SNPs) associated with RBC traits. Precise deletion of CTCF binding motifs from those dynamically bound sites alternated local CRE-interactions and disrupted erythropoiesis.  Our study highlights novel, lineage-specific functions for CTCF and provides new insights into how genetic variation regulates erythropoiesis

Project description:Metabolic programs contribute to hematopoietic stem and progenitor cell (HSPC) fate, but it is not known whether the metabolic regulation of protein synthesis controls HSPC differentiation. Here, we show that SLC7A1/CAT1-dependent arginine uptake and its catabolism to the polyamine spermidine control human erythroid specification of HSPCs via activation of the eukaryotic translation initiation factor 5A (eIF5A). eIF5A activity is dependent on its hypusination, a post-translational modification resulting from the conjugation of the aminobutyl moiety of spermidine to lysine. Notably, attenuation of hypusine synthesis in erythroid progenitors by inhibition of deoxyhypusine synthase abrogates erythropoiesis but not myeloid cell differentiation. Proteomic profiling reveals mitochondrial translation to be a critical target of hypusinated eIF5A and accordingly, progenitors with decreased hypusine activity exhibit diminished oxidative phosphorylation. This impacted pathway is critical for eIF5A-regulated erythropoiesis as interventions augmenting mitochondrial function partially rescue human erythropoiesis under conditions of attenuated hypusination. Levels of mitochondrial ribosomal proteins were especially sensitive to the loss of hypusine and we find that the ineffective erythropoiesis linked to haploinsufficiency of RPS14 in del(5q) myelodysplastic syndrome is associated with a diminished pool of hypusinated eIF5A. Moreover, patients with RPL11-haploinsufficient Diamond-Blackfan anemia as well as CD34+ progenitors with downregulated RPL11 exhibit a markedly decreased hypusination in erythroid progenitors, concomitant with a loss of mitochondrial metabolism. Thus, eIF5A-dependent protein synthesis regulates human erythropoiesis and our data reveal a novel role for RPs in controlling eIF5A hypusination in HSPC, synchronizing mitochondrial metabolism with erythroid differentiation.

Project description:Mammalian erythroid cells development can be divided into three period: hematopoietic stem and progenitor cells (HSPC), erythroid progenitor (Ery-Pro) and erythroid precursor (Ery-Pre). To better understand human erythropoiesis and its regulation, we performed genome-wide studies of chromatin architecture, enhancer and select transcription factors binding, and transcriptomics profiling utilizing modified strategy to obtain defined progenitor and precursor populations from primary human erythroid cells. Integration and analysis of these data reveals that the TAD structure is stable but promoter - enhancer interactions are highly dynamic in a stage specific manner. Erythroid master regulator - GATA1 involves in the P-E interactions stepwisely. GATA1 binding is largely stable in erythroid progenitor and precursor, but dynamic GATA1 binding during this process regulate a productive erythroid gene expression and local chromatin rewiring. Additionally, we also have showed that dosage of GATA1 control the erythroid progenitor behavior and the erythroid progression. The valuable chromatin architecture and epigenome data will provide more comprehensive insight of human erythropoiesis and dynamic gene regulation of cellular differentiation even more broadly.