Project description:To explore the mechanisms controlling erythroid differentiation and development in human, we analyzed the genome-wide transcription dynamics that occurs during the differentiation of HESCs into the erythroid lineage and development of embryonic to adult erythropoiesis using high throughput sequencing technology. Undifferentiated HESCs as well as erythroid cells at three developmental stages-ESER (embryonic stage), FLER (fetal stage) and PBER (adult stage)-were analyzed. Our findings revealed that the number of expressed genes decreased during the differentiation, while the total expression intensity increased. At the 3 transitions (HESC-ESER, ESER-FLER and FLER-PBER), differential expression of many types of genes was observed at every transition. These differentially expressed genes were involved in maintaining the pluripotency of stem cells, early erythroid specification, rapid cell growth and enucleation potential. In addition, differentially expressed genes were found to constitute networks and central nodes at each transition. Clusters of genes in some chromosomal regions switched between expression and silence. We also discovered that differentially expressed genes constituted networks and central nodes of them in each transition. Our studies provide a fundamental basis for further investigation of erythroid differentiation and development. Compare the transcriptome of embryonic stem cells and three erythroid cell types at different developmental stages

Project description:Terminal differentiation is characterized by a respecification of the global protein complement, as epitomized by erythrocytes, whose cytosol is ~98% globin. Remodeling of the proteome involves programmed elimination of generic cellular constituents in parallel with synthesis of cell-type-specific proteins. The erythroid proteome undergoes a rapid transition at the reticulocyte stage; however, the mechanisms driving elimination of preexisting cytosolic proteins are unidentified. UBE2O is a ubiquitin-conjugating enzyme expressed at elevated levels during late stage erythropoiesis. A Ube2o null mutation in mice results in anemia. Proteomic analysis of this mutant suggests that UBE2O is a broad-spectrum ubiquitinating enzyme that remodels the erythroid proteome. In particular, a hallmark of the reticulocyte to mature erythrocyte transition—ribosome elimination—is defective in Ube2o-/- mutants. UBE2O recognizes ribosomal proteins and other substrates directly, targeting them to proteasomes for degradation. Thus, in reticulocytes, and perhaps other highly differentiated cells, the induction of ubiquitinating factors may drive the transition from a complex to a simple proteome.

Project description:Identification of differentially expressed genes in runx1-/- primitive erythroid

Project description:In this study, we analyzed the genome-wide miRNAs dynamics that occur during the differentitation of HESCs into the erythroid lineage using high throughput sequencing technology. Undifferentiated HESCs as well as erythroid cells at three developmental stages-ESER (embryonic stage), FLER (fetal stage) and PBER (adult stage) were analyzed.

Project description:Genes differentially expressed during early osteoblast (OB) differentiation

Project description:While the transcriptional network of human embryonic stem cells (hESCs) has been extensively studied, relatively little is known about how post-transcriptional modulations determine hESC function. RNA-binding proteins play central roles in RNA regulation, including translation and turnover. Here we show that the RNA-binding protein CSDE1 is highly expressed in hESCs to maintain their undifferentiated state and prevent default neural fate. Notably, loss of CSDE1 accelerates neural differentiation and potentiates neurogenesis. Conversely, ectopic expression of CSDE1 impairs neural differentiation. We find that CSDE1 post-transcriptionally modulates core components of multiple regulatory nodes of hESC identity, neuroectoderm commitment and neurogenesis. Among these key pro-neural/neuronal factors, CSDE1 binds fatty acid binding protein 7 (FABP7) and vimentin (VIM) mRNAs as well as transcripts involved in neuron projection development regulating their stability and translation. Thus, our results uncover CSDE1 as a central post-transcriptional regulator of hESC identity and neurogenesis. This proteomics dataset contains the data from co-immunopreciptation experiments using CSDE1 antibody in hESCs

Project description:While enucleation is a critical step in the terminal differentiation of human red blood cells, the molecular mechanisms underlying this unique process remain unclear. To investigate erythroblast enucleation, we studied the erythroid differentiation of human embryonic stem cells (hESCs), which provide a unique model for deeper understanding of the development and differentiation of multiple cell types. First, using a two-step protocol, we demonstrated that terminal erythroid differentiation from hESCs is directly dependent on the age of the embryoid bodies. Second, by choosing hESCs in two extreme conditions of erythroid culture, we obtained an original differentiation model which allows one to study the mechanisms underlying the enucleation of erythroid cells by analyzing the gene and miRNA (miR) expression profiles of cells from these two culture conditions. Third, using an integrated analysis of mRNA and miR expression profiles, we identified five miRs potentially involved in erythroblast enucleation. Finally, by selective knockdown of these five miRs we found miR-30a to be a regulator of erythroblast enucleation in hESCs. Refer to individual Series

Project description:We generated homozygous GATA2 knockout human embryonic stem cells (GATA2-/- hESCs) and analyzed their blood differentiation potential. Paritcularly at the hemogenic endothelium (HE) stage and hematopoietic progenitor cell (HPC) stage. Our result revealed that GATA2-/- hESCs displayed attenuated generation of CD34+CD43+ HPCs, due to the impairment of endothelial to hematopoietic transition (EHT). However, GATA2-/- hESCs retained the potential to generate erythroblasts, macrophages, but never granulocytes. Through RNA-Seq and further rescue experiment, we further identified that SPI1 was responsible for the defect of GATA2-/- hESCs in generation of CD34+CD43+ HPCs and granulocytes.

Project description:While enucleation is a critical step in the terminal differentiation of human red blood cells, the molecular mechanisms underlying this unique process remain unclear. To investigate erythroblast enucleation, we studied the erythroid differentiation of human embryonic stem cells (hESCs), which provide a unique model for deeper understanding of the development and differentiation of multiple cell types. First, using a two-step protocol, we demonstrated that terminal erythroid differentiation from hESCs is directly dependent on the age of the embryoid bodies. Second, by choosing hESCs in two extreme conditions of erythroid culture, we obtained an original differentiation model which allows one to study the mechanisms underlying the enucleation of erythroid cells by analyzing the gene and miRNA (miR) expression profiles of cells from these two culture conditions. Third, using an integrated analysis of mRNA and miR expression profiles, we identified five miRs potentially involved in erythroblast enucleation. Finally, by selective knockdown of these five miRs we found miR-30a to be a regulator of erythroblast enucleation in hESCs.

Project description:While enucleation is a critical step in the terminal differentiation of human red blood cells, the molecular mechanisms underlying this unique process remain unclear. To investigate erythroblast enucleation, we studied the erythroid differentiation of human embryonic stem cells (hESCs), which provide a unique model for deeper understanding of the development and differentiation of multiple cell types. First, using a two-step protocol, we demonstrated that terminal erythroid differentiation from hESCs is directly dependent on the age of the embryoid bodies. Second, by choosing hESCs in two extreme conditions of erythroid culture, we obtained an original differentiation model which allows one to study the mechanisms underlying the enucleation of erythroid cells by analyzing the gene and miRNA (miR) expression profiles of cells from these two culture conditions. Third, using an integrated analysis of mRNA and miR expression profiles, we identified five miRs potentially involved in erythroblast enucleation. Finally, by selective knockdown of these five miRs we found miR-30a to be a regulator of erythroblast enucleation in hESCs.