Project description:The generation of the hematopoietic stem cells (HSCs) from human pluripotent stem cells (hPSCs) is a major goal for regenerative medicine. HSCs derive from hemogenic endothelium (HE) in a retinoic acid (RA)-dependent manner1. While a WNT-dependent (WNTd) patterning of nascent mesoderm specifies clonally multipotent definitive HE from hPSCs2,3, this HE is functionally unresponsive to RA4. Here we show that WNTd mesoderm, prior to HE specification, is comprised of two distinct KDR+CD34negT+ populations. In a TGFb-independent manner, CXCR4negCYP26A1+ mesoderm is specified, which gives rise to HOXA+ multilineage definitive HE, in an RA-independent manner. In contrast, CXCR4+ALDH1A2+ mesoderm is specified in a TGFb-dependent manner, and gives rise to multilineage definitive HE in a stage-specific, RA-dependent manner. Further, this NOTCH-dependent HE harbored HOXA expression resembling fetal HE. This model of human hematopoietic development defines the mesodermal origins of multiple waves of hematopoiesis, and that RA-dependent hematopoietic development occurs prior to HE development.

Project description:The generation of the hematopoietic stem cells (HSCs) from human pluripotent stem cells (hPSCs) is a major goal for regenerative medicine. HSCs derive from hemogenic endothelium (HE) in a retinoic acid (RA)-dependent manner1. While a WNT-dependent (WNTd) patterning of nascent mesoderm specifies clonally multipotent definitive HE from hPSCs2,3, this HE is functionally unresponsive to RA4. Here we show that WNTd mesoderm, prior to HE specification, is comprised of two distinct KDR+CD34negT+ populations. In a TGFb-independent manner, CXCR4negCYP26A1+ mesoderm is specified, which gives rise to HOXA+ multilineage definitive HE, in an RA-independent manner. In contrast, CXCR4+ALDH1A2+ mesoderm is specified in a TGFb-dependent manner, and gives rise to multilineage definitive HE in a stage-specific, RA-dependent manner. Further, this NOTCH-dependent HE harbored HOXA expression resembling fetal HE. This model of human hematopoietic development defines the mesodermal origins of multiple waves of hematopoiesis, and that RA-dependent hematopoietic development occurs prior to HE development.

Project description:The production of definitive haematopoietic stem/progenitor cells from human pluripotent stem cells (hPSCs) remains a significant challenge. Using reporter lines to track the endothelial (SOX17) to haematopoietic (RUNX1C) transition, we found that hPSC differentiated in growth factor supplemented serum free medium generated RUNX1C+CD34+ clonogenic cells that homed to the bone marrow, but did not engraft. Compared to repopulation-competent cord blood CD34+ cells, RUNX1C+CD34+ progenitors lacked HOXA gene expression, indicating incorrect mesoderm patterning. This deficiency was ameliorated by a timed pulse of WNT activation combined with ACTIVIN antagonism. Significantly, these HOXA+ cultures now formed complex SOX17+ vessels that produced fetal liver-like haematopoietic cells, similar to the human aorta-gonad-mesonephros (AGM). Comparison of transcriptional profiles of these nascent haematopoietic stem/progenitors with cells isolated from human AGM confirmed significant similarities, consistent with the assignment of our in vitro generated cells to the definitive human haematopoietic lineage. Our findings argue that HOXA codes established early in differentiation predict cellular potential and provide correct cell patterning for the specification of definitive haematopoietic lineages from hPSCs.

Project description:The production of definitive haematopoietic stem/progenitor cells from human pluripotent stem cells (hPSCs) remains a significant challenge. Using reporter lines to track the endothelial (SOX17) to haematopoietic (RUNX1C) transition, we found that hPSC differentiated in growth factor supplemented serum free medium generated RUNX1C+CD34+ clonogenic cells that homed to the bone marrow, but did not engraft. Compared to repopulation-competent cord blood CD34+ cells, RUNX1C+CD34+ progenitors lacked HOXA gene expression, indicating incorrect mesoderm patterning. This deficiency was ameliorated by a timed pulse of WNT activation combined with ACTIVIN antagonism. Significantly, these HOXA+ cultures now formed complex SOX17+ vessels that produced fetal liver-like haematopoietic cells, similar to the human aorta-gonad-mesonephros (AGM). Comparison of transcriptional profiles of these nascent haematopoietic stem/progenitors with cells isolated from human AGM confirmed significant similarities, consistent with the assignment of our in vitro generated cells to the definitive human haematopoietic lineage. Our findings argue that HOXA codes established early in differentiation predict cellular potential and provide correct cell patterning for the specification of definitive haematopoietic lineages from hPSCs.

Project description:MYB is well recognized to be a key regulator of definitive hematopoiesis that plays an important role in the maintenance and multilineage differentiation of hematopoietic stem cells (HSCs). In the vertebrate developmental context, MYB is widely regarded dispensable for primitive hematopoiesis but critically required for the development of definitive hematopoiesis. To explore the role of MYB in human hematopoietic development we have inactivated the gene by bi-allelic TALEN-supported gene targeting in several lines of human embryonic stem cells (hESCs) and induced pluripotent stem cells (iPSCs), and subjected these cells to hematopoietic differentiation in well-defined cell culture conditions. Venus gene reporter was inserted into the knock-in allele to monitor MYB expression during the course of the hESC/iPSC differentiation. The gene reporter system showed that MYB is specifically expressed during hematopoietic commitment in the earliest primitive blood cells. Moreover, the level of MYB expression was highest at the commitment stage of differentiation and significantly decreased at the maturations stage. We found that MYB was not required for initial hematopoietic commitment of nascent mesoderm and emergence of primitive, yolk sac-type human hematopoietic progenitors. However, inactivation of MYB severely abrogated proliferation of the primitive erythroid and mixed erythroid-macrophage-megakaryocyte progenitors. In addition, MYB-negative hESC/iPSC lines demonstrated major defects in myeloid cell development and completely failed to generate mature granulocytes. Transposon-mediated rescue of MYB expression in MYB-null cells efficiently restored both the primitive hematopoietic progenitors and immature myeloid cells. Our data indicate that in contrast to its previously attributed exclusive role in definitive hematopoiesis, MYB is indispensable for primitive human hematopoiesis.

Project description:Proper Homeobox A (HoxA) cluster genes expression is essential for embryonic stem cells (ESCs) differentiation and individual development. However, the mechanisms controlling the precise spatiotemporal expression of HoxA cluster genes during early ESCs differentiation remain largely unknown. Here, we find a CTCF binding element (CBE+47kb) closest to the 3'-end of HoxA locus within a topologically associated domains (TAD) in ESCs. CRISPR-Cas9 mediated the CBE+47kb knockout significantly promotes expression of HoxA cluster genes and early ESCs differentiation induced by RA compared with wild type cells. In mechanism, we found that there was a significant differently long-range chromatin interactions between its adjacent enhancers and HoxA in CBE+47kb knockout cells through chromosome conformation capture assay (Capture-C), indicating that CBE+47kb can precisely organize interactions between its adjacent enhancers and HoxA chromatins. Furthermore, we also showed that its adjacent enhancers deletion shows significantly synthetic inhibition effect on HoxA genes expression, suggesting that these enhancers are required for RA-induced HoxA genes expression. Our study reveals that a new functional CBE+47 can regulate HoxA genes expression through orchestrating long-range chromatin interactions between its adjacent enhancers and HoxA, thus maintaining RA-induced early ESCs proper differentiation.

Project description:A comprehensive understanding of a lineage map and molecular mechanisms underlying lineage specification is fundamental to development. To this end, ETS transcription factor Etv2 functions as the master regulator of hematopoietic and endothelial cell formation. As such, Etv2 regulated hemangiogenesis provides an excellent model for assessing cell lineage specification. Herein, we generated several reporter embryonic stem (ES) cell lines to map developmental route pertaining to hemangiogenesis. We performed transcriptome analysis and high throughput CRISPR screening to further delineate molecular mechanisms regulating hemangiogenic lineage specification. We show a distinct lineage map of hemangiogenesis, in which hemangiogenic fate is specified not simply by the onset of Etv2 expression, but in a threshold-dependent manner. Importantly, VEGF-FLK1 signaling is necessary for efficiently achieving ETV2-threshold. Moreover, we find forkhead transcription factor Foxh1 to be required for FLK1 mesoderm formation. These studies provide a roadmap in hematopoietic and vascular cell generation and applications in regenerative medicine.

Project description:Definitive hematopoiesis emerges during embryogenesis via an endothelial-to-hematopoietic transition. We attempted to induce this process in mouse fibroblasts by screening a panel of factors for hemogenic activity. We identified a combination of four transcription factors, Gata2, Gfi1b, cFos, and Etv6 that efficiently induces endothelial-like precursor cells with the subsequent appearance of hematopoietic cells. The precursor cells express a human CD34 reporter, Sca1 and Prominin1 within a global endothelial transcription program. Emergent hematopoietic cells possess nascent/specifying hematopoietic stem cell gene expression profiles and cell surface phenotypes. After transgene silencing and reaggregation culture, the specified cells generate hematopoietic colonies in vitro. Thus, we have shown that a simple combination of transcription factors is sufficient to induce a complex, dynamic and multi-step developmental program in vitro. These findings provide insights into the specification of definitive hemogenesis and a platform for future development of patient-specific stem/progenitor cells as well as more differentiated blood products. mRNA-seq profiling on populations generated after transduction with Gata2, Gfi1b, cFos and Etv6 at day 20 and day 35.

Project description:Signaling pathway driven target gene transcriptions are critical for fate determination of embryonic stem cells (ESC), but enhancer architecture-dependent transcriptional regulation remains largely unclear in this process. Here, we described a complex enhancer architecture-dependent multilayered transcriptional regulation that orchestrates retinoic acid (RA) signal-induced early differentiation of ESC. Specifically, we identified Hoxa1 and lncRNA Halr1 as the direct downstream target genes of RA signal. Chromosome conformation capture based screens show that increased enhancer interactions promoted by RA signal are essential for Hoxa1 and Halr1 expressions during early ESC differentiation. Furthermore, we find that HOXA1 promotes Halr1 expression through direct binding to enhancers; conversely, absence of Halr1 RNA enhances interaction between Hoxa1 chromatin and multiple enhancers, but weakens interaction with HoxA cluster internal chromatin, thereby promoting RA signal-induced Hoxa1 overactivation and early differentiation of ESC. These results indicate that Halr1 binds to chromatin not only acts as a brake to orchestrate interaction between enhancers and Hoxa1 chromatin, but also acts as a binder to maintain chromatin interaction within HoxA cluster. In summary, these findings reveal a complex multilayered transcriptional regulation involving the synergistic regulation of enhancer, transcription factor and lncRNA, and that increases our understanding of the intrinsic molecular mechanisms of RA signal-induced ESC differentiation.

Project description:Definitive hematopoiesis emerges during embryogenesis via an endothelial-to-hematopoietic transition. We attempted to induce this process in mouse fibroblasts by screening a panel of factors for hemogenic activity. We identified a combination of four transcription factors, Gata2, Gfi1b, cFos, and Etv6 that efficiently induces endothelial-like precursor cells with the subsequent appearance of hematopoietic cells. The precursor cells express a human CD34 reporter, Sca1 and Prominin1 within a global endothelial transcription program. Emergent hematopoietic cells possess nascent/specifying hematopoietic stem cell gene expression profiles and cell surface phenotypes. After transgene silencing and reaggregation culture, the specified cells generate hematopoietic colonies in vitro. Thus, we have shown that a simple combination of transcription factors is sufficient to induce a complex, dynamic and multi-step developmental program in vitro. These findings provide insights into the specification of definitive hemogenesis and a platform for future development of patient-specific stem/progenitor cells as well as more differentiated blood products.