Summary Hematopoietic potential arises in mammalian embryos before adult-repopulating hematopoietic stem cells (HSCs). At E9.5, we show the first murine definitive erythro-myeloid progenitors (EMPs) have an immunophenotype distinct from primitive hematopoietic progenitors, maturing megakaryocytes and macrophages, and rare B cell potential. EMPs emerge in the yolk sac with erythroid and broad myeloid, but not lymphoid, potential. EMPs migrate to the fetal liver and rapidly differentiate including production of circulating neutrophils by E11.5. While the surface markers, transcription factors and lineage potential associated with EMPs overlap with those found in adult definitive hematopoiesis, they are present in unique combinations or proportions that result in a specialized definitive embryonic progenitor. Further, we find that ES cell -derived hematopoiesis recapitulates early yolk sac hematopoiesis, including primitive, EMP and rare B cell potential. EMPs do not have long term potential when transplanted in immunocompromised adults, but can provide transient adult-like RBC reconstitution.
Directed cell movement is integral to both embryogenesis and hematopoiesis. In the adult, the chemokine family of secreted proteins signals migration of hematopoietic cells through G-coupled chemokine receptors. We detected embryonic expression of chemokine receptor messages by RT-PCR with degenerate primers at embryonic day 7.5 (E7.5) or by RNase protection analyses of E8.5 and E12.5 tissues. In all samples, the message encoding CXCR4 was the predominate chemokine receptor detected, particularly at earlier times (E7.5 and E8.5). Other chemokine receptor messages (CCR1, CCR4, CCR5, CCR2, and CXCR2) were found in E12.5 tissues concordant temporally and spatially with definitive (adult-like) hematopoiesis. Expression of CXCR4 was compared with that of its only known ligand, stromal cell-derived factor-1 (SDF-1), by in situ hybridization. During organogenesis, these genes have dynamic and complementary expression patterns particularly in the developing neuronal, cardiac, vascular, hematopoietic, and craniofacial systems. Defects in the first four of these systems have been reported in CXCR4- and SDF-1-deficient mice. Our studies suggest new potential mechanisms for some of these defects as well as additional roles beyond the scope of the reported abnormalities. Earlier in development, expression of these genes correlates with migration during gastrulation. Migrating cells (mesoderm and definitive endoderm) contain CXCR4 message while embryonic ectoderm cells express SDF-1. Functional SDF-1 signaling in midgastrula cells as well as E12.5 hematopoietic progenitors was demonstrated by migration assays. Migration occurred with an optimum dose similar to that found for adult hematopoietic cells and was dependent on the presence of SDF-1 in a gradient. This work suggests roles for chemokine signaling in multiple embryogenic events.
In the adult, platelets are derived from unipotential megakaryocyte colony-forming cells (Meg-CFCs) that arise from bipotential megakaryocyte/erythroid progenitors (MEPs). To better define the developmental origin of the megakaryocyte lineage, several aspects of megakaryopoiesis, including progenitors, maturing megakaryocytes, and circulating platelets, were examined in the murine embryo. We found that a majority of hemangioblast precursors during early gastrulation contains megakaryocyte potential. Combining progenitor assays with immunohistochemical analysis, we identified 2 waves of MEPs in the yolk sac associated with the primitive and definitive erythroid lineages. Primitive MEPs emerge at E7.25 along with megakaryocyte and primitive erythroid progenitors, indicating that primitive hematopoiesis is bilineage in nature. Subsequently, definitive MEPs expand in the yolk sac with Meg-CFCs and definitive erythroid progenitors. The first GP1b-positive cells in the conceptus were identified in the yolk sac at E9.5, while large, highly reticulated platelets were detected in the embryonic bloodstream beginning at E10.5. At this time, the number of megakaryocyte progenitors begins to decline in the yolk sac and expand in the fetal liver. We conclude that the megakaryocyte lineage initially originates from hemangioblast precursors during early gastrulation and is closely associated both with primitive and with definitive erythroid lineages in the yolk sac prior to the transition of hematopoiesis to intraembryonic sites. IntroductionHematopoiesis in the mouse embryo initiates shortly after the onset of gastrulation in the blood islands of the extraembryonic yolk sac. 1 Here, the close spatial and temporal arrangement of the first hematopoietic and endothelial precursors has long suggested that both cell types originate from a common hemangioblast progenitor. 2 This hypothesis has gained support from studies of embryonic stem cells cultured in vitro 3-7 and more recently been confirmed by the identification of blast-colony-forming cells (BL-CFCs) in mouse embryos that possess endothelial, as well as primitive erythroid, definitive erythroid, and multiple myeloid lineage potential. 8 A transient pool of primitive erythroid progenitors (EryPCFCs) emerges between embryonic days 7.25 to 9.0 (E7.25-E9.0) and generates large, nucleated H1-globin-expressing erythroid cells that eventually enucleate upon maturation. 9-11 Subsequently, a second, overlapping wave of definitive erythroid progenitors (burst-forming units-erythroid [BFU-Es]), similar to those found later in the fetal liver and adult bone marrow, emerges in the yolk sac accompanied temporally by mast cell, granulocyte, macrophage, and multipotential high proliferative potential colony forming cells (HPP-CFCs). 9,10,12,13 These findings have suggested that the definitive wave of yolk sac hematopoietic progenitors is multilineage, while the initial primitive wave is unilineage, being specifically confined to the primitive erythroid lineage. 14 In the adult bone marr...
To better understand the relationship between the embryonic hematopoietic and vascular systems, we investigated the establishment of circulation in mouse embryos by examining the redistribution of yolk sac-derived primitive erythroblasts and definitive hematopoietic progenitors. Our studies revealed that small numbers of erythroblasts first enter the embryo proper at 4 to 8 somite pairs (sp) (embryonic day 8.25 [E8.25]), concomitant with the proposed onset of cardiac function. Hours later (E8.5), most red cells remained in the yolk sac. Although the number of red cells expanded rapidly in the embryo proper, a steady state of approximately 40% red cells was not reached until 26 to 30 sp (E10). Additionally, erythroblasts were unevenly distributed within the embryo's vasculature before 35 sp. These data suggest that fully functional circulation is established after E10. This timing correlated with vascular remodeling, suggesting that vessel arborization, smooth muscle recruitment, or both are required. We also examined the distribution of committed hematopoietic progenitors during early embryogenesis. Before E8.0, all progenitors were found in the yolk sac. When normalized to circulating erythroblasts, there was a significant enrichment (20-to 5-fold) of progenitors in the yolk sac compared with the embryo proper from E9.5 to E10.5. These results indicated that the yolk sac vascular network remains a site of progenitor production and preferential adhesion even as the fetal liver becomes a hematopoietic organ. We conclude that a functional vascular system develops gradually and that specialized vascular-hematopoietic environments exist after circulation becomes fully established. IntroductionA functional circulatory system is an early requirement for survival and growth of the mammalian embryo and is the first organ system to develop in the embryo. 1 The circulatory system is composed of vascular, hematopoietic, and cardiac components, each formed from discrete regions of mesoderm. The first endothelial cells and blood cells are generated in yolk sac blood islands beginning at embryonic day 7 (E7.0) in the mouse. By E8.0, thousands of nucleated primitive red blood cells have formed within a vascular plexus in the yolk sac. [2][3][4] Concurrently, the aorta and the peristaltic beating heart tube form in the embryo proper. In the next 36 hours, there is a remarkable increase in complexity of vascular and hematopoietic systems. The vascular plexus remodels and expands into an arborized network of specialized arteries and veins. Primitive erythroblasts from the yolk sac continue to divide and mature, and a second wave of hematopoiesis creating definitive (adultlike) progenitors originates in the yolk sac. 5,6 Thus, the early vascular system is the hematopoietic environment for primitive and definitive lineages until the specialized stromal microenvironment of the fetal liver (beginning E10), and later the adult bone marrow, is available. However, the nature of any specific interactions between early embryonic hematopo...
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