Chemical and immunological characterization of proteoglycans of embryonic chick calvaria

We have previously demonstrated in quail embryos grafted on chick yolk sacs the existence of intraembryonic stem cells responsible for definitive hemopoiesis. In order to determine the origin of these cells, we now examine the diffuse hemopoietic processes within the avian embryo's mesoderm. At 4–5 days of incubation in the two species, basophilic cells were found throughout the dorsal mesentery. At 6–8 days these cells became very numerous and built up dense foci at the level of branching of the anterior and posterior cardinal veins. These cells often infiltrated the wall of lymph spaces and channels and were also present in the lumen of blood vessels. Such locations support the interpretation that these basophilic cells represent early stages of hemopoietic differentiation. At 8–10 days, erythropoiesis or granulopoiesis was seen in the foci, which then regressed rapidly. The foci maximal development coincided with the period of colonization of the intraembryonic organ rudiments. In “yolk sac chimeras,” the foci were always constituted by quail cells, indicating their intraembryonic origin. The primordial origin of the intramesodermal cells remains to be determined. A likely source might be the ventral wall of the aorta which appeared to shed cells into the lumen and into the mesentery in the 3-day embryo.     

Differential contribution of dorsal and ventral lateral plate mesoderm to hemopoiesis during Rana pipiens embryogenesis

Data obtained from studies on the origin and development of hemopoietic cells in several classes of vertebrate embryos argue for two distinct sources of hemopoietic cells, the intraembryonic dorsal lateral plate and the extraembryonic ventral blood island/yolk sac. In the present study, a stage by stage comparison of the hemopoietic potential of both of these regions was made during development of the frog, Rana pipiens. Either dorsal lateral plate or ventral blood island mesoderm was reciprocally transplanted between cytogenetically labeled triploid and diploid embryos. The ratio of donor-derived cells to host-derived cells (labeling index) was determined from Feulgen-stained DNA measurements of cells harvested from hemopoietic organs of young larvae. Blood island transplants consistently resulted in larvae with positive labeling of the circulating blood. Transplanted dorsal mesoderm supplied mesonephric granulocytes and thymocytes, but not circulating erythrocytes to larvae. However, the contribution of dorsal mesoderm to larval hemopoiesis fluctuated with respect to embryonic stage at transplantation.     

Demonstration of a phagocytic cell system belonging to the hemopoietic lineage and originating from the yolk sac in the early avian embryo.

It is well established that hemopoietic cells arising from the yolk sac invade the avian embryo. To study the fate and role of these cells during the first 2.5-4.5 days of incubation, we constructed yolk sac chimeras (a chick embryo grafted on a quail yolk sac and vice versa) and immunostained them with antibodies specific to cells of quail hemangioblastic lineage (MB1 and QH1). This approach revealed that endothelial cells of the embryonic vessels are of intraembryonic origin. In contrast, numerous hemopoietic cells of yolk sac origin were seen in embryos ranging from 2.5 to 4.5 days of incubation. These cells were already present within the vessels and in the mesenchyme at the earliest developmental stages analyzed. Two hemopoietic cell types of yolk sac origin were distinguishable, undifferentiated cells and macrophage-like cells. The number of the latter cells increased progressively as development proceeded, and they showed marked acid phosphatase activity and phagocytic capacity, as revealed by the presence of numerous phagocytic inclusions in their cytoplasm. The macrophage-like cells were mostly distributed in the mesenchyme and also appeared within some organ primordia such as the neural tube, the liver anlage and the nephric rudiment. Comparison of the results in the two types of chimeras and the findings obtained with acid phosphatase/MB1 double labelling showed that some hemopoietic macrophage-like cells of intraembryonic origin were also present at the stages considered. These results support the existence in the early avian embryo of a phagocytic cell system of blood cell lineage, derived chiefly from the yolk sac. Cells belonging to this system perform phagocytosis in cell death and may also be involved in other morphogenetic processes.     

Distinct origins of adult and embryonic blood in Xenopus

Whether embryonic and adult blood derive from a single (yolk sac) or dual (yolk sac plus intraembryonic) origin is controversial. Here, we show, in Xenopus, that the yolk sac (VBI) and intraembryonic (DLP) blood compartments derive from distinct blastomeres in the 32-cell embryo. The first adult hematopoietic stem cells (HSCs) are thought to form in association with the floor of the dorsal aorta, and we have detected such aortic clusters in Xenopus using hematopoietic markers. Lineage tracing shows that the aortic clusters derive from the blastomere that gives rise to the DLP. These observations indicate that the first adult HSCs arise independently of the embryonic lineage.     

人卵黄囊造血的探讨

采用卵黄囊组织切片、涂片的形态学、细胞化学染色、造血干/祖细胞体外培养及CD_(34)单克隆抗体免疫荧光检测等方法研究表明:人卵黄囊中存在造血岛,造血岛内由于造血微环境的特点致使此期造血主要向红系分化。血岛中检测出CD_(34)~ 细胞,比例高于胎肝及成人骨髓,干/祖细胞于体外培养形成红系集落。结论:人胚胎期造血源于卵黄囊。     

Cells released in vitro from the embryonic yolk sac of the stick insect carausius morosus (BR.) (PHASMATODEA : HETERONEMIIDAE) may include embryonic hemocytes

The embryonic yolk sac and the adult dorsal vessel of the stick insect Carausius morosus (Br.) (Phasmatodea : Heteronemiidae) were shown to release a number of cells that appear morphologically similar to circulating adult hemocytes. Like adult hemocytes, these cells reacted positively when tested for both phenoloxidase activity and a monoclonal antibody specifically raised against a vitellin polypeptide. Based on this evidence, it is suggested that yolk sac-released cells behave as potential embryonic hemocytes. A model is thus proposed whereby the yolk sac might host a number of hemopoietic stem cells on their way to the dorsal vessel, and in so doing, it may temporally act as an embryonic hemopoietic organ.     

Embryonic and fetal hemopoiesis: an overview

Our current knowledge of embryonic and fetal hemopoiesis is critically reviewed in this article. In both murine and human systems, embryonic and fetal development is associated with multiple switching in the sites of hemopoiesis. The phenomenon is first extraembryonic, occurring in blood islands of the yolk sac. Hemopoietic stem cells (HSC) appear to derive from hemangioblasts that are of mesodermal origin. Yolk sac milieu is permissive only for erythropoiesis which proceeds synchronously and may be erythropoietin-insensitive. Yolk sac milieu is not permissive for the development of other cell lines. The final product is nucleated red cells. Yolk sac hemopoiesis is an example par excellence of primitive (as compared to definitive) form of hemopoiesis. HSC then seem to migrate via the bloodstream to the liver and spleen to seed these tissues, which then carry the burden of hemopoiesis until birth and for some time thereafter. Here also erythropoiesis predominates, but some granulopoiesis also occurs. Thus, the milieu is not totally impermissive. Hemopoiesis is in definitive form, lacking synchronicity of cell growth with the end product being anucleated cells and synthesized hemoglobin not limited to embryonic type. The site of hemopoiesis is finally transferred to the bone marrow, which is predominantly granulopoietic. Certain cellular and embryological features of these types of hemopoiesis in the context of more recent molecular understanding of stem cell homing are discussed.     

Formation sites and distribution of osteoclast progenitor cells during the ontogeny of the mouse

The presence of osteoclast progenitor cells in embryonic, fetal, young growing, and adult murine tissues and organs was investigated in a coculture system with fetal metatarsal bones stripped of periosteum and not yet invaded by osteoclasts. Osteoclasts were found to originate from the early yolk sac and from every tissue tested in the fetus and young mouse. In the adult mouse they were formed only from tissues with a large mononuclear phagocyte population. No osteoclasts could be generated from the young embryo proper, prior to establishment of the vascular connection with the yolk sac. Progenitors of osteoclasts or their stem cells therefore do not develop from undifferentiated mesenchyme outside the yolk sac, but are distributed from the yolk sac to embryonic tissues and hematopoietic organs through the vascular circulation. The embryonic distribution of osteoclast progenitors coincides with the distribution of immature macrophages. Furthermore, they are present before the formation of monocytes in the fetus. The results also indicate that osteoclast precursor cells are not identical with mature, differentiated macrophages, but are cells with little capacity to phagocytose and therefore are, at the most immature progenitors of macrophages or cells of an early diverging lineage. In view of these results the derivation of osteoclasts is discussed.     

Coexpression of embryonic, fetal, and adult globins in erythroid cells of human embryos: relevance to the cell-lineage models of globin switching

The cellular control of the switch from embryonic to fetal globin formation in man was investigated with studies of globin expression in erythroid cells of 35- to 56-day-old embryos. Analyses of globins synthesized in vivo and in cultures of erythroid progenitors (burst-forming units, BFUe) showed that cells of the yolk sac (primitive) erythropoiesis, in addition to embryonic chains, produced fetal and adult globins and that cells of the definitive (liver) erythropoiesis, in addition to fetal and adult globins, produce embryonic globins. That embryonic, fetal, and adult globins were coexpressed by cells of the same lineage was documented by analysis of globin chains in single BFUe colonies: all 67 yolk sac-origin BFUe colonies and 42 of 43 liver-origin BFUe colonies synthesized epsilon-, gamma-, and beta-chains. These data showed that during the switch from embryonic to adult globin formation, embryonic and definitive globin chains are coexpressed in the primitive, as well as in the definitive, erythroid cells. Such results are compatible with the postulate that the switch from embryonic to fetal globin synthesis represents a time-dependent change in programs of progenitor cells rather than a change in hemopoietic cell lineages.     

CD41 expression defines the onset of primitive and definitive hematopoiesis in the murine embryo

The platelet glycoprotein IIb (alpha(IIb); CD41) constitutes the alpha subunit of a highly expressed platelet surface integrin protein. We demonstrate that CD41 serves as the earliest marker of primitive erythroid progenitor cells in the embryonic day 7 (E7.0) yolk sac and high-level expression identifies essentially all E8.25 yolk sac definitive hematopoietic progenitors. Some definitive hematopoietic progenitor cells in the fetal liver and bone marrow also express CD41. Hematopoietic stem cell competitive repopulating ability is present in CD41(dim) and CD41(lo/-) cells isolated from bone marrow and fetal liver cells, however, activity is enriched in the CD41(lo/-) cells. CD41(bright) yolk sac definitive progenitor cells co-express CD61 and bind fibrinogen, demonstrating receptor function. Thus, CD41 expression marks the onset of primitive and definitive hematopoiesis in the murine embryo and persists as a marker of some stem and progenitor cell populations in the fetal liver and adult marrow, suggesting novel roles for this integrin.     

Development of erythroid and myeloid progenitors in the yolk sac and embryo proper of the mouse.

In this study, we have mapped the onset of hematopoietic development in the mouse embryo using colony-forming progenitor assays and PCR-based gene expression analysis. With this approach, we demonstrate that commitment of embryonic cells to hematopoietic fates begins in proximal regions of the egg cylinder at the mid-primitive streak stage (E7.0) with the simultaneous appearance of primitive erythroid and macrophage progenitors. Development of these progenitors was associated with the expression of SCL/tal-1 and GATA-1, genes known to be involved in the development and maturation of the hematopoietic system. Kinetic analysis revealed the transient nature of the primitive erythroid lineage, as progenitors increased in number in the developing yolk sac until early somite-pair stages of development (E8.25) and then declined sharply to undetectable levels by 20 somite pairs (E9.0). Primitive erythroid progenitors were not detected in any other tissue at any stage of embryonic development. The early wave of primitive erythropoiesis was followed by the appearance of definitive erythroid progenitors (BFU-E) that were first detectable at 1-7 somite pairs (E8.25) exclusively within the yolk sac. The appearance of BFU-E was followed by the development of later stage definitive erythroid (CFU-E), mast cell and bipotential granulocyte/macrophage progenitors in the yolk sac. C-myb, a gene essential for definitive hematopoiesis, was expressed at low levels in the yolk sac just prior to and during the early development of these definitive erythroid progenitors. All hematopoietic activity was localized to the yolk sac until circulation was established (E8.5) at which time progenitors from all lineages were detected in the bloodstream and subsequently in the fetal liver following its development. This pattern of development suggests that definitive hematopoietic progenitors arise in the yolk sac, migrate through the bloodstream and seed the fetal liver to rapidly initiate the first phase of intraembryonic hematopoiesis. Together, these findings demonstrate that commitment to hematopoietic fates begins in early gastrulation, that the yolk sac is the only site of primitive erythropoiesis and that the yolk sac serves as the first source of definitive hematopoietic progenitors during embryonic development.     

Clonogenic fibroblasts from the hematopoietic organs of the human embryo and fetus at different gestational ages

Fibroblast precursors of hemopoietic organs of 72 embryos and fetuses 5-27 weeks of age have been studied. The study has shown that the increase in the number of clonogenic fibroblasts took place in the bone marrow and spleen 2-3 weeks before the beginning of hemopoiesis, that is during the period of the highest hemopoietic stem cell concentration. These data suggest possible participation of stromal fibroblasts of hemopoietic organs in the formation of microenvironment for hemopoietic stem cell functioning.     

Developmental rules in the hematopoietic and immune systems of birds: how general are they?

Fundamental rules about the development of the hematopoietic and immune systems have been established in birds, some of which are reviewed here. The organ rudiments belonging to this system provide the stroma, that has to be seeded by extrinsic stem cells. This particular developmental pattern makes it possible to create chimeric organs with stromal cells and stem cells from different origins. Grafting the thymic epithelium alone in a young embryo is sufficient to induce tolerance to tissues of the same origin as that of epithelium, even in a xenogeneic combination. Stem cells that seed the rudiments during development are born in the embryo rather than in the yolk sac and are responsible for definitive hematopoiesis. Data in frog and mouse indicate that these conclusions may be valid in other classes of vertebrates.     

Proliferation activity of stromal stem cells (CFU-f) from hemopoietic organs of pre- and postnatal mice

Stromal stem cells (CFU-f assay) from hemopoietic organs of fetuses, in contrast to adult animals, exhibit a high proliferation activity. This implies that these CFU-f are radiosensitive and potential target cells after radioactive contamination of fetuses. Furthermore, the percentage of CFU-f in DNA synthesis is correlated with the hemopoietic activity in liver, spleen, and bone marrow. As hemopoiesis starts, high numbers of CFU-f are in S phase. In fetal liver, spleen, and bone marrow, values of 70, 43, and 58%, respectively, are reached. As hemopoietic activity decreases in liver and stabilizes in spleen and bone marrow, mitotic activity of these stromal stem cells becomes undetectable.     

The origin of hematopoietic stem cells in the ontogenesis of vertebrates

A review of the origin of stem blood cells in ontogeny of vertebrates is presented. The comparative analysis of the data on laying, determination and migration of the hemopoietic precursor cells during embryogenesis in various taxonomic groups (teleosteans, urodeleans, anurans, avians and mammals) is performed. The change of the hemopoietic site and erythroid cells populations has been described. The data on sources of blood cell precursors and the origin of hemopoietic cells in the primordiums of hemopoietic organs were classified. A conclusion has been reached that in the course of evolution the hemopoietic anlage is gradually divided into two parts: one part migrates to the extraembryonic (ventral) mesoderm and another one remains intraembryonically and gives rice to the predecessors of definitive hemopoietic stem cells.     

The action of the cells of hemopoietic organs in chick embryos on mouse CFUdc and CLFUdc]

The humoral influence of cells of hemopoietic organs of chicken embryos of different terms on the development of the colony and cluster formation of mononuclears of the bone marrow of mice was studied in joint cultivation in two-compartment cylindrical diffuse microchambers. The process of formation of colonies and clusters is inhibited by cells of the yolk sac on the 2nd-4th day of the development, by cells of the liver on the 8th-12th day, of the spleen on the 13th-18th day and of the bone marrow--on the 15th day. The yolk sac cells were found to have most considerable inhibiting influence on proliferation and differentiation of cells on the 2nd day of the development of chicken embryo. The yolk sac cells on the 6th day stimulate the formation of colonies and clusters. The yolk sac, beginning from the 4th day of the development, and the liver release humoral factors promoting the formation of erythroid colonies. The erythroid colonies are formed but when cultivated on the vascular membrane of the chicken embryo; the erythroid colonies are not formed when cultivated in the abdominal cavity of mice. Local erythropoietinoid factors are not synthetized by the spleen and bone marrow cells. A supposition is put forward that a combination of the local inhibiting and erythropoietic effects promotes the erythroid differentiation of cells.     

B cell potential can be obtained from pre-circulatory yolk sac, but with low frequency

The ontogenic source of definitive hematopoietic system has been identified in non-mammalian vertebrates such as birds and amphibians by orthotopic embryo grafting, but remains unclear for mammals because of technical difficulties. Here, we successfully generated mouse chimeras by grafting yolk sac (YS) on YS of the host embryos before establishing circulation between YS and embryo proper and cultured the whole embryo for 66 h. Donor YS were isolated from C57BL/6 Ly-5.1 and EGFP-transgenic mouse embryos, and recipient embryos from C57BL/6 Ly-5.2 mouse. Almost one-half of the grafts in YS-YS chimeras survived and had obvious blood flow; graft-derived cells comprised 12.7+/-0.9% of the blood cells in the circulation. These graft-derived blood cells consisted mainly of erythroid cells, some myeloid cells and a few blastic cells. In addition, CD19(+) B cells were generated from the graft-derived cells isolated from aorta-gonad-mesonephros (AGM) regions of the YS-YS chimeras; however, the frequency of the YS-derived B cell was low (1.0+/-0.6%) when co-cultured with OP9 stromal cells. These results demonstrate that B cell potential exists in YS before the circulation. Although the major source for B cell is intra-embryonic AGM region, YS may contribute to definitive lymphopoiesis in vivo in mice.     

In vitro development of murine T cells from prethymic and preliver embryonic yolk sac hematopoietic stem cells.

Mature T cells are derived from prethymic stem cells, which arise at one or more extrathymic sites and enter and differentiate in the thymus. The nature of these prethymic stem cells is a critical factor for the formation of the T-cell repertoire. Although the bone marrow of adult mice can provide such stem cells, their origin during murine embryogenesis is still undetermined. Among potential sites for these progenitor cells are the fetal liver and the embryonic yolk sac. Our studies focus on the yolk sac, both because the yolk sac appears earlier than any other proposed site, and because the mammalian yolk sac is the first site of hematopoiesis. Although it has been shown that the yolk sac in midgestation contains stem cells that can enter the thymic rudiment and differentiate toward T-cell lineage, our aim was to analyze the developmental potential of cells in the yolk sac from earlier stages, prior to the formation of the liver and any other internal organ. We show here that the yolk sac from 8- and 9-day embryos (2-9 and 13-19 somites, respectively) can reconstitute alymphoid congenic fetal thymuses and acquire mature T-cell-specific characteristics. Specifically, thymocytes derived from the early embryonic yolk sac can progress to the expression of mature T lymphocyte markers including CD3/T-cell receptor (TCR), CD4 and CD8. In contrast, we have been unable to document the presence of stem cells within the embryo itself at these early stages. These results support the hypothesis that the stem cells capable of populating the thymic rudiment originate in the yolk sac, and that their presence as early as at the 2- to 9-somite stage may indicate that prethymic stem cells found elsewhere in the embryo at later times may have been derived by migration from this extra-embryonic site. Our experimental design does not exclude the possibility of multiple origins of prethymic stem cells of which the yolk sac may provide the first wave of stem cells in addition to other later waves of cells.