Immunohistochemical analysis of the distribution of histone H5 and hemoglobin during chicken development

We used immunohistochemical procedures to investigate embryonic erythropoiesis in serial sections of chicken embryos after 2-13 days of incubation. Antibodies specific for the erythrocyte-specific histone H5, for embryonic hemoglobin, and for adult hemoglobin were used as markers for general, primitive, and definitive erythropoiesis, respectively. Histone H5 was present in erythrocytes at all of the stages studied, i.e., in both the primitive and definitive cells. Cell of the definitive lineage were first detected, at about 5-6 days of incubation, in erythroid foci in the mesenchyme around the vitelline stalk. At 7-9 days of incubation, a massive mesenchymal conglomeration of erythropoietic cells developed, extending from the cervical to the abdominal region and ventrally to the vertebral body, with its largest extensions being around the arteries in the mediastinum. Immunostaining revealed that these erythroid cells belonged to the definitive erythropoietic lineage. These cells had disappeared completely after 12 days of incubation, i.e., before erythropoiesis is visible in the bone marrow. These observations are consistent with the notion that the yolk sac is essential for the formation of the definitive erythroid lineage.     

Identification of hemoglobin types contained in single chicken erythrocytes by fluorescent antibody technique

It has been suggested that the switch in hemoglobin (Hb) types (from embryonic to adult) during chicken embryonic development is associated with the substitution of one erythroid cell line (“primitive”) for another (“definitive”). For the detection of two Hb types inside single erythroid cells, rabbit antibodies specific for embryonic and adult Hbs were prepared. Rabbit antibody specific for embryonic Hb cross-reacted only with embryonic major Hb components, while antibody specific for adult Hb did solely with adult minor Hb component. The antibodies were conjugated with fluorescein isothiocyanate. The conjugated antibodies were used for the fluorescent staining of blood smears of developing chicken embryos at different ages. Direct fluorescent antibody technique demonstrated that the major components of embryonic Hb and the minor component of adult Hb were not present within the same erythrocyte during chicken ontogenesis. It strongly suggested that embryonic-type Hb and adult-type Hb do not coexist within the same cell.     

Globin gene expression in erythroid cell lines during larval development of Pleurodeles waltlii

We have attempted to determine whether in Pleurodeles ontogenesis there exists a close relationship between the two following characteristics: change from primitive to definitive erythroid cell populations, which parallels the change of major erythropoietic site; change in the type of synthesized hemoglobin, larval or adult. The origin of red blood cells was investigated by embryonic grafts of hemopoietic anlage from 2n to 4n embryos. The larval or adult hemoglobin type was characterized by immunofluorescence by using specific antibodies. Our results show that in Pleurodeles, blood island-originating red blood cells and spleen-originating red blood cells are both able to synthesize either Hb L or Hb A at a given time, but in separate cells.     

Cadmium-induced forelimb ectrodactyly: a proposed mechanism of teratogenesis

We have attempted to elucidate the mechanism of cadmium teratogenesis utilizing inbred mouse strains sensitive (C57BL/6J) or resistant (SWV) to the embryotoxic effect of this common heavy metal contaminant. Carbonic anhydrase activity of whole-embryo homogenates was moderately depressed in C57BL/6J mice compared to a slight and transient decrease in the resistant SWV mice. Embryonic erythrocytes were similarly examined, and the cadmium did not have any effect on carbonic anhydrase activity in either strain. Likewise, histochemical examination of carbonic anhydrase activity did not reveal any effect of cadmium in the embryos of their strain. Generally, the zinc concentration of embryos was not affected by cadmium administration. However, increased levels of zinc were observed in cadmium-exposed yolk sacs of both strains suggesting that cadmium produces an adverse effect on yolk sac function. Untreated C57BL/6J units (embryo plus surrounding extraembryonic membranes), embryos, and yolk sacs had much lower hemoglobin concentrations than those observed in untreated SWV units, embryos, and yolk sacs. Additionally, cadmium exposure significantly decreased C57BL/6J embryonic hemoglobin levels on gestation day 10 (PM) and increased C57BL/6J yolk sac hemoglobin levels on gestation days 10 (AM) and 10 (PM). No difference in hemoglobin concentration was observed between untreated and cadmium-treated SWV embryos or yolk sacs. We propose that cadmium induces forelimb ectrodactyly by creating an acidotic embryonic environment and that the primary site at which cadmium exerts its teratogenic effect might be the yolk sac.     

Evidences that hemoglobin switch in the chick embryo depends on erythroid cell line substitution

Chemical identifications of various hemoglobin types were performed on unfractionated erythroid cells derived from chicken embryos at 5 and 7 days of development and on purified primitive and definitive cells. Proteins were pulse-labelled in primitive erythroid cells at various times of culture to identify those actually synthesized. The data show that primitive cells contain and synthesize only embryonic hemoglobins at all stages of maturation and definitive cells contain adult and minor embryonic hemoglobins, but no major embryonic hemoglobins, not even in trace amounts. These results support a model for hemoglobin switch in the chicken embryo based on cell line substitution.     

Alterations in the rate of hemoglobin synthesis during chick embryogenesis

The rate of synthesis of different hemoglobin (Hb) species — embryonic, primitive, definitive, and adult — in the circulating red cells of the chick embryo have been measured. On the fifth day of chick embryogenesis, there is a marked decrease in the capability of these red cells to synthesize Hb. The rates of synthesis of embryonic and primitive Hb decrease markedly compared to that of definitive and adult Hb. On the fourth day of embryogenesis nucleic acid synthesis drops sharply in these cells. These decreases in metabolic activity preceed the disappearance of the primitive erythrocyte from the chick embryo circulation. It appears that the primitive cell line is specifically shut off with respect to its metabolic activities and possibly destroyed at this time.     

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.     

Some observations on the primitive and definitive erythrocytes of the developing chick

Summary The cytological changes in the primitive and definitive erythrocytes of the incubating chick have been followed. Observations have been made on the nucleoli, vital granules, mitochondria,Golgi apparatus, reticulum ofSinigaglia and the reticulation patterns of the basophilic substance. The cells of the primitive and definitive lines are ordinarily readily distinguished from one another. Data are included on the rate of disappearance of the primitive cells from the circulation. They may persist as long as two weeks after hatching. Giant primitive erythrocytes are common during the first week of incubation. The cells have one, two three or four nuclei. The nuclearplasma relationship is maintained somewhere near a constant. These atypical cells are due to aberrations in mitosis. Data on the percentage of mitosis in both types of erythrocytes are also included. The initial activity of the spleen and bone-marrow is reflected in the blood stream. There is a distinct rise in the proportion of young definitive erythrocytes. An attempt is made to correlate the findings ofHall (1934) on the changing affinity of the hemoglobin for oxygen with the changing blood picture. The primitive line does not persist long enough to account for the phenomenon. It is suggested, however, that the hemoglobin of the erythrocytes produced by the yolk sac may differ from that of the cells produced by the spleen and bone-marrow. With Plates I–III.     

The ontogeny of haematopoiesis in the marine teleost Leiostomus xanthurus and a comparison of the site of initial haematopoiesis with Opsanus tau

The ontogeny of haematopoiesis in the perciform fish, spot Leiostomus xanthurus , differed from that reported as the norm for fishes, as exemplified by the cypriniform zebrafish Danio rerio , and observed in the batrachoidiform oyster toadfish Opsanus tau . Erythropoiesis in spot was first evident in the head kidney of yolk‐sac larvae 3 days after hatching (DAH). No embryonic intermediate cell mass (ICM) of primitive stem cells or blood islands on the yolk were apparent within embryos. Erythrocytes were first evident in circulation near the completion of yolk absorption, c . 5 DAH, when larvae were c . 2·0 mm notochord length ( L _N). Erythrocyte abundance increased rapidly with larval development for c . 14 to 16 DAH, then became highly variable following changes in cardiac chamber morphology and volume. Erythrocytic haemoglobin (Hb) was not detected within whole larvae until they were 12 DAH or c . 3·1 mm L _N, well after yolk and oil‐globule absorption. The Hb was not quantified until larvae were >47 DAH or >7 mm standard length. The delayed appearance of erythrocytes and Hb in spot was similar to that reported for other marine fishes with small embryos and larvae. In oyster toadfish, a marine teleost that exhibits large embryos and larvae, the ICM and Hb were first evident in two bilateral slips of erythropoietic tissue in the embryos, c . 5 days after fertilization. Soon thereafter, erythrocytes were evident in the heart, and peripheral and vitelline circulation. Initial haematopoiesis in oyster toadfish conformed with that described for zebrafish. While the genes that code for the development of haematopoiesis are conserved among vertebrates, gene expression lacks phylogenetic pattern among fishes and appears to conform more closely with phenotypic expression related to physiological and ecological influences of overall body size and environmental oxygen availability.     

HoxB4 confers definitive lymphoid-myeloid engraftment potential on embryonic stem cell and yolk sac hematopoietic progenitors

The extent to which primitive embryonic blood progenitors contribute to definitive lymphoid-myeloid hematopoiesis in the adult remains uncertain. In an effort to characterize factors that distinguish the definitive adult hematopoietic stem cell (HSC) and primitive progenitors derived from yolk sac or embryonic stem (ES) cells, we examined the effect of ectopic expression of HoxB4, a homeotic selector gene implicated in self-renewal of definitive HSCs. Expression of HoxB4 in primitive progenitors combined with culture on hematopoietic stroma induces a switch to the definitive HSC phenotype. These progenitors engraft lethally irradiated adults and contribute to long-term, multilineage hematopoiesis in primary and secondary recipients. Our results suggest that primitive HSCs are poised to become definitive HSCs and that this transition can be promoted by HoxB4 expression. This strategy for blood engraftment enables modeling of hematopoietic transplantation from ES cells.     

Erythropoiesis in normal and mutant chick embryos

Hemoglobin D_Davis (Hb D_D), an autosomal codominant in chickens, the α^D-globin chain of Hb M of primitive cells and Hb D of definitive erythrocytes. Erythropoiesis and Hb synthesis was investigated in normal, heterozygous, and homozygous Hb D_D mutant embryos (stages 15–44) and adults. The time of appearance, morphology, relationships to developmental changes, and number of primitive and definitive cells were determined. Primitive hemoglobins between stages 17 and 44 showed four components, P1, P2, E, and M (or M_D), on high-resolution isoelectric focusing gels. Comparison of $\text{P1}\text{P2}$ ratios in the four phenotypes indicated that homozygous Hb D_D embryos had an increased proportion of Hb P2 relative to Hb P1 between stages 17 and 35. This difference coincided with an increase in the number of large primitive cells. In all phenotypes the proportions of primitive hemoglobins decreased after stage 25 and they were not detected after stage 40. Basophilic definitive erythroblasts were present in cell suspensions from all phenotypes between stages 24 and 25. Hb A, the major Hb and Hb D, the minor Hb, of definitive cells of embryos and adults were detected by isoelectric focusing of lysates by stage 29. Definitive cells from late embryos of all phenotypes had higher proportions of Hb D (or Hb D_D) than did red cells from corresponding adult birds. Heterozygous Hb D_D embroys and adults had both Hb D and Hb D_D. Hb D_D comprises about 30% of the total minor Hb rather than 50% expected for heterozygosity at a single locus. In this respect heterozygous Hb D_D chick embryos and adult birds are similar to certain heterozygous α-chain variants in humans. A minor Hb, H, found in lysates of later embryos disappears in lysates of normal chicks 65 days after hatching, but was present in the circulation of homozygous Hb D_D chicks until at least 195 days after hatching. Additionally, several minor Hb components which may be asymmetrical hybrids or derived precursors of Hb A and Hb D (or Hb D_D) were observed. This study provides the precise developmental stages when the switchover of erythroid cell populations and hemoglobins in the chick embryo occurs. This is the first investigation of an α-globin chain mutant which is synthesized during all stages of red cell development and may be a useful animal model for the study of hemoglobinopathies in vertebrates.     

Alternatively Spliced Tissue Factor Is Not Sufficient for Embryonic Development

Tissue factor (TF) triggers blood coagulation and is translated from two mRNA splice isoforms, encoding membrane-anchored full-length TF (flTF) and soluble alternatively-spliced TF (asTF). The complete knockout of TF in mice causes embryonic lethality associated with failure of the yolk sac vasculature. Although asTF plays roles in postnatal angiogenesis, it is unknown whether it activates coagulation sufficiently or makes previously unrecognized contributions to sustaining integrity of embryonic yolk sac vessels. Using gene knock-in into the mouse TF locus, homozygous asTF knock-in (asTFKI) mice, which express murine asTF in the absence of flTF, exhibited embryonic lethality between day 9.5 and 10.5. Day 9.5 homozygous asTFKI embryos expressed asTF protein, but no procoagulant activity was detectable in a plasma clotting assay. Although the α-smooth-muscle-actin positive mesodermal layer as well as blood islands developed similarly in day 8.5 wild-type or homozygous asTFKI embryos, erythrocytes were progressively lost from disintegrating yolk sac vessels of asTFKI embryos by day 10.5. These data show that in the absence of flTF, asTF expressed during embryonic development has no measurable procoagulant activity, does not support embryonic vessel stability by non-coagulant mechanisms, and fails to maintain a functional vasculature and embryonic survival.     

ONTOGENY OF CHICKEN HEMOGLOBIN. I. ELECTROPHORETIC STUDY OF THE HETEROGENEITY OF HEMOGLOBIN IN DEVELOPMENT

Separation of different molecular species of hemoglobin from developing chickens by starch gel electrophoresis has revealed the appearance of early embryonic (embryonic), late embryonic (fetal) and adult hemoglobin (Hb) type during development. In 5-day embryos, there are 3 or 4 forms of embryonic Hb type. They begin to decrease in 6-day embryos and cannot be detected in embryos after 10 days of incubation. In 6-day embryos, two forms of adult Hb type appear, and one of them, which is a major form in adults, becomes t o be a major one in 7-day embryos. One or two forms of fetal Hb type first appear in 10-day embryos and are still present in 5-day posthatching chickens.
Ultracentrifugation of carbonmonoxyhemoglobins from embryos at early and at later stages (fetuses), from newly hatched and from adult chickens has shown that they have a single monodisperse peak. Some heterogeneity, however, has been detected after starch gel electrophoresis, probably owing to aggregation or polymerization.
Subunit analysis of embryonic, fetal and adult Hb type by starch gel electrophoresis in formate buffer at pH 1.9 has indicated that embryonic Hb type contains total 5 subunits, C, D, E, F and G; fetal Hb type, total 2, A and H; and adult Hb type, total 3, B, F and H.     

Ontogenetic changes of circulating erythroid cells and haemoglobin components in Esox lucius

Using light microscopy the morphology, the mitotic index and levels of erythroid cell types were detected from 48 h pike Esox lucius embryos before hatching to adult specimens. At the same developmental stages, the haemoglobins and globin chains expressed were electrophoretically characterized. The erythroid cells of the primitive generation were the most abundant from 48 h before hatching until 15–20 days after hatching, then their number decreased and only rare cells remained in the 3 month‐old juvenile specimens. These cells divided and differentiated in the blood and were substituted by the definitive erythrocyte series. As in other vertebrates, the immature cells of the two generations differed in morphological properties and in the synthetized haemoglobin. The circulating erythroid cells of the definitive population cell lineage were, at all differentiation stages, smaller than those of the primitive generation. The definitive erythrocytes appeared in blood smears of 7 days post‐hatching larvae, they increased rapidly and at 20 days they represented the predominant red blood cell population in the circulation of young pike. Electrophoretic analysis of haemolysates obtained from different developmental stages indicated the presence of distinct embryonic, larval and adult haemoglobins. The embryonic haemoglobins differed from those of the older larva and juvenile specimens and were detectable within the first week of post‐hatching development when only primitive erythrocytes were present in the blood.     

Primitive erythropoiesis in chick embryogenesis. 3. Effect of FUdR on Hb synthesis

A single hematocytoblast in the yolk sac of the chick embryo has been shown previously to give rise on the average to a clone of 128 erythrocytes. Furthermore, in any given generation the erythroid cell synthesizes a characteristic amount of hemoglobin (Hb). In these experiments day 4 embryos were treated with FUdR for 12 hours, and then reversed with thymidine. We have monitored both the passage of these erythroblasts through the cell cycle, and the effect of this perturbation on the Hb content of single cells. As a result of this disruption the amount of Hb synthesized in a given generation can be varied, but the final amount of Hb/cell in the mature erythrocyte is the same as in the untreated controls. Apparently the total amount of the Hb/cell does not in itself influence the passage of the cell through the cycle. The coefficients of variation of the Hb values in the mature erythrocytes from both normal an perturbed embryos are similar.     

Analysis of extraembryonic mesodermal structure formation in the absence of morphological primitive streak

During mouse gastrulation, the primitive streak is formed on the posterior side of the embryo. Cells migrate out of the primitive streak to form the future mesoderm and endoderm. Fate mapping studies revealed a group of cell migrate through the proximal end of the primitive streak and give rise to the extraembryonic mesoderm tissues such as the yolk sac blood islands and allantois. However, it is not clear whether the formation of a morphological primitive streak is required for the development of these extraembryonic mesodermal tissues. Loss of the Cripto gene in mice dramatically reduces, but does not completely abolish, Nodal activity leading to the absence of a morphological primitive streak. However, embryonic erythrocytes are still formed and assembled into the blood islands. In addition, Cripto mutant embryos form allantoic buds. However, Drap1 mutant embryos have excessive Nodal activity in the epiblast cells before gastrulation and form an expanded primitive streak, but no yolk sac blood islands or allantoic bud formation. Lefty2 embryos also have elevated levels of Nodal activity in the primitive streak during gastrulation, and undergo normal blood island and allantois formation. We therefore speculate that low level of Nodal activity disrupts the formation of morphological primitive streak on the posterior side, but still allows the formation of primitive streak cells on the proximal side, which give rise to the extraembryonic mesodermal tissues formation. Excessive Nodal activity in the epiblast at pre‐gastrulation stage, but not in the primitive streak cells during gastrulation, disrupts extraembryonic mesoderm development.     

Influence of chromosomal determinants on development of androgenetic and parthenogenetic cells

We have examined the role of germline-specific chromosomal determinants of development in the mouse. Studies were carried out using aggregation chimaeras between androgenetic----fertilized embryos and compared with similar parthenogenetic----fertilized chimaeras. Several adult chimaeras were found with parthenogenetic cells but none were found with androgenetic cells. Analysis of chimaeras at mid-gestation showed that parthenogenetic cells were detected in the embryo and yolk sac but that androgenetic cells were found only in the trophoblast and yolk sac and not in the embryo. The contribution of parthenogenetic cells to the embryo and yolk sac was increased by aggregating 2-cell parthenogenetic and 4-cell fertilized embryos but the contribution of parthenogenetic cells in extraembryonic tissues remained negligible even after aggregation of 4-cell parthenogenetic and 2-cell fertilized embryos. Furthermore, parthenogenetic cells were primarily found in the yolk sac mesoderm and not in the yolk sac endoderm. These results suggest that maternal chromosomes in parthenogenetic cells permit their participation in the primitive ectoderm lineage but these cells are presumably eliminated by selective pressure or autonomous cell lethality from the primitive endoderm and trophectoderm lineages. Conversely paternal chromosomes in androgenetic cells confer opposite properties since the embryonic cells can be detected in the trophoblast and the yolk sac but not in the embryos, presumably because they are eliminated from the primitive ectoderm lineage. The spatial distribution of cells with different parental chromosomes may occur partly because of differential expression of some genes, such as proto-oncogenes, and partly due to their ability to respond to a variety of diffusible growth factors.