Kallichrome: A New Stain for Erythroblasts

Using the obscure dye kallichrome, erythroblasts at all stages of maturation demonstrated intense yellow to yellow-brown staining of both nucleus and cytoplasm. Staining of this type was not observed in other types of normal or pathological marrow cells. As such, kallichrome may be a valuable stain for identification of erythroblasts and their distinction from other types of blood cells.     

Conformation of RNA in situ as studied by acridine orange staining and automated cytofluorometry.

Human erythroblasts which are prereticulocyte maturation stages of red blood cells were studied by light microscopic cytochemistry and electron microscopy to provide more information on the ultrastructure of the micronucleoli which are terminal stages of nucleolar changes found during maturation of these cells. As indicated by light microscopy of smeared cells, micronucleoli were virtually the only types of nucleoli present in the last stages of maturing erythroblasts, i.e., polychromatic and orthochromatic (late polychromatic) erythroblasts. Accordingly, they were not portions of the periphery of other nucleoli. Inasmuch as most of the micronucleoli exhibited characteristic segregation of nucleolar fibrillar and granular components they presumably are producing little if any preribosomal RNA, since such segregation generally reflects inhibition of nucleolar RNA synthesis.     

Changes in the Expression of Membrane Antigens During the Differentiation of Chicken Erythroblasts

Chicken erythroblasts can be transformed by the avian retrovirus, avian erythroblastosis virus (AEV). Earlier studies have shown that the mechanism of transformation appears to involve a “block” in differentiation, in that when erythroblasts are transformed by a temperature-sensitive mutant of ts34 AEV and incubated at the nonpermissive temperature, the cells start to differentiate and produce hemoglobin. We have decided to use this system to isolate pure populations of chicken erythroblasts and raise monoclonal antibodies against their cell surface proteins. Three monoclonal antibodies were isolated and tested for their ability to bind to various hematopoietic cell types; two were shown to be erythroid-specific, whereas the other antibody bound to proliferating cells but not to erythrocytes or granulocytes. Of the erythroid-specific antibodies, one precipitated a 94,000 molecular weight protein, whereas the other precipitated a 11,000 molecular weight protein that was tentatively identified as hemoglobin. The use of this system and approach to identify and evaluate changes that occur during the differentiation is discussed.     

Absence of erythroblastic islands in plasma clot culture and their possible reconstitution after clot lysis

Ultrastructural studies of erythroid colonies derived from human peripheral blood and growing in plasma clot culture have confirmed the absence of a macrophage inside each colony of erythroblasts. However, when macrophages and erythroblasts were liberated from the semisolid media by clot lysis, these two types of cells rapidly acquired intimate contacts, suggesting the reconstitution of any erythroblastic island. The possible significance of this phenomenon is discussed.     

The cellular composition of hemopoietic spleen colonies

The cellular composition of individual hemopoietic spleen colonies has been studied using techniques which tested primarily for cell function rather than cell morphology. Erythroblastic cells were recognized by their capacity to incorporate radioiron, granulocytic cells by their content of peroxidase-positive material, and hemopoietic stem cells by their ability to form spleen colonies in irradiated hosts. It was found that, 14 days after the initiation of spleen colonies, the distribution of these cell types among individual colonies was very heterogeneous, but that most colonies contained detectable numbers of erythroblasts, granulocytes and colony-forming cells. An appreciable proportion of the cells in the colonies could not be identified as any of these three cell types. No strong correlations between numbers of erythroblasts, granulocytes and colony-forming cells in individual colonies were observed, though there was a tendency for colonies containing a high proportion of erythroblasts to contain a low proportion of granulocytes, and for colonies containing a high proportion of granulocytes to contain a higher proportion of colony-forming cells. An analysis of colonies which contained cells bearing radiation-induced chromosomal markers indicated that 83–98% of the dividing cells within 14-day spleen colonies were derived from single precursors.     

Nucleolar changes in maturing avian erythroblasts and erythrocytes

Maturing erythroblasts and erythrocytes were studied in chickens and adult hens to provide more information on the presence and frequency of various nucleolar types in these cells. Nucleoli were present at all stages of erythroblastic and erythrocytic development except in the case of a few reticulocytes and the mature erythrocytes. The number of nucleoli per cell (expressed as the nucleolar coefficient) reached a maximum at the stage of the polychromatic erythroblast. Early erythroblasts were characterized by the presence of compact nucleoli or nucleoli with nucleolonemata. Rings shaped nucleoli and micronucleoli increased in number with further maturation. Cells of the final erythroblast stage (orthochromatic erythroblasts) contained mostly micronucleoli, and micronucleoli alone were present in reticulocytes and mature erythrocytes.     

Ultrastructural study of a cytoplasmic bridge connecting a pair of erythroblasts in mice

Summary A unique cytoplasmic connection between erythroblasts was studied by electron microscopy in mouse hemopoietic tissues (fetal liver, fetal and neonatal spleen and adult bone marrow). Many pairs of interphase erythroblasts were connected by a cytoplasmic bridge that was very thin and sometimes long in comparison with telophase bridges. The stage of maturation of the cells in a pair was similar. Small numbers of microtubules ran along the cytoplasmic bridge; a mid-body was not seen. The plasma membrane at approximately the middle of the bridge bulged to form a ring-shaped ridge filled with dense amorphous substances; this was called a bulging ring. Thus, the cytoplasmic bridge between erythroblasts did not morphologically correspond to the telophase bridge in the usual cytokinesis. Cytoplasmic bridges were observed in various differentiating stages of erythroblasts, whereas other cell types of the hemopoietic lineage did not have such a bridge. The cytoplasmic bridge is unique to erythroblasts and provides an evidence for the atypical cytokinesis of the erythroblastic lineage.     

Activity of selenium-dependent enzymes in erythroid cells of animals in the postnatal period

The age dynamics of selenium-dependent enzymes glutathione peroxidase and thyroxine-5'-deiodinases type I and II (D1 and D2 respectively) in bone marrow erythroblasts of new-born, 1-, 3-, 5- and 10-day old piglets as well as influences of hormones (thyroxine, cortisol) selenium and iron on enzyme activities were investigated. The enzyme activities in the pig erythroid cells were established to increase after birth. D1 activity increased in erythroblasts of 3-day old piglets, while augmentation of D2 activity was significant in the cells of 10-day old animals. Glutathione peroxidase and thyroxine-5'deiodinase activities in pig erythroblasts decreased under the influence of thyroxine and hydrocortisone in vivo, and increased after injections of sodium selenite. For comparison, activities of 5'-deiodinases in the cells of some other tissues were also investigated.     

Immunoelectron microscopic detection of band 3 protein during erythroid cell differentiation by a monoclonal antibody

We created a monoclonal antibody, designated EB1 (IgM, kappa), that reacts with erythroblasts by fusion of P3-X63-Ag8.653 with splenocytes of rats immunized with erythroblastic islands isolated from mice spleens. Western blotting revealed that EB1 reacted with the band 3 protein of the erythrocytic membrane. It stained erythrocytes and erythroblasts, forming clusters in the bone marrow, splenic red pulp, and fetal liver, but did not stain other tissues in the cryostat sections. The EB1 antigen was detected during dimethyl sulfoxide-induced differentiation of murine erythroleukemia cells. Immunoelectron microscopy revealed that the EB1 antigen was expressed from the basophilic erythroblasts during normal erythroid differentiation. Preferential segregation of the EB1 antigen on the cell membrane of the nucleating erythroblasts was not observed. These results suggest that EB1 is specific for erythrocyte band 3 protein and may be useful for studying erythroid cell differentiation.     

Human mature erythroblasts are resistant to apoptosis

Apoptosis plays an important role in red blood cell development, notably by regulating the fate of early erythroid progenitors. We show here that, by contrast, mature erythroblasts are resistant to apoptosis. Treatment of these cells with several apoptosis-inducing agents failed to trigger caspase activation and oligonucleosomal DNA fragmentation. Interestingly, we find that cytochrome c levels are dramatically reduced even though the cells contain mitochondria. Supplementation of cytosolic extracts from mature erythroblasts with cytochrome c, however, did not rescue caspase activation. This was not due to the presence of inhibitors of apoptosis, as these proteins were also missing in these cells. We also show that cytochrome c depletion is a normal event during erythroblast differentiation, which follows transient, developmentally induced caspase activation and correlates with the loss of response to cytokine withdrawal or drug-induced apoptosis. Our data therefore suggest that erythroblasts acquire resistance to apoptosis during maturation through the developmentally induced depletion of cytochrome c and other crucial regulators of the apoptotic machinery.     

New morphological aspects of blood islands formation in the embryonic mouse hearts

Vasculogenesis in embryonic hearts proceeds by formation of aggregates consisting of erythroblasts and endothelial cells. These aggregates are called blood-islands or blood-island-like structures. We aimed to characterize blood islands in mouse embryonic hearts at stages spanning from 11 dpc through 13 dpc, i.e. prior to the establishment of the coronary circulation. Our observations suggested that there are two types of blood islands. One formed by migrating nucleated erythroblasts, which associated with migrating endothelial cell and the second by in situ emergence of two kinds of cells belonging to separate populations: one resembling an erythroblast progenitor and the second resembling an endothelial-cell progenitor. The subepicardial blood islands contain nucleated erythroblasts, undifferentiated mesenchymal cells, platelets, and early lymphocytes. The subepicardial blood islands resemble vesicles with protruding prongs directed toward the myocardium. Ahead of the prongs, angiogenic sprouting and degradation of fibronectin is observed. Vesicles gradually change their shape from spherical to tubular at 13 dpc and grow and extend along the interventricular sulcuses forming vascular tubes. We presume that the vascular tubes located within the interventricular sulcuses are precursors of coronary veins. Our data seems to indicate that embryonic heart vasculogenesis is accompanied by hematopoiesis     

H-Ferritin Is Preferentially Incorporated by Human Erythroid Cells through Transferrin Receptor 1 in a Threshold-Dependent Manner

Ferritin is an iron-storage protein composed of different ratios of 24 light (L) and heavy (H) subunits. The serum level of ferritin is a clinical marker of the body’s iron level. Transferrin receptor (TFR)1 is the receptor not only for transferrin but also for H-ferritin, but how it binds two different ligands and the blood cell types that preferentially incorporate H-ferritin remain unknown. To address these questions, we investigated hematopoietic cell-specific ferritin uptake by flow cytometry. Alexa Fluor 488-labeled H-ferritin was preferentially incorporated by erythroid cells among various hematopoietic cell lines examined, and was almost exclusively incorporated by bone marrow erythroblasts among human primary hematopoietic cells of various lineages. H-ferritin uptake by erythroid cells was strongly inhibited by unlabeled H-ferritin but was only partially inhibited by a large excess of holo-transferrin. On the other hand, internalization of labeled holo-transferrin by these cells was not inhibited by H-ferritin. Chinese hamster ovary cells lacking functional endogenous TFR1 but expressing human TFR1 with a mutated RGD sequence, which is required for transferrin binding, efficiently incorporated H-ferritin, indicating that TFR1 has distinct binding sites for H-ferritin and holo-transferrin. H-ferritin uptake by these cells required a threshold level of cell surface TFR1 expression, whereas there was no threshold for holo-transferrin uptake. The requirement for a threshold level of TFR1 expression can explain why among primary human hematopoietic cells, only erythroblasts efficiently take up H-ferritin.     

Primitive erythropoiesis in early chick embryogenesis. II. Correlation between hemoglobin synthesis and the mitotic history

Primitive erythroblasts in the circulating blood of the chick embryo continue to divide while synthesizing hemoglobin (Hb). Hb measurements on successive generations of erythroblasts show that there is a progressive increase in the Hb content of both interphase and metaphase cells. Furthermore, for any given embryo the Hb content of metaphase cells is always significantly greater than that of interphase cells. The distribution of Hb values for metaphase cells suggests that there are six Hb classes corresponding to the number of cell cycles in the proliferative phase. The location of erythroblasts in the cell cycle was determined by combining Feulgen cytophotometry with thymidine radioautography on the same cells. Measurements of the Hb content for erythroblasts in different compartments of the cell cycle (G1, S, G2, and M) show a progressive increase through the cycle. Thus, the amount of Hb per cell is a function of the number of cell divisions since the initiation of Hb synthesis and, to a lesser degree, the stage of the cell cycle. Earlier generations of erythroblasts synthesize Hb at a faster rate than the terminal generation. Several models have been proposed to explain these findings.     

Light- and Electronmicroscopic Observations on the Blood Cells of the Atlantic Hagfish,Myxine glutinosa (L.)

In the blood of Myxine glutinosa three cell lines may be distinguished: erythrocytes, granulocytes and agranulocytes. The erythrocytes are remarkably large, oval and nucleated. They are well defined in all their developmental stages by a characteristic micropinocytosis. They originate from blast cells which proliferate in the circulating blood. The blast cells probably form from agranulate stem cells of the intestinal myeloid tissue. The granulocytes constitute about half of the leucocytes. They are neutrophilic with a lobated nucleus. The granulocytopoiesis takes place in the intestinal myeloid tissue. The agranulocytes mainly include two cell types, termed spindle cells and lymphocyte-like cells. These cell types, however, transform into each other. Macrophages occur essentially in the peritoneal cavity rarely in the blood. Transition forms between macrophages and granulocytes may exist. The blood also contains cells which on morphological grounds have been termed thrombocytes. Whether these cells are identical with those necessary for clotting of the blood remains to be proved. With the exception of erythroblasts, the different lines of blast cells are difficult to identify and distinguish from each other. Possibly all lines of blood cells originate from agranulate lymphocyte-like stem cells, most of which are produced by the intestinal myeloid tissue.     

Isolation and short-term culture of mouse splenic erythroblastic islands

We isolated and cultured erythroblastic islands (EI) from the spleens of phlebotomized mice using a combination of collagenase digestion, unit gravity sedimentation, and Percoll density gradients separation. The isolated EI were composed of surrounding erythroid cells and central stromal macrophages (M phi), which were identified by Forssman antigen. While 60% of the erythroblasts incorporated bromodeoxyuridine, the M phi did not. EI could be maintained on a plastic dish for a short period in the presence of erythropoietin. Two hours later, the central M phi spread well and bound to erythroblasts via cytoplasmic processes. One day later, erythropoietic activity on the M phi surface continued, although their processes had retracted. Some EI showed synchronized expansion of erythroblasts and others showed differentiation to reticulocytes. Two days later, about 50% of the EI still showed erythropoietic activity and most erythroblasts differentiated to the orthochromatic stage. On the other hand, the M phi secreted colony-stimulating activity during the culture. It was infrequently observed that erythroid and myeloid populations simultaneously expanded on a central M phi. These results indicate that this EI culture system is useful for studying interactions between the stomal M phi and hematopoietic cells.     

Ultrastructural study of the blood cells of the beluga whale, Delphinapterus leucas

General cytological and ultrastructural features of cells found in the peripheral blood of three captive beluga whales (Delphinapterus leucas) are described. We noted all major peripheral cell types common to the circulation of mammalian species, including polymorphonuclear neutrophils, eosinophils, basophils, lymphocytes, and monocytes, as well as myelocytes, erythroblasts, and plasma cells. Platelets and two populations (normal and hypochromic) of red blood corpuscles were observed.     

PRIMITIVE ERYTHROPOIESIS IN EARLY CHICK EMBRYOGENESIS : I. Cell Cycle Kinetics and the Control of Cell Division

The primitive line of embryonic chick blood cells develop as a relatively homogeneous cohort of cells. Using an analysis based on the continuous uptake of thymidine-³H, we have established the generation time, G1, S, and G2 for progressively more mature generations of these immature erythroblasts. The data indicate that after the initiation of hemoglobin synthesis, the average cell will yield six generations of hemoglobin producing erythroblasts. The older generations of erythroblasts exhibit a longer generation time, G1, S, and G2 than the earlier generations of erythroblasts. Other methods of analysis corroborated these findings. One of these methods, an estimate of total erythrocyte productivity from the primitive stem cells (hematocytoblasts), led to the conclusion that the erythroblast cell lineage might be initiated as early as the sixth or seventh division following fertilization. In addition, primitive erythroblasts characterized by one set of cell cycle parameters, when grown in serum associated with erythroblasts of different parameters, showed no alteration in mitotic behavior. These results suggest the presence of programmed cell division not immediately cued by extracellular influence.     

Alterations in the surface glycoproteins of chicken erythrocytes following transformation with erythroblastosis strain R virus

Summary Erythroblasts from marrows of chicks infected with RNA-virus (strain Rerythroblastosis virus) were found to possess a small but consistent increase in the number of concanavalin A binding sites per cell compared to erythroblasts derived from the marrows of phenylhydrazine-treated birds. Both types of erythroblast possessed more surface glycoproteins per cell accessible to concanavalin A (Con A) than marrow and peripheral blood erythrocytes. Employment of concanavalin A conjugated to ferritin showed marked differences in the spatial arrangement of the Con A receptors between phenylhydrazine and virus-induced erythroblasts but little difference was observed in the surface density of the Con A sites between erythrocytes and erythroblasts, a result which agrees with the amount of bound labeled Con A when this data is expressed in terms of the cell surface.The amount of labeled Con A bound to erythrocytes derived from the marrow was greater than that derived from the peripheral circulation, a result which is substantiated by the ferritin Con A studies which show an increase in the density of Con A sites on the marrow blood cells. Trypsinization increases the number of sites and the agglutininability of the marrow cells.The increase in the susceptibility of the cells to agglutinate with concanavalin A paralleled the observed increase in the number of binding sites per cell.     

Identification of normal and leukemic granulocytic cells with merocyanine 540

After fixation in a modified Bouin's solution, the acid dye merocyanine 540 stained granules in granulocytic cells intensely. In immature granulocytes, such as promyelocytes and myelocytes, granules stained pink to violet. In some leukemic myeloblasts, promyelocytes and monocytes, granules also stained deep pink to violet. In more mature granulocytes, such as metamyelocytes, bands, and neutrophils, granules stained bright red to orange. In eosinophils and basophils, granules stained deep red. Granules of the type described were not visualized in normal plasma cells, lymphocytes, monocytes, or megakaryocytes. In normoblasts, cytoplasm stained diffusely red. Cytoplasmic staining in erythroblasts became darker as the cell matured, probably reflecting hemoglobin content. Used as a single agent stain, merocyanine 540 may be useful in distinguishing normal and leukemic granulocytic cells from other types of blood cells.     

小鼠胎肝红系细胞在分化过程中形态学观察及时序性表达分析

小鼠胎肝是小鼠发育早期主要的造血器官,红系细胞在胎肝造血过程中形态特征和组成成分等方面发生了明显变化。根据红系细胞体积的变化,利用Countstar细胞计数仪对小鼠E12．5-E17．5胎肝中直径8-14岬细胞进行数量统计,再结合观测到的红系细胞的形态特征和血红蛋白表达量的不同,将E9．5．E17．5胎肝中的细胞分为10类。统计结果显示,随着胎肝造血系统的发育,哺乳类红系细胞在终末分化时出现细胞体积减小、细胞核固缩、排核和血红蛋白表达量增加等时序性变化。红系细胞表面特异标志Terll9和CD71在EryD中高表达而在成体骨髓细胞和外周血细胞中表达较低的结果表明胎肝中红系细胞具有较高的分化能力。这些数据为研究红系分化、克隆红系分化相关基因及探讨红白血病发生的机制提供了理论依据。