The accumulation of basic nonhemoglobin proteins during the differentiation of primitive (embryonic) red cells of amphibia

The preferential accumulation of hemoglobin is a characteristic of the differentiation of definitive (adult) red blood cells. Since primitive (embryonic or larval) red blood cells have many properties which contrast with definitive red cells, the accumulation of red cell proteins was analyzed during the differentiation of primtive red cells to determine whether or not hemoglobin was the only protein which showed a substantial increase in amount. Primitive red cells of amphibia were used because the mature circulating cell retains large amounts (13%) of specific, well characterized, nonhemoglobin proteins (CP). Preparations of primitive red cells enriched in immature cells were obtained from the circulation of bullfrog tadpoles recovering from phenylhydrazine-induced anemia. The amount of CP, determined by electrophoresis, imunodiffusion, and ion-exchange chromatography, was compared for red cells from normal animals and anemic animals. Mature cells contained three to six times the amount of CP and three times the amount of hemoglobin found in the population of red cells enriched in immature cells. The accumulation of CP during maturation of primitive red cells indicates that differentiation of primitive red cells is less restrictive than differentiation of definitive red cells. Since the primitive red cell is less specialized than the definitive red cell, it is possible that primitive red cells have several roles in the developing animal, in contrast to the single role of synthesizing and maintaining hemoglobin in the adult animal.     

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.     

Immunolocalization of a nuclear protein bound to the sphere organelle during oogenesis and embryogenesis inPleurodeles waltl

Summary The distribution of a nuclear antigen ofPleurodeles waltl oocytes, recognized by the monoclonal antibody B24/1, has been studied during oogenesis and early embryonic development. In stage I oocytes the antigen was localized in the nucleoplasm and on two atypical structures of lampbrush chromosomes, the spheres (S) and the mass (M). The immunostaining increased as the oocyte developed. In stage VI oocytes, the nucleoplasm and spheres showed intense staining. At this stage, the nucleoplasm often contained free spheres which were also labelled. The staining of M diminished during oogenesis, as did its size. Immunoblots of nuclear proteins of oocytes at different stages confirmed that there was an accumulation of this protein during oogenesis. During embryonic development, the nuclei of all the cells of blastula and gastrula were labelled by this antibody: there was no embryonic regionalization. Starting from the neurula stage, the staining progressively disappeared from the nuclei of ectodermal and mesodermal cells. In the tailbud stage, only the endodermal cell nuclei showed faint staining. Immunoblots of proteins from embryos of different stages showed that the quantity of this protein was constant until the young gastrula stage and then decreased progressively; in the young tailbud stage, this protein was practically absent. B24/1 is the first described protein of the sphere. This protein is accumulated in the oocyte nucleus and behaves like a maternal polypeptide, shifting early in the nuclei during embryonic development. Thus, B24/1 probably has a function required from the early developmental stages, perhaps in relation with small nuclear ribonucleoproteins.     

Leishmania donovani: correlation among assays of amastigote viability

The viability of Leishmania donovani amastigotes was evaluated using two in vitro assays: the initiation of differentiation of viable cells toward the promastigote stage in tissue culture Medium 199 and the staining of nonviable amastigotes with erythrosin B. The results of these assays correlated with those of a previously described in vivo assay in which viability was related to the minimum number of amastigotes in mouse liver following intravenous injection. Results indicate that erythrosin B staining should be routinely used to evaluate viability of amastigote populations, but that the initiation of differentiation of amastigotes is a more sensitive assay. For best results with the latter method, it is suggested that no more than 1.2 × 10⁷ amastigotes in 1 ml of Medium 199 be incubated at 25 C in 5% CO₂ in air. The data presented indicate that routine manipulations may affect amastigote viability.     

Relationship between the major phosphorylated metabolic intermediates and oxygen affinity of whole blood in the loggerhead (Caretta caretta) and the Green Sea Turtle (Chelonia mydas) during development.

(1) 2,3-Diphosphoglyceric acid (2,3-DPG) is present in the erythrocytes (RBC) of the 68-day loggerhead turtle embryo and 44-day green sea turtle embryo at levels of 7.4 and 5.5 μmoles/ml of RBC, representing the major organic phosphate during the latter period of embryonic development. (2) Inositol pentaphosphate (IPP) is absent in the red blood cells of the embryos of both the loggerhead and green sea turtle. (3) Near equimolar amounts of 2,3-DPG and IPP are present in the erythrocytes of the adult loggerhead and green sea turtle. The total concentration of these two organic phosphates is approximately 0.75 μmoles/ml of RBC in the adult of both species. (4) There is a switch from embryonic to adult hemoglobin during development of these two species of turtles; the two embryonic bands have identical electrophoretic mobilities, whereas the two adult bands migrate differently on cellulose acetate at pH 8.6. (5) The whole blood oxygen affinity of the adult loggerhead and green sea turtle is 60.3 and 32.6 Torr, respectively. (6) The stripped adult hemoglobins in these two species of turtles show no change in oxygen affinity upon addition of 2,3-DPG, ATP, or IPP. (7) It therefore appears unlikely that whole blood oxygen affinity is controlled by organic phosphate modulation of hemoglobin function in these species of turtles.     

Targeted O2 delivery by low-P50 hemoglobin: a new basis for O2 therapeutics

To assess O2 delivery to tissue by a new surface-modified, polyethylene glycol-conjugated human hemoglobin [MP4; Po2 at 50% saturation of hemoglobin (P50); 5.4 mmHg], we studied microcirculatory hemodynamics and O2 release in golden Syrian hamsters hemodiluted with MP4 or polymerized bovine hemoglobin (PolyBvHb; P50 54.2 mmHg). Comparisons were made with the animals' hemodiluted blood with a non-O2 carrying plasma expander with similar solution properties (Dextran-70). Systemic hemodynamics (arterial blood pressure and heart rate) and acid-base parameters were not correlated with microhemodynamics (arteriolar and venular diameter, red blood cell velocity, and flow). Microscopic measurements of Po2 and the O2 equilibrium curves permitted analysis of O2 release in precapillary and capillary vessels by red blood cells and plasma hemoglobin separately. No significant differences between the groups of animals with respect to arteriolar diameter, flow, or flow velocity were observed, but the functional capillary density was significantly higher in the MP4-treated animals (67%) compared with PolyBvHb-treated animals (37%; P < 0.05) or dextran-treated animals (53%). In the PolyBvHb-treated animals, predominant O2 release (both red blood cells and plasma hemoglobin) occurred in precapillary vessels, whereas in MP4 animals most of the O2 was released from both red blood cells and plasma hemoglobin in capillaries. Base excess correlated directly with capillary O2 release but not systemic O2 content or total O2 release. Higher O2 extraction of both red blood cell and plasma hemoglobin in capillaries represents a new mechanism of action of cell-free hemoglobin. High O2 affinity appears to be an important property for cell-free hemoglobin solutions.     

Hb switching in chickens

We have taken advantage of the preferential digestion of active genes by DNAase I to investigate the chromosomal structure of embryonic and adult β-globin genes during erythropoiesis in chick embryos, and in particular to examine the question of hemoglobin switching during development. DNA in isolated red cell nuclei was mildly digested with DNAase I to about 10–15 kb, purified and restricted with a variety of restriction enzymes. The DNA was then separated on agarose gels, transferred to nitrocellulose filters and hybridized with an adult-specific β-globin cDNA clone or a genomic clone containing the genes coding for both an embryonic and an adult β-globin chain. Preferential sensitivity of the respective globin genes was monitored by the disappearance of specific restriction bands after DNAase I digestion of nuclei. In embryonic red cells, both adult and embryonic β-globin genes are very sensitive to DNAase I; however, in adult erythroid lines, the embryonic β-globin gene becomes relatively more resistant but the adult gene remains highly sensitive. Controls showed that all globin genes were resistant to DNAase I in brain nuclei and nuclei from lymphoid cells. Thus the switch from embryonic to adult globin expression is associated with an apparent change in the chromosome structure of the embryonic globin gene as reflected in the gene becoming less accessible to DNAase I in adult red cell nuclei. Our results also show that the chromosomal structure of both adult and embryonic genes is altered in embryonic red cell nuclei; thus the nonexpressed globin gene (that is, the adult gene in embryonic red cells) has already been “recognized” to some degree and marked by the erythroid compartment. The sensitivity of the adult globin gene in embryonic cells may represent a “pre-activation” state of the chromosome.     

Blood parameter changes during stopover in a long-distance migratory shorebird, the bar-tailed godwit Limosa lapponica taymyrensis

Bar-tailed godwits migrate from West African wintering sites to breeding areas in northern Russia with only one stopover. We compared hematocrit (Hct), blood hemoglobin concentration (Hb), and mean cell hemoglobin concentration (MCHb; a measure of the relative proportion of Hb in the cellular blood fraction) between arriving godwits lured to land 60 km short of the stopover site and godwits during subsequent refueling. The Hct and Hb of arriving godwits was low when compared to that of refueling birds. On the stopover site, Hct and Hb correlated positively with size-corrected body mass. In addition, Hb and MCHb reached peak levels in the last days of stopover. We explored the possibility of regenerative anemia in arriving godwits by comparing the fraction of reticulocytes (young red blood cells) between arriving and refueling birds. No differences were found. Therefore, we suggest that the increase in Hct, Hb, and MCHb during refueling is not in response to a severe anemic state at arrival. Rather, we suggest that the increase in blood parameters may anticipate the increased aerobic requirements of impending migratory flight and possibly satisfy heightened oxygen demands of the larger body mass of fattened birds. The Hct increase on the stopover site may also serve to buffer the red blood cell population against possible red blood cell breakdown during long-distance flight.     

The Histochemical Demonstration of Hemoglobin in Blood Cells and Tissue Smears

The demonstration of intracellular hemoglobin in permanent preparations has long been a problem. The affinity of hemoglobin for iron hematoxylin is well known but this stain also colors yolk, chromatin, and other structures and is therefore not a reliable criterion. The presence of hemoglobin has been associated with an acidophil cytoplasm which stains a characteristic color, but a careful inspection of living cells in early hematopoetic or embryological stages demonstrates that hemoglobin is present in the erythrocytes which are quite basophilic. In the course of some research on the blood of embryonic frogs it became desirable to demonstrate the presence of hemoglobin in cells by means of a specific staining reaction.     

The chianti zebrafish mutant provides a model for erythroid-specific disruption of transferrin receptor 1

Iron is a crucial metal for normal development, being required for the production of heme, which is incorporated into cytochromes and hemoglobin. The zebrafish chianti (cia) mutant manifests a hypochromic, microcytic anemia after the onset of embryonic circulation, indicative of a perturbation in red blood cell hemoglobin production. We show that cia encodes tfr1a, which is specifically expressed in the developing blood and requisite only for iron uptake in erythroid precursors. In the process of isolating zebrafish tfr1, we discovered two tfr1-like genes (tfr1a and tfr1b) and a single tfr2 ortholog. Abrogation of tfr1b function using antisense morpholinos revealed that this paralog was dispensable for hemoglobin production in red cells. tfr1b morphants exhibited growth retardation and brain necrosis, similar to the central nervous system defects observed in the Tfr1 null mouse, indicating that tfr1b is probably used by non-erythroid tissues for iron acquisition. Overexpression of mouse Tfr1, mouse Tfr2, and zebrafish tfr1b partially rescued hypochromia in cia embryos, establishing that each of these transferrin receptors are capable of supporting iron uptake for hemoglobin production in vivo. Taken together, these data show that zebrafish tfr1a and tfr1b share biochemical function but have restricted domains of tissue expression, and establish a genetic model to study the specific function of Tfr1 in erythroid cells.     

Characterization of embryonic globin genes of the zebrafish

Hemoglobin switching is a complex process by which distinct globin chains are produced during stages of development. In an effort to characterize the process of hemoglobin switching in the zebrafish model system, we have isolated and characterized several embryonic globin genes. The embryonic and adult globin genes are found in clusters in a head-to-head configuration. One cluster of embryonic and adult genes is localized to linkage group 3, whereas another embryonic cluster is localized on linkage group 12. Several embryonic globin genes demonstrate an erythroid-specific pattern of expression early during embryogenesis and later are downregulated as definitive hematopoiesis occurs. We utilized electrospray mass spectroscopy to correlate globin genes and protein expression in developing embryonic red cells. The mutation, zinfandel, has a hypochromic microcytic anemia as an embryo, but later recovers in adulthood. The zinfandel gene maps to linkage group 3 near the major globin gene locus, strongly suggesting that zinfandel represents an embryonic globin defect. Our studies are the first to systematically evaluate the embryonic globins in the zebrafish and will ultimately be useful in evaluating zebrafish mutants with defects in hemoglobin production and switching.     

Assessing acrosomal status of bovine sperm using fluoresceinated lectins

Binding of 12 lectins to bull sperm was analyzed to select a lectin that bound preferentially to the acrosomal region. Peanut agglutinin (PNA) and Pisum sativum agglutinin (PSA) were suitably specific for intracellular, acrosome-associated glycoconjugates. Peanut agglutinin exhibited almost no detectable binding to sperm surface receptors, but intense binding to the area of the acrosome anterior to the equatorial segment. In contrast, PSA bound intensely to anterior and equatorial acrosomal regions, and weakly to the other regions of the sperm. Acrosomal labeling by both lectins decreased when sperm were induced to acrosome-react with calcium ionophore. To determine if these lectins could be used to assess acrosomal status, we compared the percentage of acrosome-reacted sperm that were detected by staining with naphthol yellow and erythrosin B with the percentage that were detected by lectin labeling. The incidence of reacted sperm detected by PSA labeling was not significantly different from that detected by naphthol yellow/ erythrosin B (P = 0.46). The incidence of reacted sperm detected by PNA was correlated with the incidence detected by naphthol yellow/erythrosin B, but was significantly lower (P = 0.003). We conclude that labeling permeabilized sperm with fluoresceinated PSA can serve as a rapid assay for acrosomal status.     

Stopped-flow kinetics of oxygen uptake and release by embryonic red blood cells.

The processes of O2 uptake and release by the three embryonic haemoglobins contained within early mouse embryonic red blood cells have been studied using dual-wavelength stopped-flow kinetic spectroscopy. The rate of O2 uptake in the pseudo-spherical, nucleated, embryonic red blood cells exhibits a greater than first-order dependence on O2 concentration. The time courses for the release from the red blood cells into dithionite-containing solutions tends towards a limiting rate at high dithionite concentrations. The rates of both the uptake and release processes observed in the embryonic cells are compared with those previously seen for adult mouse red blood cells. A new mathematical model is described which accurately simulates both uptake and release experimental data for the nucleated embryonic red blood cells.     

Cathodal proteins from primitive (embryonic) red cells of amphibia. Isolation and characterization.

A group of abundant (15% of the soluble protein) nonhemoglobin proteins was isolated from the primitive (embryonic) red cells found in tadpoles, using the cationic properties of the proteins at pH 8.6 to separate them from hemoglobin and other red cell proteins. The cathodal proteins (CP) were resolved into five components, and the two most predominant proteins were separated and characterized. Purified CP-1b and CP-2 had an amino acid composition similar to that of unfractionated cathodal proteins and to each other, except for small variations in the lysine and half-cystine content. The molecular weight of the purified CP-1b and CP-2 was 13 to 14,000, determined by gel filtration chromatography and electrophoresis in the presence of sodium dodecyl sulfate. Cathodal proteins were immunologically related although there were quantitative differences in reactivity. The concentration of cathodal proteins in primitive (embryonic) red cells was 100 times that in definitive (adult) red cells coincided with the replacement of primitive red cells. The synthesis of the cathodal proteins appeared to continue throughout the life of the primitive red cells; when hemoglobin synthesis declined in primitive red cells, approximately half of the protein synthesized by the cells was cathodal protein. Although the function of the cathodal proteins is as yet unknown, the data suggest that the cathodal proteins are a unique characteristic of erythroid differentiation in early development.     

NTP pattern of avian embryonic red cells: role of RNA degradation and AMP deaminase/5'-nucleotidase activity

During terminal erythroid differentiation, degradation of RNA is a potential source for nucleotide triphosphates (NTPs) that act as allosteric effectors of hemoglobin. In this investigation, we assessed the developmental profile of RNA and purine/pyrimidine trinucleotides in circulating embryonic chick red blood cells (RBC). Extensive changes of the NTP pattern are observed which differ significantly from what is observed for adult RBC. The biochemical mechanisms have not been identified yet. Therefore, we studied the role of AMP deaminase and IMP/GMP 5'-nucleotidase, which are key enzymes for the regulation of the purine nucleotide pool. Finally, we tested the effect of major NTPs on the oxygen affinity of embryonic/adult hemoglobin. The results are as follows. 1) Together with ATP, UTP and CTP serve as allosteric effectors of hemoglobin. 2) Degradation of erythroid RNA is apparently a major source for NTPs. 3) Developmental changes of nucleotide content depend on the activities of key enzymes (AMP deaminase, IMP/GMP 5'-nucleotidase, and pyrimidine 5'-nucleotidase). 4) Oxygen-dependent hormonal regulation of AMP deaminase adjusts the red cell ATP concentration and therefore the hemoglobin oxygen affinity.     

The life span of red blood cells in the amphibian larvae, Rana catesbeiana

Nearly one hundred amphibian tadpoles were made anemic by phenylhydrazine injection. During the recovery period radioactive thymidine was incorporated into the DNA of the nucleated amphibian red blood cells. Over the next 135 days blood was drawn and smears of circulating red blood cells were prepared. The blood smears from each tadpole were autoradiographed and percentage of labeled nuclei (PLN) determined. The average life span of tadpole red blood cells was calculated from the change in PLN, and is about 100 days. It is concluded that during the transition from tadpole to frog, the tadpole red blood cell life span must be drastically shortened to account for the hemoglobin transition observed during amphibian metamorphosis.     

The Homeostasis of Plasmodium falciparum-Infected Red Blood Cells

The asexual reproduction cycle of Plasmodium falciparum, the parasite responsible for severe malaria, occurs within red blood cells. A merozoite invades a red cell in the circulation, develops and multiplies, and after about 48 hours ruptures the host cell, releasing 15–32 merozoites ready to invade new red blood cells. During this cycle, the parasite increases the host cell permeability so much that when similar permeabilization was simulated on uninfected red cells, lysis occurred before ~48 h. So how could infected cells, with a growing parasite inside, prevent lysis before the parasite has completed its developmental cycle? A mathematical model of the homeostasis of infected red cells suggested that it is the wasteful consumption of host cell hemoglobin that prevents early lysis by the progressive reduction in the colloid-osmotic pressure within the host (the colloid-osmotic hypothesis). However, two critical model predictions, that infected cells would swell to near prelytic sphericity and that the hemoglobin concentration would become progressively reduced, remained controversial. In this paper, we are able for the first time to correlate model predictions with recent experimental data in the literature and explore the fine details of the homeostasis of infected red blood cells during five model-defined periods of parasite development. The conclusions suggest that infected red cells do reach proximity to lytic rupture regardless of their actual volume, thus requiring a progressive reduction in their hemoglobin concentration to prevent premature lysis.