Proliferation kinetics of bone marrow cells in congenital dyserythropoietic anemia type II

The proliferation kinetics of erythropoiesis and of myelopoiesis have been studied in a case of congenital dyserythropoietic anemia type II (HEMPAS) by means of quantitative 14-C autoradiography, Feulgen cytophotometry and 59-Fe ferrokinetics. Increased total erythropoietic activity and ineffective erythropoiesis was demonstrated by ferrokinetics. Quantitative 14-C autoradiography showed a generally delayed proliferation rate of erythroid cells, most evident in the polychromatic compartment. A deficiency of cell production of 25% was detected among the polychromatic erythroblasts. Part of this fraction is represented by cells still capable of passing to the successive stages of maturation. We conclude that only part of the deficiency of cell production in the polychromatic compartment represents real cell destruction. Most of the measured ineffectiveness is confined to later stages of maturation, such as orthochromatic erythroblasts and marrow reticulocytes.     

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.     

Early origins of definitive erythroid cells in the chick embryo

The early maturation stages of definitive erythroid cells are observed in the embryonic circulation of the chick yolk sac at 4.5--5 days of incubation. Light and electron microscope observation of the mesoderm of the yold sac membrane indicate that individual presumptive precursors of the definitive-line are present as early as 2 days of incubation and give rise to sequestered populations of immature erythroblasts within sinusoids during the period of 2.5-6 days incubation. Such isolated populations of definitive-line erythroblasts eventually connect with the established capillary circulation of yolk sac membrane but a large proportion of the erythroblasts temporarily remain associated with the endothelium prior to free circulation.     

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.     

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.     

Changes in number, mobility, and topographical distribution of lectin receptors during maturation of chick erythroid cells

Plant lectins have been used to probe changes in cell surface characteristics that accompny differentiation in a complete series of chick erythroid cells. Dramatic differences in lectin receptor mobility were observed between the most immature cells of the series, the proerythroblasts, and cells at the next stage of maturation, the erythroblasts. Both concanavalin A and Ricinus communis agglutinin form caps on proerythroblasts, whereas they develop a patchy distribution on erythroblasts. Erythroid cells at later developmental stages show a homogeneous distribution of surface-bound R. communis agglutinin. Concanavalin A also shows a uniform distribution on the cell periphery, but appears to be concentrated in a ring above the perinuclear region of the cell. In addition to changes in mobility of lectin receptors, a large reduction (50-70%) in the number of lectin receptors per cell accompanies maturation of proerythroblasts to erythroblasts. Pretreatment of the cells with neuraminidase results in enhanced binding of R. communis agglutinin to proerythroblasts. The number of additional R. communis agglutinin receptors exposed by enzyme treatment remains relatively constant during subsequent cell maturation.     

Selective synthesis and modification of nuclear proteins during maturation of avian erythroid cells.

The synthesis of the nuclear proteins of duck erythroid cells at different stages of maturation has been investigated. Synthesis of histone fractions H1, H2a, H2b, H3, and H4 is restricted to the erythroblasts, while synthesis of H5 can be detected even at later stages of maturation after DNA synthesis has ceased. The synthesis of nonhistone nuclear proteins (NHNP), on the other hand, occurs in cells at all stages of maturation although their rates of synthesis decline as the cells mature. The same size classes of NHNP appear to be synthesized in erythroblasts and in early- and midpolychromatic erythrocytes. In late polychromatic erythrocytes the synthesis of a new group of NHNP of molecular weights ranging from 54,000 to 130,000 was observed. This group of proteins does not accumulate in the mature erythrocyte, indicating that their relative proportions are very small.Turnover of histone-bound phosphate was found to occur mainly at the erythroblast stage, except for histone H2a which was actively phosphorylated even at more advanced stages of maturation. Phosphorylation of most of the histones appears to be coupled to histone (and coordinate DNA) synthesis.Incorporation of radioactive acetate into histones occurs at all stages, but the rate of acetylation decreases four- to fivefold with maturation. Although the RNA synthetic activity of erythroid cells also decreases with age, experiments involving the use of RNA polymerase inhibitors suggest that the mechanisms that control RNA synthesis and histone acetylation are not tightly coupled.     

Membrane-bound glycoconjugates of fetal mouse erythropoietic cells with special reference to phagocytosis by hepatic macrophages

Using lectin and colloidal iron (CI) stainings in combination with neuraminidase digestion, glycoconjugates on the surface of erythropoietic cells of the yolk sac and liver in fetal mice were examined. Fetal hepatic macrophages were capable of distinguishing between phagocytozed and non-phagocytozed erythroid elements as described in our previous study. Marked differences between these two elements could be ultrahistochemically detected on their cell surface. The phagocytozed elements, such as nuclei expelled from erythroblasts and degenerating primitive erythroblasts, faintly bound neuraminidase-sensitive CI, and neuraminidase digestion imparted a weak peanut agglutinin (PNA) binding. In contrast, erythroblasts at various maturation stages, erythrocytes and normal primitive erythroblasts heavily bound neuraminidase-sensitive CI, and neuraminidase digestion imparted a moderate PNA binding. No differences in binding of either concanavalin agglutinin,Ricinus communis agglutinin-I or PNA were noted between phagocytozed and non-phagocytozed erythroid elements. Desialylation appears to be one of the most important signs for the recognition mechanism of fetal macrophage phagocytosis. During maturation of hepatic erythroblasts, sialic acid changes its affinity forLimax flavus agglutinin from strong to weak, and soybean agglutinin binding sites disappear at the basophilic erythroblast stage. Glycoconjugates on polychromatophilic erythroblasts acquire similar compositions to those of erythrocytes.     

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.     

Nucleolar silver-stained granules in maturing erythroid and granulocytic cells

Summary Human and rabbit erythroid and granulocytic precursors in bone marrow have been investigated to provide information concerning the number of nucleolar silverstained granules (SSGs), which represent active interphasic nucleolar organizer regions (NORs). The differentiation and maturation of precursor cells of both investigated cell lines are characterized by a gradual decrease in number of nucleolar SSGs. In advanced maturation stages of erythroblasts or granulocytes, which are known to lose the capacity to divide, the number of nucleolar SSGs is smaller than the reported average or maximal values of NORs determined for human or rabbit cells. Since committed stem cells from both cell lines contain several times the number of nucleolar SSGs than the last dividing maturation and differentiation stages, the number of active parts of interphasic NORs in committed stem cells seems to be increased and might represent a stock for the later stages. In addition, the number of nucleolar SSGs appear to be a very convenient marker of nucleolar biosynthetic activity in individual differentiating and maturing blood cells. The differences between erythroid and granulocytic stem cells with respect to the number of nucleolar SSGs disappear during the course of further differentiation and maturation.     

Impaired collagen maturity in vitamins B2 and B6 deficiency--probable molecular basis of skin lesions

Solubility of collagen was increased and the proportion of insoluble collagen was reduced in the skin of both riboflavin as well as pyridoxine-deficient rats. Collagen content of the skin, and aldehyde concentration of salt-soluble collagen were also lower in the deficient groups. The alpha:beta subunit ratio of salt-soluble collagen was higher in riboflavin deficiency. In food-restricted weight-matched control groups, similar changes in collagen solubility, but of lesser magnitude were observed. Both food restriction and riboflavin deficiency decreased plasma PLP concentration. Increase in the solubility of collagen, decrease in the aldehyde content of soluble collagen and increase in the alpha:beta subunit ratio of soluble collagen, suggest that the maturation of collagen may be affected in pyridoxine or riboflavin deficiency. These molecular events may be etiologically related to the pathogenesis of the skin lesions in vitamin B2 or B6 deficiency.     

Cytoskeletal distribution and function during the maturation and enucleation of mammalian erythroblasts

We have used murine splenic erythrolasts infected with the anemia- inducing strain of Friend virus (FVA cells), as an in vitro model to study cytoskeletal elements during erythroid maturation and enucleation. FVA cells are capable of enucleating in suspension culture in vitro, indicating that associations with an extracellular matrix or accessory cells are not required for enucleation to occur. The morphology of FVA cells undergoing enucleation is nearly identical to erythroblasts enucleating in vivo. The nucleus is segregated to one side of the cell and then appears to be pinched off resulting in an extruded nucleus and reticulocyte. The extruded nucleus is surrounded by an intact plasma membrane and has little cytoplasm associated with it. Newly formed reticulocytes have an irregular shape, are vacuolated and contain all cytoplasmic organelles. The spatial distribution of several cytoskeletal proteins was examined during the maturation process. Spectrin was found associated with the plasma membrane of FVA cells at all stages of maturation but was segregated entirely to the incipient reticulocyte during enucleation. Microtubules formed cages around nuclei in immature FVA cells and were found primarily in the incipient reticulocyte in cells undergoing enucleation. Reticulocytes occasionally contained microtubules, but a generalized diffuse distribution of tubulin was more common. Vimentin could not be detected at any time in FVA cell maturation. Filamentous actin (F-actin) had a patchy distribution at the cell surface in the most immature erythroblasts, but F-actin bundles could be detected as the cells matured. F-actin was found concentrated between the extruding nucleus and incipient reticulocyte in enucleating erythroblasts. Newly formed reticulocytes exhibited punctate actin fluorescence whereas extruded nuclei lacked F-actin. Addition of colchicine, vinblastine, or taxol to cultures of FVA cells did not affect enucleation. In contrast, cytochalasin D caused a complete inhibition of enucleation that could be reversed by washing out the cytochalasin D. These results demonstrate that F-actin plays a role in enucleation while the complete absence of microtubules or excessive numbers of polymerized microtubules do not affect enucleation.     

Synthesis and expression of cell-surface glycoproteins during chick erythroid differentiation

Abstract. A panel of monoclonal antibodies to differentiation antigens on avian erythroid cells was used to study the reprogramming of protein synthesis during erythroid differentiation at the molecular level. This panel detected five distinct cell-surface glycoproteins on immature leukemic erythroblasts, all of which were initially synthesised as smaller intracellular precursors. Two distinct in vitro differentiation systems (erythroblasts transformed by ts mutants of the erb-B and sea retroviral oncogenes, in which the synchronous terminal differentiation of CFU-E-like precursors is induced by simple elevation of temperature) were used to study cell-surface expression and the biosynthesis of each protein during erythroid cell maturation. For four glycoproteins, both cell-surface expression and biosynthesis decreased between the erythroblast and erythrocyte stages, although with widely different time courses. The fifth glycoprotein, which is reticulocyte specific on normal erythroid progenitors and is aberrantly expressed in onco-gene-transformed erythroblasts, rapidly disappeared shortly after differentiation induction but was then re-expressed on reticulocytes with the same time course as that seen during normal erythroid differentiation. This indicates that ts erb-B- and ts sea -transformed erythroblasts revert to a normal precursor phenotype before undergoing temperature-induced differentiation.     

ERYTHROPOIETIC CELL POPULATION CHANGES DURING THE HEPATIC PHASE OF ERYTHROPOIESIS IN THE FOETAL MOUSE

Estimates have been made of the absolute numbers of hepatogenic erythropoietic cells from 12.5 days post fertilization onwards in the mouse. All stages of maturation up to reticulocytes are present in the earliest samples but the least mature cells (proerythroblasts and basophilic erythroblasts) predominate; more mature cells (orthochromatic erythroblasts, reticulocytes and erythrocytes) predominate later in development. The number of hepatogenic haemoglobinized cells increases exponentially with a population doubling time of about 8 hr until about 15.5 days post fertilization. There is then a sharp transition and the doubling time lengthens to about 2 days. The immature cells formed during the rapid phase of increase are poorly haemoglobinized; hence the increase in haemoglobin lags behind that of cells. Calculations of the rates of formation of hepatogenic haemoglobinized cells and haemoglobin per standard number of liver cells show maxima between 15 and 16 days; these findings are in accord with direct observations of rates of haemoglobin synthesis in cultured mouse foetal livers made previously.     

Separation of haemopoietic cells for biochemical investigation. Preparation of erythroid and myeloid cells from human and laboratory-animal bone marrow and the separation of erythroblasts according to their state of maturation.

The separation of haemopoietic bone-marrow cells by centrifugation through discontinuous density gradients of Percoll is described. This method was used to prepare fractions enriched in erythroblasts, myeloid blast cells or reticulocytes from bone marrow of anaemic and non-anaemic rabbits, from the marrow of other anaemic laboratory animals and from human samples. It is a simple, rapid, reproducible and inexpensive technique that can be readily adapted to suit individual requirements. Secondly, a convenient method is presented for the separation of large quantities of bone-marrow cells into fractions enriched in erythroblasts at different stages of maturation, by velocity sedimentation through a linear gradient of 1-2% sucrose at unit gravity. In vitro, erythroblasts adhere together strongly via a mechanism almost certainly involving a beta-galactoside-specific surface lectin termed erythroid developmental agglutinin. Since the efficiency of cell-separation techniques depends heavily on the maintenance of a single cell suspension in which each unit can move independently, the presence of an adhesive molecule at the cell surface is of considerable significance. The effect of washing the marrow with a lactose-containing medium, which has been shown to remove the agglutinin, was therefore investigated in relation to both methods. The separation on Percoll gradients is considerably enhanced by this treatment. In addition, the unit-gravity sedimentation gradient can be loaded with 5-10 times more cells after lactose extraction in comparison with intact marrow. Although enrichment is less, a useful fractionation according to maturation is still obtained.     

Photodegradation of riboflavin in neonates

The biologically most important flavins are riboflavin and its related nucleotides, all highly sensitive to light. It is because of its photoreactivity and its presence in almost all body fluids and tissues that riboflavin assumes importance in phototherapy of neonatal jaundice. The absorption maxima of both bilirubin and riboflavin in the body are nearly identical: 445-450 (447) nm. In consequence, blue visible light will cause photoisomerization of bilirubin accompanied by photodegradation of riboflavin. This results in diminished erythrocyte glutathione reductase, which indicates generalized tissue riboflavin deficiency and red cell lysis. Single- and double-strand breaks in intracellular DNA have occurred with phototherapy. This light exposure of neonates may result also in alterations of bilirubin-albumin binding in the presence of both riboflavin and theophylline (the latter frequently given to prevent neonatal apnea). Many newborns, especially if premature, have low stores of riboflavin at birth. The absorptive capacity of premature infants for enteral riboflavin is likewise reduced. Consequently, inherently low stores and low intake of riboflavin plus phototherapy for neonatal jaundice will cause a deficiency of riboflavin at a critical period for the newborn. Supplementation to those infants most likely to develop riboflavin deficiency is useful, but dosage, time, and mode of administration to infants undergoing phototherapy must be carefully adjusted to avoid unwanted side effects.     

Effect of riboflavin or pyridoxine deficiency on inflammatory response.

Inflammatory response has been assessed in riboflavin or pyridoxine deficient rats. Edema was increased by 54% in pyridoxine deficiency as compared to weight-matched control rats. Food restriction per se reduced the volume of edema by 63%. In pyridoxine deficiency, concentrations of thiobarbituric acid reactive substances (which indicate the extent of lipid peroxidation) increase by 30 and 43% respectively in the edematous tissues of the paw as well as in the wounded skin. Both these parameters were not affected by riboflavin deficiency. Activities of NADPH oxidase and superoxide dismutase in elicited leukocytes from peritoneal cavity were reduced by 54 and 52%, respectively, in riboflavin deficiency but were unaltered in pyridoxine deficiency. Superoxide level and acid phosphatase activity were not influenced by either of the deficiencies, whereas hydrogen peroxide level was increased by 48% in riboflavin deficiency. Food restriction did not affect leukocyte enzymes or the levels of reduced oxygen species. The data suggest that inflammation is enhanced in pyridoxine deficiency but not in riboflavin deficiency.     

Morphogenesis of blood cell lineages in channel catfish

The morphogenesis of blood cell lineages in channel catfish Ictalurus punctatus , from head and trunk kidney and spleen imprints as well as from blood smears of bled and control fish, showed that early maturation stages resembled those in higher vertebrates. The erythroid lineage consisted of the proerythroblast, erythroblasts (basophilic, polychromatic, orthochromic), young erythrocyte and erythrocyte. The rare bilobed erythrocyte seemed to be a cell in apoptosis while old erythrocytes and erythroplastids represented remnants of this process. Maturation stages of neutrophils and basophils encompassed the granuloblast, young progranulocyte, progranulocyte and metagranulocyte. The basophilic lineage was regularly present in kidneys, rare in spleen and absent from blood. It contained large Sudan Black and PAS-negative, water soluble granules and small PAS-positive ones. Lymphocytes with azurophilic granulation occured regularly in kidneys and spleen. Monoblasts and promonocytes in kidneys preceded monocytes. A phagocytic lineage devouring apoptotic blood cell remnants was present in kidneys and spleen. Its youngest identified stage (promacrophage) resembled more a granuloid cell without granules than a monocytoid one. The larger, young macrophages contained a few to several ingestions and the very large mature macrophages were loaded with them. The latter two stages corresponded to cells in melano-macrophage centres (macrophage aggregates). Precursor stages of the thrombocyte were not identified.     

Penetration of maturating red blood cells by Toxoplasma gondii

Penetration of Toxoplasma gondii tachyzoites was studied in vitro using murine erythroid cells at different stages of development. Toxoplasma gondii penetrated nucleated erythroblasts and macroreticulocytes from foetal mouse liver and the circulating erythrocytes of foetal, neonatal or severely anaemic adult mice. Immature reticulocytes were more susceptible to penetration than mature ones, indicating that some change in their membrane properties occurred during maturation. The present results confirmed our previous finding that the major erythrocyte membrane-specific proteins do not prevent erythrocyte penetration since these proteins are known to be present in the reticulocyte membrane.