Iron uptake studies on erythroid cells

Iron uptake from ⁵⁵Fe-labelled transferrin, ferric citrate and the two fungal sideramines, ferricrocin and fusigen was studied using four erythroid cell cultures: Friend virus-transformed erythroleukemic cells (mouse), transformed bone marrow cells, Detroit-98 (human), reticulocytes (bovine), bone marrow cells (rabbit). The present comparative study reveals pronounced differences in iron uptake behaviour. Compared to transferrin, ferric citrate and the sideramines are preferred in transformed erythroid cells. In reticulocytes transferrin and ferric citrate showed a better uptake as compared to the two sideramines. Primary bone marrow cells showed nearly equal iron uptake rates using transferrin or ferricrocin.     

Hexokinase in developing rabbit erythroid cells

The activity and isozyme distribution of hexokinase were studied in bone marrow cells from normal and anemic rabbits seperated by density centrifugation or by unit-gravity sedimentation. The specific activity of the enzyme was found to be about 150-fold higher in the basophilic erythroblasts as compared with the mature circulating erythrocytes. Mos of the falls in hexokinase activity take place whent the cell completes its final division and matures from the polychromatic stage to the orthochromatic stage. Concomitant with this strong decrease in enzyme activity, qualitative as well as quantitative changes in the hexokinase isozymic pattern become apparent. While in the basophilic and polychromatic erythroblasts the only hexokinase isozyme present is hexokinase type I, the orthochromatic cells also contain hexokinase Ib. This last isozymic form, which increases further at the reticulocyte stage, is also present in the circulating reticulocytes but not in mature red blood cells.     

Iron uptake studies on erythroid cells.

Iron uptake from 55Fe-labelled transferrin, ferric citrate and the two fungal sideramines, ferricrocin and fusigen was studied using four erythroid cell cultures: Friend virus-transformed erythroleukemic cells (mouse), transformed bone marrow cells, Detroit-98 (human), reticulocytes (bovine), bone marrow cells (rabbit). The present comparative study reveals pronounced differences in iron uptake behaviour. Compared to transferrin, ferric citrate and the sideramines are preferred in transformed erythroid cells. In reticulocytes transferrin and ferric citrate showed a better uptake as compared to the two sideramines. Primary bone marrow cells showed nearly equal iron uptake rates using transferrin or ferricrocin.     

Differentiation pathways of primary erythroid cells in chickens

Proliferation and differentiation processes of chick embryo primary erythroid cells (PEC) were studied. A novel differentiation pathway was discovered by which cells of proerythroblastic and erythroblastic stages are blocked in G1 or G2 phases, to develop then directly into reticulocytes, i.e. terminally differentiated non-dividing cells with high hemoglobin contents differing in shape from erythrocytes. These cells appear in blood two days earlier than erythrocytes, then they co-exist with the latter and are eliminated in parallel with them. This pathway leads to a rapid enrichment of PEC with hemoglobin. A fraction of PEC forms accessory nuclei, which, as it is shown here, contain an extra quantity of DNA. Compared to the diploid ones, such cells reveal increased hemoglobin contents which enabled us to assume that they may have amplified the globin genes. The above-mentioned pecularities of cytodifferentiation may be presumably an adaptation to oxygen supply of growing embryos which are known to stay in hypoxia. A comparison of these results with results of our earlier study on experimental anemia makes it possible to suppose that pecularities of these two types of cytodifferentiation may be based on similar or, perhaps, analogous mechanisms of regulation.     

Hormonally stimulated adenylate cyclase and cAMP dependent protein kinase in membranes of rabbit erythroid cells separated according to density

Plasma membranes were prepared after density gradient separation of erythroid cells obtained from bled animals. In a fraction enriched in young reticulocytes (lowest density), the basal and the prostaglandin stimulated adenylate cyclase were greatly augmented if compared with the membranes from unfractionated cells or from the layers of higher densities. Potentiation by GTP or soluble factor(s) of the prostaglandin stimulated adenylate cyclase was found solely in the fractions containing the youngest cells (lowest density). A very significant augmentation of both the basal and the effectors stimulated adenylate cyclase was obtained when the white blood cells and the platelets were removed by filtration through alpha-cellulose prior to density separation. A small population of probably very young reticulocytes was shown to contain a very active adenylate cyclase coupled to the hormonal receptor. Upon short time of maturation this coupling could no longer be detected. The cAMP generated in the fraction enriched in young reticulocytes increased the phosphorylation of some membrane proteins. The presence of a hormonally regulated adenylate cyclase and eventually the phosphorylation of some specific membrane proteins by the cAMP generated in situ permit to envisage possible functions of this system in young reticulocytes.     

Further studies on the rabbit erythroid cell plasma membrane transferrin receptor

Studies reproted here indicate that a major cell surface glycoprotein of the rabbit bone marrow erythroid cell may be involved in binding transferrin. The glycoprotein has an apparent molecular weight of 18,000. It is suggested that bone marrow erythroid cells may provide an invaluable source of the red cell membrane transferrin receptor for future studies.     

Ribonucleic acid synthesis in rabbit erythroid cells.

Kinetic studies on the synthesis of RNA in mature bone-marrow erythroid cells from rabbits were made by measuring the incorporation of [2-3H]adenosine into the ATP pool and RNA over periods up to 8h. By use of equations to fit the pool specific radioactivity and an equation using the same type of pool to generate the rate of linear DNA synthesis, good agreement between the pool parameters is found, provided that the ATP pool is measured in whole cell extracts, and assuming that the dATP and ATP pools equilibrate rapidly. RNA-synthesis rates were measured by using curve fits to equations developed by using the pool specific-radioactivity curves. The rate of synthesis of poly(A)-containing RNA varied in three experiments from 90 to 220mol/min per cell, with half-life of nuclear processing of 12-22 min with a mean of 16 min. Ribosomal RNA is synthesized at a rate of 70-200 mol/min per cell with an average half-life of nuclear processing of 37 min for the 18S RNA and 214 min for the 28S RNA. When the stable rRNA components are subtracted from the nRNA synthesis, the rate of nRNA synthesis is between 2 and 6fg/min per cell with an average half-life of degradation of 27 min. The rate of synthesis of poly(A)-containing RNA is 1.5-3.5% of the RNA-synthesis rates. These rates are compared with the RNA-synthesis rates found in L cells and concentrations of globin mRNA found in various erythroid-cell preparations.     

Haemoglobin biosynthesis site in rabbit embryo erythroid cells

Properly metabolized globin synthesis and iron uptake are indispensable for erythroid cell differentiation and maturation. Mitochondrial participation is crucial in the process of haeme synthesis for cytochromes and haemoglobin. We studied the final biosynthesis site of haemoglobin using an ultrastructural approach, with erythroid cells obtained from rabbit embryos, in order to compare these results with those of animals treated with saponine or phenylhydrazine. Our results are similar to those obtained in assays with adult mammals, birds, amphibians, reptiles and fish, after induction of haemolytic anaemia. Therefore, the treatment did not interfere with the process studied, confirming our previous findings. Immunoelectron microscopy showed no labelling of mitochondria or other cellular organelles supposedly involved in the final biosynthesis of haemoglobin molecules, suggesting instead that it occurs free in the cytoplasm immediately after the liberation of haeme from the mitochondria, by electrostatic attraction between haeme and globin chains.     

The morphology of erythroid cells separated by density gradient centrifugation through ficoll

Summary The regenerating blood of geese injected with phenylhydrazine was subjected to large scale, zonal centrifugation through density gradients of Ficoll. In this way, erythroid cells were fractionated according to their respective stages of development. Highly enriched fractions were obtained, containing cells that were well preserved as assessed by both light and electron microscopy. The separated cells exhibited ribosome density and nucleic acid and protein staining patterns typically associated with erythrocyte differentiation. Morphometric analysis of nuclei indicated that despite an apparent net increase in the amount of compact chromatin during development, comparatively little difference existed between the volumes of condensed chromatin present in immature and mature cells. Instead, there was a three fold decrease in nuclear volume between young erythroblasts and reticulocytes, coupled with a concomitant decrease in the volume occupied by dispersed chromatin, RNP and nucleoli. These observations are discussed in relation to molecular changes associated with nuclear differentiation in erythroid cells.Supported by grants from the National Research Council of CanadaWe thank Dr. G. Setterfield for assistance with the EM data and we are grateful to the N.R.C. for use of centrifuges and the zonal rotor     

NADP+ catabolic enzymes in differentiating rabbit erythroid cells

NADP-glycohydrolase and NADP-pyrophosphates activities were examined during the rabbit erythroid cell differentiation. The former is high in erythroblast lysates, especially in the erythroblast nuclei. As erythroid cell maturation proceeds, the activity of NADP-glycohydrolase decreases. At the first step (erythroblast-reticulocyte transformation), this activity falls down more than by 20 times, whereas at the second step (reticulocyte-erythrocyte transformation) it decreases no more than twice. NADP-glycohydrolase is associated with the stroma of erythroid cells throughout their maturation, being bound with the nucleus in erythroblasts. NADP-pyrophosphatase activity has been detected in reticulocytes and mature cells only. The role of NADP- and NAD-glycohydrolases for characterization of the intracellular metabolic pools is discussed.     

Enzymes of NAD+ catabolism in differentiating rabbit erythroid cells

A study was made of the hydrolysis of NAD+ in the process of rabbit erythroid cell differentiation. Activities of NAD-hydrolase and NAD-pyrophosphatase, examined during maturation of erythroid cells, demonstrated a more significant decrease in the course of erythroblast-reticulocyte transformation, than at the next step of erythropoesis (reticulocyte-erythrocyte transformation). Both enzymes are strongly associated with the stroma. Under discussion is a question of the possible role of NAD+ catabolism.     

Pre-mRNA from erythroid enriched bone marrow cells of the rabbit

Different fractions of cellular RNA from erythroid enriched bone marrow cells of the rabbit, extracted by the temperature fractionation method, were investigated by hybridization to globin cDNA. 97.4% of all globin sequences were found in the 4 degrees C franction (cytoplasmic RNA) 0.11% are in the 40 degrees / 50 degrees C fraction and 2.47% in the 65 degrees C and 85 degrees C franctions (pre-mRNA). This shows a substantial purification of the pre-mRNA fractions from cytoplasmic mRNA. 33% of the globin sequences in the 65 degrees C and 85 degrees C fractions are polyadenylated. The poly(A)+-RNA from the 65 degrees C and 85 degrees C fractions separated in a formamide sucrose gradient showed a clear hybridization to globin cDNA in the region between 9S and 28S and around 4S. In a control experiment in which RNA from baby hamster kidney cells (BHK) was mixed with globin mRNA and separated in the same manner hybridization was observed at the 9S position of the gradient only.     

Changes in surface-membrane components during the differentation of rabbit erythroid cells.

The membrane components of rabbit bone-marrow-bound erythroid cells were characterized and compared with those of circulating rabbit erythroid cells. By the criteria of sodium dodecyl sulphate/polyacrylamide-gel electrophoresis, radioiodination with lactoperoxidase and binding of radioiodinated lectins, the two circulating forms of erythroid cells (the reticulocyte and erythrocyte) have the same surface components. In contrast, bone-marrow-bound nucleated erythroid cells have a unique set of membrane surface components which are completely different from those found on circulating cells. Of the ten Coomassie-Blue-staining proteins present in nucleated erythroid-cell plasma-membrane preparations, eight are accessible at the extracellular surface, and all of these are lectin-binding glycoproteins. Bone-marrow erythroid cells separated according to age by velocity sedimentation were also studied. The changeover in surface components occurs after the last nucleated stage of the erythroid cells (the orthochromatic normoblast). We discuss the alterations in membrane surface components observed during the differentiation of the erythroid-cell series in relation to the transition from bone-marrow-bound to circulating forms of these cells. We suggest that the change in membrane surface components may be linked to the loss of the nucleus from the normoblast and the entry of the erythroid cell into the circulation.     

Cyclic AMP phosphodiesterase activity during differentiation of rabbit erythroid bone marrow cells.

Changes in the activity of cyclic AMP phosphodiesterase during differentiation of rabbit bone marrow erythroid cells were investigated. The cells were separated by velocity sedimentation at unit gravity into six fractions corresponding to different stages of development: proerythroblasts, basophilic cells, polychromatic cells, early orthochromatic and late orthochromatic cells and reticulocytes. Cyclic AMP phosphodiesterase was found to be very active in the most immature cells, the proerythroblasts, which also have the highest content of cyclic AMP. After differentiation into basophilic erythroblasts, a 4-fold decrease in cyclic AMP phosphodiesterase activity was observed. In these cells the amount of cyclic AMP was about 80% lower than that in proerythroblasts. In polychromatic cells a further drop in phosphodiesterase activity occurred. After the final cell division the enzyme activity was very low and the levels of cyclic AMP in the early and late orthochromatic cells remained constant. Kinetic studies demonstrated a heterogeneity of erythroid cell cyclic AMP phosphodiesterase: high affinity, low-Km (5.5 X 10(-6) M) and low affinity, high-Km (0.1 X 10(-3) M) enzymes were found. The phosphodiesterase activity was dependent on the presence of Mg2+ and was activated by Ca2+ at low Mg2+ concentrations (1 mM). The changes in cyclic AMP phosphodiesterase activity during differentiation and maturation of erythroid cells suggest the possible importance of this enzyme in the physiological control of cyclic AMP concentrations in developing erythroblasts. The loss of cyclic AMP phosphodiesterase activity after cessation of cell division supports the concept of the significance of the final cell division in erythroblast differentiation.     

Changes in malate dehydrogenase isoenzymes during differentiation of rabbit bone marrow erythroid cells

• 1.l. Malate dehydrogenase activity was assayed in rabbit bone marrow erythroid cells which had been separated by velocity sedimentation into six fractions corresponding to different stages of development.
• 2.2. During differentiation enzyme activity decreased 10-fold and one of the two isoenzymes present in immature cells was lost.
• 3.3. The most extensive change occurred in orthochromatic erythroblasts immediately after condensation of the nucleus.