Domains of receptor mobility and endocytosis in the membranes of neonatal human erythrocytes in the membranes of neonatal human erythrocytes and reticulocytes are deficient in spectrin

It has previously shown (Schekman, R., and S.J. Singer, Proc. Natl. Acad. Sci. U.S.A. 73:4075-4079) that receptors in the membranes of neonatal human erythrocytes show a restricted degree of lateral mobility, whereas in adult human erythrocytes the receptors are essentially immobile. This restricted mobility is exhibited, for example, when concanavalin A (Con A) induces a limited clustering of its receptors in the neonatal erythrocyte membrane, resulting in the formation of invaginations and endocytic vesicles. This does not happen with adult cells. By the use of indirect immunoferritin labeling of ultrathin frozen sections of Con A-treated neonatal blood cells, we now show that the invaginations and endocytotic vesicles do not stain for spectrin, whereas the adjacent unperturbed membrane is heavily stained. The reticulocytes in the neonatal cell population undergo substantially more Con A-induced invagination and endocytosis than do the erythrocytes. These results lend strong support to the hypothesis that specialized discrete domains exist, or are induced, in the membranes of these neonatal cells, in which receptors are laterally mobile, whereas in the remaining (and predominant) part of the membrane the receptors are immobile. Such mobile domains are characterized by an absence of spectrin. During the maturation of the neonatal reticulocyte to erythrocyte, it is proposed that these domains are in large part, but not completely, eliminated.     

Member-associated changes during erythropoiesis. On the mechanism of maturation of reticulocytes to erythrocytes

The mature mammalian erythrocyte has a unique membranoskeleton, the spectrin-actin complex, which is responsible for many of the unusual membrane properties of the erythrocyte. Previous studies have shown that in successive stages of differentiation of the erythropoietic series leading to the mature erythrocyte there is a progressive increase in the density of spectrin associated with the membranes of these cells. An important stage of this progression occurs during the enucleation of the late erythroblast to produce the incipient reticulocyte, when all of the spectrin of the former cell is sequestered to the membrane of the reticulocyte. The reticulocyte itself, however, does not exhibit a fully formed membranoskeleton. In particular, the in vitro binding of multivalent ligands to specific membrane receptors on the reticulocyte was shown to cause a clustering of some fractions of these ligand-receptor complexes into special mobile domains on the cell surface. These domains of clustered ligand-receptor complexes became invaginated and endocytosed as small vesicles. By immunoelectron microscopic experiments, these invaginations and endocytosed vesicles were found to be specifically free of spectrin on their cytoplasmic surfaces. These earlier findings then raised the possibility that the maturation of reticulocytes to mature erythrocytes in vivo might involve a progressive loss of reticulocyte membrane free of spectrin, thereby producing a still more concentrated spectrin-actin membranoskeleton in the erythrocyte than in the reticulocyte. This proposal is tested experimentally in this paper. In vivo reticulocytes were observed in ultrathin frozen sections of spleens from rabbits rendered anemic by phenylhydrazine treatment. These sections were indirectly immunolabeled with ferritin-antibody reagents directed to rabbit spectrin. Most reticulocytes in a section had one or more surface invaginations and one or more intra-cellular vesicles that were devoid of spectrin labeling. The erythrocytes in the same sections did not exhibit these features, and their membranes were everywhere uniformly labeled for spectrin. Spectrin-free surface invaginations and intracellular vesicle were also observed with reticulocytes within normal rabbit spleens. Based on these results, a scheme for membrane remodeling during reticulocyte maturation in vivo is proposed.     

Pig reticulocytes. IV. In vitro maturation of naturally occurring reticulocytes with permeability loss to glucose

Naturally occurring reticulocytes of week old piglets were used to characterize the maturation process under in vitro conditions. When the reticulocytes were suspended in tissue culture medium fortified with metabolic substrates, nearly all cells were viable after 24 hours incubation and usually more than 85% of the initial cell population survived after an 80 hour period. In cells maintained as long as a week in incubation, an adequate level of total adenine nucleotide with a large accumulation of IMP was found. In most cases, reticulocytes lose their reticular materials within two days and assume normal erythrocyte configuration. Concomitant with the morphological change, the cell volume decreases toward normal erythrocyte size, the extent of which can be accounted for by the intracellular loss of salt and accompanying water. As in the in vivo reticulocyte maturation process, reticulocytes undergoing in vitro maturation lose their membrane permeability to glucose. These findings suggest that the process of reticulocyte maturation occurring in cell culture approaches that which naturally occurs in vivo. Thus, these cells may be used to delineate the mechanism of the loss of membrane transport of glucose which normally occurs in the adult pig cells.     

Maturation of rabbit reticulocytes: degradation of specific reticulocyte proteins.

As analyzed by polyacrylamide-gel electrophoresis, rabbit reticulocyte cytoplasm contains, in addition to globin, seven predominant polypeptides. The amounts of these range from 0.1 to 1.2% of globin. Rabbit erythrocytes contain only three of these nonglobin polypeptides. The loss of the four other polypeptides is correlated with maturation of the reticulocytes to erythrocytes. We also fractionated reticulocytes according to age by equilibrium centrifugation through a gradient of metrizamide and showed that younger reticulocytes contain much more of these four polypeptides than do more mature reticulocytes.The four polypeptides that are lost during differentiation are also very sensitive to in vitro destruction by chymotrypsin or trypsin under conditions where globin and the three reticulocyte nonglobin peptides that remain during reticulocyte maturation are completely resistant. Our results are consistent with the notion that the degradative rate of a reticulocyte cytoplasmic protein is determined by its susceptibility to general intracellular proteases.     

Rabbit red blood cell hexokinase:intracellular distribution during reticulocytes maturation

Summary The intracellular localization and isozyme distribution of hexokinase were studied during rabbit reticulocyte maturation and aging. In reticulocytes 50% of the enzyme was particulate while in the mature erythrocytes all the hexokinase activity was soluble. The bound enzyme co-sediments with mitochondria and by column chromatography it was found to be hexokinase Ia. The cytosol of reticulocytes contains hexokinase Ia (38%) and hexokinase Ib (62%) while the mature erythrocytes contain only hexokinase Ia. The amount of bound hexokinase decreases very quickly during cell maturation and aging as was shown by following in vivo reticulocyte maturation or by analysis of hexokinase compartmentation in cells of different ages, obtained by density gradient ultracentrifugations. A role for this intracellular distribution of hexokinase is suggested.     

Transferrin and ferritin endocytosis and recycling in guinea-pig reticulocytes

Transferrin and ferritin endocytosis and exocytosis by guinea-pig reticulocytes were studied using incubation with pronase at 4 degrees C to distinguish internalized and membrane-bound protein. Internalization of both transferrin and ferritin occurred in a time- and temperature-dependent fashion. Transferrin endocytosis was more rapid than that of ferritin. Transferrin binding to receptors was not altered, but transferrin endocytosis was decreased in the presence of ferritin. Iron accumulation from transferrin was inhibited by ferritin to a greater extent than could be accounted for by the decreased rate of endocytosis. In pulse-chase experiments, almost all of the transferrin was released intact from reticulocytes, but only about 50% of the total internalized ferritin was released, of which 85% was intact. The endocytosis of transferrin by rabbit reticulocytes was 2- to 2.5-times faster than guinea-pig reticulocytes. These data suggest that ferritin and transferrin are internalized by receptor-mediated endocytosis, possibly involving the same coated pits and vesicles, but that the proteins are recycled only partly in common.     

Transfer RNA in reticulocyte maturation

The disappearance of tRNA during the maturation of rabbit reticulocytes under the stress of phenylhydrazine-induced hemolysis was studied. The tRNA content of reticulocytes and of erythrocytes derived from them was compared. The results show that tRNA persists longer after reticulocyte maturation than ribosomes and than the ability to incorporate amino acids into protein. Considerable uniformity of tRNA degradation was noted with about 15% of the tRNA for most amino acids remaining after reticulocyte maturation. The half-life of tRNA in the maturing cells is estimated to be 50--60 h. There is little tRNA lacking the 3'-terminal pCpCpA moiety in cells derived from reticulocytes.     

Loss of insulin receptors on maturation of reticulocytes

The insulin receptors in rabbit reticulocytes have been studied; their properties are undistinguishable from those of classical receptors for insulin. During the maturation of the reticulocytes the number of hormone binding sites decreased 10 fold. Their calculated value was of 1600–2000 sites per reticulocyte compared with 110–260 sites per mature red cell.     

Hepatocytes and reticulocytes have different mechanisms for the uptake of iron from transferrin

The uptake of iron from transferrin by isolated rat hepatocytes and rat reticulocytes has been compared. The results show the following. 1) Reticulocytes and hepatocytes express plasma membrane NADH:ferricyanide oxidoreductase activity. The activity, expressed per 10(6) cells, is approximately 60-fold higher in the hepatocyte than in the reticulocyte. 2) Hepatocyte plasma membrane NADH:ferricyanide oxidoreductase activity and uptake of iron from transferrin are stimulated by low oxygen concentration and inhibited by iodoacetate. In reticulocytes, similar changes are seen in NADH:ferricyanide oxidoreductase activity, but not on iron uptake. 3) Ferricyanide inhibits the uptake of iron from transferrin by hepatocytes, but has no effect on iron uptake by reticulocytes. 4) Perturbants of endocytosis and endosomal acidification have no inhibitory effect on hepatocyte iron uptake, but inhibit reticulocyte iron uptake. 5) Hydrophilic iron chelators effectively inhibit hepatocyte iron uptake, but have no effect on reticulocyte iron uptake. Hydrophobic iron chelators generally inhibit both hepatocyte and reticulocyte iron uptake. 6) Divalent metal cations with ionic radii similar to or less than the ferrous iron ion are effective inhibitors of hepatocyte iron uptake with no effect on reticulocyte iron uptake. The results are compatible with hepatocyte uptake of iron from transferrin by a reductive process at the cell surface and reticulocyte iron uptake by receptor-mediated endocytosis.     

Impaired adenylate cyclase activity of phenylhydrazine-induced reticulocytes

A method which involves Percoll gradient centrifugation, is described for separating rabbit reticulocytes from other blood cells, including erythrocytes. This permits a quantitative comparison of the adenylate cyclase activity of reticulocyte membranes which had been induced either by bleeding (30% reticulocytosis) or by repeated injections of phenylhydrazine (90% reticulocytosis). Adenylate cyclase activity was greatly impaired on exposure to the hemolytic agent; total activity was reduced about 20-fold. However, a more selective loss was observed in terms of hormonal stimulation. Prostaglandin E1 was 2-fold more effective than either sodium fluoride or Forskolin in stimulating the enzyme from bled reticulocytes, whereas it was 3-fold less effective than either fluoride or Forskolin in the case of membranes from animals which had been exposed to phenylhydrazine. A stimulatory adenosine receptor was detectable only in reticulocytes which had not been treated with the hemolytic agent. These studies suggest that purified reticulocytes from bled animals represent the most suitable model system in which to study the maturation of red blood cells.     

The ins and outs of human reticulocyte maturation

The maturation of reticulocytes into functional erythrocytes is a complex process requiring extensive cytoplasmic and plasma membrane remodeling, cytoskeletal rearrangements and changes to cellular architecture. Autophagy is implicated in the sequential removal of erythroid organelles during erythropoiesis, although how this is regulated during late stages of erythroid differentiation, and the potential contribution of autophagy during reticulocyte maturation, remain unclear. Using an optimized ex vivo differentiation system for human erythropoiesis, we have observed that maturing reticulocytes are characterized by the presence of one or few large vacuolar compartments. These label strongly for glycophorin A (GYPA/GPA) which is internalized from the plasma membrane; however, they also contain organellar remnants (ER, Golgi, mitochondria) and stain strongly for LC3, suggesting that they are endocytic/autophagic hybrid structures. Interestingly, we observed the release of these vacuoles by exocytosis in maturing reticulocytes, and speculate that autophagy is needed to concentrate the final remnants of the reticulocyte endomembrane system in autophagosome/endosome hybrid compartments that are primed to undergo exocytosis.     

The ins and outs of human reticulocyte maturation: Autophagy and the endosome/exosome pathway

The maturation of reticulocytes into functional erythrocytes is a complex process requiring extensive cytoplasmic and plasma membrane remodeling, cytoskeletal rearrangements and changes to cellular architecture. Autophagy is implicated in the sequential removal of erythroid organelles during erythropoiesis, although how this is regulated during late stages of erythroid differentiation, and the potential contribution of autophagy during reticulocyte maturation, remain unclear. Using an optimized ex vivo differentiation system for human erythropoiesis, we have observed that maturing reticulocytes are characterized by the presence of one or few large vacuolar compartments. These label strongly for glycophorin A (GYPA/GPA) which is internalized from the plasma membrane; however, they also contain organellar remnants (ER, Golgi, mitochondria) and stain strongly for LC3, suggesting that they are endocytic/autophagic hybrid structures. Interestingly, we observed the release of these vacuoles by exocytosis in maturing reticulocytes, and speculate that autophagy is needed to concentrate the final remnants of the reticulocyte endomembrane system in autophagosome/endosome hybrid compartments that are primed to undergo exocytosis.     

Rabbit red blood cell hexokinase. Decay mechanism during reticulocyte maturation

In rabbit reticulocytes, the hexokinase (EC 2.7.1.1)-specific activity is 4-5 times that of corresponding mature red cells. Immunoprecipitation of hexokinase by a polyclonal antibody made in vitro shows that this maturation-dependent hexokinase decay is not due to accumulation of inactive enzyme molecules but to degradation of hexokinase. A cell-free system derived from rabbit reticulocytes, but not mature erythrocytes, was found to catalyze the decay of hexokinae activity and the degradation of 125I-labeled enzyme. This degradation is ATP-dependent and requires both ubiquitin and a proteolytic fraction retained by DEAE-cellulose. Maximum ATP-dependent degradation was obtained at pH 7.5 in the presence of MgATP. MgGTP could replace MgATP with a relative stimulation of 0.90. 125I-Hexokinase incubated with reticulocyte extract in the presence of ATP forms high molecular weight aggregates that reach a steady-state concentration in 1 h, whereas the degradation of the enzyme is linear up to 8 h, suggesting that the formation of protein aggregates precedes enzyme catabolism. These aggregates are stable upon boiling in 2% sodium dodecyl sulfate, 3% mercaptoethanol and probably represent an intermediate step in the enzyme degradation with hexokinase and other proteins covalently conjugate to ubiquitin. That hexokinase could be conjugated to ubiquitin was shown by the formation of 125I-ubiquitin-hexokinase complexes in the presence of ATP and the enzymes of the ubiquitin-protein ligase system. Thus, the decay of hexokinase during reticulocyte maturation is ATP- and ubiquitin-dependent and suggests a new physiological role for the energy-dependent degradation system of reticulocytes.     

Tissue distribution and immunoreactivity of heme-regulated eIF-2 alpha kinase determined by monoclonal antibodies.

A highly purified preparation of heme-regulated inhibitor (HRI), an eIF-2 alpha kinase, from rabbit reticulocyte lysates has been used for generating monoclonal antibodies (mAB). Two hybridoma clones secreting HRI-specific antibodies (mAB A and mAB F) were obtained. Both antibodies immunoprecipitated biosynthetically labeled as well as phosphorylated HRI in reticulocyte lysates and also recognized denatured HRI in a Western blot. In in vitro protein kinase assays, preincubation of HRI with the antibodies significantly diminished both autokinase and eIF-2 alpha kinase activities. HRI from reticulocyte lysates could be quantitatively removed by immunoprecipitation with mAB F, and such HRI-depleted lysates were able to maintain protein synthesis under conditions of heme deficiency. With these monoclonal antibodies, HRI was detected only in the reticulocytes and bone marrow of anemic rabbits, among several rabbit tissues tested. The antibodies did not detect cross-reacting HRI in rat or human reticulocytes or in mouse erythroleukemic cells or human K562 cells even after induction of differentiation, although eIF-2 alpha kinase activity was detected in them. Polyclonal anti-rabbit HRI antibody detected HRI in rat reticulocytes. However, no cross-reacting HRI was detected by polyclonal antibody in human reticulocytes or other cell types tested. These findings suggest that HRI is not ubiquitous, and may be erythroid-specific, and that it is antigenically different in different species.     

The function of the histidine tRNA isoaccepting species in hemoglobin synthesis.

Rabbit reticulocytes contain two RNA isoaccepting species for histidine as resolved by various chromatographic methods, while rabbit liver contains only one. These isoacceptors cannot be distinguished on the basis of coding properties, consistent with the "Wobble Hypothesis" (Smith, D.W.E., Meltzer, V.N., and McNamara, A.L. (1974) Biochim. Biophys. Acta 349, 366-375). Their function in hemoglobin synthesis in reticulocyte lysates has been investigated. Each of the tRNA isoacceptors of reticulocytes and the tRNA species of liver can incorporate histidine into positions in hemoglobin encoded by both of the histidine code words, CAC and CAU, and it is likely that each can incorporate histidine into all of the histidine-containing positions of hemoglobin. Even in experiments in which the two histidine tRNA species of reticulocytes are placed together in a lysate and are therefore in competition with each other, each incorporates histidine into all of the histidine-containing positions. There is no evidence that any residues are incorporated preferentially by either of the tRNA species. The two species are attached to reticulocyte ribosomes in the same proportion as they occur in the reticulocyte, also suggesting that neither of them is used preferentially in hemoglobin synthesis. The first of the two reticulocyte histidine isoacceptors and the histidine tRNA of rabbit liver contain Q base.     

Increase of 2,3-bisphosphoglycerate synthase/phosphatase during maturation of reticulocytes with high 2,3-bisphosphoglycerate content

In the rabbit and in the rat, which possess erythrocytes with high concentration of 2,3-bisphosphoglycerate, the 2,3-bisphosphoglycerate synthase activity increases more than two fold during reticulocyte maturation. Isolation of the enzymes with 2,3-bisphosphoglycerate synthase activity present in extracts of reticulocytes and mature erytrocytes by ion exchange fast liquid chromatography shows that the increase in the synthase activity is due to the accumulation of the bifunctional enzyme 2,3-bisphosphoglycerate synthase/phosphatase (EC 2.7.5.4/EC 3.1.3.13) which represents more than 80% of the synthase activity of the cell extracts. During reticulocyte maturation phosphoglycerate mutase (EC 5.4.2.1), which makes a small contribution to the 2,3-bisphosphoglycerate synthase activity in the erythroid cells, decreases in the rabbit and remains constant in the rat.     

Iron transport from sepharose-bound transferrin

To ascertain whether transferrin need enter the reticulocyte to deliver its iron after the association of transferrin with the cell membrane, {¹²⁵I, ⁵⁹Fe-}labeled transferrin was covalently bound to Sepharose beads. Iron uptake from Sepharose-bound transferrin into rabbit reticulocytes was about 9% that from free transferrin while heme synthesis was more efficient at nearly 19%. Similar results were obtained with murine transferrin and murine reticulocytes.These results indicate that the entrance of transferrin inside the cell is not an obligatory step in the process of iron uptake in rabbit and murine reticulocytes.     

An electron-microscope autoradiographic study of transferrin endocytosis by immature erythroid cells

The receptor-mediated endocytosis of 125I-transferrin by immature erythroid cells was studied using the technique of quantitative electron microscope autoradiography. Morphometric analysis of the grain distribution in erythroid cells from the foetal rat liver revealed that the 125I-transferrin radioactivity was localized mainly to intracellular vesicles (61%) and the cell membrane (25%) after 20 min incubation at 37 degrees C. No activity was found associated with the nucleus or mitochondria and only a small amount with the cytosol (13%). In erythroid cells which possessed a prominent Golgi complex, most of the autoradiographic grains were associated with vesicles located in this region, giving rise to a polar distribution of the 125I-transferrin. Uptake of transferrin was found to be maximal at the basophilic normoblast stage of development and then declined progressively during maturation to the reticulocyte. The kinetics of endocytosis of 125I-transferrin by rabbit reticulocytes was also studied by electron microscope autoradiography. Up to 30% of the cell-bound transferrin was internalized almost immediately upon incubation at 37 degrees C. After 30 sec incubation, 42% of the cell-bound 125I-transferrin was estimated to be internal and this rose to almost 70% at steady state between the binding and release of transferrin after 12 min incubation.     

Microscope fluorometric investigations on the reticulocytic maturation distribution as diagnostic criterion of disordered erythropoiesis.

A microscope fluorometric technique is described which permits not only the visual identification of reticulocytes under the fluorescence microscope but also the determination of their relative stage of maturation to normocytes. The technique is based on a specific staining procedure which results in a fluorescent complex between the reticulocytic RNA and acridine orange. Thus, the relative mass of RNA in the individual reticulocytes can be measured by means of mciroscope fluorometry. As the reticulocytic RNA content decreases and finally disappears during the final maturation process of reticulocytes after their release into the peripheral blood stream, the fluorescence signal indicates the relative degree of this maturation. A characteristic frequency distribution of this parameter can be obtained for a given blood sample by microscope fluorometry measuring 200 to 300 reticulocytes. The preliminary use of this technique for following up the course of two cases of hemolytic anemia and one of pernicious megaloblastic anemia during their treatment demonstrates the potential diagnostic value of this technique of identifying the change of the reticulocyte maturation distribution in addition to the reticulocyte count. Satisfactory agreement between the microscope fluorometric results and those obtained by counting separately the four reticulocytic maturation stages according to Heilmeyer and Wesb?user has been achieved. The possibility of obtaining quantitative and comparable results by use of this method may be considered a general advantage and a promising basis for the development of an automated technique.     

Modification of reticulocyte count and distribution of degree of maturity by erythropoietin in the rat

By means of an automatic system for reticulocyte analysis (Auras) the effect of administering 50 IU of intraperitoneal erythropoietin on the number of reticulocytes and the distribution of the maturation degree of reticulocytes was investigated on Wistar rats for 28 days. A single administration of erythropoietin will lead to a rapid increase in the absolute number of reticulocytes and to changes in the distribution of the maturation degree within the first five days. The maximum of the reticulocyte number can be observed on the third to fourth day after application. Even on the second day after administering erythropoietin the measuring numbers of the distribution of maturation degree indicate maximal changes, the distribution quotient being particularly evident.