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.     

Separation of red blood cells from G6PD-deficient patients in dextran density gradients

Red blood cells of 30 patients with G6PD deficiency were separated and characterized by means of isopyknic dextran density gradient centrifugation. The simultaneous determination of G6PD activity and the percentage of NADPH deficiency cells in relation to the maturation parameters of density, reticulocyte share, GOT and PK activity made it possible to recognize differences in the maturation of red blood cells with G6PD deficiency in normal persons as well as within a group of patients. In each case the more or less diminished enzyme activity of the cell suspension was accompanied by a marked enzyme deficiency of the youngest fraction. It is possible that NADPH defect cells are being eliminated at first. In many cases a direct correlation between the percentage of "empty cells" and the in vitro stability tests with and without NADP+ addition could be identified. Decreased maximal speed, changed kinetic behaviour, and instability of these variants are stressed as being the decisive parameters for the life expectation of red blood cells in patients with G6PD deficiency.     

Differences between cation-osmotic hemolysis and filterability in exaprolol- and glutaraldehyde-treated human red blood cells

The changes in human red blood cell microrheology in different glutaraldehyde (3.0 and 5.0 x 10(-6) mol x l(-1)) and exaprolol (2.5 and 5.0 x 10(-4) mol x l(-1)) concentrations were studied. The method of millipore filtration was compared with the method of cation-osmotic hemolysis. Both drugs prolonged the filtration time. Cation-osmotic hemolysis in glutaraldehyde-treated cells was significantly lower in comparison with the control group. On the other hand, there was a significant increase in cation-osmotic hemolysis in exaprolol-treated cells. Besides cation-osmotic hemolysis and filterability of erythrocytes, we evaluated the medium cell volume (MCV) and the medium cell hemoglobin concentration (MCHC). No changes in MCV and MCHC in glutaraldehyde-treated cells were observed. However, the MCV was significantly lower and the MCHC was significantly higher in exaprolol-treated cells. In conclusion, we suggest that the method of cation-osmotic hemolysis is more sensitive than the filtration method for determination of red blood cell microrheology.     

Purine and pyridine nucleotides in rabbit red blood cells of different maturity

Using reversed-phase high-performance liquid chromatography purine nucleotides, nucleosides and nucleobases as well as pyridine nucleotides were determined in extracts of reticulocytes and mature red blood cells of rabbits. The concentrations of almost all compounds measured decrease during the last phase of red blood cell maturation. These changes were interpreted with respect to the loss of mitochondria, accompanied by shifting the energy production from the preferentially oxidative mode to the exclusively glycolytic one and variations in the concentrations of purine compounds in blood plasma during reticulocytosis.     

Decreased Ca pump ATPase activity associated with increased density in human red blood cells

Red blood cells (rbcs) from five different normal humans were separated according to density using a simple procedure. The procedure involved centrifugation for 30 minutes in small glass tubes in the absence of any density gradient medium. This produced a column of rbcs arranged according to their density. Samples of the top 8% of the columns and bottom 8% of the columns were removed from the tubes with a micropipet. From each donor, samples of the least and most dense cells, respectively, were pooled from multiple tubes for each donor and designated "top" and "bottom" cells. These top and bottom cells were compared with unselected (total) cells from the same subjects, respectively. Top cells were larger and bottom cells were smaller than total cells. ATPase activities were operationally defined and measured in saponin lysates of these rbcs. The Ca pump ATPase (both in the calmodulin-activated and calmodulin-independent states [achieved by addition of compound 48/80]) of the top cells exhibited greater activity, and the Ca pump ATPase of bottom cells exhibited lower activity than total cells. It was suggested that loss of Ca pump ATPase activity is associated with rbc aging and may be a determinant of rbc life span. A mechanism for the loss of Ca pump ATPase activity was suggested. This speculative mechanism is based upon selective proteolysis of the Ca pump ATPase by the Ca-activated protease, calpain.     

Na+/H+ exchange is increased in sickle cell anemia and young normal red cells

Summary Red cell volume regulation is important in sickle cell anemia because the rate and extent of HbS polymerization are strongly dependent on initial hemoglobin concentration. We have demonstrated that volume-sensitive K:Cl cotransport is highly active in SS whole blood and is capable of increasing MCHC. We now report that Na⁺/H⁺ exchange (Na/H EXC), which is capable of decreasing the MCHC of erythrocytes with pH_i<7.2, is also very active in the blood of patients homozygous for HbS. The activity of Na/H EXC (maximum rate) was determined by measuring net Na⁺ influx (mmol/liter cell·hr=FU) driven by an outward H⁺ gradient in oxygenated, acidloaded (pH_i 6.0), DIDS-treated SS cells. The Na/H EXC activity was 33±3 FU (mean±se) (n=19) in AA whites, 37±8 FU (n=8) in AA blacks, and 85±15 FU (n=14) in SS patients (P<0.005). Separation of SS cells into four density-defined fractions by density gradient revealed mean values of Na/H EXC four to five times higher in reticulocytes (SS1), discocytes (SS2) and dense discocytes (SS3), than in the fraction containing irreversibly sickled cells and dense discocytes (SS4). In contrast to K:Cl cotransport, which dramatically decreases after reticulocyte maturation, Na/H EXC persists well after reticulocyte maturation. In density-defined, normal AA red cells, Na/H EXC decreased monotonically as cell density increased. In SS and AA red cells, the magnitude of stimulation of Na/H EXC by cell shrinkage varied from individual to individual. We conclude that Na/H EXC is highly expressed in SS and AA young red cells and decays slowly after reticulocyte maturation.     

Study of maturation of membrane transport function in red blood cells by X-ray microanalysis

Summary Red blood cells of certain species of animals, such as dogs and cats, contain low potassium and high sodium, whereas the erythropoietic stem cells giving rise to these cells are of high potassium type. This paper examines the sequence of membrane transport changes during erythropoiesis by analyzing the K, Na and Fe in single bone marrow cells, reticulocytes and mature red blood cells with X-ray microanalysis. The relationship between K/Na ratios and Fe/(K+Na) ratios were examined by X-ray microanalysis. The K/Na ratios give a measure of the membrane cation transport function. The Fe/(K+Na), which is analogous to hemoglobin concentration, gives an index of maturation stage. The relationships between K/Na and Fe/(K+Na) in the marrow cells of normal adult dog and those of a phenylhydrazine-injected dog with accelerated erythropoiesis show that the modification of cation composition occurs after the initiation of hemoglobin synthesis but before its completion. Similar relationships in the reticulocytes obtained from phenylhydrazine-injected dogs as well as from newborn dogs show a consistent decrease in K/Na with increased Hb, indicating a drastic change in cation composition during the maturation of the reticulocytes. Therefore the modification in membrane transport function must have occurred before or during the formation of reticulocytes.     

Factors that accelerate or retard red blood cell senescence

This article explores information concerning alterations in the time of age-related red blood cell (rbc) death (rbc senescence) in experimental animals and humans. Those factors that accelerate or retard the mean time for senescent death [the mean potential rbc life-span, (T)] are discussed; specifically excluded are conditions in which rbc survival is shortened due to an increase in the rate of age-independent [random hemolysis, (k)]rbc death. The factors prolonging senescence are reduction in metabolic rate through hibernation, reduced environmental temperature, hypophysectomy and thyroidectomy, and splenectomy. In general, these processes prolong rbc senescence by about 10%-15% in the models studied to date. The failure of splenectomy to prolong rbc senescence to any physiologically meaningful extent casts serious doubt on the concept that splenic processes are a major factor in the senescence process. Rbcs made under conditions of increased erythropoiesis and/or increased metabolic rate show acceleration of senescence. Thus, rbcs of animals treated with thyroxine show a 15% acceleration of senescence. "Stress reticulocytes" and normal full-term human newborn rbc may show up to 25% reduction in (T). The maximum acceleration seen to date is 50%-90%, as seen in the rbcs of the fetal and newborn rat. rbc senescence is not accelerated in rats with splenomegaly and increased rates of random hemolysis, again casting strong doubts on the spleen's ability to alter rbc senescence by progressively modifying the rbc during successive passages through that organ. It is postulated that rbc senescence is mainly a function of the red cell's initial endowment, particularly in the dynamic ability of that cell (and its membrane) to adapt to cumulative stresses that exist during its circulation through the body.     

Analysis by cell hybridization of mechanisms that regulate beta-adrenergic responses in reticulocytes and in differentiating erythroid cells.

In intact reticulocytes, but not in fragmented membranes, the loss of adenylate cyclase activity during cell maturation followed a biphasic time course. A rapid phase (t1/2 approximately 2 h) during which the initial activity was reduced by 40-50% was followed by a slow phase with t1/2 close to 3 days. The fast decay seemed to occur on the adenylate cyclase level since (-)isoprenaline- or forskolin-stimulated activities behaved similarly and bacterial toxin-monitored Gs and Gi proteins remained stable. The mechanism of the initial decrease in hormonal responsiveness was further analysed in hybrid cells prepared by fusing reticulocytes with Friend erythroleukemia (MEL) cells. The hybrids contained reticulocyte-derived beta-adrenoceptors and MEL cell-derived adenylate cyclase and G proteins. Fusion of reticulocytes to native MEL cells caused adenylate cyclase activity to drop by 30% at 2 h and 45% at 18 h after fusion. By contrast, hybrids prepared after dimethylsulfoxide-induced differentiation of MEL cells showed stable or increasing rates of receptor-coupled cAMP formation between 2 and 18 h after fusion, concomitant with the enhanced activity of the Gs protein in these cells. A cyclase-stimulating factor present in the cytosol of MEL cells and of reticulocytes appeared not to be involved in short-term regulation of hormonal responsiveness. We conclude that the strength of beta-adrenergic responses in erythroid progenitor cells is primarily regulated by modulating G protein-mediated receptor cyclase coupling while reticulocytes, during early maturation, seem to rely on direct inactivation of adenylate cyclase, probably via a cytosolic proteolytic pathway.     

NMR studies of intracellular free calcium, free magnesium and sodium in the guinea pig reticulocyte and mature red cell

During the maturation process reticulocytes lose their intracellular organelles and undergo changes in membrane lipid composition and ion transport properties. While several reports indicate differences in the levels of magnesium, sodium and calcium in reticulocytes and erythrocytes, controversy remains concerning the actual magnitude and direction of ionic alterations during reticulocyte maturation. One problem with all of these studies is that the techniques used are invasive and are limited to measuring only the total cell ion content. We have used 31P, 23Na and 19F nuclear magnetic resonance (NMR) spectroscopy to compare the intracellular free ion and phosphometabolite levels in guinea pig reticulocytes and mature red blood cells. In contrast to a sharply decreased concentration of ATP in erythrocytes in comparison to reticulocytes, the intracellular free magnesium, measured using 31P-NMR, was increased by about 65% upon maturation (150 mumol/l cell water in reticulocytes in comparison to 250 mumol/l cell water in erythrocytes). Sizeable but opposite changes in intracellular sodium (5.5 mumol/ml cells in reticulocytes vs. 8.5 mumol/ml cells in erythrocytes) and intracellular free calcium (99 nM vs. 31 nM in reticulocytes and mature red cells, respectively) were also observed, suggesting that alterations in the kinetics of membrane ion transport systems, accompanying changes in phospholipid and cholesterol content, occur during the process of red cell maturation. However, in contrast to dog red blood cells, there was no evidence for the presence of a Na+/Ca2+ exchanger in guinea pig reticulocytes or erythrocytes.     

Hexokinase microheterogeneity in rabbit red blood cells and its behaviour during reticulocytes maturation

Hexokinase in rabbit reticulocytes is present in two molecular forms (hexokinase Ia and Ib) separable by ion-exchange chromatography on DE-52 columns. By the use of ion-exchange HPLC we have been able to show that the isozymic form we previously called hexokinase la can be resolved into two peaks of activity one of which is (Ia) soluble, the other (Ia*) particulate. Hexokinase Ia* can be solubilized by detergents like saponine and Triton X-100 and disappears during ‘in vivo’ reticulocytes maturation. This new hexokinase micro-heterogeneity is not caused by different oxidized forms of the enzyme nor influenced by the presence of proteolytic inhibitors during lysate preparation.     

Multicatalytic and 26 S ubiquitin/ATP-stimulated proteases in maturing rabbit red blood cells.

Rabbit red blood cells of various ages were separated on Percoll gradients and the activities of two large cytosolic proteases were measured. Both the multicatalytic protease (MCP), assayed by hydrolysis of fluorigenic peptides, and the 26 S ubiquitin/ATP-stimulated protease, assayed by degradation of ubiquitin-lysozyme conjugates, declined 3-fold or less during maturation of rabbit reticulocytes to erythrocytes. The ability of MCP to hydrolyze three classes of peptides decreased in parallel indicating that the 20 S protease is not significantly remodeled during red blood cell maturation.     

The aging of the red blood cell. A multifactor process

Red blood cell (rbc) senescence is associated with loss of surface sialic acid, which is the principal carrier of surface negative charge and determines the electrokinetic behavior of old rbcs. Loss of sialic acid in an old rbc is demonstrated in its decreased electric mobility and lower negative charge density, determined topographically with cationic particle labeling. Surface sialic acid determines also the mutual attraction--repulsion forces, as demonstrated in enhanced aggluinability with cationic molecules, lectins, and blood group antibodies. Loss of sialic acid accompanies ATP-depletion in vitro; thus, a T-antigen site is unmasked. Macrophages have specific receptors to the site as to newly exposed galactose and N-acetyl galactosamine sugars. Furthermore, the involvement of complement molecules in the recognition of old RBCs by macrophages has been shown. This is possibly due to loss of sialic acid or at least a regrouping--relocation of surface anionic sites due to cell shape changes from discocytes to crenated forms, which accompany both in vivo and in vitro rbc aging. In turn, shape changes are apparently controlled by the cytoskeletal network underlying the rbc membrane, which undergoes structural alteration with physiologic aging in changing the dimensions of oligomeric spectrin and the thickness of the spectrin-actin cytoskeletal assembly.     

A particle-associated ATP-dependent proteolytic activity in erythroleukemia cells

An ATP-dependent proteolytic activity has been detected in both mouse erythroleukemia (Friend) cells and human (K562) erythroleukemia cells. Exposure of the Friend cells to dimethyl sulfoxide, which stimulates differentiation, increased ATP-dependent proteolysis approximately 2-fold although inducing differentiation in the K562 line had no significant effect on proteolysis. In contrast to the previously described soluble ATP-dependent proteolytic system of reticulocytes, the activity in the more primative erythroid cells is associated with a particulate fraction and is readily sedimentable by centrifugation at 100,000 X g for 1 h. Like the soluble reticulocyte system, the particulate activity requires divalent cation and is inhibited by hemin as well as vanadate. The activity was isolated on a sucrose cushion (30%) and did not appear to be associated with membranes, cytoskeleton, or polysomes. This enzymatic activity which degrades abnormal globin chains may initially reside in a particulate fraction and then become solubilized during erythroid maturation to the reticulocyte stage. Alternatively, the particulate activity may disappear with cell maturation being replaced by a distinct soluble activity. ATP-dependent proteolytic activity is eventually lost with reticulocyte maturation and further aging of erythrocytes.     

Seasonal changes in the red blood cell system in the European bison, Bison bonasus L

1. In 195 European bisons divided into four groups (Group 1, 0-3 year-old males; Group 2, 0-3 year-old females; Group 3, mature bulls, over 3 years old; Group 4, mature cows, over 3 years old) seasonal changes in red blood cell number and diameter, haemoglobin level, haematocrit value, index F, MCH, MCHC and MCV were studied. 2. Seasonal cyclicity was found only in red blood cell diameters in all groups. 3. In young males the cyclicity was found in MCHC and in MCV only. 4. In young females the cyclicity was found in Hb and Hct values, in MCH and in MCV. 5. In mature bulls cyclicity was found only in RBC diameter and in MCV. 6. In mature cows the cyclicity was found in index F, MCH and in MCHC values. 7. Seven out of 14 acrophases of cyclic indices occurred just before autumnal equinox and three before vernal equinox.     

The mean red cell volume in long distance runners

Red cell indices were determined in 6 well trained runners before and after a 100 km race, and Coulter Counter (CC) determinations compared with calculated values derived from centrifuged hematocrit (ctrf), red cell count (CC) and hemoglobin measurements. The following changes were observed immediately after the race, as compared to values 3 days before: MCV(ctrf) decreased by 4.9% (p less than 0.001), MCV(CC) increased by 1.9% (p less than 0.05), MCHC(ctrf) increased by 4% and MCHC(CC) decreased by 3%. The increase in MCV(CC) suggests that intraerythrocyte osmolality was increased, this probably leading to swelling of the cells induced by a shift of water from the diluting Coulter Counter solution into the red cells prior to the MCV measurement. The decrease in MCV(ctrf) immediately after the race was not correlated with the increase in plasma osmolality. This suggests that plasma osmolality alone was not the key factor for regulation of red cell volume. The changes in MCV(ctrf), which contributed to a surprising stability of the hematocrit value and plasma volume, might represent a physiological principle for the maintenance of a favourable blood viscosity.     

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.     

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.     

Plasmodium berghei: relative immunogenicity of infected reticulocytes and infected oxyphilic red blood cells

Hyperbleeding of mice 1 day before and 1 day after infection with Plasmodium berghei resulted in a more aggravated infection. Parasitemia rose significantly faster, but the mean survival time of these mice was not significantly different from control mice. At Day 5 of infection, parasites were almost exclusively in reticulocytes in contrast to control infections in which parasites were found in oxyphilic erythrocytes at Day 5 after infection. Purified parasitized reticulocytes taken from hyperbled mice at Day 5 after infection contained more young developmental parasite stages than purified parasitized oxyphilic erythrocytes taken from normal mice at Day 5 to 7 after infection. Parasitized reticulocytes were more readily opsonized by antibodies from immune serum when compared to parasitized oxyphilic red blood cells and when used to stimulate immune spleen cells the former were better stimulator cells than the latter. Results suggest either that parasitized reticulocytes are more immunogenic then parasitized oxyphilic red blood cells or that suspensions of parasitized reticulocytes contain more immunogenic parasite stages than suspensions of parasitized oxyphilic red blood cells.     

Association of glyceraldehyde-3-phosphate dehydrogenase with the plasma membrane of the intact human red blood cell

Glycolytic enzymes have been observed to associate in vitro with membranes and cytoplasmic filaments in a variety of systems, but their distribution in vivo is contested. We have therefore examined the distribution of glyceraldehyde-3-phosphate dehydrogenase (G3PD) in the intact human erythrocyte using indirect immunofluorescence and affinity-purified rabbit antibodies to G3PD. Antibody specificity was demonstrated by immunoblotting as well as immunofluorescence experiments with ghosts specifically depleted of and reconstituted with G3PD. Anti-G3PD immunolabeling experiments utilized both fixed whole cells and fixed cell suspensions infused with 2.3 M sucrose, frozen and thick-sectioned. In all experiments a two-step fixation protocol was employed which ensured that cytoplasmic hemoglobin was retained when cells were subjected to Triton X-100 permeabilization, the anti-genicity of G3PD was preserved, and antibody penetration was complete. We used mixtures of biotinylated affinity-purified antibodies to G3PD and dichlorotriazinylaminofluorescein-labeled, affinity-purified antibodies to hemoglobin, followed by rhodamine-streptavidin, in double-label experiments. In both whole and sectioned human erythrocytes, G3PD staining was predominantly membrane associated while hemoglobin staining was diffusely distributed throughout the cytoplasm. In isolated ghosts, some G3PD was tightly bound to the membrane and was resistant to elution with phosphate-buffered saline and NAD+/arsenate. However, in immunolabeled rat reticulocytes and erythrocytes G3PD was cytoplasmic. Nucleated human blood cells and platelets also exhibited cytoplasmic G3PD. In approximately 10% of the human erythrocyte population G3PD was also cytoplasmic. These cells were flatter in shape and exhibited strong cytoplasmic immunolabeling for hemoglobin which was sometimes concentrated along the cell membrane; possibly, these cells were late reticulocytes or early erythrocytes. We conclude that G3PD is preferentially associated with the plasma membrane of human erythrocytes in a specific fashion.