Comparative studies on red blood cell glucose phosphorylating activities of mammals.

1. ATP-D-hexose-6-phosphotransferase activity was measured in red blood cells of man, rabbit, pig and cow. Mean values ranged from 0.60 to 1.06 units/g haemoglobin and no significant difference was obtained with different glucose concentrations. 2. The characteristics of glucose phosphorylating activities in red blood cells of the species studied were similar. 3. Chromatography on DEAE column revealed two different glucose phosphorylating activities in red cells of man, rabbit and pig, and only one in cow red cells. 4. The first hexokinase activity is the predominant form and is saturated with low glucose concentrations; the second is noticeably marked at high glucose concentrations.     

Anion transport in dog, cat, and human red cells. Effects of varying cell volume and Donnan ratio

Membrane potential and the rate constants for anion self-exchange in dog, cat, and human red blood cells have been shown to vary with cell volume. For dog and cat red cells, the outward rate constants for SO4 and Cl increase while the inward rate constant for SO4 decreases as cells swell or shrink. These changes coincide with the membrane potential becoming more negative as a result of changes in cell volume. Human red cells exhibit a similar change in the rate constants for SO4 and Cl efflux in response to cell swelling, but shrunken cells exhibit a decreased rate constant for SO4 efflux and a more positive membrane potential. Hyperpolarization of shrunken dog and cat red cells is due to a volume-dependent rate constant for SO4 efflux and a more positive membrane potential. Hyperpolarization of shrunken dog and cat red cells is due to a volume-dependent increase in PNa. If this increase in PNa is prevented by ATP depletion or if the outward Na gradient is removed, the response to shrinking is identical to human red cells. These results suggest that the volume dependence of anion permeability may be secondary to changes in the anion equilibrium ratio which in red cells is reflected by the membrane potential. When the membrane potential and cell volume of human red cells were varied independently by a method involving pretreatment with nystatin, it was found that the rate of anion transport (for SO4 and Cl) does not vary with cell volume but rather with membrane potential (anion equilibrium ratio); that is, the rate constant for anion efflux is decreased and that for influx is increased as the membrane potential becomes more positive (internal anion concentration increases) while the opposite is true with membrane hyperpolarization (a fall in internal anion concentration).     

REGULATION OF HAEMOPOIESIS IN ALTERED GRAVITY

(1) The aetiology of one of the most striking physiological changes occurring during space-flight, the loss of red blood cells, remains unknown, and its precise time-pattern in flight has not yet been studied. (2) It is suggested that the changes during space-flight responsible for loss of red blood cells in man are (a) loss of plasma volume resulting from disappearance of hydrostatic pressure in the circulation during weightlessness and (b) reduced energy expended in maintenance of form, posture and locomotion resulting from elimination of the usual gravitational load on the muscles. Quadrupeds, like rats, would be expected to suffer minimal blood shifts in weightlessness and therefore have an unchanged plasma volume. However, since in weightlessness the activity-related energy expenditure by the muscles is reduced, the accompanying reduced oxygen demand by the tissues would cause a reduction in erythropoietin levels and so in the production of red blood cells, and a progressive lowering of the total red blood cell mass toward a new steady-state level. (3) Loss of plasma volume alone does not explain the observed loss of red blood cells in astronauts because, in the three manned Skylab missions, as the duration of the missions increased, loss of red blood cell mass decreased, whereas loss of plasma volume increased. This discrepancy is, however, well accounted for by the above hypothesis by taking into consideration the increased level of exercise of the astronauts as the duration of the mission increased. (4) Though water submersion of human subjects does mimic the effects of weightlessness, such effects were overriden in sea mammals because of adaptation to other factors associated with a life in the sea. (5) From the presented analysis of haemopoietic changes observed in spaceflight, an experiment can be designed for a future flight to uncover the causes and mechanisms of these changes and provide a basis for developing protective measures. Thus, the space environment can be used as an investigative tool to enhance the knowledge of the function of the haemopoietic system, which is a major homeostatic system of man and other vertebrates.     

Preparing for winter: divergence in the summer-autumn hematological profiles from representative species of the squirrel family

We examined hematological parameters in four related sciurid species in the late summer-autumn to assess the role of habitat, elevation, body size, and behavior in shaping these parameters. Red squirrels (Tamiasciurus hudsonicus) and Arctic ground squirrels (Spermophilus parryii) were sampled in southwestern Yukon, yellow-pine chipmunks (Tamias amoenus) in southern Alberta, and the eastern grey squirrel (Sciurus carolinensis) in southern Ontario. We obtained whole blood samples from each species and compared glucose levels, red blood cell characteristics (hematocrit, red blood cell count, hemoglobin concentration, mean corpuscular volume, mean corpuscular hemoglobin, and mean corpuscular hemoglobin concentration), and white blood cell counts (neutrophils, lymphocytes, monocytes, eosinophils, basophils) across species. We found species differences in glucose and red blood cell characteristics that may be a function of activity levels, phylogeny, or elevation, but not of body size, body condition, or adaptations to a semi-fossorial habitat. We also found species differences in white blood cell counts that remain unexplained by any single simple explanation and may be more useful for comparison of individuals within a given species than for interspecies comparisons.     

ATP and integrity of human red blood cells

In spite of the well known significance of ATP in the energy dependent life processes, the role of ATP in maintaining cellular integrity is poorly understood. A possible model for studying ATP dependent life processes is to monitor the kinetics of changes seen intra/extracellularly during ATP depletion. In our model system anticoagulated human whole blood was incubated at different temperatures to reduce intracellular ATP without addition of any chemicals. The red blood cells in their own plasma were incubated for several days at 4 degrees C or at 37 degrees C, and ATP, glucose, K+, Na+, hemoglobin, water content, mean corpuscular volume (MCV), pH and Ca2+ were analyzed in time-sequences. All the examined parameters remained practically unchanged at 4 degrees C, while at 37 degrees C total ATP and glucose decreased parallel and after a transient increase of MCV, the water content of red blood cells decreased. As the actual ATP fell below 10% of the initial ATP content (at 48 h), the release of potassium sharply increased. Release of hemoglobin started only after 96 hours of incubation. Maximums of changes of the examined parameters were found at different time intervals. The maximal speed of concentration changes for glucose was found at 12-24 hours of incubation and at 24-36 hours for ATP, at 48-60 hours for K+(-)Na+ and after 96 hours for hemoglobin.     

Addition of oligosaccharide decreases the freezing lesions on human red blood cell membrane in the presence of dextran and glucose

Although incubation with glucose before freezing can increase the recovery of human red blood cells frozen with polymer, this method can also result in membrane lesions. This study will evaluate whether addition of oligosaccharide (trehalose, sucrose, maltose, or raffinose) can improve the quality of red blood cell membrane after freezing in the presence of glucose and dextran. Following incubation with glucose or the combinations of glucose and oligosaccharides for 3 h in a 37 °C water bath, red blood cells were frozen in liquid nitrogen for 24 h using 40% dextran (W/V) as the extracellular protective solution. The postthaw quality was assessed by percent hemolysis, osmotic fragility, mean corpuscle volume (MCV), distribution of phosphatidylserine, the postthaw 4 °C stability, and the integrity of membrane. The results indicated the loading efficiency of glucose or oligosaccharide was dependent on their concentrations. Moreover, addition of trehalose or sucrose could efficiently decrease osmotic fragility of red blood cells caused by incubation with glucose before freezing. The percentage of damaged cell following incubation with glucose was 38.04 ± 21.68% and significantly more than that of the unfrozen cells (0.95 ± 0.28%, P < 0.01). However, with the increase of the concentrations of trehalose, the percentages of damaged cells were decreased steadily. When the concentration of trehalose was 400 mM, the percentage of damaged cells was 1.97 ± 0.73% and similar to that of the unfrozen cells (P > 0.05). Moreover, similar to trehalose, raffinose can also efficiently prevent the osmotic injury caused by incubation with glucose. The microscopy results also indicated addition of trehalose could efficiently decrease the formation of ghosts caused by incubation with glucose. In addition, the gradient hemolysis study showed addition of oligosaccharide could significantly decrease the osmotic fragility of red blood cells caused by incubation with glucose. After freezing and thawing, when both glucose and trehalose, sucrose, or maltose were on the both sides of membrane, with increase of the concentrations of sugar, the percent hemolysis of frozen red blood cells was firstly decreased and then increased. When the total concentration of sugars was 400 mM, the percent hemolysis was significantly less than that of cells frozen in the presence of dextran and in the absence of glucose and various oligosaccharides (P < 0.01). However, when both glucose and trehalose were only on the outer side of membrane, with increase of the concentrations of sugars, the percent hemolysis was increased steadily. Furthermore, addition of oligosaccharides can efficiently decrease the osmotic fragility and exposure of phosphatidylserine of red blood cells frozen with glucose and dextran. In addition, trehalose or raffinose can also efficiently mitigate the malignant effect of glucose on the postthaw 4 °C stability of red blood cells frozen in the presence of dextran. Finally, addition of trehalose can efficiently protect the integrity of red blood cell membrane following freezing with dextran and glucose. In conclusion, addition of oligosaccharide can efficiently reduce lesions of freezing on red blood cell membrane in the presence of glucose and dextran.     

Studies on the blood of fallow deer (Dama dama) and red deer (Cervus elaphus): haematology, red cell enzymes, metabolic intermediates and glycolytic rates.

1. Blood samples were obtained from fallow deer (Dama dama) and red deer (Cervus elaphus). Basic haematology, red cell enzymes, and metabolic intermediates and the glycolytic rate of the red cells incubated with different substrates were measured. 2. The major findings were (i) the activity of glucose phosphate isomerase was notably high in the red blood cells of the red deer; (ii) red deer cells also utilized adenosine more efficiently than those of fallow deer and (iii) red cells of both species utilized galactose more efficiently than other species of ruminants.     

Rosette formation by human thymocytes

A proportion of lymphocytes in human fetal and post-natal thymus, and in blood, formed rosettes with red blood cells from sheep and pig. The count of rosette-forming cells (RFC) among human thymocytes varied widely, from 2–216 per thousand cells, and was higher in fetal than in post-natal life. The count of RFC among human thymocytes was not reduced by specific rabbit anti-human immunoglobulin sera, indicating that the receptor was not of immunoglobulin character; the reaction was inhibited by antithymocyte serum and metabolic poisons and certain enzymes. The receptor may be equivalent to other “non-specific” glycoprotein hemagglutinins in plants and viruses.The importance of species differences in immunological assays is emphasized. Thus human thymocytes gave high counts of RFC only with red blood cells of sheep and pig; moreover thymus lymphocytes from only man and pig, but not several other species including rodents, were highly reactive with sheep red blood cells. The capacity for rosette formation could be a marker for T cells in human blood.     

池养鲤和草鱼血液学指标的研究

1.鲤鱼和草鱼的血液细胞包含红血球、淋巴球、单核球、嗜中性球、嗜酸性球及纺锤细胞。没有见到嗜碱性球。2.鲤鱼及草鱼的红血球数及血红蛋白量,在正常条件下,与水中溶氧量及成熟系数成十分显著的负相关。成熟雌鲤的红血球数(y)与溶氧量(x1)及成熟系数(x2)的迥归公式为:y=122+2.9x1-1.2x2。3.性腺发育程度及生殖活动强烈地影响鱼类血液有形成分。在生殖季节雄鱼的红血球数及血红蛋白量比雌鱼高,红血球沉降率则相反。白血球则在生殖季节及性腺退化吸收时比较活跃,而在非生殖季节两性之间无明显差异。4.发育成熟的雌鲤,经注射垂体后,无论产卵与不产卵其红血球数及血红蛋白量都下降,自然产卵的雌鲤亦然。5.雌鲤的红血球沉降率在临近产卵时急剧增加,而且比雄鲤明显地高。至于饥饿则对红血球沉降率无明显影响。6.在池养条件下鲤鱼的红血球数、血红蛋白量以及血式的个体差异较小,可望成为这类鱼的有应用价值的正常生理指标。       

Blood groups of anthropoid apes and their relationship to human blood groups

Affinity between blood groups of man and those of anthropoid apes is reflected not only in similarities or identities of reactions of the red cells with many specific typing reagents, but also in overall structures of some of the main blood group systems defined in man and in apes.Besides specificities of human-type, such as A-B-O, M-N, Rh-Hr, I-i, etc. known to be present on the red cells of various species of apes, specific reagents were produced by iso- or cross-immunization of chimpanzees that detect red cell specificities characteristic for apes only. Some of those specificities were found to be shared by several ape species and to fall into separate blood group systems that are counterparts of the human blood group systems. Recently obtained serological, as well as population data, indicate that the chimpanzee R-C-E-F blood group system is the counterpart of the human Rh-Hr system. Similarly to the Rh-Hr system, it is built around a main antigen, the R^c antigen, to which secondary specificities are attached by means of multiple allelic genes. The R^c is not only the principal factor of the chimpanzee R-C-E-F group system, but also constitutes a direct link with the human Rh-Hr blood group system, since anti-R^c reagents also detect Rh₀ specificity on the human red cells. Another chimpanzee blood group system, the V-A-B-D system, is counterpart of the M-N-S-s system, and is built around the central antigen V^c. the V^c is not only the principal specificity of the chimpanzee V-A-B-D system, but it also constitutes the direct link with the human M-N-S-s system since anti-V^c reagent gives with chimpanzee red cells reactions parralleling those obtained with anti-N lectin (N^v) while in tests with human red cells it detects specificity identical or closely related to the Mi^a specificity.     

Adaptations to pressure in the RBC metabolism of diving mammals

Marine mammals are known to dive up to 2000 m and, therefore, tolerate as much as 200 atm. of hydrostatic pressure. To examine possible metabolic adaptations to these elevated pressures, fresh blood samples from marine and terrestrial mammals were incubated for 2 h at 37 degrees C under 136 atm (2000 psi) of hydrostatic pressure. The consumption of plasma glucose and the production of lactate over the 2-h period were used to assess glycolytic flux in the red cells. The results indicate that glycolytic flux as measured by lactate production under pressure can be significantly depressed in most terrestrial mammals and either not altered or accelerated in marine mammals. The data also suggest that there is a significant shift in the ratio of lactate produced to glucose consumed under pressure. Interestingly, human and dolphin blood do not react to pressure. These combined data imply a metabolic adaptation to pressure in marine mammal RBC that may not be necessary in human or dolphin cells due to their unique patterns of glucose metabolism.     

Thermal acclimation and seasonal variations of erythrocyte size in the Andean mouse Phyllotis xanthopygus rupestris

Seasonal hematological adjustments in small mammals may include changes in the number and size of the red cells or changes in other linked blood parameters. The direction and magnitude of these changes vary in different species. We hypothesized that the observed variations of the red cell adjustments could be directly related to the magnitude of the seasonal temperature differential, and predicted that the annual red cell size variation in rodents from environments with marked seasonal changes would tend to disappear, if the animals were raised under milder and constant environments. To test this idea, we got field blood samples from the Andean species Phyllotis xanthopygus rupestris enduring a winter-summer thermal differential of at least 20 degrees C. These animals had significantly smaller erythrocytes during the winter. Contrary to our prediction, their offspring born and raised under constant temperature conditions showed a similar trend. Unless the effective environmental cue differed from the one we used, these results favor the idea of a genetically determined annual red cell size variation that occurs independent of thermal acclimation and acclimatization.     

Hypoosmotic hemolysis of erythrocytes by active carbonyl forms

Low-molecular-weight dicarbonyls formed during free radical peroxidation of polyene lipids (malondialdehyde) and autooxidation (glyoxal) or other oxidative transformations of glucose (methylglyoxal) are able to modify the structure of lipid-protein supramolecular complexes of cells. We investigated changes in the erythrocyte membrane structure after an 18-h exposure of human red blood cells in the presence of various natural dicarbonyls. The changes in the mechanical properties of the membrane after membrane modification by carbonyls were evaluated by the susceptibility of erythrocytes to hypoosmotic hemolysis. It has been shown that treatment of red blood cells with malondialdehyde increases the resistance of these cells to hypoosmotic hemolysis, whereas the malondialdehyde isomer, methylglyoxal, in contrast, makes red blood cells more sensitive to the action of hypoosmotic solutions. Paradoxically, a homologue of malondialdehyde, glyoxal, has no effect on hemolysis of red blood cells in hypoosmotic solutions. The findings point to the possibility of the multidirectional effect of low-molecular-weight dicarbonyls with similar structures on the structure and function of biological membranes.     

The physiological properties of human red cells as derived from kinetic osmotic volume changes

Volume changes were originally used for studying the dynamic properties of glucose transport in red cells. As an extension it has been found possible to examine the interplay of three functional proteins evolved for the physiological role of human erythrocytes in transporting carbon dioxide and bicarbonate. The proteins chiefly concerned in this investigation were the cytoplasmic carbonic anhydrase and the two membrane transporting proteins, namely the band 3 anion exchanger and the unique bicarbonate transporter, which are distinct from the anion exchanger. The rates of anion membrane transport measured and the volume changes may be more than two orders of magnitude faster than those which regulate cationic movement in red cells, but this may only be an adaptation for the physiological role of red cells. The new concepts derived from the studies and their possible wider applications to physiological mechanisms are briefly discussed.     

The influence of L-sorbose on red cell flow properties, shape and packing ability

Since the sweet ketohexose L-sorbose causes overt hemolysis in dogs but not in man, we examined the possibility that L-sorbose induces a "prehemolytic state" of human red cells, manifesting itself as impairment of rheological red cell properties. After 2 hours incubation at 37 degrees C relative viscosity of red cell suspensions measured by radial spreading in filter paper and packing ability of red cells were normal. Incubation for 24 and 48 hours of red cells in media containing L-sorbose, glucose or no sugar showed that relative viscosity was best maintained in glucose. Relative viscosity and packing ability of red cells in L-sorbose containing suspensions decreased less than in suspensions without sugar. This difference was independent of the glucose metabolism, red cell ATP, osmolality and pH of the suspending media, but appeared to be related to different degrees of spheroechinocytic red cell shape transformation observed in different suspending media. It is possible that L-sorbose has some antiechinocytic properties and/or that it induces an alteration of red cell membrane flexibility. There is no indication of an L-sorbose induced "prehemolytic state" in human red cells.     

Immunochemical evidence for the transmembrane orientation of glycophorin A. Localization of ferritin-antibody conjugates in intact cells.

Antibodies were raised in rabbits to a 51-amino acid cyanogen bromide-derived peptide of human erythrocyte glycophorin A which has been shown to represent the C-terminal end of the 131-residue polypeptide chain. Antibodies prepared by immunoadsorption were found to be directed against a chymotryptic-derived peptide (residues 102 to 118) of glycophorin A but were unreactive with either intact or proteolytically modified red blood cells. No cross-reactivity was observed with glycophorin B of human or sialoglycoproteins prepared from red blood cells of other mammalian species. Ferritin-antibody conjugates of such sera were applied to thin sections of intact red blood cells (frozen or protein embedded) and were found to localize exclusively to sites distributed uniformly along the inner surfaces of the membrane. No staining was seen on sections prepared from red blood cells from other species nor on sections of human red cells pretreated with unconjugated antisera. These results provide additional evidence in intact, fixed human erythrocytes that glycophorin A has a transmembrane orientation.     

Adenine and pyridine nucleotides in the erythrocyte of different mammalian species

Adenine (ATP, ADP, AMP) and pyridine nucleotides (NADP+, NADPH, NAD+, NADH) concentrations have been determined by HPLC in the erythrocytes from five different mammalian species (pig, rat, mouse, rabbit and cow) and compared to those in human red blood cells. Two different extraction procedures have been used and the results obtained are compared and discussed. A good correlation between the different abilities of the erythrocytes of the six species to utilize glucose and the NAD+/NADH ratio was found, with high NAD+/NADH ratio in the red blood cell of the species with high glucose utilization rates. The levels of all the glycolytic enzymes and some of the pentose phosphate shunt enzymes were also determined.     

Reticulocyte changes after experimental anemia and erythropoietin treatment of horses.

Availability of recombinant human erythropoietin (EPO) has facilitated use to enhance red blood cell production, and therefore aerobic performance, in human and equine athletes. Recombinant human EPO promotes growth and differentiation of equine erythroid precursor cells, but in some horses repeat administration induces immune interference with endogenous EPO resulting in fatal anemia. Although blood reticulocyte parameters acquire unique changes in humans treated with EPO, with manual enumeration methods, horses were not considered to release reticulocytes from the bone marrow into circulation, even under severe erythropoietic stress. The goals of this study were to determine whether reticulocytes could be detected and characterized in horses that are anemic or have been treated with EPO using a modern hematology analyzer. Anemia was induced in six horses by removal of 30 ml of blood/kg of body wt over 24 h. After 28 days, the horses were treated twice with 55 U/kg of EPO (Eprex), and after 65 days they were treated thrice with 73 U/kg of EPO. Blood samples were analyzed with the ADVIA120 instrument every 3-5 days and bone marrow samples 7 days after anemia and EPO treatments. Analysis of blood reticulocyte parameters by ANOVA in a randomized complete block design determined that anemia and EPO induced significant (P < or = 0.05) increases in red cell distribution width and reticulocyte mean cell volume. Parameters changed only after EPO treatment were cellular hemoglobin concentration mean, mean cell volume, reticulocyte concentration, proportion of macrocytic reticulocytes, and reticulocyte cellular hemoglobin. These findings indicate that horses under erythropoietic stress and after EPO treatment release reticulocytes with unique characteristics into circulation.     

A colorimetric assay for the measurement of D-glucose consumption by cultured cells

A colorimetric method is described for measuring glucose consumption by tissue culture cells. This procedure, which utilizes the coupled activities of glucose oxidase and horseradish peroxidase, is insensitive to the spectral interferences caused by the phenol red and sera present in most tissue culture media. The spectral properties (absorbance maxima and apparent absorption coefficients) and stability of a large number of chromogenic horseradish peroxidase substrates were surveyed for their ability to perform in an assay for glucose in the presence of phenol red and sera components. One of these chromophores, the product of an oxidative couple between 4-aminoantipyrine and N-ethyl-N-sulfopropyl-m-toluidine, was subsequently used to develop a fixed time assay for glucose in media samples. The assay required only 10 microliters of media in a 1-ml assay volume; reproducibility studies showed variabilities of less than 5% in the assay of a single sample, and values obtained in glucose analyses correlated well with those obtained using commercially available test kits. The assay was used to study the rate of glucose consumption in two different cell types, bovine corneal endothelial cells and human diploid fibroblasts.     

Membrane and intracellular modes of sugar-dependent increments in red cell stability.

Sugar-dependent increments in red cell stability under osmotic stress can be ascribed to changes either in the membrane or in the intracellular matrix. These two possible modes of action have been tested and characterized. Rheological investigation of membrane-free haemoglobin solutions has shown that D-glucose, but not D-fructose, promotes the formation of a visco-plastic gel structure. Gel strength is a function of glucose concentration, haemoglobin concentration and temperature. The ability of various sugars to promote gel formation correlates with their solution properties. The existence of gel structure reduces K+ and haemoglobin leak from red cells whose membranes were partially destroyed by gamma-radiation. Reduced osmotic swelling in the presence of glucose is also due to gel formation since the glucose effect is lost in resealed red cell ghosts. D-Fructose does not protect red cells against radiation damage; its mode of action in increasing red cell stability under osmotic stress is a membrane effect. Cell sizing using the Coulter Counter has shown that fructose, but not glucose, can increase the maximal volume at lysis. At 50 mM, D-fructose expands the red cell ghost volume by 11.2%; this represents a 7.2% increase in membrane area. Ghost expansion by fructose is fructose concentration dependent (0-100 mM) and is insensitive to temperature variation (0-37 degrees C).