Membrane skeleton-bilayer interaction is not the major determinant of membrane phospholipid asymmetry in human erythrocytes

Transbilayer phospholipid distribution, membrane skeleton dissociation/association, and spectrin structure have been analysed in human erythrocytes after subjecting them to heating at 50 degrees C for 15 min. The membrane skeleton dissociation/association was determined by measuring the Tris-induced dissociation of Triton-insoluble membrane skeletons (Triton shells), the spectrin-actin extractability under low ionic conditions, and the binding of spectrin-actin with normal erythrocyte membrane inside-out vesicles (IOVs). The spectrin structure was ascertained by measuring the spectrin dimer-to-tetramer ratio as well as the spectrin tryptophan fluorescence. Both the Tris-induced Triton shell dissociation and the spectrin-actin extractability under low ionic conditions were considerably reduced by the heat treatment. Also, the binding of heated erythrocyte spectrin-actin to IOVs was significantly smaller than that observed with the normal cell spectrin-actin. Further, the quantity of spectrin dimers was appreciably increased in heat-treated erythrocytes as compared to the normal cells. This change in the spectrin dimer-to-tetramer ratio was accompanied by marked changes in the spectrin tryptophan fluorescence. In spite of these heat-induced alterations in structure and bilayer interactions of the membrane skeleton, the inside-outside glycerophospholipid distribution remained virtually unaffected in the heat-treated cells, as judged by employing bee venom and pancreatic phospholipase A2, fluorescamine and Merocyanine 540 as the external membrane probes. These results strongly indicate that membrane bilayer-skeleton interaction is not the major factor in determining the transbilayer phospholipid asymmetry in human erythrocyte membrane.     

Relationship between extracellular osmolarity, NaCl concentration and cell volume in rat glioma cells

The cell volume, which controls numerous cellular functions, is theoretically linearly related with the inverse osmolarity. However, deviations from this law have often been observed. In order to clarify the origin of these deviations we electronically measured the mean cell volume of rat glioma cells under three different experimental conditions, namely: at different osmolarities and constant NaCl concentration; at different NaCl concentrations and constant osmolarity and at different osmolarities caused by changes in NaCl concentration. In each condition, the osmolarity was maintained constant or changed with NaCl or mannitol. We showed that the cell volume was dependent on both the extracellular osmolarity and the NaCl concentration. The relationship between cell volume, osmolarity and NaCl concentration could be described by a new equation that is the product of the Boyle-van't Hoff law and the Michaelis-Menten equation at a power of 4. Together, these results suggest that in hyponatriemia, the cell volume deviates from the Boyle-van't Hoff law because either the activity of aquaporin 1, expressed in glioma cells, is decreased or the reduced NaCl influx decreases the osmotically obliged influx of water.     

Geometry of the human erythrocyte. I. Effect of albumin on cell geometry.

The effects of albumin on the geometry of human erythrocytes have been studied. Individual red cells, hanging on edge from coverslips were photographed. Enlarged cell profiles were digitized using a Gradicon digitizer (Instronics Ltd., Stittsville, Ontario). Geometric parameters including diameter, area, volume, minimum cylindrical diameter, sphericity index, swelling index, maximum and minimum cell thickness, were calculated for each cell using a CDC 6400 computer. Maximum effect of human serum albumin was reached at about 1 g/liter. Studies of cell populations showed decreases in mean cell diameter of up to 6%, area 6%, and volume 15%, varying from sample to sample. The thickness of the rim was increased while that at the dimple was decreased. Studies of single cells showed that area and volume changes do not occur equally in all cells. Cells with lower sphericity indices showed larger effects. In the presence of albumin, up to 50% of the cells assumed cup-shapes (stomatocytes). These cells had smaller volumes but the same area as biconcave cells. Mechanical agitation could reversibly induce biconcave cells to assume cup shapes without area or volume changes. Experiments with de-fatted human albumins showed that the presence of bound fatty acids in varying concentrations does not alter the observed effects. Bovine serum albumin has similar effects on human erythrocytes as human serum albumin.     

Heat-induced alterations in monkey erythrocyte membrane phospholipid organization and skeletal protein structure and interactions

Rhesus monkey erythrocytes were subjected to heating at 50 degrees C for 5-15 min, and the heat-induced effects on the membrane structure were ascertained by analysing the membrane phospholipid organization and membrane skeleton dynamics and interactions in the heated cells. Membrane skeleton dynamics and interactions were determined by measuring the Tris-induced dissociation of the Triton-insoluble membrane skeleton (Triton shells), the spectrin-actin extractability at low ionic strength, spectrin self-association and spectrin binding to normal monkey erythrocyte membrane inside-out vesicles (IOVs). The Tris-induced Triton shell dissociation and spectrin-actin extractability were markedly decreased by the erythrocyte heating. Also, the binding of the heated erythrocyte membrane spectrin-actin with the IOVs was much smaller than that observed with the normal erythrocyte spectrin-actin. Further, the spectrin structure was extensively modified in the heated cells, as compared to the normal erythrocytes. Transbilayer phospholipid organization was ascertained by employing bee venom and pancreatic phospholipases A2, fluorescamine, and Merocyanine 540 as the external membrane probes. The amounts of aminophospholipids hydrolysed by phospholipases A2 or labeled by fluorescamine in intact erythrocytes considerably increased after subjecting them to heating at 50 degrees C for 15 min. Also, the fluorescent dye Merocyanine 540 readily stained the 15-min-heated cells but not the fresh erythrocytes. Unlike these findings, the extent of aminophospholipid hydrolysis in 5-min-heated cells by phospholipases A2 depended on the incubation time. While no change in the membrane phospholipid organization could be detected in 10 min, prolonged incubations led to the increased aminophospholipid hydrolysis. Similarly, fluorescamine failed to detect any change in the transbilayer phospholipid distribution soon after the 5 min heating, but it labeled greater amounts of aminophospholipids in the 5-min-heated cells, as compared to normal cells, after incubating them for 4 h at 37 degrees C. These results have been discussed to analyse the role of membrane skeleton in maintaining the erythrocyte membrane phospholipid asymmetry. It has been concluded that both the ATP-dependent aminophospholipid pump and membrane bilayer-skeleton interactions are required to maintain the transbilayer phospholipid asymmetry in native erythrocyte membrane.     

Suicidal erythrocyte death following cellular K+ loss.

Hallmarks of apoptosis include cell shrinkage, which is at least partially due to cellular K(+) loss. The decline of cellular K(+) concentration has been suggested to participate in the triggering of apoptosis. Suicidal erythrocyte death or eryptosis is triggered by increased cytosolic Ca(2+) activity leading to activation of Ca(2+)-sensitive K(+) channels with subsequent cellular K(+) loss and cell shrinkage, and to Ca(2+)-sensitive scambling of the cell membrane with subsequent phosphatidylserine (PS) exposure at the cell surface. Phosphatidylserine exposing erythrocytes are recognized by macrophages, engulfed, degraded and thus cleared from circulating blood. The present study explored whether cellular loss of K(+) and/or cell shrinkage actively participate in the triggering of cell membrane phospholipid scrambling. Cellular K(+) loss was achieved by treatment of human erythrocytes with the K(+) ionophore valinomycin (1 nM) at different extracellular K(+) concentrations (5-125 mM) and osmolarities (300-550 m Osm). Cell volume was estimated from forward scatter and PS exposure from annexin V binding in FACS analysis. Treatment with 1 nM valinomycin indeed decreased forward scatter and increased annexin V binding. The effect was significantly blunted in the presence of staurosporine (1 microM). Increase of extracellular K(+) concentration gradually blunted the decrease of forward scatter but inhibited annexin V binding only at extracellular K(+) concentrations >or=75 mM. An increase of extracellular osmolarity (+150 mM or 250 mM sucrose) reversed the protective effect of 75 mM KCl during valinomycin treatment. A correlation between forward scatter and annexin binding at different osmolarities and K(+) concentrations suggests that the cellular K(+) content determines the rate of suicidal erythrocyte death primarily through its influence on cell volume.     

Hypertonic cryohemolysis and the cytoskeletal system

Hypertonic cryohemolysis is defined as the lysis of erythrocytes in a hypertonic environment when the temperature is lowered from above 15–18°C to below that temperature. This has been found to be a general phenomenon (that is, whether the solute is charged or not), to exhibit interesting temperature characteristics and to be preventable by agents such as valimomycin which tend to dissipate the concentration gradient across the cell membrane. As yet, no clear information is available to translate this phenomenon to the molecular level and to relate it to current structure/function concepts in the erythrocyte membrane. In this study, data are presented which would indicate on the basis of two entirely separate methodologies that the spectrin-actin cytoskeletal framework is involved in this phenomenon. The first of these methodologies is based on radiation-induced ablation of cryohemolysis and indicates that an intact macromolecular complex of an order of 16 000 000 daltons is required for cryohemolysis with hypertonic NaCl. The second methodology is based on selective cross-linking of spectrin and actin in the agent diamide, which resulted in concentration-dependent suppression of cryohemolysis. Polyacrylamide gel electrophoresis of the erythrocyte from diamide-treated cells showed intense protein aggregation with loss of spectrin-actin and bands 4.1, 4.2. We conclude that the spectrin-actin cytoskeletal system possibly including its interaction with phospholipids is the key to the phenomenon of hypertonic cryohemolysis.     

The maximum and minimum water content and cell volume of human erythrocytes in vitro

The maximum and minimum water contents of human erythrocytes were measured after exposure to various osmotic pressures. Within a range of osmolarities, at which no haemolysis occurred, the water content reached its maximum, 78.1%, at 180 mosM and its minimum, 54.8%, at 800 mosM. Simultaneously, the mean cell volume increased to 98.5 microns 3 at 180 mosM and decreased to 77.2 microns 3 at 800 mosM.     

Effect of osmolarity on the zero-stress state and mechanical properties of aorta

Some pathological conditions may affect osmolarity, which can impact cell, tissue, and organ volume. The hypothesis of this study is that changes in osmolarity affect the zero-stress state and mechanical properties of the aorta. To test this hypothesis, a segment of mouse abdominal aorta was cannulated in vivo and mechanically distended by perfusion of physiological salt (NaCl) solutions with graded osmolarities from 145 to 562 mosM. The mechanical (circumferential stress, strain, and elastic modulus) and morphological (wall thickness and wall area) parameters in the loaded state were determined. To determine the osmolarity-induced changes of zero-stress state, the opening angle was observed by immersion of the sectors of mouse, rat, and pig thoracic aorta in NaCl solution with different osmolarities. Wall volume and tissue water content of the rings were also recorded at different osmolarities. Our results show that acute aortic swelling due to low osmolarity leads to an increase in wall thickness and area, a change in the stress-strain relationship, and an increase in the elastic modulus (stiffness) in mouse aorta. The opening angle, wall volume, and water content decreased significantly with increase in osmolarity. These findings suggest that acute aortic swelling and shrinking result in immediate mechanical changes in the aorta. Osmotic pressure-induced changes in the zero-stress state may serve to regulate mechanical homeostasis.     

The Erythrocyte Ghost Is a Perfect Osmometer

The osmotic swelling of intact erythrocytes in hypotonic solutions was measured using microhematocrit tubes, Van Allen tubes, and a calibrated Coulter counter. In agreement with earlier workers the intact cells did not behave as perfect osmometers, the cells swelling less than predicted by the Boyle-van't Hoff law. Erythrocyte ghosts were prepared from fresh intact erythrocytes by one-step hemolysis in 0.25% NaCl at an extremely dilute concentration of cells and the membranes were sealed at 37°. The ghosts were mixed with NaCl solutions of different osmolarities and the MCV (mean cell volume) of the shrunken cells immediately monitored by a calibrated Coulter counter. It was found that the MCV values of the shrunken ghosts were accurately predicted by the Boyle-van't Hoff law. These results indicate that these erythrocyte ghosts behaved as perfect osmometers.     

A reexamination of the role of clusterin as a complement regulator.

Clusterin is a highly conserved glycoprotein which has been proposed to protect host cells against complement-mediated cytolysis. We tested the hypothesis that clusterin is a complement regulator using erythrocytes and cells which had been stably transfected with a membrane-anchored form of clusterin as targets for complement-mediated cytolysis. Clusterin gave dose-dependent protection of antibody-coated sheep erythrocytes against complement-mediated lysis by diluted normal human serum. There was a linear relationship between the concentration of clusterin giving 50% protection and the concentration of serum; extrapolation of this to the case of undiluted human serum showed that a clusterin concentration at least two orders of magnitude greater than its physiological plasma concentration would be needed to confer protection against complement-mediated cytolysis under physiological conditions. Physiological concentrations of clusterin did not protect rabbit erythrocytes against alternative complement pathway-mediated lysis using dilute human serum. Exogenous clusterin had no effect on lysis of human erythrocytes triggered by the addition of inulin to autologous human serum. Induction of cell-surface clusterin expression by L929 (murine fibroblast) cells which had been stably transfected with cDNA for human clusterin linked to DNA coding for the 44 C-terminal amino acid residues of CD55 did not protect the cells against complement-mediated lysis by either normal or clusterin-depleted human serum. These data suggest that clusterin may not be a physiologically relevant regulator of complement activation.     

Adducin: Ca++-dependent association with sites of cell-cell contact

Adducin is a protein recently purified from erythrocytes and brain that has properties in in vitro assays suggesting a role in assembly of a spectrin-actin lattice. This report describes the localization of adducin to plasma membranes of a variety of tissues and the discovery that adducin is concentrated at sites of cell-cell contact in the epithelial tissues where it is expressed. Adducin in tissues and cultured cells always was observed in association with spectrin and actin, although spectrin and actin were evident in the absence of adducin. In sections of intestinal epithelial cells spectrin was present on all plasma membrane surfaces while adducin was restricted to the lateral cell borders. Adducin also was not detected in association with actin stress fibers in cultured cells. The presence of adducin at cell-cell contact sites of cultured epithelial cells requires extracellular Ca++ and occurs within 15 min of addition of 0.3 mM Ca++. Redistribution of adducin after addition of extracellular Ca++ is independent of formation of desmosomal and adherens junctions since assembly of adducin at contact sites requires lower concentrations of Ca++ and occurs more rapidly than redistribution of desmoplakin or vinculin. Treatment of keratinocytes and MDCK cells with nanomolar concentrations of 12-O-tetradecanoylphorbol-13-acetate (TPA) induces redistribution of adducin away from contact sites. The effect of TPA may be a direct consequence of phosphorylation of adducin, since adducin is phosphorylated in TPA-treated cells and the phosphorylation of adducin occurs before disassembly of adducin from sites of cell-cell contact. Spectrin and adducin are both present in a detergent-insoluble form at cell-cell contact sites of cultured cells. These observations are consistent with the idea that adducin recognizes and associates with specific "receptors" localized at regions of cell-cell contact and promotes assembly of spectrin into a more stable structure, perhaps analogous to the highly organized spectrin-actin network of erythrocyte membranes.     

A simulation study of the anomalous osmotic behavior of red cells

The factors responsible for movements of water across cell membranes were described mathematically and incorporated into a model which simulates water balance in the cell. Included in the model are a variable charge and osmotic coefficient of hemoglobin, a Na/K pump whose rate varies with ionic concentrations, and the standard electroneutrality and osmotic equilibrium assumptions. The model was used to investigate the phenomena whereby human red cells placed in media of varying tonicities exhibit steady state volume changes less than those predicted by van't Hoff's Law. The model results showed that this anomalous osmotic behavior was primarily due to changes in the osmotic coefficient of hemoglobin as its concentration in the cell varied. A second factor accounting for a part of this behavior was the alteration in the rate of the Na/K pump due to intracellular ionic concentration changes as cell volume varied. The effect of variable electrical charge on the hemoglobin molecule was found to be in the wrong direction to account for the observed osmotic behavior. Also, this effect was seen to produce relatively large changes in cell membrane potential, a result inconsistent with experimental data. It was concluded from the model results that the anomalous osmotic behavior of human red cells is primarily due to the variation in the osmotic coefficient of hemoglobin as the cell volume changes, and that the variable charge effect on the hemoglobin molecule, if it exists, does not play a role in this response.     

Brain adducin: a protein kinase C substrate that may mediate site-directed assembly at the spectrin-actin junction

Erythrocyte adducin is a membrane skeletal protein that binds to calmodulin, is a major substrate for protein kinase C, and associates preferentially with spectrin-actin complexes. Erythrocyte adducin also promotes association of spectrin with actin, and this activity is inhibited by calmodulin. This study describes the isolation and characterization of a brain peripheral membrane protein closely related to erythrocyte adducin. Brain and erythrocyte adducin have at least 50% antigenic sites in common, each contains a protease-resistant core of Mr = 48,000-48,500, and both proteins are comprised of two partially homologous polypeptides of Mr = 103,000 and 97,000 (erythrocytes) and Mr = 104,000 and 107,000-110,000 (brain). Brain and erythrocyte adducin associate preferentially with spectrin-actin complexes as compared to spectrin or actin alone, and both proteins also promote binding of spectrin to actin. Brain adducin binds calmodulin in a calcium-dependent manner, although the Kd of 1.3 microM is weaker by 5-6-fold than the Kd of erythrocyte adducin for calmodulin. Brain adducin is a substrate for protein kinase C in vitro and can accept up to 2 mol of phosphate/mol of protein. Adducin provides a potential mechanism in cells for mediating site-directed assembly of additional spectrin molecules and possibly other proteins at the spectrin-actin junction. Brain tissue contains 12 pmol of adducin/mg of membrane protein, which is the most of any tissue examined other than erythrocytes, which have 50 pmol/mg. The presence of high amounts of adducin in brain suggests some role for this protein in specialized activities of nerve cells.     

Red cell and ghost viscoelasticity. Effects of hemoglobin concentration and in vivo aging.

To assess the influence of intracellular hemoglobin concentration on red cell viscoelasticity and to better understand changes related to in vivo aging, membrane shear elastic moduli (mu) and time constants for cell shape recovery (tc) were measured for age-fractionated human erythrocytes and derived ghosts. Time constants were also measured for osmotically shrunk cell fractions. Young and old cells had equal mu, but tc was longer for older cells. When young cells were shrunk to equal the volume (and hence hemoglobin concentration and internal viscosity) of old cells, tc increased only slightly. Thus membrane viscosity (eta = mu . tc) increases during aging, regardless of increased internal viscosity. However, further shrinkage of young cells, or slight shrinkage of old cells, caused a sharp increase in tc. Because this increased tc is not explainable by elevated internal viscosity, eta increased, possibly due to a concentration-dependent hemoglobin-membrane interaction. Ghosts had a greater mu than intact cells, with proportionally faster tc; their membrane viscosity was therefore similar to intact cells. However, the ratio of old/young membrane viscosity was less for ghosts than for intact cells, indicating that differences between young and old cell eta may be partly explained by altered hemoglobin-membrane interaction during aging. It is postulated that these changes in viscoelastic behavior influence in vivo survival of senescent cells.     

A modification of the filtration method for studying the content of nonfilterable cells in erythrocyte suspension

The results of filtration assays provide estimates of the deformability of erythrocytes averaged over the entire suspension. These assays do not distinguish whether the entire population or only its small fraction exhibits abnormal rheological properties. We developed a simple method using a filtrometer to determine the percentage of non-filterable (under given conditions) cells in the erythrocyte suspension. Membrane filters made of a polyethylene terphthalate film had the mean pore diameter of 3.1 microns and the length of cylindrical micropores of 7 microns. The buffer flow rate tb depends on the number of free pores in a filter. The plot of the number of pores clogged by non-filterable cells versus the total number of erythrocytes passed through the filter had a linear portion whose slope represents the relative content Z of non-filterable cells in the suspension. We determined Z for various medium osmolarities u. These data were used to derive the distribution of erythrocytes in ucr, the value of u at which an erythrocyte cannot pass through a pore of a given filter because of geometric limitations. The distribution maximum corresponded to 190-200 mOsm/kg for erythrocytes from the normal blood. This means that normal erythrocytes have the median values of their surface area and area-to-volume ratio of 155-151 microns2 and 1.72-1.68 microns-1, respectively. The half-width of the distribution was approximately 30 mOsm/kg. This finding suggests that the normal blood contains a certain fraction of erythrocytes with a decreased area-to-volume ratio. Our results showed that the distribution is altered in various forms of anemia and in ATP-depleted erythrocyte suspensions.     

Osmotic properties of bovine erythrocytes aged in vivo

The osmotic properties of bovine erythrocytes aged in vivo were studied by the modified microhematocrit method. The osmotic fragility of older red cells decreases due to their larger relative osmotically non-active volume. Relative critical cell volume of bovine erythrocytes does not alter significantly with cell age. The age dependent change in the osmotic fragility of human red blood cells, the reverse of that found for bovine erythrocytes, is due to a different alteration of the critical cell volume during intravascular erythrocyte aging.     

Erythrocyte volume in man and various animals after the addition of glucose]

The optimal transmission of very diluted blood samples from 11 vertebrate species and man were measured. The red cells of 10 species reduced their volume when glucose or equi-osmotic amounts of sodium chloride were added. Only the erythrocytes of man and monkey (Japanese macaques) did not reduce their volume after addition of glucose or renormalized or overcompensated minor transitory changes. This increase of the volume of human red cells is, however, too low for noticeable viscosity changes of whole blood to be caused, if any. The different response of red cells to glucose makes a simple differentiation between animal and human blood samples possible, provided that primates other than man are excluded.     

Structural changes in the erythrocyte membrane of the trout Salmo irideus at seasonal acclimatization

Differences of thermostability were studied in red blood cells of the trout Salmo irideus differing in sex and age, as well as structural-dynamic characteristics of erythrocyte membrane proteins at seasonal acclimatization in the interval of reservoir water temperature of 0–19°C. An increase of resistance of erythrocytes to temperature lysis with elevation of the environmental temperature was revealed to be accompanied by a rise of the proteins segmental mobility and a decrease of intermolecular interactions in spectrin-actin cytoskeleton from the data of the ESR spin labeling method. Regulation of erythrocyte stability during acclimation was concluded to occur both changes of the fatty acids chain package at the variations of lipid composition and by changes of the cytoskeleton structural lability. Thereby this provides an increase of the bilayer firmness, on the one hand, while, on the other hand, a rise of elasticity and expansibility of the membrane on the whole, which increases resistance of cells to colloidal-osmotic hemolysis. Changes of concentration of oxygen dissolved in water, which are caused by temperature fluctuations, do not deem to be of crucial importance for structural stability of erythrocytes, as it can be compensated by another mechanism, specifically by changes of affinity of hemoglobin to oxygen.     

Regulation of sheep erythrocyte volume in anisotonic media.

Sheep erythrocytes of high and low potassium types were incubated in non-haemolytic hypotonic and hypertonic media for 4-5 h at 30 degrees. After initial swelling or shrinking, they readjusted their volume toward their initial isotonic volume. The volume regulation was associated with specific changes in cation fluxes. In the swollen cells, efflux of both sodium and potassium was increased and influx of both cations was slightly decreased; the converse was true for the shrunken cells. All four fluxes were changed in a direction that led to return to normal volume. The difference in the response of the two types of sheep erythrocytes to changes of extracellular fluid osmolality resided in the different activity of their cation transport systems. It is concluded that sheep erythrocytes possess some means of regulating their volume in vitro which is linked to cation permeability. The exact nature of the physical mechanisms by which they accomplish this remains to be elucidated.     

疟原虫入侵与红细胞内吞作用

用透射电镜观察红内期鼠疟原虫的入侵过程,发现红细胞在与裂殖子实际接触之前就发生很多种形状变化,主要有杯状和伪足两种类型。前者是红细胞与裂殖子相邻的一侧弯曲,形成与裂殖子表面相适应的凹陷;后者则是红细胞伸出突起或伪足逐渐接近裂殖子。附着之后,即逐渐扩展将其包围。在入侵中、后期,红细胞凹陷口周围呈波浪形突出,或者口部升高,凹陷壁逐渐变薄,有明显的前进趋势。这表明,红细胞在裂殖子诱导下,内吞活性增强了,有能力进行变形运动,包围裂殖子,从而以这种方式形成纳虫泡和使裂殖子进入其胞体内。