Temperature dependence of the sedimentation velocity of human erythrocytes]

The sedimentation velocity of yeast cells and human erythrocytes as a function of temperature was studied in a range from 6 degrees C to 40 degrees C. Whereas this function for yeast cells can be described by an exponential function the measurements with erythorcytes show minima at 10 degrees C and 20 degrees C, respectively, and maxima at 13 degrees C and 38 degrees C. Changes of the density or the shape of the cells cannot be the reason for these effects. Viscosity measurements on erythrocyte suspensions as a function of temperature also show deviations from the exponential function between 18 degrees C and 24 degrees C. The results explain that alterations of the membrane viscosity and phase transitions of the membrane lipids influence the sedimentation velocity of erythrocytes.     

Effect of transbilayer phospholipid distribution on erythrocyte fusion

Phospholipid packing has been suggested as a relevant variable in the control of membrane fusion events. To test this possibility in a model system, a comparison was made of the fusability of erythrocytes with a normal asymmetric transbilayer distribution of plasma membrane phospholipids (tightly packed exterior lipids) and erythrocytes with a symmetric transbilayer distribution of phospholipids (more loosely packed exterior lipids), using polyethylene glycol as fusogen. Not only were lipid-symmetric cells more readily fused, but fusions of mixtures of lipid-symmetric and lipid-asymmetric cells indicated that both fusing partners must have a symmetric distribution for fusion to be enhanced. Lipid-symmetric cells may fuse more readily because loose packing of the exterior lipids enhances hydrophobic interactions between cells. Alternatively, enhanced membrane fluidity may facilitate intramembranous particle clustering, previously implicated as a potentiator of fusion. Finally, exposure of phosphatidylserine on the surface of lipid-symmetric erythrocytes may be responsible for their enhanced fusion.     

Insertion of lipid domains into plasma membranes by fusion with erythrocytes

After prelabeling the plasma membrane with several lipid-specific fluorescent probes, erythrocytes with symmetric lipid bilayers were fused with culture cells using either poly(ethylene glycol) or Sendai virus as fusogen. Several nonspecific probes were transferred to, and became uniformly distributed within, the culture cell membrane upon fusion. In contrast, when merocyanine 540, which displays preferential binding to bilayers in which the lipids are loosely packed, was used to prelabel erythrocytes, fluorescence remained localized within a small confined area of the membrane, even 24 h after fusion. These results suggest that insertion of the lipids of the erythrocyte membrane into the plasma membrane of the culture cell can produce discrete domains which persist as such for long periods following fusion. Because the inserted proteins of the erythrocyte membrane similarly do not freely diffuse throughout the culture cell membrane, interactions between membrane proteins and lipids may be involved in this singular compartmentalization.     

Fatty acid composition of erythrocyte and vesicle total lipids during storage of human erythrocytes in protein-free media and in citrate-phosphate-dextrose

We have studied the fatty acid composition of total lipids of erythrocytes and vesicles either during storage of human erythrocytes in their own plasma under blood bank conditions or during incubation at 37 degrees C in protein-free media. Vesicles appear as a heterogeneous population with a diameter of about 130 nm and a varying content of hemoglobin. The fatty acid pattern of vesicle total lipids changes in respect to control erythrocytes, while in erythrocytes it remains fairly constant during the total ageing period. Our results indicate a marked rearrangement of the membrane components during blood storage.     

Divalent cations increase lipid order in erythrocytes and susceptibility to secretory phospholipase A2

Elevated concentrations of intracellular calcium in erythrocytes increase membrane order and susceptibility to secretory phospholipase A2. We hypothesize that calcium aids the formation of domains of ordered lipids within erythrocyte membranes by interacting directly with the inner leaflet of the cell membrane. The interface of these domains with regions of more fluid lipids may create an environment with weakened neighbor-neighbor interactions that would facilitate phospholipid migration into the active site of bound secretory phospholipase A2. This hypothesis was investigated by determining the effects of seven other divalent ions on erythrocyte membrane properties. Changes in membrane order were assessed with steady-state fluorescence spectroscopy and two-photon microscopy with an environment-sensitive probe, laurdan. Each ion increased apparent membrane order in model membranes and in erythrocytes when introduced with an ionophore, suggesting that direct binding to the inner face of the membrane accounts for the effects of calcium on membrane fluidity. Furthermore, the degree to which ions affected membrane properties correlated with the ionic radius and electronegativity of the ions. Lastly, erythrocytes became more susceptible to enzyme hydrolysis in the presence of elevated intracellular levels of nickel and manganese, but not magnesium. These differences appeared related to the ability of the ions to induce a transition in erythrocyte shape.     

Lytic agents, cell permeability, and monolayer penetrability

Cell lysis induced by lytic agents is the terminal phase of a series of events leading to membrane disorganization and breadkdown with the release of cellular macromolecules. Permeability changes following exposure to lytic systems may range from selective effects on ion fluxes to gross membrane damage and cell leakage. Lysis can be conceived as an interfacial phenomenon, and the action of surface-active agents on erythrocytes has provided a model in which to investigate relationships between hemolysis and chemical structure, ionic charge, surface tension lowering, and ability to penetrate monolayers of membrane lipid components. Evidence suggests that lysis follows the attainment of surface pressures exceeding a "critical collapse" level and could involve membrane cholesterol or phospholipid. Similarities of chemical composition of membranes from various cell types could account for lytic responses observed on interaction with surface-active agents. Cell membranes usually contain about 20–30 % lipid and 50–75 % protein. One or two major phospholipids are present in all cell membranes, but sterols are not detectable in bacterial membranes other than those of the Mycoplasma group. The rigid cell wall in bacteria has an important bearing on their response to treatment with lytic agents. Removal of the wall renders the protoplast membrane sensitive to rapid lysis with surfactants. Isolated membranes of erythrocytes and bacteria are rapidly dissociated by surface-active agents. Products of dissociation of bacterial membranes have uniform behavior in the ultracentrifuge (sedimentation coefficients 2–3S). Dissociation of membrane proteins from lipids and the isolation and characterization of these proteins will provide a basis for investigating the specificity of interaction of lytic agents with biomembranes.     

Evaluation of radiation damage to rat and dog erythrocyte membranes based on changes in their sedimentation properties

It was shown that injury to plasma membranes leads to a change in the sedimentation behaviour of erythrocytes: the maximum effect is produced when a protein component of the membrane is affected. The same dose-dependent character of the change in erythrocyte sedimentation in urografin is observed during the first 24 h after gamma-irradiation of rats and dogs.     

Bilirubin induces loss of membrane lipids and exposure of phosphatidylserine in human erythrocytes

Unconjugated bilirubin increasingly binds to erythrocytes as the bilirubin-to-albumin molar ratio exceeds unity, leading to toxic manifestations that can culminate in cell lysis. Our previous studies showed that bilirubin induces the release of lipids from erythrocyte membranes. In the present work, those studies were extended in order to characterize the alterations of membrane lipid composition and evaluate whether bilirubin leads to a loss of phospholipid asymmetry. To this end, human erythrocytes were incubated with several bilirubin-to-albumin molar ratios (0.5 to 5), and cholesterol as well as the total and the individual classes of phospholipids were determined. To detect erythrocytes with phosphatidylserine at the outer surface, the number of annexin V-positive cells was determined following incubation with bilirubin, fixing its molar ratio to albumin at 3. The results demonstrate profound changes in erythrocyte membrane composition, including modified cholesterol and phospholipid content. The release of membrane cholesterol, as well as of total and individual classes of phospholipids at molar ratios ≥1, indicates that damage of erythrocytes may occur in severely ill jaundiced neonates. The loss of the inner-located phospholipids, phosphatidylethanolamine and phosphatidylserine, points to a redistribution of phospholipids in the membrane bilayer. This was confirmed by the exposure of phosphatidylserine at the outer cell surface. In conclusion, this study demonstrates that bilirubin induces loss of membrane lipids and externalization of phosphatidylserine in human erythrocytes. These features may facilitate hemolysis and erythrophagocytosis, thus contributing to enhanced bilirubin production and anemia during severe neonatal hyperbilirubinemia. This revised version was published online in July 2006 with corrections to the Cover Date.     

Effect of cell shape, membrane deformability and phospholipid organization on phosphate-calcium-induced fusion of erythrocytes

Fusion of bovine and goat erythrocytes was studied using the phosphate-calcium protocol. Both bovine and goat red cells are resistant to fusion with phosphate and calcium, under conditions that promote fusion of normal human erythrocytes. Fusion resistance is not related to decreased (5%) membrane deformability of erythrocytes of these species, since chicken erythrocytes which are 40% less deformable than human erythrocytes undergo fusion with efficiency similar to human red blood cells. Incorporation of either phosphatidylcholine or phosphatidylserine into bovine erythrocytes mediated by lipid exchange/transfer protein, caused fusion of these erythrocytes. Fluorescence analysis of merocyanine 540 dye labeled erythrocytes, by flow cytometry, showed that the frequency of cells which exhibit dye binding was much less (35%) in dimyristoylphosphatidylcholine (DMPC) incorporated compared to untreated bovine erythrocytes (80%), indicating that incorporation of DMPC caused closed packing of lipids in the external leaflet of the bilayer. These studies show that fusion of bovine erythrocytes, mediated by phosphate and calcium, has a requirement for either specific phospholipids such as phosphatidylcholine, phosphatidylserine, or closed packing of lipids in the external leaflet of the bilayer.     

Gangliosides indirectly inhibit the binding of laminin to sulfatides

Laminin, a glycoprotein of basement membranes, agglutinates aldehyde-fixed erythrocytes. Laminin-mediated hemagglutination is strongly inhibited by some gangliosides and anionic phospholipids. Laminin, however, binds only to sulfatides among the lipids extracted from erythrocytes. We now report that gangliosides are remarkably potent inhibitors of laminin binding to sulfatides when both lipids are adsorbed on plastic. A 50% inhibition of laminin binding to 100 ng of sulfatides is obtained with 10 ng of GM3 and 8 ng of GM1, respectively. Mixing of sulfatides with neutral glycolipids, phosphatidyl choline, or cholesterol does not inhibit laminin binding, whereas mixing with sulfatide-depleted erythrocyte lipids enhances binding. Inhibition of binding by gangliosides is not due to competition for adsorption to the plastic, as preincubation of the adsorbed lipids with neuraminidase reverses inhibition by GM3, but not by GM1 which is not a substrate for the enzyme. These results are consistent with the observations that treatment of fixed erythrocytes with neuraminidase increases their agglutinability by laminin and that pretreatment of erythrocytes with gangliosides followed by washing gives similar inhibition as seen when gangliosides are present as competitive inhibitors. Thus, inhibition of laminin-mediated agglutination by gangliosides probably results from masking of erythrocyte sulfatides due to adsorption of gangliosides onto the membrane rather than from a direct competition for laminin binding sites.     

Hemorheological abnormalities in lipoprotein lipase deficient mice with severe hypertriglyceridemia

Severe hypertriglyceridemia (HTG) is a metabolic disturbance often seen in clinical practice. It is known to induce life-threatening acute pancreatitis, but its role in atherogenesis remains elusive. Hemorheological abnormality was thought to play an important role in pathogenesis of both pancreatitis and atherosclerosis. However, hemorheology in severe HTG was not well investigated. Recently, we established a severe HTG mouse model deficient in lipoprotein lipase (LPL) in which severe HTG was observed to cause a significant increase in plasma viscosity. Disturbances of erythrocytes were also documented, including decreased deformability, electrophoresis rate, and membrane fluidity, and increased osmotic fragility. Scanning electron microscopy demonstrated that most erythrocytes of LPL deficient mice deformed with protrusions, irregular appearances or indistinct concaves. Analysis of erythrocyte membrane lipids showed decreased cholesterol (Ch) and phospholipid (PL) contents but unaltered Ch/PL ratio. The changes of membrane lipids may be partially responsible for the hemorheological and morphologic abnormalities of erythrocytes. This study indicated that severe HTG could lead to significant impairment of hemorheology and this model may be useful in delineating the role of severe HTG in the pathogenesis of hyperlipidemic pancreatitis and atherosclerosis.     

Sedimentation velocity to characterize surfactants and solubilized membrane proteins

Analytical ultracentrifugation sedimentation velocity, which combines the separation of the macromolecules and the analysis of their transportation to reach a rigorous thermodynamics study offers a robust tool for characterizing the homogeneity and association state of membrane protein. Samples of solubilized membrane proteins are indeed complex multi-component systems where detergent micelles and protein-detergent complexes coexist in solution, with associated lipids in variable amounts. We present here the sedimentation velocity theoretical background, the principle of the data analysis and the interpretation relevant for the study of membrane proteins. The results section presents examples and refers to published work. High resolution particle distribution are obtained from measurements in absorbance and interference, which permits the characterization of protein-detergent complexes-in terms of association state and bound detergents/lipids, even in heterogeneous samples, and of surfactants. We emphasize the precaution to be taken before the analysis, and the limits of the analysis. We show how the sedimentation velocity performed in H(2)O and D(2)O solvents may help to acertain the association state of solubilized membrane proteins. We discuss the complementarity with sedimentation equilibrium, density measurement, and size exclusion chromatography combined if necessary with the use of radiolabelled detergent or light scattering detection.     

The influence of metmyoglobin and ferrylmyoglobin on the human erythrocyte membrane

Preliminary experiments revealed that ferrylmyoglobin decayed more slowly in the absence than in the presence of intact erythrocytes and erythrocyte membranes. This suggested the existence of interactions between FerrylMb and the erythrocyte membrane. Subsequent studies examined the influence of FerrylMb on the membrane of intact erythrocytes and on isolated erythrocyte membranes. The incubation of intact erythrocytes with FerrylMb did not influence their osmotic fragility or the fluidity of their membranes; the level of peroxidation of the membrane lipids increased only slightly (there was only a slight increase in the level of membrane lipid peroxidation). The activity of acetylcholinesterase significantly increased after 15 minutes of incubation, whereas longer incubation did not lead to any changes in the activity of this enzyme. The incubation of isolated erythrocyte membranes with FerrylMb resulted in an increase in their fluidity and a significant rise in the level of lipid peroxidation.     

Association of lipid peroxidation and polymerization of membrane proteins with erythrocyte aging

The addition of malondialdehyde to erythrocytes in vitro causes a decrease in bands 1 and 2 of spectrin and an increase in high molecular weight protein polymers. Additionally, this agent causes the formation of fluorscent chromolipids characteristic of those produced during the peroxidation of endogenous membrane phospholipids. These same alterations in proteins and lipids are observed in the membranes of older cells fractionated from freshly drawn blood and in the membranes of reticulocytes induced by treatment of animals with phenylhydrazine, but not in reticulocytes induced by bleeding. The former reticulocytes have a much shorter half-life in the circulation than do either normal erythrocytes or reticulocytes produced consequent to bleeding. These experiments and the apparent paradox of "young" reticulocytes with short half-lives suggest that the in vivo polymerization of membrane proteins consequent to radical-induced peroxidation of membrane lipids may contribute to the altered rheological behavior and hence to the splenic sequestration of cells. They also suggest that increases in intrinsic membrane rigidity due to lipid peroxidation, malondialdehyde, and protein polymerization may be a common feature of both aging in normal erythrocytes and in the accelerated aging that accompanies the administration of radical-generating, hemolytic agents. However, it is cautioned that other polymerization reactions involving disulfides, calcium, or direct radical attack on protein monomers may also be important determinants of the visco-elastic properties of erythrocyte membranes.     

Inhibition of Na,K-ATPase and sodium pump by anticancer ether lipids and protein kinase C inhibitors ET-18-OCH3 and BM 41.440

The anticancer ether lipid analogs ET-18-OCH3 and BM 41.440 inhibited Na, K-ATPase in the purified rat brain membrane fragments, with a potency comparable to that of their inhibition of protein kinase C. They also inhibited Na,K-ATPase in the crude membrane fraction of HL60 cells. Kinetic analysis indicated that the lipids had a mode of action different from that of ouabain, a classic inhibitor of the ATPase. The lipids also blocked 22Na uptake in the inside-out membrane vesicles of human erythrocytes. It is suggested that Na,K-ATPase might represent an additional site with which certain protein kinase C inhibitors can interact to alter cellular activities.     

The erythrocyte membrane site for the effect of temperature on osmotic fragility

The osmotic fragility of human erythrocytes is well known to decrease as the temperature is elevated. The cellular site for the temperature effect was studied by assessing possibles roles of hemoglobin and of membrane lipids and by taking advantage of the unique response of camel erythrocytes to temperature. It is concluded that the erythrocyte membrane is the site for the temperature effect on osmotic fragility. The human erythrocyte is likely to rupture in protein-lipid boundary regions in the membrane, from which cholesterol is apparently excluded.     

A special lipid mixture for membrane fluidization

The potency for membrane fluidization of mixtures containing neutral lipids (NL), phosphatidylcholine (PC) and phosphatidylethanolamine (PE) from hen egg yolk was tested on human erythrocytes and lymphocytes. A specific mixture consisting of 70% NL, 20% PC and 10% PE was found to be a potent membrane fluidizer operating almost exclusively by extracting membrane cholesterol. Spectral results and electron micrographs indicate that aqueous dispersion of this mixture consists of chylomicron-like assemblies where the neutral lipids provide the hydrophobic core on the surface of which phospholipids are spread as a monolayer.     

Phospholipid N-methylation in diabetic erythrocytes: effects on membrane Na+, K+ ATPase activity.

Phospholipid methylation was quantified in non-diabetic and streptozotocin diabetic rat erythrocytes. While the total mass of methylated lipids remained the same in both groups, the relative abundance of individual methylated lipid species differed significantly in diabetic erythrocytes. Moreover, incubation of erythrocytes membranes with S-adenosyl methionine, a substrate for methyl transferases, not only increased membrane lipid methylation but also decreased Na+, K+ ATPase activity significantly. These results suggest that phospholipid methylation may cause the observed depression of erythrocyte Na+, K+ ATPase activity in diabetes and could contribute to the altered rheology of erythrocytes in diabetes.     

Binding of anti-band 3 autoantibody to oxidatively damaged erythrocytes. Formation of senescent antigen on erythrocyte surface by an oxidative mechanism

Incubation of human erythrocytes oxidized by iron catalysts, ADP/Fe3+ or xanthine/xanthine oxidase/Fe3+, with autologous IgG resulted in IgG binding as detected by enzyme immunoassay using protein A-beta-galactosidase conjugate. The binding of autologous IgG to ADP/Fe3(+)-treated erythrocytes maximized when the cells were treated with 1.8:0.1 mM ADP/Fe3+, and declined when treated above this concentration, suggesting that autologous IgG binds to moderately but not to excessively oxidized erythrocytes. The antibody involved in the binding was anti-Band 3, the autoantibody known to bind to aged erythrocytes, because isolated anti-Band 3 bound to the oxidized cells, but anti-Band 3-depleted autologous IgG did not. In addition, purified Band 3 inhibited the autologous IgG binding. Anti-alpha-galactosyl IgG, another natural antibody which has been reported to bind to aged erythrocytes, did not bind to the oxidized cells. Oxidation of membrane lipids, SH-groups of membrane proteins, and Hb of these cells was slight, but the cells contained an increased amount of membrane-bound native Hb, indicating that the oxidized cell membrane has an altered property. alpha-Tocopherol prevented the lipid oxidation and the subsequent IgG binding. Reduction of the oxidized erythrocytes with dithiothreitol resulted in a loss of the IgG binding. These results suggest that anti-Band 3 binding sites (Band 3 senescent antigen) are formed on moderately oxidized erythrocytes as a result of oxidation of membrane protein SH-groups which can be mediated by the membrane lipid oxidation and that formation of the anti-Band 3 binding sites on the oxidized cells is an essentially reversible membrane event which is linked to oxidation and restoration of the protein SH-groups.     

Radiation-induced lipid peroxidation and the fluidity of erythrocyte membrane lipids

The effect of radiation-induced peroxidation on the fluidity of the phospholipids of the erythrocyte membrane was studied using both erythrocyte ghosts and liposomes formed from the polar lipids of erythrocytes. In liposomes, the oxidation of the phospholipids increased with radiation dose, but there was no change in the fluidity of the lipids as measured by spin-label motion. Under the same conditions of irradiation, no oxidation of phospholipid was detected in erythrocyte ghosts, although changes occurred in the motion of spin labels intercalated with the membrane. These changes were attributed to radiation-induced alterations in the membrane proteins. It is concluded that alterations in motion of spin labels, observed with intact membranes after irradiation, are most likely the result of changes in the structure of membrane proteins rather than the lipids.