Molecular basis for red cell membrane viscoelastic properties.

An unusual combination of membrane properties allows the red cell to undergo extensive deformation without cell fragmentation, enabling it to effectively perform its function of oxygen delivery during its long life span in the circulation. These material properties are the consequence of a composite structure in which a plasma membrane envelope made up of amphiphilic surfactant molecules is anchored to a network of skeletal proteins through tethering sites (transmembrane proteins) in the bilayer. Explosive growth in our understanding of the primary structure of the various red cell membrane proteins, definition of specific mutations in various red phenotypes, and detailed biophysical characterization of membrane properties of normal and mutant red cells has enabled development of models of molecular and structural basis for red cell properties.     

Marked changes in red cell membrane proteins in hereditary spherocytosis: a proteomics approach

Hereditary spherocytosis (HS) is the most common red cell membrane defect resulting from protein abnormalities. However, changes in red cell membrane proteins in HS remain under-investigated. We therefore evaluated red cell membrane proteome in non-splenectomized, mild-degree HS patients (n = 9) compared to healthy individuals (n = 5). Proteins derived from the red cell membranes of each subject were resolved in each two-dimensional gel and visualized by Deep Purple fluorescence staining. Spot matching and quantitative intensity analysis revealed 56 differentially expressed protein spots (41 increased and 15 decreased), which were then successfully identified by quadrupole time-of-flight mass spectrometry. Among these, seven isoforms/subunits of spectrin were markedly increased (up to 10.51 folds), whereas two isoforms/subunits of band-3 protein were decreased approximately 50% as compared to normal red cells. However, two isoforms/subunits of protein 4.1 were increased, while another isoform/subunit was decreased. All these significantly altered proteins were subjected to global protein network analysis using Ingenuity Pathways Analysis tool, which revealed three important networks related to HS, including Network I: Cell death, genetic and hematological disorders; Network II: Cell cycle, carbohydrate metabolism and molecular transport; and Network III: Genetic and hematological disorders, cell-to-cell signaling and interactions. These data offer many opportunities and new roadmaps for further functional studies to better understand the biology and pathogenic mechanisms of HS.     

Effect of magnesium ions on red cell membrane properties

Summary Spectrin forms aggregates in solution when incubated at relatively high concentrations (several millimolar) of divalent cations. According to the evidence of electron microscopy, aggregates of globular appearance and, rather uniform size are cooperatively formed from spectrin dimers, no intermediate structures being seen. Inter-dimer chemical cross-linking of spectrin in intact red cell membranes is enhanced if magnesium ions at a concentration of 0.5mm or more are present. On the other hand, the elimination of magnesium from the interior of intact cells causes no significant change in shear elastic modulus, measured by micropipette assays, nor is there any dependence of membrane filtration rate on intracellular free magnesium concentration in the range 0–1mm. Magnesium-depleted cells are, however, converted into echinocytes within a short period, in which, control cells, exposed to ionophore and external magnesium ions, remain completely discoid. Magnesium-depleted cells also undergo structural, changes on heating below the temperature at which vesiculation sets in. These reveal themselves by the transformation of the cells to a unique characteristic shape, by grossly reduced filtrability, and by extensive agglutination of the cells when treated with a bifunctional reagent. Magnesium ions thus regulate the stability, but not to any measurable extent the gross elasticity, of the red cell membrane.     

Advances in hereditary red cell enzyme anomalies

Conclusions From the above report we can observe that recent advances in hereditary disorders of red cell enzymes concern molecular mechanisms of the defect and relationship between molecular anomalies and pathologic consequences. Moreover, congenital nonspherocytic hemolytic anemias of undertermined cause are becoming fewer.It seems to us that the perspectives opened in this field could develop in two ways. Firstly, the current possibility of obtaining homogeneous mutant enzymes (for pyruvate kinase, glucose phosphate isomerase, glucose-6-phosphate dehydrogenase, phosphoglycerate kinase) should enable the study of the structure-function relationship, as was done for hemoglobin. Secondly, the recent progress in genetic analysis and genetic engineering could provide a direct approach of the nature of the genetic defect at the DNA level. This should be fundamental to understand the nature of some enzyme deficiencies without any detectable abnormal product of a mutant gene (e.g., glucose phosphate isomerase deficiencies with silent gene and M-type phosphofructokinase deficiency).     

Characterization of red cell membrane proteins as a function of red cell density: annexin VII in different forms of hereditary spherocytosis

Fresh human blood samples were collected from healthy controls and splenectomized and unsplenectomized patients with hereditary spherocytosis due to band 3 or ankyrin and spectrin deficiency. The erythrocytes were separated into age-related fractions using self-forming Percoll density gradients. Membrane proteins were analysed by 2D electrophoresis and identified by mass spectrometry. Annexin VII was present in reticulocytes but was then lost as the cells matured. A different pattern was found in band 3-deficient samples: annexin VII was in fact present in both mature and immature red cell membranes. Cytoskeletal anomalies may then influence the turn-over of annexin VII during erythrocyte maturation.     

Thermoelasticity of red blood cell membrane.

The elastic properties of the human red blood cell membrane have been measured as functions of temperature. The area compressibility modulus and the elastic shear modulus, which together characterize the surface elastic behavior of the membrane, have been measured over the temperature range of 2-50 degrees C with micropipette aspiration of flaccid and osmotically swollen red cells. In addition, the fractional increase in membrane surface area from 2-50 degrees C has been measured to give a value for the thermal area expansivity. The value of the elastic shear modulus at 25 degrees C was measured to be 6.6 X 10(-3) dyne/cm. The change in the elastic shear modulus with temperature was -6 X 10(-5) dyne/cm degrees C. Fractional forces were shown to be only on the order of 10-15%. The area compressibility modulus at 25 degrees C was measured to be 450 dyne/cm. The change in the area compressibility modulus with temperature was -6 dyne/cm degrees C. The thermal area expansivity for red cell membrane was measured to be 1.2 X 10(-3)/degrees C. With this data and thermoelastic relations the heat of expansion is determined to be 110-200 ergs/cm2; the heat of extension is 2 X 10(-2) ergs/cm2 for unit extension of the red cell membrane. The heat of expansion is of the order anticipated for a lipid bilayer idealized as twice the behavior of a monolayer at an oil-water interface. The observation that the heat of extension is positive demonstrates that the entropy of the material increases with extension, and that the dominant mechanism of elastic energy storage is energetic. Assuming that the red cell membrane shear rigidity is associated with "spectrin," unit extension of the membrane increases the configurational entropy of spectrin by 500 cal/mol.     

Thermal transitions of red blood cell deformability. Correlation with membrane rheological properties

Red blood cell deformability has been studied by the initial filtration flow rate as a function of temperature. The well-known transition at 49-50 degrees C (probably due to spectrin denaturation) is shown. Another transition is demonstrated around 18 degrees C (the cell becomes stiffer below this temperature range). The erythrocyte membranes prepared by a mild dialysis technique have the same deformability as intact erythrocytes at room temperature; they also show the same low-temperature transition. No such transition has been found for hemoglobin solutions of viscosity 30 g X dl-1. It is interesting to compare these results with those obtained by other methods which measure the properties of natural or artificial lipid membranes and which also demonstrate a thermal transition at 15-20 degrees C. Therefore, the deformability of intact normal erythrocytes seems to depend mainly on the rheological properties of the membrane.     

Effect of hydroperoxides on red blood cell membrane mechanical properties

We investigate the effect of oxidative stress on red blood cell membrane mechanical properties in vitro using detailed analysis of the membrane thermal fluctuation spectrum. Two different oxidants, the cytosol-soluble hydrogen peroxide and the membrane-soluble cumene hydroperoxide, are used, and their effects on the membrane bending elastic modulus, surface tension, strength of confinement due to the membrane skeleton, and 2D shear elastic modulus are measured. We find that both oxidants alter significantly the membrane elastic properties, but their effects differ qualitatively and quantitatively. While hydrogen peroxide mainly affects the elasticity of the membrane protein skeleton (increasing the membrane shear modulus), cumene hydroperoxide has an impact on both membrane skeleton and lipid bilayer mechanical properties, as can be seen from the increased values of the shear and bending elastic moduli. The biologically important implication of these results is that the effects of oxidative stress on the biophysical properties, and hence the physiological functions, of the cell membrane depend on the nature of the oxidative agent. Thermal fluctuation spectroscopy provides a means of characterizing these different effects, potentially in a clinical milieu.     

Haemoglobin and the red cell membrane.

The results presented here indicate that haemoglobin is an integral part of the red cell membrane. The haemoglobin content of the membrane is highly dependent on the Ca++ content of the membrane in health and disease. Changes in the red cell interior alter the whole organization of the membrane and are even reflected in the binding of immunoglobulins to the red cell surface. The preferential binding of Hb-s A2 and S to the membrane has been confirmed. This phenomenon cannot be explained by differences in the charge between these haemoglobins and Hb A.     

Constitutive relation for red cell membrane. Correction.

The intention of this note is to correct a subtle and somewhat esoteric error that the author discovered in his previous publications on membrane elastic behavior. The consitutive relation between membrane force resultants and large, elastic deformations of a membrane surface involves a strain tensor, characterizing the finite deformations. The original strain tensor that appeared in the equations was the Lagrangian strain tensor; however, the proper strain representation (also Lagrangian in nature because it is "measured" relative to the undeformed material state) is transformed by rotations of coordinates in the deformed material state (whereas the Lagrangian strain tensor is transformed by rotations of coordinates in the undeformed state). The principal membrane tensions are unchanged by this correction; the material elastic constants remain the same; and therefore, the material behavior in shear and isotropic tension is the same. However, the tensor, constitutive relation can be properly applied to coordinate systems other than the principal axis system.     

Apoptosis-inducing membrane vesicles. A novel agent with unique properties

The CD95 ligand (FasL) transmembrane protein is found on activated T cells and cells outside the immune system. A well-known turnover process of membrane FasL is mediated by matrix metalloproteinase, which generates soluble FasL (sFasL). Here, we demonstrate that membrane FasL turnover occurs effectively through the release of membrane vesicles. Quantitative analysis indicates that this process is as effective as sFasL release for FasL-3T3 cells but somewhat less effective for FasL-expressing T cells. The apoptosis-inducing membrane vesicles display unique properties not found in FasL-expressing cells and sFasL. Unlike sFasL, vesicle-associated FasL remained bioactive, killing the same panel of targets that are susceptible to FasL-expressing cells. In contrast to FasL-expressing T cells, FasL-mediated killing by vesicles do not involve LFA-1/ICAM interaction and do not depend on de novo protein synthesis. These observations indicate that the release of FasL-bearing vesicles contributes to the turnover of cell-associated FasL, but the impact of the bioactive FasL-expressing vesicles on the function of cell-associated FasL is different from that of sFasL.     

The red cell membrane and its cytoskeleton.

Gel-filtration (Sephadex G-75) analysis of hepatic cytosol reveals both qualitative and quantitative sex differences in oestrogen-binding proteins. The elution profile of [³H]oestradiol-labelled cytosol shows four species of oestrogen-binding proteins (peaks I, II, IV and V) common to both sexes. The amount of [³H]oestradiol binding in peak I is equivalent in both males and females and corresponds quantitatively to the specific oestrogen receptor. The amount of binding in the remaining three peaks is greater in males than females. In addition, an oestrogen-binding protein (peak III) is present that is unique to male cytosol. Proteinase-inhibition studies demonstrate that the observed multiplicity of oestrogen-binding proteins is not an artefact of proteolytic breakdown. Sex differences in oestrogen-binding proteins are absent in immature male and female animals; the oestrogen-binding protein profile in immature rats resembles that of an adult female. Gonadectomy of adult animals does not affect the oestrogen-binding-protein profile. In contrast, neonatal (day 1) castration results in partial feminization of the characteristic oestrogen-binding protein profile seen in the adult male; the appearance of Peak III is suppressed and marked decreases in the amount of oestradiol binding occurs in the remaining peaks. Hypophysectomy of adult animals results in near abolishment of the observed sex differences; the male oestrogen-binding protein profile is partially feminized and the female profile is partially masculinized, as characterized by the appearance of [³H]oestradiol binding in the region of peak III and increased amounts of binding in peaks IV and V. The present studies demonstrate a multiplicity of oestrogen-binding proteins in liver cytosol and raise the possibility that the presence of some of these proteins may be imprinted at birth through the hypothalamic–pituitary axis, by a mechanism requiring neonatal androgen exposure.     

Depletion of membrane skeleton in red blood cell vesicles.

A possible physical interpretation of the partial detachment of the membrane skeleton in the budding region of the cell membrane and consequent depletion of the membrane skeleton in red blood cell vesicles is given. The red blood cell membrane is considered to consist of the bilayer part and the membrane skeleton. The skeleton is, under normal conditions, bound to the bilayer over its whole area. It is shown that, when in such conditions it is in the expanded state, some cell shape changes can induce its partial detachment. The partial detachment of the skeleton from the bilayer is energetically favorable if the consequent decrease of the skeleton expansion energy is larger than the corresponding increase of the bilayer-skeleton binding energy. The effect of shape on the skeleton detachment is analyzed theoretically for a series of the pear class shapes, having decreasing neck diameter and ending with a parent-daughter pair of spheres. The partial detachment of the skeleton is promoted by narrowing of the cell neck, by increasing the lateral tension in the skeleton and its area expansivity modulus, and by diminishing the attraction forces between the skeleton and the bilayer. If the radius of the daughter vesicle is sufficiently small relative to the radius of the parent cell, the daughter vesicle can exist either completely underlaid with the skeleton or completely depleted of the skeleton.     

Copper-induced generation of superoxide in human red cell membrane.

The addition of CuSO₄ to erythrocyte membrane preparations causes the generation of superoxide radicals as measured by the superoxide dismutasesensitive oxidation of epinephrine. The formation of O₂^? is accompanied by the reduction of copper to the cuprous form. These events are inhibited by pCMB suggesting the involvement of membrane -SH groups in the reduction of copper, and a subsequent autoxidation of Cu⁺ to generate O₂^? and Cu⁺⁺. It is proposed that these mechanisms may be the basis for the cytotoxicity of copper in individuals exposed to copper either through a genetic deficiency of copper binding proteins or as a result of the acute ingestion of copper salts.     

Elastic area compressibility modulus of red cell membrane.

Micropipette measurements of isotropic tension vs. area expansion in pre-swollen single human red cells gave a value of 288 +/- 50 SD dyn/cm for the elastic, area compressibility modulus of the total membrane at 25 degrees C. This elastic constant, characterizing the resistance to area expansion or compression, is about 4 X 10(4) times greater than the elastic modulus for shear rigidity; therefore, in situations where deformation of the membrane does not require large isotropic tensions (e.g., in passage through normal capillaries), the membrane can be treated by a simple constitutive relation for a two-dimensionally, incompressible material (i.e. fixed area). The tension was found to be linear and reversible for the range of area changes observed (within the experimental system resolution of 10%). The maximum fractional area expansion required to produce lysis was uniformly distributed between 2 and 4% with 3% average and 0.7% SD. By heating the cells to 50 degrees C, it appears that the structural matrix (responsible for the shear rigidity and most of the strength in isotropic tension) is disrupted and primarily the lipid bilayer resists lysis. Therefore, the relative contributions of the structural matrix and lipid bilayer to the elastic, area compressibility could be estimated. The maximum isotropic tension at 25 degrees C is 10-12 dyn/cm and at 50 degrees C is between 3 and 4 dyn/cm. From this data, the respective compressibilities are estimated at 193 dyn/cm and 95 dyn/cm for structural network and bilayer. The latter value correlates well with data on in vitro, monolayer surface pressure versus area curves at oil-water interfaces.     

Viscoelastic properties of the human red blood cell membrane. II. Area and volume of individual red cells entering a micropipette.

Previous work demonstrated that human red cells can be drawn into cylindrical glass micropipettes of internal diameter approximately 2.0 mum without lysing. For pipettes of less than approximately 2.9 mum inside diameter, the red cell must become less spherical, that is, reduce its volume-to-area ratio. In this work measurements were made from 16-mm film records that allowed the determination of the cellular area and volume of individual erythrocytes as they were drawn into a 2.0-mum pipette with negative pressures. The results showed that the total surface area of the membrane remains constant and that the cell endures the passage into the pipette by losing volume. The volume loss was interpreted to be due to cell water and solute loss when the membrane is under stress. The loss of cell volume, rather than the stretching of the membrane, adds confirmation that although it is very deformable, the membrane is very resistant to two-dimensional strain.     

The structure of a model membrane in relation to the viscoelastic properties of the red cell membrane

The molecular arrangement within a lamellar structure composed of human erythrocyte lipids is determined. The 45 A thick lipid layer, in water, is filled in the interior with a liquid-like configuration of the hydrocarbon chains of phospholipid molecules and is covered on both sides by their hydrophilic polar groups. Cholesterol is located so that part of its steroid nucleus is between the polar groups of the phospholipid molecules while the rest of the molecule extends into the inner hydrocarbon layer. This lipid leaflet would be expected to have the mechanical properties of a purely liquid surface, as other authors have shown for the "black" lipid membranes. Data are presented which demonstrate that the intact erythrocyte membrane is a tough viscoelastic substance with a Young''s modulus of 10⁶–10⁸ dynes/cm² and a viscosity of 10⁷–10¹⁰ poises. The parameters and the kinetics of membrane breakdown are incompatible with the model system of pure lipid. Caution must be exercised in applying various data on the model systems to intact membranes.     

Membrane mobility agents: Alteration of human red blood cell membrane properties

Brief incubation of human red cells with the membrane mobility agent, 2-(2-methoxy)-ethoxyethyl 8-(2-n-octylcyclopropyl)-octanoate (A₂C), produces stomatocytes (with invaginations) along with a decrease in osmotic fragility, an altered distribution in a two-phase dextran-polyethylene glycol-water system, and increased permeability to the GSH oxidant, the diazene derivative, 1,2-diazenedicarboxylic acid bis(N′-methylpiperazide). These changes are consistent with what would be expected for agents which increase membrane lipid disorder. Membrane mobility agents provide a very convenient means for altering membrane properties and should be useful for studies on both normal and abnormal red cells.     

Model of red blood cell membrane skeleton: electrical and mechanical properties

A theoretical membrane skeleton model of erythrocyte has been developed and successfully applied to interpret electrical and mechanical properties of the red blood cell spectrin-actin network. The model is based on the structure of the membrane skeleton that is comprised of unit cells each containing an actin protofilament and shooting forth a few spectrin heterodimers. The loose ends of the heterodimers of adjacent cells can form bonds with each other giving rise to an integrated network. The number of bonds depends on the temperature. The bond length being excessive (2.6 times the distance between the centers of adjacent cells), the bonds are flexible, and can thus be regarded as entropy springs. The advanced model has been employed to calculate the shear modulus of the membrane skeleton as well as to establish its temperature dependence. In a wide range of temperatures mu(T) is a decreasing function well fitting the experimental data. The relationship between the membrane bilayer-free size of the skeleton and the ionic strength of the solution has been derived to appear in good agreement with the results obtained previously. Experimental data combined with the advanced theory yield the average number of heterodimers per unit cell, m0, as equal to ca. 5; the spectrin heterodimer charge has been estimated.