A new membrane concept for viscous RBC deformation in shear: spectrin oligomer complexes as a Bingham-fluid in shear and a dense periodic colloidal system in bending

Effect of tetracaine chlorhydrate on the mechanical properties of the erythrocyte membrane

Pharmacologically active agents that locate in the cell membrane are useful tools to investigate the interactions taking place between its molecular components. In the present work, the effect of tetracaine chlorhydrate (Tc) on the membrane mechanical properties of intact and desialated erythrocytes was studied. Our results evince the complex interaction between the drug and the membrane structures. The effect of Tc on erythrocyte shape suggests that this drug locates in the inner hemilayer of the lipid bilayer. Since Tc also modifies osmotic fragility and mechanical properties ascribed to the cytoskeleton, it can be inferred that the lipid bilayer has an effect on the rheology of the membrane, in a direct or indirect way, in this case through the close interaction with the structural proteins. Moreover, our results support the hypothesis of a second localization of the drug in the membrane, i.e., as monovalent cations intercalated among the glycocalix sialic endings, where it generates an effect superimposed on that produced from its typical site in the lipid bilayer.

Effects of an amphipathic drug on the rheological properties of the cell membrane

Sodium thiopental, as other amphiphilic molecules, interacts with the membrane by inserting into the lipid bilayer and causing alterations of the membrane properties such as curvature and hypotonic lysis resistance. But can it modify the mechanical properties of the membrane? In the present work it was observed that sodium thiopental affected the membrane rheological properties by improving erythrocyte deformability; this effect resulted from a reduction of both the elastic modulus and surface viscosity. In erythrocytes devoid of sialic acid after treatment with neuraminidase, sodium thiopental membrane concentration was significantly higher than in normal cells, suggesting that drug access to the lipid bilayer be facilitated by the absence of the steric and electrostatic barrier of the glycocalyx negative charges. From a rheological point of view, desialated and normal cells showed the same response to the anesthetic as regards elastic modulus but in opposite direction if surface viscosity was considered. This finding supports the hypothesis that sodium thiopental molecules enter the bilayer of desialated cells in a higher proportion, as compared to the normal erythrocyte, promoting a disorganization that results in a greater inner friction. The changes in the rheological parameters, triggered by sodium thiopental, could be attributed to the bilayer contribution to the membrane mechanical properties, either directly or through interaction between the bilayer and the cytoskeleton.

Red blood cell shape as a function of medium's ionic strength and pH

Glycocalyx, the characteristic first line of interaction between membrane and environment, can be visualized as a polyelectrolyte anchored to a bending-resistant matrix. This structure has an amazing resemblance with the ionized monolayers, in which, the cohesion among hydrocarbon chains is counteracted by the repulsion among similarly charged ionic heads, and thus the balance determines the curvature of the membrane. Likewise, it could be assumed that in biological membranes, repulsion among similarly charged groups in the glycocalyx could generate different curving trends. Hence, the factors directly influencing the electrostatic interaction among surface charged groups were studied, assessing the effect of the medium's ionic strength (mu) and pH, in an extensive range of values around the physiological one. The results point out mu variations inducing different shapes, depending on whether mu values were lower or higher than the physiological ones; which could be explained by the polyelectrolyte theory. The occurrence of more invaginated shapes as the medium's pH decreases, and the opposite event, when the pH increases, could be attributed to the coupling between the dissociation of the glycocalyx ionic groups and the H+ concentration. The behavior of the cells with reduced surface charges (by neuraminidase degradation) supports the hypothesis that the observed mu and the pH effect on erythrocyte shape could be mediated by glycocalyx charged groups.

The vicious cycle of nonhealing neointima in fabric vascular prostheses

Delayed neointimal healing of a fabric vascular prosthesis was investigated in an animal study focusing on the relationship between red thrombus, fibrinolysis, and endothelialization on the luminal surface. Fabric vascular prostheses were implanted into the descending aortas of 72 dogs. Fifty-nine grafts were explanted from 1 h to 1,705 days after implantation. One hour after implantation, the graft wall was red in color due to fresh thrombus; however, at 1 day the luminal surface became white. Red thrombus reappeared at 1 week and remained present in the long-term. Microscopically the initial red thrombus contained numerous erythrocytes. The white thrombus at 1 day was composed of a dense fibrin network without erythrocytes. At 2 days numerous lacunae appeared in the fibrin layer, and at 3-5 days cavernae and low density fibrin areas were present secondary to fibrinolysis. These areas allowed the blood components to infiltrate into the fibrin layer, and as a result red thrombus reformed within it. The thrombi on the luminal surface in the long-term was always red in color and composed of complicated, multiple stages of thrombus formation, i.e., fresh thrombus with erythrocytes, dense fibrin without erythrocytes, low fibrin density areas, lacunae and cavernae in the fibrin layer, and blood component infiltration into these spaces. Thrombus was always newly formed and present, and involuted in parallel due to fibrinolysis, suggesting that these phenomena perpetuated in a vicious cycle. However, at the anastomoses fibrinolysis was present, but blood component infiltration was prevented by the endothelial cell lining. These results suggest that endothelialization may arrest the vicious cycle of nonhealing neointima in fabric vascular prostheses.

Normal band 3-cytoskeletal interactions are maintained on tanktreading erythrocytes

Normal nonnucleated erythrocytes subjected to continuous hydrodynamic shear exhibit membrane deformation or "tanktreading," a process important for reduction of the bulk viscosity of circulating blood. To characterize the effect of this unique process on the erythrocyte membrane we have measured the lateral diffusion of band 3 during tanktreading. Band 3 is normally constrained through interactions with the spectrin-actin cytoskeleton, therefore, any significant disruption of these interactions would result in alterations in band 3 dynamics. Band 3 of human erythrocytes was labeled with dichlorotriazinyl amino fluorescein. After laser photobleaching of an equatorial stripe, fluorescence images were recorded from cells in the presence or absence of shear. The amplitude of induced nonuniformity in the surface distribution of fluorescence was calculated directly from images of unsheared cells. In shear the bleached line rotated with the tanktreading motion of the cells. The surface integral of fluorescence oscillated with this motion. For this case, the amplitude of photobleaching-induced nonuniformity was defined as the amplitude at the fundamental frequency of fast Fourier transforms in time of the oscillations. Shear stress-induced membrane flow did not interrupt the linkage of band 3 with the erythrocyte cytoskeleton. Diffusion coefficient and mobile fraction (1.5 +/- 0.5 x 10(-10) cm2/s and 54 +/- 11%, respectively) were unaffected by shear. The rate of fluorescence recovery of cells in shear was also similar at the centers and at the edges, where in-plane shear forces are maximal.

Influence of red cell surface charge on red cell membrane curvature

The wellknown biconcave shape of resting RBC reflects an intrinsic overall negative spontaneous membrane curvature. It depends to a high degree on the integrity of the spectrin-actin-ankyrin-Band-3 hetero-complex. Alterations of this complex have previously been shown to be associated with shape transitions, which have been abolished by treatment with enzymes reducing the surface charge of the RBC. In this report we show that treatment of erythrocytes with enzymes reducing the surface charge (e.g. neuraminidase, trypsin, chymotrypsin and pronase), consistently exerts a "stomatocytogenic" effect, i.e. it reduces mean mean curvature. Also the time dependency for the charge reduction and for the correlated decrease of mean mean curvature is shown. So-called stomatocytogenic agents (e.g. clorpromazine, tetracain and triton X100) and so-called echinocytogenic agents (e.g. dinitrophenol and Na-salicylate) are known to change membrane curvature in a dose dependent manner. It is further shown that by prior reduction of surface charge by various enzymes the dose response curves of all stomatocytogenic and echinocytogenic agents tested is shifted towards higher degrees of stomatocytosis or lesser degrees of echinocytosis. The data show, that in RBC pronounced curvature influences are produced by the surface charge located on the sialic acid residues in the glycocalix.

Spectrin, red cell shape and deformability. II. The antagonistic action of spectrin and sialic acid residues in determining membrane curvature in genetic spectrin deficiency in mice

In a companion paper, the shapes of spectrin deficient mouse erythrocytes were described; in contrast to previous assumptions, spherules with tethered microvesicles rather than true "spherocytes" were found. Thence, spectrin deficient mouse erythrocytes are endowed with an excess of surface area for the given volume but the membrane is assuming a highly positive curvature. Observations during and after the action of enzymes cleaving the red cell surface charge (Neuraminidase, Trypsin, Chymotrypsin) showed that the previously positive membrane curvature, as well as the tendency of the membrane to flow into fingerlike protrusions was completely abolished. The erythrocytes of the spectrin deficient, desialylated mouse erythrocytes assumed a variety of shapes, often discocytic or even stomatocytic, i.e. their membrane presented with negative curvature. However, while these desialylated membranes could be easily deformed (elongated) by shear flow they did not recoil elastically into any definitive configuration after removal of the deforming forces. It is concluded from these observations that spectrin (acting on the inner interface between membrane and cytoplasm) and sialic acid residues (acting on the outer interface between membrane and plasma) exert antagonizing effects on membrane curvature and membrane bending elasticity. Sialic acid residues, strongly charged and situated on the outer side of the cell, produce positive membrane curvature; this observation can most readily be explained by assuming that this mechanical effect is caused by repulsive coulombic forces expanding the outer half of the bilayer. To explain the effect of the spectrin-complex in counteracting positive or in producing negative membrane curvature, a similar expansive coulombic force acting between the highly charged residues has been postulated. Thence, a model for explaining the overall elastic behaviour of the normal mammalian red cell is developed which is based on the assumption of elastic interactions of proteinacous membrane components coupled to the lipid bilayer of the membrane.

Spectrin, red cell shape and deformability. I. Membrane curvature in genetic spectrin deficiency

Using novel microscopic techniques for observing individual cells in suspension, the shape and deformability of the erythrocytes of a spectrin-deficient strain of mouse were investigated in vitro (fresh and after fixation) and in vivo (intravital microscopy of the mesenteric capillaries). The animals were identical to those studied by Greenquist et al. [14]; however, in contrast to the descriptions by these authors, in the present study, spherical cells were seen only exceptionally. Instead, sphero-echinocytes, spherules with tethered microvesicles, myelin figures and occasional stomato-spherocytes were observed. This pleomorphy, also seen in scanning electron micrographs, can be explained by the fact that in the majority of these cells the membrane assumes an extremely positive outward curvature. After osmotic dehydration, all cells responded by developing progressive membrane protrusions with a positive curvature. Osmotic inflation led to reincorporation of the membrane tethers. After hypoosmolar lysis, the ghosts of the spectrum-deficient mouse cells also showed a pronounced tendency to assume shapes characterized by a progressively positive outward curvature. In vivo observation of the mouse erythrocytes using high magnification interference contrast optics confirmed this in vitro observation. Thus, it is concluded that spectrin deficiency does not primarily lead to spherocytosis: instead, the equilibrium shapes assumed are associated with membrane evaginations which are easily torn off from the main cell body by mechanical forces.

Correlation of the internal microviscosity of human erythrocytes to the cell volume and the viscosity of hemoglobin solutions

The microviscosity of the cytoplasm of human erythrocytes as well as of membrane-free hemoglobin solutions was investigated measuring the rotation of the small spin-label molecule, Tempone. The dependence of the intracellular microviscosity on the extracellular pH and osmotic pressure which was varied by NaCl or sucrose was sufficiently explained on the basis of alterations of the red blood cell volume. The intracellular microviscosity depended exclusively on the hemoglobin concentration. It did not differ from that of comparable membrane-free hemoglobin solutions. It was not necessary to take into account long-range interactions between hemoglobin molecules. The conclusion therefore was that the intracellular viscosity is not modified by cytoplasmic structures or the cell membrane. Above a hemoglobin concentration of 6 mM the viscosity of hemoglobin solutions increased much faster than the microviscosity. From measurements obtained with different spin-labels it followed that also the charge of these molecules is of importance.