Effect of cholesterol on the stability of human erythrocyte membranes to electric breakdown

Electrical stability of human erythrocyte membranes with different cholesterol content was studied. Breakdown in the cell membranes was generated by application of electric pulses with field strengths of 1.4-3.2 kV/cm. The share of perforated cells was registered by measuring hemolysis level. The red blood cells from patients with psoriasis and normal erythrocytes after incubation in the presence of liposomes were used as a model of cells with cholesterol-rich membranes. It was discovered that an increase of cholesterol content in the membranes moved the field-dependent curves to a higher field range. The obtained effect is attributed to the increase of the breakdown membrane potential. Application of high-pulse-electric-field technique for investigating the properties of cell membranes is discussed.     

Cholesterol sulfate. II. Studies on its metabolism and possible function in canine blood.

Previous in vitro studies to evaluate the possible role of cholesterol sulfate in the stabilization of the human erythrocyte membrane have been extended to the dog in vivo. Thus, following the injection of labelled cholesterol sulfate, a large fraction of the administered sterol conjugate is taken up by the membrane of the canine erythrocyte. Peak membrane levels were obtained within 30-60 min. Measurement of radioactivity associated with the plasma and red cell fractions in serial samples allowed the calculation of the half-life of cholesterol sulfate in each fraction. From the data obtained from the plasma of four dogs, the half-life was calculated to 5.8 plus or minus 0.9 h. The half-life of chlesterol sulfate associated with the erythrocyte membrane was calculated to be 6.7 plus or minus 1.2 h. In addition, following the intravenous administration of 0.2-0.7 mg of cholesterol sulfate/kg of body weight and withdrawal of serial blood samples, a significant diminution in the degree of hemolysis was observed when the red cells were exposed to hypotonic saline solutions. Maximal stabilization effects were observed at approx. 6-7 h after the administration of the sterol conjugate. Hemolytic properties returned to normal at approx. 24 h following the injection.     

Role of membrane thermotropic properties on hypotonic hemolysis and hypertonic cryohemolysis of human red blood cells

The hypothesis of a correlation between the effects of temperature on red blood cells hypotonic hemolysis and hypertonic cryohemolysis and two thermotropic structural transitions evidenced by EPR studies has been tested. Hypertonic cryohemolysis of red blood cells shows critical temperatures at 7 degrees C and 19 degrees C. In hypotonic solution, the osmotic resistance increases near 10 degrees C and levels off above 20 degrees C. EPR studies of red blood cell membrane of a 16-dinyloxyl stearic acid spin label show, in the 0-50 degrees C range, the presence of three thermotropic transitions at 8, 20, and 40 degrees C. Treatments of red blood cells with acidic or alkaline pH, glutaraldehyde, and chlorpromazine abolish hypertonic cryohemolysis and reduce the effect of temperature on hypotonic hemolysis. 16-Dinyloxyl stearic acid spectra of red blood cells treated with glutaraldehyde and chlorpromazine show the disappearance of the 8 degrees C transition. Both the 8 degrees C and the 20 degrees C transitions were abolished by acidic pH treatment. The correlation between the temperature dependence of red blood cell lysis and thermotropic breaks might be indicative of the presence of structural transitions producing areas of mismatching between differently ordered membrane components where the osmotic resistance is decreased.     

Interaction of ethanol with biological membranes

Ethanol is among the drugs with anesthetic potency determined by lipid solubility, in accord with the Meyer-Overton hypothesis. Thus, it is likely that ethanol acts in a hydrophobic environment. Using electron paramagnetic resonance with 5-doxylstearic acid as spin label, we find that ethanol disorders mouse cell membranes, making the lipid matrix more fluid. We surmise that consequent disruption of the function of integral membrane proteins may be the cause of ethanol's central actions. When mice are treated for 8 days with ethanol, their membranes become tolerant to the disordering effect of ethanol. This tolerance is accompanied by an increased proportion of cholesterol in the membranes.     

Chronic ethanol increases liver plasma membrane fluidity

Purified plasma membrane fractions of cultured well-differentiated Reuber H35 hepatoma cells were studied after growth in the presence or absence of ethanol. Growth of cells in the presence of ethanol significantly increased plasma membrane 5'-nucleotidase activity but did not influence sodium-potassium adenosinetriphosphatase activity. Fluorescence polarization of lipophilic probes was used to study membrane lipid structure. Steady-state polarization of diphenylhexatriene (DPH), a probe of the hydrophobic core, was significantly lower in plasma membranes from cells grown in 80 mM ethanol for 3 weeks, compared to controls. Decreased polarization of DPH in plasma membranes was observed after 3-weeks growth of cells in as little as 1 mM ethanol. A 1-h exposure to 80 mM ethanol had no effect. Altered DPH polarization was due to a decrease in the order parameter of the probe. The rotational correlation time of the probe was virtually unchanged. Chronic ethanol treatment of cells did not alter the polarization of the membrane surface probe trimethylammoniodiphenylhexatriene. Plasma membranes from cells grown in 80 mM ethanol had decreased contents of both phospholipid and unesterified cholesterol, but the cholesterol to phospholipid ratio was unchanged. The percentages of sphingomyelin and phosphatidylserine in plasma membrane phospholipids were significantly decreased after ethanol treatment, while the phosphatidylcholine/sphingomyelin ratio was increased by 42%. Vesicles prepared from total plasma membrane lipids of ethanol-treated cells, as well as vesicles prepared from polar lipids alone, showed the same alterations in DPH polarization as did plasma membranes. The importance of ethanol metabolism in the observed plasma membrane changes was demonstrated in two ways.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hypotonic hemolysis of human red blood cells: a two-phase process.

Previous use of hemolysis time measurement to determine permeability coefficients for the red blood cell membrane rested on the assumption that cells swelling in a hypotonic medium hemolyzed immediately on reaching critical volume. By preswelling red cells to various volumes prior to immersion in hemolytic solutions we extrapolate to the hemolysis time of red cells immersed at critical volume and thereby find a significant period of time during which the cells apparently remain in a spherical form prior to release of hemoglobin. Revised estimates of permeability coefficients follow from including this spherical (nonswelling) phase. In addition, the appreciation of a characteristic time period during which the membrane is under tension provides new opportunity to study physical and chemical properties of the membrane.     

The effect of lidocaine on lysophosphatidylcholine-induced cardiac arrhythmias and cellular disturbances

The production of arrhythmias in the isolated heart by perfusion with lysophosphatidylcholine has been well documented. However, the role of the lysophospholipid as a physiological factor in the generation of cardiac arrhythmias is not clear. In this study, a pharmacological approach was used to delineate the physiological significance of lysophosphatidylcholine during this cardiac dysfunction. Lidocaine (5-20 mg/L) was found to be effective in the protection of the isolated rat heart from the lysophospholipid-induced arrhythmias at pharmacological concentrations. The effect of lidocaine in the protection of lysophospholipid-induced membrane dysfunction was studied with red blood cells. Lidocaine (2 mg/mL) protected red blood cells from hemolysis in the presence of lysophosphatidylcholine. Lidocaine did not inhibit the binding of the lysophospholipid to the red cell membrane, but inhibited hemolysis in a manner similar to cholesterol. The results are consistent with the postulate that lysophosphatidylcholine is a physiological factor in the pathogenesis of cardiac arrhythmias during myocardial ischemia.     

Alterations in brain lipid composition of mice made physically dependent to ethanol

The ability of chronic ethanol treatment to alter CNS membrane lipids was tested. Adult male C57/BL6 mice were given a liquid diet containing ethanol for eight days. This regimen produced strong physical dependence as judged by withdrawal seizures, tremors and concomitant hypothermia. Analyses were performed on cholesterol, total phospholipid content and total phospholipid acyl composition of myelin, crude (P2), light and heavy synaptosomes as well as synaptosomal plasma membranes. Chronic ethanol treatment had no effect on total phospholipid levels nor phospholipid acyl composition in any of the above subcellular fractions. In ethanol dependent mice, significant increases in cholesterol content and cholesterol/ phospholipid ratios were observed only in synaptosomal plasma membranes.     

Effects of a series of alcohols on the binding of a fluorescent dye to erythrocyte membranes.

1. The effects of a series of aliphatic alcohols (methanol to octanol) on membrane proteins of erythrocytes were studied by monitoring the flueorescence of a dye (1-anilino-8-naphthalenesulfonic acid (ANS)) that adsorbs to erythrocyte ghost membranes. Low concentrations of all the alcohols reduced the ANS fluorescence of the membrane-ANS suspensions; lent to those which protect against hypotonic hemolysis on intact erythrocytes; higher concentrations markedly increased the fluorescence. Ethanol and methanol decreased ANS fluorescence at all concentrations. 2. Lytic concentrations of saponin did not increase ANS fluorescence and did not modify the membrane action of the alcohols. 3. None of these effects were observed in liposomes prepared from lipid extracts of the erythrocyte membrane. 4. Since the apparent dissociation constant for the ANS-membrane interaction was unchanged in the presence of the alcohols, it was assumed that the fluorescence changes anesthetic concentration of the alcohols alter the conformation of membrane proteins, as indicated by the decreased number of ANS binding sites.     

Biophysical correlates of lysophosphatidylcholine- and ethanol-mediated shape transformation and hemolysis of human erythrocytes. Membrane viscoelasticity and NMR measurement

The effects of monopalmitoylphosphatidylcholine (MPPC or lysophosphatidylcholine) and a series of short-chain primary alcohols (ethanol, 1-butanol and 1-hexanol) on cell shape, hemolysis, viscoelastic properties and membrane lipid packing of human red blood cells (RBCs) were studied. For MPPC, the effective membrane concentration to induce the formation of stage 3 echinocytes (8 x 10(6) molecules per cell) was one order of magnitude lower than that needed to induce 50% hemolysis (7 x 10(7) molecules per cell). In contrast, short-chain alcohols induced both shape changes and hemolysis within close concentration range (2.5 x 10(8) to 3.5 x 10(8) molecules per cell). Viscoelastic properties of the RBCs were studied by micropipette aspiration and correlated with shape change. Ethanol-treated RBCs showed a decrease in membrane elastic modulus and an increase in membrane viscosity in the recovery phase at the early stage of shape change. MPPC-treated cells showed the same type of viscoelastic changes, but these were not observed until the formation of stage 2 echinocytes. High-resolution solid-state 13C nuclear magnetic resonance technique was applied to study membrane lipid packing in the ghost membrane by following the chemical shift of hydrocarbon chains. Both MPPC and ethanol caused the 13C-NMR chemical shift to move upfield, indicating that membrane lipids were expanded due to the intercalation of these exogenous molecules. Using data obtained from model compounds, we convert values of chemical shift into a lipid packing parameter, i.e., number of gauche bonds for fatty acyl hydrocarbon chains. Approximately 10(8) interacting molecules per cell are required to induce a detectable change of lipid packing by both MPPC and ethanol. The results indicate that homolysis occurs at a smaller surface area for MPPC- than ethanol-treated RBCs. Our findings suggest that progressive changes in the molecular packing in the membrane lead eventually to hemolysis, but the mode responsible for shape transformation varies with these amphipaths.     

Properties of the leak permeability induced by a cytotoxic protein from Pseudomonas aeruginosa (PACT) in rat erythrocytes and black lipid membranes

A cytotoxic protein, isolated from Pseudomonas aeruginosa (PACT), was tested on red blood cells of rats and on black lipid membranes for changes of membrane permeability. In rat erythrocytes PACT induces lysis indicative of the formation of a leak permeable to monovalent ions. The dose response curve for the PACT-induced hemolysis demonstrates that the rate of lysis as well as the fraction of lytic cells increases with increasing toxin concentration. Furthermore, the leak pathway discriminates hydrophilic non-electrolytes according to their molecular weight. The findings indicate formation by PACT of a pore with an apparent radius of about 1.2 nm. In pure lipid membranes PACT forms hydrophilic pathways with moderate selectivity for small cations over small anions. The presence of cholesterol is a prerequisite for the occurrence of these PACT-induced permeability changes.     

The use of ELISA to monitor amplified hemolysis by the combined action of osmotic stress and radiation: potential applications

A new assay has been developed to study the osmotic fragility of red blood cells (RBCs) and the involvement of oxygen-derived free radicals and other oxidant species in causing human red blood cell hemolysis. The amount of hemoglobin released into the supernatant, which is a measure of human red blood cell hemolysis, is monitored using an ELISA reader. This ELISA-based osmotic fragility test compared well with the established osmotic fragility test, with the added advantage of significantly reduced time and the requirement of only 60 mul of blood. This small amount of blood was collected fresh by finger puncture and was immediately diluted 50 times with PBS, thus eliminating the use of anticoagulants and the subsequent washings. Since exposure of RBCs to 400 Gy gamma radiation caused less than 5% hemolysis 24 h after irradiation, the RBC hemolysis induced by gamma radiation was amplified by irradiating the cell in hypotonic saline. The method was validated by examining the protective effect of Trolox, an analog of vitamin E and reduced glutathione (GSH), a well-known radioprotector, against human RBC hemolysis caused by the combined action of radiation and osmotic stress. Trolox, a known membrane stabilizer and an antioxidant, and GSH offered significant protection. This new method, which is simple and requires significantly less time and fewer RBCs, may offer the ability to study the effects of antioxidants and membrane stabilizers on human red blood cell hemolysis induced by radiation and oxidative stress and assess the osmotic fragility of erythrocytes.     

Differential response of chick liver and brain membranes to short ethanol treatment

The effect of 60 hr ethanol ingestion on lipid composition of liver and brain membranes from 2-day-old chicks was investigated. Analysis of hepatic membrane cholesterol shows that ethanol induced a slight increase in microsomes exclusively due to free cholesterol while mitochondria was not affected. In brain, both fractions showed a clear increase in their cholesterol content, while a high decrease was observed in myelin. Free cholesterol was also the main responsible for the changes found in brain. The ethanol-treated animals showed an alteration in their phospholipid composition exclusively in brain microsomes and myelin. Despite all these changes, the values of cholesterol/phospholipid molar ratio in both liver and brain membranes remained unaltered after short ethanol treatment. Our results indicate that neonatal chick brain membranes appears to be especially sensitive to the presence of ethanol.     

Hypotonic hemolysis of human red blood cells: a two-phase process

Summary Previous use of hemolysis time measurement to determine permeability coefficients for the red blood cell membrane rested on the assumption that cells swelling in a hypotonic medium hemolyzed immediately on reaching critical volume. By preswelling red cells to various volumes prior to immersion in hemolytic solutions we extrapolate to the hemolysis time of red cells immersed at critical volume and thereby find a significant period of time during which the cells apparently remain in a spherical form prior to release of hemoglobin. Revised estimates of permeability coefficients follow from including this spherical (nonswelling) phase. In addition, the appreciation of a characteristic time period during which the membrane is under tension provides new opportunity to study physical and chemical properties of the membrane.Presented in part at the 1974 joint meeting of the Biophysical Society and the American Society of Biological Chemists.     

Interaction of benzocaine with model membranes

We measured the absorption properties, water solubility and partition coefficients (P) between n-octanol, egg phosphatidylcholine (EPC) liposomes and erythrocyte ghosts/water for benzocaine (BZC), an ester-type always uncharged local anesthetic. The interaction of BZC with EPC liposomes was followed using Electron Paramagnetic Resonance, with spin labels at different positions in the acyl chain (5, 7, 12, 16-doxylstearic acid methyl ester). Changes in lipid organization upon BZC addition allowed the determination of P values, without phase separation. The effect of BZC in decreasing membrane organization (maximum of 11.6% at approx. 0.8:1 BZC:EPC) was compared to those caused by the local anesthetics tetracaine and lidocaine. Hemolytic tests revealed a biphasic (protective/inductive) concentration-dependent hemolytic effect for BZC upon rat erythrocytes, with an effective BZC:lipid molar ratio in the membrane for protection (RePROT), onset of hemolysis (ReSAT) and 100% membrane solubilization (ReSOL) of 1.0:1, 1.1:1 and 1.3:1, respectively. The results presented here reinforce the importance of considering hydrophobic interactions in the interpretation of the effects of anesthetics on membranes.     

Properties of the leak permeability induced by a cytotoxic protein from Pseudomonas aeruginosa (PACT) in rat erythrocytes and black lipid membranes

A cytotoxic protein, isolated from Pseudomonas aeruginosa (PACT), was tested on red blood cells of rats and on black lipid membranes for changes of membrane permeability. In rat erythrocytes PACT induces lysis indicative of the formation of a leak permeable to monovalent ions. The dose response curve for the PACT-induced hemolysis demonstrates that the rate of lysis as well as the fraction of lytic cells increases with increasing toxin concentration. Furthermore, the leak pathway discriminates hydrophilic non-electrolytes according to their molecular weight. The findings indicate formation by PACT of a pore with an apparent radius of about 1.2 nm. In pure lipid membranes PACT forms hydrophilic pathways with moderate selectivity for small cations over small anions. The presence of cholesterol is a prerequisite for the occurrence of these PACT-induced permeability changes.     

Neurochemical and behavioural effects of extended exposure to isopropanol vapour with simultaneous ethanol intake

Exposure of male Wistar rats to 12.3 mumol/l (300 ppm) isopropanol vapour for 5-21 weeks, 5 days a week for 6 h daily with a simultaneous ethanol administration in drinking water (5% v/v) caused a significant increase in isopropanol removal as assessed by blood isopropanol and acetone determinations. Ethanol treatment caused a marked synergistic effect during early exposure. Neurochemical studies revealed decreased superoxide dismutase and azoreductase activities at the end of the exposure whereas increased protein degradation was found in glial cells isolated from ethanol-fed rats throughout the experiment. Analyses of spinal cord axon lipid composition showed increases in cholesterol content in relation to lipid phosphorus in animals exposed to isopropanol or to the isopropanol and ethanol combination. Behavioural tests indicated minor effects on emotional reactivity from the 10th week onwards with isopropanol exposure whereas caffeine-stimulated activity was augmented only in rats ingesting ethanol. Co-exposure to isopropanol vapour abolished the increased excitability. The data indicate that marked metabolic and functional adaptation towards the small-molecular-weight alcohols takes place at moderate dose levels.     

Suppression of an ethanol withdrawal syndrome in rats by 3-hydroxybutyrate

An ethanol withdrawal syndrome was elicited by withholding ethanol from physically dependent, male Sprague-Dawley rats. Ethanol dependence had been induced by intragastric administration of ethanol at a dosage of 9 to 15 grams per kilogram per day over a four-day period. Oral administration of 3-hydroxybutyrate, a compound which is elevated in blood of ethanol dependent rats and is a substrate of both the cerebral small-pool and large-pool Krebs-cycle, was effective in suppressing the tremulous component of the ethanol withdrawal syndrome. 3-Hydroxybutyrate did not function as a central nervous system depressant at the dose levels employed.     

Cholesterol sulfate inhibits the fusion of Sendai virus to biological and model membranes

Cholesterol sulfate is a component of several biological membranes. In erythrocytes, cholesterol sulfate inhibits hypotonic hemolysis, while in sperm, it can decrease fertilization efficiency. We have found cholesterol sulfate to be a potent inhibitor of Sendai virus fusion to both human erythrocyte and liposomal membranes. Cholesterol sulfate also raises the bilayer to hexagonal phase transition temperature of dielaidoyl phosphatidylethanolamine as demonstrated by differential scanning calorimetry and 31P nuclear magnetic resonance spectrometry. Although hexagonal phase structures are not readily found in biological membranes, there is a correlation between the effects of membrane additives on bilayer/non-bilayer equilibria and membrane stabilization. It is proposed that the ability of cholesterol sulfate to alter the physical properties of membranes contributes to its stabilization of biological membranes and the inhibition of membrane fusion.     

Phospholipase C activation by ethanol in rat hepatocytes is unaffected by chronic ethanol feeding.

The activation of phosphoinositide-specific phospholipase C by ethanol was compared in hepatocytes isolated from ethanol-fed rats and from pair-fed control animals. Ethanol (100-300 mM) caused a dose-dependent transient increase in cytosolic free Ca2+ levels in indo-1-loaded hepatocytes from both groups of animals. The rate of Ca2+ increase was similar in hepatocytes from control and ethanol-fed rats, but the decay of the Ca2+ increase was somewhat slower in the latter preparation. The ethanol-induced Ca2+ increase caused activation of glycogen phosphorylase, with 50% response at 50 mM-ethanol and a maximal response at 150-200 mM-ethanol, not significantly different in hepatocytes from control and ethanol-fed animals. Ins(1,4,5)P3 formation in response to ethanol (300 mM) or vasopressin (2 nM or 40 nM) was also similar in the two preparations. It is concluded that long-term ethanol feeding does not lead to an adaptive response with respect to the ethanol-induced phospholipase C activation in rat hepatocytes. The ability of ethanol in vitro to decrease membrane molecular order in liver plasma membranes from ethanol-fed and control rats was measured by e.s.r. Membranes from ethanol-fed animals had a significantly lower baseline order parameter compared with control preparations (0.313 and 0.327 respectively), indicative of decreased membrane molecular order. Addition of 100 mM-ethanol significantly decreased the order parameter in control preparations by 2.1%, but had no effect on the order parameter of plasma membranes from ethanol-fed rats, indicating that the plasma membranes had developed tolerance to ethanol, similar to other membranes in the liver. Thus the membrane structural changes associated with this membrane tolerance do not modify the ethanol-induced activation of phospholipase C. The transient activation of phospholipase C by ethanol in hepatocytes may play a role in maintaining an adaptive phenotype in rat liver.