The Effect of Fatal Carbon Monoxide Poisoning on the Surface Charge of Blood Cells

The objective of this investigation was to evaluate postmortem changes of electric charge of human erythrocytes and thrombocytes after fatal carbon monoxide (CO) poisoning. The surface charge density values were determined on the basis of the electrophoretic mobility measurements of the cells carried out at various pH values of electrolyte solution. The surface charge of erythrocyte membranes after fatal CO poisoning as well as after sudden unexpected death increased compared to the control group in the whole range of experimental pH values. Also, a slight shift of the isoelectric point of erythrocyte membranes to high pH values was observed. The surface charge of thrombocyte membranes after fatal CO poisoning decreased at low pH compared to the control group. However, at high pH, the values increased compared to the control group. The isoelectric point of thrombocyte membranes after fatal CO poisoning was considerably shifted toward low pH values compared to the control group. The observed changes are probably connected with the destruction of blood cell structure.     

The Effect of Contrast Medium SonoVue<Superscript>®</Superscript> on the Electric Charge Density of Blood Cells

The effect of contrast medium SonoVue® on the electric charge density of blood cells (erythrocytes and thrombocytes) was measured using a microelectrophoretic method. We examined the effect of adsorbed H⁺ and OH^? ions on the surface charge of erythrocytes or thrombocytes. Surface charge density values were determined from electrophoretic mobility measurements of blood cells performed at various pH levels. The interaction between solution ions and the erythrocyte’s or thrombocyte’s surface was described by a four-component equilibrium model. The agreement between the experimental and theoretical charge variation curves of the erythrocytes and thrombocytes was good at pH 2–9. The deviation observed at a higher pH may be caused by disregarding interactions between the functional groups of blood cells.     

Ion concentration and charge adjacent to electrically charged cell membrane

Equations describing ion concentration profiles and electric charge in electrolyte solutions adjacent to an electrically charged cell membrane model in the electrochemical equilibrium state are developed and completely solved. The membrane system model consists of an infinitely large planar sheet of finite thickness separating two electrolyte solutions. Electric charges in the membrane model consist of planes of charge parallel to the surfaces of the planar sheet. The charge in solution adjacent to each surface of the membrane is due to differences in the total anion and cation concentrations in each solution.Expressions of concentration and charge are functions of the quantity and location of charge in the membrane, the various permittivities and thickness of the membrane, and the ionic compositions, permittivities, and temperature of the electrolyte solutions.The validity and relation of the model to real membranes are discussed.     

Effect of A, E, C, P vitamin complex on erythrocyte hemocoagulation properties and platelet aggregation in thrombinemia]

The protective effect of A, E, C, P vitamin complex has been experimentally proven to display in a decrease of animal death rate and in limiting the intensity of hemocoagulation shifts in thrombinemia. This effect is stipulated by a decrease in thrombocyte aggregation and in coagulation activity and by the increase of erythrocyte deformation properties. These changes seem to be caused by the effect of vitamins on the phospholipid spectrum, electrolyte transport of ATPases and erythrocyte membrane stability.     

Quantitative membrane electrostatics with the atomic force microscope

The atomic force microscope (AFM) is sensitive to electric double layer interactions in electrolyte solutions, but provides only a qualitative view of interfacial electrostatics. We have fully characterized silicon nitride probe tips and other experimental parameters to allow a quantitative electrostatic analysis by AFM, and we have tested the validity of a simple analytical force expression through numerical simulations. As a test sample, we have measured the effective surface charge density of supported zwitterionic dioleoylphosphatidylcholine membranes with a variable fraction of anionic dioleoylphosphatidylserine. The resulting surface charge density and surface potential values are in quantitative agreement with those predicted by the Gouy-Chapman-Stern model of membrane charge regulation, but only when the numerical analysis is employed. In addition, we demonstrate that the AFM can detect double layer forces at a separation of several screening lengths, and that the probe only perturbs the membrane surface potential by <2%. Finally, we demonstrate 50-nm resolution electrostatic mapping on heterogeneous model membranes with the AFM. This novel combination of capabilities demonstrates that the AFM is a unique and powerful probe of membrane electrostatics.     

Modeling the Electric Potential across Neuronal Membranes: The Effect of Fixed Charges on Spinal Ganglion Neurons and Neuroblastoma Cells

We present a model for the electric potential profile across the membranes of neuronal cells. We considered the resting and action potential states, and analyzed the influence of fixed charges of the membrane on its electric potential, based on experimental values of membrane properties of the spinal ganglion neuron and the neuroblastoma cell. The spinal ganglion neuron represents a healthy neuron, and the neuroblastoma cell, which is tumorous, represents a pathological neuron. We numerically solved the non-linear Poisson-Boltzmann equation for the regions of the membrane model we have adopted, by considering the densities of charges dissolved in an electrolytic solution and fixed on both glycocalyx and cytoplasmic proteins. Our model predicts that there is a difference in the behavior of the electric potential profiles of the two types of cells, in response to changes in charge concentrations in the membrane. Our results also describe an insensitivity of the neuroblastoma cell membrane, as observed in some biological experiments. This electrical property may be responsible for the low pharmacological response of the neuroblastoma to certain chemotherapeutic treatments.     

Electrostatic free energy and shift of the phase transition for charged lipid membranes

For a charged membrane in an electrolyte solution the electrostatic free energy is derived treating the system as a diffuse double layer. The dependence of the free energy on external parameters like surface charge density and temperature is obtained and the physical basis discussed. As an application the charges are shown to exert an electrostatic surface pressure on the lipid chain packing which leads to a shift in the phase transition of lipid membranes. The results confirm the interpretation of experimental data as given by Träuble et al. in the accompanying paper.     

Decreased fluidity of isolated erythrocyte membranes in type 1 and type 2 diabetes. The effect of resorcylidene aminoguanidine.

Changes in the physico-chemical properties of erythrocyte membranes induced by nonenzymatic glycation as well as the possible prevention of their rise were studied. Using the fluorescent probe 1,6-diphenyl-1,3,5-hexatriene (DPH), fluorescence anisotropy values were determined in erythrocyte membranes isolated from type 1 and type 2 diabetic patients with and without complications. The mean anisotropy values for the groups of diabetic patients were significantly higher than those for the control group (p < 0.01). This indicated pathologically decreased fluidity in cell membranes in the diabetics regardless of the type of diabetes or the presence of complications. The fluorescence anisotropy positively correlated (p < 0.01) with clinical parameters, such as glycohaemoglobin and plasma cholesterol content, which are important for the monitoring of the compensation status of the diabetic patient. Our results support the suggestion that protein crosslinking and oxidative stress induced by nonenzymatic glycation contribute to changes in the physico-chemical properties of erythrocyte membranes. In vitro testing of a new potential drug resorcylidene aminoguanidine (RAG) showed its ability to increase significantly (p < 0.001), to various extent (p < 0.01), the fluidity of both diabetic and control erythrocyte membranes. Upon the administration of RAG, reduced fluorescence anisotropy values for the groups of diabetic patients approached the normal values obtained for the controls. This may play an important role in the improvement of impaired cell functions found in diabetes that are controlled by the cell membrane.     

Molecular mechanism of action of chlorogenic acid on erythrocyte and lipid membranes

Abstract

The high antioxidant capacity of chlorogenic acid (CGA) in respect to biological systems is commonly known, though the molecular mechanism underlying that activity is not known. The aim of the study was to determine that mechanism at the molecular and cell level, in particular with regard to the erythrocyte and the lipid phase of its membrane. The effect of CGA on erythrocytes and lipid membranes was studied using microscopic, spectrophotometric and electric methods. The biological activity of the acid was determined on the basis of changes in the physical parameters of the membrane, in particular its osmotic resistance and shapes of erythrocytes, polar head packing order and fluidity of erythrocyte membrane as well as capacity and resistivity of black lipid membrane (BLM). The study showed that CGA becomes localized mainly in the outer part of membrane, does not induce hemolysis or change the osmotic resistance of erythrocytes, and induces formation of echinocytes. The values of generalized polarization and fluorescence anisotropy indicate that CGA alters the hydrophilic region of the membrane, practically without changing the fluidity in the hydrophobic region. The assay of electric parameters showed that CGA causes decreased capacity and resistivity of black lipid membranes. The overall result is that CGA takes position mainly in the hydrophilic region of the membrane, modifying its properties. Such localization allows the acid to reduce free radicals in the immediate vicinity of the cell and hinders their diffusion into the membrane interior.     

Biophysical Mechanism of the Protective Effect of Blue Honeysuckle (Lonicera caerulea L. var. kamtschatica Sevast.) Polyphenols Extracts Against Lipid Peroxidation of Erythrocyte and Lipid Membranes

The aim of the present research was to determine the effect of blue honeysuckle fruit and leaf extracts components on the physical properties of erythrocyte and lipid membranes and assess their antioxidant properties. The HPLC analysis showed that the extracts are rich in polyphenol anthocyanins in fruits and flavonoids in leaves. The results indicate that both extracts have antioxidant activity and protect the red blood cell membrane against oxidation induced by UVC irradiation and AAPH. The extracts do not induce hemolysis and slightly increase osmotic resistance of erythrocytes. The research showed that extracts components are incorporated mainly in the external part of the erythrocyte membrane, inducing the formation of echinocytes. The values of generalized polarization and fluorescence anisotropy indicate that the extracts polyphenols alter the packing arrangement of the hydrophilic part of the erythrocyte and lipid membranes, without changing the fluidity of the hydrophobic part. The DSC results also show that the extract components do not change the main phase transition temperature of DPPC membrane. Studies of electric parameters of membranes modified by the extracts showed that they slightly stabilize lipid membranes and do not reduce their specific resistance or capacity. Examination of IR spectra indicates small changes in the degree of hydration in the hydrophilic region of liposomes under the action of the extracts. The location of polyphenolic compounds in the hydrophilic part of the membrane seems to constitute a protective shield of the cell against other substances, the reactive forms of oxygen in particular.     

Resolution of the paradox of red cell shape changes in low and high pH

The molecular basis of cell shape regulation in acidic pH was investigated in human erythrocytes. Intact erythrocytes maintain normal shape in the cell pH range 6.3-7.9, but invaginate at lower pH values. However, consistent with predicted pH-dependent changes in the erythrocyte membrane skeleton, isolated erythrocyte membranes evaginate in acidic pH. Moreover, intact cells evaginate at pH greater than 7.9, but isolated membranes invaginate in this condition. Labeling with the hydrophobic, photoactivatable probe 5-[125I]iodonaphthyl-1-azide demonstrated pH-dependent hydrophobic insertion of an amphitropic protein into membranes of intact cells but not into isolated membranes. Based on molecular weight and on reconstitution experiments using stripped inside-out vesicles, the most likely candidate for the variably labeled protein is glyceraldehyde-3-phosphate dehydrogenase. Resealing of isolated membranes reconstituted both the shape changes and the hydrophobic labeling profile seen in intact cells. This observation appears to resolve the paradox of the contradictory pH dependence of shape changes of intact cells and isolated membranes. In intact erythrocytes, the demonstrated protein-membrane interaction would oppose pH-dependent shape effects of the spectrin membrane skeleton, stabilizing cell shape in moderately abnormal pH. Stabilization of erythrocyte shape in moderately acidic pH may prevent inappropriate red cell destruction in the spleen.     

Effect of insulin on lipid bilayer viscoelasticity

Changes in the Young elasticity modulus in perpendicular direction to the membrane surface E perpendicular, in the coefficient of dynamic viscosity eta, in the electric capacitance C, in the surface charge U1, in the conductivity g and in the coefficient of non-linearity beta of current-voltage characteristic caused by insulin were studied in bilayer lipid membranes (BLM) prepared from a mixture of egg lecithin and cholesterol (4:1, w/w) in n-heptane. Even relatively small concentrations of insulin in electrolyte (ci approximately 4.8 x 10(-11) mol/l) caused a diminution in parameters E perpendicular and eta. Negative surface charge emerged on the membrane due to the insulin absorption, and U1 gradually increased depending on the concentration of the hormone in the electrolyte. Addition of insulin was also followed by an increase in membrane conductivity and affected the value of the coefficient of non-linearity beta of current-voltage characteristic. The effect of insulin on the BLM structure was discussed on the basis of the results obtained.     

Protective effect of green tea on erythrocyte membrane of different age rats intoxicated with ethanol

It is known that aging is characterized by changes in cell metabolism resulting in modification of the structure and function of cell membrane components which is mainly the consequence of reactive oxygen species action. These disturbances are also enhanced by different xenobiotics, e.g. ethanol. Therefore, the aim of this paper is to examine green tea influence on total antioxidant status (TAS) and on composition and electric charge of erythrocyte membrane phospholipids in ethanol intoxicated rats of various ages. Antioxidant abilities of erythrocytes were estimated by measuring TAS. Qualitative and quantitative composition of phospholipids in the membrane was determined by HPLC, while the extent of erythrocytes lipid peroxidation was estimated by HPLC measurement of malondialdehyde (MDA) and 4-hydroxynonenal (4-HNE) levels. Electrophoresis was used to determine the surface charge density of the rat erythrocyte membrane. It was shown that the process of aging was accompanied by a decrease in TAS and in the total amount of phospholipids as well as by enhancement of lipid peroxidation and increase in surface charge density of erythrocyte membrane. Ethanol administration caused, in term, decrease in TAS and increase in the level of all phospholipids and lipid peroxidation products. Ethanol as well significantly enhanced changes in surface charge density of erythrocyte membrane. The ingestion of green tea partially prevented decrease in erythrocyte antioxidant abilities observed during aging and ethanol intoxication. Moreover, long-term drinking of green tea protects the structure of the erythrocytes membrane disturbed during aging process and/or chronic ethanol intoxication.     

Surface charge of erythrocyte membrane during disorders of lipid metabolism from the data of microelectrophoresis, H+-titration and fluorescence studies

The surface charges and the isoelectric points (pI) as well as changes in these values depending on the lipid composition are determined for erythrocyte membranes of rat, rabbit, bull and man under conditions of hypercholesterinemia, atherosclerosis, D-hypovitaminosis and in experiments in vitro using the techniques of microelectrophoresis and positive charged ligands (proton, probe astraphloxin) binding. The ionogenic groups forming charge and essential differences in their nature (pK) and quantity depending on the erythrocyte type are found. Inverse correlation between the content of cholesterol and cholesterol ethers and the value of erythrocyte membrane surface charges was established for each sample examined. A comparative evaluation of the methods used was conducted.     

Measuring local surface charge densities in electrolyte solutions with a scanning force microscope

To show that local surface charge densities can be measured with a scanning force microscope purple membranes adsorbed to alumina were imaged in electrolyte solutions. Force versus distance curves were measured on purple membranes and on the bare alumina with standard silicon nitride tips. By comparing the electrostatic force measured on both substances, the surface charge density of purple membranes could be calculated from the known charge density of alumina. The charge density of purple membranes was estimated to be -0.05 C/m².     

Size-dependent mobile surface charge model of cell electrophoresis

A model that accurately predicts the effects of cellular size and electric field strength on electrophoretic mobility has been developed. Previous models have predicted that electrophoretic mobility (EPM) is dependent only on cell surface charge, bath viscosity and ionic strength of the electrolyte. However, careful analysis of experimental data from the literature shows that these models do not accurately depict the relationship between chemically determined surface charge and observed mobility. We propose a new model that accounts for electrically driven redistribution of mobile surface charge islands, such as the recently proposed lipid raft structures. This model predicts electrophoretic mobility as a function of a new dimensionless quantity, A, that incorporates the cell radius, the electric field strength, and the average diameter of charged membrane complexes.     

Changes in electric charge and phospholipids composition in human colorectal cancer cells

Cancer cells perform their malicious activities through own cell membranes that screen and transmit inhibitory and stimulatory signals out of the cells and into them. This work is focused on changes of phospholipids content (PI—phosphatidylinositol, PS—phosphatidylserine, PE—phosphatidylethanolamine, PC—phosphatidylcholine) and electric charge that occur in cell membranes of colorectal cancer of pT3 stage, various grades (G2, G3) and without/with metastasis. Qualitative and quantitative composition of phospholipids in the membrane was determined by HPLC (high-performance liquid chromatography). The surface charge density of colorectal cancer cell membranes was measured using electrophoresis. The measurements were carried out at various pH of solution. It was shown that the process of cancer transformation was accompanied by an increase in total amount of phospholipids as well as an increase in total positive charge at low pH and total negative charge at high pH. A malignant neoplasm cells with metastases are characterized by a higher PC/PE ratio than malignant neoplasm cells without metastases. (Mol Cell Biochem 276: 113–119, 2005)     

Equilibrium electropotentials in electrolyte systems

The determinationof electric potentials in finite regions of symmetrical electrolyte in one-dimensional equilibrium situations requires the solution of the one-dimensional Poisson-Boltzmann equation in which the dependent variable is linearly related to the electric potential and contains unknown parameters. These require evaluation as part of the solution to a given boundary value problem. The general solution of the equation is presented. This involves elliptic functions and integrals and is sectionally isomorphic with respect to an integration parameter. The application to problems posed in terms of both initial values and two-point boundary values is discussed. The solution is used to determine the potential and concentration distributions between two flat-faced charged particles immersed in an electrolyte liquid and having interacting double layers.     

Adsorption equilibria between liposome membrane formed of phosphatidylcholine and aqueous sodium chloride solution as a function of pH

The effect has been studied of the adsorption of ions (H(+), Na(+), OH(-), Cl(-)) which are present in solution upon the electric charge of the liposome membrane formed of phosphatidylcholine (PC). The surface charge density of the membrane was determined as a function of pH and electrolyte concentration from electrophoretic mobility measurements. The measurements were carried out by the laser-Doppler microelectrophoresis method. A four-equilibria model has been proposed to describe the phenomena occurring on the membrane surface. The equilibria in which the adsorption of other ions on the liposome membrane surface was involved were assumed to exist beside the equilibria in which the H(+) and OH(-) ions were engaged. The idea was confirmed by mathematical calculations. Association constants of the liposome membrane surface with ions of solution (K(AH), K(ANa), K(BOH), K(BCl)) were determined. The proposed model has been proved to be correct by comparing the resulting theoretic charge variation curves of the lecithin membrane with the experimental data.