Interaction between filamentous actin and lipid bilayer causes the increase of syringomycin E channel-forming activity

The effect of filamentous (F) actin on the channel-forming activity of syringomycin E (SRE) in negatively charged and uncharged bilayer lipid membranes (BLM) was studied. F-actin did not affect the membrane conductance in the absence of SRE. No changes in SRE-induced membrane conductance were observed when the above agents were added to the same side of BLM. However, the opposite side addition of F-actin and SRE provokes a multiple increase in membrane conductance. The similar voltage dependence of membrane conductance, equal values of single channel conductance and the effective gating charge of the channels upon F-actin action suggests that the actin-dependent increase in BLM conductance may result from an increase in the number of opened SRE-channels. BLM conductance kinetics depends on the sequence of SRE and F-actin addition, suggesting that actin-dependent rise of conductance may be induced by BLM structural changes that follow F-actin adsorption. F-actin exerted similar effect on membrane conductance of both negatively charged and uncharged bilayers, as well as on conductance of BLM with high ionic strength bathing solution, suggesting the major role for hydrophobic interactions in F-actin adsorption on lipid bilayer.     

Static and dynamic components of renal cortical brush border and basolateral membrane fluidity: Role of cholesterol

Summary Static polarization and differential polarized phase fluorimetry studies on rat renal cortical brush border (BBM) and basolateral membranes (BLM) were undertaken to determine the membrane components responsible for differences in BBM and BLM fluidity, whether these differences were due to the order or dynamic components of membrane fluidity and if a fluidity gradient existed within the bilayer. Surface membrane proteins rigidified both BBM and BLM fluidity. Neutral lipid extraction, on the other hand, caused a larger decrease in BBM than BLM fluorescence polarization (0.104vs. 0.60,P<0.01) using diphenyl hexatriene (DPH). Cholesterol addition to phospholipid fractions restored membrane fluidity to total lipid values in both BBM and BLM phospholipids. The response to cholesterol in the BBM was biphasic, while the BLM response was linear. Lateral mobility, quantitated using dipyrenylpropane, was similar in both BBM and BLM fractions at 35°C. BBM and BLM differed primarily in the order component of membrane fluidity as DPH-limiting anisotropy (r ) (0.212vs. 0.154,P<0.01) differed markedly between the two membrane fractions. The two membrane components also differed with respect to 2 and 12-anthroyloxy stearate (2-AS, 12-AS) probes, indicating a difference in the dynamic component of membrane fluidity may also be present. DPH and 12-As probes were also used to quantitate inner core membrane fluidity and showed the BBM was less fluid than the BLM for intact membranes, total lipid extracts and phospholipids. Results obtained using the surface membrane probes trimethylammonium-DPH (TMA-DPH) and 2-AS suggested a fluidity gradient existed in both BBM and BLM bilayers with the inner core being more fluid in both membranes. These data indicate cholesterol is in large part responsible for fluidity differences between BBM and BLM and that these membranes, while clearly differing in the order component of membrane fluidity, may also difer in the dynamic component as well.     

Elasticity, strength and stability of bilayer lipid membranes and their changes due to phospholipid modification

Elasticity measurements of bilayer lipid membranes (BLM) based on registration of the third harmonic of the membrane current during the application of a periodic tension to the membrane was used to study the effects of lipid peroxidation (LPO) and phospholipase A on BLM. LPO resulted in decreased values of the Young modulus for BLM, while some products of LPO and phospholipid hydrolysis (linolenic acid) were able to increase drastically the modulus. The presence of individual products of LPO and phospholipid hydrolysis in BLM produced non-additive effects on the elasticity, strength and stability of BLM. Lysolecithine strongly affected both the strength and stability of BLM. without changing its elasticity modulus. It was found that the lower the rate of structural changes in lecithine BLM, the longer its lifetime. Membranes having a heterogeneous polar composition form more stable BLM as compared to chemically homogeneous membranes.     

The effect of rimantadine on the structure of model and biological membranes

The action of the antiviral drug rimantadine on the structure of bilayer lipid membranes (BLM) and RBC membranes was investigated. Structural changes in BLM were recorded by ionophore conductivity changes and by changes in the third harmonic of capacity current signal due to lateral compression of BLM in an electric field. It was shown that the adsorption of rimantadine on BLM results in an increase in ionophore mobility in bilayer membranes of dioleolyllecithin (DOL) and common lipids of bovine brain (CL) and in a decrease in those of azolectin (A). Relative changes in the third harmonic signal also depend on the membrane composition and have different signs. The results may be explained by the rimantadine action on the lipid bilayer structure: "rigidification" of A-membranes and "fluidization" of BLM from DOL and CL. Structural reorganization of RBC membranes as investigated by the ability of the cells to enter a micropipette (inner diameter greater than or equal to 3 microns) thereby undergoing deformation. It was shown that rimantadine influences RBC deformability due to drug induced inhomogenous mechanical membrane properties. Also, rimantadine accelerated the process of artificially induced aggregation of erythrocytes. The relation of the effects on artificial and biological membranes, and the structural changes in the lipid phase of membrane are discussed.     

Fusion of a single influenza virion particle with BLM

One of the key stages of cell infection with influenza virus is the enveloped virus fusion with the cell endosome membrane. To study fusion of single fluorescently-labeled influenza virions with a model bilayer membrane (BLM), a special model system was developed. A small patch of BLM with several adsorbed virions was localized upon a contact with a glass micropipette. Low pH of solution inside the pipette triggered fusion that could be registered by a change in the conductance and integral fluorescence of the BLM patch. It has been shown that the fusion initiation is followed by an increase of fluorescence signal due to the probe redistribution from the virus membrane to the BLM fragment. The increase in fluorescence was accompanied by changes in conductance. Usually, from two to five periods of the channel activity were observed, each of which probably corresponded to fusion of a single virion. It has been found that electric activity was completely inhibited by amantadine known as a blocking agent of M2 channels. This allows one to suggest that the observed changes in conductance are connected with the activity of M2 channels in the virus membrane, whose electric accessibility was the result of fusion of single virions with BLM.     

Characterization of ischemia-induced loss of epithelial polarity

Summary Total renal ischemia for various time intervals (0–50) min) resulted in the rapid and duration-dependent redistribution of polarized membrane lipids and proteins in renal proximal tubule cells. Following only 15 min of ischemia, apical membrane enrichment of NaK-ATPase, normally a basolateral membrane (BLM) enzyme, had increased (1.6±0.6vs. 2.9±1.2,P<0.01). In vivo histochemical localization of NaK-ATPase showed reaction product throughout the apical microvillar region. PTH-stimulatable adenylate cyclase, another BLM protein, was also found in ischemic but not control apical membrane fractions. One dimensional SDS-PAGE showed four bands, present in control BLM and ischemic apical membranes, which could not be found in control apical membrane fractions. Immunohistochemical localization of leucine aminopeptidase (LAP) showed the enzyme was limited to the apical domain in control cells. Following ischemic injury (50 min), LAP staining could be seen within the cell and along the BLM. Following 24 hr of reperfusion, the BLM distribution of LAP was further enhanced. With cellular recovery from ischemic injury (5 days), LAP was again only visualized in the apical membrane. Duration-dependent alterations in apical and BLM lipids were also observed. Apical sphingomyelin and phosphatidylserine and the cholesterol-tophospholipid ratio decreased rapidly while apical phosphatidylcholine and phosphatidylinositol increased. Taken together, these results indicate renal ischemia causes rapid duration-dependent reversible loss of surface membrane polarity in proximal tubule cells.     

Modeling of damage to cell membranes during photodynamic therapy: photosensitization of planar lipid bilayers by hematoporphyrin dimethyl ether

The variations of electrical conductance of planar bilayer lipid membranes (BLM) sensitized by hematoporphyrin dimethyl ether under visible light illumination were studied. The conductance of BLM does not change for some period after switching on the light, then an increase in the conductance starts and the membrane breaks. This "induction" time does not depend on addition of azide or ferricyanide to the solution, on addition of BHT to the lipid and on substitution of air for argon in the cell. The induction time for any new BLM, formed in the same cell immediately after the previous membrane was broken, is shorter. The variation of BLM boundary potentials during induction time was not observed. The results obtained suggest that the photodamage of BLM sensitized by HPD leads to accumulation of uncharged reaction products and oxygen does not take part in this process.     

Gill Na+-K+-ATPase activity correlates with basolateral membrane lipid composition in seawater- but not freshwater-acclimated Arctic char (Salvelinus alpinus)

The successful migration of euryhaline teleost fish from freshwater to seawater requires the upregulation of gill Na+-K+-ATPase, an ion transport enzyme located in the basolateral membrane (BLM) of gill chloride cells. Following 39 days of seawater exposure, Arctic char had similar plasma sodium and chloride levels as individuals maintained in freshwater, indicating they had successfully acclimated to seawater. This acclimation was associated with an eightfold increase in gill Na+-K+-ATPase activity but only a threefold increase in gill Na+-K+-ATPase protein number, suggesting that other mechanisms may also modulate gill Na+-K+-ATPase activity. We therefore investigated the influence of membrane composition on Na+-K+-ATPase activity by examining the phospholipid, fatty acid, and cholesterol composition of the gill BLM from freshwater- and seawater-acclimated Arctic char. Mean gill BLM cholesterol content was significantly lower ( approximately 22%) in seawater-acclimated char. Gill Na+-K+-ATPase activity in individual seawater Arctic char was negatively correlated with BLM cholesterol content and positively correlated with %phosphatidylethanolamine and overall %18:2n6 (linoleic acid) content of the BLM, suggesting gill Na+-K+-ATPase activity of seawater-acclimated char may be modulated by the lipid composition of the BLM and may be especially sensitive to those parameters known to influence membrane fluidity. Na+-K+-ATPase activity of individual freshwater Arctic char was not correlated to any membrane lipid parameter measured, suggesting that different lipid-protein interactions may exist for char living in each environment.     

Effect of polymyxin B on the conductivity of negatively charged bilayer lipid membranes

Effect of polymyxin B on the planar bilayer lipid membranes (BLM) formed from synthetic phosphatidic acid has been studied. The addition of cholesterol to phospholipid in molar ratio 1 : 2 was followed by an increase of BLM conductance from 2 x 10(-8) to 3 x 10(-7) Ohm-1 cm-2. It was suggested that the observed increase of conductance was due to the fluidity of the membrane matrix in the presence of cholesterol. It was shown that 10(-6)--10(-5) M polymyxin slightly affected the conductance of BLM from phosphatidic acid. It was found that polymyxin increased conductance of negatively charged BLM modified by palmitic acid from 10(-8) to 10(-6) Ohm-1 cm-2.     

Immunohistochemical localization and characterization of a protein from the basolateral membrane of rat small intestine epithelium using monoclonal antibody GZ-1

The proteins of the basolateral membrane (BLM) of small intestine epithelial cell in rat have been less precisely described than those of the microvillus membrane (MVM). To identify BLM-specific proteins, Balb/c mice were immunized with isolated intestinal epithelial cells and monoclonal antibodies (MAb) to their cell membrane, produced with the hybridoma technique. One of the MAb so obtained (GZ-1), a class 1 IgG, is specifically directed to a surface membrane protein of intestinal epithelium (GZ-1-Ag). The MAb served to characterize the protein as follows. Light microscopic immunohistochemical FITC labeling and, still more clearly, electron microscopic labeling with colloidal gold on Lowicryl sections of small intestinal tissue, show that the GZ-1-Ag occurs only in BLM of the absorptive cell and the goblet cell. It is not present in the MVM, the tight-junction area, and probably in the desmosomal sections of the membrane. The crypt cells are more markedly labeled with GZ-1 than are the villus cells; the villus cells are also more clearly labeled from the duodenum to the ileum. Gross analysis of the position of the gold marker on the BLM indicates that GZ-1-Ag is probably integrated into the lipid bilayer. With immunoblotting (with HRP as marker), a single band of MW 42,000 D can be identified as the corresponding GZ-1-Ag from the protein band pattern obtained with SDS-PAGE from BLM isolated in the presence of protease inhibitors (PI). In BLM fractions isolated without protease inhibition, a band of MW 30,000 D can be labeled with GZ-1. These results are interpreted as follows: GZ-1-Ag is a protein of MW 42,000 D. On isolation of the BLM without PI, a piece of this protein is broken off by proteolysis. The larger piece of the molecule (30,000 D) is not accessible to the proteolytic enzyme owing to its localization in the BLM, and therefore remains intact (and recognizable by the Ab). The preferred position of the gold marker on the BLM is in agreement with this explanation.     

Study of the interaction of myoglobin with lipid bilayer membranes by potentiodynamic method

For modeling the interaction of myoglobin with mitochondrial membranes, the adsorption of different ligand forms, the physiologically active reduced MbO2 and inactive oxidized met-Mb, on one of the surfaces of artificial bilayer lipid membrane (BLM) was studied using potentiodynamic technique known as the "capacity minimization" method. As mitochondrial membranes are negatively charged, BLM from the negatively charged palmitoyl-2-oleil-phosphatidyl glycerol (POPG) and neutral soybean phosphatidylcholine (lecithin) were used. It is shown that both myoglobins strongly interact with BLM in the pH range 6-8. The dependence of the potential difference between cis-and trans-surfaces of the lipid membrane (deltaE, mV) on the protein concentration is characteristic for the Langmuir adsorption isotherm, and the saturation level (deltaEmax, mV) corresponds to monolayer of myoglobin. The protein adsorption is essentially electrostatic in nature, as adsorption activity increases sharply in the case of the membrane from POPG: in a approximately 15-fold in the case of MbO2 and in a approximately 2.5 times for the met-Mb. The parameters of the MbO2 and met-Mb adsorption on BLM from lecithin and POPG do not change in the pH 6-8 range. It can be assumed that the anionic groups of phospholipids associate with the cationic groups of the protein, the charge state of those does not change in the pH 6-8 range. The most likely candidates for interaction with phospholipids of BLM are invariant lysines and arginines in the environment of the myoglobin heme cavity.     

Effect of beta-lactam antibiotics on lipid bilayer membranes. I. Penicillin antibiotics

Interaction between penicillins and model membrane systems, flat black bilayer lipid membranes (BLM) composed of vegetable or bacterial phospholipids was studied with an account of the complicated structure of bacterial cell membranes and possible presence in them of "pure" bilayer lipid areas. By their effect on electroconductivity of the BLM the antibiotics could be divided into three groups: those having no effect on the BLM electroconductivity at the maximum concentrations i.e. benzylpenicillin, carbenicillin, piperacillin (at pH 6.0 and 7.0) and ampicillin (at pH 6.0), those insignificantly changing electroconductivity of the BLM i.e. carfecillin and azlocillin and those having a significant effect on the BLM electroconductivity i.e. ampicillin N-acyl derivatives and 6-APA. The effect of ampicillin on the BLM conductivity markedly depended on the electrolite pH. The penicillins bound to the bilayer and induced changes in the transmembrane potential (evident from the changes in the second harmonic of the capacitive current) and the BLM elasticity-capacitance parameters (evident from the changes in the ratio of the amplitudes of the first and third harmonics). It was shown that all the penicillins penetrated through the BLM composed of either vegetable or bacterial phospholipids. The capacity for the transmembrane transfer without changing of the bilayer conductivity must be connected with the fact that the penetrating antibiotics did not induce any changes in the BLM structure. The effect on the conductivity probably depended in its turn on the form of the molecule and the ratio of the hydrophilic and hydrophobic parts in it.     

Interaction of dopamine with artificial phospholipid membranes

The interaction of dopamine (DA) with phospholipid membranes has been investigated. The membrane current in planar bilipid membrane (BLM) modified by amphotericin B in voltage clamp conditions under alternating polarity was shown to symmetrically increase 1.2 times when DA was added outside the BLM. This implies a uniform change of charge on each membrane surface and hence the diffusion of DA within the BLM and its exposure on the internal side. The appearance of single threads and bundles of filaments within the internal liposomal cavities was observed in the ultrastructure of suspended thin-walled liposomes filled with globular actin after the introduction of DA into external solution. This reshaped liposomes into rod-like, spindle-shaped or angular structures. Actin serves as a marker for DA due to its property to polymerize itself under the influence of DA. Thus, the structural reorganization of liposomes manifests the presence of DA inside them and the induction of actin polymerization.     

Interaction of the nuclear proteins protamine and histone with charged bilayer membranes]

The interaction of nuclear proteins of protamine and histone with neutral and charged BLM was studied. Anion and cation detergents were used to create the surface charge. The surface density of charges in BLM was comparable with that in biomembranes. Protamine and histone increased the electroconductivity of negatively charged BLM for anions and cations correspondingly. It is suggested that the surface charge of the membrane may influence the ion transport directly and indirectly due to the interaction of the membrane structures with charged proteins present in the surrounding medium.     

The Role of Membrane Lateral Tension in Calcium-Induced Membrane Fusion

Calcium-induced fusion of liposomes was studied with a view to understand the role of membrane tension in this process. Lipid mixing due to fusion was monitored by following fluorescence of rhodamine-phosphatidyl-ethanolamine incorporated into liposomal membrane at a self-quenching concentration. The extent of lipid mixing was found to depend on the rate of calcium addition: at slow rates it was significantly lower than when calcium was injected instantly. The vesicle inner volume was then made accessible to external calcium by adding calcium ionophore A23187. No effect on fusion was observed at high rates of calcium addition while at slow rates lipid mixing was eliminated. Fusion of labeled vesicles with a planar phospholipid membrane (BLM) was studied using fluorescence microscopy. Above a threshold concentration specific for each ion, Ca²⁺, Mg²⁺, Cd²⁺ and La³⁺ induce fusion of both charged and neutral membranes. The threshold calcium concentration required for fusion was found to be dependent on the vesicle charge, but not on the BLM charge. Pretreatment of vesicles with ionophore and calcium inhibited vesicle fusion with BLM. This effect was reversible: chelation of calcium prior to the application of vesicle to BLM completely restored their ability to fuse. These results support the hypothesis that tension in the outer monolayer of lipid vesicle is a primary reason for membrane destabilization promoting membrane fusion. How this may be a common mechanism for both purely lipidic and protein-mediated membrane fusion is discussed. Received: 27 September 1999/Revised: 22 March 2000     

Protein from beef heart mitochondria inducing the potassium channel conductivity of bilayer lipid membrane

Protein (M. m. 60 000) inducing selective potassium conductance of bilayer lipid membranes (BLM) was isolated from mitochondria and homogenate of the beef heart. This protein was obtained by means of alcohol (ethanol) extraction and was purified by gel-filtration on Sephadex G-15 and G-50 followed by electrophoresis in the 10% polyacrylamide gel. 6-10 g/ml of the protein produced the conductivity channels on BLM with amplitude divisible of 24 +/- 4 pmho. The channels of 175 +/- 7 pmho were the most typical ones. The modification of BLM by K+-transport in protein under the conditions of potassium gradient resulted in the appearance of the membrane potential close to the theoretical Nernst potential.     

Interaction of all-<Emphasis Type="Italic">trans</Emphasis>-Retinal with bilayer lipid membranes

The interaction of all-trans-retinal (hereinafter referred to as retinal) with planar bilayer lipid membranes has been studied. Addition of retinal into aqueous solutions on both sides of the membrane formed from diphytanoilphosphatidylcholine (DPhPC) or its mixture with diphytanoilphosphatidylethanolamine (DPhPC/DPhPE in w/w proportion of 3: 5) led to a change of conductance induced by ionophores nonactin (increase of conductance) or pentachlorophenol (decrease). Increase of nonactin-induced conductance was dependent on the membrane lipid composition and was two times higher in the case of DPhPC/DPhPE mixture. The change of conductance caused by ionophores of different signs (plus or minus) had different direction suggesting the influence of the retinal on the dipole potential upon its incorporation into BLM. The boundary potentials difference measured by the intramembrane field compensation method (IFC) after the retinal addition on one side of the membrane did not exceed 2.5 mV suggesting that its distribution in the bilayer is almost symmetrical. The illumination of the retinal-containing BLM caused a decrease in its lifetime when the membranes were formed from unsaturated lipids. Retinal incorporated into BLM led also to photoinactivation of the gramicidin channels. The process was completely inhibited by a singlet oxygen quencher (sodium azide). These results indicate that retinal accumulated in the membrane can affect both membrane proteins and the unsaturated lipids by their oxidation by the singlet oxygen.     

Action of natural and synthetic antioxidants on the electrical parameters and stability of natural and artificial membranes

The effect of antioxidants alpha-tocopherol and ionol on membranes of human red cells and bilayer lipid membrane (BLM) from azolektin has been studied. Ionol at concentration 4-10 mM induces the hemolysis of erythrocytes, the cells form changes are observed at concentration 2 mM alpha-tocopherol doesn't show the hemolytic properties at concentration 23 mM. The ionol concentration 1 mM doesn't change the form of the cells, but influence the passive electric parameters: the capacity (Cs) of erythrocytic membrane increases and the intracellular conductance (chi i) decreases. Tocopherol (3 mM) induces the decrease both Cs and chi i. The fast increase of membrane conductance is almost immediately registered on one side of BLM at addition of ionol (0,2-0,4 g/ml). Phosphatidylionol synthesized from ionol and contining the acyl chains C15H31 and C17H35 doesn't influence the electrical properties of BLM.     

Study of conductance changes of bilayer lipid membrane induced by electric field

Changes in the bilayer lipid membrane (BLM) conductance induced by electric field were studied. BLMs were formed from diphytanoylphosphocholine (DPhPC) solution in squalene. Certain time after a constant voltage (200-500 mV) was applied to the BLM in the voltage-clamp mode, the BLM conductance started to grow up to approximately 10 nS until the BLM ruptured. The conductance often changed abruptly (with the front duration of less than 33 micros) and then stabilized for a relatively long time (up to 10; 300 ms on average) thus resembling the ion channel activity. The mean amplitude of conductance steps was 650 pS. However, in some cases a slow conductance drift was recorded. When N-methyl-D-glucamine/glutamate ions were used instead of KCl, the conductance changes became 5 times smaller. We suggest that formation in the BLM of single pores approximately 1 nm in diameter should result in the observed changes in BLM conductance. The BLM conductance growth was due to consecutive opening of several such pores. When the electric field amplitude was abruptly decreased (down to 50-100 mV), the conductance dropped rapidly to the background value. When we increased the voltage again, the BLM conductance right after the increase depended on the time BLM spent under "weak" electric field. If this time exceeded 500 ms, the conductance was at the background level, but when the time was diminished, the conductance reached the value recorded before the voltage decrease. These data imply that the closure of the pores should lead to the formation in BLM of small defects (prepores) that can be easily transformed into pores when the voltage is increased. The lifetimes of such prepores did not exceed 500 ms.     

Effect of phloretin on the carrier-mediated electrically silent ion fluxes through the bilayer lipid membrane: measurements of pH shifts near the membrane by pH microelectrode.

The effect of phloretin on the carrier-mediated electrically silent ion fluxes through the bilayer lipid membrane (BLM) was studied. The measurements were carried out according to our conventional technique, i.e. electrical potential recording in the presence of a protonophore, and by a new method--direct measurements of pH shifts in the unstirred layers of the BLM by pH microelectrode. Both techniques gave similar results. It was shown that the addition of phloretin increased the rate of cation/H+ exchange induced by nigericin and decreased the rate of anion/OH(-)-exchange induced by tributyltin. The effect of phloretin was higher in the presence of cholesterol in the BLM. Cholesterol decreased the nigericin- and tributyltin-induced fluxes under our experimental conditions. The application of an external voltage to the membrane had no effect on the ion fluxes thereby showing that these fluxes were electroneutral. The most probable explanation of these results bases on the effect of the membrane dipole potential on the electroneutral fluxes of ions. The possible mechanism of the dipole potential effect on the carrier-mediated electrically silent ion fluxes was discussed in terms of two competing hypotheses--the translocation through the membrane or the reactions at the membrane surface being the rate-limiting steps of the whole transport process.