Membranotropic action of cardiotonic agents and ubiquinone

Interaction of cardiotonic drugs (strophantidine acetate, suphan, para-oxybenzoic acid) and ubiquinone with phospholipid bilayers has been studied. Exothermic effect of the reaction followed by an increase in microviscosity and hydrophobicity of the bilayer from cardiolipin, but by a decrease of the microviscosity of the bilayer from lecithin has been estimated. A correlation is observed between changes in the lecithin bilayer fluidity and the heat effect of the interaction at the initial period of time after mixing of reagents.     

Thermotropic behavior of liposomes from egg yolk lecithin, hydrogenized egg yolk lecithin and their mixtures

The thermotropic properties of multilamellar liposomes from egg yolk lecithin, hydrogenized egg yolk lecithin and several mixtures of these two lipids were studied with the application of excimer--forming optical probe pyrene and microcalorimetry. It was discovered that when the proportion of the egg yolk lecithin in the lipid mixture was raised the temperature of the main phase transition reduced. For all this, independent of the lipid mixture composition when the temperature was raised, apparently, polarity of pyrene microenvironment in the liposomes bilayers decreased. On the basis of the analysis of solidus and liquidus curves obtained from calorimetric studies of the lipid mixtures and bend points of Arrhenius anamorphose obtained during the pyrene excimer formation measurements some conclusions were made about the role of unmodified and hydrogenized egg yolk lecithin cluster formation in the determination of thermotropic properties of the liposomes from the above two lipids mixtures. High temperature phase transition discovered for the egg yolk lecithin while measuring the pyrene excimer formation is proposed to be closely connected with temperature-dependent changes in the organization of phospholipid heads on the interphase bilayer/H2O solution.     

A membrane-bound fluorescent probe to detect phospholipid vesicle-cell fusion

Summary Pyrenesulfonylphosphatidylethanolamine has been incorporated into sonicated phospholipid vesicles to provide a fluorescent signal from a membrane-bound probe whose spectrum is sensitive to the local concentration of dye molecules. When vesicle material was taken up by viable mouse splenocytes, the disappearance of the pyrene excimer fluorescence emission peak that accompanied dilution of the vesicle membrane lipid could be quantitated. One can thus measure, by a simple and rapid procedure, a new parameter which is related to the extent of vesicle-cell fusion and which is independent of the transfer of aqueous vesicle contents to the cell cytoplasm.Abbreviations used 6-CF 6-carboxyfluorescein - HBSS Hanks Balanced Salt Solution - DMPC dimyristoylphosphatidylcholine - DOPC dioleoyl-phosphatidylcholine - DPPC dipalmitoylphosphatidylcholine - EYL egg yolk lecithin - PE phosphatidylethanolamine - PEG polyethylene glycol - PLV phospholipid vesicle - PSPE pyrenesulfonylphosphatidylethanolamine     

Regulating and disturbing effects of alpha-tocopherol on lipid bilayers

Using the high resolution 1H-NMR spectroscopy and spin-probes the influence of alpha-tocopherol on lipid bilayer microviscosity has been studied. It has been established that alpha-tocopherol shows the cholesterol-like action on the physical state of lipid bilayer: alpha-tocopherol increase microviscosity of unsaturated bilayers and decrease microviscosity of saturated bilayers. The character of alpha-tocopherol action is determined by the fatty acidic lipid composition but does not depend on the polar group structure of phospholipid molecule as cholesterol-like action of alpha-tocopherol is found itself in liposomes prepared both from phosphatidylcholine and phosphatidylethanolamine. Analog of alpha-tocopherol without phytol chain 2,2,5,7,8-penthamethyl-6-oxychroman does not show the cholesterol-like action as it is not able to disorder the saturated bilayers.     

Changes in the microviscosity of lipid bilayer membranes of various malignant cells and tumor transplantability

It is shown that cholesterol incorporation into the membranes of Zajdel hepatoma cells, lymphoblast leukemia cells L1210 and into those of ovary tumour causes an increase in the membrane phospholipid bilayer microviscosity measured by pyrene as fluorescent probe. The increase in the membrane lipid microviscosity resulted in a decrease in the activity of Na,K-ATPase and 5-nucleotidase of the tumour cells. After the injection of tumour cells with an increase of cholesterol/phospholipid ratio we observed an increase of the life-span of experimental animals as compared to the control groups.     

Influence of membrane lipids on the photochemistry of bacteriorhodopsin in the purple membrane of Halobacterium halobium

Purple membrane fragments from Halobacterium halobium were reconstituted with the native lipids replaced by dipalmitoyl phosphatidylcholine and by egg lecithin. In parallel studies the temperature dependence of bacteriorhodopsin phototransient lifetime and absorption dichroism and of in situ lipid microviscosity were determined; the former two by, respectively, conventional and polarization flash photometry, and the latter by observation of emission depolarization of an embedded fluorescent dye, 1,6-diphenyl-1,3,5-hexatriene. Discontinuities in lipid microviscosity profiles in native and egg lecithin purple membrane were reflected in both the photochemical cycle frequency and bacteriorhodopsin chromophore rotational mobility. The influence exerted by membrane-lipid viscosity appears to be a secondary effect, and points to the bacteriorhodopsin chromophoric group being situated in the protein interior.     

Effect of phase transition on the kinetics of dye transport in phospholipid bilater structures.

Binding of 8-anilino-1-naphthalenesulfonate to dimyristoyl-L-alpha-lecithin bilayers enhances the fluorescence quantum yield of the dye molecule by 100-fold. By following the generation of fluorescence after a rapid mixing in a stopped-flow apparatus (mixing time 2 msec), kinetics of the binding of the fluorescence probe to the phospholipid vesicles has been investigated in the temperature range where the crystal-liquid crystal phase transition of the bilayer structures occurs. No reactions depending on the dye or the vesicle concentrations were detected. This suggests that the initial adsorption of the dye was very rapid. Two kinetic phases which appear in the 50 msec and the second time ranges are unimolecular. The faster one has a small amplitude and is observable in the entire temperature range studied. In the phase transition region the slower reaction becomes the major kinetic phase. It also increases the apparent concentration of bound dye by a factor of 2. These observations suggest that the 50-msec reaction has detected a reorientation of the probe molecule after the initial binding, and that the slow reaction represents a transport of the dye molecule into the inner layer of the lipid vesicle. The transport reaction is extremely temperature sensitive and exhibits a maximum rate at the midpoint of the bilayer phase transition (Tm = 24.1 degrees). the Arrhenius plot of the transport reaction shows a maximum at the Tm. the same temperature dependence was also observed for the bromothymol blue transport reaction. However, no such effects were detected for less amphiphilic molecules such as tetracycline, chlortetracycline, and pyrene. In the latter systems only a slight bending of the Arrhenius plots were seen at the phase transition temperature. Since the kinetics of the transport of 8-anilino-1-naphthalenesulfonate is sensitive to the physical state of the phospholipid bilayers this reaction may be used for probing membrane structures.     

Stabilization of synaptic membranes with alpha-tocopherol against the damaging effect of phospholipases. Possible mechanism of the biological action of vitamin E

Using fluorescent and EPR spin probing techniques, the effects of phospholipases A2, C and D on rat brain synaptosomal membranes were investigated. It was shown that treatment of synaptosomal membranes with phospholipases A2, C and D results in their depolarization and increase of their surface negative charge. In case of phospholipases A2 and C, these changes are also accompanied by a decrease of the microviscosity of the synaptosomal membrane lipid bilayer. alpha-Tocopherol protects synaptosomal membranes against the damaging action of phospholipases. The stabilization of synaptosomes by vitamin E consists in the reconstitution of the transmembrane potential and in an increased microviscosity of phospholipase-treated membranes. The stabilizing effect of alpha-tocopherol is due to the binding of phospholipid hydrolysis products rather than to the inhibition of phospholipases. The observed stabilization of synaptosomal membranes by alpha-tocopherol is interpreted as a feasible mechanism of biological effects of vitamin E on biological membranes.     

Changes in the membrane lipids and lymphocyte function in staphylococcal infection and the development of delayed hypersensitivity

Experimental staphylococcal infection was reproduced in rats by the intraperitoneal injection of S. aureus strain 75. The degree of the development of delayed hypersensitivity (DH) to staphylococci, microviscosity, the levels of free radical oxidation and antioxidation resistance were evaluated in the dynamics of the infectious process by the methods of chemiluminometry and fluorescent probing with pyrene. The functional activity of lymphocytes was determined by the inclusion of 3H-thymidine into DNA as the consequence of stimulation with phytohemagglutinin. The development of DH was found to depend on the microviscosity and antioxidation resistance of membrane lipids. The increase of microviscosity and the simultaneous decrease of the induction time of chemifluorescent rapid flash inhibit the development of DH, leading to the aggravation of the infectious process. The increase of fluidity and the accumulation of antioxidants facilitate the development of DH and lead to a milder course of the infectious process.     

Nonsymmetrical polymethine dyes as fluorescent probes for the study of microviscosity of membrane phospholipid bilayers

Nonsymmetrical polymethine dyes are shown to be applied as a new approach in the studies of phospholipid membrane microviscosity. The method requires determination of the intensity ratio for the long-wave length (Ig) and short-wave length (Ik) bands of fluorescence spectra in the region of 730-770 nm at exitation 600 nm. It allows determination of microviscosity by comparative measurements of the fluorescence parameter Ig/Ik in the model medium of the known viscosity (glycerol) and the object under study. Microviscosity in egg phosphatidylcholine vesicules (liposomes) is found to be 0.6-1.2 P. It depends on the surface curvature (size of vesicle), cholesterol content and temperature. It the studies of dimiristoylphosphatidyl choline liposomes the changes in microviscosity at the phase transition temperature are shown to be from 4.5 to 1.1 P. The transition temperature is 24.5 degrees C, the transition range being 2.2 degrees C. The results of this work demonstrate the advantages of the suggested approach to study mobility in phospholipid membranes and confirm it to be promising to study natural membranes and whole cells.     

The effect of holotoxin A1 on transport of calcium ions across the lipid models of biological membranes

Planar bilayer lipid membranes formed from trepang phospholipids possess an intrinsic Ca2(+)-permeability. These phospholipids dissolved in a non-polar solvent can extract 45Ca2+ from the aqueous to the organic phase. The triterpenic glycoside holotoxin A isolated from the trepang Stichopus japonicus inhibits the Ca2+ flux of lipid bilayers from trepang phospholipids as well as the Ca2+ flux induced in phosphatidylcholine bilayers by the calcium ionophore X-537A. Toxin inhibits the Ca2+ ionophore A23187 induced Ca2+ efflux from phosphatidylcholine liposomes and 45Ca2+ transition from the aqueous to the organic phase. Holotoxin A does not inhibit the 45Ca2+ transfer to the non-polar phase induced by holoturia phospholipids and does not affect the phosphatidylcholine hydroperoxide-induced Ca2+ flux of lipid bilayers. Using the fluorescent probe pyrene, it was demonstrated that toxin increases the microviscosity of liposomal membranes and trepang oocyte "ghosts".     

Cardiolipin binds nonyl acridine orange by aggregating the dye at exposed hydrophobic domains on bilayer surfaces.

10-N-Nonyl acridine orange (NAO) has been used at low concentrations as a fluorescent indicator for cardiolipin (CL) in membranes and bilayers. The mechanism of its selective fluorescence in the presence of CL, and not any other phospholipids, is not understood. The dye might recognize CL by its high pK (pK(2)>8.5). To investigate that, we established that NAO does not exhibit a pK in a pH range between 2.3 and 10.0. A second explanation is that the dye aggregates at hydrophobic domains on bilayers exposed by the CL. We found that a similar spectral shift occurs in the absence of CL in a concentrated solution of the dye in methanol and in the solid state. A model is proposed in which the nonyl group inserts in the bilayer at the hydrophobic surface generated by the presence of four chains on the phospholipid.     

Transverse location of the fluorescent probe 1,6-diphenyl-1,3,5-hexatriene in model lipid bilayer membrane systems by resonance excitation energy transfer

A fluorescent phospholipid derivative, the fluoresceinthiocarbamyl adduct of a natural phosphatidylethanolamine, has been synthesized and incorporated into sonicated single-bilayer vesicles of egg lecithin and dipalmitoyllecithin. The surface location of this probe has been confirmed by using extrinsic fluorescence quenching studies together with steady-state emission anisotropy measurements. Electronic excitation energy transfer between 1,6-diphenyl-1,3,5-hexatriene incorporated within the hydrophobic core of the bilayer and the novel derivative has been investigated to estimate the depth within the bilayer at which the former is located. Efficiencies have been measured for two different phospholipids, egg lecithin and dipalmitoyllecithin, in the latter case both above and below the phospholipid phase transition, with and without added cholesterol. The observed dependence of the transfer efficiency on the acceptor concentration was compared with that calculated according to F?rster theory applied to random two-dimensional distributions of donor and acceptor molecules in parallel planes for various interplanar separations, taking into account orientational effects. The F?rster R0 of about 45 A for this donor-acceptor pair is particularly well suited to such studies since it is of the order of the width of the bilayer. The experiments showed that energy-transfer spectroscopy can provide useful quantitative information as to the transverse location of diphenylhexatriene in homogeneous phospholipid bilayers and may also reflect lateral partitioning of donor or of both donor and acceptor into different phases in systems exhibiting phase separations.     

A spin probe study of the influence of cholesterol on motion and orientation of phospholipids in oriented multibilayers and vesicles

Spin probes have been used to study at the molecular level the influence of cholesterol on bilayers of egg lecithin and dipalmitoyl lecithin. Distinct differences between the two lecithin systems were revealed. Increasing amounts of cholesterol result in extension of the fatty acid chains and decreased amplitude of motion of the long axes of the fatty acids in egg lecithin. In dipalmitoyl lecithin cholesterol causes an increase in the mobility and amplitude of motion of the fatty acid side chains, presumably due to alteration of the molecular interactions between phospholipids by relaxing the close packing of these molecules. These data provide an explanation for the condensing and fluidizing effects of cholesterol in water-containing phases and monolayers of egg lecithin and dipalmitoyl lecithin, respectively, and for the permeability behavior of egg lecithin and dipalmitoyl lecithin liposomes in the presence and absence of cholesterol. Differences are revealed between the spin bilayer environments in hydrated phospholipid films and vesicles.     

Repulsive forces in lecithin glycol lamellar phases.

The repulsive pressure vs. distance for phospholipid bilayers in glycol has been determined from vapor pressure measurements. The magnitude of this pressure is similar to the case when water is present between the lipid bilayers. Hence, an interaction directly corresponding to the previously reported hydration force is shown also for nonaqueous lecithin/solvent systems.     

Vitamin A and microsomal membranes: the effect of retinol deficiency on lipid microviscosity and phospholipid turnover in rat liver microsomes

Studies with the use of the fluorescent probe pyrene revealed that vitamin A deficiency in maturing male rats results in the increased microviscosity of liver lipids. This effect seems to be due to changes in the lipid composition of microsomal membranes (increased cholesterol/phospholipid ratio and lowered polyunsaturated fatty acid content) as well as to the low level of retinol. Analysis of microsomal phospholipids labeled with [3H]palmitate and [14C]glycerol revealed that vitamin A deficiency accelerates the turnover of the glycerol skeleton but sharply decelerates that of fatty acid residues. It is concluded that the observed effect of retinol on the structural and functional properties of biological membranes is due to its ability to control the microviscosity and turnover of membrane lipids.     

Microviscosity of mucosal cellular membranes in toad urinary bladder: Relation to antidiuretic hormone action on water permeability

Summary The microviscosity of cellular membranes (or membrane fluidity) was measured in suspensions of single mucosal cells isolated from the urinary bladder of the toad,Bufo marinus, by the technique of polarized fluorescence emission spectroscopy utilizing the hydrophobic fluorescent probe, perylene. At 23°C, 5mm dibutyryl cyclic 3,5-AMP decreased the apparent microviscosity of the cell membranes from 3.31 to 3.07 P, a minimum decrease of 7.3% (P<0.001) with a physiological time course. Direct visualization of the cell suspension indicated that 98% of the cells were viable, as indicated by Trypan Blue dye exclusion. The fluorescent perylene could be seen only in plasma membranes, suggesting that the measured viscosity was that of plasma membrane with little contribution from the membranes of cellular organelles. Addition of antidiuretic hormone to intact hemibladders stained with perylene produced changes in fluorescence consistent with a similar 7% decrease in apparent microviscosity with a physiological time course. However, finite interpretation of the findings in intact tissue cannot be made because the location and the fluorescent lifetime of the probe could only be conducted on the isolated cells. Comparison with previously determined relationships between water permeability and microviscosity in artificial bilayers suggests that the 7% (a lower limit) decrease in microviscosity would produce only a 6.5% increase in water permeability.     

The effect of alpha-tocopherol and ionol on the physical structure of the membranes of rat liver microsomes under conditions of antioxidant insufficiency

Physiochemical conformity of the alpha-tocopherol interaction with hepatic microsomal membranes has been studied by means of fluorescent probes (pyrene and 1-anilinonaphthalene-8-sulphonate). The microsomal membrane microviscosity is shown to sharply decrease under conditions of the antioxidant deficiency with vitamin E expelled into animals normalizes microviscosity, but feebly influences the microsomal surface charge. Microcalorimetry has been used to establish that penetration of tocopherol into microsomal membranes was accompanied by the exothermic effect.     

Protein-dependent Reduction of the Pyrene Excimer Formation in Membranes

The presence of proteins in lipid bilayers always decreases the excimer formation rate of pyrene and pyrene lipid analogues in a way that is related to the protein-to-lipid ratio. Energy transfer measurements from intrinsic tryptophans to pyrene have shown (Engelke et al., 1994), that in microsomal membranes, the excimer formation rate of pyrene and pyrene fatty acids is heterogeneous within the membrane plane, because a lipid layer of reduced fluidity surrounds the microsomal proteins. This study investigates whether of not liposomes prepared from egg yolk phosphatidylcholine with incorporated gramicidin A give results comparable to those from microsomal membranes. The results indicate that the influence of proteins on the lipid bilayer cannot be described by one unique mechanism: Small proteins such as gramicidin A obviously reduce the excimer formation rate by occupying neighboring positions of the fluorescent probe and thus decrease the pyrene collision frequency homogeneously in the whole membrane plane, while larger proteins are surrounded by a lipid boundary layer of lower fluidity than the bulk lipid. The analysis of the time-resolved tryptophan fluorescence of gramicidin A incorporated liposomes reveals, that the tryptophan quenching by pyrene is stronger for tryptophans located closely below the phospholipid headgroup region because of the pyrene enrichment in this area of the lipid bilayer. Received: 29 December 1996/Revised: 15 May 1996     

1-Palmitoyl-2-pyrenedecanoyl glycerophospholipids as membrane probes: evidence for regular distribution in liquid-crystalline phosphatidylcholine bilayers

We have synthesized 1-palmitoyl-2-pyrenedecanoyl-sn-glycero derivatives of 3-phosphatidylcholine, 3-phosphatidylethanolamine, 3-phosphatidylserine, 3-phosphatidylglycerol, 3-phosphatidylinositol, and 3-phosphatidic acid and investigated their behavior in monolayers and in neat and mixed bilayers. Fluorescence spectroscopy of neat pyrene phospholipid dispersions revealed a well-defined thermotropic transition at 13.5-19 degrees C depending on the polar head group. An endotherm coinciding with this transition was observed with differential scanning calorimetry, indicating it to be due to the melting of the lipid acyl chains. For pyrenephosphatidylethanolamine, the endotherm was observed at a much higher temperature (70 degrees C). Compression isotherms obtained at an argon/water interface revealed that the pyrene moiety somewhat increases the mean molecular area of a phospholipid molecule but does not prevent the expression of head-group-dependent packing behavior. Partition of the pyrene lipids between coexisting fluid and solid phases was investigated with fluorometry and calorimetry. Both techniques indicate that these lipids prefer the fluid phase and that this preference is independent of the head group. The rates and apparent activation energies of lateral diffusion in fluid bilayers were found to be similar for most pyrene lipids, suggesting that the lateral movement of phospholipids is not critically dependent on interactions at the head-group level. Lateral distribution of the pyrene lipids in gel and fluid phosphatidylcholine bilayers was studied with the excimer technique and calorimetry. In gel-state dipalmitoylphosphatidylcholine bilayers, the pyrene lipids form clusters. These clusters, however, do not consist of pure pyrene lipid but of aggregates (compounds) of the labeled and unlabeled lipid.(ABSTRACT TRUNCATED AT 250 WORDS)