Locations and dynamical perturbations for lipids of cationic forms of procaine, tetracaine, and dibucaine in small unilamellar phosphatidylcholine vesicles as studied by nuclear Overhauser effects in 1H nuclear magnetic resonance spectroscopy

Locations and dynamical perturbations for lipids of local anesthetics (procaine . HCl, tetracaine . HCl, and dibucaine . HCl) in sonicated egg yolk phosphatidylcholine (PC) vesicles have been studied by 1H-1H nuclear Overhauser effect (NOE) measurements. It was found that tetracaine and dibucaine bind much strongly to the neutral lipids than does procaine and that their mobilities are lowered to such an extent that spin diffusion is transmitted (i.e., omega 2 tau c2 much greater than 1). The intermolecular NOEs between drugs and PC were more effective in the case of dibucaine than with tetracaine, indicating that dibucaine binds to the lipids more strongly than tetracaine; this order agrees well with that of anesthetic potency. However, it was only tetracaine that gave any appreciable dynamical perturbation to the PC vesicles when they were monitored by the extent of transfer of the negative NOE from alpha-methylene protons to choline methyls, olefinic methines, acyl methylenes and terminal methyl protons. This finding was interpreted as being due to the differences in the locations of these drugs in small unilamellar vesicles: (1) procaine interacts with lipids very weakly at the outer surface of the vesicles; (2) tetracaine binds to the lipids both at the outer and inner halves of the bilayer, inserting its rod-like molecule in a forest of acyl chains of PC; (3) dibucaine binds tightly to the polar head-group of PC, which resides only at the outer half of the bilayer vesicles. It was concluded that the relative order of anesthetic potency within these drugs can be correlated not with the ability to affect membrane fluidity but with the ability to bind to lipids at the polar head-group of the bilayer vesicles.     

Ca2+-induced phosphatidylcholine vesicle aggregation in the presence of ferricyanide

The titration of sonicated vesicles of egg phosphatidylcholine with ferricyanide in the presence of Ca2+ results in the formation of aggregates. The turbidity increase caused by these aggregates cannot be reversed by EDTA treatment. In addition, no rearrangement of the bilayer structure has been found in this process, either measuring leakage of vesicle content or exchange of lipids among the bilayers themselves. The aggregation is dependent on the Ca2+ content of the vesicles, the outer Ca2+ and Fe(CN)3-(6) concentration and the order of addition of Ca2+ and ferricyanide. The results can be explained by a specific adsorption of Fe(CN)3-(6) to bilayers of sonicated vesicles, in contrast to other multivalent anions. In contrast to the stability found with sonicated vesicles, the aggregation causes a leakage of the internal solution when multilamellar liposomes are titrated with Fe(CN)3-(6).     

Effect of temperature on Ca-ATPase from sarcoplasmic reticulum membranes: ESR studies

Using spin-labeled fatty acid derivatives and maleimide, the effect of temperature on the structural state of various parts of the lipid bilayer of sarcoplasmic reticulum (SR) membranes and the segmental motion of the Ca-ATPase molecule were investigated. The mobility of the spin probes localized in the hydrophobic zone and the outer part of the SR membrane was shown to increase with a rise in temperature from 4 to 44 degrees C, the temperature of 20 degrees C being critical for these changes. In the presence of ATP, critical changes in the spin probe mobility occur at lower temperatures, while in the presence of ATP and Ca2+ they are observed at 20 degrees C for a spin probe localized in the outer part of the SR membrane. The mobility of a spin probe localized in the hydrophobic part of the membrane increases linearly with a rise in temperature. In the absence of ligands, the segmental motion of Ca-ATPase changes linearly within a temperature range of 10-30 degrees C. However, when ATP alone or ATP and Ca2+ are simultaneously added to the incubation mixture, the protein mobility undergoes critical changes at 20 degrees C. The Arrhenius plots for ATPase activity and Ca2+ uptake rate in SR membrane preparations also have a break at 20 degrees C. It is assumed that changes in the structural state of membrane lipids produce conformational changes in the Ca-ATPase molecule; the enzyme seems to be unsensitive to the structural state of the membrane lipid matrix in the absence of the ligands.     

Electron microscopic investigation of the morphology and calcium-induced fusion of lipid vesicles with an oligomerised inner leaflet

The lipid head groups in the inner leaflet of unilamellar bilayer vesicles of the synthetic lipids DHPBNS and DDPBNS can be selectively oligomerised. Earlier studies have established that these vesicles fuse much slower and less extensively upon oligomerisation of the lipid head groups. The morphology and calcium-induced fusion of vesicles of DHPBNS and DDPBNS were investigated using cryo-electron microscopy. DHPBNS vesicles are not spherical but flattened, ellipsoidal structures. Upon addition of CaCl(2), DHPBNS vesicles with an oligomerised inner leaflet were occasionally observed in an arrested hemifused state. However, the evidence for hemifusion is not equivocal due to potential artefacts of sample preparation. DDPBNS vesicles show the expected spherical morphology. Upon addition of excess CaCl(2), DDPBNS vesicles fuse into dense aggregates that show a regular spacing corresponding to the bilayer width. Upon addition of EDTA, the aggregates readily disperse into large unilamellar vesicles. At low concentration of calcium ion, DDPBNS vesicles with an oligomerised inner leaflet form small multilamellar aggregates, in which a spacing corresponding to the bilayer width appears. Addition of excess EDTA results in slow dispersal of the Ca2+-lipid aggregates into a heterogeneous mixture of bilamellar, spherical vesicles and networks of thread-like vesicles. These lipid bilayer rearrangements are discussed within the context of shape transformations and fusion of lipid membranes.     

A spin-label study of the viscosity profile of sarcoplasmic reticular vesicles.

Sarcoplasmic reticular vesicles were prepared from both lobster and rabbit muscle. A variety of water-soluble, lipid-soluble, and alkylating spin labels were used to treat the sarcoplasmic reticular vesicles. All spin label analyses were carried out with and without NiCl₂. Nickel is used to remove spin label signal originating from outside of, on the surface of, or localized in the outermost part of the outer bilayer half of the sarcoplasmic reticular membrane.We conclude that the hydrocarbon portion of sarcoplasmic reticular vesicles has symmetry in regard to the physical properties that limit spin label motion; however, we find that the membrane interface limits spin label motion more on the inner surface than the outer surface and that the trapped aqueous volume which is sampled by water soluble spin labels inside the vesicle enclosure limits spin label motion much more than the average aqueous medium outside.     

Effects of paramagnetic shift reagents on the 13C nuclear magnetic resonance spectra of egg phosphatidylcholine enriched with 13C in the N-methyl carbons.

Effects of paramagnetic shift reagents on the 13C NMR spectra obtained from single-walled vesicle dispersions of egg phosphatidylcholine enriched with 13C in the N-methyl carbons are investigated. Spectra obtained at 25.1 MHz show that, at Yb3+ to phospholipid molar ratios as low as 0.06, complete resolution of the N-methyl carbon resonances is obtained from molecules on the inner and outer faces of the vesicle bilayer. No precipitation of the vesicles is caused by Yb3+ at these concentrations nor is appreciable line broadening observed. Other paramagnetic shift reagents frequently used in proton NMR investigations of phosphatidylcholine vesicles do not give complete separation of the N-methyl 13C signals from the two bilayer surfaces. K3Fe(CN)b,Eu3+, and Pr3+ cause precipitation of the phosphatidylcholine vesicles at concentrations, which give only incomplete resolution of these signals. T1 measurements of the resonances separated by Yb3+ indicate that the choline groups on the inner bilayer surface are less mobile than are the same groups in the outer surface. Gated proton decoupling measurements, which show that the nuclear Overhauser effect is 2.8 +/- 0.1, indicate that the dominant mode of relaxation is dipolar interaction.     

Fluorescence lifetime and quenching studies on some interesting diphenylhexatriene membrane probes

The fluorescence lifetimes of a number of membrane probes based on the 1,6-diphenylhexatriene (DPH) chromophore have been measured in small unilamellar phospholipid vesicles and found to be multiphasic. These probes were quenched by sodium iodide with different efficiencies in vesicles and this has been attributed to the depth of the particular probe in the bilayer. The distribution of the probe between the outer and inner monolayer has been determined for those probes with fixed positions in the bilayer. The iodide ion permeability of the bilayer was found to be immeasurably small over a 3 h period.     

A new electron spin resonance assay for membrane asymmetry and entrapped volume of unilamellar lipid vesicles based on photoreduced flavin adenine dinucleotide

A new ESR assay has been developed for the characterization of unilamellar lipid vesicles. It is based on the reduction by photogenerated FADH2 of amphiphilic spin-labels having the spin in the polar group. FADH2 is generated in situ under anaerobic conditions from its oxidized form (FAD) by photoreduction in the presence of excess EDTA as the reducing agent. Photoreduction is induced by exposing the FAD/EDTA mixture to white light of a commercial slide projector. FADH2 as an impermeable agent reduces spin-label molecules located on the outer layer of the bilayer that are readily accessible in a first fast reaction; spin-label located on the inner layer of the bilayer is reduced in a second slow reaction. The ESR assay is suitable for the routine characterization of unilamellar membrane vesicles: it allows the determination of the vesicle size, the entrapped volume, the bilayer asymmetry, the bilayer integrity, and the vesicle stability. The ESR assay developed is of general applicability: it can be used with charged and uncharged bilayers which may be labeled with either neutral or charged spin-labels. An assessment of the new ESR assay is given in comparison to the existing ascorbate method which uses sodium ascorbate as the reducing agent. Various other potential reducing agents for spin-labels have been tested and found unsuitable for the ESR assays discussed here.     

Characteristics of the interaction of melittin with sarcoplasmic reticulum membranes.

Addition of an amphipathic bee venom peptide, melittin, to sarcoplasmic reticulum (SR) vesicles isolated from rabbit skeletal muscles resulted in a fast (<1 min) blue shift in the fluorescence maximum of the melittin--SR membrane complex. Over the following 45 min the position of the fluorescence maximum did not change, but the fluorescence intensity of the melittin--SR membrane complex decreased by approximately 35% with rate constant 0.14 min-1. Melittin rapidly quenched the isotropic signal in the EPR spectrum of spin-labeled stearic acid added to SR membranes. Further changes in the spectral parameters of the spin probe bound to SR membranes in the presence of melittin indicated an increase of the viscosity of the probe microenvironment (empiric parameter T/eta was decreased by approximately 35% with rate constant 0.11 min-1). The surface potential of SR membranes measured using a pH-sensitive dye, neutral red, decreased after melittin addition from -60 to -30 mV. It was demonstrated with the use of a cross-linking agent, cupric o-phenanthroline, that melittin induced slow aggregation of Ca-ATPase protein in SR membranes; the content of enzyme in the monomeric form decreased with rate constant 0.14 min-1. It is concluded that melittin binds rapidly to SR membranes, inducing slow changes in Ca-ATPase conformation and oligomeric state as well as structural transitions in the lipid bilayer of SR membranes.     

NMR, calorimetric, spin-label, and optical studies on a trifluoromethyl-substituted styryl molecular probe in dimyristoylphosphatidylcholine vesicles and multilamellar suspensions: a model for location of optical probes

NMR, calorimetric, and optical spectroscopic studies have been performed on a trifluoromethyl-substituted styryl molecular probe bound to vesicles and multilamellar suspensions formed from dimyristoylphosphatidylcholine (DMPC). In the fluorine NMR spectrum at 35 degrees C there are two partially resolved resonances, but these collapse to an apparently single resonance at temperatures above 60 degrees C. However, a line-shape analysis is not consistent with exchange between two sites on an NMR time scale, and the two resonances are assumed to be due to probe sites in the inner and outer leaflets of the vesicles. Two fluorescence lifetimes, each associated with one of these sites, characterize the decay curves for the molecular probe bound to DMPC vesicles. The shift reagent Eu(FOD)3 and several nitroxide spin labels covalently bound to lipophilic structures strongly attenuate the lower frequency component of the fluorine NMR spectrum and also shift the other resonance to higher frequencies. The effect of two spin labels on the probe fluorine T2 relaxation time has been used to estimate the distance between the spin label unpaired electron and the trifluoromethyl group. The location of the spin label site in the membrane was determined from the effect of the unpaired electron on the lipid 13C linewidths. A model for the location of the probe in the bilayer was developed from the above information and refined using molecular mechanics calculations on a probe-DMPC lipid complex. The long axis of the probe parallels the bilayer normal; the styryl-group portion of the optical chromophore is located slightly below the glycerol backbone, and the remainder of the chromophore extends well into the hydrophobic region of the bilayer. Therefore, the optical properties of the probe should not be significantly influenced by alterations of the membrane surface charge density. Parameters derived from DSC studies in the gel-to-lipid crystal phase transition of DMPC are extremely sensitive to the probe. Even at 0.0001 mol fraction of probe, the transition is substantially broadened, and the delta H for the transition has increased, just as one predicts for the formation of a tight complex described above.     

An evaluation of paramagnetic broadening agents for spin probe studies of intact mammalian cells.

Six transition metal ion complexes have been examined for their effects on the cell survival as well as their effectiveness in inducing the broadening of the electron spin resonance (ESR) spectra of nitroxide spin probes. These paramagnetic species are Ni(EDTA), Ni(DTPA), potassium tris(oxalato) chromate (chromium oxalate), K3Fe(CN)6, Cu(DTPA), and NiCl2. At 100 mM concentration, the typical concentration used in cell studies to broaden the extracellular nitroxide ESR signal, only Ni(EDTA) and Ni(DTPA) are found to be non-toxic to Chinese hamster ovary cells. The relative cytotoxicities of the six metal ion complexes are Cu(DTPA) greater than K3Fe(CN)6 greater than NiCl2 greater than chromium oxalate greater than Ni(DTPA) greater than Ni(EDTA). Thus, potassium ferricyanide and NiCl2, two most commonly used paramagnetic broadening agents, are relatively toxic to the cell. In contrast, among the six paramagnetic species tested here, chromium oxalate appears to be the most effective agent at non-toxic concentrations in inducing the broadening of the ESR spectra of both cationic and neutral nitroxide spin probes. By considering both their cytotoxicity and their effectiveness in causing line broadening of the nitroxide ESR spectra, chromium oxalate is a good paramagnetic broadening agent for spin probe studies of intact mammalian cells.     

Rapid transbilayer movement of phospholipids induced by an asymmetrical perturbation of the bilayer

Phospholipase D is used to convert egg phosphatidylcholine to phosphatidic acid in unilamellar vesicles. The transbilayer distribution of both lipids is determined by 31P NMR using paramagnetic ions. Phosphatidic acid formed in the outer monolayer is translocated to the inner monolayer with a halftime of 30-40 min or less. This is accompanied by an equally fast movement of part of the phosphatidylcholine from the inner to the outer monolayer. During these fast transbilayer movements the barrier properties of the vesicle bilayer are maintained.     

Use of an oriented transmembrane protein to probe the assembly of a supported phospholipid bilayer.

Planar-supported phospholipid bilayers formed by the adsorption of vesicles are increasingly used in the investigation of lipid-dependent reactions. We have studied the way in which these bilayers are formed with phospholipid vesicles containing the transmembrane protein Tissue Factor (TF). TF complexed with the serine protease, factor VIIa, is the primary initiator of blood coagulation by way of activation of the zymogen factor X. TF has been shown to orient randomly on the inner and outer leaflets of vesicles. We used proteolytic digestion to produce vesicles in which the extracellular domain of TF is located on the inner leaflet. These vesicles show no cofactor activity for factor VIIa as a result of the inability of the extracellular domain of TF to bind VIIa. After freeze/thawing, 50% of the cofactor activity was regained, indicating reorientation of the sequestered, inner leaflet TF. Adsorption of these vesicles to the inner surface of glass microcapillaries results in a continuous phospholipid bilayer. The microcapillaries were perfused with a solution of factors VIIa and X, and the effluent was monitored for factor Xa production, a sensitive measure of the activity of the TF-VIIa complex. For coatings produced with the digested vesicles, minimal TF-VIIa activity was observed, showing that the supported bilayer preserves the orientation of the leaflets in the vesicles, i.e., the outer leaflet of the vesicles forms the outer leaflet of the supported bilayer.     

Age-dependent effect of oxidative stress on cardiac sarcoplasmic reticulum vesicles

The oxidative stress hypothesis of aging suggests that accumulation of oxidative damage is a key factor of the alterations in physiological function during aging. We studied age-related sensitivity to oxidative modifications of proteins and lipids of cardiac sarcoplasmic reticulum (SR) isolated from 6-, 15- and 26-month-old rats. Oxidative stress was generated in vitro by exposing SR vesicles to 0.1 mmol/l FeSO4/EDTA + 1 mmol/l H2O2 at 37 degrees C for 60 min. In all groups, oxidative stress was associated with decreased membrane surface hydrophobicity, as detected by 1-anilino-8-naphthalenesulfonate as a probe. Structural changes in SR membranes were accompanied by degradation of tryptophan and significant accumulation of protein dityrosines, protein conjugates with lipid peroxidation products, conjugated dienes and thiobarbituric acid reactive substances. The sensitivity to oxidative damage was most pronounced in SR of 26-month-old rat. Our results indicate that aging and oxidative stress are associated with accumulation of oxidatively damaged proteins and lipids and these changes could contribute to cardiovascular injury.     

Phospholipid Flip-Flop and the Distribution of Surface Charges in Excitable Membranes

There is now good evidence that most of the lipids in a biological membrane are arranged in the form of a bilayer. Charged lipids in the membrane of an excitable cell are subject to a significant driving force, the gradient of the intramembrane potential, which will tend to redistribute the lipids between the two halves of the bilayer by a “phospholipid flip-flop” mechanism. We have calculated, by combining the Boltzmann relation from statistics and the Gouy equation from the theory of the diffuse double layer, the steady-state distribution of charged lipids in the bilayer. This distribution is completely determined, within the framework of the model, by three experimentally accessible variables; the percentage of charged lipid in the bilayer as a whole, the resting potential and the ionic strength. The known values for the percentage of anionic phospholipids in squid axons (10-15%), the membrane potential (50-100 mV) and ionic strength (0.5 M) imply that the charge density and double layer potential at the outer surface of the nerve will be substantially greater than the charge density and double layer potential at the inner surface, in agreement with the best available evidence from physiological measurements.     

The effect of surface curvature on the head-group structure and phase transition properties of phospholipid bilayer vesicles

Proton nuclear magnetic resonance spectra at 360 MHz of small sonicated distearoyl phosphatidylcholine vesicles show easily distinguishable resonances due to choline N-methyl head-group protons located in the inner and outer bilayer halves. A study of the chemical shift of these resonances as a function of temperature reveals that the splitting between them increases below the phase transition. This occurs as a result of an upfield shift of the inner layer resonance at the phase transition. Consideration of the possible causes of this effect results in the conclusion that, at the phase transition, there is a change in the organization of the inner layer head-groups which does not occur for the outer layer head-groups.     

Membrane asymmetry and enhanced ultrastructural detail of sarcoplasmic reticulum revealed with use of tannic acid

Fixation of purified sarcoplasmic reticulum (SR) membrane vesicles, using glutaraldehyde supplemented with 1% tannic acid, reveals newly visualized ultrastructure in thin sections. The trilaminar appearance of the membrane is highly asymmetric; the outer electron-opaque layer is appreciably wider (70 A) than the inner layer (20 A). The asymmetry is not referable to lack of penetration of the tannic acid since: (a) SR vesicles made permeable with 1 mM EDTA, pH 8.5, show similar asymmetry; (b) treatment of SR with trypsin results in progressive loss in protein content and decrease in the thickness of the outer layer, until in the limit the trilayer has a symmetric appearance; (c) within the same muscle section, the SR membrane appears highly asymmetric whereas the sarcolemma has a more symmetric appearance; (d) reconstituted SR vesicles have a symmetric appearance with equally broad inner and outer layers (approximately 70 A); the symmetric structure is confirmed by freeze-fracture and negative staining electron microscopy. Heavy and light SR vesicles obtained by isopycnic density sedimentation of purified SR have the same asymmetric appearance of the membrane and seem to differ mainly in that the heavy vesicles contain internal contents consisting largely of Ca++-binding protein. The asymmetry of the SR membrane is referable mainly to the unidirectional alignment of the Ca++ pump protein, the major component (90% of the protein) of the membrane. The asymmetry of the SR membrane can be visualized now for the first time in situ in thin sections of muscle.     

Phosphatidylserine Asymmetry Promotes the Membrane Insertion of a Transmembrane Helix

The plasma membrane (PM) contains an asymmetric distribution of lipids between the inner and outer bilayer leaflets. A lipid of special interest in eukaryotic membranes is the negatively charged phosphatidylserine (PS). In healthy cells, PS is actively sequestered to the inner leaflet of the PM, but PS redistributes to the outer leaflet when the cell is damaged or at the onset of apoptosis. However, the influence of PS asymmetry on membrane protein structure and folding are poorly understood. The pH low insertion peptide (pHLIP) adsorbs to the membrane surface at a neutral pH, but it inserts into the membrane at an acidic pH. We have previously observed that in symmetric vesicles, PS affects the membrane insertion of pHLIP by lowering the pH midpoint of insertion. Here, we studied the effect of PS asymmetry on the membrane interaction of pHLIP. We developed a modified protocol to create asymmetric vesicles containing PS and employed Annexin V labeled with an Alexa Fluor 568 fluorophore as a new probe to quantify PS asymmetry. We observed that the membrane insertion of pHLIP was promoted by the asymmetric distribution of negatively charged PS, which causes a surface charge difference between bilayer leaflets. Our results indicate that lipid asymmetry can modulate the formation of an α-helix on the membrane. A corollary is that model studies using symmetric bilayers to mimic the PM may fail to capture important aspects of protein-membrane interactions.     

Rearrangement of aminophospholipids in bilayers from sheep platelet plasma membranes and platelet liposomes by increasing their cholesterol levels

Phospholipid orientation in platelet plasma membranes and other blood cells, such as erythrocytes, appears to be rather similar. The negatively charged phospholipids are almost exclusively located on the inner leaflet of the bilayer. No phosphatidylserine is present on the outer membrane bilayer. The results of the present study, using a specific reagent for amino groups, trinitrobenzenesulfanilic acid, showed that in sheep platelet plasma membranes enriched with free exogenous cholesterol, an alteration in the aminophospholipid topology occurs, with a portion of phosphatidylserine moving from the inner to the outer side. A progressive appearance of aminophospholipids in the outer membrane bilayer was also observed in artificial vesicles prepared with total lipids from sheep platelets supplemented with increased amounts of free cholesterol.     

Interaction of Salmonella typhimurium with phospholipid vesicles. Incorporation of exogenous lipids into intact cells.

Incubation of intact cells of Salmonella typhimurium with bilayer phospholipid vesicles results in significant transfer of vesicle lipids to the cells. The transfer requires Ca2+ or spermine, and is dependent on time, temperature, the concentration and composition of the vesicles, and the nature of the cellular lipopolysaccharide. The process results in bulk transfer of vesicle lipids to the cells rather than reciprocal molecular exchange between vesicles and the outer membrane. All components of mixed lipid vesicles, including cholesteryl oleate and lipopolysaccharide, are transferred to the cells in a ratio similar to that of the donor vesicles. The properties of the transfer process are consistent with direct fusion of vesicles with the outer membrane of the cell.