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.     

Apocytochrome c binding to negatively charged lipid dispersions studied by spin-label electron spin resonance

The interaction of apocytochrome c with aqueous dispersions of phosphatidylserine from bovine spinal cord and with other negatively charged phospholipids has been studied as a function of pH and salt concentration by using spin-label electron spin resonance (ESR) spectroscopy and chemical binding assays. The ESR spectra of phospholipids spin-labeled at different positions on the sn-2 chain indicate a generalized decrease in mobility of the lipids, while the characteristic flexibility gradient toward the terminal methyl end of the chain is maintained, on binding of apocytochrome c to phosphatidylserine dispersions. This perturbation of the bulk lipid mobility or ordering is considerably greater than that observed on binding of cytochrome c. In addition, a second, more motionally restricted, lipid component is observed with lipids labeled close to the terminal methyl ends of the chains. This second component is not observed on binding of cytochrome c and can be taken as direct evidence for penetration of apocytochrome c into the lipid bilayer. It is less strongly motionally restricted than similar spectral components observed with integral membrane proteins and displays a steep flexibility gradient. The proportion of this second component increases with increasing protein-to-lipid ratio, but the stoichiometry per protein bound decreases from 4.5 lipids per 12 000-dalton protein at low protein contents to 2 lipids per protein at saturating amounts of protein. Apocytochrome c binding to phosphatidylserine dispersions decreases with increasing salt concentration from a saturation value corresponding to approximately 5 lipids per protein in the absence of salt to practically zero at 0.4 M NaCl.(ABSTRACT TRUNCATED AT 250 WORDS)     

The binding of tyrosine hydroxylase to negatively charged lipid bilayers involves the N-terminal region of the enzyme

Tyrosine hydroxylase (TH) is the rate-limiting enzyme in the synthesis of catecholamines. We have studied the association of recombinant human TH with model membranes by using either liposomes or silica gel beads coated with single phospholipid bilayers (TRANSIL). The use of TRANSIL beads has allowed the determination of apparent dissociation constants (Kd) for the binding of the enzyme to negatively charged bilayers (Kd=230-380 microM, at pH 6.0-7.0). Binding to the bilayers is accompanied by a decrease in enzyme activity. Proteolysed forms of the enzyme show decreased binding affinity and two putative amphipathic N-terminal alpha-helices are proposed to be involved in membrane binding. As seen by circular dichroism, binding to the bilayer does not seem to induce significant changes on the secondary structure content of the enzyme, but alpha-helical structures appear to be stabilized against thermal denaturation in the membrane-bound state. Thus, amphitropism, a mechanism that regulates the function of peripheral proteins by weak binding to membrane lipids, may add to the factors that regulate both the activity and the stability of TH.     

Covalent binding of negatively charged phospholipid to Na,K-ATPase

Phosphatidylglycolaldehyde and its lyso derivative were applied as probes in order to study lipid-protein interactions with purified, membrane-bound Na,K-ATPase. Reduction with [3H]NaCNBH3 led to formation of a stable chemical derivative between added lipid and protein. The extent of modification of the two subunits of Na,K-ATPase was similar. Extensive tryptic digestion of derivatized ATPase resulted in cleavage of the alpha-subunit without hydrolysis of the beta-subunit.     

Adsorption of polyvalent cations to bilayer membranes from negatively charged lipid: estimating the lipid accessibility in the case of complete binding

The effect of trivalent (Gd(3+) and Yb(3+)) and divalent (Be(2+) and Ca(2+)) cations on suspensions of multilamellar liposomes formed from brain PS and DMPS has been studied using microelectrophoresis and DSC techniques, respectively. The zeta potential values have been shown to strongly depend on the total lipid concentration in the suspension. At moderate concentrations of the polyvalent cations, the total cation concentration exceeds the bulk one several times due to adsorption of cations to the liposomes. A modification of the Gouy-Chapman-Stern theory in the case of unknown bulk concentration of the polyvalent cation is presented. An intrinsic association constant for Be(2+) ions was evaluated to be about K(2) approximately 50 M(-1). The algorithm for estimating the concentrations of the accessible (to exogenously added polyvalent cations) lipid-binding sites is described. These values are consistent with the subsurface concentrations of the polyvalent cations, which monotonously increase with the total concentration of the polyvalent cations. The calculated lipid accessibilities are shown to be in accordance with the DSC data.     

Interaction of electrically charged lipid monolayers with malate dehydrogenase

Malate dehydrogenase was adsorbed onto monomolecular lipid films, using a multicompartment trough. The quantity of adsorbed protein and its enzymatic activity were studied with monolayers of various electrical charge densities and subphases of various electrolyte compositions. A closely packed layer of enzyme molecules was adsorbed onto negatively charged films, whereas considerably less protein was adsorbed onto neutral and positively charged monolayers. Electrolytes reduce the quantity of adsorbed protein. The adsorption was found to be irreversible even at high ionic strength. When adsorbed to uncharged lipid films the enzyme is nearly inactive, whereas negatively charged lipid headgroups enhance the specific activity of the enzyme.     

Deuterium and phosphorus nuclear magnetic resonance studies on the binding of polymyxin B to lipid bilayer-water interfaces

Deuterium and phosphorus NMR methods have been used to study the binding of polymyxin B to the surface of bilayers containing lipids that were deuterated at specific positions in the polar head-group region. The binding of polymyxin B to acidic dimyristoylphosphatidylglycerol (DMPG) membranes induces only small structural distortions of the glycerol head group. The deuterium spin-lattice relaxation times for the different carbon-deuterium bonds in the head group of the same phospholipid are greatly reduced on binding of polymyxin B, indicating a restriction of the motional rate of the glycerol head group. Only very weak interactions were detected between polymyxin B and bilayers of zwitterionic dimyristoylphosphatidylcholine (DMPC). In mixed bilayers of the two phospholipid types, in which either of the two phospholipids was deuterated, the presence of polymyxin B caused a lateral phase separation into DMPG-enriched phospholipid-peptide clusters and a DMPG-depleted phase. Complete phase separation did not occur: peptide-containing complexes with charged phosphatidylglycerol contained substantial amounts of zwitterionic phosphatidylcholine. Exchange of both phospholipid types between complexes and the bulk lipid matrix was shown to be fast on the NMR time scale, with a lifetime for phospholipid-peptide association of less than 1 ms.     

Serum-induced leakage of negatively charged liposomes at nanomolar lipid concentrations

An enzyme inhibition assay was developed to determine methotrexate-gamma-aspartate leakage from liposomes at lipid concentrations as low as 43 nM phospholipid. When negatively charged liposomes prepared with phosphatidylglycerol/cholesterol 67:33 or phosphatidylinositol/cholesterol 67:33 were incubated in 10% (v/v) newborn calf serum, they leaked over 90% of their contents in 2 min. In contrast, liposomes prepared from phosphatidylcholine/cholesterol 67:33 leaked 18% of their contents under the same conditions. The amount of negative charge required to induce liposome leakage was determined by preparing liposomes with varying amounts of phosphatidylglycerol and phosphatidylcholine. Extensive leakage was observed only from liposomes prepared with greater than 50 mol of phosphatidylglycerol per 100 mol of phospholipid. The effect of the phase transition temperature on leakage of negatively charged liposomes in 10% (v/v) serum was investigated by using a series of phosphatidylglycerols with varying acyl chain lengths. Liposomes prepared from distearoylphosphatidylglycerol or dipalmitoylphosphatidylglycerol leaked less than 18% of their contents in 10% serum, whereas liposomes prepared with dilauroylphosphatidylglycerol or unsaturated lipids leaked more than 70% of their contents. Lipoprotein removal from serum followed by treatment with lipid to remove residual apoproteins reduced the leakage from phosphatidylglycerol liposomes in 10% serum. Phosphatidylglycerol liposomes leaked 73% in the presence of human low-density lipoproteins, but only 29% in the presence of bovine apolipoprotein A-I, and 25% in the presence of human high-density lipoproteins. Phosphatidylglycerol/cholesterol and phosphatidylserine/cholesterol liposomes leaked 67% in 4 mg/mL bovine serum albumin purified by cold ethanol extraction. The leakage of liposomes in albumin solutions could be substantially reduced by treating the albumin with lipid.(ABSTRACT TRUNCATED AT 250 WORDS)     

Anion binding to neutral and positively charged lipid membranes

Aqueous anion binding to bilayer membranes consisting of 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) was investigated by using deuterium and phosphorus-31 nuclear magnetic resonance (NMR) spectroscopy. Only those anions that exhibit chaotropic properties showed significant binding to POPC membranes. A detailed investigation of thiocyanate binding to neutral POPC and to positively charged mixed POPC/dihexadecyldimethylammonium bromide (DHDMAB) (8:2 mol/mol) membranes revealed changes in the 2H NMR quadrupole splittings from POPC specifically deuteriated at either the alpha-segment or the beta-segment of the choline head group which were consistent with a progressive accumulation of excess negative charge at the membrane surface with increasing SCN- concentration. Both the 2H and 31P NMR spectra indicated the presence of fluid lipids in a bilayer configuration up to at least 1.0 M NaSCN with no indication of any phase separation of lipid domains. Calibration of the relationship between the change in the 2H NMR quadrupole splitting and the amount of SCN- binding provided thiocyanate binding isotherms. At a given SCN- concentration the positively charged membranes bound levels of SCN- 3 times that of the neutral membranes. The binding isotherms were analyzed by considering both the electrostatic and the chemical equilibrium contributions to SCN- binding. Electrostatic considerations were accounted for by using the Gouy-Chapman theory. For 100% POPC membranes as well as for mixed POPC/DHDMAB (8:2 mol/mol) membranes the thiocyanate binding up to concentrations of 100 mM was characterized by a partition equilibrium with an association constant of K approximately 1.4 +/- 0.3 M-1.(ABSTRACT TRUNCATED AT 250 WORDS)     

Use of spin labels to determine the percentage of interdigitated lipid in complexes with polymyxin B and polymyxin B nonapeptide

Long chain spin labels with the nitroxide group located near the terminal methyl of the chain were used to determine the percentage interdigitated lipid in complexes of polymyxin B (PMB) and polymyxin B nonapeptide (PMBN) with the acidic lipids dipalmitoylphosphatidylglycerol (DPPG) and dipalmitoylphosphatidic acid (DPPA) at varying mole ratios of drug to lipid and at different pH values. These spin labels are more motionally restricted in the interdigitated than in the non-interdigitated gel phase bilayer. This allows determination of the percentage interdigitated lipid by resolution of the spectrum into motionally restricted and more mobile components. At nonsaturating concentrations of PMB, significantly more DPPG than that which can be maximally PMB-bound, becomes interdigitated. As the temperature approaches the gel to liquid crystalline phase transition temperature, the bilayer becomes progressively non-interdigitated. The ESR spectrum indicates that PMB also causes interdigitation of DPPA. However, in contrast to DPPG, the amount of DPPA which is interdigitated at pH 6, is less than the amount which is expected to be PMB-bound. This is attributed to the ability of DPPA to participate in lateral interlipid hydrogen bonding interactions. Such lateral interactions would be abolished in the interdigitated bilayer and thus they are expected to inhibit its formation. At pH 9, where the interlipid interactions of DPPA are weakened, PMB induces even more lipid than that which is PMB-bound to become interdigitated. Indeed, the percentage interdigitated lipid is even greater than found for DPPG. This may be partly a result of the greater negative charge of DPPA at this pH. A greater repulsive negative charge is expected to favor interdigitation. PMBN is less effective than PMB at inducing interdigitation of DPPG and causes little or no interdigitation of DPPA at pH 6, even at saturating concentrations. PMBN also does not lower the phase transition temperature of DPPA at pH 6 as much as PMB. At pH 9, the effect of PMBN on DPPA is more similar to the effect of PMB. However, even for DPPG, and DPPA at pH 9, PMBN does not maintain interdigitation of the lipids at higher temperatures as effectively as PMB. PMBN's smaller perturbing effect and greatly decreased ability to cause interdigitation of DPPA at pH values below 9 may be related to a decreased ability to cause lateral separation of the lipid molecules, which is necessary in order to weaken the interlipid interactions.(ABSTRACT TRUNCATED AT 400 WORDS)     

Interaction of electrically charged lipid monolayers with malate dehydrogenase.

Malate dehydrogenase was adsorbed onto monomolecular lipid films, using a multicompartment trough. The quantity of adsorbed protein and its enzymatic activity were studied with monolayers of various electrical charge densities and subphases of various electrolyte compositions. A closely packed layer of enzyme molecules was adsorbed onto negatively charged films, whereas considerably less protein was adsorbed onto neutral and positively charged monolayers. Electrolytes reduce the quantity of adsorbed protein. The adsorption was found to be irreversible even at high ionic strength. When adsorbed to uncharged lipid films the enzyme is nearly inactive, whereas negatively charged lipid headgroups enhance the specific activity of the enzyme.     

Interfacial pH at electrically charged lipid monolayers investigated by the lipid pH-indicator method

Monomolecular films of various charge densities are prepared by mixing methylstearate with long chain sulfate and quaternary ammonium ions. A lipoid fluorescence pH indicator is embedded in the charged interface. Interfacial pH changes are detected as a function of the charge density of the monolayer and the NaCl concentration of the subphase. In the case of the positive films the results are in agreement with the Gouy-Chapman theory of the diffuse double layer. In the case of the negative film significant deviations are found.     

The fusogenic effect of synthetic polycations on negatively charged lipid bilayers

The effect of synthetic polycations, polyallylamine, and polyethylenimine, on liposomes containing phosphatidylserine was investigated along with that of polylysine and divalent cations. The addition of polycations caused aggregation of sonicated vesicles composed of phosphatidylserine and phosphatidylcholine (molar ratio 1:4) as determined by measuring the turbidity changes. Liposomal turbidity increased 10 times compared with that of control liposomes at charge ratios of polymer/vesicle from 0.23 (polylysine) to 2.5 (linear polyethylenimine), while the turbidity was unchanged by the addition of Ca2+ or Mg2+ at charge ratios up to 500. These polycations also induced intermixing of liposomal membranes as indicated by resonance energy transfer between fluorescent lipids incorporated in lipid bilayers, without inducing drastic permeability changes as determined from the calcein release. Fifty percent intermixing of liposomes (0.05 mM as lipid concentration) was induced by these polycations at charge ratios of around 1.0. However, the highest resonance energy transfer was produced by the addition of polyallylamine, which caused multicycles of membrane intermixing between vesicles. Polycation-induced membrane intermixing and permeability changes of phosphatidylserine liposomes were also investigated. At charge ratios of around 1.0, these polymers caused resonance energy transfer of fluorescent lipids incorporated in separate vesicles; however, polyallylamine and branched polyethylenimine also caused permeability increases of liposomal membranes. Membrane intermixing and permeability changes of phosphatidylserine vesicles induced by polyallylamine were dependent on the polymer/vesicle charge ratio, and were different from those induced by Ca2+ since the latter caused half-maximal membrane intermixing or permeability change of phosphatidylserine vesicles at about 1 mM at the liposomal concentrations investigated.     

Membrane potential-dependent binding of polysialic acid to lipid monolayers and bilayers

Polysialic acids are linear polysaccharides composed of sialic acid monomers. These polyanionic chains are usually membrane-bound, and are expressed on the surfaces of neural, tumor and neuroinvasive bacterial cells. We used toluidine blue spectroscopy, the Langmuir monolayer technique and fluorescence spectroscopy to study the effects of membrane surface potential and transmembrane potential on the binding of polysialic acids to lipid bilayers and monolayers. Polysialic acid free in solution was added to the bathing solution to assess the metachromatic shift in the absorption spectra of toluidine blue, the temperature dependence of the fluorescence anisotropy of DPH in liposomes, the limiting molecular area in lipid monolayers, and the fluorescence spectroscopy of oxonol V in liposomes. Our results show that both a positive surface potential and a positive transmembrane potential inside the vesicles can facilitate the binding of polysialic acid chains to model lipid membranes. These observations suggest that these membrane potentials can also affect the polysialic acid-mediated interaction between cells.     

Binding of GAPR-1 to negatively charged phospholipid membranes: Unusual binding characteristics to phosphatidylinositol

Abstract

Golgi-Associated Plant Pathogenesis-Related protein 1 (GAPR-1) is a mammalian protein that belongs to the superfamily of plant pathogenesis-related proteins group 1 (PR-1). GAPR-1 strongly associates with lipid rafts at the cytosolic leaflet of the Golgi membrane. The myristoyl moiety at the N-terminus of GAPR-1 contributes to membrane binding but is not sufficient for stable membrane anchorage. GAPR-1 is positively charged at physiological pH, which allows for additional membrane interactions with proteins or lipids. To determine the potential contribution of lipids to membrane binding of GAPR-1, we used a liposome binding assay. Here we report that non-myristoylated GAPR-1 stably binds liposomes that contain the negatively charged lipids phosphatidylserine, phosphatidylglycerol, phosphatidylinositol, or phosphatidic acid. GAPR-1 displays the highest preference for phosphatidic acid-containing liposomes. In contrast, lysozyme, which contains a similar surface charge, did not bind to these liposomes, except for a weak membrane association with PA-containing liposomes. Interestingly, GAPR-1 binds to phosphatidylinositol with unusual characteristics. Denaturation or organic extraction of GAPR-1 does not result in dissociation of phosphatidylinositol from GAPR-1. The association of phosphatidylinositol with GAPR-1 results in a diffuse gel-shift in SDS-PAGE. Mass spectrometric analysis of gel-shifted GAPR-1 showed the association of up to 3 molecules of phosphatidylinositol with GAPR-1. These results suggest that the lipid composition contributes to the GAPR-1 binding to biological membranes.     

Double layer potential and degree of dissociation in charged lipid monolayers

One of the contributions to the surface potential in charged phospholipid monolayers at air-water interfaces is the double layer potential. In this note several misconceptions found in the literature concerning the relationship between the double layer potential and the degree of dissociation of the lipid polar headgroups are critically analyzed. The deviations of the double layer potential measurements from the Gouy-Chapman theory observed by several authors are explained by taking into account the dependence of the degree of dissociation with concentration, area per lipid molecule and pH.     

Electrostatic effects on the kinetics of electron transfer reactions of cytochrome c caused by binding to negatively charged lipid bilayer vesicles.

The effect of binding reduced tuna mitochondrial cytochrome c to negatively charged lipid bilayer vesicles at low ionic strength on the kinetics of electron transfer to various oxidants was studied by stopped-flow spectrophotometry. Binding strongly stimulated (up to 100-fold) the rate of reaction with the positively charged cobalt phenanthroline ion, whereas the rate of reaction with the negatively charged ferricyanide ion was greatly inhibited (up to 60-fold), as compared with the same systems either at high ionic strength or at low ionic strength either in the presence of electrically neutral vesicles or in the absence of vesicles. Reactions of tuna cytochrome c with uncharged or electrically neutral oxidants such as benzoquinone and Rhodospirillum rubrum cytochrome c2 were unaffected by binding to vesicles, suggesting little or no effect of membrane association on cytochrome structure or accessibility of the heme center. The kinetic effects were largest at lower cytochrome c to vesicle ratios, where there was a greater degree of exposure of negatively charged regions on the membrane. The reduction of cobalt phenanthroline and ferricyanide by bound cytochrome c proceeded by nonexponential kinetics, as compared with the monophasic kinetics observed in the absence of vesicles. This was probably due to the heterogeneous distribution of vesicle sizes which exists at a given lipid to protein ratio. Nonlinear oxidant concentration dependencies were observed for cobalt phenanthroline oxidation of membrane-bound cytochrome c, consistent with a (minimal) two-step kinetic mechanism involving association of the oxidant with the membrane followed by electron transfer. Based on a comparison of second-order rate constants as a function of lipid to protein mole ratio, binding of cytochrome c to the bilayer increased the efficiency of the cobalt phenanthroline reaction by a factor of approximately 500 at the highest lipid:protein ratio used. The results suggest a mechanism involving attractive and repulsive electrostatic interactions between the negatively charged bilayer and the electrically charged oxidants, which increase or decrease their effective concentrations at the membrane surface.     

Interaction of melittin with negatively charged phospholipids: consequences for lipid organization

A characterization of the structural alterations induced by melittin in model-membranes of dioleoylphosphatidic acid and egg phosphatidylglycerol is presented, based on the use of 31P-NMR, freeze-fracture electron microscopy and small angle X-ray scattering. In accordance with earlier findings on the cardiolipin-melittin system, melittin is found to have an inverted phase inducing effect on these negatively charged lipids, in contrast to the influence on zwitterionic phospholipids. In phosphatidic acid this is expressed in the formation of an HII phase; in phosphatidylglycerol a less ordered, non-lamellar structure with low water content is adopted.     

Polymyxin binding to charged lipid membranes an example of cooperative lipid-protein interaction

The binding of polymyxin-B to lipid bilayer vesicles of synthesis phosphatidic acid was studied using fluorescence, ESR spectroscopy and electron microscopy. 1,6-Diphenylhexatriene (which exhibits polarized fluorescence) and pyrene decanoic acid (which forms excimers) were used as fluorescene probes to study the lipid phase transition.The polymyxin binds strongly to negatively charged lipid layers. As a result of lipid/polymyxin chain-chain interactions, the transition temperature of the lipid. This can be explained in terms of a slight expansion of the crystalline lipid lattice (Lindeman's rule). Upon addition of polymyxin to phosphatidic acid vesicles two rather sharp phase transitions (with ΔT = 5°C) are observed. The upper transition (at T_u) is that of the pure lipid and the lower transition (at T₁) concerns the lipids bound to the peptide. The sharpness of these transitions strongly indicates that the bilayer is characterized by a heterogeneous lateral distribution of free and bound lipid regions, one in the crystalline and the other in the fluid state. Such a domain structure was directly observed by electron microscopy (freeze etching technique). In (1:1) mixtures of dipalmitoyl phosphatidic acid and egg lecithin, polymyxin induces the formation of domains of charged lipid within the fluid regions of egg lecithin.With both fluorescence methods the fraction of lipid bound to polymxin-B as a function of the peptide concentration was determined. S-shaped binding curves were obtained. The same type of binding curve is obtained for the interaction action of Ca²⁺ with phosphatidic acid lamellae, while the binding of polylysine to such membranes is characterized by a linear or Langmuir type binding curve. The S-shaped binding curve can be explained in terms of a cooperative lipid-ligand (Ca²⁺, polymyxin) interaction.A model is proposed which explains the association of polymyxing within the membrane plane in terms of elastic forces caused by the elastic distortion of the (liquid crystalline) lipid layer by this highly asymmetric peptide.