Influence of temperature on complement-dependent immune damage to liposomes

Maximal release of trapped liposomal glucose, in the presence of saturating amounts of liposomal antigen (galactocerebroside), antiserum (anti-galactocerebroside), and complement, was dependent on temperature. At lower temperatures (20--25 degrees C), maximal glucose release was inversely related to liposomal phospholipid fatty acyl chain length (dimyristoyl phosphatidylcholine > dipalmitoyl phosphatidylcholine > distearoyl phosphatidylcholine > sphingomyelin). At higher temperatures (32--35 degrees C) a limiting plateau of glucose release, at approx. 60%, was reached, or approached, by all preparations. Sphingomyelin liposomes still released less glucose than those prepared from other phospholipids, even at 35 degrees C. The titers of antiserum and complement (ABL50/ml and CL50/ml) were dependent on temperature, and differences based on liposomal phospholipid fatty acyl chain length were observed. Analysis of antiserum and complement-dependence on temperature, and on phospholipid type, revealed that although antibody binding to galactocerebroside undoubtedly was subject to steric hindrance due to interference by surrounding phospholipids at 20--25 degrees C, steric hindrance did not play a major role in blocking antibody binding above 32 degrees C.     

The influence of retinal on complement-dependent immune damage to liposomes

Retinal was incorporated into liposomes containing dipalmitoyllecithin, cholesterol, dicetyl phosphate and galactocerebroside; the latter substance served as antigen. They were compared to control liposomes, lacking retinal, with regard to glucose release due to complement-dependent immune damage in the presence of anticerebroside serum. The liposomes were indistinguishable from each other in the amount of total glucose trapped, light scattering characteristics and phosphate content. The rate and extent of glucose release in 30 min was inhibited by the incorporation of retinal. In addition, inhibition was directyl related to retinal concentration and was also observed in the presence of a wide range of concentrations of antigen and complement. Damage to liposomes in the presence of either guinea pig or human complement was inhibited by retinal; this was in contrast to the erythrocyte system in which the hemolytic activity of guinea pig complement was inhibited while that of human complement was enhanced by retinal. Addition of retinal to performed liposomes did not influence complement-dependent damage. Inhibition occurred only when retinal was present during the initial formation of the model membranes. Inhibition persisted even after washing the liposomes free of any unincorporated retinal. The data indicate that liposomes may be an excellent model for studying the influences of retinal on complement mechanism in membranes.     

Experimental verification of the model of complement-dependent immune lysis of liposomes

The quantitative dependences of the complement-dependent immune lysis of a monodisperse suspension of 200-nm liposomes sensitized by a monovalent hapten (2,4-DNP-ɛ-caproyl-DPPE) or a polyvalent antigen (LPS from Francisella tularensis) on the initial concentration of specific antibodies (IgG) to the hapten and antigen have been investigated. The quantity of antibody-binding sites on the liposome surface was evaluated. The difference between the complement-dependent lysis of poly- and monodisperse suspensions of liposomes was shown. The experimental results are well described by the direct binding model.     

Cholesterol-dependent tetanolysin damage to liposomes

Tetanolysin caused membrane damage, resulting in release of trapped glucose from liposomes containing cholesterol. Maximum glucose release occurred from liposomes that contained 50 mol% cholesterol. At higher or lower levels of cholesterol, glucose release was reduced and glucose release did not occur at all below 40 mol% cholesterol. The apparent activity of tetanolysin was not influenced by temperature (24°C compared to 32°C) or by liposomal phospholipid fatty acyl chain length. We conclude that tetanolysin caused cholesterol-dependent lysin-mediated damage to liposomes, possibly by means of a pore consisting of a complex of toxin and cholesterol.     

Influence of glycolipids on immune reactions of phospholipid antigens in liposomes

Complement-dependent immune damage to liposomes mediated by a murine monoclonal antibody to the liposomal bilayer was completely inhibited by ceramide tetrasaccharide (globoside) at an 8% concentration in the liposomes. Lower concentrations of globoside, or higher concentrations of ceramide tri-, di-, or monohexoside, were not inhibitory. At a globoside concentration of 5.8%, inhibition of the monoclonal antibody activity was reduced and inhibition was related to antibody concentration; but at 2% globoside, suppression of antibody activity was not observed at all. Analysis of space-filling models revealed that at 8% globoside the distance between adjacent tetrasaccharides of globoside approached the dimensions of the antigen-binding end of a 7S immunoglobulin molecule. We therefore propose that globoside, and perhaps other glycolipids, can exert steric hindrance to the binding of extracellular proteins to nonglycolipid constituents of the lipid bilayer. We conclude that microheterogeneity among polar groups of glycolipids may be a novel mechanism for allowing selective access of proteins to phospholipids on the lipid bilayer.     

Influence of glycolipids on immune reactions of phospholipid antigens in liposomes

Complement-dependent immune damage to liposomes mediated by a murine monoclonal antibody to the liposomal bilayer was completely inhibited by ceramide tetrasaccharide (globoside) at an 8% concentration in the liposomes. Lower concentrations of globoside, or higher concentrations of ceramide tri-, di-, or monohexoside, were not inhibitory. At a globoside concentration of 5.8%, inhibition of the monoclonal antibody activity was reduced and inhibition was related to antibody concentration; but at 2% globoside, suppression of antibody activity was not observed at all. Analysis of space-filling models revealed that at 8% globoside the distance between adjacent tetrasaccharides of globoside approached the dimensions of the antigen-binding end of a 7S immunoglobulin molecule. We therefore propose that globoside, and perhaps other glycolipids, can exert steric hindrance to the binding of extracellular proteins to nonglycolipid constituents of the lipid bilayer. We conclude that microheterogeneity among polar groups of glycolipids may be a novel mechanism for allowing selective access of proteins to phospholipids on the lipid bilayer.     

The inhibition of complement-dependent hemolysis by liposomes containing cerebroside sulfate

Cerebroside sulfate (CGS) was found to be capable of inhibiting complement-dependent hemolysis. The activity dependence of CGS-containing liposomes on their composition was studied. Mixtures of CGS with phosphatidylethanolamine, phosphatidylserine, sphingomyelin from cattle brain, cerebroside from cattle spinal cord (CG), and egg yolk phosphatidylcholine (ePC) were investigated. In the case of binary CGS/ePC mixtures, the antihemolytic activity varied nonlinearly with an increase in the mass part of CGS: it sharply increased with an increase in the CGS part from 0.3 to 0.5 and decreased by 20–30% of the maximum value with an increase in the CGS part from 0.9 to 1. On the basis of these experiments, the optimum distance between the charged groups of CGS was estimated to be 0.92–1.6 nm. In the ternary compositions of 4:3:3 CGS/ePC/polar lipid, only CG increased the activity of liposomes as compared to that of liposomes from the 4:6 CGS/ePC. The preliminary incubation of CGS-containing liposomes with complement decreased hemolysis more effectively than incubation with other components of the hemolytic system. This suggests that the interaction of CGS-containing liposomes with the complement proteins is responsible for their antihemolytic activity.     

The inhibition of complement-dependent hemolysis of liposomes containing cerebroside sulfate

Cerebroside sulfate (CGS) was found to be capable of inhibiting complement-dependent hemolysis. The activity dependence of CGS-containing liposomes on their composition was studied. Mixtures of CGS with phosphatidylethanolamine, phosphatidylserine, sphingomyelin from cattle brain, cerebroside from cattle spinal cord (CG), and egg yolk phosphatidylcholine (ePC) were investigated. In the case of binary CGS/ePC mixtures, the antihemolytic activity varied nonlinearly with an increase in the mass part of CGS: it sharply increased with an increase in the CGS part from 0.3 to 0.5 and decreased by 20-30% of the maximum value with an increase in the CGS part from 0.9 to 1. On the basis of these experiments, the optimum distance between the charged groups of CGS was estimated to be 0.92-1.6 nm. In the ternary compositions of 4:3:3 CGS/ePC/polar lipid, only CG increased the activity of liposomes as compared to that of liposomes from the 4:6 CGS/ePC. The preliminary incubation of CGS-containing liposomes with complement decreased hemolysis more effectively than incubation with other components of the hemolytic system. This suggests that the interaction of CGS-containing liposomes with the complement proteins is responsible for their antihemolytic activity.     

Cholesterol-dependent tetanolysin damage to liposomes.

Tetanolysin caused membrane damage, resulting in release of trapped glucose from liposomes containing cholesterol. Maximum glucose release occurred from liposomes that contained 50 mol% cholesterol. At higher or lower levels of cholesterol, glucose release was reduced and glucose release did not occur at all below 40 mol% cholesterol. The apparent activity of tetanolysin was not influenced by temperature (24 degrees C compared to 32 degrees C) or by liposomal phospholipid fatty acyl chain length. We conclude that tetanolysin caused cholesterol-dependent lysin-mediated damage to liposomes, possibly by means of a pore consisting of a complex of toxin and cholesterol.     

Dehydration-rehydration vesicle methodology facilitates a novel approach to antibody binding to liposomes

Mouse monoclonal IgG1 specific for hepatitis B surface antigen and ovine polyclonal antibody raised against digoxin were covalently coupled by a diazotisation method to small unilamellar vesicles (SUV) composed of equimolar phospholipid and cholesterol supplemented with 6 mol% aminophenylstearylamine (APSA). Up to 33% of the antibody used was associated with vesicles, depending on the phospholipid and the antibody type used. Antibody-coated SUV were mixed with carboxyfluorescein (CF) or beta-galactosidase to generate multilamellar dehydration-rehydration vesicles (DRV) containing CF or active enzyme. In contrast, coupling of antibodies directly to beta-galactosidase-containing DRV resulted in total inactivation of the enzyme. About 85% of the SUV-bound antibody was recovered in DRV and of this, 78-82% was exposed on the liposomal surface, possibly because of reorientation of the APSA-antibody complex during DRV formation. Antibody-coated DRV remained stable in the presence of plasma at 37 degrees C and also under storage at 4 degrees C. Further, antibody coupled to such liposomes was capable of efficient interaction with the respective antigen. The present method allows the attachment of antibodies to the liposomal surface independently of entrapment of solutes, the activity of which is thus preserved, and could be adapted to alternative coupling procedures or ligands.     

Evaluation of antisperm complement-dependent immune mediators in human ovarian follicular fluid

A "sandwich"-type radiolabeled antiglobulin assay using monoclonal anti-C5b-9 neoantigen and polyclonal anti-C5b-9 was used to evaluate the presence of terminal C complexes (SC5b-9 or MC5b-9) in the sera and ovarian follicular fluid (FF) from 45 infertile women. FF SC5b-9 was detectable in all clinical diagnostic categories. The mean SC5b-9 levels in FF and sera were 399 ng/ml (range 75 to 1350 ng/ml) and 798 ng/ml (range 0 to 2700 ng/ml), respectively. Twelve (26.6%) of the 45 FF samples had normal hemolytic C activity, and all FF (n = 44) samples initiated C8/C9-dependent lysis of sensitized sheep E coated with human C1-7. Human plasma IgG antisperm antibodies (ASA) were capable of activating C in 31 (72%) of 43 FF samples as detected by their ability to deposit MC5b-9 on human sperm. Sera from infertile women with ASA in their sera and FF impaired human sperm binding to human zona pellucida and binding and penetration of zona-free hamster oocytes in vitro. The discovery of SC5b-9 and MC5b-9 in ovarian FF implies that the interaction of ASA and C could have a deleterious effect on sperm during in vivo and in vitro sperm-egg interactions in women with antisperm antibodies.     

The use of liposomes to study COPII- and COPI-coated vesicle formation and membrane protein sorting

We have established systems that reconstitute the biogenesis of coated transport vesicles with liposomes made of pure lipids and purified coat proteins. Optimization of the lipid composition in the liposomes allowed the efficient binding of both coat protein I and coat protein II (COPII) coat subunits. Coated vesicles of approximately the size generated from biomembranes were detected and characterized by centrifugation analysis and electron microscopy. A variation of this budding reaction allowed us to measure the sorting of v-SNARE proteins into synthetic COPII vesicles. We developed a novel system to tether glutathione S-transferase (GST)-hybrid proteins to the surface of liposomes formulated with a glutathione-derivatized phospholipid. This system allowed us to detect the positive role of cytoplasmic domains of two v-SNARE proteins that are packaged into COPII vesicles. Therefore, both generation of coated vesicles and protein sorting into the vesicles can be reproduced with liposomes and purified proteins.     

Pleiotropic effects of positively charged liposomes on immune functions

Summary Positively charged liposomes have been shown to inhibit the proliferation of lymphocytes induced by various polyclonal activators. We demonstrated that this inhibition is essentially restricted to early phases of activation. B cell proliferation, induction of suppressor cells, and cytotoxic activities are all profoundly inhibited, whereas T4+ cells response to mitogenic stimulation is only moderately affected. The results are discussed in terms of membrane perturbations potentially induced by liposome-lymphocyte interactions. This work has been supported by grants from the National Sciences and Engineering Council of Canada.     

Inhibitory effects of gangliosides on immune reactions of antibodies to neutral glycolipids in liposomes

Specific immune damage to liposomes containing Forssman or globoside glycolipid was inhibited when the liposomes also contained ganglioside. The activity of a human monoclonal Waldenstr?m macroglobulin antibody to Forssman glycolipid was inhibited by each of three gangliosides tested, GM3, GD1a and GD1b. Inhibition of the monoclonal antibody was dependent on the amount of ganglioside in the liposomes, and was diminished by reducing the relative amount of ganglioside. Inhibition also correlated positively with the number of ganglioside sialic acid groups, with inhibition by GT1b greater than GD1a greater than GM3. Naturally occurring human antibodies to globoside glycolipid were detected in 18% (9 out of 50) of normal human sera tested. Immune damage to liposomes induced by each of the three highest-reacting human anti-globoside sera was blocked by liposomal GM3. We conclude that gangliosides can strongly influence immune damage to membranes induced by antibody interactions with adjacent neutral glycolipids.     

Bile salt damage of egg phosphatidylcholine liposomes

Physiochemical damage of egg phosphatidylcholine liposomes, caused by the salts of three bile acids, chenodeoxycholic acid, ursodeoxycholic acid, and cholic acid, has been investigated. Of the three bile salts, that of chenodeoxycholic acid was the most destructive, and the effect of the damage was examined by monitoring the induced 6-carboxyfluorescein release from the liposomes. For all three of the bile salts and under the experimental conditions, the minimum (effective) concentrations causing the 6-carboxyfluorescein release were below their critical micelle concentrations. In the case of the salt of chenodeoxycholic acid, the presence of cholesterol in the liposomal bilayers did not show any significant effect on the induced 6-carboxyfluorescein release, while, for the salts of ursodeoxycholic acid and cholic acid, the presence of cholesterol tended to depress the release. Permeation of bile salts into the membranes of liposomal bilayers made these membranes more fluid, and this fluidity was monitored by measuring the change in fluorescence polarization using 1,6-diphenylhexatriene entrapped in the liposomes. Coating the liposomes with polysaccharides, to make them more hydrophobic, led to their easier lysis by the bile salts.     

Mitochondrial creatine kinase binding to liposomes and vesicle aggregation: effect of cleavage by proteinase K

Mitochondrial creatine kinase and its proteinase K nicked-derivative interaction with liposomes induced slight secondary structure changes evidenced by infrared spectra. In nondenaturing conditions, the N-terminal (K₁) and the C-terminal (K₂) fragments remained associated with each other and bound to liposomes. When the two fragments were separated by denaturation, K₂ was soluble, whereas most of K₁ was adsorbed onto liposomes. The three-dimensional structure of uncleaved mtCK suggests that the C-terminal moiety, which contains positively charged surface residues, interacted with membranes. After denaturation and renaturation of the nicked enzyme, both peptides did not refold properly and did not reassociate with each other. The misfolded K₁ fragment bound to the membrane through a stretch of positive residues, which were buried in the native enzyme. The lack of binding of the ill-folded K₂ peptide could be related to the disruption of the optimal disposition of its positive charges, responsible for the correct interaction of native mtCK with membrane.     

Effect of phosphatidylcholine vesicle size on chirality induction and chiral discrimination

The effect of the size of phosphatidylcholine (PC) vesicles on the induction of chirality and chiral discrimination was examined. Three kinds of vesicles formed with l-dimyristoyl, l-dipalmitoyl, or egg yolk PCs induced circular dichroisms (CDs) with the sign and intensity of the Cotton effect different from those of monomeric PCs. The CD intensity of the vesicles increased with a decrease in the vesicle size. Furthermore, the helicity of heterohelicene derivatives in a rapid equilibrium between right-handed (P) and left-handed (M) enantiomers was biased toward the M enantiomer side in l-PC vesicles, implying chiral discrimination by the vesicles. The extent of the bias toward the M enantiomer increased with an increase in vesicle size. Both the chirality induction and chiral discrimination were enhanced in a low-fluidity gel phase in comparison with those in a high-fluidity liquid-crystalline phase for every kind of vesicle of every size examined.