Interactions of Phospholipid Vesicles with Murine Lymphocytes

The effect of unilamellar lipid vesicles composed of dioleoyl lecithin (DOL), egg yolk lecithin (EYL), 1:1 EYL:cholesterol (Chol), dipalmitoyl lecithin (DPL), and dimyristoyl lecithin (DML) on the mitogenic response in mouse lymphocytes was tested. Cortisone-resistant thymocytes were briefly treated with lipid vesicles and subsequently stimulated with concanavalin A (con A). All of the lipid vesicles induced an enhanced mitogenic response on day 3 as tested by [³H]TdR incorporation and by counting total cells. The order of enhanced [³H]TdR incorporation (?5.3 times the control) was DML>DPL>1:1 EYL:Chol>EYL?DOL> untreated control cells. These increases were paralleled by increased numbers of total cells. The response of spleen cells to a B-cell mitogen, bacterial lipopolysaccharide, was similarly enhanced by vesicle pretreatments in the same order. Vesicle treatments alone were not mitogenic.

Pretreatment of cells with lipid vesicles modified lectin binding: DML and DPL increased the binding of [¹²⁵I]con A by three to four times the control, whereas 1:1 EYL:Chol, EYL, or DOL had little or no effect. The binding of [125I]phytohemagglutinin-P (PHA-P) to vesicle-treated cells was indistinguishable from untreated cells. The lectin (con A; PHA-P)-induced agglutination of vesicle-treated cells was also modified by different lipid vesicles in the same order as the mitogenic response.

Based on the results presented in the accompanying report [6], we find that the cell surface adsorption properties of the applied lipid vesicles correlate with their ability to enhance the mitogenic response, and that they modify agglutinability and lectin binding. These results are further discussed in terms of the possible alteration of membrane properties and subsequent cellular activity.     

Interactions of phospholipid vesicles with murine lymphocytes. II. Correlation between altered surface properties and enhanced proliferative response.

The effect of unilamellar lipid vesicles composed of dioleoyl lecithin (DOL), egg yolk lecithin (EYL), 1:1 EYL:cholesterol (Chol), dipalmitoyl lecithin (DPL), and dimyristoyl lecithin (DML) on the mitogenic response in mouse lymphocytes was tested. Cortisone-resistant thymocytes were briefly treated with lipid vesicles and subsequently stimulated with concanavalin A (con A). All of the lipid vesicles induced an enhanced mitogenic response on day 3 as tested by [3H]TdR incorporation and by counting total cells. The order of enchanced [3H]TdR incorporation (less than or equal to 5.3 times the control) was DML greater than DPL greater than 1:1 EYL:Chol greater than EYL congruent to DOL greater than untreated control cells. These increases were paralleled by increased numbers of total cells. The response of spleen cells to a B-cell mitogen, bacterial lipopolysaccharide, was similarly enhanced by vesicle pretreatments in the same order. Vesicle treatments alone were not mitogenic Pretreatment of cells with lipid vesicles modified lectin binding: DML and DPL increased the binding of [125I]con A by three to four times the control, whereas 1:1 EYL:Chol, EYL, or DOL had little or no effect. The binding of [125I]phytohemagglutinin-P (PHA-P) to vesicle-treated cells was indistinguishable from untreated cells. The lectin (con A; PHA-P)-induced agglutination of vesicle-treated cells was also modified by different lipid vesicles in the same order as the mitogenic response. Based on the results presented in the accompanying report [6], we find that the cell surface adsorption properties of the applied lipid vesicles correlate with their ability to enhance the mitogenic response, and that they modify agglutinability and lectin binding. These results are further discussed in terms of the possible alteration of membrane properties and subsequent cellular activity.     

Adhesion of phospholipid vesicles to Chinese hamster fibroblasts: Role of cell surface proteins

The adhesion of artificially generated lipid membrane vesicles to Chinese hamster V79 fibroblasts in suspension was used as a model system for studying membrane interactions. Below their gel-liquid crystalline phase transition temperature, vesicles comprised of dipalmitoyl lecithin (DPL) or dimyristoyl lecithin (DML) absorbed to the surfaces of EDTA- dissociated cells. These adherent vesicles could not be removed by repeated washings of the treated cells but could be released into the medium by treatment with trypsin. EM autoradiographic studies of cells treated with[(3)H]DML or [(3)H]DPL vesicles showed that most of the radioactive lipids were confined to the cell periphery. Scanning electron microscopy and fluorescence microscopy further confirmed the presence of adherent vesicles at the cell surface. Adhesion of DML or DPL vesicles to EDTA-dissociated cells modified the lactoperoxidase-catalyzed iodination pattern of the cell surface proteins; the inhibition of labeling of two proteins with an approximately 60,000- dalton mol wt was particularly evident. Incubation of cells wit h (3)H-lipid vesicles followed by sodium dodecyl sulfate (SDS)- polyacrylamide gel electrophoresis showed that some of the (3)H-lipid migrated preferentially with these approximately 60,000-mol wt proteins. Studies of the temperature dependence of vesicle uptake and subsequent release by trypsin showed that DML or DPL vesicle adhesion to EDTA- dissociated cells increased with decreasing temperatures. In contrast, cells trypsinized before incubation with vesicles showed practically no temperature dependence of vesicle uptake. These results suggest two pathways for adhesion of lipid vesicles to the cell surface-a temperature-sensitive one involving cell surface proteins, and a temperature-independent one. These findings are discussed in terms of current models for cell-cell interactions.     

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     

Peculiar behaviour of rabbit thymocytes in interaction with liposomes of different compositions shown by fluorescence polarization studies,lipid analysis,and uptake of vesicle-entrapped carboxyfluorescein

In order to obtain more information on membrane phenomena occurring at the cell surface of rabbit thymocytes we have performed experiments aimed at altering the lipid composition of the plasma membrane. Thymocytes were incubated at 37°C with phospholipid vesicles of different compositions. Vesicle-cell interaction was followed by measuring the degree of fluorescence polarization and the uptake of vesicle-entrapped carboxyfluorescein. Neutral and negatively charged liposomes prepared from egg phosphatidylcholine are currently used in investigations of vesicle-cell interaction. In this report we show that these liposomes do not interact with rabbit thymocytes as is evident from unaltered lipid fluidity measured in whole cells and in isolated plasma membranes. This was confirmed by experiments with vesicle-entrapped carboxyfluorescein showing hardly any uptake of the fluorophor from neutral and negatively charged egg phosphatidylcholine liposomes. Using both techniques substantial interaction was found with positively charged egg phosphatidylcholine liposomes and with liposomes prepared from soybean lecithin which is composed of a variety of phospholipids. The results of these experiments were supported by lipid analysis of cells treated with soybean lecithin liposomes. Increase in phosphatidylcholine contents of mixed phospholipid vesicles was further shown to result in decreased vesicle-cell interaction. From measurements of the quantity of carboxyfluorescein inside cells and the total amount of cell-associated carboxyfluorescein it is concluded that adsorption plays a prominent role in interaction between liposomes and rabbit lymphocytes. The grade of maturation of lymphocytes was also found to affect vesicle-cell interaction. The more mature thymocytes took up more vesicle-entrapped carboxyfluorescein from soybean liposomes than immature thymocytes. Mesenteric lymph node cells exhibited a still stronger interaction. The role of vesicle and cell surface charge and membrane fluidity of both vesicles and cells in interaction between liposomes and rabbit thymocytes is discussed.     

Nuclear magnetic resonance studies of amphiphile hydration: Effects of the gel-to-liquid crystalline phase transition on the hydration of dioleoyl lecithin

The hydration of dioleoyl lecithin (DOL) and dimyristoyl lecithin (DML) has been measured as a function of temperature between ?15 and ?30 °C, using low-temperature proton magnetic resonance. The hydration of DOL is considerably higher than that of DML. We detect 9 mol of unfrozen water/mol of phospholipid at ?25 °C (our “standard” temperature) for DOL, and only 6 mol of water/mol of phospholipid for DML. The gel-to-liquid crystalline phase transition in DOL centered at ca. ?19 °C is manifested by a 70% increase in hydration for both vesicles and dispersions. Preparations of either DML vesicles or vesicles of DOL which contain 33 mol% cholesterol would not be expected to undergo this phase transition, and the hydration increase observed for these preparations in the same range of temperature is less than 20%.     

Interaction of phospholipid vesicles with cultured mammalian cells. II. Studies of mechanism

The mechanism of interaction of artificially generated lipid vesicles (approximately 500 A diameter) with Chinese hamster V79 cells bathed in a simple balanced salt solution was investigated. The major pathways of exogenous lipid incorporation in vesicle-treated cells are vesicle-cell fusion and vesicle-cell lipid exchange. At 37 degrees C, the fusion process is dominant, while at 2 degrees C or with energy depleted cells, exchange of lipids between vesicles and cells is important. The fusion mechanism was demonstrated using vesicles of [14C]lecithin containing trapped [13H]inulin. Consistent with a fusion hypothesis, both components became cell associated at 37 degrees C in nearly the same proportions as they were present in the applied vesicles. Additional arguments in favor of vesicle-cell fusion and against phagocytosis or adsorption of intact vesicles are presented. At 2 degrees C or with inhibitor-treated cells, the [3H]inulin uptake was largely suppressed, while the lipid uptake was reduced to a lesser extent. Evidence for vesicle-cell lipid exchange was obtained using V79 cells grown on 3H precursors for cellular lipids. [14C]lecithin vesicles, incubated with such cells, showed no change in their elution properties when subjected to molecular sieve chromatography on Sepharose 4B. However, radioactivity and thin-layer chromatographic analyses revealed that a variety of cell lipiids had been exchanged into the uniamellar vesicles. Further evidence for the fusion and exchange processes was obtained using vesicles prepared from mixtures of [3H]lecithin and [14C]cholesterol. A two-step fusion mechanism consistent with the present findings is proposed as a working model for other fusion studies.     

Phospholipid exchange between bilayer membrane vesicles.

The turbidity of lipid vesicles, freshly prepared by sonicating purified dimyristoyllecithin (DML) in dilute KCl solutions, was measured as a function of time at various temperatures. A sharp maximum in the rate of increase of turbidity is found just above the crystal:liquid-crystal phase transition temperature (Tm). The initial rate of turbidity increase is first order with respect to DML concentration. Electron and light microscopy reveal large vesicles which are not present before incubation or after incubation at temperatures far from the Tm. When temperature, rather than time, is the independent variable, a sharp drop in turbidity is seen at the Tm. The magnitude of this drop and the temperature at which it occurs were used to measure the rate of lipid transfer between vesicles composed of different lipids. A mixture of DML vesicles and dipalmitoyllecithin (DPL) vesicles exhibits sharp drops in turbidity at 24 and 41 degrees, the corresponding Tm's. With time, the magnitude of the transition at 24 degrees decreases while that which was originally at 41 degrees moves to lower temperatures and increases in magnitude. At equilibrium there is a single transition at 32.5 degrees characteristic of vesicles composed of equimolar DPL and DML. The rate at which equilibrium is approached increases at around 24 degrees and again around 41 degrees. These observations indicate that vesicles are in equilibrium with monomolecular lipid, the concentration of the latter being higher the shorter the lipid acyl group or the smaller the vesicle. DML molecules are therefore lost from small vesicles to large vesicles (DML system) or lost from DML vesicles to DML-DPL vesicles (mixed system). When DML vesicles containing a few percent brain gangliosides were studied, different behavior was observed; the initial rate of increase of turbidity becomes second order in lipid concentration, and the rate constant increases with increasing concentrations of KCl. The kinetic order, coupled with the fact that electrolyte reduces intervesicle electrostatic repulsion, argues that in this situation the mechanism of vesicle growth requires vesicle collision.     

Carbon-13 nuclear magnetic resonance studies of cerebroside derivatives and their properties in lecithin bilayers (1)

The ¹³C NMR chemical shifts and spin-lattice relaxation times of D-galactosylsphingosine derivatives in CDCl₃-CD₃OD and in egg-yolk lecithin vesicles in D₂O, and of N-acetylpsychosine micelles, are reported. Results with sonicated, unilamellar vesicles containing cerebroside and EYL^a show that (1) cerebrosides decrease the fluidity of the lecithin bilayer membrane and have the greatest effect on the glycerol backbone and choline methyl carbons. (2) N-acetylpsychosine experiences a greater freedom of motion in the galactose region than does cerebroside and does not reduce the fluidity of the lecithin as much as cerebroside. (3) Ac-Psy/EYL vesicles formed are permeable to Yb³⁺ but cerebroside/lecithin vesicles are not. (4) The choline groups on the inner bilayer surface are less mobile than those on the outer surface according to preliminary T₁ measurements of the Yb³⁺-separated resonances. (5) Yb³⁺-induced chemical shifts of choline methyl and choline $\text{C}\text{H}{}_2$OP peaks in mixed cerebroside-lecithin vesicle systems indicate a small preference for cerebroside in the outside monolayer. The data show that these molecules have significant effects on bilayer conformational mobilities, particularly near the surface, and thus demonstrate one mechanism for modulation of cell surface properties by glycosphingolipids.     

Vesicle membrane-water partition coefficients determined from Fourier transform pulsed-gradient spin-echo NMR based self-diffusion data. Application to anesthetic binding in tetracaine-phosphatidylcholine-water systems

Multicomponent self-diffusion data on dioleoyl(DOL)- and dipalmitoyllecithin (DPL) vesicle-water systems have been determined using a Fourier transform NMR technique. The self-diffusion of vesicles is characterized by diffusion coefficients two magnitudes lower than that of small molecules in solution. Consequently, the degree of binding of small molecules is strongly reflected in their time-averaged self-diffusion coefficient in vesicle-water systems. This provides a new basis for the determination of vesicle-water partition equilibria. The feasibility of the technique has been investigated in one anesthetic-lipid system and is found to be very good. The binding of the hydrochloride form of tetracaine to DOL vesicles at pH 3 and 7 (K_p = 30–50) is found to be very much lower than that of the neutral molecule at pH 9 (K_p = 800–900). No significant difference in the tetracaine binding characteristics was found between DOL, DOL-cholesterol and DPL systems.     

Interactions of polymerizable phosphatidylcholine vesicles with blood components: relevance to biocompatibility

We have studied the biocompatibility properties of polymerizable phosphatidylcholine bilayer membranes, in the form of liposomes, with a view toward the eventual utilization of such polymerized lipid assemblies in drug carrier systems or as surface coatings for biomaterials. The SH-based polymerizable lipid 1,2-bis[1,2-(lipoyl)dodecanoyl]-sn-glycero-3-phosphocholine (dilipoyl lipid, DLL) and the methacryl-based lipid 1,2-bis[(methacryloyloxy)dodecanoyl]-sn-glycero-3-phosphocholine (dipolymerizable lipid, DPL) were studied in comparison to ‘conventional’ zwitterionic or charged phospholipids. We examined binding of serum proteins to liposomes and effects of liposomes on fibrin clot formation and on platelet aggregation. All types of liposomes tested bound complex mixtures of serum proteins with IgG being the most abundant bound component. DPL vesicles and anionic vesicles bound substantially more protein than other vesicle types. Polymerized DPL vesicles uniquely bound a protein of about 53 kDa which was not bound to other types of phosphatidylcholine liposomes. Likewise polymerized DPL vesicles, but not other types of phosphatidylcholine vesicles, caused a marked alteration in coagulation as measured by activated partial thromboplastin time (APTT) and prothrombin time (PT) tests; this effect was shown to be due to binding and depletion of clothing factor V by the DPL polymerized vesicles. Polymerized DPL liposomes and DLL liposomes in polymerized or nonpolymerized form, were without substantial effect on platelet aggregation. However, DPL nonpolymerized vesicles, while not causing aggregation, did impair ADP-induced aggregation of platelets. These studies suggest that SH based polymerizable lipids of the DLL type may be very suitable for in vivo use in the contexts of drug delivery systems or biomaterials development. Methacryloyl-based lipids of the DPL type seem to display interactions with the hemostatic process which militate against their in vivo utilization.     

Interactions of phospholipid vesicles with rat hepatocytes in vitro influence of vesicle-incorporated glycolipids

We examined the interaction of glycolipid-containing phospholipid vesicles with rat hepatocytes in vitro. Incorporation of either $\text{N-}\text{lignoceroyldihydrolactocerebroside}$ or the monosialoganglioside, G_M1, enhanced liposomal lipid uptake 4–5-fold as judged by the uptake of radioactive phosphatidylcholine as a vesicle marker. Cerebroside enhanced phospholipid uptake only when incorporated into dimyristoyl, but not into egg phosphatidylcholine vesicles. The lack of cerebroside effect in egg phosphatidylcholine-containing vesicles appeared to be due to a limited exposure of the carbohydrate part of the glycolipid as suggested by the reduced agglutinability of those vesicles by Ricinus communis agglutinin.In contrast to the results with radioactive phosphatidylcholine, we observed only a 20% increase in vesicle-cell association as a result of glycolipid incorporation, when a trace amount of [¹⁴C]cholesteryloleate served as a marker of the liposomal lipids or when using the fluorescent dye, carboxyfluorescein, as a marker of the aqueous space of the vesicles. By the same token, intracellular delivery of vesicle-contents was only slightly enhanced (approx. 10%).The discrepancy between the association with the cells of phosphatidylcholine on the one hand and cholesteryoleate or entrapped marker on the other suggests different mechanisms of uptake for these markers. Our results are compatible with the notion that the main effect of incorporation of glycolipids into the vesicles is the enhancement of exchange or transfer of phospholipid molecules between vesicles and cells. Incubation of the cells with galactose or lactose, prior to addition of vesicles, suggests that this enhanced phospholipid exchange or transfer involves specific recognition of the terminal galactose residues of the glycolipid vesicles by a receptor present on the plasma membranes of hepatocytes.     

Insertion of fluorescent phosphatidylserine into the plasma membrane of red blood cells. Recognition by autologous macrophages

The interaction of macrophages with red blood cells (RBC) displaying phosphatidylserine (PS) in their surface membranes was investigated after the transfer of an exogenously supplied fluorescent lipid analog to the RBC. Nonfluorescent (quenched) lipid vesicles were formed by ultrasonication from 1-acyl-2-[(N-4-nitro-benzo-2-oxa-1,3 diazole)aminocaproyl]phosphatidyl-serine (NBD-PS) or 1-acyl-2[(N-4-nitrobenzo-2-oxa-1,3 diazole)aminocaproyl]phosphatidylcholine (NBD-PC). The interaction of these vesicles with RBC was monitored as a function of vesicle concentration by assessment of the degree to which cell-associated lipid fluorescence was dequenched after vesicle treatment. When vesicle concentrations of less than 100 ng/ml were used, lipid fluorescence was largely dequenched, indicating that lipid transfer was the predominant mechanism of both NBD-PS and NBD-PC uptake; however, when vesicle concentrations were increased to greater than 100 ng/ml, a concentration-dependent increase in the fraction of quenched cell-associated lipid was observed, indicating that another mechanism, possibly vesicle-cell adhesion, also occurred. Using NBD-PS at concentrations at which dilution of all the phospholipid analog in the recipient cell membrane could be unequivocally confirmed, we observed that the uptake of NBD-PS-treated RBC by macrophages was increased 5-fold over that of controls, whereas the uptake of RBC containing an equivalent amount of exogenously supplied NBD-PC was unaltered. Furthermore, preincubation of macrophage monolayers with vesicles containing PS resulted in a approximately 60% inhibition in the uptake of NBD-PS-treated RBC, whereas no inhibition in the uptake of control, opsonized, or NBD-PC-treated RBC was observed. These findings suggest that PS in the outer leaflet of RBC might serve as a signal for triggering their recognition by macrophages.     

In vitro interaction of zajdela ascites hepatoma cells with lipid vesicles

We studied the in vitro interaction between Zajdela ascites hepatoma cells and small unilamellar vesicles, consisting of ¹⁴C-labeled phosphatidylcholine, cholesterol, and phosphatidylserine (molar ratio 5: 4: 1), containing high intravesicular concentrations of carboxyfluorescein or fluorescein isothiocyanate tagged dextran.The entrapped markers were found to be associated with the cells to a lesser degree than the vesicle membrane marker. This discrepancy, which is slightly less pronounced for fluorescein isothiocyanate tagged dextran than for carboxyfluorescein, increases with incubation time and decreases with increasing vesicle lipid concentration in the incubation mixture. Vesicle-plasma membrane exchange of the vesicle lipid marker could not entirely explain the observed discrepancy. It is tentatively concluded that the gap mainly arises from a selective loss of entrapped dyes from vesicles actually interacting with the cell surface. Both spectrofluorimetric and fluorescence microscopic observations, as well as the relative insensitivity of vesicle uptake towards the presence of metabolic inhibitors, exclude a major contribution of endocytosis as a vesicle uptake route. We therefore conclude that vesicles are primarily internalized by a vesicle-cell fusion-like process. The observed discrepancy in uptake between entrapped materials and vesicle lipid is discussed in terms of a two-site vesicle cell surface interaction model.     

Fusion of lipid vesicles with ascites tumor cells and their lipid-depleted variants. Studies with radioactive- and fluorescent-labeled vesicles

Cultured ascites tumor cells and their lipid-depleted variants, which contained 35-40% less membrane phospholipid and cholesterol, were used for fusion experiments with unilamellar lipid vesicles which were between 300 and 600 nm in diameter. Vesicle-cell interaction was followed by tracer studies using vesicles double-labeled in the lipid moiety, by vesicle-encapsulated [3H] dextran, and by measurements of energy transfer between N-(10-[1-pyrene]decanoyl)sphingomyelin-labeled vesicles and alpha-parinaric acid-labeled cells in the presence of poly(ethylene glycol) (PEG) as fusogen. The reaction rates measured with the radiolabeled vesicles were found to follow patterns similar to those obtained with the resonance energy transfer assay. This latter method revealed a vesicle-cell membrane fusion reaction, which was substantiated by radiolabeling the internal cellular compartment after treatment of the cells with [3H]dextran-encapsulated vesicles as shown by electron microscopic autoradiography on semi-thin sections. Endocytosis as a reaction mechanism can be excluded, since no energy transfer was observed at 25 degrees C in the absence of PEG. Investigations of vesicle bilayer order and fluidity on vesicle-cell interaction revealed optimal reactivity, with intermediate fluidity corresponding to cholesterol/phospholipid ratios between 0.7 and 1.0 and fluorescence depolarization (P) values of 0.18 and 0.21. Lipid depletion decreased the reaction velocity between cells and vesicles by about 20%, exhibiting V values of 33.2 mumol/min, as compared to the control of 41.4 mumol/min determined for 10(7) cells. The affinity constants for vesicle lipid were affected only slightly with Km values of 0.195 mM (0.210 mM). The activation energies for the reaction were calculated to give values of EA = 22.44 kJ/mol for the control and of EA = 20.4 kJ/mol for the modified cells. These data indicate that the decrease in membrane lipid content apparently has no major influence on the extent of the interaction.     

NMR study of rapid water diffusion across lipid bilayers in dipalmitoyl lecithin vesicles

A method for measurement of rapid diffusional exchange between external and internal water in lecithin vesicles is described. Paramagnetic ions were inserted inside DPL vesicles and the NMR relaxation times for water protons were measured as a function of temperature. It was found that water diffusion rate is described by a single activation energy of 15±1 kcal/mole in the temperature range 16 – 35°C and exhibits a maximum at 44°C. The permeability of DPL vesicles to water was calculated to 16–18 × 10^?4 cm/s at 44°C and 1.7 × 10^?4 cm/s at 20°C.     

Osmotic pressure induced pores in phospholipid vesicles.

We report a comparative study of the leadage of hydrophilic molecules from vesicles of egg lecithin (EL) and of dipalmitoyllecithin (DPL). The effect of osmotic pressure differences a leakage is consistent with a model for statistical pore nucleation process. The major difference in osmotic pressure induced leakage from DPL and EL is that the number of pore creation sites is much greater in DPL. We suggest that the difference in number of these sites also accounts for other differences in the properties of DPL and EL, namely for differences in vesicle fusion and apparent rate of "flip-flop".     

Equilibrium studies of lecithin-cholesterol interactions. II. Phase relations in surface films: analysis of the "condensing" effect of cholesterol

From measurements of the equilibrium spreading pressure pie for dispersions of lecithin--dimyristoyl (DML) or dioleoyl (DOL)--and cholesterol (CHOL) in water, we have deduced the phase relations in both the aqueous dispersions and the equilibrium surface films. At 29.5 degrees C, when the mole fraction of cholesterol in the dispersion chi(CHOL) is 0 chi(CHOL) less than chi(CHOL) less than 0.33, pie is constant and equal to the value for pure lecithin (DOL or DML). The phase rule predicts than two bulk lipid phases coexist; these are pure lecithin and lecithin:cholesterol 2:1 complex. The equilibrium surface film contants only lecithin and therefore lecithin and 2:1 complex are immiscible in surface films. When 0.33 less than chi/CHOL) less than 1.0, pie is also contant with a value intermediate between that for pure lecithin and cholesterol. In this range of lipid composition two bulk lipid phases also coexist: lecithin:cholesterol 2:1 complex and pure cholesterol. However, the equilibrium surface film contains only the 2:1 complex and, therefore, 2:1 complex is also immiscible with cholesterol in surface films. When pi less than pie, as in the case of spread films, we deduce that two surface phases may coexist; the composition of the phases will depend on chi(CHOL). When 0 less than chi(CHOL) less than 0.33, both lecithin and 2:1 complex coexist, and when 0.33 less than chi(CHOL) less than 1.0, 2:1 complex and cholesterol coexist. The "condensing" effect of cholesterol in lecithin surface films is reexamined. The effect is attributed to formation of the lecithin:cholesterol 2:1 complex and nonequilibrium conditions in the two-phase surface film.     

In vitro interaction of Zajdela ascites hepatoma cells with lipid vesicles.

We studied the in vitro interaction between Zajdela ascites hepatoma cells and small unilamellar vesicles, consisting of 14C-labeled phosphatidylacholine, cholesterol, and phosphatidylserine (molar ratio 5 : 4 : 1), containing high intravesicular concentrations of carboxyfluorescein or fluorescein isothiocyanate tagged dextran. The entrapped markers were found to be associated with the cells to a lesser degree than the vesicle membrane marker. This discrepancy, which is slightly less pronounced for fluorescein isothiocyanate tagged dextran than for carboxyfluorescein, increases with incubation time and decreases with increasing vesicle lipid concentration in the incubation mixture. Vesicle-plasma membrane exchange of the vesicle lipid marker could not entirely explain the observed discrepancy. It is tentatively concluded that the gap mainly arises from a selective loss of entrapped dyes from vesicles actually interacting with the cell surface. Both spectrofluorimetry and fluorescence microscopic observations, as well as the relative insensitivity of vesicle uptake towards the presence of metabolic inhibitors, exclude a major contribution of endocytosis as a vesicle uptake route. We therefore conclude that vesicles are primarily internalized by a vesicle-cell fusion-like process. The observed discrepancy in uptake between entrapped materials and vesicle lipid is discussed in terms of a two-site vesicle-cell surface interaction model.     

Lipid vesicle-cell interactions. I. Hemagglutination and hemolysis

The interaction of lipid vesicles (liposomes) of several different compositions with erythrocytes has been investigated. Lecithin liposomes, rendered positively charged with stearylamine, exhibit potent hemagglutination activity in media containing low concentrations of electrolytes. The hemagglutination titer is found to be a linear function of the zeta potential of the lipid vesicles. Hemagglutination is reduced when the surface potential of the cells is made more positive by pH adjustment or enzyme treatment. Similarly, hemagglutination is reduced by increasing concentrations of electrolytes. Hemagglutination is examined theoretically and is shown to be consistent with vesicle-cell interactions that are due to only electrostatic forces. Vesicles containing lysolecithin in addition to lecithin and stearylamine cause lysis of erythrocytes, provided the lipids of the vesicles are above the crystal-liquid crystal phase transition temperature. In addition, hemolysis requires close juxtaposition of the vesicle to the cell membrane; vesicles precoated with antibodies exhibit severely diminished hemolytic activities, only a small fraction of which can be attributed to a reduction in hemagglutination titer. Evidence is presented indicating that a single vesicle is sufficient to lyse one cell. With regard to hemagglutination and hemolysis, lipid vesicles of simple composition mimic paramyxoviruses such as Sendai virus.