Membrane contact, fusion, and hexagonal (HII) transitions in phosphatidylethanolamine liposomes

The behavior of phosphatidylethanolamine (PE) liposomes has been studied as a function of temperature, pH, ionic strength, lipid concentration, liposome size, and divalent cation concentration by differential scanning calorimetry (DSC), by light scattering, by assays measuring liposomal lipid mixing, contents mixing, and contents leakage, and by a new fluorometric assay for hexagonal (HII) transitions. Liposomes were either small or large unilamellar, or multilamellar. Stable (impermeable, nonaggregating) liposomes of egg PE (EPE) could be formed in isotonic saline (NaCl) only at high pH (greater than 8) or at lower pH in the presence of low ionic strength saline (less than 50 mOsm). Bilayer to hexagonal (HII) phase transitions and gel to liquid-crystalline transitions of centrifuged multilamellar liposomes were both detectable by DSC only at pH 7.4 and below. The HII transition temperature increased, and the transition enthalpy decreased, as the pH was raised above 7.4, and it disappeared above pH 8.3 where PE is sufficiently negatively charged. HII transitions could be detected at high pH following the addition of Ca2+ or Mg2+. No changes in light scattering and no lipid mixing, mixing of contents, or leakage of contents were noted for EPE liposomes under nonaggregating conditions (pH 9.2 and 100 mM Na+ or pH 7.4 and 5 mM Na+) as the temperature was raised through the HII transition region. However, when aggregation of the liposomes was induced by addition of Ca2+ or Mg2+, or by increasing [Na+], it produced sharp increases in light scattering and in leakage of contents and also changes in fluorescent probe behavior in the region of the HII transition temperature (TH). Lipid mixing and contents mixing were also observed below TH under conditions where liposomes were induced to aggregate, but without any appreciable leakage of contents. We conclude that HII transitions do not occur in liposomes under conditions where intermembrane contacts do not take place. Moreover, fusion of PE liposomes at a temperature below TH can be triggered by H+, Na+, Ca2+, or Mg2+ or by centrifugation under conditions that induce membrane contact. There was no evidence for the participation of HII transitions in these fusion events.     

Destabilization of phosphatidylethanolamine-containing liposomes: hexagonal phase and asymmetric membranes

We have measured the temperature of the L alpha-HII phase transition, TH, for several types of phosphatidylethanolamine (PE), their binary mixtures, and several PE/cholesteryl hemisuccinate (CHEMS) mixtures. We have shown for liposomes composed of pure PE and in mixtures with CHEMS that there is an aggregation-mediated destabilization which is greatly enhanced at and above TH. We now ask the question: How well can a dioleoylphosphatidylethanolamine/CHEMS liposome, for example, destabilize TPE (transesterified from egg phosphatidylcholine)/CHEMS liposome and vice versa? We use Ca2+ and H+ to induce aggregation and to provide different values of TH: the TH of the PE/CHEMS mixture is much lower at low pH than with Ca2+. We find that if the temperature is above the TH of one lipid mixture, e.g., A, and below the TH of the other lipid mixture, e.g., B, then the destabilization sequence [measured by the fluorescent 1-aminonaphthalene-3,6,8-trisulfonic acid/p-xylylenebis(pyridinium bromide) leakage assay] is AA greater than AB much greater than BB. That is, the bilayer of the lipid A (which on its own would end up in the HII phase) destabilizes itself better than it destabilizes the bilayer of lipid B (which on its own would remain in the L alpha phase). The BB contact is the least unstable. From these experiments, we conclude that the enhanced destabilization of membranes provided by the polymorphism accessible to these lipids above TH is effective even if only one of the apposed outer monolayers is HII phase competent. The surprising result is that if the temperature is above the TH of both lipid mixtures, then the destabilization sequence is AB greater than AA, BB. That is, the mixed bilayers are destabilized more by contact than either of the pure pairs. We believe that this is due to specific differences in the kinetics of aggregation or close approach of the membranes. Similar results were obtained with pure PE liposomes induced to aggregate by Ca2+ at pH 9.5. We also found that the kinetics of low-pH-induced leakage from PE/CHEMS liposomes were initially faster when the CHEMS on both sides of the bilayer is fully protonated. However, in a citrate buffer, which cannot cross intact membranes, the leakage was eventually faster. Flip-flop of the protonated CHEMS to the inner monolayer can explain this observation.     

beta-Galactosidase-induced destabilization of liposome composed of phosphatidylethanolamine and ganglioside GM1

A novel type of liposome bilayer destabilization catalyzed by the enzyme, beta-galactosidase, is described. Unsaturated phosphatidylethanolamine (PE), an HII-phase-forming lipid, does not form stable liposomes at physiological temperature and pH. However, stable unilamellar liposomes can be prepared by mixing PE with a minimum of 5 mol% ganglioside GM1, a micellar-phase-forming lipid. Treatment of these GM1/PE liposomes with beta-galactosidase induces a rapid leakage (3-6 min) of the entrapped fluorescent dye, calcein. The studies indicate that liposome destabilization is the result of catalytic degradation of GM1, rather than a stoichiometric binding of GM1 by beta-galactosidase. Kinetic data indicate that the destabilization takes place via liposome collision. This simple, rapid method of liposome destabilization by beta-galactosidase will be useful in designing a liposome-based signal amplification mechanism for assays involving enzymes.     

Fusion of phosphatidylethanolamine-containing liposomes and mechanism of the L alpha-HII phase transition

The initial kinetics of fusion and leakage of liposomes composed of N-methylated dioleoylphosphatidylethanolamine (DOPE-Me) have been correlated with the phase behavior of this lipid. Gagné et al. [Gagné, J., Stamatatos, L., Diacovo, T., Hui, S. W., Yeagle, P., & Silvius, J. (1985) Biochemistry 24, 4400-4408] have shown that this lipid is lamellar (L alpha) below 20 degrees C, is hexagonal (HII) above 70 degrees C, and shows isotropic 31P NMR resonances at intermediate temperatures. This isotropic state is also characterized by complex morphological structures. We have prepared DOPE-Me liposomes at pH 9.5 and monitored the temperature dependence of the mixing of aqueous contents, leakage, and changes in light scattering upon reduction of the pH to 4.5. At and below 20 degrees C, where the lipid is in the L alpha phase, there is very little aggregation or destabilization of the liposomes. Between 30 and 60 degrees C, i.e., where the lipid is in the isotropic state, the initial rates of liposome fusion (mixing of aqueous contents) and leakage increase. At temperatures approaching that where the hexagonal HII phase transition occurs, the initial rates and extents of fusion decrease, whereas leakage is enhanced. Similar results were found for dioleoylphosphatidylethanolamine/dioleoylphosphatidylcholine (2:1) liposomes. These results clearly establish a common mechanism between the appearance of the isotropic state (between the L alpha and HII phases) and the promotion of liposome fusion. We propose a simple model to explain both the observed behavior of phosphatidylethanolamine-containing membranes with respect to liposome fusion and/or lysis and the beginning of the L alpha-HII phase transition.     

脂质体通透性与脂多型性关系的研究

本文以TPE和TPE/DOPE(1:1.mol:mol)制成包裹荧光分子calcein的脂质体,通过测量荧光强度随扫描温度的变化,探讨了脂质体通透性与脂多型性之间的关系.结果表明,在不发生双层相(L)变成六角形Ⅱ相(H)相转变时,脂质体悬液的荧光强度不增加;当发生该转变时,脂质体悬液的荧光强度开始增加;完成该相转变后,脂质体悬液的荧光强度仍继续增加.据此,我们认为:脂质体的通透性与脂的多型性密切相关,当发生L→HⅡ相转变时,脂质体的通透性增加.由于荧光强度的变化对相变非常敏感,我们建议用测量脂质体荧光强度随温度的变化来监测脂质体稀悬液中脂的多型性.     

pH-Sensitive Liposomes

Abstract

pH sensitive liposomes are lipid compositions that can be destabilized when the external pH is changed; usually from a neutral or slightly alkaline pH to an acidic pH. They are designed to circumvent delivery of liposome contents to the lysosomes of cells following internalization of the vesicle via the endocytic pathway. In the majority of compositions, a lipid containing a pH titratable group is mixed with phosphatidylethanolamine containing unsaturated acyl chains in a molar ratio (pH sensitive component/PE) of 1/4 or greater. There are five major groups of phosphatidylethanolamine containing pH-senstive lipid compositions. These can be classified by their acid-titratable component: phospholipids, acylated amino acids, fatty acids, cholesterol derivatives and miscellaneous double chain amphiphiles. The biophysical mechanism of action involves a transition of the lipids from the lamellar phase to the hexagonal phase. In cell culture, pH sensitive vesicles can increase the delivery of fluorescent markers, proteins, cytotoxic compounds, RNA and DNA into the cytoplasm. The mechanism of delivery is suggested to involve the destabilization of the liposome in the endosome as the pH is reduced from 7.4 to 5.0 and subsequent destabilization of, or fusion with, the endosomal membrane; some of the liposome contents are introduced into the cytoplasm. In most cases, the extent of liposome contents delivery into the cytoplasm is less than 1% of the amount that becomes cell associated. However further studies, with more reliable assays to differentiate cytoplasmic from lysosomal delivery, are required to place an exact value on this efficiency. The efficiency of pH sensitive liposomes in vivo is limited by stability of certain of the liposome compositions in serum and targeting to the appropriate cell. Cholesterol hemisuccinate is a particularly attractive component for in vivo use since it stabilizes the liposome when in serum at pH 7.4. The use of pH sensitive liposomes in drug delivery should continue to expand due to the increasing number of macromolecular therapeutic agents with intracellular targets.     

H+- and Ca2+-induced fusion and destabilization of liposomes

A new liposome fusion assay has been developed that monitors the mixing of aqueous contents at neutral and low pH. With this assay we have investigated the ability of H+ to induce membrane destabilization and fusion. The assay involves the fluorophore 1-aminonaphthalene-3,6,8-trisulfonic acid (ANTS) and its quencher N,N'-p-xylylenebis(pyridinium bromide) (DPX). ANTS is encapsulated in one population of liposomes and DPX in another, and fusion results in the quenching of ANTS fluorescence. The results obtained with the ANTS/DPX assay at neutral pH give kinetics for the Ca2+-induced fusion of phosphatidylserine large unilamellar vesicles (PS LUV) that are very similar to those obtained with the Tb3+/dipicolinic acid (DPA) assay [Wilschut, J., & Papahadjopoulos, D. (1979) Nature (London) 281, 690-692]. ANTS fluorescence is relatively insensitive to pH between 7.5 and 4.0. Below pH 4.0 the assay can be used semiquantitatively by correcting for quenching of ANTS due to protonation. For PS LUV it was found that, at pH 2.0, H+ by itself causes mixing of aqueous contents, which makes H+ unique among the monovalent cations. We have shown previously that H+ causes a contact-induced leakage from liposomes composed of phosphatidylethanolamine and the charged cholesteryl ester cholesteryl hemisuccinate (CHEMS) at pH 5.0 or below, where CHEMS becomes protonated. Here we show that H+ causes lipid mixing in this pH range but not mixing of aqueous contents. This result affirms the necessity of using both aqueous space and lipid bilayer assays to comprehend the fusion event between two liposomes.     

Mechanism of pH-triggered collapse of phosphatidylethanolamine liposomes stabilized by an ortho ester polyethyleneglycol lipid

The mechanism of pH-triggered destabilization of liposomes composed of a polyethyleneglycol-orthoester-distearoylglycerol lipid (POD) and phosphatidyl ethanolamine (PE) has been studied using an ANTS/DPX leakage and a lipid-mixing assay. We developed a kinetic model that relates POD hydrolysis to liposome collapse. This minimum-surface-shielding model describes the kinetics of the pH-triggered release of POD/PE liposomes. In the model, when acid-catalyzed hydrolysis lowers the mole percentage of POD on the liposome surface to a critical level, intervesicular lipid mixing is initiated, resulting in a burst of contents release. Two phases of content leakage are observed: a lag phase and a burst phase. During the lag phase, less than 20% of liposomal contents are released and the leakage begins to accelerate when approaching to the transition point. During the burst phase, the leakage rate is dependent on interbilayer contact. The burst phase occurs when the surface density of the PEG lipid is 2.3 +/- 0.6 mol%, regardless of the pH. Vesicles containing 4 mol% of a pH-insensitive PEG-lipid conjugate and 10% POD did not leak contents or collapse at any pH. These data are consistent with the stalk theory to describe the lamellar-to-inverted hexagonal phase transition and set a lower bound of approximately 16 PE lipids on the external monolayer as the contact site required for lipid mixing between two bilayers.     

Acid- and calcium-induced structural changes in phosphatidylethanolamine membranes stabilized by cholesteryl hemisuccinate

The membrane stabilization effect of cholesteryl hemisuccinate (CHEMS) and the sensitivity of the CHEMS-phosphatidylethanolamine membranes to protons and calcium ions were studied by differential scanning calorimetry, freeze-fracture electron microscopy, and 31P NMR. (1) At neutral pH, the addition of 8 mol % CHEMS to transesterified egg phosphatidylethanolamine (TPE) raised the lamellar-hexagonal transition temperature of TPE by 11 degrees C. Stable bilayer vesicles were formed when the incorporated CHEMS exceeded 20 mol %. (2) At a pH below 5.5, the protonation of CHEMS enhanced the formation of the hexagonal phase (HII) of TPE. At 25 mol % CHEMS the bilayer-hexagonal transition temperature was lowered by 30 degrees C at pH 4.5. (3) The endothermic acid-induced hexagonal hexagonal transition of TPE-CHEMS was suppressed at 35 mol % CHEMS. However, 31P NMR and electron microscopy indicated that a lamellar-hexagonal transition still occurred at this composition. (4) The main transition of TPE was not affected by the protonation of the incorporated CHEMS, indicating that no macroscopic phase separation occurred in TPE-CHEMS mixtures at low pH. (5) In contrast to the HII-promoting effect of H+, the neutralization of the negative charge on TPE-CHEMS by Ca2+ resulted in aggregates that remained in the lamellar structure even at the hexagonal transition temperature of TPE. It is suggested that calcium might form a complex between CHEMS in apposed bilayers. These results are related to the possible biological function of acidic cholesterol esters in biomembranes.     

Stability and fusion of lipid vesicles containing headgroup-modified analogues of phosphatidylethanolamine

We have used lipid mixing, contents mixing and contents-leakage assays to characterize the divalent cation-mediated interactions of vesicles composed of various headgroup-modified analogues of phosphatidylethanolamine, PE (N- and C-2-alkylated derivatives, and analogues with increased separations of the phosphoryl and amino groups) together with a low mole percentage of phosphatidylserine (PS). Vesicles containing different structural analogues of PE exhibit marked differences, both in the threshold divalent cation concentrations that are required to initiate vesicle-vesicle interactions and in the rates of contents mixing and leakage observed at suprathresholds divalent cation concentrations. The efficiencies of divalent cation-promoted contents leakage, and to a slightly lesser extent those of contents mixing, for PS/PE (analogue) vesicles show a marked inverse correlation with the lamellar-to-hexagonal II transition temperature (TH) of the PE (analogue) component. However, the destabilization kinetics for such vesicles show no abrupt changes over the temperature range around the equilibrium TH value measured for the vesicle lipids. Vesicles combining PS with different PE analogues exhibit divalent cation thresholds for aggregation that are not correlated with the TH values of the PE (analogue) components but appear instead to be correlated with the equilibrium interbilayer separations measured in multilamellar dispersions of these species. We have identified headgroup-modified analogues of PE that can be used to prepare vesicles that fuse more rapidly under a given set of conditions, or that show a bette ratio of fusion-to-contents-leakage rates, than do PE-containing vesicles. These results may be useful both for understanding better the bases for the high fusion-supporting ability of PE and for the preparation of lipid vesicles 'tailored' for particular practical applications.     

Implications of a non-lamellar lipid phase for the tight junction stability. Part I: Influence of basic amino acids, pH and protamine on the bilayer-hexagonal II phase behaviour of PS-containing PE membranes.

Inverted lipid micelles have been proposed, among other biological functions, to constitute the structural basis of the so-called tight junctions, a special cell cell contact found in epithelia and endothelial, which act as a barrier for the paracellular solute passage. As a model system for the opening and closing of this gate, we investigated the formation of the inverted hexagonal phase (HII phase) in lipid bilayer systems consisting of egg phosphatidylethanolamine (egg PE) and mixed egg PE/bovine brain phosphatidylserine (BBPS) membranes. The formation of the HII phase was modulated by Ca2+ ions, pH, basic amino acids and protamine. The lamellar-HII phase transition temperature TH of pure egg PE membranes at pH 7.0 was lowered with increasing Ca2+ concentration. This effect was attenuated by the presence of 50 mM lysine methyl ester. In the mixed lipid system, this effect was also observed, but even more pronounced. However this effect could be compensated for by raising the Ca2+ concentration from 2 to 10 mM. This was not observed in the pure PE system. In the absence of Ca2+, lysine methyl ester and protamine lowered TH in both monocomponent and mixed lipid systems, whereas lysine caused the opposite effect. The pH-dependence of mixed lipid systems, which were investigated up to a BBPS content of 20 mol%, clearly shows that increasing PS content stabilizes the lamellar phase even at low pH. The results obtained with model membranes are discussed with respect to biological implications of the lamellar-HII phase transition for the modulation of tight junction stability.     

Proton and divalent cations induce synergistic but mechanistically different destabilizations of pH-sensitive liposomes composed of dioleoyl phosphatidylethanolamine and oleic acid

Protons and divalent cations show synergistic effects on the destabilization of liposomes composed of unsaturated phosphatidylethanolamine and oleic acid (Düzgünes et al., Biochemistry (1985) 24, 3091). We have extended these observations and investigated the effects of Ca2+ and Mg2+ on the proton-induced destabilization of dioleoyl phosphatidylethanolamine/oleic acid (DOPE/OA) (4:1 molar ratio) liposomes. Temperature-induced aggregation was measured by 90 degrees light scattering. Lipid mixing was used to monitor vesicle destabilization and freeze-fracture electron microscopy was used to examine the structures formed from DOPE/OA vesicles in the presence of Ca2+ and/or protons. Both Mg2+ and Ca2+ shift the pH required for 50% lipid mixing to higher values. Temperature-induced vesicle aggregation occurs at lower temperatures in the presence of divalent cations and/or protons, indicating that intervesicular repulsions are decreased. Freeze-fracture electron micrographs show that the structures formed from DOPE/OA in the presence of Ca2+ differ significantly from those found in the presence of protons. In general, protons induce the formation of hexagonal phase, while the presence of Ca2+ leads to the formation of extensive regions of lamellar sheets with numerous lipidic particles. The synergistic effect of divalent cations and proton may be important for the maximal biological activity of DOPE/OA liposomes.     

Inverted micellar intermediates and the transitions between lamellar, cubic, and inverted hexagonal lipid phases. II. Implications for membrane-membrane interactions and membrane fusion.

Results of a kinetic model of thermotropic L alpha----HII phase transitions are used to predict the types and order-of-magnitude rates of interactions between unilamellar vesicles that can occur by intermediates in the L alpha----HII phase transition. These interactions are: outer monolayer lipid exchange between vesicles; vesicle leakage subsequent to aggregation; and (only in systems with ratios of L alpha and HII phase structural dimensions in a certain range or with unusually large bilayer lateral compressibilities) vesicle fusion with retention of contents. It was previously proposed that inverted micellar structures mediate membrane fusion. These inverted micellar structures are thought to form in all systems with such transitions. However, I show that membrane fusion probably occurs via structures that form from these inverted micellar intermediates, and that fusion should occur in only a sub-set of lipid systems that can adopt the HII phase. For single-component phosphatidylethanolamine (PE) systems with thermotropic L alpha----HII transitions, lipid exchange should be observed starting at temperatures several degrees below TH and at all higher temperatures, where TH is the L alpha----HII transition temperature. At temperatures above TH, the HII phase forms between apposed vesicles, and eventually ruptures them (leakage). In most single-component PE systems, fusion via L alpha----HII transition intermediates should not occur. This is the behavior observed by Bentz, Ellens, Lai, Szoka, et al. in PE vesicle systems. Fusion is likely to occur under circumstances in which multilamellar samples of lipid form the so-called "inverted cubic" or "isotropic" phase. This is as observed in the mono-methyl DOPE system (Ellens, H., J. Bentz, and F. C. Szoka. 1986. Fusion of phosphatidylethanolamine containing liposomes and the mechanism of the L alpha-HII phase transition. Biochemistry. In press.) In lipid systems with L alpha----HII transitions driven by cation binding (e.g., Ca2+-cardiolipin), fusion should be more frequent than in thermotropic systems.     

Kinetic and ultrastructural studies of interactions of target-sensitive immunoliposomes with herpes simplex virus

The bilayer phase of dioleoylphosphatidylethanolamine (PE) can be stabilized with palmitoyl-IgG monoclonal antibody to the glycoprotein gD of the herpes simplex virus (HSV). Interactions of PE immunoliposomes with the target virions were characterized by analyzing the kinetics of lipid mixing, by liposomal content release, and by ultrastructural studies. As revealed by a resonance energy transfer assay, lipid mixing between PE immunoliposomes and virions was very rapid, with a second-order rate constant (kapp) of 0.173 (min)-1 (microgram/mL virus)-1. In comparison, content release from PE immunoliposomes was much slower and exhibited multiple-phase, mixed-order kinetics, indicating that liposome destabilization involved fusion of liposomes with HSV. The extent and the apparent rate of liposome destabilization were strongly dependent on liposome concentration. This was evident by the fact that only one to two liposomes were destabilized by each virus particle at low liposome concentration (0.1 microM). For higher liposome concentrations (1-10 microM), this value was 35-104. This finding implies that collision among the virus-bound liposomes is essential for the eventual collapse of PE immunoliposomes to form the hexagonal (HII) equilibrium phase which was observed using freeze-fracture electron microscopy. Studies employing soluble gD, immobilized on latex beads, indicated that a multivalent antigen source is essential for PE immunoliposome destabilization. Immediately after liposome-virus binding, fusion of liposome with the viral membrane then follows. Upon growth of the fusion complexes, which increase to 35-104 liposomes for each virus, an eventual collapse of the structure results, driving PE to its equilibrium structure of HII phase.     

Synexin enhances the aggregation rate but not the fusion rate of liposomes

The effect of synexin on the calcium-induced fusion of large unilamellar liposomes was studied by using two assays for the mixing of aqueous contents. The results were analyzed in terms of the mass action kinetic model, which describes the overall fusion reaction as a two-step sequence consisting of a second-order process of liposome aggregation followed by a first-order fusion reaction. By using several different lipid compositions and varying the electrolyte composition, it was possible to select the rate-limiting step of the overall fusion process. When aggregation was the rate-limiting step, as in the case of Ca2+-induced fusion of phosphatidylserine (PS), phosphatidate (PA)/phosphatidylethanolamine (PE) (1:3), and PS/PE (1:3) liposomes, synexin increased the overall fusion kinetics by increasing the aggregation rate constant (up to 100-fold). When aggregation was rapid compared to destabilization of apposed membranes, i.e., fusion was rate limiting, synexin either had no effect or reduced the overall fusion kinetics. In one such case involving liposomes composed of PA/PS/PE/phosphatidylcholine (PC) (10:15:65:10), synexin reduced the fusion rate constant by 50%. The effect of calcium-induced synexin polymerization was investigated by preincubation of synexin with calcium prior to addition of liposomes. Prepolymerization by Ca2+ always decreased the activity of synexin such that it was less than the activity of an equal amount of untreated monomers. However, it was found that the activity of synexin monomers polymerized to an average hexameric size was greater than that of one-sixth as many untreated monomers, with respect to the liposome aggregation rate constant. Neither polymers nor monomers increased the fusion rate constant.     

Membrane fusion and inverted phases

We have found a correlation between liposome fusion kinetics and lipid phase behavior for several inverted phase forming lipids. N-Methylated dioleoylphosphatidylethanolamine (DOPE-Me), or mixtures of dioleoylphosphatidylethanolamine (DOPE) and dioleoylphosphatidylcholine (DOPC), will form an inverted hexagonal phase (HII) at high temperatures (above TH), a lamellar phase (L alpha) at low temperatures, and an isotropic/inverted cubic phase at intermediate temperatures, which is defined by the appearance of narrow isotropic 31P NMR resonances. The phase behavior has been verified by using high-sensitivity DSC, 31P NMR, freeze-fracture electron microscopy, and X-ray diffraction. The temperature range over which the narrow isotropic resonances occur is defined as delta TI, and the range ends at TH. Extruded liposomes (approximately 0.2 microns in diameter) composed of these lipids show fusion and leakage kinetics which are strongly correlated with the temperatures of these phase transitions. At temperatures below delta TI, where the lipid phase is L alpha, there is little or no fusion, i.e., mixing of aqueous contents, or leakage. However, as the temperature reaches delta TI, there is a rapid increase in both fusion and leakage rates. At temperatures above TH, the liposomes show aggregation-dependent lysis, as the rapid formation of HII phase precursors disrupts the membranes. We show that the correspondence between the fusion and leakage kinetics and the observed phase behavior is easily rationalized in terms of a recent kinetic theory of L alpha/inverted phase transitions. In particular, it is likely that membrane fusion and the L alpha/inverted cubic phase transition proceed via a common set of intermembrane intermediates.     

Stimulation of superoxide release in neutrophils by 1-oleoyl-2-acetylglycerol incorporated into pH-sensitive liposomes

Incorporation of 1-oleoyl-2-acetylglycerol (OAG) into multilamellar liposomes composed of egg phosphatidylethanolamine (PE) and arachidonic acid (AA) resulted in a significant enhancement of superoxide release by guinea pig neutrophils when compared to free OAG. OAG incorporated into liposomes containing phosphatidylcholine and arachidonic acid were generally less effective than free OAG. The potency of the liposomes correlates well with the ability of the liposomes to undergo lipid mixing at acidic pH. The enhanced effect of liposome-associated OAG could be related to exposure to an acidic environment in the endosomes/lysosomes once liposomes are endocytosed by neutrophils.     

Trypsin induced destabilization of liposomes composed of dioleoylphosphatidylethanolamine and glycophorin

Destabilization of liposomes composed of phosphatidylethanolamine (PE) and purified glycophorin of human erythrocytes was studied with the release of an entrapped fluorescent dye, calcein. Proteolytic cleavage of liposomes by trypsin induced a rapid increase of turbidity and the leakage of calcein from the liposomes. Kinetic experiments indicated that the destabilization was a second order reaction, i.e. it required liposome collision. Using N-(7-nitro-2,1,3-benzoxadiazol-4-yl) PE as a fluorescent probe for the formation of hexagonal phase of PE, tryptic digestion of the liposomes resulted in a higher tendency of the PE bilayer to transform into the hexagonal phase. We propose that hexagonal (or inverted micellar) structures are involved in the trypsin induced liposome destabilization.     

Structural and functional comparisons of pH-sensitive liposomes composed of phosphatidylethanolamine and three different diacylsuccinylglycerols

The titratable, double-chain amphiphiles 1,2-dipalmitoyl-sn-3-succinylglycerol (1,2-DPSG), 1,2-dioleoyl-sn-3-succinylglycerol (1,2-DOSG) and 1,3-dipalmitoylsuccinylglycerol (1,3-DPSG) have been used in combination with phosphatidylethanolamine (PE) to form pH-sensitive liposomes. The effect of the compounds on dielaidoyl PE bilayer stabilization was examined by differential scanning calorimetry. Only 1,2-DPSG showed bilayer stabilization activity; whereas the other two are destabilizers at pH 7.4. All three amphiphiles became strong destabilizers at pH 5.0. The ability of the amphiphiles to stabilize DOPE liposomes was examined by light scattering and calcein entrapment. In general, 1,2-DPSG is the most potent stabilizer of PE bilayers while 1,3-DPSG is the weakest liposome stabilizer. All three compounds can be combined with DOPE to generate liposomes which are stable at neutral and basic pH. At weakly acidic pH, the liposomes are leaky and exhibit extensive lipid mixing, with protons and calcium showing synergistic effects on lipid mixing. DOPE/1,2-DPSG liposomes are stable in human plasma and remain acid-sensitive even after prolonged plasma incubation. Immunoliposomes prepared from either DOPE/1,2-DPSG or DOPE/1,2-DOSG can deliver diphtheria toxin A fragment to the cytoplasm of cultured cells in a process which involves endocytosis of the liposomes. Immunoliposomes prepared with 1,2-DPSG are more effective drug carriers than those prepared with 1,2-DOSG. These results indicate that the bilayer- and, hence the liposome-stabilization activity of the diacylsuccinylglycerol depends on the structure of the compounds. The potential drug delivery activity of the pH-sensitive liposomes composed of these lipids is discussed.     

Resonance energy-transfer and fluorescence intensity studies of the transport of liposome-encapsulated molecules into isolated mouse liver nuclei

We present evidence that liposomes (composed of egg yolk L-alpha-phosphatidylcholine/phosphatidylethanolamine/cholesterol, in a molar ratio of 4:5:1) fuse with isolated mouse liver nuclei at low pH. Using the resonance energy-transfer assay, we determined the rate and extent of liposome and nuclear membrane lipid mixing. Fusion was substantial when the pH was below 5. The half-time of lipid mixing decreased by acidification of the solvent, reaching about 2 min at pH 4.5. In order to study the transport of the liposome-aqueous contents to the interior of the nuclei during the process, we developed fluorescence assays in which fluorescein isothiocyanate labeled dextrans of 150 kDa molecular mass (FITC-D150) were encapsulated in liposomes. These liposomes also included in their bilayers the fluorescent lipid N-tetramethylrhodamine-L-alpha-dipalmitoylphosphatidylethanolamine (N-Rh-DPPE). After incubation of these liposomes with mouse liver nuclei (pH 4.5, 37 degrees C, 30 min), we measured the fluorescence spectra of a suspension of washed nuclei and of nuclei treated by the detergent Triton X-100 (membrane-denuded nuclei). These Triton X-100 treated nuclei had no N-Rh-DPPE fluorescence while they showed a FITC-D150 fluorescence which amounted to 20% of that of the intact nuclei. In another assay, a laser beam was focused on single nuclei by a microscope epiexcitation device. The variation of the N-Rh-DPPE and FITC-D150 fluorescence with the nuclear radius was determined with the microphotometric attachment of the microscope.(ABSTRACT TRUNCATED AT 250 WORDS)