The mode of action of polyacetylene and thiophene photosensitizers on liposome permeability to glucose

The mode of action of the two photosensitizers 1-phenylhepta-1,3,5-triyne and alpha-terthienyl on membrane permeability was investigated using liposomes entrapped with glucose as a model membrane system. Upon exposure to UV-A light, alpha-terthienyl, and to a much lesser extent phenylheptatriyne, induced leakage of glucose via a photodynamic mechanism in liposomes which had a high degree of unsaturated fatty acid side chains. Enhanced permeability to glucose in these liposomes due to the action of alpha-terthienyl and phenylheptatriyne involved lipid peroxidation, but neither of the two assays used to monitor lipid peroxidation (malondialdehyde and peroxide formation) was directly correlated with the increase in liposome permeability. In liposomes with highly ordered lipid where the fatty acid side chains are saturated, alpha-terthienyl had no effect on glucose permeability. In contrast, phenylheptatriyne was very effective in increasing glucose permeability in these liposomes via a photodynamic mechanism. Addition of lysophosphatidylcholine, which perturbs the order of lipid packing, to these liposomes, completely inhibited the effect of phenylheptatriyne. Conversely, incorporation of cholesterol which increases lipid order, into egg PC liposomes, enhanced the action of phenylheptatriyne. These data suggest that under UV-A irradiation (a) alpha-terthienyl and phenylheptatriyne enhance permeability in liposomes with a high degree of unsaturation involving lipid peroxidation and (b) phenylheptatriyne enhances membrane permeability through some other mechanism when present in a bilayer with a highly ordered lipid environment.     

The mode of action of polyacetylene and thiophene photosensitizers on liposome permeability to glucose

The mode of action of the two photosensitizers 1-phenylhepta-1,3,5-triyne and α-terthienyl on membrane permeability was investigated using liposomes entrapped with glucose as a model membrane system. Upon exposure to UV-A light, α-terthienyl, and to a much lesser extent phenylheptatriyne, induced leakage of glucose via a photodynamic mechanism in liposomes which had a high degree of unsaturated fatty acid side chains. Enhanced permeability to glucose in these liposomes due to the action of α-terthienyl and phenylheptatriyne involved lipid peroxidation, but neither of the two assays used to monitor lipid peroxidation (malondialdehyde and peroxide formation) was directly correlated with the increase in liposome permeability. In liposomes with highly ordered lipid where the fatty acid side chains are saturated, α-terthienyl had no effect on glucose permeability. In contrast, phenylheptatriyne was very effective in increasing glucose permeability in these liposomes via a photodynamic mechanism. Addition of lysophosphatidylcholine, which perturbs the order of lipid packing, to these liposomes, completely inhibited the effect of phenylheptatriyne. Conversely, incorporation of cholesterol which increases lipid order, into egg PC liposomes, enhanced the action of phenylheptatriyne. These data suggest that under UV-A irradiation (a) α-terthienyl and phenylheptatriyne enhance permeability in liposomes with a high degree of unsaturation involving lipid peroxidation and (b) phenylheptatriyne enhances membrane permeability through some other mechanism when present in a bilayer with a highly ordered lipid environment.     

The role of membrane bound glycoprotein on the permeability of liposomes

The liposome permeability to potassium and methanosulfonate ions was determined in the presence of bound glycoprotein and protein. The permeability changes were registered by light-scattering measurements of the osmotic volume changes of liposome suspension after mixing with solutions containing K+ and MS- ions respectively. The permeability changes varied considerably with the change of glycoprotein-protein molar ratio in the liposomes. It was suggested that topological distribution of both molecules (glycoprotein and protein) in the lipid bilayer would play a substantial role and influence the permeability. It was confirmed from fluorescence measurements with ANS as a fluorescence marker. There was an increase of the number of binding sites (n) for ANS, increasing glycoprotein-protein molar ratio in the liposomes. These results were interpreted in terms of electrostatical changes of the membrane lipid region and membrane surface, caused by the interaction of glycoprotein and protein with lipids, as well as the associated role of these components on the permeability.     

Mycobacteria glycolipids as potential pathogenicity effectors: alteration of model and natural membranes

Four mycobacterial wall glycolipids were tested for their effects on phospholipidic liposome organization and passive permeability and on oxidative phosphorylation of isolated mitochondria. From fluorescence polarization of diphenylhexatriene performed on liposomes it was concluded that the two trehalose derivatives (dimycoloyltrehalose and polyphthienoyltrehalose) rigidified the fluid state of liposomes, the triglycosyl phenolphthiocerol slightly fluidized the gel state, while the peptidoglycolipid ("apolar" mycoside C) just shifted the phase transition temperature upward. Dimycoloyltrehalose was without effect on liposome passive permeability, as estimated from dicarboxyfluorescein leak rates, and polyphthienoyltrehalose and triglycosyl phenolphthiocerol slightly decreased leaks, while mycoside C dramatically increased leaks. Activity of these lipids on mitochondrial oxidative phosphorylation was examined. The two trehalose derivatives have been tested previously: both had the same type of inhibitory activity, dimycoloyltrehalose being the most active. Triglycosyl phenolphthiocerol was inactive. Mycoside C was very active, with effects resembling those of classical uncouplers: this suggested that its activity on mitochondria was related to its effect on permeability. All these membrane alterations were called nonspecific because it is likely that they result from nonspecific lipid-lipid interactions, and not from recognition between specific molecular structures. Such nonspecific interactions could be at the origin of some of the effects of mycobacteria glycolipids on cells of the immune system observed in the last few years.     

Adrenocorticotropic hormone (ACTH)-lipid interactions. Implications for involvement of amphipathic helix formation

ACTH-lipid interactions were investigated by: (1) lipid-monolayer studies using several zwitterionic and anionic phospholipids and gangliosides, (2) permeability experiments by following the swelling rate of liposomes in isotonic glycerol solutions by light scattering, using liposomes of synthetic lipids and liposomes made of lipids extracted from light synaptic plasma membranes, and (3) by steady-state fluorescence anisotropy measurements on liposomes derived from light synaptic plasma membranes employing 1,6-diphenyl-1,3,5-hexatriene as fluorescent probe. (1) The monolayer experiments demonstrated an interaction with gangliosides GT1, GM1, dioleoylphosphatidic acid and phosphatidylserine, but little or no interaction with phosphatidylcholine or sphingomyelin. The interaction with monolayers of GT1 or phosphatidic acid decreased for ACTH1-13-NH2 and ACTH1-10. (2) The liposome experiments showed that 2 X 10(-5) M ACTH1-24 increased the glycerol permeability by 20% and decreased the activation energy only when liposomes derived from light synaptic plasma membranes were used. Treatment of the liposomes with neuraminidase abolished the ACTH-induced permeability increase. (3) Steady-state fluorescence depolarization measurements revealed that ACTH1-24, ACTH1-16-NH2 and ACTH1-10 did not change the fluidity of liposomes derived from light synaptic plasma membranes as sensed by diphenylhexatriene. It is concluded that ACTH1-24 can bind to negatively charged lipids and can form an amphipathic helix aligned parallel to the membrane surface involving the N-terminal residues 1 to 12, possibly to 16. Polysialogangliosides will favorably meet the condition of a high local surface charge density under physiological circumstances. It is suggested that ACTH-ganglioside interactions will participate in ACTH-receptor interactions.     

Distribution of [3H]cholesterol-labelled liposomes with or without praziquantel in mice infected with Mesocestoides corti (Cestoda) tetrathyridia

The anthelmintic drug praziquantel (PZQ) has a short half-life in the circulation, necessitating repeated daily administration of PZQ for the therapy of larval stages of cestodes. The effect of incorporation of PZQ into multilamellar liposomes on their biodistribution in Mesocestoides corti (syn. M. vogae) infected mice has been examined using [3H]cholesterol as a liposomal marker. Incorporation of PZQ significantly increased the average size of liposomes with 70.3% of [3H]lip.PZQ particles up to 1.9 microm, whereas higher portion of [3H]liposomes (66.3% of total) were of smaller (up to 1.3 microm). Both liposome preparations were given intraperitoneally to avoid rapid sequestration in the liver. There were significant differences between [3H]liposomes and [3H]lip.PZQ-associated radioactivity in peritoneal adherent cells, liver- and peritoneal larvae, liver, spleen and lymph nodes within 16 days of examination. The highest uptake (about 2-fold more [3H]lip.PZQ than [3H]liposomes from the total dose) was found in peritoneal cells on day 1 post therapy (p.t.) followed by a rapid decline. The kinetic of decline in these cells recovered on day 1 p.t. was studied also in vitro. Disappearance of the marker due to the breakdown of liposomes and efflux of lipids and PZQ from cells was slower for [3H]lip.PZQ in comparison with drug-free liposomes and was not completed after 4 days-incubation. Significantly increased levels of radioactivity, more in [3H]liposomes treated groups, were recorded in the liver- and peritoneal larvae between days 8-16 p.t. indicating re-utilization of cholesterol by the larvae. The data suggest that incorporation of PZQ into liposomes contributes to the enlargement of liposome average size and slows down their degradation in phagocytosing cells. In this respect, these cells could serve as the secondary circulating depots for PZQ releasing it slowly to the circulation.     

Novel immobilized liposomal glucose oxidase system using the channel protein OmpF and catalase

The reactivity of immobilized glucose oxidase-containing liposomes (IGOL) prepared in our previous work (Wang et al. [2003] Biotechnol Bioeng 83:444-453) was considerably improved here by incorporating the channel protein OmpF from Escherichia coli into the liposome membrane as well as by entrapping inside the liposome's aqueous interior not only glucose oxidase (GO), but also catalase (CA), both from Aspergillus niger. CA was used for decomposing the hydrogen peroxide produced in the glucose oxidation reaction inside the liposomes. The presence of OmpF enhanced the transport of glucose molecules from the exterior of the liposomes to the interior. In a first step of the work, liposomes containing GO and CA (GOCAL) were prepared and characterized. A remarkable protection effect of the liposome membrane on CA inside the liposomes at 40 degrees C was found; the remaining CA activity at 72 h incubation was more than 60% for GOCAL, while less than 20% for free CA. In a second step, OmpF was incorporated into GOCAL membranes, leading to the formation of OmpF-embedded GOCAL (abbreviated GOCAL-OmpF). The activity of GO inside GOCAL-OmpF increased up to 17 times in comparison with that inside GOCAL due to an increased glucose permeation across the liposome bilayer, without any leakage of GO or CA from the liposomes. The optimal system was estimated to contain on average five OmpF molecules per liposome. Finally, GOCAL-OmpF were covalently immobilized into chitosan gel beads. The performance of this novel biocatalyst (IGOCAL-OmpF) was examined by following the change in glucose conversion, as well as by following the remaining GO activity in successive 15-h air oxidations for repeated use at 40 degrees C in an airlift bioreactor. IGOCAL-OmpF showed higher reactivity and reusability than IGOL, as well as IGOL containing OmpF (IGOL-OmpF). The IGOCAL-OmpF gave about 80% of glucose conversion even when the catalyst was used repeatedly four times, while the corresponding conversions were about 60% and 20% for the IGOL and IGOL-OmpF, respectively. Due to the absence of CA, IGOL-OmpF was less stable and resulted in drastically inhibited GO.     

The physical properties and photopolymerization of diacetylene-containing phospholipid liposomes

(a) The physical properties and photopolymerization of diacetylene-containing phosphatidylcholines with acyl chains of different length and in liposome form have been studied. (b) The structure of these liposomes and their stability during polymerization have been examined using electron microscopy and glucose trapping. (c) Photopolymerization of the diacetylene groupings has been followed by monitoring the conversion of monomer and the formation of coloured polymer and the optimum conditions for polymerization have been established. (d) Changes induced by irradiation on the phase transition behaviour of these lipids were determined by differential scanning calorimetry. Polymerization decreases both the transition temperature and the enthalpy of the main endothermic transition. (e) The permeability of liposomes to glycerol is changed as a result of the polymerization process.     

Application of purging biotinylated liposomes from plasma to elucidate influx and efflux processes associated with accumulation of liposomes in solid tumors

Although small, 100-nm liposomes are known to selectively accumulate in solid tumors, the individual contributions of liposome influx and egress rates are not well understood. The aim of this work was to determine influx and efflux kinetics for 100-nm, 1,2-distearoyl-sn-glycero-3-phosphocholine (DSPC)/cholesterol (Chol) liposomes by inducing aggregate formation of biotinylated liposomes upon administering avidin. Injecting 50 microg of neutravidin intravenously to mice that had previously been administered 100 mg/kg DPSC/Chol liposomes containing 0.5 mol% biotin-conjugated lipid resulted in >90% elimination of the liposomes from plasma within 1 h. This rapid removal by the reticuloendothelial system (RES) permitted the determination of the tumor efflux kinetics due to negligible tumor influx after neutravidin injection. The tumor efflux rate constant (k(-1)) was determined to be 0.041 h(-1) when neutravidin was injected 4 h after liposome injection. This allowed the determination of the tumor influx rate constant (k(1)), which under these conditions was 0.022 h(-1). Therefore, DSPC/Chol liposomal accumulation, in LS180 solid tumors, is dictated primarily by plasma liposome concentrations and liposome egress is comparable or slightly faster than influx into the tumors. This method is applicable for a wide range of lipid doses, and can be used to characterize influx and efflux parameters at different time points after accumulation. The application, therefore, has the potential to be used to fully characterize the impact of different liposome parameters such as lipid composition, steric stabilization, size and dose on tumor accumulation kinetics.     

Release of macromolecular markers (enzymes) from liposomes treated with antibody and complement: An attempt at correlation with electron microscopic observations

Antibody-complement dependent damage to liposomal model membranes has been previously investigated by measuring the release of low molecular weight markers such as glucose. To determine whether larger solutes are also released under these conditions, experiments have been performed using immunologically sensitive liposomes that contained not only trapped glucose, but also enzymes (hexokinase, glucose-6-phosphate dehydrogenase, β-galactosidase) as macromolecular markers. The largest of these enzymes (β-galactosidase) has dimensions which closely approximate the diameter of the lesions detected by negative staining in natural membranes after immune lysis. Liposomes prepared with lecithin, and either actively sensitized with globoside or passively sensitized with alkali-treated lipopolysaccharide, released the enzymes in parallel with glucose upon incubation with the appropriate antiserum and native guinea pig serum as source of complement. Immune damage to sphingomyelin liposomes was characterized by a significantly lower loss of the enzymes in comparison to the percentage of glucose released; a comparable response was manifested by liposomes prepared from sheep erythrocyte lipids. Electron microscopic examination of negatively stained lecithin liposomes, which had released the macromolecular markers, failed to reveal the characteristics lesions; these findings are consistent with evidence obtained by other laboratories suggesting that the lesions may not correspond to functional holes. Lesions were, however, consistently observed in liposome preparations that had been treated with the polyene antibiotics, filipin; this antibiotic causes appreciable loss of both glucose and enzymes from either lecithin or sphingomyelin liposomes.     

pH gradient loading of anthracyclines into cholesterol-free liposomes: enhancing drug loading rates through use of ethanol

Application of cholesterol-free liposomes as carriers for anticancer drugs is hampered, in part, because of standard pH gradient based loading methods that rely on incubation temperatures above the phase transition temperature (Tc) of the bulk phospholipid to promote drug loading. In the absence of cholesterol, liposome permeability is enhanced at these temperatures which, in turn, can result in the collapse of the pH gradient and/or unstable loading. Doxorubicin loading studies, for example, indicate that the drug could not be loaded efficiently into cholesterol-free DSPC liposomes. We demonstrated that this problem could be circumvented by the addition of ethanol as a permeability enhancer. Doxorubicin loading rates in cholesterol-free DSPC liposomes were 6.6-fold higher in the presence of ethanol. In addition, greater than 90% of the added doxorubicin was encapsulated within 2 h at 37 degrees C, an efficiency that was 2.3-fold greater than that observed in the absence of ethanol. Optimal ethanol concentrations ranged from 10% to 15% (v/v) and these concentrations did not significantly affect liposome size, retention of an aqueous trap marker (lactose) or, most importantly, the stability of the imposed pH gradient. Cryo-transmission electron micrographs of liposomes exposed to increasing concentrations of ethanol indicated that at 30% (v/v) perturbations to the lipid bilayer were present as evidenced by the appearance of open liposomes and bilayer sheets. Ethanol-induced increased drug loading was temperature-, lipid composition- and lipid concentration-dependent. Collectively, these results suggest that ethanol addition to preformed liposomes is an effective method to achieve efficient pH gradient-dependent loading of cholesterol-free liposomes at temperatures below the Tc of the bulk phospholipid.     

Interaction of cells from murine organs with liposomes of various composition

The distribution of liposomes prepared from total mouse liver lipids and containing (3H)-labelled platelet activation factor in mouse organs was studied. It was shown that the majority of intraperitoneally injected liposomes prepared from total mouse liver lipids were transported to mouse liver and spleen. The interaction of liposomes with spleen cells in vitro revealed that the affinity of liposomes prepared from total spleen macrophage or total spleen lymphocyte lipids for mouse spleen cells was much higher than that of liposomes prepared from a model lipid mixture. The liposome binding to isolated spleen macrophages or lymphocytes was much higher than the liposome uptake by these cells in the total population of mouse spleen cells.     

Kinetics of the interaction of hemin liposomes with heme binding proteins

As a model for the transport of hemin across biological membranes, sonicated phosphatidylcholine liposomes with incorporated hemin were characterized. The interaction of the hemin liposomes with the heme binding proteins albumin, apomyoglobin, and hemopexin was examined as a function of liposome charge and cholesterol content. In all cases, there was an almost complete transfer of hemin from liposome to protein; a rapid phase and a slow phase were observed for the transfer. For negatively charged liposomes (with 11% dicetyl phosphate), the rapid and slow phases showed observed rates of transfer of ca. 2 and 0.01 s-1, respectively, for all three proteins. The presence of cholesterol in the liposomes decreased the observed rates by a factor of 2, and positively charged liposomes (with 11% stearylamine) showed about one-fifth the observed rates of negatively charged liposomes. The observed rates were independent of protein concentration, indicating that the rate-determining step is hemin efflux from the lipid bilayer. The hemin interaction with the phospholipid bilayer is suggested to be primarily hydrophobic with some electrostatic character. The two phases are suggested to arise from two different populations of hemin within the liposomes and are interpreted as arising from two different orientations of hemin within the bilayer.     

The effect of aging on the physical stability of liposome dispersions.

In this study, the effect of aging, in terms of hydrolytic decomposition of the bilayer forming (phospho)lipids, on the physical stability of aqueous liposome dispersion was investigated in partially hydrogenated egg phosphatidylcholine (PHEPC) and egg phosphatidylglycerol (EPG) containing liposomes with or without cholesterol. The physical stability of the liposome dispersions was assessed by measuring the leak-in rate of a non-bilayer interacting hydrophilic marker molecule, calcein and changes in the particle size and its distribution in time. Additionally, permeability of either partially hydrolysed phospholipids or exogenous lyso-phosphatidylcholine(LPC) containing bilayers was calculated. The experiments were performed at 40 degrees C. Liposome dispersions were aged artificially by storing at 60 degrees C. The size of the liposomes and polydispersity index of the dispersions, in general, did not change significantly. The leak-in rate of calcein in externally added LPC containing liposomes was increased relative to the incorporated LPC concentration. The higher the LPC content of the bilayers, the higher the leak-in rate of calcein into liposomes. The leak-in rate of calcein, however, decreased first in partially hydrolysed phospholipids containing liposomes up to around 10% of hydrolysis and, afterwards, it started to increase. The leak-in rate was always lower in partially hydrolysed phospholipids containing liposomes than externally added LPC containing ones. Furthermore, the permeability of cholesterol containing bilayers was also always lower than the bilayers without cholesterol. In conclusion, addition of LPC into liposomal bilayers increases the permeability of bilayer. However, bilayers containing the hydrolysis products of phospholipids, both lyso-phospholipids and free fatty acids, did not show any enhanced permeability up to around 15% hydrolysis. Bilayer permeability is enhanced above 15% hydrolysis.     

Adrenocorticotropic hormone (ACTH)-lipid interactions. Implication for involvement of amphipathic helix formation

ACTH-lipid interactions were investigated by: (1) lipid-monolayer studies using several zwitterionic and anionic phospholipids and gangliosides, (2) permeability experiments by following the swelling rate of liposomes in isotonic glycerol solutions by light scattering, using liposomes of synthetic lipids and liposomes made of lipids extracted from light synaptic plasma membranes, and (3) by steady-state fluorescence anisotropy measurements on liposomes derived from light synaptic plasma membranes employing 1,6-diphenyl-1,3,5-hexatriene as fluorescent probe. (1) The monolayer experiments demonstrated an interaction with gangliosides G_T1, G_M1, dioleoylphosphatidic acid and phosphatidylserine, but little or no interaction with phosphatidylcholine or sphingomyelin. The interaction with monolayers of G_T1 or phosphatidic acid decreased for ACTH_1-13-NH₂ and ACTH_1-10. (2) The liposome experiments showed that $\text{2·10}{}^{\mathrm{?5}}$ M ACTH_1–24 increased the glycerol permeability by 20% and decreased the activation energy only when liposomes derived from light synaptic plasma membranes were used. Treatment of the liposomes with neuraminidase abolished the ACTH-induced permeability increase. (3) Steady-state fluorescence depolarization measurements revealed that ACTH_1–24, ACTH_1-16-NH₂ and ACTH_1–10 did not change the fluidity of liposomes derived from light synaptic plasma membranes as sensed by diphenylhexatriene. It is concluded that ACTH_1–24 can bind to negatively charged lipids and can form an amphipathic helix aligned parallel to the membrane surface involving the N-terminal residues 1 to 12, possibly to 16. Polysialogangliosides will favorably meet the condition of a high local surface charge density under physiological circumstances. It is suggested that ACTH-ganglioside interactions will participate in ACTH-receptor interactions.     

Interactions between pH-sensitive liposomes and model membranes

The structure and dynamics of two different pH-sensitive liposome systems were investigated by means of cryo-transmission electron microscopy and different photophysical techniques. Both systems consisted of dioleoylphosphatidylethanolamine (DOPE) and contained either oleic acid (OA) or a novel acid-labile polyethylene glycol-conjugated lipid (DHCho-MPEG5000) as stabiliser. Proton induced leakage, lipid mixing and structural changes were studied in the absence and presence of EPC liposomes, as well as in the presence of liposomes designed to model the endosome membrane. Neither DHCho-MPEG5000- nor OA-stabilised liposomes showed any tendency for fusion with pure EPC liposomes or endosome-like liposomes composed of EPC/DOPE/SM/Cho (40/20/6/34 mol.%). Our investigations showed, however, that incorporation of lipids from the pH-sensitive liposomes into the endosome membrane may lead to increased permeability and formation of non-lamellar structures. Taken together the results suggest that the observed ability of DOPE-containing liposomes to mediate cytoplasmic delivery of hydrophilic molecules cannot be explained by a mechanism based on a direct, and non-leaky, fusion between the liposome and endosome membranes. A mechanism involving destabilisation of the endosome membrane due to incorporation of DOPE, seems more plausible.     

Effect of grafted polyethylene glycol (PEG) on the size, encapsulation efficiency and permeability of vesicles

Liposomes have been prepared by the vesicle extrusion method (VETs) from mixtures of dipalmitoylphosphatidylcholine (DPPC), phosphatidylinositol (PI) and dipalmitoylphosphatidylethanolamine with covalently linked poly(ethylene glycol) molecular mass 5000 and 2000 (DPPE-PEG 5000 and DPPE-PEG 2000) covering a range of 0-7.5 mole%. The encapsulation of D-glucose has been studied and found to be markedly dependent on the mole% DPPE-PEG. The permeability of the liposomes to D-glucose has been measured both as a function of temperature and liposome composition. The permeability coefficients for D-glucose increase with mole% DPPE-PEG 5000 and with temperature over the range 25-50 degrees C. The activation energies for glucose permeability range from 90 to 23 kJ mol(-1). The decrease in activation energy with increasing temperature is attributed to an increasing number of bilayer defects as the liposome content of PEG-grafted lipid is increased. The dependence of D-glucose encapsulation as a function of PEG-grafted lipid content is discussed in terms of the conformation of the PEG molecules on the inner surface of the bilayer. For liposomes containing DPPE-PEG 5000 the relative percentage encapsulation of glucose, assuming that the PEG surface layer excludes glucose, is comparable to that predicted from the mushroom and brush conformational models.     

pH gradient loading of anthracyclines into cholesterol-free liposomes: enhancing drug loading rates through use of ethanol

Application of cholesterol-free liposomes as carriers for anticancer drugs is hampered, in part, because of standard pH gradient based loading methods that rely on incubation temperatures above the phase transition temperature (Tc) of the bulk phospholipid to promote drug loading. In the absence of cholesterol, liposome permeability is enhanced at these temperatures which, in turn, can result in the collapse of the pH gradient and/or unstable loading. Doxorubicin loading studies, for example, indicate that the drug could not be loaded efficiently into cholesterol-free DSPC liposomes. We demonstrated that this problem could be circumvented by the addition of ethanol as a permeability enhancer. Doxorubicin loading rates in cholesterol-free DSPC liposomes were 6.6-fold higher in the presence of ethanol. In addition, greater than 90% of the added doxorubicin was encapsulated within 2 h at 37 °C, an efficiency that was 2.3-fold greater than that observed in the absence of ethanol. Optimal ethanol concentrations ranged from 10% to 15% (v/v) and these concentrations did not significantly affect liposome size, retention of an aqueous trap marker (lactose) or, most importantly, the stability of the imposed pH gradient. Cryo-transmission electron micrographs of liposomes exposed to increasing concentrations of ethanol indicated that at 30% (v/v) perturbations to the lipid bilayer were present as evidenced by the appearance of open liposomes and bilayer sheets. Ethanol-induced increased drug loading was temperature-, lipid composition- and lipid concentration-dependent. Collectively, these results suggest that ethanol addition to preformed liposomes is an effective method to achieve efficient pH gradient-dependent loading of cholesterol-free liposomes at temperatures below the Tc of the bulk phospholipid.     

The role of apolipoprotein A-IV in reverse cholesterol transport studied with cultured cells and liposomes derived from an ether analog of phosphatidylcholine

Cholesterol efflux was studied in a model system in culture using apolipoproteins and phospholipids added in the form of liposomes at concentrations expected to be present in the extracellular fluid. Fibroblasts were seeded in medium containing [3H]cholesterol-labeled serum, grown till confluent, and the [3H]cholesterol efflux was studied in serum-free medium. Addition of delipidated HDL apolipoprotein resulted in a very low release of [3H]cholesterol, which did not increase with time of exposure or concentration of apolipoproteins. Addition of increasing amounts of HDL apolipoprotein to liposomes prepared from either dioleoylphosphatidylcholine (PC) or its nonhydrolysable ether analog, dioleylphosphatidylcholine (DOEPC) resulted in a 3-5-fold increase of [3H]cholesterol efflux, over that achieved with liposomes alone. This model system permitted the test of the putative role of apolipoprotein A-IV in cholesterol removal from cells. The ability of apolipoprotein A-IV to enhance [3H]cholesterol efflux from cells by DOEPC liposomes was compared to that of apolipoproteins A-I, E and C, which were added at equimolar concentrations. At nM concentrations, apolipoproteins A-IV, A-I and E were equally able to enhance cholesterol efflux, while C apolipoproteins were less effective at these low concentrations. Mixtures prepared from apolipoprotein A-IV, A-I and E and PC or DOEPC liposomes were equally effective in cholesterol removal, while phosphatidylethanolamine liposome apolipoprotein mixtures had a much lower capacity. The present study provides the first evidence that apolipoprotein A-IV can play a role in reverse cholesterol transport as was suggested on the basis of high concentrations of this apolipoprotein in nonlipoprotein form in plasma and extracellular fluid. The efficacy of DOEPC liposomes to serve as cholesterol acceptors might be of potential value for enhancement of reverse cholesterol transport in vivo.     

Serum albumin-lipid membrane interaction influencing the uptake of porphyrins

It is frequently observed in pharmaceutical practice that entrapped substances are lost rapidly when liposomes are used as carriers to introduce substances into cells. The reason for the loss is the interaction of serum components with liposomes. To elucidate the mechanism of this phenomenon the partition of mesoporphyrin (MP) was systematically studied in model systems composed of various lipids and human serum albumin (HSA). As surface charge is an important factor in the interaction, neutral (1, 2-dimyristoyl-sn-glycero-3-phosphatidylcoline, DMPC) and negatively charged (1,2-dimyristoyl-sn-glycero-3-phosphatidylcoline/1, 2-dimyristoyl-sn-glycero-3-phosphatidylglycerol, DMPC/DMPG = 19/1 w/w) lipids were compared. The liposome/apomyoglobin system was the negative control. The size distribution of sonicated samples was carefully analyzed by dynamic light scattering. Constants of association of MP to the proteins and to the liposomes were determined: K(p,1) = (2.5 +/- 0.7) x 10(7) M(-1), K(p,2) = (1.0 +/- 0.7) x 10(8) M(-1), K(L,1) = (1.3 +/- 0.3) x 10(5) M(-1), and K(L,2) = (3.2 +/- 0.6) x 10(4) M(-1) for HSA, apomyoglobin, DMPC, and DMPC/DMPG liposomes, respectively. These data were used to evaluate the partition experiments. The transfer of MP from the liposomes to the proteins was followed by fluorescence spectroscopy. In the case of apomyoglobin, the experimental points could be interpreted by ruling out the protein-liposome interaction. In the case of HSA, the efflux of MP from the liposomes was strongly inhibited above a critical HSA concentration range for negatively charged vesicles. This effect was interpreted as the result of HSA coat formation on the liposome surface. This direct interaction is significant for small liposomes. The interpretation is fully supported by differential scanning calorimetry experiments.