Programmable fusogenic vesicles for intracellular delivery of antisense oligodeoxynucleotides: enhanced cellular uptake and biological effects.

Programmable fusogenic vesicles (PFV) are liposomes composed of non-bilayer lipid components stabilized by the inclusion of an exchangeable poly(ethylene glycol) (PEG)-lipid conjugate. Vesicle destabilization by loss of the PEG-lipid results in recovery of the inherent fusogenic character. As a result, PFV can be designed to display a long circulation lifetime after i.v. administration, high accumulation at disease sites and full bioavailability of an encapsulated compound. In the present study, we investigated the potential application of PFV as carriers for intracellular delivery of antisense oligodeoxynucleotides (ODN). Antisense phosphorothioate ODN were encapsulated into PFV containing dioleoylphosphatidylethanolamine, cholesterol, dioleyldimethylammonium chloride and PEG-ceramides with different carbon chain length (C(8), C(14) and C(20)). In vitro fluorescent microscopy and flow cytometry analysis demonstrated that PFV containing PEG-ceramide C(14) provided enhanced intracellular delivery of FITC-labelled antisense ODN compared to PFV displaying faster or slower rates of destabilization (containing PEG-ceramide C(8) or C(20), respectively). Therapeutic efficacy of PFV-encapsulated antisense ODN against two proto-oncogenes, c-myc and bcl-2, was examined in various cell lines. At antisense concentrations of 0.5 microM, no significant downregulation of c-myc mRNA levels was observed in HEK293, B16 and MCA207 cells. However, treatment of 518A2 melanoma cells with PFV-encapsulated antisense targeting bcl-2 at concentrations of 0.5 microM and 1.0 microM resulted in reduced bcl-2 mRNA level by about 20% and 25% after 48 h incubation. Free antisense ODN did not affect bcl-2 mRNA expression at the concentrations used in this study and encapsulated control antisense (reverse polarity) led to a non-specific increase in mRNA levels. Our results suggest that PFV carriers displaying appropriate rates of destabilization have the potential to act as intracellular delivery vehicles and may improve the bioavailability and potency of antisense oligonucleotides.

Kupffer cells do not play a role in governing the efficacy of liposomal mitoxantrone used to treat a tumor model designed to assess drug delivery to liver.

A tumor model designed to assess liposome-mediated drug delivery to liver has been used in an attempt to better understand the mechanism of activity of liposomal mitoxantrone, a liposomal anticancer drug formulation that appears to be uniquely effective in treating this tumor model. Reductions in liposomal mitoxantrone accumulation in the liver were achieved either by use of poly(ethylene)glycol (PEG)-modified lipids or by methods designed to deplete liver phagocytes, a method referred to as hepatic mononuclear phagocytic system (MPS) blockade. A 2-fold reduction in mitoxantrone delivery to the liver was obtained using a mitoxantrone formulation with PEG-modified lipids, and a 3-fold reduction was obtained when liposomal mitoxantrone was given to animals pretreated to induce hepatic MPS blockade. Results demonstrate that the liposomal mitoxantrone formulation prepared with PEG-modified lipids was significantly less active than the formulations that did not contain PEG lipids, with median survival times of 17 days and 100% 60-day survival, respectively. In contrast, hepatic MPS blockade had no effect on the therapeutic activity of 1,2-dimyristoyl phosphatidylcholine/cholesterol (DMPC/Chol) mitoxantrone (100% 60-day survival). These data suggest that the hepatic MPS does not play a role in mediating the therapeutic activity of DMPC/Chol mitoxantrone in the treatment of liver localized disease. Results with formulations prepared with a PEG-stabilized surface, however, suggest that nonspecific methods to decrease liposome cell interactions inhibit the therapeutic activity of DMPC/Chol mitoxantrone.

Liposomal encapsulation of topotecan enhances anticancer efficacy in murine and human xenograft models.

Topotecan was encapsulated in sphingomyelin/cholesterol liposomes using an ionophore-generated proton gradient. After i.v. injection, liposomal topotecan was eliminated from the plasma much more slowly than free drug, resulting in a 400-fold increase in plasma area under the curve. Further, high-performance liquid chromatography analysis of plasma samples demonstrated that topotecan was protected from hydrolysis within the liposomal carrier with >80% of the drug remaining as the active, lactone species up to 24 h. The improved pharmacokinetics observed with liposomal topotecan correlated with increased efficacy in both murine and human tumor models. In the L1210 ascitic tumor model, optimal doses of liposomal topotecan resulted in a 60-day survival rate of 60-80%, whereas in a L1210 liver metastasis model, 100% long-term survival (>60 days) was achieved. In contrast, long-term survivors were rarely seen after treatment with free topotecan. Further, in a human breast carcinoma model (MDA 435/LCC6), liposomal topotecan provided greatly improved increase in life span relative to the free drug. These results suggest that liposomal encapsulation can significantly enhance the therapeutic activity of topotecan.

Role of drug release and liposome-mediated drug delivery in governing the therapeutic activity of liposomal mitoxantrone used to treat human A431 and LS180 solid tumors.

A previous study suggested that drug release is the dominating factor controlling biological activity of liposomal mitoxantrone in tissues where the rate of liposome accumulation is rapid. The studies described here attempted to address the question: under conditions where the rate of liposome accumulation is slow, does drug release or liposome-mediated drug delivery become the dominant factor controlling therapeutic activity? Liposomal mitoxantrone formulations exhibiting different drug-release characteristics were injected i.v. in mice bearing human carcinoma xenografts: A431 human squamous cell carcinoma and LS180 human colon cell carcinoma in SCID/RAG 2 mice. When lipid and drug levels were measured in established (>100-mg) tumors, accumulation was more rapid in the LS180 tumors (C(max) 4 h) than in the A431 tumors (C(max) 48 h). Mean area under the curve values for mitoxantrone measured over a 96-h time course in A431 tumors were 505, 304, and 93 microg. g(-1). h(-1) for 1,2-distearoyl-sn-glycero-3-phosphocholine (DSPC)/cholesterol (Chol), 1, 2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC)/Chol, and free mitoxantrone, respectively. When a similar analysis was completed in LS180 tumors, the area under the curve values were 999, 749, and 251 microg. g(-1). h(-1) for DSPC/Chol, DMPC/Chol, and free mitoxantrone, respectively. Although drug delivery was less after administration of the DMPC/Chol liposomal mitoxantrone compared with the DSPC/Chol formulation, LS180 solid-tumor growth curves showed the treatment with the DMPC/Chol formulation produced greater delays in tumor growth compared with animals treated with the DSPC/Chol formulation. These data emphasize the importance of designing liposomal formulations that release drug after localization within a region of tumor growth.

Incorporation of bacterial membrane proteins into liposomes: factors influencing protein reconstitution.

Meningococcal and gonococcal outer membrane proteins were reconstituted into liposomes using detergent-mediated dialysis. The detergents octyl glucopyranoside (OGP), sodium cholate and Empigen BB were compared with respect to efficiency of detergent removal and protein incorporation. The rate of OGP removal was greater than for cholate during dialysis. Isopycnic density gradient centrifugation studies showed that liposomes were not formed and hence no protein incorporation occurred during dialysis from an Empigen BB containing reconstitution mixture. Cholate-mediated reconstitution yielded proteoliposomes with only 75% of the protein associated with the vesicles whereas all of the protein was reconstituted into the lipid bilayer during OGP-mediated reconstitution. Essentially complete protein incorporation was achieved with an initial protein-to-lipid ratio of 0.01:1 (w/w) in the reconstitution mixture; however, at higher initial protein-to-lipid ratios (0.02:1) only 75% protein incorporation was achieved. Reconstituted proteoliposomes were observed as large (>300 nm), multilamellar structures using cryo-electron microscopy. Size reduction of these proteoliposomes by extrusion did not result in significant loss of protein or lipid. Extruded proteoliposomes were unilamellar vesicles with mean diameter of about 100 nm.

Controlled destabilization of a liposomal drug delivery system enhances mitoxantrone antitumor activity.

Programmable fusogenic vesicles (PFVs) are lipid-based drug-delivery systems that exhibit time-dependent destabilization. The rate at which this destabilization occurs is determined by the exchange rate of a bilayer-stabilizing component, polyethylene glycol-phosphatidylethanolamine (PEG-PE) from the vesicle surface. This exchange rate is controlled, in turn, by the acyl chain composition of the PEG-PE. We describe in vitro and in vivo studies using PFVs as delivery vehicles for the anticancer drug mitoxantrone. We demonstrate that the PEG-PE acyl composition determined the rate at which PFVs are eliminated from plasma after intravenous administration, and the rate of mitoxantrone leakage from PFV. The nature of the PEG-PE component also determined the antitumor efficacy of mitoxantrone-loaded PFV in murine and human in murine and human xenograft tumor models. Increased circulation time and improved activity were obtained for PFV containing PEG-PE with an 18-carbon acyl chain length, as a result of slower vesicle destabilization.

Separation of liposomes from plasma components using fast protein liquid chromatography.

We describe an efficient method for separating liposomes (large unilamellar vesicles, 120-150 nm diameter) from plasma lipoproteins employing fast protein liquid chromatography (FPLC). This method resolves very low density lipoprotein (VLDL), low-density lipoprotein, high-density lipoprotein, and other plasma components. Selective detection of liposomes (large unilamellar vesicles, 120-150 nm diameter) was achieved using either radiolabeled or fluorescent lipid probes. The liposomes were found to coelute with the earliest FPLC-eluting lipoprotein fraction, VLDL. The remaining plasma lipoprotein and protein components eluted at later times and were resolved from liposomes and VLDL. In order to separate VLDL from liposomes, we selectively precipitated the VLDL fraction from plasma using tungstophosphoric acid and magnesium chloride, prior to separation by FPLC. Furthermore, we demonstrate that this technique can be used to separate liposomes from lipoproteins in plasma samples collected after intravenous administration of liposomes to mice. This technique has wide application in studies of liposome stability in blood and, in particular, for the characterization of liposomal drug carrier systems.

Biophysical and antigenic characterization of gonococcal protein I incorporated into liposomes.

The major gonococcal outer membrane protein, protein I (Por), was reconstituted into liposomes composed of either 1-palmitoyl, 2-oleoyl phosphatidylcholine (POPC) or POPC:1-palmitoyl, 2-oleoyl phosphatidylethanolamine (POPE) (1:1 weight ratio) and the resulting proteoliposomes characterized with respect to their biophysical and antigenic properties. Isopycnic density gradient centrifugation studies established that essentially all of the protein was reconstituted into the lipid bilayer with no significant differences in incorporation seen as a function of lipid composition. Examination of Por orientation in these proteoliposomes revealed that over 80% of the protein was oriented facing outwards in the same 'hairpin loop' fashion found in the native bacterial membrane. Reconstituted Por proteoliposomes exhibited a mean vesicle diameter of > 0.5 micron but could be reduced by extrusion without significant loss of protein or lipid. These extruded systems were suitable for sterilization by terminal filtration. The antibody binding activities of various Por liposome formulations were determined using both anti-Por monoclonal antibodies and an immunized rabbit sera. No significant differences in antibody binding were observed as a function of proteoliposome lipid composition. However, consistently higher levels of antibody binding were obtained for Por liposomes prepared in this way compared with reconstituted systems prepared as described in earlier publications.

Influence of drug release characteristics on the therapeutic activity of liposomal mitoxantrone.

The influence of liposome drug release on the therapeutic activity of encapsulated mitoxantrone was investigated. Liposomes prepared from 1,2-distearoyl-sn-glycero-3-phosphocholine (DSPC)/cholesterol (Chol) (55:45, molar ratio) or 1,2 dimyristoyl-sn-glycero-3-phosphocholine (DMPC)/Chol (55:45, molar ratio) were loaded with mitoxantrone using the transmembrane pH gradient loading procedure. In vivo studies demonstrated that DMPC/Chol liposomes released drug faster (1.7 microg drug/microg lipid/hr) than did DSPC/Chol liposomes (<0.025 microg drug/microg lipid/hr). In BDF1 mice, the acute toxicities of DMPC/Chol and DSPC/Chol liposomal mitoxantrone were similar, with a maximum tolerated dose of approximately 30 mg drug/kg, in comparison with the maximum tolerated dose of free drug, which was approximately 10 mg/kg. Efficacy studies were conducted in BDF1 mice inoculated i.v. with murine P388 cells or L1210 tumor cells. These cells seed in the liver and spleen of animals after i.v. inoculation, and a single dose of DMPC/Chol liposomal mitoxantrone of 10 mg drug/kg resulted in 100% of the treated animals surviving for >60 days. In contrast, no long-term survivors were obtained in any other treatment group, even when drug doses were escalated to the maximum tolerated dose. Pharmacodynamic studies with DMPC/Chol liposomal mitoxantrone and DSPC/Chol liposomal mitoxantrone illustrate the importance of achieving a balance between drug release characteristics and drug delivery to the site of tumor progression.

Plasma clearance, biodistribution and therapeutic properties of mitoxantrone encapsulated in conventional and sterically stabilized liposomes after intravenous administration in BDF1 mice.

Mitoxantrone can be efficiently loaded into large unilamellar vesicles using a transmembrane pH gradient. Release studies indicate that these drug-loaded carriers are highly stable and even after dissipation of the residual pH gradient retain more than 85% of encapsulated mitoxantrone following dialysis at 37 degrees C for 5 days. In murine studies we have compared the plasma clearance and biodistribution of both mitoxantrone and liposomal lipid following intravenous administration of free drug or mitoxantrone encapsulated in either conventional or sterically stabilized liposomes. In contrast to the rapid blood clearance observed for free mitoxantrone, both liposomal systems provided extended circulation lifetimes, with over 90% of the drug present 1 h after administration and 15-30% remaining at 24 h. In agreement with previous reports, longer plasma half-lives were observed for sterically stabilized liposomes than for conventional systems. In addition, a strong correlation between drug and carrier biodistribution was seen, with uptake occurring mainly in the liver and spleen and paralleling plasma clearance. This would suggest that tissue disposition reflects that of drug-loaded liposomes rather than the individual components. Liposomal encapsulation also significantly reduced mitoxantrone toxicity, allowing administration of higher, more efficacious drug doses. In a murine L1210 tumour model, for example, no long-term survivors were seen in animal groups treated with free drug, whereas at the maximum therapeutic dose of liposomal mitoxantrone survival rates of 40% were observed.

Liposomal bupivacaine. Extended duration nerve blockade using large unilamellar vesicles that exhibit a proton gradient.

BACKGROUND: There is a clinical requirement for longer-acting local anesthetics, particularly for the management of post-operative and chronic pain. In this regard, liposomes have been suggested to represent a potentially useful vehicle for sustained drug release after local administration. In the current study, the authors used a transmembrane pH gradient to efficiently encapsulate bupivacaine within large unilamellar vesicles. They report on the kinetics of drug uptake and release and the duration of nerve blockade. METHODS: The rate and extent of bupivacaine uptake into large unilamellar vesicles that exhibit a pH gradient (interior acidic) were determined and compared to drug association with control liposomes that did not exhibit a proton gradient. In subsequent studies, researchers examined the kinetics of bupivacaine release from these liposome systems in vitro. Using the guinea pig cutaneous wheal model, the rate of clearance of the liposome carrier was monitored after intradermal administration, using a radiolabelled lipid marker, and the duration of nerve blockade produced by free and liposomal bupivacaine was compared. RESULTS: Bupivacaine was rapidly and efficiently accumulated within liposomes that exhibited a pH gradient (interior acidic) with trapping efficiencies of 64-82% of total drug, depending on the initial bupivacaine:phospholipid ratio. Little uptake was seen, however, for control vesicles that did not exhibit a transmembrane proton gradient. Using an in vitro model of drug clearance, liposomally encapsulated bupivacaine was found to be slowly released for a longer period of time compared with either the free drug or bupivacaine associated with control (no pH gradient liposomes). In the guinea pig cutaneous wheal model, more than 85% of the liposomal carrier was found to remain at the site of administration for 2 days. The sustained drug release afforded by liposomes that exhibited a pH gradient resulted in an increase in the duration of nerve blockade of as much as threefold compared with either the free drug or bupivacaine in the presence of control (no pH gradient) liposomes. Recovery of half maximal response (R2.5) after administration of 0.75% free bupivacaine, for example, was approximately 2 h, whereas the same dose of bupivacaine in pH gradient liposomes exhibited a R2.5 of approximately 6.5 h. CONCLUSIONS: Large unilamellar vesicles that exhibit a pH gradient can efficiently encapsulate bupivacaine and subsequently provide a sustained-release system that greatly increases the duration of neural blockade.

Poly(ethylene glycol)-lipid conjugates promote bilayer formation in mixtures of non-bilayer-forming lipids.

The influence of poly(ethylene glycol)-lipid conjugates on phospholipid polymorphism has been examined using 31P-NMR and freeze--fracture electron microscopy. An equimolar mixture of dioleoylphosphatidylethanolamine (DOPE) and cholesterol adopts the hexagonal (HII) phase when hydrated under physiological conditions but can be stabilized in a bilayer conformation when a variety of PEG-lipid conjugates are included in the lipid mixture. These PEG conjugates produced an increase in the bilayer to hexagonal (HII) phase transition temperature and a broadening of the temperature range over which both phases coexisted. Further, the fraction of phospholipid adopting the bilayer phase increased with increasing mole fraction of PEG-lipid such that at 20 mole % DOPE--PEG2000 no HII phase phospholipid was observed up to a least 60 degrees C. Increasing the size of the PEG moiety from 2000 to 5000 Da (while maintaining the PEG--lipid molar ratio constant) increased the proportion of lipid in the bilayer phase. In contrast, varying the acyl chains of the PE anchor had no effect on polymorphic behavior. PEG--lipid conjugates in which ceramide provides the hydrophobic anchor also promoted bilayer formation in DOPE:cholesterol mixtures but at somewhat higher molar ratios compared to the corresponding PEG--PE species. The slightly greater effectiveness of the PE conjugates may result from the fact that these derivatives also possess a net negative charge. Phosphorus NMR spectroscopy indicated that a proportion of the phospholipid in DOPE:cholesterol:PEG--PE mixtures experienced isotropic motional averaging with this proportion being sensitive to both temperature and PEG molecular weight. Surprisingly, little if any isotropic signal was observed when PEG--ceramide was used in place of PEG--PE. Consistent with the 31P-NMR spectra, freeze-fracture electron microscopy showed the presence of small vesicles (diameter <200 nm) and lipidic particles in DOPE:cholesterol mixtures containing PEG--PE. We conclude that the effects of PEG--lipid conjugates on DOPE:cholesterol mixtures are 2-fold. First, the complementary "inverted cone" shape of the conjugate helps to accommodate the "cone-shaped" lipids, DOPE and cholesterol, in the bilayer phase. Second, the steric hindrance caused by the PEG group inhibits close apposition of bilayers, which is a prerequisite for the bilayer to HII phase transition.

Poly(ethylene glycol)--lipid conjugates regulate the calcium-induced fusion of liposomes composed of phosphatidylethanolamine and phosphatidylserine.

The effect of poly(ethylene glycol)--lipid (PEG--lipid) conjugates on liposomal fusion was investigated. Incorporation of PEG--lipids into large unilamellar vesicles (LUVs) composed of equimolar phosphatidylethanolamine (PE) and phosphatidylserine (PS) inhibited calcium-induced fusion. The degree of inhibition increased with increasing molar ratio of the PEG conjugate and with increasing size of the PEG moiety. Inhibition appeared to result from the steric barrier on the surface of the liposomes which opposed apposition of bilayers and interbilayer contact. In the presence of a large excess of neutral acceptor liposomes, however, fusogenic activity was restored. The rate of fusion under these conditions depended on the initial molar ratio of the PEG conjugate in the PE:PS vesicles and the length and degree of saturation of the acyl chains which composed the lipid anchor. These results are consistent with spontaneous transfer of the PEG--lipid from PE:PS LUVs to the neutral lipid sink reducing the steric barrier and allowing fusion of the PE:PS LUVs. The primary determinant of the rate of fusion was the rate of transfer of the PEG--lipid, indicating that liposomal fusion could be programmed by incorporation of appropriate PEG--lipid conjugates. Interestingly, increasing the size of the PEG group did not appear to affect the rate of fusion. The implications of these results with respect to the design of fusogenic liposomal drug delivery systems are discussed.

Liposomal cyclosporine. Comparison of drug and lipid carrier pharmacokinetics and biodistribution.

In a preceding paper (Ouyang et al., 1995, this issue), we have characterized cyclosporine incorporation into well-defined liposomal systems, large unilamellar vesicles. This study demonstrated that only modest drug levels could be accommodated within the membrane, particularly for cholesterol-containing liposomes, and that rapid drug exchange could occur between vesicles. This raised the possibility that following intravenous administration, drug migration to other blood components might negate the potential benefits arising from liposomal delivery. We have, therefore, examined the pharmacokinetics and biodistribution of both cyclosporine and its liposomal carrier. We show that whereas liposomes, as expected, are only slowly cleared from the blood, redistribution of cyclosporine occurs much more rapidly. Further we have shown that liposomal loss of cyclosporine in blood results from drug migration to the lipoproteins and, to a lesser extent, the erythrocytes. As a result, while liposomes accumulate preferentially in organs of the reticuloendothelial system after intravenous administration, tissue cyclosporine levels, in general, do not reflect the distribution profile obtained for the liposomal carrier.

Liposomal cyclosporine. Characterization of drug incorporation and interbilayer exchange.

A number of previous studies have examined the application of liposomes as carriers for the immunosuppressive agent cyclosporine. These studies, however, have generated equivocal results, particularly with regard to the therapeutic properties of such systems. In the present work, we have characterized cyclosporine incorporation into well defined liposomes, large unilamellar vesicles, and have examined the stability of drug association. Contrary to some earlier reports, we show that only modest levels of cyclosporine can be accommodated in the liposomal membrane and that the extent of drug incorporation is greatly reduced as the bilayer cholesterol content is increased. Furthermore, we demonstrate that cyclosporine, despite its hydrophobic character, can rapidly exchange between vesicles. This raises the possibility that, after i.v. administration, drug migration to other blood components might negate the potential benefits arising from liposomal delivery. In a companion paper, therefore (Choice et al., Transplantation, 1995, this issue), we have followed the pharmacokinetics and biodistribution of liposomal cyclosporine in a study that examined the behavior of both the drug and the liposomal carrier.

Influence of transbilayer area asymmetry on the morphology of large unilamellar vesicles.

The morphological consequences of differences in the monolayer surface areas of large unilamellar vesicles (LUVs) have been examined employing cryoelectron microscopy techniques. Surface area was varied by inducing net transbilayer transport of dioleoylphosphatidylglycerol (DOPG) in dioleoylphosphatidylcholine (DOPC):DOPG (9:1, mol:mol) LUVs in response to transmembrane pH gradients. It is shown that when DOPG is transported from the inner to the outer monolayer, initially invaginated LUVs are transformed to long narrow tubular structures, or spherical structures with one or more protrusions. Tubular structures are also seen in response to outward DOPG transport in DOPC:DOPG:Chol (6:1:3, mol:mol:mol) LUV systems, and when lyso-PC is allowed to partition into the exterior monolayer of DOPC:DOPG (9:1, mol:mol) LUVs in the absence of DOPG transport. Conversely, when the inner monolayer area is expanded by the transport of DOPG from the outer monolayer to the inner monolayer of non-invaginated LUVs, a reversion to invaginated structures is observed. The morphological changes are well described by an elastic bending theory of the bilayer. Identification of the difference in relaxed monolayer areas and of the volume-to-area ratio of the LUVs as the shape-determining factors allows a quantitative classification of the observed morphologies. The morphology seen in LUVs supports the possibility that factors leading to differences in monolayer surface areas could play important roles in intracellular membrane transport processes.

Transmembrane distribution of lipophilic cations in response to an electrochemical potential in reconstituted cytochrome c oxidase vesicles and in vesicles exhibiting a potassium ion diffusion potential.

It has been shown previously that biogenic amines and a number of pharmaceutical agents can redistribute across vesicle membranes in response to imposed potassium ion or proton gradients. Surprisingly, drug accumulation is observed for vesicles exhibiting either a pH gradient (interior acidic) or a membrane potential (interior negative), implying that these compounds can traverse the lipid bilayer as either the neutral or charged species. This interpretation, however, is complicated by the fact that vesicles exhibiting a membrane potential (interior negative) accumulate protons in response to this potential, thereby creating a pH gradient (interior acidic). This raises the possibility that in both vesicle systems drug redistribution occurs in response to the proton gradient present. We have therefore compared the uptake of several lipophilic cations by reconstituted cytochrome c oxidase vesicles and by similar vesicles exhibiting a potassium ion diffusion potential. While turnover of the oxidase generates a membrane potential of comparable magnitude to the potassium ion diffusion system, it is associated with a proton gradient of opposite polarity (interior basic). Both systems show rapid uptake of the permanently charged lipophilic cation, tetraphenylphosphonium, but only the potassium ion diffusion system accumulates the lipophilic amines doxorubicin and propranolol. This provides compelling evidence that such weak bases redistribute only in response to pH gradients and not membrane potential.

Influence of plasma on the osmotic sensitivity of large unilamellar vesicles prepared by extrusion.

In the presence of plasma, the osmotic differential required to trigger lysis of large unilamellar vesicles is significantly decreased with the membrane tension at rupture being reduced from about 36 to about 12 dynes/cm for vesicles composed of palmitoyloleoylphosphatidylcholine: cholesterol (55:45). Despite increasing vesicle sensitivity, however, plasma does not alter the characteristics of osmotically induced lysis. As in the absence of plasma, lysis is not an all-or-nothing event but instead results in only partial loss of intravesicular solute, so that following membrane resealing the vesicle interior remains hyperosmotic with respect to the external medium. To identify the component responsible for the observed increase in vesicle osmotic sensitivity, plasma was fractionated by density centrifugation. Albumin and other soluble plasma proteins, including those associated with the complement system, were found to exert only a modest influence on vesicle osmotic behavior. In contrast all of the lipoprotein fractions lowered vesicle tolerance to osmotic pressure, with high density lipoprotein exerting an effect comparable to whole plasma.

Osmotic properties of large unilamellar vesicles prepared by extrusion.

We have examined the morphology and osmotic properties of large unilamellar vesicles (LUVs) prepared by extrusion. Contrary to expectations, we observe by cryo-electron microscopy that such vesicles, under isoosmotic conditions, are non-spherical. This morphology appears to be a consequence of vesicle passage through the filter pores during preparation. As a result when such LUVs are placed in a hypoosmotic medium they are able to compensate, at least partially, for the resulting influx of water by "rounding up" and thereby increasing their volume with no change in surface area. The increase in vesicle trapped volume associated with these morphological changes was determined using the slowly membrane-permeable solute [3H]-glucose. This allowed calculation of the actual osmotic gradient experienced by the vesicle membrane for a given applied differential. When LUVs were exposed to osmotic differentials of sufficient magnitude lysis occurred with the extent of solute release being dependent on the size of the osmotic gradient. Surprisingly, lysis was not an all-or-nothing event, but instead a residual osmotic differential remained after lysis. This differential value was comparable in magnitude to the minimum osmotic differential required to trigger lysis. Further, by comparing the release of solutes of differing molecular weights (glucose and dextran) a lower limit of about 12 nm diameter can be set for the bilayer defect created during lysis. Finally, the maximum residual osmotic differentials were compared for LUVs varying in mean diameter from 90 to 340 nm. This comparison confirmed that these systems obey Laplace's Law relating vesicle diameter and lysis pressure. This analysis also yielded a value for the membrane tension at lysis of 40 dyn cm-1 at 23 degrees C, which is in reasonable agreement with previously published values for giant unilamellar vesicles.