Properties of stearylamine liposomes containing tyrosine phenol-lyase

The activity of tyrosine phenol-layse a chemotherapeutic enzyme with a dissociable pyridoxal phosphate cofactor, was studied after incorporation into multilamellar positively charged liposomes. Tyrosine phenol-lyase activity was assessed in the presence and absence of exogenous pyridoxal phosphate. A maximum of 75% total enzyme activity was associated with liposomes when prepared from a molar lipid ratio of egg lecithin, cholesterol, stearylamine (7 : 2 : 1, w/w). The total tyrosine phenol-lyase activity was comprised of 25% membrane-associated enzyme and 50% encapsulated enzyme. Encapsulation increased the stability of the enzyme under the in vitro conditions of cold storage at 4°C for 3 weeks and under elevated temperatures up to 61°C. Liposomal encapsulation afforded little protection against trypsin and no protection against whole mouse plasma in vitro. Heat-treated plasma (100°C for 1 h) had little effect on the activity of free and encapsulated tyrosine phenol-lyase. These results indicated that whole plasma contained a heat-labile factor(s) which destroyed both the liposomal and free tyrosine phenol-lyase activity. Plasma clearance after intraperitoneal injection of tyrosine phenol-lyase in B6D2F₁ female mice was reduced by liposomal encapsulation, particularly when the animals were pre-treated with empty liposomes; however, only a small proportion of free and liposomal tyrosine phenol-lyase was absorbed. The free enzyme rapidly lost holoenzyme activity after absorption but the liposomes maintained holoenzyme activity. Even though liposomes preserved holo-tyrosine phenol-lyase activity, the holoenzyme was not present in sufficient concentration to sustain a reduced plasma tyrosine level.     

Endocytosis of liposomes by macrophages: binding, acidification and leakage of liposomes monitored by a new fluorescence assay

The interaction of liposomes with macrophage cells was monitored by a new fluorescence method (Hong, K., Straubinger, R.M. and Papahadjopoulos, D., J. Cell Biol. 103 (1986) 56a) that allows for the simultaneous monitoring of binding, endocytosis, acidification and leakage. Profound differences in uptake, cell surface-induced leakage and leakage subsequent to endocytosis were measured in liposomes of varying composition. Pyranine (1-hydroxypyrene-3,6,8-trisulfonic acid, HPTS), a highly fluorescent, water-soluble, pH sensitive dye, was encapsulated at high concentration into the lumen of large unilamellar vesicles. HPTS exhibits two major fluorescence excitation maxima (403 and 450 nm) which have a complementary pH dependence in the range 5-9: the peak at 403 nm is maximal at low pH values while the peak at 450 nm is maximal at high pH values. The intra- and extracellular distribution of liposomes and their approximate pH was observed by fluorescence microscopy using appropriate excitation and barrier filters. The uptake of liposomal contents by cells and their subsequent exposure to acidified endosomes or secondary lysosomes was monitored by spectrofluorometry via alterations in the fluorescence excitation maxima. The concentration of dye associated with cells was determined by measuring fluorescence at a pH independent point (413 nm). The average pH of cell-associated dye was determined by normalizing peak fluorescence intensities (403 nm and 450 nm) to fluorescence at 413 nm and comparing these ratios to a standard curve. HPTS-containing liposomes bound to and were acidified by a cultured murine macrophage cell line (J774) with a t1/2 of 15-20 min. The acidification of liposomes exhibited biphasic kinetics and 50-80% of the liposomes reached an average pH lower than 6 within 2 h. A liposomal lipid marker exhibited a rate of uptake similar to HPTS, however the lipid component selectively accumulated in the cell; after an initial rapid release of liposome contents, 2.5-fold more lipid marker than liposomal contents remained associated with the cells after 5 h. Coating haptenated liposomes with antibody protected liposomes from the initial release. The leakage of liposomal contents was monitored by co-encapsulating HPTS and p-xylene-bis-pyridinium bromide, a fluorescence quencher, into liposomes. The time course of dilution of liposome contents, detected as an increase in HPTS fluorescence, was coincident with the acidification of HPTS. The rate and extent of uptake of neutral and negatively charged liposomes was similar; however, liposomes opsonized with antibody were incorporated at a higher rate (2.9-fold) and to a greater extent (3.4-fold).(ABSTRACT TRUNCATED AT 400 WORDS)     

Tissue distribution of EDTA encapsulated within liposomes of varying surface properties

Liposomes containing ethylenediaminetetraacetic acid (EDTA) were prepared with different surface properties by varying the liposomal lipid constituents. Positively charged liposomes were prepared with a mixture of phosphatidylcholine, cholesterol, and stearylamine. Negatively charged liposomes were prepared with a mixture of phosphatidylcholine, cholesterol, and phosphatidylserine. Neutral liposomes were prepared with phosphatidylcholine alone, dipalmitoyl phosphatidylcholine alone, or with a mixture of phosphatidylcholine and cholesterol. Distributions of ¹⁴C-labeled EDTA were determined in mouse tissues from 5 min to 24 h after a single intravenous injection of liposome preparation. Differences in tissue distribution were produced by the different liposomal lipid compositions. Uptake of EDTA by spleen and marrow was highest from negatively charged liposomes. Uptake of EDTA by lungs was highest from positively charged liposomes; lungs and brain retained relatively high levels of EDTA from these liposomes between 1 and 6 h after injection. Liver uptake of EDTA from positively or negatively charged liposomes was similar; the highest EDTA uptake by liver was from the neutral liposomes composed of a mixture of phosphatidylcholine and cholesterol. Liposomes composed of dipalmitoyl phosphatidylcholine produced the lowest liposomal EDTA uptake observed in liver and marrow but modrate uptake by lungs. Tissue uptake and retention of EDTA from all of the liposome preparations were greater than those of non-encapsulated EDTA. The results presented demonstrate that the tissue distribution of a molecule can be modified by encapsulation of that substance into liposomes of different surface properties. Selective delivery of liposome-encapsulated drugs to specific tissues could be effectively used in chemotherapy and membrane biochemistry.     

Targeting of piperine intercalated in mannose-coated liposomes in experimental leishmaniasis

The leishmanicidal property of piperine intercalated in liposomes and in mannose-coated liposomes was tested in experimental visceral leishmaniasis in hamsters. Mannose-coated liposomal piperine eliminated intracellular amastigotes of Leishmania donovani in splenic macrophages much more efficiently than did the liposomal piperine or free piperine. At a dose equivalent to 6 mg/kg body wt every 4th day for a total of 4 doses in 12 days, the mannose-coated liposomal piperine was found to reduce spleen parasite load to the extent of 90% in comparison to that achieved by liposomal piperine (77%) or free piperine (29%). Histological examination of spleen and liver function tests showed that the toxicity of piperine was reduced when mannosylated liposomal piperine was administered.     

Interactions of serum proteins with small unilamellar liposomes composed of dioleoylphosphatidylethanolamine and oleic acid: high-density lipoprotein, apolipoprotein A1, and amphipathic peptides stabilize liposomes

Small unilamellar liposomes composed to dioleoylphosphatidylethanolamine (DOPE) and oleic acid (OA) are stabilized by incubation with normal human serum or plasma [Liu, D., & Huang, L. (1989) Biochemistry 28, 7700-7707]. The present report describes a systematic study of interactions of purified serum proteins and lipoproteins with these liposomes. Albumin destabilized liposomes by extracting OA from the liposomes, whereas immunoglobulins and lipoproteins (HDL, LDL, and VLDL) had no effect. However, HDL and, to some extent, VLDL showed a rapid stabilization activity against the lytic effect of albumin. HDL added together with or shortly after the addition of albumin completely abolished the liposome leakage and aggregation effects induced by albumin. SDS-PAGE analysis of the HDL-stabilized liposomes revealed that apolipoprotein A1 was associated with liposomes. Purified apolipoprotein A1, but not a lipid mixture resembling the lipid composition of HDL, showed comparable liposome stabilization activity as HDL. Furthermore, synthetic peptides resembling the amphipathic helices found in apolipoprotein A1 also showed strong liposome stabilization activity. Peptides which were able to form amphipathic helixes of a wedge shape were more effective stabilizers than those which could not. These data indicate that HDL plays a major role in human serum or plasma for the liposome stabilization activity. HDL exerts its activity probably by the interactions of the amphipathic helices of apolipoprotein A1 with the hydrophobic voids found on the outer surface of the highly curved, small liposomes.     

Surface-linked liposomal antigen induces ige-selective unresponsiveness regardless of the lipid components of liposomes

We have previously reported that antigen coupled with liposomes induced antigen-specific and IgE-selective unresponsiveness in mice. This antigen preparation was investigated for application in a novel vaccine protocol to induce minimal IgE synthesis. In this study, ovalbumin (OVA)-liposome conjugates were made using liposomes of four different lipid components, including unsaturated carrier lipid and three different saturated carrier lipids, after which the induction of anti-OVA antibody production was investigated in mice. All of the OVA-liposome conjugates induced IgE-selective unresponsiveness. The membrane fluidity of liposomes, as measured by detecting changes in the fluorescence polarization of a 1,6-diphenyl-1,3,5-hexatriene (DPH) probe located in the bilayers, was significantly higher in liposomes consisting of unsaturated carrier lipids than those of the other liposomes consisting of saturated carrier lipids. The highest titer of anti-OVA IgG was observed in mice immunized with OVA-liposomes made using liposomes consisting of unsaturated carrier lipids. In addition, among these OVA-liposomes, the one possessing the longest carbon chain induced the lowest IgG antibody production. These results suggest that the membrane fluidity of liposomes might affect the adjuvant effect of liposomes but not the induction of IgE-selective unresponsiveness in immunizations with surface-linked liposomal antigens.     

Interaction of liposomes with human leukocytes in whole blood

The uptake of multilamellar liposomes into human leukocytes in whole blood in vitro was evaluated on the basis of the cellular association of liposomal markers (3H-labelled cholesterol, lipid phase; [14C]inulin, aqueous phase). The entry of liposomes into human blood leukocytes was linear for 60 min and was mediated by a saturable mechanism displaying affinity constants of 0.28 +/- 0.17 and 0.16 +/- 0.05 mM liposomal lipid (means +/- S.E.) for liposomal lipid and aqueous phase markers, respectively. Amicon filtration analysis of incubation mixtures containing blood and liposomes (phosphatidylcholine:dicetyl phosphate:cholesterol, 70:20:10) showed that 34% of [14C]inulin was lost (neither liposome-associated nor cell-associated) after 60 min. By preincorporating sphingomyelin (35 mol%) into multilamellar liposomes, the leakage of the model aqueous phase marker inulin was reduced to 8% after 60 min, thus enhancing the drug carrier potential of liposomes in blood. As a consequence of their interaction with liposomes, the polymorphonuclear leukocytes in whole blood decreased in apparent buoyant density, while maintaining their viability. These results indicate that blood leukocytes in their natural milieu of whole blood are capable of interacting with, and taking up multilamellar liposomes.     

Enzyme replacement via liposomes. Variations in lipid compositions determine liposomal integrity in biological fluids.

Liposomes survive exposure to biological fluids poorly, extruding trapped enzymes, drugs, or solutes upon interaction with serum or plasma constituents. We have quantified the disruptive effects of human serum on liposomes and have studied whether various modifications in their phospholipid composition might produce liposomes with an increased carrier potential for application in vivo. Multilamellar liposomes (phosphatidycholine 70:dicetyl phosphate 20:cholesterol 10) were prepared with 3H-labeled phosphatidylcholine as the lipid phase marker and [14C]inulin and horseradish peroxidase as aqueous phase markers. Gel exclusion chromatography showed that 32 +/- 3% of [14C]inulin and 27 +/- 7% of horseradish peroxidase were lost after 1 h incubation with 10% (v/v) human serum. Loss of aqueous solutes was reduced to 20 +/- 5%/h and 17 +/- 2%/h, respectively, after treatment with decomplemented serum (56 degrees C, 30 min). Loss induced by serum was concentration and time dependent: to 57 +/- 2% at 1 h and 67 +/- 14% at 24 h, with 50% serum; plasma was slightly less perturbing whereas human serum albumin was not at all disruptive. By incorporating sphingomyelin (35 mol%) into multilamellar liposomes, the leakage of [14c]-inulin in the presence of 10% serum was reduced to 12 +/- 4%/h; increasing the molar percentage of cholesterol to 35% also stabilized the lipid bilayers, reducing leakage to 20 +/- 7%/h. Both small and large unilamellar vesicles could not be stablilized against serum-mediated leakage by the incorporation of sphingomyelin. The data suggest that cholesterol and sphingomyelin enhance liposomal integrity in the presence of serum or plasma and promise to yield enhanced survival of drug-laden lipid vesicles in biological fluids in vivo.     

Hypoglycemic effect of insulin incorporated into liposomes after oral administration to animals with different types of experimental diabetes

Different doses of insulin incorporated into liposomes were administered to normal animals and to those with certain forms of experimental diabetes. Lecithin-cholesterol liposomes in the molar ratio 9:1 were used. They were formed by the supersound treatment of the lipid suspension with the crystalline insulin in the buffer containing 140 mM NaCl and 10 mM tris-HCl (pH 7.4). Incorporation of insulin into liposomes was 16.2% in determination by [125I] insulin and 9.7% in determination of immunoreactive insulin after destruction of liposomes. Dynamics of glycemia and insulinemia was studied in these animals. It is established that insulin from liposomes being per os administered to animals evokes an expressed hypoglycemic effect and hyperinsulinemia. Effective sugar-lowering doses of liposomal insulin for animals with the experimental diabetes were from 6 ME/kg and for normal animals--from 30 ME/kg.     

Prostaglandin and thromboxane in liposomes: suppression of the primary immune response to liposomal antigens

Liposomes containing lipid A as adjuvant and also containing prostaglandin E2 or thromboxane B2 were examined for the ability to influence induction of humoral immunity against liposomal protein or lipid antigens in rabbits. The protein antigen consisted of cholera toxin that was bound to ganglioside GM1 on the surface of the liposomes. High titers of anti-cholera toxin antibodies were produced and IgM and IgG responses were detected. When the immunizing liposomes contained either prostaglandin E2 or thromboxane B2 as part of the lipid bilayer, the primary immune response, involving both IgM and IgG antibodies, was greatly reduced. The secondary immune response observed after a boosting immunization was not suppressed by liposomal eicosanoids. A similar inhibitory effect on the primary response was observed when liposomal lipid antigens were examined instead of cholera toxin. An inhibitory effect of liposomal prostaglandin E2 on the phagocytic uptake of opsonized liposomes by cultured macrophages was also observed, suggesting that liposomal eicosanoids can have direct local effects on macrophages that might influence the immune response to liposomal antigens.     

Interaction of liposomes with Kupffer cells in vitro

We investigated the interaction of liposomes with rat Kupffer cells in monolayer maintenance culture. The liposomes (large unilamellar vesicles, LUV) were composed of 14C-labelled phosphatidylcholine, cholesterol and phosphatidylserine (molar ratio 4:5:1) and contained either 3H-labelled inulin or 125I-labelled bovine serum albumin as a non-degradable or a degradable aqueous space marker, respectively. After 2-3 days in culture the cells exhibited optimal uptake capacity. The uptake process showed saturation kinetics, maximal uptake values amounting to 2 nmol of total liposomal lipid/h/10(6) cells. This is equivalent to 1500 vesicles per cell. The presence of fetal calf serum (FCS) during incubation increased uptake nearly two-fold, whereas freshly isolated rat serum had no effect. The binding of the liposomes to the cells caused partial release of liposomal contents (about 15-20%) both at 4 degrees C and at 37 degrees C. In the presence of metabolic inhibitors the uptake at 37 degrees C was reduced to about 20% of the control values. Inulin and lipid label became cell-associated at similar rates and extents, whereas the association of albumin label gradually decreased after attaining a maximum at relatively low values. When, after 1 h incubation, the liposomes were removed continued incubation for another 2 h in absence of liposomes led to an approx. 30% release of cell-associated lipid label into the medium in water-soluble form. Under identical conditions as much as 90% of the cell-associated albumin label was released in acid-soluble form. Contrarily, the inulin label remained firmly cell-associated under these conditions. From these results we conclude that Kupffer cells in monolayer culture take up liposomes primarily by way of an adsorptive endocytic mechanism. This conclusion was confirmed by morphological observations on cells incubated with liposomes containing fluorescein isothiocyanate (FITC) dextran or horseradish peroxidase as markers for fluorescence microscopy and electron microscopy, respectively.     

Effect of membrane composition on lipid oxidation in liposomes

To study the effect of membrane composition on the oxidation of liposomes, different systems were prepared by adding one component at time to phosphatidylcholine (Epikuron 200). In particular, the effect of cholesterol and its ester, cholesterol stearate, on membrane structure and oxidation was studied. A first screening of the structure and net charge of the different preparation was made by means of z-potential and size measurements. Then the liposomes were oxidized by using a hydrophilic radical initiator, the (2,2-azobis(2-amidinopropane) hydrochloride, AAPH, which thermally decomposes to give a constant radical flux in water. The oxidation of liposomes, monitored by following the absorbance of the primary products of oxidation at 234 nm, was shown to be dependent on the composition of the liposomal bilayer and so on its biophysical properties. In addition, size and z-potential measurements gathered in the time course of the peroxidation reaction, revealed that the oxidation induced a modification of the superficial characteristics of the membrane bilayer so as to change its charge at the shear plane (z-potential). This behaviour was shared by all liposomal preparations independent of the composition. The change in sizes of the different liposomal preparation, instead, followed different trends, being more stable both in control samples and in oxidized ones when cholesterol was present. From the analysis of the results, it can be concluded that cholesterol affects the oxidation induced by hydrophilic radical initiator of model membranes by changing the biophysical properties of the phospholipid bilayer. The rigidity induced by cholesterol at temperatures above the T_m makes the membrane more resistant to radical attack from an external aqueous phase and this in turn delays the start of the reaction. The decrease of z-potential of the liposomal particles induced by the oxidation process can be an important clue to understand the mechanisms involved in the etiology of important diseases.     

Enzyme replacement via liposomes variations in lipid composition determine liposomal integrity in biological fluids

Liposomes survive exposure to biological fluids poorly, extruding trapped enzymes, drugs, or solutes upon interaction with serum or plasma constituents. We have quantified the disruptive effects of human serum on liposomes and have studied whether various modifications in their phospholipid composition might produce liposomes with an increased carrier potential for applications in vivo. Multilamellar liposomes (phosphatidylcholine 70:dicetyl phosphate 20: cholesterol 10) were prepared with ³H-labeled phosphatidylcholine as the lipid phase marker and [¹⁴C]inulin and horseradish peroxidase as aqueous phase markers. Gel exclusion chromatography showed that 32 ± 3% of [¹⁴C]inulin and 27 ± 7% of horseradish peroxidase were lost after 1 h incubation with 10% (v/v) human serum. Loss of aqueous solutes was reduced to 20 ± 5%/h and 17 ± 2%/h, respectively, after treatment with decomplemented serum (56°C, 30 min). Loss induced by serum was concentration and time dependent: to 57 ± 2% at 1 h and 67 ± 14% at 24 h, with 50% serum; plasma was slightly less perturbing whereas human serum albumin was not at all disruptive. By incorporating sphingomyelin (35 mol%) into multilamellar liposomes, the leakage of [¹⁴C]-inulin in the presence of 10% serum was reduced to 12 ± 4%/h; increasing the molar percentage of cholesterol to 35% also stabilized the lipid bilayers, reducing leakage to 20 ± 7%/h. Both small and large unilamellar vesicles could not be stabilized against serum-mediated leakage by the incorporation of sphingomyelin. The data suggest that cholesterol and sphingomyelin enhance liposomal integrity in the presence of serum or plasma and promise to yield enhanced survival of drug-laden lipid vesicles in biological fluids in vivo.     

Stability of protein-encapsulating DRV liposomes after freeze-drying: A study with BSA and t-PA

Stability of protein-encapsulating DRV (dried-rehydrated vesicle) liposomes is evaluated after freeze-drying vesicles in presence (or not) of trehalose. Two proteins, bovine serum albumin (BSA) and tissue-type plasminogen activator (t-PA), are used, and protein-encapsulating liposomes with different lipid compositions are prepared by DRV technique. Encapsulation efficiencies are calculated, after measuring BSA with a fluorescence technique and t-PA's amidolytic activity toward a chromogenic substrate.Experimental results show that encapsulation of BSA in vesicles ranges between 35 and 53% of the protein and is only slightly affected by lipid composition. For t-PA, entrapment efficiencies are lower, ranging between 2 and 16%, while lipid composition has substantial effect on entrapment (cholesterol inclusion is very important). After freeze-drying, some lipid compositions remain stable, retaining most of initially entrapped proteins, while others do not, but they may be stabilized by trehalose. In the case of BSA, liposome behavior cannot be explained based on lipid membrane rigidity (more rigid = more stable). This may be connected with previously demonstrated interactions of BSA with membranes. Oppositely, t-PA behavior is more predictable, meaning that the lipid composition selected for the specific therapeutic application determines the need for cryoprotectant addition before freeze-drying t-PA containing DRV liposomes, perhaps due to the fact that under conditions applying minimum or no interactions between t-PA and lipid membranes occur.Thereby, interactions between proteins and membranes determine not only the encapsulation efficiency but also the need for cryopreservation of liposomal protein formulations.     

Effect of lipid composition on HVJ-mediated fusion of glycophorin liposomes to erythrocytes

We previously reported that liposomes containing glycophorin or gangliosides, both of which were isolated from human erythrocytes, are efficiently fused to erythrocyte membranes in the presence of HVJ (Umeda, M. et al., J. Biochem. 94, 1955-1966 (1983), and Virology 133, 172-182 (1984]. In the present work, the effect of lipid composition in glycophorin liposomes on their sensitivity to fusion with erythrocytes was studied. Very little fusion occurred when glycophorin liposomes composed of dipalmitoylphosphatidylcholine-dicetylphosphate (9:1), dimyristoylphosphatidylcholine-dicetylphosphate (9:1), or egg yolk phosphatidylcholine-dicetylphosphate (9:1) were incubated with human erythrocytes in the presence of HVJ at 37 degrees C. Addition of cholesterol into these liposomal membranes greatly enhanced the sensitivity of the liposomes to fusion. The presence of phosphatidic acid and phosphatidylethanolamine in liposomes also enhanced the sensitivity, whereas the presence of lysophosphatidylcholine had no significant effect on the ability of the liposomes to fuse. The fusion efficiency of liposomes was also enhanced by the presence of glucosylceramide. Change of lipid composition in liposomes had, however, no appreciable influence on the HVJ-mediated binding of liposomes to erythrocytes, suggesting that the interaction between HANA protein of HVJ and glycophorin in liposomes was not affected by the lipid composition of the liposomes.     

Differential uptake of liposomes varying in size and lipid composition by parenchymal and kupffer cells of mouse liver

Using liposomes differing in size and lipid composition, we have studied the uptake characteristics of the liver parenchymal and Kupffer cells. Desferal labeled with iron-59 was chosen as a radiomarker for the liposomal content, because Desferal in its free form does not cross cellular membranes. At various time intervals after an intravenous injection of liposomes into mice, the liver was perfused with collagenase, and the cells were separated in a Percoll gradient. It was found that large multilamellar liposomes (diameter of about 0.5 μm) were mainly taken up by the Kupffer cells. For these large liposomes, the rate of uptake by Kupffer cells was rapid, with maximum uptake at around 2 hours after liposome injection. Unexpectedly, small unilamellar liposomes (diameter of about 0.08 μm) were less effectively taken up by Kupffer cells, and the rate of uptake was slow, with a maximum uptake at about 10 hours after liposome injection. In contrast, parenchymal cells were more effective in taking up small liposomes and the uptake of large liposomes was negligible. In addition, liposomes made with a galactolipid as part of the lipid constituents appeared to have higher affinity to parenchymal cells than liposomes made without the galactolipid. These findings should be of importance in designing suitable liposomes for drug targeting.     

Incorporation of some glycoconjugates into the membrane of liposomes and interaction of ganglioside-containing liposomes with rat hepatocytes in vitro

Inclusion of some glycosides, gangliosides and ceruloplasmin into large (300-400 nm in diameter) unilamellar liposomes was performed. About 100% of the gangliosides, 30-50% of ceruloplasmin and 3-5% of the glycosides were incorporated into the phospholipid vesicles under these conditions. The liposomes containing ceruloplasmin or gangliosides, in contrast to the glycoside-containing vesicles, were precipitated in the presence of agglutinin from Ricinus communis. The interaction of phospholipid vesicles containing gangliosides with rat hepatocytes "in vitro" was studied. It was found that the incorporation of gangliosides into the liposomal membrane increased the liposomal lipid uptake by 50% as can be judged from the uptake of radioactive cholesterol. Possible mechanisms of incorporation of carbohydrate-containing compounds into liposomes are discussed. It is concluded that beside the density of carbohydrates the degree of their exposure on the liposomal membrane is important for specific interactions of the vesicles with lectins.     

Investigation of lipid peroxidation in liposomes induced by heavy ion irradiation

Lipid peroxidation induced by heavy ion irradiation was investigated in 1,2-dilinoleoyl-sn-glycero-3-phosphocholine (DLPC) liposomes. Lipid peroxidation was induced using accelerated heavy ions that exhibit linear energy transfer (LET) values between 30 and 15 000 keV/μm and doses up to 100 kGy. With increasing LET, the formation of lipid peroxidation products such as conjugated dienes, lipid hydroperoxides, and thiobarbituric acid-reactive substances decreased. When comparing differential absorption spectra and membrane fluidity following irradiation with heavy ions and x-rays (3 Gy/min), respectively, it is obvious that there are significant differences between the influences of densely and sparsely ionizing radiation on liposomal membranes. Indications for lipid fragmentation could be detected after heavy ion irradiation. Received: 6 March 1997 / Accepted in revised form: 31 March 1998     

Effects of membrane-stabilizing agents,cholesterol and cepharanthin,on radiation-induced lipid peroxidation and permeability in liposomes

Effects of two membrane-stabilizing agents, cholesterol and cepharanthin, on radiation-induced lipid peroxidation and membrane permeability were examined. Radiation-induced lipid peroxidation caused an increase in membrane permeability in phosphatidylcholine liposomes. The presence of cholesterol in liposomal membranes caused a decrease in the degree of membrane permeability in spite of an increased lipid peroxidation. On the other hand, cepharanthin suppressed both lipid peroxidation and the changes in permeability induced by radiation. The membrane-stabilizing effect of cholesterol against radiation-induced changes in permeability seemed to depend on the rigidification of membranes, which was estimated by ESR studies. Cepharanthin suppressed the degree of membrane permeability mainly by inhibiting the radiation-induced lipid peroxidation. However, cepharanthin did not exhibit a radical-trapping ability.     

Interaction of bovine brain phospholipid exchange protein with liposomes of different lipid composition

The major phospholipid exchange protein from bovine brain catalyzes the transfer of phosphatidylinositol and phosphatidylcholine between rat liver microsomes and sonicated liposomes. The effect of liposomal lipid composition on the transfer of these phospholipids has been investigated. Standard liposomes contained phosphatidylcholine-phosphatidic acid (98:2, mol%); in general, phosphatidylcholine was substituted by various positively charged, negatively charged, or zwitterionic lipids. The transfer of phosphatidylinositol was essentially unaffected by the incorporation into liposomes of phosphatidic acid, phosphatidylserine, or phosphatidylglycerol (5–20 mol%) but strongly depressed by the incorporation of stearylamine (10–40 mol%). Marked stimulation (2–4-fold) of transfer activity was observed into liposomes containing phosphatidylethanolamine (2–40 mol%). The inclusion of sphingomyelin in the acceptor liposomes gave mixed results: stimulation at low levels (2–10 mol%) and inhibition at higher levels (up to 40 mol%). Cholesterol slightly diminished transfer activity at a liposome cholesterol/phospholipid molar ratio of 0.81. Similar effects were noted for the transfer to phosphatidylcholine from microsomes to these various liposomes. Compared to standard liposomes, the magnitude of $\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ tended to increase for liposomes which depressed phospholipid transfer and to decrease for those which stimulated; little change was observed in the values of $\text{V}$. Single phospholipid liposomes of phosphatidylinositol were inhibitory when added to standard liposomes.