Lecithin-cholesterol Vesicles Research Articles

Hepatic Bile Formation: Developing a New Paradigm.

In 1959, Ivar Sperber contrasted bile formation with that of urine and proposed that water flow into the canalicular conduit is in response to an osmotic, not a hydrostatic, gradient. Early attempts to support the hypothesis using a bile acid, sodium taurocholate, and the hormone secretin to stimulate bile flow led to conflicting data and a moratorium on attempts to further develop the initial proposal. However, current data amplify the initial proposal and indicate both paracellular and transcellular water flow into hepatic ductules and the canalicular conduit in response to an osmotic gradient. Also, the need to further modify the initial proposal became apparent with the recognition that bile acid aggregates (micelles), which form in the canalicular conduit, generate lecithin-cholesterol vesicles that contain water unrelated to an osmotic gradient. As part of this development is the recent introduction of the fluorescent localization after photobleaching technique for direct determination of hepatic duct flow and clarification of the role of biomarkers such as mannitol and polyethylene glycol 900. With the new paradigm, these biomarkers may prove useful for quantifying paracellular and transcellular water flow, respectively. SIGNIFICANCE STATEMENT: It is essential to identify and characterize all the sites for water flow during hepatic bile formation to obtain more precision in evaluating the causes and possible therapeutic approaches to cholestatic syndromes. Updating the Sperber proposal provides a new paradigm that addresses the advances in knowledge that have occurred.

Interaction of apolipoprotein A-I with lecithin-cholesterol vesicles in the presence of phospholipase C

Here we study the anti-nucleating mechanism of apolipoprotein A-I (apo A-I) on model biliary vesicles in the presence of phospholipase C (PLC) utilizing dynamic light scattering (DLS), steady-state fluorescence spectroscopy, cryogenic transmission electron microscopy (cryo-TEM), and UV/Vis spectroscopy. PLC induces aggregation of cholesterol-free lecithin vesicles from an initial, average size of 100 nm to a maximal size of 600 nm. The presence of apo A-I likely inhibits vesicle aggregation by shielding the PLC-generated hydrophobic moieties, which results in vesicles of an average size of 200 nm. A similar phenomenon is observed in cholesterol-enriched lecithin vesicles. Whereas PLC alone produces aggregates of 300 nm, no aggregation is observed when apo A-I is present along with PLC. However, the ability of apo A-I to inhibit aggregation is temporary, and after 8 h, a broad particle size distribution with sizes as high as 800 nm is observed. Apo A-I possibly induces the formation of small apo A-I/lecithin/cholesterol complexes of about 5–20 nm similar to the discoidal pre-HDL complexes found in blood when it can no longer effectively shield all the DAG molecules. Concomitant with formation of complexes, DAG molecules coalesce into large oil droplets, which account for the large particles observed by light scattering. Thus, apo A-I acts as an anti-nucleating agent by two mechanisms, anti-aggregation and microstructural transition. The mode of protection is dependent on the cholesterol content and the relative amounts of DAG and apo A-I present. This study supports the possibility of apo A-I solubilizing lipids in bile in a similar fashion as it does in blood and also delineates the mechanism of formation of the complexes.

Characterization of model bile using fluorescence energy transfer from dehydroergosterol to dansylated lecithin

Fluorescence energy transfer from dehydroergosterol (DHE) to dansylated lecithin (DL) was used to characterize lecithin-cholesterol vesicles in the presence of the bile salt, sodium taurocholate. At lipid concentrations approximating physiological levels, exposure of fluorescently labeled vesicles to the bile salt led to a dose-dependent increase in the DHE-to-DL fluorescence ratio during the first 24 h after mixing. The initial changes in the fluorescence ratio correlated well with conventional turbidity measurements that quantify partial micellization of vesicles as a function of bile salt loading. In addition, fluorescence energy transfer from DHE to DL revealed cholesterol enrichment of vesicles and re-vesiculation of micelles at bile salt loadings for which vesicles and micelles coexisted. Samples containing the cholesterol-enriched vesicle fraction exhibited further increases in the DHE-to-DL fluorescence ratio during a 4-week observation period but only after a significant lag period of several days. The lag period decreased with cholesterol loading, and the increase in the fluorescence ratio always preceded the appearance of microscopic, birefringent, either needlelike or platelike, cholesterol crystals, in samples that were initially supersaturated with cholesterol. Cholesterol crystals were not observed, and the fluorescence ratio did not increase, for any sample that was undersaturated with cholesterol. Taken together, these results suggest that the latter changes in fluorescence are the result of cholesterol nucleation. Fluorescence energy transfer from DHE to DL is therefore a promising technique for the characterization of model bile and, possibly, provides a direct measurement of cholesterol nucleation.—Wrenn, S. P., M. Gudheti, A. N. Veleva, E. W. Kaler, and S. P. Lee. Characterization of model bile using fluorescence energy transfer from dehydroergosterol to dansylated lecithin.

A fluorescence energy transfer study of lecithin-cholesterol vesicles in the presence of phospholipase C

We demonstrate Förster resonance energy transfer from dehydroergosterol to dansylated lecithin in lecithin-cholesterol vesicles and characterize the vesicles in the presence of the pro-nucleating enzyme, phospholipase C (PLC). Exposure to phospholipase C causes a temporary decrease in the dehydroergosterol to dansyl fluorescence ratio followed by an increase to and above the initial value. The temporary decrease in the fluorescence ratio results from an increase in the dansylated lecithin intensity that coincides with a dansyl blue shift. The extent of the blue shift correlates with the level of diacylglycerol generated in situ by PLC, suggesting an increased association between dansylated lecithin and cholesterol as membrane fluidity increases and membrane polarity decreases. The subsequent increase in the fluorescence ratio results from both an increase in the dehydroergsterol intensity and a concomitant decrease in the dansylated lecithin intensity of equal magnitude. This signifies a reduction in energy transfer from dehydroergosterol to dansylated lecithin and indicates an increased separation between the two fluorophores. The increase in the fluorescence ratio persists beyond the time scales for vesicle aggregation and fusion, as measured by turbidity, and precedes the onset of macroscopic cholesterol crystals observed with an optical microscope. Thus, the increased separation between dehydroergosterol and dansylated lecithin is consistent with a mechanism of cholesterol nucleation from the vesicles. Moreover, the onset and rate of increase in the fluorescence ratio correlate with the cholesterol:lecithin mole ratio of the vesicles.▪Fluorescence energy transfer from dehydroergosterol to dansylated lecithin therefore shows potential as a methodology for measuring cholesterol nucleation in model bile.—Wrenn, S. P., E. W. Kaler, and S. P. Lee. A fluorescence energy transfer study of lecithin-cholesterol vesicles in the presence of phospholipase C. J. Lipid Res. 1999. 40: 1483–1494.

Tauroursodeoxycholate and taurochenodeoxycholate stabilize bile lipid metastability through different mechanisms: relation to phospholipid fatty acid composition

Lecithin–cholesterol vesicles are present in bile and play a role in cholesterol metastability. Cholesterol holding capacity of vesicles is regulated by lecithin hydrophobicity. In the present study, the effect of therapeutic bile salts on biliary lipid secretion rate and phospholipid fatty acid composition was evaluated in bile duct-fistula rats to determine whether bile salts modulate biliary phospholipid species to, thereby, regulate a physico-chemical metastability of bile cholesterol. Rats were depleted with bile salt pool by overnight biliary diversion and reinfused intravenously with sodium taurocholate (TC) at a constant rate (200 nmol/min per 100 g b.w.) for 3 h, followed by infusion of either sodium taurochenodeoxycholate (TCDC) or tauroursodeoxycholate (TUDC) at a compatible rate. TCDC-infusion increased the biliary secretion rate of cholesterol and phospholipids with a decrease in molar ratio of cholesterol to phospholipid ( C/ P) when compared to values under TC-infusion, and this was associated with an increase in the molar ratio of phospholipid saturated to unsaturated fatty acids ( S/ U). In contrast, TUDC-infusion decreased such a biliary lipid secretion rate with an increase in C/ P, and this was associated with a decrease in a molar ratio of arachidonate in phospholipids. These findings indicate that TCDC enhances a cholesterol packing density of biliary particulate species by decreasing C/ P ratio and increasing S/ U, whereas TUDC improves bile lithogenecity by decreasing biliary cholesterol and phospholipid secretion rates and reducing bile arachidonyl phospholipids.

Distribution of mixtures of bile salt taurine conjugates between lecithin-cholesterol vesicles and aqueous media: an empirical model

Bile salts are surfactants that partition into phospholipid bilayers. When liposomes or membranes are exposed to mixed solutions of bile salts, the more hydrophobic bile salt species associate preferentially with the lipid bilayer. As a consequence, in the aqueous phase, the free monomeric concentration of bile salt declines and the more hydrophilic species become relatively enriched. Above a critical saturating concentration of lecithin-associated bile salt, a phase transition occurs with loss of membrane integrity and formation of mixed micelles. In this paper we present a quantitative model which, for mixed solutions of bile salt taurine conjugates, predicts the distribution of bile salt monomers between large unilamellar vesicles composed of lecithin and cholesterol and the aqueous phase. The model is based on association isotherms for individual bile salts, determined by an ultrafiltration method with empirical curve fitting, and is critically dependent upon the observation that association coefficients of each bile salt are a function of the total bound bile salt/lecithin mole ratio. Given the concentrations of individual bile salts, lecithin and cholesterol, the model permits calculation of the membrane-bound bile salt/lecithin ratio and the concentration of each bile salt remaining free as soluble monomer in the aqueous phase, as well as the overall hydrophilic-hydrophobic balance (hydrophobicity index) of the bile salts remaining free in aqueous solution. Distribution data determined empirically for a variety of mixtures of bile salt taurine conjugates and large unilamellar vesicles of varying cholesterol:lecithin ratio agree closely with predictions. This model may be of value in predicting the physical, biological and toxic properties of mixed bile salt solutions.

Site-directed mutagenesis and structure-function analysis of the human apolipoprotein A-I. Relation between lecithin-cholesterol acyltransferase activation and lipid binding.

We have mutagenized the human apoA-I gene and have generated cell lines which express normal and mutant apoA-I forms. Point mutations were introduced which changed Gln-1, Gln-2 to Arg,Arg, Pro99 to His, and Pro121 to His. In addition, the following amino acid deletions (delta) were generated: delta 113-124, delta 148-186, delta 212-233, and delta 213-243. The apoA-I form isolated from the culture medium of C127 cells was analyzed for its ability to activate lecithin-cholesterol acyltransferase (LCAT) and to bind to phospholipid vesicles and high density lipoprotein (HDL). Compared with the wild type (WT) apoA-I, the relative activation of LCAT achieved by the point mutations Gln-1, Gln-2----Arg,Arg, Pro99----His, and Pro121----His were 106 +/- 7, 92 +/- 6, and 77 +/- 9%, respectively. Kinetic analysis of one mutant apoA-I form showed similar Vmax but a 15-fold increase in the Km of the mutant apoA-I form. Furthermore, the activation achieved by the internal deletion mutants delta 113-124, delta 148-186, delta 212-233, and delta 213-243 was 47 +/- 3, 0.5 +/- 0.4, 28 +/- 4 and 13 +/- 5%, respectively. Mutants deficient in their ability to activate LCAT displayed alterations in liposome and HDL binding, compared with WT as determined by density gradient ultracentrifugation analysis of the culture medium. Thus, the peak recovery (approximately 50%) of apoA-I bound to HDL was at density 1.14 g/ml for the WT apoA-I, at 1.18 g/ml for the mutants delta 113-124 and delta 148-186, and at d greater than 1.21 g/ml for the delta 212-233 and delta 213-243. Electron microscopy of the proteoliposome LCAT substrate generated by WT and mutant apoA-I forms showed that the carboxyl-terminal deletion mutants which displayed aberrant binding to HDL also displayed reduced ability to convert the spherical lecithin-cholesterol vesicles into discs compared with WT. The findings suggest that (a) the importance of the carboxyl terminus of apoA-I for LCAT activation is related to its ability to bind to lipid and/or to form discoidal substrate for LCAT, and (b) the interaction of several domains of apoA-I are required for the activation of LCAT.

Bilirubin monoglucuronide promotes cholesterol gallstone formation

Recent evidence suggests that cholesterol (Ch) solubility in bile is determined by a complex interaction of mixed micelles and lecithin-cholesterol vesicles. Bilirubin monoglucuronide (BMG), which binds to bile salts and incorporates into mixed micelles, may displace cholesterol from micelles into vesicles, thus favoring cholesterol monohydrate crystal precipitation. Therefore, we designed an experiment to test the hypothesis that BMG may enhance cholesterol gallstone formation without inducing cholesterol supersaturation. For 8 weeks, 28 adult male prairie dogs were fed either a control, nonlithogenic diet (0.03% Ch), a high carbohydrate diet (CHO) which has no cholesterol but increases hepatic bilirubin secretion, or the same CHO diet plus 0.03% Ch. Cholecystectomy was then performed, and bile was examined microscopically for stones or crystals and analyzed for BMG and biliary lipids. Cholesterol saturation index was calculated. Cholesterol gallstones were found in none of the control animals and in 13% of the CHO-fed animals. However, the addition of trace cholesterol to the CHO diet resulted in an 88% incidence of cholesterol gallstones ( P < 0.001 vs control, P < 0.01 vs CHO, respectively). Gallbladder bile was unsaturated with cholesterol in all groups. (control = 0.65 ± 0.05, CHO = 0.46 ± 0.05, CHO + 0.03% Ch = 0.70 ± 0.03). CHO feeding alone or with trace cholesterol significantly elevated gallbladder bilirubin monoglucuronide, phospholipid, and cholesterol concentrations when compared to controls. These data suggest that in the prairie dog a high carbohydrate diet with only trace amounts of cholesterol increases bilirubin monoglucuronide in gallbladder bile and causes cholesterol gallstone formation without inducing cholesterol supersaturation. We conclude that bilirubin monoglucuronide may promote cholesterol precipitation by displacing cholesterol from mixed micelles into lecithin-cholesterol vesicles.

Structural alterations in lecithin-cholesterol vesicles following interactions with monomeric and micellar bile salts: physical-chemical basis for subselection of biliary lecithin species and aggregative states of biliary lipids during bile formation.

Using complementary physical-chemical methods including turbidimetry, quasielastic light scattering, gel filtration, and phase analysis, we examined the interactions between dilute concentrations of the common bile salt, taurochenodeoxycholate (TCDC), and uni- and multilamellar vesicles (MLVs) composed of defined molecular species of lecithin (L) and varying contents of cholesterol (Ch). Dissolution rates of MLVs with micellar TCDC, as assessed by turbidimetry, were more rapid with vesicles composed of sn-1 palmitoyl species, typical of biliary L, compared with those composed of the more hydrophobic sn-1 stearoyl species. Incorporation of Ch retarded MLV dissolution rates in proportion to the Ch content, and only at high Ch contents were dissolution rates appreciably influenced by the sn-2 fatty acid composition of L. When MLVs contained Ch in amounts characteristic of intracellular membranes (Ch/L approximately 0.1), the dissolution rates of the individual L species by TCDC accurately predicted the steady state L composition of human bile. TCDC interacted with small unilamellar L/Ch vesicles (SUVs) at concentrations well below, as well as appreciably above, its critical micellar concentration. In accordance with the TCDC-egg yolk L-H2O phase diagram, perimicellar concentrations of TCDC interacted with SUVs to form aggregates that were approximately twice the size of the SUVs. These were consistent with the formation of a dispersed hexagonal (rod-like) phase, which co-existed with aqueous bile salt (BS) monomers and either micellar or unilamellar SUV phases. Micellar TCDC completely solubilized SUVs as mixed micelles, putatively via this transient hexagonal phase. With modest Ch-supersaturation, dissolution was followed by the reemergence of a new vesicle population that coexisted metastably with mixed micelles. With high Ch supersaturation, TCDC extracted L and Ch molecules from SUVs in different proportions to form Ch-supersaturated mixed micelles and Ch-enriched SUVs, in accordance with the metastable phase diagram. These experiments are consistent with the hypothesis that sn-1 palmitoyl L species are subselected for bile, in part, by physical-chemical interactions of intracellular BS concentrations with Ch-poor membranes and that the subsequent evolution of Ch-rich vesicles and Ch-saturated mixed micelles occurs via a transitional hexagonal (rod) phase. These liquid-crystalline states are likely to be transient in Ch-unsaturated biles, but may persist in Ch-supersaturated human biles because of their high Ch contents which retard or inhibit these phase transitions.

High-resolution proton and carbon-13 NMR of membranes: why sonicate?

We have obtained high-field (11.7-T) proton and carbon-13 Fourier transform (FT) nuclear magnetic resonance (NMR) spectra of egg lecithin and egg lecithin-cholesterol (1:1) multibilayers, using "magic-angle" sample spinning (MASS) techniques, and sonicated egg lecithin and egg lecithin-cholesterol (1:1) vesicles, using conventional FT NMR methods. Resolution of the proton and carbon-13 MASS NMR spectra of the pure egg lecithin samples is essentially identical with that of sonicated samples, but spectra of the unsonicated lipid, using MASS, can be obtained very much faster than with the more dilute, sonicated systems. With the 1:1 lecithin-cholesterol systems, proton MASS NMR spectra are virtually identical with conventional FT spectra of sonicated samples, while with 13C NMR, we demonstrate that most 13C nuclei in the cholesterol moiety can be monitored, even though these same nuclei are essentially invisible, i.e., are severely broadened, in the corresponding sonicated systems. In addition, 13C MASS NMR, spectra can again be recorded much faster than with sonicated samples, due to concentration effects. Taken together, these results strongly suggest there will seldom be need in the future to resort to ultrasonic disruption of lipid bilayer membranes in order to obtain high-resolution proton or carbon-13 NMR spectra.

Aqueous bile salt-lecithin-cholesterol systems: equilibrium aspects.

Cholesterol is solubilized by bile salt and bile salt-lecithin micelles without appreciable alteration in preexisting micellar size or structure. In dilute (approximately 3 gm per dl) model bile, but not in concentrated (approximately 10 gm per dl) systems, supramicellar concentrations of cholesterol are also solubilized in "stable" microdispersions of small lecithin-cholesterol vesicles (approximately 200 to 400 A in radius). Under physical-chemical conditions of physiological importance, the micellar solubilities of cholesterol are influenced by the total lipid concentrations, lecithin-to-bile salt ratio and bile salt species. The hydrophilic-hydrophobic balance of the bile salt monomer also influences the number and composition of precipitate phases coexisting in equilibrium with saturated micelles. When diluted below the critical micellar concentration (more correctly, the intermicellar concentration) of the bile salt species, the systems no longer contain micelles, but cholesterol remains dispersed in unilamellar liposomes that form spontaneously from the mixed micellar concentrations of the biliary lipids.

Interaction of lecithin-cholesterol acyltransferase with human plasma lipoproteins and with lecithin-cholesterol vesicles.

Interaction of lecithin-cholesterol acyltransferase with human plasma lipoproteins and with lecithin-cholesterol vesicles.

Binding and incorporation of lecithin-cholesterol vesicles to lymphocytes: a spin-label study.

When lecithin-cholesterol vesicles, containing the membrane-bound spin probe 3-doxyl-cholestane, were set in contact with mouse lymphocytes, the vesicles adsorbed to the cell and vesicle-membrane components were transferred to it. The spin probe was enzymatically reduced at the inside of the cell membrane. The spin-label method provided a means to determine quantitatively the extent of vesicles adsorption and vesicle-cell fusion by measuring the transfer of vesicles membrane material to the cell. This method, together with the reduction of spin label by the cell, allowed also a quantitative estimate to the extent of endocytosis during cell-liposome interaction.

Preparation and properties of spin-labeled lecithin-cholesterol liposomes.

Lecithin-cholesterol vesicles of various compositions containing membrane-bound spin-labeled cholestane can be prepared by appropriate choice of initial concentrations of components during sonication. Increasing incorporation of spin label increases incorporation of cholesterol and decreases incorporation of lecithin, with the result that liposomes with cholesterol-lecithin molar ratios larger than 2 can be obtained. Besides associating with cholesterol-lecithin complexes in the liposome, the spin label seems to associate with cholesterol. Changes of the paramagnetic resonance spectrum of the liposome-bound spin label due to changes in liposomal cholesterol and spin label mole fractions - assessed by three parameters - can be used in cell-liposome interaction studies.

In vitro mass: Activity distribution of lecithin-cholesterol acyltransferase among human plasma lipoproteins

In order to compare the mass-activity distribution of lecithin-cholesterol acyltransferase (LCAT) among plasma lipoproteins separated by various ultracentrifugal or chromatographic procedures, we have quantified the enzyme by an electroimmunoassay technique using a specific antibody raised in the rabbit. This antibody, when added to whole serum, inhibited all of the enzyme activity present in it. The percent mass distribution of the enzyme among the lipoproteins isolated by rate-zonal ultracentrifugation ( d 1.00–1.36 g/ml, SW 40 rotor, 37000 rpm, 16 h) was as follows: very low density lipoproteins (VLDL), 0; low density lipoproteins (LDL), 6.2; HDL 2, 6.5; HDL 3, 12 and d> 1.21 g/ml fraction, 75. Measurement of LCAT activity of each lipoprotein fraction against mixed single bilayer lecithin-cholesterol vesicles (molar ratio, 4:1) containing apo A-1, indicated that VLDL, LDL and HDL 2 were inactive or minimally active under the experimental conditions used, whereas HDL 3 and the d > 1.21 g/ml fraction contained 17.5 and 79.9% of the total enzyme activity. Prolonged ultracentrifugation of the LCAT-containing lipoproteins resulted in the recovery of activity in the lipoprotein-free infranatant. In studies with lipoproteins linked to Sepharose 4B, LCAT was found to bind LDL, HDL 2, and HDL 3 It is concluded that LCAT is present in all the major lipoproteins except for VLDL. The activity appears to be dependent, at least in part, on the type of lipoproteins to which the enzyme is associated with.

The rapid transbilayer movement of thiocholesterol in small unilamellar phospholipid vesicles

Cholesterol is a major component of biological membranes, yet there is very little information concerning its distribution across the membrane. Recent experiments in our laboratory, using cholesterol oxidase, have demonstrated that cholesterol can undergo a rapid transbilayer movement in lecithin-cholesterol vesicles in a half-time of 1 min or less at 37°C. In order to support this conclusion, we have sought other approaches to the measurement of this process. We now report our finding that the transbilayer movement of thiocholesterol in phospholipid vesicles occurs in a half-time of 1 min or less at 20°C.

Is cholesterol the receptor for polyene antibiotic-induced B-lymphocyte activation

Stimulation induced by polyene antibiotics has previously been considered to be mediated via binding to cell membrane cholesterol. However, stimulation by polyenes such as nystatin was not affected differently than other polyclonal B-cell activators by the addition of cholesteral-blocking drugs such as digitonin, tomatin, or pimaricin, nor did cholesterol-containing serum diminish its mitogenic properties. Incubation of cells with lecithin-cholesterol vesicles, thereby increasing total cell cholesterol, greatly reduces cell reactivity toward polyenes to the same extent as toward other B- or T-cell activators. We therefore, tentatively suggest that polyene-induced mitogenesis is not mediated via binding to cell membrane cholesterol but via interaction with a distinct mitogen receptor on the cell surface.

A rapid radioassay procedure for plasma lecithin-cholesterol acyltransferase.

A rapid and accurate single step procedure is described for the assay of lecithin-cholesterol acyltransferase activity. After incubation, using radiolabeled cholesterol as the substrate, an ethanolic solution of digitonin is added directly to the incubation mixture to extract the lipids. Excess cholesterol is then added, and the labeled cholesterol-digitonide along with denatured proteins are sedimented by low speed centrifugation, leaving the labeled esterified cholesterol in solution. An aliquot of the supernatant is counted in an aqueous scintillation mixture. The method correlates well with the established thin-layer chromatographic procedure using either lecithin-cholesterol vesicles or heat-inactivated plasma as the substrate for lecithin-cholesterol acyltransferase.

The rapid transmembrane movement of cholesterol in small unilamellar vesicles

The exchange of cholesterol between two populations of small unilamellar vesicles has been investigated using a new system. Uniformly sized egg lecithin-cholesterol vesicles containing [3H]cholesterol and the glycolipid N-palmitoyl-DL-dihydrolactocerebroside were used as donors, whereas similar vesicles containing unlabelled cholesterol and no glycolipid were used as cholesterol acceptors. The two populations of vesicles were separated with the castor bean lectin Ricinus communis. It was found that greater than 90% of the cholesterol in the donor vesicle could be exchanged with a single time constant, the half-time for the completion of this exchange process being 1.5 h at 37 degrees C. Therefore, the rate of transmembrane movement or flip-flop of cholesterol in these vesicles must be at least as fast as the intermembrane exchange process. Similar results were obtained using hemoglobin-free human erythrocyte ghosts as the acceptor membrane. If the molecular-sieve chromatography step used to fractionate the vesicles was omitted, a non-exchangeable pool of cholesterol was detected which was shown not to be due to the presence of multilamellar vesicles.

Interaction between lymphocytes and lecithin-cholesterol vesicles.

Interaction between lymphocytes and lecithin-cholesterol vesicles.