The internal aqueous volume of small unilamellar vesicles changes at the phase transition temperature of the phospholipid

Changes in the fluorescence of partially self-quenched 5(6)-carboxyfluorescein trapped within the internal aqueous compartment of small unilamellar dipalmitoylphosphatidylcholine vesicles indicate that the trapped volume of these vesicles decreases when the phospholipid undergoes the liquid crystalline to gel state transition. This volume change is completely reversible and is not caused by vesicle-vesicle fusion. Furthermore, this decrease in volume of the internal aqueous compartment may be attributed to a change in vesicle shape upon undergoing the phase transition.     

Comparison of large unilamellar vesicles prepared by a petroleum ether vaporization method with multilamellar vesicles: ESR, diffusion and entrapment analyses.

Large unilamellar vesicles, prepared by a petroleum ether vaporization method, were compared to multilamellar vesicles with respect to a number of physical and functional properties. Rotational correlation time approximations, derived from ESR spectra of both hydrophilic (3-doxyl cholestane) and hydrophobic (3-doxyl androstanol) steroid spin probes, indicated similar molecular packing of lipids in bilayers of multilamellar and large unilamellar liposomes. Light scattering measurements demonstrated a reduction in apparent absorbance of large unilamellar vesicles, suggesting loss of multilamellar structure which was confirmed by electron microscopy. Furthermore, large unilamellar vesicles exhibited enhanced passive diffusion rates of small solutes, releasing a greater percentage of their contents within 90 min than multilamellar vesicles, and reflecting the less restricted diffusion of a unilamellar system. The volume trapping capacity of large unilamellar vesicles far exceeded that of multilamellar liposomes, except in the presence of a trapped protein, soy bean trypsin inhibitor, which reduced the volume of the aqueous compartments of large unilamellar vesicles. Finally, measurement of vesicle diameters from electron micrographs of large unilamellar vesicles showed a vesicle size distribution predominantly in the range of 0.1--0.4 micron with a mean diameter of 0.21 micron.     

Comparison of large unilamellar vesicles prepared by a petroleum ether vaporization method with multilamellar vesicles: ESR,diffusion and entrapment analyses

Large unilamellar vesicles, prepared by a petroleum ether vaporization method, were compared to multilamellar vesicles with respect to a number of physical and functional properties. Rotational correlation time approximations, derived from ESR spectra of both hydrophilic (3-doxyl cholestane) and hydrophobic (3-doxyl androstanol) steroid spin probes, indicated similar molecular packing of lipids in bilayers of multilamellar and large unilamellar liposomes. Light scattering measurements demonstrated a reduction in apparent absorbance of large unilamellar vesicles, suggesting loss of multilamellar structure which was confirmed by electron microscopy. Furthermore, large unilamellar vesicles exhibited enhanced passive diffusion rates of small solutes, releasing a greater percentage of their contents within 90 min than multilamellar vesicles, and reflecting the less restricted diffusion of a unilamellar system. The volume trapping capacity of large unilamellar vesicles far exceeded that of multilamellar liposomes, except in the presence of a trapped protein, soy bean trypsin inhibitor, which reduced the volume of the aqueous compartments of large unilamellar vesicles. Finally, measurement of vesicle diameters from electron micrographs of large unilamellar vesicles showed a vesicle size distribution predominantly in the range of 0.1–0.4 μm with a mean diameter of 0.21 μm.     

Preparation and characterization of unilamellar vesicles from cholate-phospholipid micelle treated with cholestyramine

Cholestyramine, a well-known bile-salt sequestrant, can be used effectively to remove cholate or deoxycholate from a solution of phosphatidylcholine-bile salt mixed micelle. Upon removal of the bile salt, unilamellar phospholipid vesicles form essentially instantaneously. Cholestyramine resin could be pelleted and removed from the vesicle solution after a low speed centrifugation. Based on phosphate analyses, the recovery of vesicles was approximately 60% of the starting material. The average diameter of these vesicles, as estimated by gel exclusion chromatography on sephacryl S-1000 beads and by trapped volume measurement using [3H]sucrose, ranged between 85 to 121 nm. Phosphatidylethanolamine, cholesterol, or n-alkane such as tetradecane can be incorporated into the vesicles without any selective loss; however, selective loss was experienced when negatively charged phospholipid species such as phosphatidylglycerol or phosphatidylserine was included in vesicle formation.     

Influence of dilution on the physical state of model bile systems: NMR and quasi-elastic light-scattering investigations

Multinuclear (1H and 31P) nuclear magnetic resonance (NMR) spectroscopy and quasi-elastic light scattering have been used to characterize molecular aggregates formed in dilute sodium taurocholate--egg lecithin solutions. When mixed micelles (1.25 g/dL) are diluted with 150 mM aqueous sodium chloride, light-scattering measurements suggest a transformation from mixed micelles to unilamellar vesicle species. Decreased 1H NMR line widths for bile salt resonances are consistent with predominance of a monomer form. The concurrent appearance of a second phospholipid choline methyl resonance indicates two types of phospholipid environment in slow chemical exchange: this behavior is consistent with small unilamellar vesicles. The appearance of bilayer vesicles in dilute model bile solutions is confirmed by addition of a lanthanide shift reagent (Pr3+), which splits the 1H or 31P head-group peak into two components with distinct chemical shift sensitivities. These mixed micelle and vesicle aggregates are also distinguished by their susceptibility to the lipolytic enzyme phospholipase A2 from cobra venom.     

Interaction of phospholipid vesicles with cells. Endocytosis and fusion as alternate mechanisms for the uptake of lipid-soluble and water-soluble molecules

Depending on their phospholipid composition, liposomes are endocytosed by, or fuse with, the plasma membrane, of Acanthamoeba castellanii. Unilamellar egg lecithin vesicles are endocytosed by amoeba at 28 degrees C with equal uptake of the phospholipid bilayer and the contents of the internal aqueous space of the vesicles. Uptake is inhibited almost completely by incubation at 4 degrees C or in the presence of dinitrophenol. After uptake at 28 degrees C, the vesicle phospholipid can be visualized by electron microscope autoradiography within cytoplasmic vacuoles. In contrast, uptake of unilamellar dipalmitoyl lecithin vesicles and multilamellar dipalmitoyl lecithin liposomes is only partially inhibited at 4 degrees C, by dinitrophenol and by prior fixation of the amoebae with glutaraldehyde, each of which inhibits pinocytosis. Vesicle contents are taken up only about 40% as well as the phospholipid bilayer. Electron micrographs are compatible with the interpretation that dipalmitoyl lecithin vesicles fuse with the amoeba plasma membrane, adding their phospholipid to the cell surface, while their contents enter the cell cytoplasm. Dimyristoyl lecithin vesicles behave like egg lecithin vesicles while distearoyl lecithin vesicles behave like dipalmitoyl lecithin vesicles.     

The association of D-glucose with unilamellar phospholipid vesicles

The equilibrium uptake of hydrophilic solutes, D-glucose and L-carnitine, by large unilamellar phospholipid vesicles composed of egg lecithin (PC), phosphatidic acid (PA), and various concentrations of cholesterol (Chol) has been measured. Calculation of the encapsulated volume of PC-PA and PC-PA-Chol vesicles, based on electron-microscopy data, agreed with the values directly measured by fluorescence techniques. Likewise, vesicle surface areas determined directly and from electron microscopy were in good agreement. Equilibrium uptake experiments by these well-characterized vesicles showed that glucose was taken up in excess of that amount predicted on the basis of the encapsulated aqueous volume. In contrast, the equilibrium uptake of carnitine can be predicted solely on the basis of the vesicle encapsulated volume. Each excess glucose molecule was found to be associated with from 7 to 5200 phospholipid molecules for 100 and 0.1 mM glucose, respectively. Uptake of glucose by PC-PA-Chol vesicles is independent of the cholesterol concentration and is similar to that observed in PC-PA vesicles. The cholesterol concentration independence and oil/buffer partitioning studies with octane and octanol, coupled with previous studies, strongly suggest that excess glucose is located in the vicinity of the phospholipid head group. A probable mechanism would have phospholipid, water and glucose all involved in the interaction rather than a competition between water and glucose for the phospholipid surface, as has been suggested in the literature.     

Effect of cholesterol on vesicle bilayer geometry of choline plasmalogen and comparison with dialkyl-, alkylacyl- and diacyl-glycerophosphocholines

Small unilamellar vesicles containing alkenylacyl-, alkylacyl-, dialkyl- or diacyl-glycerophosphocholine were prepared by sonication. Their size was determined from the average internal volume after chromatography on Sepharose 2B and from 31P-NMR linewidths. Alkenylacyl glycerophosphocholine (choline plasmalogen) was found to form the largest vesicles. By addition of 30 mol% cholesterol, the size of plasmalogen vesicles, but not of those containing the alkyl and acyl analogue lipids, was significantly increased. The presence of 50 mol% sterol led to highly increased vesicle sizes of alkylacyl, dialkyl and diacyl-glycerophosphocholine. Mixtures of plasmalogens with 50 mol% cholesterol did not form unilamellar vesicles upon sonication. Bilayer thickness and surface area per phospholipid molecule were determined by small angle X-ray scattering and measurement of partial specific volumes. There is little difference between alkenylacyl glycerophosphocholine and the corresponding diacyl-analog, whereas bilayers consisting of dioleoyl glycerophosphocholine are significantly thinner. Correspondingly their molecular surface area is by about 8% larger than that of the mixed-chain diradyl glycerophosphocholine, since the partial molar volumes are similar for all vesicles tested.     

Disappearance of macrophage surface folds after antibody-dependent phagocytosis

We have employed the method of Burwen and Satir (J. Cell Biol., 1977, 74:690) to measure the disappearance of surface folds from resident guinea pig peritoneal macrophages after antibody-dependent phagocytosis. Unilamellar phospholipid vesicles containing dimyristoylphosphatidylcholine and 1 mol % dinitrophenyl-epsilon- aminocaproyl-phosphatidylethanolamine, a lipid that possesses a hapten headgroup, were prepared by an ether injection technique. These vesicles were taken up by macrophages in a time- and temperature- dependent fashion. Vesicles that contained ferritin trapped in the internal aqueous volume were identified within macrophages by transmission electron microscopy. Scanning electron microscopy has shown that macrophage surface folds decrease dramatically after phagocytosis. The surface fold length (micrometer) per unit smooth sphere surface area (micrometer2) decreases from 1.3 +/- 0.3 micrometer- 1 to 0.53 +/- 0.25 micrometer-1 when cells are incubated in the presence of specific anti-DNP antibody and vesicles at 37 degrees C. No significant effect was observed in the presence of antibody only or vesicles only. Our studies shown that phagocytosis is associated with a loss of cell surface folds and a loss of cell surface area, which is consonant with current views of the endocytic process. On the basis of our uptake data, we estimate that approximately 400 micrometer2 of vesicle surface membrane is internalized. The guinea pig macrophage plasma membrane has a total area of approximately 400 micrometer2 in control studies, whereas the cells have roughly 300 micrometer2 after phagocytosis. These estimates of surface areas include membrane ruffles and changes directly related to changes in cell volume. We suggest that during antibody-dependent phagocytosis a membrane reservoir is made available to the cell surface.     

Effects of the pore-forming agent nystatin on giant phospholipid vesicles

The effects of the polyene pore-forming agent nystatin were investigated on individual giant unilamellar phospholipid vesicles (GUVs), made of 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC), in different methanol-water solutions using phase-contrast optical microscopy. Three characteristic effects were detected in three different nystatin concentration ranges: vesicle shape changes (between 150 and 250μM); transient, nonspecific, tension pores (between 250 and 400μM); and vesicle ruptures (above 400μM). Both the appearance of the transient tension pores and the vesicle ruptures were explained as being a consequence of the formation of size-selective nystatin channels, whose membrane area density increases with the increasing nystatin concentrations. Our results also show that nystatin is able to form pores in the absence of sterols. In addition, study of the cross-interactions between nystatin and methanol revealed mutually antagonizing effects on the vesicle behavior for methanol volume fractions higher than 10%.     

Pyranine (8-hydroxy-1,3,6-pyrenetrisulfonate) as a probe of internal aqueous hydrogen ion concentration in phospholipid vesicles

The fluorescence intensity (at 510 nm) of the hydrophilic pyrene analogue 8-hydroxy-1,3,6-pyrenetrisulfonate (pyranine) is strongly dependent upon the degree of ionization of the 8-hydroxyl group (pKa = 7.2) and hence upon the medium pH, over the range pH 6--10. Because of its polyanionic character, pyranine does not bind significantly to phospholipid vesicles having a net anionic surface charge. As a result, it is possible to form vesicles in the presence of pyranine which, after removal of external probe by gel filtration, contain pyranine entrapped within the internal aqueous compartment. Once entrapped, pyranine does not readily leak out of the vesicles. Because the fluorescence properties of entrapped pyranine resemble closely the properties of bulk pyranine solution with respect to pH sensitivity, pyranine can be used as a reliable reporter of aqueous pH changes within anionic vesicles. When HCl is rapidly added to a suspension of unilamellar soybean phospholipid (asolectin) vesicles preincubated at alkaline pH, a biphasic decrease in the pH of the vesicle inner aqueous compartment is observed. An initial, very rapid and electrically uncompensated H+ influx (t 1/2 less than 1 s) results in the generation of a transmembrane electric potential opposing further H+ influx. This leads to the development of a much slower (t 1/2 approximately equal to 5 min), valinomycin-sensitive, proton--counterion exchange which continues until the proton concentration gradient is eliminated. Similar results were obtained in asolectin vesicles prepared by detergent dilution, in sonicated egg phosphatidylcholine vesicles, and in multilamellar asolectin liposomes. The rather high permeability of soybean lipid membranes to H+ is surprising in view of the widespread use of these lipids for the reconstitution of membrane proteins which are thought to generate or utilize H+ ion gradients in energy transduction reactions.     

Preparation and analysis of small unilamellar phospholipid vesicles of a uniform size

The interaction of carbonmonoxyhemoglobin and heme with small unilamellar phospholipid vesicles was studied using dynamic light scattering. Addition of carbonmonoxyhemoglobin to dimyristoylphosphatidylcholine:dimyristoylphosphatidylserine small unilamellar vesicles resulted in an increase of average vesicle size from 17.4 to 32.0nm. Addition of heme to vesicles produced a smaller size increase, from 17.4 to 21.0nm. Also reported is a method for preparing small unilamellar lipid vesicles of a uniform size, suitable for use in NMR spectroscopy.     

Morphology of gel state phosphatidylethanolamine and phosphatidylcholine liposomes: A negative stain electron microscopic study

The capture volumes (internal aqueous spaces) of liposomes prepared from a series of saturated phosphatidylcholines (PC) and saturated phosphatidylethanolamines (PE) had previously been found to be a function of lipid structure. PE vesicles have larger internal aqueous spaces than PC vesicles and for lipids with the same head group, capture volume increases with lengthening of the fatty acyl chains. Capture volume is determined by vesicle size, number of lamellae, and interlamellar distance. In this study, liposomes were formed from a saturated PC or PE and their morphology studied in the gel state using the technique of negative staining transmission electron microscopy. The measured interlamellar distances were quite similar among these various lipids while the number of lamellae was found to decrease as the fatty acyl chain length increased. In general PEs form fewer lamellae than PCs and in particular mono- and di-methylated dipalmitoyl-PE form only unilamellar vesicles. The number of lamellae then appears to bear a relationship to the size of the capture volume in that liposomes with largercapture volumes have fewer lamellae.     

Rapid determination of internal volumes of membrane vesicles with electron spin resonance-stopped flow technique

We have developed an electron spin resonance (ESR)-stopped flow technique and employed it for the simple and rapid determination of internal volumes of biomembrane vesicles and liposomes. A vesicle suspension containing a neutral and membrane-permeable spin label, 2,2,6,6-tetramethyl-4-oxopiperidine-1-oxyl (TEMPONE), was mixed in the stopped-flow apparatus with an isotonic solution of relatively impermeable line broadening agents, potassium tris(oxalato)chromate(III) or potassium ferricyanide, and an ESR spectrum was recorded. From the relative intensity of the sharp triplet signal due to TEMPONE in the aqueous space within vesicles, the determination of the internal aqueous volume was straightforward. Using this technique, it is possible to measure intravesicular volumes in 0.1 s. The internal volume of sonicated phospholipid vesicles was approximately 0.3 microliter/mg lipid. The light fraction of sarcoplasmic reticulum membrane vesicles isolated from rabbit skeletal muscle was estimated to have an internal volume of 2.2-2.6 microliter/mg protein in its resting state. Activation of Ca2+ pumps in the membrane upon addition of ATP and Ca2+ ions decreased the internal volume by about 10%. This finding supports the hypothesis that the Ca2+ pump is electrogenic and that the efflux of potassium ions compensates for the influx of positive charges. The present technique is widely applicable to the simple and rapid determination of the internal volumes of membrane vesicles.     

Phase behaviour of a diglyceride prodrug: spontaneous formation of unilamellar vesicles

A prodrug (Fig. 1(IV)) is synthesized consisting of the beta-blocker bupranolol which is covalently linked to 1, 3-dipalmitoyl-2-succinyl-glycerol. The resulting lipid-like prodrug is amphipathic and surface active. It disperses readily in H2O above 30 degrees C forming a smectic lamellar phase. This prodrug bears one positive charge at neutral pH and hence the swelling behaviour of dispersions in H2O is similar to that of charged phospholipids: the dispersions show continuous swelling with increasing water content and consequently in the excess H2O region of the phase diagram the thermodynamically most stable structure is the unilamellar vesicle. This includes oligomeric vesicles which may be defined as unilamellar vesicles containing smaller, also unilamellar vesicles entrapped in their internal aqueous compartment. The prodrug dispersions in H2O are polydisperse with vesicle sizes ranging from 0.1 micron to several micron. Sonication of these dispersions produce small unilamellar vesicles of an average size and size distribution similar to sonicated egg phosphatidylcholine dispersions. Unsonicated dispersions of the prodrug in H2O undergo reversibly sharp order-disorder transitions at 32 degrees C with an enthalpy change of delta H = 10 kcal/mol. In sonicated aqueous dispersions this phase transition is asymmetric and significantly broadened indicating that the cooperativity is markedly reduced. The peak temperature and enthalpy change of this broad transition are reduced compared to the transition observed with unsonicated dispersions. The temperature dependence of the electron spin resonance (ESR) hyperfine splitting and order parameter also reflects the order-disorder transition. From ESR spin labeling it is concluded that in sonicated dispersions the prodrug molecule is more mobile and its anisotropy of motion is reduced compared to unsonicated dispersions. This result indicates that the molecular packing in the highly curved bilayers of small unilamellar prodrug vesicles is significantly perturbed compared to bilayers of unsonicated dispersions.     

Interaction of short-chain lecithin with long-chain phospholipids: characterization of vesicles that form spontaneously

Stable unilamellar vesicles formed spontaneously upon mixing aqueous suspensions of long-chain phospholipid (synthetic, saturated, and naturally occurring phosphatidylcholine, phosphatidylethanolamine, and sphingomyelin) with small amounts of short-chain lecithin (fatty acid chain lengths of 6-8 carbons) have been characterized by using NMR spectroscopy, negative staining electron microscopy, differential scanning calorimetry, and Fourier transform infrared (FTIR) spectroscopy. This method of vesicle preparation can produce bilayer vesicles spanning the size range 100 to greater than 1000 A. The combination of short-chain lecithin and long-chain lecithin in its gel state at room temperature produces relatively small unilamellar vesicles, while using long-chain lecithin in its liquid-crystalline state produces large unilamellar vesicles. The length of the short-chain lecithin does not affect the size distribution of the vesicles as much as the ratio of short-chain to long-chain components. In general, additional short-chain decreases the average vesicle size. Incorporation of cholesterol can affect vesicle size, with the solubility limit of cholesterol in short-chain lecithin micelles governing any size change. If the amount of cholesterol is below the solubility limit of micellar short-chain lecithin, then the addition of cholesterol to the vesicle bilayer has no effect on the vesicle size; if more cholesterol is added, particle growth is observed. Vesicles formed with a saturated long-chain lecithin and short-chain species exhibit similar phase transition behavior and enthalpy values to small unilamellar vesicles of the pure long-chain lecithin prepared by sonication. As the size of the short-chain/long-chain vesicles decreases, the phase transition temperature decreases to temperatures observed for sonicated unilamellar vesicles. FTIR spectroscopy confirms that the incorporation of the short-chain lipid in the vesicle bilayer does not drastically alter the gauche bond conformation of the long-chain lipids (i.e., their transness in the gel state and the presence of multiple gauche bonds in the liquid-crystalline state).     

Directly Observed Membrane Fusion Between Oppositely Charged Phospholipid Bilayers

A novel method was developed for the direct examination of pairwise encounters between positively and negatively charged phospholipid bilayer vesicles. Giant bilayer vesicles (unilamellar, 4–20 μm in diameter) prepared from 1,2-dioleoyl-sn-glycero-3-ethylphosphocholine, a new cationic phospholipid derivative, were electrophoretically maneuvered into contact with individual anionic phospholipid vesicles. Fluorescence video microscopy revealed that such vesicles commonly underwent fusion within milliseconds (1 video field) after contact, without leakage. Fusion occurred at constant volume and, since flaccid vesicles were rare, the excess membrane was not available after fusion. Hemifusion (the outer monolayers of each vesicle fused while the inner monolayers remained intact) was inferred from membrane-bound dye transfer and a change in the contact area. Hemifusion was observed as a final stable state and as an intermediate to fusion of vesicles composed of charged phospholipids plus zwitterionic phospholipids. Hemifusion occurred in one of three ways following adhesion: either delayed with an abrupt increase in area of contact, immediately with a gradual increase in area of contact, or with retraction during which adherent vesicles dissociated from a flat contact to a point contact. Phosphatidylethanolamine strongly promoted immediate hemifusion; the resultant hemifused state was stable and seldom underwent complete fusion. Although sometimes single contacts between vesicles led to rupture of both, in other cases, a single vesicle underwent multiple fusion events. Direct observation has unequivocally demonstrated the fusion of two, isolated bilayer-bounded bodies to yield a stable, non-leaky product, as occurs in cells, in the absence of proteins. Received: 25 November 1998/Revised: 23 March 1999     

Preparation of unilamellar lipid vesicles at 37°C by vaporization methods

We have developed a method utilizing low boiling solvents to prepare large, unilamellar vesicles at physiologic temperatures. Solutions of ethyl methyl ether or dichlorofluoromethane (Freon-21) at 4°C containing solubilized lipids were injected into a column of a aqueous buffer at 37°C. Vesicles prepared in this manner have been examined by freeze-fracture, negative stain electron microscopy, and fluorescence microscopy. The principal advantages of this technique are: (1) heat labile substances may be more readily entrapped in the internal vesicle volume without thermal denaturation, and (2) the range of lipids which are soluble in dichlorofluoromethane is greater than that of many other solvents, e.g. diethyl ether.     

Interaction of intestinal brush border membrane vesicles with small unilamellar phospholipid vesicles. Exchange of lipids between membranes is mediated by collisional contact

The kinetics of lipid transfer from small unilamellar vesicles as the donor to brush border vesicles as the acceptor have been investigated by following the transfer of radiolabeled or spin-labeled lipid molecules in the absence of exchange protein. The labeled lipid molecules studied were various radiolabeled and spin-labeled phosphatidylcholines, radiolabeled cholesteryl oleate, and a spin-labeled cholestane. At a given temperature and brush border vesicle concentration similar pseudo-first-order rate constants (half-lifetimes) were observed for different lipid labels used. The lipid transfer is shown to be an exchange reaction leading to an equal distribution of label in donor and acceptor vesicles at equilibrium (time t----infinity). The lipid exchange is a second-order reaction with rate constants being directly proportional to the brush border vesicle concentration. The results are only consistent with a collision-induced exchange of lipid molecules between small unilamellar phospholipid vesicles and brush border vesicles. Other mechanisms such as collision-induced fusion or diffusion of lipid monomers through the aqueous phase are negligible at least under our experimental conditions.     

Fusion of phospholipid vesicles with planar phospholipid bilayer membranes. I. Discharge of vesicular contents across the planar membrane

Multilamellar phospholipid vesicles are introduced into the cis compartment on one side of a planar phospholipid bilayer membrane. The vesicles contain a water-soluble fluorescent dye trapped in the aqueous phases between the lamellae. If a vesicle containing n lamellae fuses with a planar membrane, an n-1 lamellar vesicle should be discharged into the opposite trans compartment, where it would appear as a discernible fluorescent particle. Thus, fusion events can be assayed by counting the number of fluorescent particles appearing in the trans compartment. In the absence of divalent cation, fusion does not occur, even after vesicles have been in the cis compartment for 40 min. When CaCl2 is introduced into the cis compartment to a concentration of greater than or equal to 20 mM, fusion occurs within the next 20 min; it generally ceases thereafter because of vesicle aggregation in the cis compartment. With approximately 3 x 10(8) vesicles/cm3 in the cis compartment, about 25-50 fusion events occur following CaCl2 addition. The discharge of vesicular contents across the planar membrane is the most convincing evidence of vesicle-membrane fusion and serves as a model for that ubiquitous biological phenomenon--exocytosis.