Parameters affecting fusion between liposomes and synaptosomes. Role of proteins,lipid peroxidation,pH and temperature

We investigated the effect of several parameters, such as temperature, pH and proteins, on the fusion between synaptosomes, freshly isolated from rat brain cortex, and large unilamellar phosphatidylserine liposomes. These studies were carried out in both peroxidized and nonperoxidized synaptosomes. Mixing of membrane lipids was monitored using a fluorescence resonance energy transfer assay. Ascorbate (0.8 mm)/ Fe²⁺ (2.5 m)-induced peroxidation of synaptosomes enhanced the fusion process (twofold) which may reflect an increase in synaptosomal protein hydrophobicity and hence a facilitation of intermembrane aggregation. The fusion process was shown to be temperature sensitive, a reduction in the extent being observed (twofold) as the temperature was lowered from 37 to 25°C. This effect may be due to changes in membrane fluidity. The fusion process is pH dependent, an increase in both kinetics and extent being observed when the pH was lowered from 7.4 to 5.5. A significant inhibition (92% at pH 7.4; 35% at pH 5.5) of the interaction between synaptosomes and liposomes by trypsin pretreatment of synaptosomes was found, thus indicating that the fusion reaction is a protein-mediated process. The inhibitory effect of trypsin at pH 5.5 is not so strong as that at physiological pH. These results suggest that, in addition to the involvement of proteins, nonspecific interactions between the synaptosomal and liposomal membranes under acidic conditions may also play a role in the fusion process. The investigation of binding of synaptosomes to liposomes under several experimental conditions provided evidence for the participation of proteins in membrane aggregation, as well as for the role of electrostatic forces in this process, at mild acidic pH.This work was supported by Junta National de Investigação Científica e Tecnológica (JNICT) and the Calouste Gulbenkian Foundation, Portugal.     

Effect of lipid composition upon fusion of liposomes with Sendai virus membranes

How the lipid composition of liposomes determines their ability to fuse with Sendai virus membranes was tested. Liposomes were made of compositions designed to test postulated mechanisms of membrane fusion that require specific lipids. Fusion does not require the presence of lipids that can form micelles such as gangliosides or lipids that can undergo lamellar to hexagonal phase transitions such as phosphatidylethanolamine (PE), nor is a phosphatidylinositol (PI) to phosphatidic acid (PA) conversion required, since fusion occurs with liposomes containing phosphatidylcholine (PC) and any one of many different negatively charged lipids such as gangliosides, phosphatidylserine (PS), phosphatidylglycerol, dicetyl phosphate, PI, or PA. A negatively charged lipid is required since fusion does not occur with neutral liposomes containing PC and a neutral lipid such as globoside, sphingomyelin, or PE. Fusion of Sendai virus membranes with liposomes that contain PC and PS does not require Ca2+, so an anhydrous complex with Ca2+ or a Ca2+-induced lateral phase separation is not required although the possibility remains that viral binding causes a lateral phase separation. Sendai virus membranes can fuse with liposomes containing only PS, so a packing defect between domains of two different lipids is not required. The concentration of PS required for fusion to occur is approximately 10-fold higher than that required for ganglioside GD1a, which has been shown to act as a Sendai virus receptor. When cholesterol is added as a third lipid to liposomes containing PC and GD1a, the amount of fusion decreases if the GD1a concentration is low.(ABSTRACT TRUNCATED AT 250 WORDS)     

Membrane vesicles containing the Sendai virus binding glycoprotein, but not the viral fusion protein, fuse with phosphatidylserine liposomes at low pH

Membrane vesicles containing the Sendai virus hemagglutinin/neuraminidase (HN) glycoprotein were able to induce carboxyfluorescein (CF) release from loaded phosphatidylserine (PS) but not loaded phosphatidylcholine (PC) liposomes. Similarly, fluorescence dequenching was observed only when HN vesicles, bearing self-quenched N-(7-nitro-2,1,3-benzoxadiazol-4-yl)phosphatidylethanolamine (N-NBD-PE), were incubated with PS but not PC liposomes. Thus, fusion between Sendai virus HN glycoprotein vesicles and the negatively charged PS liposomes is suggested. Induction of CF release and fluorescence dequenching were not observed when Pronase-treated HN vesicles were incubated with the PS liposomes. On the other hand, the fusogenic activity of the HN vesicles was not inhibited by treatment with dithiothreitol (DTT) or phenylmethanesulfonyl fluoride (PMSF), both of which are known to inhibit the Sendai virus fusogenic activity. Fusion was highly dependent on the pH of the medium, being maximal after an incubation of 60-90 s at pH 4.0. Electron microscopy studies showed that incubation at pH 4.0 of the HN vesicles with PS liposomes, both of which are of an average diameter of 150 nm, resulted in the formation of large unilamellar vesicles, the average diameter of which reached 450 nm. The relevance of these observations to the mechanism of liposome-membrane and virus-membrane fusion is discussed.     

Kinetic modeling of Sendai virus fusion with PC-12 cells. Effect of pH and temperature on fusion and viral inactivation.

We have studied the fusion activity of Sendai virus, a lipid-enveloped paramyxovirus, towards a line of adherent cells designated PC-12. Fusion was monitored by the dequenching of octadecyl-rhodamine, a fluorescent non-exchangeable probe. The results were analysed with a mass action kinetic model which could explain and predict the kinetics of virus-cell fusion. When the temperature was lowered from 37 degrees C to 25 degrees C, a sharp inhibition of the fusion process was observed, probably reflecting a constraint in the movement of viral glycoproteins at low temperatures. The rate constants of adhesion and fusion were reduced 3.5-fold and 7-fold, respectively, as the temperature was lowered from 37 degrees C to 25 degrees C. The fusion process seemed essentially pH-independent, unlike the case of liposomes and erythrocyte ghosts. Preincubation of the virus in the absence of target cell membranes at neutral and alkaline pH (37 degrees C, 30 min) did not affect the fusion process. However, a similar preincubation of the virus at pH = 5.0 resulted in marked, though slow, inhibition in fusion with the fusion rate constant being reduced 8-fold. Viral preincubation for 5 min in the same acidic conditions yielded a mild inhibition of fusogenic activity, while preincubation in the cold (4 degrees C, 30 min) did not alter viral fusion activity. These acid-induced inhibitory effects could not be fully reversed by further viral preincubation at pH = 7.4 (37 degrees C, 30 min). Changes in internal pH as well as endocytic activity of PC-12 cells had small effect on the fusion process, thus indicating that Sendai virus fuses primarily with the plasma membranes.     

Parameters affecting low-pH-mediated fusion of liposomes with the plasma membrane of cells infected with influenza virus

Unilamellar liposomes can be fused at low pH with the plasma membrane of cells that express the hemagglutinin glycoprotein of influenza virus on their surface [van Meer, G., & Simons, K. (1983) J. Cell Biol. 97, 1365-1374]. Here, we have resolved this fusion process into two kinetically distinct steps. The first and more rapid step converts the bound liposome to a form that can no longer be released by neuraminidase. The second step is the actual membrane fusion as measured by the loss of resonance energy transfer between two liposomal fluorescent phospholipids, N-(7-nitro-2,1,3-benzoxadiazol-4-yl)dioleoylphosphatidylethanolami ne (N-NBD-PE) and N-(lissamine rhodamine B sulfonyl)dioleoylphosphatidylethanolamine (N-Rh-PE). In contrast to the first step, the rate of the second one was highly dependent on the liposomal lipid composition and the cell type used. The replacement of 50% of the phosphatidylcholine (PC) in egg PC-cholesterol liposomes by unsaturated phosphatidylethanolamine (PE) species increased the rate of fusion at least 2-fold. Of the PE-containing liposomes that were associated with Madin-Darby canine kidney (MDCK) cells after 30 s of fusion, 80% had actually fused with the plasma membrane. Fringe pattern fluorescence photobleaching experiments showed that after fusion a fraction of the cell-associated N-Rh-PE diffused laterally in the plasma membrane. Without fusion, the N-Rh-PE was completely immobile. Under optimal conditions, the mobile fractions were 65% on MDCK cells and 78% on baby hamster kidney cells. The mobility was acquired simultaneously with the dilution of the fluorescent phospholipids as measured from the loss of resonance energy transfer. The mobile fraction of N-Rh-PE on the cell surface can therefore be used as a second independent measure of actual membrane fusion. Finally, we observed that upon fusion up to 80% of the nonexchangeable liposome markers cholesterol [14C]oleate and glycerol tri[14C]oleate became accessible to cellular hydrolases. The results showed that this hydrolysis assay can also be used to monitor the second step of the fusion process.     

Mechanism of fusion of Sendai virus: role of hydrophobic interactions and mobility constraints of viral membrane proteins. Effects of polyethylene glycol

The mechanism of Sendai virus fusion was investigated by studying the effect of the dehydrating agent polyethylene glycol (PEG) on the interaction of the virus with erythrocyte membranes. The initial rate of virus fusion, monitored continuously by a fluorescence membrane fusion assay, increases approximately 5-fold in the presence of small amounts (4%, w/v) of PEG. The polymer did not trigger a massive nonspecific fusion event, as the limited number of virus particles that fuse per erythrocyte ghost remains unaltered. A mass action kinetic analysis reveals that the binding rate constant increases approximately 1.5-fold; however, the fusion rate constant is enhanced by about an order of magnitude. The results demonstrate that hydrophobic interaction forces dominate the actual fusion step of the virus. Below about 22 degrees C, the viral membrane proteins appear to be clustered, as revealed by temperature-dependent fluorescence measurements of fluorescently tagged viral proteins. Clustering is not modulated by the presence of PEG, and fusion at those conditions is not observed. It is concluded that in addition to hydrophobic interactions, constraints in the mobility of the viral membrane proteins codetermine the fusogenic capacity of the virus. Such constraints have to be relieved in order to allow the occurrence of the hydrophobic interactions. PEG primarily affects the surface properties of the viral membrane, including the properties of the membrane glycoproteins. We hypothesize that during virus-target membrane interaction but prior to the actual fusion reaction, the fusion protein may undergo a conformational change, triggered by an enhancement in hydrophobic environment, which accounts for the need to establish close, i.e. fusion-susceptible intermembrane contact between virus and target membrane.     

Kinetics of pH-dependent fusion between influenza virus and liposomes

The pH-dependent fusion between influenza virus and liposomes (large unilamellar vesicles) has been investigated as a model for the fusion step in the infectious entry of the virus into cells. Fusion was monitored continuously, with a fluorescence assay based on resonance energy transfer (RET) [Struck, D. K., Hoekstra, D., & Pagano, R. E. (1981) Biochemistry 20, 4093-4099], which allows an accurate quantitation of the fusion process. Evidence is presented indicating that the dilution of the RET probes from the liposomal bilayer into the viral membrane is not due to transfer of individual lipid molecules. The initial rate and final extent of the fusion reaction increase dramatically with decreasing pH, fusion being virtually complete within 1 min at pH 4.5-5.0. From experiments in which the ratio of virus to liposomes was varied, it is concluded that virus-liposome fusion products continue to fuse with liposomes, but not with virus. Fusion is most efficient with liposomes consisting of negatively charged phospholipids, while phosphatidylcholine and sphingomyelin are inhibitory. The reaction is completely blocked by an antiserum against the virus and inhibited by pretreatment of the virus with trypsin. The effect of proteolytic pretreatment at pH 7.4 is enhanced after preincubation of the virus at pH 5.0, consistent with the occurrence of a low pH induced, irreversible, conformational change in the viral fusion protein, the hemagglutinin (HA), exposing trypsin cleavage sites. When, after initiation of the fusion reaction at pH 5.0, the pH is readjusted to neutral, the process is arrested instantaneously, indicating that the low pH induced conformational change in the HA protein, in itself, is not sufficient to trigger fusion activity.     

Sendai virus membrane fusion: time course and effect of temperature, pH, calcium, and receptor concentration

The conditions that optimize Sendai virus membrane fusion with liposomes have been studied. No fusion occurs in the absence of ganglioside receptors. Maximum fusion occurs when the molar ratio of ganglioside GD1a to phospholipid is 0.02 or greater. The amount of fusion at 37 degrees C increases with time up to at least 6.5 h. The rate of fusion increases from the lowest temperature tested, 10 degrees C, to 40 degrees C. Above 43 degrees C the amount of fusion decreases because of thermal inactivation of the viral proteins. There is a broad pH maximum between pH 7.5 and pH 9.0. At both ends of the pH range the amount of fusion increases and exceeds that found in the physiologic pH range. Neither ethylenediaminetetraacetic acid nor Ca2+ changes the amount of membrane fusion. The optimal conditions for membrane fusion of Sendai virus membranes with liposomes are the same as the optimal conditions for fusion with host cells and with red blood cells. Since the liposomes contain no proteins, the optimal conditions for Sendai virus membrane fusion must be determined by the viral proteins and be mostly independent of the nature or presence of the host proteins.     

Glutathione inhibits replication and expression of viral proteins in cultured cells infected with Sendai virus.

Addition of reduced glutathione inhibited the production of Sendai virus in African green monkey kidney (AGMK) cells. This result could be accounted for by a direct action of GSH on viral replication. The inhibitory action was associated to an increase of the GSH intracellular level, while the host cell metabolism was unaffected. The antiviral effect was related to decrease and inactivation of the hemagglutinin-neuraminidase (HN) virus glycoprotein.     

Fusion of Sendai virions with phosphatidylcholine-cholesterol liposomes reflects the viral activity required for fusion with biological membranes

Sendai virus envelopes were reconstituted after solubilization of intact virions with either Triton X-100 or octylglucoside. Envelopes obtained from Triton X-100, but not from octylglucoside solubilized virions, were hemolytic and promoted cell-cell fusion. Fluorescence dequenching studies [using N-4-nitrobenzo-2-oxa-1,3-diazole phosphatidylethanolamine-bearing viral envelopes] revealed that both preparations fused with negatively charged phospholipids. Fusion with phosphatidylcholine (PC)/cholesterol (chol) liposomes was promoted only by the hemolytic viral envelopes. Fluorescence dequenching studies, using intact virions bearing octadecylrhodamine B chloride, revealed that intact virions fused with PC/chol as well as with negatively charged phospholipids. Only fusion with PC/chol liposomes was inhibited by phenylmethylsulfonyl fluoride and dithiothreitol, reagents which are known to block the viral ability to fuse with biological membranes.     

Association of ganglioside-protein conjugates into cell and Sendai virus. Requirement for the HN subunit in viral fusion

We have prepared several electron and light microscopic labels of epidermal growth factor (EGF) to analyse the morphologic features of its binding and internalization by cultured cells. These include a ferritin conjugate of EGF, a covalent conjugate of EGF and horseradish peroxidase (EGF-HRP), a colloidal gold marker system using EGF-HRP as a primary antigen, and a covalent complex of EGF with rhodamine-labelled lactalbumin. All of the light and electron microscopic labels showed similar patterns of binding. EGF initially bound to diffusely distributed cell surface receptors at 4 degrees C. The EGF-receptor complexes clustered into clathrin-coated pits on the cell surface only when the temperature was raised to 37 degrees C. In KB and Swiss 3T3 cells, this was followed by rapid internationalization into receptosomes, compartmentalization into the Golgi system, clustering in the clathrin-coated regions of the Golgi, and finally delivery into lysosomes from the Golgi. This general pathway was seen in Swiss 3T3 cells which have a low number of EGF receptors, KB cells which have a moderate number of receptors and A431 cells that have a high number of receptors. However, the ruffling activity induced in A431 cells by EGF produced some internalization through macropinosomes, making the pathway of entry more difficult to evaluate. Double label experiments showed that EGF is internalized together with alpha 2-macroglobulin and adenovirus particles. These data clarify the route of entry of EGF in different cell types using multiple labels, and shows that it enters cells through the same coated pit entry pathway as most other ligands previously examined.     

Role of heterologous and homologous glycoproteins in phenotypic mixing between Sendai virus and vesicular stomatitis virus.

Phenotypic mixing between Sendai virus and vesicular stomatitis virus (VSV) or the mutant VSV ts045 was studied. Conditions were optimized for double infection, as shown by immunofluorescence microscopy. Virions from double-infected cells were separated by sequential velocity and isopycnic gradient centrifugations. Two types of particles with mixed protein compositions were found. One type was VSV particles with Sendai virus spikes, i.e., phenotypically mixed particles. A second type was Sendai virus-VSV associations, which in plaque assays also behaved as phenotypically mixed particles. The ratio of VSV G protein to Sendai virus glycoproteins on the cell surface was varied, using the VSV mutant ts045 in double infections. Thus, different amounts of the VSV G protein were allowed to reach the cell surface at 32, 38, and 39 degrees C in Sendai virus-infected cells. However, a fixed number of Sendai virus spikes was always found in the ts045 virions. This represented 12 to 16% of the number of G proteins present in normal VSV. Furthermore, the yield of ts045 virions was radically reduced during double infection when the temperature was raised to block G-protein transport to the cell surface, suggesting that the Sendai virus glycoproteins were not able to compensate for G protein in budding. These results emphasize the role of the G protein in VSV assembly.     

Conformation and stability of Sendai virus fusion protein

The conformation and stability of Sendai virus fusion (F) protein were studied by circular dichroism spectroscopy, and the protein predictive models of Chou and Fasman and Robson and Suzuki were used to elucidate the secondary structure of Sendai virus F protein. The F protein conformation is predicted to contain 33% alpha-helix, 53% beta-sheet and 15% beta-turn by the Chou and Fasman model, and 30% alpha-helix, 55% beta-sheet, 9% beta-turn and 7% random coil by the Robson and Suzuki model. C.d. studies of F protein purified in the presence of the non-ionic detergent, n-octylglucoside, indicated the presence of 49% alpha-helix and 31% beta-sheet at pH 7.0, 54% alpha-helix and 28% beta-sheet at pH 9.0 and 50% alpha-helix and 23% beta-sheet at pH 5.4. A small change in conformation of the protein occurred when the pH was titrated from 7.0 to 5.4 and from 7.0 to 9.0 and a more pronounced conformational change occurred when the pH was changed from 9.0 to 5.4. The F protein in 0.2% n-octylglucoside was resistant to denaturation by 4 M guanidine hydrochloride, the reducing agent 20 mM mercaptoethanol, and to increases in temperature from 5 to 80 degrees C. Monoclonal anti-F protein antibody showed an increased binding to whole virus when the pH was changed from 7.0 to 9.0. The antibody binding was decreased when the pH was shifted from 9.0 to 5.4 Maximum haemolytic activity was observed with virus that was preincubated at pH 8.0.(ABSTRACT TRUNCATED AT 250 WORDS)     

Binding of HBs antigen to HeLa cells by use of reconstitution into liposomes and fusion by Sendai virus

Hepatitis B surface antigen (HBsAg) was reconstituted into liposomes composed of phosphatidylserin. An isolated membrane fraction of HeLa cells was mixed with the liposomes, then the liposomes were incubated with HeLa cells in the presence of Sendai virus. In this system the attachment of HBsAg to the cell surface was enhanced and became resistant to treatment with trypsin-EDTA. The presence of the HBsAg on the cell surface was revealed by immunoelectronmicroscopy. This technique may provide a model system for studying immunological reactions to HBsAg-bearing target cells in vitro.     

Role of metastability and acidic pH in membrane fusion by tick-borne encephalitis virus.

The envelope protein E of the flavivirus tick-borne encephalitis (TBE) virus is, like the alphavirus E1 protein, a class II viral fusion protein that differs structurally and probably mechanistically from class I viral fusion proteins. The surface of the native TBE virion is covered by an icosahedrally symmetrical network of E homodimers, which mediate low-pH-induced fusion in endosomes. At the pH of fusion, the E homodimers are irreversibly converted to a homotrimeric form, which we have found by intrinsic fluorescence measurements to be more stable than the native dimers. Thus, the TBE virus E protein is analogous to the prototypical class I fusion protein, the influenza virus hemagglutinin (HA), in that it is initially synthesized in a metastable state that is energetically poised to be converted to the fusogenic state by exposure to low pH. However, in contrast to what has been observed with influenza virus HA, this transition could not be triggered by input of heat energy alone and membrane fusion could be induced only when the virus was exposed to an acidic pH. In a previous study we showed that the dimer-to-trimer transition appears to be a two-step process involving a reversible dissociation of the dimer followed by an irreversible trimerization of the dissociated monomeric subunits. Because the dimer-monomer equilibrium in the first step apparently depends on the protonation state of E, the lack of availability of monomers for the trimerization step at neutral pH could explain why low pH is essential for fusion in spite of the metastability of the native E dimer.     

Sendai virus-erythrocyte membrane interaction: quantitative and kinetic analysis of viral binding, dissociation, and fusion.

A kinetic and quantitative analysis of the binding and fusion of Sendai virus with erythrocyte membranes was performed by using a membrane fusion assay based on the relief of fluorescence self-quenching. At 37 degrees C, the process of virus association displayed a half time of 2.5 min; at 4 degrees C, the half time was 3.0 min. The fraction of the viral dose which became cell associated was independent of the incubation temperature and increased with increasing target membrane concentration. On the average, one erythrocyte ghost can accommodate ca. 1,200 Sendai virus particles. The stability of viral attachment was sensitive to a shift in temperature: a fraction of the virions (ca. 30%), attached at 4 degrees C, rapidly (half time, ca. 2.5 min) eluted from the cell surface at 37 degrees C, irrespective of the presence of free virus in the medium. The elution can be attributed to a spontaneous, temperature-induced release, rather than to viral neuraminidase activity. Competition experiments with nonlabeled virus revealed that viruses destined to fuse do not exchange with free particles in the medium but rather bind in a rapid and irreversible manner. The fusion rate of Sendai virus was affected by the density of the virus particles on the cell surface and became restrained when more than 170 virus particles were attached per ghost. In principle, all virus particles added displayed fusion activity. However, at high virus-to-ghost ratios, only a fraction actually fused, indicating that a limited number of fusion sites exist on the erythrocyte membrane. We estimate that ca. 180 virus particles maximally can fuse with one erythrocyte ghost.     

Studies on the interaction of Sendai virus with liposomal membranes. Sendai virus-induced agglutination of liposomes containing glycophorin

Liposomes constituted with the major sialoglycoprotein of human erythrocytes, glycophorin, were used as models for studies on cell-virus interactions. Liposomes composed of egg yolk phosphatidylcholine, cholesterol and glycophorin were found to interact with the paramyxovirus HVJ to form aggregates. The aggregation process was temperature dependent: it was maximal at 0 degrees C and decreased with increase of the incubation temperature. The activity of viral neuraminidase is also temperature dependent, and it increases with increase of the incubation temperature; release of N-acetylneuraminic acid was negligible at 0 degrees C. Shift-up of the incubation temperature immediately cancelled HVJ-induced agglutination of liposomes. Viruses attached to liposomes seemed to be released into the supernatant when the 'virus-liposome' complex formed at 0 degrees C was incubated at 37 degrees C, possibly as a result of breakdown of the 'binding' site by neuraminidase. The characteristics of the interaction of HVJ with liposomes containing glycophorin appeared to be phenomenologically similar to those of HVJ-cell interaction.     

Structure of Sendai viral proteins in plasma membranes of virus-infected cells.

Purified plasma membranes attached to polycationic polyacrylamide beads by their external surface were isolated from BHK cells infected with Sendai virus. Each of the viral proteins could be identified in the membranes of infected cells. Proteolysis with trypsin, which digests only the cytoplasmic surface of these membranes (because the external surface is protected by its attachment to beads), revealed that the internal proteins, L, P, NP, and M, were present on the cytoplasmic surface of the membrane and that small segments of the viral envelope glycoproteins, HN and F0, were partially exposed on the cytoplasmic surface. Since the major portions of HN and F0 are known to be present on the external membrane surface, these glycoproteins are transmembrane proteins before Sendai virus budding in infected cells.     

Mass action analysis of kinetics and extent of fusion between Sendai virus and phospholipid vesicles

The kinetics and extent of fusion between Sendai virus particles and liposomes were investigated with an assay for lipid mixing based on the relief of self-quenching of fluorescence. The measurements, which were carried out at pH 7.4 and 5.0, included liposomes of three compositions, cardiolipin (CL), CL/dioleoylphosphatidylcholine (CL/DOPC 1:1), and phosphatidylserine (PS). Liposomal lipid concentrations varied from 2.5 to 50 microM. In addition, the effect of low concentrations of the dehydrating agent poly(ethylene glycol) (PEG) on fusion between the virus and the liposomes at pH 7.4 was studied. The results were analyzed in terms of a mass action kinetic model which views the overall fusion reaction as a sequence of a second-order process of virus-liposome adhesion or aggregation, followed by the first-order fusion reaction itself. The fusion products were shown to consist of a single virus particle and several liposomes. Analytical solutions were found for the final extent of fusion and increase in fluorescence intensity following the fusion of fluorescently labeled virus particles with liposomes. The final extents of fluorescence intensity were explained by assuming an essentially irreversible binding of liposomes to inactive virus particles. The percents of active virus particles and the rate constants of fusion and aggregation were larger at pH 5 than at pH 7.4, increased when PEG was included in the medium, and varied with liposomal lipid composition according to the sequence CL greater than CL/DOPC greater than PS.(ABSTRACT TRUNCATED AT 250 WORDS)