Parameters affecting fusion between Sendai virus and liposomes. Role of viral proteins, liposome composition, and pH

A kinetic and quantitative characterization of the fusion process between Sendai virus and phospholipid vesicles is presented. Membrane fusion was monitored in a direct and continuous manner by employing an assay which relies on the relief of fluorescence self-quenching of the probe octadecylrhodamine B chloride which was located in the viral membrane. Viral fusion activity was strongly dependent on the vesicle lipid composition and was most efficient with vesicles solely consisting of acidic phospholipids, particularly cardiolipin (CL). This result implies that the fusion of viruses with liposomes does not display an absolute requirement for specific membrane receptors. Incorporation of phosphatidylcholine (PC), rather than phosphatidylethanolamine (PE), into CL bilayers strongly inhibited fusion, suggesting that repulsive hydration forces interfere with the close approach of viral and target membrane. Virus-liposome fusion products were capable of fusing with liposomes, but not with virus. In contrast to fusion with erythrocyte membranes, fusion between virus and acidic phospholipid vesicles was triggered immediately, did not strictly depend on viral protein conformation, and did not display a pH optimum around pH 7.5. On the other hand, with vesicles consisting of PC, PE, cholesterol, and the ganglioside GD1a, the virus resembled more closely the fusogenic properties that were seen with erythrocyte target membranes. Upon decreasing the pH below 5.0, the viral fusion activity increased dramatically. With acidic phospholipid vesicles, maximal activity was observed around pH 4.0, while with GD1a-containing zwitterionic vesicles the fusion activity continued to increase with decreasing pH down to values as low as 3.0.(ABSTRACT TRUNCATED AT 250 WORDS)     

Modification of cell membranes with viral envelopes during fusion of cells with HVJ (Sendai virus).

A large number of viral materials are associated with the surface of cells after cell fusion with HVJ at 37 °C for 30 min. This is due to fusion of viral envelopes with the cell membrane. Studies were made on the process from viral adsorption to cell-cell, or cell-viral envelope fusion. On incubation at low temperatures, such as 0–15 °C, no envelope fusion or cell fusion was observed, although there was some interaction between the virus and cells. This interaction resulted in loss of hemadsorption (HA) activity of the cells and partial damage of the ion barrier of the cell membrane. The viral particles seem to come close to the lipid layer of the cell membrane at the low temperatures and to distort the non-flexible membrane structure. On incubation of the cell-virus complex at 37 °C, the cells rapidly became HA-positive and the HA activity was maximal within 5 min. At this stage there was much leakage of ions through the cell membrane. On further incubation the damage to the ion barrier of the cell membrane was repaired completely with completion of cell fusion. This process may be correlated with fusion of viral envelopes with cell membranes and restoration of the cell membrane fused with them.     

Hemagglutinin-neuraminidase enhances F protein-mediated membrane fusion of reconstituted Sendai virus envelopes with cells.

Reconstituted Sendai virus envelopes containing both the fusion (F) protein and the hemagglutinin-neuraminidase (HN) (F,HN-virosomes) or only the F protein (F-virosomes) were prepared by solubilization of the intact virus with Triton X-100 followed by its removal by using SM2 Bio-Beads. Viral envelopes containing HN whose disulfide bonds were irreversibly reduced (HNred) were also prepared by treating the envelopes with dithiothreitol followed by dialysis (F,HNred-virosomes). Both F-virosomes and F,HNred-virosomes induced hemolysis of erythrocytes in the presence of wheat germ agglutinin, but the rates and extents were markedly lower than those for hemolysis induced by F,HN-virosomes. Using an assay based on the relief of self-quenching of a lipid probe incorporated in the Sendai virus envelopes, we demonstrate the fusion of both F,HN-virosomes and F-virosomes with cultured HepG2 cells containing the asialoglycoprotein receptor, which binds to a terminal galactose moiety of F. By desialylating the HepG2 cells, the entry mediated by HN-terminal sialic acid receptor interactions was bypassed. We show that both F-virosomes and F,HN-virosomes fuse with desialylated HepG2 cells, although the rate was two- to threefold higher if HN was included in the viral envelope. We also observed enhancement of fusion rates when both F and HN envelope proteins were attached to their specific receptors.     

Fluorescence photobleaching recovery as a method to quantitate viral envelope-cell fusion: application to study fusion of Sendai virus envelopes with cells

A method to quantitate viral envelope-cell fusion at the single-cell level is presented. The method is based on the incorporation of nonquenching concentrations of a fluorescent lipid probe into the viral envelope; fluorescence photobleaching recovery (FPR) is then applied to measure the lateral mobilization of the probe in the cell membrane following fusion. In adsorbed (unfused) viral envelopes, the probe is constricted to the envelope and is laterally immobile on the micrometer scale of FPR. After fusion, the envelope lipids intermix with the plasma membrane, the probe becomes laterally mobile, and the fraction of fused viral envelopes can be extracted from the fraction of mobile probe molecules. The method has several advantages: (i) It clearly distinguishes fused from internalized envelopes, as probes in the latter are immobile in FPR studies; (ii) focusing the laser beam on specific regions of the cell enables region-specific measurements of the fusion level; (iii) one cell is measured at a time, enabling studies on the distribution of the fusion level within the cell population. The new method was employed to study fusion of reconstituted Sendai virus envelopes (RSVE) containing N-(7-nitro-2,1,3-benzoxadiazol-4-yl)phosphatidylethanolamine with several cell types. Experiments with human erythrocytes demonstrated that the lateral mobilization measured is due to fusion and not the result of exchange processes. The extent of RSVE-erythrocyte fusion determined by FPR was similar to that measured by two other independent methods (fluorescence dequenching and removal of adsorbed RSVE by dithiothreitol).(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

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.     

Estimation by radiation inactivation of the size of functional units governing Sendai and influenza virus fusion

The target sizes associated with fusion and hemolysis carried out by Sendai virus envelope glycoproteins were determined by radiation inactivation analysis. The target size for influenza virus mediated fusion with erythrocyte ghosts at pH 5.0 was also determined for comparison; a value of 57 +/- 15 kDa was found, indistinguishable from that reported previously for influenza-mediated fusion of cardiolipin liposomes [Gibson, S., Jung, C. Y., Takahashi, M., & Lenard, J. (1986) Biochemistry 25, 6264-6268]. Sendai-mediated fusion with erythrocyte ghosts at pH 7.0 was likewise inactivated exponentially with increasing radiation dose, yielding a target size of 60 +/- 6 kDa, a value consistent with the molecular weight of a single F-protein molecule. The inactivation curve for Sendai-mediated fusion with cardiolipin liposomes at pH 7.0, however, was more complex. Assuming a "multiple target-single hit" model, the target consisted of 2-3 units of ca. 60 kDa each. A similar target was seen if the liposomes contained 10% gangliosides or if the reaction was measured at pH 5.0, suggesting that fusion occurred by the same mechanism at high and low pH. A target size of 261 +/- 48 kDa was found for Sendai-induced hemolysis, in contrast with influenza, which had a more complex target size for this activity (Gibson et al., 1986). Sendai virus fusion thus occurs by different mechanisms depending upon the nature of the target membrane, since it is mediated by different functional units. Hemolysis is mediated by a functional unit different from that associated with erythrocyte ghost fusion or with cardiolipin liposome fusion.     

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.     

Effect of chitooligosaccharide on neuronal differentiation of PC-12 cells

Chitosan is now being widely used biomaterial in the tissue engineering field, and has great potential as a candidate material for preparing nerve guidance conduits due to its various favorable properties, especially that of good nerve cell affinity. Chitosan can be degraded in vivo into chitooligosaccharide. We have investigated the in vitro effects of chitooligosaccharide on neuronal differentiation of PC-12 cells to see what effects chitooligosaccharide have on certain functions in the regenerating neurons. The morphologic observation and assessment using the specific reagent of tetrazolium salt WST-8 indicated that neurite outgrowths from PC-12 cells and the viability of PC-12 cells were enhanced by treatment of chitooligosaccharide. The real-time quantitative RT-PCR and Western blot analysis revealed showed that chitooligosaccharide could upregulate the expression of neurofilament-H mRNA or protein and N-cadherin protein in PC-12 cells. The maximum effect of 0.1 mg/ml chitooligosaccharide was obtained after 2 week culture. All the data suggest that chitooligosaccharide possesses good nerve cell affinity by supporting nerve cell adhesion and promoting neuronal differentiation and neurite outgrowth.     

Modification of cell membranes with viral envelopes during fusion of cells with HVJ (Sendai virus) : I. Interaction between cell membranes and virus in the early stage

A large number of viral materials are associated with the surface of cells after cell fusion with HVJ at 37 °C for 30 min. This is due to fusion of viral envelopes with the cell membrane. Studies were made on the process from viral adsorption to cell-cell, or cell-viral envelope fusion. On incubation at low temperatures, such as 0–15 °C, no envelope fusion or cell fusion was observed, although there was some interaction between the virus and cells. This interaction resulted in loss of hemadsorption (HA) activity of the cells and partial damage of the ion barrier of the cell membrane. The viral particles seem to come close to the lipid layer of the cell membrane at the low temperatures and to distort the non-flexible membrane structure. On incubation of the cell-virus complex at 37 °C, the cells rapidly became HA-positive and the HA activity was maximal within 5 min. At this stage there was much leakage of ions through the cell membrane. On further incubation the damage to the ion barrier of the cell membrane was repaired completely with completion of cell fusion. This process may be correlated with fusion of viral envelopes with cell membranes and restoration of the cell membrane fused with them.     

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)     

Instability of the viral M protein in BHK-21 cells persistently infected with Sendai virus

The study of viral protein expression in BHK cells persistently infected with Sendai virus showed that the viral M protein was greatly reduced in amount or absent in these cells. Pulse-chase experiments demonstrated that the M protein was synthesized at a normal rate, but was unstable compared to the other viral proteins. The M protein instability was independent of temperature and could account for part of the reduction in viral production by persistently infected cells. When a virus stock was grown in embryonated chicken eggs from viruses produced by persistently infected BHK cells, the M protein of this stock presented a restored stability in BHK cells.     

Effects of cytochalasin D on fusion of cells by HVJ (Sendai virus).

Fusion of cells mediated by HVJ was inhibited completely with 5 μg/ml or more of cytochalasin D (CD). With cytochalasin, HVJ-cell interaction at 0 °C proceeded as well as without cytochalasin; HVJ was adsorbed to cell surfaces and the cells agglutinated together. Then the virus particles were enfolded with cell membranes, which resulted in the disappearance of hemadsorption activity on the cell surfaces. When the cell-virus complex was incubated at 37 °C, the early reactions proceeded as well as without cytochalasin; the hemadsorption activity reappeared on the cell surfaces, the viral envelopes fused with cell membranes at the same degree as without cytochalasin, and a stage sensitive to sodium azide appeared as in a control without cytochalasin. But cell-to-cell fusion did not occur in the presence of cytochalasin; cells were dissociated freely from the cell aggregates during incubation. This indicates that cell-to-cell fusion was inhibited but HVJ envelope to cell membrane interactions proceeded well on incubation at 37 °C. These findings suggest that viral envelope-cell membrane fusion and cell-cell fusion are separable, and participation of a cytoskeleton system including microfilaments in the cells is essential for cell-cell fusion.     

Peptide inhibitors of enveloped virus infection inhibit phospholipid vesicle fusion and Sendai virus fusion with phospholipid vesicles

Small hydrophobic peptides that are capable of inhibiting Sendai virus infection of cells (Richardson, C. D., Scheid, A., and Choppin, P. W. (1980) Virology 105, 205-222) are also capable of inhibiting membrane fusion in a pure lipid vesicle system. Large unilamellar vesicles of N-methyl dioleoylphosphatidylethanolamine containing encapsulated 1-aminonaphthalene-3,6,8-trisulfonic acid and/or p-xylene bis (pyridinium bromide) were formed by extrusion. Vesicle fusion (contents mixing) and leakage were then monitored with the 1-aminonaphthalene-3,6,8-trisulfonic acid/p-xylene bis(pyridinium bromide) fluorescence assay. Sendai virus fusion with lipid vesicles was measured by following the relief of fluorescence quenching of virus labeled with octadecylrhodamine B chloride, a lipid mixing assay for fusion. The efficiency with which the peptides carbobenzoxy-D-Phe-L-PheGly, carbobenzoxy-L-Phe-L-Tyr, and carbobenz-oxy-Gly-L-Phe inhibit fusion of N-methyl dioleoyl-phosphatidylethanolamine large unilamellar vesicles directly paralleled their previously known effectiveness in blocking virus infectivity of cultured cells. In addition, above a certain concentration threshold, the inhibitory peptides decreased the initial rate of leakage from lipid vesicles. The inhibition by these peptides of virus-vesicle fusion followed the same order of potency as for vesicle-vesicle fusion. The observation of the same relative potency of these peptides toward inhibition of virus-cell infection, and virus-vesicle and vesicle-vesicle membrane fusion suggested that these peptides inhibited virus-cell infection by inhibiting the ability of the virus to fuse with the cell. Furthermore, these results suggest that the mechanism of inhibition of all three fusion events may have steps in common.     

Effects of low pH on influenza virus. Activation and inactivation of the membrane fusion capacity of the hemagglutinin

The hemagglutinin of influenza virus undergoes a conformational change at low pH, which results in exposure of a hydrophobic segment of the molecule, crucial to expression of viral fusion activity. We have studied the effects of incubation of the virus at low pH either at 37 or 0 degrees C. Treatment of the virus alone at pH 5.0 induces the virus particles to become hydrophobic, as assessed by measuring the binding of zwitterionic liposomes to the virus. At 37 degrees C this hydrophobicity is transient, electron microscopic examination of the virus reveals a highly disorganized spike layer, and fusion activity toward ganglioside-containing zwitterionic liposomes, measured at 37 degrees C with a kinetic fluorescence assay, is irreversibly lost. By contrast, after preincubation of the virus alone at pH 5.0 and 0 degrees C fusion activity remains unaffected. Yet, the preincubation at 0 degrees C does result in exposure of the hydrophobic segment of hemagglutinin, but now hydrophobicity is sustained and viral spike morphology unaltered. Hydrophobicity also remains to a significant extent upon pH neutralization, but fusion activity is negligible under these conditions. It is concluded that for optimal expression of fusion activity the virus must be bound to the target membrane before exposure to low pH. Furthermore, even after exposure of the hydrophobic segment of hemagglutinin, fusion occurs only at low pH. Finally, fusion occurs only at elevated temperature, possibly reflecting the unfolding of hemagglutinin trimers or the cooperative action of several hemagglutinin trimers in the reaction.     

Modification of cell membranes with viral envelopes during fusion of cells with HVJ (Sendai virus) : II. Effects of pretreatment with a small number of HVJ

Ehrlich ascites tumor cell membranes were completely modified after incubation at 37 °C for 30 min with a small dose of HVJ (about 0.7% of the maximum number of the virus particles that could be adsorbed onto the cells). After this treatment, the cells could adsorb further added HVJ onto their surfaces at 0 °C. But the cell agglutination which was induced by viral adsorption at 0 °C was very weak, and the interaction of the adsorbed virus with the lipid layer of the cell membrane at 37 °C preceding fusion or lysis of the cells was not strong. A discrepancy was observed between acquisition of the modification and liberation of sialic acid (destruction of viral receptors) by viral neuraminidase. The modification proceeded well on incubation at 37 °C but not at lower temperatures. The possibility that the modification is induced by fusion of viral envelopes with cell membranes is discussed.