Fusion of Sendai virions or reconstituted Sendai virus envelopes with liposomes or erythrocyte membranes lacking virus receptors

Incubation of intact Sendai virions or reconstituted Sendai virus envelopes with phosphatidylcholine/cholesterol liposomes at 37 degrees C results in virus-liposome fusion. Neither the liposome nor the virus content was released from the fusion product, indicating a nonleaky fusion process. Only liposomes possessing virus receptors, namely sialoglycolipids or sialoglycoproteins, became leaky upon interaction with Sendai virions. Fusion between the virus envelopes and phosphatidylcholine/cholesterol liposomes was absolutely dependent upon the presence of intact and active hemagglutinin/neuraminidase and fusion viral envelope glycoproteins. Fusion between Sendai virus envelopes and phosphatidylcholine/cholesterol liposomes lacking virus receptors was evident from the following results. Anti-Sendai virus antibody precipitated radiolabeled liposomes only after they had been incubated with fusogenic Sendai virions. Incubation of N-4-nitrobenzo-2-oxa-1,3-diazole-labeled fusogenic reconstituted Sendai virus particles with phosphatidylcholine/cholesterol liposomes resulted in fluorescence dequenching. Incubation of Tb3+-containing virus envelopes with phosphatidylcholine/cholesterol liposomes loaded with sodium dipicolinate resulted in the formation of the chelation complex Tb3+-dipicolinic acid, as was evident from fluorescence studies. Virus envelopes fuse efficiently also with neuraminidase/Pronase-treated erythrocyte membranes, i.e. virus receptor-depleted erythrocyte membranes, although fusion occurred only under hypotonic conditions.     

Reconstitution of functional influenza virus envelopes and fusion with membranes and liposomes lacking virus receptors.

Reconstituted influenza virus envelopes were obtained following solubilization of intact virions with Triton X-100. Quantitative determination revealed that the hemolytic and fusogenic activities of the envelopes prepared by the present method were close or identical to those expressed by intact virions. Hemolysis as well as virus-membrane fusion occurred only at low pH values, while both activities were negligible at neutral pH values. Fusion of intact virions as well as reconstituted envelopes with erythrocyte membranes--and also with liposomes--was determined by the use of fluorescently labeled viral envelopes and fluorescence dequenching measurements. Fusion with liposomes did not require the presence of specific virus receptors, namely sialoglycolipids. Under hypotonic conditions, influenza virions or their reconstituted envelopes were able to fuse with erythrocyte membranes from which virus receptors had been removed by treatment with neuraminidase and pronase. Inactivated intact virions or reconstituted envelopes, namely, envelopes treated with hydroxylamine or glutaraldehyde or incubated at low pH or 85 degrees C, neither caused hemolysis nor possessed fusogenic activity. Fluorescence dequenching measurements showed that only fusion with liposomes composed of neutral phospholipids and containing cholesterol reflected the viral fusogenic activity needed for infection.     

Sendai Virus Fusion Activity as Modulated by Target Membrane Components

We have studied the differences between erythrocytes and erythrocyte ghosts as target membranes for the study of Sendai virus fusion activity. Fusion was monitored continuously by fluorescence dequenching of R18-labeled virus. Experiments were carried out either with or without virus/target membrane prebinding. When Sendai virus was added directly to a erythrocyte/erythrocyte ghost suspension, fusion was always lower than that obtained when experiments were carried out with virus already bound to the erythrocyte/erythrocyte ghost in the cold, since with virus prebinding fusion can be triggered more rapidly. Although virus binding to both erythrocytes and erythrocyte ghosts was similar, fusion activity was much more pronounced when erythrocyte ghosts were used as target membranes. These observations indicate that intact erythrocytes and erythrocyte ghosts are not equivalent as target membranes for the study of Sendai virus fusion activity. Fusion of Sendai virus with both target membranes was inhibited when erythrocytes or erythrocyte ghosts were pretreated with proteinase K, suggesting a role of target membrane proteins in this process. Treatment of both target membranes with neuraminidase, which removes sialic acid residues (the biological receptors for Sendai virus) greatly reduced viral binding. Interestingly, this treatment had no significant effect on the fusion reaction itself.     

Animal viruses are able to fuse with prokaryotic cells. Fusion between Sendai or influenza virions and Mycoplasma

Sendai and influenza virions are able to fuse with mycoplasmata. Virus-Mycoplasma fusion was demonstrated by the use of fluorescently labeled intact virions and fluorescence dequenching, as well as by electron microscopy. A high degree of fusion was observed upon incubation of both virions with Mycoplasma gallisepticum or Mycoplasma capricolum. Significantly less virus-cell fusion was observed with Acholeplasma laidlawii, whose membrane contains relatively low amounts of cholesterol. The requirement of cholesterol for allowing virus-Mycoplasma fusion was also demonstrated by showing that a low degree of fusion was obtained with M. capricolum, whose cholesterol content was decreased by modifying its growth medium. Fluorescence dequenching was not observed by incubating unfusogenic virions with mycoplasmata. Sendai virions were rendered nonfusogenic by treatment with trypsin, phenylmethylsulfonyl fluoride, or dithiothreitol, whereas influenza virions were made nonfusogenic by treatment with glutaraldehyde, ammonium hydroxide, high temperatures, or incubation at low pH. Practically no fusion was observed using influenza virions bearing uncleaved hemagglutinin. Trypsinization of influenza virions bearing uncleaved hemagglutinin greatly stimulated their ability to fuse with Mycoplasma cells. Similarly to intact virus particles, also reconstituted virus envelopes, bearing the two viral glycoproteins, fused with M. capricolum. However, membrane vesicles, bearing only the viral binding (HN) or fusion (F) glycoproteins, failed to fuse with mycoplasmata. Fusion between animal enveloped virions and prokaryotic cells was thus demonstrated.     

Fusion of fluorescently labeled Sendai virus envelopes with living cultured cells as monitored by fluorescence dequenching

Fluorescently labeled (bearing N-4-nitrobenzo-2-oxa-1,3-diazole-phosphatidylethanolamine (N-NBD-PE)) reconstituted Sendai virus envelopes (RSVE) were used to study fusion between the viral envelopes and cultured living cells such as lymphoma, Friend erythroleukemia cells (FELC) and L cells. Incubation of fusogenic viruses with the above cell lines resulted in a relatively high degree (40-45%) of fluorescence dequenching. On the other hand, incubation of unfusogenic (trypsin or phenylmethylsulfonylfluoride (PMSF)-treated) RSVE with these cells led to very little (6-9%) fluorescence dequenching. The degree of fluorescence dequenching was linearly correlated to the surface density of the virus-inserted N-NBD-PE molecules. Fluorescence photobleaching recovery experiments showed that fusion of fluorescent RSVE with FELC resulted in an infinite dilution of the fluorescent molecules in the recipient cell membranes. The fluorescent probe 4-chloro-7-nitrobenzo-2-oxa-1,3-diazole (N-NBD-Cl) was covalently attached to envelopes of intact Sendai virions without significantly impairing their biological activity. Incubation of fluorescently labeled, intact Sendai virions with cultured cells resulted in about 20% fluorescence dequenching. The present data clearly indicate that fluorescently labeled Sendai virions can be used for a quantitative estimation of the degree of virus-membrane fusion.     

Fusion between Sendai virus envelopes and biological membranes. The use of fluorescent probes for quantitative estimation of virus-membrane fusion

The fluorescent probes, N-4-nitrobenzo-2-oxa-1,3-diazole-phosphatidylethanolamine and lissamine-rhodamine-B-sulfonylphosphatidylethanolamine, were inserted at the appropriate surface density into membranes of reconstituted Sendai virus envelopes, thus allowing transfer of energy between the fluorescent probes. In addition, only the fluorescent molecule N-4-nitrobenzo-2-oxa-1,3-diazole-phosphatidylethanolamine was inserted into the viral envelopes, resulting in self-quenching. Incubation of fluorescent, reconstituted Sendai virus envelopes with human erythrocyte ghosts resulted in either reduction in the efficiency of energy transfer or in fluorescence dequenching. No reduction in the efficiency of energy transfer or fluorescence dequenching was observed when fluorescent, reconstituted Sendai virus envelopes were incubated with glutaraldehyde-fixed or desialized human erythrocyte ghosts. Similarly, no change in the fluorescence value was observed when nonfusogenic, reconstituted Sendai virus envelopes were incubated with human erythrocyte ghosts. These results clearly show that reduction in the efficiency of energy transfer or dequenching is due to virus-membrane fusion and not to lipid-lipid exchange. Incubation of reconstituted Sendai virus envelopes, carrying inserted N-4-nitrobenzo-2-oxa-1,3-diazolephosphatidylethanolamine, with cultured cells also resulted in a significant and measurable dequenching. However, incubation of nonfusogenic, fluorescent reconstituted Sendai virus envelopes with hepatoma tissue culture cells also resulted in fluorescent dequenching, the degree of which was about 50% of that observed with fusogenic, fluorescent reconstituted viral envelopes. It is therefore possible that, in addition to virus-membrane fusion, endocytosis of fluorescent viral envelopes results in fluorescence dequenching as well.     

Quantitative determination of virus-membrane fusion events. Fusion of influenza virions with plasma membranes and membranes of endocytic vesicles in living cultured cells

Incubation of fluorescently labeled influenza virus particles with living cultured cells such as lymphoma S-49 cells or hepatoma tissue culture cells resulted in a relatively high degree of fluorescence dequenching. Increase in the degree of fluorescence (35-40% fluorescence dequenching) was observed following incubation at pH 5.0 as well as at pH 7.4. On the other hand, incubation of fluorescently labeled influenza virions with erythrocyte ghosts resulted in fluorescence dequenching only upon incubation at pH 5.0. Only a low degree of fluorescence dequenching was observed upon incubation with inactivated unfusogenic influenza or with hemagglutinino-influenza virions. The results of the present work clearly suggest that the fluorescence dequenching observed at pH 5.0 resulted from fusion with the cells' plasma membranes, while that at pH 7.4 was with the membranes of endocytic vacuoles following endocytosis of the virus particles. Our results show that only the fluorescence dequenching observed at pH 7.4--but not that obtained at pH 5.0--was inhibited by lysosomotropic agents such as methylamine and ammonium chloride, or inhibitors of endocytosis such as EDTA and NaN3.     

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.     

Fusion of membrane vesicles bearing only the influenza hemagglutinin with erythrocytes, living cultured cells, and liposomes

Membrane vesicles, bearing only the influenza viral hemagglutinin glycoprotein, were reconstituted following solubilization of intact virions with Triton X-100. The viral hemagglutinin glycoprotein was separated from the neuraminidase glycoprotein by agarose sulfanilic acid column. The hemagglutinin glycoprotein obtained was homogenous in gel electrophoresis and devoid of any neuraminidase activity. A quantitative determination revealed that the hemolytic activity of the hemagglutinin vesicles was comparable to that of intact virions. Incubation of fluorescently labeled hemagglutinin vesicles with human erythrocyte ghosts (HEG) or with liposomes composed of phosphatidylcholine/cholesterol or phosphatidylcholine/cholesterol/gangliosides, at pH 5.0 but not at pH 7.4, resulted in fluorescence dequenching. Very little, if any, fluorescence dequenching was observed upon incubation of fluorescently labeled HA vesicles with neuraminidase or glutaraldehyde-treated HEG or with liposomes composed only of phosphatidylcholine. Hemagglutinin vesicles were rendered non-hemolytic by treatment with NH2OH or glutaraldehyde or by incubation at 85 degrees C or low pH. No fluorescence dequenching was observed following incubation of non-hemolytic hemagglutinin vesicles with HEG or liposomes. These results clearly suggest that the fluorescence dequenching observed is due to fusion between the hemagglutinin vesicles and the recipient membranes. Incubation of hemagglutinin vesicles with living cultured cells, i.e. mouse lymphoma S-49 cells, at pH 5.0 as well as at pH 7.4, also resulted in fluorescence dequenching. The fluorescence dequenching observed at pH 7.4 was inhibited by lysosomotropic agents (methylamine and ammonium chloride) as well as by EDTA and NaN3, indicating that it is due to fusion of hemagglutinin vesicles taken into the cells by endocytosis.     

Fusogenic properties of reconstituted hybrid vesicles containing Sendai and influenza envelope glycoproteins: fluorescence dequenching and fluorescence microscopy studies

Co-reconstitution of influenza and Sendai virus phospholipids and glycoproteins resulted in the formation of membrane vesicles containing the envelope glycoproteins from both viruses within the same membrane. Reconstituted influenza-Sendai hybrids (RISH) were able to lyse human erythrocytes and fuse with their membranes or with living cultured cells at pH 5.0 as well as at pH 7.4, thus exhibiting the fusogenic properties of both viruses. This was also inferred from experiments showing that the fusogenic activity of RISH was inhibited by anti-influenza as well as by anti-Sendai virus antibodies. Fusion of FISH and of reconstituted influenza (RIVE) or reconstituted Sendai virus envelopes (RSVE) with recipient membranes was determined by the use of fluorescently labeled envelopes and fluorescence dequenching methods. Observations with the fluorescence microscope were used to study localization of fused reconstituted envelopes within living cells. Incubation of RISH and RSVE with living cells at pH 7.4 resulted in the appearance of fluorescence rings around the cell plasma membranes and of intracellular distinct fluorescent spots indicating fusion with cell plasma membranes and with membranes of endocytic vesicles, respectively. The fluorescence microscopy observations clearly showed that RIVE failed to fuse, at pH 7.4, with cultured cell plasma membranes, but fused with membranes of endocytic vesicles.     

Fusogenic properties of reconstituted hybrid vesicles containing Sendai and influenza envelope glycoproteins: fluorescence dequenching and fluorescence microscopy studies

Co-reconstitution of influenza and Sendai virus phospholipids and glycoproteins resulted in the formation of membrane vesicles containing the envelope glycoproteins from both viruses within the same membrane. Reconstituted influenza-Sendai hybrids (RISH) were able to lyse human erythrocytes and fuse with their membranes or with living cultured cells at pH 5.0 as well as at pH 7.4, thus exhibiting the fusogenic properties of both viruses. This was also inferred from experiments showing that the fusogenic activity of RISH was inhibited by anti-influenza as well as by anti-Sendai virus antibodies. Fusion of FISH and of reconstituted influenza (RIVE) or reconstituted Sendai virus envelopes (RSVE) with recipient membranes was determined by the use of fluorescently labeled envelopes and fluorescence dequenching methods. Observations with the fluorescence microscope were used to study localization of fused reconstituted envelopes within living cells. Incubation of RISH and RSVE with living cells at pH 7.4 resulted in the appearance of fluorescence rings around the cell plasma membranes and of intracellular distinct fluorescent spots indicating fusion with cell plasma membranes and with membranes of endocytic vesicles, respectively. The fluorescence microscopy observations clearly showed that RIVE failed to fuse, at pH 7.4, with cultured cell plasma membranes, but fused with membranes of endocytic vesicles.     

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.     

Fusion of Sendai virus with human HL-60 and CEM cells: different kinetics of fusion for two isolates.

The kinetics of fusion of Sendai virus (Z strain) with the human promyelocytic leukemia cell line HL-60, and the human T lymphocytic leukemia cell line CEM was investigated. Fusion was monitored by fluorescence dequenching of octadecylrhodamine (R-18) incorporated in the viral membrane. For one virus isolate (Z/G), the overall rate of fusion (at 37 degrees C) increased as the pH was lowered, reaching a maximum at about pH 5, the lowest pH tested. For another isolate (Z/SF) the rate and extent of fusion were lower at pH 5 than at neutral pH. Lowering the pH from neutral to 5 after several minutes of incubation of either isolate with HL-60 cells resulted in an enhanced rate of fluorescence dequenching. Nevertheless, experiments utilizing NH4Cl indicated that fusion of the virus with cells was not enhanced by the mildly acidic pH of the endosome lumen. Analysis of the kinetics of fusion by means of a mass action model resulted in good simulation and predictions for the time-course of fusion. For the isolate which showed maximal fusogenic activity at pH 5, the rate constant of fusion (approx. 0.1 s-1) at neutral pH was in the range found previously for virus-liposome fusion, whereas the rate constant of adhesion was close to the upper limit for diffusion-controlled processes (1.4.10(10) M-1 s-1). However, for the other isolate (Z/SF) the rate constant of fusion at neutral pH was very small (less than 0.01 s-1), whereas the rate constant of adhesion was larger (greater than or equal to 2.10(10) M-1 s-1). Lowering the temperature decreased the fusion rate. Experiments involving competition with excess unlabeled virions indicated that not all binding sites for Sendai virus on HL-60 cells are fusion sites. The virus fusion activity towards HL-60 cells at neutral pH was not altered significantly by pre-incubation of the virus at pH 5 or 9, in contrast to earlier observations with liposomes and erythrocyte ghosts, or results based on erythrocyte hemolysis or cell-cell fusion.     

Energy transfer measurements of fusion between Sendai virus and vesicles corrected for decreased absorption of acceptor probe

The fusion of Sendai virus at pH 4-7 with artificial lipid vesicles composed of phosphatidylserine or phosphatidylcholine was quantified by measuring fluorescence energy transfer from N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)-phosphatidylethanolamine to N-(lissamine-rhodamine-B-sulfonyl)-phosphatidylethanolamine in the target membranes. About 60% of the phosphatidylserine vesicles and virus appeared to fuse at pH 4 and about 100% at pH 5. Fusion was much less under all other conditions. The apparent fusion at pH 4, however, was due to a decrease in absorption of the acceptor probe, instead of dilution of acceptor as a result of fusion of labeled vesicles with unlabeled virus. After correction for this fusion-independent effect of Sendai virus, the extent of fusion was only 4-20% at pH 4 but still 80-100% at pH 5. These findings paralleled the loss of hemagglutinating and hemolytic activities of the virus induced by incubation at pH 4 but not at pH 5. Vesicle-virus hybrids were observed with the electron microscope after incubation at pH 5 but not at pH 7. The assay of membrane fusion by fluorescence energy transfer can be misleading unless correction is made for changes in energy transfer due to fusion-independent effects.     

Protein blot analysis of virus receptors: identification and characterization of the Sendai virus receptor

Receptors for Sendai virions in human erythrocyte ghost membranes were identified by virus overlay of protein blots. Among the various erythrocyte polypeptides, only glycophorin was able to bind Sendai virions effectively. The detection of Sendai virions bound to glycophorin was accomplished either by employing anti-Sendai virus antibodies or by autoradiography, when 125I-labeled Sendai virions were used. The binding activity was associated with the viral hemagglutinin/neuraminidase (HN) glycoprotein, as inferred from the observation that the binding pattern of purified HN glycoprotein to human erythrocyte membranes was identical to that of intact Sendai virions. No binding was observed when blots, containing either human erythrocyte membranes or purified glycophorin, were probed with the viral fusion factor (F glycoprotein). Active virions competed effectively with the binding of 125I-labeled Sendai virions (or purified HN glycoprotein), whereas no competition was observed with inactivated Sendai virus. The results of the present work clearly show that protein blotting can be used to identify virus receptors in cell membrane preparations.     

Characteristics of fusion of respiratory syncytial virus with HEp-2 cells as measured by R18 fluorescence dequenching assay.

The characteristics of fusion of respiratory syncytial virus (RSV) with HEp-2 cells were studied by the R18 fluorescence dequenching assay of membrane fusion. A gradual increase in fluorescence intensity indicative of virion-cell fusion was observed when R18-labeled RSV was incubated with HEp-2 cells. Approximately 35% dequenching of the probe fluorescence was observed in 1 h at 37 degrees C. Fusion showed a temperature dependence, with significant dequenching occurring above 18 degrees C. The dequenching was also dependent on the relative concentration of target membrane. Thus, increasing the concentration of target membrane resulted in increased levels of dequenching. In addition, viral glycoproteins were shown to be involved in this interaction, since dequenching was significantly reduced by pretreatment of labeled virus at 70 degrees C for 5 min or by trypsinization of R18-labeled virions prior to incubation with HEp-2 cells at 37 degrees C. The fusion of RSV with HEp-2 cells was unaffected over a pH range of 5.5 to 8.5, with some increase seen at lower pH values. Treatment of HEp-2 cells with ammonium chloride (20 and 10 mM), a lysosomotropic agent, during early stages of infection did not inhibit syncytium formation or progeny virion production by RSV. At the same concentrations of ammonium chloride, the production of vesicular stomatitis virus was reduced approximately 4 log10 units. These results suggest that fusion of the virus with the cell surface plasma membrane is the principal route of entry.     

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.     

The role of the target membrane structure in fusion with Sendai virus

Fusion between membranes of Sendai virus and liposomes or human erythrocytes ghosts was studied using an assay for lipid mixing based on the relief of self-quenching of octadecylrhodamine (R18) fluorescence. We considered only viral fusion that reflects the biological activity of the viral spike glycoproteins. The liposomes were made of phosphatidylcholine, and the effects of including cholesterol, the sialoglycolipid GD1a, and/or the sialoglycoprotein glycophorin as receptors were tested. Binding of Sendai virus to those liposomes at 37 degrees C was very weak. Fusion with the erythrocyte membranes occurred at a 30-fold faster rate than with the liposomes. Experiments with biological and liposomal targets of different size indicated that size did not account for differences in fusion efficiency.     

The Role of the Target Membrane Structure in Fusion with Sendai Virus

Fusion between membranes of Sendai virus and liposomes or human erythrocytes ghosts was studied using an assay for lipid mixing based on the relief of self-quenching of octadecylrhodamine (R18) fluorescence. We considered only viral fusion that reflects the biological activity of the viral spike glycoproteins. The liposomes were made of phosphatidylcholine, and the effects of including cholesterol, the sialoglycolipid GD1a, and/or the sialoglycoprotein glycophorin as receptors were tested. Binding of Sendai virus to those liposomes at 37 ?C was very weak. Fusion with the erythrocyte membranes occurred at a 30-fold faster rate than with the liposomes. Experiments with biological and liposomal targets of different size indicated that size did not account for differences in fusion efficiency.     

Quantitative measurement of fusion between human immunodeficiency virus and cultured cells using membrane fluorescence dequenching

Human immunodeficiency virus (HIV) was purified by sucrose gradient centrifugation and labeled with octadecylrhodamine B-chloride (R-18) under conditions resulting in 90% quenching of the fluorescence label. Incubation of R-18-labeled HIV (R-18/HIV) with CD4-positive CEM and HUT-102 cells, but not with CD4-negative MLA-144 cells, resulted in fluorescence dequenching (DQ, increase in fluorescence) of 20-25%. Similar level of DQ was observed upon incubation of CEM cells with R-18-labeled Sendai virus. DQ was observed when R-18/HIV was incubated with CD4+ cells at 37 degrees C, but not at 4 degrees C. Most of the increase in fluorescence occurred within 5 min of incubation at 37 degrees C and was independent of medium pH over the range of pH 5-8. Preincubation of cells with the lysosomotropic agent NH4Cl had no inhibitory effect on DQ. Complete inhibition was observed when target cells were fixed with glutaraldehyde prior to R-18/HIV addition. Our results demonstrate application of membrane fluorescence dequenching method to a quantitative measurement of fusion between HIV and target cell membranes. As determined by DQ, HIV penetrates into target cells by a rapid, pH-independent, receptor-mediated and specific process of fusion between viral envelope and cell plasma membrane, quite similar to that observed with Sendai virus.