Attachment of Sendai virus particles to cell membranes: dissociation of adsorbed virus particles with dithiothreitol.

Sendai virus particles bind to human erythrocytes at 4 degrees C and fuse with them at 37 degrees C. The present work describes a new method by which adsorbed virus particles can be removed from human erythrocytes, allowing quantitative determination of the number of virus particles which can bind and fuse with human erythrocyte membranes. Through the use of 125I-labeled Sendai virus particles, it is shown that incubation with 50 mM dithiothreitol removed about 90 to 95% of adsorbed virus particles. Fused virus particles were resistant to treatment with dithiothreitol. Negligible amounts of 125I-labeled Sendai virus particles were removed by treatment with dithiothreitol after incubation of virus-cell complexes at 37 degrees C. Trypsinized virus particles were able to attach to, but not fuse with, human erythrocytes even after prolonged incubation at 37 degrees C. Treatment with dithiothreitol removed as much as 80 to 85% of trypsinized virus particles incubated with human erythrocytes at 37 degrees C. A quantitative determination revealed that about 1,000 to 1,200 and 600 to 800 Sendai virus particles can bind to or fuse with human erythrocytes, respectively.     

Kinetics and extent of fusion between Sendai virus and erythrocyte ghosts: application of a mass action kinetic model

The kinetics and extent of fusion between Sendai virus and erythrocyte ghosts were investigated with an assay for lipid mixing based on the relief of self-quenching of fluorescence. 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-cell adhesion followed by the first-order fusion reaction itself. The fluorescence development during the course of the fusion process was calculated by numerical integration, employing separate rate constants for the adhesion step and for the subsequent fusion reaction. Dissociation of virus particles from the cells was found to be of minor importance when fusion was initiated by mixing the particles at 37 degrees C. However, besides the initiation of fusion, extensive dissociation does occur after a preincubation of a concentrated suspension of particles at 4 degrees C followed by a transfer of the sample to 37 degrees C. The conclusion drawn from the levels of fluorescence increase obtained after 20 h of incubation is that in principle most virus particles can fuse with the ghosts at 37 degrees C and pH 7.4. However, the number of Sendai virus particles that actually fuse with a single ghost is limited to 100-200, despite the fact more than 1000 particles can bind to one cell. This finding may imply that 100-200 specific fusion sites for Sendai virus exist on the erythrocyte membrane. A simple equation can yield predictions for the final levels of fluorescence for a wide range of ratios of virus particles to ghosts.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Analysis of a Viral Agent Isolated from Multiple Sclerosis Brain Tissue: Characterization as a Parainfluenzavirus Type 1

A virus originally isolated from cell cultures obtained by lysolecithin-induced fusion of human multiple sclerosis brain cells with CV-1 cells has been analyzed for its antigenic, RNA, and polypeptide compositions, and for selective biological properties. Our findings establish that this isolate, designated 6/94 virus, contains a 50S RNA genome and is, as yet, indistinguishable from Sendai virus in its antigenic and total polypeptide compositions. Despite these similarities, the 6/94 and Sendai viruses differ in certain phenotypic properties. 6/94 virus is markedly less cytocidal for chick fibroblasts, especially at 37 C and, after beta-propiolactone inactivation, it possesses a greater capacity for cell fusion and a lower toxicity than does comparably treated Sendai virus. In addition, 6/94 virus shows greater hemolytic activity.     

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.     

Virus Meets Liposome

Abstract

Sendai virus was the first virus to encounter liposomes. Gangliosides when incorporated into liposomes act as Sendai virus receptors even at 0–4°C. When receptor-containing liposomes are incubated with virus at 37°C, they envelop the virus. At 37°C liposomes also fuse with Sendai virus membrane.

Virus binding initially involves weak adhesion, which may allow the virus to “browse” the cell, and which is followed by adhesion strengthening. MicrogrΔpHs of Sendai virus fusion with liposomes after one minute at 37°C indicate that fusion occurs at the very curved leading edge of the region of the liposome enveloping virus. A model of fusion is proposed that emphasizes the role of the curvature and membrane tension in this localized region of “host” membrane. The curvature assists close approach and destabilizes the outer monolayer. The proposed intermediates are consistent with the “stalk” hypothesis.     

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.     

Trifluoperazine inhibits Sendai virus-induced hemolysis

Sendai virus-induced hemolysis, a manifestation of virus-red cell fusion, is inhibited by exposure of the virus to 50 microM and higher concentrations of trifluoperazine. Trifluoperazine does not disrupt the virus, since trifluoperazine-treated virus with no hemolytic activity sediments slightly faster than untreated virus on sucrose density gradients and contains viral proteins in proportions characteristic of untreated virus. Trifluoperazine affects the fusion protein to a greater extent than the hemagglutinin, since trifluoperazine-treated virus with no hemolytic activity is as active or nearly as active in agglutinating red cells. The partition coefficient of trifluoperazine between the virus membrane and buffer is lower at 4 degrees C than, but the same at 37 degrees C, as that between the red cell membrane and buffer. Nevertheless, virus-independent red cell lysis and inactivation of virus-mediated hemolysis occur when the red cell and viral membranes, respectively, contain similar concentrations of trifluoperazine. Furthermore, 13-28% more trifluoperazine is necessary to achieve either effect at 4 degrees C or at 25 degrees C than at 37 degrees C. Changes in the surface activity of trifluoperazine do not explain these results, insofar as the critical micellar concentration of (0.75 mM) and maximal reduction in surface tension by (40 dyn/cm) trifluoperazine are the same at 25 degrees C and 37 degrees C. The fluorescence of viral tryptophan decreases by approx. 25% when viral hemolysis is inactivated by trifluoperazine, by trypsin treatment or by heating at 100 degrees C for 5 min.     

Fusion between Sendai virus envelopes and biological membranes as monitored by energy transfer methods

Chlorophyll a and chlorophyll b have been inserted into reconstituted envelopes of Sendai virus particles. Fluorescence measurements indicated a high efficiency of energy transfer between the two chlorophyll molecules due to their close proximity in the viral envelope. Fusion of reconstituted, pigmented virus envelopes with various biological cell membranes at 37 degrees C resulted in a significant decrease in the yield of energy transfer. Reduction in the efficiency of energy transfer was temperature and time dependent, and was also dependent upon the ratio between the reconstituted Sendai virus envelopes (donor) and recipient cells (acceptor). No reduction in the efficiency of energy transfer was observed when non-fusogenic, reconstituted viral envelopes were incubated with cell membranes.     

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.     

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.     

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.     

Immunoelectron microscopic study on interactions of noninfectious sendai virus and murine cells.

The early interactions of LLC-MK2 cell-grown noninfectious Sendai virus and a murine cell line, P815 mastocytoma ascitic cells, were studied by electron microscopy, using the ferritin-conjugated antibody technique with anti-virus glycoprotein serum. For comparison, the interactions of egg-grown infectious Sendai virus with the same cells were also examined. When noninfectious virus was adsorbed to the cells in the cold, the cell membranes become partially invaginated at the site of contact of adsorbed virions, but ferritin-conjugated antibodies did not penetrate into the areas of envelope-cell membrane association. This pattern of virus attachment was similar to that of infectious virus attachment. Upon subsequent incubation at 37 degrees C, most of the adsorbed noninfectious virions were taken into cytoplasmic vesicles and then degraded, although a few virions remained attached to the cell membrane. No evidence of fusion of envelopes of noninfectious virions was obtained. On the other hand, envelopes of infectious virions fused with the cell membrane, and the transferred viral antigens diffused on the cell surfaces and then decreased in number.     

The Sendai virus membrane fusion mechanism studied using image correlation spectroscopy.

The mechanism of Sendai virus membrane fusion to cultured cell membranes was studied. Viral lipids were labeled with the lipophilic dye, 4-(4-(dihexadecylamino)styryl-N-methylquinolinium iodine) (DiQ), and viral proteins were labeled using fluorescein isothiocyanate (FITC). The redistribution of these probes from the virus to cultured cells was followed using the technique of image correlation spectroscopy. This technique assayed the intensity change and the redistribution of these probes as fusion progressed from a more to less aggregated state. The lipid probe DiQ dispersed into the membrane of the target membrane at both 22 and 37 degrees C, while the FITC-labeled proteins dispersed only at 37 degrees C. Simultaneous labeling of virus with both of these probes showed that at 37 degrees C their redistribution proceeded at different rates. These data were consistent with the formation of a hemifusion intermediate during the fusion process.     

Oxygen uptake associated with Sendai-virus-stimulated chemiluminescence in rat thymocytes contains a significant non-mitochondrial component.

Sendai virus (150 haemagglutinating units/10(6) cells) stimulates rat thymocytes incubated in medium containing 5 mM-glucose at 37 degrees C to produce luminol-dependent chemiluminescence and a simultaneous increase in O2 consumption of 40%. Stimulation of thymocytes with Sendai virus is accompanied by reduction of exogenous acetylated ferricytochrome c, which is inhibited by superoxide dismutase, and the quantitative conversion of ferricyanide to ferrocyanide, which is not. Replacement of air in the gas space with N2 inhibits the chemiluminescent response by 97% but does not prevent the virus-stimulated reduction of ferricyanide. The non-permeant ferricyanide anion (2 mM) also inhibits the chemiluminescent response to Sendai virus, its accompanying 'extra' O2 uptake and the reduction of acetylated ferricytochrome c without affecting the basal respiration of the cells. Thymocytes in which the basal O2 consumption has been stimulated maximally with dinitrophenol (10 microM) or inhibited completely with antimycin A (0.1 microM) respond to Sendai virus with an additional increment of ferricyanide-inhibitable O2 consumption. The chemiluminescent response to virus is not inhibited by concentrations of antimycin A that block the basal respiration completely. We suggest that a portion of the increased O2 uptake induced by Sendai virus is involved in the non-mitochondrial reduction of O2 to O2- at the cell surface where the non-permeant ferricyanide anion inhibits O2-. formation by acting as an alternative high-affinity electron acceptor to O2.     

Sendai virus stimulates chemiluminescence in mouse spleen cells.

Sendai virus stimulates chemiluminescence within a few seconds after it is added to a suspension of mouse spleen cells. Virus rendered non infectious by irradiation with ultraviolet light induces a similar burst of chemiluminescence. Heating or pronase treatment of the virus abrogate this reaction, as does sonication of the cells before the addition of the virus. The ability of the virus to stimulate chemiluminescence is correlated with its hemagglutination, neuraminidase, cell fusion and hemolytic properties. It is suggested that Sendai virus-induced chemiluminescence is initiated by the interaction of the virus envelope spike glycoproteins with the cell membrane.     

Early changes in the membrane of HeLa cells adsorbing Sendai virus under conditions of fusion.

Adsorption of Sendai virus at high multiplicity (500-1,000 HAU/10(6) cells) to HeLa cells grown in monolayers causes immediate changes in the ion barrier of the cell membrane, as well as changes in the morphology of the virus-treated cells. Within minutes of adsorption the cells begin to lose potassium and an extensive influx of ions into the cells occurs. Concomitantly with these changes, the cell membrane becomes depolarized, and the resting potential across its membrane decreases. Twenty to sixty minutes post adsorption the damage to the cell membrane is repaired, and both the potassium uptake and the resting potential return to their pre-exposure values. Scanning electron-micrographs of Sendai infected cells incubated at 37 degrees C show formation of bridging microvilli in a zipper-like fashion within two to five minutes post-adsorption; 30 to 60 minutes thereafter the majority of cells in the monolayer are fused. Biochemical changes induced by virus adsorption and the role of Ca++ ions in the observed effects are discussed.     

Selective inactivation of the infectivity of freeze-dried Sendai virus by heat

The infectivity of freeze-dried Sendai virus was destroyed after heating at 100 ° C for 20 min while the hemagglutinin (HA) titer and the hemolytic (HL) activity were not affected. The HA titer was unaltered after heating at up to 140 ° C for 30 min. The HL activity was increased after freeze-drying, further increased after heating of freeze-dried virus at 115 ° C for 20 min, but was destroyed after heating for 30 min at 140 ° C.The selective heat inactivation of freeze-dried Sendai virus could be of use in the production of myxovirus vaccines and inactivated virus for cell-fusion studies.     

Expression of five proteins from the Sendai virus P/C mRNA in infected cells.

The polycistronic P/C mRNA of Sendai virus is translated under cell-free conditions into five proteins (P, C', C, Y1, and Y2) from overlapping reading frames. In this study, we showed that in addition to the P, C', and C proteins, Y1 and Y2 were expressed by six different Sendai virus strains in infected cells. The Y proteins exhibited strain-specific variation in their gel mobility which corresponds to the variation seen in the cognate C proteins. While the relative levels of the P, C', and C proteins were consistent among various cell lines, the levels of Y1 and Y2 proteins varied among the cell lines used for viral infection.     

Fusion of Sendai virus with vesicles of oligomerizable lipids: a microcalorimetric analysis of membrane fusion

Sendai virus fuses efficiently with small and large unilamellar vesicles of the lipid 1,2-di-n-hexadecyloxypropyl-4- (beta-nitrostyryl) phosphate (DHPBNS) at pH 7.4 and 37 degrees C, as shown by lipid mixing assays and electron microscopy. However, fusion is strongly inhibited by oligomerization of the head groups of DHPBNS in the bilayer vesicles. The enthalpy associated with fusion of Sendai virus with DHPBNS vesicles was measured by isothermal titration microcalorimetry, comparing titrations of Sendai virus into (i) solutions of DHPBNS vesicles (which fuse with the virus) and (ii) oligomerized DHPBNS vesicles (which do not fuse with the virus), respectively. The observed heat effect of fusion of Sendai virus with DHPBNS vesicles is strongly dependent on the buffer medium, reflecting a partial charge neutralization of the Sendai F and HN proteins upon insertion into the negatively-charged vesicle membrane. No buffer effect was observed for the titration of Sendai virus into oligomerized DHPBNS vesicles, indicating that inhibition of fusion is a result of inhibition of insertion of the fusion protein into the target membrane. Fusion of Sendai virus with DHPBNS vesicles is endothermic and entropy-driven. The positive enthalpy term is dominated by heat effects resulting from merging of the protein-rich viral envelope with the lipid vesicle bilayers rather than by the fusion of the viral with the vesicle bilayers per se.