Sendai virus envelope glycoproteins become laterally mobile on the surface of human erythrocytes following fusion

Gene transfection by quantitatively reconstituted Sendai envelope proteins into liposomes

Fusogenic liposomes (virosomes) consisting of Sendai virus envelope proteins have been utilized for in vitro and in vivo genetic modification of animal cells. In this study, the virosomes containing DNA were prepared by quantitative reconstitution of Sendai envelope proteins, fusion protein and hemagglutinin-neuramindase in liposomal vesicles. The Sendai virosomes more efficiently transferred genes into cultured 293 transformed kidney cells than 1,2-dioleoyl-3-(trimethylammonium) propane-based cationic liposomes. At 200:1 weight ratio of envelope protein and lipid, the virosomes exhibited the best efficiency of gene transfection into the cells. The Sendai virosomes required relatively a short period of incubation time and much less cytotoxic, compared to the cationic liposome/DNA complex. The transfection efficiency of the Sendai virosomes containing DNA was maintained 70% after a month. This type of Sendai virosomes is relatively convenient for preparation and storage, compared to fusogenic liposomes prepared by liposome-virus fusion. First of all, because the constituents are quantitatively formulated, this type of virosome formulation can provide further consistent transfection for gene therapy.

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.

Transforming growth factor-beta induces formation of a dithiothreitol-resistant type I/Type II receptor complex in live cells

Transforming growth factor-beta (TGF-beta) binds to and signals via two serine-threonine kinase receptors, the type I (TbetaRI) and type II (TbetaRII) receptors. We have used different and complementary techniques to study the physical nature and ligand dependence of the complex formed by TbetaRI and TbetaRII. Velocity centrifugation of endogenous receptors suggests that ligand-bound TbetaRI and TbetaRII form a heteromeric complex that is most likely a heterotetramer. Antibody-mediated immunofluorescence co-patching of epitope-tagged receptors provides the first evidence in live cells that TbetaRI. TbetaRII complex formation occurs at a low but measurable degree in the absence of ligand, increasing significantly after TGF-beta binding. In addition, we demonstrate that pretreatment of cells with dithiothreitol, which inhibits the binding of TGF-beta to TbetaRI, does not prevent formation of the TbetaRI.TbetaRII complex, but increases its sensitivity to detergent and prevents TGF-beta-activated TbetaRI from phosphorylating Smad3 in vitro. This indicates that either a specific conformation of the TbetaRI. TbetaRII complex, disrupted by dithiothreitol, or direct binding of TGF-beta to TbetaRI is required for signaling.

Oligomeric structure of type I and type II transforming growth factor beta receptors: homodimers form in the ER and persist at the plasma membrane

Transforming growth factor beta (TGF-beta) signaling involves interactions of at least two different receptors, types I (TbetaRI) and II (TbetaRII), which form ligand-mediated heteromeric complexes. Although we have shown in the past that TbetaRII in the absence of ligand is a homodimer on the cell surface, TbetaRI has not been similarly investigated, and the site of complex formation is not known for either receptor. Several studies have indicated that homomeric interactions are involved in TGF-beta signaling and regulation, emphasizing the importance of a detailed understanding of the homooligomerization of TbetaRI or TbetaRII. Here we have combined complementary approaches to study these homomeric interactions in both naturally expressing cell lines and cells cotransfected with various combinations of epitope-tagged type I or type II receptors. We used sedimentation velocity of metabolically labeled receptors on sucrose gradients to show that both TbetaRI and TbetaRII form homodimer-sized complexes in the endoplasmic reticulum, and we used coimmunoprecipitation studies to demonstrate the existence of type I homooligomers. Using a technique based on antibody-mediated immunofluorescence copatching of receptors carrying different epitope tags, we have demonstrated ligand-independent homodimers of TbetaRI on the surface of live cells. Soluble forms of both receptors are secreted as monomers, indicating that the ectodomains are not sufficient to mediate homodimerization, although TGF-beta1 is able to promote dimerization of the type II receptor ectodomain. These findings may have important implications for the regulation of TGF-beta signaling.

Partitioning of proteins into plasma membrane microdomains. Clustering of mutant influenza virus hemagglutinins into coated pits depends on the strength of the internalization signal

Internalization of membrane proteins involves their recruitment into plasma membrane clathrin-coated pits, with which they are thought to interact by binding to AP-2 adaptor protein complexes. To investigate the interactions of membrane proteins with coated pits at the cell surface, we applied image correlation spectroscopy to measure directly and quantitatively the clustering of influenza hemagglutinin (HA) protein mutants carrying specific cytoplasmic internalization signals. The HA system enables direct comparison between isolated internalization signals, because HA itself is excluded from coated pits. The studies presented here provide, for the first time, a direct quantitative measure for the degree of clustering of membrane proteins in coated pits at the cell surface. The degree of clustering depended on the strength of the internalization signal and on the integrity of the clathrin lattices and correlated with the internalization rates of the mutants. The clustering of the HA mutants fully correlated with their ability to co-precipitate alpha-adaptin from whole cells, the first such demonstration for a membrane protein that is not a member of the epidermal growth factor receptor family. Furthermore, both the clustering in coated pits and the co-precipitation with alpha-adaptin were dramatically reduced in the cold, suggesting that low temperature can interfere with the sorting of proteins into coated pits. In addition to the specific results reported here, the general applicability of the image correlation spectroscopy approach to study any process involving the clustering or oligomerization of membrane receptors at the cell surface is discussed.

Dynamic or stable interactions of influenza hemagglutinin mutants with coated pits. Dependence on the internalization signal but not on aggregation

Measurements of the lateral mobility of native and mutated membrane proteins, combined with treatments that alter clathrin lattice structure, are capable of characterizing their interactions with coated pits in live cells (Fire, E., Zwart, D. E., Roth, M. G., and Henis, Y. I. (1991) J. Cell Biol. 115, 1585-1594). To explore the dependence of these interactions on the internalization signal and the aggregation state of the protein, we have extended this approach to investigate the interactions between coated pits and several influenza hemagglutinin (HA) mutants, which differ in the internalization signals in their short cytoplasmic tails. The lack of internalization signals in the trimeric wild-type HA enables a direct comparison between specific internalization signals introduced singly in each mutant. We have selected for these studies HA mutants that showed different internalization rates and varied in their tendency to aggregate into complexes larger than trimers. Our results indicate that the mode of interaction with coated pits (transient association-dissociation versus stable entrapment) depends on the internalization signal and affects the internalization efficiency. Mutants that contain a strong internalization signal and undergo fast endocytosis were entrapped in coated pits for the entire duration of the lateral mobility measurement, suggesting stable association with (slow dissociation from) coated pits. A mutant with a suboptimal internalization signal, which was internalized 10-fold slower, exhibited transient interactions with coated pits. Both types of interactions disappeared or were significantly reduced upon disruption of the clathrin lattices under hypertonic conditions, and were modulated following the "freezing" of coated pits by cytosol acidification. Unlike the dependence on the cytoplasmic internalization signal, the interactions with coated pits did not depend on the aggregation state (measured by sucrose gradient centrifugation after solubilization in n-octylglucoside) of the mutants.

Roles for a cytoplasmic tyrosine and tyrosine kinase activity in the interactions of Neu receptors with coated pits

The neu proto-oncogene product, p185neu (HER2, c-ErbB-2), encodes a cell-surface tyrosine kinase receptor with high oncogenic potential, which correlates with increased tyrosine kinase activity and a rapid receptor internalization rate. To investigate the interactions and signal(s) leading to the endocytosis of Neu receptors, we employed lateral mobility and internalization studies. Fluorescence photobleaching recovery measurements revealed that activation of Neu receptors (induced by mutation or by agonistic antibodies) markedly reduced their mobile fractions. To elucidate the signals involved, other mutants, all carrying a constitutively dimerizing oncogenic mutation, were analyzed. A kinase-negative mutant and a mutant lacking all cytoplasmic tyrosine phosphorylation consensus sequences exhibited high mobile fractions, similar to nonactivated Neu. Retention of a single tyrosine autophosphorylation site (Tyr-1253) out of the five known such sites was sufficient to immobilize a large fraction of the receptor. For all mutants, internalization correlated with receptor immobilization and was blocked by treatments that interfere with coated pit structure, indicating that the immobilization is due to interactions with coated pits. This was supported by the coimmunoprecipitation of alpha-adaptin only with the constitutively activated Neu mutants. We conclude that activated Neu receptors become stably associated with coated pits via plasma membrane adaptor complexes (AP-2). Efficient Neu receptor endocytosis requires activation, a functional kinase domain, and at least one tyrosine autophosphorylation site.

The types II and III transforming growth factor-beta receptors form homo-oligomers

Affinity-labeling experiments have detected hetero-oligomers of the types I, II, and III transforming growth factor beta (TGF-beta) receptors which mediate intracellular signaling by TGF-beta, but the oligomeric state of the individual receptor types remains unknown. Here we use two types of experiments to show that a major portion of the receptor types II and III forms homo-oligomers both in the absence and presence of TGF-beta. Both experiments used COS-7 cells co-transfected with combinations of these receptors carrying different epitope tags at their extracellular termini. In immunoprecipitation experiments, radiolabeled TGF-beta was bound and cross-linked to cells co-expressing two differently tagged type II receptors. Sequential immunoprecipitations using anti-epitope monoclonal antibodies showed that type II TGF-beta receptors form homo-oligomers. In cells co-expressing epitope-tagged types II and III receptors, a low level of co-precipitation of the ligand-labeled receptors was observed, indicating that some hetero-oligomers of the types II and III receptors exist in the presence of ligand. Antibody-mediated cross-linking studies based on double-labeling immunofluorescence explored co-patching of the receptors at the cell surface on live cells. In cells co-expressing two differently tagged type II receptors or two differently tagged type III receptors, forcing one receptor into micropatches by IgG induced co-patching of the receptor carrying the other tag, labeled by noncross-linking monovalent Fab'. These studies showed that homo-oligomers of the types II and III receptors exist on the cell surface in the absence or presence of TGF-beta 1 or -beta 2. In cells co-expressing types II and III receptors, the amount of heterocomplexes at the cell surface was too low to be detected in the immunofluorescence co-patching experiments, confirming that hetero-oligomers of the types II and III receptors are minor and probably transient species.

Echinhibin-1--an inhibitor of Sendai virus isolated from the venom of the snake Echis coloratus

The snake venom of Echis coloratus was found to abolish the hemagglutinating activity, hemolytic activity and in vivo infectivity of Sendai virus. The active factor (Echinhibin-1) was purified by gel filtration on Sephadex G-50, followed by chromatography on DEAE-Sepharose and CM-Sepharose. Echinhibin-1 is a protease with a molecular weight of about 25 kDa, an isoelectric point of 7 and is stained by PAS, indicating that it is a glycoprotein. It showed a strong azocollase activity that was stable up to 68 degrees C and at pH values of 4.5-10.5. Ten micrograms/ml were sufficient to abolish the hemolytic effect of the virus on human erythrocytes when incubation was at 37 degrees C for 2 h, while 20 micrograms/ml abolished the hemagglutinating activity. Addition of Echinhibin-1 after the adsorption of Sendai virions onto washed erythrocytes at 4 degrees C did not inhibit the subsequently hemolytic activity at 37 degrees C, indicating that Echinhibin-1 interferes with virus adsorption to the cells. Of various protease inhibitors, only Na2 EDTA and o-phenanthroline inhibited the antiviral activity of the purified factor, indicating that it is a metalloproteinase. In vivo, mice inoculated intranasally with the virus pretreated with Echinhibin-1 developed well and gained weight, whereas untreated virus-infected mice lost weight and died within 1 week. Intravenous administrations of the purified factor up to 80 micrograms/mouse produced no signs of toxicity and subcutaneous injections caused no hemorrhagic activity, while the whole venom is very hemorrhagic with an LD50 of 250 micrograms/kg for mice.

Inhibition of Sendai virus by various snake venom

Viperid, elapid and crotalid snake venoms were screened in vitro for antiviral activity against Sendai virus. The hemolysis of 10(8) human erythrocytes in 1 ml, caused by 70 HAU of Sendai virus, was abolished when the virions were pretreated with 10 ug of the viperid venom of Echis coloratus, and was considerably diminished when pretreated with 10 ug of the venom of Echis carinatus sochureki, the cobra venoms of Naja atra and Naja nigricollis nigricollis. These venoms did not affect the erythrocytes but inhibited the virions themselves irreversibly. All other examined snake venoms had low or no antiviral activity. There was no correlation between the proteolytic and the antiviral activity of the venoms.

Evidence from lateral mobility studies for dynamic interactions of a mutant influenza hemagglutinin with coated pits

Replacement of cysteine at position 543 by tyrosine in the influenza virus hemagglutinin (HA) protein enables the endocytosis of the mutant protein (Tyr 543) through coated pits (Lazarovits, J., and M. G. Roth. 1988. Cell. 53:743-752). To investigate the interactions between Tyr 543 and the clathrin coats in the plasma membrane of live cells, we performed fluorescence photobleaching recovery measurements comparing the lateral mobilities of Tyr 543 (which enters coated pits) and wild-type HA (HA wt, which is excluded from coated pits), following their expression in CV-1 cells by SV-40 vectors. While both proteins exhibited the same high mobile fractions, the lateral diffusion rate of Tyr 543 was significantly slower than that of HA wt. Incubation of the cells in a sucrose-containing hypertonic medium, a treatment that disperses the membrane-associated coated pits, resulted in similar lateral mobilities for Tyr 543 and HA wt. These findings indicate that the lateral motion of Tyr 543 (but not of HA wt) is inhibited by transient interactions with coated pits (which are essentially immobile on the time scale of the lateral mobility measurements). Acidification of the cytoplasm by prepulsing the cells with NH4Cl (a treatment that arrests the pinching-off of coated vesicles from the plasma membrane and alters the clathrin lattice morphology) led to immobilization of a significant part of the Tyr 543 molecules, presumably due to their entrapment in coated pits for the entire duration of the lateral mobility measurement. Furthermore, in both untreated and cytosol-acidified cells, the restrictions on Tyr 543 mobility were less pronounced in the cold, suggesting that the mobility-restricting interactions are temperature dependent and become weaker at low temperatures. From these studies we conclude the following. (a) Lateral mobility measurements are capable of detecting interactions of transmembrane proteins with coated pits in intact cells. (b) The interactions of Tyr 543 with coated pits are dynamic, involving multiple entries of Tyr 543 molecules into and out of coated pits. (c) Alterations in the clathrin lattice structure can modulate the above interactions.

Cytochrome b5 and a recombinant protein containing the cytochrome b5 hydrophobic domain spontaneously associate with the plasma membranes of cells

Both cytochrome b5, isolated from rabbit liver microsomes, and LacZ:HP, a recombinant protein consisting of enzymatically active Escherichia coli beta-galactosidase coupled to the C-terminal membrane-anchoring hydrophobic domain of cytochrome b5, were shown to spontaneously associate with the plasma membranes of erythrocytes and 3T3 cells. Association was promoted by low pH values, but proceeded satisfactorily over several hours at physiological pH and temperature. About 150,000 cytochrome b5 molecules or 100,000 LacZ:HP molecules could be associated per erythrocyte. These proteins were not removed from the membrane by extensive washing, even at high ionic strength. After incubation with fluorescently labeled cytochrome b5 or LacZ:HP, cells displayed fluorescent membranes. The lateral mobility of fluorescently labeled cytochrome b5 and LacZ:HP was measured by photo-bleaching techniques. In the plasma membrane of erythrocytes and 3T3 cells, the apparent lateral diffusion coefficient D ranged from 1.0.10(-9) to 8.10(-9) cm2 s-1 with a mobile fraction M between 0.4 and 0.6. The lateral mobility of these proteins closely resembled that reported for lipid-anchored proteins and was much higher than that reported for Band 3, an erythrocyte membrane-spanning protein with a large cytoplasmic domain. These results suggest that the hydrophobic domain of cytochrome b5 could be employed as a universal, laterally mobile membrane anchor to associate a variety of diagnostically and therapeutically useful recombinant proteins with cells.

Oligomeric structure of the human asialoglycoprotein receptor: nature and stoichiometry of mutual complexes containing H1 and H2 polypeptides assessed by fluorescence photobleaching recovery

The interactions between H1 and H2, the two polypeptides comprising the human asialoglycoprotein receptor (ASGP-R), were investigated by immunofluorescence and lateral mobility measurements combined with antibody-mediated cross-linking and immobilization. Immunofluorescence microscopy revealed two ASGP-R populations on the cell surface, one homogeneously distributed and the other in micropatches. This was observed both in stably transfected NIH 3T3 lines expressing H1 and/or H2, and in the human hepatoma cell line HepG2. In transfected cells expressing both polypeptides (the 1-7-1 line), H1 and H2 were colocalized in the same micro aggregates. Moreover, enhancement of the patching of, e.g., H1 by IgG-mediated crosslinking was accompanied by copatching of H2. To quantify H1-H2 complex formation, the lateral diffusion of H1 and H2 was measured at 12 degrees C (to avoid internalization) by fluorescence photobleaching recovery. H1 (or H2) was immobilized by crosslinking with specific IgG molecules; the other chain was labeled with fluorescent monovalent Fab' fragments, and is lateral mobility was measured. In HepG2 cells, immobilization of either H1 or H2 led to an equal immobilization of the other, indicating that all the mobile H1 and H2 are in stable heterooligomers. In 1-7-1 cells, immobilization of H2 immobilized H1 to the same degree, but immobilization of H1 reduced the mobile fraction of H2 only by 2/3. Thus, in 1-7-1 cells all surface H1 molecules are associated with H2, but 1/3 of the H2 population is independent of H1. From these data and from measurements of the relative surface densities of H1 and H2, conclusions are drawn regarding the oligomeric structure and stoichiometry of the ASGP-R.

Digital fluorescence imaging of fusion of influenza virus with erythrocytes

Fusion of influenza virus with human erythrocytes at pH 5.2 was followed by fluorescence microscopy using a cooled slow-scan CCD camera. The high sensitivity of the CCD permits repetitive digital imaging of the same cells with minimal photobleaching. The experimental conditions were such that only a small number of virus particles were adsorbed per cell. Quantitative analysis of the data indicated that for most cells only a single fusion event took place. This was, however, sufficient to cause haemolysis within 30 min at 20-22 degrees C for about 60% of cells. There was a highly variable time lag between fusion and haemolysis. The lateral diffusion coefficient of virus particles on the cell surface when bound at pH 7.4 was less than 2 x 10(-13) cm2.s-1. The technique should be of value for more detailed studies of the dynamics of viral and other membrane fusion events.

Modification of membrane permeability by animal viruses

Animal viruses modify membrane permeability during lytic infection. There is a co-entry of macromolecules and virion particules during virus penetration and a drastic change in transport and membrane permeability at the late stages of the lytic cycle. Both events are of importance to understand different molecular aspects of viral infection, as virus entry into the cell and the interference of virus infection with cellular metabolism. Other methods of cell permeabilization of potential relevance to understand the mechanism of viral damage of the membrane are also discussed.

Effects of fusion temperature on the lateral mobility of Sendai virus glycoproteins in erythrocyte membranes and on cell fusion indicate that glycoprotein mobilization is required for cell fusion

In order to investigate the requirement for lateral mobilization of viral envelope glycoproteins on the cell surface in the induction of cell-cell fusion, we employed fluorescence photobleaching recovery to study the effect of the fusion temperature on the lateral mobilization of Sendai virus glycoproteins in the human erythrocyte membrane. As the fusion temperature was reduced below 37 degrees C (to 31 or 25 degrees C), the rates of virus-cell fusion, the accompanying hemolysis, and cell-cell fusion were all slowed down. However, the plateau (final level) after the completion of fusion was significantly reduced at lower fusion temperatures only in the case of cell-cell fusion, despite the rather similar final levels of virus-cell fusion. A concomitant decrease as a function of the fusion temperature was observed in the fraction of cell-associated viral glycoproteins that became laterally mobile in the erythrocyte membrane during fusion, and a strict correlation was found between the level of laterally mobile viral glycoproteins in the cell membrane and the final extent of cell-cell fusion. The accompanying reduction in the lateral diffusion coefficients (D) of the viral glycoproteins (1.4-fold at 31 degrees C and 1.9-fold at 25 degrees C, as compared to 37 degrees C) does not appear to determine the final level of cell-cell fusion, since fusing the cells with a higher amount of virions at 25 degrees C increased the final level of cell-cell fusion while D remained constant.(ABSTRACT TRUNCATED AT 250 WORDS)

Herpes simplex virus type 1 penetration initiates mobilization of cell surface proteins

Changes in membrane structure resulting from herpes simplex virus 1 (HSV-1) penetration were detected using fluorescence photobleaching recovery methods. The effect could be blocked by inhibitors of viral and cellular processes involved in virus penetration. A rapid mode of HSV-1 strain KOS penetration into VERO cells at 37 degrees C normally occurs after a 5 min lag period and is 90-95% complete within 20-30 min. Rates of cell surface protein diffusion increase 2-3-fold after 5 min and return to normal after 25-30 min, this return correlating temporally with the penetration of the virus. At pH 6.3 the lag period preceeding penetration of HSV is increased to 20 min and penetration proceeds much more slowly than at pH 7.4. Inhibition of virus penetration with cytochalasin B or with the antiherpes drug tromantadine also prevents the HSV-1-induced increase in cell surface protein mobility. Colchicine, which does not block HSV-1 penetration, prevents the recovery of the membrane following virus penetration. Therefore, the changes in membrane structure characterized by increased cell surface protein mobility seem to be caused by virus penetration. Cytoskeletal function and integrity are required for the initiation of, and cell recovery from, virus penetration. A pH-sensitive activity, likely to be a virion fusion glycoprotein, is also required.

Influenza virus-model membrane interaction. A morphological approach using modern cryotechniques

The membrane fusion activity of influenza virus was characterized morphologically using a model system composed of a highly purified influenza B virus suspension and ganglioside-containing zwitterionic liposomes. Electron microscopical analysis was performed after a combination of fast-freezing with either freeze-fracture or freeze-substitution-thin sectioning, ensuring maximal time resolution and avoiding preparation artifacts. In a parallel fluorescence 'lipid mixing' fusion assay, influenza virus-membrane fusion was characterized biochemically. Biochemical and morphological data are in full agreement, indicating negligible membrane fusion activity at neutral pH and high fusion activity at low pH. The freeze-fracture morphology strongly suggests a local point contact between viral and liposomal membrane at neutral pH, and a local point fusion mechanism for influenza virus-membrane fusion upon lowering of the pH. Fusion is followed by lipid mixing, lateral diffusion of viral spike proteins and exposure of viral contents at the inner liposomal surface.

Interaction of Sendai virions with resealed human erythrocyte ghosts. Lateral mobility of the viral glycoproteins in the cell membrane following fusion

Two independent methods demonstrated that resealed human erythrocyte ghosts undergo Sendai virus-mediated cell-cell fusion to a much lower degree (about 4%) than intact erythrocytes, in spite of similar levels of viral envelope-cell fusion in the two preparations. Fluorescence photobleaching recovery (FPR) showed similar lateral mobilities of the viral glycoproteins following fusion with either ghosts or whole erythrocytes. It is suggested that although viral glycoprotein mobilization in the cell membrane is essential for cell-cell fusion, the target cell properties are also important; in the absence of the required cellular parameters, the mobilization may not be a sufficient condition.

Fusion of native Sendai virions with human erythrocytes. Quantitation by fluorescence photobleaching recovery

We have recently developed a method to quantitate the fusion of reconstituted viral envelopes with cells by fluorescence photobleaching recovery (FPR) (Aroeti, B & Henis, Y I, Biochemistry 25 (1986) 4588). The method is based on the incorporation of non quenching concentrations of the fluorescent lipid probe N-(7-nitrobenz-2-oxa-1, 3-diazol-4-yl)phosphatidylethanolamine during the reconstitution of the viral envelopes (the latter probe does not incorporate efficiently into the membrane of native virions). In the present work, we employed the fluorescent dye octadecyl rhodamine B chloride (R18), which can be incorporated directly into the membrane of native enveloped virions, to extend the FPR method to study fusion between native Sendai virions and intact human erythrocytes. The R18 fluorescence was found to be quenched in the viral envelope at the concentration range required for the FPR experiments, possibly due to preferential insertion of the probe into specific domains in the viral membrane. We therefore developed a correction (presented in the Appendix) which takes into account the lower quantum yield of the probe molecules in the membranes of unfused virions in the calculation of the fraction of fused virions from the FPR experiments. The results demonstrate that the method does indeed measure virus-cell fusion, and that the contribution of exchange to the measurements is not significant. The applicability of the method was further verified by the similarity of the results to those obtained independently by fluorescence dequenching measurements, and its ability to measure the distribution of virus-cell fusion within the cell population was demonstrated. These results suggest that the use of R18 can enlarge the scope of the FPR experiments to study the fusion of native virions with cells.

A putative protein-sequestration site involving intermediate filaments for protein degradation by autophagy. Studies with transplanted Sendai-viral envelope proteins in HTC cells

Reconstituted Sendai-viral envelopes (RSVE) were fused with hepatoma tissue-culture (HTC) cells, thereby introducing viral membrane glycoproteins into the plasma membrane [Earl, Billett, Hunneyball & Mayer (1987) Biochem. J. 241, 801-807]. Fractionation of homogenized cells on Nycodenz gradients shows that much of the viral 125I-labelled HN and F proteins were rapidly sequestered into a dense fraction distinct from fractions containing plasma membrane, lysosomes and mitochondria. Electron microscopy (results not shown) indicates that the dense fraction contains nuclear residues, multivesicular structures, dense bodies and fibrous structures. Both the dense fraction and a hexosaminidase-enriched fraction contain trichloroacetic acid-insoluble radioactivity, including intact 125I-labelled viral proteins. The viral proteins are progressively transferred from the dense fraction to the hexosaminidase-enriched fraction; the transfer is retarded by 50 micrograms of leupeptin/ml. Trichloroacetic acid-soluble radiolabel is progressively released into the culture medium as the proteins are degraded. Within 5 h after transplantation of viral HN and F proteins into recipient cells, a proportion (approx. 45%) of the 125I-labelled glycoproteins cannot be extracted by sequentially treating cells with digitonin (1 mg/ml), Triton X-100 (1%, w/v) and 0.3 M-KI. HN and F proteins in the non-extractable residue are tightly associated with nuclear-intermediate-filament (vimentin) material, as shown by Western blots and electron microscopy. The viral proteins are progressively transferred out of the nuclear-intermediate-filament residue; the transfer is slowed when cells are cultured with leupeptin. The data are consistent with the notion that transplanted viral HN and F proteins are sequestered to a perinuclear site in tight association with intermediate filaments before transfer into the autophagolysosomal system for degradation.

Sendai-viral HN and F glycoproteins as probes of plasma-membrane protein catabolism in HTC cells. Studies with fusogenic reconstituted Sendai-viral envelopes

Reconstituted Sendai-viral envelopes (RSVE) were produced by the method of Vainstein, Hershkovitz, Israel & Loyter [(1984) Biochim. Biophys. Acta 773, 181-188]. RSVE are fusogenic unilamellar vesicles containing two transmembrane glycoproteins: the HN (haemagglutinin-neuraminidase) protein and the F (fusion) factor. The fate of the viral proteins after fusion-mediated transplantation of RSVE into hepatoma (HTC) cell plasma membranes was studied to probe plasma-membrane protein degradation. Both protein species are degraded at similar, relatively slow, rates (t1/2 = 67 h) in HTC cells fused with RSVE in suspension. Even slower degradation rates for HN and F proteins (t1/2 = 93 h) were measured when RSVE were fused with HTC cells in monolayer. Lysosomal degradation of the transplanted viral proteins is strongly implicated by the finding that degradation of HN and F proteins is sensitive to inhibition by 10 mM-NH4Cl (81%) and by 50 micrograms of leupeptin/ml (70%).

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)

The lateral mobility of cell membrane components is not altered following cell fusion induced by Sendai virus

The interaction of Sendai virus glycoproteins with cell membranes was proposed to increase the lateral mobility of membrane proteins, enabling membrane fusion and the aggregation of intramembrane particles by thermotropic separation (Volsky, DJ & Loyter, A, Biochim biophys acta 514 (1978) 213 [13]; Maeda, T et al. Exp cell res 123 (1979) 333 [15]; and Kim, J & Okada, Y, Exp cell res 132 (1981) 125 [44]). In order to test this hypothesis, we employed fluorescence photobleaching recovery to investigate the effects of Sendai virus-induced fusion on the lateral mobility of membrane proteins and lipids in a variety of cell types (human erythrocytes, BHK21, HeLa, 3T3 NIH, and mouse spleen lymphocytes). The results of the lateral diffusion measurements demonstrate that no significant alterations occur in the lateral motion of membrane proteins or a fluorescent phospholipid on all the cell types examined, including cells which revealed high susceptibility to the virally mediated fusion (human erythrocytes and BHK21 cells). These findings suggest that a permanent increase in the lateral mobility of cell surface components does not generally occur during Sendai virus-induced cell fusion, and thus cannot play a role in the fusion mechanism. The possible involvement of transient alterations in the lateral mobility of membrane components in the fusion mechanism is discussed.