Plasma membrane microdomains containing vesicular stomatitis virus M protein are separate from microdomains containing G protein and nucleocapsids

Immunogold electron microscopy and analysis were used to determine the organization of the major structural proteins of vesicular stomatitis virus (VSV) during virus assembly. We determined that matrix protein (M protein) partitions into plasma membrane microdomains in VSV-infected cells as well as in transfected cells expressing M protein. The sizes of the M-protein-containing microdomains outside the virus budding sites (50 to 100 nm) were smaller than those at sites of virus budding (approximately 560 nm). Glycoprotein (G protein) and M protein microdomains were not colocalized in the plasma membrane outside the virus budding sites, nor was M protein colocalized with microdomains containing the host protein CD4, which efficiently forms pseudotypes with VSV envelopes. These results suggest that separate membrane microdomains containing either viral or host proteins cluster or merge to form virus budding sites. We also determined whether G protein or M protein was colocalized with VSV nucleocapsid protein (N protein) outside the budding sites. Viral nucleocapsids were observed to cluster in regions of the cytoplasm close to the plasma membrane. Membrane-associated N protein was colocalized with G protein in regions of plasma membrane of approximately 600 nm. In contrast to the case for G protein, M protein was not colocalized with these areas of nucleocapsid accumulation. These results suggest a new model of virus assembly in which an interaction of VSV nucleocapsids with G-protein-containing microdomains is a precursor to the formation of viral budding sites.     

Membrane recognition by vesicular stomatitis virus involves enthalpy-driven protein-lipid interactions

Vesicular stomatitis virus (VSV) infection depends on the fusion of viral and cellular membranes, which is mediated by virus spike glycoprotein G at the acidic environment of the endosomal compartment. VSV G protein does not contain a hydrophobic amino acid sequence similar to the fusion peptides found among other viral glycoproteins, suggesting that membrane recognition occurs through an alternative mechanism. Here we studied the interaction between VSV G protein and liposomes of different phospholipid composition by force spectroscopy, isothermal titration calorimetry (ITC), and fluorescence spectroscopy. Force spectroscopy experiments revealed the requirement for negatively charged phospholipids for VSV binding to membranes, suggesting that this interaction is electrostatic in nature. In addition, ITC experiments showed that VSV binding to liposomes is an enthalpically driven process. Fluorescence data also showed the lack of VSV interaction with the vesicles as well as inhibition of VSV-induced membrane fusion at high ionic strength. Intrinsic fluorescence measurements showed that the extent of G protein conformational changes depends on the presence of phosphatidylserine (PS) on the target membrane. Although the increase in PS content did not change the binding profile, the rate of the fusion reaction was remarkably increased when the PS content was increased from 25 to 75%. On the basis of these data, we suggest that G protein binding to the target membrane essentially depends on electrostatic interactions, probably between positive charges on the protein surface and negatively charged phospholipids in the cellular membrane. In addition, the fusion is exothermic, indicating no entropic constraints to this process.     

Heterogeneity of vesicular stomatitis virus particles: implications for virion assembly

Vesicular stomatitis virus (VSV) particles formed at early times after infection contain only one-third the amount of viral glycoportein (G protein), relative to the major internal structural proteins M and N, as is found in particles released later. These "early" particles also have a lower density in equilibrium sucrose gradients than do those formed later; however, the sedimentation velocity and specific infectivity of these two classes of particles are the same. VSV-infected cells also release virus-like particles which sediment considerably faster than authentic virions and contain a higher-than-normal proportion of the VSV G protein relative to internal VSV proteins. These particles have a reduced specific infectivity but a normal density in sucrose gradients. All classes of VSV virions contain a constant proportion of M and N polypeptides. The ratio of G protein to M or N protein, in contrast, can vary over a sixfold range; this implies that an interaction between a precise number of surface G proteins with either of the underlying M and N proteins is not a prerequisite for budding of infectious viral particles from the cell surface.     

Vaccine entrapment in liposomes.

The use of liposomes as carriers of peptide, protein, and DNA vaccines requires simple, easy-to-scale-up technology capable of high-yield vaccine entrapment. Work from this laboratory has led to the development of techniques that can generate liposomes of various sizes, containing soluble antigens such as proteins and particulate antigens (e.g., killed or attenuated bacteria or viruses), as well as antigen-encoding DNA vaccines. Entrapment of vaccines is carried out by the dehydration-rehydration procedure which entails freeze-drying of a mixture of "empty" small unilamellar vesicles and free vaccines. On rehydration, the large multilamellar vesicles formed incorporate up to 90% or more of the vaccine used. When such liposomes are microfluidized in the presence of nonentrapped material, their size is reduced to about 100 nm in diameter, with much of the originally entrapped vaccine still associated with the vesicles. A similar technique applied for the entrapment of particulate antigens (e.g., Bacillus subtilis spores) consists of freeze-drying giant vesicles (4-5 microm in diameter) in the presence of spores. On rehydration and sucrose gradient fractionation of the suspension, up to 30% or more of the spores used are associated with generated giant liposomes of similar mean size.     

Antibody-independent neutralization of vesicular stomatitis virus by human complement. II. Formation of VSV-lipoprotein complexes in human serum and complement-dependent viral lysis.

Vesicular stomatitis virus (VSV) is efficiently neutralized by normal, nonimmune human serum without the participation of antibody. Neutralization is complement- (C) dependent and requires the early-acting components of the classical pathway, C1, C4, C2, and C3, but not later-acting C components. In further studies, normal human serum was found to markedly increase the density of a variable but significant proportion of virus-associated RNA and to markedly decrease the density of the remainder of virus-associated RNA. The RNA of increased density was found to be dense ribonucleocapsid cores released from VSV by C-dependent viral lysis mediated through the classical pathway. The released ribonucleocapsid cores found at the bottom of sucrose density gradient after incubation of VSV with human serum were resistant to degradation by proteolytic enzymes. The VSV-derived RNA found floating on the tops of sucrose density gradients performed on serum-treated VSV was infectious virus. The decreased density was due to binding of VSV to human serum lipoproteins (LP), primarily very low density lipoproteins (VLDL). Binding of VLDL to VSV required the presence of the viral envelope and the external glycoprotein, G. Despite the binding of LP to VSV, LP did not neutralize VSV, and LP-depleted sera were fully active in neutralizing VSV. Thus, LP do not represent an accessory factor for the C-dependent neutralization of VSV.     

Liposomes as Immunoadjuvants and Vaccine Carriers: Antigen Entrapment

Successful use of liposomes as immunological adjuvants in vaccines requires simple, easy to scale up technology capable of high-yield antigen entrapment. Recent work from this laboratory has led to the development of techniques that can generate liposomes of various sizes containing soluble antigens such as proteins or particulate antigens such as whole, live, or attenuated bacteria or viruses. Entrapment of proteins is carried out by the dehydration-rehydration procedure, which entails freeze-drying of a mixture of "empty" small unilamellar vesicles and free antigens. Upon rehydration, the large multilamellar vesicles that are formed incorporate up to 80% of the antigen used. When such liposomes are microfluidized in the presence of nonentrapped material, their size is reduced to about 100 nm in diameter, with much of the originally entrapped antigen still associated with the vesicles. A similar technique applied to the entrapment of particulate antigens (e.g., Bacillus subtilis spores) consists of freeze-drying giant vesicles (4-5 μm in diameter) in the presence of spores. On rehydration and sucrose gradient fractionation of the suspension, up to 27% of the spores used are associated with generated giant liposomes of similar mean size.     

Incorporation of the purified Epstein Barr virus/C3d receptor (CR2) into liposomes and demonstration of its dual ligand binding functions

The 145-kDa molecule that has been identified as the C3d receptor CR2 was isolated from lysates of Raji cells by affinity chromatography by using the monoclonal antibody (MoAb)HB-5. The purified protein was incorporated into 14C-phosphatidylcholine liposomes by deoxycholate dialysis followed by flotation on discontinuous sucrose gradients. Incorporation of the receptor was verified by testing the gradient fractions for CR2 by an enzyme-linked immunosorbent assay. Liposomes were shown to be unilamellar vesicles ranging in diameter from 25 to 100 nm by electron microscopy. The external orientation of CR2 in the membranes was demonstrated by immunoelectron microscopy. The functional activities of liposomes containing CR2 and liposomes without protein were compared. CR2 liposomes bound to EC3d, but not to E, and this binding was inhibited by the anti-CR2 MoAb OKB7 and by a MoAb specific for C3d. Control liposomes failed to bind to either E or EC3d. The ability of CR2 to function as a receptor for Epstein Barr virus (EBV) was tested in two ways. First, CR2 liposomes bound to B95-8, a cell line expressing EBV membrane antigens, but not to B95-8 cells treated with the viral DNA polymerase inhibitor phosphonoformic acid. Second, liposomes containing CR2 were shown by ultracentrifugal analyses to bind directly to purified EBV, and this binding was also inhibited by OKB7. Control liposomes did not bind to B95-8 cells or to EBV. These findings show that CR2 purified from detergent extracts of Raji cells can be reconstituted into lipid membranes with maintenance of its dual functions as a receptor for C3d and EBV.     

Biological, Physical, and Chemical Properties of Eastern Equine Encephalitis Virus I. Purification and Physical Properties

A new purification procedure was adopted for Eastern equine encephalitis virus which does not subject the virus to pelleting at any stage. Three- to 4-liter volumes were passed through a diethylaminoethyl cellulose column. The virus-containing fractions were banded on a sucrose cushion and finally concentrated in an isopycnic band in a linear sucrose gradient. This method reduced the volume 1,000-fold with a concomitant increase in viral titer, i.e., better than 90% recovery. Numerous criteria have been used to establish that this viral preparation was essentially free from cellular debris and nonviral material. Physical studies on this purified viral product were initiated. The sedimentation coefficient as determined by band sedimentation was 240S, the buoyant density in sucrose was 1.18 g/cc, and the diameter of the virus was 54 nm. From the diameter and the buoyant density it was possible to calculate the molecular weight of a spherical particle. In this case, the calculated molecular weight for Eastern equine encephalitis virus was 58 x 10(6) daltons.     

Pseudotypes of vesicular stomatitis virus with CD4 formed by clustering of membrane microdomains during budding

Many plasma membrane components are organized into detergent-resistant membrane microdomains referred to as lipid rafts. However, there is much less information about the organization of membrane components into microdomains outside of lipid rafts. Furthermore, there are few approaches to determine whether different membrane components are colocalized in microdomains as small as lipid rafts. We have previously described a new method of determining the extent of organization of proteins into membrane microdomains by analyzing the distribution of pairwise distances between immunogold particles in immunoelectron micrographs. We used this method to analyze the microdomains involved in the incorporation of the T-cell antigen CD4 into the envelope of vesicular stomatitis virus (VSV). In cells infected with a recombinant virus that expresses CD4 from the viral genome, both CD4 and the VSV envelope glycoprotein (G protein) were found in detergent-soluble (nonraft) membrane fractions. However, analysis of the distribution of CD4 and G protein in plasma membranes by immunoelectron microscopy showed that both were organized into membrane microdomains of similar sizes, approximately 100 to 150 nm. In regions of plasma membrane outside of virus budding sites, CD4 and G protein were present in separate membrane microdomains, as shown by double-label immunoelectron microscopy data. However, virus budding occurred from membrane microdomains that contained both G protein and CD4, and extended to approximately 300 nm, indicating that VSV pseudotype formation with CD4 occurs by clustering of G protein- and CD4-containing microdomains.     

Reconstituted G protein-lipid vesicles from vesicular stomatitis virus and their inhibition of VSV infection

The single glycoprotein (G) of vesiclar stomatitis virus (VSV) was isolated in nearly quantitative yield by extraction of the purified virions with 0.05 M octyl-β-D- glucoside (OG) in 0.01 M sodium phosphate, pH 8.0. The extract contained essentially all of the viral phospholipids and glycolipids, and was free of other essentially all of the viral phospholipids and glycolipids, and was free of other viral proteins. Dialysis to remove OG resulted in the formation of G protein-viral lipid vesicles having a lipid-G protein ratio similar to that of the intact virions. The vesicles were 250-1,000 A in diameter, with a “fuzzy” external layer also similar to that of intact virions. The vesicles were predominantly unilamellar and sealed, with both phosphatidyl ethanolamine and gangliosides symmetrically distributed in the bilayer. G protein was asymmetrically oriented, with about 80 percent accessible to exogenous protease. Addition of soybean phospholipid to the viral extract before dialysis resulted in vesicles that incorporated viral proteins and lipids quantitatively, but that were markedly decreased in buoyant density. The G neutralized protein-lipid vesicles were effective in eliciting specific anti-G antibodies that neutralized viral infectivity. Competitive radioimmunoassay showed that both reconstituted vesicles and a soluble form of G protein (Gs) were indistinguishable from purified VSV in their antibody binding properties. Addition of G protein-lipid vesicles of BHK-21 cells before, or simultaneously with, infection by VSV inhibited viral infectivity, as measured by two independent techniques (viral RNA production in the presence of actinomycin D and a neutral red assay of cell viability). The total inhibitory activity of G protein in the vesicular form was, however, less than 5 percent of that found for intact virus particles that have been inactivated by ultraviolet light irradiation. Gs was inactive as an inhibitor as determined by the RNA production assay.     

Functional reconstitution of the integral membrane proteins of influenza virus into phospholipid liposomes

The integral membrane proteins of influenza virus, a hemagglutinin and a neuraminidase, have been incorporated into liposomes composed of either phosphatidylcholine or a mixture of phosphatidylcholine and phosphatidylethanolamine (2:1 w/w) using detergent dialysis. The virus spike glycoproteins for reconstitution were selectively solubilized by using cetyltrimethylammonium bromide to leave a "core particle", which lacked a lipid bilayer but possessed quaternary structure as observed by electron microscopy. The viral spike proteins were combined with exogenous phospholipid in excess sodium cholate followed by exhaustive dialysis for 150 h. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed that only the viral glycoproteins were associated with all the complexes formed. The level of sodium cholate remaining after dialysis was shown to be reduced to less than 1 molecule per 80 protein molecules. Viral proteins reconstituted into dimyristoylphosphatidylcholine liposomes were shown to have retained hemagglutination, low-pH-dependent hemolysis, and neuraminidase activities and were associated with a lipid bilayer in two types of complexes with average lipid to protein mole ratios after sucrose density gradient purification of either 590:1 or 970:1. The bilayer vesicles formed were of similar sizes and were shown by negative-stain electron microscopy to be 150-300 nm in diameter with well-defined spikes on their surface. Reconstituted liposomes of dimyristoylphosphatidylcholine were found to be unstable with respect to their trapped volume and therefore were unsuitable for fusion studies, unlike complexes formed with phosphatidylcholine or a mixture of phosphatidylcholine/phosphatidylethanolamine derived from hen eggs.(ABSTRACT TRUNCATED AT 250 WORDS)     

Analysis of the role of p200-containing vesicles in post-Golgi traffic.

p200 is a cytoplasmic protein that associates with vesicles budding from the trans-golgi network (TGN). The protein was identified by a monoclonal antibody AD7. We have used this antibody to analyze whether p200 functions in exocytic transport from the TGN to the apical or basolateral plasma membrane in Madin-Darby canine kidney cells. We found that transport of the viral marker proteins, influenza hemagglutinin (HA) to the apical surface or vesicular stomatitis virus glycoprotein (VSV G) to the basolateral surface in streptolysin O-permeabilized cells was not affected when p200 was depleted from both the membranes and the cytosol. When vesicles isolated from perforated cells were analyzed by equilibrium density gradient centrifugation, the p200 immunoreactive membranes did not comigrate with either the apical vesicle marker HA or the basolateral vesicle marker VSV G. Immunoelectron microscopy of perforated and double-labeled cells showed that the p200 positive vesicular profiles were not labeled by antibodies to HA or VSV G when the viral proteins were accumulated in the TGN. Furthermore, the p200-decorated vesicles were more electron dense than those labeled with the viral antibodies. Together, these results suggest that p200 does not function in the transport pathways that carry HA from the TGN to the apical surface or VSV G from the TGN to the basolateral surface.     

Glycoprotein cytoplasmic domain sequences required for rescue of a vesicular stomatitis virus glycoprotein mutant.

We have used transient expression of the wild-type vesicular stomatitis virus (VSV) glycoprotein (G protein) from cloned cDNA to rescue a temperature-sensitive G protein mutant of VSV in cells at the nonpermissive temperature. Using cDNAs encoding G proteins with deletions in the normal 29-amino-acid cytoplasmic domain, we determined that the presence of either the membrane-proximal 9 amino acids or the membrane-distal 12 amino acids was sufficient for rescue of the temperature-sensitive mutant. G proteins with cytoplasmic domains derived from other cellular or viral G proteins did not rescue the mutant, nor did G proteins with one or three amino acids of the normal cytoplasmic domain. Rescue correlated directly with the ability of the G proteins to be incorporated into virus particles. This was shown by analysis of radiolabeled particles separated on sucrose gradients as well as by electron microscopy of rescued virus after immunogold labeling. Quantitation of surface expression showed that all of the mutated G proteins were expressed less efficiently on the cell surface than was wild-type G protein. However, we were able to correct for differences in rescue efficiency resulting from differences in the level of surface expression by reducing wild-type G protein expression to levels equivalent to those observed for the mutated G proteins. Our results provide evidence that at least a portion of the cytoplasmic domain is required for efficient assembly of the VSV G protein into virions during virus budding.     

Role of viral envelope sialic acid in membrane fusion mediated by the vesicular stomatitis virus envelope glycoprotein.

Fusion of vesicular stomatitis virus (VSV) with cells and liposomes before and after treatment with neuraminidase was studied using the R18 dequenching assay. Desialylation of VSV significantly enhanced the extent of fusion with Vero cells but affected neither the pH dependence nor the binding of VSV to Vero cells. The enhanced fusion of asialo-VSV was observed both at the plasma membrane as well as via the endocytic pathway. Both VSV and asialo-VSV fused with liposomes made of neutral phospholipid, but only asialo-VSV fused with liposomes containing a 1:1 mixture of neutral and negatively charged phospholipid. To examine factors which contribute to the extent of fusion, we analyzed the various activation and inactivation reactions that take place as a result of low-pH triggering of VSV prebound to the target membrane. Lag times for the onset of fusion were similar for VSV and asialo-VSV, indicating that desialylation did not affect the activation reactions. However, exposure of VSV bound to target membranes at pH 6.5 for 400 s led to considerable inactivation, whereas little inactivation was seen after desialylation of VSV. These results are analyzed in terms of a model which allows us to determine which components of the overall fusion process are dominated by viral envelope sialic acid.     

Insertion of the human immunodeficiency virus CD4 receptor into the envelope of vesicular stomatitis virus particles.

Enveloped virus particles carrying the human immunodeficiency virus (HIV) CD4 receptor may potentially be employed in a targeted antiviral approach. The mechanisms for efficient insertion and the requirements for the functionality of foreign glycoproteins within viral envelopes, however, have not been elucidated. Conditions for efficient insertion of foreign glycoproteins into the vesicular stomatitis virus (VSV) envelope were first established by inserting the wild-type envelope glycoprotein (G) of VSV expressed by a vaccinia virus recombinant. To determine whether the transmembrane and cytoplasmic portions of the VSV G protein were required for insertion of the HIV receptor, a chimeric CD4/G glycoprotein gene was constructed and a vaccinia virus recombinant which expresses the fused CD4/G gene was isolated. The chimeric CD4/G protein was functional as shown in a syncytium-forming assay in HeLa cells as demonstrated by coexpression with a vaccinia virus recombinant expressing the HIV envelope protein. The CD4/G protein was efficiently inserted into the envelope of VSV, and the virus particles retained their infectivity even after specific immunoprecipitation experiments with monoclonal anti-CD4 antibodies. Expression of the normal CD4 protein also led to insertion of the receptor into the envelope of VSV particles. The efficiency of CD4 insertion was similar to that of CD4/G, with approximately 60 molecules of CD4/G or CD4 per virus particle compared with 1,200 molecules of VSV G protein. Considering that (i) the amount of VSV G protein in the cell extract was fivefold higher than for either CD4 or CD4/G and (ii) VSV G protein is inserted as a trimer (CD4 is a monomer), the insertion of VSV G protein was not significantly preferred over CD4 or CD4/G, if at all. We conclude that the efficiency of CD4 or CD4/G insertion appears dependent on the concentration of the glycoprotein rather than on specific selection of these glycoproteins during viral assembly.     

Assembly of Plasmid DNA into Liposomes After Condensation by Cationic Lipid in Anionic Detergent Solution

A novel strategy to prepare negatively charged and small DNA-containing liposomes after condensation of plasmid DNA by a cationic lipid in deoxycholate micelle environment is described. The average diameter of resulting complexes was 62±8 nm. DNA-containing liposomes were then prepared by dialysis. The shape of the resulting liposomes was spherical. The average diameter and the surface charge of the liposomes were 86±6 nm and −24±3 mV, respectively. The plasmid DNA inside liposomes remained in a supercoiled form after incubation with DNase.     

Mechanisms of Ras Protein Targeting in Mammalian Cells

Syncollin is a 16-kDa protein that is associated with the luminal surface of the zymogen granule membrane in the pancreatic acinar cell. Detergent-solubilized, purified syncollin migrates on sucrose density gradients as a large (120-kDa) protein, suggesting that it exists naturally as a homo-oligomer. In this study, we investigated the structure of the syncollin oligomer. Chemical cross-linking of syncollin produced a ladder of bands, the sizes of which are consistent with discrete species from monomers up to hexamers. Electron microscopy of negatively stained syncollin revealed doughnut-shaped structures of outer diameter 10 nm and inner diameter 3 nm. Atomic force microscopy (AFM) of syncollin on mica supports at pH 7.6 showed particles of molecular volume 155 nm(3). Smaller particles were observed either at alkaline pH (11.0), or in the presence of a reducing agent (dithiothreitol), conditions that cause dissociation of the oligomer. AFM imaging of syncollin attached to supported lipid bilayers again revealed doughnut-shaped structures (outer diameter 31 nm, inner diameter 6 nm) protruding 1 nm from the bilayer. Finally, addition of syncollin to liposomes rendered them permeable to the water-soluble fluorescent probe 5(6)-carboxyfluorescein. These results are discussed in relation to the possible physiological role of syncollin.     

Evaluation of the high-pressure extrusion technique as a method for sizing plasmid DNA-containing cationic liposomes

A promising strategy to improve the immunogenic potential of DNA vaccines is the formulation of plasmid DNA (pDNA) with cationic liposomes. In this respect, particle size may be of crucial importance. This study aimed at the evaluation of high-pressure extrusion as a method for sizing cationic liposomes after entrapment of pDNA. This is a well-known sizing method for liposomes, but so far, it has not been applied for liposomes that are already loaded with pDNA. Liposomes composed of egg PC, DOTAP, and DOPE with entrapped pDNA were prepared by the dehydration-rehydration method and subjected to various extrusion cycles, comparing different membrane pore sizes and extrusion frequencies. At optimized extrusion conditions, liposome diameter (Zave) and polydispersity index (PDI) were reduced from 560 nm and 0.56-150 nm and 0.14 respectively, and 35% of the pDNA was retained. Importantly, gel electrophoresis and transfection experiments with pDNA extracted from these extruded liposomes demonstrated the preservation of the structural and functional integrity of the pDNA. The reduction in size resulted in enhanced transfection of HeLa cells, as detected by functional expression of the fluorescent protein, eGFP. In addition, these liposomes were able to stimulate Toll-like receptor 9, indicating efficient endosomal uptake and release of the included pDNA. In conclusion, high-pressure extrusion is a suitable technique to size cationic liposomes with entrapped pDNA and allows preparation of well-defined nanosized pDNA-liposomes, with preserved pDNA integrity. Their improved transfection efficiency and ability to activate an important pattern-recognition receptor are favorable properties for DNA vaccine delivery vehicles.