Pseudotypes of vesicular stomatitis virus with the mixed coat of reticuloendotheliosis virus and vesicular stomatitis virus.

Vesicular stomatitis virus (VSV) forms pseudotypes with envelope components of reticuloendotheliosis virus (REV). The VSV pseudotype possesses the limited host range and antigenic properties of REV. Approximately 70% of the VSV, Indiana serotype, and 45% of VSV, New Jersey serotype, produced from the REV strain T-transformed chicken bone marrow cells contain mixed envelope components of both VSV and REV. VSV pseudotypes with mixed envelope antigens can be neutralized with excess amounts of either anti-VSV antiserum or anti-REV antiserum.     

Isolation of the envelope of vesicular stomatitis virus.

Vesicular stomatitis virus was disrupted by a combination of freezing and thawing, osmotic shock, and sonic treatment. Subviral components were separated by isopycnic centrifugation. The low-density, lipid-rich fractions were pooled and shown to contain primarily viral glycoprotein. Further purification of this material resulted in the isolation of a preparation of vesicles which contained only the G protein and the same phospholipids as in the intact virions and exhibited spikelike structures similar to those on intact vesicular stomatitis virions. We conclude that we have isolated fragments of native vesicular stomatitis virus envelopes.     

Stereo images of vesicular stomatitis virus assembly.

Viral assembly was studied by viewing platinum replicas of cytoplasmic and outer plasma membrane surfaces of baby hamster kidney cells infected with vesicular stomatitis virus. Replicas of the cytoplasmic surface of the basilar plasma membrane revealed nucleocapsids forming bullet-shaped tight helical coils. The apex of each viral nose cone was anchored to the membrane and was free of uncoiled nucleocapsid, whereas tortuous nucleocapsid was attached to the base of tightly coiled structures. Using immunoelectron microscopy, we identified the nucleocapsid (N) viral protein as a component of both the tight-coil and tortuous nucleocapsids, whereas the matrix (M) protein was found only on tortuous nucleocapsids. The M protein was not found on the membrane. Using immunoreagents specific for the viral glycoprotein (G protein), we found that the amount of G protein per virion varied. The G protein was consistently localized at the apex of viral buds, whereas the density of G protein on the shaft was equivalent to that in the surrounding membrane. These observations suggest that G-protein interaction with the nucleocapsid via its cytoplasmic domain may be necessary for the initiation of viral assembly. Once contact is established, nucleocapsid coiling proceeds with nose cone formation followed by formation of the helical cylinder. M protein may function to induce a nucleocapsid conformation favorable for coiling or may cross-link adjacent turns in the tight coil or both.     

Glycosylation sites of vesicular stomatitis virus glycoprotein.

Detailed analysis on DEAE-Sephadex of the tryptic digestion products of the glycoprotein from vesicular stomatitis virus grown in HeLa suspension cultures revealed the presence of two major and several minor sugar-labeled species. The minor tryptic glycopeptides were converted to one of the two major glycopeptide species by treatment with neuraminidase. Thus, vesicular stomatitis virus glycoprotein contains only two oligosaccharide side chains that are heterogeneous in their sialic acid content.     

Oligosaccharide moieties of the glycoprotein of vesicular stomatitis virus.

Vesicular stomatitis virus contains a single structural glycoprotein whose carbohydrate sequences are probably specified by the host cell. The glycopeptides derived by Pronase digestion of the glycoprotein of vesicular stomatitis virus grown in HeLa cells have an average molecular weight of 1,800. There are multiple oligosaccharide chains on the vesicular stomatitis virus glycoprotein with protein-carbohydrate linkages that are cleaved only by strong alkali under reducing conditions, suggesting that they contain asparagine and N-acetylglucosamine. The oligosaccharide moieties, in addition, appear to be heterogeneous in sequence on the basis of their mobilities during electrophoresis and their sensitivities to cleavage by an endoglycosidase. The carbohydrate-peptide linkage region of the major class of oligosaccharides of the vesicular stomatitis virus glycoprotein has the proposed sequence: (see article).     

Biologically active peptides of the vesicular stomatitis virus glycoprotein.

A peptide corresponding to the amino-terminal 25 amino acids of the mature vesicular stomatitis virus glycoprotein has recently been shown to be a pH-dependent hemolysin. In the present study, we analyzed smaller constituent peptides and found that the hemolytic domain resides within the six amino-terminal amino acids. Synthesis of variant peptides indicates that the amino-terminal lysine can be replaced by another positively charged amino acid (arginine) but that substitution with glutamic acid results in the total loss of the hemolytic function. Peptide-induced hemolysis was dependent upon buffer conditions and was inhibited when isotonicity was maintained with mannitol, sucrose, or raffinose. In sucrose, all hemolytic peptides were also observed to mediate hemagglutination. The large 25-amino acid peptide is also a pH-dependent cytotoxin for mammalian cells and appears to effect gross changes in cell permeability. Conservation of the amino terminus of vesicular stomatitis virus and rabies virus suggests that the membrane-destabilizing properties of this domain may be important for glycoprotein function.     

Reconstitution of the fusogenic activity of vesicular stomatitis virus.

Enveloped virus glycoproteins exhibit membrane fusion activity. We have analysed whether the G protein of vesicular stomatitis virus, reconstituted into liposomes, is able to fuse nucleated cells in a pH-dependent fashion. Proteoliposomes produced by octylglucoside dialysis did not exhibit cell fusion activity of the G protein. However, by making use of n-dodecyl octaethylene monoether (C12E8) as the solubilizing agent and by removal of the detergent in two steps, we were able to produce fusogenic G protein liposomes. These G protein liposomes fuse to the BHK-21 cell surface at pH 5.7-6.0 with an efficiency of fusion comparable with that of the parent virus. Physical and chemical analysis revealed that the fusogenic liposomes exhibited a protein to lipid weight ratio of 0.67 and showed an average diameter of 130 nm.     

Association of polyadenylic acid with messenger RNA of vesicular stomatitis virus

Polyadenylate (poly(A)) sequences are associated with the 28 S and 13–15 S messenger RNA species of vesicular stomatitis virus. These sequences contain approximately 125 to 150 nucleotides. Virion RNA contains little or no poly(A) sequences. The association of poly(A) with viral messenger RNA species and the gross distribution of poly(A) among these species remain unaltered even when the RNA is synthesized in the presence of cordycepin or cycloheximide and whether viral messenger RNA is polyribosome-bound or free. Also, when viral translation is completely inhibited by superinfection with poliovirus, there is no effect on poly(A) association with the messenger RNA of vesicular stomatitis virus.     

Biophysical studies of vesicular stomatitis virus

McCombs, Robert M. (Baylor University College of Medicine, Houston, Tex.), Matilda Benyesh-Melnick, and Jean P. Brunschwig. Biophysical studies of vesicular stomatitis virus: J. Bacteriol. 91:803-812. 1966.-The infectivity and morphology of vesicular stomatitis virus (VSV) were studied after density gradient centrifugation in cesium chloride (CsCI), potassium tartrate (KT), and sucrose. Centrifugation in CsCl revealed two equally infectious bands corresponding to densities of 1.19 and 1.22 g/ml, and a third (density, 1.26 g/ml) band of low infectivity. Two bands (densities of 1.16 and 1.18 g/ml) were observed in the KT gradient, in which the lighter band contained most of the infectivity. Centrifugation in sucrose resulted in a single broad infectious band (density, 1.16 g/ml). The typical rod-shaped VSV particles were found mainly in the lighter bands obtained in CsCl (1.19 g/ml) and KT (1.16 g/ml) and in the single sucrose gradient band (1.16 g/ml). Bent particles equally as infectious as the rod-shaped particles were a constant finding in the CsCl preparations, and were observed mainly in the second band (density, 1.19 g). Numerous strands 15mmu wide were found in the third CsCl (density, 1.26 g/ml) and the second KT (1.18 g/ml) bands. Similar strands could be liberated from VSV particles after treatment with deoxycholate. Internal transverse striations were found to be a regular feature of VSV particles examined with the pseudoreplication negative-staining technique. For crude virus stocks, the physical particle-to-infectivity ratio ranged from 73 to 194. Several morphological similarities between VSV and myxoviruses were observed, including 10 mmu surface projections, pleomorphic morphological forms, and 15 mmu seemingly nucleoprotein strands.     

A fusion-defective mutant of the vesicular stomatitis virus glycoprotein.

We have recently described an assay in which a temperature-sensitive mutant of vesicular stomatitis virus (VSV; mutant tsO45), encoding a glycoprotein that is not transported to the cell surface, can be rescued by expression of wild-type VSV glycoproteins from cDNA (M. Whitt, L. Chong, and J. Rose, J. Virol. 63:3569-3578, 1989). Here we examined the ability of mutant G proteins to rescue tsO45. We found that one mutant protein (QN-1) having an additional N-linked oligosaccharide at amino acid 117 in the extracellular domain was incorporated into VSV virions but that the virions containing this glycoprotein were not infectious. Further analysis showed that virus particles containing the mutant protein would bind to cells and were endocytosed with kinetics identical to those of virions rescued with wild-type G protein. We also found that QN-1 lacked the normal membrane fusion activity characteristic of wild-type G protein. The absence of fusion activity appears to explain lack of particle infectivity. The proximity of the new glycosylation site to a sequence of 19 uncharged amino acids (residues 118 to 136) that is conserved in the glycoproteins of the two VSV serotypes suggests that this region may be involved in membrane fusion. The mutant glycoprotein also interferes strongly with rescue of virus by wild-type G protein. The strong interference may result from formation of heterotrimers that lack fusion activity.     

Extreme heterogeneity in populations of vesicular stomatitis virus.

Vesicular stomatitis virus (VSV) sequence evolution and population heterogeneity were examined by T1 oligonucleotide mapping. Individual clones isolated from clonal pools of wild-type Indiana serotype VSV displayed identical T1 maps. This was observed even after one passage at high concentrations of the potent viral mutagen 5-fluorouracil. Under low-multiplicity passage conditions, the consensus T1 fingerprint of this virus remained unchanged after 523 passages. Interestingly, however, individual clones from this population (passage 523) differed significantly from each other and from consensus sequence. When virus population equilibria were disrupted by high-multiplicity passage (in which defective interfering particle interference is maximized) or passage in the presence of mutagenic levels of 5-fluorouracil, rapid consensus sequence evolution occurred and extreme population heterogeneity was observed (with some members of these population differing from others at hundreds of genome positions). A limited sampling of clones at one stage during high-multiplicity passages suggested the presence of at least several distinct master sequences, the related subpopulations of which exhibit at least transient competitive fitness within the total virus population (M. Eigen and C.K. Biebricher, p. 211-245, in E. Domingo, J.J. Holland, P. Ahlquist, ed., RNA Genetics, vol. 3, 1988). These studies further demonstrate the important role of selective pressure in determining the genetic composition of RNA virus populations. This is true under equilibrium conditions in which little consensus sequence evolution is observed owing to stabilizing selection as well as under conditions in which selective pressure is driving rapid RNA virus genome evolution.     

Sub-cellular localization of vesicular stomatitis virus messenger RNAs.

Vesicular stomatitis virus (VSV) messenger RNAs (mRNAs) appear to be compartmentalized within the infected HeLa cells. Analysis by polyacrylamide gel electrophoresis in formamide of the RNA associated with the membrane bound polyribosomes from VSV-infected cytoplasmic extracts shows predominantly one size class of VSV mRNA, which is absent from the remaining cytoplasm. These results are consistent with the mRNA for the viral glycoprotein being exclusively associated with membrane bound polysomes since the latter have been shown to synthesize mainly the virion glycoprotein in an $\text{in vitro}$ translation system.