Fluorescence studies of dipalmitoylphosphatidylcholine vesicles reconstituted with the glycoprotein of vesicular stomatitis virus

The vesicular stomatitis virus glycoprotein (G) was reconstituted into dipalmitoylphosphatidylcholine (DPPC) vesicles by detergent dialysis. The DPPC gel to liquid-crystalline phase transition of the DPPC-G protein vesicles was monitored by the fluorescence anisotrophy of trans-paranaric acid, 16-(9-anthroyloxy)palmitoylglucocerebroside, 1,6-diphenyl-1,3,5-hexatriene, and 4-heptadecyl-7-hydroxycoumarin. The DPPC transition temperature measured by all four fluorescent probes was lowered in the presence of the G protein and the DPPC gel state was disordered by the G protein as evidenced by a decreased fluorescence anisotropy for all four probes below the phase-transition temperature. A possible ordering of the DPPC liquid-crystalline state by the G protein was indicated by an increased anisotropy of trans-paranaric acid and 16-(9-anthroyloxy)palmitoylglucocerebroside in the liquid-crystalline state of DPPC-G protein vesicles. The G protein in addition affected the ionization of the 4-heptadecyl-7-hydroxycoumarin in lipid vesicles, increasing the apparent pK of the probe from 9.05 to 9.45.     

Cell-free fatty acylation of microsomal integrated and detergent-solubilized glycoprotein of vesicular stomatitis virus

An enzymatic activity associated with intracellular membrane fractions of Merwin plasma cell tumor II, baby hamster kidney, and chicken embryo fibroblast cells and bovine kidney has been characterized which covalently links fatty acids onto the G protein of vesicular stomatitis virus. Exogenous G protein extracted from native vesicular stomatitis virus particles can be acylated in vitro only after it has been previously deacylated. The fatty acids transferred in vitro are sensitive to treatment with hydroxylamine, indicating an ester linkage. Cell-free acyl transfer was also observed with endogenous G protein present in membrane fractions prepared from vesicular stomatitis virus-infected cells. In this case, the fatty acids become linked to a G protein species (G1) which is not terminally glycosylated and therefore has not entered the trans-Golgi compartment. The same G protein species also becomes acylated in infected cells during short pulses with radioactive palmitic acid. Acylation of the G protein in vitro with free palmitic or myristic acid is energy-dependent, and the addition of ATP is specifically required. Other nucleoside triphosphates cannot substitute for ATP in the activation of free acyl chains. Alternatively, activated fatty acids linked in a high energy thioester bond to coenzyme A, e.g. [14C] palmitoyl-CoA, are suitable lipid donors in the in vitro acylation reactions. Palmitic acid transfer onto G protein shows the typical characteristics of an enzyme-catalyzed reaction.     

Synthesis and assembly of membrane glycoproteins. Membrane anchoring COOH-terminal domain of vesicular stomatitis virus envelope glycoprotein G contains fatty acids

Two polypeptides associated with the envelope of vesicular stomatitis virus are obtained by exhaustive proteolytic digestion of the virion. Analysis of the tryptic peptides and determination of the partial amino acid sequence show that the larger membrane-anchoring peptide is derived from the hydrophobic COOH terminus of the viral transmembrane glycoprotein G. The smaller peptide is, however, derived from the nonglycosylated matrix protein M. Analysis of the membrane-anchoring peptide fragments obtained from virus labeled with [3H]palmitic acid shows that the larger peptide fragment contained all the fatty acid present in G, suggesting that the fatty acids in conjunction with the hydrophobic domain may be involved in the binding of G protein to the membrane.     

Nucleotide sequences of the mRNA''s encoding the vesicular stomatitis virus G and M proteins determined from cDNA clones containing the complete coding regions.

The complete nucleotide sequences of the vesicular stomatitis virus mRNA's encoding the glycoprotein (G) and the matrix protein (M) have been determined from cDNA clones that contain the complete coding sequences from each mRNA. The G protein mRNA is 1,665 nucleotides long, excluding polyadenylic acid, and encodes a protein of 511 amino acids including a signal peptide of 16 amino acids. G protein contains two large hydrophobic domains, one in the signal peptide and the other in the transmembrane segment near the COOH terminus. Two sites of glycosylation are predicted at amino acid residues 178 and 335. The close correspondence of the positions of these sites with the reported timing of the addition of the two oligosaccharides during synthesis of G suggests that glycosylation occurs as soon as the appropriate asparagine residues traverse the membrane of the rough endoplasmic reticulum. The mRNA encoding the vesicular stomatitis virus M protein is 831 nucleotides long, excluding polyadenylic acid, and encodes a protein of 229 amino acids. The predicted M protein sequence does not contain any long hydrophobic or nonpolar domains that might promote membrane association. The protein is rich in basic amino acids and contains a highly basic amino terminal domain. Details of construction of the nearly full-length cDNA clones are presented.     

Release of fatty acids from virus glycoproteins by hydroxylamine

The fatty acids bound to the glycoproteins of Sindbis and vesicular stomatitis viruses can be released by treating the protein with 1 M hydroxylamine at pH 8.0, but the rates of release vary greatly among the three proteins. The most labile fatty acyl bonds were in the Sindbis virus PE2/E2 proteins and the most stable were in the E1 protein. Some of the fatty acids in Sindbis virus glycoproteins were reduced to the alcohol after treatment with sodium borohydride, indicating that protein-bound fatty acids could be in thiolester linkage. Sindbis virus PE2/E2 has several cysteine residues near the carboxy terminus, a region of the protein postulated to be localized on the inside (cytoplasmic face) of the bilayer, and protease digestion of microsomal membranes containing E2 protein removed a small portion of this cytoplasmic tail as well as significant amounts of the fatty acid. For the vesicular stomatitis virus G protein, the sensitivity of fatty acid hydrolysis appeared to depend on the conformation of the protein and a significant fraction of G protein was converted to a disulfide-linked dimer by hydroxylamine. These data implicate cysteinyl groups on these proteins as sites involved in fatty acid acylation.     

Subunit interactions of vesicular stomatitis virus envelope glycoprotein stabilized by binding to viral matrix protein.

The mechanism by which viral glycoproteins are incorporated into virus envelopes during budding from host membranes is a major question of virus assembly. Evidence is presented here that the envelope glycoprotein (G protein) of vesicular stomatitis virus binds to the viral matrix protein (M protein) in vitro with the specificity, reversibility, and affinity necessary to account for virus assembly in vivo. The assay for the interaction is based on the ability of M protein to stabilize the interaction of G protein subunits, which exist as trimers of identical subunits in the virus envelope. The interaction with M protein was shown by using G proteins labeled with fluorescent probes capable of detecting subunit dissociation and reassociation in vitro. The results show that the M protein isolated from virions either as purified soluble protein or as nucleocapsid-M protein complexes interacts with the G protein in vitro and that the reaction is reversible. The interaction between the G and M proteins was not serotype specific, but no interaction between the vesicular stomatitis virus M protein and the influenza virus hemagglutinin could be detected. These results support the conclusion that the interactions described here are the ones that govern assembly of G protein into virus envelopes in vivo.     

Fatty acid binding to vesicular stomatitis virus glycoprotein: a new type of post-translational modification of the viral glycoprotein.

The glycoprotein (G) of vesicular stomatitis virus (VSV) binds 1–2 moles of fatty acid per mole of protein. The fatty acids cannot be released by repeated extractions of the protein with organic solvents, nor can they be released by denaturing the protein with ionic or nonionic detergents. Pronase digestion of G yields an organic extractable fragment that contains bound fatty acid. The fatty acid is quantitatively released from this fragment and from intact G by mild alkali treatment in methanol and is identified by gas-liquid and thin-layer chromatography as, predominantly, the methyl ester of palmitic acid. Insignificant amounts of phosphate are found in G, thus ruling out the presence of bound phospholipid. Chicken embryo fibroblast pre-labeled with ³H-palmitate and then infected with VSV for 4 hr show the presence of ³H label in G but not in other viral structural proteins. The ³H label is present only in the fatty acid moiety of the protein. Much smaller amounts of ³H fatty acid are bound to G protein formed by the VSV mutant ts045 grown at the nonpermissive temperature, and no ³H fatty acid is bound to G synthesized at 37°C in cells pretreated with tunicamycin, an inhibitor of glycosylation. However, infection with the VSV-Orsay strain at 30°C in the presence of tunicamycin allows for production of VSV particles with nonglycosylated G (Gibson, Schlesinger and Kornfeld, 1979), and this G has the same proportion of the fatty acid as does the normal glycosylated G. These data indicate that fatty acids become covalently attached to the G polypeptide chain during maturation of the protein—perhaps as the glycoprotein moves to the cell's plasma membrane.     

Translation of Vesicular Stomatitis Messenger RNA by Extracts from Mammalian and Plant Cells

RNA was isolated from polyribosomes of vesicular stomatitis virus (VSV)-infected cells and tested for its ability to direct protein synthesis in extracts of animal and plant cells. In cell-free, non-preincubated extracts of rabbit reticulocytes, the 28S VSV RNA stimulated synthesis of a protein the size of the vesicular stomatitis virus L protein whereas the 13 to 15S RNA directed synthesis of the VSV M, N, NS, and possibly G proteins. In wheat germ extracts, 13 to 15S RNA also directed synthesis of the N, NS, M, and possibly G proteins. Analysis of extracts labeled with formyl [(35)S]methionine showed that the 28S RNA directed the initiation of synthesis of one protein, whereas the 13 to 15S RNA directed initiation of at least four proteins. It is concluded that the 28S RNA encodes only the L protein, whereas the 13 to 15S RNA is a mixture of species, presumably monocistronic, which code for the four other known vesicular stomatitis virus proteins.     

Cerulenin blocks fatty acid acylation of glycoproteins and inhibits vesicular stomatitis and Sindbis virus particle formation

Cerulenin, an antibiotic that inhibits de novo fatty acid and cholesterol biosynthesis, effectively inhibited the formation and release of virus particles from chicken embryo fibroblasts infected with Sindbis or vesicular stomatitis virus (VSV). When added for 1 h at 3 h postinfection, the antibiotic blocked VSV particle production by 80 to 90% and inhibited incorporation of [3H]palmitic acid into the VSV glycoprotein by an equivalent amount. The effect of this antibiotic on virus protein and RNA biosynthesis was significantly less than that on fatty acid acylation. Nonacylated virus glycoproteins accumulated inside and on the surface of cerulenin-treated cells. These data indicate that fatty acid acylation is not essential for intracellular transport of these membrane proteins, but it may have an important role in the interaction of glycoproteins with membranes during virus assembly and budding.     

Respiratory syncytial virus F envelope protein associates with lipid rafts without a requirement for other virus proteins

Like many enveloped viruses, human respiratory syncytial virus (RSV) assembles at and buds from lipid rafts. Translocation of the envelope proteins to these membrane subdomains is essential for production of infectious virus, but the targeting mechanism is poorly understood and it is not known if other virus proteins are required. Here we demonstrate that F protein of RSV intrinsically targets to lipid rafts without a requirement for any other virus protein, including the SH and G envelope proteins. Recombinant virus deficient in SH and G but retaining F protein expression was used to demonstrate that F protein still localized in rafts in both A549 and HEp-2 cells. Expression of a recombinant F gene by use of plasmid vectors demonstrated that F contains its own targeting domain and localized to rafts in the absence of other virus proteins. The domain responsible for translocation was then mapped. Unlike most other virus envelope proteins, F is unusual since the target signal is not contained within the cytoplasmic domain nor did it involve fatty acid modified residues. Furthermore, exchange of the transmembrane domain with that of the vesicular stomatitis virus G protein, a nonraft protein, did not alter F protein raft localization. Taken together, these data suggest that domains present in the extracellular portion of the protein are responsible for lipid raft targeting of the RSV F protein.     

Localization of Membrane-Associated Proteins in Vesicular Stomatitis Virus by Use of Hydrophobic Membrane Probes and Cross-Linking Reagents

The location of membrane-associated proteins of vesicular stomatitis virus was investigated by using two monofunctional and three bifunctional probes that differ in the degree to which they partition into membranes and in their specific group reactivity. Two hydrophobic aryl azide probes, [(125)I]5-iodonaphthyl-1-azide and [(3)H]pyrenesulfonylazide, readily partitioned into virion membrane and, when activated to nitrenes by UV irradiation, formed stable covalent adducts to membrane constituents. Both of these monofunctional probes labeled the glyco-protein G and matrix M proteins, but [(125)I]5-iodonaphthyl-1-azide also labeled the nucleocapsid N protein and an unidentified low-molecular-weight component. Protein labeling of intact virions was unaffected by the presence of cytochrome c or glutathione, but disruption of membrane by sodium dodecyl sulfate greatly enhanced the labeling of all viral proteins except G. Labeling of G protein was essentially restricted to the membrane-embedded, thermolysin-resistant tail fragment. Three bifunctional reagents, tartryl diazide, dimethylsuberimidate, and 4,4'-dithiobisphenylazide, were tested for their capacity to cross-link proteins to membrane phospholipids of virions grown in the presence of [(3)H]palmitate. Only G and M proteins of intact virions were labeled with (3)H-phospholipid by these cross-linkers; the reactions were not affected by cytochrome c but were abolished by disruption of virus with sodium dodecyl sulfate. Dimethylsuberimidate, which reacts with free amino groups, cross-linked (3)H-phospholipid to both G and M protein. In contrast, the hydrophilic tartryl diazide cross-linked phospholipid primarily to the M protein, whereas the hydrophobic 4,4'-dithiobisphenylazide cross-linked phospholipid primarily to the intrinsic G protein. These data support the hypothesis that the G protein traverses the virion membrane and that the M protein is membrane associated but does not penetrate very deeply, if at all.     

Exit of newly synthesized membrane proteins from the trans cisterna of the Golgi complex to the plasma membrane

The intracellular location at which the G protein of vesicular stomatitis virus accumulated when transport was blocked at 20 degrees C has been studied by biochemical, cytochemical, and immunocytochemical methods. Our results indicated that the viral G protein was blocked in that cisterna of the Golgi stack which stained for acid phosphatase. At 20 degrees C this trans cisterna became structurally altered by the accumulation of G protein. This alteration was characterized by extensive areas of membrane buds which were covered by a cytoplasmic coat. These coated structures were of two kinds--those that labeled with anti-clathrin antibodies and those that did not. The clathrin-coated pits consistently did not label with anti-G antibodies. Upon warming infected cells to 32 degrees C, G protein appeared on the surface within minutes. Concomitantly, the trans cisterna lost its characteristic structural organization. Double-labeling experiments were performed in which G protein localization was combined with staining for horseradish peroxidase, which had been taken up from the extracellular medium by endocytosis. The results suggest that the trans cisterna was distinct from the endosome compartment and that the latter was not an obligatory station in the route taken by G protein to the cell surface.     

An evaluation of the contribution of membrane lipids to protection against ultraviolet radiation

Using dioleoylphosphatidylcholine liposomes incorporating various fatty acids and neutral lipids, we have examined the ability of such lipids to provide protection of Escherichia coli and vesicular stomatitis virus (VSV) against the lethal effect of ultraviolet (254 nm) radiation. While the presence of varying amounts of saturated (palmitic) or polyunsaturated (arachidonic) fatty acids or the lipid antioxidant, alpha-tocopherol, had little effect on killing by ultraviolet radiation, considerable radioprotection was observed with beta-carotene, retinal and vitamin K-1 at final concentrations of 1 mg/ml. In another approach, vesicular stomatitis virus grown under conditions in which its envelope fatty acid composition was substantially modified, showed little change in its sensitivity to inactivation by ultraviolet radiation. The results provide strong evidence for a radioprotective role of certain, relatively rare natural lipid components with conjugated polyene systems, but not of the more ubiquitous and abundant membrane fatty acids.     

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.     

Assembly of vesicular stomatitis virus glycoprotein and matrix protein into HeLa cell plasma membranes.

The kinetics of the incorporation of the proteins of vesicular stomatitis virus into the HeLa cell plasma membrane have been studied. The virus M and NS proteins become associated with the plasma membrane very rapidly (< 5 min) while the glycoprotein G shows a lag of about 20 minutes. A similar lag is observed for the incorporation of the G protein into released virus. By pulse-chase experiments the transit time for the G protein from the site of completion to the plasma membrane was also calculated to be about 20 minutes although not all of the G protein could be chased into the plasma membranes.     

Mechanism of interferon action. Expression of vesicular stomatitis virus G gene in transfected COS cells is inhibited by interferon at the level of protein synthesis

The effect of interferon on the expression of the vesicular stomatitis virus glycoprotein G gene was examined in simian COS cells transfected with the expression vector pSVGL containing the G gene under the control of the SV40 late promoter. When COS cells were treated with interferon 24 h after transfection, the synthesis of vesicular stomatitis virus G protein was inhibited by about 80% as compared to that in untreated controls. By contrast, under the same conditions, neither the plasmid copy number nor the G gene mRNA levels were detectably affected by interferon treatment. Likewise, the synthesis of simian virus 40 large T-antigen was not inhibited by interferon treatment of transfected COS cells even though the synthesis of vesicular stomatitis virus G protein was markedly inhibited. The residual G protein synthesized in transfected, interferon-treated COS cells appeared to be normally glycosylated.     

Cytoplasmic Compartmentalization of the Protein and Ribonucleic Acid Species of Vesicular Stomatitis Virus

The cytoplasmic sites of synthesis in L cells of the protein and ribonucleic acid species of vesicular stomatitis virus were studied by polyacrylamide gel electrophoresis after fractionation of membrane and other cytoplasmic components by the Caliguiri-Tamm technique. The viral spike protein (glycoprotein G) was found primarily associated with a smooth membrane fraction which is rich in plasma membrane; the G protein was also present in fractions containing rough endoplasmic reticulum. The nonglycosylated envelope protein S (also called M) was found in the smooth membrane fractions but was more abundant in endoplasmic reticulum-enriched fractions. Longer labeling resulted in detection of nucleoprotein N, as well as other minor nucleocapsid proteins L and NS₁, in the cellular membrane fractions. The N protein appeared to be made in membrane-free cytoplasm along with progeny ribonucleic acid and later became associated with membrane containing G and S viral proteins.     

Role of cell membrane composition in receptor-mediated internalization of vesicular stomatitis virus in human HEp-2 cells

The role of essential fatty acids in membrane functions related to receptor-mediated endocytosis of vesicular stomatitis virus (VSV) was investigated using a human laryngeal carcinoma cell line (HEp-2) grown in chemically defined serum-free medium (DM) to deplete their essential fatty acid contents. VSV replicated much less effectively in HEp-2 cells grown in DM as compared to serum containing complete medium (CM). Observed reduction in the rate of virus multiplication was, at least in part, due to reduced virus penetration which was monitored using VSV labeled with nitroxyl free radicals as electron spin probe. Surface proteins of VSV were labeled with maleimide spin-label, and succinimide spin-label. Ni2+ was used as a broadening agent to identify the spin-label signals from viruses inside the cell. HEp-2 cells and mouse leukemia cell line L1210 treated with 5-dimethylaminonaphthalene-1-sulfonyl (dansyl) cadaverine, an agent previously shown to inhibit the uptake of VSV in vitro, was used as a positive control in some experiments. VSV penetrated less effectively in both DM-grown cells and in CM-grown cells in the presence of dansylcadaverine. Similar results were obtained by monitoring the uptake of 125I-labeled VSV. When HEp-2 cells grown for several generations in DM were incubated with 10% fetal calf serum for 16 h, the cells supported virus replication to a similar extent as the cells grown in CM. In contrast, addition of arachidonic acid restored VSV growth only partially. Continued growth of HEp-2 cells in DM resulted in a shift in fatty acyl chain composition of phospholipids. The results indicate a finite role for essential fatty acids in receptor-mediated internalization of virus particles.     

Influence of membrane anchoring and cytoplasmic domains on the fusogenic activity of vesicular stomatitis virus glycoprotein G.

Chimeric proteins in which the transmembrane anchoring sequence (TM) or both the TM and the cytoplasmic tail (CT) of vesicular stomatitis virus glycoprotein G were replaced with corresponding domains of viral or cellular integral membrane proteins were used to examine the influence of these domains on acidic-pH-induced membrane fusion by G protein. The TM and CT of G were also replaced with the lipid anchor glycosylphosphatidylinositol. Hybrids containing foreign TM or TM and CT sequences were fusogenic at acidic pH but glycosylphosphatidylinositol-anchored G was nonfusogenic at acidic pH. The results suggest that the fusogenic activity of G protein requires membrane anchoring by a hydrophobic peptide sequence and the specific amino acid sequence of the TM has no influence on fusogenic activity.