The M protein of vesicular stomatitis virus associates specifically with the basolateral membranes of polarized epithelial cells independently of the G protein (original) (raw)
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Journal of virology, 1978
To explore the interaction of vesicular stomatitis virus (VSV) proteins with cellular membranes, we have isolated membranes from infected cells that have been radioactively pulse-labeled. We have found conditions of isolation that result in membrane preparation which contain primarily the VSV membrane protein (M) and glycoprotein (G). Both of these proteins are very firmly attached to membranes: conditions known to release peripherally associated membrane proteins from membranes (S. Razin, Biochim, Biophys. Acta 265:241-246, 1972; S. J. Singer, Annu. Rev. Biochem. 43:805-826, 1974; S. J. Singer and G. L. Nicholson, Science 175:720-731, 1972) are ineffective in detaching either the G or the M protein. The results of trypsin digestion of these membrane fractions suggest that the M protein resides primarily on one side, the cytoplasmic side of cellular membranes, whereas the glycoprotein has been transported to the lumen of the membrane vesicle. However, we present evidence that the gl...
Journal of Virology, 1977
We report here an in vitro system designed to study the interactions of vesicular stomatitis virus (VSV) proteins with cellular membranes. We have synthesized the VSV nucleocapsid (N) protein, nonstructural (NS) protein, glycoprotein (G protein), and membrane (M) protein in a wheat germ, cell-free, protein-synthesizing system directed by VSV 12 to 18S RNA. When incubated at low salt concentrations with purified cytoplasmic membranes derived from Chinese hamster ovary cells, the VSV M and G proteins bind to membranes, whereas the VSV N and NS proteins do not. The VSV M protein binds to membranes in low or high divalent cation concentrations, whereas binding of significant amounts of G protein requires at least 5 mM magnesium acetate concentrations. Vesicular stomatitis virus (VSV) is a simple, lar membranes, whereas the VSV N and NS enveloped virus that contains two membrane proteins do not. proteins: the glycoprotein (G protein), which forms the spikes of the virion (4, 23), and the MATERIALS AND METHODS membrane (M) protein, which lines the inner Cells and viruses. Membranes were prepared surface of the viral membrane (3). There are from CHO cells. Stocks of VSV (pure B particles of three other known viral proteins, the VSV nuthe Indiana serotype) were grown in CHO cells and cleocapsid (N) protein, the nonstructural (NS) purified as described previously (20). protein, and the viral transcriptase (L) protein. Preparation of VSV 12-186 polyribosomal RNA. These three proteins are associated with the The procedure described by Palmiter (15) was used core ofthe virus particle (16, 23, 24). Each of the with several modifications for the preparation of five viral proteins is synthesized from a mono-VSV 12-18S polyribosomal RNA. CHO cells growing cistronic mRNA (9, 13, 14). at 37°C were infected with VSV at a multiplicity of 3 risngtic m arNAl(9 13, 14). PFU/cell as described previously (20), except that 5 During the early stages in the maturation Of~.tg of actinomycin D per ml was added at the beginthis virus, host cell membranes are modified ning of infection. [3H]uridine (70 Ci/mmol, 25 ,uCi/ with the VSV G and M proteins. Cell fractionaml; New England Nuclear Corp.) was added 2 h tion studies of VSV-infected cells have shown postinfection. Infected cells were harvested at 4.5 h that the VSV M and G proteins rapidly become postinfection, suspended in sucrose-TKM buffer associated with the membrane fraction of the (0.05 M Tris [pH 7.5], 0.025 M KCl, 0.005 M magnecells after their synthesis (5, 11, 12, 24). Nucleo-sium acetate, 0.25 M sucrose), and disrupted with 10 capsid structures containing the genome RNA strokes of a tight-fitting Dounce homogenizer. Nuas well as the viral N, NS, and L proteins are clei were removed by centrifugation (1,000 x g for 2 asswemlld as the vira plaNsm. andsLptroteisures min). The resulting cytoplasmic extract was centriassembled in the cytoplasm. These structures fuged at 20,000 x g for 20 min, and the pellet (mem
Formation of membrane domains by the envelope proteins of vesicular stomatitis virus
Biochemistry, 1994
The properties of the two envelope-associated proteins of vesicular stomatitis virus, the glycoprotein (G) and the matrix protein (M), were investigated in order to understand the mechnanism of virus budding and domain formation in membranes. Fluorescence resonance energy transfer was used to study the interaction between the G protein and specific phospholipids. The protein had the highest affinity for phosphatidic acid among the phospholipids tested. Fluorescence digital imaging microscopy also was used to determine how the protein could alter the lateral distribution of phospholipids in membranes. Large domains enriched in phosphatidic acid were observed when the protein was incorporated into phospholipid vesicles. The G protein colocalized with the phosphatidic acid-enriched domains. Similar experiments carried out with the M protein showed that the M protein induced the formation of domains enriched not only in phosphatidic acid but also in phosphatidylserine. The phosphatidic acid-enriched domains induced by either the G or M proteins were similar in terms of the degree of enrichment of phosphatidic acid and the size of the domains. When the two proteins were reconstituted in vesicles at the same time, the domains were condensed. There was a greater degree of phosphatidic acid enrichment, and the size of the domains was reduced. The formation of domains enriched in the viral proteins and specific phospholipids may mimic the first steps that occur during budding of the virus from the plasma membrane of infected cells. This workwas supported in part by a grant from the American Cancer Society (BE-167).
Impact of Vesicular Stomatitis Virus M Proteins on Different Cellular Functions
PLOS ONE, 2015
Three different matrix (M) proteins termed M1, M2 and M3 have been described in cells infected with vesicular stomatitis virus (VSV). Individual expression of VSV M proteins induces an evident cytopathic effect including cell rounding and detachment, in addition to a partial inhibition of cellular protein synthesis, likely mediated by an indirect mechanism. Analogous to viroporins, M1 promotes the budding of new virus particles; however, this process does not produce an increase in plasma membrane permeability. In contrast to M1, M2 and M3 neither interact with the cellular membrane nor promote the budding of double membrane vesicles at the cell surface. Nonetheless, all three species of M protein interfere with the transport of cellular mRNAs from the nucleus to the cytoplasm and also modulate the redistribution of the splicing factor. The present findings indicate that all three VSV M proteins share some activities that interfere with host cell functions.
Isolation of the Glycoprotein of Vesicular Stomatitis Virus and its Binding to Cell Surfaces
Journal of General Virology, 1980
The glycoprotein (G) of vesicular stomatitis virus (VSV) was radiolabelled, extracted and purified so that its potential interaction with host cell surfaces could be studied. When BHK-2I cells were incubated with the radiolabelled virus glycoprotein, the virus component rapidly attached to the cell surface. The attachment was shown to be temperature-dependent and saturated at approx. 3 x IO 5 molecules/cell. The omission of Mg 2+ or Ca 2+ from the incubation medium had little effect on the glycoprotein binding. Treating the isolated G protein and intact virions with neuraminidase did not significantly decrease their binding to BHK-21 cells. Pre-incubating cells with trypsin did not decrease the attachment of VSV virions nor the binding of purified G protein. Treating cells with phospholipase A or phospholipase C suggested that the binding of the glycoprotein and the intact virion might have been dissimilar. Unlabelled glycoprotein competitively inhibited binding of the labelled molecules although the presence of intact virions did not inhibit attachment of the G protein. Likewise, saturating amounts of the glycoprotein did not decrease binding of VSV to BHK-zt cells. These observations suggested that either the isolated glycoprotein bound to cell surface components that were distinct from the virion receptor or that the manner of the purified glycoprotein attachment differed from the G protein still associated with the intact virion. Chemical crosslinking and diagonal two-dimensional gel electrophoresis were used to identify and to compare the cell surface components responsible for glycoprotein and virion attachment.
Biochemistry, 1981
The mobility of vesicular stomatitis virus (VSV) G protein on the surface of infected BHK cells was studied by using the technique of fluorescence photobleaching recovery. The fraction of surface G protein that was mobile in the time scale of the measurement (minutes) was at least 75%, a relatively high value among cell surface proteins so far observed. For studies of the effect of an internal viral protein (M protein) on G protein mobility, cells infected with wild-type VSV were compared with those infected with temperature-sensitive VSV mutants of complementation group 111, which contain lesions in the M protein. At the permissive temperature, a pronounced