Translation of individual species of vesicular stomatitis viral mRNA.

Vesicular stomatitis virus mRNAs from three of the four bands fractionated by polyacrylamide gel electrophoresis in 99% formamide have been eluted from gels and translated in the Krebs II ascites cell-free system. Band 2 mRNA (0.7 times 10-6 daltons) directed the synthesis of the protein moiety of the glycoprotein (G), and band 3 (0.55 times 10-6 daltons) coded for the nucleocapsid (N) protein. Band 4 mRNA (o.28 times 10-6 daltons) directed the synthesis of the NS and matrix (M) proteins. The authenticity of viral proteins synthesized in vitro was shown by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and by analysis of (35-S)metionine-labeled tryptic peptides. These results are consistent with the complexity analysis and coding capacities for the vesicular stomatitis virus mRNA species presented in the accompanying paper.     

Message activity of influenza viral RNA.

The message activity of influenza virion RNA in the wheat germ cell-free protein-synthesizing system was investigated. RNA extracted from purified virions was found to direct the synthesis of a polypeptide that had the mobility of viral nucleocapsid protein on sodium dodecyl sulfate-polyacrylamide gels. Further characterization of the protein indicated it was not the nucleocapsid protein. No other polypeptides were detected. We conclude that influenza virion RNA is inactive as a template for the synthesis of virus-specific proteins.     

Proteins of Avian Tumor Viruses with Different Coat Antigens

Isoelectric focusing of avian tumor viruses with distinct type-specific envelope antigens demonstrated no differences in isoelectric points. Viruses with different type-specific antigens were found to contain different glycoprotein components when virion proteins were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis.     

Characterization of an oviductal glycoprotein associated with the ovulated hamster oocyte

Hamster oviducts in culture incorporate [35S]-methionine into secretory proteins. One of these proteins is immunoprecipitated by a monoclonal antibody specific to an antigen found in oviductal oocytes but not in ovarian oocytes. This antigen, called oviductin, is progressively added to the oocyte during its transit through the oviduct. Oviductin migrates as a diffuse band with a molecular mass between 160 and 250 kDa on sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing conditions. The electrophoretic behavior of this protein suggests the presence of polysaccharide side chains. Chemical deglycosylation causes a decrease in molecular mass and removes the antigenic determinant originally present on the glycoprotein. By using the radiation inactivation method, the molecular mass of the core protein has been found to be approximately 44 kDa. These results indicate that the oviduct is an actual site of synthesis of the oviductin. This glycoprotein contains a high proportion of sugar residues, which account for antigenic determinant recognized by the monoclonal antibody.     

Translation of bovine leukemia virus virion RNAs in heterologous protein-synthesizing systems.

Bovine leukemia virus 60 to 70S RNA was heat denatured, the polyadenylic acid-containing species were separated by velocity sedimentation, and several size classes were translated in a micrococcal nuclease-treated cell-free system from rabbit reticulocytes. The major RNA species sedimented at 38S and migrated as a single component of molecular weight 2.95 x 10(6) when analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The predominant polypeptides of the in vitro translation of bovine leukemia virus 38S RNA were products with molecular weights of 70,000 and 45,000; minor components with molecular weights of 145,000 and 18,000 were also observed. Two lines of evidence indicate that the 70,000- and 45,000-molecular weight polypeptides represent translation products of the gag gene of the bovine leukemia virus genome (Pr70gag and Pr45gag). First, they are specifically precipitated by a monospecific antiserum to the major internal protein, p24, and second, they are synthesized and correctly processed into virion proteins p24, p15, and p10 in Xenopus laevis oocytes microinjected with bovine leukemia virus 38S RNA. The 145,000-molecular weight polypeptide was immunoprecipitated by the anti-p24 serum and not by an antiserum to the major envelope glycoprotein, gp60. It contained all the tryptic peptides of Pr70gag and additional peptides unique to it, and thus represents in elongation product of Pr70gag in an adjacent gene, presumably the pol gene. The 18,000-molecular weight product was antigenically unrelated to p24 and gp60 and shared no peptides in common with Pr70gag, Pr45gag, or the 145,000-molecular weight polypeptide. It was maximally synthesized on a polyadenylic acid-containing virion 16 to 18S RNA, and we present evidence that this RNA is a 3' end-derived subgenomic fragment of the bovine leukemia virus genome rather than a contaminating cellular RNA.     

Expression of a recombinant DNA gene coding for the vesicular stomatitis virus nucleocapsid protein.

A cDNA clone containing the entire vesicular stomatitis virus nucleocapsid gene was assembled by fusing portions of two partial clones. When the cDNA clone was inserted into a new general-purpose eucaryotic expression vector and introduced into appropriate host cells, abundant N-protein synthesis ensued. The expressed protein was indistinguishable from authentic N protein produced during vesicular stomatitis virus infections. The recombinant N protein was recognized by a polyclonal antibody and two different monoclonal antibodies and could not be resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis from authentic N. Our results suggest that the recombinant N protein produced in transfected cells rapidly aggregates into high-molecular-weight complexes in the absence of vesicular stomatitis virus genomic RNA.     

Translation of three mouse hepatitis virus strain A59 subgenomic RNAs in Xenopus laevis oocytes

We have purified the seven virus-specific RNAs which were previously shown to be induced in Sac(-) cells upon infection with mouse hepatitis virus strain A59 (W. J. M. Spaan, P. J. M. Rottier, M. C. Horzinek, and B. A. M. van der Zeijst, Virology 108:424-434, 1981). The individual RNAs, prepared by agarose gel electrophoresis of the polyadenylated RNA fraction from infected cells, were obtained pure, except for the preparations of RNAs 4, 5, and 6, which contained some contamination of RNA 7. The RNAs were microinjected into Xenopus laevis oocytes, and after incubation of these cells in the presence of [35S]methionine, the proteins synthesized were analyzed by polyacrylamide gel electrophoresis. Whereas no translation products of RNAs 1, 2, 4, and 5 were detected, the synthesis of virus-specific polypeptides coded by RNAs 3, 6, and 7 was observed. RNA 7 (0.6 X 10(6) daltons) directed the synthesis of a 54,000-molecular-weight polypeptide which comigrated with viral nucleocapsid protein and which was immunoprecipitated by antiserum from mice that had been infected with the virus. RNA 6 (0.9 X 10(6) daltons) directed the synthesis of three polypeptides with molecular weights of 24,000, 25,500, and 26,500, which migrated with the same electrophoretic mobilities as three low-molecular-weight virion polypeptides. After injection of RNA 3 (3.0 X 10(6) daltons), a polypeptide with a molecular weight of about 150,000 was immunoprecipitated. This polypeptide had no counterpart in the virion, but comigrated with a virus-specific glycoprotein present in infected cells which is immunoprecipitated by a rabbit antiserum against the mouse hepatitis virus strain A59 structural proteins. This antiserum could also immunoprecipitate the translation products of RNAs 3, 6, and 7. These results indicate that RNAs 3, 6, and 7 encode viral structural proteins. The significance of the data with respect to the strategy of coronavirus replication is discussed.     

Antibody responses to Four Corners hantavirus infections in the deer mouse (Peromyscus maniculatus): identification of an immunodominant region of the viral nucleocapsid protein.

Antibody responses to Four Corners hantavirus (FCV) infections in the deer mouse (Peromyscus maniculatus) were characterized by using FCV nucleocapsid protein (N), glycoprotein 1 (G1), and glycoprotein 2 (G2) recombinant polypeptides in Western immunoblot assays. Strong immunoglobulin G reactivities to FCV N were observed among FCV-infected wild P. maniculatus mice (n = 34) and in laboratory-infected P. maniculatus mice (n = 11). No immunoglobulin G antibody reactivities to FCV G1 or G2 linear determinants were detected. The strongest N responses were mapped to an amino-proximal segment between amino acids 17 and 59 (QLVTARQKLKDAERAVELDPDDVNKSTLQSRRAAVSALETKLG). FCV N antibodies cross-reacted with recombinant N proteins encoded by Puumala, Seoul, and Hantaan viruses.     

Transducing particles of Staphylococcus aureus pathogenicity island SaPI1 are comprised of helper phage-encoded proteins

The relationship between the composition of SaPI1 transducing particles and those of helper phage 80alpha was investigated by direct comparison of virion proteins. Twelve virion proteins were identified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and mass spectrometry; all were present in both 80alpha and SaPI1 virions, and all were encoded by 80alpha. No SaPI1-encoded proteins were detected. This confirms the prediction that SaPI1 is encapsidated in a virion assembled from helper phage-encoded proteins.     

Structural Proteins of Rabies Virus

Purified rabies virions, unlabeled or labeled with radioactive amino acids or d-glucosamine, were dissociated into their polypeptides by treatment with sodium dodecyl sulfate in a reducing environment and fractionated by electroiphoresis in sodium dodecyl sulfate-containing polyacrylamide gel. The molecular weights of individual polypeptides were estimated by comparison of their rate of migration with that of protein markers of known molecular weight. Purified viral nucleocapsid and a mixture of envelope components, isolated from virions disrupted by sodium deoxycholate, were analyzed by the same procedure. The number of molecules per virion of each polypeptide was estimated from the proportions of the separated components, the known molecular weight of the viral ribonucleic acid, and the chemical composition of the nucleocapsid. The protein moiety of the nucleocapsid particle was estimated to consist of 1,713 molecules of a major polypeptide (molecular weight, 62,000 daltons) and 76 molecules of a minor polypeptide (molecular weight, 55,000 daltons). In addition to 1,783 molecules of a glycoprotein component (molecular weight, 80,000 daltons), the viral envelope contains 789 and 1,661 molecules, respectively, of two other polypeptides (molecular weight, 40,000 and 25,000 daltons).     

Cell-free translation of murine coronavirus RNA.

The coding assignments of the intracellular murine hepatitis virus-specific subgenomic RNA species and murine hepatitis virion RNA have been investigated by cell-free translation. The six murine hepatitis virus-specific subgenomic RNAs were partially purified by agarose gel electrophoresis and translated in an mRNA-dependent rabbit reticulocyte lysate, and the cell-free translation products were characterized by gel electrophoresis, immunoprecipitation, and tryptic peptide mapping. These studies have shown that RNA 7 codes for the nucleocapsid protein, RNA 6 codes for the E1 protein, RNA 3 codes for the E2 protein, and RNA 2 codes for a 35,000-dalton nonstructural protein. Genomic RNA directs the cell-free synthesis of three structurally related polypeptides of greater than 200,000 in molecular weight.     

Toward an in vitro system for picornavirus assembly: purification of mengovirus 14S capsid precursor particles.

Mengovirus 14S subviral protein particles generated in infected L cells and in a cell-free translation system primed with mengovirus RNA were purified by sucrose gradient centrifugation and immunoaffinity chromatography. The preparations from both sources contained essentially pure proteins epsilon, alpha, and gamma, as was demonstrated in terms of virus-specific proteins (by autoradiography) and total protein content (by silver staining of sodium dodecyl sulfate-polyacrylamide electrophoresis gels). These purified proteins sedimented as discrete particles at the 14S position when recentrifuged in sucrose gradients. Although their assembly properties have not yet been studied in detail, preliminary results indicate that during incubation with virion RNA the 14S particles purified from infected cells can form a structure cosedimenting with mature mengovirus.     

Characterization of a slow-migrating component of the rabies virus matrix protein strongly associated with the viral glycoprotein

We investigated multiple forms of rabies virus matrix (M) protein. Under non-reducing electrophoretic conditions, we detected, in addition to major bands of monomer forms (23- and 24-kDa) of M protein, an M antigen-positive slow-migrating minor band (about 54 kDa) in both the virion and infected cells. Relative contents of the 54-kDa and monomer components in the virion were about 20-30% and 70-80% of the whole M protein, respectively, while the content of the 54-kDa component was smaller (about 10-20% of the total M protein) in the cell than in the virion. The 54-kDa components could be extracted from the infected cells with sodium deoxycholate, but they were quite resistant to extraction with 1% nonionic detergents by which most monomer components were solubilized. The 54-kDa component was precipitated more efficiently than the monomer by a monoclonal antibody (mAb; #3-9-16), which recognized a linear epitope located at the N-terminal of the M protein. The mAb #3-9-16 coprecipitated the viral glycoprotein (G), which was demonstrated to be due to strong association between the G and 54-kDa component of the M protein. Monomers and the 54-kDa polypeptide migrated to the same isoelectric point (pI) in twodimensional (2-D) gel electrophoresis, implicating that the 54-kDa component was composed of component(s) of the same pI as that of the M protein monomers. From these results, we conclude that the M antigen-positive 54-kDa polypeptide is a homodimer of M protein, taking an N-terminal-exposed conformation, and is strongly associated with the viral glycoprotein. Possible association with a membrane microdomain of the cell will be discussed.     

Role of the vesicular stomatitis virus matrix protein in maintaining the viral nucleocapsid in the condensed form found in native virions.

Vesicular stomatitis virus was extracted with 60 mM octylglucoside in the absence of salts and in the presence of 0.5 M NaCl. The resulting extracted virus particles were examined by electron microscopy, and the proteins present were identified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Extraction in the absence of salts yielded subviral structures which we cell "skeletons" as originally suggested by Cartwright et al. (J. Gen. Virol. 7:19-32, 1970). The skeletons contained the viral N, M, and L proteins, but they lacked the glycoprotein (G) entirely. Morphologically, the skeletons resembled intact vesicular stomatitis virus but they were slightly longer and smaller in diameter. Like native vesicular stomatitis virus, skeletons were found to have lateral striations spaced 5.0 to 6.0 nm apart along the length of the structure. In contrast to extraction in the absence of NaCl, extraction of vesicular stomatitis virus with 60 mM octylglucoside in the presence of 0.5 M NaCl yielded highly extended viral nucleocapsids in which N was the predominant protein; no M or G proteins could be detected. These results support the view that the M protein is involved in maintaining the nucleocapsid in the compact form found in native virions.     

Measles Virus-Specified Polypeptide Synthesis in Two Persistently Infected HeLa Cell Lines

Measles virus-directed protein synthesis was examined in two HeLa cell lines (K11 and K11A) that are persistently infected with wild-type measles virus. Four viral proteins (H, hemagglutination protein; P, nucleocapsid-associated protein; NP, the major nucleocapsid protein; and M, the matrix protein) were readily detected in both cell lines by immune precipitation of [(35)S]methionine-labeled cell extracts followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. When analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, three (H, NP, and M) of the four viral proteins in both K11 and K11A cells differed from the corresponding viral proteins synthesized in HeLa cells acutely infected with the parental wild-type virus. In addition, the M protein from K11A cells migrated significantly more slowly on sodium dodecyl sulfate-polyacrylamide gel electrophoresis than the M protein from K11 cells, and there appeared to be slight differences in the H and NP proteins between these two persistently infected cell lines. The altered viral proteins detected in K11 and K11A cells appeared to be the result of viral mutations rather than changes in the host cell, since virus recovered from these cells directed the synthesis of similar aberrant viral proteins in HeLa cells. Virus recovered from K11 cells and virus recovered from K11A cells were both temperature sensitive and grew more slowly than wild-type virus. HeLa cells infected with virus recovered from K11 cells readily became persistently infected, resembling the original persistently infected K11 cells. Thus, viral mutations are associated with persistent measles virus infections in cell cultures.     

Sickness and recovery of dogs challenged with a street rabies virus after vaccination with a vaccinia virus recombinant expressing rabies virus N protein.

Dogs were vaccinated intradermally with vaccinia virus recombinants expressing the rabies virus glycoprotein (G protein) or nucleoprotein (N protein) or a combination of both proteins. The dogs vaccinated with either the G or G plus N proteins developed virus-neutralizing antibody titers, whereas those vaccinated with only the N protein did not. All dogs were then challenged with a lethal dose of a street rabies virus, which killed all control dogs. Dogs vaccinated with the G or G plus N proteins were protected. Five (71%) of seven dogs vaccinated with the N protein sickened, with incubation periods 3 to 7 days shorter than that of the control dogs; however, three (60%) of the five rabid dogs recovered without supportive treatment. Thus, five (71%) of seven vaccinated with the rabies N protein were protected against a street rabies challenge. Our data indicate that rabies virus N protein may be involved in reducing the incubation period in dogs primed with rabies virus N protein and then challenged with a street rabies virus and, of more importance, in subsequent sickness and recovery.     

Amplification of rabies virus-induced stimulation of human T-cell lines and clones by antigen-specific antibodies.

The effect of antigen-specific antibodies on the response of human T-cell lines and clones to rabies virus was studied. Plasmas from rabies-immune vaccine recipients, but not those from nonimmune individuals, enhanced the proliferative response of rabies-reactive T cells to whole inactivated virus or to the purified glycoprotein and nucleocapsid from the rabies virion. Rabies-immune plasma also increased the antigen-induced production of gamma interferon by the rabies-specific T-cell lines. Experiments performed on T-cell clones specific for either rabies glycoprotein or nucleocapsid showed that immune plasma as well as antiglycoprotein and antinucleoprotein murine monoclonal antibodies possessed the capacity to increase significantly the antigen-induced proliferative responses of these clones. The overall results indicate that this in vitro effect of antigen-specific antibodies on the response of regulatory T lymphocytes to rabies virus could be an important factor in the development of effective immune responses in vivo to rabies virus.     

Identification of the nucleocapsid, tegument, and envelope proteins of the shrimp white spot syndrome virus virion

The protein components of the white spot syndrome virus (WSSV) virion have been well established by proteomic methods, and at least 39 structural proteins are currently known. However, several details of the virus structure and assembly remain controversial, including the role of one of the major structural proteins, VP26. In this study, Triton X-100 was used in combination with various concentrations of NaCl to separate intact WSSV virions into distinct fractions such that each fraction contained envelope and tegument proteins, tegument and nucleocapsid proteins, or nucleocapsid proteins only. From the protein profiles and Western blotting results, VP26, VP36A, VP39A, and VP95 were all identified as tegument proteins distinct from the envelope proteins (VP19, VP28, VP31, VP36B, VP38A, VP51B, VP53A) and nucleocapsid proteins (VP664, VP51C, VP60B, VP15). We also found that VP15 dissociated from the nucleocapsid at high salt concentrations, even though DNA was still present. These results were confirmed by CsCl isopycnic centrifugation followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and liquid chromatography-nanoelectrospray ionization-tandem mass spectrometry, by a trypsin sensitivity assay, and by an immunogold assay. Finally, we propose an assembly process for the WSSV virion.