Identification of immunologically distinct antigens in pseudorabies virus

Antigenic proteins of pseudorabies viruses (PrV) are poorly understood. Proteins from purified PrV and membrane proteins from these viral infected cells, therefore, have been studied by antigenic analysis, using virus neutralization and agargel immunoelectrophoresis tests and by polyacrylamide gel electrophoresis, respectively. The study of crossed immunoelectrophoresis against specific antiviral serum antibodies revealed four immunologically distinct antigens involved in PrV. According to their electromobilities, these four immunologically distinct antigens were designated as Ag 1, Ag 2, Ag 3 and Ag 4. The study of dodecyl sulfate-polyacrylamine gel electrophoresis of a membrane-bound but detergent solubilized viral antigenic complex from PrV infected cells also demonstrated the involvement of four glycoprotein antigens. By interpolations of relative mobilities between known protein markers, the molecular weights of these four glycoproteins were estimated to be 61,500, 68,000, 75,000, and 88,000. Results from two dimentional immunoelectrophoresis seemed to be concordant with those obtained by dodecyl sulfate-polyacrylamide gel electrophoresis. This report, therefore presents results, which strongly suggest antigenic similarities in the virion of PrV and cellular membrane glycoproteins of cells infected by this agent. The molecular weight of these four immunologically distinct antigens, Ag 1, Ag 2, Ag 3 and Ag 4, are presumed to have the following molecular weights of 88,000, 75,000, 68,000 and 61,500, respectively.     

Location of the Glycoprotein in the Membrane of Sindbis Virus

SINDBIS virus, which is transmitted by arthropods, consists of a nucleoprotein core within a lipid-containing envelope. Its components assemble at a cellular membrane and virus particles form by an outfolding of this membrane. Thus, such viruses provide useful systems for studies of the structure and synthesis of membranes. The Sindbis virus particle contains only two proteins, one associated with the viral envelope and the other with the viral RNA in the core, or nucleocapsid¹. The protein associated with the membrane is a glycoprotein, whereas the core protein contains no carbohydrate². The exact location of the glycoprotein within the viral envelope has not been determined, nor has information been obtained about the function of the carbohydrate in the virion. The results described here indicate that the spikes which cover the surface of the virion are glycoprotein in nature.     

Junin virus structural proteins.

Polyacrylamide gel electrophoresis of purified Junin virus revealed six distinct structural polypeptides, two major and four minor ones. Four of these polypeptides appeared to be covalently linked with carbohydrate. The molecular weights of the six proteins, estimated by coelectrophoresis with marker proteins, ranged from 25,000 to 91,000. One of the two major components (number 3) was identified as a nucleoprotein and had a molecular weight of 64,000. It was the most prominent protein and was nonglycosylated. The other major protein (number 5), with a molecular weight of 38,000, was a glucoprotein and a component of the viral envelope. The location on the virion of three additional glycopeptides with molecular weights of 91,000, 72,000, and 52,000, together with a protein with a molecular weight of 25,000, was not well defined.     

In Vitro Synthesis of Proteins by Membrane-Bound Polyribosomes from Vesicular Stomatitis Virus-Infected HeLa Cells

Membrane-bound polysomes from vesicular stomatitis virus (VSV)-infected HeLa cells synthesize predominantly three proteins in an in vitro protein synthesizing system. These three proteins have different molecular weights than the viral structural proteins, i.e., 115,000, 88,000, and 72,000. Addition of preincubated L or HeLa cell S10 or HeLa cell crude initiation factors stimulates amino acid incorporation and, furthermore, alters the pattern of proteins synthesized. Stimulated membrane-bound polysomes synthesize predominantly viral protein G and lesser amounts of N, NS, and M. In vitro synthesized proteins G and N are very similar to virion proteins G and N based on analysis of tryptic methionine-labeled peptides. Most methionine-labeled tryptic peptides of virion G protein contain no carbohydrate moieties, since about 90% of sugar-labeled peptides co-chromatograph with only about 10% of methionine-labeled peptides. Sucrose gradient analysis of the labeled RNA present in VSV-infected membrane-bound polysomes reveals a relative enrichment in a class of viral RNA sedimenting slightly faster than the total population of the 13 to 15S mRNA, as compared to a VSV-infected crude cytoplasmic extract. A number of proteins, other than the viral structural proteins, are synthesized in the cytoplasm of five lines of VSV-infected cells. One of these proteins has the same molecular weight as the major in vitro synthesized protein, P(88). In vitro synthesized protein P(88) does not appear to be a precursor of viral structural proteins G, N, or M based on pulse-chase experiments and tryptic peptide mapping. Nonstimulated membrane-bound polysomes from uninfected HeLa cells synthesize the same size distribution of proteins as nonstimulated VSV-infected membrane-bound polysomes.     

Chromatographic and Electrophoretic Analysis of Viral Proteins from Hamster and Chicken Cells Transformed by Rous Sarcoma Virus

Several methods have been explored for the detection and characterization of viral proteins from soluble extracts of cells transformed by Rous sarcoma virus (RSV). Viral antigens have been analyzed after gel filtration in several solvents. In addition, immune complexes formed with virus-specific sera have been isolated by agarose gel filtration and by high- or low-speed centrifugation through sucrose solutions. Radioactive proteins from these immune complexes have been analyzed by gel filtration in 6 m guanidine hydrochloride or by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. Comparison with proteins from purified virus indicates the presence of two viral core proteins (gs1 and gs2) in the soluble fraction from virus-producing chicken cells. In the same fraction from RSV-transformed hamster cells (which do not produce virus), three gs proteins (gs1, gs2, and gs3) could be identified. The soluble viral gs proteins are strongly bound to at least two larger polypeptides in cell extracts. These polypeptides do not appear to be viral in origin and have the property of undergoing a time-dependent aggregation in the extracts. One of these cell-derived proteins, which is present in a variety of uninfected cell types, closely resembles actin.     

Proteins and Glycoproteins of Paramyxoviruses: a Comparison of Simian Virus 5, Newcastle Disease Virus, and Sendai Virus

The polypeptides of three paramyxoviruses (simian virus 5, Newcastle disease virus, and Sendai virus) were separated by polyacrylamide gel electrophoresis. Glycoproteins were identified by the use of radioactive glucosamine as a carbohydrate precursor. The protein patterns reveal similarities among the three viruses. Each virus contains at least five or six proteins, two of which are glycoproteins. Four of the proteins found in each virus share common features with corresponding proteins in the other two viruses, including similar molecular weights. These four proteins are the nucleocapsid protein (molecular weight 56,000 to 61,000), a larger glycoprotein (molecular weight 65,000 to 74,000), a smaller glycoprotein (molecular weight 53,000 to 56,000), and a major protein which is the smallest protein in each virion (molecular weight 38,000 to 41,000).     

Synthesis and Cleavage of Influenza Virus Proteins

The NWS strain of influenza virus grows rapidly in and kills the MDCK dog kidney cell strain. Within 1 to 2 hr, the virus inhibits host cell protein synthesis and for 3 to 4 hr more it directs the synthesis of influenza virus proteins at a rate about twice that of uninfected cell synthesis. The rates of virus ribonucleic acid (RNA) and protein synthesis reach a maximum within the first few hours after infection and then drop. Plaque assays exhibit a linear dose-response, indicating that only one virion is necessary for productive infection. We have confirmed earlier reports regarding the fragmented nature of the RNA genome of purified influenza virions. However, high resolution gel electrophoresis indicated that each size class of viral RNA is heterogenous, so that there are at least 10 and probably more fragment sizes of RNA in these virions. Repeated attempts to detect infectivity in preparations of extracted viral RNA were completely negative (over a 10(8)-fold loss of infectivity after extraction). Even infection of the "infectious" RNA-treated cells with intact, related, influenza viruses failed to support infectivity of the isolated RNA or to rescue a host range genetic marker of the RNA. Purified influenza virions exhibit only three major protein peaks based on separation according to molecular weights. These three major virion proteins are the only major virion proteins synthesized in infected cells. This is true throughout the infectious cycle from several hours after infection until the cells are dying. However, the molecular weight of these virion proteins differs slightly depending upon the cell type in which the virus is grown. No host membrane proteins are incorporated into the virions as they bud through the cell membrane. Pulse-chase labeling early after infection or prolonged chase experiments indicate that influenza virus proteins are cleaved from one or more precursor polypeptides. In fact, each of the three major peaks seems to be a heterogeneous mixture of polypeptides in various stages of cleavage. Peptide analysis confirms that the three major peaks share common peptides, but the exact precursor product relationships are not clear. There may be one or several precursor proteins. Also there could be overlapping messenger RNA molecules of varying length giving rise to polypeptides of various sizes and overlapping sequences. Late in infection, amino acid labeling shows a preponderance of internal nucleocapsid protein synthesis, indicating that either this protein is much more stable to cleavage in infection or it is made from a more stable messenger. There is no obvious relationship between virion RNA fragments and viral protein sizes, so these fragments may be artifacts.     

Structural components of the arenavirus Pichinde.

Purified Pichinde virions grown in monolayers of BHK-21 cells were found to contain three major species of virion proteins as described previously (Ramos et al., J. Virol. 10:661-667, 1972). Two of the proteins were glycosylated (G1, molecular weight = 64,000; G2, molecular weight = 38,000) and were present in similar proportions on the outer surface of the virions. A third protein (N, molecular weight = 66,000) was not glycosylated and, in association with the viral RNA species, was the major protein component of the viral nucleocapsids. An estimate of the approximate number of molecules of these three major proteins per virion was made. Minor amounts of other proteins were also routinely observed in Pichinde virus preparations. None of the three major protein species were phosphorylated to any significant exten, nor did they contain sulfated components. Two virion RNA species (L and S), but no 18S rRNA species, were detected in Pichinde virus preparations obtained from infected BHK-21 cells.     

Biochemical, biophysical, and biological properties of densonucleosis virus. I. Structural proteins.

The polypeptide composition of highly purified densonucleosis virus was studied by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The viral proteins showed a different behavior in sodium dodecyl sulfate-gels in comparison with the marker proteins. Therefore, the molecular weights were estimated by analyzing the retardation of the electrophoretic mobility of these proteins in gels with increasing polyacrylamide concentrations. Four structural proteins with molecular weights of 49,000, 58,500, 69,000, and 98,000 were found, ant they were designated p49, p59, p69, and p98, respectively. There are several indications that p98 is a dimer of p49. The relative quantity of the structural proteins in a virion suggests that at least p49 (accounting for +/-70% of total protein mass) is a capsid protein and that there will be 12 capsomers per virion.     

Synthesis and glycosylation of polyprotein precursors to the internal core proteins of Friend murine leukemia virus

Synthesis and post-translational processing of murine leukemia virus proteins were analyzed in a murine cell line (Eveline) that produces large amounts of Friend lymphatic leukemia virus. Immunoprecipitation of l-[(35)S]methionine-labeled cell extracts demonstrated that several different virus-specific proteins antigenically related to the virion core (gag) proteins p12 and p30 become radioactive within 1 min of labeling and exhibit labeling kinetics characteristic of primary translation products. The most abundant of these were proteins with molecular weights of 75,000 and 65,000. There were, in addition, two large glycosylated polyproteins with apparent molecular weights of 220,000 and 230,000, which were precipitated by antisera to p30 or p12 but not by antiserum to the major envelope glycoproteins gp69/71. Several lines of evidence, including labeling with d-[(3)H]glucosamine and binding to insolubilized lectins, suggested that the 75,000-dalton internal core polyprotein is slowly processed to form a glycoprotein with an apparent molecular weight of 93,000. On the contrary, the 65,000-dalton protein appeared to be an immediate precursor to the virion core proteins. Its processing can involve intermediates containing p30 and p12 antigens with molecular weights of 50,000 and 40,000; however, the latter did not appear to be obligatory intermediates. The detection of the 40,000-dalton protein suggested that the genes for p30 and p12 are adjacent on the viral genome. These results indicated that there are several pathways of synthesis and post-translational processing of polyprotein precursors to the gag proteins and that several of these polyproteins are glycosylated. A comparison of gag precursor processing in rapidly growing, slowly growing, and stationary cells indicated that different pathways are favored under different conditions of cell growth. Our analysis of envelope glycoprotein synthesis has confirmed the existence of two rapidly labeled 90,000-dalton glycoproteins, which appear to be precursors to the envelope glycoproteins gp69/71.     

Vaccinia virus A6 is essential for virion membrane biogenesis and localization of virion membrane proteins to sites of virion assembly

Poxvirus acquires its primary envelope through a process that is distinct from those of other enveloped viruses. The molecular mechanism of this process is poorly understood, but several poxvirus proteins essential for the process have been identified in studies of vaccinia virus (VACV), the prototypical poxvirus. Previously, we identified VACV A6 as an essential factor for virion morphogenesis by studying a temperature-sensitive mutant with a lesion in A6. Here, we further studied A6 by constructing and characterizing an inducible virus (iA6) that could more stringently repress A6 expression. When A6 expression was induced by the inducer isopropyl-β-D-thiogalactoside (IPTG), iA6 replicated normally, and membrane proteins of mature virions (MVs) predominantly localized in viral factories where virions were assembled. However, when A6 expression was repressed, electron microscopy of infected cells showed the accumulation of large viroplasm inclusions containing virion core proteins but no viral membranes. Immunofluorescence and cell fractionation studies showed that the major MV membrane proteins A13, A14, D8, and H3 did not localize to viral factories but instead accumulated in the secretory compartments, including the endoplasmic reticulum. Overall, our results show that A6 is an additional VACV protein that participates in an early step of virion membrane biogenesis. Furthermore, A6 is required for MV membrane protein localization to sites of virion assembly, suggesting that MV membrane proteins or precursors of MV membranes are trafficked to sites of virion assembly through an active, virus-mediated process that requires A6.     

Characterization of a small, nonstructural viral polypeptide present late during infection of BHK cells by Semliki Forest virus.

BHK cells, late in infection with Semliki Forest virus, were found to contain a small virus-specific polypeptide not found in the mature virion. This polypeptide had an apparent molecular weight of 6,000 and is referred to here as the 6K protein. No [2-3H]mannose was incorporated into 6K, and hence it does not appear to be a glycoprotein. This protein appears to be a primary translation product of the subgenomic 26S mRNA, which encodes the viral structural proteins. The genes encoding the viral structural proteins are arranged on the message in the order of 5'-C-E3-E2-E1-3'. We have found that the gene coding for 6K is located to the 3' side of the gene encoding E2. Subcellular fractionation of pulse-labeled cells infected with Semliki Forest virus demonstrated that 6K, like the viral glycoproteins p62 and E1, was present predominantly in the rough microsomal membrane fraction. 6K appears to be analogous, therefore, to the nonstructural 4.2K protein present in cells infected with Sindbis virus.     

Characterization of early stages in vaccinia virus membrane biogenesis: implications of the 21-kilodalton protein and a newly identified 15-kilodalton envelope protein.

Vaccinia virus (VV) membrane biogenesis is a poorly understood process. It has been proposed that cellular membranes derived from the endoplasmic reticulum-Golgi intermediate compartment (ERGIC) are incorporated in the early stages of virion assembly. We have recently shown that the VV 21-kDa (A17L gene) envelope protein is essential for the formation of viral membranes. In the present work, we identify a 15-kDa VV membrane protein encoded by the A14L gene. This protein is phosphorylated and myristylated during infection and is incorporated into the virion envelope. Both the 21- and 15-kDa proteins are found associated with cellular tubulovesicular elements related to the ERGIC, suggesting that these proteins are transported in these membranes to the nascent viral factories. When synthesis of the 21-kDa protein is repressed, organized membranes are not formed but numerous ERGIC-derived tubulovesicular structures containing the 15-kDa protein accumulate in the boundaries of the precursors of the viral factories. These data suggest that the 21-kDa protein is involved in organizing the recruited viral membranes, while the 15-kDa protein appears to be one of the viral elements participating in the membrane recruitment process from the ERGIC, to initiate virus formation.     

Vaccinia virus penetration requires cholesterol and results in specific viral envelope proteins associated with lipid rafts

Vaccinia virus infects a wide variety of mammalian cells from different hosts, but the mechanism of virus entry is not clearly defined. The mature intracellular vaccinia virus contains several envelope proteins mediating virion adsorption to cell surface glycosaminoglycans; however, it is not known how the bound virions initiate virion penetration into cells. For this study, we investigated the importance of plasma membrane lipid rafts in the mature intracellular vaccinia virus infection process by using biochemical and fluorescence imaging techniques. A raft-disrupting drug, methyl-beta-cyclodextrin, inhibited vaccinia virus uncoating without affecting virion attachment, indicating that cholesterol-containing lipid rafts are essential for virion penetration into mammalian cells. To provide direct evidence of a virus and lipid raft association, we isolated detergent-insoluble glycolipid-enriched membranes from cells immediately after virus infection and demonstrated that several viral envelope proteins, A14, A17L, and D8L, were present in the cell membrane lipid raft fractions, whereas the envelope H3L protein was not. Such an association did not occur after virions attached to cells at 4 degrees C and was only observed when virion penetration occurred at 37 degrees C. Immunofluorescence microscopy also revealed that cell surface staining of viral envelope proteins was colocalized with GM1, a lipid raft marker on the plasma membrane, consistent with biochemical analyses. Finally, mutant viruses lacking the H3L, D8L, or A27L protein remained associated with lipid rafts, indicating that the initial attachment of vaccinia virions through glycosaminoglycans is not required for lipid raft formation.     

Mechanisms for generating cell membrane antigens that are recognized by cytotoxic T lymphocytes

Studies with many viruses have revealed that viral specific protein synthesis is an obligatory step in generating antigens on target cells for antiviral cytotoxic T lymphocytes. This has been most clearly demonstrated with DI particles, virions that are structurally complete but lack infectious RNA. Adsorption of such particles onto target cell membranes does not render these cells susceptible to lytic attack by antiviral effector cells, unless some viral protein synthesis transpires. However, some viruses, such as Sendai virus, circumvent the requirement for viral protein synthesis via fusion of the viral envelope with the target cell membrane, a process mediated by a specialized fusion protein. Once inserted into the lipid bilayer, it is likely that viral components and self H-2 noncovalently associate so that the complex can be recognized by antiviral cytotoxic T cells. This idea is supported by the demonstration that viral proteins and H-2 containing membrane proteins, incorporated into reconstituted membrane vesicles or liposomes are recognized by cytotoxic T cells. These data further show that native rather than altered viral and H-2 molecules are the moieties recognized. Associations between antigen and H-2 have been detected by a variety of techniques and in some cases are not random but selective; that is, viral antigens perferentially associate with some H-2 alleles and not others. In summary, these findings indicate that although viral antigens are present in the mature virions, these components are not recognized by antiviral killer cells until integrated into the plasma membrane. This may be achieved either through direct fusion of the viral envelope with the target cell or following viral protein synthesis and insertion of viral antigens into the plasma membrane.     

Impaired intracellular migration and altered solubility of nonglycosylated glycoproteins of vesicular stomatitis virus and Sindbis virus.

Tunicamycin, an antibiotic which prevents the glycosylation of newly synthesized proteins, inhibits the replication of both vesicular stomatitis virus and Sindbis virus. In tunicamycin-treated infected cells, all of the viral proteins are synthesized but the glycoproteins are devoid of carbohydrate. The nonglycosylated glycoproteins could not be detected on the outside of the plasma membrane by lactoperoxidase labeling, indirect immunofluorescence staining, or chymotrypsin treatment of intact cells, whereas the glycosylated glycoproteins were readily detected by all three methods. These results indicate that the bulk of the nonglycosylated glycoproteins are unable to undergo the normal migration to the cell surface. In contrast to the normal glycosylated viral glycoproteins, the nonglycosylated glycoproteins were insoluble in nonionic detergents such as Triton X-100. The nonglycosylated glycoprotein of vesicular stomatitis virus could be solubilized using a combination of 6 M guanidine hydrochloride and 0.2% Triton X-100, but precipitated when the 6 M guanidine was removed by dialysis. These results suggest that the lack of carbohydrate alters the properties of the glycoproteins, which may explain their impaired mobility through the intracellular membranous system.     

Structural proteins of densonucleosis virus isolated from the silkworm, Bombyx mori, infected with the flacherie virus

Four structural proteins were found in highly purified Bombyx densonucleosis virus particles which were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The molecular weight was estimated from the relative mobility and the retardation coefficient. The major viral protein (VP1), accounting for 65% of the total virion protein, had a molecular weight of about 50,000, and the other three minor proteins (VP2, VP3, VP4) had molecular weights of about 57,000, 70,000, and 77,000, respectively. The Bombyx densonucleosis virus particle contains about 60 molecules of VP1, and VP1 is believed to be capsid protein.     

Antigens of human cytomegalovirus

In considering HCMV antigens one must take into consideration not only structural proteins of virus particles but also HCMV specific proteins associated with the infected cell, for all of these proteins may play a part in eliciting an humoral and/or cell-mediated immune response in the infected individual. The virion is composed of some 35 polypeptides ranging in molecular weight from 12 000 to more than 200 000 daltons (Table I). Viral polypeptide synthesis at the level of the infected cell occurs in three waves, the immediate early, the early and the late (Table II). During the immediate early and early phases a dozen polypeptides appear. Two glycoproteins appear during the early period but these are poorly represented in the virion. Many antigens have been described both in the cytoplasm and nucleus during these periods (Table II). Viral DNA synthesis marks the beginning of the late phase of virus replication. Many new proteins and glycoproteins appear but not all of them will become part of the virus particle (Table II). It is interesting to compare the kinetics of appearance of antibodies as detected by different serodiagnostic techniques, at the time of primary infection, with the location of the antigens which these antibodies detect in the infected cells (Table III). CMV-IgM, the first antibodies to be detected, react with late appearing intracellular nuclear inclusion antigens. This contrasts with the relatively long time required for the development of neutralizing antibodies which react with antigens accessible not only on the viral envelope and at the infected cell membrane.(ABSTRACT TRUNCATED AT 250 WORDS)     

Capsid Polypeptides of Mouse Elberfeld Virus I. Amino Acid Compositions and Molar Ratios in the Virion

The four major polypeptide chains (alpha, beta, gamma, delta) constituting the capsid protein of mouse Elberfeld (ME) virus were isolated by preparative electrophoresis on polyacrylamide gels, and the amino acid composition of each chain was determined. In addition, the molecular weights of the smallest chains of ME virus, mengovirus, and poliovirus, which had previously been determined by gel electrophoretic methods, were redetermined by gel filtration chromatography in 6 m guanidine hydrochloride. Each was found to have a molecular weight about 7,300. Using the reevaluated molecular weights and the known amino acid compositions of the chains, the molar ratio of each chain in the ME virion was determined by quantitative analysis of the distribution of radioactivity in the electrophoretically separated chains of virus which had been specifically radiolabeled with leucine or with methionine. Equimolar proportions of all four chains were found in the virion.