Biochemical characterization of the structural and nonstructural polypeptides of a porcine group C rotavirus.

Purified virions or radiolabeled lysates of infected MA104 cells were used to characterize the structural and nonstructural polypeptides of a porcine group C rotavirus. At least six structural proteins were identified from purified group C rotavirus by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Of these, two (37,000- and 33,000-molecular-weight polypeptides) were associated with the outer shell, as demonstrated by the ability of EDTA to remove them from the purified virion. The other four polypeptides (molecular weights, 125,000, 93,000, 74,000, and 41,000) were located in the inner shell. The structural or nonstructural nature of a 25,000-molecular-weight protein identified in our studies was unclear. Glycosylation inhibition studies with tunicamycin in infected cells demonstrated that the 37,000- and 25,000-molecular-weight proteins were glycosylated and contained mannose-rich oligosaccharides identified by radiolabeling of the infected cells with [3H]mannose. The 37,000-molecular-weight outer shell glycoprotein was shown by pulse-chase experiments to be posttranslationally processed. The kinetics of viral polypeptide synthesis in infected cells were also studied, and maximal synthesis occurred at 6 to 9 h postinfection. The 41,000-molecular-weight inner capsid polypeptide was the most abundant and was the subunit structure of a 165,000-molecular-weight protein aggregate. Two polypeptides (molecular weights, 39,000 and 35,000) appeared to be nonstructural, as determined by comparison of the protein pattern of radiolabeled infected cell lysates with that of purified virions. Radioimmunoprecipitation was used to examine the serologic cross-reactions between the viral polypeptides of a group C rotavirus with those of a group A rotavirus. No serologic cross-reactivities were detected. The polypeptides of group A and C rotaviruses are compared and discussed.     

Identification and characterization of a porcine parvovirus nonstructural polypeptide.

Sera from porcine parvovirus (PPV)-infected swine fetuses immunoprecipitated and 84- to 86-kilodalton polypeptide in addition to the A and B virion structural proteins. This polypeptide, designated NS-1, was present in PPV-infected cell lysates but not in purified virions. Partial proteolysis mapping revealed that NS-1 was not related to the A and B viral structural proteins. All three proteins in infected cells were phosphorylated at serine residues, and NS-1 also contained phosphothreonine. From pulse-labeling experiments with either 32Pi or [35S]methionine, NS-1 was found to first appear 5 to 7 h postinfection, whereas the viral structural polypeptides were first synthesized 9 to 11 h postinfection. Pulse-chase experiments revealed that NS-1 initially appeared as an 84-kilodalton protein and was subsequently structurally modified to forms of slower electrophoretic mobilities. The time of appearance of NS-1 after virus infection coincided with the initiation of viral DNA synthesis, suggesting that this polypeptide (and the modified forms thereof) may be involved in PPV replication.     

Sequence of protein synthesis in cells infected by human cytomegalovirus: early and late virus-induced polypeptides.

At least 10 distinct early virus-induced polypeptides were synthesized within 0 to 6 h after infection of permissive cells with cytomegalovirus. These virus-induced polypeptides were synthesized before and independently of viral DNA replication. A majority of these early virus-induced polypeptides were also synthesized in nonpermissive cells, which do not permit viral DNA replication. The virus-induced polypeptides synthesized before viral DNA replication were hypothesized to be nonstructural proteins coded for by the cytomegalovirus genome. Their synthesis was found to be a sequential process, since three proteins preceded the synthesis of the others. Synthesis of all early cytomegalovirus-induced proteins was a transient process; the proteins reached their highest molar ratios before the onset of viral DNA replication. Late viral proteins were synthesized at the time of the onset of viral DNA replication, which was approximately 15 h after infection. Their synthesis was continuous and increased in molar ratios with the accumulation of newly synthesized viral DNA in the cells. The presence of the amino acid analog canavanine or azetadine during the early stage of infection suppressed viral DNA replication. The amount of viral DNA synthesis was directly correlated to the relative amount of late viral protein synthesis. Because synthesis of late viral proteins depended upon viral DNA replication, the proteins were not detected in permissive cells treated with an inhibitor of viral DNA synthesis or in nonpermissive cells that are restrictive for cytomegalovirus DNA replication.     

Tyrosine phosphorylation events during coxsackievirus B3 replication.

In order to study cellular and viral determinants of pathogenicity, interactions between coxsackievirus B3 (CVB3) replication and cellular protein tyrosine phosphorylation were investigated. During CVB3 infection of HeLa cells, distinct proteins become phosphorylated on tyrosine residues, as detected by the use of antiphosphotyrosine Western blotting. Two proteins of 48 and 200 kDa showed enhanced tyrosine phosphorylation 4 to 5 h postinfection (p.i.), although virus-induced inhibition of cellular protein synthesis had already occurred 3 to 4 h p.i. Subcellular fractionation experiments revealed distinct localization of tyrosine-phosphorylated proteins of 48 and 200 kDa in the cytosol and membrane fractions of infected cells, respectively. In addition, in Vero cells infected with CVB3, echovirus (EV)11, or EV12, increased tyrosine phosphorylation of a 200-kDa protein was detected 6 h p.i. Herbimycin A, a specific inhibitor of Src-like protein tyrosine kinases, was shown to inhibit virus-induced tyrosine phosphorylations and to reduce the production of progeny virions. In contrast, in cells treated with the inhibitors staurosporine and calphostin C, the synthesis of progeny virions was not affected. Immunoprecipitation experiments suggested that the tyrosine-phosphorylated 200-kDa protein in CVB3-infected cells is of cellular origin. In summary, these investigations have begun to unravel the effect of CVB3 as well as EV11 and EV12 replication on cellular tyrosine phosphorylation and support the importance of tyrosine phosphorylation events for effective virus replication. Such cellular phosphorylation events triggered in the course of enterovirus infection may enhance virus replication.     

Biochemical and electron microscopic studies of the replication and composition of milker''s node virus

Replication of milker's node virus (MNV) DNA begins 4 to 8 h postinfection, continues to 30 to 36 h postinfection in the cytoplasm of infected, primary bovine embryonic kidney cells, and is accompanied by an inhibition of host nuclear DNA synthesis. Between 20 and 24 h postinfection, newly replicated genomes are incorporated into particles which cosediment with purified MNV. These biochemical measurements could be correlated with the development of MN virions as revealed by electron microscopic analysis of thin sections prepared from infected cells. Analysis of the DNA in purified MNV showed that the virions contained a double-stranded DNA molecule with a molecular weight of 85 x 10(6) to 87 x 10(6) and a guanine-plus-cytosine content of about 63%. After denaturation and sedimentation analysis of MNV DNA in alkaline sucrose gradients, three major DNA species were resolved. These species appeared to represent intact, terminally cross-linked genomes (approximately 75 to 80S); genomes bearing one nick (or with one cross-link removed) (60 to 65S); and complementary, denatured DNA strands released from cross-linked genomes bearing two nicks (or with both cross-links removed) (52 to 55S). Forty [35S]methionine-labeled polypeptides, ranging from approximately 200,000 daltons to 10,000 to 15,000 daltons, were detected by radioautography after polyacrylamide gel electrophoresis of the proteins present in detergent-solubilized MNV preparations. Treatment of MN virions with Nonidet P-40, beta-mercaptoethanol, and sonication released 10 polypeptides, which were apparently located on the surface of virions. Further fractionation of these released polypeptides, followed by electron microscopy and polyacrylamide gel electrophoresis, indicated that a 42,000- to 45,000-dalton polypeptide is a major component of the threadlike tubule structure present on the surface of MN virions.     

Identification of Virus-Induced Proteins in Cells Productively Infected with Simian Virus 40

The number and molecular weight of the structural polypeptides of highly purified simian virus 40 (SV40) were determined by polyacrylamide gel electrophoresis. Six different polypeptides were found, two of which (VP1 and VP2) comprise the bulk of the viral capsid proteins. The pattern of protein synthesis in productively infected CV-1 cells was studied by sodium dodecyl sulfate polyacrylamide gel electrophoresis. Identification of virus-induced proteins in the infected CV-1 cells was achieved in double-labeling experiments by electrophoresis with purified labeled SV40 capsid proteins. Four of these proteins (VP1 and VP4) could be classified as components of the virion because their synthesis occurred after the onset of viral deoxyribonucleic acid (DNA) replication and because they were inhibited by arabinofuranosylcytosine (ara-C). Appearance of two other virus-induced proteins was not prevented by ara-C; one of them did not comigrate in the electrophoresis with purified virion polypeptides, and both could be detected before the onset of viral DNA synthesis. These latter two proteins were classified on the basis of these criteria as nonvirion capsid proteins (NCVP1 and NCVP2).     

Replication of simian herpesvirus SA8 and identification of viral polypeptides in infected cells

The replication of the simian herpesvirus SA8 in Vero cells was examined. The time course of replication of the simian herpesvirus SA8 was found to be similar to that of the herpes simplex viruses. Infectious progeny virions were first detectable by 6 h postinfection and were readily released into the extracellular fluids beginning at 9 h postinfection. All cell lines tested, with the exception of Madin-Darby canine kidney cells, were permissive for SA8. Analysis of SA8-infected cells by sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed over 40 infected cell polypeptides ranging in molecular weight from 158,000 to less than 10,000. Of these proteins, 23 were present in virions. Three classes of infected cell polypeptides could be identified based on the kinetics of their synthesis. Post-translational processing of several SA8-induced proteins was also observed in pulse-chase experiments. Six distinct SA8-specific glycoproteins ranging from 118,000 to 19,500 daltons were also identified in infected cells. Of these glycoproteins, five were present in virions.     

DNA-binding proteins in the cytoplasm of vaccinia virus-infected mouse L-cells.

Mouse L cell fibroblasts were infected with vaccinia virus and labeled 2 to 3 h postinfection with [35S]methionine. Labeled proteins were fractionated on native and denatured DNA-cellulose columns and then analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Twenty-four 90,000 to 12,500, were detected. VDP-12A (molecular weight, 29,750) had affinity for denatured but not native DNA, and its synthesis was dependent on viral DNA replication. VDP-20 (molecular weight, 41,000) bound very tightly to native and denatured DNA and was displaced only after boiling the protein-DNA-cellulose matrix in 1% sodium dodecyl sulfate. VDP-8,-11,-12,-13, -and-14 behaved electrophoretically like the polypeptide species previously shown to be present in DNA-protein complexes prepared from infected cells. The molecular weights of VDP-10 (50,000), VDP-11 (36,000), and VDP-8 (67,000) were similar to the polypeptide subunits of polyadenylate polymerase and phosphohydrolase I, enzymes purified from virions which have also been shown to have affinity for DNA.     

Synthesis of plus- and minus-strand RNA in rotavirus-infected cells.

The genomes of the rotaviruses consist of 11 segments of double-stranded RNA. During RNA replication, the viral plus-strand RNA serves as the template for minus-strand RNA synthesis. To characterize the kinetics of RNA replication, the synthesis and steady-state levels of viral plus- and minus-strand RNA and double-stranded RNA in simian rotavirus SA11-infected MA104 cells were analyzed by electrophoresis on 1.75% agarose gels containing 6 M urea (pH 3.0). Synthesis of viral plus-strand and minus-strand RNAs was detected initially at 3 h postinfection. The steady-state levels of plus- and minus-strand RNAs increased from this time until 9 to 12 h postinfection, at which time the levels were maximal. Pulse-labeling of infected cells with [3H]uridine showed that the ratio of plus- to minus-strand RNA synthesis changed during infection and that the maximal level of minus-strand RNA synthesis occurred several hours prior to the peak of plus-strand RNA synthesis. No direct correlation was found between the levels of plus-strand and minus-strand RNA synthesis in the infected cell. Pulse-labelling studies indicated that both newly synthesized and preexisting plus-strand RNA can act as templates for minus-strand RNA synthesis throughout infection. Studies also showed that less than 1 h was required between the synthesis of minus-strand RNA in vivo and its release from the cell within virions.     

Multiplication of parvovirus LuIII in a synchronized culture system. IV. Association of viral structural polypeptides with the host cell chromatin.

Newly synthesized structural polypeptides of parvovirus LuIII, VP1 (62,000 daltons) and VP2 (74,000 daltons), were detected in nuclei of synchronized, infected HeLa cells at 11 to 12 h postinfection, i.e., after cells had passed through the S phase of the cell cycle. At this time, most of intranuclear viral polypeptides were associated with the chromatin acidic proteins. However, 13 to 14 h postinfection, about one-third of intranuclear VP1 and VP2 also could be extracted in the fraction containing nuclear sap proteins. According to pulse-chase experiments, VP1 and VP2 accumulated in the chromatin with a time lag of 20 to 30 min. About 90% of these chromatin-associated viral polypeptides represented empty viral capsids. In addition, chromatin prepared at 14 h postinfection contained 90 to 95% of the total intranuclear viral 16S replicative-form DNA. Since viral replicative-form DNA and empty viral capsids seem to be associated specifically with cellular chromatin, we assume that this subnuclear structure is the site of the synthesis of progeny viral DNA and the formation of complete virions.     

Characterization of cricket paralysis virus-induced polypeptides in Drosophila cells

Cricket paralysis virus purified from Galleria mellonella larvae was shown to be similar to virus purified from Drosophila melanogaster cells. Cricket paralysis virus contained three major structural polypeptides of similar molecular weight (around 30,000), had a buoyant density of 1.344 g/ml, and had a capsid diameter of 27 nm. Twenty virus-induced polypeptides could be detected in CrPV-infected Drosophila cells. Two major polypeptides found in the infected cells corresponded to two structural viral polypeptides (VP1 and VP3), whereas the third major intracellular polypeptide was the apparent precursor of the third viral structural polypeptide (VP2). Three of the primary virus-induced polypeptides had molecular weights of 144,000, 124,000, and 115,000. These and other polypeptides were chased into lower-molecular-weight proteins when excess cold methionine was added after a short [³⁵S]methionine pulse. Although cricket paralysis virus has a number of characteristics in common with the mammalian enteroviruses, the extremely fast processing of high-molecular-weight polypeptides into viral proteins seems atypical. Also, no VP4 (8,000 to 10,000 molecular weight) has been found in the virus particles.     

Protein Synthesis in a Lymantria dispar Cell Line Infected by Cytoplasmic Polyhedrosis Virus

The efficiency of replication of a cytoplasmic polyhedrosis virus isolated from a member of the order Lepidoptera, Euxoa scandens, was studied in eight different lepidopterean cell lines. Lymantria dispar cells, which were found to support viral replication, more efficiently, were used to follow the kinetics of appearance of viral-specific polypeptides by a 2-h pulse with [³⁵S]methionine. Five polypeptides (ca. 120,000 molecular weight [120K], 105K, 66K, 46K, and 28K) were identified as components of the polyhedral inclusion bodies, and two polypeptides (112K and 39K) were assigned as viral-particle polypeptides. All these polypeptides were present after 24 h and were still being produced 96 h after infection. The rate of synthesis of the major polyhedral polypeptide (28K) increased in the time course of infection, whereas the background of cellular polypeptides seemed to be unaffected. An indirect immunoperoxidase technique, after sodium dodecyl sulfate-polyacrylamide gel electrophoresis was blotted to a nitrocellulose membrane, showed that traces of the major polyhedral polypeptide were found from 8 h postinfection.     

Intracellular synthesis of measles virus-specified polypeptides.

The intracellular synthesis of measles-specified polypeptides was examined by means of polyacrylamide gel electrophoresis of cell extracts. Since measles virus does not efficiently shut off host-cell protein synthesis, high multiplicities of infection were used to enable viral polypeptides to be detected against the high background of cellular protein synthesis. The cytoplasm of infected cells contained viral structural polypeptides with estimated molecular weights of 200,000, 80,000, 70,000, 60,000, 41,000, and 37,000. All of these structural polypeptides, with the exception of P1, the only virion glycoprotein (molecular weight congruent to 80,000), were also found in the nuclei. In addition, two nonstructural polypeptides with estimated molecular weights of 74,000 and 72,000 were also present in the cytoplasm of infected cells. The initial synthesis of the smaller, nonstructural polypeptide began later in infection than the structural polypeptides. Pulse-chase experiments failed to detect any precursor-product relationships. The intracellular glycosylation and phosphorylation of the viral polypeptides were found to be similar to those found in purified virions.     

Structural components of mouse mammary tumor virus. II. Isolation and purification of virion polypeptides.

Mouse mammary tumor virus (MMTV) glycoproteins and nonglycosylated polypeptides were purified by preparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Primary amino groups were labeled with fluorescamine to enable visualization of MMTV polypeptides in the gels. Protein bands were sliced from the gels and eluted with 90 to 95% recovery. Eight MMTV polypeptides, including three of the major viral components as well as five minor proteins, were routinely obtained. Double diffusion assays and immunoelectrophoresis confirmed the retention of antigenicity identical to that of untreated MMTV virions. Antisera obtained from MMTV-free BALB/c mice immunized with these purified proteins reacted with the polypeptide immunogen as well as with detergent-disrupted MMTV virions from mouse milk or cell culture. Double diffusion assays using the specific mouse antisera failed to detect any cross-reactivity among the isolated polypeptides. A hemagglutination-inhibition assay demonstrated that the ability of MMTV virions to inhibit the hemagglutinating properties of influenza virus resides in the glycosylated polypeptides gp52, gp37.7, and gp33.     

Restricted replication of human hepatitis A virus in cell culture: intracellular biochemical studies.

When hepatitis A virus was inoculated into Vero cells, virus-specified protein and RNA synthesis was detected. Production of viral protein was detected by electrophoretic analysis in polyacrylamide gels by using a double-label coelectrophoresis and subtraction method which eliminated the contribution of host protein components from the profiles of virus-infected cytoplasm. Eleven virus-specified proteins were detected in the net electrophoretic profiles of hepatitis A virus-infected cells. The molecular weights of these proteins were very similar to those detected in cells infected with poliovirus type 1. Virus-specified protein synthesis could be detected at 3 to 6 h and continued for at least 48 h postinfection, but no significant effect on host-cell macromolecular synthesis was observed. Limited viral RNA replication occurred between 2 and 6 h postinfection. The genomic RNA of hepatitis A virus was extracted and shown to be capable of infecting cells and inducing the same set of proteins as intact virus, indicating that the RNA genome is positive stranded. Progeny virus was never detected in the supernatant fluids of infected cell cultures, and the cells showed no observable cytopathology, even though hepatitis A virus-specific proteins and antigens were being produced. The nature of the defect in the replicative cycle of hepatitis A virus in this system remains unknown.     

Immunological Studies on Viral Polypeptide Synthesis in Cells Replicating Murine Sarcoma-Leukemia Virus

Antibodies to disrupted murine sarcoma-leukemia virus (MSV[MLV]) were used to study the synthesis of viral polypeptides in the transformed, virus-producing rat cell line 78A1. When cultures were labeled for 10 min with radioactive amino acids, about 9% of the total labeled proteins were precipitated with antiserum against purified MSV(MLV), and 3 to 4% were precipitated with the same antiserum after it had been absorbed with an extract from uninfected rat cells. The difference is due to the presence in the unabsorbed antiserum of antibodies to cellular proteins that are present in purified virus preparations. Intracellular viral proteins labeled with radioactive amino acids were isolated by immunoprecipitation and analyzed by electrophoresis in sodium dodecyl sulfate-polyacrylamide gels. The mobilities of intracellular viral polypeptides were identical to those of the purified virion. However, labeled polypeptides having electrophoretic mobilities lower than that of the major virion polypeptide, the group-specific antigen of molecular weight 31,000, were present in higher proportion in the total cell extract and in the membrane fraction than in the virion. These polypeptides appear to be of cellular origin for they were present only in minute amounts in the immunoprecipitates obtained with the absorbed serum. After a 10-min labeling period, radioactive proteins were assembled into extracellular virions rapidly for the first 4 hr followed by a slower rate. More than 2% of the total proteins of the cell labeled in a 10-min pulse were assembled into virions at the completion of a 24-hr chase. The high-molecular-weight polypeptides with the same mobilities as those detected in the immunoprecipitate of intracellular proteins were found in virions released from cells after a 10-min pulse. A larger proportion of these high-molecular-weight proteins was detected in virions released after short chase periods (30-120 min) than after longer chase periods (6-24 hr). Two possible interpretations of these data are that the high-molecular-weight cell-derived polypeptides (i) have a turnover rate higher than that of the major virion polypeptides or (ii) are cleaved proteolytically from the virions during long incubation in the culture media.     

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.