Soluble antigens of vaccinia-infected mammalian cells. I. Separation of virus-induced soluble antigens into two classes on the basis of physical characteristics

Cohen, Gary H. (University of Pennsylvania, Philadelphia), and Wesley C. Wilcox. Soluble antigens of vaccinia-infected mammalian cells. I. Separation of virus-induced soluble antigens into two classes on the basis of physical characteristics. J. Bacteriol. 92:676-686. 1966-Infection of mammalian cells with members of the poxvirus group elicits production of a number of virus-induced, soluble antigens. Immunoelectrophoresis and immunodiffusion techniques employing soluble antigen preparations obtained from vaccinia virus-infected KB cells revealed at least seven well-defined immunoprecipitin bands. On the basis of fractionation and subsequent characterization of the soluble antigen mixture by gel filtration, calcium phosphate chromatography, isoelectric precipitation, disc electrophoresis, and ultracentrifugation studies, two distinct classes of virus-induced antigens differing markedly in molecular weight were recognized. A high molecular weight class (200,000 and greater) contained at least three virus-induced antigens; a low molecular weight class (50,000 to 100,000 range) contained at least four immunoprecipitins. Further separation of the antigens within the two groups was accomplished. The two classes were distinguished also by their ability to stimulate synthesis of virus-neutralizing antibody. Antisera prepared against the high molecular weight class proved effective in neutralizing vaccinia virus. In contrast, the low molecular weight antigens showed little, if any, ability to induce formation of neutralizing antibody.     

Developmental Sequence and Intracellular Sites of Synthesis of Three Structural Protein Antigens of Influenza A2 Virus

Specific antisera for hemagglutinin (HA) and neuraminidase antigens of influenza A(2) virus (A(2)E) were produced through the segregation of the two proteins in reciprocal viral recombinants of A(2)E and A(0)e viruses. Gamma globulin fractions of these specific antisera and of antiserum specific for the nucleoprotein (NP) antigen of A(0)e virus were conjugated with fluorescein isothiocyanate and employed to follow the synthesis of the three structural proteins in clone 1-5C-4 human aneuploid cells, with parallel measurement of serological and biological activity of the antigens by other techniques. In this system, NP antigen appeared first (at 3 hr) in the cell nucleus, whereas HA and neuraminidase appeared coincidentally, at 4 hr after infection, in the cytoplasm. The initial detectability of biological or complement-fixing activity of the proteins coincided with their demonstrability as stainable antigens. Late in infection, all three antigens were detected at the cell surface. Antibody specific for HA partially blocked the intracellular staining of neuraminidase and inhibited the enzymatic activity of both extracted and intact extracellular virus. These observations suggest the close intracytoplasmic proximity of the two envelope antigens and perhaps their initial association in a larger 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)     

Changes in Nuclear Basic Proteins During Pseudorabies Virus Infection

As a preliminary study to investigation of the possible role played by basic proteins in the genetic regulation of virus-infected cells, acid-extractable proteins synthesized during pseudorabies virus infection were investigated. The synthesis of histones was found to decrease in a gradual manner, and arrest was complete by 6 hr after infection. Five virus-induced acid-extractable proteins appeared in nuclei of infected cells after 4 hr of infection. Four of these proteins were virus structural proteins; one was not. All these proteins contained tryptophan and, therefore, were not "classic" histones.     

Cellular Compartmentalization of Herpesvirus Antigens During Viral Replication

HEp-2 cells infected with herpes simplex virus develop five distinct immunofluorescent elements. Three (small nuclear granules, large nuclear granules, and an amorphous mass filling the nucleus) contain antigens which react with a rabbit serum prepared against boiled infected cell debris. A labeled pool of human antibody revealed antigens making up cytoplasmic granules and those responsible for a diffuse cytoplasmic fluorescence. All five immunofluorescent elements are demonstrable with a rabbit serum prepared against unheated infected cell debris. Viral antigens are segregated in the nucleus or in the cytoplasm; within the limits of detection, each antigen accumulates in one compartment only. The antigens responsible for the diffuse cytoplasmic fluorescence and for the amorphous nuclear mass are synthesized early in infection; they are formed in arginine-deprived cells and exist in a form which does not sediment on centrifugation at 79,000 x g for 2 hr. The antigens comprising the nuclear and cytoplasmic granules arise relatively late in infection; they are not formed in arginine-deprived cells, and they are readily sedimented on centrifugation at 79,000 x g for 2 hr. Heating (60 C for 2 hr) confers on one or more cytoplasmic viral antigens a new specificity; the altered antigens are demonstrable with labeled rabbit anti-boiled infected cell serum which normally does not combine with cytoplasmic antigens.     

Characterization of a Tumorlike Antigen in Type 12 and Type 18 Adenovirus-Infected Cells.

Gilead, Zvee (University of Pennsylvania, Philadelphia), and Harold S. Ginsberg. Characterization of a tumor-like antigen in type 12 and type 18 adenovirus-infected cells. J. Bacteriol. 90:120-125. 1965.-An antigen that reacts with antibody from type 12 adenovirus tumor-bearing hamsters was identified in extracts of KB cells infected with type 12 or 18 adenovirus. In contrast, viral structural proteins separated by chromatography on diethylaminoethyl-cellulose did not react with the sera from tumorous hamsters. The tumorlike (T) antigen in infected cells was found to be smaller than the viral structural antigens and, therefore, could be separated from them by centrifugation in a linear sucrose gradient. Investigation of the production of the T antigen in virus-infected cells further distinguished it from viral structural proteins by the following properties: (i) the T antigen was first detected 3 to 4 hr after infection, whereas viral antigens were synthesized 17 to 20 hr after infection; and (ii) the T antigen was produced when deoxyribonucleic acid (DNA) biosynthesis was inhibited by 5-fluorodeoxyuridine (10(-6)m), but viral proteins were not synthesized in the absence of viral DNA replication.     

Induction of pre-early nuclear antigen(s) in HEL cells infected with human cytomegalovirus.

Human cytomegalovirus (HCMV)-specific nuclear antigen could be detected within 1 hr after infection in human embryo lung cells by the anticomplement immunofluorescence (ACIF) test. This antigen has been named the pre-early nuclear antigen (PENA) in this paper. Serum absorption tests suggested that PENA is immunologically different from the early antigen and the major nuclear inclusion antigens detected by the indirect immunofluorescence test before and after viral DNA replication, respectively. PENA-forming ability of the virus corresponded to its plaque forming ability. PENA formation was not affected by phosphonoacetate but was inhibited by the addition of inhibitors of RNA and protein syntheses or by UV-irradiation of infecting virus, suggesting that the formation of PENA depends on the expression of infecting virus gene functions. Virus-specific proteins were isolated by indirect immunoprecipitation from HCMV-infected cells exposed to 35S-methionine. SDS-polyacrylamide gel electrophoresis of the immunoprecipitate showed that at least two species of virus-specific polypeptides with molecular weights o.f 70,000 and 30,000 were synthesized de novo within 3 hr after infection.     

Structural and Nonstructural Proteins of an Arbovirus

Purified Semliki Forest virus (SFV) contains three structural proteins while its core (nucleocapsid) contains two of these proteins. To identify all of the proteins synthesized under virus direction, cells were infected with SFV in the presence of actinomycin D and guanidine. Cell protein synthesis was markedly and irreversibly inhibited under these conditions; virus growth was reversibly inhibited by guanidine and began when the cells were washed to remove the guanidine. When cells were treated with guanidine for 4 hr after virus infection and then were washed, five major proteins were produced early in infection. Three of these proteins corresponded to virus structural proteins. None of these five proteins was a major protein of uninfected cells or of virus-infected cells which had been incubated with partially purified interferon before infection. Late in infection, three major proteins, the virus structural proteins, were produced.     

Inhibitory proteins in the Newcastle disease virus-induced suppression of cell protein synthesis

Bolognesi, D. P. (Rensselaer Polytechnic Institute, Troy, N.Y.), and D. E. Wilson. Inhibitory proteins in the Newcastle disease virus-induced suppression of cell protein synthesis. J. Bacteriol. 91:1896-1901. 1966.-Infection by Newcastle disease virus brings about a rapid and marked inhibition of cell protein synthesis (CPS) in chick embryo fibroblast monolayers. The block to CPS is initiated about 5 hr after infection, and by 9 hr about 85% of the host protein synthesis is shut off. Azauridine (3 mg/ml), a ribonucleic acid (RNA) synthesis inhibitor, prevents the virus-induced inhibition of CPS when added at the time of infection; but it does not prevent the inhibition when added at 3 hr after infection. When puromycin (60 mug/ml), a protein synthesis inhibitor, was added at 3.5 hr after infection, viral RNA was synthesized in normal amounts, but the virus-induced inhibition of CPS was prevented. Actinomycin D added at the time of infection does not, however, prevent the virus-induced inhibition of CPS. The results of these experiments indicate that proteins synthesized during Newcastle disease virus replication are responsible for the inhibition of host-cell protein synthesis. The synthesis of these inhibitory proteins depends on the prior synthesis of viral RNA.     

BVD Virus Antigens in Tissues of Persistently Viraemic,Clinically Normal Cattle: Implications for the Pathogenesis of Clinically Fatal Disease

The cellular events involved in precipitation of the clinically fatal outcome of an infection with bovine viral diarrhoea virus (BVDV) remain unresolved, though it is now known that this course of the infection, Mucosal Disease (MD), only occurs in calves persistently infected with non-cytopathic BVDV. In studies aimed at elucidating the pathogenesis of MD, the distribution of BVDV antigens and infectious virus in tissues of persistently infected, clinically normal calves was investigated. Virus antigen was detected in most tissues, in epithelial and immune cells. No signs of an inflammatory response were detected and cytopathological changes were subtle or absent. The infection may nevertheless create a cell-environment which will enhance replication of cytopathic virus. Variations in the clinical, pathomorphologies and virological appearance of MD-cases may depend on both the host-reactions, including virus-induced immunopathology, and the virus-strain combinations in a putative mixed infection.     

Antigens of Pichinde virus I. Relationship of soluble antigens derived from infected BHK-21 cells to the structural components of the virion.

Antigens detected by the complement-fixation (CF) test were prepared from BHK-21 cells infected with Pichinde virus.The preparations contained two antigens demonstrable by immunodiffusion. The antigen present in abundance was heat stable, Pronase resistant, and had a molecular weight of 20,000 to 30,000 as estimated by gel filtration. Polyacrylamide gel electrophoresis of purified antigen demonstrated two low-molecular-weight polypeptides. An identical antigenic determinant was found by disrupting purified virus with Nonidet P-40; however, none of the viral polypeptides co-migrated with the polypeptides derived from purified CF antigen. Pronase digestion of disrupted virus did not alter antigenicity but degraded the viral peptides to sizes similar to those associated with the major CF antigen. These observations suggest that the major CF antigen of Pichnide virus is a cleavage product of the structural proteins of the virus.     

Simian Virus 40-Induced T and Tumor Antigens

Antigen extracts from simian virus 40 (SV40) transplanted hamster tumors were studied by rate-zonal centrifugation. Three species or molecular forms of antigen were demonstrated. The major antigen component corresponded to a molecular weight of 65,000 to 75,000, and two larger species were detectable in smaller quantities. Similar studies were carried out on SV40 virus-induced T antigen from BSC-1 cells. Three antigen components were again detected. Quantitative differences in the expression of "T" and tumor antigen species were reproducibly found.     

Soluble Antigens of Vaccinia-infected Mammalian Cells: III. Relation of “Early” and “Late” Proteins to Virus Structure

The structural proteins of vaccinia virus can be divided into two classes on the basis of their times of synthesis in the infected cell. The production of one of these classes of proteins begins prior to the onset of viral deoxyribonucleic acid (DNA) replication. These are referred to as "early" proteins. Synthesis of the second class of structural proteins follows the onset of viral DNA replication; hence, the term "late" proteins for this class. We are able, by immunological procedures, to identify three "early" virus-structural proteins. These materials, when incorporated into virions, appear to be associated with the "core" of the virion and do not elicit production of virus-neutralizing antibody. It would seem, therefore, that those virus-structural proteins synthesized early in the course of infection act as internal components of the virion. The "late" proteins may be subdivided into two groups on the basis of certain physical properties and molecular weight differences. The first of these groups, comprised of at least two proteins, corresponds to the classical LS antigens and elicits production of neutralizing antibodies. These proteins, when incorporated into virions, are found only in the outer ("coat") fraction of the virion. The second group of "late" antigens, also comprised of two proteins, termed the G antigens, do not elicit synthesis of neutralizing antibody. One of these proteins is associated with the virus "core"; the other is found in the "coat" fraction of the virion and appears to occupy an intermediary, subsurface position. Procedures suitable for the isolation of the G antigens are described, in addition to the partial characterization of these antigens.     

Translation of Taenia crassiceps mRNA in cell-free heterologous systems.

1. mRNA isolated from larval Taenia crassiceps directs efficiently the synthesis of proteins in cell-free heterologous systems. 2. Part of the newly synthesized proteins in a reticulocyte system are precipitable by a rabbit antiserum against T. crassiceps proteins. 3. Analysis of the antiserum-protein dissociated complex by sodium dodecyl sulfate polyacrylamide gel electrophoresis indicates that most of the proteins synthesized are of low molecular weight (13,000-22,000) although a protein of mol. wt. 260,000 is also produced. 4. Whether the newly synthesized proteins which are precipitable by specific antisera correspond to parasite antigens or to proteins with closely antigenic similarities remains to be established.     

Relationship Among Tau Antigens Isolated from Various Lines of Simian Virus 40-Transformed Cells

In addition to the virus-specified tumor antigens, simian virus 40-transformed cells contain at least one other protein which can be immunoprecipitated with serum from animals bearing simian virus 40-induced tumors. This protein, which is designated Tau antigen, has an apparent molecular weight of 56,000 as determined by electrophoresis on acrylamide gels. The relationship among Tau antigens isolated from different lines of simian virus 40-transformed cells was examined by comparing the methionine-labeled tryptic peptides of these proteins by two-dimensional fingerprinting on thin-layer cellulose plates. In this fashion, we initially determined that the Tau antigens isolated from three different lines of transformed mouse cells were very similar. Second, we found that Tau antigen isolated from a line of rat transformants was closely related, but not identical, to the mouse cell Tau antigens. Approximately 70% of their methionine peptides comigrated in two dimensions. Finally, we showed that Tau antigen isolated from a line of transformed human cells was only partially related to the mouse and rat proteins. About 40% of the methionine peptides of the human protein were also contained in the Tau antigens from the other two species. These results strongly indicate that the Tau antigens isolated from these various simian virus 40-transformed cell lines contain common amino acid sequences.     

Murine Virus-Induced Proteins Synthesized by Hamster Tumor Cells Transformed by, But Not Producing, Murine Sarcoma Virus

The 8303 hamster tumor cells transformed by Moloney strain of murine sarcoma virus (M-MSV), but which do not produce virus, do contain murine virus-induced proteins. The virus-induced proteins within the cell were identified either as free proteins or in association with membranous material, including the plasma membrane. In addition, some were excreted by the 8303 hamster tumor cells into the growth medium. Most virus-induced proteins were larger than 68,000 daltons, and they did not dissociate into components of smaller size in the presence of detergent and a reducing agent. A small amount of virus-induced protein with a molecular weight of less than 20,000 was also found in the hamster tumor cells. No virus-specific proteins with the identical antigenic specificity or size of the major internal group specific antigen (molecular weight about 30,000) of the murine leukemia viruses were present in these cells. There is a common cell surface antigen present in three other tumor cell lines, both virus-producing and non-virus-producing, identical in reactivity to that of the murine virus-induced antigen of the 8303 hamster tumor cell. This antigen is not present on the cell surface of normal mouse embryo cells.     

Effect of Mengovirus Replication on Choline Metabolism and Membrane Formation in Novikoff Hepatoma Cells

Infection of Novikoff rat hepatoma cells (subline NlSL-67) with mengovirus resulted in a two- to threefold increase in the rate of choline incorporation into membrane phosphatidylcholine at about 3 hr after infection, without affecting the rate of transport of choline into the cell or its phosphorylation. The time course of virus-stimulated phosphatidylcholine synthesis was compared with the time courses of other virus-induced processes during a single cycle of replication. The formation of viral ribonucleic acid (RNA) polymerase and of viral RNA commenced about 1 hr earlier than the virus-stimulated choline incorporation. Further, isopycnic centrifugation of cytoplasmic extracts indicated that the excess of phosphatidylcholine synthesized by infected cells is not located in the membrane structures associated with the viral RNA replication complex, but with structures of a lower density (1.08 to 1.14 g/cc). These membrane structures probably represent the smooth vesicles which accumulate in the cytoplasm of infected cells during the period of increased phosphatidylcholine synthesis between 3 and 5 hr after infection. They are formed with both newly synthesized phosphatidylcholine and phosphatidylcholine present prior to infection. However, concomitant protein synthesis is not required for the stimulated synthesis of membranes; the effect was not inhibited by treating the cells with inhibitors of protein synthesis at 3 hr after infection, although virus production was inhibited about 90% and virus-induced cell degeneration was markedly reduced and delayed. Production of mature virus began normally at about the same time as the stimulation of phosphatidylcholine synthesis. Treatment of infected cells with puromycin at 2 hr, on the other hand, completely inhibited the stimulation of phosphatidylcholine synthesis.     

Nonstructural proteins of herpes simplex virus. I. Purification of the induced DNA polymerase.

Herpes simplex virus-induced DNA polymerase purified by published methods was found to be contaminated with many others proteins, including virus structural proteins. Thus, DEAE-cellulose and phosphocellulose chromatography were used in combination with affinity chromatography to purify DNA polymerase from herpes simplex virus type 1- and type 2-infected cells. The purified enzyme retained unique features of the herpesvirus-induced DNA polymerase, including a requirement for high salt concentrations for maximal activity, a sensitivity to low phosphonoacetate concentrations, and the capacity to be neutralized by rabbit antiserum to herpesvirus-infected cells. By polyacrylamide gel electrophoresis, the purified DNA polymerase was associated with a virus-induced polypeptide of about 150,000 molecular weight.     

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.     

Identification of herpesvirus sylvilagus-induced polypeptides in productively infected cells.

Polypeptides synthesized in cell cultures infected with high multiplicities of herpesvirus sylvilagus were identified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of [35S]methionine-labeled cell extracts. Initiation of polypeptide synthesis was detected by 6 h after infection. The maximum intensity of many [35S]methionine-labeled viral bands was observed at 45 h after infection. Production of detectable infectious virus began between 18 and 24 h and reached a plateau at 48 h after infection. Immunoprecipitation of cell extracts identified a minimum of 45 virus-induced polypeptides ranging in molecular weight from 230,000 to 27,000. The major polypeptide appeared to have a molecular weight of 150,000. The pattern of these extracts suggested that the synthesis of host polypeptides is stimulated during the first 12 h and thereafter reduced, but not completely inhibited, during the remaining course of infection.