Establishment of a Vero cell line persistently infected with African swine fever virus.

A Vero cell line persistently infected with African swine fever virus was established by infecting the cells in the presence of 10 mM NH4Cl (Vero-P cell line). The virus derived from the Vero-P cultures infected Vero cells, and virus titers were comparable to those obtained in Vero cells acutely infected with African swine fever virus. The structural proteins of the virus from Vero-P cells were similar to those of the virus produced in lytic infections. Virus production was low when the Vero-P cells were growing logarithmically and increased considerably in confluent cultures when lysis appeared in a fraction of the cell population.     

Activation of a Latent Measles Virus Infection in Hamster Cells

The characteristics of infectious measles virus released from latently infected hamster embryo fibroblast cells are described. Low levels of virus were released spontaneously when the cultures were incubated at 37 C; this phenomenon was observed 19 passages after the cells had been exposed to the virus and has continued through cell passage 45. The virus yield could be significantly increased by cocultivation of the hamster cells with BSC-1 cells or incubation of the latently infected cells at 33.5 C rather than at 37 C. Measles virus released after cocultivation demonstrated increased cytopathology in cell culture and reduced temperature sensitivity when compared to the virus released at 33.5 C. After cell passage 45, there was an increase in spontaneous release of virus. However, the viruses recovered by cocultivation or temperature release after cell passage 45 were nearly identical. These observations suggest a possible mechanism for measles virus activation in cells latently infected with this virus.     

Distribution of the Receptor Sites for Sindbis Virus on the Surface of Chicken and BHK Cells

Sindbis virus was adsorbed to chicken cells or to BHK cells, and the distribution of virus over the surface of the cell was examined by electron microscopy of surface replicas. The distribution of virus particles on the cell was used to indicate the position of virus receptors at the cell surface. When purified Sindbis virus was adsorbed at 37 C to cells prefixed with glutaraldehyde, the virus particles were evenly distributed over the surface of most cells. There was a large variability from cell to cell, however, in the number of virus particles adsorbed, and regions with different concentrations of virus particles were sometimes observed on the same cell. The concentration of virus receptors observed varied from 20 to 160/mum(2) of cell surface, and, thus, the total number of virus receptors per chicken cell is on the order of 10(5). When virus was adsorbed to unfixed cells at 4 C, the virus particles were clustered into aggregates varying from a few particles to large crystalline arrays (the latter seen only in chicken cells). These conditions are apparently conducive to virus aggregation, and this, coupled with free lateral diffusion of the virus-receptor complex in the cell membrane at 4 C, leads to the observed clustering.     

Growth characteristics of bovine herpesvirus 1 (infectious bovine rhinotracheitis) in human diploid cell strain WI-38.

IBR virus was found to replicate in WI-38 cells. At a high input multiplicity the virus yield was comparable to that obtained in bovine cells, but comparable degree of CPE took longer to achieve. At a low input multiplicity of IBR virus, such as may be encountered in virus contaminated bovine serum, virus yield was only about 1% of that in bovine cells, with 50% of the cells showing CPE, followed by cell regrowth. Infectious virus was not recoverable from the regrown cells by 5 weeks after initial infection, and these regrown cells were susceptible to reinfection with IBR virus. Aging of WI-38 cells in cultures for as little as 1 week reduced IBR virus yield to 90% less than the yield from the same lot of cells inoculated 7 days earlier.     

Lytic and transforming functions of individual products of the adenovirus E1A gene.

To distinguish the individual roles of the 13S, 12S, and 9S adenovirus E1A gene products, we isolated the corresponding cDNA clones and recombined them into both plasmids and viruses. Only the expected E1A mRNA products were made from the corresponding 12S and 13S viruses. The 9S mRNA was detected when the 9S virus was coinfected with the 13S virus but not when either virus was infected alone. The 13S virus formed plaques equally well in 293 cells, HeLa cells, and A549 cells, a human lung oat cell carcinoma line. Plaque titers of the 12S virus were much reduced in HeLa and A549 cells compared with 293 cells, although the 12S virus is multiplicity-dependent leaky in both HeLa and A549 cells. A549 cells were significantly more permissive than HeLa cells for growth of the 12S virus. In A549 cells even at low multiplicities of infection the final yield of 12S virus eventually approached the maximum yield from 293 cells. Expression from the adenovirus early region 2 and early region 3 promoters in HeLa cells was activated in the presence of a 13S cDNA E1A region but not in the presence of a 12S E1A cDNA region. Although defective for lytic growth in HeLa cells, the 12S virus immortalized BRK cells at very high efficiency, whereas infection of these cells with 13S virus, as with wild-type E1A virus, resulted mainly in cell death. The 13S product does have an immortalization function, however, revealed in the absence of adenovirus lytic functions when a plasmid containing the E1A 13S cDNA region was transfected into BRK cells. The 9S virus failed to immortalize infected BRK cells or to interfere with focus formation when coinfected with the 12S virus.     

DNA distribution and respiratory activity of Spodoptera frugiperda populations infected with wild-type and recombinant Autographa californica nuclear polyhedrosis virus.

Spodoptera frugiperda cells were infected with a wild-type Autographa californica nuclear polyhedrosis virus and with a recombinant Autographa californica nuclear polyhedrosis virus. The recombinant virus was derived from the wild-type virus and produced beta-galactosidase instead of polyhedrin. The changes in cell size, cell growth, viability, DNA distribution, and respiratory activity were followed through the time course of the infection. The DNA content as measured by flow cytometry of infected cells increased to approximately 1.8 times the value of uninfected cells and the distributions of single-cell DNA content of the infected cells were strongly deformed. Early in the infection the respiratory activity passed through a maximum. The mitochondrial activity based on Rhodamine 123 labelling of cells infected with the recombinant virus, as determined by flow cytometry, also passed through a maximum at 24 h post infection while the mitochondrial activity of cells infected with the wild-type virus continued to increase. Evolution of single-cell mitochondrial activity was different in uninfected populations and in populations infected with wild-type and with recombinant virus. In all experiments performed, the recombinant virus influenced cell behavior and the measured parameters earlier than the wild-type virus. The influence of the multiplicity of infection was stronger for the wild-type virus than for the recombinant virus.     

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.     

Comparison of Transformation and T Antigen Induction in Human Cell Lines

Skin fibroblast cultures were established from eight individuals. These cell cultures, together with WI-38 cells, were examined for susceptibility to transformation by SV40 virus. Four transformation-susceptible cell lines (TS), established from patients with Down's syndrome, were found to be three to four times more susceptible to transformation than transformation-resistant cell lines (TR) from normal individuals. TR and TS cell lines were compared for their susceptibility to induction of SV40 T antigen. For dividing cells T antigen was detected in a higher percentage of TS cells than TR cells. For nondividing cells, the reverse was found; T antigen was detected in 10-fold more cells of the TR lines than in cells of the TS lines. Similar results were obtained after infection of cells with CELO virus. Titration of vaccinia virus and influenza virus A2/Scotland/49/57 indicated that TR and TS cells were equally sensitive to the former virus, but TR cells were three to five times more sensitive to influenza virus A2/Scotland/49/57 than were TS cells.     

Characteristics of Murayama virus in various cell cultures and laboratory animals

Some biological properties of Murayama virus, a new paramyxovirus, were studied. The virus grew well in primary monkey kidney cells as well as embryonated eggs, while the virus yields in primary chick embryo and BHK-21 cells were much lower. The infected BHK-21 cells formed large syncytia and showed typical hemadsorption, but did not produce any detectable amount of hemagglutinin in the culture fluid. The virus yields were very low in Vero. LLC-MK2 and MDCK cells at first passages. The addition of trypsin to the medium enhanced virus growth in Vero and LLC-MK2 but not in MDCK cells. Cell fusion activity of the virus was observed in Molt-4 cells. Hemolytic activity was enhanced by freeze-thawing. Several species of mammals and birds were susceptible to experimental infections with the virus as evidenced by seroconversion and positive virus isolation without showing any clinical signs.     

Formation of Viral Ribonucleic Acid and Virus in Cells that are Permissive or Nonpermissive for Murine Encephalomyelitis Virus (GDVII)

GDVII virus growth in BHK-21 cells, a permissive host for the virus, resembled productive infections with other picornaviruses. Virus yields ranged from 100 to 600 plaque-forming units (PFU)/cell. Virus replication in HeLa cells, a nonpermissive host for GDVII virus, was characterized by virus yields of only 0.1 to 5 PFU/cell. Similar low yields of virus have been obtained from HeLa cells at all multiplicities of input up to 6,000 per cell. The progeny particles from HeLa cells were, like the infecting particles, restricted in the HeLa cell host. Despite the great difference in final yields of virus from BHK-21 and HeLa cells, the times when maximal yields were reached were similar. GDVII virus stock grown in BHK-21 cells was designated HeLa(-). A variant of GDVII virus which is capable of extensive growth in HeLa cells was obtained. This variant, designated HeLa(+) GDVII virus, was passaged serially in HeLa cells. Virus yields of 50 to 150 infective virus particles per cell were obtained from infection of HeLa cells with HeLa(+) GDVII virus. The major species of HeLa(+) virus-specific ribonucleic acid (RNA) produced was single stranded and sedimented with an S value of 35S. The rate of accumulation of HeLa(+) virus-specific RNA in HeLa cell cultures was about four times that of HeLa(-) RNA. The amount of virus-specific HeLa(+) RNA formed in HeLa cells was several-fold greater than that of HeLa(-) RNA. With HeLa(-) parent GDVII virus undergoing productive replication in BHK-21 cells or abortive replication in HeLa cells, the major species of virus-specific RNA produced was single stranded and sedimented with an approximate S value of 35S. The amount of HeLa(-) virus-specific RNA extracted from BHK-21 cells was several-fold greater than the amount obtained from HeLa cells.     

A study of the functional capabilities of human neonatal lymphocytes for in vitro specific antibody production

The ability of neonatal B and T cells to participate in the in vitro production of anti-influenza virus antibody was studied. Peripheral blood mononuclear cells from nearly all normal adults produce anti-influenza virus antibody when stimulated in vitro with type A influenza virus. Cord blood mononuclear cells, however, consistently failed to do so. Using Epstein-Barr virus activation or coculture with irradiated adult T cells in the presence of influenza virus to identify precursor B cells for anti-viral antibody production, newborns were found to have a decreased number of influenza-specific B cells as compared with adults. Thus, a paucity of precursor B cells for anti-influenza virus antibody was one factor contributing to the absent in vitro antibody response. Additional studies were undertaken to investigate the capabilities of newborn T cells in the in vitro response to influenza virus. Newborn T cells failed to proliferate when cultured with influenza virus. Irradiated newborn T cells were, however, able to provide help for specific antibody production in influenza virus-stimulated cocultures with allogeneic adult B cells, and newborn T cells proliferated when stimulated with alloantigens; their helper function in allogeneic coculture was, thus, likely mediated by T cells stimulated by alloantigens rather than by influenza virus. In the absence of T cell irradiation, no antibody was produced in cocultures of adult B cells and neonatal T cells, at least in part as the result of a radiosensitive suppressor T cell. Suppression in influenza virus-stimulated allogeneic cocultures was also observed with normal adult T cells and is, therefore, a property of both newborn and adult T cells. Thus, allogeneic help and suppression can both be manifested in exogenous antigen-stimulated allogeneic cocultures. In addition, both of these allogeneic effects can be mediated by neonatal T cells, indicating that these functions are present at the time of birth and do not require previous exogenous antigenic exposure for expression.     

Effect of Puromycin and Actinomycin D on a Persistent Mumps Virus Infection In Vitro

Puromycin and actinomycin D were used to treat a line of human conjunctiva cells persistently infected with mumps virus (C-M cells) in order to determine where virus synthesis is inhibited. Although 90% of the cells in C-M cultures are infected, little or no infectious virus is produced by most cells in a growing culture. Adding puromycin to inhibit protein synthesis resulted in the production of infectious virus. Thus, all the viral proteins needed for virus completion were made in the growing cells. When actinomycin D was added to growing cells, infectious virus was again produced. Since mumps virus synthesis is actinomycin D-insensitive, this suggested a host control of the virus. Interferon was not detected. The possible mechanisms of host control are discussed.     

Response of Simian Virus 40-Transformed Cell Lines and Cell Hybrids to Superinfection with Simian Virus 40 and Its Deoxyribonucleic Acid

Whereas normal human and monkey cells were susceptible both to intact simian virus 40 (SV40) and to SV40 deoxyribonucleic acid (DNA), human and monkey cells transformed by SV40 were incapable of producing infectious virus after exposure to SV40, but displayed susceptibility to SV40 DNA. On the other hand, mouse and hamster cells, either normal or SV40-transformed, were resistant both to the virus and to SV40 DNA. Hybrids between permissive and nonpermissive parental cells revealed a complex response: whereas most hybrids tested were resistant, three of them produced a small amount of infectious virus upon challenge with SV40 DNA. All were resistant to whole virus challenge. The persistence of infectious SV40 DNA in permissive and nonpermissive cells up to 96 hr after infection was ascertained by cell fusion. The decay kinetics proved to be quite different in permissive and nonpermissive cells. Adsorption of SV40 varied widely among the different cell lines. Very low adsorption of SV40 was detected in nonsusceptible cells with the exception of the mKS-BU100 cell line. A strong increase in SV40 adsorption was produced by pretreating cells with polyoma virus. In spite of this increased adsorption, the resistance displayed by SV40-transformed cells to superinfection with the virus was maintained.     

Role of Interferon in the Propagation of MM Virus in L Cells

MM virus propagated in mouse brain replicates to low titers in L cells without production of cytopathic effect (CPE). After growing the virus in BHK-21 cells, however, the virus replicates to high titers in L cells with complete CPE. It was found that suspensions of MM virus propagated in L cells directly from the mouse brain contained much more interferon than did suspensions of virus which had first been grown in BHK-21 cells. Mouse brain suspensions of the virus were also found to contain high interferon titers. Treatment of L cells with actinomycin D before infection with mouse brain-grown virus resulted in full virus replication with CPE. BHK-21 cell-grown virus diluted in L cell interferon behaved like mouse brain-grown virus in L cells. It is concluded that the presence of interferon in the inoculum is largely responsible for the suppression of MM virus replication in L cells.     

Transformation of Rat Liver Cells with Chicken Sarcoma Virus B77 and Murine Sarcoma Virus

Rat liver cells in vitro were transformed with chicken sarcoma virus B77, giving RL(B77) cells, and with murine sarcoma virus (Harvey), giving RL(MSV) cells. Rat liver cells transformed spontaneously in vitro were designated RL cells. In addition, the RL(MSV) cell line was adapted for growth in culture fluid containing 25 mug of 5-bromodeoxyuridine per ml. All cell lines were tumorigenic in 1-wk-old rats. The number of cells needed for induction of tumor growth was 1,000-fold higher in the case of RL(B77) cells in comparison with RL(MSV) cells and RL cells. No production of viral particles from any of the cell lines investigated was detected by plating concentrated supernatant fluid of the cultures on different secondary embryo cells with and without fusion by Sendai virus, by labeling with uridine-5-(3)H, or by assay for deoxyribonucleic acid polymerase activity. The viral genome was rescued by fusion of RL(B77) cells with chicken cells. Chicken sarcoma virus rescued from (RL(B77) cells differed in plating efficiency on duck cells from B77 virus rescued from transformed rat embryo cells. No virus was rescued after fusion of RL(MSV) and RL cells with mouse, rat, or chicken embryo cells. Infectious murine sarcoma virus can be induced by 5-bromodeoxyuridine from RL(MSV) cells.     

Monoclonal antibodies suppress replication of herpes simplex virus type 1 in trigeminal ganglia.

The effect of monoclonal antibodies on the growth of herpes simplex virus type 1 in trigeminal ganglia was investigated. Four-week-old mice were infected on an abrased cornea with herpes simplex virus type 1. Forty-eight hours after infection, trigeminal ganglia ipsilateral with infected eyes were removed and placed in culture. Incubation of infected ganglia in the presence of a pool of nonneutralizing monoclonal antibodies specific for glycoproteins of gB and gE suppressed virus growth by greater than 90%. This was comparable to the amount of suppression observed when infected ganglia were incubated in hyperimmune serum. Individual monoclonal antibodies were less efficient, being able to inhibit virus growth by only two- to threefold. The mechanism of suppression was examined. Reduction in virus growth was observed under conditions in which all susceptible ganglion cells were infected in vitro before nonneutralizing monoclonal antibody was added. Similar results were obtained in tests with virus-infected neuroblastoma cells. Furthermore, suppression of infectious progeny was seen in the absence of complement and immunologically reactive cells. Thus, neither virus neutralization nor immunocytolysis could account for the effects of antibody on virus growth. Rather, the data suggest that antibody can bind to herpes simplex virus type 1-infected neuronal cells and suppress intracellular virus replication.     

Trypsin enhancement of rotavirus infectivity: mechanism of enhancement.

The infectivity of most rotaviruses is enhanced by treatment with trypsin. We studied the mechanism of enhancement of examining the effect of trypsin on rotavirus infectivity, aggregation, early interactions with host cells, and structure. The results indicated that trypsin does not increase levels of infectious virus by dispersion of aggregates or affect the efficiency or rate of attachment of virus to cells. A fraction of virus that was not infections without trypsin treatment was found to attach to cells, but did not initiate antigen synthesis. When cells were infected with labeled, purified virus, increased levels of uncoated particles were found in cells infected with trypsin-treated virus. Infection of cells with trypsin-treated virus also led to greater levels of RNA synthesis early in the infection. The results suggest that trypsin converts a noninfectious fraction of virus into infectious virus by allowing this fraction to uncoat in the infected cell. Trypsin was found to cleave an 88,000-dalton structural polypeptide of bovine rotavirus generating 67,000- and 20,000-dalton cleavage products.     

Repair and mutagenesis of herpes simplex virus in UV-irradiated monkey cells

Mutagenic repair in mammalian cells was investigated by determining the mutagenesis of UV-irradiated or unirradiated herpes simplex virus in UV-irradiated CV-1 monkey kidney cells. These results were compared with the results for UV-enhanced virus reactivation (UVER) in the same experimental situation. High and low multiplicities of infection were used to determine the effects of multiplicity reactivation (MR). UVER and MR were readily demonstrable and were approximately equal in amount in an infectious center assay. For this study, a forward-mutation assay was developed to detect virus mutants resistant to iododeoxycytidine (ICdR), probably an indication of the mutant virus being defective at its thymidine kinase locus. ICdR-resistant mutants did not have a growth advantage over wild-type virus in irradiated or unirradiated cells. Thus, higher fractions of mutant virus indicated greater mutagenesis during virus repair and/or replication. The data showed that: (1) unirradiated virus was mutated in unirradiated cells, providing a background level of mutagenesis; (2) unirradiated virus was mutated about 40% more in irradiated cells, indicating that virus replication (DNA synthesis?) became more mutagenic as a result of cell irradiation; (3) irradiated virus was mutated much more (about 6-fold) than unirradiated virus, even in unirradiated cells; (4) cell irradiation did not change the mutagenesis of irradiated virus except at high multiplicity of infection. High multiplicity of infection did not lead to higher mutagenesis in unirradiated cells. Thus the data did not demonstrate UVER or MR alone to be either error-free or error-prone. When the two processes were present simultaneously, they were mutagenic.     

Generation of defective interfering particles of Semliki Forest virus in a clone of Aedes albopictus (mosquito) cells.

Serial undiluted passage of Semliki Forest virus in a clone of Aedes albopictus cells resulted in a marked decrease in infectious virus yields due to the generation and accumulation of defective interfering particles. Virus from the third passage had a high particle/infectivity ratio and interfered specifically with homologous but not heterologous standard virus replication. Two RNA species of molecular weights 0.78 X 10(6) and 0.61 X 10(6) were the major RNA components of purified passage 4 virus. These RNA species were also the predominant virus RNA species detected in cells infected with passage 3 virus. Synthesis of standard virus RNA and virus-specified protein was much reduced in passage 3 virus-infected cells. Interference with standard virus replication and the synthesis of large amounts of defective interfering RNA were also observed in chicken embryo cells infected with passage 3 virus from mosquito cells.     

Host cell reactivation by excision repair is error-free in human cells

Do host cell repair processes affect the mutagenesis of UV-irradiated virus in human cells? The answer was obtained by investigating the mutagenesis of UV-irradiated herpes simplex virus after the irradiated virus was grown in human cells that possess normal repair capacity (normal) or lack excision repair (XPA) or post-replication repair (XP var). Evidence is presented which indicate that XPA cells express no host cell reactivation, while XP var cells express the normal level. Viral mutagenesis was measured as the fraction of the progeny of the surviving virus capable of plaque formation in the presence of iododeoxycytidine. In the normal and XPA cells mutagenesis of the irradiated virus increased linearly with UV exposure. The UV exposure needed to yield a given mutagenesis level for virus grown in XPA cells was much lower than that for virus grown in normal cells. However, when the mutation frequencies were compared at similar virus survival levels, the data from virus grown in normal cells and in XPA cells were indistinguishable. Mutagenesis in XP var cells increased as dose squared and was similar in magnitude to that in normal cells. Thus the excision repair of normal cells which provided host cell reactivation by removing lethal UV damage also removed mutagenic lesions from the virus with the same efficiency, while the repair deficiency of XP var cells had a minor role in host cell reactivation and in mutagenesis. This demonstrates that in human cells host cell reactivation by excision repair is primarily an error-free process.