Adenovirus Susceptibility to Human Interferon During One-Step Replication

Susceptibility of adenovirus types 2, 7, and 12 to human interferon was measured in three human diploid cell strains during a single-cycle infection. Although the relative susceptibility of adenovirus to interferon varied in these cell strains, the final yield of each type in each cell strain decreased as the interferon dose increased. On the other hand, wide difference in interferon susceptibility of adenoviruses and vesicular stomatitis virus (VSV) was noted, as interferon doses above 100 units profoundly inhibited VSV but not the adenoviruses.     

Persistence of vesicular stomatitis virus in interferon-treated cell cultures.

A significant difference was observed in the functional stability of the vesicular stomatitis virus (VSV) genome in mouse L cells and the RK-13 line of rabbit kidney cells pretreated with homologous interferon. By utilizing the ability of vaccinia to rescue VSV from the inhibitory effects of interferon in these cell lines, it was demonstrated that there was a loss of a rescuable form of VSV genome in RK-13 cells pretreated with interferon; superinfection with vaccinia 24 hr after VSV infection did not result in a significant increase in VSV yield. In contrast, significant rescue of VSV occurred in interferon-treated L cells superinfected with vaccinia as late as 72 hr after VSV infection.The present study also provides evidence that in interferon-treated RK-13 cells doubly infected with VSV and vaccinia there was a correlation of the rescuability of the VSV genome and its ability to direct RNA synthesis.     

Differences in the response of normal and transformed BHK21 cells to dual virus infection. Conditions affecting synergism between vesicular stomatitis virus and newcastle disease virus

Polyoma-transformed BHK21 cells were less sensitive than untransformed BHK21 cells to plaque production by vesicular stomatitis virus (VSV) although neither the adsorption of the input virus to transformed cells nor the burst size were found to be reduced. Infection of either cell type with an avirulent strain (BI) of Newcastle disease virus (NDV) resulted in only a single cycle of noninfectious NDV hemagglutinin production. Neither BHK21 cells nor a polyoma-transformed clonal derivative (Cl-I) produced detectable interferon in response to NDV infection. On the contrary, dual infection with NDV and VSV resulted in a paradoxical enhancement of VSV plaque number and size in Cl-I but not in BHK21 cells. The degree of synergism was affected by the density of Cl-I cell cultures, by NDV multiplicity, and by the time interval between NDV and VSV infection. These findings suggest that alteration of cell functions affecting cellular sensitivity to single (VSV) and also dual (NDV-VSV) infection may be associated with the virus-transformed state.     

The use of vesicular stomatitis virus pseudotype production in the study of a temperature-sensitive murine leukemia virus.

A mutant of Moloney murine leukemia virus (MoLV), designated ts₃ was recently shown to have a temperature-sensitive defect associated with the release of mature virus particles budding from the cell membrane [Wong, P. K. Y., and McCarter, J. A., Virology58, 396–408 (1974)]. In an attempt to determine whether the defective function resides in an envelope component of the virion, the formation of pseudotypes between VSV and ts₃ was studied under nonpermissive and permissive conditions of ts₃ infection. Whereas similar levels of phenotypic mixing were observed between VSV and wild-type MoLV at both 39 and 34°, the level of pseudotypes formed between VSV and ts₃ was found to be considerably lower at 39° (nonpermissive temperature) than at 34° (permissive temperature). The results of temperature-shift experiments indicate that two separate blocks to VSV ts₃ pseudotype production may occur depending on the length of time ts₃-infected cells are incubated at the nonpermissive temperature. Preincubation of ts₃-infected cells for 24 hr at 39°, prior to superinfection with VSV at 39°, prevents pseudotype formation. In contrast, brief incubation at 39°C, coincident with VSV infection, introduces a reversible block on the release of VSV (ts₃) pseudotypes from the cell membrane. Complementation of ts₃ through ts₃ (VSV) pseudotype production was not detected at the nonpermissive temperature.     

Further characterization of proteins assembled by vesicular stomatitis virus from human tumor cells

Vesicular stomatitis virus (VSV), when reproduced in human tumor cell lines, assembled a specific subset of cell-derived proteins. These were detected by [³⁵S]methionine labeling of cells prior to infection and subsequent immunoprecipitation of VSV grown in these cells, as well as by direct immunoprecipitation of labeled cell extracts with antiserum directed against the VSV-assembled proteins. Their molecular weight (M_r) ranged between 15K and 180K; the larger proteins were glycosylated. Two of the major protein species (gp88 and gp130) were common to all four cell lines used (HeLa—cervical carcinoma, T47D—breast carcinoma, and HMB2 and SK1477—two melanoma cell lines). Proteins of other molecular weights were detected only in one or two of the cell lines. The melanoma cell lines (even in the absence of VSV) shed large particulate material which had contained the same spectrum of proteins that were assembled by VSV. The major protein component had an M_r of 30K. Some of the VSV-assembled proteins might possibly serve as specific tumor markers. It is also conceivable that the proteins assembled by VSV as well as the large particulate material might be products of defective endogenous human retroviruses.     

Prolonged infection of L cells with vesicular stomatitis virus. Defective interfering forms and temperature-sensitive mutants as factors in the infection.

When L_y cells were treated with 100 units per milliliter of mouse interferon and then infected with vesicular stomatitis virus (VSV) at a multiplicity of 10–60 PFU/cell, a prolonged infection of cultures ensued, lasting in one case longer than 60 days. After four passages in L_y cells at high multiplicities of VSV from a prolonged infection, there was no inhibition of virus growth, and virus from the prolonged infection had the same distribution of intracellular and extracellular RNA forms as was found in wild-type virus passed four times in L_y cells. Also, the intracellular and extracellular RNA forms of virus taken directly from a prolonged infection of L_y cells were indistinguishable from those of the wild-type virus. A morphological examination of VSV from a prolonged infection did not show a significant number of small defective viral forms after four passages in L_y cells at a high multiplicity of infection. There was, however, evidence for the emergence of temperature-sensitive mutants of VSV during the course of the prolonged infection. Changing the incubation temperature of the cultures from 37° to 32° resulted in an increase in virus production and virus-induced cytopathology. The virus produced during prolonged infections grew to higher titers at 32° than at 37° and its plaque size at 39° progressively decreased with the length of time that the infection persisted. Furthermore, interferon production also seemed to have a role in the persistence of infections such as the treatment of cultures with rabbit anti-mouse interferon globulin and resulted in a significant rise in virus production and viral cytopathology in the cell cultures.     

Genetic variability and integration of Merkel cell polyomavirus in Merkel cell carcinoma

Puumala (PUUV) and Hantaan (HTNV) viruses are hantaviruses within the family Bunyaviridae and associated with Hemorrhagic Fever with Renal Syndrome (HFRS) in humans. Little is known about how these viruses interact with host cells, though pathogenic hantaviruses interact with α_vβ₃ integrin. To study host cell interactions and rapidly test the ability of antibodies to prevent infection, we produced HTNV and PUUV pseudovirions on a vesicular stomatitis virus (VSV) core. Similar to replication-competent hantaviruses, infection was low-pH-dependent. Despite broad cell tropism, several human T cell lines were poorly permissive to hantavirus pseudovirions, compared to VSV, indicating a relative block to infection at the level of entry. Stable expression of α_vβ₃ integrin in SupT1 cells did not restore infectivity. Finally, the pseudovirion system provided a rapid, quantitative, and specific method to screen for neutralizing antibodies in immune sera.     

The relationship between autointerference and the replication of defective interfering particle.

The amounts of progeny infective (B) and defective (DI) vesicular stomatitis virus (VSV) particles released from cells undergoing standard and autointerfered infections were measured. In experiments using DI₀₁₁, an unusual DI particle containing self-complementary RNA, the maximum yield of progeny DI particles was obtained from cultures infected with so little DI that they showed no signs of autointerference (measured as the reduced yield of standard-size virus or plaque-forming units). Increasing the amount of infecting DI particles above this level did not appreciably affect the yield of DI particles, but did severely diminish the number of infectious progeny particles. The helper function necessary for the replication of the Indiana serotype DI particles which we have used can be supplied by the New Jersey serotype VSV. Surprisingly, much greater amounts of progeny DI particles are obtained from this heterotypic infection than from the homotypic one. Despite the high level of DI replication, very little interference is observed. These results indicate that DI₀₁₁ replication and autointerference are not mutually dependent phenomena.     

Recent vesicular stomatitis virus infection detected by immunoglobulin M antibody capture enzyme-linked immunosorbent assay.

We developed an enzyme-linked immunosorbent assay (ELISA) that was capable of detecting immunoglobulin M (IgM) antibody to vesicular stomatitis virus (VSV) in the sera of experimentally and naturally infected cattle and horses. The detection of IgM in the sera of these animals permitted an estimate of the recency of infection by VSV serotype New Jersey. A VSV serotype New Jersey epizootic strain isolated from a horse and passed once in an Aedes albopictus cell line was used to infect a horse and a calf. Sera from these animals were used to standardize the ELISA. This assay was used to test sera from cattle and horses involved in the 1982 VSV epizootic. Comparative antibody titrations were performed by three systems: the serum-dilution plaque-reduction neutralization, complement fixation, and indirect immunofluorescent tests. The antibody titers by neutralization and the ELISA were comparable for the period that IgM was present; when IgM ELISA titers diminished, the neutralization titers remained high. The complement fixation and indirect immunofluorescent antibody titers followed closely the IgM pattern determined by the ELISA. The capture IgM ELISA is applicable for the rapid detection of IgM antibody to VSV in cattle and horses and is a useful assay of recent infection.     

Productive entry of type C foot-and-mouth disease virus into susceptible cultured cells requires clathrin and is dependent on the presence of plasma membrane cholesterol

We have characterized the entry leading to productive infection of a type C FMDV in two cell lines widely used for virus growth, BHK-21 and IBRS-2. Inhibition of clathrin-mediated endocytosis by sucrose treatment decreased both cell entry and virus multiplication. Evidence of a direct requirement of clathrin for productive viral entry was obtained using BHK21-tTA/anti-CHC cells, which showed a significant reduction of viral entry and infection when the synthesis and functionality of clathrin heavy chain was inhibited (Tet- cells). This was also observed for vesicular stomatitis virus (VSV) productive entry. The effect of NH(4)Cl and concanamycin A on FMDV entry and infection was consistent with the requirement of acidic compartments for decapsidation and virus replication. As expected from its higher stability at acidic pH, this requirement was higher for VSV. Since BHK-21 and IBRS-2 cells expressed caveolin-1, we explored the effect on productive virus entry of drugs that interfere with caveolae-mediated endocytosis. Treatment with nystatin did not reduce entry and infection of FMDV or VSV, while cholesterol depletion with MbetaCD significantly inhibited both steps of the FMDV cycle, indicating that plasma membrane cholesterol is required for virus productive entry.     

Comparative susceptibilities of human embryonic fibroblasts and HeLa cells for isolation of human rhinoviruses.

The recovery of human rhinovirus (HRV) from nasal washings and nasal and pharyngeal swabs from volunteers with naturally acquired colds was compared in different cell types. Human embryonic lung fibroblast (HELF) strain WI-38 (sensitivity, 61 to 84%) and HeLa-I, an HRV-susceptible HeLa clone (sensitivity, 86 to 94%), were the most sensitive cell types used. HELF-WI-38 cells showed a cytopathic effect earlier than the other cells used, and the different strains of HRV-susceptible HeLa cells varied in their sensitivities for HRV isolation. HRV was detected in a single cell type in 20 to 35% of the positive samples, suggesting that use of a combination of different HRV-susceptible cell lines is the best approach for the recovery of HRV. Although nasal washings tended to yield more HRV isolates than nasal and pharyngeal swabs, the two sampling methods were not found to be significantly different.     

Pseudotypes of vesicular stomatitis virus-bearing envelope antigens of certain HIV-1 strains permissively infect human syncytiotrophoblasts cultured in vitro: implications for in vivo infection of syncytiotrophoblasts by cell-free HIV-1

Intrauterine infection of the fetus is clearly an important mode of vertical transmission of human immunodeficiency virus type 1 (HIV-1). The syncytiotrophoblast layer of the human placenta must be traversed by HIV-1 in order to reach underlying cells and fetal capillaries. Although HIV-1 has been detected in the syncytiotrophoblast layer in situ, there is conflicting evidence regarding infection of syncytiotrophoblast cells with cell-free virus. The phenotypic mixing between HIV-1 and vesicular stomatitis virus (VSV) has been exploited to assay the susceptibility of human term syncytiotrophoblast cells to penetration by various strains of HIV-1. VSV(HIV-1(IIIB)) and VSV(HIV-1(Ba-L)) pseudotypes were found to enter syncytiotrophoblast cells. In contrast, VSV pseudotyped with envelope glycoproteins of RF, MN, or Ada-M strains of HIV-1 did not infect syncytiotrophoblasts. Plating efficiency of VSV(HIV-1(IIIB)) and VSV(HIV-1(Ba-L)) was 10-fold lower on syncytiotrophoblasts than on T-cells and macrophages, respectively. Incubation of VSV(HIV-1(IIIB)) and VSV(HIV-1(Ba-L)) viruses with appropriate HIV-1 neutralizing sera before infection strongly inhibited entry of pseudotyped VSV into syncytiotrophoblast cells. These findings demonstrated that infection of syncytiotrophoblasts with VSV(HIV-1) pseudotypes was mediated by Env from IIIB and Ba-L strains of HIV-1. Monoclonal antibodies (MAb) to CD4, CXCR4, CCR5, and CCR3 were tested for their ability to block VSV(HIV-1) infection of syncytiotrophoblast cells. Neither the anti-CD4 nor the anti-CXCR4, anti-CCR5, and anti-CCR3 MAb had any inhibitory effect on infection of syncytiotrophoblast cells with VSV(HIV-1) pseudotypes. Results from this study suggest that cell-free HIV-1 can enter syncytiotrophoblasts and the susceptibility of these cells to penetration by the virus is strain dependent. Pseudotype infection merely demonstrates that the first steps in HIV-1 replication are possible in syncytiotrophoblast cells.     

An acquired immune suppression in mice caused by infection with lymphocytic choriomeningitis virus

A murine model of virally induced acquired immunodeficiency was analyzed in mice. The effect of systemic infection with various isolates of lymphocytic choriomeningitis virus (LCMV) on the capacity of mice to mount a T cell-independent IgM and a T cell-dependent IgG neutralizing antibody response against a subsequent infection with vesicular stomatitis virus (VSV) was analyzed. DBA/2 mice infected with the LCMV-WE isolate were impaired in their IgM and IgG responses to VSV. Immune suppression was not caused by interferons inhibiting proper VSV antigen expression, since responses to inactivated VSV were also suppressed. The higher the dose of the LCMV and the lower the dose of the challenging VSV infection the more drastic was the apparent lack of immune responsiveness and the longer it lasted. Kinetics of induction of suppression of the T cell-independent IgM responses closely followed that of a normal cytotoxic T cell response to LCMV-WE, starting on day 6 and reaching maximal levels by day 8 to 10. The T cell-dependent IgG response to VSV was suppressed with a kinetics that was shifted by about 6 days when compared with suppression of IgM responses, i.e. LCMV infection on the same day or before (but not after) VSV infection led to suppression of IgG responses that are usually first detected by day 6-7 after initiation of the VSV infection. Severity and duration of immunosuppressiveness depended upon the LCMV isolate and the mouse strain used: LCMV-WE and LCMV-Docile were most, whereas LCMV-Armstrong was in general least immunosuppressive. Antibody responses to VSV-NJ seemed to be more subject to LCMV-induced immune suppression than VSV-IND-specific responses. Mouse strains differed considerably with respect to extent of suppression, dependent upon both major histocompatibility genes (MHC) and non-MHC genes. DBA and Swiss type mice were generally more susceptible than C57BL and CBA mice, and H-2q and H-2k seemed to be more susceptible than H-2b or H-2d mice. Mice infected with LCMV-WE showed signs of acquired immunodeficiency diseases since they were more susceptible to superinfection with VSV and developed paralytic disease and tended to die from VSV infection. Since LCMV is basically a noncytopathic virus, this murine model of virally induced immune suppression may serve to analyze immune pathogenesis of virus-induced acquired immunodeficiency.     

Inducible Vesicular Stomatitis Virus (VSV) L Cell Line for Packaging of Recombinant VSV

Recently, recombinant vesicular stomatitis viruses (VSV) have been developed as high-level expression vectors which serve as effective vaccine vectors in animals. An ideal approach for VSV vector production would be the development of stable packaging cell lines that can produce vector particles without transfection step. In this report, we describe generation of an inducible cell line that expresses the VSV polymerase gene (L) under the control of the reverse tetracycline-controlled transactivator (rtTA) system as a first step to make VSV-based packaging cell lines. Integrated polymerase (L) gene was controlled by an rtetR-dependent promoter in the rtTA-producing BHK cell line. When the cell lines were cultured in the presence of tet (tetracycline) or tetracycline derivative doxycycline, the recombinant VSV and wild type VSV were replicated, whereas in the absence of tet or tetracycline derivative doxycycline, the recombinant VSV was not replicated. Viral supernatants were harvested, diluted, and monitored by plaque assay for the presence of infectious VSV. Plaques of VSV containing an additional sequence encoding the EGFP protein allowed rapid detection of infection. Our results suggest wide applications of other surrogate viruses based on VSV. The availability of stable packaging cell lines represents a step toward the use of a VSV vector delivery system that can allow scale-up production of vector-stocks for gene therapy.     

RNA adenosine deaminase ADAR1 deficiency leads to increased activation of protein kinase PKR and reduced vesicular stomatitis virus growth following interferon treatment

Two size forms of ADAR1 adenosine deaminase are known, one constitutively expressed (p110) and the other interferon (IFN)-induced (p150). To test the role of ADAR1 in viral infection, HeLa cells with ADAR1 stably knocked down and 293 cells overexpressing ADAR1 were utilized. Overexpression of p150 ADAR1 had no significant effect on the yield of vesicular stomatitis virus. Likewise, reduction of p110 and p150 ADAR1 proteins to less than ∼10 to 15% of parental levels (ADAR1-deficient) had no significant effect on VSV growth in the absence of IFN treatment. However, inhibition of virus growth following IFN treatment was ∼1 log₁₀ further reduced compared to ADAR1-sufficient cells. The level of phosphorylated protein kinase PKR was increased in ADAR1-deficient cells compared to ADAR1-sufficient cells following IFN treatment, regardless of viral infection. These results suggest that ADAR1 suppresses activation of PKR and inhibition of VSV growth in response to IFN treatment.     

Varied responses of human B-lymphoblastoid cell lines to infection with vesicular stomatitis virus

Previous studies carried out with a limited number of human lymphoblastoid cell lines of B-cell origin concluded that B cells were relatively insensitive to cell killing by vesicular stomatitis virus (VSV) (Nowakowski et al., J. Virol.12, 1272–1278, 1973; Creager et al., Virology111, 211–222, 1981). The B-cell lines employed in those studies all contained endogenous Epstein-Barr virus (EBV). The present investigation was carried out using additional B-cell lines with and without endogenous EBV genomes. It was found that the presence of EBV in human B-lymphoblastoid cells has a marked influence on the outcome of infection by VSV. In the EBV-negative B-cell lines, few, if any, cells survived VSV infection. The EBV-positive B-cell lines responded quite differently: much less cytopathology occurred, and persistent infections invariably were established. These findings suggest that EBV may play a critical role in the response of human B-lymphoblastoid cell lines to VSV infection, especially in regard to cell killing and the establishment of VSV persistence. Although there was a striking difference in the ability of VSV to kill EBV-positive and EBV-negative B-cell lines, there was no correlation between cell destruction and the amount of viral RNA or progeny virus synthesized.     

Restriction of vesicular stomatitis virus in a nonpermissive rabbit cell line is at the level of protein synthesis

Replication of vesicular stomatitis virus (VSV) is restricted in a line of rabbit cornea (RC-60) cells; less than one infectious particle is produced per infected cell. We show that VSV is blocked at the level of viral-specific protein synthesis. VSV proteins are synthesized early in infection but the rate of VSV protein synthesis declines rapidly as infection proceeds. At times when synthesis of VSV proteins is barely detectable, VSV mRNA is produced and polyribosome structures are present. The VSV mRNA recovered from the polysome region directs the synthesis of VSV proteins in an in vitro reticulocyte translation system. This suggests that protein synthesis is blocked at some step beyond the level of initiation possibly at the level of elongation. Coinfection with vaccinia virus converts RC-60 cells to a permissive host. In contrast to the abortive infection with VSV alone, VSV proteins are synthesized throughout the replication cycle in doubly infected cells. Vaccinia supplies a product essential for sustained protein synthesis in the abortive system. We have confirmed that the replication of genome length 42 S RNA does not occur at late times in the abortive infection. This lack of 42 S RNA replication is explained by the shut-off of VSV protein synthesis, since continuous protein synthesis is required for the replication of VSV 42 S RNA.     

Matrix protein mutations contribute to inefficient induction of apoptosis leading to persistent infection of human neural cells by vesicular stomatitis virus

In a model system to study factors involved in the establishment of a persistent viral infection that may lead to neurodegenerative diseases, Indiana and New Jersey variants of vesicular stomatitis virus (VSV) with different capacities to infect and persist in human neural cells were studied. Indiana matrix (M) protein mutants and the wild-type New Jersey strain persisted in the human neural cell line H4 for at least 120 days. The Indiana wild-type virus (HR) and a non-M mutant (TP6), both unable to persist, induced apoptosis more strongly than all the other variants tested, as indicated by higher levels of DNA fragmentation and caspase-3-like activity. Transfection of H4 cells with mRNA coding for the VSV M protein confirmed the importance of this protein in the induction of apoptosis. Furthermore, the pan-caspase inhibitor ZVAD-fmk maintained cell survival to about 80%, whereas inhibition of caspase-8, caspase-9, or both only partially protected the cells against death, consistent with the fact that anti-apoptotic molecules from the Bcl-2 family also protect cells from death only partially. These results suggest that VSV activates many pathways of cell death and that an inefficient induction of caspase-3-related apoptosis participates in the establishment of a persistent infection of human neural cells by less virulent VSV variants.     

Different pH requirements for entry of the two picornaviruses,human rhinovirus 2 and murine encephalomyocarditis virus

The entry into cells of human rhinovirus 2 (HRV 2) and murine encephalomyocarditis (EMC) virus was studied by the use of light-sensitive virus grown in the presence of acridine orange (HRV 2) and neutral red (EMC). HeLa cells were protected against infection with HRV 2 by NH₄Cl, monensin, and other compounds known to increase the pH of intracellular vesicles. Preincubation of the cells with the same compounds reduced the ability of the cells to bind [³⁵S]methionine-labeled HRV 2, apparently due to inhibition of recycling of endocytosed receptors back to the cell surface. The cells were also protected against infection when HRV 2 was bound to cells on ice and the cells were then incubated at 37° with the different compounds. This indicates that low pH is also necessary for some event in the entry process taking place after the virus is bound to the cells. In contrast, compounds which increase the pH in acidic intracellular compartments did not protect mouse L-cells against infection with EMC-virus, and the entry of the virus was inhibited by low pH in the medium. This inhibition was partly overcome by the presence of the ionophore monensin, which elevates the pH in endosomes and lysosomes. Possibly, EMC virus enters the cytosol from vesicles with neutral or slightly alkaline pH.