Inhibition of vesicular stomatitis virus replication in dexamethasone-treated L929 cells

We previously demonstrated that dexamethasone treatment of L929 cells inhibited plaque formation by vesicular stomatitis virus (VSV), encephalomyocarditis virus, or vaccinia virus. We now have characterized the antiviral effects of glucocorticoids in L929 cells. Dexamethasone did not directly inactivate VSV nor did steroid treatment of L929 cells affect virion adsorption or penetration. The VSV yield in L929 cells treated with dexamethasone for a period of only 4 or 8 hr was decreased by 50% when cells were infected the day following steroid treatment. Treating L929 cells with dexamethasone for a longer period resulted in greater inhibitions of virus synthesis. Interferon activity (less than 5 units/ml) was not detected in L929 cell culture fluids and cell sonicates from steroid-treated cells and the addition of antiserum to murine alpha/beta-interferon had no effect on the ability of dexamethasone to inhibit VSV replication. Dexamethasone treatment of L929 cells did not induce the production of double-stranded RNA-dependent protein kinase but did result in a slight elevation of 2-5A oligoadenylate synthetase activity, two enzymatic activities associated with the antiviral state induced by interferon. However, the elevated 2-5A synthetase activity was not associated with an inhibition of VSV RNA accumulation in dexamethasone-treated L929 cells. By contrast, the synthesis of all five VSV proteins was reduced by 50-75% in dexamethasone-treated L929 cells as early as 4 hr after infection. Thus, the dexamethasone-mediated inhibition of VSV replication in L929 cells is associated with decreased production of VSV structural proteins.     

The target reaction in the antiviral action of mouse interferon against vesicular stomatitis virus multiplication

Treatment of mouse L929 cells with mouse interferon (IFN) lowered the yield of vesicular stomatitis virus (VSV) in a dose-dependent manner. Accumulation of viral proteins was severely inhibited in IFN-treated cells, whereas cellular protein synthesis was not, indicating that the virus-induced shutoff of cellular protein synthesis was prevented by IFN. In order to identify the major target of IFN action precisely, the effect of IFN treatment on the synthesis of viral RNAs and proteins at various stages during the course of viral replication was examined. Accumulation of viral RNAs late in infection was inhibited, as was the case with viral proteins, but the synthesis of leader RNA and mRNAs early in infection was not significantly inhibited by treatment with a moderate dose of IFN. On the other hand, viral protein synthesis at an early stage of infection was strongly inhibited by IFN. The results indicate that the major target reaction of antiviral action of IFN against VSV multiplication is the translation of viral mRNA.     

ISG20, a new interferon-induced RNase specific for single-stranded RNA,defines an alternative antiviral pathway against RNA genomic viruses

Interferons (IFNs) encode a family of secreted proteins that provide the front-line defense against viral infections. Their diverse biological actions are thought to be mediated by the products of specific but usually overlapping sets of cellular genes induced in the target cells. We have recently isolated a new human IFN-induced gene that we have termed ISG20, which codes for a 3' to 5' exonuclease with specificity for single-stranded RNA and, to a lesser extent, for DNA. In this report, we demonstrate that ISG20 is involved in the antiviral functions of IFN. In the absence of IFN treatment, ISG20-overexpressing HeLa cells showed resistance to infections by vesicular stomatitis virus (VSV), influenza virus, and encephalomyocarditis virus (three RNA genomic viruses) but not to the DNA genomic adenovirus. ISG20 specifically interfered with VSV mRNA synthesis and protein production while leaving the expression of cellular control genes unaffected. No antiviral effect was observed in cells overexpressing a mutated ISG20 protein defective in exonuclease activity, demonstrating that the antiviral effects were due to the exonuclease activity of ISG20. In addition, the inactive mutant ISG20 protein, which is able to inhibit ISG20 exonuclease activity in vitro, significantly reduced the ability of IFN to block VSV development. Taken together, these data suggested that the antiviral activity of IFN against VSV is partly mediated by ISG20. We thus show that, besides RNase L, ISG20 has an antiviral activity, supporting the idea that it might represent a novel antiviral pathway in the mechanism of IFN action.     

Large-population passages of vesicular stomatitis virus in interferon-treated cells select variants of only limited resistance.

Vesicular stomatitis virus (VSV) populations were repeatedly passaged in L-929 cells treated with alpha interferon (IFN-alpha) at levels of 25 U/ml. This IFN-alpha concentration induced a 99.9% inhibition of viral yield in standard infections. Analysis of viral fitness (overall replicative ability measured in direct competition with a reference wild-type VSV) after 21 passages in IFN-treated cells showed only a limited increase or no increase in fitness, compared with the greater increase upon parallel passage in cells not treated with IFN-alpha. However, this limited increase in fitness was more pronounced when competition assays were carried out with IFN-alpha-treated cells, suggesting the selection of VSV populations with a low level of resistance to IFN-alpha. Thus, despite the extensively documented capacity of VSV to adapt to changing environments, the antiviral state induced by IFN-alpha imposes adaptive constraints on VSV which are not readily overcome.     

Biological activity of oligonucleotide-poly(L-lysine) conjugates: mechanism of cell uptake

We have previously shown that antisense oligomers linked to poly(L-lysine) (PLL) exhibit antiviral properties against vesicular stomatitis virus (VSV) at concentrations lower than 1 microM. The conjugation to PLL provides an interesting alternative to natural or neutral oligomers to increase the biological effects of antisense oligomers. The internalization pathway of oligomer-PLL conjugates as compared to unconjugated oligomers has been studied in L929 cells. In parallel to their enhanced antiviral activity, PLL increases greatly the uptake of fluorescently tagged oligomers. This internalization follows a classical endocytic pathway and the oligomer has to be cleaved from PLL in the cell to exhibit an antiviral effect.     

Regulation of the antiviral and anticellular activities of interferon by exogenous double-stranded RNA

The effects of double-stranded RNA (dsRNA) on interferon (IFN)-induced antiviral and anticellular activities was investigated by introducing poly(I)-poly(C) into mouse L-cells. Coprecipitation of dsRNA with calcium phosphate enabled its efficient penetration into cells in culture. Rate of cellular protein synthesis was inhibited by dsRNA only in cultures pretreated with IFN. Moreover, the anticellular effect of IFN, as measured by the inhibition of cell DNA synthesis, was also enhanced by dsRNA. The kinetics of dsRNA-mediated inhibition of protein synthesis were relatively slow as compared with the inhibitory effect of 2'-5' oligoadenylic acid (2'5'A), which was also introduced into cells by the calcium phosphate coprecipitation technique. To analyze the effects of dsRNA on the antiviral state induced by IFN, vesicular stomatitis virus (VSV) and encephalomyocarditis virus (EMC), replications were followed by measuring viral-specific RNA synthesis in the cell. Introduction of dsRNA after the infection had no effect on VSV and EMC replication in control cells, and it enhanced, to a small extent, the antiviral state of cells pretreated with IFN. In contrast, introduction of 2'5'A into virus-infected cells inhibited VSV and EMC replications regardless of IFN pretreatment. This work demonstrated that the role of dsRNA in regulating the antiviral and anticellular activities of IFN could be studied by introducing exogenous dsRNA into cells in culture by the calcium phosphate coprecipitation technique.     

Different interferon-producing capacities of L929 cell sublines and the enhancement of interferon production by priming are controlled pretranslationally

Two sublines of mouse L929 cells designated L929B and L929M were studied. The L929B cells, which displayed a 2-3-fold higher IFN production in response to Sendai virus than that of the L929M cells, had a higher sensitivity to the antiviral and priming effects of IFN and were more resistant to VSV. In good accord with the amount of IFN produced, more translatable IFN mRNA was isolated from the L929B cells. IFN production and IFN mRNA activities were proportionally increased in the IFN-primed cultures of both sublines. Results indicate that both inherent and priming-induced increased-IFN production are based on pretranslational control mechanisms.     

Both 2',3'-dideoxythymidine and its 2',3'-unsaturated derivative (2',3'-dideoxythymidinene) are potent and selective inhibitors of human immunodeficiency virus replication in vitro

2',3'-Dideoxythymidine (ddThd) and its 2',3'-unsaturated derivative 2',3'-dideoxythymidinene (ddeThd) are potent and selective inhibitors of human immunodeficiency virus (HIV) in vitro. When evaluated for their inhibitory effects on the cytopathogenicity of HIV in MT-4 cells, ddThd and ddeThd completely protected the cells against destruction by the virus at a concentration of 1 microM and 0.04 microM, respectively. In this aspect, ddeThd was about 5 times more potent than 2',3'-dideoxycytidine (ddCyd), one of the most potent and selective anti-HIV compounds now pursued for its therapeutic potential in the treatment of AIDS. ddThd and ddeThd also suppressed HIV antigen expression at 1 microM and 0.04 microM, respectively. Their selectivity indexes, as based on the ratio of the 50% cytotoxic dose to the 50% antiviral effective dose, were 120 (ddeThd) and greater than 625 (ddThd).     

Homologous interference of lymphocytic choriomeningitis virus involves a ribavirin-susceptible block in virus replication.

Depending on the multiplicity of infection (MOI), infection of L929 cells results in either productive lymphocytic choriomeningitis virus replication or homologous interference M. Bruns, A. Gessner, H. Lother, and F. Lehmann-Grube, Virology 166:133-139, 1988). As shown in this communication, productive lymphocytic choriomeningitis virus replication as observed at a low MOI was effectively inhibited by ribavirin. In contrast, virus yields increased if cells were infected with a high MOI and in the presence of 5 microM of the antiviral compound. This drug-dependent release of infectious virus was preceded by enhanced nucleoprotein (NP) synthesis, a change in intracellular NP distribution, and by an onset of glycoprotein synthesis. It is therefore proposed that this block in viral replication is brought about by a posttranslational effect on a viral gene product, probably the NP, present in reasonably large quantities both during homologous interference as well as persistent infection.     

2',3'-Dideoxythymidine 5'-triphosphate inhibition of DNA replication and ultraviolet-induced DNA repair synthesis in human cells: evidence for involvement of DNA polymerase delta

It is well established that DNA replication and ultraviolet-induced DNA repair synthesis in mammalian cells are aphidicolin-sensitive and thus are mediated by one or both of the aphidicolin-sensitive DNA polymerases, alpha and/or delta. Recently, it has been shown that DNA polymerase delta is much more sensitive to inhibition by the nucleotide analogue 2',3'-dideoxythymidine 5'-triphosphate (ddTTP) than DNA polymerase alpha but is less sensitive than DNA polymerase beta [Wahl, A. F., Crute, J. J., Sabatino, R. D., Bodner, J. B., Marraccino, R. L., Harwell, L. W., Lord, E. M., & Bambara, R. A. (1986) Biochemistry 25, 7821-7827]. We find that DNA replication and ultraviolet-induced DNA repair synthesis in permeable human fibroblasts are also more sensitive to inhibition by ddTTP than polymerase alpha and less sensitive than polymerase beta. The Ki for ddTTP of replication is about 40 microM and that of repair synthesis is about 25 microM. These are both much less than the Ki of polymerase alpha (which is greater than 200 microM) but greater than the Ki of polymerase beta (which is less than 2 microM). These data suggest that DNA polymerase delta participates in DNA replication and ultraviolet-induced DNA repair synthesis in human cells.     

Virus inactivation by anilinonaphthalene sulfonate compounds and comparison with other ligands

Bis-(8-anilinonaphthalene-1-sulfonate) (bis-ANS) causes inactivation of vesicular stomatitis virus (VSV) at micromolar concentrations while butyl-ANS and ANS are effective at concentrations one and two orders of magnitude higher, respectively. VSV fully inactivated by the combined effects of 10 microM bis-ANS and 2.5 kbar hydrostatic pressure elicited a high titer of neutralizing antibodies. Incubation of VSV with >/=2 M urea at atmospheric pressure caused very little virus inactivation, whereas at a pressure of 2.5 kbar, 1 M urea caused inactivation that exceeded by more than two orders of magnitude the sum of the inactivating effects produced by urea and pressure separately. Measurements of bis-ANS fluorescence showed that increasing the urea concentration reduces the pressure required to disrupt the structure. We conclude that anilinonaphthalene sulfonate compounds inactivate VSV by a mechanism similar to that produced by pressure. The most effective antiviral compound was bis-ANS which can be used for the preparation of safe viral vaccines or as an antiviral drug eventually.     

Effect of Vesicular Stomatitis Virus Infection on the Histocompatibility Antigen of L Cells

When mouse L cells are infected for 22 hr with vesicular stomatitis virus (VSV), a ribonucleic acid-containing enveloped virus, greater than 70% of the major histocompatibility antigen (H-2), is no longer detectable by the method of inhibition of immune cytolysis. Infected cells prelabeled with (14)C-glucosamine also show a correspondingly greater loss of trichloroacetic acid-insoluble radioactivity than uninfected cells. The loss of H-2 antigenic activity is not due to the viral inhibition of host cell protein synthesis since cells cultured for 18 hr in the presence of cycloheximide have the same amount of H-2 activity as untreated controls. Also, cells infected with encephalomyocarditis virus, a picornavirus, show no loss of H-2 activity at a time when host cell protein synthesis is completely inhibited. VSV structural proteins associated in vitro with uninfected L-cell plasma membranes do not render H-2 sites inaccessible to the assay. Although antibodies may not combine with all the H-2 antigenic sites on the plasma membrane, anti-H-2 serum reacted with L cells before infection does not prevent a normal infection with VSV. H-2 activity can be detected in virus samples purified from the medium of infected L cells; this virus purified after being mixed with L-cell homogenates shows greater H-2 activity than virus purified after being mixed with HeLa cell homogenates. However, VSV made in HeLa cells shows no H-2 activity when mixed with L-cell homogenates.     

Antiviral effects of 2',5'oligoadenylates (2-5As), and related compounds

Dephosphorylated "core" of 2',5'-oligoadenylate (2-5A) dimer (A2'p5'A), exogenously added to nonpermeabilized FL cells, inhibited the multiplication of Sindbis virus and vesicular stomatitis virus (VSV). The compound was shown to inhibit viral protein synthesis. The addition of A2'p5'A at the early stage of viral replication was more effective than that at the late stage. In contrast with the core, phosphorylated 2-5A (p5'A2'p5'A and ppp5'A2'p5'A) and 2-5A analogs containing cordycepin (3'-deoxyadenosine) did not show such antiviral effects. The rate of uptake of [3H]ppp5'A 2'p5'A into acid-soluble and acid-insoluble fractions, especially into the acid-insoluble fraction, was faster than that of [3H]A2'p5'A. These results suggest that the difference of antiviral activity between A2'p5'A and ppp5'A2'p5'A does not result from the different rate of uptake by cells, but from the different rate of from acid-soluble to acid-insoluble fractions.     

Vesicular stomatitis virus mRNA and inhibition of translation of cellular mRNA--is there a P function in vesicular stomatitis virus?

Infection of animal cells by vesicular stomatitis virus (VSV) results in inhibition of translation of cellular mRNA. We showed previously that, in BHK cells infected by the Glasgow isolate of VSV Indiana, this is due to competition during the initiation step of protein synthesis of viral and cellular mRNA for a constant, limiting number of ribosomes. We show here that infection of the same cells with the San Juan isolate of VSV resulted in a more rapid shutoff of host protein synthesis and that this was paralleled by a more rapid accumulation of viral mRNA. Extending our conclusion that shutoff is due to mRNA competition, we show further that the average size of polysomes translating viral and cellular mRNA was threefold smaller in cells infected by VSV San Juan than by VSV Glasgow, which, in turn, was about one-half that of uninfected cells. In all cases, cellular and viral mRNA's which encoded the same-sized polypeptides were found on the same-sized polysomes, a result indicating that the efficiency of translation of both types of mRNA's is about the same in the infected cell. Also, there was no preferential sequestration of viral or cellular mRNA's in ribonucleoprotein particles. Additional correlations between the levels of viral mRNA's and the inhibition of protein synthesis came from studies of three other wild-type VSV strains and also from studies with Vero and L cells. In particular, the rate of shutoff of L-cell protein synthesis after infection by any VSV isolate was slower than that in BHK cells, and this was correlated with a slower rate of accumulation of viral mRNA. VSV temperature-sensitive mutants which synthesized, at the nonper-missive temperature, no VSV mRNA failed to inhibit synthesis of cellular proteins. Stanners and co-workers (C. P. Stanners, A. M. Francoeur, and T. Lam, Cell 11:273-281, 1977) claimed that VSV mutant R1 inhibited synthesis of L cell protein synthesis less rapidly than did its parent wild-type strain HR. They concluded that this effect was due to a mutation in an unspecified VSV protein, “P.” We found, in both L and BHK cells, that R1 infection resulted in a slightly slower inhibition of cellular mRNA translation than did HR infection and that this was correlated with a slightly reduced accumulation of VSV mRNA. The level of VSV mRNA, rather than any specific VSV protein, appeared to be the key factor in determining the rate of shutoff of host protein synthesis.