Interferon-Inducing Characteristics of MM Virus

Interferon induction by MM virus in mice and in L cells was studied. In mice the virus readily induced interferon. The time of appearance was dose-dependent. A large virus dose induced interferon by 4 hr, whereas a small dose resulted in interferon production which paralleled virus replication 24 hr after infection. In L cells the interferon-inducing capacity of the virus was rapidly destroyed by ultraviolet light irradiation. Heating (56 C) of the virus, on the other hand, greatly increased its ability to induce interferon. Interferon production could also be increased by prior treatment of the cells with homologous interferon (priming). The increase in interferon production after priming was dependent on the concentration of interferon used for priming, the length of interferon treatment, and the multiplicity of infection. It is suggested that MM virus might be useful for the further study of the mechanisms involved in the production and action of interferon.     

The induction of interferon by vesicular stomatitis virus in mouse L cells.

Although no detectable interferon was produced when L cells were infected with wild-type VSV (VSV-o), considerable amounts of interferon were produced when cells were infected with UV-irradiated VSV-o at a multiplicity equivalent to 10 PFU/cell. Treatment of VSV-o with UV-light resulted in the marked reduction of the RNA synthesizing capacity and cytotoxity of the virus, and the UV-irradiated virus had neither infectivity nor interfering activity against homologous viruses. The amount of interferon induced by UV-VSV-o was markedly influenced by multiplicity of infection and incubation temperature. Less-virulent temperature-sensitive mutants (VSV-mp and VSV-sp) derived from L cells persistently infected with VSV induced interferon in L cells without treatment of the viruses with UV-light, but these viruses could not induce interferon if the infected cells were incubated at nonpermissive temperature, or if cells were infected at multiplicities of more than 10 PFU/cell. On the other hand, it was shown that treatment of cells with cycloheximide (100 μg/ml) delayed the expression of cell damage caused by non-irradiated VSV-o and resulted in the production of interferon when cycloheximide was removed from the cultures. These results indicate that VSV has intrinsically interferon-inducing capacity in L cells and can induce interferon if the induction is carried out under such condition that cell damage caused by VSV are suppressed or delayed. Furthermore, the effect of pretreatment of cells by interferon and undiluted passage of VSV-o on interferon induction was discussed in relation to persistent infection.     

Interferon priming. Effects on interferon messenger RNA.

The effects of priming mouse cells with interferon on the production of interferon and its mRNA were investigated. Interferon-treated (primed) mouse L929 cells produce 3 to 10 times more interferon than do nonprimed cells following induction with Newcastle disease virus. Interferon appears 2 to 4 h sooner in the primed cultures than in nonprimed cultures and interferon production by primed cells becomes resistant to inhibition by actinomycin D about 4 h sooner than interferon production in nonprimed cells. Interferon mRNA is detected in primed-induced cells about 2 h earlier than in nonprimed-induced cells. It reaches peak levels about 2 to 4 earlier in primed cells, but it also disappears sooner in primed cells. The total amounts of interferon mRNA isolated from primed-induced cells and nonprimed-induced cells were indistinguishable, by the methods utilized. Therefore, although primed cells can produce significantly more interferon and make interferon mRNA sooner than nonprimed cells, the total amount of interferon mRNA produced is apparently not increased, nor is its half-life prolonged in primed cells. Thus, enhanced interferon production in primed cells may result from enhanced efficiency of translation of interferon mRNA in the primed cells.     

Resistance of nude mice to herpes simplex virus and correlation with in vitro production of interferon.

Homozygous nude mice and their phenotypically normal littermates were infected intraperitoneally with herpes simplex virus (HSV). Nude mice did not show increased mortality rates. In fact, at lower virus doses they were consistently less susceptible than the controls. Spleen cells from nude mice, when challenged in vitro with HSV, produced equal amounts of interferon as spleen cells from the normal littermates.     

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.     

Requirement of newly synthesized protein for the priming activity of interferon.

Pretreatment of mouse L cells with interferon (IF) enhanced IF production in response to polyinosinic-polycytidylic acid (poly I-poly C). Post-treatment of cells with IF caused no significant enhancement of IF production. The enhancing effect of IF pretreatment (priming) reached a maximum after incubation with IF (10 or 100 units/ml) for 4-6 hr at 37 C, but this effect was absent when the incubation was done at 4 C. Cells which were incubated for additional several hours at 37 C after IF pretreatment at 4 C did not develop the primed state nor the antiviral state. The presence of protein synthesis inhibitors during the IF pretreatment depressed, though not completely, the development of the primed state. The residual priming effect was lost when the cells were incubated with the inhibitors at 37 C for 2 hr before they were exposed to poly I-poly C. There was no significant difference in the binding rate of poly I-poly C to cells between IF-treated and untreated cells. The degradation rate of cell-bound poly I-poly C and its sensitivity to exogenous pancreatic ribonuclease in the pretreated cells were also similar to those in the untreated cells.     

Destruction of L Cells by Mengo Virus: Use of Interferon to Study the Mechanism

Interferon, when added to L cells, inhibited the synthesis of infectious Mengo viral ribonucleic acid, hemagglutinins, and infectious virus by 85 to 95%. Serum-blocking antigens were also reduced by the action of interferon, but threefold excess amounts of these antigens accumulated in interferon-treated cultures above the amounts expected for the quantity of infectious virus that was produced in these cultures. Radioautographic analysis showed that 28 to 36% of the cells of an interferon-treated population synthesized viral ribonucleic acid and 36 to 47% produced viral antigens as determined by an immunofluorescence technique. Despite the reductions in synthesis of viral components, all cells in an interferon-treated culture underwent cytopathic effects at the same time as cells in infected cultures which had not been treated with interferon. The results are compatible with the hypothesis that the cell destruction which results from the infection of L cells with Mengo virus is due to a protein which is coded for by the virus but is not a component of the mature virion.     

Requirement of Newly Synthesized Protein for the Priming Activity of Interferon

Pretreatment of mouse L cells with interferon (IF) enhanced IF production in response to polyinosinic-polycytidylic acid (poly I·poly C). Post-treatment of cells with IF caused no significant enhancement of IF production. The enhancing effect of IF pretreatment (priming) reached a maximum after incubation with IF (10 or 100 units/ml) for 4–6 hr at 37 C, but this effect was absent when the incubation was done at 4 C. Cells which were incubated for additional several hours at 37 C after IF pretreatment at 4 C did not develop the primed state nor the antiviral state. The presence of protein synthesis inhibitors during the IF pretreatment depressed, though not completely, the development of the primed state. The residual priming effect was lost when the cells were incubated with the inhibitors at 37 C for 2 hr before they were exposed to poly I·poly C. There was no significant difference in the binding rate of poly I·poly C to cells between IF-treated and untreated cells. The degradation rate of cell-bound poly I·poly C and its sensitivity to exogenous pancreatic ribonuclease in the pretreated cells were also similar to those in the untreated cells.     

Immunization of mice with lipopeptides bypasses the prerequisite for adjuvant. Immune response of BALB/c mice to human immunodeficiency virus envelope glycoprotein.

In vivo priming of CTL requires the association with MHC class I molecules of peptides derived from the processing of endogenously produced proteins. Immunization with exogenous proteins or peptides rarely induces MHC class I-restricted CTL unless they are associated with lipidic compounds. The capacity to induce CTL was compared in synthetic peptides and simple lipopeptides containing the Immunodominant MHC class I H-2Dd-restricted T-cell epitope of HIV-1 gp160. In contrast with free peptides in saline, lipopeptides induced strong primary CTL responses in vivo. These CTL were able to lyse cells infected with a recombinant vaccinia virus expressing the HIV-1 env gene. Priming of CTL was also successful when using 16-amino acid lipopeptides as 34-amino acid lipopeptides, suggesting that several epitopes might be included in a single construct. In vivo priming of CTL also requires CD4+ T cell help. We therefore searched for Th cell activation after priming with lipopeptides. Our results show that, as with CTL induction, Th cell activation with lipopeptides did not require mixing with adjuvant. In addition, lipopeptides were also efficient at stimulating antibody-mediated responses. Our results show that a single lipopeptidic construct can induce a total immune response, which is of importance in vaccine development.     

Defectiveness of Interferon Production and of Rubella Virus Interference in a Line of African Green Monkey Kidney Cells (Vero)

Vero cells, a line of African green monkey kidney cells, failed to produce interferon when infected with Newcastle disease, Sendai, Sindbis, and rubella viruses, although the cells were sensitive to interferon. Further, infection of Vero cells with rubella virus did not result in interference with the replication of echovirus 11, Newcastle disease virus, or vesicular stomatitis virus, even in cultures where virtually every cell was infected with rubella virus. Under the same conditions, BSC-1 cells and other cells of primate origin produced interferon and showed rubella virus interference. The results indicate that the presence of rubella virus in the cell does not in itself exclude multiplication of other viruses and that rubella virus interference appears to be linked to the capability of the cell to produce interferon.     

Comparative Studies on Large- and Small-Plaque-Forming Clones of Newcastle Disease Virus (Miyadera Strain)

The Miyadera strain of Newcastle disease virus (NDV) consisted predominantly of virus particles forming small plaques on monolayers of chick embryo fibroblasts (CEF), and contained small amounts of virus particles forming large plaques. These large- and small-plaque-forming clones of this virus (NDV-L and NDV-S) were isolated. The small size of the NDV-S plaques did not appear to be due to an agar inhibitor. NDV-L produced a much higher yield of infective virus particles in CEF and they were released more completely from the infected cells than were those produced by NDV-S. The yield of infective virus of NDV-L per cell from cultures of CEF was comparable to the yield from the allantoic cells. The infectivity/hemagglutinin ratio for NDV-L from CEF was as high as the ratio for virus from the allantoic cells, but the ratio for NDV-S from CEF was lower. NDV-S demonstrated an autointerference phenomenon in CEF when infected at high multiplicities, but NDV-L did not. Contrary to virus multiplication, NDV-S exhibited a more rapid and marked cytopathic effect on monolayers of CEF than NDV-L. In the allantoic cavity of eggs NDV-S produced slightly higher virus yields than NDV-L. No correlation existed between plaque size of the two viruses and the capacity to induce interferon synthesis or the susceptibility to the action of interferon. The properties of both distinctive plaque isolates were stable on egg passage.     

Interferon Production and Inhibition of Host Synthesis in Cells Infected with Vesicular Stomatitis Virus

Infection of L cells with wild-type (L(1)) vesicular stomatitis virus at high or low multiplicities does not result in the production of interferon; however, infection of L cells with low multiplicities of a small-plaque mutant (S(2)) results in the synthesis of large amounts of interferon. In chick embryo (CE) cells, both viruses induce synthesis of interferon; there is no significant multiplicity effect in CE cells. The rate and efficiency of shutoff of macromolecular synthesis in the different host cells is a critical factor in determining the ability of the viruses to induce interferon synthesis. If host ribonucleic acid or protein synthesis is shut off by the virus before the required new ribonucleic acid is transcribed or translated, interferon production does not occur. The relative yield of the two viruses in CE and L cells is not related to the effects of interferon produced during the course of infection.     

Defense mechanisms against primary influenza virus infection in mice. I. The roles of interferon and neutralizing antibodies and thymus dependence of interferon and antibody production.

To investigate the defensive roles and production of interferon and antibodies, C3H/He mice were subjected to various immunosuppressive treatments and infected with influenza virus. In infected normal control mice the pattern of pulmonary viral growth can be divided into three phases. The first phase is characterized by an exponential increase of virus titer, the second by a rapid decrease, and the third by a moderate decrease. At the time of transition from the first phase to the second in pulmonary virus growth, interferon could be detected in the tracheobronchial washings of infected mice, but neutralizing antibodies could not. In infected B cell-deprived mice and infected anti-mu-treated mice, the transition from the first phase to the second occurred without any detectable antibody production, and interferon could be induced in the early stage of infection. However, the pulmonary virus in these mice increased again exponentially until the death of the mice. In infected T cell-deprived mice which could not induce interferon, but produced IgM-neutralizing antibodies, the second phase was not observed after the first phase, but a transient plateau phase could be demonstrated, and then the pulmonary virus increased again exponentially until the death of the mice. In anti-gamma-treated infected mice, pulmonary virus growth and production of interferon and neutralizing antibody were almost similar to those of infected normal control mice except for the absence of IgG neutralizing antibody production. Although anti-alpha-treated infected mice produced interferon and no IgA antibody, the transition from the first exponential increase of pulmonary virus to the second rapid decrease was seen, but then the virus increased exponentially again until the death of the mice. These results suggest that interferon plays an important role in the transition from the first phase to the second, and that T cells are required for interferon induction in mice infected with influenza virus. These data also suggest that IgA antibodies play an important role in the inhibition of virus propagation in the lungs after the disappearance of interferon. Moreover, infected T cell-deprived mice could produce only IgM neutralizing antibodies, but not IgG and IgA antibodies. Therefore, T cells are required for the production of IgG and IgA antibodies and even     

Variation of Interferon Production During the Cell Cycle

The capacity of cells to produce interferon has been found to depend on the phase in the cell cycle at which virus infection took place. Monolayer cultures of L cells were synchronized by the double thymidine-block method. Such synchronously growing cultures were used to study the ability of cells to produce interferon when they were infected with ultraviolet-inactivated Newcastle disease virus (UV-NDV) at different phases of the cell cycle. In all instances, interferon was detected early and reached a maximum at about 16 hr after infection. However, the levels of interferon found in medium of cultures infected at early post-deoxyribonucleic acid (DNA) synthetic (G2) and to some extent at late G2 phases of the cell cycle were comparatively lower than those found in cultures infected at the early DNA synthetic (S) phase. There appeared also in these infected growing cultures a transient period when interferon production was apparently delayed. This period corresponded interestingly with the time of mitotic burst. Infection of thymidine- or 1-beta-d-arabino-furanosylcytosine-inhibited cultures with UV-NDV also led to similar interferon response as that observed in growing cultures infected at early S. However, no transient delay of interferon production was demonstrated in these cultures.     

Antigen presentation by nonhemopoietic cells amplifies clonal expansion of effector CD8 T cells in a pathogen-specific manner

Professional APCs of hemopoietic-origin prime pathogen-specific naive CD8 T cells. The primed CD8 T cells can encounter Ag on infected nonhemopoietic cell types. Whether these nonhemopoietic interactions perpetuate effector T cell expansion remains unknown. We addressed this question in vivo, using four viral and bacterial pathogens, by comparing expansion of effector CD8 T cells in bone marrow chimeric mice expressing restricting MHC on all cell types vs mice that specifically lack restricting MHC on nonhemopoietic cell types or radiation-sensitive hemopoietic cell types. Absence of Ag presentation by nonhemopoietic cell types allowed priming of naive CD8 T cells in all four infection models tested, but diminished their sustained expansion by approximately 10-fold during lymphocytic choriomeningitis virus and by < or =2-fold during vaccinia virus, vesicular stomatitis virus, or Listeria monocytogenes infections. Absence of Ag presentation by a majority (>99%) of hemopoietic cells surprisingly also allowed initial priming of naive CD8 T cells in all the four infection models, albeit with delayed kinetics, but the sustained expansion of these primed CD8 T cells was markedly evident only during lymphocytic choriomeningitis virus, but not during vaccinia virus, vesicular stomatitis virus, or L. monocytogenes. Thus, infected nonhemopoietic cells can amplify effector CD8 T cell expansion during infection, but the extent to which they can amplify is determined by the pathogen. Further understanding of mechanisms by which pathogens differentially affect the ability of nonhemopoietic cell types to contribute to T cell expansion, how these processes alter during acute vs chronic phase of infections, and how these processes influence the quality and quantity of memory cells will have implications for rational vaccine design.     

Inhibition of Arbovirus Protein Synthesis by Interferon

Infection of cells treated with guanidine and actinomycin D and then washed to remove the guanidine inhibition of virus growth had no effect on antiviral activity already established by interferon. Protein synthesis in interferon-treated cells infected under these conditions was decreased as compared to control cells similarly treated but not exposed to interferon. In these control cells, analysis by polyacrylamide gel electrophoresis indicated that six proteins were produced during the first hour after guanidine reversal. Five of these proteins have been previously identified as probably being viral in origin. In interferon-treated cells, only a single major protein was produced. Ribonucleic acid (RNA) synthesis by Semliki Forest virus during the first hour after guanidine reversal was markedly depressed by incubation at 42 C, but no inhibition of total virus protein synthesis was seen; this finding suggested that much of the virus protein produced in the first hour after guanidine reversal was carried out by input virus RNA. Interferon was fully active in cells incubated at 42 C. The results suggested that interferon inhibits the production of Semliki Forest virus proteins ordinarily produced under the direction of the virus genome.     

Cellular and antigenic requirements for production of mixed leukocyte reaction suppressor factor

When murine spleen cells, alloantigen-sensitized previously in vivo, are incubated with spleen cells bearing the sensitizing alloantigens, a supernatant factor is produced that inhibits 3H-thymidine incorporation by responding lymphocytes in the mixed leukocyte reaction. This study evaluates the cellular and antigenic requirements during restimulation for elaboration of this suppressor factor, MLR-TsF. BALB/c spleen cells, sensitized to C57BL/6 (B6) alloantigens in vivo, produced MLR-TsF when cultured with B6 spleen cells in vitro, despite depletion of Sephadex G-10-adherent cells from factor-producing cells, stimulator cells, or from both populations. T cells were not required within the stimulating population, but a requirement for viable stimulator cells was demonstrated when heat-killed or glutaraldehyde-fixed stimulator cells failed to induce MLR-TsF production. The alloantigenic requirements for MLR-TsF production were addressed by 2 approaches. Treatment of stimulator cells with appropriate anti-I region antisera and complement did not affect MLR-TsF production, demonstrating that an absolute requirement for cells expressing I region determinants did not exist. However, spleen cells primed against entire H-2 haplotype differences produced significant quantities of MLR-TsF when they were restimulated with spleen cells homologous to the priming cells in only the I region, in the K and D regions, or in the D region alone. The additive nature of subregion-specific restimulation suggests that distinct subpopulations of K, I, and D region-specific MLR-Ts comprise the MLR-Ts population primed to entire H-2 haplotype differences.     

Vaccinia virus F9 virion membrane protein is required for entry but not virus assembly, in contrast to the related L1 protein

All sequenced poxviruses encode orthologs of the vaccinia virus L1 and F9 proteins, which are structurally similar and share about 20% amino acid identity. We found that F9 further resembles L1 as both proteins are membrane components of the mature virion with similar topologies and induce neutralizing antibodies. In addition, a recombinant vaccinia virus that inducibly expresses F9, like a previously described L1 mutant, had a conditional-lethal phenotype: plaque formation and replication of infectious virus were dependent on added inducer. However, only immature virus particles are made when L1 is repressed, whereas normal-looking intracellular and extracellular virions formed in the absence of F9. Except for the lack of F9, the polypeptide components of such virions were indistinguishable from those of wild-type virus. These F9-deficient virions bound to cells, but their cores did not penetrate into the cytoplasm. Furthermore, cells infected with F9-negative virions did not fuse after a brief low-pH treatment, as did cells infected with virus made in the presence of inducer. In these respects, the phenotype associated with F9 deficiency was identical to that produced by the lack of individual components of a previously described poxvirus entry/fusion complex. Moreover, F9 interacted with proteins of that complex, supporting a related role. Thus, despite the structural relationships of L1 and F9, the two proteins have distinct functions in assembly and entry, respectively.     

Effect of the expression of a hepatocyte-specific MHC molecule in transgenic mice on T cell tolerance

A hybrid murine class I gene, Q10/L, was injected into C3H/HeJ fertilized ova to produce transgenic (TG) mice. This fusion gene contained 414 bp of Q10 promoter sequences which was sufficient to direct liver-specific expression in two lines of animals. Animals from these lines did not have Q10/L mRNA in 10 nonhepatic tissues examined including thymus, spleen, and bone marrow. The ontogeny of Q10/Ld expression in both liver and yolk sac paralleled expression of endogenous Q10. Analysis of liver cells from these lines by flow cytometry and immunofluorescence demonstrated the presence of the Q10/L Ag solely on hepatocytes. TG animals showed no signs of hepatic disease as evidenced by an absence of cellular infiltrates in the liver and a normal profile of serum enzymes that are elevated in association with hepatic disease. When spleen cells from TG animals were cocultured with splenocytes that express Ag cross-reactive with Q10/L, CTL were generated that recognized and lysed L cells which express Q10/L. However, the extent of lysis was less than that generated from non-TG control littermates. That these cross-reactive T cells were physiologically significant was demonstrated by adoptive transfer of in vivo primed T cell enriched spleen cells which produced a mononuclear infiltration of the liver of TG recipients. However, inoculation of Q10/L L cells or splenocytes expressing Q10/L cross-reactive Ag into TG mice did not induce cellular infiltration or overt hepatic disease. Whereas inoculation of normal C3H mice with these cells led to priming of Q10/L reactive CTL, anti-Q10/L CTL could not be primed in TG mice. This suggests that Ag expression solely on hepatocytes can lead to inactivation of specific CTL clones and thus account for the observed in vivo tolerance.