Increase of vulnerability to lymphotoxin in cells infected by vesicular stomatitis virus and its further augmentation by interferon

The cytotoxic effect of lymphotoxin (LT) and its modulation by interferon (IFN) was quantitatively assessed in uninfected and vesicular stomatitis virus (VSV)-infected cultured cells. Preparations of human LT, which were depleted of IFN, had a significant cytotoxic effect on VSV-infected HeLa, SV-80, WISH, and Vero cells. IFN, most notably IFN-gamma, further potentiated destruction of the infected cells by these LT preparations, when applied on the cells at sub-antiviral IFN concentrations. In contrast, no cytotoxic effect could be observed in any of the examined cells, when applying LT, IFN, or their combination, in the absence of viral infection. Infected cells in which VSV replication was suppressed by treatment with antiviral concentrations of IFN also resisted destruction by LT. These findings indicate that LT cytotoxicity can be selectively directed against virus-infected cells and that IFN can augment this cell-killing mechanism when failing to exert an antiviral effect.     

Synergism of antiviral activity in cell cultures treated with low concentrations of interferon and interferon-treated lymphocytes

Human T cells treated with low levels of interferon (IFN) (1-10 units/ml), and washed to remove the IFN, transferred the same level of antiviral activity to recipient WISH cells as an equivalent IFN treatment alone could induce in WISH cells. Further, when T cells pretreated with IFN (1-10 units/ml) were cocultivated with WISH cells in the presence of IFN (1-10 units/ml), a 2.5- to 5-fold greater level of protection developed than could be expected from the additive effect of each. Antibody to leukocyte, fibroblast, or immune IFN blocked the antiviral effect of the respective IFN types but had no effect on the transfer of antiviral activity initiated by leukocyte, fibroblast, or immune IFN. Also, treatment of T cells with actinomycin D blocked the transfer of antiviral activity of IFN-treated T cells. Taken together, the data suggest that the increased antiviral activity is not merely an additive effect of the IFN, but represents a synergistic amplification of protection most likely due to the combination of the separate effects of IFN and IFN-induced transfer. Such interactions would be expected to play a major role in early protection against virus infections in vivo when low levels of interferon are present and lymphocytes are migrating into the area.     

Persistence of echovirus 6 in cloned human cells.

Establishment of a persistent infection by echovirus 6 in cloned human WISH cells (PI) was demonstrated. The cloned human WISH cells were maintained for 3.0 years (over 125 passages) and released virus continuously without cellular destruction. Neither temperature-sensitive virus mutants nor interferon appears to play a role in either establishment or maintenance of viral persistence. The majority of the virus produced by cloned human WISH cells is defective (2 X 10(6) particles per PFU) and differs from standard virus in its polypeptide profile and its inability to attach to parental WISH cells.     

Species specificity of interferon action: maintenance and establishment of the antiviral state in the presence of a heterospecific nucleus.

The expression of the interferon-induced antiviral state was studied in heterokaryons and cytoplasmic hybrids (cybrids). An autoradiographic assay for the antiviral state, in which the percentage of cells containing vaccinia viral DNA factories was determined, was used. The expression of the antiviral state was dominant in homokaryons and heterokaryons formed by fusion of interferon-treated cells with untreated cells. Cytoplasts derived from treated cells conferred resistance to virus growth on cybrids formed by fusing such cytoplasts with untreated cells. Treatment of L cell x HeLa cell heterokaryons with human interferon or mouse interferon was much less effective in inducing a detectable antiviral state than was similar treatment of parental cells with homospecific interferon. The antiviral state was fully induced when heterokaryons were treated simultaneously with both types of interferon. Cybrids formed by fusing L cell cytoplasts with HeLa cells or HeLa cytoplasts with L cells did not enter a detectable antiviral state after treatment with interferon specific for the cell type of the enucleated parent. However, treatment of cybrids with interferon specific for the cell type of the nucleated parent was effective in inducing a detectable antiviral state.     

Interferon-induced transfer of viral resistance by human B and T lymphocytes

Enriched human B lymphocytes cocultivated with mouse L cells produced human leukocyte interferon (IFN-alpha) and shortly thereafter transferred antiviral activity to the recipient cells (99% inhibition of expected virus yield). In contrast, cocultivation of enriched T-cell populations with mouse L cells resulted in no IFN production or transfer of antiviral activity. In addition, both T and B lymphocytes pretreated with exogenous IFN or stimulated in vitro by mitogens could transfer antiviral activity to human WISH cells. The transfer of antiviral activity was not blocked by antibodies to IFN. The data indicate that both T and B cells can be recruited by IFN to transfer antiviral activity. Thus, once cells are recruited by IFN they can transfer antiviral activity in the absence of IFN and protect cells locally or distally from the site of infection.     

Mechanism of the suppressive effect of interferon on antibody synthesis in vivo.

Mouse interferon preparations significantly suppress the in vivo antibody response to sheep red blood cells (SRBC), a thymus-dependent antigen, and to Salmonella typhimurium lipopolysaccharide (LPS), a thymus-independent antigen. It is also possible to effect the late responses of antigen sensitive "memory" cells observed during secondary immunization by administration of interferon prior to primary immunization. The immunosuppressive activity of interferon was time- and dose-dependent. Maximum suppression was produced when animals were given 1.5 times 10-5 units of interferon between 4 and 48 hr before antigenic stimulation. These findings suggested that interferon affects some early event(s) in the process of antibody synthesis which might be related to the general inhibitory effect of interferon on rapidly dividing cells and viral m-RNA translation. In addition, the use of nonadherent spleen cell cultures from interferon-treated mice, immunized in vitro with a thymus-independent antigen, indicated that in this situation the inhibitory effect of interferon was due to an action on B lymphocytes. A variety of soluble "suppressive" factors are secreted by T cells as a consequence of activation by mitogens or specific antigens in vitro. Since T cells are recognized as one of the sources of interferon, it is suggested that interferon should be investigated as a suppressor T cell-produced lymphokine which can regulate B cell expression.     

Enhancement of bactericidal activity of mouse peritoneal macrophages against Staphylococcus aureus by mouse interferon preparations

The effect of mouse interferon on the bactericidal activity of macrophages against pyogenic cocci was examined. Mouse peritoneal macrophages were cultivated with Staphylococcus aureus in vitro and viable Staphylococcus was recovered by treatment of the mixed macrophage-bacteria culture with sodium dodecyl sulphate (SDS) solution. Results showed that S. aureus was phagocytized and killed by the macrophages. Mouse L cell interferon enhanced the bactericidal activity of macrophages. A mouse brain interferon preparation also enhanced this activity. However, heat-inactivated L cell interferon and heterologous rabbit RK-13 cell interferon and human leukocyte interferon did not enhance it. This suggests that interferon enhances the bactericidal activity of macrophages against S. aureus.     

Leukocytes and interferon in the host response to viral infections. II. Enhanced interferon response of leukocytes from immune animals

Glasgow, Lowell A. (University of Rochester School of Medicine and Dentistry, Rochester, N.Y.). Leukocytes and interferon in the host response to viral infections. II. Enhanced interferon response of leukocytes from immune animals. J. Bacteriol. 91:2185-2191. 1966.-The production of interferon was studied under in vitro conditions in peritoneal leukocytes or macrophages from mice immunized with Chikungunya virus (CV). Cultures of leukocytes obtained from animals immune to CV produced 2- to 10-fold greater amounts of interferon when exposed to an inoculum of CV than similar cell preparations from nonimmune, control animals. The viral inhibitor produced in increased quantity by CV-immune leukocytes had the biological and biochemical properties of interferon. The enhanced interferon production was inhibited by actinomycin D. This response of immune leukocytes was specific, and was initiated only by CV; it was not observed in leukocytes from animals immunized against other viruses which were challenged with CV. The presence of neutralizing antibody could not be related to this response. The observed increase in interferon production was not dependent upon an enhanced virus uptake. The data are presented as a possible new dimension of the "immune response" and may suggest a mechanism for the phenomenon of "tissue immunity."     

A cell surface alteration in mouse L cells induced by interferon

Mouse L cells grown in suspension culture when treated with L cell interferon have a greater electrophoretic mobility toward the anode than control cells. This change in electrophoretic mobility depends on the concentration of interferon in the medium and the duration of interferon interaction with the cells. It is concluded that the interferon-treated cells have a greater net negative charge on the cell surface than control cells and it is suggested that the cell surface is altered because of the interaction with interferon.     

Classification of interferons with antibody to immune interferon

Mouse immune Interferon, induced by the T-cell mitogen staphylococcal enterotoxin A (SEA), was partially purified and used to immunize rabbits. The resulting antiserum neutralized all immune interferon preparations tested, including interferon induced in vitro by SEA, concanavalin A, phytohemagglutinin P, and pokeweed mitogen, and in mixed lymphocyte cultures. Interferon produced in vivo with specific antigen was also neutralized. The antiserum was equally potent against all these interferon preparations. The serum did not neutralize any virus-type interferon preparation tested, but immune interferon induced by SEA in athymic nude mouse spleen cells was neutralized. The neutralizing activity was precipitable by 33% ammonium sulfate, and was not removed by absorption of the serum with mouse cells. The data suggest that immune interferons produced under diverse conditions are antigenically the same or closely related.     

Effect of alpha interferon on the hepatitis C virus replicon

Chronic hepatitis C virus (HCV) infections can be cured only in a fraction of patients treated with alpha interferon (IFN-alpha) and ribavirin combination therapy. The mechanism of the IFN-alpha response against HCV is not understood, but evidence for a role for viral nonstructural protein 5A (NS5A) in IFN resistance has been provided. To elucidate the mechanism by which NS5A and possibly other viral proteins inhibit the cellular antiviral program, we have constructed a subgenomic replicon from a known infectious HCV clone and demonstrated that it has an approximately 1,000-fold-higher transduction efficiency than previously used subgenomes. We found that IFN-alpha reduced replication of HCV subgenomic replicons approximately 10-fold. The estimated half-life of viral RNA in the presence of the cytokine was about 12 h. HCV replication was sensitive to IFN-alpha independently of whether the replicon expressed an NS5A protein associated with sensitivity or resistance to the cytokine. Furthermore, our results indicated that HCV replicons can persist in Huh7 cells in the presence of high concentrations of IFN-alpha. Finally, under our conditions, selection for IFN-alpha-resistant variants did not occur.     

Alveolar macrophage lipoxygenase products of arachidonic acid: isolation and recognition as the predominant constituents of the neutrophil chemotactic activity elaborated by alveolar macrophages

Human immune interferon preparations have anticellular activity on human cell lines (WISH and HEp-2). This anticellular activity copurified with the human immune interferon and appears to be a function of the immune interferon molecule. On the basis of a unit of antiviral activity, purified human immune interferon had about 20 and 100 times more anticellular activity than purified fibroblast or leukocyte interferon, respectively. The possible implications of this finding in the treatment of human neoplasia are discussed.     

2',5'-Oligoadenylate synthetase expression is induced in response to heat shock

Hyperthermia (45 degrees C) induced the synthesis of a characteristic heat-shock protein of 70,000 daltons (70 hsp) in Madin-Darby bovine kidney (MDBK) cells. In addition, subsequent to heat shock, there was a substantial increase in the 2',5'-oligoadenylate synthetase (2',5'-A synthetase) activity in both MDBK and human WISH cells. However, in contrast to 70 hsp synthesis, which reached its maximum 3 h after cell transfer from 45 to 37 degrees C, increase in 2',5'-A synthetase expression, conspicuous after 6 h, attained its maximum only 18 h after transfer. Another interesting observation is that, during recovery at 37 degrees C, the cells released into the medium heat-shock-induced factor(s) (HSIF) capable of inducing an increase in 2',5'-A synthetase activity in fresh MDBK cells. HSIF behaves as a polypeptide with a molecular weight of more than 5,000; it is relatively heat stable and sensitive to acidic treatment. HISF seems different from interferon (IFN) since: 1) no detectable antiviral state developed after infection in cells treated with HSIF; 2) antibovine IFN antibodies did not abolish the inducing capacity of HSIF; 3) IFN had an additive effect on the inducing capacity of HSIF, and 4) HSIF released from bovine cells induced a net enhancement of 2',5'-A synthetase activity in human WISH cells. The first three of these observations applied also to heat-shocked MDBK cells.     

Comparison of the antiviral action of different human interferons against DNA and RNA viruses

Abstract Five different interferon preparations were compared for their antiviral activity against Herpes simplex virus type 1 (HSV-1) and several RNA viruses. The interferons used were: interferon α from human buffy coats, interferon β from human fibroblasts, interferon γ from human lymphocytes after stimulation with phytohemagglutinin (PHA), lymphoblastoid interferon from Namalva cells IFN-α (Ly) and cloned α ₂ interferon produced by Escherichia coli containing the human gene for interferon α ₂. All preparations were able to protect monolayers of HeLa cells against HSV-1 infection when low multiplicities were used. The five IFN preparations were also tested against encephalomyocarditis (EMC) virus, poliovirus and vesicular stomatitis virus (VSV).     

Use of Disposable Micro Tissue Culture Plates for Antiviral and Interferon Induction Studies

A reproducible test system requiring small amounts of test compound was developed for evaluating antiviral and interferon-inducing activity. In the antiviral experiments, KB cells were grown in disposable polystyrene microplates covered with a standard domestic plastic wrap. Viruses used in the system were types 1 and 2 herpes simplex virus, vaccinia virus, type 3 adenovirus, myxoma virus, pseudorabies virus, type 3 parainfluenza virus, types 1A and 13 rhinovirus, vesicular stomatitis virus, coxsackievirus B, and type 2 poliovirus. Inhibition of viral cytopathogenic effect was the primary criterion of evaluation of antiviral activity. Reduction in cell and supernatant fluid virus titers was used as a secondary means of evaluation. The microplate system was adaptable for determining prophylactic, therapeutic, and inactivating effects against viruses. Mouse L-929 cells were used for the interferon induction studies, with vesicular stomatitis virus utilized as the indicator of interferon activity. Known active compounds evaluated in this microplate system had activity similar to that seen in macro in vitro systems.     

Action of interferon on cell membrane of mouse lymphocytes : Inhibition of ligand-induced redistribution of surface receptors

Mouse interferon at 50–100 U/ml or higher concentrations inhibited cap formation of surface components on mouse lymphocytes induced by anti-lymphocyte serum, concanavalin A (ConA), phytohemagglutinin (PHA) and soybean agglutinin (SBA). Interferon from species other than mouse were not effective, suggesting that interferon itself in the preparations used was responsible for the observed effect. The inhibition was observed immediately after addition of interferon, without preincubation of cells with it. The effect was reversible, disappearing after a short lag when interferon was removed. The effect may thus be a reflection of a rapid change in cell membrane upon binding of interferon molecules. On the other hand, the cap formation by anti-immunoglobulin, anti-thy 1, 2, anti-H-2 sera and wheat germ agglutinin (WGA) were not influenced by interferon at all, indicating that the inhibition by interferon was not a general phenomenon. The cap formations susceptible to interferon are those that are enhanced by pretreatment of cells with colchicine and are accompanied by marked uropod formation, but those insusceptible to interferon occur readily, becoming sharp spots which are then shed. It is suggested that interferon may modify the microtubule-containing structure, it it may selectively affect those membrane components that are anchored to it.     

INHIBITION OF PROTEIN SYNTHESIS IN NONINFECTED L CELLS BY PARTIALLY PURIFIED INTERFERON PREPARATIONS

Partially purified interferon preparations, obtained from L-cell monolayers infected with Newcastle disease virus (NDV), were shown to inhibit protein synthesis in noninfected L cells. The incorporation of several amino acids-¹⁴C was equally sensitive to the pretreatment of the cells with the interferon preparation. Treatment of L-cell monolayers for 24 hr with 800 units of interferon resulted in a 50% decrease in amino acid incorporation. The degree of inhibition was found to be a function of the interferon concentration and the time of exposure of the cells to the partially purified preparations. No inhibitory effect was detected in medium obtained from noninfected cells and purified in an identical manner. The inhibitory effect was shown to be cell specific in that the partially purified interferon from L cells did not reduce amino acid incorporation in heterospecific cell lines. Heating the interferon preparations at 60°C destroyed their antiviral activity and their ability to inhibit valine-¹⁴C incorporation in L cells.     

Analysis of interferon signaling by infectious hepatitis C virus clones with substitutions of core amino acids 70 and 91

Substitution of amino acids 70 and 91 in the hepatitis C virus (HCV) core region is a significant predictor of poor responses to peginterferon-plus-ribavirin therapy, while their molecular mechanisms remain unclear. Here we investigated these differences in the response to alpha interferon (IFN) by using HCV cell culture with R70Q, R70H, and L91M substitutions. IFN treatment of cells transfected or infected with the wild type or the mutant HCV clones showed that the R70Q, R70H, and L91M core mutants were significantly more resistant than the wild type. Among HCV-transfected cells, intracellular HCV RNA levels were significantly higher for the core mutants than for the wild type, while HCV RNA in culture supernatant was significantly lower for these mutants than for the wild type. IFN-induced phosphorylation of STAT1 and STAT2 and expression of the interferon-inducible genes were significantly lower for the core mutants than for the wild type, suggesting cellular unresponsiveness to IFN. The expression level of an interferon signal attenuator, SOCS3, was significantly higher for the R70Q, R70H, and L91M mutants than for the wild type. Interleukin 6 (IL-6), which upregulates SOCS3, was significantly higher for the R70Q, R70H, and L91M mutants than for the wild type, suggesting interferon resistance, possibly through IL-6-induced, SOCS3-mediated suppression of interferon signaling. Expression levels of endoplasmic reticulum (ER) stress proteins were significantly higher in cells transfected with a core mutant than in those transfected with the wild type. In conclusion, HCV R70 and L91 core mutants were resistant to interferon in vitro, and the resistance may be induced by IL-6-induced upregulation of SOCS3. Those mechanisms may explain clinical interferon resistance of HCV core mutants.     

Gamma interferon (IFN-gamma) receptor null-mutant mice are more susceptible to herpes simplex virus type 1 infection than IFN-gamma ligand null-mutant mice

Mouse strains with null mutations in the gamma interferon gene (Ifng) or the gamma interferon receptor gene (Ifngr) have been engineered. The use of these strains as animal models of viral and bacterial infections has enhanced our understanding of the role of gamma interferon (IFN-gamma) in the host immune response. However, direct comparisons between Ifng-/- (GKO) and Ifngr-/- (RGKO) mice have been problematic because previously available strains of these mice have had different genetic backgrounds (i.e., C57BL/6 and BALB/c for GKO mice and 129/Sv//Ev for RGKO mice). To enable direct comparison of herpes simplex virus type 1 (HSV-1) infections in GKO and RGKO mice, we introduced the IFN-gamma null mutation into the 129/Sv//Ev background. We report that, after HSV-1 inoculation, mortality was significantly greater in RGKO mice than in GKO mice (38 versus 23%, P = 0.0001). Similarly, the mortality from vaccinia virus challenge was significantly greater in RGKO mice than in GKO mice. With differences in genetic background excluded as a confounding issue, these results are consistent with the existence of an alternative ligand(s) for the IFN-gamma receptor that is also capable of mediating protection against viral challenge.