Human interferon and cell growth inhibition. V. Effect of ouabain on interferon activities

The effect of ouabain on the antiviral and anticellular activities of interferon and its components was tested in RSb cells. These cells were found to be inhibited in growth by both components. Ouabain, known to block the antiviral effect of interferon without affecting the growth inhibitory effect, depressed both effects of the antiviral component. The effect of the growth inhibitory component was unaltered by the drug. The results support earlier suggestions that two different mechanisms may be involved in the growth regulation by interferon.     

The role of cell membrane in the antiviral effect of interferon

The mechanism of interferon action in human fibroblasts has been studied by use of both antisera to human fibroblast interferon and the antisera to the surface of human fibroblast cell. The anti-interferon serum completely neutralized the antiviral effect of human fibroblast interferon. Interferon antiserum prevented the intracellular antiviral state from developing when added to the medium of the cells in which interferon synthesis had already been induced by poly (I · C). This suggests that development of the antiviral state involves interferon interaction with the external part of the producing cell. Treatment with the serum directed against the surface of human fibroblast cells failed to inhibit the antiviral activity of human interferon in these cells. In addition, the effect of gangliosides on the antiviral activity of human interferon was studied and it was found that human interferon binds to gangliosides and that this interaction leads to inactivation of the antiviral effect of interferon. Pretreatment of human fibroblasts with gangliosides had no effect on the sensitivity of these cells to exogenous interferon.     

Interferon-associated, dsRNA-dependent enzyme activities in a mutant 3T6 cell engaged in the semiconstitutive synthesis of interferon

Cytoplasmic extracts of untreated cultures of a virus-resistant mutant of mouse 3T6 cells, designated 3T6-VrB2, contain two double-stranded, RNA-activated enzyme activities associated with interferon action. These are the synthesis of a low molecular weight oligonucleotide inhibitor of cell-free protein synthesis from ATP, and the phosphorylation of a 67,000 dalton polypeptide by transfer of the gamma phosphate of ATP. Basal levels of both enzyme activities are detectable in extracts of untreated parental 3T6 cells, and are greatly enhanced upon interferon pretreatment. A procedure was developed, using a nonionic detergent to effect cell lysis, which allowed the analysis of the protein kinase activity from as few as 2 x 10(7) cells. Using this procedure, direct proportionalities were demonstrated between the concentration of interferon to which 3T6 cells were exposed, and both the level of protein kinase activity and the magnitude of the antiviral state were established in these cells. Furthermore, untreated cultures of 3T6-VrB2 exhibited both an antiviral state and an intracellular protein kinase activity equal to that of cultures of the parental 3T6 cells pretreated with a single concentration of mouse interferon.     

Effects of butyrate on induction and action of interferon

We have identified two different and independent effects of sodium butyrate on induction and action of interferon. In the monkey cell line, GL-V3, simultaneous treatment with interferon and butyrate strongly reduced the antiviral activity of the interferon preparation, Whereas addition of butyrate before interferon or after establishment of the antiviral state had no effect. Interferon production induced by Sendai virus was also reduced by simultaneous treatment with butyrate, but pretreatment resulted in marked enhancement of interferon yields. Whereas the inhibitory effects of simultaneous butyrate treatment were also observed in human (WISH) and bovine (MDBK) cells, pretreatment with butyrate in these cells had no effect on interferon yields.     

Mechanism of interferon action: inhibition of vesicular stomatitis virus replication in human amnion U cells by cloned human leukocyte interferon. I. Effect on early and late stages of the viral multiplication cycle

The kinetics of induction in human amnion U cells of the antiviral activity against vesicular stomatitis virus (VSV) produced by a single molecularly cloned subspecies of human leukocyte interferon (IFN-alpha A) were examined. IFN-alpha A-induced inhibition was found to be biphasic over a period of 24 h with the major extent of VSV inhibition occurring within the first 6 h of IFN treatment. The relationship of this major phase of inhibition to the early and late events of the VSV multiplication cycle was investigated. IFN-alpha A treatment had no detectable effect on the adsorption and penetration of VSV virions or on their uncoating to yield viral nucleocapsids. The polypeptides of adsorbed or uncoated VSV particles were neither preferentially degraded nor detectably altered in IFN-treated cells, as compared to untreated cells. Progeny virions released from IFN-treated cells, although greatly reduced in number, were found to be equally as infectious as those released from untreated cells. Progeny virions from IFN-treated cells also had a normal complement of VSV proteins in the same ratios as were seen in virions from untreated cells; specifically, IFN treatment produced no reduction in the incorporation of G or M protein into assembled virions. These results suggest that conditions of IFN treatment sufficient to reduce the yield of infectious VSV progeny greater than 99% do not detectably affect either the early or the late stages of the VSV multiplication cycle.     

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.     

Induction of cell surface antigens on a lymphomatous cell line by gamma interferon

The interferons are known to induce the expression of cell surface determinants. Gamma interferon, in particular, has been shown to enhance class II antigens (DR) on the cell surface. We used this gamma interferon to induce beta 2-microglobulin (beta 2 mu) and a minor, sex related transplantation antigen called H-Y on the surface of B lymphoma cells. The antitumor effect of interferon could thus be at least twofold: an antiviral effect already known and an increase of intercellular recognition (by cell surface marker enhancement); allowing the tumor cells to be "seen" better by cells of the immune system.     

Antiviral activity of Lactobacillus brevis towards herpes simplex virus type 2: role of cell wall associated components

The aim of this research was to study the mechanisms of Lactobacillus brevis antiviral activity towards HSV-2 and to identify the bacterial components responsible for the inhibiting effect. Bacterial extract and cell walls were prepared by lysozyme digestion of L. brevis cells untreated or treated with LiCl to remove S-layer proteins. Bacterial extract and cell wall fragments showed a dose dependent inhibitory effect on HSV-2 multiplication. In order to characterize the inhibitory activity of L. brevis, the bacterial extract was subjected to different physical and chemical treatments. The inhibitory activity was resistant to high temperature and proteases digestion and appeared to be associated with compounds with a molecular weight higher than 10 kDa. DNA, RNA and lipids isolated from bacterial cells were devoid of inhibitory effect. The antiviral activity of both bacterial extract and cell wall fragments obtained from L. brevis cells after the S-layer removal was significantly reduced compared to untreated cells suggesting that the inhibitory activity is likely due to a heat-resistant non-protein cell surface bacterial component.     

Antiviral and anticellular effects of interferon on the mouse embryonic cells transformed by viruses and/or chemical carcinogen.

The antiviral and anticellular activity of partially purified mouse interferon has been tested in cell lines transformed with Simian Virus 40 (MEB-SV 40), mouse sarcoma virus (Harvey strain) (MEB-MSV), and 20-methylcholanthrene (MEB-MCH), respectively. The transformed lines were derived from C3H mouse embryonic primary cells. It has been shown that the MEB-MSV cells were 10 to 50 times less sensitive to the antiviral effect of interferon than the MEB-SV 40 or MEB-MCH cells. A 30% reduction of the number of treated cells as compared with untreated control cells was taken as basis for comparison of anticellular activity of interferon in transformed lines. While the MEB-MCH cells required 1000 units of interferon for a 30% growth inhibition, about 3000 units were necessary for a comparable suppression of MEB-SV 40 cells and/or MEB-MSV cells.     

Production and properties of immune interferon from spleen cell cultures of Toxoplasma-infected mice

In response to antigenic stimulation, spleen cells from Toxoplasma-infected mice produce a factor showing inhibitory activity against vesicular stomatitis virus infection in L cell cultures. When BALB/C and ICR mice were inoculated intraperitoneally with the low-virulent S-273 strain of T. gondii, such activity was first detected in 4 and 7 days and reached maximum levels at 10 and 14 days respectively, and retained these levels for at least three weeks. However, BALB/C mice, which are considerably more sensitive to Toxoplasma infection than ICR mice, produced significantly smaller amounts of interferon (IF) after challenge with the high virulent strain. The IF produced in this system possessed certain known properties of immune (type II) IF and was not neutralized by rabbit antiserum against mouse type I IF. The immune IF preparation also inhibited multiplication of Toxoplasma within nonphagocytic L cells in an IF-like fashion, whereas Newcastle disease virus-induced (type I) IF had no effect on this parasite. The antiviral and anti-Toxoplasma activity in immune IF preparations could not be distinguished solely on the bases of their molecular weight and isoelectric point. The experiments with anti-theta serum plus complement and with nylon wool column effluent cells strongly suggest that immune IF was produced by T lymphocytes and required the assistance of macrophages.     

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.     

Some biological properties of the human amniotic membrane interferon.

Human amniotic interferon was investigated to define the species specificity of its antiviral action and to compare its anti-cellular and NK cell stimulating activities with those of other human interferons. The antiviral effect was titrated in bovine (RV-IAL) and monkey (VERO) cells. Amniotic interferon exhibited, in bovine cells, 5% of the activity seen in monkey cells, while alpha interferon displayed 200%. No effect was detected with either beta or gamma interferon in bovine cells. Daudi cells were exposed to different concentrations of various interferons and the cell numbers were determined. The anticellular effect of the amniotic interferon reached its peak on the third day of incubation. Results suggested a higher activity for alpha and gamma interferons and a lower activity for beta when compared to amniotic interferon. Using total mononuclear cells as effector cells and K 562 as target cells in a 51Cr release assay, it was demonstrated that low concentrations of amniotic interferon consistently stimulated NK cell activity in cells derived from several donors, the results indicating a higher level of activity with this interferon than with alpha and beta interferons.     

Influence of increased temperature on the inhibition of rat osteosarcoma cell multiplication "in vitro" by interferon

Purified rat interferon preparations proved effective in inhibiting cell multiplication in a rat osteosarcoma cell line. A pronounced increase in the inhibitory activity was found with increasing temperature. At 39 degrees C 20 Interferon units/ml appeared to be cytotoxic whereas incubation of cells with 2,000 Interferon units/ml at 35 degrees C resulted in a cytostatic effect.     

Human T-lymphoblastoid cell lines with high and low abilities to produce interferon-gamma constitutively and their susceptibilities to interferon

A human T-lymphoblastoid cell line, TCL-Fuj, produces large amounts of interferon (IFN)-gamma constitutively. A variant cell line, 2M, was derived from it. Both cell lines express similar surface antigen markers, but differ in surface morphology. Compared with the parent TCL-Fuj cell line, 2M produced less IFN-gamma constitutively but more in response to IFN inducers. The IFNs produced constitutively and on stimulation with inducers were analyzed by SDS-polyacrylamide gel electrophoresis. In TCL-Fuj cells, the constitutive and induced IFNs consisted of the same molecular species (22K and 39K). In 2M cells, smaller IFNs were produced constitutively (18K and 32K) and induction resulted in a marked increase of 22K molecules. These two cell lines also differed in sensitivity to the antiviral activity of IFN. Other T-lymphoblastoid cell lines, HPB-ALL and TCL-Fuj 4 cells, which did not produce IFN-gamma were permissive for vesicular stomatitis virus (VSV) replication; its growth was markedly suppressed by IFN-gamma and -alpha. TCL-Fuj cells were also permissive for VSV, but were not susceptible to the antiviral effect of the IFNs. In contrast, in 2M cells the multiplication of VSV was restricted; the viral yield was further reduced by the IFNs and increased by treatment with anti-human IFN-gamma serum. Several clonal cell lines derived from TCL-Fuj and 2M cells had characteristics similar to the respective parent cell lines. The growth of both cell lines was not affected by IFN-gamma or by -alpha. The separation of antiviral and anti-proliferative susceptibilities was peculiar to 2M cells unlike other cell lines.     

Beta-interferon inhibits cell infection by Trypanosoma cruzi

Preparations containing alpha/beta-interferon produced by L-929 cells were found to inhibit the capacity of bloodstream forms of Trypanosoma cruzi to associate with and infect mouse peritoneal macrophages or rat heart myoblasts. Marked reductions in the number of parasites per cell as well as in the percentage of cells associated with the trypanosomes were systematically observed in cultures of these cells that contained interferon. The inhibitory effect was abrogated in the presence of specific antibodies against alpha/beta-interferon, and purified beta-interferon induced a similar inhibitory effect, indicating that the active principle in the preparation was indeed interferon. Pretreatment of the parasites with alpha/beta-interferon reduced their infectivity for untreated host cells, whereas pretreatment of either type of host cell had no consequence on the interaction. The effect of interferon on the trypanosomes was reversible; the extent of the inhibitory effect was significantly reduced after 20 min, and was undetectable after 60 min when macrophages were used as host cells. Longer periods of time were required for the inhibitory effect to begin to subside (60 min) and to become undetectable or insignificant (120 min) when rat heart myoblasts were used. The results of additional studies performed with purified preparations of alpha- or beta-interferon revealed that only the latter was inhibitory of cell-parasite association. Because interferon is known to be produced shortly after T. cruzi infection and its administration has been shown to have a marked protective effect against this infection, our results suggest that the latter may involve inhibition of cell infection by interferon.     

Inhibition of herpes simplex virus type 2-induced biochemical transformation by interferon.

The effect of interferon on the biochemical transformation of thymidine kinase-deficient cells by UV-inactivated herpes simplex virus type 2 has been studied. Transformation was much less sensitive to the action of interferon than virus multiplication. However, the continuous presence of a high dose of interferon (2,000 U) inhibited transformation almost completely. Although we could not differentiate between the effect of interferon on fixation and expression of the virus thymidine kinase gene, data suggest that the inhibitory effect of interferon on transformation might be partially due to the suppression of virus thymidine kinase expression.     

Human interferon and cell growth inhibition. III. Separation of activities by treatment with sodium dodecyl sulphate

When human leukocyte interferon was treated with boiling sodium dodecyl sulphate antiviral activity without detectable effect on the growth of human amnion cells could be separated from the growth inhibitory activity by a single gel filtration. Similar results were obtained with mouse L-cell interferon. It is concluded that the two effects of interferon can be separated in distinct molecular entities.     

Effect of mycoplasma on interferon production and interferon assay in cell cultures

Armstrong, D. (The Children's Hospital of Philadelphia, Philadelphia, Pa.), and K. Paucker. Effect of mycoplasma on interferon production and interferon assay in cell cultures. J. Bacteriol. 92:97-101. 1966.-The influence of mycoplasma on the production and action of interferon was studied in cultures of both L and human embryonic kidney (HEK) cells. Mycoplasma hominis 1, the Negroni agent, and the F12 mycoplasma were used for infection of L cells, and M. hominis 1 and M. pneumoniae for inoculation of HEK cells. All strains were capable of multiplication in the culture systems employed. None produced detectable levels of interferon, and responsiveness of the cells to induction of interferon by virus remained unaltered. Infection with mycoplasma did not impair the sensitivity of the cells to the action of interferon, nor was the replication of vesicular stomatitis virus noticeably diminished.     

Stochastic receptor expression determines cell fate upon interferon treatment

Type I interferons trigger diverse biological effects by binding a common receptor, composed of IFNAR1 and IFNAR2. Intriguingly, while the activation of an antiviral state is common to all cells, antiproliferative activity and apoptosis affect only part of the population, even when cells are stimulated with saturating interferon concentrations. Manipulating receptor expression by different small interfering RNA (siRNA) concentrations reduced the fraction of responsive cells independent of the interferon used, including a newly generated, extremely tight-binding variant. Reduced receptor numbers increased 50% effective concentrations (EC(50)s) for alpha interferon 2 (IFN-α2) but not for the tight-binding variant. A correlation between receptor numbers, STAT activation, and gene induction is observed. Our data suggest that for a given cell, the response is binary (+/-) and dependent on the stochastic expression levels of the receptors on an individual cell. A low number of receptors suffices for antiviral response and is thus a robust feature common to all cells. Conversely, a high number of receptors is required for antiproliferative activity, which allows for fine-tuning on a single-cell level.     

A cell surface glycoprotein virus inhibitor that is not interferon

The possible relationship between a newly isolated glycoprotein virus inhibitor and interferon was assessed. Comparisons of the cell surface glycopeptide, obtained from mouse cerebral cortex, and interferon included antiviral activity, radioimmune assays, and the ability of antibodies raised against the brain cell surface glycoprotein (BCSG) and against mouse L cell interferon to precipitate the biological activity. BCSG was able to inhibit virus replication but only in a transient fashion. Although anti-BCSG precipitated a major portion of the radiolabelled inhibitor in a double antibody assay, anti-mouse interferon did not. Over 90% of the inhibitory activity was removed with anti-BCSG and $\text{Staphylococcus}$ protein A while anti-mouse interferon removed little, or none, of the activity under similar reaction conditions. Other properties of the BCSG that distinguish it from interferon are presented.