Human chromosome 21 dosage: effect on the expression of the interferon induced antiviral state

Human primary skin fibroblasts trisomic for chromosome 13, 18, or 21 and diploid human skin fibroblasts were induced for an antiviral response with human interferon. The cells that were trisomnic for chromosome 21 were three to seven times more sensitive to protection by human interferon than the normal diploid or trisomic 18 or 13 fibroblasts. The differential response in trisomnic 21 cells is consistent with the known assignment of the human antiviral gene to chromosome 21.

Common pathways of interferon and hormonal action

The action of interferon as well as polypeptide hormones has been shown to be transmissible between cells, possibly through gap-junctional transfer of secondary messenger molecules. This and other similarities between interferon and polypeptide hormones have led us to propose that there is a common cellular pathway of interferon and hormonal action. If correct, this hypothesis would predict that interferon should cause a species-specific hormonal response and a hormone should induce tissue-specific antiviral activity. If these two responses are mediated by similar secondary messengers, they should be transmissible and cross-activate cells. Here, we show that interferon caused a species-specific hormonal response (noradrenaline-like stimulation of the beat frequency of cultured mouse myocardial cells). Noradrenaline induced an interferon-like antiviral state in mouse myocardial cells but not human amnion (WISH) cells. In conditions which demonstrate interferon-induced transfer of viral resistance, exposure of co-cultures of mouse myocardial cells and WISH cells to either human interferon or noradrenaline caused an increased beat frequency in the myocardial cells and development of antiviral activity in WISH cells, respectively. These studies strongly suggest common pathways of interferon and hormonal stimulation that are transmissible between cells.

Mode of action of SDZ NIM 811, a nonimmunosuppressive cyclosporin A analog with activity against human immunodeficiency virus type 1 (HIV-1): interference with early and late events in HIV-1 replication

SDZ NIM 811 is a cyclosporin A analog that is completely devoid of immunosuppressive capacity but exhibits potent and selective anti-human immunodeficiency virus type 1 (HIV-1) activity. The mechanism of action of SDZ NIM 811 is clearly different from those of all other anti-HIV agents described so far. In cell-free assays, it is not an inhibitor of reverse transcriptase, protease, integrase, and it does not interfere with Rev or Tat function. SDZ NIM 811 does not down-regulate CD4 or inhibit fusion between infected and uninfected, CD4-expressing cells. p24 production from chronically HIV-infected cells is not impaired either. To elucidate the mode of action of SDZ NIM 811, we performed DNA PCR analysis in HIV-1 IIIB-infected MT4 cells in one cycle of virus replication. The effects of SDZ NIM 811 on the kinetics of viral DNA synthesis, appearance of two-long terminal repeat circles (2-LTR circles), and integration of DNA were studied. SDZ NIM 811 inhibited 2-LTR circle formation in a concentration-dependent manner, which is indicative of nuclear localization of preintegration complexes. Half-maximal inhibition was achieved at 0.17 microgram/ml; this concentration is close to the 50% inhibitory concentrations (0.01 to 0.2 microgram/ml) for viral growth inhibition. As expected, integration of proviral DNA into cellular DNA was also inhibited by SDZ NIM 811. Analysis of the viral particles produced by SDZ NIM 811-treated, chronically infected cells revealed amounts of capsid proteins, reverse transcriptase activity, and viral RNA comparable to those of the untreated control. However, these particles showed a dose-dependent reduction in infectivity (50% inhibitory concentration of 0.028 microgram/ml) which indicates that the assembly process is also impaired by SDZ NIM 811. Gag proteins are postulated to play a role not only in assembly but also in early steps of viral replication, e.g., nuclear localization of the preintegration complex. Recently, it was reported that HIV-1 Gag protein binds to cyclophilin A, the intracellular receptor for cyclosporin A. Interference with Gag-cyclophilin interaction may be the molecular basis for the antiviral activity of cyclosporin A and its analogs.

Transmembrane signaling by interferon alpha involves diacylglycerol production and activation of the epsilon isoform of protein kinase C in Daudi cells

The early events that occur after treatment of the highly interferon alpha (IFN-alpha)-sensitive human lymphoblastoid Daudi cell line with human leukocyte IFN-alpha have been examined. IFN-alpha treatment of Daudi cells results in a rapid and transient increase in the cellular content of diacylglycerol, which occurs in the absence of inositol phospholipid turnover, or an increase in intracellular calcium concentration. Furthermore, IFN-alpha treatment results in a selective, time-dependent activation of the Ca(2+)-independent epsilon isoform of protein kinase C (PKC), while the alpha isoform is unaffected by IFN-alpha treatment. In contrast, IFN-alpha treatment of an IFN-resistant subclone of Daudi cells had no effect on the diacylglycerol content of cells and on the activation of PKC-epsilon. The selective PKC inhibitor staurosporine blocked the transcriptional activation of IFN-alpha-stimulated genes, the cytoplasmic accumulation of mRNAs for these genes, and the induction of antiviral activity by IFN-alpha against vesicular stomatitis virus in IFN-sensitive cells. These observations suggest that transmembrane signaling of IFN-alpha involves diacylglycerol production and activation of PKC-epsilon in Daudi cells.

Interferon increases HLA synthesis in melanoma cells: interferon-resistant and -sensitive cell lines

We report that human leukocyte interferon preparations increase the expression of beta 2-microglobulin by 100-200% on the surface of normal fibroblast and melanoma cell lines sensitive to interferon. This increase in expression can be correlated with an increase in HLA synthesis as measured by incorporation of [35S]methionine in these antigens. This enhanced HLA synthesis, which is 5- to 17-fold, is time dependent and dose related. Synchronized cells in the G0/G1 phase of the cell cycle appear to be more sensitive to this interferon action. Neither an increase in surface expression nor in HLA synthesis is observed in a melanoma cell line resistant to the antiviral and antigrowth effects of interferon. Furthermore, there appears to be a stronger correlation between this increased HLA synthesis and the antiviral function than between it and the antiproliferative action of interferon.

Immune and virus-induced interferons may activate cells by different derepressional mechanisms

Virus-induced interferon (VIF), and immune interferon (IIF) produced by lymphocytes following activation by various mitogens (phytohaemagglutinin, concanavalin A, staphlococcal enterotoxin A) or by specific antigenic stimulation (tuberculin, bacterial toxoids, and viral antigens) show important functional differences. These include different antitumour and immunoregulatory activities and differential inhibition of activity by mercaptoethanol. Another important difference has recently been shown: cells treated with IIF acquire the antiviral state much more slowly than those treated with VIF. This may be due to (1) difference in cellular receptors, (2) presence of an inhibitor of antiviral activity in the IIF preparations, or (3) a different mechanism of activation of the antiviral state by the two types of interferon. The first two hypotheses seem unlikely, since (1) no difference between cell association by the two types of interferon has been detected, and (2) the presence of the slow acting IIF preparation did not inhibit the rapid activation by VIF. The present study shows that the different kinetics of induction of the antiviral state result from a major difference in the mechanism by which IIF and VIF activate cells.

Potentiation by thyroxine of interferon-gamma-induced antiviral state requires PKA and PKC activities

Added to HeLa cells previously exposed to recombinant human interferon (IFN)-gamma for 20 h, thyroid hormone [L-thyroxine (T4)] in physiological concentrations potentiates the antiviral action of IFN-gamma by more than 100-fold in 4 h. We examined protein kinase activities for their contributions to the mechanism of this posttranslational effect of thyroid hormone. Added concurrently with thyroid hormone, the protein kinase C (PKC) inhibitor CGP-41251 (5 nM) blocked T4 potentiation of IFN-gamma action. Coincubated with CGP-41251, phorbol 12-myristate 13-acetate (PMA) reversed the effect of the inhibitor on thyroid hormone action. U-73122 (10 nM), a phospholipase C inhibitor, also blocked hormone potentiation. KT-5720 (500 nM), a protein kinase A (PKA) inhibitor, completely inhibited the T4 effect, whereas 8-bromoadenosine 3',5'-cyclic monophosphate (8-BrcAMP) restored hormone action in the presence of KT-5720. In the absence of T4, 8-BrcAMP and PMA, added together to cells in the 4-h paradigm, fully reproduced hormone potentiation of the antiviral effect of IFN-gamma. Incubated individually with IFN-gamma-treated cells, the two agonists had no potentiating action. Thyroid hormone apparently must activate both PKA and PKC in the nongenomic pathway of IFN-gamma action to enhance antiviral activity in HeLa cells.

Platelet-derived growth factor (PDGF) inhibits antiviral and anticellular actin of interferon in synchronized mouse or human cells

Antiviral and anticellular action of purified mouse or human interferon was found to be inhibited in the quiescent, monolayer cultures of mouse or human fibroblasts (3T3 and FS-14) stimulated for growth by PDGF. In the asynchronous cell cultures the antagonistic effect of PDGF towards interferon, was much less evident. The optimal synchronization of cells for division was obtained by density inhibition and the incubation of the confluent cell monolayers in the low serum medium for 24 h and in 5% platelet poor plasma serum (PPPS) medium for further 24 h at 37 degrees C. Under appropriate conditions also pure epidermal growth factor (EGF) and fibroblast growth factor (FGF) acted as antagonists of interferon. It is suggested that interferons and growth factors are two families of hormones. The effects induced by interferons and growth factors are found to be directly opposite.

Interferon induction by poly (I): poly (C) enclosed in phospholipid particles

Liposomes were prepared with phospholipids (sphingomyelin, lecithin, and phosphatidylethanolamine) in combination with cholesterol and charged lipids (dicetyl phosphate and stearylamine) and contained either poly(I):poly(C) or poly(I). Neutral and positively charged liposomes attached much better to L-929 cells in tissue culture than did negatively charged particles. Liposomes were toxic to L cells at relatively low concentrations, making the determination of antiviral activity induced by particles containing poly(I):poly(C) difficult to measure by the plaque reduction assay. When injected into mice, all of the liposomes containing poly(I):poly(C), except phosphatidylethanolamine liposomes, greatly potentiated and extended the serum interferon response of poly(I):poly(C). Lecithin and sphingomyelin liposomes given intravenously were ten times more effective than free poly(I):poly(C) in stimulating production of serum interferon. Sphingomyelin liposomes containing [(14)C]poly(I):poly(C) were 88% cleared from the bloodstream of mice by 3 min after intravenous injection. Most of the radioactivity (70%) was captured by the liver and remained there for at least 4 h. By 2 h, 7% of the radioactivity could be found in the spleen. Five percent of the radioactivity was found in the lungs at 30 min, with decreasing amounts thereafter. Small amounts of radioactivity were found in the muscle and kidneys. The spleen was shown to contain appreciable levels of interferon at 4 h, and low levels were found in the liver. Radioactivity accumulated slowly in the liver following an intraperitoneal injection of sphingomyelin liposomes containing [(14)C]poly(I):poly(C). By 4 h, 26% of the dose was recovered from the liver and 4.9% from the spleen, with small amounts in the lung, kidney, and omentum.

Foot-and-mouth disease virus inhibition induced in mice by synthetic double-stranded RNA (polyriboinosinic and polyribocytidylic acids)

Synthetic 2-stranded RNA-a helical complex formed by duplexing homopolymers of polyriboinosinic and polyribocytidylic acids (poly I:C)-induced host resistance to foot-and-mouth disease virus when microgram quantities were injected into mice. There was a graded response as shown by titrations of polynucleotide complex or virus. Protection was effective for >48 hours after a single injection of polynucleotide complex. Survival and serum interferon titers were directly related.

Interference among defective interfering particles of vesicular stomatitis virus

Three defective interfering (DI) particles of vesicular stomatitis virus (VSV), all derived from the same parental standard San Juan strain (Indiana serotype), were used in various combinations to infect cells together with the parental virus. The replication of their RNA genomes in the presence of other competing genomes was described by the hierarchical sequence: DI 0.52 particles greater than DI 0.45 particles less than or equal to DI-T particles greater than standard VSV. The advantage of one DI particle over another was not due simply to multiplicity effects nor to the irreversible occupation of limited cellular sites. Interference, however, did correlate with a change in the ratio of plus and minus RNA templates that accumulated intracellularly and with the presence of new sequences at the 3' end of the DI genomes. DI 0.52 particles contained significantly more nucleotides at the 3' end that were complementary to those at the 5' end of its RNA than did DI-T or DI 0.45 particles. The first 45 nucleotides at the 3' ends of all of the DI RNAs were identical. VSV and its DI particles can be separated into three classes, depending on their terminal RNA sequences. These sequences suggest two mechanisms, one based on the affinity of polymerase binding and the other on the affinity of N-protein binding, that may account for interference by DI particles against standard VSV and among DI particles themselves.

Homologous interference induced by a temperature-sensitive mutant derived from an HVJ (Sendai virus) carrier culture

Homologous interference between a temperature-sensitive small plaque mutant (HVJ-pB) derived from an HVJ (haemagglutinating virus of Japan - the Sendai strain of parainfluenza I virus) carrier culture of BHK cells and the original wild-type virus (HVJ-W) has been investigated. Prior infection of LLCMK2, HeLa, BHK or mouse L cells with HVJ-pB, both at permissive and non-permissive temperatures, for 24 h resulted in a reduced yield of superinfecting HVJ-W, reflecting a smaller number of cells capable of producing the superinfecting virus. However, HVJ-pB did not interfere with the replication of vesicular stomatitis virus, Sindbis virus or Newcastle disease virus. Interference in this system seems to be due to inhibition of the attachment of superinfecting HVJ-W as a result of intracellular mechanisms operating at a late stage in the replication of the interfering virus. There is also blocking or destruction of cellular receptors by extra-cellular particles of the interfering virus. Protein synthesis coded for by the complete virus genome is required to establish and maintain the interference, and treatment with actinomycin D has no effect on the interference phenomenon.

Lead aggravates viral disease and represses the antiviral activity of interferon inducers

Lead acetate was administered continuously in the drinking water to CD-1 male mice beginning at 4 weeks of age. An LD(10-20) of the lytic viruses or 300 plaque-forming units of RLV was inoculated intrapertioneally at 6 weeks of age. Lead increased the response of the mice to all classes of viruses against which it was tested: an RNA picornavirus-encephalomyocarditis (EMCV), a DNA herpesvirus-pseudoribies, an RNA leukemia-virus-Rauscher leukemia (RLV), an RNA arbovirus B-St. Louis encephalitis, and an RNA arbovirus A-western encephalitis. Most studies were performed between lead and EMCV. Increases in EMCV mortality in lead treated mice over controls ranged from 2x at a lead level of 0.004M to 7x (100% mortality) at a 0.1M lead level. Splenomegaly with spleens 800 to 1100 mg in weight containing high titers of RLV occurred in lead (0.03M)-treated mice 3 and 6 weeks after RLV inoculation; spleens or RLV controls were normal in weight (200 mg) and were free of virus. Lead did not reduce the protective effect of mouse interferon (IF) against the lethal action of EMCV, but it did repress the EMCV antiviral effect of poly I/poly C (PIC) and of Newcastle disease virus (NDV) against EMCV mortality. These data indicate several new facts concerning adverse effects lead may have on an animal: (1) lead aggravates viral disease, most likely in part, through reduced IF synthesis; (2) lead represses the anti-EMCV protective effects of both PIC and of NDV, which, in other reports, were shown to induce IF in radioresistant macrophages (PIC) or in radiosensitive lymphocytes (NDV); (3) lead may then be said to repress IF induction in two kinds of cells; (4) however, lead does not inhibit IF action.

Effect of stereospecificity of chemically synthesized lipid A-subunit analogues GLA-27 and GLA-40 on the expression of immunopharmacological activities

Tumor necrosis factor (TNF)-inducing, mitogenic, polyclonal B cell activation (PBA), macrophage activation and antiviral activities of chemically synthesized lipid A-subunit analogues, GLA-27 and GLA-40, were investigated. The structure of GLA-27 comprises 4-O-phosphono-D-glucosamine carrying tetradecanoyl and 3-tetradecanoyloxytetradecanoyl [C14-O-(C14)] groups as the 3-O- and 2-N-acyl substituents, respectively. GLA-40 is a 1-deoxy compound of GLA-27. The activities of stereoisomers, (R) and (S) forms at the C3 position of the C14-O-(C14) group, of both compounds were also investigated. TNF-inducing activity of the (S) isomers of GLA-27 and GLA-40 was stronger than that of the (R) isomers while the (R) isomers exhibited stronger mitogenic and PBA activities than the (S) isomers. With respect to macrophage activation such as phagocytosis, acid phosphatase and N-acetyl-beta-D-glucosaminidase activity as cellular lysosomal enzymes and cytostasis, peritoneal macrophages obtained from mice administered i.p. with test samples showed significant activities. Among stereoisomers of GLA-27, the (R) isomer exhibited somewhat stronger phagocytic and lysosomal enzyme activities than those of the (S) isomer while there was no appreciable difference in the activities between the isomers of GLA-40. Significant cytostasis-inducing activity was observed in stereoisomers tested. All of the isomers showed remarkable antiviral activity against vaccinia virus.

Conditions required for induction of interferon by rotaviruses and for their sensitivity to its action

Our investigations of interferon induction by rotaviruses showed that only when cells were pretreated with interferon, i.e., primed, could infectious rotaviruses induce significant quantities of interferon. As little as 0.5 U of interferon provided sufficient priming for this induction. UV-irradiated rotaviruses induced significant levels of interferon, and priming only marginally enhanced the yields. Neither heat-inactivated virus nor serum-neutralized virus was able to induce interferon, even when cells were primed. When cells were treated with purified virus double-stranded RNA in the presence of DEAE-dextran to facilitate uptake, interferon was induced, although priming did not enhance yields. These results strongly implicate the viral double-stranded RNA as the effector for interferon induction. The insensitivity of rotaviruses to interferon in vitro was also studied. Results suggested that this lack of sensitivity was not due to any inherent resistance of the virus to the antiviral proteins, but rather to lack of activation of cellular enzymes exhibiting antiviral activity.