The mechanism of the antiviral activity of an antiviral factor of a non-interferon nature]

Antiviral factor (AF) of protein nature has been isolated from chick embryo fibroblasts infected with Venezuelan equine encephalitis virus. The suppression of virus reproduction has been observed both in homologous and heterologous cell cultures when the preparation was introduced immediately after the adsorption of the virus after pretreatment of the cell monolayer. The study has demonstrated that the antiviral effect of AF is not linked with its IFN-alpha and TNF-alpha activity. Analysis of the results obtained in this study and earlier data contained in literature suggests that infected chick embryo fibroblasts release original cytokine of non-interferon nature with antiviral activity.     

Effect of Actinomyces rimosus ribonuclease on the reproduction of viruses]

Antiviral activity of RNA-ase isolated from the fermentation broth of Actinomyces rimosus was studied. The effect of the enzyme on multiplication of the viruses of vesicular stomatitis, Newcastle and cariolovaccine diseases was investigated. It was found that the enzyme was capable of suppressing reproduction of the vesicular stomatitis virus (VSV) in the culture of chick fibroblast cells. The suppression level directly depended on the enzyme concentration and decreased with an increase in the infection multiplicity. The enzyme had no effect on multiplication of other viruses tested. RNA-ase decreased the infectious properties of the freshly isolated virus-containing material in concentrations showing the antiviral effect. Preliminary incubation of the cells with the enzyme resulted in suppression of the plaque formation by VSV. The RNA synthesis in such cultures treated with RNA-ase was somewhat lower. It was shown that the antiviral effect of RNA=ase was connected with its enzymic activity. RNA-ase has no antiviral effect in the experiments with mice infected with VSV.     

Therapeutical effect of modified adamantane copolymer compounds: study of molecular mechanisms.

Copolymers of N-polyvinylpyrrolidone-acrylic acid (AB-1) and adamantane derivatives are known to possess marked antiviral activity in in vitro and in ovo models. Among the constructed preparations of AB-1 modified by adamantane derivatives some, especially AB-4 (modified by deitiforin), were found to show more extended antiviral activity and to inhibit markedly virus reproduction in susceptible permissive cell cultures and chicken embryos. In AB-4 treated cells and allantoic sacs, virus titers (influenza virus, herpes virus, and HIV) and virus antigen concentration were decreased. On the other hand, herpes virus-specific thymidine kinase and of DNA-polymerases isolated from Escherichia coli, Plectonema boryanum, and herpes virus type 1 infected murine brain tissue retained their activity after incubation with AB-4 or AB-2. The compounds investigated, in view of their effect on virus reproduction, are thought to be prospective as antiviral agents.     

In vivo effects of coronavirus-specific T cell clones: DTH inducer cells prevent a lethal infection but do not inhibit virus replication

A lethal infection by neurotropic JHM strain of mouse hepatitis virus was prevented by the local adoptive transfer of three virus-specific Lyt-1+2-, L3T4+ T cell clones. The transfer of Lyt-1+ T cells specific for an unrelated antigen (hen egg lysozyme) did not protect. Protection required I region compatibility between the T cells and the recipients, and was reversed either by irradiation of the cells before transfer or by pretreatment of the recipients with cyclophosphamide. Adoptive transfer prevented death due to JHM virus infection but did not result in altered antiviral immunoglobulin synthesis or the suppression of viral replication in the central nervous system (CNS). The data presented implicate a local DTH response in the protection of the host from lethal infection of the CNS by a neurotropic virus, but clearly imply that other antiviral effector mechanisms are necessary for the suppression of viral replication.     

Monoclonal antibody, but not synthetic peptide, targeting the ectodomain of influenza B virus M2 proton channel has antiviral activity

The proton channels of influenza A virus (A/M2) and influenza B virus (BM2) are essential for viral replication. Previously we have shown that monoclonal antibodies targeting the ectodomain of the A/M2 proton channel have antiviral activity in vitro. In this study, we generated both monoclonal antibody and phage displayed peptide against the eight amino acids comprising the ectodomain of the BM2 proton channel and investigated their antiviral activities in vitro. A cytopathic assay showed that the monoclonal antibody potently protected MDCK cells from homologous, but not heterologous, virus infections. A plaque forming assay showed that viral replication was not completely neutralized, but greatly inhibited, by the monoclonal antibody. In contrast, no antiviral activity was observed for the synthetic native or engineered peptides. These results indicate that antibody targeting the M2 proton channel is a promising therapeutic candidate for treating influenza virus infections, and that antibody structure is important for antiviral activity.     

茜草对II型单纯疱疹病毒的体外生长抑制作用

茜草为常用中药。本研究发现,茜草的甲醇提取物在体外细胞培养上对HSV-2有明显的抑制作用。在Vero细胞上,病毒抑制数可达3个对数。病毒增殖抑制实验表明,该制剂确实抑制了HSV-2感染性病毒颗丝的产生。在不同的细胞系上进行比较,发现该制剂的抗病毒作用具有明显的细胞系依赖性。本文认为,茜草的甲醇提取物具有抑制HSV-2的作用,但其有效成分为何种,尚待进一步研究。     

Increase in the antiviral resistance of cells after treating them with messenger RNA for antiviral protein]

The authors studied antiviral resistance of murine cells L-929 following single introduction into them of homologous and heterologous informative RNA preparations for antiviral protein (i-RNA-AVP). As shown, in using homologous i-RVA-AVP preparations suppression of the virus production constituted 90--93%, and was stably traced in cell passage in the course of 1 1/2 months (observation period). Following cell contact with heterologous i-RNA-AVP preparations suppression the first 6 passages of the virus production constituted about 90%, rising by the 16th passage to 99.9%. The data obtained pointed to the possibility of stable increase of cell antiviral resistance with the aid of i-RNA-AVP, this could serve as a new effective method of nonspecific cell protection from the viruses.     

Comparison of Antiviral Activity between IgA and IgG Specific to Influenza Virus Hemagglutinin: Increased Potential of IgA for Heterosubtypic Immunity

Both IgA and IgG antibodies are known to play important roles in protection against influenza virus infection. While IgG is the major isotype induced systemically, IgA is predominant in mucosal tissues, including the upper respiratory tract. Although IgA antibodies are believed to have unique advantages in mucosal immunity, information on direct comparisons of the in vitro antiviral activities of IgA and IgG antibodies recognizing the same epitope is limited. In this study, we demonstrate differences in antiviral activities between these isotypes using monoclonal IgA and IgG antibodies obtained from hybridomas of the same origin. Polymeric IgA-producing hybridoma cells were successfully subcloned from those originally producing monoclonal antibody S139/1, a hemaggulutinin (HA)-specific IgG that was generated against an influenza A virus strain of the H3 subtype but had cross-neutralizing activities against the H1, H2, H13, and H16 subtypes. These monoclonal S139/1 IgA and IgG antibodies were assumed to recognize the same epitope and thus used to compare their antiviral activities. We found that both S139/1 IgA and IgG antibodies strongly bound to the homologous H3 virus in an enzyme-linked immunosorbent assay, and there were no significant differences in their hemagglutination-inhibiting and neutralizing activities against the H3 virus. In contrast, S139/1 IgA showed remarkably higher cross-binding to and antiviral activities against H1, H2, and H13 viruses than S139/1 IgG. It was also noted that S139/1 IgA, but not IgG, drastically suppressed the extracellular release of the viruses from infected cells. Electron microscopy revealed that S139/1 IgA deposited newly produced viral particles on the cell surface, most likely by tethering the particles. These results suggest that anti-HA IgA has greater potential to prevent influenza A virus infection than IgG antibodies, likely due to increased avidity conferred by its multivalency, and that this advantage may be particularly important for heterosubtypic immunity.     

Impact of delivery method on antiviral activity of phosphodiester,phosphorothioate, and phosphoryl guanidine oligonucleotides in MDCK cells infected with H5N1 bird flu virus

We have previously described nanocomposites containing conjugates or complexes of native oligodeoxyribonucleotides with poly-L-lysine and TiO₂ nanoparticles. We have shown that these nanocomposites efficiently suppressed influenza A virus reproduction in MDCK cells. Here, we have synthesized previously undescribed nanocomposites that consist of TiO₂ nanoparticles and polylysine conjugates with oligonucleotides that contain phosphoryl guanidine or phosphorothioate internucleotide groups. These nanocomposites have been shown to exhibit antiviral activity in MDCK cells infected with H5N1 influenza A virus. The nanocomposites containing phosphorothioate oligonucleotides inhibited virus replication ~130-fold. More potent inhibition, i.e., ~5000-fold or ~4600-fold, has been demonstrated by nanocomposites that contain phosphoryl guanidine or phosphodiester oligonucleotides, respectively. Free oligonucleotides have been nearly inactive. The antiviral activity of oligonucleotides of all three types, when delivered by Lipofectamine, has been significantly lower compared to the oligonucleotides delivered in the nanocomposites. In the former case, the phosphoryl guanidine oligonucleotide has appeared to be the most efficient; it has inhibited the virus replication by a factor of 400. The results make it possible to consider phosphoryl guanidine oligonucleotides, along with other oligonucleotide derivatives, as potential antiviral agents against H5N1 avian flu virus.     

Chemical inhibition of RNA viruses reveals REDD1 as a host defense factor

A chemical genetics approach was taken to identify inhibitors of NS1, a major influenza A virus virulence factor that inhibits host gene expression. A high-throughput screen of 200,000 synthetic compounds identified small molecules that reversed NS1-mediated inhibition of host gene expression. A counterscreen for suppression of influenza virus cytotoxicity identified naphthalimides that inhibited replication of influenza virus and vesicular stomatitis virus (VSV). The mechanism of action occurs through activation of REDD1 expression and concomitant inhibition of mammalian target of rapamycin complex 1 (mTORC1) via TSC1-TSC2 complex. The antiviral activity of naphthalimides was abolished in REDD1(-/-) cells. Inhibition of REDD1 expression by viruses resulted in activation of the mTORC1 pathway. REDD1(-/-) cells prematurely upregulated viral proteins via mTORC1 activation and were permissive to virus replication. In contrast, cells conditionally expressing high concentrations of REDD1 downregulated the amount of viral protein. Thus, REDD1 is a new host defense factor, and chemical activation of REDD1 expression represents a potent antiviral intervention strategy.     

Membrane phenotype of murine effector and suppressor T cells involved in delayed hypersensitivity and protective immunity to herpes simplex virus

The membrane phenotype of T cells involved in delayed hypersensitivity (DH), protective immunity, and suppression of delayed hypersensitivity to herpes simplex virus (HSV) has been determined. T cells from immune lymph nodes transferring DH and antiviral immunity to normal recipients were characterized as Lyt 1+2-. There appeared to be no detectable antiviral role for Lyt 1-2+ cells in the transferred cell suspension. Splenic T cells suppressing the induction of DH to HSV were characterized as being both Lyt 1+2- and Lyt 1-2+ 4 weeks after their induction. At earlier times, i.e., after 7 days, the suppression was mediated solely by the Lyt 1+2- population. Thereafter, a progressive increase in the contribution of the Lyt 1-2+ suppressor was observed. Both the early and later phases of suppression were due to I-J positive cells. The nature of the two suppressor cell types is discussed in relation to suppressor cell "cascades" and to the pathogenesis of herpes simplex virus infection.     

Monoclonal antibodies against baboon endogenous virus and against host cell antigens.

Monoclonal antibodies were produced by murine hybridomas after immunization with semipurified baboon endogenous virus. In a solid-phase radioimmunoassay, two antibodies (F12-9 and B9-18) reacted with viral antigen only. The antibodies A6-8 and C9-12 also reacted with virus-producing cells but not with control cells, whereas antibodies E4-6 and D12-2 bound to virus-free cells as well. The cytofluorometry technique confirmed these results and showed a competition between antibodies A6-8 and C9-12 for binding to virus-producing cells as well as a competition between antibodies D12-2 and E4-6 for binding to virus-free human cells. An immune precipitation assay with disrupted virions indicated that antibodies A6-8, B9-18, and C9-12 were directed against the gp70 glycoprotein, and that antibody F12-9 reacted with a viral antigen with a molecular weight of 18,000. The syncytia induced in RSa cells by baboon molecular weight of 18,000. The syncytia induced in RSa cells by baboon endogenous virus could be inhibited either when antibody A6-8 or C9-12 was combined to the virus or when the RSa cells were treated with the anticellular antibody D12-2 or E4-6. These two effects were not observed with Mason-Pfizer virus. Thus, of three antibodies with specificities for viral gp70, two (A6-8 and C9-12) were directed at viral sites responsible for syncytium formation. Another antiviral antibody (F12-9) reacted with a protein of unknown function with a molecular weight of 18,000. The two anticellular antibodies were directed at similar or neighboring epitopes, which may be situated within the receptor to the virus.     

Monoclonal antibodies suppress replication of herpes simplex virus type 1 in trigeminal ganglia.

The effect of monoclonal antibodies on the growth of herpes simplex virus type 1 in trigeminal ganglia was investigated. Four-week-old mice were infected on an abrased cornea with herpes simplex virus type 1. Forty-eight hours after infection, trigeminal ganglia ipsilateral with infected eyes were removed and placed in culture. Incubation of infected ganglia in the presence of a pool of nonneutralizing monoclonal antibodies specific for glycoproteins of gB and gE suppressed virus growth by greater than 90%. This was comparable to the amount of suppression observed when infected ganglia were incubated in hyperimmune serum. Individual monoclonal antibodies were less efficient, being able to inhibit virus growth by only two- to threefold. The mechanism of suppression was examined. Reduction in virus growth was observed under conditions in which all susceptible ganglion cells were infected in vitro before nonneutralizing monoclonal antibody was added. Similar results were obtained in tests with virus-infected neuroblastoma cells. Furthermore, suppression of infectious progeny was seen in the absence of complement and immunologically reactive cells. Thus, neither virus neutralization nor immunocytolysis could account for the effects of antibody on virus growth. Rather, the data suggest that antibody can bind to herpes simplex virus type 1-infected neuronal cells and suppress intracellular virus replication.     

Mechanism of recovery from acute virus infection: treatment of lymphocytic choriomeningitis virus-infected mice with monoclonal antibodies reveals that Lyt-2+ T lymphocytes mediate clearance of virus and regulate the antiviral antibody response.

After intravenous infection of mice, lymphocytic choriomeningitis virus multiplied in spleens and livers, attaining highest concentrations on days 4 to 6. The subsequent clearance was as rapid, and 8 to 10 days after inoculation, infectivity was usually below detectability. During the effector phase of virus elimination, both cytotoxic T-cell (CTL) activity and the number of cells producing antiviral antibodies were high. Monoclonal antibodies directed against T lymphocytes and T-lymphocyte subsets were inoculated once intravenously 5, 6, or 7 days after infection of the animals, and the effects on antiviral immune responses, as well as on elimination of virus from the organs, were determined. Treatment with anti-Thy-1 and anti-Lyt-2 antibodies blocked elimination of the virus and profoundly diminished the activity of spleen CTLs but reduced the antibody response partially (anti-Thy-1) or increased it (anti-Lyt-2). In contrast, treatment with the anti-L3T4 antibody had essentially no effect on either virus elimination or CTL response but abolished antibody production. We conclude that Lyt-2+ (cytotoxic-suppressive) T lymphocytes are needed for elimination of the virus and also regulate the humoral response but that antiviral antibodies are not essential for control of the infection.     

Microinjection of anti-interferon antibodies into cells does not inhibit the induction of an antiviral state by interferon.

Affinity-purified polyclonal antibodies directed against human lymphoblastoid interferon (IFN), Escherichia coli-derived human IFN-alpha 2, or two synthetic fragments of human IFN-alpha 1 all neutralized the antiviral activity of human alpha IFNs when added to the culture medium of MDBK cells together with IFNs. However, when these antibodies were microinjected into the cytoplasm or the nucleus of cells, subsequent treatment of the cells with IFNs induced full protection against vesicular stomatitis virus. This suggests that IFNs themselves need not act in the cytoplasmic compartment or the nucleus to induce an antiviral state.     

T4+ T helper cell function in vivo: differential requirement for induction of antiviral cytotoxic T-cell and antibody responses.

This study documents the differential requirements of T4+ T helper cells in the induction of virus-specific cytotoxic T-lymphocyte (CTL) and antibody responses during acute lymphocytic choriomeningitis virus infection. Two monoclonal antibodies (GK1.5 and RL172.4) directed against the L3T4 (T4) molecule were used for depleting T helper cells from mice. Depletion of T4+ cells caused a pronounced suppression of antiviral antibody response (20-fold decrease) but had minimal effect on virus-specific CTL response (less than 2-fold reduction). Despite the elimination of greater than 90% of T helper cells, anti-L3T4-treated mice were able to generate a CTL response of sufficient magnitude to control the viral infection. In contrast, depletion of Lyt2+ T cells abrogated the CTL response and the ability to eliminate virus. Thus, our results underscore the importance of the Lyt2+ T-cell subset in controlling infection with this virus and show that a deficiency of T4+ T cells is likely to have a more severe effect on antibody production than on CTL responses.     

In vitro Antiviral Activity of Recombinant Antibodies of IgG and IgA Isotypes to Hemagglutinin of the Influenza A Virus

Seasonal and highly infectious strains of the influenza A and influenza B viruses cause millions of cases of severe complications in elderly people, children, and patients with immune diseases each year. Immunoglobulin A (IgA), which is an active component of humoral immunity, can prevent the spread of the virus in the upper respiratory tract. The preparation and study of the properties of recombinant virus-specific IgA could be an important approach to finding new means of preventing and treating influenza. Based on CHO DG44 cells, we developed stable monoclonal cell lines that produce monomeric and dimeric antibodies FI6-IgA1 and FI6-IgA2m1 to hemagglutinin (HA) of the influenza A virus. When studying the productivity, growth, and stability of the obtained clones, we found that the dimeric form of antibodies of IgA1 isotype is superior to other forms. The dimeric form of IgA antibodies plays a key role in mucosal immunity. Recognizing the prospects of using dimeric IgA as prophylactic and therapeutic mucosal drugs for viral infections, we studied their virus-neutralizing and antiviral activities on MDCK cell culture and compared them with the antibodies of the IgG1 isotype. This study presents the data on antiviral and virus-neutralizing activities of the FI6-IgA1 dimers to seasonal and highly infectious strains of influenza A virus.     

African swine fever virus: achievements over the last decade of the 20th century]

Complete nucleotide sequence of African swine fever (ASF) virus genome was determined in 1993-1999. Deletion mutants with low virulence for pigs were obtained. Genes of structural (p72, p54, p12, cleavage products pp220 and pp60, hemagglutinin) and nonstructural (p32) proteins were mapped. The significance of different proteins in virus adsorption and resistance to challenge was elucidated, their location in infected cell and virion was determined. Lipid composition of the virus was studied. A protocol of virion morphogenesis was suggested, which explains their morphology. Apoptosis, consumption coagulopathy, and development of delayed type hypersensitivity are regarded as the main pathogenetic mechanisms. Antigens acting as targets and inductors of immune cytological reactions and antibodies mediating suppression of virus reproduction were determined.     

Therapy-induced antibodies against the antiviral and antiproliferative effects of interferons in patients with chronic hepatitis C virus infection

Sera from 86 patients with chronic hepatitis C virus (HCV) infection treated with recombinant interferons-alpha (rIFN-alpha) were screened for IFN-binding and antiviral effect-neutralizing antibodies. Out of the 61 patients treated with rIFN-alpha2b, 46% had binding and 28% had neutralizing antibodies. 44% of the 25 patients treated with rIFN-alpha2a developed binding antibodies and 24% had neutralizing antibodies. Contradictory data were observed concerning the appearance of anti-IFN antibodies and the outcome of IFN therapy. A significantly higher number of the patients with a sustained response to rIFN-alpha2b therapy formed antibodies than the number among the non-responder patients. At the same time, in the patients treated with rIFN-alpha2a, opposite data were found. The activity of the antibodies in some sera was studied against the antiproliferative effect of IFNs on Daudi cells by measuring the [3H]thymidine incorporation. The binding antibodies without neutralization of the antiviral effect of the IFNs inhibited the antiproliferative activity of the rIFNs, similarly to antibodies having both IFN-binding and antiviral effect-neutralizing capacities. At the same time, the antiproliferative effect of the natural IFN was less affected. It is suggested that the antiproliferative assay is more sensitive than the antiviral method for demonstration of the presence of antibodies exerting an inhibitory effect on the biological activities of IFN.