Virginia S. Hinshaw

Influenza Virus NS1 Protein Induces Apoptosis in Cultured Cells

ABSTRACT The importance of influenza viruses as worldwide pathogens in humans, domestic animals, and poultry is well recognized. Discerning how influenza viruses interact with the host at a cellular level is crucial for a better understanding of viral pathogenesis. Influenza viruses induce apoptosis through mechanisms involving the interplay of cellular and viral factors that may depend on the cell type. However, it is unclear which viral genes induce apoptosis. In these studies, we show that the expression of the nonstructural (NS) gene of influenza A virus is sufficient to induce apoptosis in MDCK and HeLa cells. Further studies showed that the multimerization domain of the NS1 protein but not the effector domain is required for apoptosis. However, this mutation is not sufficient to inhibit apoptosis using whole virus.

Influenza viral infection of swine in the United States 1988-1989.

SummarySwine are an animal reservoir for influenza viruses capable of causing disease in humans. A serological survey in 1988–1989 demonstrates that subtype H1 influenza viruses continue to circulate at high frequency among swine in the north-central U.S.A. (average 51% incidence). Subtype H3 viruses antigenically similar to current human H3 viruses are circulating at low frequency (average 1.1%), particularly in the southeast U.S.A.

Immunogenicity and efficacy of baculovirus-expressed and DNA-based equine influenza virus hemagglutinin vaccines in mice

Two fundamentally different approaches to vaccination of BALB/c mice with the hemagglutinin (HA) of A/Equine/Kentucky/1/81 (H3N8) (Eq/KY) were evaluated, that is, administration of HA protein vs administration of HA-encoding DNA. Each vaccine was tested for its immunogenicity and ability to provide protection from homologous virus challenge. HA protein was synthesized in vitro by infection of Sf21 insect cells with a recombinant baculovirus. Intranasal administration of this vaccine induced virus-specific antibodies, as measured by enzyme-linked immunosorbent assay (ELISA), but did not induce virus neutralizing (VN) antibodies. This route of administration provided partial protection from virus challenge, but interestingly, this protection was completely abrogated, rather than enhanced, by co-administration of 10 micrograms of cholera holotoxin. As a second approach, mice were directly vaccinated in vivo by Accell gene gun delivery of plasmid DNA encoding the Eq/KY HA gene. This approach induced VN antibodies as well as virus-specific ELISA antibodies. When two doses of DNA vaccine were administered 3 weeks apart, mice were not protected from challenge, although they cleared the infection more rapidly than control mice. However, when the second DNA vaccination was delayed until 9 weeks after the first, 9 out of 10 vaccinated mice were completely protected. These results indicate that the time between initial and booster DNA vaccinations may be an important variable in determining DNA vaccination efficacy.

Destruction of Lymphocytes by a Virulent Avian Influenza A Virus

Infection of chickens by a virulent avian influenza A virus, A/turkey/Ont/7732/66 (H5N9), was associated with a severe lymphopenia. High titres of infectious virus were found in lymphoid tissues early in infection and were accompanied by severe damage to the lymphocyte populations as demonstrated by histopathological examination. Non-lymphoid cell populations in these tissues were unaffected, as were other organs examined. The viral nucleoprotein was localized by immunoperoxidase staining to lymphocytes in affected tissues early in infection.

Antigenic Conservation of H1N1 Swine Influenza Viruses

Influenza viruses of the H1N1 subtype have been continually circulating in pigs in the U.S.A. for at least 50 years. To examine the level of antigenic variation in these swine viruses, a panel of 60 monoclonal antibodies (MAbs) to the haemagglutinin (HA) of recent swine isolates was prepared. Evaluation of neutralization escape mutants selected with these MAbs defined four antigenic sites on the HA, two of which overlap. Swine viruses isolated over 24 years in an enzootic area in Wisconsin were examined by ELISA and haemagglutination inhibition (HI) with these MAbs and the results indicated that the antigenic sites defined by these MAbs were highly conserved in these viruses. In comparing recent H1N1 viruses from pigs, turkeys, ducks and humans, changes in the antigenic sites were detected on the basis of HI reactivity. However, results of ELISA with these viruses clearly showed that the antigenic sites were still present on almost all H1N1 viruses of swine origin; thus, altered reactivity of these viruses in HI tests with MAbs was not a reflection of changes in the antigenic sites defined by the MAbs. It seems likely that the variation detected in these viruses occurs by a mechanism other than immune selection.

Virulent avian influenza A viruses: their effect on avian lymphocytes and macrophages in vivo and in vitro.

To investigate the pathogenesis of virulent avian influenza A viruses, the effect of A/turkey/Ont/7732/66 (H5N9) (Ty/Ont), A/tern/South Africa/1961 (H5N3) (Tern/S.A.) and A/chicken/Pennsylvania/1370/83 (H5N2) (Ck/Penn) on avian lymphoid cell populations was examined in vivo. Previous studies have shown that infection of chickens with Ty/Ont resulted in the extensive destruction of lymphoid tissues. In this study, other virulent avian H5 influenza viruses, Tern/S.A. or Ck/Penn, had little or no effect on lymphoid tissues of infected chickens. Therefore the effect of Ty/Ont on lymphoid tissue is a specific activity of this virus only and not of other virulent avian H5 influenza strains. To examine the role of viral replication in the destruction of lymphocytes, in vitro cultures of avian macrophages and lymphocytes were inoculated with Ty/Ont. Macrophages supported the synthesis of viral proteins whereas lymphocytes produced small, but detectable amounts of viral protein; however, infectious virus was not produced by either cell type. Furthermore inoculation of chicken spleen cells with Ty/Ont in vivo and in vitro had a profound effect on the proliferative response of lymphocytes to concanavalin A. These results suggest that Ty/Ont infects macrophages as well as lymphocytes in the chicken, and the effects of the virus on both cell types may well contribute to lymphoid necrosis.

Pathological Lesions in the Lungs of Ducks Infected with Influenza A Viruses

To determine histopathological damage in the respiratory tract, ducks were inoculated with five different influenza A viruses, including viruses virulent for other avian hosts. Lungs were collected for detection of virus and histopathological examination. Small amounts of infectious virus were recovered from lungs, and viral antigens were demonstrated by immunoperoxidase staining with monoclonal antibodies to the viral nucleoprotein. Although clinical signs were not detected, lungs of ducks infected with both virulent and avirulent viruses had mild pneumonia characterized by infiltrates of lymphocytes and macrophages. These findings show that although clinical signs are not evident, ducks may have damage to the respiratory tract during influenza.

Genetic relatedness of the nucleoprotein (NP) of recent swine, turkey, and human influenza Avirus(H1N1) isolates

The sequences of nucleoprotein (NP) genes of recent human and turkey isolates of influenza A viruses, which serologically could be correlated to contemporary swine viruses, were determined. These sequences were closely related to the NPs of these swine viruses and they formed a separate branch on the phylogenetic tree. While the early swine virus from 1931 resembled the avian strains in consensus amino acids of the NP and in its ability to rescue NP ts mutants of fowl plague virus in chicken embryo cells, the later strains on that branch were different: at 15 positions they have their own amino acids and they rescued the NP ts mutants only poorly. Of the NPs of the human New Jersey/76 isolates analysed, one clustered with the recent H1N1 swine viruses of the U.S.A., the other one with contemporary human strains. Since the NP is one of the main determinants of species specificity it is concluded that, although the H1N1 swine isolates from the U.S.A. form their own branch in the phylogenetic tree, they can be transmitted to humans and turkeys, but they do not spread further in these populations and so far have not contributed to human pandemics. It is not very likely that they will do so in future, since its branch in the phylogenetic tree develops further away from the human and avian branch.

Inhibition of nitric oxide induction from avian macrophage cell lines by influenza virus.

The virulent avian influenza virus A/Ty/Ont/7732/66 (H5N9) (Ty/Ont) causes a rapid destruction of lymphoid cells in infected birds. Avian macrophage cell lines, HD11 and MQ-NCSU, support productive replication of Ty/Ont and other influenza viruses. Therefore, the ability of these cell lines to produce nitric oxide (NO), a potentially cytotoxic mediator, in response to infection with Ty/Ont was examined. Although treatment with bacterial lipopolysaccharides (LPS) resulted in high NO levels, infection of macrophages with Ty/Ont resulted in NO levels lower than NO levels in untreated cells. Furthermore, Ty/Ont was able to inhibit the positive response to LPS in cultures simultaneously treated with LPS and virus. However, inactivated influenza virus did not exhibit this inhibitory effect. Different strains of influenza virus varied in their ability to inhibit NO production by the macrophages; this may be related to the level of virus replication in these cells. These data suggest that the ability of the avian macrophage to activate the NO synthesis pathway is seriously impaired by infection with virulent influenza viruses such as Ty/Ont.

Replication of Influenza A Viruses in an Avian Macrophage Cell Line

The virulent avian influenza virus A/Ty/Ont/7732/66 (H5N9) (Ty/Ont) causes severe destruction of the lymphoid cells in infected birds. Previous studies have suggested that viral infection of macrophages may be involved. However, Ty/Ont failed to replicate productively in primary cultures of chicken macrophages. Therefore, in an effort to develop an in vitro system for our studies, we examined the susceptibility of an avian macrophage cell line, HD11, to Ty/Ont. We found that Ty/Ont replicated in the HD11 cells to high titres, as measured by haemagglutination (HA) assays and infectivity yields. To determine whether this property was unique to Ty/Ont, we also examined the replication of influenza viruses representative of all 13 HA subtypes and an attenuated variant of Ty/Ont. All of the tested viruses replicated in HD11 cells; the avirulent strains required the presence of trypsin in the culture medium whereas virulent viruses and the attenuated variant of Ty/Ont did not. These results suggest that the HD11 cells can support the replication of a wide variety of influenza viruses and that this continuous avian cell line may prove useful for in vitro studies on these viruses.