Influenza virus A stimulates expression of eotaxin by nasal epithelial cells.

BACKGROUND: Respiratory virus is one of the most common causes of airway inflammation, but its pathogenic mechanisms are not well understood. Eotaxin is a potent eosinophil chemoattractant and is a selective agonist for C-C chemokine receptor 3 (CCR3). Although it has recently been demonstrated that epithelial cells express eotaxin, both in vivo and in vitro, there are few data concerning the expression in viral infection. OBJECTS: We hypothesized that eotaxin may play an important role in attracting inflammatory cells into the airway after viral infection and analysed whether viral infection induces eotaxin in nasal epithelial cells in vitro. METHODS: Nasal epithelial cells obtained from polypectomy for nasal polyp were infected with influenza virus A (subtype H3N2). The cells and supernatants were collected 8, 24 and 48 h after infection. Eotaxin mRNA was analysed by RT-PCR. Eotaxin concentration in the supernatants was analysed by enzyme-linked immunosorbent assay. We also examined a blocking assay to analyse the intervention of pro-inflammatory cytokines, TNF-alpha and IL-1beta in eotaxin production induced by influenza virus. RESULTS: The results showed that eotaxin was expressed constitutively in uninfected cells, but was up-regulated for both mRNA and protein levels in infected cells. Blocking experiments using anti-TNF-alpha and anti-IL-1beta antibodies showed no effects of these agents on the level of eotaxin. In addition, UV-inactivated virus did not enhance the expression of eotaxin. CONCLUSIONS: These results suggest that influenza virus A infection in nasal epithelial cells stimulates the expression of eotaxin, and may play an important role in the pathogenesis of airway inflammation by inducing eotaxin.

Characterization of porcine reproductive and respiratory syndrome virus hemagglutinin.

Porcine reproductive and respiratory syndrome virus hemagglutinin (HAin) was readily adsorbed on mouse erythrocytes at 4, 22, or 37 degrees C, but not on goose erythrocytes. The adsorbed HAin could not be eluted from the cells by resuspending in phosphate buffered saline, by incubating at 37 or 50 degrees C, or by incubating in the presence of neuraminidase. The hemagglutinating activity was not dependent on the pH and NaCl molarity tested. The receptor of mouse erythrocytes for the HAin was relatively stable to trypsin, neuraminidase, sodium deoxycholate (DOC), potassium periodate (KIO4), dithiothreitol (DTT), 2-mercaptoethanol (2-ME) and formalin treatments. The HAin was inactivated by 2-ME and was gradually inactivated by pepsin, formalin and DTT, but not by beta-glucosidase, trypsin, alpha-amylase, papain, phospholipase C, neuraminidase, KIO4, and ethylendiamine tetraacetic acid (EDTA) treatments. The HAin was stable at 37 degrees C or lower temperatures, but not at 56 degrees C or higher. The HAin was relatively resistant to ultraviolet irradiation and sonication. In the equilibrium centrifugation of the HAin preparation on a CsCl density gradient, the HAin activity showed a sharp peak at 1.17 g/cm2. In the SDS-PAGE analysis, the structural polypeptide of HAin in the peak fraction seems to be the nucleocapsid (N) polypeptide with molecular weight of 15 kDa.

Physicochemical properties of pseudorabies virus hemagglutinin.

Pseudorabies virus hemagglutinin was readily adsorbed on mouse erythrocytes at 4, 22, or 37 degrees C, but not on cattle erythrocytes. The adsorbed hemagglutinin could not be eluted from the cells by resuspending in phosphate-buffered saline (PBS), by incubating at 37 or 50 degrees C, or by incubating in the presence of neuraminidase. The receptor on mouse erythrocytes for the hemagglutinin was inactivated by trypsin, but not by neuraminidase, sodium deoxycholate (DOC), potassium periodate (KIO4), dithiothreitol (DTT), 2-mercaptoethanol (2-ME) and formalin. The hemagglutinin was inactivated by trypsin, alpha-amylase, pepsin, DOC, KIO4, and ethylendiamine-tetraacetic acid (EDTA), but not by papain, beta-glucosidase, phospholipase C, neuraminidase, DTT, 2-ME, Tween-80, ethylether, chloroform, trichloro-trifluoroethane, beta-propiolactone and formalin, suggesting that the hemagglutinin active component involved glycoproteins. The hemagglutinin was stable at 37 degrees C for lower temperatures but not at 60 degrees C or higher. The hemagglutinin activity was resistant to ultraviolet irradiation, while the infectivity was very susceptible. The hemagglutinin and the infectivity were readily sedimented by ultracentrifugation at 48,000 x g for 3 hr. In rate zonal centrifugation of the preparation on a sucrose density gradient, the hemagglutination (HA) activity showed a sharp peak at 1.22 g/ml coinciding with the peak of infectivity. The HA activity in the peak fraction seemed to be structually associated with virus particles. After fractionation of the virus by Nonidet P-40, the HA activity was found only in the fraction of the envelope material, indicating that the hemagglutinin is situated in the viral envelop.

Retention of immunogenicity after X-irradiation of mouse colon tumor cells expressing the transfected influenza virus hemagglutinin gene.

We have previously demonstrated that murine colon tumor cells transfected with the gene coding for the hemagglutination antigen (HA) of influenza virus acquire an inherent immunogenicity, fail to grow in syngeneic mice, and demonstrate an ability to cross-protect against a challenge with parental nontransfected cells. In the present study the immunogenic potential of HA-transfected cells correlated with cell-surface HA expression, as measured both by a fluorescence-activated cell sorter and by radio-labeled antibody binding. HA-transfected immunogenic cells had a median lethal dose (LD50) that was 10,000-fold greater than that of nontransfected cells. Most importantly this study demonstrated that HA-transfected cells retained their immunogenicity after X-irradiation with 12,000 rad. This characteristic makes their potential usefulness in treating human neoplasia more plausible.