Neutrophil deactivation by influenza A virus. Role of hemagglutinin binding to specific sialic acid-bearing cellular proteins.

Bacterial superinfections are the most common cause of mortality during influenza epidemics. Depression of phagocyte functions by influenza A viruses (IAVs) is a likely contributory cause of such infections. We used an in vitro model of viral depression of neutrophil respiratory burst responses to FMLP and PMA to examine the mechanism of IAV-induced phagocyte deactivation. Respiratory burst responses or intracellular calcium mobilization were triggered by the virus itself, but these were not causally related to deactivation. By treating neutrophils with neuraminidase, and by use of purified IAV hemagglutinin (HA) preparations, cross-linking of sialic acid-bearing neutrophil surface components by the IAV HA was shown to be responsible for deactivation. IAV competed for binding to neutrophils with Abs directed against CD43, sialyl-Le(x), CD45, and gangliosides. Deactivation could be reproduced by treating neutrophils with anti-CD43 or -sialyl-Le(x) Abs in the absence of IAV. However, treatment of neutrophils with elastase markedly reduced CD43 expression, without affecting overall IAV binding or the ability of IAV to cause deactivation. Hence, although IAV binding to CD43 can account for deactivation, other IAV-binding proteins exist (e.g., those bearing sialyl-Le(x)) that can independently mediate functional depression.

Comparison of influenza A virus and formyl-methionyl-leucyl-phenylalanine activation of the human neutrophil.

Influenza A virus (IAV) activates the human neutrophil, but induces a dysfunctional state as well. Cell activation may contribute to the containment of the virus and/or cause local tissue damage. Certain features of the neutrophil activation response elicited by IAV are distinctive when compared with that triggered by formyl-methyl-leucyl-phenylalanine (FMLP). An atypical respiratory burst response occurs in which hydrogen peroxide, but no superoxide, is formed. This unusual respiratory burst stoichiometry persists despite marked priming of the IAV-induced response. A comprehensive examination of the activation cascade initiated by these stimuli failed to show an explanation for these differences. Both IAV and FMLP comparably stimulate inositol trisphosphate and phosphatidic acid production. The subsequent increase in intracellular calcium (Ca2+i) upon FMLP stimulation was more dependent on extracellular Ca2+ than with IAV activation, but both stimuli induced Ca2+ influx. FMLP and IAV exhibited equal susceptibility to inhibition by protein kinase inhibitors in eliciting the respiratory burst, and actin polymerization occurred in response to each agonist. A possible explanation for the anomalous respiratory burst induced by IAV is that O2- is generated at an intracellular site inaccessible to assay, and/or virus binding to sialic acid constituents of the plasma membrane alters the O2- generating capacity of the respiratory burst oxidase; evidence for each mechanism is offered.