Anti-Interferon gamma Antikörper [MTF19] (Biotin) (A269694)

Ferrets are an ideal animal model in which to study the transmission of respiratory viruses as well as disease progression and vaccine efficacy because of their close anatomical and physiological resemblances to humans. However, a paucity of reagents and standardized procedures has hampered research progress, especially for studying cell-mediated immunity. The approaches described here-leukocyte isolation from whole blood and secondary lymphoid tissues-are generalizable, highly reproducible, and deliver single cell suspensions with excellent cell viability. Importantly, we have now developed assays to quantify key cellular components and antigen-specific T cell responses at the single cell level from multiple tissue compartments following influenza infection in ferrets. Collectively, these methods were instrumental in flow cytometry studies that revealed alterations in immune cell composition and distribution across lymphoid tissues following viral infection. Furthermore, sorting of T cell populations and peptide restimulation ex vivo in cytokine ELISpot assays has provided novel insight into the influenza-specific CD4 and CD8 T cell repertoire. The detailed procedures for these techniques are described in this chapter and can likely be adapted for the analyses of responses to many respiratory pathogens.

Epidemiological studies have observed that the seasonal peak incidence of influenza virus infection is sometimes separate from the peak incidence of human respiratory syncytial virus (hRSV) infection, with the peak incidence of hRSV infection delayed. This is proposed to be due to viral interference, whereby infection with one virus prevents or delays infection with a different virus. We investigated viral interference between hRSV and 2009 pandemic influenza A(H1N1) virus (A[H1N1]pdm09) in the ferret model. Infection with A(H1N1)pdm09 prevented subsequent infection with hRSV. Infection with hRSV reduced morbidity attributed to infection with A(H1N1)pdm09 but not infection, even when an increased inoculum dose of hRSV was used. Notably, infection with A(H1N1)pdm09 induced higher levels of proinflammatory cytokines, chemokines, and immune mediators in the ferret than hRSV. Minimal cross-reactive serological responses or interferon ?-expressing cells were induced by either virus =14 days after infection. These data indicate that antigen-independent mechanisms may drive viral interference between unrelated respiratory viruses that can limit subsequent infection or disease.

Background: Two influenza B virus lineages, B/Victoria and B/Yamagata, cocirculate in the human population. While the lineages are serologically distinct, cross-reactive responses to both lineages have been detected. Viral interference describes the situation whereby infection with one virus limits infection and replication of a second virus. We investigated the potential for viral interference between the influenza B virus lineages.

Methods: Ferrets were infected and then challenged 3, 10, or 28 days later with pairs of influenza B/Victoria and B/Yamagata viruses.

Results: Viral interference occurred at challenge intervals of 3 and 10 days and occasionally at 28 days. At the longer interval, shedding of challenge virus was reduced, and this correlated with cross-reactive interferon ? responses from lymph nodes from virus-infected animals. Viruses from both lineages could prevent or significantly limit subsequent infection with a virus from the other lineage. Coinfections were rare, indicating the potential for reassortment between lineages is limited.

Conclusions: These data suggest that innate and cross-reactive immunity mediate viral interference and that this may contribute to the dominance of a specific influenza B virus lineage in any given influenza season. Furthermore, infection with one influenza B virus lineage may be beneficial in protecting against subsequent infection with either influenza B virus lineage.