Department of Veterinary Medicine Theses and Dissertations

Permanent URI for this collectionhttp://hdl.handle.net/1903/2762

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    Host Molecular Responses in Chickens Infected with an Avian Influenza Virus
    (2008-11-20) Ramirez-Nieto, Gloria Consuelo; Perez, Daniel R.; Veterinary Medical Science; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Avian influenza virus has a segmented RNA genome that allows the virus to evolve continuously and generate new strains. Wild birds serve as natural reservoirs of avian influenza virus and provide a potential source for emergence of new viruses, which traverse host barriers and infect new avian or mammalian species. The mechanisms involved in this process are not completely understood. Our main goal is to understand host-pathogen interactions involved in avian influenza pathogenicity. As part of our approach we studied the effect of pre-exposure of chickens to IBDV (infectious bursal disease virus) on host susceptibility to infection, disease progression, and host molecular responses to infection with a mallard H5N2 low pathogenic avian influenza (LPAI) virus. We found that prior exposure of chickens to IBDV led to increased susceptibility to infection with the mallard H5N2 LPAI virus compared to normal chickens. This increased susceptibility allowed us to further adapt the virus to chickens. After 22 passages (P22) in IBDV-pre-exposed chickens, the LPAI virus replicated substantially better than the wild-type (WT) mallard virus in both IBDV-exposed and normal chickens. Interestingly, the P22 virus showed similar levels of replication in the respiratory and intestinal tracts of both groups, although it caused exacerbated signs of disease and severe lesions in the IBDV-pre-exposed group. We suggest that prior IBDV exposure provides a port of entry for avian influenza in an otherwise resistant chicken population. Furthermore, adaptation of avian influenza (AI) in IBDV-exposed chickens may allow for the selection of AI virus strains with expanded tissue tropism. We also studied the effects of host response to H5N2 AI in normal and IBDV-infected birds using high-throughput gene expression analysis. We demonstrated that IBDV-exposed chickens showed less than optimal humoral responses to LPAI infection as well as alterations in local molecular pathways that eventually led to exacerbated disease and death. At the molecular level we found amino acid substitutions in the surface glycoprotein hemagglutinin (HA). Those changes suggest selection for a virus that binds to and replicates more efficiently in chickens. Taken together our results suggest that IBDV-pre-exposure may play a role in exacerbating AI-induced pathogenicity.
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    MOLECULAR PATHOGENESIS OF INFLUENZA IN SWINE AND ENGINEERING OF NOVEL RECOMBINANT INFLUENZA VIRUSES
    (2011) Pena, Lindomar Jose; Perez, Daniel R; Veterinary Medical Science; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Influenza A viruses (IAVs) belong to the family Orthomyxoviridae and represent major pathogens of both humans and animals. Swine influenza virus is an important pathogen that affects not only the swine industry, but also represents a constant threat to the turkey industry and is of particular concern to public health. In North America, H3N2 triple reassortant (TR) IAVs first emerged in 1998 and have since become endemic in swine populations. In the first part of this dissertation, we focused on the role of surface glycoproteins and PB1-F2 to unravel their roles in the virulence of TR IAVs in this important natural host. We found that surface glycoproteins are necessary and sufficient for the lung pathology, whereas the internal genes play a major role in the febrile response induced by TR H3N2 IAVs in swine. With respect to PB1-F2, we found that PB1-F2 exerts pleiotropic effects in the swine host, which are expressed in a strain-dependent manner. Pathogenicity studies in swine revealed that the presence of PB1-F2 leads the following effects in context of three TR strains tested: no effect in the context of sw/99 strain; increases the virulence of pH1N1; and decreases the virulence of ty/04. Next, we developed temperature-sensitive live attenuated influenza vaccines for use in swine and shown that these vaccines are safe and efficacious against aggressive intratracheal challenge with pH1N1. Lastly, we rearranged the genome of an avian H9N2 influenza virus to generate replication competent influenza virus vectors that provide a robust system for expression and delivery of foreign genes. As a proof-of-principle, we expressed the hemagglutinin from a prototypical highly pathogenic avian influenza virus (HPAIV) H5N1 and shown that this vectored H5 vaccine retained its safety properties in avian and mammalian species, and induced excellent protection against aggressive HPAIV H5N1 challenges in both mice and ferrets. Taken together, these studies have advanced our understanding of molecular basis of pathogenesis of influenza in the swine host and have contributed to the development of improved vaccines and influenza-based vectors with potential applications in both human and veterinary medicine.