Newcastle Disease Virus Virulence: Mechanism of the Interferon Antagonistic Activity of the V Protein and Characterization of a Putative Virulence-Specific Antibody to the Attachment Protein: a dissertation

Newcastle disease virus (NDV) is a member of the genus Avulavirus of the Paramyxoviridaefamily of enveloped negative-stranded RNA viruses. The virus causes respiratory, neurological, or enteric disease in many species of birds, resulting in significant losses to the poultry industry worldwide. Strains of the virus are classified into three pathotypes based on the severity of disease in chickens. Avirulent strains that produce mild or asymptomatic infections are termed lentogenic, whereas virulent strains are termed velogenic. Strains of intermediate virulence are termed mesogenic. The envelope of NDV virions contains two types of glycoproteins, the hemagglutinin-neuraminidase (HN) and fusion (F) proteins. HN mediates three functions: 1) virus attachment to sialic acid-containing receptors; 2) neuraminidase activity that cleaves sialic acid from progeny virions to prevent self-aggregation; and, 3) complementation of the F protein in the promotion of fusion. Though it is widely accepted that cleavage of a fusion protein precursor is the primary determinant of NDV virulence, it is not the sole determinant. At least two other proteins, HN and the V protein, contribute to virulence. The V protein possesses interferon (IFN) antagonistic activity. The long-range goal of these studies is to understand the roles of HN and V in the differential virulence patterns exhibited by members of the NDV serotype. The first aim is to compare the IFN antagonistic activity of the V protein from a lentogenic and a mesogenic strain of the virus. The results of this study demonstrate that the V protein of the mesogenic strain Beaudette C (BC) exhibits greater IFN antagonistic activity than that of the lentogenic strain La Sota. Hence, the IFN antagonistic activities of the two V proteins correlate with their known virulence properties. Comparison of the C-terminal regions of La Sota and BC V proteins revealed four amino acid differences. The results demonstrate that the IFN antagonistic activity of La Sota V increases when any one of these residues is mutated to the corresponding residue in BC V. Conversely, the IFN antagonistic activity of BC V decreases when any one of these four residues is mutated to the corresponding residue in La Sota V. However, no single residue accounts for the difference in IFN antagonistic activity between the two V proteins. Also, analysis of La Sota V and BC V proteins with multiple mutations in these positions revealed that the four residues are collectively responsible for the difference in the IFN antagonistic activity of the two V proteins. Finally, characterization of chimeric La Sota/BC V proteins showed that the N-terminal region also contributes to the IFN antagonistic activity of V. Contrary to an earlier report, results described here demonstrate that the NDV V protein does not target STAT1 for degradation. However, both La Sota and BC V proteins target interferon regulatory factor (IRF)-7 for degradation and promote the conversion of full-length IRF-7 to a lower molecular weight form (IRF-7*). This is the first demonstration that IRF-7 is targeted by a paramyxovirus V protein. The amount of IRF-7* decreases in a dose-dependent manner in the presence of a proteasome inhibitor, suggesting that IRF-7* is a degradation product of IRF-7. Furthermore, the BC V protein promotes complete conversion of IRF-7 to IRF7*, whereas the La Sota V protein does so less efficiently. Again, this is consistent with the difference in IFN antagonistic activity of the two V proteins, and in turn, with their virulence. The second aim is to characterize an HN-specific monoclonal antibody called AVS-I. A previous study suggested that AVS-I recognizes an epitope that is conserved in lentogenic strains and raises the possibility that this epitope may colocalize with a determinant of virulence in HN. To further characterize antibody AVS-I and the epitope it recognizes, we (i) determined its specificity for several additional strains of the virus, (ii) mapped its binding to HN in competition with our own antibodies, (iii) determined its functional inhibition profile, and (iv) isolated and sequenced an AVS-I escape mutant. The results demonstrate that AVS-I binds to a conformational epitope at the carboxy terminus of HN. This suggests that this region of HN may define a determinant of virulence. However, it was also shown that AVS-I, which was previously thought to be specific for avirulent strains of NDV, actually recognizes individual mesogenic and velogenic strains. In conclusion, the data presented in this dissertation contributes to a greater understanding of the molecular basis for NDV virulence and may aid in development of antiviral strategies and generation of recombinant NDVs suitable for use in cancer and gene therapy

Monoclonal Antibody Routinely Used To Identify Avirulent Strains of Newcastle Disease Virus Binds to an Epitope at the Carboxy Terminus of the Hemagglutinin-Neuraminidase Protein and Recognizes Individual Mesogenic and Velogenic Strains

Newcastle disease virus (NDV) strains are classified as having high (velogenic), intermediate (mesogenic), or low (lentogenic) pathogenesis and virulence in chickens. Recent studies have established that the hemagglutinin-neuraminidase (HN) protein plays an important role in viral tropism and virulence. A monoclonal antibody (AVS-I) has previously been shown to be specific for lentogenic strains of NDV (Srinivasappa et al., Avian Dis. 30:562-567, 1986) and is routinely used to identify these strains. We have used competition antibody binding assays with a previously characterized panel of monoclonal antibodies, binding to chimeric HN proteins, and the characterization of an escape mutant to localize the binding site of AVS-I to the extreme carboxy terminus of the protein. In addition, we have shown that AVS-I does recognize at least one mesogenic strain and one velogenic strain of the virus, calling into question the potential of this antibody as a diagnostic reagent for avirulent NDV strains

Enterohaemorrhagic Escherichia coli Tir requires a C-terminal 12-residue peptide to initiate EspF-mediated actin assembly and harbours N-terminal sequences that influence pedestal length

Enterohaemorrhagic Escherichia coli (EHEC) and enteropathogenic E. coli (EPEC) both utilize type III secretion systems that translocate the effector protein Tir into the plasma membrane of mammalian cells in order to stimulate localized actin assembly into \u27pedestals\u27. The Tir molecule that EPEC delivers is phosphorylated within its C-terminus on tyrosine-474, and a clustered 12-residue phosphopeptide encompassing this residue initiates an efficient signalling cascade that triggers actin polymerization. In addition to Y474, tyrosine-454 of EPEC Tir is phosphorylated, although inefficiently, and promotes actin polymerization at low levels. In contrast to EPEC Tir, EHEC Tir lacks Y474 and triggers pedestal formation in a phosphotyrosine-independent manner by interacting with an additional effector protein, EspF(U). To identify EHEC Tir sequences that regulate localized actin assembly, we circumvented the strict requirements for type III translocation and directly expressed Tir derivatives in mammalian cells by transfection. Infection of Tir-expressing cells with a Tir-deficient EHEC strain demonstrated that ectopically expressed Tir localizes to the plasma membrane, is modified by mammalian serine-threonine kinases and is fully functional for actin pedestal formation. Removal of portions of the cytoplasmic N-terminus of Tir resulted in the generation of abnormally long pedestals, indicating that this region of EHEC Tir influences pedestal length. In the presence of the entire N-terminal domain, a 12-residue peptide from the C-terminus of EHEC Tir is both necessary and sufficient to recruit EspF(U) and initiate actin pedestal formation. This peptide encompasses the portion of EHEC Tir analogous to the EPEC Tir-Y454 region and is present within the Tir molecules of all pedestal-forming bacteria, suggesting that this sequence harbours a conserved signalling function

Human host factors required for influenza virus replication

Influenza A virus is an RNA virus that encodes up to 11 proteins and this small coding capacity demands that the virus use the host cellular machinery for many aspects of its life cycle. Knowledge of these host cell requirements not only informs us of the molecular pathways exploited by the virus but also provides further targets that could be pursued for antiviral drug development. Here we use an integrative systems approach, based on genome-wide RNA interference screening, to identify 295 cellular cofactors required for early-stage influenza virus replication. Within this group, those involved in kinase-regulated signalling, ubiquitination and phosphatase activity are the most highly enriched, and 181 factors assemble into a highly significant host-pathogen interaction network. Moreover, 219 of the 295 factors were confirmed to be required for efficient wild-type influenza virus growth, and further analysis of a subset of genes showed 23 factors necessary for viral entry, including members of the vacuolar ATPase (vATPase) and COPI-protein families, fibroblast growth factor receptor (FGFR) proteins, and glycogen synthase kinase 3 (GSK3)-beta. Furthermore, 10 proteins were confirmed to be involved in post-entry steps of influenza virus replication. These include nuclear import components, proteases, and the calcium/calmodulin-dependent protein kinase (CaM kinase) IIbeta (CAMK2B). Notably, growth of swine-origin H1N1 influenza virus is also dependent on the identified host factors, and we show that small molecule inhibitors of several factors, including vATPase and CAMK2B, antagonize influenza virus replication