Your search keyword '"Eaton, Bryan T."' showing total 6 results

1. Ephrin-B2 Ligand Is a Functional Receptor for Hendra Virus and Nipah Virus

Author

Bonaparte, Matthew I., Dimitrov, Antony S., Bossart, Katharine N., Crameri, Gary, Mungall, Bruce A., Bishop, Kimberly A., Choudhry, Vidita, Dimitrov, Dimiter S., Wang, Lin-Fa, Eaton, Bryan T., Broder, Christopher C., and Moss, Bernard

Published

2005

2. Inhibition of Henipavirus fusion and infection by heptad-derived peptides of the Nipah virus fusion glycoprotein.

Author

Bossart, Katharine N., Mungall, Bruce A., Crameri, Gary, Lin-Fa Wang, Eaton, Bryan T., and Broder, Christopher C.

Subjects

NIPAH virus, PARAMYXOVIRUSES, GLYCOPROTEINS, PEPTIDES, VIRUS diseases, VIRUS research

Abstract

Background: The recent emergence of four new members of the paramyxovirus family has heightened the awareness of and re-energized research on new and emerging diseases. In particular, the high mortality and person to person transmission associated with the most recent Nipah virus outbreaks, as well as the very recent re-emergence of Hendra virus, has confirmed the importance of developing effective therapeutic interventions. We have previously shown that peptides corresponding to the C-terminal heptad repeat (HR-2) of the fusion envelope glycoprotein of Hendra virus and Nipah virus were potent inhibitors of both Hendra virus and Nipah virus-mediated membrane fusion using recombinant expression systems. In the current study, we have developed shorter, second generation HR-2 peptides which include a capped peptide via amidation and acetylation and two poly(ethylene glycol)-linked (PEGylated) peptides, one with the PEG moity at the C-terminus and the other at the N-terminus. Here, we have evaluated these peptides as well as the corresponding scrambled peptide controls in Nipah virus and Hendra virus-mediated membrane fusion and against infection by live virus in vitro. Results: Unlike their predecessors, the second generation HR-2 peptides exhibited high solubility and improved synthesis yields. Importantly, both Nipah virus and Hendra virus-mediated fusion as well as live virus infection were potently inhibited by both capped and PEGylated peptides with IC50 concentrations similar to the original HR-2 peptides, whereas the scrambled modified peptides had no inhibitory effect. These data also indicate that these chemical modifications did not alter the functional properties of the peptides as inhibitors. Conclusion: Nipah virus and Hendra virus infection in vitro can be potently blocked by specific HR-2 peptides. The improved synthesis and solubility characteristics of the second generation HR-2 peptides will facilitate peptide synthesis for pre-clinical trial application in an animal model of Henipavirus infection. The applied chemical modifications are also predicted to increase the serum half-life in vivo and should increase the chance of success in the development of an effective antiviral therapy. [ABSTRACT FROM AUTHOR]

Published

2005

3. Neutralization assays for differential henipavirus serology using Bio-Plex Protein Array Systems

Author

Bossart, Katharine N., McEachern, Jennifer A., Hickey, Andrew C., Choudhry, Vidita, Dimitrov, Dimiter S., Eaton, Bryan T., and Wang, Lin-Fa

Subjects

*PARAMYXOVIRUSES, *NIPAH virus, *GLYCOPROTEINS, *SEROLOGY

Abstract

Abstract: Hendra virus (HeV) and Nipah virus (NiV) are related emerging paramyxoviruses classified in the genus Henipavirus. Both cause fatal disease in animals and humans and are classified as biosafety level 4 pathogens. Here we detail two new multiplexed microsphere assays, one for antibody detection and differentiation and another designed as a surrogate for virus neutralization. Both assays utilize recombinant soluble attachment glycoproteins (sG) whereas the latter incorporates the cellular receptor, recombinant ephrin-B2. Spectrally distinct sGHeV- and sGNiV-coupled microspheres preferentially bound antibodies from HeV- and NiV-seropositive animals, demonstrating a simple procedure to differentiate antibodies to these closely related viruses. Soluble ephrin-B2 bound sG-coupled microspheres in a dose-dependent fashion. Specificity of binding was further evaluated with henipavirus G-specific sera and MAbs. Sera from henipavirus-seropositive animals differentially blocked ephrin-B2 binding, suggesting that detection and differentiation of HeV and NiV neutralizing antibodies can be done simultaneously in the absence of live virus. [Copyright &y& Elsevier]

Published

2007

4. Receptor Binding, Fusion Inhibition, and Induction of Cross-Reactive Neutralizing Antibodies by a Soluble G Glycoprotein of Hendra Virus.

Author

Bossart, Katharine N., Crameri, Gary, Dimitrov, Antony S., Mungall, Bruce A., Yan-Ru Feng, Patch, Jared R., Choudhary, Anil, Lin-Fa Wang, Eaton, Bryan T., and Broder, Christopher C.

Subjects

*PARAMYXOVIRUSES, *GLYCOPROTEINS, *PROTEOLYTIC enzymes, *CYTOPLASM, *IMMUNOGLOBULINS

Abstract

Hendra virus (HeV) and Nipah virus (NiV) are closely related emerging viruses comprising the Henipavirus genus of the Paramyxovirinae, which are distinguished by their ability to cause fatal disease in both animal and human hosts. These viruses infect cells by a pH-independent membrane fusion event mediated by their attachment (G) and fusion (F) glycoproteins. Previously, we reported on HeV- and NiV-mediated fusion activities and detailed their host-cell tropism characteristics. These studies also suggested that a common cell surface receptor, which could be destroyed by protease, was utilized by both viruses. To further characterize the G glycoprotein and its unknown receptor, soluble forms of HeV G (sG) were constructed by replacing its cytoplasmic tail and transmembrane domains with an immunoglobulin κ leader sequence coupled to either an S-peptide tag (sGS-tag) or myc-epitope tag (sGmyc-tag) to facilitate purification and detection. Expression of sG was verified in cell lysates and culture supernatants by specific affinity precipitation. Analysis of sG by size exclusion chromatography and sucrose gradient centrifugation demonstrated tetrameric, dimeric, and monomeric species, with the majority of the sG released as a disulfide-linked dimer. Immunofluorescence staining revealed that sG specifically bound to HeV and NiV infection-permissive cells but not to a nonpermissive HeLa cell line clone, suggesting that it binds to virus receptor on host cells. Preincubation of host cells with sG resulted in dose-dependent inhibition of both HeV and NiV cell fusion as well as infection by live virus. Taken together, these data indicate that sG retains important native structural features, and we further demonstrate that administration of sG to rabbits can elicit a potent cross-reactive neutralizing antibody response against infectious HeV and NiV. This HeV sG glycoprotein will be exceedingly useful for structural studies, receptor identification strategies, and vaccine development goals for these important emerging viral agents. [ABSTRACT FROM AUTHOR]

Published

2005

5. Identification of Hendra Virus G Glycoprotein Residues That Are Critical for Receptor Binding.

Author

Bishop, Kimberly A., Stantchev, Tzanko S., Hickey, Andrew C., Khetawat, Dimple, Bossart, Katharine N., Krasnoperov, Valery, Gill, Parkash, Yan Ru Feng, Lemin Wang, Eaton, Bryan T., Lin-Fa Wang, and Broder, Christopher C.

Subjects

*PARAMYXOVIRUSES, *MAMMALS, *VIRAL receptors, *GLYCOPROTEINS, *ALANINE, *AMINO acids, *MEASLES virus, *MEMBRANE fusion

Abstract

Hendra virus (HeV) is an emerging paramyxovirus capable of infecting and causing disease in a variety of mammalian species, including humans. The virus infects its host cells through the coordinated functions of its fusion (F) and attachment (G) glycoproteins, the latter of which is responsible for binding the virus receptors ephrinB2 and ephrinB3. In order to identify the receptor binding site, a panel of G glycoprotein constructs containing mutations was generated using an alanine-scanning mutagenesis strategy. Based on a predicted G structure, charged amino acids residing in regions that could be homologous to those in the measles virus H attachment glycoprotein known to be involved in its protein receptor interaction were targeted. Using a coprecipitation-based assay, seven single-amino-acid substitutions in HeV G were identified as having significantly impaired binding to both the ephrinB2 and ephrinB3 viral receptors: D257A, D260A, G439A, K443A, G449A, K465A, and D468A. The impairment of receptor interaction conferred a concomitant diminution in their abilities to promote membrane fusion when coexpressed with F. The G glycoprotein mutants were also recognized by three or more conformation-dependent monoclonal antibodies of a panel of five, were expressed on the cell surface, and retained their abilities to bind and coprecipitate F. Interestingly, some of these mutant G glycoproteins coprecipitated with F more efficiently than wild-type G. Taken together, these data provide strong biochemical and functional evidence that some of these residues could be part of a conformation-dependent, discontinuous, and overlapping ephrinB2 and -B3 binding domain within the HeV G glycoprotein. [ABSTRACT FROM AUTHOR]

Published

2007

6. Feline Model of Acute Nipah Virus Infection and Protection with a Soluble Glycoprotein-Based Subunit Vaccine.

Author

Mungall, Bruce A., Middleton, Deborah, Crameri, Gary, Bingham, John, Halpin, Kim, Russell, Gail, Green, Diane, McEachern, Jennifer, Pritchard, L. Ian, Eaton, Bryan T., Lin-Fa Wang, Bossart, Katharine N., and Broder, Christopher C.

Subjects

*NIPAH virus, *PARAMYXOVIRUSES, *EPIDEMICS, *VIRUS diseases, *CATS as laboratory animals, *VIRAL vaccines, *GLYCOPROTEINS, *TROPISMS, *THERAPEUTICS, *CAT diseases

Abstract

Nipah virus (NiV) and Hendra virus (HeV) are paramyxoviruses capable of causing considerable morbidity and mortality in a number of mammalian species, including humans. Case reports from outbreaks and previous challenge experiments have suggested that cats were highly susceptible to NiV infection, responding with a severe respiratory disease and systemic infection. Here we have assessed the cat as a model of experimental NiV infection and use it in the evaluation of a subunit vaccine comprised of soluble G glycoprotein (sG). Two groups of two adult cats each were inoculated subcutaneously with either 500 or 5,000 50% tissue culture infective dose(s) (TCID50) of NiV. Animals were monitored closely for disease onset, and extensive analysis was conducted on samples and tissues taken during infection and at necropsy to determine viral load and tissue tropism. All animals developed clinical disease 6 to 9 days postinfection, a finding consistent with previous observations. In a subsequent experiment, two cats were immunized with HeV sG and two were immunized with NiV sG. Homologous serum neutralizing titers were greater than 1:20,000, and heterologous titers were greater than 1:20,000 to 16-fold lower. Immunized animals and two additional naive controls were then challenged subcutaneously with 500 TCID50 of NiV. Naive animals developed clinical disease 6 to 13 days postinfection, whereas none of the immunized animals showed any sign of disease. TaqMan PCR analysis of samples from naive animals revealed considerable levels of NiV genome in a wide range of tissues, whereas the genome was evident in only two immunized cats in only four samples and well below the limit of accurate detection. These results indicate that the cat provides a consistent model for acute NiV infection and associated pathogenesis and an effective subunit vaccine strategy appears achievable. [ABSTRACT FROM AUTHOR]

Published

2006