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Literature DB >> 1851871

Heterotypic passive protection induced by synthetic peptides corresponding to VP7 and VP4 of bovine rotavirus.

M K Ijaz¹, S K Attah-Poku, M J Redmond, M D Parker, M I Sabara, P Frenchick, L A Babiuk.

Abstract

We have evaluated the potential of two peptides derived from highly conserved regions of rotavirus outer capsid proteins (VP7 and VP4) to act as a rotavirus vaccine. The capacity of peptides coupled to rotavirus VP6 spherical particles to provide passive protection in a murine model was compared with the protection induced by peptide-keyhole limpet hemocyanin (KLH) conjugates. Female mice were immunized a total of three times before and during pregnancy. Suckling mouse pups were challenged at 7 days of age with either homologous or heterologous rotavirus serotypes. The efficacy of vaccination was determined by analyzing the clinical symptoms and measuring xylose adsorption in the intestine. In this model the VP4 peptide-VP6 conjugate provided protection equal to that obtained using bovine rotavirus (BRV) as the immunogen. The VP7 peptide-VP6 conjugate provided slightly less protection than the VP4 peptide-VP6 conjugate. A mixture of the VP4 peptide-VP6 and VP7 peptide-VP6 conjugates provided better heterologous protection than immunization with BRV. In contrast, KLH-conjugated peptides provided only partial protection. The significance of a synthetic-peptide-based rotavirus vaccine in the prevention of rotavirus infections is discussed.

Entities: Chemical Disease Species

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Year: 1991 PMID： 1851871 PMCID： PMC240966

Source DB: PubMed Journal: J Virol ISSN： 0022-538X Impact factor: 5.103

40 in total

1. Rotavirus-specific cytotoxic T lymphocytes passively protect against gastroenteritis in suckling mice.

Authors: P A Offit; K I Dudzik
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Authors: E R Mackow; R D Shaw; S M Matsui; P T Vo; M N Dang; H B Greenberg
Journal: Proc Natl Acad Sci U S A Date: 1988-02 Impact factor: 11.205

3. In vitro assembly of bovine rotavirus nucleocapsid protein.

Authors: K F Ready; M Sabara
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4. Biochemical evidence for the oligomeric arrangement of bovine rotavirus nucleocapsid protein and its possible significance in the immunogenicity of this protein.

Authors: M Sabara; K F Ready; P J Frenchick; L A Babiuk
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5. Immunogenic structure of the influenza virus hemagglutinin.

Authors: N Green; H Alexander; A Olson; S Alexander; T M Shinnick; J G Sutcliffe; R A Lerner
Journal: Cell Date: 1982-03 Impact factor: 41.582

6. Purification of an outer capsid glycoprotein of neonatal calf diarrhea virus and preparation of its antisera.

Authors: S Matsuno; S Inouye
Journal: Infect Immun Date: 1983-01 Impact factor: 3.441

7. Carrier-priming leads to hapten-specific suppression.

Authors: L A Herzenberg; T Tokuhisa; L A Herzenberg
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8. Application of denatured, electrophoretically separated, and immobilized lysates of herpes simplex virus-infected cells for detection of monoclonal antibodies and for studies of the properties of viral proteins.

Authors: D K Braun; L Pereira; B Norrild; B Roizman
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9. Role of VP3 in human rotavirus internalization after target cell attachment via VP7.

Authors: N Fukuhara; O Yoshie; S Kitaoka; T Konno
Journal: J Virol Date: 1988-07 Impact factor: 5.103

10. Influenza virus antigens conjugated with a synthetic polyelectrolyte: a novel model of vaccines.

Authors: R V Petrov; R M Khaitov; V M Zhdanov; M S Sinyakov; A Sh Norimov; A V Nekrasov; I G Kharitonenkov; M V Shchipanova
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12 in total

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2. Assembly of double-shelled rotaviruslike particles by simultaneous expression of recombinant VP6 and VP7 proteins.

Authors: M Sabara; M Parker; P Aha; C Cosco; E Gibbons; S Parsons; L A Babiuk
Journal: J Virol Date: 1991-12 Impact factor: 5.103

3. Attenuated poliovirus strain as a live vector: expression of regions of rotavirus outer capsid protein VP7 by using recombinant Sabin 3 viruses.

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Authors: J Lee; D Yoo; M J Redmond; S K Attah-Poku; J V van den Hurk; L A Babiuk
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5. Serotypic differentiation of rotaviruses in field samples from diarrheic pigs by using nucleic acid probes specific for porcine VP4 and human and porcine VP7 genes.

Authors: B I Rosen; A V Parwani; S Lopez; J Flores; L J Saif
Journal: J Clin Microbiol Date: 1994-02 Impact factor: 5.948

10. Enumeration of isotype-specific antibody-secreting cells derived from gnotobiotic piglets inoculated with porcine rotaviruses.

Authors: W K Chen; T Campbell; J VanCott; L J Saif
Journal: Vet Immunol Immunopathol Date: 1995-04 Impact factor: 2.046