Molecular determinants of rotavirus virulence: localization of a potential virulence site in a murine rotavirus VP4.

The molecular basis of pathogenesis in vivo for a virulent mouse rotavirus (MRV) and a less virulent bovine rotavirus (BRV) were compared under in vitro and in vivo conditions. Obvious differences in the mobility of several genomic RNA segments were observed in one-dimensional gels. Under in vitro conditions, partial proteolytic peptide mapping identified differences between the two outer capsid proteins of these virus and no difference in inner capsid protein was observed. Since it has been observed by us and others that the gene coding for VP4 protein plays a significant role in determining virulence, the variability observed in the present study between the 84 k proteins (VP4) provided a basis for further investigations in order to locate a potential virulence determinant. A comparison of the carboxypeptidase digests of the MRV- and BRV-VP4 revealed an area of variability between amino acids 307 and 407, which may represent a site of virulence determinant. Under in vivo conditions the virulence of both parenteral BRV and MRV isolates and their corresponding reassortants (with replaced gene 4) were studied in murine and bovine hosts. Like their parents, BRV and MRV isolates, reassortants obtained by replacement of gene 4 in BRV with MRV gene 4 indicated that the dose of the virus isolate used and the clinical outcome in vivo was determined by gene segment 4. The implications of these findings to elucidate the molecular basis of pathogenesis of rotaviruses are discussed.

Characterization of two rotaviruses differing in their in vitro and in vivo virulence.

The proteins, genomic RNA and disassembly conditions and pathogenesis in vivo for a virulent mouse rotavirus (MRV) and a less virulent bovine rotavirus (BRV) were compared. An obvious difference in the mobility of several genomic RNA segments were observed in one-dimensional gels. Reassortants obtained by replacement of gene 4 in BRV with MRV gene 4 indicated that the dose of the virus used and the clinical outcome in vivo was determined by gene segment 4. Under in vitro conditions, a comparison of the inner capsid proteins by partial proteolytic peptide mapping did not reveal any difference between corresponding proteins. However, this technique did identify differences between the two corresponding outer capsid proteins of these viruses. These differences, in turn, may account for the increased stability of MRV, as compared to BRV, when subjected to calcium-chelating and chaotropic agents and may be one of the mechanisms involved in conferring virulence on the virus. The observed variability between the 84K proteins (VP4) provided a basis for further investigations in order to locate a potential virulence determinant, since it has been observed by us and others that the gene coding for this protein plays a role in determining virulence. A comparison of the carboxypeptidase digests of the MRV and BRV VP4 revealed an area of variability between amino acids 307 and 407, which may represent the site of a virulence determinant.

Biochemical and immunological characterization of a novel peptide carrier system using rotavirus VP6 particles.

A system which allows for the efficient attachment of synthetic peptides to spherical virus-like particles assembled from the VP6 rotavirus nucleocapsid protein is described. This attachment was shown to be mediated by peptide-protein interactions and did not require additional chemicals for conjugation. The resulting large macromolecular structure was highly immunogenic for both the VP6 protein and the coupled peptides. The antibody response to peptides bound to VP6 particles was of higher titre and longer duration than that induced by other carriers. In addition, the response to VP6-coupled peptides was not affected by prior exposure to rotavirus and exhibited a range of immunoglobulin subclasses in the absence of an adjuvant. These data demonstrate that assembled VP6 spherical particles are useful carriers for low doses of synthetic peptides.

In vitro assembly of the outer capsid of bovine rotavirus is calcium-dependent.

The nucleocapsid protein (VP6) and outer capsid glycoprotein (VP7) of bovine rotavirus (BRV) assemble in vitro, in 0.01 M Tris-HCl, pH 8.0, 50 mM CaCl2, into smooth particles resembling double-shelled BRV. That the two proteins interact is demonstrated by the immunoprecipitation of both by antibody directed against either VP6 or VP7. The calcium-dependence, particle morphology, and immunoreactivity in ELISA suggest that VP7 is presented authentically on the outer capsid. The implications for rotavirus morphogenesis are discussed.

The structure of tubes of bovine rotavirus nucleocapsid protein (VP6) assembled in vitro.

The structure of tubes of reassembled nucleocapsid protein (VP6) from bovine rotavirus (BRV) was determined using optical diffraction of electron micrographs. The tubes consist of a five-start helix of hexagons, with 38 hexagons per helix in a true repeat of three turns. The morphological subunits comprising the hexagons are probably elongated trimers. The structure of naturally occurring tubes (D. Chasey and J. Labram, 1983, J. Gen. Virol. 64, 863-872) was also examined and shown to be similar but not identical to that of tubes assembled in vitro. Considerations of the assembly process are discussed.

In vitro assembly of bovine rotavirus nucleocapsid protein.

The nucleocapsid protein (VP6) of bovine rotavirus was purified from in vitro-derived single shelled particles by CaCl2 or LiCl treatment. The protein exhibits polymorphism. Specifically, hexamers and small hexagonal lattices were present in many of the samples. Tubular particles formed between pH 5.0 and 9.0 were moderately stable to changes in temperature and ionic strength and were shown to be composed of nucleocapsid protein. Their formation is fully reversible. Spherical particles resembling single-shelled virus formed at pH 4.0. A novel structure in the form of sheets composed of a small-hole lattice formed in samples shifted from pH 6.0 to 4.0. The results demonstrate the importance of the nucleocapsid protein and of protein-protein interactions for rotavirus assembly.

Biochemical evidence for the oligomeric arrangement of bovine rotavirus nucleocapsid protein and its possible significance in the immunogenicity of this protein.

The nucleocapsid protein of bovine rotavirus was shown to exist in trimeric units in both the virus particle and in infected cells, with the subunits linked by non-covalent interactions. These trimeric units complex further by disulphide bridges into larger units which may represent the hexameric structures observed by electron microscopy. Visualization of various nucleocapsid protein complexes was also achieved on polyacrylamide gels by treating virus preparations with urea at 37 degrees C or boiling in the presence and absence of 2-mercaptoethanol. Since virus particles devoid of nucleic acid were also broken down into trimeric subunits by such treatments, assembly of virus particles appears not to require an RNA-protein interaction. Four nucleocapsid-specific monoclonal antibodies with low neutralizing ability reacted with the monomeric (45,000 mol. wt., 45K), dimeric (90K), trimeric (135K) and trimeric pair (270K) subunits, indicating that a site responsible for neutralization is probably exposed after assembly of these subunits. Analysis of radiolabelled virus revealed that a high proportion (80%) of infectious particles could be immunoprecipitated by these monoclonal antibodies, suggesting that the virus particles are either partially double-shelled or have the nucleocapsid exposed on the surface. The monoclonal antibodies also cross-reacted with the nucleocapsid proteins of simian (SA11), pig (OSU), bovine (NCDV and UK) and human (Wa and ST4) rotaviruses in an immunoblot ELISA reaction. Since these six viruses belong to two different subgroups, it is likely that the antibodies did not recognize the subgroup-specific site, but a shared exposed antigenic determinant. Due to the hexameric configuration of the nucleocapsid in virus particles the neutralizing epitope may be repeatedly presented and, therefore, may contribute to the immunogenicity of this protein.

The assembly of barrel cactus virus protein.

The coat protein of barrel cactus virus, a member of the potexvirus family, self-assembles into long tubular particles in the absence of the RNA. The particles have the same structure as the virus. The conditions under which they form suggest a new control mechanism not involving carboxyl-carboxylate interactions.