Michael D. Parker

Protection of cattle from BHV-1 infection by immunization with recombinant glycoprotein gIV

High levels of recombinant bovine herpesvirus-1 (BHV-1) glycoprotein IV were produced in baculovirus, adenovirus, vaccinia virus and Escherichia coli expression systems. The different recombinant forms as well as authentic gIV were injected intramuscularly into seronegative calves. With the exception of E. coli-produced gIV, all forms of gIV induced high levels of neutralizing antibodies both in the serum and in the nasal superficial mucosa. Animals immunized with gIV produced in insect or mammalian cells were completely protected from infection with BHV-1, as demonstrated by the absence of temperature responses, clinical signs or detectable virus in the nasal secretions after challenge exposure. The E. coli-derived gIV induced partial protection from clinical disease, even though it was not glycosylated and did not induce appreciable levels of neutralizing antibodies. This study demonstrated that all forms of glycosylated gIV, whether authentic or recombinant, confer protection from BHV-1 infection and thus may be useful as an effective subunit vaccine.

Assembly of recombinant rotavirus proteins into virus-like particles and assessment of vaccine potential

Rotavirus structural proteins VP4, VP6 and VP7 from Bovine Rotavirus Strain C486 were cloned and expressed in a baculovirus expression system. Combinations of the proteins were assembled into a series of virus-like particles, and a murine model was used to determine the capacity of the recombinant proteins and particles to induce protective immunity. All of the proteins induced humoral immunity as measured by an ELISA against whole virus. However, only the antisera from animals immunized with VP4 neutralized virus and inhibited haemagglutination. Challenge of neonates born to animals immunized with VP4 protein on assembled particles or in cell lysates showed protection against challenge with both homologous (bovine C486) and heterologous (SA-11) strains of rotavirus. In contrast, the offspring of mice immunized with VP6 were only partially protected. Neonates of animals immunized with virus-like particles composed of VP7 assembled on VP6 spherical particles were protected against challenge with the homotypic virus and significantly protected from a heterotypic challenge whereas unassembled VP7 protein provided only partial protection against challenge.

THE S2 SUBUNIT OF THE SPIKE GLYCOPROTEIN OF BOVINE CORONAVIRUS MEDIATES MEMBRANE FUSION IN INSECT CELLS

Abstract The hemagglutinin/esterase (HE), spike precursor (S) and the S1 and S2 subunits of the spike precursor protein of bovine coronavirus were expressed in Spodoptera frugiperda (Sf9) cells, and the cell-fusing activity of each recombinant glycoprotein was examined. Extensive syncytia formation was observed in cells infected with the S2 recombinant but not with the HE or S1 recombinant baculoviruses. Fusion of Sf9 cells expressing the intact S protein precursor was evident after trypsin treatment. These results demonstrate that proteolytic cleavage of the S spike precursor is required for fusion induction and that the fusion is mediated by the S2 subunit. These observations may reflect the biological role of the S2 subunit in fusion-penetration during bovine coronavirus infection.

Structural, functional, and immunological characterization of bovine herpesvirus-1 glycoprotein gl expressed by recombinant baculovirus☆

Abstract The major glycoprotein complex gl of bovine herpesvirus-1 was expressed at high levels (36 μg per 1 × 106 cells) in insect cells using a recombinant baculovirus. The recombinant gl had an apparent molecular weight of 116 kDa and was partially cleaved to yield 63-kDa (glb) and 52-kDa (glc) subunits. This processing step was significantly less efficient in insect cells than the analogous step in mammalian cells, even though the cleavage sites of authentic and recombinant gl were shown to be identical. The oligosaccharide linkages were mostly endoglycosidase-H-sensitive, in contrast to those of authentic gl, which has mostly endoglycosidase-H-resistant linkages and an apparent molecular weight of 130/74/55 kDa. Despite the reduced cleavage and altered glycosylation, the recombinant glycoprotein was transported and expressed on the surface of infected insect cells. These surface molecules were biologically active as demonstrated by their ability to induce cell-cell fusion. Fusion was inhibited bythree monoclonal antibodies specific for antigenic domains I and IV on gl. Domain I maps to the extracellular region of the carboxy terminal fragment glc and domain IV to the very amino terminus of the glb fragment, indicating that domains mapping in two distinct regions of gl function in cell fusion. Monoclonal antibodies specific for eight different epitopes recognized recombinant gl, indicating that the antigenic characteristics of the recombinant and authentic glycoproteins are similar. In addition, the recombinant gl was as immunogenic as the authentic gl, resulting in the induction of gl-specific antibodies in cattle.

Bovine coronavirus nonstructural protein ns2 is a phosphoprotein

Abstract To investigate the nature of the bovine coronavirus (BCV) ns2 protein, the gene encoding this protein was cloned and was expressed as a β-galactosidase fusion protein. Antiserum raised against this protein reacted specifically with BCV-infected fixed cells in indirect immunofluorescence microscopy and precipitated an in vitro synthesized product approximately 32-kDa in molecular weight and an equivalent protein from BCV-infected cells. The synthesis of ns2 was found to be similar to the structural proteins of BCV and pulse-chase experiments indicated that ns2 protein was stable and that it accumulated in BCV-infected cells. Synthesis of ns2 in the presence of [31P] orthophosphate revealed that it is a phosphoprotein. Phosphoamino acid analysis confirmed the phosphorylated nature of ns2 and identified serine and threonine as its phosphorylated amino acid residues. This is the first demonstration of a phosphorylated nonstructural protein in coronavirus-infected cells.

Analysis of the S spike (peplomer) glycoprotein of bovine coronavirus synthesized in insect cells

Abstract The bovine coronavirus (BCV) spike glycoprotein precursor (S, formerly termed peplomer) and its two subunit polypeptides (S1 and S2) were individually expressed in Spodoptera frugiperda (Sf9) insect cells. Each recombinant baculovirus expressed both glycosylated (S, 170K; S1, 95K; S2, 80K) and unglycosylated (S0, 140K; S10, 75K; and S20, 65K) forms of BCV spike polypeptides in Sf9 cells. The mature 95K S1 polypeptide was secreted whereas the S and S2 polypeptides remained cell-associated. The S precursor was partially cleaved in Sf9 cells, and the resulting S1 was also released into the medium. Neutralizing monoclonal antibodies representing two antigenic domains bound to recombinant S and S1 but not the S2 polypeptides, indicating that two major epitopes for BCV neutralization are located on the S1 subunit.

The Haemagglutinin of Bovine Coronavirus Exhibits Significant Similarity to the Haemagglutinin of Type C Influenza Virus

Coronaviruses are large enveloped RNA viruses containing a single-stranded genome complexed with a phosphorylated nucleocapsid protein which is surrounded by an envelope derived from intracellular membranes. The envelope contains two or three species of glycoproteins. The largest, E2 or S, is cleaved to S1 and S2 subunits and forms the large club-shaped peplomers on the surface of the virion which gives the virus its characteristic appearance. The El glycoprotein is believed to be responsible for determining the intracellular site of viral morphogenesis. A smaller group of coronaviruses contain a third membrane glycoprotein (Hogue and Brian, 1986, King et al., 1985, Pocock and Garwes, 1977), E3 or H, which, in the case of bovine Coronavirus , exhibits haemagglutinating and acetylesterase activities.