Functional dissection of the major structural protein of bluetongue virus: identification of key residues within VP7 essential for capsid assembly.

A lattice of VP7 trimers forms the surface of the icosahedral bluetongue virus (BTV) core. To investigate the role of VP7 oligomerization in core assembly, a series of residues for substitution were predicted based on crystal structures of BTV type 10 VP7 molecule targeting the monomer-monomer contacts within the trimer. Seven site-specific substitution mutations of VP7 have been created using cDNA clones and were employed to produce seven recombinant baculoviruses. The effects of these mutations on VP7 solubility, ability to trimerize and formation of core-like particles (CLPs) in the presence of the scaffolding VP3 protein, were investigated. Of the seven VP7 mutants examined, three severely affected the stability of CLP, while two other mutants had lesser effect on CLP stability. Only one mutant had no apparent effect on the formation of the stable capsid. One mutant in which the conserved tyrosine at residue 271 (lower domain helix 6) was replaced by arginine formed insoluble aggregates, implying an effect in the folding of the molecule despite the prediction that such a change would be accommodated. All six soluble VP7 mutants were purified, and their ability to trimerize was examined. All mutants, including those that did not form stable CLPs, assembled into stable trimers, implying that single substitution may not be sufficient to perturb the complex monomer-monomer contacts, although subtle changes within the VP7 trimer could destabilize the core. The study highlights some of the key residues that are crucial for BTV core assembly and illustrates how the structure of VP7 in isolation underrepresents the dynamic nature of the assembly process at the biological level.

Expression of goose parvovirus VP1 capsid protein by a baculovirus expression system and establishment of fluorescent antibody test to diagnose goose parvovirus infection.

The gene encoding VP1 capsid protein of a goose parvovirus was cloned into a baculovirus transfer vector and a recombinant baculovirus was produced. The recombinant virus expressed a protein of 88 kDa corresponding to the molecular weight of VP1 protein and the protein was detected by immunoblotting. By indirect fluorescent antibody (IFA) test, the expressed protein was detected in the nucleus of the insect cells as big granules and electron microscopy also showed several big granules in the nucleus infected with the recombinant virus. The IFA test was developed for screening antibody in Muscovy ducks.

Detection of Goose parvovirus genome by polymerase chain reaction: distribution of Goose parvovirus in Muscovy ducklings.

A portion of the Goose parvovirus (GPV) genome DNA was cloned, sequenced, and primers for polymerase chain reaction (PCR) were prepared. The specificity of the clone was checked by Southern blot hybridization to GPV genome and by in situ hybridization with GPV infected cells. In Muscovy ducklings experimentally infected with the virulent GPV strain IH, the viral genome was detected by PCR on and after 2 days in many tissues including the brain. Using PCR, the primers also detected another GPV strain Ma isolated in Japan.