Localization of the non-structural protein NS3 in bluetongue virus-infected cells.

The localization of the blue tongue virus (BTV) non-structural proteins NS3 and NS3a has been identified using immunoelectron microscopical techniques. NS3 and NS3a have been observed in the plasma membrane of BTV- and recombinant vaccinia virus (expressing NS3)-infected cells. The NS3 protein was associated with areas of membrane perturbation. There was a good correlation between the presence of NS3 and NS3a and BTV release. The NS3 protein was associated with membrane fragments and the inability to detect it on the extracellular aspect of intact cells suggested that the protein was not exposed extracellularly. Electron microscopical and biochemical evidence suggested that fragments of plasma membrane containing NS3 and NS3a were released from infected cells. Collectively, the data indicate that NS3 and NS3a may be involved in the final stages of BTV morphogenesis, i.e. the release of BTV from infected cells.

A characterization of the nonstructural protein from which the virus-specified tubules in epizootic haemorrhagic disease virus-infected cells are composed.

The complete nucleotide sequence of segment 6 of epizootic haemorrhagic disease virus serotype 2 (Alberta) which encodes nonstructural protein NS1 was determined from a cDNA clone containing a full-length copy of the gene. The gene was found to be 1806 bp in length, constituted by one open reading frame of 1656 bp which is flanked by 5' and 3' noncoding regions of 32 and 118 bp, respectively. The conserved 5' and 3' terminal hexanucleotide sequences were identical to those of BTV-10. The 5' noncoding nucleotide sequences of cognate genome segments 4, 6 and 8 were found to be highly conserved in EHDV-2 and BTV-10. The 3' noncoding regions are less conserved but share common characteristics. The predicted EHDV-2 NS1 gene product, a 552 amino acid polypeptide, is predominantly hydrophobic and has a net charge of +5 at neutral pH. Comparison to its BTV-10 counterpart revealed a high degree of homology. Regions of high amino acid similarity were shown to correlate with hydrophobic domains on the proteins whilst regions of lower amino acid similarity corresponded with the hydrophilic domains. Thirteen conserved cysteine residues of which the majority occurred in hydrophobic regions with more than 80% amino acid similarity were identified.

Biophysical studies on the morphology of baculovirus-expressed bluetongue virus tubules.

Bluetongue virus tubules were purified from Spodoptera frugiperda cells infected with a recombinant baculovirus containing the NS1 gene from bluetongue virus serotype 10, and expressed under control of the Autographa californica nuclear polyhedrosis virus polyhedrin promoter. These tubules were subjected to a variety of chemical and physical treatments and the resulting effects on tubule morphology were examined by electron microscopy. A number of morphological similarities were noted between bluetongue virus tubules and cellular microtubules despite a lack of homology between the component proteins at the primary sequence level. A possible multistranded helical configuration is proposed for the tubule structure.

Bluetongue virus: surface exposure of VP7.

The exposed proteins of bluetongue virus serotype 17 were determined using surface labeling and reactivity with monoclonal antibodies. Iodination of amino groups predominantly labeled VP2; however, iodination of tyrosine residues labeled both VP2 and VP5, with VP7 labeled to a significantly lesser degree. To investigate the exposure of VP7 on the intact virion further, monoclonal antibodies that reacted with this protein were used. At least two antibodies, reacting with different epitopes on VP7, bound to intact virions, as determined by adsorption of infectious particles, electron microscopic observation of antibody-bound virus, and co-sedimentation of antibody and virus. Surface iodination of viral cores was used to show that VP7 and VP3 are major exposed proteins on these particles. We conclude that a major core protein, VP7, has at least two epitopes exposed on the virus surface.

Effects of proteolytic enzymes on the infectivity, haemagglutinating activity and protein composition of bluetongue virus type 20.

The effects on virus infectivity, haemagglutinating (HA) activity and polypeptide composition of bluetongue virus type 20 (BTV 20) were determined after digestion with the proteolytic enzymes, chymotrypsin, thermolysin and trypsin. Virus infectivity increased eight to 50-fold after exposure periods which reflected the activity of the proteases. Identical maximum increases in HA activity (i.e. 4096, 1024 and 128 HAU per 0.05 ml with sheep, bovine and human erythrocytes, respectively) occurred with each of the three proteases. Peak increases in virus infectivities and HA activities occurred after similar exposure periods. Outer capsid protein VP2 was the most sensitive virus protein to proteolytic digestion, being cleaved into a number of smaller polypeptides that remained attached to the virus particle. Digestion with chymotrypsin and thermolysin yielded four common cleavage products, designated P93, P76, P54 and P25 according to their estimated molecular weight, which suggested that they shared at least three cleavage sites. VP2 cleavage products resulting from digestion with trypsin differed somewhat from those of chymotrypsin and thermolysin, although the generation of polypeptides P93, P54 and P25.5 suggested the existence of common cleavage sites for the three proteases. Possible mechanisms whereby proteolytic cleavage of VP2 may enhance the infectivity and HA activity of BTV 20 are discussed.

Selective separation of virus proteins and double-stranded RNAs by SDS-KCl precipitation.

The total viral structural polypeptides and the double-stranded genomic RNAs of bluetongue virus can be selectively separated by a single SDS-KCl precipitation step. This simple, rapid and highly reproducible method enables greater than 95% recovery and purity of both viral proteins and dsRNAs within 30 min. The serotypic identity of the separated dsRNAs can be analyzed by SDS-PAGE electrophorogram immediately. After a single phenol/chloroform extraction, the dsRNA can also be used as hybridization probes, templates for molecular cloning and direct RNA sequencing. The SDS-KCl-precipitated viral proteins could be used readily for peptide mapping and as immunogens. Polyclonal and monoclonal antibodies raised against SDS-KCl-precipitated viral structural polypeptides were useful in Western immunoblots.

Characterization of a nonstructural phosphoprotein of two orbiviruses.

A phosphorylated nonstructural protein, NS2, was detected in bluetongue and African horsesickness virus (BTV and AHSV) infected-radiolabeled-cell lysates by electrophoresis on SDS-polyacrylamide gels (SDS-PAGE). The NS2 proteins of both viruses have similar migration on one-dimensional (1D) 10% SDS-PAGE. Examination of infected cell lysates on two-dimensional (2D) gels (isoelectric focusing followed by SDS-PAGE) separated two phosphorylated isoelectric forms of BTV NS2 and four phosphorylated forms of AHSV NS2. The isoelectric points of both species of BTV NS2 were acidic relative to all forms of AHSV NS2. Nonphosphorylated NS2 polypeptides were not detected by 2D gels. A nonphosphorylated host protein, which comigrated with NS2 on 1D gels, could be distinguished from viral proteins by isoelectric focusing on 2D gels. High performance liquid chromatography (HPLC) elution profiles of NS2 tryptic peptides from the two orbiviruses were compared. Three 32P-labeled tryptic peptides were generated from both AHSV and BTV NS2 proteins, which had been isolated and eluted from SDS-polyacrylamide gels. The elution profile from reverse phase HPLC was very similar for the tryptic phosphopeptides; in contrast, 35S-labeled tryptic peptides displayed considerable differences in elution profiles for the two NS2 proteins. Phosphoamino acid analysis revealed only phosphoserine in hydrolysates of BTV and AHSV NS2.

Rapid identification of bluetongue virus by nucleic acid hybridization in solution.

A liquid phase hybridization format has been adapted for the identification of bluetongue virus (BTV) with respect to serogroup and serotype. In this paper we present experiments which demonstrate the identification of bluetongue virus with respect to both serogroup and serotype. BTV serogroup-specific and BTV serotype 17-specific single-stranded RNA probes labeled with 35S-CTP were used to identify BTV viral nucleic acids in infected cell culture lysates. Cell lysates were prepared for testing by rapid solubilization in a guanidine isothiocyanate/EDTA/dithiothreitol medium. Hybridizations were done in 12.5 microliter reaction volumes for 2 h or overnight using nanogram quantities of probe. An RNAse solution was added subsequent to hybridization and incubated for 30 min. TCA-precipitable counts were collected and quantitated by scintillation counting. Specific hybridization signals were obtained in as little as 3 h in assays consisting of uninfected controls, cells infected with different BTV serotypes, and cells infected with a strain of epizootic hemorrhagic disease of deer (EHDV-1). By using asymmetric single-stranded RNA probes we were able to distinguish viral mRNA and viral double-stranded RNA components. We propose this technique as an ancillary or replacement procedure for the confirmation and classification of viral isolates using an appropriate battery of nucleic acid probes. Potential applications and methods of enhancing the technique are discussed.

Localization of the nonstructural protein NS1 in bluetongue virus-infected cells and its presence in virus particles.

Seven monoclonal antibodies to the nonstructural protein NS1 of an Australian isolate of bluetongue virus (BTV) have been used in immunofluoresence and immunogold procedures to locate NS1 in virus-infected cells and cytoskeletons. The antibodies fall into three groups indicating that NS1 contains at least three antigenic sites. One group consists of four antibodies which react solely with cytoskeleton-associated virus-specific tubules. A second group contains one antibody which reacts with cytoskeleton-associated virus particles, released viruses, and purified virus and core particles. Two antibodies constituting a third group react with both tubules and cytoskeleton-associated and released virus particles. NS1 was found in [35S]methionine-labeled, purified virus and core particles. Immunofluorescence tests reveal that those antibodies which react with virus particles also bind to cytoskeleton-associated virus inclusion bodies (VIB). The nature of this association was examined by probing cytoskeletons of BTV-infected cells with antibodies to NS1 and protein A-gold. VIB observed in thin sections were not uniformly labeled. Gold was associated with fibrillar arrays found around virus particles either leaving or in close proximity to the VIB. Fibrillar material was not found in association with all virus particles elsewhere in the cell and this suggests that fibril-virus complexes may be intermediate in virus morphogenesis.

Purification and properties of virus particles, infectious subviral particles, and cores of bluetongue virus serotypes 1 and 4.

Effective purification methods have been developed for virus particles, infectious subviral particles (ISVP), and virus cores of bluetongue virus (BTV) serotypes 1 and 4. The purified particles were analysed by indirect ELISA or PAGE using either silver staining, or fluorography of [35S]methionine-labelled preparations. No significant contamination with host cell proteins, or with the majority of BTV nonstructural proteins was detectable in any of the particle preparations. In addition to the two major outer capsid and five core proteins previously described, the purified virus particles of both serotypes were consistently found to contain small amounts of BTV protein NS2, previously regarded as exclusively nonstructural. This protein could be removed from the particle surface by treatment with a combination of chymotrypsin and sodium N-lauroyl sarcosinate, which also resulted in the cleavage of the larger of the two major outer capsid components (protein VP2). Two of the cleavage products of VP2 and the whole of the other major outer capsid component (protein VP5) formed a modified outer capsid layer in the resultant ISVP. These subviral particles were as or more infectious than the intact virus particles but had lost haemagglutinating activity. The core-associated RNA polymerase remained inactive in ISVP.

Correlation of serotype specificity and protein structure of the five U.S. serotypes of bluetongue virus.

The relationship between serotype specificity and protein structure was studied by polyacrylamide gel electrophoresis, peptide mapping and radioimmune precipitation (RIP) of structural and non-structural proteins of the five U.S. serotypes of bluetongue virus (BTV). The surface proteins, VP2 and VP5, showed the most variation in size among the serotypes. Peptide mapping of the proteins showed that VP2 is unique for each of the U.S. serotypes. The nucleocapsid and non-structural proteins showed a high degree of conservation, whereas the other surface protein, VP5, showed intermediate conservation among the serotypes. Monospecific neutralizing antiserum produced in rabbits against each serotype was used in cross-RIP against cytoplasmic extracts prepared from cells infected with each BTV serotype. There were extensive cross-reactions among those proteins which showed a high degree of structural conservation, whereas VP2 was immunoprecipitated best in the homologous RIP system. Thus, a correlation between serotype specificity and protein structure was shown among the five U.S. serotypes of BTV.

Sequence relationships of United States prototype and wild-type bluetongue virus RNA genomes investigated by northern blot hybridization analysis.

The 10 double-stranded RNA (dsRNA) genome segments of various isolates of bluetongue virus (BTV) were separated on a polyacrylamide gel, denatured in NaOH, and blotted onto 2-aminophenylthioether paper. Blotted dsRNA segments were detected, using radioactive probes, a cloned copy of DNA 70% fragment of genome segment 7 of BTV-17, whole genome BTV-17 copy DNA, or whole genome BTV-17 dsRNA. These probes detected sequence diversities in different isolates of BTV and these diversities are discussed in relation to the serotype and the electrophoretic migration patterns of the isolates.

Biochemical characterisation of Australian orbiviruses.

There are over 30 antigenically distinct orbiviruses found in Australia, including members in the bluetongue virus (BTV) and epizootic hemorrhagic disease of deer virus (EHDV) serogroups. Genomic RNA profiles were analysed by polyacrylamide gel electrophoresis (PAGE) on both 10% Laemmli and tris-borate-EDTA-(TBE)-urea gels. There was considerably more variation in the RNA profiles in Laemmli gels than was apparent in the TBE-urea gels. Since the latter system separates on molecular size, then presumably migration in the Laemmli gels may depend upon molecular weight (MW) and conformation. Analyses of 35S-methionine labeled proteins in virus-infected cells was carried out by PAGE in 10 to 20% gradient Laemmli gels. Twelve to 15 virus-specific labeled protein bands were observed in cells infected with orbiviruses. A detailed analysis of Australian BTV 1 isolates was made to identify these proteins. In addition to previously reported proteins (P1 to P8A) an additional low MW protein, P9, was observed (approx. MW 12,000). In the EHDV serogroup, 3 viruses (Ibaraki, CSIRo402 and CSIRo439), which were very closely related by virus neutralization tests and in protein-PAGE, were distinct in their migration by RNA-PAGE. Analyses of the individual RNA segments by 1-dimensional T1-ribonuclease oligonucleotide mapping showed minor differences between Ibaraki and the Australian EHDV isolates, suggesting that the 3 viruses have similar 3'-terminal RNA sequences. These studies suggest that Ibaraki (IBA) virus is closely related to but distinct from the Australian isolates.

Bluetongue virus serotype 20 infections in cattle of breeding age.

Ten cattle (6 heifers and 4 bulls) were inoculated with bluetongue virus (BTV) type 20. Clinical signs, antibody responses, and capabilities of these animals to replicate and maintain virus were assessed. The cattle showed no clinical signs of disease, although they did develop antibodies to BTV which showed long-term increasing titers. Virus was intermittently isolated from samples of blood, but not beyond day 21. Virus was not detected in the semen of the bulls, nor isolated from the tissues of the cattle at necropsy except from the genital tract of the 2 bulls which had been killed within 30 days after their inoculation. Gross and microscopic pathologic changes were not seen in any tissues that were attributable to BTV infection. There was no evidence of damage to the reproductive organs or of the development of a latent carrier state in either the heifers or the bulls.

Analysis of the genomes of bluetongue virus serotype 10 vaccines and a recent BTV-10 isolate from Washington.

The 10 double-stranded RNA gene segments of 2 vaccinal strains of bluetongue virus (BTV) serotype 10 that are used in the United States (BTV CA8 California and BT-8 Colorado), and a BTV-10 isolate recently obtained from infected sheep in Washington (state) were characterized by oligonucleotide fingerprint analyses. It was determined that although the 2 BTV-10 vaccinal strains are genotypically distinct, they are closely related both to each other and to the United States prototype BTV-10 virus. The BTV-10 field isolate appears to be a naturally occurring reassortment virus with genome segments derived from both United States prototype BTV-10 and BTV-11 viruses. However, one RNA segment of the isolate was totally unlike the corresponding segments of United States prototype BTV-10, -11, -13 and -17 viruses.

Comparison of bluetongue type 20 with certain viruses of the bluetongue and Eubenangee serological groups of orbiviruses.

The genome of bluetongue virus type 20 consists of 10 segments of double-stranded RNA each of which contains unique sequences as determined by oligonucleotide mapping. The 10 polypeptide products of the virus genome were detected in virus-infected cells, and in pulse--chase experiments there was no secondary cleavage of the primary gene products. Using stringent conditions for RNA--RNA reassociation, no significant homology could be detected between the genomes of bluetongue type 20 isolated in Australia and representative serotypes isolated in other geographic regions. The results suggest sequence divergence between geographically isolated viruses and not the recent introduction of a bluetongue virus into Australia.

Identification of the serotype-specific and group-specific antigens of bluetongue virus.

The bluetongue virus (BTV) core particle contains 2 major polypeptides, P3 and P7, and is surrounded by an outer capsid layer that is composed of the 2 major polypeptides, P2 and P5. Analysis of the immune precipitates from soluble 14C-labelled BTV polypeptides and hyper-immune rabbit and guinea-pig sera indicated that polypeptide P2 precipitates only with homologous BTV sera. This would indicate that P2 is the main determinant of serotype specificity. It was also found that in sheep infected with BTV the P2-precipitating antibodies in the serum correlate with the neutralizing antibody titres, whereas the appearance and subsequent decline of P7-precipitating antibodies correspond well with those of the complement fixing antibodies. This suggests that BTV group specificity, as measured by a complement fixation tests, is determined by the core protein P7. This result was supported by the observation that mouse ascitic fluid, which contains a high titre of BTV-specific complement fixing antibodies and a very low titre of neutralizing antibodies, contains almost exclusively antibodies that precipitate P7.

A comparison of an australian bluetongue virus isolate (CSIRO 19) with other bluetongue virus serotypes by cross-hybridization and cross-immune precipitation.

No major differences in size were observed when both the double-stranded RNA and the polypeptides of the Australian bluetongue virus (BTV) isolate CSIRO 19 (BTV-20) were compared with those of other BTV serotypes such as BTV-10 and BTV-4. Minor capsid polypeptide P6 of both BTV-20 and BTV-4, which electrophoreses as a single band on continuous phosphate buffered gels, in separated into 2 distinct bands on discontinuous glycine-buffered gels. This was not the case with BTV-10. Cross-immune precipitation of BTV-20 with BTV-10, BTV-17, BTV-4 and BTV-3 indicated strong immunological cross-reaction of the group-specific antigen P7 of the different serotypes. There was also some cross-immune precipitation of the serotype-specific polypeptide P2 of BTV-20 and BTV-4. This result is in agreement with the observed cross neutralization of these 2 viruses. The main distinction between BTV-20 and the other BTV serotypes was observed in cross-hybridization experiments. The homology between the nucleic acid of BTV-20 and other BTV serotypes was less than 30%, whereas homology normally found between BTV serotypes is at least 70%. The hybridization products of the different BTV serotypes were analysed by electrophoresis and fluorography. Two main hybrid segments were observed in all heterologous hybridizations with BTV-20 as a compared with 7 hybrid segments in hybridizations between BTV-4 and BTV-10. In order to determine from which genome segment of BTV-20 these 2 hybrid segments were derived, the hybridizations were carried out with individually purified double-stranded RNA segments. These results indicate that the 2 segments of BTV-20 that show the largest homology to corresponding segments of a heterologous BTV serotype are No. 7 and 10.