Limits of detection of bluetongue virus with different assay systems

The sensitivity of different assay systems for detecting low concentrations of bluetongue virus (BTV) were compared. These assays included blind passage on baby hamster kidney (BHK-21) cells and on cattle pulmonary artery endothelial (CPAE) cells, immunoperoxidase staining of cells on multiwell slides, and cDNA/RNA hybridization of BTV infected cells. Nine serial 10-fold dilutions of a cell culture-adapted BTV serotype 11 were tested (each dilution was treated as a separate sample) in all assays. Visual inspection for cytopathic effects (CPE) during 3 passages in BHK-21 cells detected samples that contained greater than or equal to 3 plaque forming units (PFU)/ml of BTV. Evidence of CPE during 3 passages in CPAE cells detected samples that contained greater than or equal to 0.3 PFU/ml of BTV. A limit of detection (greater than or equal to 0.3 PFU/ml) was obtained faster by immunoperoxidase staining of BTV-inoculated CPAE cells on multiwell slides and incubated for 3 days. The cDNA/RNA hybridizations of CPAE and BHK-21 cells incubated for 2 or 3 days, respectively, with BTV dilution samples detected samples that contained greater than or equal to 30 PFU/ml. Of the assay systems examined, immunoperoxidase staining of CPAE cells on multiwell slides inoculated with cell culture-adapted BTV was the most sensitive and fastest assay for definitive virus identification.     

Bluetongue virus serotypes 20 and 17 infections in sheep: Comparison of clinical and serological responses

The clinical, virological and serological responses of sheep infected with an Australian bluetongue virus (BTV) isolate (serotype 20) were compared to responses in sheep inoculated with an American bluetongue isolate (serotype 17) with which it had shown cross-reactions in serum neutralization tests. In sheep inoculated with BTV 20, clinical signs were very mild and viremia was first detected by day 5; virus was isolated intermittently for a further 2 to 3 days. Neutralizing and precipitating antibodies were first detected in the serum of the sheep between 2 to 3 weeks following inoculation. In contrast, sheep inoculated with BTV 17 showed pyrexia and severe hyperemia of the nasolabial area and oral mucosa from day 7 to 17. Viremia was first detected on day 3 and extended to day 20, while the appearance and titers of serum antibodies was similar in both groups.After challenge with BTV 17 the sheep in both groups remained clinically normal, and virus was not detected in the blood; however, serum neutralizing antibody titers to both viruses increased 2 weeks after challenge and the mean titer of the two groups ranged from 1:250 to 1:640.     

Competitive ELISA for serodiagnosis of bluetongue: evaluation of group-specific monoclonal antibodies and expressed VP7 antigen.

The performance of 2 competitive enzyme-linked immunosorbent assays (C-ELISA) was compared with the reference C-ELISA I for the detection of antibodies to bluetongue virus (BTV). One of the assays (C-ELISA II) used a group-specific monoclonal antibody (MAb) to BTV, obtained from the American Type Culture Collection (8A3B-6) and tissue culture (TC)-derived BTV antigen (Ag), and the other assay (C-ELISA III) used BTV core protein VP7 (expressed in yeast) and the reference MAb (Pirbright Laboratory, 3-17-A3). Test sera were obtained by sequential blood samples from 22 calves, each inoculated with a different serotype (T) of BTV (South African [SA] T-1-T-16 and T-18-T-20 and USA T-11, T-13, and T-17). Sera were also obtained from 4 calves and 4 sheep inoculated with USA BTV T-10 and from several groups of calves exposed to single or multiple doses of epizootic hemorrhagic disease virus (EHDV) T-1-T-4 grown in TC (BHK-21) or suckling mouse brain (SMB). A total of 618 bovine and ovine field sera collected from BT-free and BT-endemic areas were also tested. The C-ELISA III was more sensitive than the C-ELISA II in the detection of anti-BTV antibody in sera from cattle and sheep early after infection with BTV. Seroconversion was demonstrated by the 3 C-ELISAs in all animals inoculated with BTV by 20 days postinfection (DPI), except in calves that received SA T-3 or USA T-13, which became positive at 40 DPI.(ABSTRACT TRUNCATED AT 250 WORDS)     

Immunologic response of sheep to inactivated and virulent bluetongue virus

Humoral and cellular immune responses of sheep to inactivated and virulent bluetongue virus (BTV) were studied. All sheep inoculated with inactivated BTV developed BTV group-specific nonneutralizing antibodies, as determined by agar-gel immunodiffusion. The development of group-specific, nonneutralizing, complement-fixing antibodies was variable and appeared to be dependent on immunizing BTV serotype, sheep breed, and individual variation. Virus-neutralizing antibodies were never detected after inoculation with the inactivated BTV. In vitro lymphocyte stimulation to BTV soluble antigen was observed with cells from all inoculated Warhill sheep and with cells from 1 of 3 inoculated Suffolk cross sheep. Complement-fixation titers did not appear to correlate with the degree of protection observed, ie, duration of postchallenge-exposure viremia. The development of postchallenge-exposure neutralizing antibody titer was inversely correlated to protective immunity. The development of a response to BTV antigen in the lymphocyte-stimulation test associated most closely with protection. Warhill sheep were afforded better protection, by inoculation with inactivated BTV, to live virus challenge exposure than were the Suffolk cross sheep. Approximately 30% of the inoculated Suffolk cross sheep responded to challenge exposure with intensified clinical signs of blue-tongue, compared with the challenge-exposed control sheep of the same breed.     

Experimental transmission of bovine viral diseases by insemination with contaminated semen or during embryo transfer

Three experimental approaches were used to study transmission of blue tongue (BT), infectious bovine rhinotracheitis (IBR) and bovine virus diarrhoea (BVD) viruses. These were insemination with contaminated semen, experimental infection of embryo donor cows, or transfer of embryos experimentally exposed to virus in vitro to normal recipients. Parameters assessed included number and quality of embryos produced, virus detection (isolation and electron microscopy), serology and histopathology. All superovulated sesceptible cows inseminated with semen containing blue tongue virus (BTV) (n = 2) or infectious bovine rhinotracheitis virus (IBRV) (n = 2) became infected. One cow inseminated with semen containing BTV produced seven virus-free seven-day-old embryos; the second cow failed to produce any embryos. One of two cows inseminated with semen containing IBRV produced two underdeveloped, virus-free embryos while no embryos were produced by the second cow. One of two cows inseminated with semen containing bovine viral diarrhoea virus (BVDV) became infected. Two poorly developed, virus-free seven-day-old embryos were recovered from one of these cows. Superovulated susceptible cows inoculated either intramuscularly with BTV (n = 3) or intranasally with IBR virus (n = 2) became infected. Virus was isolated from some tissues of two BTV-infected cows, neither of which produced embryos. A third BTV-infected cow produced two virus-free embryos collected at necropsy five days after inoculation. One of two cows experimentally infected with IBR virus, produced three embryos but virus was not detected either by electron microscopy (1 embryo) or in cell culture by cytopathic alterations (1 embryo).(ABSTRACT TRUNCATED AT 400 WORDS)     

Comparison of the characteristics of avian reoviruses isolated from the digestive and respiratory tract, with viruses isolated from the synovia.

Two-week-old gnotobiotic chicks were inoculated in the foot pad with viruses isolated from synovia and synovial membrane-WVU 1464-29H, WVU 1675, WVU 2937, WVU 2986, and WVU 71-212; from digestive tract-reoviruses 24, 25, and 59; or from respiratory tract-reovirus Fahey-Crawley (FC). All viruses induced swelling of the foot pad and inflammatory changes of synovial membrane. Serum from virus-infected chicks had a common agar gel precipitin (AGP) line. On the basis of the plaque-reduction test in primary chicken kidney (PCK) cells, the viruses were classified into 4 major serotypes. All viruses produced cytopathic effects (CPE) in primary chicken tissue cultures. Other than reovirus FC and WVU 1464-29H, all viruses produced CPE in the Vero cell line.     

Comparison of persistence of seven bovine viruses on bovine embryos following in vitro exposure

The ability of seven cytopathic strains of bovine viruses to adhere to the zona pellucida of six-to-eight day-old bovine embryos were compared. Embryos were exposed to virus by placing them either in virus suspensions or by culturing them on infected bovine turbinate cultures for 18-24 h. After exposure to bovine virus diarrhea virus (BVDV), infectious bovine rhinotracheitis virus (IBV), bluetongue virus (BTV), pseudorabies virus (PRV), vesicular stomatitis virus (VSV), parainfluenza 3 virus (PI3), or bovine enterovirus virus (BEV), the embryos were tested for virus by culture in bovine turbinate cells and by morphological examination using electron microscopy (EM). A special technique to minimize loss of embryos processed for EM was developed. More embryos had viral particles on the surface of the zona pellucida after exposure to 18-24 hour infected cell cultures than did embryos exposed to viral culture suspensions. The most dramatic finding was that BTV adhered in large numbers to the surface of the zona pellucida of exposed embryos. IBRV, PRV, and VSV comprised an intermediate group, with virions occasionally detected on the surface of exposed embryos after 5 washes. Therefore, extensive washing is required. The PI3 and BEV were easily removed from embryo-exposed virus by washing. BVD was difficult to identify morphologically, making assessment by EM unreliable. There was no evidence that any one of the seven viruses penetrated the intact zona pellucida. Using a micromanipulator, 42 embryos were also directly inoculated through the zona pellucida with +/- 50 picoliters of virus inoculum or medium.(ABSTRACT TRUNCATED AT 250 WORDS)     

Immunodiffusion test antigen from bluetongue virus-infected newborn mouse brains

Three methods of extracting bluetongue virus (BTV)-infected newborn mouse brains to prepare immunodiffusion (ID) test antigen were used. The most readily readable and reproducible results were obtained with fluorocarbon-extracted brains homogenized in 8.5% sucrose. Mouse brain- and reference cell culture-derived antigens gave a line of identity with anti-BTV serum. Extracts of noninfected brains were nonreactive. ID tests on field-collected bovine sera, comparing the two types of antigen, resulted in only 73% agreement due to a greater sensitivity of cell culture-derived antigen. A 70.5% agreement resulted when comparing mouse brain-derived antigen in ID tests with complement fixation tests, the latter being least sensitive. ID test results with sera from experimental sheep gave 95.9% agreement between cell culture- and mouse brain-derived antigens. Between ID, which detects antibody to the BTV common or group antigen, and virus neutralization, which detects type-specific antibody, the agreement was 71.4% with postchallenge sera. Data from pre- and postinjection sera, however, indicate the possible activity in Texas of viruses other than International BTV Types 10, 11, 13, and 17.     

Comparative studies on the growth of Australian bluetongue virus serotypes in continuous cell lines and embryonated chicken eggs

The replication of cell culture passaged Australian bluetongue virus (BTV) isolates, serotypes 20 (CSIRO19) and 1 (CSIRO156), and an untyped BTV (CSIRO154) was assessed in eight continuous cell lines (one derived from baby hamster kidney cells, BHK-21; three derived from monkey kidney cells, Vero, LLC-MK2 and CV-1P; a foetal ovine lung and a mouse fibroblast cell line, CSL503 and L929, respectively, a Super-Vero-Porcine stable cell line, SVP; and a mosquito cell line, Aedes albopictus cells) and in 11-day-old embryonated chicken eggs (ECE) at different multiplicities of infection. All three viruses replicated in the cell lines tested, maximum extracellular virus yields being attained from BHK-21 cells at high multiplicities of infection (approximately 10 PFU per cell). Also BHK-21 cells produced much higher yields of virus than the other cell lines tested when low multiplicities of infection were used (approximately 10(-4) PFU per cell). All BTV serotypes multiplied in Singh's Aedes albopictus cells with no cytopathogenic effects over the 4 day period tested. The viruses also replicated in 11-day-old ECE; however, the sensitivity of ECE for growth of the Australian serotypes was not as high as has been reported for BTV isolates in other countries. In all cell culture systems and in ECE, BTV1 and BTV20 replicated more efficiently than did CSIRO154 virus.     

A study of cytopathic rotavirus strains isolated from calves with acute enteritis

Nine cytopathic bovine rotavirus strains were isolated in MA-104 cell cultures from fecal specimens of dairy calves suffering from diarrhea. Isolation of the virus was accomplished from three outbreaks which occurred on dairy farms located in Central and Southern Italy. Fecal suspensions were treated with a high concentration (1000 micrograms/ml) of trypsin, and inoculated into MA-104 cell cultures grown out in Eagle's minimum essential medium (MEM) containing 5 micrograms/ml of the enzyme. Cytopathic effects (CPE), characterized by intracytoplasmic inclusion bodies of different sizes and shapes, were observed on the 1st passage with five of the strains and on the 2nd (2 strains) or the 3rd (2 strains) passage for the others. The presence of trypsin and the use of MA-104 cells appeared to be essential for the occurrence of CPE, inasmuch as no CPE was detected when trypsin was omitted in the MA-104 cell system. Replication failed to occur when primary bovine embryo kidney cell cultures with or without trypsin were used. Electron microscopy revealed the presence of particles with a typical rotavirus morphology. In MA-104 cells, the titre of virus reached its maximum 48 hr after inoculation. Small, clear-cut plaques were produced by the isolates in MA-104 cells under the overlay of MEM containing carboxymethyl cellulose, trypsin and DEAE-dextran. The nine rotavirus strains were antigenically related, whereas the relationship to either the Nebraska or the Compton rotaviruses was quite weak.     

Protection against bovine leukosis virus infection in sheep with the BL 20 bovine lymphoblastoid cell line

The bovine lymphoblastoid BL 20 cell line derived from a case of sporadic bovine leukosis when inoculated into sheep did not induce an antibody response directed against bovine leukosis virus (BLV) structural proteins. Sheep were inoculated twice with the BL 20 cell line and then challenged with BLV infected lymphocytes. Three out of four sheep challenged four weeks after BL 20 inoculation did not develop BLV antibodies. Of the 12 sheep challenged later, three sheep did not develop BLV antibodies. BLV was isolated from all the seropositive animals and from none of the seronegative animals.     

The propagation of avian viruses in a continuous cell line (QT35) of Japanese quail origin

Seven of nine avian virus families tested (Birnaviridae, Coronaviridae, Herpesviridae, Paramyxoviridae, Poxviridae, Reoviridae, and Retroviridae) were found to replicate in a quail fibroblast cell line, designated QT35, resulting in a cytopathic effect (CPE) visible with the naked eye or by low-power microscopy. In comparison, only one (Paramyxoviridae) of seven mammalian virus families tested produced an observable CPE. Cytopathic changes induced by examined viruses were round cell, syncytial, and focus formation. Trypsin did not promote cytopathic changes by selected CPE-negative avian and mammalian viruses in QT35 cells. Several avian viruses (infectious bursal disease virus, Newcastle disease virus, Canary pox virus, and reovirus) formed plaques under agar. Avian reovirus and infectious bursal disease virus produced similar titers in chicken embryo fibroblast (CEF) and QT35 cell cultures. Chicken-egg-yolk neutralizing-antibody titers to IBDV were comparable in CEF and QT35 cell-culture systems.     

Bighorn sheep fetal lung cell line for detection of respiratory viruses

Pneumonia is an important disease of bighorn sheep (BHS) that is primarily responsible for the drastic decline in numbers of these animals in North America. Members of the genus Mannheimia and Pasteurella have frequently been isolated from the pneumonic lungs of BHS. Antibodies to several respiratory viruses, including bovine parainfluenza virus 3 (BPIV-3), bovine respiratory syncytial virus (BRSV), bovine viral diarrhea virus (BVDV), and bovine herpesvirus 1 (BoHV-1), have been detected in herds of BHS. The availability of BHS fetal lung cell lines is likely to enhance the chances of isolation of these viruses. Here we report the development of such a cell line. This line is permissive for BPIV-3, BRSV, BVDV, and BoHV-1 infection, as revealed by an enzyme immunoassay of virus-infected cells with antibodies specific for each of these viruses. This cell line should be valuable for detecting these 4, and possibly other, respiratory viruses in BHS.     

Preliminary characterisation of the sersenk strain of goat pox virus

The Sersenk strain of goat pox virus first isolated in Iraq, grew on chorioallantoic membranes (CAM) of developing chicken embryos producing generalised large pocks, 2 to 3 mm in diameter, on the third day post-inoculation. The virus killed the inoculated embryos. Replication of the virus in primary cultures of lamb testis cells induced a cytopathic effect (CPE) and plaque formation characteristic of pox viruses. It was antigenically related to reference strains of goat pox and sheep pox viruses. The virus was sensitive to ether and chloroform, failed to agglutinate erythrocytes and was strictly pathogenic to goats.     

Selection of foot-and-mouth disease viruses by passage in bovine and swine kidney cell cultures

Two uncloned populations of foot-and-mouth disease virus, one pathogenic for adult mice and the other nonpathogenic, were passaged in cultures of primary bovine kidney (BK) cells and a line of pig kidney (MVPK) cells. Within 10 passages in MVPK cells, the nonpathogenic virus became pathogenic for adult mice, but similar passages of this virus in BK cells did not affect its pathogenicity. In contrast, passage of the pathogenic virus in MVPK cells resulted in a decrease in pathogenicity, but again passage in BK cells had no effect on this characteristics. Neither of the viruses changed in pathogenicity for infant mice during the four passages that were tested. The nonpathogenic virus passaged in BK cells was more infectious for BK than for MVPK cells, but after passage in MVPK cells, this virus was about equally infectious for the two types of cells. Infectivity of the pathogenic virus was relatively unchanged by passage in either type of cell. The parent nonpathogenic virus and the 10th BK cell passage of this virus were much more resistant to adsorption with homogenized mouse kidney than were the MVPK cell passages of nonpathogenic virus. The parent and passaged pathogenic viruses were readily adsorbed. The results demonstrated that passage of the two viruses in MVPK cells had a pronounced selective effect.     

Transplacental transmission of field and rescued strains of BTV-2 and BTV-8 in experimentally infected sheep

Transplacental transmission of bluetongue virus has been shown previously for the North European strain of serotype 8 (BTV-8) and for tissue culture or chicken egg-adapted vaccine strains but not for field strains of other serotypes. In this study, pregnant ewes (6 per group) were inoculated with either field or rescued strains of BTV-2 and BTV-8 in order to determine the ability of these viruses to cross the placental barrier. The field BTV-2 and BTV-8 strains was passaged once in Culicoides KC cells and once in mammalian cells. All virus inoculated sheep became infected and seroconverted against the different BTV strains used in this study. BTV RNA was detectable in the blood of all but two ewes for over 28 days but infectious virus could only be detected in the blood for a much shorter period. Interestingly, transplacental transmission of BTV-2 (both field and rescued strains) was demonstrated at high efficiency (6 out of 13 lambs born to BTV-2 infected ewes) while only 1 lamb of 12 born to BTV-8 infected ewes showed evidence of in utero infection. In addition, evidence for horizontal transmission of BTV-2 between ewes was observed. As expected, the parental BTV-2 and BTV-8 viruses and the viruses rescued by reverse genetics showed very similar properties to each other. This study showed, for the first time, that transplacental transmission of BTV-2, which had been minimally passaged in cell culture, can occur; hence such transmission might be more frequent than previously thought.     

A continuous bovine kidney cell line for routine assays of foot-and-mouth disease virus

A continuous bovine kidney cell line, LF-BK, arose from primary bovine calf kidney cells that survived infection with a temperature-sensitive mutant of foot-and-mouth disease virus. No virus was recovered after the first passage. Cells of Passage 48 were inoculated into two steers which remained healthy and did not develop neutralizing antibodies to the virus. The karyotype of cells of the 53rd and 87th passages was similar and revealed that the cells were markedly transformed. The modal number of diploid chromosomes was 52 at both passage levels. LF-BK cells and primary bovine kidney cells were equally susceptible in plaque assays to each of the 7 types of foot-and-mouth disease virus. The cell line and primary bovine kidney cells were less susceptible than primary bovine thyroid cells to several subtypes of the virus in suspensions of tongue epithelium. The LF-BK continuous cell line is recommended for routine plaque assays or plaque neutralization tests as a substitute for primary bovine kidney cells.     

Prevalence of bovine herpesvirus-1, bovine viral diarrhea, parainfluenza-3, goat respiratory syncytial, bovine leukemia, and bluetongue viral antibodies in sheep

Sera from healthy sheep were collected in January and March 1982 from flocks of sheep located in southwestern and southeastern Louisiana. These sera were tested for bovine herpesvirus-1 (BHV-1), bovine viral diarrhea virus (BVDV), parainfluenza-3 (PI-3) virus, and goat respiratory syncytial virus (GRSV) antibodies by microtitration virus-neutralization test. The sera were tested also for bovine leukemia virus (BLV) and bluetongue virus (BTV) antibodies by immunodiffusion tests. The number of flocks with seropositive sheep for each virus were: 2/8 (25%) for BVDV; 8/8 (100%) for PI-3 virus; 7/8 (87.5%) for GRSV; and 6/8 (75%) for BTV. Seropositive rates for each virus for the individual sheep tested were: 4/158 (2.5%) for BVDV; 117/158 (74.1%) for PI-3 virus; 77/158 (48.7%) for GRSV; and 21/158 (13.3%) for BTV. All sheep were seronegative for BHV-1 and BLV.     

Genetic stability in calves of a single strain of bluetongue virus

Newborn calves were inoculated IV with highly plaque-purified bluetongue virus (BTV), serotype 10. The electrophoretic migration patterns of RNA segments and proteins of viruses isolated from calves at intervals after inoculation were compared. In addition, sera collected from calves at intervals after inoculation were compared for their abilities to neutralize several virus isolates from the same calf. Viremia persisted in calves for up to 56 days. Differences were not detected in the electrophoretic migration pattern of RNA segments or proteins of any of the BTV isolates. All calves produced high titers of neutralizing antibody to the original BTV inoculum by 28 days after inoculation, and significant (greater than or equal to 4-fold) differences were not detected in the neutralizing titers of sera to viruses collected at intervals after inoculation. The plaque-purified strain of BTV appeared to be stable genetically in infected calves, and failure to demonstrate antigenic variation among isolates indicated that antigenic shift was not the mechanism that allowed viremia to persist in BTV-infected calves.     

A rapid virus neutralization assay for Newcastle disease virus with the swine testicular continuous cell line.

Five continuous cell lines, swine testicular (ST), human rectal tumor (HRT 18), fetal rhesus monkey kidney (MA104), bovine turbinate (BT), and quail tracheal (QT35), were evaluated and compared with chicken embryo fibroblasts (CEFs) for their ability to propagate B1 or Texas GB strains of Newcastle disease virus (NDV). The NDV Texas GB strain replicated in all the continuous cell lines used in this study. Only the ST and QT35 cells produced a cytopathic effect (CPE) similar to that produced in CEFs. However, the ST cell line remained attached while displaying CPE, whereas infected QT35 cells detached, as did the CEFs. The B1 strain of NDV replicated in ST cells, MA104 cells, and CEFs but with less CPE as compared with the Texas GB strain. Pretreatment with trypsin did not enhance CPE with either NDV strain at the level tested. Sera evaluated for neutralizing antibody titers to NDV were significantly higher in titer when the ST cell line was used and compared with CEFs. A high correlation was found between the microscopic examination and the tetrazolium dye (MTT) microassay methods for determining the viral neutralization endpoint, thus suggesting the ST cell line and MTT microassay could be used as an alternative to CEFs and microscopic examination for evaluating neutralizing antibodies titers to NDV.