Some epidemiological and economic aspects of a bluetongue-like disease in cattle in South Africa--1995/96 and 1997

In December 1995 to March 1996 and the early summer of 1997 South Africa experienced above average rainfall which favoured the occurrence of Culicoides transmitted diseases. During this period several outbreaks of an uncommon disease of cattle occurred over a large part of the country. The clinical signs were similar to those of infection with the viruses of bluetongue (BT) and epizootic haemorrhagic disease of deer (EHD). Virus isolation from cattle and Culicoides yielded both viruses. Dual infections occurred on several farms. Typing of BT isolates yielded types 2, 3, 6 and 8. On at least two farms more than one BT virus serotype was involved. On one farm only EHD virus could be isolated from cattle and Culicoides. Serological tests confirmed that on this farm the disease was caused by EHD. In 1932/33, when a similar disease was reported conditions were vastly different. Rainfall figures show that the 1932/33 season was exceptionally dry. Techniques available at that time could not identify EHD and the cause was reported to be BT. The occurrence of BT in a dry season and over a much wider area than the distribution in South Africa of Culicoides imicola, the only proven vector for BT, is a clear indication that other species less dependent on high rainfall are involved. The present isolation of BT virus from three of five pools of parous C. bolitinos is evidence that this species, which breeds in cattle dung, may be an additional vector for BT.

Virulence-associated antigenic and genetic characteristics of bluetongue virus-17 isolates

Bluetongue virus (BLU), an orbivirus, is of importance to the sheep and cattle industries. We have obtained 5 United States BLU-17 isolates which have been tested for virulence in sheep and 16 BLU-17 field isolates from the Caribbean and Central America. Using a panel of 15 monoclonal antibodies (MAb) against an avirulent BLU-17, we observed that 6 MAbs had negligible or very low neutralization titers for the virulent isolates in contrast to moderate to high titers for the avirulent isolates. These MAbs also differentiated the field isolates into two groups--inadequate vs effective neutralization. All 6 MAbs immunoprecipitated the outer capsid protein, VP2. Electropherotyping of genomic RNA from all 21 viruses identified an increase in RNA segment 3 mobility for those isolates which were not neutralized by the 6 specific MAbs. RNA segment 3 codes for the inner core protein, VP3. There were no detectable electrophoretic differences for RNA segment 2, which encodes VP2. In summary, the virulent BLU-17 isolates differed from the avirulent isolates in both the antigenicity of the outer capsid protein, VP2, and the electrophoretic mobility of RNA segment 3, and we hypothesize that one or both of these changes may result in BLU virulence.

Bluetongue virus infection in sheep: haematological changes and detection by polymerase chain reaction

Eight sheep vaccinated with 10(6) pfu of attenuated Australian bluetongue virus serotype 23 (BTV 23A) and eight BTV-free sheep were challenged with virulent BTV 23. There was little subsequent variation in the mean clinical score, or in the mean lymphocyte and platelet concentrations in the peripheral blood of the eight vaccinated sheep. There was a marked thrombocytopenia and lymphopenia in the naive sheep as the mean lymphocyte and platelet concentrations fell to a minimum at days 8 and 11 after inoculation, respectively. Similar changes were observed in three other naive sheep inoculated with field isolates of BTV 1,9 or 23. BTV was detected by nested polymerase chain reaction in whole blood of these sheep between days 6 and 28, in mononuclear leukocytes between days 3 and 14, and in platelets between days 6 and 21.

Diagnostic analysis of the prolonged bluetongue virus RNA presence found in the blood of naturally infected cattle and experimentally infected sheep

Bluetongue virus (BTV) RNA was detected by the polymerase chain reaction (PCR) in the blood of 24 naturally infected cattle as long as 160 days after the estimated date of infection. Blood samples from these animals and from 10 experimentally BTV-infected sheep, which also exhibited a prolonged hematologic BTV RNA presence, were concurrently evaluated for viral infectivity. Infectivity analyses were conducted using the sentinel sheep inoculation and embryonated chicken egg inoculation procedures. Blood specimens from the experimental sheep 50, 56, 71, and 89 days after BTV inoculation were uniformly negative for viral infectivity despite their uniformly positive status with PCR evaluation. Three collections of blood from the naturally infected cattle at least 100, 135, and 160 days after infection also revealed no recoverable viral infectivity but an initially high and progressively decreasing prevalence of BTV with the PCR technique. These retrospective epidemiologic and prospective experimental approaches were concordant in that both studies demonstrated consistent discrepancies between the viral infectivity and the PCR diagnostic data. The significance of these discrepancies is discussed with respect to Koch's postulates and with respect to the possibility that the biological vector of BTV (Culicoides variipennis) may recover BTV infectivity from PCR-positive but virus isolation-negative blood.

Phylogenetic characterisation of bluetongue viruses from naturally-infected insects, cattle and sheep in Australia

The polymerase chain reaction was used to detect the presence of bluetongue virus (BTV) in a number of clinical and insect samples collected in the Northern Territory of Australia. Sequence analyses of the amplified BTV genes differentiated endemic Australian and exotic viruses. Two potential exotic BTV were detected as a result of PCR analyses of blood from sentinel animals and of the insect vector, Culicoides wadai. The detection of BTV in C wadai was the first direct demonstration of the presence of BTV in this potential vector. This new technology can significantly reduce the time taken for a diagnosis from a clinical sample and increase the amount of useful information obtained on a BTV isolate by using rapid sequencing techniques. Sequence data were used to differentiate between BTV20 isolated in 1975 and two isolates of the same serotype, isolated in 1992, and indicated that the latter were probably a recent incursion into Australia from Indonesia due to their greater VP3 sequence homology to the BTV9 (Java) than to Australian BTV isolates.

Detection of bluetongue virus in the blood of inoculated calves: comparison of virus isolation, PCR assay, and in vitro feeding of Culicoides variipennis

The interval after infection when bluetongue virus (BTV) was present in the blood of calves inoculated with BTV serotype 10 (BTV 10) was evaluated by virus isolation (VI) in embryonated chicken eggs (ECE), BTV-specific polymerase chain reaction (PCR), and in vitro blood feeding of vector Culicoides variipennis (C.v.) sonorensis. BTV nucleic acid was detected by PCR in blood cells for 16 to 20 weeks after infection whereas infectious virus was detected by VI in ECE for 2 to 8 weeks. BTV was detected in calf blood by in vitro feeding of C.v. sonorensis for only 0 to 2 weeks after inoculation of calves with BTV 10. Selected bloods which were positive by PCR analysis but not by VI in ECE were not infectious for sheep. The data are consistent with the hypothesis that prolonged viremia in BTV-infected cattle results from association of the virus with blood cells, especially erythrocytes. The fact that calf blood that contained viral nucleic acid as determined by PCR analysis, but not infectious virus as determined by VI in ECE, was not infectious for either the insect vector or sheep suggests that cattle whose blood contains BTV nucleic acid but not infectious virus are unimportant to the epidemiology of BTV infection.

Association of bluetongue virus gene segment 5 with neuroinvasiveness

Two strains (UC-2 and UC-8) of bluetongue virus were used to determine genetic factors influencing neuroinvasiveness. Reassortants were produced in vitro, and the parental origins of their genes were determined by polyacrylamide gel electrophoresis profiles and restriction endonuclease digestion. Gene segment 5 of UC-8 correlated with neuroinvasiveness of reassortants when inoculated subcutaneously into newborn mice.

Bluetongue virus isolations from vectors and ruminants in Central America and the Caribbean. Interamerican Bluetongue Team

A regional prospective study of the epidemiology of bluetongue virus (BTV) serotypes covering 11 countries in Central America and the Caribbean took place between 1987 and 1992. Active surveillance revealed BTV infection to be endemic in the absence of confirmed indigenous cases of bluetongue. During the 6-year span of the study, over 300 BTV isolations were obtained from cattle and sheep. Results of the earlier years of the study were summarized, and surveillance activities in the concluding months of the study from November 1990 to February 1992 were evaluated. Forty-five BTV isolations were made during this time, 44 from sentinel cattle and 1 from a ram with clinical signs compatible with contagious ecthyma. Virus isolation from potential vectors also was attempted, yielding a further 9 BTV isolates from parous Culicoides insignis and C pusillus, 2 BTV isolates from blood-engorged C filarifer, and 1 epizootic hemorrhagic disease virus type-2 isolate from parous C pusillus. Our extensive network of sentinel herds in the region detected BTV-1 as the predominant serotype in Central America in 1991, after an apparent absence of 1 year in the sentinel animals. Other serotypes in Central America at that time included BTV-3 and BTV-6. In Puerto Rico and the Dominican Republic, BTV-4 became the predominant serotype, without detection of BTV-8 and BTV-17, which were common in recent years of the study. The serotypes found in the Caribbean Basin continued to have marked differences from those in North America. The importance of viewing bluetongue as an infection, the distribution of which is determined principally by ecologic factors, is emphasized.

The use of discriminant analysis in predicting the distribution of bluetongue virus in Queensland, Australia

The climatic variables that were most useful in classifying the infection status of Queensland cattle herds with bluetongue virus were assessed using stepwise linear discriminant analysis. A discriminant function that included average annual rainfall and average daily maximum temperature was found to correctly classify 82.6% of uninfected herds and 72.4% of infected herds. Overall, the infection status of 74.1% of herds was correctly classified. The spatial distribution of infected herds was found to parallel that of the suspected vector, Culicoides brevitarsis. This evidence supports the role of this arthropod species as a vector of bluetongue viruses in Queensland. The effect of potential changes in temperature and rainfall (the so-called 'global warming' scenario) on the distribution of bluetongue virus infection of cattle herds in Queensland was then investigated. With an increase in both rainfall and temperature, the area of endemic bluetongue virus infection was predicted to extend a further 150 km in and in southern Queensland. The implications of this for sheep-raising in Queensland are discussed.

Heterogeneity of the L2 gene of field isolates of bluetongue virus serotype 17 from the San Joaquin Valley of California

Genome segment 2 (L2) from six field isolates of bluetongue virus (BTV) serotype 17 was sequenced by cycling sequencing after the amplification of the viral cDNA by the polymerase chain reaction. The viruses were isolated from sheep, cattle and a goat in the San Joaquin Valley of California during the years 1981 and 1990. These viruses exhibit divergent patterns of neutralization with BTV 17-specific monoclonal antibodies. The six L2 genes of the BTV 17 field isolates all encode a protein of 955 amino acids. Similarity of the nucleotide sequences of the L2 genes with respect to the prototype strain ranges between 93.8% and 95.1%, whereas the similarity between the field isolates ranges from 96.8% to 99.1%. Although very closely related, the L2 gene of each virus is distinct. Furthermore, mutations in the L2 gene of field isolates of BTV do not consistently follow a linear pattern of accumulation over time. Some amino acid changes in the VP2 protein of field strains were conserved over time, whereas others were not correlated with the year of isolation and some substitutions were unique to individual viruses. The predicted VP2s constitute a group of non-identical, but closely related proteins. Phylogenetic analyses suggest that the viral variants which co-circulate in the San Joaquin Valley could evolve by different evolutionary pathways.

Prevalence of bluetongue virus expression in leukocytes from experimentally infected ruminants

Replication of bluetongue virus (BTV) in leukocytes from the blood of sheep, cattle, elk, and mule deer inoculated with BTV serotype 10 or 17 was assessed by immunocytochemical staining and dot blot northern hybridization to determine if differences in the prevalence of infection in this blood fraction might account for the differences in clinical disease among these species. Viremia was confirmed by virus isolation in all inoculated animals. Analysis of leukocytes with monoclonal antibodies specific for BTV proteins revealed low numbers of infected leukocytes in only 2 sheep 8 days after inoculation with BTV serotype 10. Most of the cells expressing BTV were identified morphologically as monocytes; approximately 10% of infected cells were lymphocytes. Bluetongue virus was not detected by use of dot-blot hybridization on samples of blood. Our results suggest that differential infection of leukocytes does not account for the pronounced differences in clinical signs and pathologic changes among ruminants.

Neutralization determinants of United States bluetongue virus serotype ten

A panel of five neutralization-resistant escape mutant (EM) viruses was used to investigate the neutralization determinants of the U.S. prototype strain of bluetongue virus serotype 10 (BTV-10). The phenotypic properties of each EM virus were characterized by neutralization and immuneprecipitation assays with a panel of four monoclonal antibodies (MAbs). These MAbs were used to select the various EM viruses and together the MAbs define four distinct neutralizing epitopes on the prototype strain of BTV-10 (Heidner, H.W., Rositto, P.V., and MacLachlan, N.J., Virology 176, 658-661 (1990)). Sequencing of the L2 gene identified mutations responsible for the altered phenotypic properties exhibited by each EM virus. The L2 gene encodes BTV outer capsid protein VP2 which is responsible for virus neutralization. Four amino acids in three distinct regions of VP2 are critical to expression of the epitopes recognized by the MAb panel. Both amino acid 208 and 211 can affect the binding of MAb 039 and MAb 045, amino acid 327 affects binding of MAb 041, and amino acids 327 and 402 cooperatively interact to affect binding by MAb 034. The location of two of these critical regions on VP2 of BTV-10 is identical to two of those which affect neutralization of Australian BTV-1, despite the fact that these two viruses are antigenically distinct and have divergent L2 gene sequences (Gould, A.R., and Eaton, B.T., Virus Res. 17, 161-172 (1990)). The four individual neutralizing epitopes on VP2 of BTV-10 are interactive (Heidner, H.W., Rositto, P.V., and MacLachlan, N.J., Virology 176, 658-661 (1990)) and at least two are conformationally dependent.

Clinical pathology of Australian bluetongue virus serotype 16 infection in merino sheep

Viraemic blood from an ox naturally infected with Australian bluetongue (BLU) virus serotype 16 was passaged twice in sheep. Twelve 2- to 4-years-old Merino ewes, negative in a bluetongue agar gel immunodiffusion test, were inoculated with viraemic blood from the second sheep passage. They were examined for 18 days and compared with a control group. Significant changes in haematological measurements, namely packed cell volume, total white cell count and lymphocyte count, and in plasma enzyme concentrations, namely aspartate transaminase and creatine kinase, occurred in the infected sheep. All infected sheep became sick. The antibody response, and clinical and necropsy findings were consistent with other reports of mild to moderate disease with Australian BLU serotypes.

Detection of bluetongue virus RNA in cell cultures and in the central nervous system of experimentally infected mice using in situ hybridization

Two radiolabelled complementary DNA (cDNA) probes (1663 bp and 200 bp respectively) were prepared from the genome segment that encodes the non-structural protein 1 (NS1) of bluetongue virus serotype 4 (BTV4). The probes were used to optimize the in situ hybridization (ISH) method on baby hamster kidney-21 (BHK-21) cells and to investigate the use of the technique as a diagnostic procedure. Cells were infected with BTV4 at a multiplicity of infection of 0.5 PFU/cell. An intense cytoplasmic hybridization signal could be detected from 3 hours post-infection onwards, reaching a peak at 17 hours. The ISH procedure has potential use as a diagnostic technique, but will probably find a wider application in pathogenesis studies. An in situ hybridization method was also developed for the detection of BTV RNA in the central nervous system of newborn mice after intracranial inoculation with BTV10. Viral RNA-positive cells were detected from Day 3 onwards, predominantly in areas where the virus caused necrotic encephalitis.

Comparison of slot blot nucleic acid hybridization, immunofluorescence, and virus isolation techniques to detect bluetongue virus in blood mononuclear cells from cattle with experimentally induced infection

A slot blot hybridization technique was applied for detection of bluetongue virus (BTV) in blood mononuclear cells (BMNC) obtained from cattle with experimentally induced infection. This technique lacked sensitivity to detect the viral nucleic acid directly in clinical specimens. When aliquots of mononuclear cells from these cattle were cultivated in vitro for 10 days to amplify virus titer, only 33.3% of the samples collected during viremia gave a positive signal in the slot blot hybridization format. By contrast, results for 34.3% of noncultured and 63.3% of cultured mononuclear cell samples collected during viremia were positive by immunofluorescence. The average number of infected cells, as detected by immunofluorescence in the noncultured mononuclear cell samples, was 1 to 5/300,000, and was usually > 10/300,000 in the cultured cell samples. Virus was isolated from all postinoculation blood samples obtained from 4 heifers that were seronegative at the time of inoculation, but was not isolated from any of the preinoculation samples, or from any of the postinoculation samples obtained from 2 heifers that were seropositive at the time of inoculation. When virus isolation was attempted from separated mononuclear cells in 2 heifers, 43.7% of the noncultured and 87.5% of the cultured samples had positive results.

Experimental bluetongue and epizootic hemorrhagic disease virus infection in California black-tailed deer

Four adult black-tailed deer (Odocoileus hemioneus columbianus) and five fawns were inoculated with bluetongue virus (BTV) and one adult deer was inoculated with epizootic hemorrhagic disease (EHD) virus to produce clinical signs and lesions of hemorrhagic disease. Serologic response was monitored using the agar gel immunodiffusion (AGID) test and the competitive enzyme-linked immunosorbent assay (C-ELISA). Embryonating chicken eggs and vero cells were used to detect viremia. No animal exhibited clinical or pathologic signs of hemorrhagic disease. Bluetongue viremia was detected as early as 2 days post-inoculation (DPI-2) and in some animals, persisted until at least DPI-12. The earliest detection of BTV antibodies using the AGID was DPI-8. Two adult deer remained seropositive for BTV antibodies for > 9 mo and 1 yr, respectively, using both the AGID and C-ELISA tests. We observed cross reactions between BT and EHD antibodies using the AGID tests. Also, the AGID test did not consistently detect exposure to BTV. Viremia was not detected in the deer inoculated with EHD although this animal was AGID positive between DPI-6 and DPI-49.

Variation amongst the neutralizing epitopes of bluetongue viruses isolated in the United States in 1979-1981

Neutralizing epitopes present on field isolates of bluetongue virus (BTV) serotypes 10, 11, 13 and 17 were evaluated with a panel of polyclonal and neutralizing monoclonal antibodies (MAbs). A total of 91 field isolates were evaluated, including 15 isolates of BTV-10, 29 isolates of BTV-11, 26 isolates of BTV-13, and 21 isolates of BTV-17. The viruses were isolated from cattle, goats, sheep, elk and deer in Idaho, Louisiana, Nebraska and, predominantly, California, in the years 1979, 1980 and 1981. The isolates were analyzed and compared using a panel of neutralizing MAbs which included five MAbs raised against BTV-2, seven against BTV-10, five against BTV-13, and six against BTV-17. Neutralization patterns obtained with the MAb panel and individual field isolates were compared to those obtained with prototype viruses of each serotype. All field isolates were neutralized by at least some of the MAbs raised against the prototype virus of the same serotype. All field isolates of BTV-10 were neutralized by the seven MAbs raised to BTV-10, whereas the field isolates of BTV-11, BTV-13 and BTV-17 were not consistently neutralized by all of the MAbs raised against the prototype virus of the same serotype. Variation in neutralizing epitopes recognized by the MAb panel was most pronounced amongst the field isolates of BTV-17. A one-way cross neutralization was evident between BTV-10 and BTV-17 as all field isolates of BTV-17 were neutralized by four of the MAbs raised against BTV-10. In contrast, no BTV-10 isolates were neutralized by the MAbs raised against BTV-17. Differences in the MAb neutralization patterns of field isolates of BTV-11, BTV-13 and BTV-17 suggest that the immunogenic domain responsible for their neutralization is plastic, such that individual epitopes within the domain may vary in their significance to the neutralization of different viruses, even of the same serotype. The apparent conservation of neutralizing epitopes on field isolates of BTV-10 suggests that the field isolates may be derived from the modified-live vaccine strain of BTV-10.

A new bluetongue virus serotype isolated in Kenya

An apparently new strain of bluetongue virus was first isolated in Kenya in 1965 and since, has been obtained on 7 further occasions from diseased sheep during clinical outbreaks of disease. It proved to be serologically different from the 16 bluetongue virus strains then held at this laboratory. The virus was modified by passage in embryonated hens eggs to produce a live virus strain suitable for inclusion in a polyvalent vaccine. Recent neutralisation tests, carried out with 24 guinea pig immune sera prepared at Pirbright against the currently known World serotypes, have confirmed the earlier results and show that it is different from any of the existing serotypes.

Infection of bovine fetuses at 120 days' gestation with virulent and avirulent strains of bluetongue virus serotype 11

Bluetongue virus infection in sheep and cattle during fetal development causes neuropathology. Two strains of bluetongue virus serotype 11 designated as UC-2 and UC-8 have different virulence patterns in newborn mice. These viruses have distinctly different electropherotype patterns on polyacrylamide gel electrophoresis indicating a genetic difference in these two viruses of the same serotype. Four bovine fetuses each were inoculated intramuscularly with either UC-2 or UC-8, and one fetus was inoculated with placebo. The inoculation was made intramuscularly through the uterine wall at 120 days' gestation, and the bovine fetuses were recovered by cesarean section 12 or 20 days after inoculation. Fetal blood was collected for virus isolation and serology. Virus was reisolated from brain, blood, lung and liver. Both strains, UC-2 and UC-8, cause severe lesions in the 120 day fetuses. The encephalomalacic lesions occurred earlier and were more severe in fetuses inoculated with UC-8 as compared to those inoculated with UC-2. The subtle differences observed in the fetuses inoculated with the two different strains suggest that there is a difference in pathogenic potential of the two viruses. These differences do not appear to be completely dependent upon the host species.

Isolation and identification of a variant of bluetongue virus serotype 11 from a ram in a bluetongue outbreak in western Texas

A field strain of bluetongue virus was isolated from a blood sample of a ram during an outbreak of bluetongue in November 1985 in western Texas. In this bluetongue outbreak at least 25 of the 2,000 sheep were infected. Isolation was made by intravenous inoculation of 11-day-old embryonated chicken eggs. The serotype was identified as serotype 11 by serum neutralization tests. The genomic pattern on sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis (PAGE) of the new isolate is similar to that of bluetongue virus prototype 11. Comparisons were also made with proteins labeled in vivo with [3H]leucine and separated by SDS-PAGE. We conclude that this virus belongs to serotype 11, with slight differences in both genome and protein electrophoretic patterns.

Isolation and identification of arboviruses from the Sultanate of Oman

Sentinel herds and a vector surveillance system were used to identify the presence of arboviruses in Oman. Two strains of bluetongue virus (BTV) serotype 4 and two strains of Akabane virus, were isolated and identified. Both BTV isolates and one Akabane virus isolate came from goats while the second Akabane isolate came from Culicoides imicola. This is the first isolation of an Akabane virus from Culicoides in Arabia. Vector competence studies with the Oman viruses in laboratory reared C. variipennis showed that after oral infection both viruses replicated in Culicoides and were maintained at high titre for at least 10 days post infection.

Failure to establish congenital bluetongue virus infection by infecting cows in early pregnancy

Two groups of 10 pregnant cows were inoculated with bluetongue virus type 11 at either 40 or 60 days of gestation. All the cows became infected as judged by the detection of viraemia and seroconversion but they showed no clinical signs. Seventeen of the cows produced live calves none of which showed any evidence of prenatal infection. After challenge with the same virus all the calves became viraemic and seroconverted. The response to challenge of the two groups did not differ from that of a control group challenged at the same time. It was concluded that the infection of pregnant cows in early gestation with this virus did not result in the transplacental infection of the fetuses and did not produce immunotolerant, latently infected calves.

Temporal relationships of viremia, interferon activity, and antibody responses of sheep infected with several bluetongue virus strains

Sheep had viremias that were first detected on day 3 (+/- 1) after infection with several strains of bluetongue virus (BTV) representing United States serotypes 10, 11, 13, and 17. Diphasic peaks of infectivity were attained on days 6 and 10 (+/- 2). Interferon (IFN) was first detected in serum samples on day 5 (+/- 1), and reached greatest concentrations on day 6 (+/- 2), which coincided with the first viremic peak; IFN concentrations then decreased toward zero by day 10 (+/- 2). Interferon peak concentrations induced approximately a 90% decrease in virus titer. The decrease in IFN concentrations by day 9 (+/- 2) corresponded with the second viremic peak on day 10 (+/- 2). Onset of the decrease in detectable concentrations of virus after the second peak of viremia corresponded to the initial detection of serum antibody to BTV by day 10 (+/- 2). Virus titer decreased and antibody production increased until approximately days 21 to 28, when the titers plateaued and virus was not detected. Febrile responses peaked on day 7 (+/- 1) during the peak viremic period. The WBC count was depressed at the time the virus titer increased, but returned to normal values while the sheep were still viremic. Diphasic viremias in BTV-infected sheep were attributed to induction of high concentrations of IFN concurrent with the first virus titer peak, followed by production of antibody to specific BTV strains and a subsequent reduction in viremia at the second virus titer peak.

The amino acid sequence of the outer coat protein VP2 of neutralizing monoclonal antibody-resistant, virulent and attenuated bluetongue viruses

Monoclonal antibodies which reacted with four different epitopes were used to select neutralization-resistant variants of Australian bluetongue virus serotype 1 (BTV1AUS; isolate CS156). Nucleotide sequencing of the VP2 outer coat protein gene of these variants showed that two of them contained alterations within the previously defined neutralization site at amino acids 328 to 335 (Gould et al., 1988). Comparison of VP2 sequences of several BTV serotypes, in addition to nucleotide sequence changes in a number of variants, suggested that this neutralization site was larger and contained 19 amino acids, the conformation of which could be affected by other regions of the VP2 protein. Nucleotide sequencing of neutralization-resistant variants revealed a total of four other regions of VP2 affecting the ability of monoclonal antibodies to neutralize the virus and these results support the notion that the neutralization site in VP2 was conformation dependent. The complete nucleotide sequence of the VP2 gene of virulent BTV1AUS (C5156) was determined directly from viral nucleic acid isolated from the blood of a sheep suffering clinical bluetongue disease. Comparison of the VP2 sequence of this virulent virus with that previously published for an avirulent, laboratory strain (Gould, 1988), indicated that the passage of virulent virus approximately 20 times in tissue culture over the last decade, not only led to attenuation but resulted in the appearance of ten nucleotide changes in the VP2 gene. Six of these nucleotide changes were silent, two resulted in conservative amino acid substitutions and two generated radical amino acid changes. However, in a separate experiment, a single passage of the virulent virus in tissue culture while leading to attenuation did not result in a nucleotide change in the VP2 outer coat protein gene.

Limitations of in situ hybridization for the detection of bluetongue virus in blood mononuclear cells

In situ nucleic acid hybridization was tested for the ability to detect bluetongue virus (BTV) nucleic acids in blood mononuclear cells. A standard protocol was devised and applied to the demonstration of BTV genetic sequences in cultured bovine mononuclear cells that had been infected in vitro. In situ hybridization using biotinylated single-stranded RNA probes, in the presence of 50% formamide at 50 C, demonstrated an intense, positive signal in 0.001-0.01% of the BTV-infected cultured mononuclear cells. The protocol was applied to isolated mononuclear cells from an experimentally infected heifer. No infected cells were observed by this method, although the blood specimens were obtained during peak viremia.

The pathogenesis of experimental bluetongue virus infection of calves

Eleven seronegative calves were intravenously inoculated with bluetongue virus (BTV) serotype 10, and two calves were inoculated with a placebo. Cellular association of BTV during viremia was investigated in three of the calves by titrating virus present in plasma and different blood cell fractions at weekly intervals after infection. Viremia persisted 35 to 49 days in individual calves. Virus was transiently isolated from blood mononuclear cells and plasma collected from two of the calves but was consistently isolated from erythrocytes throughout infection of all three animals. Titers of BTV present in the erythrocyte fraction were comparable to those of the unseparated blood cell fraction. Tissue tropism of BTV was determined by viral isolation from tissues collected from calves euthanatized at 1, 2, 3, 4, 5, 7, 14, 28, 42, and 56 (2 calves) days after inoculation with BTV. Tropism was also determined by immunohistochemical staining of selected tissues with an avidin-biotin complex immunoperoxidase staining procedure using three BTV-specific monoclonal antibodies. The BTV infected calves remained healthy throughout the study. Virus was isolated from at least one tissue collected from calves euthanatized at 1 through 28 days after inoculation, but not thereafter. High titers of BTV were present in the lungs, prescapular and mesenteric lymph nodes, thymus, and spleen of calves euthanatized at 1 to 4 days after inoculation, whereas BTV was either not isolated or isolated in low titer from bone marrow collected from these animals.(ABSTRACT TRUNCATED AT 250 WORDS)

Molecular cloning of serogroup- and serotype-specific genome segments from bluetongue virus serotype 11

Genome segments 2, 6, 8, and 9 of bluetongue virus (BTV) serotype 11, coding for P2, NS1, NS2, and P6, respectively, were cloned into pUC 8. Sizes of segment-2 and segment-6 clones indicated partial copies (55% and 80% of full length, respectively), whereas segment 8 and 9 clones represented full-length copies. Northern blot hybridizations of the clones to the 5 United States BTV prototypic serotypes (2, 10, 11, 13, and 17) revealed segment-2 clone to be serotype-specific to BTV-11, whereas segment 6, 8, and 9 clones were able to detect all serotypes to varying degrees. All clones failed to detect the related orbivirus, epizootic hemorrhagic disease virus.

Investigations of bluetongue and other arboviruses in the blood and semen of naturally infected bulls

Small groups of bulls were exposed to natural infection with arboviruses. The bulls were bled and ejaculated regularly and the blood and semen were processed for virus isolation. Over a 5-year observation period, virus isolation and serology indicated that the 29 exposed bulls had experienced 79 viraemic episodes with the viruses of the bluetongue, epizootic haemorrhagic disease, Palyam and Simbu serogroups and an incompletely characterised rhabdovirus. In no instance was there unequivocal evidence of bluetongue virus contamination of semen, despite 18 infections in the study period.

Bluetongue virus infection of bovine monocytes

Cultures of adherent and non-adherent bovine blood mononuclear cells were infected with bluetongue virus (BTV) serotype 10. Production of BTV proteins in mononuclear cell cultures was detected by immune precipitation of viral proteins from [35S]methionine-labelled extracts of these cells, by immunofluorescence staining of cells using monoclonal antibodies (MAbs) to BTV proteins VP7 and NS2, and by flow cytometry with MAbs to VP2, VP7, NS1 and NS2. BTV-infected cells were most numerous in cultures of adherent mononuclear cells; infected cells were initially identified as monocytes on the basis of their morphology, and size and scatter characteristics as determined by analysis with a fluorescence-activated cell sorter (FACS). The majority of adherent mononuclear cells with these scatter characteristics were confirmed to be monocytes by FACS analysis with a MAb specific for bovine monocytes. Identification of BTV-infected adherent mononuclear cells as monocytes was further established by double immunofluorescent labelling, as infected adherent cells reacted with the MAb specific for bovine monocytes, and with another MAb specific for class II antigen. Infection of adherent mononuclear cells was also confirmed by transmission electron microscopy, as BTV virions and tubules were present in lysates of cultures of BTV-infected adherent mononuclear cells and within the cytoplasm of adherent cells. In contrast, BTV proteins were detected in few cells identified as lymphocytes on the basis of their scatter characteristics, and mean fluorescence of such cells was considerably less than that of BTV-infected monocytes. Viraemia persisted until 35 days after inoculation of a colostrum-deprived calf inoculated with BTV. Virus was isolated from blood mononuclear cells at 1 week after infection of the calf, but not thereafter. BTV infection of blood mononuclear cells was demonstrated until 9 days after inoculation by indirect immunofluorescence staining of mononuclear cells. In contrast, virus was consistently isolated from erythrocyte-enriched preparations throughout viraemia in titres comparable to those in whole blood. These results indicate that although bovine monocytes are readily infected in vitro with this strain of BTV serotype 10, infection of blood monocytes is unlikely to be responsible for the prolonged viraemia that consistently occurs in BTV-infected cattle.

Genotypic transitions among bluetongue viral isolates from domestic ruminants in Colorado during 1981-1984

Two predominant electropherotypes of bluetongue virus (BTV) serotype 11 isolates from cattle during a 1981-1984 field study in eastern Colorado were characterized. The genomes of strains isolated from the first 2 years of the study had 1 predominant electropherotype (CO81), with the exception of 1 isolate that differed only in the migration of segment 3. A second electropherotype (CO83), with differences in the migration of 4 segments, coexisted in the same region during 1983 and 1984 with strains having the CO81 RNA profile. The genomes of CO81 and CO83 were also distinguishable from those of the US prototype of BTV 11. Analysis of the polypeptides of representative strains of each electropherotype by sodium dodecyl sulfate-polyacrylamide gel electrophoresis indicated that the proteins were very similar. The occurrence of the CO81 electropherotype was apparently the result of multiple viral infections since the positions of 7 segments had faint second bands and single-banded variants were isolated after serial plaque purifications. In addition, protein 7 of 1 of the CO81 isolates and protein 7 of the single-banded variant differed as shown by reverse phase-high performance liquid chromatography of 35S-methionine-labeled tryptic peptides.

Comparison of virologic and serologic responses of lambs and calves infected with bluetongue virus serotype 10

Four lambs and 3 calves, seronegative to bluetongue virus (BTV), were inoculated intravenously with a highly plaque-purified strain of BTV Serotype 10. A single calf and lamb served as controls and were inoculated with uninfected cell culture lysate. All BTV-inoculated lambs exhibited mild clinical manifestations of bluetongue, whereas infected calves were asymptomatic. Viremia persisted in BTV-infected lambs for 35-42 days, and for 42-56 days in BTV-infected calves. Neutralizing antibodies were first detected in sera collected at Day 14 post-inoculation (PI) from 2 BTV-infected calves and all 4 infected lambs, and at Day 28 PI in the remaining calf. The appearance of neutralizing antibody in serum did not coincide with clearance of virus from blood; BTV and specific neutralizing antibody coexisted in peripheral blood of infected lambs and calves for as long as 28 days. The sequential development, specificity and intensity of virus protein-specific humoral immune responses of lambs and calves were evaluated by immunoprecipitation of [35S]-labelled proteins in BTV-infected cell lysates by sera collected from inoculated animals at bi-weekly intervals PI. Sera from infected lambs and calves reacted most consistently with BTV structural proteins VP2 and VP7, and nonstructural protein NS2, and less consistently with structural protein VP5, and nonstructural protein NS1. Lambs developed humoral immune responses to individual BTV proteins more rapidly than calves, and one calf had especially weak virus protein-specific humoral immune responses; viremia persisted longer in this calf than any other animal in the study. The clearance of virus from the peripheral blood of BTV-infected lambs and calves is not caused simply by the production of virus-specific neutralizing antibody, however the intensity of humoral immune responses to individual BTV proteins might influence the duration of viremia in different animals.

Bluetongue virus genome remains stable throughout prolonged infection of cattle

Infection of three calves with a highly plaque-purified strain of bluetongue virus (BTV) resulted in prolonged infections, during which virus and neutralizing antibodies co-circulated in peripheral blood. Oligonucleotide fingerprint analyses of the original challenge virus and of the final virus isolate obtained from each calf demonstrated the BTV genome to remain stable throughout prolonged infection as no differences in fingerprint patterns were detected. Six neutralizing monoclonal antibodies (MAbs), and a polyclonal rabbit antiserum, were produced against the challenge virus. This panel of MAbs recognized at least two distinct neutralizing epitopes as demonstrated by immune precipitation. Neutralizing epitopes remained stable through the prolonged infections, as all MAbs and the polyclonal rabbit antiserum neutralized the challenge virus and the final calf isolates to equivalent titres. These results suggest that antigenic drift is not the mechanism by which BTV is able to persist in cattle in spite of a strong humoral immune response.

Genetic reassortment of bluetongue virus serotype 11 strains in the bovine

Reassortants of bluetongue virus Serotype 11 (BTV-11) were isolated from a yearling heifer experimentally infected with two electrophoretically different strains (UC-2 and UC-8) by subcutaneous inoculation. Viruses were recovered by direct titration of sonicated blood samples onto Vero cell monolayers, which were overlaid with agarose and later plaque purified. The parental electropherotype of UC-8 was identified as the predominant virus strain during the infection; UC-2 was not isolated. UC-2 infectivity was shown by reassortants which contained genome segments that were identical in migration pattern to the parental UC-2 electropherotype. The observations demonstrate that segmental reassortment can occur during mixed infections in the bovine, between strains of the same BTV serotype.

Neurovirulence of the UC-2 and UC-8 strains of bluetongue virus serotype 11 in newborn mice

In vivo and in vitro experiments were done to investigate whether the difference in neurovirulence between the two strains of bluetongue virus 11, UC-2 and UC-8, is based on a different capability to gain access to the brain from the subcutaneous inoculation site or on a different tropism for neural cells. In newborn Balb/c mice subcutaneous inoculation of UC-8 at doses between 10(-0.2) plaque forming units (PFU) and 10(4.8) PFU caused a severe necrotizing encephalitis whereas UC-2 at doses of up to 10(4.4) PFU did not affect newborn Balb/c mice. However, intracranial inoculation of 10(2.4) PFU of either virus strain produced severe necrotizing encephalitis. In vitro both virus strains infected dissociated brain cell cultures similarly. Double labelling immunofluorescent staining with markers specific for neural cells did not reveal differences in the target cells for the two viruses. The difference in neurovirulence between UC-2 and UC-8, therefore, appears to be determined by the ability of UC-8 to infect the brain from a subcutaneous inoculation site.

Analysis of mixed infection of sheep with bluetongue virus serotypes 10 and 17: evidence for genetic reassortment in the vertebrate host

Two seronegative sheep were infected intravenously with 10(9) PFU each of bluetongue virus (BTV) serotype 10 and BTV serotype 17. One animal experienced a mild bluetongue-like disease, and both experienced a short-duration viremia and developed neutralizing immune responses to both virus serotypes. Progeny virus was isolated from venous blood from each animal by using conditions in which reassortment could not have occurred during isolation. Electropherotypes were determined for the progeny viruses from the infected sheep, yielding strikingly similar results for the two animals. In both sheep, serotype 10 dominated among the progeny, accounting for 92% of the progeny. Serotype 17 was rarely isolated and accounted for 3% of the progeny analyzed. The remaining 5% of the progeny clones were reassortant and derived genome segments from both serotypes 10 and 17. Analysis of the parental origin of genome segments in the small number of reassortant progeny analyzed suggested that selection of specific genome segments may have occurred in the infected sheep. These data indicate that reassortment of genome segments occurs, at low frequency, in sheep mixedly infected with BTV.

Experimental infection of bulls and cows with bluetongue virus serotype 20

Bluetongue virus serotype 20 (BTV20) was inoculated intradermally and subcutaneously in 4 bulls and by the intrauterine route in 8 nulliparous cows after insemination at oestrus. Viraemia was detected intermittently between 8 and 21 days after inoculation. Virus was isolated from tissue samples of 2 cows and a bull after slaughter at 14 days and from one bull at 28 days. Group reactive and type specific antibodies to BTV20 were demonstrated from 17 to 27 days after infection. No antibodies were detected in the animals slaughtered at 14 days. No clinical signs of disease were seen during the experiment and no gross or histopathological changes referable to BTV20 infection were observed post-mortem. Because of the viraemia and the production of detectable serum antibodies, gametes from these cattle would be excluded from export.

Virulence of bluetongue virus for British sheep

A South African isolate of bluetongue virus type 3 was inoculated intradermally into three different breeds of British sheep under conditions designed to test its virulence in animals under stress. All animals inoculated developed a pyrexia and viraemia followed by clinical evidence of bluetongue disease. Marked alterations in serum enzyme levels, in particular of creatine phosphokinase, lactate dehydrogenase and aldolase occurred in the more severely affected animals. Nine out of the 12 inoculated animals subsequently died. No major differences in response could be detected in the different breeds of sheep nor in the stressed compared with the unstressed groups. The virulence of this bluetongue virus isolate was thereby confirmed and its potential risk to the British sheep industry. Consequently, stringent import regulations must be maintained to prevent its entry into Britain.

Bluetongue virus serotype 20: experimental infection of pregnant heifers

Three groups of 4 cows at 84 to 95 days, 100 to 160 days, and 170 to 180 days pregnant were inoculated both intradermally and subcutaneously with bluetongue virus serotype 20 (BTV20). Clinical observations and the viraemic and serological responses of the cows were followed for 9 to 17 weeks after inoculation. Viraemia developed in 9 of the 12 cows and was first detected 4 to 9 days after inoculation. Viraemia was detected for 4 to 21 days and in some animals only intermittently. The titre of the viraemia was obtained in 4 cows and ranged from detectable only, to 10(1) to 10(2.8) 50% tissue culture infecting doses per ml. Both serum neutralising and precipitating antibodies were detected in 11 of the 12 cows within 2 to 8 weeks after inoculation. No clinical responses were seen and one cow (516) did not develop a viraemia or produce detectable antibodies to the virus. The cows, calves and foetuses were necropsied following either parturition or slaughter between 200 and 270 days of pregnancy. No virus isolations were made from a wide range of tissues from the cows, calves or foetuses and no immunoglobulins or serum neutralising antibodies were detected in the serums of precolostral calves or foetuses at necropsy. No gross or histopathological lesions were seen in the cows, calves or foetuses, and there was no evidence that BTV20 crossed the bovine placenta or infected the foetus.

Strain-dependent virulence characteristics of bluetongue virus serotype 11

Two strains of bluetongue virus (BTV) serotype 11, UC-2 and UC-8, were identified by the electrophoretic migration pattern of their genomic RNA segments on polyacrylamide gel electrophoresis. Significant differences in virulence of these two viruses could be demonstrated by subcutaneous inoculation of newborn mice. No signs of disease were observed in mice infected with UC-2. Mice infected with UC-8 died of a severe necrotizing encephalitis, which resembled lesions in bovine and ovine foetuses infected with BTV.

Immune response of sheep to bluetongue virus: in vitro induced lymphocyte blastogenesis

Sheep were inoculated with 2 ml of 10(7) plaque forming units per ml of purified prototypes of the four United States serotypes (10, 11, 13 and 17) of bluetongue virus. Nine weeks following the initial inoculation, a challenge inoculation with homologous virus was done. Animals were followed for virus isolation and evidence of cell-mediated immunity by weekly lymphocyte stimulation tests (LST). Two dilutions (10 micrograms/ml and 1 microgram/ml) of pure virus from each of the purified serotypes were used as antigen as were the phytomitogens phytohemagglutinin, Concanavalin A, and pokeweed mitogen. LST data were analyzed by the analysis of variance method and reported as counts per minute and stimulation index (SI). Significant SI were observed following primary and secondary challenge with both homologous and heterologous virus. There was evidence of lymphocyte perturbations characterized by a sharp decrease in response to mitogens following primary and secondary challenge lasting for one week followed by a significant increase in blastogenesis three to four weeks after inoculation of virus. These results provide evidence that cell-mediated immunity is evident in bluetongue infection, that there is cross reactivity between viral serotypes and that BTV infection leads to perturbations in lymphocyte function including suppression of responses. An increase in the blastogenic response to phytomitogens correlated with viral clearance.

The coexistence of multiple bluetongue virus electropherotypes in individual cattle during natural infection

Evidence of multiple genotypes of bluetongue virus (BTV) serotype 11 simultaneously infecting individual cattle was demonstrated in a California sentinel herd naturally infected with two BTV serotypes (11 and 17). Monitoring of weekly virus isolates by PAGE demonstrated genome segment diversity among BTV serotype 11 isolates and an individual bull simultaneously infected with multiple electropherotypes of this serotype. No electrophoretic variations were apparent in BTV serotype 17 isolates. The results of this study indicate that multiple plaque clonings and comparative electrophoresis are required to analyse BTV field isolates accurately for the presence of mixed infections.

A genetic probe for identifying bluetongue virus infections in vivo and in vitro

We have used a DNA copy of segment 3 RNA of bluetongue virus serotype 17 (BTV-17) to detect sequence homology among the equivalent segments of five U.S.A. BTV serotypes (BTV-2, BTV-10, BTV-11, BTV-13 and BTV-17) as well as 14 other BTVs isolated from different endemic areas of the world. Both by in situ and Northern hybridization all the BTV serotypes were found to have RNA that reacted with the DNA probe. No homology was detected with epizootic haemorrhagic disease virus serotype 1, a related orbivirus. The BTV-17 DNA clone has also been used to detect viral RNA in infected sheep blood. This information has led us to develop a simple and sensitive procedure for the detection of viral genome-biotinylated clone DNA hybrids in vivo or in cultured cells following direct staining with either the avidin-fluorescein complex or the streptavidin-horseradish peroxidase complex.