Antibodies against certain bluetongue and epizootic haemorrhagic disease viral serotypes in Indonesian ruminants.

The orbiviruses contain several important viruses of livestock including bluetongue (BT) and epizootic haemorrhagic disease of deer (EHD) which share some group antigens. Preliminary screening of sera for antibodies to orbiviruses by the agar gel immunodiffusion (AGID) test has previously revealed widespread infections with the BT group in Indonesia. However serum neutralization (SN) tests give a more accurate estimate of exposure to each serotype in the BT and EHD groups, and in this study were applied to sera that had reacted previously in the AGID test. Five different serotypes of BT and one serotype of EHD virus were studied. Reactors to BT serotype 20 were the most prevalent, followed by EHD type 5 and BT types 21, 12, 1 and 17. Antibodies against BT serotype 20 were present in cattle, buffaloes, goats and sheep, but were most common in buffaloes. Buffaloes showed the highest exposure to the BT serotypes tested. Antibody to EHD type 5 occurred most frequently in cattle. Antibodies against all BT and EHD serotypes tested were found in buffaloes and cattle while goats had antibodies against BT types 20, 21 and EHD type 5 and sheep had antibodies only against BT type 20.     

Studies on Bovine Virus Diarrhea: Serum Neutralization, Complement-fixation and Immunofluorescence

The complement-fixation, the serum neutralization tests and the fluorescent-antibody technique were the serological methods applied in this laboratory for the detection of antigens for bovine virus diarrhea (BVD). As observed previously, the modified direct complement-fixation (MDCF) test was required to demonstrate antibodies against virus infections of cattle.

At a certain stage of infection, the MDCF test was found to be as accurate and less time-consuming than the serum neutralization test for the detection of antibodies in bovine sera. The modified direct complement-fixing antibodies were detectable in the serum from approximately three weeks up to a few months after infection as compared to several years for the serum neutralization test. Thus, as in most other viral diseases, the MDCF test was of value for detecting recent infections while the serum neutralization test detects both recent and long-standing infections.

The fluorescent antibody technique was of value to detect viral antigens of both cytopathogenic and noncytopathogenic strains of BVD in primary fetal kidney cell cultures inoculated with field specimens. In addition, the virus was detected in six of 220 fetuses collected at a local slaughter house for the preparation of primary cell cultures. The length of time required for the detection and identification of specific viral antigens by immunofluorescence was considerably reduced over that of the serum neutralization and virus interference tests.

     

Bluetongue and related viruses in Nigeria: Experimental infection of West African dwarf sheep with Nigeria strains of the viruses of epizootic haemorrhagic disease of deer and bluetongue

West African dwarf sheep were inoculated by the subcutaneous route with epizootic haemorrhagic disease of deer (EHD) virus or bluetongue (BT) virus. No clinical disease was observed following primary EHD or BT infection, or subsequent challenge with either homologous or heterologous virus. However, viraemia was detected in non-immune sheep exposed to BT virus, but not in BT- or EHD-immune sheep challenged with either virus, or in non-immune sheep exposed to primary EHD virus infection. Complement fixing antibodies developed against both EHD and BT viruses following the primary infection with either virus, or subsequent challenge with homologous or heterologous virus. Following a primary infection, virus-neutralising (VN) antibodies developed only against the inoculated virus, while the detection of VN antibodied to both viruses followed the challenge of an EHD- or BT-immuned sheep with either the homologous or heterologous virus. These findings further support previous reports of a relationship between EHD and BT viruses. between EHD and BT viruses.     

Bluetongue and epizootic hemorrhagic disease in ruminants in Georgia: survey by serotest and virologic isolation

The frequencies of precipitating antibodies to bluetongue virus (BTV) and epizootic hemorrhagic disease virus (EHDV) in domestic ruminants and white-tailed deer (WTD) in Georgia were 36% and 32%, respectively (n = 2,200). The frequencies of seropositivity to BTV and EHDV were high among cattle (47% and 42%, respectively [n = 1,068]) and less so in WTD (36% and 34% [n = 414]). The frequencies among sheep were 34% for BTV and 29% for EHDV (n = 286), whereas among goats, seropositivity was 8% for BTV and 7% for EHDV (n = 433). Serum samples from northeastern Georgia (1 of the 4 regions in the survey) had the highest frequency of precipitating antibodies for BTV (45%) and EHDV (38%). The lowest frequency was in southeastern Georgia, with 29% seropositivity for BTV and 24% seropositivity for EHDV. Of the 175 farms or herds in the serosurvey, 70% included animals that had BTV-precipitating antibodies, and 67% included animals which had EHDV-precipitating antibodies. Seventeen viral isolates were obtained from individual animals on 9 different farms. Fifteen of the isolates were BTV--8 from cattle, 4 from sheep, and 3 from WTD; 8 of them were serotype 11, and 7 were serotype 17. Viral isolates from each of 2 WTD were identified as EHDV serotype 1 and serotype 2. Of the total 17 isolates, 11 were from clinically healthy ruminants, and 6 were from animals with clinical signs of BT or EHD. Five of the viral isolates originated from northeastern Georgia, 7 from the northwestern region, and 5 from the southwestern region; none was obtained from specimens from the southeastern region.     

Viral and viral protein specificity of antibodies induced in cows persistently infected with noncytopathic bovine viral diarrhea virus after vaccination with cytopathic bovine viral diarrhea virus

Neutralizing and nonneutralizing antibodies to bovine viral diarrhea (BVD) virus were detected in 3 cows persistently infected with noncytopathic BVD virus after vaccination with modified-live cytopathic BVD virus. Neutralizing antibodies detected in serum samples from each persistently infected cow at 3 weeks after vaccination were highly specific for certain isolates of cytopathic BVD virus and reacted only with a viral protein with a molecular weight of 53,000. Neutralizing antibodies to 1 of 3 isolates of noncytopathic BVD virus were detected in a serum sample obtained at 12 weeks after vaccination from 1 of 3 persistently infected cows. Nonneutralizing antibodies were detected in all cows at 7 to 12 weeks after vaccination. The nonneutralizing antibodies were less specific for isolates of BVD virus and reacted with viral proteins with molecular weights of 115,000, 80,000, 53,000, and 47,000.     

Growth of bluetongue and epizootic hemorrhagic disease of deer viruses in poikilothermic cell systems

Continuous cell lines from the ticks Dermacentor variabilis, D. parumapertus, D. nitens, Rhipicephalus sanguineus and R. appendiculatus, the mosquitoes Aedes albopictus and Culex quinquefasciatus and the African toad Xenopus laevis were tested for their ability to replicate bluetongue (BT) and epizootic hemorrhagic disease of deer (EHD) viruses, and for their sensitivity as potential isolation systems. BT serotype 17 grew to peak titers of 10(4.5)-10(7.5) TCID50 ml-1 in all except one of the tick cell lines, EHD 2 virus attained titers similar to that of BT 17 in the mosquito and toads cells, but failed to replicate in tick cells. Only Aedes albopictus and Xenopus laevis cells were as sensitive to infection with low-passage BT 11 and EHD 2 viruses as control cultures of Vero and BHK cells. At 27 degrees C, persistent infection of Xenopus laevis cells occurred, producing low yields of BT 17 and EHD 2. When shifted to 32 degrees C, these cultures expressed virus in exponential increments. No cytopathic effect (CPE) was seen in any of the tick-virus systems, but infected mosquito and toad cells detached from the monolayer within 3-6 days after inoculation with either virus. In the toad cells, this CPE was presaged by the development of plaques within 48 h after infection. Potential applications of poikilotherm systems in orbivirus research are discussed.     

Identification of hog cholera viral isolates by use of monoclonal antibodies to pestiviruses

A collection of 90 field isolates of hog cholera virus (HCV) was used to test the specificity of four hybridoma cell lines secreting monoclonal antibodies against pestiviruses. Reaction of virus isolates and monoclonal antibodies was controlled by an indirect immunofluorescence assay (IFA). Two monoclonal antibodies which had been generated against HC virus strain "Alfort 187" were reactive only with HCV field isolates and an HCV reference strain but not with bovine viral diarrhoea virus (BVDV) reference strains. Two other monoclonal antibodies (generated against BVDV, strain NADL) reacted only with BVDV reference strains but not with HCV field isolates, although with 3 of these strains focal reactions involving only a few cells were detected. The ability to discriminate between both viruses is a diagnostic need which may be fulfilled by these monoclonal antibodies.     

A monoclonal antibody blocking ELISA detects antibodies specific for epizootic haemorrhagic disease virus.

The isolation of a monoclonal antibody (1G9/C9) with specificity for the epizootic haemorrhagic disease (EHD) serogroup has enabled the development of a highly sensitive and specific blocking ELISA (B-ELISA) for the detection of serum antibodies to EHD viruses. The assay was sensitive to blocking antibodies present in hyperimmune reference antisera to all six EHD serotypes tested but was unaffected by reference antisera to 19 South African and eight Australian serotypes of the related orbivirus bluetongue virus (BTV). The sensitivity of the EHD B-ELISA exceeded that of an indirect ELISA (I-ELISA) for EHD-specific antibody detection. Serum antibody titres to BTV and EHD in experimental and field sera, including a sentinel herd from which virus isolations were made, were examined in both the BTV and EHD B-ELISA tests. These results showed the B-ELISA was only sensitive to antibodies specific for the homologous serogroup in each case, even where sequential and mixed infections with each virus type occurred.     

Bluetongue: Laboratory diagnosis

Definitive diagnosis of bluetongue virus (BTV) infection, often subclinical in domestic and wild ruminant relies heavily on laboratory techniques for BTV isolation and demonstration of BTV antigens, viral nucleic acids and antibodies. The virus can be isolated from blood components, mainly the erythrocyte fraction, collected from affected animals during the period of febrile response. Semen collected from male animals at the peak of viremia and tissues from affected animals and fetuses may also be used for BTV isolation. The primary procedure for BTV isolation is inoculation of embryonated chicken eggs with a subpassage onto cell cultures (e.g. BKH-21, Vero cell lines). In addition to the conventional techniques such as fluorescent antibody staining and virus neutralization procedures for sero-grouping and serotyping of BTV isolates, immunohistochemical, immunoenzymatic and immunoelectron microscopic techniques, using monoclonal antibodies (MAb), offer more rapid, specific and sensitive approaches for BTV identification and antigen detection. The progress of molecular biology, especially the development of genetic probes for hybridization analysis and polymerase chain reaction techniques for detection of BTV nucleic acids hold the promise of most efficient diagnostic assays. Among the various serogroup-specific assays for antibody detection, the agar gel immunodiffusion (AGID) and competitive (C) ELISA are the most widely used tests. Because of its limitations (i.e. anticomplementary serum and complexity of the procedure) the complement fixation (CF) test is virtually abandoned and is used in only a few laboratories. Although the AGID test is simple to perform and rapid, it is not highly sensitive or quantitative and has limitations in its specificity. Sera containing antibodies to other group of Orbiviruses (e.g. epizootic hemorrhagic disease) may result in non-specific reaction in the AGID test. Among several ELISAs that have recently been developed, the C.ELISA in which a group-specific MAb to BTV is used, has proved to be the most sensitive and specific assay for detection of antibodies to BTV. Following extensive national and international validation, the C.ELISA is gradually replacing the AGID as a universal test to certify ruminants for trade purposes and to diagnose BT infection in domestic and wild animals. The cell culture-based microtiter serum neutralization (MTSN) is the most commonly used assay for the detection of serotype-specific antibodies to the recognized BTVs in animal sera. The MTSN may be used to type virus isolates and also to monitor animal population for specific serotypes of BTV in epidemiological investigations.     

Serosurvey for selected viral agents in white rhinoceros (Ceratotherium simum) in Kruger National Park, 2007

One hundred serum samples collected from free-ranging white rhinoceros (Ceratotherium simum) in Kruger National Park (KNP) during the 2007 capture season were selected for measurement of antibody levels to several different vector-borne viral agents. These infectious diseases were chosen to compare with an earlier serosurvey that had been conducted in KNP in rhinos during 1987-1997. Positive antibody titers were found against epizootic hemorrhagic disease (EHD) of deer (8%), Bluetongue (BT) (1%), and Rift Valley fever (RVF) (49%). However, none of the 100 animals tested had detected antibody levels to African horse sickness (AHS). These values were in sharp contrast to those measured in the 1987-1997 survey in KNP white rhinos (AHS 60%, EHD 30%, BT 37%, RVF 0%). Vector-borne viral infection prevalence in white rhinos in the same geographical location appears to vary over time and may be important for monitoring presence of pathogens in an ecosystem.     

Range of viral neutralizing activity and molecular specificity of antibodies induced in cattle by inactivated bovine viral diarrhea virus vaccines

The range of neutralizing activity to bovine viral diarrhea (BVD) virus and viral protein specificity of antibodies induced by 3 inactivated vaccines were evaluated by use of samples of sera obtained from 13 cattle 14 days after vaccination. Viral neutralizing antibodies wee detected in all cattle to each of 10 noncytopathic and 10 cytopathic isolates of BVD virus. A viral-induced polypeptide (53,000 to 56,000 daltons) was detected by radioimmunoprecipitation with serum from all vaccinates. Other viral-induced polypeptides of 115,000, 80,000, 48,000, and 25,000 daltons were precipitated with sera from some vaccinates. Precipitation of those polypeptides was related to the vaccine used. When multiple viral polypeptides were precipitated, the 53,000- to 56,000-dalton polypeptide appeared immunodominant.     

Antigenic characterisation of virus isolates from vaccinated dogs dying of rabies

Four rabies virus isolates from dogs that succumbed to rabies infection in Nigeria within one year of anti-rabies vaccination were characterised by monoclonal antibodies (MAbs). The samples were screened for rabies and rabies-related viral antigens by the indirect fluorescent antibody test, performed with MAb 502-2, which recognises the nucleocapsid (NC) protein of all known Lyssaviruses and with MAb 422-5 which identifies African rabies-related viruses. All four canine virus isolates displayed positive fluorescence with MAb 502-2 and were negative with MAb 422-5. In the anti-NC MAb characterisation with a panel of 34 additional MAbs, all isolates displayed positive staining with 32 of the MAbs, were negative with MAb 102-27 and all displayed poor immunofluorescence with MAb 377-7. On the basis of reactivity with a panel of 40 anti-glycoprotein (G) MAbs the isolates were separated into four distinct viral subtypes. None of these canine isolates was identified as the common attenuated Flury LEP rabies strain used for domestic animal vaccination and none resembled other previously characterised rabies viruses from Nigeria.     

Bluetongue in cattle: effects of vector-transmitted bluetongue virus on calves previously infected in utero.

Three of 7 principal calves, after a challenge of immunity exposure by bites of bluetongue (BT) virus-infected Culicoides variipennis, became latently infected with BT virus. These calves were born to heifers infected with the homologous virus by bites of C variipennis at 60 or 120 days' gestation. Latent BT virus infection was detected by isolation of BT virus from washed erythrocyte samples obtained from the calves at 57, 100 to 102, 200 to 202, 300 to 302, and 400 to 402 days after challenge of immunity and from 1 of the calves over 5 years after challenge of immunity. The 3 latently infected calves were healthy; 2 were immunologically competent and 1 was immunologically incompetent to develop detectable BT virus antibodies in their blood. Bluetongue virus infection was detected (by viral isolation) in 2 other principal calves during the challenge of immunity, but they were not considered latently infected. The latter 2 calves were immunologically incompetent to develop detectable BT virus antibodies.     

Epizootiologic study of bluetongue: virologic and serologic results

Heparinized blood and serum samples were obtained from 1,295 ruminants in herds or flocks with bluetongue virus (BTV) infection in 4 western states. Submissions were from herds or flocks with clinical bluetongue (BT), as well as from animals on premises with no history of BT disease. Insects, including Culicoides variipennis, were collected in areas enzootic for BT disease. Viral isolations were in 10-day-old embryonating chicken eggs that were then adapted to Vero cells for serotyping. Sera were tested from group-specific antibody to BTV by the micro agar gel precipitin (AGP) test. Viral isolations were from cattle (81), sheep (122), goats (9), antelope (2), and C varipennis (5). There were 7 isolates of serotype 120, 114 of serotype 11, 42 of serotype 13, and 56 of serotype 17. In herds or flocks from which BTV was isolated, 51% of cattle, 56% of sheep, 21% of goats, and 52% of antelope had AGP antibodies. Virus was isolated from 43% of the cattle and 23% of the sheep that had no demonstrable evidence of AGP antibodies. Viral isolations were seasonal, occurring from August until December. Approximately 30% of the herds or flocks from which virus was isolated had more than one serotype of virus causing infection.     

Enzyme linked immunoassay and fluorescent antibody techniques in the diagnosis of viral diseases using staphylococcal protein-A instead of anti-gamma-globulins

Staphylococcal protein-A (SpA) is known to interact with the crystallizable fragment (Fc) of IgG molecules from several species. In the present study, SpA coupled to either fluorescein isothiocyanate (FITC) or peroxidase was used in place of antisera to IgG for the fluorescent antibody (FA) techniques and the enzyme linked immunoassay (ELISA). The SpA conjugates produced low background staining when applied in these techniques, and provide a rapid, highly specific and sensitive means for the identification of viral isolates and the detection of serum antibodies. Moreover, SpA is a single reagent that replaces various preparations of anti-gamma globulin against many species. SpA-FITC conjugate was successfully applied for the identification of pseudorabies virus, hog cholera virus, swine vesicular disease virus, transmissible gastroenteritis virus, porcine parvovirus and porcine enteroviruses. Antibody titers against the mentioned viruses could be determined semi-quantitatively in the indirect FA test with SpA-FITC. In our laboratory the ELISA became a routinely practicable serological test for the detection of antibodies only after we introduced SpA-peroxidase as a marker for the IgG.     

Specificity of neutralizing and precipitating antibodies induced in healthy calves by monovalent modified-live bovine viral diarrhea virus vaccines

Serum was obtained at weekly intervals after vaccination of 6 healthy calves with either of 2 commercially available monovalent modified-live bovine viral diarrhea (BVD) virus vaccines. Detectable neutralizing antibodies to each of 10 cytopathic and 10 noncytopathic isolates of BVD virus were produced by 1 or more of the calves by 14 days after vaccination, but no calf produced detectable neutralizing antibodies to all 20 BVD viruses. At that time, precipitating antibodies against viral-induced polypeptides of approximately 115,000; 80,000; 56,000; 48,000; 39,000; and 25,000 daltons were detected in sera from some calves. Also at that time, specificity of the antibodies for polypeptides of certain viruses was detected. At 21 days after vaccination, each calf produced neutralizing antibodies to all 20 BVD viruses. At that time, precipitating antibodies to each of the aforementioned viral induced polypeptides were detected in serum from each calf. Precipitating antibodies to viral induced polypeptides of 61,000 and 37,000 daltons were detected in samples of sera obtained from some calves at 42 days after vaccination.     

Production and Characterization of Monoclonal Antibodies to Peste des Petits Ruminants (PPR) Virus

Peste des petits ruminants (PPR) is an acute, febrile viral disease of small ruminants, caused by a virus of the genus Morbillivirus. PPR and rinderpest viruses are antigenically related and need to be differentiated serologically. In the present study, 23 mouse monoclonal antibodies were produced by polyethyleneglycol (PEG)-mediated fusion of sensitized lymphocytes and myeloma cells. Among these, two belong to the IgM class and the remaining 21 to various subclasses of IgG. The MAbs from the IgG class designated 4B6 and 4B11 neutralized PPR virus in vitro. In radioimmunoprecipitation assay, 10 MAbs recognized nucleoprotein, 4 recognized the matrix protein and one each haemagglutinin and phosphoprotein. The remaining 7 MAbs failed to precipitate any defined viral protein. The reactivity pattern of the monoclonal antibodies in indirect ELISA indicated a close antigenic relationship within three Indian PPR (lineage 4) virus isolates and also within two rinderpest vaccine strains. All PPR virus isolates could be distinguished from rinderpest vaccine viruses on the basis of the reactivity pattern of all MAbs and anti-N protein MAbs. A set of six monoclonal antibodies specific to PPR virus could also be identified from the panel. From the panel of MAbs available, two MAbs were selected for diagnostic applications, one each for the detection of antigens and antibodies to PPR virus.     

Virus neutralising antibodies against 22 bovine viral diarrhoea virus isolates in vaccinated calves.

Seven of nine colostrum deprived calves, free from bovine viral diarrhoea virus (BVDV), were vaccinated with a commercially available vaccine containing two inactivated strains of BVDV, an inactivated strain of bovine herpesvirus-1 and modified-live strains of bovine respiratory syncytial virus and para-influenza-3 virus. The two other calves were kept as controls. The virus neutralising (VN) antibodies induced by vaccination were tested against 22 antigenically diverse BVDV isolates, including reference strains and field isolates, both cytopathic and non-cytopathic, as well as genotypes I and II. The strains were isolated in Belgium, France, Germany, the United Kingdom and the USA. While there were variations in the VN titres of the individual calves against all the strains, serum from the seven animals neutralised 20 or more of the strains tested. From the results, it can be concluded that the vaccine can stimulate the production of VN antibodies capable of neutralising a wide range of European and American isolates of BVDV, including genotypes I and II.     

Monoclonal antibodies to bovine viral diarrhea virus: cross-reactivities to field isolates and hog cholera virus strains.

Monoclonal antibodies to bovine viral diarrhea virus (BVDV) were examined for binding with a large number of North American BVDV isolates and eight strains of the serologically related pestivirus, hog cholera virus (HCV). No single BVDV monoclonal antibody reacted with all BVDV isolates. The most cross-reactive monoclonal antibody was an anti-p80/p125 antibody which showed a positive reaction with 173 of 180 (96%) North American isolates. From a fewer number of isolates tested, one anti-gp53 monoclonal antibody also showed a high cross-reactivity (94%). All BVDV isolates showed a positive reaction with at least one of the seven monoclonal antibodies in the panel. Thus, the results indicated that a pool of these monoclonal antibodies may be used in place of polyclonal antisera for the detection of BVDV contamination of cell lines or for virus isolation. For HCV, all three anti-p80/p125 monoclonal antibodies reacted positively with all eight virus strains. In contrast, none of the anti-gp53 monoclonal antibodies were reactive to HCV strains. Thus, the anti-gp53 monoclonal antibodies may be useful for distinguishing between usually innocuous BVDV infections and the highly significant HCV infections in swine for foreign animal disease surveillance.     

Monoclonal antibodies to the p80/125 gp53 proteins of bovine viral diarrhea virus: their potential use as diagnostic reagents.

Monoclonal antibodies reactive to the bovine viral diarrhea virus (BVDV) protein gp53 were produced and characterized. These antibodies and our panel of anti-p80/125 monoclonal antibodies were tested for their cross-reactivity with 11 different North American and European (Danish) BVDV strains and isolates including viruses of both cytopathic and noncytopathic biotypes. The four anti-gp53 monoclonal antibodies were neutralizing for the homologous Danish cytopathic isolate and cross-reacted with all BVDV strains examined except for the Draper strain. Further, anti-gp53 monoclonal antibodies neutralized the majority of BVDV strains examined. The anti-p80/125 monoclonal antibodies cross-reacted with all eleven strains and isolates tested. This indicated that various strains of BVDV have common epitopes. The broad cross-reactivities demonstrated by these monoclonal antibodies suggest that a pool of these antibodies may be used for detection of BVDV cellular contamination or for virus isolation, in place of polyclonal antiserum.