A serological survey for antibodies against foot-and-mouth disease virus (FMDV) in domestic pigs during outbreaks in Kenya

Foot-and-mouth disease (FMD) is endemic in Kenya and has been well studied in cattle, but not in pigs, yet the role of pigs is recognised in FMD-free areas. This study investigated the presence of antibodies against FMD virus (FMDV) in pigs sampled during a countrywide random survey for FMD in cattle coinciding with SAT 1 FMDV outbreaks in cattle. A total of 191 serum samples were collected from clinically healthy pigs in 17 districts. Forty-two of the 191 sera were from pigs vaccinated against serotypes O/A/SAT 2 FMDV. Antibodies against FMDV non-structural proteins were found in sera from 30 vaccinated and 71 non-vaccinated pigs, altogether 101/191 sera (53 %), and 91 % of these (92/101) also had antibodies measurable by serotype-specific ELISAs, predominantly directed against SAT 1 with titres of 10–320. However, only five high titres against SAT 1 in vaccinated pigs were confirmed by virus neutralisation test (VNT). Due to high degree of agreement between the two ELISAs, it was concluded that positive pigs had been infected with FMDV. Implications of these results for the role of pigs in the epidemiology of FMD in Kenya are discussed, and in-depth studies are recommended.     

Four-layer enzyme immunoassay (EIA) detection of differences in IgG, IgM and IgA antibody response to Aujeszky's disease virus in infected and vaccinated pigs

The use of the four-layer enzyme immunoassay (EIA) for the detection of IgG, IgM and IgA antibodies against Aujeszky's disease virus in blood and oropharyngeal swabs of infected and vaccinated pigs is described. Mean antibody titres obtained using the four-layer EIA were 6.1 and 3829 times higher compared with the indirect enzyme-linked immunosorbent assay (ELISA) and virus neutralization (VN) test, respectively. The VN test detected mainly IgG antibodies, while the IgM antibodies did not react. Using the EIA, the first antiviral antibodies in sera were demonstrated on Days 5-7 after infection or vaccination. Up to the 7th day, demonstrable antibodies were almost exclusively of the IgM class. In infected pigs high titres of IgM antibodies were still detected on Day 18, while in vaccinated animals they were absent by this time. Antibodies of the IgG class appeared in infected pigs sooner (Day 7) than in vaccinated pigs (Day 10) and reached higher mean titres. Antibodies of the IgA class were demonstrable from Day 10 only in samples from infected pigs. Similar antibody dynamics and distribution were detected in oropharyngeal swabs, except that the IgG and IgM titres were roughly 100 times lower than in sera. However, titres of IgA antibodies in oropharyngeal swabs were two times higher than in sera. The greatest differences between both groups of animals were recorded on Day 18; in the infected pigs, IgG, IgM and IgA antibodies were present in sera and oropharyngeal swabs at that time, while in vaccinated pigs only IgG antibodies were demonstrable. The effect of infection and vaccination on the pattern of the immune response as well as the importance of the detection of individual immunoglobulin classes for the specificity of the enzyme immunoassay are discussed.     

Use of an enzyme-linked immunosorbent assay for the detection of IgG antibodies to rinderpest virus in epidemiological surveys

A comparison was made between an indirect enzyme-linked immunosorbent assay (ELISA) and the virus neutralisation test (VNT) for the detection of antibodies to rinderpest virus in field sera. The results did not agree for 6 per cent of the sera tested where 3 per cent of the samples gave ELISA positive/VNT negative and 3 per cent gave ELISA negative/VNT positive. The latter sera all had high levels of IgM antibody, which may indicate animals being at an early stage of infection or detection of a non-specific reaction. The ELISA results give a representative picture of the immune status for field surveys and a greater number of sera can be assayed with relative ease, compared to the traditional serum neutralisation test.     

Serology for diagnosis and epizootiological studies of bovine respiratory syncytial virus infections

The complement fixation test (CFT) and the virus neutralisation test (VNT), performed as a plaque reduction test, were employed to measure antibodies to bovine respiratory syncytial virus. The CFT with bovine sera was performed with supplementation of the complement factors in fresh guinea pig serum by an adequate amount of Clq-factor of the bovine species. Kinetics of maternally derived antibodies and the antibody response after spontaneous and experimental infections and after intramuscular vaccination were studied by both tests. Patterns of development of complement fixing and virus neutralising antibodies were generally similar and titres equalled each other in the test systems that are described. However a VNT detected antibodies a few days earlier after an infection than a CFT and peak-levels reached after a naturally acquired infection decreased faster in a CFT than in a VNT: a mean decrease of 3.1 and 1.4 log2 units was found in 13 weeks respectively. Mean half-life of passive antibodies was 25 days in a VNT. An infection with bovine respiratory syncytial virus could be diagnosed by serology, using a CFT on acute and convalescent serum samples of a number of animals in a group. Serology is preferable to virus isolation for routine diagnosis of bovine respiratory syncytial virus infections. Paired sera, collected at 14-day intervals and examined by CFT, are recommended for the diagnosis of the cause of respiratory disease. A VNT is preferable if low antibody levels are to be detected because non-specific reactions occur in a CFT at low serum dilutions.     

Investigations of the efficacy of European H1N1- and H3N2-based swine influenza vaccines against the novel H1N2 subtype

The efficacy of a commercial swine influenza vaccine based on A/New Jersey/8/76 (H1N1) and A/Port Chalmers/1/73 (H3N2) strains was tested against challenge with an H1N2 swine influenza virus. Influenza virus-seronegative pigs were vaccinated twice with the vaccine when they were four and eight weeks old, or with the same vaccine supplemented with an H1N2 component. Control pigs were left unvaccinated. Three weeks after the second vaccination, all the pigs were challenged intratracheally with the swine influenza strain Sw/Gent/7625/99 (H1N2). The commercial vaccine induced cross-reactive antibodies to H1N2, as detected by the virus neutralisation (VN) assay, but VN antibody titres were 18 times lower than in the pigs vaccinated with the H1N2-supplemented vaccine. The challenge produced severe respiratory signs in nine of 10 unvaccinated control pigs, which developed high H1N2 virus titres in the lungs 24 and 72 hours after the challenge. Vaccination with the commercial vaccine resulted in milder respiratory signs, but H1N2 virus replication was not prevented. Mean virus titres in the pigs vaccinated with the commercial vaccine were 1-5 log10 lower than in the controls at 24 hours but no different at 72 hours. In contrast, the H1N2-supplemented vaccine prevented respiratory disease in most pigs. There was a 4-5 log10 reduction in the mean virus titre at 24 hours in the pigs vaccinated with this vaccine, and no detectable virus replication at 72 hours. These data indicate that the commercial swine influenza vaccine did not confer adequate protection against the H1N2 subtype.     

Laboratory decision-making during the classical swine fever epidemic of 1997-1998 in The Netherlands

The National Reference Laboratory for classical swine fever (CSF) virus in the Netherlands examined more than two million samples for CSF virus or serum antibody during the CSF epizootic of 1997–1998. The immense amount of samples and the prevalence of border disease (BD) virus and bovine viral diarrhoea (BVD) virus infections in Dutch pig herds necessitated the diagnostic efforts of the laboratory to be focused on generating CSF specific test results throughout the eradication campaign.

Detection of 82% of the 429 outbreaks was achieved through the combined use of a direct immunofluorescence and peroxidase assay (FAT/IPA) with samples (tonsils) collected from clinically-suspected pigs. This suggests that in the majority of the outbreaks, the pigs had clinical signs that were recognised by the farmer and/or veterinarians, indicating the presence of CSF virus in a pig herd. A positive diagnosis of 74% of all the tissue samples (tonsils) collected at infected pig holdings was established by FAT. More than 140,000 heparinised blood samples were examined by virus isolation, resulting in the detection of 4.5% of the infected herds. CSF virus was isolated in approximately 29% of all the blood samples collected from pigs at infected or suspected farms.

Several serological surveys — each done within a different framework — led to the detection of 13.5% of the total number of outbreaks. The detection of CSF virus antibody in serum was carried out by semi-automated blocking ELISA. Approximately 28.5% of the sera which reacted in the ELISA were classified as CSF virus-neutralising antibody positive and 26.5% as positive for other pestiviruses following the virus neutralisation test (VNT).

We concluded that two of the CSF laboratory diagnostic methods described were determinative in the eradication campaign: first, the FAT for the screening of diseased pigs; and second, the ELISA and VNT when millions of predominantly healthy pigs needed to be screened for the presence of CSF serum antibody. Decision-making on the basis of results generated by either method can, however, be seriously hindered when samples are examined from pig herds with a high prevalence of non-CSF pestiviruses.     

Differentiation by western blotting of immune responses of cattle vaccinated with Brucella abortus strain 19 or infected experimentally or naturally with virulent Brucella abortus

Brucella abortus strain 19 salt-extractable proteins fractionated by differential ammonium sulfate precipitation were used in a western blotting method to detect bovine immunoglobulin G antibodies to B. abortus. Sera from infected cattle and from cattle vaccinated with strain 19 and subsequently exposed to virulent B. abortus bound to a common group of antigens ranging in molecular weights from 31,000 to 45,000 daltons. Immunoglobulin G antibodies in sera from the latter group in addition also bound to antigens with molecular weights of 66,000 to 71,000 daltons. Some sera from cattle vaccinated when sexually mature reacted similar to those from infected cattle, while immunoglobulin G antibodies in sera from Brucella-free cattle and vaccinated calves did not bind to either group of antigens. In general, fractionation of the proteins by ammonium sulfate precipitation offered no advantage for detecting differences between groups of sera. Ammonium sulfate fraction 0 to 35% reacted with a larger number of sera from a naturally infected group than fraction 0 to 70%. Both fractions reacted equally well with sera from the other groups of cattle, while fractions 35 to 70% and 70 to 100% reacted poorly in this technique. The attractive feature of the blot is that sera from calfhood-vaccinated cattle did not react.     

No serological evidence for the presence of swine vesicular disease virus in South Africa.

An indirect ELISA incorporating a protein A-peroxidase conjugate was developed for detecting antibodies to swine vesicular disease virus (SVDV) in pig sera. This test and a conventional virus neutralization test were found to be equally sensitive. A total of 2846 pig sera collected from various abattoirs in South Africa were tested using the indirect ELISA. No serological evidence of infection with SVDV in pigs in South Africa was found.     

The Recombinant Nonstructural Polyprotein NS1 of Porcine Parvovirus (PPV) as Diagnostic Antigen in ELISA to Differentiate Infected from Vaccinated Pigs

To differentiate pigs infected with porcine parvovirus (PPV) from those vaccinated with inactivated whole-virus vaccine, an enzyme-linked immunosorbent assay (ELISA) based on detection of a nonstructural polyprotein 1 (NS1) was developed. A threshold of 0.23 optical density units was established and the assayhad high specificity (100), sensitivity (88), accuracy (90) and positive predictive value (100) using haemagglutination inhibition as the standard method. A reproducibility test revealed that the coefficients of variation of sera within-plates and between-run were less than 10%. The assayshowed no cross-reactivitywith antibodies to porcine reproductive respiratorysyndrome virus, pseudorabies virus, foot and mouth disease virus, Actinobacillus pleuropneumoniae, Toxoplasma or Chlamydia. Sera obtained from pigs infected with PPV reacted with recombinant NS1 protein in the ELISA. Sera from pigs vaccinated with inactivated whole virus did not recognize this protein in the ELISA. In contrast, antibodies against PPV whole virus were present in both PPV-infected and vaccinated animals. Serum conversion against NS1 was first detected 10 days after infection and NS1-specific antibodies were detectable up to half a year post infection. In conclusion, the PPV-NS1 ELISA can differentiate PPV-infected versus inactivated PPV-vaccinated pigs and could be applied in disease diagnosis and surveillance.     

Oronasal challenge of fattening pigs after vaccination with an inactivated Aujeszky's disease vaccine

Groups of pigs from vaccinated and unvaccinated sows were vaccinated once or twice between the ages of eight and 20 weeks with a commercial inactivated, oil adjuvanted Aujeszky's disease virus vaccine. Pigs were challenged by the oronasal route when 22 to 27 weeks old. Pigs from unvaccinated sows developed neutralising antibodies after vaccination but no seroconversion was detected in eight-week-old pigs or in 80 per cent of 15-week-old pigs from vaccinated sows. Challenge resulted in severe disease and weight loss in control pigs. In vaccinated animals the duration and severity of clinical signs and the amount of weight lost decreased with increasing serum neutralisation titres. The results indicate that parenteral vaccination at weaning with the vaccine described will not protect pigs at slaughter age against infection and disease, particularly if they were born from seropositive mothers.     

Development of a Neutralizing Monoclonal Antibody-based Blocking ELISA for Detection of Equine Herpesvirus 1 Antibodies

A single-dilution, sensitive and specific monoclonal antibody-based blocking enzyme-linked immunosorbent assay (B-ELISA) was developed as an alternative to the cumbersome virus neutralization test (VNT) for detection of equine herpesvirus-1 (EHV-1) antibodies. Neutralizing monoclonal antibodies (1H6 and 9C6) raised against EHV-1 (Hisar-90-7 strain) and sera from 70 horses (30 known negative and 40 known positive for EHV-1 antibodies by VNT) were used for standardization of the B-ELISA. Using a single serum dilution of 1:250 in B-ELISA, 100% specificity was obtained with both monoclonal antibodies (Mabs) in comparison to VNT. Similarly, the sensitivity of the B-ELISA was 92.5% and 100% with 1H6 and 9C6 Mabs, respectively. A very high correlation coefficient (r = 0.85) was observed between B-ELISA and VNT that was significant at the p < 0.01 level. B-ELISA detected a more than 3-fold rise in antibody titres in paired serum samples collected from mares aborting owing to EHV-1 infection. Mab 9C6 was chosen for testing 231 field sera from apparently healthy vaccinated and non-vaccinated horses from organized breeding farms belonging to 11 Indian states, and from Bhutan, by B-ELISA and VNT. There was very good agreement between the results obtained by both VNT and B-ELISA (K = 0.9438). Of 231 field sera, 144 samples were negative for EHV- 1 antibodies by both VNT and B-ELISA and 81 were positive by both tests. Two samples negative by VNT were found positive in B-ELISA. On the other hand, four weakly positive samples in VNT (VN antibody titre 0.9 1.2 log10) were negative in B-ELISA. The Mab (9C6)-based B-ELISA was found to be a suitable alternative to VNT for screening large numbers of field sera and enabled confirmatory EHV-1 serodiagnosis.     

A complex-trapping-blocking (CTB) ELISA, using monoclonal antibodies and detecting specifically antibodies directed against foot-and-mouth disease types A, O and C. II. Application

The complex-trapping-blocking (CTB) enzyme-linked immunosorbent assay (ELISA) was evaluated to detect antibodies directed against foot-and-mouth disease virus (FMDV) strains A10 Holland, O1 BFS, and C1 Detmold. Log10 serum titres of uninfected, unvaccinated cattle (n = 100) were less than 1.80 in the CTB-ELISA. Sera from cattle vaccinated with either monovalent or trivalent vaccines were tested in both the CTB-ELISA and the serum neutralisation test (SNT); titres in both tests correlated positively (P less than 0.001). Titres of sera from cattle, sheep, and pigs vaccinated twice with FMDV A10 Holland also correlated positively in both tests. In another experiment, cattle vaccinated with FMDV strain C1 Detmold were intradermolingually challenged 3 weeks after primary vaccination; at the same time two controls were challenged. At 8 days after challenge, serum titres of the controls were distinctly higher in the CTB-ELISA than in the SNT, whereas serum titres of the vaccinated cattle were equally high in both tests. In potency tests for monovalent vaccines against FMDV strains A10 Holland, O1 BFS or C1 Detmold, serum titres correlated strongly in both tests with protection against the homologous FMDV strain. We concluded that the CTB-ELISA is not only sensitive, but easier to perform and more rapid and reproducible than the SNT. The CTB-ELISA may be useful in evaluating the immune response in cattle during FMD vaccine potency tests.     

Swine vesicular disease, studies on pathogenesis, diagnosis, and epizootiology: a review

Swine vesicular disease (SVD) is a contagious viral disease of swine. It causes vesicular lesions indistinguishable from those observed of foot-and-mouth disease. Infection with SVD virus (SVDV) can lead to viraemia within 1 day and can produce clinical signs 2 days after a pig has come into contact with infected pigs or a virus-contaminated environment. Virus can be detected 3.5 hours after infection using immunohistochemistry. In these in vitro studies, this technique was superior to in-situ hybridization. In SVDV-infected tissues, however, more infected cells were positive using in-situ hybridization, and these were already seen 4.5 hours after infection. For serological diagnosis of SVD several new enzyme-linked immunosorbent assays (ELISA's) have been developed. The newest ELISAs, based on monoclonal antibodies, are superior to the previous tests. The new tests produce fewer less false-negative results and enable large-scale serological screening. In screening programmes a small percentage of false positive reactors have been detected. The cause of these false-positive reactions has not been identified, though infections with human Coxsackie B5 virus can be excluded.     

The detection of transmissible gastroenteritis viral antibodies by immunodiffusion.

Precipitating antibodies against transmissible gastroenteritis viral antigens were detected by the immunodiffusion test in two transmissible gastroenteritis viral hyperimmune antisera and in antiserum prepared against haemagglutinating encephalomyelitis virus but not in sera from several species of normal animals, in antisera prepared against a variety of othet viruses and bacteria or sera from swine with bacterial enteritis. When the immunodiffusion test was compared with the virus neutralization test for the detection of transmissible gastroeneritis viral antibodies in 20 swine sera certain samples which contained high titres of virus neutralizing antibodies failed to produce precipitation while other sera were positive in the immunodiffusion test although their virus neutralizing antibody titres were relatively low. Precipitating antibodies were also detected by immunodiffusion in several samples of milk whey from a sow which had been vaccinated with inactivated transmissible gastroenteritis virus.     

Comparison of the Antibody Response in Adult Cattle Against Different Epitopes of Brucella abortus Lipopolysaccharide

The comparison of serological responses in a sample of adult, vaccinated and field‐infected bovines with Brucella abortus is reported. Indirect enzyme immunoassay (EIA) titration curves and Western blotting tests for smooth‐type lipopolysaccharide (S‐LPS), rough‐type LPS (R‐LPS) and lipid A were performed. In the initial screening of sera, an overall prevalence of 20.5 % was found, which corresponds to a country with a high incidence of brucellosis. End‐point EIA titres against LPS antigens from vaccinated and field‐infected cows were not significantly different. However, the absorbance values in the titration curves were significantly higher for S‐LPS as compared with the other antigens. A high correlation coefficient (r=0.933) was obtained when the titres to R‐LPS versus lipid A were compared. Western blotting reactions of vaccinated and field‐infected animals were indistinguishable. S‐LPS, R‐LPS and lipid A epitopes were recognized in a heterogeneous manner. In general, the number of bovines that reacted against LPS was higher in the field‐infected group, with a stronger binding to S‐LPS. Based on our observations, the vaccinated and field‐infected bovines are capable of producing similar antibody responses to the Brucella main outer surface antigen, LPS. It should be emphasized that the humoral response of cattle to Brucella LPS contains significant amounts of antibodies to other antigenic moieties of this important surface molecule, which may contribute to the immunity to brucellosis.     

Antibody response in cattle and rabbits to early antigens of malignant catarrhal fever virus in cultured cells.

Cytosine arabinoside (Ara-C) inhibited the production of late antigens and of infectious virus in monolayers of bovine kidney cells infected with the high-passage, WC-11 strain of malignant catarrhal fever virus. Early antigens were not affected. Using hyperimmune and acute-phase sera from cattle and rabbits in indirect immunofluorescence tests, it was shown that Ara-C treated cultures contained two early antigens; one was diffuse and distributed throughout the cells, the other was particulate and intranuclear. Antibody to early antigens developed later and attained lower titres in infected animals, especially rabbits; only hyperimmune sera reacted with the diffuse early antigen.     

Porcine parvovirus: propagation in microcarrier cell culture and immunogenic evaluation in pregnant gilts

Porcine parvovirus was propagated in PK-15 cells cultured in roller bottles or on microcarrier beads. After inactivation, the virus was used as antigen in the preparation of vaccines. The immunogenic potency and safety of the vaccines were evaluated in specific pathogen free pregnant gilts and guinea pigs. Experimental challenge tests determined the efficacy of the vaccine in preventing porcine parvovirus transplacental infection. Neither viral antigens nor specific antibodies were detected in fetuses from vaccinated gilts. In contrast, fetal death and, or, mummification occurred when unvaccinated gilts were infected. Both virus and, or, antibodies were also detected in fetuses from these unvaccinated gilts. Serum conversion after vaccination was assayed by microserum neutralisation using guinea pig erythrocytes as cell indicators and by haemagglutination inhibition tests. Viral antigens in fetal tissues were detected using ELISA, the immunobeads technique, the haemagglutination test and by virus isolation.     

Comparison of two antigens for use in an enzyme-linked immunosorbent assay to detect African swine fever antibody

Two African swine fever virus (ASFV) antigens were tested for use in an ELISA to detect antibody to ASFV. Antigens used were the cytoplasmic soluble fraction (CS-P) of infected cells grown in the presence of porcine serum and the semipurified viral structural protein VP73 (SVP73). Both antigens were tested by ELISA against 72 sera obtained during several ASF field episodes and from ASFV-inapparent carriers. Of the 72 sera, only 2.8% has positive results by ELISA against CS-P antigen; 60% of positive-reacting sera (to both antigens) had higher ELISA values when the CS-P antigen was used. Samples (with positive results) that reacted only to CS-P antigen had results confirmed by immunoblot analysis. Such sera reacted against ASFV-infection proteins IP25, IP25.5, and IP30, but not against IP73. In time-course experiments to detect appearance of ASFV-antibodies in infected miniature pigs, antibodies were detected by immunoblot analysis on postinoculation day (PID) 8. At that time, only the polypeptides IP25, IP25.5 IP30, and IP31 were recognized; IP73 and IP12 were first detected 3 and 4 days later, respectively. In the same experiments, ASFV antibodies were detected by ELISA, using CS-P or SVP73 antigens, on PID 7 and 9, respectively. These results could explain the percentage of sera not having positive results by ELISA using SVP73 antigen, if the sera were obtained from ASFV-infected pigs during the first days of infection before induction of antibody response against the IP73 protein. This feature makes the use of CS-P antigen advantageous in early serologic detection of ASFV-infected pigs.     

Sensitive glycoprotein gIII blocking ELISA to distinguish between pseudorabies (Aujeszky's disease)-infected and vaccinated pigs.

A blocking enzyme-linked immunosorbent assay (ELISA) test has been developed to distinguish pseudorabies virus (PRV) (Aujeszky's disease virus) -infected pigs from those immunized with a glycoprotein g92 (gIII) deletion mutant, PRV (dlg92dltk) [OMNIMARK-PRV]. This blocking ELISA test utilizes an anti-PRV gIII monoclonal antibody (mAbgIII)-horseradish peroxidase (HRPO) conjugate, TMB for color development and a cloned PRVg92 (gIII) antigen to coat wells of microtiter test plates. Undiluted sera are used to block the binding of the mAbgIII-HRPO conjugate to the antigen. The gIII blocking ELISA is specific and has a sensitivity comparable to screening ELISA and latex agglutination tests. PRV-negative sera and sera from pigs vaccinated once, twice, or four times with the gIII-negative vaccine all showed negative S/N values of greater than 0.70 (S/N defined as the optical density at 630 nm of test sera/optical density at 630 nm of negative control sera). Sera from PRV-infected herds, sera from pigs experimentally infected with virulent PRV, and sera from pigs vaccinated with modified-live or inactivated gIII+ vaccines were positive for gIII antibodies (S/N less than 0.7). Sera from pigs experimentally infected with 200 PFU virulent PRV seroconverted to gIII+ antibodies 7-10 days postinfection. Sera from pigs vaccinated with gpX- and gI- vaccines seroconverted to gIII+ antibodies 7-8 days after vaccination. The gIII antibodies persisted after gIII+ vaccinated for at least 376 days postvaccination. Sera from pigs protected by vaccination with PRV (dlg92dltk) and then challenge exposed to virulent PRV at 21 days postvaccination showed gIII+ antibodies by 14 days postchallenge. The specificity and sensitivity of the gIII blocking ELISA assay was further demonstrated on the United States Department of Agriculture-National Veterinary Services Laboratory (USDA-NVSL) sera from the 1988 PRV check set and the 1989 gIII PRV check set by comparing the gIII blocking ELISA assay with virus neutralization, screening/verification ELISA and latex agglutination assays.     

Confirmation of the occurrence of the chewing louse Bovicola (Lepikentron) breviceps (Insecta: Phthiraptera: Trichodectidae) on alpacas (Lama pacos) in New Zealand

Abstract

AIM: To investigate the cause of classical swine fever (CSF) virus-seropositive animals in a nucleus pig-breeding herd in New Zealand, where porcine circovirus-associated disease had been diagnosed.

CASE HISTORY AND CLINICAL FINDINGS: An exotic disease investigation was undertaken to exclude CSF and porcine reproductive and respiratory syndrome (PRRS) on a nucleus pig-breeding herd comprising approximately 300 breeding sows, 1,000 weaners, and 650 grower pigs. The herd was experiencing poor reproductive performance in sows, and breeding records showed a declining farrowing rate attributable to a single manager. The growing pigs (10–15 weeks old) were experiencing respiratory disease and wasting, and the mortality rate by pen varied between 9 and 20%. Post-mortem changes in affected grower pigs were consistent with circovirus-associated diseases.

DIAGNOSTIC TESTING: Serological screening using an IDEXX-ELISA gave negative results for PRRS virus antibodies, but two grower pigs and one sow tested positive for CSF virus antibodies. These three seropositive animals remained positive to CSF virus, using three commercial ELISA test kits, over 27 weeks. A newly developed virus neutralisation test (VNT), using a New Zealand isolate of border disease (BD) virus, demonstrated that the seropositive pig sera had higher antibody titres to BD virus than to bovine viral diarrhoea (BVD) virus and CSF virus.

PCR performed on tonsil, kidney, ileum and spleen gave negative results for CSF virus, and histopathology on lymph nodes, intestine, lung, kidney, liver and brain showed no evidence of the disease. Virus isolation performed on a number of samples was negative.

CLINICAL RELEVANCE: The seropositive samples for CSF virus found in this investigation were likely to be a cross reaction to a pestivirus other than CSF virus. The finding of a possible endemic pestivirus capable of being transmitted between sheep and pigs on this farm may explain findings from previous serological survey work in New Zealand, and supports experience elsewhere, where BD virus was found to be the predominant ruminant pestivirus infecting pigs. The results show that pestivirus cross reactivity can result in unexpectedly high titres, and that testing with a full set of (local) pestiviruses is necessary to reach the correct conclusion. The investigation has direct relevance where pig herds with a low seroprevalence are encountered during surveillance for CSF.