Production and characterization of monoclonal antibodies directed against pseudorabies virus.

Hybridoma cell lines producing monoclonal antibodies to pseudorabies virus (PRV) were established. The monoclonal antibodies were characterized with respect to their antigenic specifications and biological activities. Two monoclonal antibodies immunoprecipitated the 50 kDa PRV glycoprotein (gp50) and two immunoprecipitated the 82 kDa glycoprotein (gp82). The monoclonal antibodies were used to analyze the biological roles of these two glycoproteins. One monoclonal antibody directed against each glycoprotein did not require complement for in vitro viral neutralization while the other monoclonal antibody directed against the glycoprotein required complement for neutralization. The monoclonal antibodies against gp50 were shown to be directed against different epitopes within the glycoprotein. In contrast, the monoclonal antibodies against gp82 were shown to be directed against the same antigenic site on the glycoprotein. In vivo passive immunity studies in mice showed that monoclonal antibodies directed against either gp50 or gp82 could be protective.

Immunological surveillance in a pseudorabies quarantined herd using gilts and their progeny as sentinels.

Specific pathogen free gilts and their progeny were evaluated to use as sentinels in a pseudorabies virus (PRV) infected herd by immunologically monitoring for PRV seroconversions. Time intervals targeted were pre- and post-PRV vaccinations, herd exposure, and farrowing to finishing. Post-PRV vaccinations, gilts showed low PRV lymphocyte stimulation and humoral responses. Following herd exposure, control gilts PRV seroconverted and PRV vaccinated gilts increased (2 to 4 times) in virus neutralization (VN) titers. Sixty-seven percent (4/6) of the progeny from a control gilt were PRV seropositive at finishing. Progeny from PRV vaccinated gilts were depleted of passive immunity by week 7, and were seronegative until week 9. At finishing 47% (14/30) of them were PRV seropositive indicating exposure to PRV. The VN test was not sensitive enough to detect weak positive serums, noted as positives by latex agglutination (LA) test, ELISA, and Western blots. The gilts and progeny detected PRV, respectively, in the herd housing quarters and in the farrow to finish facilities. A strategy for future sentinel experimental surveillances using primarily the LA test is proposed.

Evaluation of a diagnostic antigen for the detection of Aujeszky's disease virus-infected subunit-vaccinated pigs.

An early virus protein complex that is found in the maintenance medium of Aujeszky's disease (AD) virus-infected cells was evaluated as a subunit diagnostic antigen (SUDA) in the enzyme-linked immunosorbent assay (ELISA). This antigen was found in purer form and in larger quantities for up to 12 h post-infection in the maintenance medium of AD virus-infected MDBK cell cultures than in the maintenance medium of virus-infected porcine Fallopian tube (PFT) and PK1a cell cultures. The SUDA was shown to be compatible with a lectin-derived subunit vaccine by the absence of positive ELISA reactions for antibody to this antigen in 25 AD virus-free subunit-vaccinated pigs. Following virus challenge, all fo 24 surviving vaccinated pigs seroconverted to SUDA within 10 days. Compatibility with the vaccine was further demonstrated by the absence of positive ELISA reactions for antibody to SUDA in 12 pigs that received five or six consecutive vaccine doses at 3-wk intervals. The sensitivity of the ELISA with SUDA was demonstrated by the detection of antibody in virus-infected vaccinated and non-vaccinated pigs for at least 15 and 22 weeks, respectively, following exposure to virus. The SUDA was also economical: it was calculated that 8000-14 000 tests could be run with the antigen present in the maintenance medium of one 850 cm2 plastic tissue culture roller bottle of virus-infected MDBK cells.

Studies of porcine reproductive and respiratory syndrome (PRRS) virus infection in avian species.

Porcine reproductive and respiratory syndrome virus (PRRSV) is a recently recognized virus of swine. As a newly emerging virus, much of the basic information regarding PRRSV is in the process of discovery. We report three experiments with PRRSV in birds, and a fourth experiment to evaluate the infectivity and transmissibility of avian-derived PRRSV in swine. Experiment 1 compared the susceptibility of Muscovy ducks, Mallard ducks, guinea fowl, and chickens to PRRSV. Birds were exposed to PRRSV (ATCC VR-2402) in drinking water and virus isolation was attempted from feces collected from cages. Based on the duration of fecal shedding of the virus, this experiment showed that Mallard ducks were particularly susceptible to PRRSV. Experiment 2 was done in mallards to corroborate and augment the observations of experiment 1. Virus was isolated from pooled mallard feces up to 25 days post exposure (PE) and from the intestinal contents of 8 of 20 birds euthanized on day 38 PE. No gross or microscopic lesions were observed in ducks collected between 0 and 15 days PE. Experiment 3 evaluated the infectivity and transmissibility of mallard-derived PRRSV in mallards. A cage of mallards orally exposed to PRRSV shed the virus in feces. Exposure of a second cage of mallards to feces from the first cage resulted in fecal shedding of PRRSV by birds in cage two. In turn, exposure to feces from the second cage led to fecal shedding by mallards in a third cage. Experiment 4 assessed the infectivity and transmissibility of mallard-derived virus in swine. Pigs intranasally exposed to PRRSV isolaed from mallard feces in experiment 2 became viremic, seroconverted by ELISA, and transmitted the virus to sentinel swine. Collectively, these studies show that the possibility exists for avian species to be involved in the epidemiology of PRRSV. This is the first report of PRRSV infection in a species other than swine.

Sequential changes in the humoral immune response of pigs to pseudorabies virus after vaccination, exposure to virulent virus, and reactivation of latent virus.

Sequential changes in the humoral immune response of pigs to pseudorabies virus (PRV) after each of several exposures to the virus were evaluated by determining virus neutralization (VN) and radioimmunoprecipitation (RIP) activities of sera collected at selected intervals. Pigs were vaccinated intramuscularly with live attenuated virus (6 pigs), inactivated attenuated virus (6 pigs), or inactivated virulent virus (6 pigs). All pigs were challenged oronasally with virulent virus 3 weeks later and 12 (4 pigs of each vaccine group) were subsequently treated with dexamethasone in an attempt to reactivate latent virus. The relatively low serum titers of VN antibody that were raised by vaccination (titers ranged from 2 to 32) increased markedly (at least 16-fold) for all pigs after exposure to virulent virus. After dexamethasone treatment, the VN titers of 2 pigs increased 16-fold, whereas those of the other 10 dexamethasone-treated pigs and the 6 nontreated pigs either remained the same or increased only minimally (i.e., no more than 2-fold). The results of RIP using 35S-methionine-labeled viral proteins were initially similar to those of VN in that the low levels of serum RIP activity detected after vaccination increased markedly after subsequent exposure to virulent virus. In contrast to VN, however, most pigs (11 of 12) treated with dexamethasone had a clear increase in serum RIP activity. The increase was particularly striking for viral proteins of relatively low (less than 46K) molecular weight. Precipitating activity for 14C-glucosamine-labeled viral glycoproteins was not detected until after pigs were exposed to virulent virus. The increase in RIP activity detected after dexamethasone treatment was likely due to an additional antigenic stimulus associated with virus reactivation. However, virus was isolated from nasal swabs of only 4 of the 12 treated pigs. None of the results appeared to be affected appreciably by the type of vaccine used for initial immunization.

Virus survival in the environment.

Viruses pass into the environment from clinically ill or carrier hosts; although they do not replicate outside living animals or people, they are maintained and transported to susceptible hosts. Population concentrations and movement, both animal and human, have been steadily increasing in this century, enhancing transmission of respiratory and enteric viruses and compounding the difficulty of preventing environmental transmission. Studies on environmental survival factors of viruses have been most definitive for polioviruses, foot and mouth disease viruses and Aujeszky's disease virus. In addition, heat resistance studies have been reported on adenoviruses, African swine fever virus and the Norwalk virus. Resistance to disinfectants has been studied for many viruses, including picornaviruses, papovaviruses, reoviruses and retroviruses. Survival of viruses in and on a variety of fomites has been studied for influenza viruses, paramyxoviruses, poxviruses and retroviruses. The subacute spongiform encephalopathy agents, under extensive current studies, are being found to have incredible stability in the environment.

A necrotizing pneumonia in lambs caused by pseudorabies virus (Aujesky's disease virus).

An outbreak of pseudorabies occurred in sheep housed with swine in the same building. Although the sheep and swine were not in physical contact, the lambs and ewes were exposed to air from the sows' section. Three dead lambs were submitted to the Iowa State University Veterinary Diagnostic Laboratory for necropsy. Grossly there were pulmonary congestion and multifocal pulmonary hemorrhages. Microscopic lesions were severe acute multifocal necrotizing bronchopneumonia with necrotizing vasculitis and intranuclear inclusion bodies within the neurons of the parabronchial ganglia. Bacterial cultures were negative for pathogenic agents; pseudorabies virus was isolated from ovine brain tissue. Viral antigen was demonstrated in the neurons of the parabronchial ganglia by immunoperoxidase staining. Electron microscopy revealed nucleocapsids in the parabronchial ganglionic neurons which contained basophilic intranuclear inclusion bodies. Viral DNA prepared from the ovine pseudorabies virus isolate was found by restriction endonuclease analysis to be related to the Indiana Funkhauser strain of pseudorabies virus.

Surveillance of Iowa swine herds for influenza-like illness: combined serologic and virus isolation method.

Five Iowa swine herds (involving about 7,000 swine) were placed under surveillance for signs of influenza-like illness. Blood samples for hemagglutination-inhibition (HI) tests of serums and nasal secretions on swabs for viral isolation were collected from 20 feeder swine in each herd at the outset of surveillance. On the basis of results of HI tests, 6 swine in each herd tested were chosen to be resampled 6 weeks after the first blood sample was collected if swine influenza virus (SIV) was not isolated, but 3 weeks after the first blood sample was collected if SIV was isolated at the outset of surveillance. The swine chosen for resampling were considered sentinels in a herd for the duration of surveillance. Swine influenza virus was isolated from 20 of 20 swine in each of 2 herds that had signs of influenza-like illness. The initial HI titer of each of the 20 swine in the 2 herds was less than 10. However, serum samples prepared from blood collected from sentinel swine in the 2 herds 3 weeks after isolation of SIV had HI geometric mean titers (GMT) of 23 and 34. One herd had an initial HI GMT of 21. A SIV was not isolated from this herd, and serum samples obtained from 3 of the 6 sentinel seine 6 weeks after the first blood sample was collected still had demonstrable HI antibody.

Morphologic heterogeneity of a strain of swine influenza virus (A/swine/Wisconsin/1/68, Hsw1N1) propagated at different temperatures.

Strain A/swine/Wisconsin/1/68 (WI/68) swine influenza virus (SIV) was propagated in embryonating chicken eggs at 33, 35, or 37 C. The SIV harvested from eggs incubated at 33 C invariably had higher hemagglutination (HA) and egg infectivity titers than did SIV propagated in eggs at the 2 higher temperatures. When SIV inoculum propagated at 33 C was inoculated into separate groups of eggs and incubated at 33, 35, and 37 C, the SIV harvested from inoculum incubated at the 2 higher temperatures had significantly lower infectivity and HA titers than did that propagated at 33 C. By electron microscopy (EM), viral particles of Wi/68 were of various sizes and shapes regardless of the temperature used to propagate the virus. However, in contrast to what was seen in SIV harvested from innoculum incubated at 33 C incubation, pleomorphic shapes and particles with surface abnormalities were much more frequent in SIV harvested from inoculums kept at the 2 higher temperatures. Approximately one-third of the particles from 35 and 37 C incubation either were spikeless or were relatively deficient in surface spikes.

Virus isolation and immune responses in susceptible swine exposed with pseudorabies virus (Shope strain).

Eighteen seronegative swine weighing from 9 to 11 kg were exposed intranasally with the Shope strain of pseudorabies virus (PRV) and were observed for 21 days in an experiment to detect virus shedding and immune responses. All swine had PRV in their nasal passages at 7 days after exposure; they also had precipitating antibodies to PRV as determined by the microimmunodiffusion test (MIDT) and very low levels of virus-neutralizing (VN) antibodies. The PRV was isolated from only 2 swine at postexposure day 14; all swine were MIDT positive, and VN titers ranged from 4 to 128. Virus was not isolated from the swine at 21 days after exposure, but all were MIDT positive; VN titers ranged between 8 and greater than or equal to 256.

Attenuated properties of thymidine kinase-negative deletion mutant of pseudorabies virus.

A thymidine kinase (TK)-negative (TK-) deletion mutant of the Bucharest (BUK) strain of pseudorabies virus (PRV) was isolated. The mutant, designated as PRV (BUK d13), did not revert to TK-positive (TK+), even when propagated in medium that selected for TK+ viruses. The mutant also replicated equally well at 39.1 C and 34.5 C, and was easily distinguished from other PRV strains by molecular hybridization experiments, restriction nuclease fingerprints, and plaque autoradiography or other assays for the TK phenotype. The PRV (BUK d13) had greatly reduced virulence for mice and rabbits, compared with parental TK+ strains, PRV (BUK-5) and PRV (BUK-5A-R1), and provided mice with solid protection against the TK+ BUK and Aujeszky strains of PRV. Experiments were done in 5- to 6-week-old pigs to assess the safety and efficacy of PRV (BUK d13) in the natural host. In one experiment, pigs were vaccinated IM with 7.5 X 10(8) plaque-forming units of TK- PRV (BUK d13), and were then challenge exposed intranasally (IN) with 4.3 X 10(8) TCID50 of virulent PRV [Indiana-Funkhauser (IND-F)]. Vaccinated pigs did not have clinical signs of illness after vaccination or after challenge exposure. One nonvaccinated control pig died on postchallenge day 4; a 2nd nonvaccinated control pig became moribund, but eventually recovered. Pigs developed virus-neutralizing antibodies after vaccination, and had a secondary immunologic response after challenge exposure; however, PRV was not isolated from the tonsils or trigeminal ganglia of vaccinated pigs at postchallenge exposure day 11.(ABSTRACT TRUNCATED AT 250 WORDS)

Antiviral effectiveness of butylated hydroxytoluene against pseudorabies (Aujeszky's disease) virus in cell culture, mice, and swine.

Butylated hydroxytoluene (BHT) was evaluated for antiviral effectiveness on pseudorabies virus (PRV) in cell culture, mice, and swine. When relatively small amounts of BHT were mixed with PRV and incubated at 37 C for 30 or 60 minutes before inoculation into cell cultures, the cell cultures did not become infected with virus. The PRV was not infectious when the virus was treated with BHT and then inoculated intraperitoneally into mice, but was infectious when BHT and PRV were inoculated simultaneously or when BHT was inoculated either 30 or 60 minutes before PRV. Swine fed BHT-medicated feed for 10 days before they were intranasally exposed with virulent PRV did not have overt signs of pseudorabies, had a lower concentration of PRV in nasal mucus than did control swine, and had acceptable blood enzyme and cholesterol concentrations during the experiment. The BHT was detected in tissues of 2 swine after they were fed BHT-medicated feed for 10 days, and higher concentrations of BHT were detected in tissues of 3 swine given BHT feed for 29 days.

Development and evaluation of a microimmunodiffusion test for detection of antibodies to pseudorabies virus in swine serum.

A microimmunodiffusion test (MIDT) was developed for the detection of pseudorabies virus (PRV) antibodies in swine serum. The optimal medium for the MIDT was determined to contain 0.69% agarose in 0.05 M tris buffer (pH 7.2) with 0.025% sodium azide and no NaCl. The PRV antigen prepared by (NH4)2SO4 precipitation of viral fluids (42.5 g/100 ml), dialyzed against distilled water, and concentrated to approximately 100-fold of the original volume with polyethylene glycol (mol wt 20,000) provided a good reproducible antigen. The sensitivity of the MIDT was compared with the microtitration procedure of the virus-neutralization (VN) test by assaying 2,203 swine serums for PRV antibodies. An equal percentage of serums was positive in both tests; 419 had VN titers of greater than or equal to 4, and 421 were MIDT positive. Serums (314) that had VN titers of greater than or equal to 16 were all positive by the MIDT. Of serum samples with a VN titer of 8 (53), 50 were MIDT positive, a 94% correlation, and of 52 serums that had VN titers of 4, 36 were MIDT positive, a 69% correlation. In addition, 8 serums that had titer of less than 4 by VN test were positive by MIDT. Seventy-one serum samples were too cytotoxic, markedly hemolyzed, or contaminated to evaluate properly in the VN test; of these serums, 13 were MIDT positive. The MIDT is an accurate, rapid, economical, and sensitive diagnostic test for the detection of PRV antibodies in swine serums.

Duration and biological half-life of passively acquired colostral antibodies to porcine parvovirus.

The duration of passive immunity and biological half-lives of passively acquired antibodies to porcine parvovirus (PPV) were determined in 4 pigs from each of 10 litters. All sows were randomly selected from a herd naturally infected with PPV. At parturition, blood and colostral samples from the 10 sows contained hemagglutination-inhibiting (HI) antibodies to PPV; the HI titers of colostrum were about 5 times higher than that of serum. The HI antibodies in serum and colostrum of sows were resistant to 2-mercaptoethanol, indicating that antibodies were of immunoglobulin G class. Pigs were allowed to suckle, and their blood samples were collected at 2 days of age and every 2 weeks thereafter. At 3 to 4 weeks of age, pigs were weaned and moved to an isolation facility. All pigs had HI antibodies to PPV at 2 days of age. Passively acquired antibodies steadily decreased from the circulation of pigs, and the rate of antibody decrease was similar in all pigs. Antibodies to PPV persisted for about 16 to 24 (mean 21.2) weeks, and all pigs were seronegative at 26 weeks of age. Pigs were susceptible to experimental infection with PPV as early as 1 week after they became seronegative. The biological half-lives of antibodies to PPV, unadjusted and adjusted for body weight gain, were determined to be approximately 19.7 and 29.0 days, respectively.

Antibody response of pigs to inactivated monovalent and bivalent vaccines for porcine parvovirus and pseudorabies virus.

Groups of pigs vaccinated with an inactivated bivalent vaccine containing porcine parvovirus (PPV) and pseudorabies virus (PRV) developed geometric mean titers (GMT) of humoral antibody for each of the viruses as high or slightly higher than those of other groups of pigs that were vaccinated with inactivated monovalent vaccines containing one or the other of the same viruses. An increase in GMT after challenge exposure of vaccinated pigs to live virus indicated that vaccination did not prevent virus replication. However, an indication that replication was less extensive in vaccinated pigs was provided by the following. Although neither vaccinated nor nonvaccinated (control) pigs had clinical signs after exposure to the live PPV, the effect of vaccination was evident by the fact that GMT were higher in nonvaccinated pigs after exposure than they were in vaccinated pigs. Conversely, all pigs exposed to live PRV had clinical signs, but these signs varied between mild-to-moderate and transient for vaccinated pigs to severe and fatal for nonvaccinated pigs.

Development of a nonneuronal cell line derived from porcine spinal ganglia.

A cell line from porcine spinal ganglion (PSPG) tissue was initiated and characterized. The PSPG cell line contained epithelioid, fibroblast-like, and stellate-like cells. There were numerous intercellular communications between cells in the culture. Neuronal cells were not present in the PSPG cell line. The PSPG cell line was aneuploid at the 5th and 45th subculture levels. Seven porcine viruses replicated in cultures of PSPG cells, and 2 pseudorabies virus strains infected the cells after being diluted 10(-7).

Evaluation of field isolates of pseudorabies (Aujeszky's disease) virus as determined by restriction endonuclease analysis and hybridization.

Sixty-seven isolates of pseudorabies virus (PRV) from 13 states were cleaved with 4 restriction endonucleases (RE), and after electrophoresis in agarose, their banding patterns were photographed and evaluated. The deoxyribonucleic acid (DNA) cleavage fragments were designated into regions specified by molecular weight ranges based on lambda phage DNA as a size marker. The 67 PRV isolates were evaluated according to the total number of cleavage fragments, by the number of fragments within designated molecular weight regions, and finally, by the migration of fragments within regions. Four of the 67 PRV isolates (all 4 from California) did not have a 4.1 to 4.6 megadalton HinfI band, but hybridization of the HinfI digests with a 32P probe made with the 4.4 megadalton band hybridized with 2 lighter fragments, 2.5 and 1.9 megadaltons, respectively. The BamHI digests of DNA from some PRV isolates with submolar fragments were hybridized with 32P probes made with fragments from the submolar region and the BamHI E fragment. Both probes hybridized to the submolar region of PRV with BamHI submolar fragments, but only to the trimolar (E, F, and G) band of PRV without submolar fragments in the 4.1 to 7.5 BamHI megadalton region. Epidemiologic evidence was obtained which indicated that a Missouri strain of PRV was transferred to an Illinois swine herd by importation of feeder pigs from Missouri. The results indicate that there are numerous genomically different PRV currently in circulation in the United States and that the combination of RE analysis and DNA hybridization offers useful epidemiologic information to evaluate the various strains.

Isolation of pseudorabies virus from trigeminal ganglia of a latently infected sow.

A 2-year-old sow with a relatively low virus-neutralization (VN) titer (1:8) against pseudorabies virus (PRV) was brought to the National Animal Disease Center for observation and study. The sow was kept in isolation for approximately 6 weeks, and repeated nasal and tonsillar swabs for virus isolation and blood samples for VN tests were obtained during this interval. At the end of 5 weeks' observation, the sow was injected IM with 200 mg of dexamethasone and was euthanatized 1 week later. Parts of the two trigeminal ganglia, tonsillar tissue, and nasal secretions were cultured in porcine kidney cells. The rest of the trigeminal ganglia was extracted with phenol and tested for presence of the PRV-DNA genome by hybridization with tritiated complementary RNA. The PRV was isolated from the trigeminal ganglia only, and the PRV genome was demonstrated in the same tissue. This latently infected sow was a potential shedder of PRV.

Serologic survey for transmissible gastroenteritis virus neutralizing antibodies in selected feral and domestic swine sera in the southern United States.

Serum samples collected from feral and domestic swine (Sus scrofa) in Florida and feral swine in Georgia and Texas were assayed by plaque reduction for their virus neutralizing (VN) antibodies against the porcine transmissible gastroenteritis virus (TGE). None of 560 samples collected from feral swine contained VN antibodies for TGE virus, but experimentally infected feral swine seroconverted. None of 665 samples from domestic swine contained TGE-VN antibodies. These results indicate feral swine are not a significant reservoir for TGE virus in southern states, but are capable of becoming infected and developing VN antibodies against TGE.

Prevalence and transmission of pseudorabies virus in an isolated population of feral swine.

Six hundred sixty-one feral swine (Sus scrofa) from Ossabaw Island, Georgia (USA) were captured, bled, and their sera tested for pseudorabies virus (PRV) antibody during a 6 yr period. Prevalence of seroconversion in females was somewhat higher than in males (10% versus 7%), but the difference was not statistically significant. Adults had a significantly higher prevalence than juveniles (29% versus 1%). An important finding in this study was that seroconversion occurred primarily in the adult feral swine.