Serological response of pigs infected with Aujeszky's disease virus

The temporal development of antibody in four groups of pigs infected with different Aujeszky's disease virus isolates was examined. The enzyme-linked immunosorbent assay detected antibody by five to six days after infection and the antibody-dependent cell-mediated cytotoxicity assay detected antibody seven to nine days after infection. Neutralising antibody was first detected nine to 10 days after infection, whereas assays measuring complement mediated antibody lysis did not detect antibody until 10 days after infection. These results are discussed in terms of their importance to the diagnosis of and recovery from Aujeszky's disease.     

Studies on the role of humoral and cell-mediated immunity in pigs after vaccination with Aujeszky's disease virus

Humoral and cellular immunity in pigs vaccinated twice with Aujeszky's disease virus (ADV) was studied by seroneutralizing test and direct leucocyte migration inhibition technique. Significant migration inhibition of leucocytes (LMI) was found on the fifth day, whereas specific antibodies began to appear at that time only in very low titers. Anamnestic reaction due to the second injection of ADV did not bring about a significant increase of migration inhibition of leucocytes, instead the level of antibodies elevated markedly.     

Multiplication and immunogenicity of a temperature-sensitive and thymidine kinase-deficient strain of Aujeszky's disease virus in pigs.

Hysterectomy-produced colostrum-deprived 5- and 27-day-old pigs were inoculated intramuscularly (IM) or intranasally (IN) with the temperature-sensitive and thymidine kinase-deficient ZHtsTK- strain of Aujeszky's disease virus (ADV), and the nasal swabs and organs of the pigs were periodically collected for virus isolation. No abnormal clinical signs were observed in these pigs, except for a mild febrile response. Viral shedding in the nasal swabs with low titers was detected in the pigs inoculated IN between postinoculation day (PID) 1 and 5, but not in those of the pigs inoculated IM. No contact infection, however, occurred in the cohabiting pigs. Viruses with low titers were isolated only from the muscles and lymph nodes at the site of inoculation in the pigs inoculated IM on PID 2 and 4, but not from any organs of the pigs inoculated IN. To investigate the ability of the ZHtsTK- strain to establish a latent infection in pigs, the pigs inoculated IM or IN with the ZHtsTK- strain were treated with prednisolone. No virus was detected in the trigeminal ganglia or the nasal swabs collected after prednisolone treatment by the cocultivation method. The immunological evaluation demonstrated that immunization of pigs with this strain was effective in preventing clinical signs caused by ADV infection. The duration of virus shedding was markedly shortened in immunized pigs, particularly in those immunized twice and the total quantity of virus recovered from immunized pigs was reduced in comparison with unimmunized pigs.     

Antibodies to Aujeszky's disease virus in pigs immunized with purified virus glycoproteins

Antibodies to Aujeszky's disease virus (ADV) glycoproteins gII, gIII, and gp50 were compared using four in vitro tests. Antibodies generated by vaccination with a modified-live vaccine (MLV) were also compared. The serological assays employed were: serum neutralization test (SNT), complement facilitated serum neutralization test (C'SNT), complement-mediated cytolysis and antibody dependent cellular cytotoxicity (ADCC). Pigs were immunized with single glycoproteins twice 14 days apart, or once with the modified-live vaccine. Fourteen days after the second immunization, sera were collected. Virus neutralizing activity (SNT) was demonstrated in the sera from all pigs immunized with gp50 and in one out of three immunized with gIII. Sera from the MLV group all had neutralization titers higher than animals immunized with single glycoproteins. Addition of guinea pig complement to the serum neutralization test (i.e., C'SNT) produced an enhancement of antibody titers in all groups except the pigs immunized with gIII. The complement-mediated cytolysis test rendered antibody titers similar in magnitude for all pigs immunized with single glycoproteins, but slightly lower than values for MLV vaccinated pigs. ADCC activity was clearly displayed in sera from pigs immunized with gIII or vaccinated with MLV, whereas sera from pigs immunized with gII or gp50 had a minimal response. The results indicate that the relative efficiency of antibodies against ADV glycoproteins in protection should be considered for selecting or producing gene-deleted strains for use in vaccine production.     

Horizontal transmission of Aujeszky's disease virus from sheep to pigs

Eight 2-month-old merino lambs were inoculated intranasally with different (10(2.0)-10(5.0)TCID50) amounts of Aujeszky's disease virus (ADV). Electron microscopic studies indicated that ADV replicated in extra-neural sites, in the epithelial cells of the mucosa of the upper and lower respiratory tract. Although the virus was excreted continuously in nasal discharges, horizontal transmission to contact lambs failed. The surviving exposed and contact lambs had no demonstrable antibodies against ADV and they were susceptible when challenged by ADV. However, the virus was transmitted to susceptible pigs in contact with the exposed lambs. One of the five contact pigs showed characteristic clinical signs of Aujeszky's disease, developed a nonsuppurative meningoencephalomyelitis and ADV was recovered from the brain, nasal discharge and other organs. Restriction enzyme analysis of DNA from this virus confirmed the sheep origin of the isolate. The other 4 pigs seroconverted. ADV infection in sheep is therefore a possible source of infection for pigs, but the lack of horizontal transmission in sheep was confirmed.     

Infection of pigs by Aujeszky's disease virus via the breath of intranasally inoculated pigs

Aujeszky's disease is a worldwide problem in the pig industry. In this experiment, four pigs chosen to act as shedder pigs were intranasally infected with Aujeszky's disease virus. Next, on three consecutive days, eight recipient pigs were exposed to the breath of a pair of shedder pigs via a mask-to-mask module. Except for the virtual absence of CNS signs, shedder pigs expressed clinical signs that were similar to pigs infected naturally or experimentally. Only mild respiratory signs occurred in recipient pigs, but all were infected by aerosols of Aujeszky's disease virus as evidenced by seroconversion. The pig is a much more sensitive indicator of airborne virions than our aerosol collection methods. We conclude that the mild respiratory disease acquired by the aerogenous route in recipient pigs is an easily managed model for studying the transmission of airborne respiratory infections and the immune responses to this type of infection.     

猪伪狂犬病活疫苗(Bartha K61株)对变异株的保护效力

本研究旨在检测仔猪免疫猪伪狂犬病活疫苗(Bartha K61株)后,抵抗伪狂犬病病毒(PRV)变异株攻击的保护效果。取4~6周龄PRV抗体阴性仔猪,接种猪伪狂犬病活疫苗,1周后用PRV变异株(AH02LA株)攻毒,检测攻毒后临床症状、直肠温度、鼻腔排毒和肺部病变。疫苗免疫组在免疫后7 d均可以检测到gB抗体。攻毒对照组攻毒后出现典型伪狂犬症状,发病率为100%,死亡率为60%,所有猪只鼻拭子均检出排毒,所有猪只肺部均有出血、淤血等病变。免疫组的猪只攻毒后,所有猪只均未出现明显临床症状,部分猪只鼻拭子检出排毒,排毒持续时间缩短,排毒量显著减少,所有免疫猪只肺部未见明显病变。结果表明:伪狂犬病活疫苗免疫猪后对PRV变异株的攻击具有良好的保护效果。     

Functional antibody responses in pigs vaccinated with live and inactivated Aujeszky's disease virus

Functional antibody tests, including virus neutralising activity of serum, antibody dependent cellular cytotoxicity and complement mediated lysis, were used to measure the response of pigs given either live or inactivated Aujeszky's disease virus vaccines. Pigs were then challenged with virulent Aujeszky's disease virus and antibody responses were analysed and found not to correlate with protection. Reasons for this lack of correlation are discussed and it is suggested that these results indicate that more emphasis should be placed on measuring the local immune response.     

Infection of pigs by aerosols of Aujeszky's disease virus and their shedding of the virus

On three consecutive days, six pigs were exposed for 15 minutes to aerosols of Aujeszky's disease virus. The total estimated dose was 4·5 log₁₀ 50. Within each isolation room, a sentinel pig was placed on a deck two feet away from the infected pig. The breath of the pigs that had inhaled the aerosols was collected on days 3, 7 and 13. The respiratory and other clinical signs of the infected pigs resembled those in field cases of Aujeszky's disease. All the pigs infected with Aujeszky's disease virus seroconverted within seven to 10 days after infection. Among the sentinel pigs, clinical signs were minimal and only three seroconverted.     

Tonsillar changes in pigs given pseudorabies (Aujeszky's disease) virus

All of the eight 5-day-old pigs orally given pseudorabies (Aujeszky's disease) virus developed tonsillitis. The initial changes occurred in the subepithelial area between the lymphoid nodule and the crypt epithelium, showing a characteristic pattern of necrosis. The necrosis became more severe and gained access into the lymphoid nodule and crypt epithelium. Coincident with the histopathologic changes, numerous specific immunofluorescences were detected, first in the nucleus and in some parts of the cytoplasm of cells distributed in the subepithelial area. The fluorescence subsequently spread into adjacent lymphoid nodules and crypt epithelial cells. Ultrastructurally, many enveloped virus particles were detected in the center of the necrosis. Thereafter, the crypt epithelial cells also underwent degeneration, and a small number of virus particles were detected in the nucleus of the degenerating epithelial cells. In the more advanced stage, the enveloped virus particles were discharged into the crypt lumen.     

Effect of experimental infection with pseudorabies (Aujeszky's disease) virus on pigs with maternal immunity from vaccinated sows.

Live-virus and inactivated-virus vaccines were used to immunize sows against pseudorabies (Aujeszky's disease) virus. To test the efficacy of the vaccination, 53 pigs of different ages were taken from the 1st and the 2nd litters of vaccinated sows and placed separately in isolation units. The pigs were challenge exposed with virulent pseudorabies virus and examined for clinical signs, virus excretion, and serologic reaction. The challenge inoculum caused severe nervous or respiratory signs of disease in 12 of the 13 control pigs, with a mortality of 76%. The pigs from the 1st litters of sows vaccinated with the live-virus vaccine did not become sick, whereas 2 of the 9 pigs (22%) from the 2nd litters had clinical signs and died of pseudorabies. All pigs from sows vaccinated with the inactivated-virus vaccine remained healthy. The results of virus isolation from oronasal swabs, combined with the serotest results, indicated that challenge exposure of all except 1 of the pigs resulted in a subclinical infection with the formation of active immunity.     

Immunoperoxidase study of Aujeszky's disease in pigs

Viral antigen was detected by an immunoperoxidase technique in histological sections from pigs with Aujeszky's disease. The antigen was found mainly in association with focal necrosis in the cerebellum, tonsils, oral and nasal mucosa, salivary glands, lungs, liver, kidneys, pancreas, spleen and adrenal glands. Cells at the margin of the necrotic foci especially were strongly positive. Viral antigen was also demonstrated in the cerebral cortex and in the brain stem. Two types of intranuclear inclusion bodies were found to contain viral antigen and one type also contained viral nucleic acids. Inflammatory cells usually contained no viral antigen. The possible significance of some of these infected tissues in the excretion of the virus is discussed.