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.     

Detection of latent pseudorabies virus in porcine tissue, using a DNA hybridization dot-blot assay

A DNA-hybridization dot-blot technique was developed to detect the presence of pseudorabies virus (PRV) DNA in porcine tissue. Seven 32P-nick translated probes of high specific activity were prepared from transformed Escherichia coli plasmids into which Bacillus amyloliquefaciens H (Bam HI) restriction fragments of PRV-DNA had been inserted. Samples of DNA that had been extracted from porcine tissue or from PRV grown in tissue culture were transferred to nitrocellulose paper, using a microsample filtration manifold and were hybridized to the probes under high-stringency conditions. Under optimal hybridization conditions, the minimum detection amount of PRV-DNA was 10(-11) g, which is equivalent to 1 copy of the PRV genome/80 host cells. Four probes did not show cross hybridization with DNA extracted from tissues of known PRV-negative swine, and these were subsequently used to detect PRV-DNA in infected porcine tissues. Generally, correlation between virus isolation and hybridization data was good for tissues from swine that had died of acute PRV infection. Furthermore, PRV-DNA was present in specific tissues of all 4 seropositive swine that had recovered from pseudorabies and in which no infective virus or viral products were detected at necropsy. Pseudorabies virus DNA was present in the rostralis cerebral cortex (n = 2) or in the medulla oblongata (n = 1) and trigeminal ganglion (n = 1). This probably indicated the portal of entry of the virus into the CNS. In another seropositive pig, there was evidence of a productive infection in the tonsils, although virus was not isolated in a tissue culture system.(ABSTRACT TRUNCATED AT 250 WORDS)     

The response of pigs inoculated with a thymidine kinase-negative (TK-) pseudorabies virus to challenge infection with virulent virus

12 Large-White-Landrace piglets were subdivided in four groups of 3 and housed in separate units. The piglets of three groups were inoculated with the 86/27V 6C2 thymidine kinase negative (TK-) mutant of pseudorabies virus (PRV), by different routes. A second inoculation with the same mutant was given to the pigs 21 days later. The animals of a fourth group were left as uninoculated controls. 21 days following the second inoculation with the TK- mutant all pigs were challenge infected with the virulent PRV. On post challenge day (PCD) 30 all pigs were killed and samples for virus detection and histology were taken from several organs. The inoculated TK- mutant of PRV did not induce any ill effects in the pigs except a transient febrile reaction in some animals. Virus was recovered from nasal swabbings from one pig 2 days after the first inoculation of the mutant. After challenge exposure with virulent PRV, the TK- mutant-inoculated pigs were apparently protected, whereas the control pigs all were severely affected and recovered very slowly over 3 weeks. Virus was isolated from the nasal swabbings from the TK- mutant-inoculated pigs on PCDs 2 and 4, whereas the nasal swabbings from the control piglets were all positive for virus from PCD 2 through PCD 10. DNA analysis of the virus recovered showed a pattern identical to that of the virulent PRV. Histologic lesions were found in the respiratory and the central nervous systems, however, the lesions in the TK- mutant-inoculated pigs were much milder compared to those registered for the control pigs. Virus was not isolated from any of the tissue samples that were tested, but viral DNA with sequences typical of PRV genome was detected by PCR in all samples of trigeminal ganglia from either the TK- mutant-inoculated pigs or from the controls.     

DNA hybridization procedure to detect pseudorabies virus DNA in swine tissue

A DNA hybridization technique was developed to detect the presence of pseudorabies virus (PRV) DNA. P Nick translated probes of high specific activity were prepared from transformed Escherichia coli plasmids into which Bacillus amyloliquefaciens H (Bam H1) restriction fragments of PRV DNA had been inserted. Swine cellular DNA and tissue culture PRV DNA were digested with Bam H1, separated by agarosegel electrophoresis, transferred onto nitrocellulose paper, hybridized to the radioactive probes, and washed under high stringency conditions; autoradiographs were then prepared. Under the optimal hybridization conditions described, the detection limit of these probes was 10(-11)g of PRV DNA. In reconstruction experiments, 3 of the selected probes cross hybridized with digested swine cellular DNA, and 4 probes did not. The addition of polyuridylic acid and polyguanylic acid to the hybridization reactions did not alter the amount of hybridization. The results indicated that this procedure may be useful for studying the latency of pseudorabies viral infection.     

Identification of the cross-reactive antigens between Marek's disease virus and pseudorabies virus by monoclonal antibodies

Among the 33 monoclonal antibodies (MAbs) against pseudorabies virus (PRV) examined, three MAbs (24-17, 74-26, and 8) were found to react with cells infected with Marek's disease virus (MDV)-related viruses by immunofluorescence test. Two of the MAbs (24-17 and 74-26) reacted with the nuclei of cells infected with MDV serotype 1 (MDV1), MDV serotype 2 (MDV2), and herpesvirus of turkeys (HVT), whereas MAb 8 reacted with the cytoplasm of MDV2- and HVT-infected cells. However, none of the MAbs against MDV1, MDV2, and HVT that were examined reacted with PRV-infected cells. None of these three MAbs against PRV reactive with MDV-related viruses cross-reacted with the cells infected with other herpesviruses, such as herpes simplex virus type 1, herpes simplex virus type 2, varicella zoster virus, Epstein-Barr virus, or human herpesvirus 6. Southern-blot hybridization under stringent or less-stringent conditions showed that no significant DNA homology was detected between PRV DNA and MDV DNA.     

Detection of latent pseudorabies virus in swine using in situ hybridization

We have examined methods for detection of pseudorabies virus (PRV) latency in three groups of swine; naturally infected animals obtained from a field case; animals which have been experimentally infected with Becker or Iowa strains of PRV; and single reactors (single seropositive animals within PRV-free herds). In situ hybridization was shown to be more sensitive than explanation/co-cultivation for the detection of latent virus. Nervous tissues, in particular the trigeminal ganglia, were found to be the most reliable source for detecting latent PRV. The presence of latent PRV was not detected in lymphoid tissues examined.     

伪狂犬病毒荧光定量PCR检测方法的建立

根据猪伪狂犬病毒gD基因的序列,设计和合成了一对特异的可用于检测伪狂犬病毒的PeR引物和一条Taqman荧光探针,采用LightCycle 480荧光定量PCR仪,建立了一种可实时定量检测猪伪狂犬病毒的荧光定量PCR技术。该方法的线性范围为1．0×10^1-1．0×10^10拷贝,灵敏度可达2拷贝,比常规PCR高100倍。该方法检测时间短,速度快,仪器的运行时间仅为1h,特异性明显高于常规PCR。对15株猪伪狂犬病毒进行了检测,结果均为阳性;与猪细小病毒和鸭瘟病毒无非特异性反应。与病毒分离培养和常规PeR相比较,该方法具有快速、灵敏、特异、定量、重复性好的优点,可望用于,临床上伪狂犬病的检测和病毒分布的研究等。     

猪伪狂犬病病毒潜伏感染检测方法研究进展

猪伪狂犬病是由伪狂犬病病毒引起的 ,是以仔猪的发病死亡和怀孕母猪繁殖障碍为特征的猪病 ,是危害养猪业的重要疫病之一。该病在世界上分布广泛 ,并有不断蔓延扩大的趋势。任何年龄的猪在耐过伪狂犬病病毒急性感染后均能形成潜伏感染 ,并可在体内终生潜伏 ,且不表现临床症状 ,在一定条件下 ,潜伏状态的病毒能被激活 ,引起复发性感染并向外散毒。这种伪狂犬病病毒潜伏 -激活循环机制决定了伪狂犬病病毒在猪群中的永远存在。猪一旦感染必须视为伪狂犬病病毒散播的潜在来源。因而对潜伏感染猪的剔除对于根除伪狂犬病病毒感染具有重要意义。国内外对潜伏感染的检测方法主要有鉴别血清学诊断、潜伏病毒的激活与检测、组织块培养技术、核酸探针技术以及PCR技术。本文主要综述了这几种方法的研究情况 ,并比较了其优缺点     

Polymerase chain reaction amplification of pseudorabies virus DNA from acutely and latently infected cells

A characteristic of alphaherpesviruses, including pseudorabies virus (PRV), is that the acute phase of the disease is followed by lifelong latency. Latently infected animals are asymptomatic but can transmit reactivated virus. Corticosteroid administration, tissue explanation, blot- and in situ hybridizations have been used to demonstrate the presence of latent PRV infections. The use of blot hybridization as a convenient method for defining the incidence of PRV infections in swine herds has been hampered by the detection limit of this method. The objective of this study was to increase this sensitivity of blot hybridization by polymerase chain reaction (PCR) amplification of target sequences. Two sets of 20-mer primers were synthesized and used to amplify gX and gII glycoprotein gene sequences in two different strains of PRV. The specificity of the amplification was verified by Southern blot hybridization and restriction endonuclease analysis of the amplified fragments. Amplification of target sequences by PRC increased their detection limit by a factor of at least 10(5). Porcine ganglion samples, in which latency had been demonstrated by in vitro explanation, were analyzed by PCR together with positive and negative controls. Duplicate slot blot analyses of a portion of the amplified products were used to demonstrate latency in seven of eight samples. It was concluded that blot hybridization of PCR amplified DNA appears to be both a sensitive and convenient method for the detection of PRV induced latency.     

Rapid detection of pseudorabies virus genomic sequences in biological samples from infected pigs using polymerase chain reaction DNA amplification

The presence of the pseudorabies virus (PRV) genome in infected hosts has previously been studied by standard hybridization techniques, which showed the viral genome to be present at very low levels in infected tissues. The recently introduced polymerase chain reaction (PCR) procedure provides an alternative and rapid means of amplifying small quantities of specific DNA sequences. We applied this technique to a study of pigs infected by PRV. The sequence selected for amplification consisted of 222 base pairs lying in the gene coding for the glycoprotein gp50. We used a pair of 20-mer oligonucleotides flanking this sequence as primer and a cloned Stu-Nde fragment containing the sequence as target DNA. To avoid the tedious DNA extraction procedure we performed PCR directly on disrupted cells and detected specific amplification after 25 cycles of PCR with the thermostable Taq DNA polymerase. Amplified products were detected by gel electrophoresis directly. Nasal samples from experimentally and naturally infected pigs were tested by this PCR technique. When compared with tissue culture and serological tests, detection by gel electrophoresis of PCR amplified fragments provided excellent specificity and sensitivity. We concluded that PCR amplification will be a valuable tool for rapid diagnosis of PRV infection in pigs, taking less than 1 h to complete.     

伪狂犬病病毒野毒荧光定量PCR检测方法的建立

根据伪狂犬病病毒gE基因的序列,设计和合成了一对特异的可用于检测伪狂犬病病毒野毒的PCR引物和一条Taqman荧光探针,采用Li ght Cycl e 480荧光定量PCR仪,建立了一种可实时定量检测伪狂犬病病毒野毒的荧光定量PCR技术。该方法的线性范围为1.0×102～1.0×1010拷贝,灵敏度可达4拷贝。检测速度快,仪器的运行时间仅为1 h。对13株猪伪狂犬病病毒野毒进行了检测,结果均为阳性;与伪狂犬病gE基因缺失疫苗、猪细小病毒和鸭瘟病毒无非特异性反应。与病毒分离培养比较,该方法具有快速、灵敏、特异、定量、重复性好等优点,可望用于临床上伪狂犬病病毒野毒与疫苗毒的区分,伪狂犬病病毒野毒的检测和病毒分布的研究等。     

Investigation of sites of pseudorabies virus latency, using polymerase chain reaction.

Pseudorabies virus (PRV) latency was investigated, using polymerase chain reaction (PCR). A PCR protocol was developed that specifically amplified a 217-base pair sequence within the gene encoding the essential glycoprotein gp50 of PRV. Using this PCR procedure, the gp50 sequence was amplified from tissues of pigs infected with various doses of PRV (Becker strain). At postinoculation day 64, viral isolation was performed on nasal swab specimens and homogenates of tonsils and trigeminal nerve ganglia obtained from 11 PRV-convalescent, seropositive pigs. Results were negative in all cases. By use of PCR, 11 of 11 pigs had PRV-positive trigeminal nerve ganglia and brain stem, 10 of 11 pigs had PRV-positive tonsils, and 9 of 11 pigs had PRV-positive olfactory bulbs.     

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.     

区分猪伪狂犬病病毒gE基因缺失疫苗株和野毒株的gE-PCR方法的建立

根据编码猪伪狂犬病病毒gE基因保守序列,设计合成一对引物,通过优化PCR反应条件,成功地从猪伪狂犬病病毒感染的细胞中扩增出预期的178bp片段,而猪繁殖与呼吸综合征病毒、猪细小病毒、猪瘟病毒、猪流感病毒和猪伪狂犬病病毒gE基因缺失株均未扩增出相应的片段,经PCR扩增产物测序鉴定,证实了该扩增片段为预期目的片段;敏感性试验表明,该体系可检测到102TCID50的猪伪狂犬病病毒。本方法的建立能够区分基因缺失疫苗免疫猪和野毒感染猪,使猪伪狂犬病病毒的检测更为快速、准确。     

Comparison of dot blot hybridization, polymerase chain reaction, and virus isolation for detection of bovine herpesvirus-1 (BHV-1) in artificially infected bovine semen.

Bovine semen samples spiked with bovine herpesvirus 1 (BHV-1) were used to compare dot blot hybridization, polymerase chain reaction (PCR), and virus isolation for detection of BHV-1 in bovine semen. The PCR amplification used primers targeting the BHV-1 thymidine kinase gene and a nucleic acid releasing cocktail (GeneReleaser); the PCR product was used as the DNA probe in dot blot hybridization; virus isolation was done in primary bovine fetal testis (BFT) cell cultures. Semen diluted 1:20 in tissue culture medium had the least cytotoxicity and inhibition of viral cytopathic effects in BFT cells, allowing detection of 1 TCID50/100 microL of BHV-1 suspension by virus isolation. The presence of foreign DNA such as bovine sperm DNA or salmon sperm DNA increased the sensitivity of dot blot hybridization in detecting BHV-1, allowing detection of 20,000 TCID50/100 microL of neat semen. The inhibition of PCR amplification of BHV-1 DNA in bovine semen was eliminated by diluting the samples 1:20 in tissue culture medium. The best PCR amplification was obtained when semen was diluted 1:20 and when a reaction buffer of pH 9.0, with 1.0 mM MgCl2 was used. Under these conditions, the PCR followed by ethidium bromide staining of agarose gels could detect 1 TCID20/100 microL of sample, whereas PCR followed by Southern blot hybridization could detect 0.01 TCID50/100 microL of sample.(ABSTRACT TRUNCATED AT 250 WORDS)     

Detection of infectious laryngotracheitis virus infected cells with cloned DNA probes.

A genomic library of infectious laryngotracheitis virus (ILTV) DNA BamH1 fragments was prepared and two cloned fragments were evaluated for their potential as probes for the detection of ILTV infected cells. The virus was purified by a modified sucrose density gradient procedure for the isolation of pure ILTV DNA. A genomic library was constructed using BamH1-digested ILTV DNA and pGEM7 as a vector. A 1.1 kb cloned BamH1 fragment of ILTV DNA was tested in a slot or dot blot assay for the detection of ILTV infected cells. The limit of detection for this probe was at least 0.12 ng of pure ILTV DNA. The probe was able to identify both chicken embryo liver (CELi) cells and choriallantoic membranes infected with ILTV. Chicken embryo liver cells infected with several field isolates and a vaccine strain of ILTV were positive by dot blot analysis using this probe. Some qualitative differences in the degree of hybridization to cells infected by different ILTV isolates were observed. Uninfected cells and cells infected with fowlpox virus, turkey herpesvirus, Marek's disease virus or Newcastle disease virus were negative by the same assay. Compared with the 1.1 kb fragment, a larger 6 kb cloned BamH1 fragment of ILTV DNA showed a stronger hybridization signal to DNA from ILTV infected cells.     

Experimental infection of pigs with a thymidine kinase negative strain of pseudorabies virus

Sixteen 20 day old pigs, devoid of neutralizing antibody to pseudorabies virus (PRV), were divided into two groups of eight, and the animals of each group were housed in a separate unit. In each group 6 pigs were inoculated intranasally with the thymidine kinase (TK⁻) mutant (Group 1) or the field strain of PRV (Group 2), each pig receiving an inoculum of 4 ml. The remaining 2 pigs in each group served as uninoculated controls. The only clinical sign observed in the pigs of Group 1 was a transient febrile reaction, in the case of six pigs inoculated with the TK⁻ mutant of PRV, whereas no signs of disease were seen in the uninoculated controls. The virus was isolated from the 6 infected pigs of the group only on post infection day (PID) 2, whereas it was never isolated from the controls. By contrast, the pigs of Group 2, had a severe clinical response and one, among those that were inoculated with the field strain of the PRV, died on PID 9. Virus was consistently isolated from all pigs of Group 2, inoculated and control. On PID 30 all pigs, i.e. the 8 of Group 1 and 7 of the Group 2 which survived to the infection, were subjected to dexamethasone (DMS) treatment. After DMS treatment virus was never isolated from the nasal swabbings obtained from the pigs of Group 1, whereas it was consistently isolated from pigs of Group 2. After 30 d from the start of DMS treatment the pigs were killed and several tissues were collected from each pig for virus detection, by isolation in tissue culture and by PCR analysis. At necropsy no lesions were found in pigs of Group 1, whereas acute pneumonia and gliosis in the trigeminal ganglia were observed in pigs of Group 2. Virus was never isolated from any of the tissues taken from pigs of both, Group 1 and Group 2, nevertheless sequences of PRV were detected by PCR analysis in the trigeminal ganglia of the pigs of both Groups.     

Pathogenicity of a modified-live pseudorabies vaccine virus in lambs

Subcutaneous injections of modified-live pseudorabies virus (PRV) vaccine into lambs caused clinical signs and death within 1 week after injection in 4 of 5 inoculated lambs. The clinical signs included depression, high fever, muscle fasciculations and convulsions, occasionally followed by death within 48 hours of the initial clinical signs. Histologic examinations and virus isolation procedures demonstrated PRV in the CNS of infected lambs. Sera from sick lambs remained negative for PRV antibodies. Two subsequent serial passages of the vaccine virus in lambs resulted in similar clinical signs and death in 6 of 10 inoculated lambs. Again, PRV was isolated from tissues of sick lambs, and the histopathologic findings were characteristic of the disease. Affected lambs remained seronegative to PRV, as did lambs that remained clinically normal after inoculation. There was no evidence of PRV transmission to uninoculated lambs and pigs housed with the infected lambs.     

Detection of bovine adenovirus nucleic acid sequences in nasal specimens by biotinylated DNA probes.

Bovine adenovirus infection has been detected in experimentally infected lambs by applying the rapid and simple DNA detection method of direct filter hybridization (DFH). Three fragments of BAV-2 DNA were obtained by molecular cloning and labelled with biotin. Clone 207, representing an EcoRI fragment between coordinates 35 to 55 of the viral genome, showed the highest sensitivity to detect adenovirus DNA, thus, this probe was applied on nasal cells from the lambs. Comparative tests revealed a concordance over 97% between the results of conventional virus isolation and of the DFH method. Virus isolation required several weeks to be completed, whereas the DFH method gave results within 10 hours. Considering its simplicity, speed and economy, the DFH method is recommended as a practical diagnostic tool for the direct detection of adenoviruses in clinical specimens.