Immunohistochemical detection of antigen in lamb tissues naturally infected with sheeppox virus

The present study describes the detection of sheeppox virus antigen in various lamb tissues, using an immunohistochemical technique, in sheeppox cases which occurred naturally. Sheeppox viral antigen was detected in the cytoplasm of sheeppox cells and degenerated epithelial cells of the skin, lungs and digestive tract involving typical sheeppox lesions. Nuclear staining was also observed in some typically deformed nuclei of sheeppox cells. The immunostaining of sheeppox virus showed a correlation with the presence of sheeppox cells and degenerated epithelial cells resembling them. Additionally, in order to confirm the presence of sheeppox virus in the skin and lung samples, direct electron microscopy was performed and sheeppox virus was only demonstrated in two skin samples.     

Diagnosis of swine influenza with an immunofluorescence technique using monoclonal antibodies

Direct diagnosis of swine influenza infection by an indirect immunofluorescence technique using anti-nucleoproteine monoclonal antibody was compared with virus isolation. Five 8-week-old pigs were inoculated with 2 x 10(7) EID50 of strain A H1N1Sw/4115/85. Clinical signs developed in only three pigs. Antigen was detected in nasal epithelial cells obtained from all animals the first day after inoculation; the antigen was detected in one pig 6 days after the infection. Fluorescence was present in the nucleus, nucleolus and cytoplasm of infected cells. The indirect immunofluorescence test was specific and as sensitive as virus isolation in embryonated eggs, allowing a rapid diagnosis that could be achieved within hours.     

Fluorescent antibody test for rapid diagnosis of coronaviral enteritis of turkeys (bluecomb).

Intestinal tissues obtained from coronavirus-infected embryos and turkeys were examined by fluorescent antibody tissue section technique (FAT). Evidence of viral antigen was demonstrated in the cytoplasm of the intestinal epithelial cells covering the villi. Embryo intestines that were examined from 24 to 96 hours after inoculation were positive for immunofluorescence (IF), whereas bursa of Fabricius was negative. Poults hatched from infected embryos were examined at 2 days of age and were positive for IF. Coronaviral antigen was detected by FAT in the cytoplasm of intestinal epithelial cells of the jejunum, ileum, duodenum, and cecum in all turkeys that were examined from 24 hours to 28 days.     

Diagnosis of swine influenza with an immunofluorescence technique using monoclonal antibodies

Summary

Direct diagnosis of swine influenza infection by an indirect immunofluorescence technique using anti‐nucleoproteine monoclonal antibody was compared with virus isolation. Five 8‐week‐old pigs were inoculated with 2 × 107 EID₅₀ of strain A H₁N₁ Sww//4115/85. Clinical signs developed in only three pigs. Antigen was detected in nasal epithelial cells obtained from all animals the first day after inoculation; the antigen was detected in one pig 6 days after the infection. Fluorescence was present in the nucleus, nucleolus and cytoplasm of infected cells. The indirect immunofluorescence test was specific and as sensitive as virus isolation in embryonated eggs, allowing a rapid diagnosis that could be achieved within hours.     

Comparison of the sensitivity of laboratory animals and tissue cultures to infection with Aujeszky's disease virus]

In mice and guinea-pigs high susceptibility was demonstrated following i. c. administration of the virus, approximately equalling to that of rabbits and tissue cultures. Also a relatively high susceptibility of guinea-pigs was demonstrated, with very distinct clinical symptoms of the disease, as compared with mice and rats after the other manners of infection. On the basis of the results obtained white mice were utilized for routine diagnostic of Aujeszky disease. After i. c. administration of positive, virus-containing material encephalitis develops with a rapid exitus occurring 12-24 hours earlier than in the rabbits. In brain tissue antigen was always demonstrated by immunofluorescence examination. Along with the biological experiment replicas of pig organs were examined by immunofluorescence method. Maximum of positive yellow-green fluorescence is found in the cytoplasma of epithelial tonsillar cells, sporadically in the cell nuclei. Epithelial cells are deformed according to the infection degree. The amount of antigen in the brain tissue is not so pronounced as in the tonsillar tissue, yet in animals with clinical pathological symptoms the antigen was always demonstrated.     

Lesions in clinically healthy cattle persistently infected with the virus of bovine viral diarrhea--glomerulonephritis and encephalitis

Four clinically healthy cattle persistently infected with the virus of bovine viral diarrhea were examined for viral antigen and lesions. Antigen was seen by direct immunofluorescence in cytoplasm of the neurons of the brain and cervical part of the spinal cord, cells and basement membrane of renal glomeruli, reticular cells of lymph nodes and spleen, epithelial cells of small intestinal crypts and renal and testicular tubules, and endothelial cells of blood vessels. Infected neurons were pyknotic and surrounded by astrocytes and macrophages. A few blood vessels in the brains were cuffed with mononuclear cells. Basement membranes of renal glomeruli were irregularly thick with eosinophilic material, and mesangial cells in the glomeruli were plentiful. The virus had a direct effect on some tissues, but was restricted in its cytopathogenicity and was not eliminated by defense mechanisms of the host. Renal glomerular lesions were believed to have an immunologic basis.     

Cultivation of bovine adenovirus type 3 in tracheal organ cultures

A growth curve study of the WBR-1 strain of bovine adenovirus type 3 (BAV-3) in bovine foetal tracheal organ cultures showed that the virus replicated at high titres, was mainly cell-associated and persisted in the cultures. The histopathological changes were characterized by the progressive swelling, rounding and shedding of the epithelial cells which often showed intranuclear inclusions. The indirect immunoperoxidase reaction demonstrated that the virus replicated only in the epithelial cells of the organ cultures. Ultrastructural studies demonstrated that BAV-3 induced three different types of nuclear inclusions in the epithelial cells. A network of highly electron-dense, finely granular material was interspersed with patches of granular material of low electron density in the centre of the infected nuclei. In some nuclei, there were also some small circular very dense bodies near the central inclusion. The virions were either dispersed or packed into crystals, and they were released into the cytoplasm through breaks in the nuclear membrane. These ultrastructural changes were comparable with those induced by other oncogenic adnoviruses.     

Detection of fowlpox virus DNA by in situ hybridization using a biotinylated probe

In situ hybridization was applied to detect fowlpox virus (FPV) DNA in formalin-fixed paraffin-embedded sections of the skin from infected chickens by using a biotinylated probe and a streptavidin-alkalinephosphatase conjugate. The immunohistochemical examination was applied to compare the distribution of the FPV DNA to that of related antigenic protein in serial sections. In the infected epithelial cells, FPV DNA was detected in cytoplasmic inclusion bodies and in the rest of cytoplasm. Likewise, immunohistochemical examination revealed the virus antigen in cytoplasm. Ultrastructurally, virions were observed in the cytoplasmic inclusion bodies, and immature virus particles were in the rest of the cytoplasm. The study proved restricted distribution of FPV DNA in the cytoplasm.     

鸡传染性支气管炎病理形态学及发病机理的研究

１５０只１８日龄雏鸡随机分为两组，试验组９０只接种传染性支气管炎病毒（ＩＢＶ－Ｍ４１）后３５天内分３０批依次于不同时间扑杀，作组织病理学、超微结构及病毒抗原位检查，对照组６０只作相同的检查。结果表明，ＩＢＶ攻击的靶器官是气管，气管的病变表现为粘膜上皮细胞的损伤和脱、残留的在皮细胞增殖形成复层上皮、粘膜固有层及粘膜下层大量淋巴细胞浸润及粘膜逐渐恢复的相互连续的病理过程。肺脏初级、次级支气管也有类似的     

The pathology of concurrent bovine viral diarrhoea and infectious bovine rhinotracheitis virus infection in newborn calves

Concurrent bovine viral diarrhoea (BVD) and systemic infectious bovine rhinotracheitis (IBR) are reported from two neonatal (11 and 15 days old) calves. The diseases occurred sporadically in a large-scale herd which may have been due to the calves' heterogeneous immunobiological status. Gross pathological and histopathological examinations revealed focal interstitial pneumonia with acidophilic intranuclear inclusions in the alveolar epithelial cells and necrotic foci in the liver with a few intranuclear inclusions in the hepatocytes. There were subserous haemorrhages in the forestomachs and intestine, necrotic changes in the rumen, enteritis, lymphocytic necrosis in the Peyer's patches, and fibrinoid necrosis in the wall of some of the neighbouring blood vessels. BVD virus was demonstrated by immunofluorescence (IF), whereas IBR virus by electron microscopy, immunofluorescence and virus isolation.     

Immunohistochemical detection of parainfluenza type 3 virus antigens in paraffin sections of pneumonic caprine lungs

Pneumonia is a leading cause of loss to ruminants throughout the world. Parainfluenza type-3 virus (PI-3) is one of the most important respiratory pathogens of bovine and ovine. In this study, prevalence of PI-3 virus infection as causative agent of pneumonia in goats was investigated. For this purpose, a total of 1505 goat lungs slaughtered in Bitlis and Van slaughterhouses were grossly examined and pneumonia was detected in 74 cases (4.91%). Lesions were more frequently encountered in anteroventral lobes than caudal lobes. With the exception of verminous pneumonia observed in 32 cases, immunohistochemical examinations were performed on 42 pneumonic lungs. Formalin-fixed and paraffin-embedded lung tissue samples were immunohistochemically stained by the avidin-biotin-peroxidase complex procedure using polyclonal antibodies to detect PI-3 viral antigens. The presence of PI-3 viral antigens was detected in 28 (66.6%) of 42 pneumonic lungs. Viral antigens were found most frequently in the cytoplasm of bronchiolar epithelial cells, type II pneumocytes, and less frequently in the epithelial cells of bronchial glands, syncytial cells, alveolar macrophages, and lymphocytes and plasma cells. In conclusion, it was found that there was a close relationship between the pneumonia in goats and the presence of PI-3 viral antigens. Incidence of PI-3 virus in pneumonic lungs of goats was detected to be very high in the present study performed in the region of Bitlis and Van, Turkey.     

Detection of intracellular canine distemper virus antigen in mink inoculated with an attenuated or a virulent strain of canine distemper virus

Using an indirect immunofluorescence technique, the distribution of viral antigen in various tissues and blood mononuclear leukocytes was studied in wild mink, either vaccinated with an attenuated vaccine strain of canine distemper virus (CDV) or experimentally inoculated with the virulent Snyder-Hill strain of CDV. Viral antigen was detected in cells of the lymphoid system 6 to 12 days after vaccination. From 2 to 3 days after inoculation with the virulent strain, CDV antigen was demonstrated in cells of the lymphoid system and, during the incubation period, the antigen had spread to the epithelia and brain at days 6 and 12, respectively. In clinical cases of acute fatal canine distemper, the viral antigen was detected in a wide variety of tissues, including the cells of the lymphoid system, epithelial cells of skin, mucous membranes, lung, kidney, and cells of the CNS. The diagnostic importance of CDV antigen detection is discussed on the basis of these findings.     

Cultivation and partial characterization of bovine astrovirus

Bovine astrovirus serotype 2 (US2) was adapted to primary neonatal kidney cell (NBK) cultures by the addition of 50 micrograms ml-1 of trypsin in the medium. Infectious virus was released from the cells within 7 days post-infection in early passages and within 3 days in later passages. In the absence of trypsin, neither passage of infected cells nor release of infectious virus occurred. The virus was shown to be similar to the fecal astrovirus by a neutralization test and by ultrastructural studies of infected cells. Primary embryo bovine kidney (EBK) and NBK cell cultures supported infection with both fecal and tissue culture adapted (TCA) astrovirus. The time-related development of infection, as studied by immunofluorescence, was similar for both fecal and TCA astrovirus and for both cell culture types. The first indication of viral infection and expression of viral antigens occurred at 7 h post-infection and was characterized by the appearance of a diffuse faint immunofluorescence (IF) of the cytoplasm. Soon after, two or three brilliant IF granules were observed in the nucleus, which appeared to involve the nucleoli. Subsequently, dense granular IF was seen in the perinuclear region of the cytoplasm, which later extended to involve all the cytoplasmic area. In both EBK and NBK cultures infected with either fecal or tissue culture adapted astrovirus, only a minority of cells became infected, even when the multiplicity of infection exceeded one. Occasionally 10-20% of cells were infected, but in most cultures the proportion did not exceed 2% and in NBK cultures, from 3/9 calves, no infected cells were observed. The virus did not infect bovine cell lines. Infectivity of the virus was not removed by treatment with chloroform, and iododeoxyuridine and actinomycin D when added to the medium, did not block replication. Masses of virions were observed by electron microscopy in discrete areas in the cytoplasm, with similar distributions as the viral antigen foci as seen by IF. The mean diameter of the virions was 34 nm. In conclusion, bovine astrovirus lacks both essential lipids and an envelope, probably has an RNA genome, may have a nuclear phase of replication involving the nucleoli which is not blocked by DNA inhibitors, and has a selective cell tropism.     

人工感染IBDV鸡法氏囊的电镜研究

通过透射电镜系统观察了人工感染传染性法氏囊病病毒（ＩＢＤＶ）后鸡法氏囊各类细胞的病理变化。感染后１２￣２４ｈ,病毒粒子主要见于髓质淋巴细胞中,细胞中可见到大量纤维样病毒发生基质及无囊膜包围的大型病毒晶格,细胞核染色质浓缩,核中出现纤维样结构。感染后３６ｈ,淋巴细胞开始大量裂解死亡。无囊膜包围的病毒晶格也出现于髓质网状细胞中,被感染的网状细胞并不裂解,而表现出细胞凋亡的特征：染色质固缩呈颗粒块状,胞     

Electron microscopy of Aujeszky's disease virus in explants of Gasser's ganglion from pigs with a latent infection

Different developmental stages of the Aujeszky's disease virus were demonstrated by electron microscopy in the ultra-thin slices by the cultivated fragments of the Gasserian ganglion (G. g.) of two pigs latently infected with the Aujeszky's disease virus (ADV). In a pig vaccinated with the inactivated vaccine against the disease, the virus was detected in the G. g. cells 186 days after virus challenge, the reactivation of latency being obtained after immunosuppression with dexamethasone. In the non-vaccinated pig the virus was detected in G. g. cells after three months from experimental infection. In the ultra-thin slices the largest amount of virus was located in the nuclei and cytoplasm of satellite and Schwann's cells, in the connective-tissue cells and in the extracellular space. In the ganglion cells the virus was present in the cytoplasm and sporadically in the myelinized axons.     

Isolation and trypsin-enhanced propagation of turkey enteric (bluecomb) coronaviruses in a continuous human rectal adenocarcinoma cell line

Turkey enteric coronavirus (TCV) from intestinal contents of diarrheal poults was isolated and serially propagated in HRT-18 cells, an established cell line derived from a human rectal adenocarcinoma. In these cells, TCV induced cytopathic changes, including polykaryocytosis, which depended on trypsin in the medium and incubation at 41 C. Viral antigens could be demonstrated in the cytoplasm by immunofluorescence, and extracellular virus was detected by an ELISA and negative electron microscopy. The cell-free virus had characteristics of TCV: shape, surface projections, buoyant density of 1.18 to 1.20 g/ml in sucrose, and hemagglutination of rat RBC. The one-step growth curve was complete by postinoculation hours 14 to 16, and maximal titers reached 9 to 9.5 log10 TCID50/ml during 5 passages, after which the titer remained stable. Electron microscopic examination of infected cell monolayers revealed budding of typical coronavirus particles through intracytoplasmic membranes and accumulation of complete virus in cytoplasmic vesicles. Late in the infection, aggregated progeny vial particles were detected near the outer surface of infected cells. One-day-old turkey poults inoculated orally with tissue culture-adapted TCV isolates developed mild to severe diarrhea.     

Goat uterine epithelial cells are susceptible to infection with Caprine Arthritis Encephalitis Virus (CAEV) in vivo

ABSTRACT: The aim of this study was to determine, using immunofluorescence and in situ hybridization, whether CAEV is capable of infecting goat uterine epithelial cells in vivo. Five CAEV seropositive goats confirmed as infected using double nested polymerase chain reaction (dnPCR) on leucocytes and on vaginal secretions were used as CAEV positive goats. Five CAEV-free goats were used as controls. Samples from the uterine horn were prepared for dnPCR, in situ hybridization, and immunofluorescence. The results from dnPCR confirmed the presence of CAEV proviral DNA in the uterine horn samples of infected goats whereas no CAEV proviral DNA was detected in samples taken from the uninfected control goats. The in situ hybridization probe was complementary to part of the CAEV gag gene and confirmed the presence of CAEV nucleic acids in uterine samples. The positively staining cells were seen concentrated in the mucosa of the lamina propria of uterine sections. Finally, laser confocal analysis of double p28/cytokeratin immunolabelled transverse sections of CAEV infected goat uterus, demonstrated that the virus was localized in glandular and epithelial cells. This study clearly demonstrates that goat uterine epithelial cells are susceptible to CAEV infection in vivo. This finding could help to further our understanding of the epidemiology of CAEV, and in particular the possibility of vertical transmission.     

Pathogenesis of canine parvovirus enteritis: sequential virus distribution and passive immunization studies

After oral inoculation, the sequential distribution of canine parvovirus was studied in 14 nine-week-old seronegative beagle dogs. Two or three dogs were necropsied on days 1 through 6 after inoculation. Tissues were collected for virus isolation, immunofluorescence testing, and light microscopy. Virus was isolated from, and fluorescent cells were seen in the tonsil, retropharyngeal and mesenteric lymph nodes one and two days after inoculation. Virus infection of systemic and intestinal lymphoid tissues occurred as early as three days after inoculation and was associated with viremia. Intestinal epithelial infection was first seen four days after oral inoculation. All dogs were viremic before intestinal epithelial infection was found. Fecal virus excretion first occurred four days after oral virus inoculation. Intestinal virus infection and lesions became progressively more severe between four and six days after inoculation. The severity of intestinal lesions was variable and related to the severity of systemic lymphoid tissue lesions and the magnitude and duration of viremia. Four littermates of virus-infected dogs were passively immunized against canine parvovirus with convalescent canine serum 24 hours after oral virus inoculation. Neither clinical signs, lymphopenia, nor fecal virus excretion occurred in passively immunized dogs. Intestinal epithelial infection was not demonstrable by immunofluorescence testing when passively immunized dogs were necropsied four, five, and six days after virus inoculation.     

Studies on the replication of a bovine parvovirus

Optimal replication of a bovine parvovirus type 1 was found to occur when parasynchronous bovine embryonic lung cells were infected during the S phase of the cell cycle, just prior to maximum DNA synthesis. Viral antigen was first detected in the cytoplasm by immunofluorescence at 8 h post-infection, reaching a maximum at this location by 16 h and then disappearing. In the nucleus, antigen was first detected at 12 h, concurrent with early inclusion body formation and first detection of intracellular virus production. Intranuclear antigen then increased rapidly to a maximum at 20 h, as the inclusions progressively matured, large amounts of virus were produced within the cell, with some release to the environment. From 24 h, the nuclear inclusions became increasingly shrunken and basophilic as virus migrated to the cytoplasm and was progressively released to the exterior concurrent with cell degeneration and fragmentation. The majority of virus remained cell associated, even at 28 h post-inoculation. Two morphological types of early and late stage intranuclear inclusions were produced by the virus, these appearing to be a distinct feature of bovine strains. In other aspects, the replication of bovine parvovirus appeared similar to that of other members of the genus.     

Equine viral arteritis

Equine viral arteritis (EVA) can cause prominent economic losses for the equine industry. The purpose of this review is to provide the pathologist some familiarity with the clinical history, lesions, pathogenesis, and diagnosis of EVA. EVA is caused by an arterivirus (equine arteritis virus, EAV), and the vascular system is the principal but not unique viral target. EVA has variable presentations, including interstitial pneumonia, panvasculitis with edema, thrombosis and hemorrhage, lymphoid necrosis, renal tubular necrosis, abortion, and inflammation of male accessory genital glands. EAV antigen (EAVAg) can be demonstrated within the cytoplasm of epithelial cells such as alveolar pneumocytes, enterocytes, adrenal cortical cells, trophoblasts, thymus stroma, renal tubular cells, and male accessory genital gland cells. It can be also demonstrated within endothelia, in vascular, myometrial, and cardiac myocytes, macrophages, dendritelike cells of lymphoid organs, and chorionic mesenchymal stromal cells. In young and adult horses, following colonization of macrophages, the virus spreads systemically using circulating monocytes and enters the endothelium and tunica media of blood vessels, histiocytes, and dendritelike cells. Eventually, the virus multiplies within renal tubular cells. Lesions are uncommon in the aborted fetus; if present, they are mild, and EAVAg is frequently not detectable within fetal tissues and placenta. The clinical presentation and lesions of EVA may resemble those of other diseases. Complete pathologic examination associated with immunohistochemistry, virus isolation, and, especially in cases of abortion, serology will guarantee a directed and accurate diagnosis.