Diagnosis of feline herpesvirus infection by immunohistochemistry, polymerase chain reaction, and in situ hybridization.

An adult domestic shorthair cat had severe chemosis due to purulent and necrotizing blepharitis and conjunctivitis. Purulent rhinitis, necrotizing glossitis, and dermatitis were also diagnosed. The cat was positive for feline immunodeficiency virus and feline leukemia virus. Histologically, intranuclear Cowdry type A inclusions were found within numerous epithelial cells adjacent to the lesions in skin, conjunctiva, and tongue. Electron microscopic examination revealed herpesviral particles within the lesions. Paraffin-embedded skin and tongue tissues were processed in a polymerase chain reaction, using primers to amplify a 306-bp region of the thymidine kinase gene of feline herpesvirus type 1, resulting in a distinct amplification product of the predicted size. The distribution of feline herpesvirus was demonstrated by immunohistochemistry and nonradioactive in situ hybridization. Positive immunostaining was found in nuclei and cytoplasm of numerous epithelial cells within and next to the lesions, whereas in situ hybridization, performed with a digoxigenin-labeled double-stranded DNA probe, revealed hybridization signal only in nuclei of intact epithelial cells. Neither immunohistochemistry nor in situ hybridization showed feline herpesvirus type 1 in tissues of lungs, liver, spleen, intestine, or brain.     

A novel herpesvirus associated with chronic superficial keratitis and proliferative conjunctivitis in a great horned owl (Bubo virginianus)

An adult great‐horned owl (Bubo virginianus; GHOW) presented with a history of recurrent corneal ulceration of the right eye (OD). Findings included ulcerative superficial keratitis, proliferative conjunctivitis, and iris pigmentary changes. The ulcer was initially nonresponsive to medical therapy, but showed rapid and appropriate healing following diamond burr debridement. Proliferative conjunctivitis markedly improved following topical antiviral therapy with cidofovir 1%, interferon alpha 2B ophthalmic solutions, and oral l ‐lysine. Histopathologic evaluation of a conjunctival biopsy revealed epithelial features suspicious for viral cytopathic changes and intranuclear structures suspicious for viral inclusions, suggestive of a possible viral‐induced papillomatous conjunctivitis. A novel alphaherpesvirus, referred to as Strigid Herpesvirus 1 (StrHV1), was identified using PCR and gene sequencing. This case represents a new clinical manifestation of a previously unreported herpesvirus in the GHOW. Identification of the herpes virus was critical to administration of appropriate therapy and resolution of the conjunctivitis, and corneal epithelial debridement promoted resolution of the chronic corneal epithelial defect.     

Three viruses of the bovine respiratory disease complex apply different strategies to initiate infection

Bovine respiratory disease complex (BRDC) is the major cause of serious respiratory tract infections in calves. The disease is multifactorial, with either stress or reduced immunity allowing several pathogens to emerge. We investigated the susceptibility of bovine airway epithelial cells (BAEC) to infection by the three major viruses associated with the BRDC: bovine respiratory syncytial virus (BRSV), bovine herpesvirus type 1 (BHV-1) and bovine parainfluenza virus type 3 (BPIV3). For this purpose, two culture systems for well-differentiated BAEC were used: the air-liquid interface (ALI) system, where filter-grown BAEC differentiate into a pseudostratified respiratory epithelium and precision-cut lung slices (PCLS) where BAEC are maintained in the original tissue organisation. Comparative infection studies demonstrated that entry and release of BPIV3 occurred specifically via the apical membrane with ciliated cells being the major target cells. By contrast, airway epithelial cells were largely resistant to infection by BHV-1. When the epithelial barrier was abolished by opening tight junctions or by injuring the cell monolayer, BHV-1 infected mainly basal cells. Respiratory epithelial cells were also refractory to infection by BRSV. However, this virus infected neither differentiated epithelial cells nor basal cells when the integrity of the epithelial barrier was destroyed. In contrast to cells of the airway epithelium, subepithelial cells were susceptible to infection by BRSV. Altogether, these results indicate that the three viruses of the same disease complex follow different strategies to interact with the airway epithelium. Possible entry mechanisms are discussed.     

Infectious Center Assay of Intracellular Virus and Infective Virus Titer for Equine Mononuclear Cells Infected in vivo and in vitro with Equine Herpesviruses

A novel, simple method of infectious center assay was developed to detect and quantitate the intracellular existence of equine herpesvirus 1 and equine herpesvirus 2 in peripheral blood mononuclear cells infected in vivo and in vitro with the viruses by cocultivation of these cells with a permissive equine cell culture. The infectious center titers were correlated with the infectious virus titers. In vivo equine herpesvirus 1-infected mononuclear cells obtained from ponies experimentally infected with the virus and equine herpesvirus 2-infected mononuclear cells obtained from selected naturally infected ponies with the virus gave by infectious center assay a mean value of 67 infectious center/2 x 10⁶ cells as a peak titer on day 4 postinfection and 26 infectious center/2 x 10⁶ cells for equine herpesvirus 1 and equine herpesvirus 2 respectively. The mononuclear cells, in both cases, did not contain detectable infectious virus, but the infectious virus was detected from the respective cells when they were cultured in the presence of mitogen. The equine herpesvirus 1 infected mononuclear cells in culture gave a mean count of 8.05 x 10² infectious center/2 x 10⁶ cells/mL and contained 1.08 x 10⁴ plague assay/mL of infectious virus. Similarly the equine herpesvirus 2 infected mononuclear cells in culture gave a mean count of 7.1 x 10¹ infectious center/2 x 10⁶ cells/mL and contained <10¹ tissue culture infective dose₅₀/mL of infectious virus. Mononuclear cells infected in vitro with equine herpesvirus 1 gave a mean count of 9.3 x 10⁴ infectious center/2 x 10⁶ cells/mL and contained 5.75 x 10³ plaque assay/mL of infectius virus. Culturing these cells in the presence of mitogen gave a mean count of 5.5 x 10³ infectious center/2 x 10⁶ cells/mL and contained 9 x 10³ plague assay/mL of infectious virus. A correlation between infectious center assay and infectious virus assay is discussed.     

Outbreak of herpesviral conjunctivitis and respiratory disease in gouldian finches

An outbreak of tracheitis, sinusitis, and conjunctivitis, originating in recently imported birds, caused high morbidity and mortality in a flock of finches in Central Illinois. Although several species were present, Gouldian finches (Erythrura [Chloebia] gouldiae) were most commonly and severely affected. Birds submitted for necropsy displayed microscopic lesions characteristic of herpesviral infection, including epithelial cytomegaly and karyomegaly with basophilic, intranuclear inclusion bodies in the nasopharynx, sinuses, trachea, parabronchi, conjunctiva, and occasionally the lacrimal gland or proximal proventricular glands. Viral particles consistent with herpesvirus were visualized within affected epithelial cells with electron microscopy. Based on a partial sequence of the viral DNA polymerase gene, this virus was found to be identical to a herpesvirus previously implicated in a similar outbreak in Canada and is most likely an alphaherpesvirus.     

甲型疱疹病毒亚科的疱疹病毒囊膜糖蛋白gC对病毒感染复制的影响

甲型疱疹病毒亚科的疱疹病毒宿主广泛,能感染哺乳类、两栖类和禽类,主要侵害宿主的皮肤、黏膜和神经组织,病毒还会在宿主神经组织潜伏感染,一经感染,难以清除。gC是甲型疱疹病毒亚科的病毒囊膜糖蛋白之一,在病毒感染复制过程中发挥了重要作用。gC与细胞上受体结合帮助病毒吸附至宿主细胞表面、介导低pH条件下病毒入侵上皮细胞、影响病毒基因组的复制。此外,gC帮助病毒逃避补体和抗体的中和,促进病毒的吸附入侵。本文就gC影响病毒感染复制的相关功能进行综述,旨在为研究gC和深入了解甲型疱疹病毒亚科病毒的生命周期,以及gC亚单位疫苗和mRNA疫苗的研究提供参考。     

Survival of equine herpesvirus-4, feline herpesvirus-1, and feline calicivirus in multidose ophthalmic solutions

Objective To determine survival over time of infectious equine herpesvirus‐4, feline herpesvirus‐1, and feline calicivirus in three commercially available and commonly used ophthalmic solutions (eyewash, fluorescein, and proparacaine HCl). Sample population Viruses used in this study were originally isolated from eyes of animals referred to the University of Illinois. Equine herpesvirus‐4 was propagated in MDBK cells and feline herpesvirus‐1 and feline calicivirus in CRFK cells. Procedure After separately inoculating a designated solution with a specific titer of an individual virus, solutions were incubated per manufacturer's recommendations, either at 4 °C or 25 °C. Virus titers within solutions were subsequently measured at 1, 8, and 24 h and 3, 5 and 7 days post inoculation using either plaque or TCID₅₀ assays. Results Equine herpesvirus‐4, feline herpesvirus‐1, and feline calicivirus were present in eyewash for 7 days, 5 days, and 7 days, respectively. Eyewash did not decrease survival time of any virus when compared to controls. Equine herpesvirus‐4 and feline herpesvirus‐1, both enveloped viruses, were not recovered at any time ≥ 1 h post inoculation in fluorescein. Feline calicivirus, a nonenveloped virus, was present in fluorescein for 7 days. Equine herpesvirus‐4 and feline herpesvirus‐1 did not remain infectious in proparacaine at any time ≥ 1 h post inoculation, but feline calicivirus was recovered at up to 24 h post inoculation. Conclusions Equine herpesvirus‐4, feline herpesvirus‐1, and feline calicivirus may be readily transmissible via the eyewash solution used in this study. Risk of iatrogenic transmission of the three viruses used in this study was significantly reduced in both fluorescein and proparacaine solutions. Feline calicivirus, the only nonenveloped virus evaluated, remained viable longer in both fluorescein and proparacaine solutions.     

Marek's disease virus-induced skin leukosis in scaleless chickens: tumor development in the absence of feather follicles

Marek's disease virus (MDV) is an oncogenic cell-associated herpesvirus that causes T-cell lymphoma in chickens. Lymphoproliferative neoplasms in Marek's disease (MD) occur in various organs and tissues, including the viscera, peripheral nerves, skin, gonads, and musculatures. MDV is restrictively produced in the feather follicle epithelial (FFE) cells, and it gains access to the external environment via infected cells or as infectious enveloped cell-free virus particles. The goals of the present study were to 1) determine whether the MDV-induced skin lesions are neoplastic in nature or inflammatory reactions to viral infection, 2) determine whether physical presence of feather follicles (FF) is necessary for skin tumor development, and 3) study the role of skin epithelial cells not associated with feathers or FF in the replication and dissemination of infectious virus particles. Scaleless chickens that produce only a few scattered feathers and no sculate scales along the anterior metatarsi were used as a unique model to study the pathogenesis of dermal lesions. Histologic and immunohistochemical analysis revealed that the cutaneous lesions were tumorous as was manifested by massive accumulation of lymphoblasts and extensive activation of meq oncoprotein, the hallmark of MDV oncogenesis, within the skin lesions. Neoplastic cutaneous lesions in the scaleless chickens indicate that feather follicles are not necessary for skin tumor development. Finally, our preliminary data indicate that inoculation with supernatant fluid from homogenized and sonicated skin samples of MDV-infected scaleless chickens induces MD in susceptible birds, suggesting that skin epithelial cells not associated with FF also harbor infectious viral particles.     

Immunological relationships between malignant catarrhal fever virus (alcelaphine herpesvirus 1) and bovine cytomegalovirus (bovine herpesvirus 3)

Strains of malignant catarrhal fever virus (alcelaphine herpesvirus 1 (AHV-1)) and bovine cytomegalovirus (bovine herpesvirus 3 (BHV-3)) were compared for serological relatedness by cross-titration in an indirect immunofluorescent (IIF) antibody assay. There was definite cross-reactivity between these 2 viruses, with heterologous sera staining intracellular and membrane antigens of infected cells. Heterologous antibody titres were approximately 50-fold lower than homologous titres and could be removed by absorption with either homologous or heterologous virus-infected cells, but not with uninfected cells. Regression analyses of IIF antibody titres to AHV-1 and BHV-3 virus in 3 groups of wild ungulate sera also indicated a serological relationship between these herpesviruses. In a cross-immunity trial, 2 of 3 cattle immunized with a BHV-3 virus and 2 of 3 cattle immunized with avirulent AHV-1 resisted challenge with virulent AHV-1-infected blood which killed 3 unimmunized controls. These results are discussed particularly with respect to the involvement of BHV-3 in malignant catarrhal fever.     

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.     

Aujeszky's disease ELISA: cross-reactions with other herpesvirus antisera

The production of antibodies in pigs to 11 herpesviruses was investigated in relation to their ability to cross-react with Aujeszky's disease virus (suid herpesvirus 1--SHV1). Of the herpesviruses tested only two, sheep herpesvirus (caprine herpesvirus 1) and dog herpesvirus (canid herpesvirus 1), failed to produce homologous virus antibodies. Only the antibodies to bovine herpesvirus 1 (BHV1) produced a cross-reaction by SHV1 enzyme-linked immunosorbent assay (ELISA). No SHV1 neutralizing antibodies were detected in any of the herpesvirus antisera. A cross-reaction with SHV1 by a serum from a pig naturally infected with BHV1 or with any of the other herpesviruses tested was considered unlikely.     

Pathogenesis of gammaherpesvirus infections

Gammaherpesviruses are members of an emerging subfamily among the Herpesviridae. Two genera are discriminated: (i) lymphocryptovirus, including its type species Epstein-Barr virus (EBV), and (ii) rhadinovirus, including viruses of interest for medicine, veterinary medicine, and biomedical research, i.e. alcelaphine herpesvirus 1, bovine herpesvirus 4, equine herpesvirus 2, human herpesvirus 8, mouse herpesvirus 68, and ovine herpesvirus 2 (OvHV-2). The perception that these viruses have a narrow host range is misleading, since they cover a surprisingly wide host range, both on the cellular and the organism's level. For example, the natural range of OvHV-2 infection extends over a common animal order. While the host range determinants of EBV are well known, the corresponding features of the rhadinoviruses need still to be defined. Similarly, the gene expression patterns of the veterinary rhadinoviruses during latency require further characterization. In vivo, the gammaherpesviruses have evolved to actively protect their latently infected cells from being destroyed by immune functions of their native host. In return, those reservoir hosts have evolved to being infected and transmit the virus without overt disease symptoms. However, a balanced immune response needs to be in control over the number of infected cells. Virus excretion is usually at low level and may occur either constantly or intermittently. Animal species that are targeted by the virus but did not participate in the process of co-evolution as well as hosts with immune deficiencies are known to loose control over the amount of latently infected cells, which results in the development of lethal diseases, such as malignant catarrhal fever or Kaposi's sarcoma.     

Propagation and quantitation of animal herpesviruses in eight cell culture systems

A comparative study was carried out to determine the relative sensitivities of eight different cell culture systems to six different herpesviruses of animals. The cells used were: OFL (ovine fetal lung), ML (mink lung), FK (ferret kidney), PTK-2 (potoroo kidney), TEK (turkey embryo kidney), ED (equine dermal), BT (bovine turbinate), and PK15 (porcine kidney). The viruses tested were: PRV (pseudorabies) of swine, CPHV (caprine herpesvirus), IBRV (infectious bovine rhinotracheitis virus), DN-599 strain of bovine herpesvirus type 4, EHV-1 (equine herpesvirus), and CHV (canine herpesvirus). On the basis of virus titers obtained and the time of appearance of CPE (cytopathic effects), ML cells were found to be the most useful because of their sensitivity to all six viruses tested. BT and OFL cells were also found to be highly sensitive to all viruses with the exception of CHV.     

牛疱疹病毒1型主要囊膜糖蛋白研究进展

牛疱疹病毒(BHV-1)属于α疱疹病毒亚科的DNA病毒,可引起牛高热、上呼吸道感染和母牛流产。该病毒能在牛的感觉神经节内建立潜伏感染,因此,对于该病毒感染的预防和治疗较为困难。BHV-1除了引起初始感染外,还可通过免疫抑制引起动物继发感染,导致动物死亡。研究发现,病毒入侵牛机体时,病毒囊膜糖蛋白在病毒与细胞间相互作用的过程中发挥了重要作用。论文对牛疱疹病毒1型主要囊膜糖蛋白(包括gB、gD、gN)的结构特征和生物学特征加以归纳总结,为该病毒的感染特性研究和预防提供参考。     

Detection of Bovine herpesvirus 4 DNA in aborted bovine fetuses

The presence of Bovine herpesvirus 4 (BoHV-4) was investigated by several methods in 24 aborted bovine fetuses. Polymerase chain reaction (PCR) and in situ DNA hybridization proved the presence of BoHV-4 DNA in 7 (29%) of the fetuses. The BoHV-4 genome was detected in the cytoplasm of splenic lymphocytes and monocytes, and sometimes in renal tubular epithelial cells or hepatic Kupffer cells, in all 7 PCR-positive fetuses. However, BoHV-4-specific monoclonal antibody failed to detect viral antigen in the formalin-fixed, paraffin-embedded tissue samples. No bacterial pathogens were found in the tissues of the BoHV-4-positive fetuses. Fungi were detected in 1 sample, and antibody to bovine viral diarrhea virus was detected in another. These results indicate that BoHV-4 could play a role in reproductive disorders of cattle, including abortion.     

Bovine T lymphocyte response to bovine herpesvirus-1: cell phenotypes, viral recognition and acid-labile interferon production

The phenotype of bovine cells that proliferate to bovine herpesvirus (BHV-1) were identified by peanut agglutinin (PNA) and monoclonal antibodies with specificity for Pan T cells (B29), a T cell subset (B24), and an MHC class II (Ia-like) antigen (R-1). PNA+ cells but not PNA- cells separated by fluorescent activated cell sorting responded to BHV-1. Virally-activated T cells expressed MHC class II antigens, and possibly antigen specific receptors for virus. Binding of radiolabeled virus increased six-fold beyond the expected value for activated cells suggesting specificity of the lymphocytes for the virus. Finally, cells that responded to BHV-1 produced high levels of acid sensitive interferon. Taken together these results characterize the phenotypes of bovine lymphocytes that interact with BHV-1.     

Adaptation of Marek's disease virus to the Vero continuous cell line

Marek's disease virus (MDV) is a highly infectious, cell-associated oncogenic herpesvirus. Production of MD vaccines has been limited to primary chicken and duck embryo fibroblast (CEF and DEF) cultures. These have a limited life span and cannot be readily stored in liquid nitrogen. Moreover, the need to prepare CEF and DEF cells on a regular basis from 10 to 11 day-old embryos derived from a flock that must be tested continuously for the presence of avian pathogens adds to the cost of vaccine production. A continuous cell line that would support MDV replication could have significant advantages for the rapid large-scale preparation of MD vaccines. In this report, we describe the adaptation to growth of CEF-grown preparations of serotype 1 and serotype 3 (herpesvirus of turkeys; HVT) strains of MDV in cells of the Vero continuous cell line. Although both viruses produced typical CPE, higher levels of infectious progeny and more extensive virus-specific immunofluorescence were obtained for HVT than for the serotype 1 virus. PCR and pulsed field electrophoresis (PFE) analysis of the DNA from Vero cells infected with either virus confirmed the presence of virus-specific DNA.     

Acute herpesvirus-gastritis in a cat

Gastritis in cats is caused, among other things, by infectious agents, like bacteria, metazoic parasites or viruses. Herpesvirus-gastritis has not as yet been documented in cats. Therefore in this paper such a case will be described. In this case the mucous membrane of the stomach shows multifocal acute necroses with evidence of intranuclear inclusion bodies in epithelial cells of the gastric glands. By means of electron microscopy the causative virus can be specified as herpesvirus.     

Isolation of Feline Herpesvirus 1 from the Trigeminal Ganglia of Acutely and Chronically Infected Cats

Feline herpesvirus 1 (FHV-1) is one of the most common viral infections of domestic cats worldwide, estimated to cause 50% of all respiratory infections in this species. Feline herpesvirus 1 is also an important ocular pathogen of cats, causing conjunctivitis, epithelial and stromal keratitis, symblepharon formation, keratocon-junctivitis sicca, and corneal sequestration. Despite the importance of this viral disease, major questions remain unanswered concerning the pathogenesis of its most important manifestation, the recrudescent infection. Although the taxonomic classification of FHV-1 as an alpha herpesvirus implies the ability of FHV-1 to establish neural latency, attempts at recovering the virus from the trigeminal ganglia of latently infected cats have typically yielded negative results. This failure has stimulated speculation that neural tissue is not an important site for latent FHV-1. However, in the most successful of such studies, FHV-1 was isolated from the trigeminal ganglia of 3 of 17 cats using an explant technique. In the present study, we describe the successful isolation of FHV-1 from the trigeminal ganglia of cats using a similar tissue culture method.     

Serological comparisons of antigenically related herpesviruses in cattle,red deer and goats

Serological comparisons were made using related herpesviruses from cattle (bovid herpesvirus 1), red deer (herpesvirus of cervidae 1) and goats (bovid herpesvirus 6) by virus neutralization and enzyme-linked immunosorbent assays. The test samples comprised field sera from British cattle, red deer and goats and sera from experimentally infected or immunized animals. Both the cervine and caprine viruses appeared to be more closely related to bovid herpesvirus 1 than they were to each other. Cattle sera reacted most strongly with the bovine virus and deer sera with the cervine virus. Antibodies to the caprine virus were not detected in the samples from British goats.