Response of embryonic chicken lymphocytes to in ovo exposure to lymphotropic viruses.

OBJECTIVE: To examine effects of virus exposure on embryonic lymphoid organ structure, apoptosis, and lymphoid cell subpopulations. ANIMALS: Eggs of specific pathogen free (SPF) White Leghorn chickens at embryonation day (ED) 17. PROCEDURES: Eggs were inoculated with 2,000 plaque-forming units (PFU) of serotype 1 herpesvirus (Marek's disease virus [MDV 1]), 2,000 PFU of herpesvirus of turkeys (MDV 3), or 1,000 embryo infectious doses (EID50) of infectious bursal disease virus (IBDV). On post-inoculation days (PID) 3 and 5, lymphoid organ to body weight ratios were determined, and bursa of Fabricius, thymus, and spleen were evaluated for lesions and apoptosis. Proportions of lymphoid cell subpopulations of PID-3 chicken embryos and 7- to 10-day-old chicks were quantitated by flow cytometry. RESULTS: Lymphoid organ weights were similar in virus-free, MDV1, and IBDV groups. Embryos inoculated with 2,000 PFU MDV 3/egg had lower bursal weights than virus-free controls. In a repeated trial, MDV 3 (1,000 PFU to 4,000 PFU) did not reduce bursal weights among groups. Histologic changes were seen in bursae after MDV 1 and IBDV inoculation. Apoptosis was greater in bursae of MDV 1-infected embryos than controls. Lymphoid cell subpopulations were similar among all groups with the exception of CD8+ and IgM+ cells in spleens of IBDV-infected 10-day-old chicks. CONCLUSIONS AND CLINICAL RELEVANCE: Infection with pathogenic strains of MDV 1 and IBDV did not alter lymphocyte subpopulations in embryos or cause complete destruction of lymphoid organs. Changes in lymphoid cell subpopulations exposed as embryos to IBDV were seen only after hatching.     

Delayed replication of Marek's disease virus following in ovo inoculation during late stages of embryonal development

Several oncogenic and non-oncogenic isolates of Marek's disease virus (MDV) were inoculated into embryonated eggs on embryonation day (ED) 16 to 18, and embryos or chicks hatching from inoculated eggs were examined for infectious virus and viral internal antigen (VIA) in lymphoid organs. There was no evidence of extensive replication of MDV in any of the embryonic tissues examined. Levels of VIA peaked 4-5 days after chicks hatched. This indicated that MDV remained inactive during embryonation and did not initiate pathogenic events until chicks hatched. Because HVT replicated rapidly in the embryo but MDV did not, in ovo inoculation of HVT simultaneously with oncogenic MDV or several days after MDV resulted in significant protection (P less than 0.025) of hatched chicks against Marek's disease (MD). Little protection was obtained if HVT was given simultaneously with MDV or after MDV to chicks already hatched. The relative susceptibility of the embryo to extensive replication of the vaccine virus but not the challenge virus apparently accounted for protection against MD in chicks hatching from dually infected eggs.     

Early posthatch protection against Marek's disease in chickens vaccinated in ovo with a CVI988 serotype 1 vaccine

CVI988, a serotype 1 Marek's disease virus (MDV), was used as an in ovo vaccine in specific-pathogen-free chickens to determine if this virus induces early posthatch protection against Marek's disease as has been shown previously for turkey herpesvirus. MDV CVI988 was injected at embryonation day (ED) 17 (group 1) or at hatch (group 2). A third group (group 3) was left unvaccinated. At 1, 2, 3, 4, 5, and 7 days of age, chickens from each group were sampled and examined as follows: a) single-cell suspensions of spleen were inoculated onto chicken embryo fibroblast monolayers to isolate the virus; b) sections of bursal tissues were stained by indirect immunofluorescence assays with anti-pp38 monoclonal antibody to identify viral antigen expression; and c) chickens were exposed intra-abdominally to MDV RB1B, a virulent serotype 1 MDV. Results revealed that in chickens given MDV CVI988 at ED 17, virus and virus-encoded protein were not detected until chickens were 3 and 2 days old after hatching, respectively. Results also indicated that during the first 4 days after hatch, the chickens given MDV CVI988 at ED 17 were better protected against virulent MDV than those given MDV CVI988 at hatch (P < or = 0.001). These results suggested that MDV CVI988 proteins were adequately expressed in the embryo to initiate prehatch immunologic response. Additional efforts with more sensitive techniques than used in this study are needed to identify the nature of viral expression in embryos.     

In situ production of interferon in tissues of chickens exposed as embryos to turkey herpesvirus and Marek's disease virus

Chicken eggs at embryonation day (ED) 18 or newly hatched chicks were inoculated with turkey herpesvirus (HVT), Marek's disease virus (MDV), or virus-free diluent and, at intervals after inoculation, tissue homogenates of virus-exposed and virus-free chickens or chicken embryos were examined for interferon (IFN) activity. Homogenates of lung, thymus and spleen specimens from chickens given HVT at ED 18 had IFN activity. Activity of IFN in the lungs was studied further. Homogenates of lung specimens from chickens exposed to HVT at hatching also had IFN activity, although the concentration of IFN was lower than that in chickens given HVT at ED 18. The pathogenic isolates of MDV (JM-MDV), but not the attenuated (Md11/75C-MDV) or nonpathogenic (SB1-MDV) isolates, inoculated at ED 18 also induced high lung IFN activity. Exposure to a combination of HVT and SB1-MDV induced IFN activity comparable with that in chickens given HVT alone. The IFN activity in homogenates of lung specimens from virus-exposed chickens was species specific and heat and pH stable, but was destroyed by trypsin treatment. Occasionally, low IFN activity also was detected in homogenates of tissue specimens from virus-free chickens or chicken embryos. This IFN activity could have been produced constitutively or may have been induced by substances (inducers) in the environment.     

Mortality of one-week-old chickens during naturally occurring Marek's disease virus infection

Marek's disease (MD) is a disease of chickens that occurs worldwide and has serious economic consequences. MD can present as one of several forms, with the most commonly occurring forms being the lymphoproliferative diseases. Under experimental conditions, an early mortality syndrome has been recognized following infection by some but not all strains of MD virus (MDV). This is the first report of a confirmed case of mortality due to naturally occurring MDV infection in 1-week-old, nonvaccinated, chickens. Necrotizing lesions were observed in the bursa of Fabricius, lung, duodenum, jejunum, and proventriculus, and large intranuclear inclusion bodies were a striking feature in tissues with lesions in all birds. Immunohistochemical staining for the pp38 protein of MDV revealed abundant pp38 antigen in the affected tissues, confirming the presence of MDV within the lesions. PCR yielded an amplicon with 97% homology to the meq gene of MDV. No evidence of co-infection by either of the immunosuppressive agents chicken anemia virus and infectious bursal disease virus was detected.     

Isolation and Identification of a Field Strain of Marek's Disease Virus and Analysis of Major Pathogenic Genes

In a certain area of Shandong province, Marek's disease (MD) occurred in diseased chickens that had been vaccinated by turkey herpesvirus.In order to isolate the virus strain and detect the virus pathogenicity, agar diffusion test, cell culture and indirect immunofluorescence assay (IFA) were used to isolate the Marek's virus from chicken's blood and feather marrow.The isolated strain was adapted to grow in chick embryo fibroblasts (CEF).Genes involved in pathogenesis of MDV, such as meq, pp38 and 132 bp repeat sequence were amplified by PCR.The obtained sequences were compared with that of standard strains published in GenBank by DNAStar software.The results showed that pp38 gene of the SDAU-1 shared homology from 100% with standard virulent sequence.Analysis of 132 bp repeat sequence and meq gene sequences of the viral genome showed that the isolated virus belongs to the highly virulent MDV strains.     

一株鸡马立克氏病病毒的分离鉴定及主要致病基因分析

山东省某地区鸡马立克氏病疫苗免疫鸡群暴发马立克氏病(MD),为分离得到致病毒株,检测其致病性,采用琼脂扩散试验、细胞培养和间接免疫荧光试验(IFA)等方法从发病鸡的血液及羽髓中分离到一株适应鸡胚成纤维细胞(CEF)生长的马立克氏病病毒。采用PCR方法扩增分离毒株的meq、pp38、132bp重复序列等病毒致病相关基因,所得序列用DNAStar软件与GenBank上登录的参考毒株进行比对分析。结果显示,该分离株SDAU-1的pp38基因与标准强毒序列同源性为100%,132bp重复序列的拷贝数及meq基因的变异均符合MDV强毒株的序列特征。     

Electron microscopic and immunohistochemical localization of Marek's disease (MD) herpesvirus particles in MD skin lymphomas.

Skin lymphomas induced in 11 specific-pathogen-free chickens by inoculation at 1 day of age with Marek's disease virus (MDV) were biopsied weekly and examined by electron microscopy and immunohistochemistry. In the sequentially biopsied lymphomas, immature MDV particles (abortive replication) were found only in the nuclei of necrotic lymphoblasts within necrotizing neoplasms. The necrotizing lymphomas were observed in two of the 11 experimental birds and were associated with prominent vascular endothelial cell injury, including fibrinoid necrosis of blood vessels. Nonnecrotizing lymphomas biopsied sequentially from the 11 experimental birds did not contain virus particles of any kind in the lymphoblasts and had no distinct vascular lesions. Immunohistochemically, MDV early antigen (pp38), but not late antigens (glycoproteins B and C), was detected only in the necrotizing lymphomas. These findings indicate that abortive MDV replication mainly occurred in necrotic lymphoblasts, which might have been induced by ischemia.     

The effect of experimental infection of mouse preimplantation embryos with paramyxovirus Sendai.

Zona-intact and zona-free mouse embryos at the morula stage were exposed to Sendai virus in vitro, and then transferred to the uteri of recipient foster mothers. Both embryos developed into expanded blastocyst stage after 48 hr of culture. Zona-intact embryos were resistant to infection and subsequent transfer resulted in the development of fetuses, indicating that the zona pellucida plays a role of a barrier to virus infection. On the other hand, zona-free embryos were susceptible to infection and only one fetus out of 64 transfers developed to term. Implantation sites were scarcely observed in the uteri of the foster mothers that received zona-free embryos, suggesting that most of the embryos did not develop after embryo transfer. Sendai virus was shed in the culture fluid of the zona-free embryos indicating viral replication in the embryonic cells. By immunofluorescence assay, viral antigens were detected in the embryos, tissues of the fetus and implantation site derived from the zona-free embryos. These findings indicate that replication of Sendai virus in the embryonic cells interfere with early embryonic development and fetal growth of the embryo.     

Immunohistochemical identification and quantitative analysis of cytoplasmic Cu/Zn superoxide dismutase in mouse organogenesis

Cytoplasmic Cu/Zn superoxide dismutase (SOD1) is an antioxidant enzyme that converts superoxide to hydrogen peroxide in cells. Its spatial distribution matches that of superoxide production, allowing it to protect cells from oxidative stress. SOD1 deficiencies result in embryonic lethality and a wide range of pathologies in mice, but little is known about normal SOD1 protein expression in developing embryos. In this study, the expression pattern of SOD1 was investigated in post-implantation mouse embryos and extraembryonic tissues, including placenta, using Western blotting and immunohistochemical analyses. SOD1 was detected in embryos and extraembryonic tissues from embryonic day (ED) 8.5 to 18.5. The signal in embryos was observed at the lowest level on ED 9.5-11.5, and the highest level on ED 17.5-18.5, while levels remained constant in the surrounding extraembryonic tissues during all developmental stages examined. Immunohistochemical analysis of SOD1 expression on ED 13.5-18.5 revealed its ubiquitous distribution throughout developing organs. In particular, high levels of SOD1 expression were observed in the ependymal epithelium of the choroid plexus, ganglia, sensory cells of the olfactory and vestibulocochlear epithelia, blood cells and vessels, hepatocytes and hematopoietic cells of the liver, lymph nodes, osteogenic tissues, and skin. Thus, SOD1 is highly expressed at late stages of embryonic development in a cell- and tissue-specific manner, and can function as an important antioxidant enzyme during organogenesis in mouse embryos.     

Safety and efficacy of in ovo administration of infectious bursal disease viral vaccines

In ovo vaccination against Marek's disease virus and infectious bursal disease virus (IBDV) in commercial broilers in the United States is common. Little information exists as to the safety and efficacy of intermediate IBDV vaccines given in ovo. Experiments were initiated to determine the safety and efficacy of three commercially available live intermediate IBDV vaccines by in ovo route. Commonly used vaccines were given at 18 days of embryonation to specific-pathogen-free (SPF) broiler embryos (first and second study) or to commercial broiler embryos (third study) that had maternal antibody against IBDV. When any of the antigenic standard vaccines was given at full dose to SPF embryos, embryonic and 3-wk posthatch mortality increased. Vaccines also caused significant microscopic lesions in the bursa of Fabricius at 1 and 3 wk posthatch. In contrast, there was no adverse effect on embryonic or posthatch mortality when vaccines were given at half dose to SPF or commercial broiler embryos. However, significant microscopic lesions were evident at 1 and 3 wk posthatch in the bursae of SPF embryos given the vaccines at half dose. When vaccines were given at half dose to commercial broiler embryos, lesions were evident at 1 but not 3 wk of age. In the third study, in ovo vaccinated chickens were challenged with either a virulent standard (APHIS) or antigenic variant (variant E) IBDV virus at 3 wk of age. All vaccines produced at least 87% protection against the standard and 60% protection against the variant challenge IBDV, as measured by bursal weight to body weight ratios. This study was the first to examine the safety and efficacy of the three commonly used intermediate IBDV vaccines given in ovo in protection against standard and antigenic variant IBDV challenge viruses.     

Nonlethal experimental inoculation of Columbia black-tailed deer (Odocoileus hemionus columbianus) with virus of epizootic hemorrhagic deer disease.

Intramuscular or intravenous inoculation of 5 Columbia black-tailed deer (Odocoileus hemionus columbianus) with virus of epizootic hemorrhagic deer disease (EHD) did not produce overt clinical disease. Two white-tailed deer (Odocoileus virginianus) exposed identically died in 5 to 6 days. There were no significant lesions in 1 black-tailed deer euthanatized on postinoculation day 5. The EHd virus was not isolated from the spleen of that deer. Seroconversion occurred in black-tailed deer, from zero EHD virus antibody titer before inoculation to titers of 1:128 to 1:256 after inoculation.     

鸡新城疫山东强毒株的分离鉴定及致病性研究

从山东省不同地区的发病鸡群中分离了6株病毒，经HA、HI试验、病毒回归试验和血清中和接种鸡胚试验确定所分离的毒株为新城疫病毒。分别对6个毒株MDT、ICPI和IVPI进行了测定，结果表明这些毒株为鸡新城疫强毒，但各个毒株的致病性有所差异。     

病毒接种后死亡鸡胚绿脓杆菌的分离鉴定及药敏试验

鸡胚的种毒接种是禽流感疫苗生产的一个必要环节.从接种病毒后的死亡鸡胚中分离到一株细菌,通过细菌生长特性观察、显微镜检查、生化鉴定以及16 S rDNA PCR鉴定,结果表明为绿脓杆菌.该细菌对青霉素钾、硫酸链霉素、硫酸丁胺卡那耐受,对盐酸环丙沙星敏感.这是在国内首次报道由于接种引起绿脓杆菌污染间接致死大量鸡胚.     

Effect of in ovo vaccine delivery route on herpesvirus of turkeys/SB-1 efficacy and viremia

A study was designed to ascertain the influence of in ovo site of inoculation and embryonic fluid type on the development of Marek's disease (MD) vaccine viremia and efficacy against MD challenge. The experiments were divided into in vitro and in vivo phases. In the in vitro phase, herpesvirus of turkeys/SB-1 vaccine was combined with basal medium eagle (BME) medium (control), amniotic fluid, or allantoic fluid and subsequently titrated on secondary chick embryo fibroblast cultures. There were no significant differences in titer between the virus inoculum carried in BME and the virus inoculum combined with either the allantoic fluid or the amniotic fluid. In the in vivo phase, five routes of inoculation, amniotic, intraembryonic, allantoic, air cell, and subcutaneous at hatch, were compared for generation of protection against virulent MD challenge. Comparisons were made in both specific-pathogen-free and commercial broiler embryos/chicks and, for the amniotic and allantoic routes, injection at either day 17 or day 18 of embryonation. Reisolation of the vaccine virus at day 3 of age was also done for all routes with the exception of the air cell route. Vaccine virus was recovered from all birds tested that were injected in ovo via the amniotic and intraembryonic routes and the subcutaneously at hatch route but was isolated only sporadically from birds inoculated via the allantoic route. Vaccination protective efficacy against virulent MD for all birds vaccinated in ovo via the amniotic or intraembryonic routes and birds vaccinated subcutaneously at hatch was over 90% regardless of day of in ovo injection or bird type. Protective efficacy for vaccines delivered in ovo by either the allantoic or the air cell routes was less than 50% regardless of day of injection or bird type. Therefore, in ovo MD vaccines must be injected either via the amniotic route or the intraembryonic route for optimal performance.     

Coinfection of specific-pathogen-free chickens with Marek's disease virus (MDV) and chicken infectious anemia virus: effect of MDV pathotype

Both Marek's disease virus (MDV) and chicken infectious anemia virus (CIAV) infections are prevalent in chickens throughout the world. In the past decade, MDV strains with increased virulence (very virulent plus MDV pathotype [vv+MDV]) have been isolated. The purpose of this experiment was to determine the effects of coinfection of chickens with CIAV and a vv+MDV isolate. Specific-pathogen-free chickens were inoculated at 1 day posthatch with RB1B (very virulent MDV pathotype [vvMDV]) only, 584A (vv+MDV) only, CIAV only, RB1B + CIAV, 584A + CIAV, or nothing. Samples of spleen, thymus, and bursa of Fabricius were collected at 4, 7, 10, and 13 days postinoculation (DPI). Thymic and bursal atrophy at 13 DPI and final mortality at 30 DPI were significantly greater in chickens inoculated with 584A with or without added CIAV, or with RB1B plus CIAV, compared with birds inoculated with RB1B alone. Both amounts of virus reisolated and levels of virus detected by quantitative-competitive polymerase chain reaction were greater at 4 DPI in 584A inoculates compared with RB1B inoculates. To monitor the early cytolytic infection, northern analysis was done with a probe for the MDV immediate early gene ICP4 (infected cell protein 4). In the absence of CIAV, ICP4 expression was more apparent in chickens inoculated with 584A than in those inoculated with RB1B. CIAV coinfection increased ICP4 expression in the spleens of chickens infected with RB1B. These results indicated that inoculation of chickens with the 584A isolate caused a more robust early cytolytic infection compared with inoculation with RB1B alone and support the classification of 584A as a vv+MDV strain. Coinfection with CIAV exacerbated vvMDV strain RB1B infection. The extent of this exacerbation was less evident when birds were coinfected with 584A and CIAV.     

Quantitative analysis of embryonic kidney impairment by confocal microscopy and stereology: effect of 1,2-dibromoethane in the chick mesonephros

1. Chick embryos in ovo were treated with a teratogenic dose of 1,2-dibromoethane (DBE) on embryonic day (ED) 3. On ED 6 and 10, histological sections of whole embryos were prepared for confocal microscopy. In parallel, mesonephroi of 10-d-old embryos were dissected for in situ staining with acridine orange (AO), a fluorescence probe for lysosomes. 2. DBE impaired differentiation of renal vessels which manifested as a delay in rearrangement of primitive renal vascular architecture on ED 6 and a significant reduction of the mesonephric vascularisation on ED 10. This was accompanied by delayed functional maturation of embryonic kidney, as suggested by staining with AO. 3. Renal vessels appeared to be more susceptible to DBE than tubules. Unequal growth of these renal components might be a cause of DBE-induced spatial disorganisation of tubular apparatus. 4. Nephrotoxic effects of DBE during the embryonic period are associated primarily with damage to the renal blood supply. 5. Confocal microscopy, stereological methods and three-dimensional reconstruction of developing tissues are useful tools to investigate pathogenic processes during embryonic development.     

Experimental transmission of bovine viral diseases by insemination with contaminated semen or during embryo transfer

Three experimental approaches were used to study transmission of blue tongue (BT), infectious bovine rhinotracheitis (IBR) and bovine virus diarrhoea (BVD) viruses. These were insemination with contaminated semen, experimental infection of embryo donor cows, or transfer of embryos experimentally exposed to virus in vitro to normal recipients. Parameters assessed included number and quality of embryos produced, virus detection (isolation and electron microscopy), serology and histopathology. All superovulated sesceptible cows inseminated with semen containing blue tongue virus (BTV) (n = 2) or infectious bovine rhinotracheitis virus (IBRV) (n = 2) became infected. One cow inseminated with semen containing BTV produced seven virus-free seven-day-old embryos; the second cow failed to produce any embryos. One of two cows inseminated with semen containing IBRV produced two underdeveloped, virus-free embryos while no embryos were produced by the second cow. One of two cows inseminated with semen containing bovine viral diarrhoea virus (BVDV) became infected. Two poorly developed, virus-free seven-day-old embryos were recovered from one of these cows. Superovulated susceptible cows inoculated either intramuscularly with BTV (n = 3) or intranasally with IBR virus (n = 2) became infected. Virus was isolated from some tissues of two BTV-infected cows, neither of which produced embryos. A third BTV-infected cow produced two virus-free embryos collected at necropsy five days after inoculation. One of two cows experimentally infected with IBR virus, produced three embryos but virus was not detected either by electron microscopy (1 embryo) or in cell culture by cytopathic alterations (1 embryo).(ABSTRACT TRUNCATED AT 400 WORDS)