Gut microbiota is associated with protection against Marek's disease virus infection in chickens.

Marek's Disease Virus (MDV) infects chickens via respiratory route and causes lymphomas in internal organs including gastrointestinal tract. MDV infection causes a shift in the gut microbiota composition. However, interactions between the gut microbiota and immune responses against MDV infection are not well understood. Therefore, the current study was performed to understand the effect of the gut microbiota on Marek's disease (MD) pathogenesis. The findings showed that depletion of gut microbiota increased the severity of MD in infected chickens. In addition, an increase in the transcription of interferon (IFN)-α, IFN-ß and IFN-γ in the bursa of Fabricius at 4 days post-infection (dpi) was observed in the gut microbiota depleted chickens. The observations in this study shed more light on the association between the gut microbiota and MDV infection in chickens. More research is needed to explore the mechanisms of involvement of the gut microbiota in immunity against MD in chickens.

Marek's disease virus influences the core gut microbiome of the chicken during the early and late phases of viral replication.

Marek's disease (MD) is an important neoplastic disease of chickens caused by the Marek's disease virus (MDV), an oncogenic alphaherpesvirus. In this study, dysbiosis induced by MDV on the core gut flora of chicken was assessed using next generation sequence (NGS) analysis. Total fecal and cecum-derived samples from individual birds were used to estimate the influence of MDV infection on the gut microbiome of chicken. Our analysis shows that MDV infection alters the core gut flora in the total fecal samples relatively early after infection (2-7 days) and in the late phase of viral infection (28-35 days) in cecal samples, corresponding well with the life cycle of MDV. Principle component analyses of total fecal and cecal samples showed clustering at the early and late time points, respectively. The genus Lactobacillus was exclusively present in the infected samples in both total fecal and cecal bird samples. The community colonization of core gut flora was altered by viral infection, which manifested in the enrichment of several genera during the early and late phases of MDV replication. The results suggest a relationship between viral infection and microbial composition of the intestinal tract that may influence inflammation and immunosuppression of T and B cells in the host.

Marek's disease, candidiasis and megabacteriosis in a flock of chickens (Gallus gallus domesticus) and Japanese quail (Coturnix japonica).

An outbreak of mortality in chickens and Japanese quail sharing the same airspace was investigated. Marek's disease was diagnosed in five of 11 chickens examined, and in 20 of 24 quail; crop candidiasis was found in four of the chickens and in five of the quail, and moderate to large numbers of organisms referred to as megabacteria were observed in eight of the chickens and 16 of the quail. The disease was so severe that almost all of the quail in the flock died or were culled during the following six months. In contrast, only approximately 5 per cent of the chickens died from Marek's disease.

Characterization of Marek's disease virus BamHI-A-specific cDNA clones obtained from a Marek's disease lymphoblastoid cell line.

A cDNA library was constructed from poly(A)+ RNA fractions obtained from a Marek's disease (MD) lymphoblastoid cell line, MDCC-CU41, in which viral gene expression is very limited. Three independent groups (1, 2, and 3) of MD virus (MDV)-specific clones were obtained, which were mapped in the inverted repeat region of the BamHI-A fragment of the MDV genome. Northern blot analysis showed that probes prepared from these cDNA clones hybridized with several transcripts of different sizes in poly(A)+ RNA of MDCC-CU41, although the amounts of these transcripts were relatively small compared to those in MDV lytically infected cells. Moreover, a small open reading frame, which can encode a 94-amino-acid protein, was identified in the A41 cDNA clone (Group 3). By RNase protection assays, the 1.2-kb Group 3 transcriptional unit has been defined. In indirect immunofluorescent antibody assays, antiserum against the bacterially expressed fusion protein, glutathione S-transferase-A41, reacted specifically with the cytoplasmic regions of MDV (strain RB1B)-infected chick kidney cells. However, MDCC-CU41 did not contain a detectable level of the protein determined by these methods.

Assembly pathway of avian infectious laryngotracheitis virus.

Infectious laryngotracheitis virus (ILTV) is the causative agent of a highly contagious upper respiratory tract infection in chickens. At present, ILTV vaccines are not satisfactory because of development of a latent carrier status in vaccinated birds. Development of recombinant virus vaccines has been hampered by the limited information available on the molecular level and organization of this virus. We isolated 3 assembly intermediates, designated A, B, and C from ILTV-infected cells. Analysis of [3H]thymidine-and [35S]methionine-labeled particles, and electron microscopic studies indicated that particle A was the empty capsid, particle B was the procapsid containing scaffolding protein, and particle C was the DNA-filled capsid. The ILTV procapsids could only be found in the nucleus, which indicated that procapsids could not translocate through the nuclear membrane until they packaged the DNA. The DNA-filled capsids migrated through the nuclear membrane and obtained an envelope from the inner membrane of the nucleus. The enveloped particles then migrated through the lumen of the endoplasmic reticulum into vacuoles in the cytoplasm. Infective virions were isolated from within the infected cells, indicating that budding through the cytoplasmic membrane is not a necessary step in ILTV maturation. Abundant arrays composed of tubules about 45 to 50 nm wide were found in the cytoplasm of chicken embryonic liver cells about 30 to 38 hours after infection. Comparison of the assembly intermediates and the DNA packaging pathway of ILTV with that of bacteriophage pi 29 indicates that similarity exists.(ABSTRACT TRUNCATED AT 250 WORDS)

Development of PCR method specific for Marek's disease virus.

A rapid polymerase chain reaction (PCR) assay specific for Marek's Disease Virus (MDV) was developed. This assay was able to detect MDV in inoculated chick kidney cells at dilutions of 10(-5). Negative PCR results were obtained using uninoculated chick cells, Marek's Disease Vaccine (SB), Herpesvirus of Turkeys (HVT) and Fowl Laryngotracheitis Vaccine (LT). Bursae, feathers and kidneys from MDV infected chickens were positive in the PCR assay. The same tissues from normal chickens were negative. This method required only 0.5 h for sample preparatory, 3 h for PCR application and 1 h for electrophoresis. Internal probe hybridization confirmed that the PCR products are from MDV, but this hybridization will not be necessary for future MDV detection.

[The isolation of the herpes virus from the white crane and a study of its properties]. / Vydelenie virusa gerpesa ot belogo zhuravlia i izuchenie nekotorykh ego svoistv.

Isolation of a virus agent from sick white cranes in National Oka Preserve is described. The results of virological and serological studies on specimens from the sick birds permitted a conclusion that the infection in the cranes could be induced by avian herpes virus.

Polymerase chain reaction for differentiation between pathogenic and non-pathogenic serotype 1 Marek's disease viruses (MDV) and vaccine viruses of MDV-serotypes 2 and 3.

A polymerase chain reaction (PCR) test based on primers flanking the 132 bp tandem repeat in pathogenic MDV-1 DNA was developed. These primers amplify a dimer or a trimer 132 bp repeat in pathogenic MDV-1 DNA from blood and organs of commercial chickens with Marek's disease (MD) symptoms. Using the same primers in a radioactive PCR test, it was possible to distinguish between vvMDV-1 and the non-pathogenic MDV-1 CVI-988 vaccine in which the 132 bp repeats in the DNA were increased up to 9 repeats. The MDV-1 specific primers did not amplify MDV-2 (SB1) and MDV-3 (HVT) DNA. Primers prepared according to the nucleotide sequence of MDV-1 antigen A gene amplified MDV-1 DNA only. Specific primers prepared according to the nucleotide sequence of MDV-3 (HVT) antigen A gene amplified MDV-3 DNA but not MDV-1 nor MDV-2 DNA. The results of the present study show that the PCR tests can be used for the early identification of vvMDV-1 DNA in pathological samples from diseased commercial chickens and to distinguish between the vvMDV-1 and the three types of virus vaccines used to immunize chickens. The tests are accurate and can be performed in the presence of vaccine virus DNA in the sample.

[Isolation and study of biological properties of non-oncogenic Marek's disease herpesviruses in chickens. 2. Characterization in vivo]. / Izolace a studium biologických vlastností neonkogenních kurecích herpesviru Markovy nemoci. 2. Charakterizace in vivo.

In a previous paper (Jurajda and Halouzka, 1992) the in vitro isolation of two chicken herpesviruses of Marek's disease (M and K strains) was described and results of their characterization were presented. The present paper deals with the in vivo characterization of both isolates: pathogenicity and immunosuppressive characteristics of isolates were observed in a five-week test period, along with the development and production dynamics of antibodies and viral antigen in the feathers of experimentally infected chickens of the Brown Leghorn breed. A technique of double immunodiffusion in agar gel according to Ouchterlony, modified by Woernl (1966), was used to determine the presence of antibodies to Marek's disease virus (MDV) in blood serum and of precipitating MDV-antigen in feather quills of tested chickens. Isolate multiplication and titration were performed in a system of chicken embryonal fibroblasts (CEF) (Jurajda et al., 1984). Chickens were infected i.m. with three virus doses - 10(2) to 10(4) PFU per chicken while the dose 10(4) corresponded to the titre of 10,800 PFU/0.2 ml for M isolate and to the titre of 8,600 PFU/0.2 ml for K isolate. The nature and rate of regressive changes in lymphatic organs were determined according to criteria described by Halouzka and Jurajda (1991). The results are summarized in Tabs. I and II. Neither of the isolates evoked clinical or pathomorphological macroscopic symptoms of the disease. M isolate induced microscopic MD-specific changes in the peripheral nerves (of C type) and only moderate and transient signs of immunosuppression in 11% of infected chickens.(ABSTRACT TRUNCATED AT 250 WORDS)

Differentiation of pathogenic and non-pathogenic serotype 1 Marek's disease viruses (MDVs) by the polymerase chain reaction amplification of the tandem direct repeats within the MDV genome.

There are no simple, direct methods to reliably distinguish oncogenic serotype 1 Marek's disease viruses (MDVs) from their attenuated variants. The present study was an attempt to apply polymerase chain reaction (PCR) to develop a rapid and sensitive assay for the presence of the MDV genome. PCR oligos were chosen to flank the 132-base-pair tandem direct repeats in the serotype 1 MDV genome. The PCR reaction was specific for serotype 1 MDVs, amplifying fragments corresponding to one to three copies of the tandem repeats present in Md11/8, JM/102W, and GA viruses. A high-molecular-weight DNA smear was observed when the DNA from an attenuated Md11/100 was PCR-amplified. Use of the PCR technique allowed the detection of two copies of the 132-base-pair repeat in the DNA extracted from MDV-induced lymphomas removed from two chickens. No DNA was amplified from the DNA extracted from lymphomas induced by either an avian leukosis virus (RAV-1) or reticuloendotheliosis virus (chick syncytial virus).

Gordon Memorial Lecture. Chicken neoplasia--a model for cancer research.

1. The use of animal models has been immensely important for the advancement of our knowledge of the aetiology and pathogenesis of human diseases, including neoplasia. 2. Viruses, as oncogenic agents, were first described in the early 1900s when cell-free filtrates were used experimentally to transmit leukemias and sarcomas in chickens. In more recent years, studies with avian leukosis/sarcoma viruses have led the field in attempts to establish the genetic and molecular basis of viral oncogenesis. 3. Marek's disease of chickens was the first neoplasm proven to be caused by a herpesvirus and it remains the only neoplastic disease for which an effective vaccine has been developed and deployed. It serves as an elegant model as we seek an understanding of the pathogenesis of herpesvirus-induced lymphomas at both the cellular and molecular levels.

Protection against Marek's disease by a fowlpox virus recombinant expressing the glycoprotein B of Marek's disease virus.

Fowlpox virus (FPV) recombinants expressing the glycoprotein B and the phosphorylated protein (pp38) of the GA strain of Marek's disease virus (MDV) were assayed for their ability to protect chickens against challenge with virulent MDV. The recombinant FPV expressing the glycoprotein B gene elicited neutralizing antibodies against MDV, significantly reduced the level of cell-associated viremia, and, similar to the conventional herpesvirus of turkeys, protected chickens against challenge with the GA strain and the highly virulent RB1B and Md5 strains of MDV. The recombinant FPV expressing the pp38 gene failed to either elicit neutralizing antibodies against MDV or protect the vaccinated chickens against challenge with MDV.

Attenuated revertant serotype 1 Marek's disease viruses: safety and protective efficacy.

In earlier studies, a revertant serotype 1 Marek's disease virus (MDV), clone Md11/75C/R2, was found to be a highly protective vaccine virus but was mildly pathogenic for susceptible chickens. The term "revertant" indicates that the virus, after attenuation, gained virulence following backpassage in chickens. The present study is an attempt to develop a more attenuated but still protective vaccine virus from Md11/75C/R2. Forty-two derivative viruses or clones from Md11/75C/R2 were evaluated. Two of these, designated clones R2/23 and R2/29, induced viremia but little or no pathology in preliminary trials and were selected for further study. In a series of nine trials, both clones provided protection against challenge with very virulent MDV strains that was superior to that induced by turkey herpesvirus (HVT) and was not significantly different (P greater than 0.05) from that induced by a bivalent (HVT + SB-1) vaccine. Both clones appeared fully attenuated based on pathogenicity tests in susceptible antibody-negative chickens. Both clones gained virulence on backpassage in chickens, but this seemed of little concern because neither virus spread by contact to other chickens. Although the two clones were very similar, clone R2/23 appeared to have a slightly lower pathogenic potential following backpassage and thus best meets the combined criteria of safety and efficacy.

The early pathogenesis in chicken inoculated with non-pathogenic serotype 2 Marek's disease virus.

A newly cloned serotype 2 Marek's disease virus (MDV), strain ML-6, was inoculated via the nasal cavity in specific-pathogen-free chicks to examine early virus replication and the expression of Marek's disease (MD)-related antigens. Following inoculation, viral intracellular antigens (VIAs) were detected in lymphoid organs (bursas and spleens) between 5 and 14 days post inoculation (PI), in feather follicles between 14 and 30 days PI, and in lungs at 3 days PI by the immunohistopathological staining of avidin-biotin-peroxidase complex method. But, very few VIAs were expressed in the thymuses between 5 and 14 days PI. However, MD tumor-associated surface antigens were not detected in any organs. Viruses were isolated from separated spleen cells at 14 and 30 days PI. Fluorescent antibodies of convalescent sera were also detected after 10 days PI. As most of the VIAs were detectable in B-cells in bursas and spleens. B-cells were considered to be the main first target cells for the serotype 2 MDV infection.

Biological diversity among serotype 2 Marek's disease viruses.

Selected biological characteristics were determined for 14 low-passage serotype 2 Marek's disease virus (MDV) isolates. Four of these isolates were also tested after extensive serial passage in chicken embryo fibroblast cultures. Observations were made on replication in vitro and in vivo, pathogenicity by in ovo inoculation, antigenicity, and protection against virulent MDV challenge. Among the low-passage isolates, there were some differences in pathogenicity after in ovo inoculation but relatively little difference in other characteristics, with the exception of the HN-1 strain, which replicated more rapidly in cell culture but produced generally lower in vivo responses than other isolates. After extended in vitro passage, isolates replicated much more readily in cell culture and produced lower pathologic responses in vivo than low-passage isolates, as has been reported for serotype 1 isolates. No antigenic differences among isolates were detected, but high-passage isolates induced lower levels of precipitating antibodies than low-passage isolates, indicating a possible reduction in A antigen production. The observed diversity associated with strain and passage level may be of value in the selection of optimum vaccine strains.

Isolation of very virulent Marek's disease viruses from vaccinated chickens in Australia.

Very virulent Marek's disease viruses (vvMDV), defined as isolates against which the herpesvirus of turkey (HVT) vaccine provide poor protection, have been isolated from poultry flocks in both the United States and Europe. Twenty-one samples from vaccinated Australian flocks, experiencing problems with excessive Marek's disease (MD), were tested for the presence of transmissible MD viruses (MDV). Of the 16 samples which contained a transmissible agent, 14 were pathogenic in chickens, based on the development of MD lesions or depression of the bursa/body weight ratio. Of the pathogenic isolates which have been successfully typed 10 were serotype 1, and one was serotype 2 MDV. Pathogenicity of isolates varied. Several isolates caused tumours in 20-30% of both vaccinated and unvaccinated chickens. Two isolates, MPF6 and MPF23, caused tumours in more than 50% of chickens. When MPF6 and MPF23 were tested in vaccine trials bivalent vaccine gave no better protection against development of MD lesions than a monovalent vaccine. Isolate MPF23 was so pathogenic that lesions were produced in all chickens, regardless of the vaccine protocol used. Therefore vvMDV have been isolated in Australia, and unlike the vaccines tested overseas, bivalent Australian vaccines do not appear to provide greater protection against these vvMDV.

Detection of Marek's disease virus antigen in chickens by a novel immunoassay.

An immunoassay was developed to detect Marek's disease virus (MDV) antigen on the tips of feathers obtained from MDV-infected chickens. MDV in follicular debris on the feather tip was demonstrated by use of a specific monoclonal antibody. The principle of an indirect ELISA was employed and the feather tip was used as the solid phase. Presence of MDV was reflected by a dark brown precipitate on the feather tip which could be observed by naked eye. This test system proved to be more sensitive than the agar-gel precipitation (AGP) test as all feather tips of MDV-infected animals gave a positive reaction in the feather tip-ELISA whereas about a half yielded a detectable precipitate in the AGP. Advantages of this feather tip-ELISA and applications are discussed.

Replicating Marek's disease virus (MDV) serotype 2 DNA with inserted MDV serotype 1 DNA sequences in a Marek's disease lymphoblastoid cell line MSB1-41C.

We characterized the properties of herpes-type viruses which grew well in a Marek's disease lymphoblastoid cell line, MSB1-41C, inducing cytopathic effect characterized by the formation of syncytial giant cells. Examination of the infectious virus by field inversion gel electrophoresis revealed the presence of DNA of about 180 kbp in both the culture fluid and cell fractions of the infected MSB-41C cells. The DNA was found to consist of Marek's disease virus (MDV) serotype 2 (MDV2) and MDV serotype 1 (MDV1) DNA by Southern blot hybridization. The MDV1 DNA consisted of sequences mainly from the long inverted repeats including multiple copies of 132 bp direct tandem repeats. Molecular cloning of BamHI digests of the MDV2 DNA revealed a fragment of MDV1 DNA and MDV2 DNA fused together, indicating that the recombinant MDV2 DNA had been generated by genetic recombination with the latent MDV1 DNA.