No homology detectable between Marek's disease virus (MDV) DNA and herpesvirus of the Turkey (HVT) DNA

The relation of four different strains of MDV and two strains of HVT was analyzed by gel electrophoresis of viral DNA digested by various restriction endonucleases and by filter hybridization of viral DNA with complementary RNA.The four MDV strains showed fragment patterns completely different from those of HVT upon digestion of the viral DNA with Bam H I, Eco R I, Hind III, Hpa I, and Xho and separation of fragments on agarose gels.The cleavage patterns of the four MDV strains showed great similarities among each other as well as some differences between the individual strains. In the cleavage patterns of HVT a similar close relationship was observed between the two HVT strains with slight divergence between both.Filter hybridizations of viral DNA with labelled complementary RNA prepared from the DNA of the GA strain of MDV or from the DNA of the PH-THV1 strain of HVT revealed no cross-hybridization between the MDV and the HVT strains.cRNA prepared from the DNA of an MDV strain hybridized only to restriction enzyme fragments of the MDV strains transferred to nitrocellulose filters, but not to fragments of HVT DNA, and vice versa.     

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

Summary 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.     

Comparative studies on Marek's disease virus and herpesvirus of turkey DNAs.

DNA of Marek's disease virus (MDV) was compared to that of herpes virus of turkey (HVT). Centrifugation of the two virus DNAs in neutral glycerol and CsCl density gradients showed that the MDV genome was slightly larger than that of HVT and that the buoyant density (1.705 g/ml) of MDV DNA in CsCl gradients was slightly lower than that (1.707 g/ml) of HVT DNA. MDV and HVT DNAs were digested with either EcoRI or HindIII restriction endonuclease and analysed by 0.5% agarose gel electrophoresis. The cleavage patterns of HindIII or EcoRI DNA digests of two strains of these two viruses showed general similarities between the strains, but not between MDV and HVT. However, a few fragments of EcoRI or HindIII digests of MDV DNA co-migrated with those of HVT DNA. DNA-DNA reassociation kinetics and DNA-RNA hybridization between the two viruses indicated that MDV and HVT DNAs share detectable homology, although it is less than 5%. The DNA of a HVT variant, which has lost the ability to protect chickens from Marek's disease, appeared similar to DNA of the vaccine strain in the size buoyant density and in its restriction endonuclease cleavage pattern.     

Differentiation between strains of Marek's disease virus and turkey herpesvirus by immunofluorescence assays

Two serological types of Marek's disease virus and a herpesvirus of turkeys have been differentiated by indirect immunofluorescence tests as (1) pathogenic strains of Marek's disease virus (MDV) and their attenuated variants: HPRS-16, HPRS-16/att, HPRS-B14, JM, JM/att, GA, VC and 'Oldenburg', a recent field isolate; (2) apathogenic strains HPRS-24 and HPRS-27 of MDV; (3) herpesvirus of turkeys strain FC126 and its HVT(A-) variant. Virus strains could not be distinguished on the basis of qualitative differences in immunofluorescent staining of intracellular virus-induced antigens. Results were similar whether chicken kidney, chicken embryo fibroblast or duck embryo fibroblast cell cultures were used. Fluorescence of virus-induced antigens was stronger with homologous than with heterologous antisera. Using the direct immunofluorescence technique Marek's disease virus and turkey herpesvirus infections could be distinguished. There were never any significant differences in the appearance and distribution of antigen in infected cells treated with homologous or heterologous antisera at dilutions of comparable activity using the indirect immunofluorescence technique. Antibody titres of antisera were 4 to 8-fold higher in the indirect immunofluorescence test against the homologous virus-induced antigens than against heterologous antigens. Cross-reactions between the 3 serological types could be prevented by absorption of antisera with the appropriate antigens. Cross-reactions could also be prevented by the appropriate dilution of antisera before use in the indirect immunofluorescence test.     

Immunosuppressive effects of Marek's disease virus (MDV) and herpesvirus of turkeys (HVT) in broiler chickens and the protective effect of HVT vaccination against MDV challenge

Much of the impact of Marek's disease in broiler chickens is considered to be due to immunosuppression induced by Marek's disease virus (MDV). The present study evaluates the effects of an Australian isolate of pathogenic MDV (strain MPF 57) and a non-pathogenic vaccinal strain of herpesvirus of turkeys (HVT) (strain FC 126) on the immune system of commercial broiler chickens for 35 days following challenge at days 0 or 3 of age. It also investigates the extent of protection provided by HVT vaccine against MDV-induced immunosuppression. Immune system variables, including relative lymphoid organ weight, blood lymphocyte phenotype (CD45+/CD3+, putatively T, and CD45+/LC+, putatively B) and antibody production following vaccination against infectious bronchitis (IB) at hatch, were used to assess the immune status of chickens. Immunosuppression was also assessed by susceptibility to secondary challenge with pathogenic Escherichia coli on day 29 post-MDV challenge. MDV infection reduced the weight of the thymus and bursa of Fabricius, the numbers of circulating T lymphocytes and B lymphocytes, and IB antibody titre. The timing of these effects varied. MDV infection greatly increased susceptibility to E. coli infection. HVT alone caused mild depletion of T and B lymphocytes but no effect on immune organ weight or IB titre. Vaccination with HVT provided good protection against most of the immunosuppressive effects of MDV but not against MDV-induced growth impairment and reduced responsiveness to IB vaccination, suggesting that recent Australian strains of MDV may be evolving in virulence to overcome the protective effects of HVT.     

Kinetics of Marek's disease virus (MDV) infection in broiler chickens 1: effect of varying vaccination to challenge interval on vaccinal protection and load of MDV and herpesvirus of turkey in the spleen and feather dander over time

Two experiments in commercial broiler chickens vaccinated with herpesvirus of turkeys (HVT) and challenged with Marek's disease virus (MDV) investigated the effects of the vaccination-to-challenge interval (VCI) on vaccinal protection against Marek's disease, and the kinetics of MDV and HVT load in the spleen and feather dander determined using real-time quantitative polymerase chain reaction. Experiment 1 in isolators tested VCI of 2, 4 and 7 days, while Experiment 2 in floor pens tested VCI of 0, 2, 4, 7 and 10 days. MDV challenge induced gross Marek's disease lesions in 14% to 74% of chickens by 56 days post-challenge. Vaccinal protection increased from ～40% to ～80% with increasing VCI between days 2 and 7 in both experiments, but not thereafter. MDV was detected in both the spleen and dander at 7 days post-challenge and increased rapidly to approximately 21 days post-challenge, after which levels plateaued, rose or fell gradually depending on treatment. HVT was also shed in significant amounts, 1 to 2 logs lower than for MDV, with a clear peak around 14 to 21 days post-vaccination. Vaccination significantly reduced the log₁₀MDV load in the spleen (vaccinated, 2.99±0.20/10⁶ spleen cells; unvaccinated, 4.60±0.23/10⁶ spleen cells) and dander (vaccinated, 5.28±0.13/mg; unvaccinated, 6.00±0.18/mg) from infected chickens. The MDV load had a significant negative association with the VCI and the level of vaccinal protection. Measurement of dander production in Experiment 1 and the dust content of air in Experiment 2, combined with determination of the MDV load in these, enabled estimation of total daily shedding rates of MDV per chicken and of the MDV load in air for the first time.     

Replication of Marek's disease virus in chicken feather tips containing vaccinal turkey herpesvirus DNA

The presence of herpesvirus of turkeys (HVT) DNA in the feather tips of chickens vaccinated with HVT was assessed by dot blot hybridisation with a probe specific for HVT and lacking homology to MDV DNA. Only small amounts of HVT DNA were detected in the feather tips of chickens that were vaccinated or left in contact with HVT vaccinated chickens. However when chickens were challenged with virulent MDV, HVT DNA was detected in the feather tips of vaccinated chickens and the largest amount was detected 35 days after vaccination. HVT DNA was recovered in significantly higher quantities from some of the MDV-infected chickens than from those infected by contact. This suggests that MDV infection may provide helper functions for HVT. MDV DNA was identified in the feather tips of MDV-challenged chickens from 25 to 45 days after challenge. Thus, immunisation of chickens with HVT did not prevent the replication of MDV in the feather tips but only diminished it.     

Further study on the three-dimensional structure of the core of Marek's disease virus and herpesvirus of turkey

Summary Three-dimensional structures of the core of Marek's disease virus and herpesvirus of turkey were examined by the tilting apparatus of an electron microscope. Various types of the core found in the infected cells were considered to represent developmental stages of the viruses. The basic structure of the core consisted of a toroid surrounding a cylindrical mass, which was clearly demonstrated by tilting the core in two directions. A cylindrical mass spooled by more than two toroids, which seemed to constitute a spiral band of 10 to 20 nm, was demonstrated. The maturation process of the cores of the viruses was also discussed.With 7 Figures     

Protection of chickens against very virulent infectious bursal disease virus (IBDV) and Marek's disease virus (MDV) with a recombinant MDV expressing IBDV VP2.

To develop a herpes virus vaccine that can induce immunity for an extended period, a recombinant Marek's disease (MD) virus (MDV) CVI-988 strain expressing infectious bursal disease virus (IBDV) host-protective antigen VP2 at the US2 site (rMDV) was developed under the control of an SV40 early promoter. Chickens vaccinated with the rMDV showed no clinical signs and no mortality and 55% of the chickens were considered protected histopathologically after challenge with very virulent IBDV (vvIBDV), whereas all of the chickens vaccinated with the conventional IBDV vaccine showed no clinical signs and were protected. Chickens vaccinated with the CVI-988 or chickens in the challenge control showed severe clinical signs and high mortality (70-75%) and none of them were protected. Also, the rMDV conferred full protection to chickens against vvMDV just as the CVI-988 strain did, whereas 90% of the challenge control chickens died of MD. Antibody levels against IBDV and MDV following the vaccination increased continuously for at least 10 weeks. No histopathological lesions in the rMDV-vaccinated chickens and no contact transmission of the rMDV to their penmates were confirmed. These results demonstrate that an effective and safe recombinant herpesvirus-based IBD vaccine could be constructed by expressing the VP2 antigen at the US2 site of the CVI-988 vaccine strain.     

Restriction enzyme map of herpesvirus of turkey DNA and its collinear relationship with Marek's disease virus DNA

The genome of herpesvirus of turkey (HVT) was shown to consist of long and short unique regions flanked by inverted repeats (J. Cebrian, Kaschka-Dietrich, C., Berthelot, N., and Sheldrick, P., 1982, Proc. Natl. Acad. Sci. USA 79, 555-558). In this paper we report the construction of the linkage map of HVT DNA for BamHI, HindIII, and PstI restriction endonucleases. The maps were constructed by hybridization of 19 cloned BamHI fragments of HVT DNA to electrophoretically separated digests of genomic DNA. Our results indicate that the terminal and internal inverted repeats (TRL and IRL) flanking the long unique sequences (UL) are spanned by BamHI-F fragment and a -F-related terminal fragment, respectively, whereas the terminal and internal inverted repeats (TRS and IRS) flanking the short unique sequences (US) are mostly contained in BamHI-A fragment. Both BamHI-A and -F showed a heterogeneity in size, suggesting the presence of amplification of certain sequences in the inverted repeats. We also report that the HVT genome is collinear with the genetically related Marek's disease virus (MDV) genome, as determined by hybridization of labeled cloned HVT DNA fragments with electrophoretically separated MDV DNA fragments.     

The restriction endonuclease map of Marek's disease virus (MDV) serotype 2 and collinear relationship among three serotypes of MDV.

A BamHI, EcoRI, and XhoI restriction endonuclease map of Marek's disease virus (MDV) serotype 2 (MDV2) DNA was constructed by double-digest analyses of 28 cloned BamHI and 11 cloned EcoRI fragments of MDV2 DNA, followed by hybridization tests of these cloned BamHI DNA fragments with electrophoretically separated digests of MDV2-infected cell DNA. On this map, MDV2 genome consisted of two segments which have unique regions inserted between two inverted repeat regions as observed in MDV serotype 1 and 3 genomes. Further, the DNA homology among three serotypes of MDV was examined by hybridization under less stringent conditions using cloned BamHI fragments of MDV2 DNA. Most of the MDV2 fragments located within the unique regions hybridized with MDV serotype 1 and 3 DNAs, indicating the presence of the collinear relationship among three serotypes. In addition, MDV2 DNA fragments which hybridized with the DNA fragments encoding MDV1 gp57-65 (or A antigen) or MDV1 gp100, gp60, gp49 (or B antigen) were identified and these fragments of serotypes 1 and 2 found to be collinear.     

Phylogeny and recombination history of gallid herpesvirus 2 (Marek's disease virus) genomes

Phylogenetic analyses based on concatenated amino acid sequences from orthologous loci from eight genomes of alpha herpesviruses infecting birds provided strong support for the following hypotheses: (1) gallid HV3 is a sister taxon to gallid HV2 but gallid HV1 is not closely related to the other two chicken herpesviruses; (2) meleagrid HV1 is closer to both gallid HV2 and gallid HV3 than is gallid HV1; (3) within gallid HV2, the virulent GA genome forms an outgroup to both the avirulent CVI988 genome and the highly virulent Md5 and Md11 genomes. Analysis of the pattern of synonymous nucleotide substitution between orthologous genes shared by four complete genomes of gallid HV2 showed strong evidence of past events of homologous recombination that homogenized certain loci between genomes. Eight of these loci represented cases of loci homogenized between the CVI988, on the one hand, and the Md5 and Md11 genomes, on the other hand. Two others represented loci where the GA genome was homogenized with those of Md5 and Md11. The two loci (UL49.5 and RLORF12) that were homogenized among the virulent genomes GA, Md5, and Md11 are candidates for contributing to viral virulence.     

Multiplication of turkey herpes virus and Marek's disease virus in chick embryo skin cell cultures.

A simple method for the in vitro cultivation of chick embryo skin epithelial cells was developed and the replication of turkey herpes virus (HVT) and Marek's disease herpes virus (MDHV) in this system was studied. A high percentage of cells in monolayers inoculated with HVT (19·7 per cent) and MDHV (4·6 per cent) was infected on the fourth day post-incubation. Titres of infectious cells in the culture fluid or cell-free virus in the cell extract were low and cell-free virus was not detected in the culture medium. Enveloped particles of HVT, but not of MDHV, were detected by electron microscopy.     

Infectious laryngotracheitis virus, an alpha herpesvirus that does not interact with cell surface heparan sulfate

Among the alpha herpesviruses studied to date, the initial stage of wild-type virus attachment involves an interaction between virally encoded structural envelope glycoproteins (predominantly glycoprotein C) and cell surface heparan sulfate proteoglycans. An analysis of the infectious laryngotracheitis virus (ILTV) glycoprotein C and glycoprotein B sequences suggested that these proteins lacked consensus heparin-binding domains. This indicated that ILTV might attach to its host cell in a heparan-independent manner, distinct from other alpha herpesviruses. The infectivity of two ILTV strains, a tissue-culture-adapted vaccine strain and a virulent field challenge strain, were found to be insensitive to the presence of exogenous heparin or chondroitin. Furthermore, infectivity was retained in chicken embryonic liver cells treated with heparinase. However, 4 degrees C attachment studies and penetration studies in the presence of citrate buffer clearly demonstrated that ILTV attaches stably to and effectively penetrates chicken embryonic liver cells. Consequently, ILTV represents an alpha herpesvirus whose initial attachment step does not involve interactions with heparan or chondroitin sulfate containing proteoglycans.     

Use of lectins to detect and differentiate subtypes of Marek's disease virus and turkey herpesvirus glycoproteins in tissue culture

Biotinylated lectins in conjunction with an avidin-biotin-peroxidase complex were used for the first time to reveal glycoproteins in chicken and duck embryo fibroblasts infected with three prototype members of the avian herpesvirus group, Marek's disease virus serotypes 1 and 2 and turkey herpesvirus. By using a panel of 10 lectins, a pattern of reactivity emerged which was both group- and type-specific. Morphological details of the lectin-stained cells include cytoplasmic granulation, capping and bleb-like protrusions of the cell membrane. Although no antibody is necessary for the reaction, this novel approach allows specific detection of the glycan moieties of viral glycoproteins as they are synthesized during infection.     

Effect of reticuloendotheliosis virus and infectious bursal disease virus on Marek's disease herpesvirus latency

Birds infected with reticuloendotheliosis virus (REV) were exposed to Marek's disease virus (MDV) to determine if the establishment of MDV latency was affected by REV-induced immunosuppression, while other chickens, already latently infected with MDV, were challenged with REV or infectious bursal disease virus (IBDV) to determine if the consequent immunosuppression caused a return to cytolytic infection. Immunosuppression was assessed by in vitro mitogen stimulation assays with spleen cells. Latently MDV-infected cells were free of viral internal antigen(s) (VIA) but could be identified by their ability to produce VIA after in vitro cultivation. The results were unexpected: chickens infected with either of these viruses had very low, and often undetectable, levels of MDV infection when compared with appropriate controls. REV infection interfered with early cytolytic MDV infection, and IBDV and REV both failed to activate latent MDV infection in the face of inferred (IBDV) or demonstrated (REV) immunosuppression by these viruses. Apparently, both viruses reduced the number of MDV infected cells since neither cytolytic nor latent infection could be demonstrated. This was based on an absence of cells with VIA either before or after cultivation and, in the case of REV infection, on failure to detect MDV-DNA using a dot-blot hybridisation technique.