Absolute quantitation of Marek's disease virus genome copy number in chicken feather and lymphocyte samples using real-time PCR.

A real-time PCR method was developed, optimised and validated, to enable quantitation of Marek's disease virus genomes as copy number per million host cells. The duplex PCR measured the virus meq gene and host ovotransferrin gene in a single reaction enabling correction for differences in amount of sample DNA added. A bacterial artificial chromosome (BAC) clone of the virus genome, and a plasmid (pGEM-T-ovo) bearing a fragment of the chicken ovotransferrin gene, were used to quantify virus and host genomes respectively. This sensitive and reproducible assay was established initially using chicken lymphocyte DNA, then adapted for feather tip DNA by inclusion of bovine serum albumin in the reaction to overcome inhibition by melanin. The principal advantages are: (1) determination of absolute virus genome copy number enabling meaningful comparison between samples; (2) expression of copy number per million cells, allowing direct correlation with plaque assays; (3) using BAC-cloned whole virus genome as a standard potentially enables any virus gene to be used as the PCR target. This is the first report of quantitation of MDV genomes in feather tips, and application of this assay could significantly further our understanding of pathogenesis, spread, diagnosis, genetic resistance and vaccinal control of Marek's disease.

Oncogenicity of virulent Marek's disease virus cloned as bacterial artificial chromosomes.

Marek's disease virus (MDV) is an oncogenic alphaherpesvirus that induces T-cell lymphomas in poultry. We report the construction of bacterial artificial chromosome (BAC) clones of the highly oncogenic RB-1B strain by inserting mini-F vector sequences into the U(S)2 locus. MDV reconstituted from two BAC clones induced rapid-onset lymphomas similar to those induced by the wild-type virus. Virus reconstituted from another BAC clone that showed a 7.7-kbp deletion in the internal and terminal unique long repeat regions was nononcogenic, suggesting that the deleted region may be associated with oncogenicity. The generation of the oncogenic BAC clones of MDV is a significant step in unraveling the oncogenic determinants of this virus.

Assessing the roles of endogenous retrovirus EAV-HP in avian leukosis virus subgroup J emergence and tolerance.

Avian leukosis virus (ALV) subgroup J is thought to have emerged through a recombination event between an unknown exogenous ALV and the endogenous retrovirus elements designated EAV-HP. All EAV-HP elements identified to date in the chicken genome show large deletions, including that of the entire pol gene. Here we report the identification of four segregating chicken EAV-HP proviruses with complete pol genes, one of which shows exceptionally high sequence identity and a close phylogenetic relationship with ALV-J with respect to the env gene. Embryonic expression of EAV-HP env has been suggested as a factor associated with immunological tolerance induction in a proportion of ALV-J-infected meat-type chickens. In support of this, env gene transcripts expressed from two of the four newly identified EAV-HP proviruses were demonstrated in chicken embryos. However, when ALV-J-infected outbred meat-type chickens were assessed, the presence of intact EAV-HP proviruses failed to directly correlate with ALV-J tolerance. This association was further examined using F(2) progeny of two inbred lines of layer chicken that differed in EAV-HP status and immunological responses to ALV-J. Immunological tolerance developed in a small proportion of F(2) progeny birds, reflecting the expected phenotypic ratio for inheritance of a double-recessive genotype; however, the status of tolerance did not show any direct correlation with the presence of the intact EAV-HP sequence. Nevertheless, identification of an intact chicken EAV-HP locus showing a uniquely close relationship to the ALV-J prototype clone HPRS-103 in the env region provides the strongest evidence of its contribution to the emergence of ALV-J by recombination.

Infection of macrophages by a lymphotropic herpesvirus: a new tropism for Marek's disease virus.

Marek's disease virus (MDV) is classified as an oncogenic lymphotropic herpesvirus of chickens. MDV productively and cytolytically infects B, alphabetaT and gammadeltaT lymphocytes and latently infects T-helper lymphocytes. The aims of this study were to identify whether MDV infects macrophages in vivo and, if so, whether quantitative differences in macrophage infection are associated with MDV strain virulence. Chickens were infected with either virulent MDV (HPRS-16) or 'hypervirulent' MDV (C12/130). Flow cytometry with monoclonal antibodies recognizing MDV pp38 antigen and leukocyte antigens was used to identify MDV lytically infected cells. Macrophages from HPRS-16- and C12/130-infected chickens were pp38(+). It is demonstrated that macrophages are pp38(+) because they are infected and not because they have phagocytosed MDV antigens, as assessed by confocal microscopy using antibodies recognizing MDV antigens of the three herpesvirus kinetic classes: infected cell protein 4 (ICP4, immediate early), pp38 (early) and glycoprotein B (gB, late). Spleen macrophages from MDV-infected chickens were ICP4(+), pp38(+) and gB(+), and ICP4 had nuclear localization denoting infection. Finally, MDV pp38(+) macrophages had high inherent death rates, confirming cytolytic MDV infection, although production of virus particles has not been detected yet. These results have two fundamental implications for understanding MDV pathogenesis: (i) MDV evolved to perturb innate, in addition to acquired, immunity and (ii) macrophages are excellent candidates for transporting MDV to primary lymphoid organs during the earliest stages of pathogenesis.

Replication-competent bacterial artificial chromosomes of Marek's disease virus: novel tools for generation of molecularly defined herpesvirus vaccines.

Marek's disease (MD), a highly infectious disease caused by an oncogenic herpesvirus, is one of the few herpesvirus diseases against which live attenuated vaccines are used as the main strategy for control. We have constructed bacterial artificial chromosomes (BACs) of the CVI988 (Rispens) strain of the virus, the most widely used and effective vaccine against MD. Viruses derived from the BAC clones were stable after in vitro and in vivo passages and showed characteristics and growth kinetics similar to those of the parental virus. Molecular analysis of the individual BAC clones showed differences in the structure of the meq gene, indicating that the commercial vaccine contains virus populations with distinct genomic structures. We also demonstrate that, contrary to the published data, the sequence of the L-meq of the BAC clone did not show any frameshift. Virus stocks derived from one of the BAC clones (clone 10) induced 100 percent protection against infection by the virulent strain RB1B, indicating that BAC-derived viruses could be used with efficacies similar to those of the parental CVI988 vaccines. As a DNA vaccine, this BAC clone was also able to induce protection in 6 of 20 birds. Isolation of CVI988 virus from all of these six birds suggested that immunity against challenge was probably dependent on the reconstitution of the virus in vivo and that such viruses are also as immunogenic as the in vitro-grown BAC-derived or parental vaccine viruses. Although the reasons for the induction of protection only in a proportion of birds (33.3%) that received the DNA vaccine are not clear, this is most likely to be related to the suboptimal method of DNA delivery. The construction of the CVI988 BAC is a major step towards understanding the superior immunogenic features of CVI988 and provides the opportunity to exploit the power of BAC technology for generation of novel molecularly defined vaccines.

Monocytosis is associated with the onset of leukocyte and viral infiltration of the brain in chickens infected with the very virulent Marek's disease virus strain C12/130.

Marek's disease (MDV) virus is mainly known for the induction of visceral lymphomas and lymphoid infiltration of peripheral nerves. Recently, additional tropism for the central nervous system has been recognised as a distinct feature of disease induced by very virulent MDV isolates. During the analysis of changes in the peripheral blood leukocyte subpopulations in chickens infected with either a virulent (HPRS-16) or a very virulent (C12/130) strain of MDV, we observed a marked monocytosis in chickens infected with C12/130. Perivascular cuffing in brain and mononuclear cell infiltration into the meninges of chickens infected with C12/130 were associated with the appearance of the monocytosis from 6-10 days post-infection. Our results show that a peripheral blood monocytosis may be a contributory factor in establishing or accelerating the severity of mononuclear infiltration into the meninges and perivascular spaces in the brain during infection by very virulent C12/130 strain of MDV.