Demonstration of a Marek's disease virus-specific antigen in tumour lesions of chickens with Marek's disease using monoclonal antibody against a virus phosphorylated protein

Marek’s Disease Is a Threat for Large Scale Poultry Production

Marek’s disease (MD) is one of the widespread infectious diseases that causes huge losses in large-scale poultry production. This is due to weight loss, poorer feed conversion and an increased number of deaths among infected birds. The etiological agent is a Marek’s disease virus (MDV) belonging to the Herpesviridae family. It is mainly described in poultry, however, it is also found in geese. There are three MDV serotypes, and four patotypes within serotype 1. Currently, Marek’s disease is very rare in its classical form. There are non-specific clinical symptoms, and anatomopathological changes are mainly observed in the liver, spleen and the reproductive system. This may be due to the evolution in the pathogenicity of MDV field strains over the past several decades. The presence of MDV and number of molecular diagnostic tests based on the detection of viral nucleic acids and viral proteins is already found in birds that have several weeks old. Laboratory diagnostics are based mainly on molecular biology (mainly PCR) methods. The only relatively effective method instead of biosecurity measures, of preventing MD is prophylactic vaccination of 1-day-old chickens or in ovo vaccination. Nevertheless, Marek’s disease is still recorded in poultry flocks around the world, with estimated losses reaching several million dollars.

Construction and characterization of Marek's disease viruses having green fluorescent protein expression tied directly or indirectly to phosphoprotein 38 expression

Marek's disease (MD) is caused by Marek's disease virus (MDV), a highly cell-associated alphaherpesvirus. MD is primarily characterized by lymphocyte infiltration of the nerves and the development of lymphomas in visceral organs, muscle, and skin. MDV encodes two phosphoproteins, pp24 and pp38, that are highly expressed during lytic infection. These proteins were initially identified in MDV-induced tumors but are now known to be linked primarily to MDV lytic infection. Despite the recent characterization of a pp38 deletion mutant MDV, the functions of these phosphoproteins remain unknown. The goal of this work was to construct recombinant MDVs having direct fusions of a marker gene, the green fluorescent protein (GFP), to pp38 in order to study the expression patterns and localization of this protein during stages of MDV infection. We report the construction of two recombinant viruses, one having the enhanced green fluorescent protein (eGFP) fused in-frame to the pp38 open reading frame (ORF) (RB1Bpp38/eGFP) and the other having soluble-modified GFP (smGFP) downstream but out-of-frame with pp38 (RB1Bpp38/smGFP). During construction of RB1Bpp38/eGFP, an ORF located downstream of pp38 (LORF12) was partially deleted. In RB1Bpp38/smGFP, however, LORF12 and its immediate 5' upstream sequence was left intact. This report describes the construction, cell culture, and in vivo characterization of RB1Bpp38/eGFP and RB1Bpp38/smGFP. Structural analysis showed that the virus stocks of RB1Bpp38/eGFP and RB1Bpp38/smGFP had incorporated the GFP cassette and were free of contaminating parent virus (RB1B). Moreover, RB1Bpp38/eGFP and RB1Bpp38/smGFP contained two and three and four and five copies of the 132-bp repeats, respectively. Expression analysis showed that the transcription of genes in RB1Bpp38/eGFP-and RB1Bpp38/smGFP-infected chicken embryo fibroblasts (CEFs) were similar to RB1B-infected CEFs, with the notable exception of deletion of a LORF12-specific transcript in RB1Bpp38/ eGFP-infected cells. In CEFs, RB1Bpp38/eGFP and RB1Bpp38/smGFP showed comparable one-step growth kinetics to parental virus (RB1B). RB1Bpp38/eGFP and RB1Bpp38/smGFP, however, showed quite distinct growth characteristics in vivo. Two independent clones of RB1Bpp38/eGFP were highly attenuated, whereas RB1Bpp38/smGFP exhibited pathogenesis similar to parent virus and retained oncogenicity. Our results suggest that the RB1Bpp38/eGFP phenotype could be due to an interference with an in vivo-specific pp38 function via GFP direct fusion, to the deletion of LORF12, or to a targeting of the immune response to eGFP. Because deletion of pp38 was recently found not to fully attenuate very virulent MDV strain MD-5, it is possible that deletion of LORF12 may be at least partially responsible for the attenuation of RB1Bpp38/eGFP. The construction of these viruses and the establishment of cell lines from RB1Bpp38/smGFP provide useful tools for the study of MDV lyric infection in cell culture and in vivo, in studies of the reactivation of MDV from latency, and in the functional analysis of LORF12.

The genome of a very virulent Marek's disease virus

Here we present the first complete genomic sequence, with analysis, of a very virulent strain of Marek's disease virus serotype 1 (MDV1), Md5. The genome is 177,874 bp and is predicted to encode 103 proteins. MDV1 is colinear with the prototypic alphaherpesvirus herpes simplex virus type 1 (HSV-1) within the unique long (UL) region, and it is most similar at the amino acid level to MDV2, herpesvirus of turkeys (HVT), and nonavian herpesviruses equine herpesviruses 1 and 4. MDV1 encodes 55 HSV-1 UL homologues together with 6 additional UL proteins that are absent in nonavian herpesviruses. The unique short (US) region is colinear with and has greater than 99% nucleotide identity to that of MDV1 strain GA; however, an extra nucleotide sequence at the Md5 US/short terminal repeat boundary results in a shorter US region and the presence of a second gene (encoding MDV097) similar to the SORF2 gene. MD5, like HVT, encodes an ICP4 homologue that contains a 900-amino-acid amino-terminal extension not found in other herpesviruses. Putative virulence and host range gene products include the oncoprotein MEQ, oncogenicity-associated phosphoproteins pp38 and pp24, a lipase homologue, a CxC chemokine, and unique proteins of unknown function MDV087 and MDV097 (SORF2 homologues) and MDV093 (SORF4). Consistent with its virulent phenotype, Md5 contains only two copies of the 132-bp repeat which has previously been associated with viral attenuation and loss of oncogenicity.

The Leeuwenhoek Lecture, 1997. Marek's disease herpesvirus: oncogenesis and prevention

There are a number of neoplasias for which a herpesvirus is an essential part of the aetiology. Of these, Marek's disease is the most common and provides excellent opportunities for the study of a herpesvirus-induced tumour both experimentally and under natural conditions in the field. Marek's disease is caused by an alpha herpesvirus; it differs from the other oncogenic herpesviruses which are gamma herpesviruses. It is a ubiquitous virus in poultry populations of the world and is highly cell-associated and contagious, yet only a proportion of infected fowl develop tumours. Evidence is presented to suggest that at least one of the reasons for a wide variation in the incidence of the disease is a temporal interplay between virulent viruses and viruses of low or no virulence. The viral genes associated with the oncogenicity of Marek's disease virus (MDV) are discussed and it is concluded that it is likely that several genes are involved. Finally, a brief history of vaccination to control Marek's disease is given and mode of action discussed. It is concluded that the mechanism of protection is mainly through an antiviral cell mediated immune response, resulting in a lowered challenge virus burden. Marek's disease viruses over the past 40 years have been evolving greater oncogenicity, some of which are not adequately controlled by the vaccines that are currently available. It is suggested that for MDV to produce tumours, there is a need for the cytolytic infection phase and that infection must be with an MDV which possesses a functional gC, ICP4 for maintaining latency which allows the expression of at least the 1.8 kb family, pp38, meq, and possibly pp14 genes, for maintaining the tumour state and possibly initiating this state. Intervention in this process reduces the chance of tumour formation and incidence in a population which can occur through natural or man-mediated infection with non-pathogenic MDVs.

Expression of Marek's disease virus (MDV) serotype 2 gene which has partial homology with MDV serotype 1 pp38 gene

We constructed the recombinant baculovirus expressing the gene of non-pathogenic Marek's disease virus (MDV) serotype 2 (MDV2) which encodes a polypeptide with partial homology to MDV serotype 1 (MDV1) pp38, an antigen associated with transformed cells. The recombinant MDV2 protein was detected as a band of 32 kDa in immunoblot analysis with MDV2-infected chicken serum. Mouse serum against insect Spodoptera frugiperda cells infected with the recombinant baculovirus immunoprecipitated a 38 kDa molecule from the lysate of MDV2-infected chicken embryo fibroblasts (CEFs) but did not immunoprecipitate the MDV1 pp38 from the lysate of MDV1-infected CEFs. This result indicates that the recombinant MDV2 protein has no epitopes shared with the MDV1 pp38.

Use of recombinant pp38 antigen of Marek's disease virus to identify serotype 1-specific antibodies in chicken sera by western blotting

A fowlpox recombinant expressing the pp38 antigen of Marek's disease virus has been constructed. Production of pp38 in chick embryo fibroblasts (CEF) infected at a m.o.i. of 1 pfu/cell occurred over a period of 5 days and reached a peak at 72 h after infection. The pp38 antigen could be released from infected cells by freezing and thawing. Western blot analysis showed that denatured pp38 antigen reacted with antisera from chickens inoculated with serotype 1 MDV but failed to react with antisera from chickens inoculated with MDV serotype 2 or HVT. The results suggest that MDV pp38 contains a serotype 1-specific epitope which becomes available upon denaturation of the antigen and that this could be exploited to identify MDV-specific antibodies in epidemiological studies. The relationship between pp38 and the related polypeptides pp24 and pp41 in MDV-infected cells was also examined. The results suggest that pp24 and pp38 are synthesised independently and that MDV coded proteins (probably a protein kinase) might be required to convert pp38 to pp41.

Mapping of Marek's disease virus genome: identification of junction sequences between unique and inverted repeat regions

Polymerase chain reaction (PCR) to amplify MDV DNA and subsequent sequencing identified the junction of TRL/UL, UL/IRL, IRS/US, and US/TRS. The TRL/UL junction is located 192 bp downstream of the last EcoRI site in the TRL region, while the UL/IRL junction is located 192 bp upstream of the first EcoRI restriction enzyme site in the IRL region. The IRS/US junction is located 950 bp downstream of the second EcoRI site in the IRS region, while the US/TRS junction is located 950 bp upstream of the first EcoRI restriction enzyme site in the TRS region. BamHI restriction enzyme mapping of one of the PCR products identified two novel DNA subfragments, BamHI-U2 and -P4, upstream of the US/TRS junction of the MDV genome. Sequencing of the BamHI-D fragment revealed a novel open reading frame (ORF) encoding a 155 amino acid protein. The TRL/UL junction is located in this ORF. The N-terminal 65 amino acids of this protein is homologous to the N-terminal region of the previously reported pp38, which is located in the UL/IRL region. Computer-assisted analysis indicated that both are transmembrane proteins and that they share an antigenic domain.

Alterations in DNA sequence and RNA transcription of the Bam HI-H fragment accompany attenuation of oncogenic Marek's disease herpesvirus

The nucleotide sequences of the BamHI-H fragment of the HPRS16 strain of Marek's disease virus (MDV) and of its attenuated derivative HPRS16/att have been determined. The results show that in addition to the tandem expansion of a 132 bp sequence from two copies in HPRS16 virus to eight copies in HPRS16/att, nucleotide substitutions, deletions, and insertions were also noted. Several potential open reading frames (ORFs) were identified. One of these (ORF 13) encoded a deduced protein, mol wt 32 kD, which is likely to be the serotype-1 specific phosphoprotein expressed in tumours (1) and mapped to an EcoRI fragment within BamHI-H (2). Our results suggest that this ORF is unlikely to be the B antigen (3). ORF 4, which had some similarity to CD4 and immunoglobulin M heavy chain, was encoded by a transcript that originated within the first copy of the 132 bp repeat. ORF 21, which mapped entirely within UL, encoded a deduced protein at least 322 amino acids long that had some similarity to varicella zoster virus (VZV) alpha trans-inducing protein. None of these ORFs was altered significantly by attenuation, except ORF 4 and another small ORF (ORF 3), 5' of the 132 bp repeats, which would probably fail to be transcribed because of truncation of an RNA transcript.

Comparison of indirect immunofluorescence (IF) test with enzyme-linked immunosorbent assay (ELISA) in screening of hybridomas to very virulent Marek's disease virus

For identifying virus-specific antigens of Marek's disease virus (MDV), monoclonal antibodies (MAbs) against strain Md5 of serotype 1, which is known to be a very virulent MDV (vvMDV), were isolated. Fifty-eight hybridoma clones that secreted MAbs against vvMDV were obtained. Of these MAbs, 36 gave positive reactions in an immunofluorescence (IF) test, and 22 gave positive reactions on enzyme-linked immunosorbent assay (ELISA). None of these MAbs gave positive reactions in both the IF test and ELISA. Of the MAbs that gave positive reactions in the IF test, 33 clones reacted with MDV1-specific epitopes, the other three reacting with MDV1-HVT intertypic epitopes. None of the clones reacted with MDV1-MDV2 intertypic epitopes. Three virus-specific polypeptides were identified by radioimmunoprecipitation and sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) or immunoblotting. These polypeptides were recognized by 12 MAbs giving positive reactions by IF, but by none of those giving positive reactions by ELISA. In addition, size heterogeneity of the MDV1-specific phosphorylated polypeptides in the MDV1 strains was shown using the MAbs against Md5.