The pathogenicity of a field isolate of Marek's disease virus (MDV) named GXY2 integrated with retroviral long terminal repeat (LTR) sequence from a chicken with MD tumors was evaluated. Experimental chickens were divided into group A, B, C, D and E. The later four groups were vaccinated on one-day-old with CVI988/Rispens for group B and D, with HVT for group C and E, while group A was taken as no-vaccinated control. On 8-day-old, group A, B and C were challenged with GXY2 by intra-abdominal injection, group D and E were kept as un-challenged control. All the birds were raised routinely until 82 days post-challenge (PC), died birds during the experiment and the slaughtered birds at the end of the experiment were necropsied and examined for gross lesions of MD and further confirmed by a developed polymerase chain reaction (PCR) based differential diagnosis technique for avian neoplastic diseases. The results showed that time of onset of MD death of group A, B and C were PC 25, 77 and 29 days with the incidences of visible MD visceral tumors. On PC 82 days, tumor incidences and mortalities of group A, B and C were 72%, 34.8% and 50%, 84%, 21.7% and 20%, respectively. The vaccination protection of CVI988/Rispense and HVT were 51.67% and 30.56% respectively. Among all the visceral organs, heart had the highest tumor incidences (23.5%), and then followed by liver (14.7%) and gizzard (10.3%). The weight-gain of unvaccinated birds was significantly depressed and severe dystrophy of thymus and bursa of Fabricius were also found. The results of the study demonstrated that isolate GXY2 possessed the ability of causing acute tumors and overcoming the protection of the vaccinations of either CVI988/Rispense or HVT.
Animals ; Chickens ; Mardivirus ; genetics ; pathogenicity ; Marek Disease ; pathology ; virology ; Polymerase Chain Reaction ; Retroviridae ; genetics ; Terminal Repeat Sequences ; genetics

The UL49.5 gene of most herpesviruses is conserved and encodes glycoprotein N. However, the UL49.5 protein of duck enteritis virus (DEV) (pUL49.5) has not been reported. In the current study, the DEV pUL49.5 gene was first subjected to molecular characterization. To verify the predicted intracellular localization of gene expression, the recombinant plasmid pEGFP-C1/pUL49.5 was constructed and used to transfect duck embryo fibroblasts. Next, the recombinant plasmid pDsRed1-N1/glycoprotein M (gM) was produced and used for co-transfection with the pEGFP-C1/pUL49.5 plasmid to determine whether DEV pUL49.5 and gM (a conserved protein in herpesviruses) colocalize. DEV pUL49.5 was thought to be an envelope glycoprotein with a signal peptide and two transmembrane domains. This protein was also predicted to localize in the cytoplasm and endoplasmic reticulum with a probability of 66.7%. Images taken by a fluorescence microscope at different time points revealed that the DEV pUL49.5 and gM proteins were both expressed in the cytoplasm. Overlap of the two different fluorescence signals appeared 12 h after transfection and continued to persist until the end of the experiment. These data indicate a possible interaction between DEV pUL49.5 and gM.
Animals ; Ducks/virology ; Genes, Viral/genetics ; Mardivirus/*genetics ; Membrane Glycoproteins/*genetics ; Microscopy, Fluorescence ; Phylogeny ; Polymerase Chain Reaction/veterinary ; Viral Envelope Proteins/*genetics

We used a meq-deleted attenuated MDV-I strain GX0101Δmeq as a vector to construct a recombinant virus expressing the exogenous gene NDV-F. The ORF of exogenous gene NDV-F was inserted into the eukaryotic expression vector pcDNA3.1(-). Then, the expression cassette of NDV-F which contains the CMV promoter was amplified. Simultaneously, we amplified the selected gene Kan+ expression cassette and inserted them into the PMD18-T vector. Tandem expression cassettes were amplified using primers containing the 50-bp homologous arm of MDV-US2. The PCR product was electroporated into EL250 host bacteria containing GX0101Δmeq. Then, the Kan+ expression cassette was deleted from the recombinant virus genome using 1% arabinose. The plasmid of the positive clone which the Kan+ expression cassette was deleted was extracted and transfected into CEFs to rescue the recombinant virus. The recombinant virus was injected into chickens to observe its growth and replication. The recombinant virus rMDV-F containing the exogenous gene NDV-F was rescued successfully. The recombinant virus could duplicate and express well in CEFs, and grow and replicate well in chickens. Using GX0101Δmeq as a vector, combined with a recombinant system of Red E/T and FLP/FRT, we constructed a recombinant virus that expressed the exogenous gene NDV-F. This study could lay the foundation for further study of recombinant viruses.
Animals ; Cell Line ; Chickens ; virology ; DNA, Recombinant ; genetics ; Gene Expression ; Genetic Engineering ; Genetic Vectors ; genetics ; Mardivirus ; genetics ; physiology ; Plasmids ; genetics ; Viral Proteins ; genetics ; Virus Replication

The aim of this study was to construct the complete genome of Marek's disease virus serotype 814 strain as an infectious bacterial artificial chromosome (BAC). Using self-designed selection marker Eco-gpt (1.3 kb) and BAC vector pBeloBAC11 (7.5 kb), we constructed the transfer plasmid pUAB-gpt-BAC11. The plasmid pUAB-gpt-BAC11 and MDV total-DNA were cotransfected into secondary CEFs; we put the virus-containing cells in selection medium for eight rounds and obtained purified recombinant viruses. Recombinant viral genomes were extracted and electroporated into E. coli, BAC clones were identified by restriction enzyme digestion and PCR analysis. Finally, we obtained 38 BAC clones, DNA from various MDV-1 BACs was transfected into CEFs, and recombinant virus was reconstituted by transfection of MDV-BAC2 DNA. We successfully cloned the complete genome of MDV-1814 strain as an infectious bacterial artificial chromosome. With these cloned genomes, a revolutionary MDV-DNA engineering platform utilizing RED/ET recombination system was constructed successfully, which can help the understanding of MDV gene functions and promote the using of MDV as a vector for expressing foreign genes. In addition, it opens the possibility to generate novel MDV-1 vaccines based on the BACs.
Animals ; Chickens ; immunology ; virology ; Chromosomes, Artificial, Bacterial ; genetics ; Cloning, Molecular ; DNA, Recombinant ; genetics ; DNA, Viral ; genetics ; Fibroblasts ; metabolism ; Genetic Engineering ; methods ; Mardivirus ; classification ; genetics ; physiology ; Serotyping ; Transfection ; Viral Proteins ; genetics ; physiology ; Virus Replication

A transfer plasmid vector pUC18-US10-VP2 was first constructed by inserting the gene of the enhancer green fluorescent protein(eGFP) fused to the VP2 gene of very virulent Infectious bursal disease virus (IBDV) JS strain into the US10 fragment of the Marek's disease virus (MDV) CV1988/Rispens. The recombinant virus, designated as rMDV, was developed by co-transfecting CEF with the transfer plasmid vector and simultaneously infecting with the CVI988/Rispens virus. The PCR and IFA results indicated that the rMDV is stable after 31 passages. Chickens vaccinated with rMDV were protected from challenge with 100LD50 of IBDV JS. The protection ratio of the chickens vaccinated with the 1000PFU, 2000PFU, 5000PFU of the rMDV were 50%, 60%, and 80% respectively. It is interesting that the average histopathology BF lesion scores of chicken group immunized with 5000PFU of rMDV by one-time vaccination was close to that of chicken group vaccinated with IBDV live vaccine NF8 strain for twice (2.0/1.5). There is no difference in protection between the groups (P > 0.05) but significent difference between groups immunized with 5000 PFU of rMDV and with normal MDV. This demonstrated that rMDV expressing VP2 fusion protein was effective vaccine against IBDV in SPF chickens.
Animals ; Birnaviridae Infections ; prevention & control ; veterinary ; Chickens ; Genetic Vectors ; Green Fluorescent Proteins ; genetics ; Infectious bursal disease virus ; genetics ; immunology ; Mardivirus ; genetics ; metabolism ; Recombinant Fusion Proteins ; biosynthesis ; genetics ; immunology ; Recombination, Genetic ; Transfection ; Vaccination ; Vaccines, DNA ; genetics ; immunology ; Viral Structural Proteins ; biosynthesis ; genetics ; immunology ; Viral Vaccines ; genetics ; immunology

Animals ; Forecasting ; Herpesvirus 2, Gallid ; genetics ; physiology ; Marek Disease ; genetics ; metabolism ; virology ; MicroRNAs ; metabolism

To rapidly and accurately manipulate genome such as gene deletion, insertion and site mutation, the whole genome of a very virulent strain Md5 of Marek's disease virus (MDV) was inserted into bacterial artificial chromosome (BAC) through homogeneous recombination. The recombinant DNA was electroporated into DH10B competent cells and identified by PCR and restriction fragment length polymorphism analysis. An infectious clone of Md5BAC was obtained following transfection into chicken embryo fibroblast (CEF) cells. Furthermore, a lorf10 deletion mutant was constructed by two step Red-mediated homologous recombination. To confirm the specific role of gene deletion, the lorf10 was reinserted into the original site of MDV genome to make a revertant strain. All the constructs were rescued by transfection into CEF cells, respectively. The successful packaging of recombinant viruses was confirmed by indirect immunofluorescence assay. The results of growth kinetics assay and plaques area measurement showed that the lorf10 is dispensable for MDV propagation in vitro. Overall, this study successfully constructed an infectious BAC clone of MDV and demonstrated its application in genome manipulation; the knowledge gained from our study could be further applied to other hepesviruses.
Animals ; Chick Embryo ; Chickens ; Chromosomes, Artificial, Bacterial ; DNA, Recombinant ; Herpesvirus 2, Gallid/genetics* ; Marek Disease

Amino Acid Sequence ; Animals ; Birds ; Cell Transformation, Viral ; Herpesvirus 2, Gallid ; genetics ; physiology ; Marek Disease ; virology ; Models, Biological ; Molecular Sequence Data ; Oncogene Proteins, Viral ; genetics ; physiology

Earlier studies have determined that the repeat regions of oncogenic serotype 1 MDV (Marek's disease virus) encode a basic leucine zipper protein, Meq, which structurally resembles the Jun/Fos family of transcriptional activators. Meq has been suggested as the MDV-associated oncogene. In this paper, based on the published sequence of Meq gene of GA strain of MDV, a pair of primers were designed and synthesized. Meq gene ORF (Open reading frame) of the four Chinese local MDV isolates, the reference strain J-1 and the vaccine strain 814 were amplified by using polymerase chain reaction(PCR). Then the PCR products were cloned and sequenced respectively. The results of sequence comparison indicated that the sequences of Meq gene in different strains are relatively conserved and homology of the amino acid sequences is 96.5%-99.7%. The proline-rich repeats of Meq gene of four MDV isolates have site mutations, and it is related to MDV's virulence. Two unique site mutations appear in Meq gene of Chinese local MDV isolates, but they aren't present in Meq gene of the published MDV strains from abroad and the early domestic strains. It seems that some regularities exist between such mutations in four Chinese local MDV isolates and the virulence of MDV, but the regularities need further research.
Amino Acid Sequence ; Animals ; Base Sequence ; Chickens ; Cloning, Molecular ; Herpesvirus 2, Gallid ; genetics ; Molecular Sequence Data ; Mutation ; Oncogene Proteins, Viral ; genetics

Microglial cells were purified from a mixed neuroglia culture prepared from the neonatal chicken brain in vitro, and were infected with the vvMDV YL040920 isolate and an attenuated MDV vaccine strain CVI988/Rispens, respectively. The presence of cytopathic effect (CPE) was examined daily, and the MEQ expression in MDV-infected microglia was detected by immunohistochemistry assay. DNA replication of the MDV meq gene and transcription of the gB gene were determined by real-time quantitative PCR (qPCR) and qRT-PCR, respectively. The transcripts of Toll-like receptor (TLR) mRNA in microglia post MDV infection were quantified by qRT-PCR. The results of this study showed that both vvMDV YL040920 and attenuated vaccine strain CVI988/Rispens could infect microglia and produce characteristic CPE with plaque formation. The plaques were formed due to cells shedding at multi-sites, then quickly expanded and integrated. Furthermore, the MEQ protein was detected in nuclei of YL040920 and CVI988/ Rispens-infected microglia, and MDV meq DNA replication and gB gene transcription in MDV-infected microglia were also confirmed. Although both MDV DNA copies and gB transcripts were increased in the virus-infected microglia, the higher viral DNA load and gB transcript were observed for CVI988/Rispens than for YL040920 in vitro (P < or = 0.05/0.001). The transcriptions of TLR15 and TLR1LB gene were found to be up-regulated in microglia following MDV infection in vitro. Purified microglia infected with YL040920 was observed increased TLR15 and TLR1LB transcripts as early as 1 day post infection (dpi), and reached its peak level at 3 dpi, then decreased mildly at 5 dpi. For CVI988/Rispens, it induced an increase of TLR15 transcript as early as 1 dpi, and rose rapidly at 3 dpi, and then decreased slightly at 5 dpi. At the same time, CVI988/Rispens induced the increase of chTLR1LB transcript at 3 dpi and decreased at 5 dpi. By comparing the TLRs transcription between YL040920 and CVI988/Rispens-infected microglia, it was suggested that vvMDV YL040920 might induce more TLR15 transcript than the attenuated vaccine strain CVI988/Rispens (P < or = 0.01/0.001), while CVI988/Rispens induced more TLR1LB transcript than YL040920 (P < or = 0.001).
Animals ; Brain ; metabolism ; virology ; Chickens ; Gene Expression ; Herpesvirus 2, Gallid ; genetics ; physiology ; Marek Disease ; genetics ; metabolism ; virology ; Microglia ; metabolism ; virology ; Poultry Diseases ; genetics ; metabolism ; virology ; Toll-Like Receptor 1 ; genetics ; metabolism ; Toll-Like Receptors ; genetics ; metabolism ; Transcription, Genetic