Marek's disease in turkeys. I. A seven-year survey of commercial flocks and experimental infection using two field isolates

Marek's disease virus (MDV) causes immunosuppression and tumors in chickens, but the turkey is an unusual host for the virus, and tumors caused by MDV in turkeys are unique. We describe the prevalence of turkey tumors in Israel between 1993 and 2000, their molecular diagnosis by polymerase chain reaction (PCR), and the natural distribution of herpesvirus of turkeys (HVT). Most clinical cases with tumors in commercial turkeys were diagnosed as MDV. The reproduction of Marek's disease (MD) in turkeys by two turkey MDV strains, Ar and La, was analyzed, and it was shown that these strains can induce tumors in experimental trials. The severity of experimental disease differed from those features of the original outbreak, since a less severe disease was recorded.     

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).     

一株鸡马立克氏病病毒的分离鉴定及主要致病基因分析

山东省某地区鸡马立克氏病疫苗免疫鸡群暴发马立克氏病(MD),为分离得到致病毒株,检测其致病性,采用琼脂扩散试验、细胞培养和间接免疫荧光试验(IFA)等方法从发病鸡的血液及羽髓中分离到一株适应鸡胚成纤维细胞(CEF)生长的马立克氏病病毒。采用PCR方法扩增分离毒株的meq、pp38、132bp重复序列等病毒致病相关基因,所得序列用DNAStar软件与GenBank上登录的参考毒株进行比对分析。结果显示,该分离株SDAU-1的pp38基因与标准强毒序列同源性为100%,132bp重复序列的拷贝数及meq基因的变异均符合MDV强毒株的序列特征。     

Isolation and Identification of a Field Strain of Marek's Disease Virus and Analysis of Major Pathogenic Genes

In a certain area of Shandong province, Marek's disease (MD) occurred in diseased chickens that had been vaccinated by turkey herpesvirus.In order to isolate the virus strain and detect the virus pathogenicity, agar diffusion test, cell culture and indirect immunofluorescence assay (IFA) were used to isolate the Marek's virus from chicken's blood and feather marrow.The isolated strain was adapted to grow in chick embryo fibroblasts (CEF).Genes involved in pathogenesis of MDV, such as meq, pp38 and 132 bp repeat sequence were amplified by PCR.The obtained sequences were compared with that of standard strains published in GenBank by DNAStar software.The results showed that pp38 gene of the SDAU-1 shared homology from 100% with standard virulent sequence.Analysis of 132 bp repeat sequence and meq gene sequences of the viral genome showed that the isolated virus belongs to the highly virulent MDV strains.     

Partial protection against Marek's disease in chickens immunized with glycoproteins gB purified from turkey-herpesvirus-infected cells by affinity chromatography coupled with monoclonal antibodies

Glycoproteins gB of Marek's disease virus (MDV) and herpesvirus of turkeys (HVT) related to virus neutralization were purified from HVT-infected cells by affinity chromatography. Immunization of chickens with purified glycoproteins gB resulted in partial protection against MD. Neutralizing antibodies were detected in chickens immunized with HVT-gB.     

Adaptation of Marek's disease virus to the Vero continuous cell line

Marek's disease virus (MDV) is a highly infectious, cell-associated oncogenic herpesvirus. Production of MD vaccines has been limited to primary chicken and duck embryo fibroblast (CEF and DEF) cultures. These have a limited life span and cannot be readily stored in liquid nitrogen. Moreover, the need to prepare CEF and DEF cells on a regular basis from 10 to 11 day-old embryos derived from a flock that must be tested continuously for the presence of avian pathogens adds to the cost of vaccine production. A continuous cell line that would support MDV replication could have significant advantages for the rapid large-scale preparation of MD vaccines. In this report, we describe the adaptation to growth of CEF-grown preparations of serotype 1 and serotype 3 (herpesvirus of turkeys; HVT) strains of MDV in cells of the Vero continuous cell line. Although both viruses produced typical CPE, higher levels of infectious progeny and more extensive virus-specific immunofluorescence were obtained for HVT than for the serotype 1 virus. PCR and pulsed field electrophoresis (PFE) analysis of the DNA from Vero cells infected with either virus confirmed the presence of virus-specific DNA.     

鸡马立克病病毒强毒与疫苗毒PCR鉴别检测方法的建立

在Ⅰ型马立克病病毒(MDV)基因组中针对132 bp串联重复序列的两侧合成一对引物,应用PCR技术对临床病例采集的疑似马立克病肿瘤病变鸡肝组织和1日龄接种CVI988弱毒疫苗的健康雏鸡羽髓样本进行检测。结果表明,从临床病例采集的10份肝脏组织,7份扩增出一条314 bp的条带,相当于2个拷贝数的132 bp串联重复序列;在接种疫苗健康雏鸡的羽髓样本中,扩增出与CVI988弱毒一致的PCR图谱,相当于6个~8个或更多拷贝数的132 bp串联重复序列。根据PCR图谱的差异即可鉴别MDV强毒株与CVI988疫苗弱毒株。     

Identification of the cross-reactive antigens between Marek's disease virus and pseudorabies virus by monoclonal antibodies

Among the 33 monoclonal antibodies (MAbs) against pseudorabies virus (PRV) examined, three MAbs (24-17, 74-26, and 8) were found to react with cells infected with Marek's disease virus (MDV)-related viruses by immunofluorescence test. Two of the MAbs (24-17 and 74-26) reacted with the nuclei of cells infected with MDV serotype 1 (MDV1), MDV serotype 2 (MDV2), and herpesvirus of turkeys (HVT), whereas MAb 8 reacted with the cytoplasm of MDV2- and HVT-infected cells. However, none of the MAbs against MDV1, MDV2, and HVT that were examined reacted with PRV-infected cells. None of these three MAbs against PRV reactive with MDV-related viruses cross-reacted with the cells infected with other herpesviruses, such as herpes simplex virus type 1, herpes simplex virus type 2, varicella zoster virus, Epstein-Barr virus, or human herpesvirus 6. Southern-blot hybridization under stringent or less-stringent conditions showed that no significant DNA homology was detected between PRV DNA and MDV DNA.     

Response of embryonic chicken lymphocytes to in ovo exposure to lymphotropic viruses.

OBJECTIVE: To examine effects of virus exposure on embryonic lymphoid organ structure, apoptosis, and lymphoid cell subpopulations. ANIMALS: Eggs of specific pathogen free (SPF) White Leghorn chickens at embryonation day (ED) 17. PROCEDURES: Eggs were inoculated with 2,000 plaque-forming units (PFU) of serotype 1 herpesvirus (Marek's disease virus [MDV 1]), 2,000 PFU of herpesvirus of turkeys (MDV 3), or 1,000 embryo infectious doses (EID50) of infectious bursal disease virus (IBDV). On post-inoculation days (PID) 3 and 5, lymphoid organ to body weight ratios were determined, and bursa of Fabricius, thymus, and spleen were evaluated for lesions and apoptosis. Proportions of lymphoid cell subpopulations of PID-3 chicken embryos and 7- to 10-day-old chicks were quantitated by flow cytometry. RESULTS: Lymphoid organ weights were similar in virus-free, MDV1, and IBDV groups. Embryos inoculated with 2,000 PFU MDV 3/egg had lower bursal weights than virus-free controls. In a repeated trial, MDV 3 (1,000 PFU to 4,000 PFU) did not reduce bursal weights among groups. Histologic changes were seen in bursae after MDV 1 and IBDV inoculation. Apoptosis was greater in bursae of MDV 1-infected embryos than controls. Lymphoid cell subpopulations were similar among all groups with the exception of CD8+ and IgM+ cells in spleens of IBDV-infected 10-day-old chicks. CONCLUSIONS AND CLINICAL RELEVANCE: Infection with pathogenic strains of MDV 1 and IBDV did not alter lymphocyte subpopulations in embryos or cause complete destruction of lymphoid organs. Changes in lymphoid cell subpopulations exposed as embryos to IBDV were seen only after hatching.     

马立克氏病病毒“814”疫苗株基因组重复区序列测定及分析

为了解马立克氏病病毒(MDV)强、弱毒株主要致肿瘤相关基因变异情况,本研究根据MDV GA株基因组序列,设计合成扩增基因组重复区的引物,得到MDV814疫苗株病毒基因组中约26kb的序列片段。与GenBank登录的强、弱毒株进行比较分析表明,扩增的MDV1型814疫苗株的长重复区为12774bp,预测的开放阅读框(ORF)有48个;短重复区为11426bp,预测的ORF有38个。发现了4个MDV814株特有的ORF。814株在编码Meq、RLORF6和23ku的重叠基因内具有类似于疫苗株CVI988的177bp的插入;在RLORF12基因编码区内存在69bp的缺失,该缺失位于病毒复制起始位点内。同时,发现7个814疫苗株特有的氨基酸突变,分布在6个ORF内。单核苷酸多态性(SNP)的鉴定发现,多个基因具有单核苷酸的突变,主要分布于Meq基因,其中氨基酸A115V(丙氨酸-缬氨酸),N142D(天冬酰胺-天门冬氨酸)的变异是814疫苗株所特有的。MDV814疫苗株重复区的基因序列的比较分析将有助于MDV致肿瘤机制的研究。     

Isolation of serotype 2 Marek's disease virus from birds belonging to genus Gallus in Japan

Serotype 2 of Marek's disease virus (MDV) was isolated from apparently healthy birds belonging to genus Gallus that had no history of vaccination with MDV or herpesvirus of turkeys (HVT). Buffy-coat cells from these birds were inoculated onto chicken embryo fibroblast (CEF) cultures for primary isolation. Thirteen isolates from one golden pheasant and three white silky fowls, three black silky fowls, three Japanese long crowers, and three Japanese bantams produced herpes-like cytopathic effects (CPE) in the CEF cultures. Using serotype-specific monoclonal antibodies to MDV and HVT, 11 isolates were identified as serotype 2 MDV by indirect fluorescent antibody tests. The other two isolates were complicated with serotypes 1 and 3 of MDV-related viruses. Of 13 isolates, three cloned by the limiting-dilution method were further characterized as serotype 2 MDV biologically, genetically, and serologically. The results showed that the birds of the genus Gallus were naturally infected with serotype 2 MDV. This is the first report ever published about the distribution of serotype 2 MDV among healthy birds of the genus Gallus.     

Genome analysis of Marek's disease virus strain CVI-988: effect of cell culture passage on the inverted repeat regions.

The genomes of different derivatives of Marek's disease virus (MDV) strain CVI-988, a low oncogenic isolate of a serotype 1 MDV, were analyzed by restriction enzyme analyses to detect whether alterations occurred after passages in cell culture. DNA molecules of strain 988 isolated directly from blood cells contained mainly two copies of the 132-bp repeat sequence previously reported within BamH1-H and -D fragment as previously reported for more virulent MDV strains. Although a minority of virus particles showed repeat amplification was already at the fifth passage level, amplification mainly occurred between passages 17 and 34 in cell culture. In addition, a 400-bp deletion was detected within the BamH1-A fragment of two derivatives of CVI-988, 988C and 988C/R6.     

应用双重实时荧光定量PCR方法检测鸡马立克氏病血清1型病毒

本研究建立了鸡马立克氏病血清1型病毒（MDV1）绝对定量检测方法。研究中选择MDV1特有的Meq基因的一段保守序列作为检测对象，将其克隆到质粒载体中，作为阳性标准品；同时将管家基因．鸡卵铁转蛋白（Ovo）特异性基因片段克隆到质粒载体上作为内参照的标准品。经荧光定量PCR（FQ-PCR）法扩增获得MDV1的FQ-PCR两条标准曲线，建立了MDV1双重FQ-PCR检测方法。应用该方法绝对定量检测了实验攻毒鸡及吉林省某地发病鸡只的羽髓、淋巴细胞等组织样本中单位细胞病毒拷贝数，并与琼脂扩散（AGP）、常规PCR等检测方法进行比较。结果表明，不论实验攻毒鸡还是自然发病鸡，羽髓中病毒富含量均高于其它组织，每百万宿主细胞内病毒含量为10^7～10^8拷贝；FQ-PCR检测MD发病鸡只的阳性率高于AGP，达100％；该方法的灵敏度比常规PCR检测高10～100倍，在单位细胞内可灵敏地检测到2．78个拷贝的病毒。该方法可以在不同的样品中有效的绝对定量检测MDVl。     

Cell-mediated immunity in Marek's disease: cytotoxic responses in resistant and susceptible chickens and relation to disease

Two experiments were conducted to study the cell-mediated cytotoxicity of peripheral blood leukocytes (PBL) from chickens inoculated with Marek's disease virus (MDV) against a Marek's disease-derived lymphoblastoid cell line (MSB-1) and to associate the cytotoxicity with incidence of disease. In experiment I, moderately susceptible random-bred, specific-pathogen-free chickens were inoculated with MDV (group 1), vaccinated with a herpesvirus of turkeys (HVT) and inoculated with MDV (group 2), vaccinated with HVT and inoculated with chicken kidney cells (CKC; group 3), and inoculated with CKC only (group 4). Cytotoxic activity in the PBL was detected initially during the first week after MDV inoculation and periodically throughout the observation period (groups 1, 2, and 3). Throughout the observation period, the magnitude of cytotoxic activity was similar in PBL from groups 1 and 2 chickens. The PBL from both surviving and fatally infected chickens (groups 1 and 2) were similarly cytotoxic when sampled during the first 16 days after MDV inoculation. In experiment II, inbred genetically susceptible (line 7) and resistant (line 6) chickens were used. Cytotoxic activity of PBL of significantly greater magnitude was associated with a lower mortality or incidence of gross lesions (or both) in MDV-inoculated line 6 (group B) and HVT-vaccinated and MDV-inoculated line 7 (group C) chickens compared with activity of PBL from MDV-inoculated line 7 (group A) chickens. The cytotoxic activity of PBL from individual inbred chickens did not correlate with the outcome of the infection.     

Natural killer cell activity in chickens exposed to Marek's disease virus: inhibition of activity in susceptible chickens and enhancement of activity in resistant and vaccinated chickens

Chickens of 2 genetic lines (lines P and N) were inoculated with a pathogenic strain of Marek's disease (MD) virus (MDV) and chronologically examined for disease response and natural killer (NK) cell expression. The NK cell reactivity was assayed in an in vitro cytotoxicity assay in which effector cells from the spleen of test chickens were reacted with 51Cr-labeled LSCC-RP9 target cells. Chickens of line P developed progressive debilitating disease and a high incidence of gross tumors and death. The NK cell reactivity of line-P chickens infected with MDV was significantly lower than that of uninfected control hatchmates. In contrast, NK cell levels were significantly elevated in MDV-inoculated line-N chickens that were resistant to MD and in chickens of lines P or N that had been inoculated with herpesvirus of turkeys (HVT). NK cell levels were also elevated in line P if chickens were vaccinated with HVT before infection with MDV. Inhibition of NK reactivity in susceptible chickens and elevation of reactivity in naturally resistant or vaccinated chickens may indicate a role for the NK cell system in regulating resistance to MD.     

Rapid detection of Marek's disease virus in feather follicles by loop-mediated amplification

Marek's disease (MD) remains a serious problem in the production of poultry. The disease is caused by Marek's disease virus (MDV), and despite the ubiquitous use of vaccination to control losses, MD still affects poultry farming worldwide. The aim of this study was to develop a loop-mediated isothermal amplification (LAMP) method for the simple and inexpensive detection of MDV in feather tips of chickens. Two pairs of specific primers complementary to the meq oncogene of MDV were designed, targeting the sequence of the very virulent MDV strain, RB1B. Bst polymerase was used for the isothermal amplification of viral DNA at 65 C for 90 min in a water bath. The fluorescence signal was identified in MDV-positive samples after the addition of SYBR Green and ultraviolet (UV) illumination. The sensitivity of LAMP was 2 log 10 plaque-forming units (PFU)/ml of HPRS16 and 10(3) copies/il of plasmid containing the target gene (meq) and was equal in sensitivity to PCR amplification. Due to the use of three sets of primers, LAMP was highly specific for MDV-1 DNA. The developed LAMP technique is a rapid and simple tool for the specific detection of MDV in samples of feathers taken from live chickens. Since the use of thermocyclers is not necessary for LAMP assay, it can be conducted by small laboratories and even field veterinarians.     

Marek's disease in turkeys. II. Characterization of the viral glycoprotein B gene and antigen of a turkey strain of Marek's disease virus

Marek's disease virus (MDV) causes immunosuppression and tumors in chickens. As sporadic cases of Marek's disease (MD) were recorded in turkeys, the antigenic and genomic characteristics of the MDV glycoprotein B (gB) gene and antigen of turkeys were compared to the chicken MDV gB. The whole chicken and turkey gB genes were sequenced and found identical. By immunoblotting of infected-cell culture lysates using chicken convalescent and gB monoclonal antibodies, the antigenic epitopes of the chicken and turkey viruses were found to differ. The turkey MDV had a unique epitope, compared to the chicken MDV and compared with our previous findings. While the chicken MDV had two epitope types, heat-labile but dithiothreitol (DTT)-stable and heat-stable but DTT-labile, the turkey MDV gB epitope is both heat and DTT-labile.     

Comparative analysis of Marek's disease virus (MDV) glycoprotein-, lytic antigen pp38- and transformation antigen Meq-encoding genes: association of meq mutations with MDVs of high virulence

Marek's disease (MD) is a highly contagious lymphoproliferative and demyelinating disorder of chickens. MD is caused by Marek's disease virus (MDV), a cell-associated, acute-transforming alphaherpesvirus. For three decades, losses to the poultry industry due to MD have been greatly limited through the use of live vaccines. MDV vaccine strains are comprised of antigenically related, apathogenic MDVs originally isolated from chickens (MDV-2), turkeys (herpesvirus of turkeys, HVT) or attenuated-oncogenic strains of MDV-1 (CVI-988). Since the inception of high-density poultry production and MD vaccination, there have been two discernible increases in the virulence of MDV field strains. Our objectives were to determine if common mutations in the major glycoprotein genes, a major lytic antigen phosphoprotein 38 (pp38) or a major latency/transformation antigen Meq (Marek's EcoRI-Q-encoded protein) were associated with enhanced MDV virulence. To address this, we cloned and sequenced the major surface glycoprotein genes (gB, gC, gD, gE, gH, gI, and gL) of five MDV strains that were representative of the virulent (v), very virulent (vv) and very virulent plus (vv+) pathotypes of MDV. We found no consistent mutations in these genes that correlated strictly with virulence level. The glycoprotein genes most similar among MDV-1, MDV-2 and HVT (gB and gC, approximately 81 and 75%, respectively) were among the most conserved across pathotype. We found mutations mapping to the putative signal cleavage site in the gL genes in four out of eleven vv+MDVs, but this mutation was also identified in one vvMDV (643P) indicating that it did not correlate with enhanced virulence. In further analysis of an additional 12 MDV strains, we found no gross polymorphism in any of the glycoprotein genes. Likewise, by PCR and RFLP analysis, we found no polymorphism at the locus encoding the pp38 gene, an early lytic-phase gene associated with MDV replication. In contrast, we found distinct mutations in the latency and transformation-associated Marek's EcoRI-Q-encoded protein, Meq. In examination of the DNA and deduced amino acid sequence of meq genes from 26 MDV strains (9 m/vMDV, 5 vvMDV and 12 vv+MDVs), we found distinct polymorphism and point mutations that appeared to correlate with virulence. Although a complex trait like MDV virulence is likely to be multigenic, these data describe the first sets of mutations that appear to correlate with MDV virulence. Our conclusion is that since Meq is expressed primarily in the latent/transforming phase of MDV infection, and is not encoded by MDV-2 or HVT vaccine viruses, the evolution of MDV virulence may be due to selection on MDV-host cell interactions during latency and may not be mediated by the immune selection against virus lytic antigens such as the surface glycoproteins.     

Pathogenicity studies with plaque-purified preparations of Marek's disease virus strain CVI-988

The pathogenicity of Marek's disease (MD) strain CVI-988 vaccine, eight plaque-purified preparations originating from this strain, and the vaccine HVT FC126 (based on herpesvirus of turkeys) was determined by intramuscular administration of high virus doses to day-old specific-pathogen-free Rhode Island Red (RIR) chickens, which are extremely MD-susceptible. Paralysis and neuritis were observed in 88% of RIR chickens inoculated with MDV CVI-988 at the cell-passage level of the commercial vaccine. HVT FC126 caused paralysis in two of 39 RIR chickens tested, of which one had an endoneural lymphoma, and another three had endoneural inflammation. Five plaque-purified MDV CVI-988 virus preparations at various cell-culture-passage levels caused no lesions. Of another three clones, two caused inflammatory B-type lesions in the nerves of 1/10 chickens, and the third clone caused inflammatory nonneoplastic MD lesions in the liver of 1/11 chickens.