Fluorescent tagging of VP22 in N-terminus reveals that VP22 favors Marek’s disease virus (MDV) virulence in chickens and allows morphogenesis study in MD tumor cells

Marek’s disease virus (MDV) is an alpha-herpesvirus causing Marek’s disease in chickens, mostly associated with T-cell lymphoma. VP22 is a tegument protein abundantly expressed in cells during the lytic cycle, which is essential for MDV spread in culture. Our aim was to generate a pathogenic MDV expressing a green fluorescent protein (EGFP) fused to the N-terminus of VP22 to better decipher the role of VP22 in vivo and monitor MDV morphogenesis in tumors cells. In culture, rRB-1B EGFP22 led to 1.6-fold smaller plaques than the parental virus. In chickens, the rRB-1B EGFP22 virus was impaired in its ability to induce lymphoma and to spread in contact birds. The MDV genome copy number in blood and feathers during the time course of infection indicated that rRB-1B EGFP22 reached its two major target cells, but had a growth defect in these two tissues. Therefore, the integrity of VP22 is critical for an efficient replication in vivo, for tumor formation and horizontal transmission. An examination of EGFP fluorescence in rRB-1B EGFP22-induced tumors showed that about 0.1% of the cells were in lytic phase. EGFP-positive tumor cells were selected by cytometry and analyzed for MDV morphogenesis by transmission electron microscopy. Only few particles were present per cell, and all types of virions (except mature enveloped virions) were detected unequivocally inside tumor lymphoid cells. These results indicate that MDV morphogenesis in tumor cells is more similar to the morphorgenesis in fibroblastic cells in culture, albeit poorly efficient, than in feather follicle epithelial cells.     

Development of a nested polymerase chain reaction method to detect oncogenic Marek's disease virus from feather tips.

For the easy survey of Marek's disease virus (MDV), feather tip-derived DNA from MDV-infected chickens can be used because feather tips are easy to collect and feather follicle epithelium is known to be the only site of productive replication of cell-free MDV. To develop a diagnostic method to differentiate highly virulent strains of MDV from the attenuated MDV vaccine strain, CVI988, which is widely used, nested polymerase chain reaction (PCR) was performed to detect a segment of the meq gene in feather tip samples of chickens experimentally infected with MDV. In chickens infected with Md5, a strain of oncogenic MDV, the meq gene was consistently detected, whereas the L-meq gene, in which a 180-base pair (180-bp) sequence is inserted into the meq gene, was detected in CVI988-infected chickens. Moreover, the meq gene was mainly detected even in chickens co-infected with both Md5 and CVI988. These results suggest that this method is appropriate for the surveillance of the highly virulent MDV infection in the field.     

Selection of a recombinant Marek's disease virus in vivo through expression of the Marek's EcoRI-Q (Meq)-encoded oncoprotein: characterization of an rMd5-based mutant expressing the Meq of strain RB-1B

Marek's disease (MD) is a highly contagious viral disease of chickens (Gallus gallus domesticus) caused by MD virus (MDV), characterized by paralysis, neurologic signs, and the rapid onset of T-cell lymphomas. MDV-induced T-cell transformation requires a basic leucine zipper protein called Marek's EcoRI-Q-encoded protein (Meq). We have identified mutations in the coding sequence of Meq that correlated with virus pathotype (virulent, very virulent, and very virulent plus). The aim of this study was to determine whether recombinant viruses could be isolated based on Meq expression through in vivo selection. Chicken embryo fibroblasts (CEFs) were cotransfected with an rMd5 strain-based Meq deletion virus (rMd5deltaMeq) and meq loci from strains representing different pathotypes of MDV. Transfected CEFs were inoculated into chickens in two independent studies. We were able to isolate a single recombinant virus, rMDV-1137, in a contact-exposed chicken. rMDV-1137 had recombined two copies of the meq gene of RB-1B and was found to have pathogenicity similar to both RB-1B and rMd5 parental strains. We found the RB-1B- and rMd5-induced lymphomas showed differences in composition and that rMDV-1137-induced lymphomas were intermediate in their composition. We were able to establish cell lines from both RB-1B- (MDCC-UD35, -UD37) and rMDV-1137 (MDCC-UD36, -UD38)-induced, but not rMd5-induced, lymphomas. To date, no rMd5- or parent Md5-transformed T-cell lines have been reported. Our results suggest that 1) a recombinant MDV can be selected on the basis of oncogenicity; 2) changes in Meq sequence seem to affect tumor composition and the ability to establish cell lines; and 3) in addition to meq, other genomic loci affect MDV pathogenicity and oncogenicity.     

Similar pattern of iNOS expression, NO production and cytokine response in genetic and vaccination-acquired resistance to Marek's disease

NO is produced by macrophages through activation of the inducible enzyme NOS and its production is triggered as an antiviral and antitumoral immune mechanism. Replication of Marek's disease herpes virus (MDV) is inhibited by NO in vitro. MDV induces T-lymphomas in the chicken and a genetic resistance to tumor development has been linked to the B21 major histocompatibility complex. During the first initial week of viral replication after inoculation of the highly virulent RB-1B MDV strain, histocompatible B21/B21 chickens developed strong iNOS expression and NO production capacity in the spleen, in parallel with strong systemic NO production in the serum. Comparable NO response was not seen with the vaccinal strain HVT. In contrast, reduction in spleen macrophage number and delay in iNOS gene expression was observed in genetically susceptible B13/B13 chickens after MDV infection, in addition to suppression of IFN-gamma-inducible NO production. However, vaccination with HVT 3 days before RB-1B inoculation restored strong iNOS gene expression in the spleen 1 week later and inducible NO production 3 weeks later. Following the pattern of iNOS gene expression, early strong expression of cytokines with powerful iNOS-inducing activity such as IFN-gamma and CC chemokines from the MIP family (MIP-1beta, K203) was observed in genetic resistance and resistance acquired after vaccination with HVT. In conclusion, resistance to MDV appeared preferentially linked in both types of resistance to the early establishment of cytokine induction characteristic of a Th1 immune response, thus favoring the development of an early and strong NO response.     

The detection of the meq gene in chicken infected with Marek's disease virus serotype 1

In the genome of strains of very virulent Marek's disease virus serotype 1(vvMDV1), such as Md5 and RB1B, the meq open reading frame (ORF) encoding a 339-amino-acid bZIP protein, is present, while a slightly longer meq ORF, termed as L-meq, in which a 180-bp sequence is inserted into the meq ORF is found in other strains of MDV1, such as CV1988/R6 and attenuated JM. When chickens were infected with vvMDV1 strains and the meq gene was amplified by nested polymerase chain reaction (PCR), the meq gene was detected throughout the experimental period for 7 weeks post inoculation (pi). However, the L-meq gene was also detected at 3 to 5 weeks and 3 to 4 weeks pi. in Md5-infected and RB1B-infected chickens, respectively. In the case of chickens infected with an attenuated MDV1, the JM strain, the L-meq gene was detected at 2 to 7 weeks pi., and the meq gene was also detected at 2 to 6 weeks pi. Both L-meq and meq genes were detected in chickens infected with an attenuated nononcogenic vaccine strain of MDV1 (CVI988/R6), throughout the experimental period. Though quantitative PCR was not performed, a larger amount of the PCR products corresponding to the L-meq than the meq gene was amplified from chickens infected with JM or CVI988/R6. These results suggest that a dynamic population shift between the MDV subpopulations displaying meq and L-meq genes occurs in chickens during the course of MDV infection. Since the MDV subpopulation that displays the L-meq gene only displays it during the latent phase, the L-meq and its gene product, if any, might contribute to the maintenance of the MDV latency.     

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。     

Coinfection of specific-pathogen-free chickens with Marek's disease virus (MDV) and chicken infectious anemia virus: effect of MDV pathotype

Both Marek's disease virus (MDV) and chicken infectious anemia virus (CIAV) infections are prevalent in chickens throughout the world. In the past decade, MDV strains with increased virulence (very virulent plus MDV pathotype [vv+MDV]) have been isolated. The purpose of this experiment was to determine the effects of coinfection of chickens with CIAV and a vv+MDV isolate. Specific-pathogen-free chickens were inoculated at 1 day posthatch with RB1B (very virulent MDV pathotype [vvMDV]) only, 584A (vv+MDV) only, CIAV only, RB1B + CIAV, 584A + CIAV, or nothing. Samples of spleen, thymus, and bursa of Fabricius were collected at 4, 7, 10, and 13 days postinoculation (DPI). Thymic and bursal atrophy at 13 DPI and final mortality at 30 DPI were significantly greater in chickens inoculated with 584A with or without added CIAV, or with RB1B plus CIAV, compared with birds inoculated with RB1B alone. Both amounts of virus reisolated and levels of virus detected by quantitative-competitive polymerase chain reaction were greater at 4 DPI in 584A inoculates compared with RB1B inoculates. To monitor the early cytolytic infection, northern analysis was done with a probe for the MDV immediate early gene ICP4 (infected cell protein 4). In the absence of CIAV, ICP4 expression was more apparent in chickens inoculated with 584A than in those inoculated with RB1B. CIAV coinfection increased ICP4 expression in the spleens of chickens infected with RB1B. These results indicated that inoculation of chickens with the 584A isolate caused a more robust early cytolytic infection compared with inoculation with RB1B alone and support the classification of 584A as a vv+MDV strain. Coinfection with CIAV exacerbated vvMDV strain RB1B infection. The extent of this exacerbation was less evident when birds were coinfected with 584A and CIAV.     

The efficacy of recombinant fowlpox vaccine protection against Marek's disease: its dependence on chicken line and B haplotype

Earlier studies have shown that the B haplotype has a significant influence on the protective efficacy of vaccines against Marek's disease (MD) and that the level of protection varies dependent on the serotype of MD virus (MDV) used in the vaccine. To determine if the protective glycoprotein gene gB is a basis for this association, we compared recombinant fowlpox virus (rFPV) containing a single gB gene from three serotypes of MDV. The rFPV were used to vaccinate 15.B congenic lines. Nonvaccinated chickens from all three haplotypes had 84%-97% MD after challenge. The rFPV containing gB1 provides better protection than rFPV containing gB2 or gB3 in all three B genotypes. Moreover, the gB proteins were critical, since the B*21/*21 chickens had better protection than chickens with B*13/*13 or B*5/*5 using rFPV with gB1, gB2, or gB3. A newly described combined rFPV/gB1gEgIUL32 + HVT vaccine was analyzed in chickens of lines 15 x 7 (B*2/*15) and N (B*21/*21) challenged with two vv+ strains of MDV. There were line differences in protection by the vaccines and line N had better protection with the rFPV/gB1gEgIUL32 + HVT vaccines (92%-100%) following either MDV challenge, but protection was significantly lower in 15 X 7 chickens (35%) when compared with the vaccine CVI988/Rispens (94%) and 301B1 + HVT (65%). Another experiment used four lines of chickens receiving the new rFPV + HVT vaccine or CVI988/Rispens and challenge with 648A MDV. The CVI 988/Rispens generally provided better protection in lines P and 15 X 7 and in one replicate with line TK. The combined rFPV/gB1gEgIUL32 + HVT vaccines protected line N chickens (90%) better than did CVI988/Rispens (73%). These data indicate that rFPV + HVT vaccines may provide protection against MD that is equivalent to or superior to CVI988/ Rispens in some chicken strains. It is not clear whether the rFPV/gB1gEgIUL32 + HVT vaccine will offer high levels of protection to commercial strains, but this vaccine, when used in line N chickens, may be a useful model to study interactions between vaccines and chicken genotypes and may thereby improve future MD vaccines.     

马立克氏病病毒感染鸡羽髓上皮细胞差异蛋白质组学研究

为鉴定鸡羽髓上皮细胞感染马立克氏病病毒(MDV)前后差异表达的蛋白,本研究以MDV强毒GA株人工感染SPF鸡,并通过双向电泳技术进行分析.结果显示:在病毒感染后4 d、7 d、14 d和21 d显著差异表达的蛋白点分别有2个、8个、25个和9个;而通过质谱技术鉴定出29种蛋白质,其中包括能量代谢相关蛋白、增殖和凋亡相关蛋白、细胞骨架蛋白、信号传导蛋白、转录相关蛋白、免疫相关蛋白和其他功能蛋白质.本实验首次对鸡羽髓上皮细胞感染MDV后各时期蛋白表达水平的变化进行研究,鉴定了多种差异表达蛋白质,为进一步揭示MDV与宿主的相互关系、感染性病毒粒子的成熟和致病机制提供了依据.     

Resistance and susceptibility to Marek's disease: nitric oxide synthase/arginase activity balance

The metabolic NO pathway, catalyzed by the enzyme NO synthase in macrophages, is a key defense element against viruses and tumors. However, arginase is an other enzyme able to metabolize the substrate L-arginine, and the two enzymes are alternatively regulated by Th1 and Th2 cytokines in murine macrophages. Marek's disease is characterized by strong immunosuppression and development of T-cell lymphomas in chickens. Inoculation of the very virulent strain of MDV RB-1B induced strong and long-lasting arginase macrophage-dependent activity, which was inhibited by L-norvaline in vitro, but induced low NO production in monocytes and splenocytes from highly susceptible B(13)/B(13) chickens. By contrast, in B(21)/B(21) chickens genetically resistant to tumor development, RB-1B induced a weak and transient increase in arginase activity and strong NO production. The vaccinal HVT strain did not induce any arginase activity in monocytes or splenocytes. Moreover, vaccination with HVT prevented tumor appearance after RB-1B challenge and increase in arginase activity, but favored NO production in susceptible chickens. Differential expression of NO synthase and arginase was modulated in chicken macrophages, with IFN-gamma and LPS being strong inducers of both, depending on the type of macrophage, and TGF-beta 1 and PGE(2) stimulating only arginase activity. This increase in arginase activity in macrophages from chickens inoculated with Marek's disease virus might thus be due to a direct effect of the virus on macrophages, possibly through viral products, or to indirect effects on the cytokine balance.     

表达马立克氏病病毒CVI988／Rispens株糖蛋白B基因的重组鸡痘病毒疫苗的免疫保护研究

用鸡痘病毒载体表达马立克氏病病毒（MDV）糖蛋白B（gB）基因构建成重组鸡痘病毒（rFPV）。以MDV　GA或Md5和RBIB混合攻毒，在不同品种的鸡中评价rFPV－gB／R单价苗和与火鸡疱疹病毒（HVT）组成的二价苗的免疫保护效力。试验结果表明，MDV疫苗和FPV母源抗体阴性的SPF鸡和母源抗体阳性的商品鸡中，rFDV－gB／R均能提供免疫保护作用，且其中一种商品蛋鸡中rFPV－gB／R与HVT液氮苗或HVT冻干苗结合使用，均有显著的免疫协同保护作用。免疫学研究指出，rFPV－gB／R与常规疫苗一样，可显著地降低疫苗免疫攻毒鸡的病毒血症和羽囊排毒。     

Characterization of LORF11, a unique gene common to the three Marek's disease virus serotypes

The unique open reading frame 11 (LORF11) of Marek's disease virus (MDV) is present in all three serotypes of MDV and is located in the unique long region of the MDV genome. In the serotype 1 Md5 genome, LORF11 comprises 2711 nucleotides and encodes a predicted protein of 903 amino acids. In order to study the biological function of LORF11 we deleted it from the MDV cosmid A6 by using the RecA-assisted restriction endonuclease cleavage method. The recombinant cosmid, A6DeltaLORF11, was transfected into duck embryo fibroblasts (DEF) in conjunction with parental SN5, P89, SN16, and B40 cosmid clones. Recombinant rMd5DeltaLORF11 plaques were evident at 12-13 days after transfection. Polymerase chain reaction amplification of DEF cells infected with rMd5DeltaLORF11 viruses confirmed the deletion of a 2.57-kb fragment resulting in a 296-bp fragment. Three rMd5DeltaLORF11 mutants were generated and their biological functions were studied in vitro and in vivo. In vitro growth characteristics of rMd5DeltaLORF11 viruses were similar to those of parental rMd5, indicating that LORF11 is not essential for replication in vitro. In vivo studies of rMd5DeltaLORF11 mutants showed that they were impaired in viral replication in the lymphoid organs and had 100x lower viremia than chickens infected with the parental rMd5 virus. Furthermore, rMd5-infected chickens horizontally transmitted the virus to contact controls whereas no horizontal transmission occurred in rMd5DeltaLORF11-infected chickens. Three independent deletion mutants were tested and showed the same phenotypes, so it is unlikely that the observed phenotype is because of any random mutation in the genome. Therefore the LORF11 gene of MDV is essential for normal virus replication in chickens and deletion of LORF11 renders an attenuated virus.     

Replication of turkey herpesvirus and Marek's disease virus in chick embryo skin organ culture.

Turkey herpesvirus (HVT) and an attenuated Marek's disease virus (MDV) replicated in organ cultures of chick embryo skin as assessed by immunofluorescence and/or electron microscopy. HVT-specific immunofluorescent antigen was detected in the feather follicle epithelium (FFE) and in the surface layer of the skin epidermis. Electron microscopy of infected explants revealed herpes-type cytopathology. Immature particles of both viruses appeared first in the nucleus. Oval or horseshoe-shaped non-enveloped particles of HVT and enveloped virions of MDV were seen in the cytoplasm of some transitional cells. The difference in the ability of HVT and MDV to form an envelope was believed to account for the difference in their transmissibility in chickens. The results indicated that HVT replicated in the FFE and in the epidermis of the skin. However, attempts to localise the site(s) of MDV replication by electron microscopy were unsuccessful.     

Protection and synergism by recombinant fowl pox vaccines expressing multiple genes from Marek's disease virus

Recombinant fowl poxviruses (rFPVs) were constructed to express genes from serotype 1 Marek's disease virus (MDV) coding for glycoproteins B, E, I, H, and UL32 (gB1, gE, gI, gH, and UL32). An additional rFPV was constructed to contain four MDV genes (gB1, gE, gI, and UL32). These rFPVs were evaluated for their ability to protect maternal antibody-positive chickens against challenge with highly virulent MDV isolates. The protection induced by a single rFPV/gB1 (42%) confirmed our previous finding. The protection induced by rFPV/gI (43%), rFPV/gB1UL32 (46%), rFPV/gB1gEgI (72%), and rFPV/gB1gEgIUL32 (70%) contributed to additional knowledge on MDV genes involved in protective immunity. In contrast, the rFPV containing gE, gH, or UL32 did not induce significant protection compared with turkey herpesvirus (HVT). Levels of protection by rFPV/gB1 and rFPV/gl were comparable with that of HVT. Only gB1 and gI conferred synergism in rFPV containing these two genes. Protection by both rFPV/gB1gEgI (72%) and rFPV/gB1gEgIUL32(70%) against Marek's disease was significantly enhanced compared with a single gB1 or gI gene (40%). This protective synergism between gB1 and gI in rFPVs may be the basis for better protection when bivalent vaccines between serotypes 2 and 3 were used. When rFPV/gB1gIgEUL32 + HVT were used as vaccine against Md5 challenge, the protection was significantly enhanced (94%). This synergism between rFPV/gB1gIgEUL32 and HVT indicates additional genes yet to be discovered in HVT may be responsible for the enhancement.     

Indications of immunodepression in chickens infected with various strains of Marek's disease virus

The effect of infection by various strains of Marek's disease virus (MDV) on the immune function of 3-week-old chickens was examined. MDV strains of low (CU-2, RB-7) and high (RB-3, MD-5, and MD-11) pathogenicity were compared with prototype JM-10 strain of moderate pathogenicity. Mortality, whole body weight, relative weights of lymphoid organs, histopathology, humoral antibody responses to thymus-dependent and -independent antigens, and in vitro lymphocyte responses to mitogen stimulation were investigated at 1, 2, and 3 weeks postinfection. MDV strains of high pathogenicity significantly depressed responses at 3 weeks postinfection, seeming to indicate the ability of these viruses to induce severe immunodepression. However, the fact that the moderately pathogenic and even some of the low-pathogenicity strains induced immunodepression suggests that other viral mechanisms are also important in its determination.     

Marek's disease virus-induced skin leukosis in scaleless chickens: tumor development in the absence of feather follicles

Marek's disease virus (MDV) is an oncogenic cell-associated herpesvirus that causes T-cell lymphoma in chickens. Lymphoproliferative neoplasms in Marek's disease (MD) occur in various organs and tissues, including the viscera, peripheral nerves, skin, gonads, and musculatures. MDV is restrictively produced in the feather follicle epithelial (FFE) cells, and it gains access to the external environment via infected cells or as infectious enveloped cell-free virus particles. The goals of the present study were to 1) determine whether the MDV-induced skin lesions are neoplastic in nature or inflammatory reactions to viral infection, 2) determine whether physical presence of feather follicles (FF) is necessary for skin tumor development, and 3) study the role of skin epithelial cells not associated with feathers or FF in the replication and dissemination of infectious virus particles. Scaleless chickens that produce only a few scattered feathers and no sculate scales along the anterior metatarsi were used as a unique model to study the pathogenesis of dermal lesions. Histologic and immunohistochemical analysis revealed that the cutaneous lesions were tumorous as was manifested by massive accumulation of lymphoblasts and extensive activation of meq oncoprotein, the hallmark of MDV oncogenesis, within the skin lesions. Neoplastic cutaneous lesions in the scaleless chickens indicate that feather follicles are not necessary for skin tumor development. Finally, our preliminary data indicate that inoculation with supernatant fluid from homogenized and sonicated skin samples of MDV-infected scaleless chickens induces MD in susceptible birds, suggesting that skin epithelial cells not associated with FF also harbor infectious viral particles.