A Systematic Analysis of miRNA Transcriptome in Marek’s Disease Virus-Induced Lymphoma Reveals Novel and Differentially Expressed miRNAs

Marek’s disease is a lymphoproliferative neoplastic disease of the chicken, which poses a serious threat to poultry health. Marek’s disease virus (MDV)-induced T-cell lymphoma is also an excellent biomedical model for neoplasia research. Recently, miRNAs have been demonstrated to play crucial roles in mediating neoplastic transformation. To investigate host miRNA expression profiles in the tumor transformation phase of MDV infection, we performed deep sequencing in two MDV-infected samples (tumorous spleen and MD lymphoma from liver), and two non-infected controls (non-infected spleen and lymphocytes). In total, 187 and 16 known miRNAs were identified in chicken and MDV, respectively, and 17 novel chicken miRNAs were further confirmed by qPCR. We identified 28 down-regulated miRNAs and 11 up-regulated miRNAs in MDV-infected samples by bioinformatic analysis. Of nine further tested by qPCR, seven were verified. The gga-miR-181a, gga-miR-26a, gga-miR-221, gga-miR-222, gga-miR-199*, and gga-miR-140* were down-regulated, and gga-miR-146c was up-regulated in MDV-infected tumorous spleens and MD lymphomas. In addition, 189 putative target genes for seven differentially expressed miRNAs were predicted. The luciferase reporter gene assay showed interactions of gga-miR-181a with MYBL1, gga-miR-181a with IGF2BP3, and gga-miR-26a with EIF3A. Differential expression of miRNAs and the predicted targets strongly suggest that they contribute to MDV-induced lymphomagenesis.     

Isolation of recombinant field strains of Marek's disease virus integrated with reticuloendotheliosis virus genome fragments

Two Marek's disease virus (MDV) field strains were isolated from chickens with tumors independently from Guangdong and Guangxi provinces, and it was confirmed that there were no co-infections with reticuloendotheliosis viruses (REV) in chicken embryo fibroblast cells (CEF) in indirect fluorescence antibody test (IFA) with REV-specific monoclonal antibodies. By dot blot hybridization and PCR of genomic DNA of MDV-infected CEF, it was indicated that LTR fragments of REV genome were integrated into genome of these two MDV field strains. To amplify and clone the integrated REV LTR with MDV sequence at the junction, 4 primers from REV LTR and 7 primers from MDV genome fragment with REV LTR insertion hot points were synthesized and 28 (4x7) pairs of primers (one from REV and another from MDV for each pair) were used in PCR while using the genomic DNA of both strains as the templates. The sequence data demonstrated that both recombinant field strains contained the same REV LTR inserted into MDV at the identical sites in US fragment of the genomes. From the above, it was speculated that both recombinant field MDVs were originated from a same recombinant virus and spread among chicken flocks in two provinces.     

Isolation of recombinant field strains of Marek’s disease virus integrated with reticuloendotheliosis virus genome fragments

Two Marek's disease virus (MDV) field strains were isolated from chickens with tumors independently from Guangdong and Guangxi provinces, and it was confirmed that there were no co-infections with reticuloendotheliosis viruses (REV) in chicken embryo fibroblast cells (CEF) in indirect fluorescence antibody test (IFA) with REV-specific monoclonal antibodies. By dot blot hybridization and PCR of genomic DNA of MDV-infected CEF, it was indicated that LTR fragments of REV genome were integrated into genome of these two MDV field strains. To amplify and clone the integrated REV LTR with MDV sequence at the junction, 4 primers from REV LTR and 7 primers from MDV genome fragment with REV LTR insertion hot points were synthesized and 28 (4x7) pairs of primers (one from REV and another from MDV for each pair) were used in PCR while using the genomic DNA of both strains as the templates. The sequence data demonstrated that both recombinant field strains contained the same REV LTR inserted into MDV at the identical sites in US fragment of the genomes. From the above, it was speculated that both recombinant field MDVs were originated from a same recombinant virus and spread among chicken flocks in two provinces.     

Changes in the Gallus gallus proteome induced by Marek's disease virus

Marek's disease virus (MDV) is a highly oncogenic avian herpesvirus. We have used a modified MudPIT analysis to examine the effect of MDV infection on the chicken proteome. We identified 3561 unique nonphosphorylated peptides, representing 1460 chicken proteins, in a mock-infected sample versus 4240 unique nonphosphorylated peptides, representing 1676 proteins, in an MDV-infected sample. Of these unique peptides, 59.1% from the mock- and 49.6% from the MDV-infected samples were detected in both samples, and for the represented proteins, 69.1% from the mock- and 60.2% from the MDV-infected samples were common to both samples. In terms of phosphorylation, 357 and 506 phosphopeptides, representing 342 and 483 proteins, were detected in the mock- and MDV-infected samples, respectively. At the phosphopeptide level, 10.1% from the mock- and 7.1% from the MDV-infected samples overlapped, and for the represented phosphoproteins, 12.0% from the mock- and 8.5% from the MDV-infected samples were common to both samples. There were no significant differences in the hydropathicity values and number of transmembrane domains of the identified protein sets. Subtle differences were observed for subcellular localizations of the identified proteins. These results suggest that MDV infection may alter host cell biochemistry by perturbing the host's proteomic composition.     

MicroRNA profiling in the bursae of Marek's disease virus-infected resistant and susceptible chicken lines

Marek's disease (MD) is a lymphoproliferative disease of domestic chickens caused by a cell-associated oncogenic alpha-herpesvirus, Marek's disease virus (MDV). Clinical signs of MD include bursal/thymic atrophy, neurologic disorders, and T cell lymphomas. MiRNAs play key roles in regulation of gene expression by targeting translational suppression or mRNA degradation. MDV encodes miRNAs that are associated with viral pathogenicity and oncogenesis. In this study, we performed miRNA sequencing in the bursal tissues, non-tumorous but viral-induced atrophied lymphoid organ, from control and infected MD-resistant and susceptible chickens at 21 days post infection. In addition to some known miRNAs, a minimum of 300 novel miRNAs were identified in each group that mapped to the chicken genome with no sequence homology to existing miRNAs in chicken miRbase. Comparative analysis identified 54 deferentially expressed miRNAs between the chicken lines that might shed light on underlying mechanism of bursal atrophy and resistance or susceptibility to MD.     

Induction of host gene expression following infection of chicken embryo fibroblasts with oncogenic Marek's disease virus

Microarrays containing 1,126 nonredundant cDNAs selected from a chicken activated T-cell expressed sequence tag database (http://chickest.udel.edu) were used to examine changes in host cell gene expression that accompany infection of chicken embryo fibroblasts (CEF) with Marek's disease virus (MDV). Host genes that were reproducibly induced by infection of CEF with the oncogenic RB1B strain of MDV included macrophage inflammatory protein, interferon response factor 1, interferon-inducible protein, quiescence-specific protein, thymic shared antigen 1, major histocompatibility complex (MHC) class I, MHC class II, beta(2)-microglobulin, clusterin, interleukin-13 receptor alpha chain, ovotransferrin, a serine/threonine kinase, and avian leukosis virus subgroup J glycoprotein.     

Microsatellite Instability in Marek's Disease Virus Infected Primary Chicken Embryo Fibroblasts

ABSTRACT: BACKGROUND: Marek's disease virus (MDV), an oncogenic alpha-herpesvirus, causes a devastating disease in chickens characterized by development of lymphoblastoid tumors in multiple organs. Microsatellite instability (MSI), a symptom of defect in DNA mismatch repair function, is a form of genomic instability frequently detected in many types of tumors. However, the involvement of MSI in MDV-infected cells has not been investigated. In this study, we determined the presence and frequency of MSI in primary chicken embryo fibroblasts infected with or without virulent RB-1B strain of MDV in vitro. RESULTS: 118 distinct microsatellite markers were analyzed by polymerase chain reaction (PCR) in 21 samples. MSI was found in 91 of 118 markers, and 12 out of 118 demonstrated frequency of MSI at [greater than or equal to] 40%. 27 of 118 microsatellite loci did not show microsatellite instability. CONCLUSIONS: These findings showed that MSI was a real event occurring in primary chicken embryo fibroblasts infected with MDV in vitro as evidenced by the high frequency of MSI, and may be specifically associated with genome alteration of host cells during MDV infected.     

Deoxyribonucleic Acid of Marek''s Disease Virus in Virus-Induced Tumors

DNA was extracted from [(3)H]thymidine-labeled Marek's disease virus (MDV) and purified by two cycles of CsCl gradient centrifugation in a fixed-angle rotor. The DNA was transcribed in vitro into (32)P-labeled complementary RNA (cRNA). MDV cRNA did not hybridize with DNA from chicken embryo fibroblast cultures or from chicken spleen, but hybridized efficiently with DNA from MDV particles or MDV-infected cell cultures. Five Marek's disease tumors from different chickens and different organs (ovary, liver, testis) were all found to contain MDV DNA sequences. The relative amount of MDV DNA varied from tumor to tumor and was between 3 and 15 virus genome equivalents per cell. The content of virus DNA per cell in spleens from tumor-bearing chickens was much lower than in tumors from the same animals. MDV-infected cell cultures contained a large proportion (28-59%) of virus antigen-positive cells, as measured by immunofluorescence, but tumor cells were negative in this respect (<0.02% positive cells). These data indicate that MDV is present in a provirus form in tumor cells.     

Marek's disease virus type 1 microRNA miR-M3 suppresses cisplatin-induced apoptosis by targeting Smad2 of the transforming growth factor beta signal pathway

Viruses cause about 15% of the cancers that are still the leading causes of human mortality. The discovery of viral oncogenes has enhanced our understanding of viral oncogenesis. However, the underlying molecular mechanisms of virus-induced cancers are complex and require further investigation. The present study has attempted to investigate the effects of the microRNAs (miRNAs) encoded by Marek's disease virus 1 (MDV1), a chicken herpesvirus causing acute T-cell lymphomas and solid visceral tumors in chickens, on anti-cancer drug-induced apoptosis and identify the targets of the miRNAs. The results showed that of the total 14 miRNAs encoded by MDV1, MDV1-miR-M3 significantly promoted cell survival under treatment with cisplatin, a widely used chemotherapy drug. MDV1-miR-M3 suppressed cisplatin-induced apoptosis by directly downregulating expression at the protein but not the mRNA level of Smad2, a critical component in the transforming growth factor β signal pathway. Our data suggest that latent/oncogenic viruses may encode miRNAs to directly target cellular factors involved in antiviral processes including apoptosis, thus proactively creating a cellular environment beneficial to viral latency and oncogenesis. Furthermore, the knowledge of the apoptosis resistance conferred by viral miRNAs has great practical implications for improving the efficacy of chemotherapies for treating cancers, especially those induced by oncogenic viruses.     

Marek's disease virus type 2 (MDV-2)-encoded microRNAs show no sequence conservation with those encoded by MDV-1

MicroRNAs (miRNAs) are increasingly being recognized as major regulators of gene expression in many organisms, including viruses. Among viruses, members of the family Herpesviridae account for the majority of the currently known virus-encoded miRNAs. The highly oncogenic Marek's disease virus type 1 (MDV-1), an avian herpesvirus, has recently been shown to encode eight miRNAs clustered in the MEQ and LAT regions of the viral genome. The genus Mardivirus, to which MDV-1 belongs, also includes the nononcogenic but antigenically related MDV-2. As MDV-1 and MDV-2 are evolutionarily very close, we sought to determine if MDV-2 also encodes miRNAs. For this, we cloned, sequenced, and analyzed a library of small RNAs from the lymphoblastoid cell line MSB-1, previously shown to be coinfected with both MDV-1 and MDV-2. Among the 5,099 small RNA sequences determined from the library, we identified 17 novel MDV-2-specific miRNAs. Out of these, 16 were clustered in a 4.2-kb long repeat region that encodes R-LORF2 to R-LORF5. The single miRNA outside the cluster was located in the short repeat region, within the C-terminal region of the ICP4 homolog. The expression of these miRNAs in MSB-1 cells and infected chicken embryo fibroblasts was further confirmed by Northern blotting analysis. The identification of miRNA clusters within the repeat regions of MDV-2 demonstrates conservation of the relative genomic positions of miRNA clusters in MDV-1 and MDV-2, despite the lack of sequence homology among the miRNAs of the two viruses. The identification of these novel miRNAs adds to the growing list of virus-encoded miRNAs.     

Development and application of a phosphoproteomic method using electrostatic repulsion-hydrophilic interaction chromatography (ERLIC), IMAC, and LC-MS/MS analysis to study Marek's Disease Virus infection

Marek's Disease (MD) is an avian neoplastic disease caused by Marek's Disease Virus (MDV). The mechanism of virus transition between the lytic and latent cycle is still being investigated; however, post-translational modifications, especially phosphorylation, have been thought to play an important role. Previously, our group has used strong cation exchange chromatography in conjunction with reversed-phase liquid chromatography-tandem mass spectrometry (LC-MS/MS) to study the changes in global proteomic expression upon MDV infection (Ramaroson , M. F.; Ruby, J.; Goshe, M. B.; Liu , H.-C. S. J. Proteome Res. 2008, 7, 4346-4358). Here, we extend our study by developing an effective separation and enrichment approach to investigate the changes occurring in the phosphoproteome using electrostatic repulsion-hydrophilic interaction chromatography (ERLIC) to fractionate peptides from chicken embryo fibroblast (CEF) digests and incorporating a subsequent IMAC enrichment step to selectively target phosphorylated peptides for LC-MS/MS analysis. To monitor the multidimensional separation between mock- and MDV-infected CEF samples, a casein phosphopeptide mixture was used as an internal standard. With LC-MS/MS analysis alone, no CEF phosphopeptides were detected, while with ERLIC fractionation only 1.2% of all identified peptides were phosphorylated. However, the incorporation of IMAC enrichment with ERLIC fractionation provided a 50-fold increase in the percentage of identified phosphopeptides. Overall, a total of 581 unique phosphopeptides were identified (p < 0.05) with those of the MDV-infected CEF sample containing nearly twice as many as the mock-infected control of which 11% were unique to MDV proteins. The changes in the phosphoproteome are discussed including the role that microtubule-associated proteins may play in MDV infection mechanisms.