Overexpression of cellular telomerase RNA enhances virus-induced cancer formation.

The telomerase RNA subunit (TR) is overexpressed in many tumors; however, the contribution of TR in cancer formation remains elusive. The most frequent clinically diagnosed cancer in the animal kingdom is caused by the highly oncogenic herpesvirus Marek's disease virus (MDV). MDV encodes a TR (vTR) that plays an important role in virus-induced tumorigenesis and shares 88% sequence identity with its cellular homologue. To determine if the cellular TR possesses pro-oncogenic activity, we replaced vTR with the cellular homologue in the virus genome. Insertion of cellular TR resulted in a strong overexpression in virus infected cells, while virus replication was not affected. Strikingly, cellular TR promoted tumor formation as efficient as vTR, while tumorigenesis was severely impaired in the absence of vTR. Our data provide the first evidence that overexpression of cellular TR can contribute to tumor formation in vivo using this natural virus-host model for herpesvirus-induced oncogenesis.

Hyperediting by ADAR1 of a new herpesvirus lncRNA during the lytic phase of the oncogenic Marek's disease virus.

Marek's disease virus, or Gallid herpesvirus 2 (GaHV-2), is an avian alphaherpesvirus that induces T-cell lymphoma in chickens. During transcriptomic studies of the RL region of the genome, we characterized the 7.5 kbp gene of the ERL lncRNA (edited repeat-long, long non-coding RNA), which may act as a natural antisense transcript (NAT) of the major GaHV-2 oncogene meq and of two of the three miRNA clusters. During infections in vivo and in vitro, we detected hyperediting of the ERL lncRNA that appeared to be directly correlated with ADAR1 expression levels. The ERL lncRNA was expressed equally during the lytic and latent phases of infection and during viral reactivation, but its hyperediting increased only during the lytic infection of chicken embryo fibroblasts. We also showed that chicken ADAR1 expression was controlled by the JAK/STAT IFN-response pathway, through an inducible promoter containing IFN-stimulated response elements that were functional during stimulation with IFN-α or poly(I:C). Like the human and murine miR-155-5p, the chicken gga-miR-155-5p and the GaHV-2 analogue mdv1-miR-M4-5p deregulated this pathway by targeting and repressing expression of suppressor of cytokine signalling 1, leading to the upregulation of ADAR1. Finally, we hypothesized that the natural antisense transcript role of the ERL lncRNA could be disrupted by its hyperediting, particularly during viral lytic replication, and that the observed deregulation of the innate immune system by mdv1-miR-M4-5p might contribute to the viral cycle.

ICP27 protein of Marek's disease virus interacts with SR proteins and inhibits the splicing of cellular telomerase chTERT and viral vIL8 transcripts.

All herpesviruses have a post-transcriptional regulatory protein that prevents precursor mRNA splicing and leads to the shutting off of host protein synthesis. The ICP27 protein of herpes simplex virus 1 (HSV-1) is the prototype of these proteins. Marek's disease virus (MDV-1), an alphaherpesvirus that induces lymphoma in birds, also has an ICP27 protein that is produced in lytic MDV-1-infected cells. We characterized this protein. We demonstrated ICP27 production in latently infected MSB-1 cells, but only on MDV-1 reactivation. ICP27 was found predominantly in specific structures within the nucleus. The ICP27 of MDV-1 colocalized and interacted with SR proteins. We demonstrated inhibitory effects of MDV-1 ICP27 on the splicing of both the viral vIL8 and cellular chTERT (telomerase reverse transcriptase) genes. Thus, the ICP27 of MDV-1 plays a similar role to the ICP27 of HSV-1 and may be involved in MDV-1 replication and the development of Marek's disease.

Herpesvirus telomerase RNA(vTR)-dependent lymphoma formation does not require interaction of vTR with telomerase reverse transcriptase (TERT).

Telomerase is a ribonucleoprotein complex involved in the maintenance of telomeres, a protective structure at the distal ends of chromosomes. The enzyme complex contains two main components, telomerase reverse transcriptase (TERT), the catalytic subunit, and telomerase RNA (TR), which serves as a template for the addition of telomeric repeats (TTAGGG)(n). Marek's disease virus (MDV), an oncogenic herpesvirus inducing fatal lymphoma in chickens, encodes a TR homologue, viral TR (vTR), which significantly contributes to MDV-induced lymphomagenesis. As recent studies have suggested that TRs possess functions independently of telomerase activity, we investigated if the tumor-promoting properties of MDV vTR are dependent on formation of a functional telomerase complex. The P6.1 stem-loop of TR is known to mediate TR-TERT complex formation and we show here that interaction of vTR with TERT and, consequently, telomerase activity was efficiently abrogated by the disruption of the vTR P6.1 stem-loop (P6.1mut). Recombinant MDV carrying the P6.1mut stem-loop mutation were generated and tested for their behavior in the natural host in vivo. In contrast to viruses lacking vTR, all animals infected with the P6.1mut viruses developed MDV-induced lymphomas, but onset of tumor formation was significantly delayed. P6.1mut viruses induced enhanced metastasis, indicating functionality of non-complexed vTR in tumor dissemination. We discovered that RPL22, a cellular factor involved in T-cell development and virus-induced transformation, directly interacts with wild-type and mutant vTR and is, consequently, relocalized to the nucleoplasm. Our study provides the first evidence that expression of TR, in this case encoded by a herpesvirus, is pro-oncogenic in the absence of telomerase activity.

Vaccination against Marek's disease reduces telomerase activity and viral gene transcription in peripheral blood leukocytes from challenged chickens.

We investigated whether telomerase activity and viral gene transcription were associated with protection against the RB-1B strain of Marek's disease virus (MDV) in chickens vaccinated with Rispens CVI988 or the herpes virus of turkey (HVT). Telomerase activity in peripheral blood leukocytes (PBLs) seemed to be an appropriate marker of lymphoma and levels of viral transcription were correlated with the virulence of MDV strains. Vaccinated protected birds had lower levels of telomerase activity and RB-1B viral gene transcription than unvaccinated chickens infected with RB-1B. The decrease in RB-1B viral transcription was more marked in chickens vaccinated with CVI988 than in those vaccinated with HVT. Indeed, RB-1B viral transcription was not detectable after 14 days post-challenge. In conclusion, telomerase activity and gene transcription in challenge MDV strains are potential new reliable criteria of protection in vaccinated chickens.

Sequential autoprocessing of Marek's disease herpesvirus protease differs from that of other herpesviruses.

Herpesviruses encode a unique serine protease essential for viral capsid maturation. This protease undergoes autoprocessing at two sites, R and M, at the consensus sequence (V, L, I)(P3)-X(P2)-A(P1)/S(P1') (where X is a polar amino acid). We observed complete autoprocessing at the R and M sites of Marek's disease virus (MDV) protease following production of the polyprotein in Escherichia coli. Site-directed mutagenesis confirmed the predicted sequence of the R and M sites, with the M site sequence being nonconsensual: M(P3)-N(P2)-A(P1)/S(P1'). Mutagenesis and expression kinetics studies suggested that the atypical MDV M site was cleaved exclusively by the processed short protease, a feature making MDV unique among herpesviruses.

Telomerase flies the coop: the telomerase RNA component as a viral-encoded oncogene.

Telomerase, the enzyme that elongates our telomeres, is crucial for cancer development based on extensive analyses of human cells, human cancers, and mouse models. New data now suggest that a viral telomerase RNA gene encoded by Marek's disease virus (MDV), an oncogenic herpesvirus of chickens, promotes tumor formation. These findings highlight the importance of telomerase in cancer and raise new questions regarding the mechanisms by which the telomerase RNA component supports tumorigenesis.

A virus-encoded telomerase RNA promotes malignant T cell lymphomagenesis.

Telomerase is a ribonucleoprotein complex consisting of two essential core components: a reverse transcriptase and an RNA subunit (telomerase RNA [TR]). Dysregulation of telomerase has been associated with cell immortalization and oncogenesis. Marek's disease herpesvirus (MDV) induces a malignant T cell lymphoma in chickens and harbors in its genome two identical copies of a viral TR (vTR) with 88% sequence identity to chicken TR. MDV mutants lacking both copies of vTR were significantly impaired in their ability to induce T cell lymphomas, although lytic replication in vivo was unaffected. Tumor incidences were reduced by >60% in chickens infected with vTR- viruses compared with animals inoculated with MDV harboring at least one intact copy of vTR. Lymphomas in animals infected with the vTR- viruses were also significantly smaller in size and less disseminated. Constitutive expression of vTR in the chicken fibroblast cell line DF-1 resulted in a phenotype consistent with transformation as indicated by morphological alteration, enhanced anchorage-independent cell growth, cell growth beyond saturation density, and increased expression levels of integrin alpha v. We concluded that vTR plays a critical role in MDV-induced T cell lymphomagenesis. Furthermore, our results provide the first description of tumor-promoting effects of TR in a natural virus-host infection model.

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.

Mitochondrial PEPCK: a highly polymorphic gene with alleles co-selected with Marek's disease resistance in chickens.

The gene coding for the mitochondrial phosphoenolpyruvate carboxykinase (PEPCK-M), a pivotal component in gluconeogenesis from lactate via the Cori cycle, was highly polymorphic in strains of egg-type chickens (White Leghorn) of different origins. Based on MspI restriction fragment polymorphisms a total of seven alleles could be distinguished. The allele frequencies were determined in six pairs of strains derived from different genetic base populations. Each pair consisted of two strains which differed in their susceptibility to Marek's disease (MD), a virus-induced neoplastic disease. The frequency of the most common haplotype (M2) was consistently higher in the susceptible strains than in the corresponding resistant strains (P < 0.05, Wilcoxon signed-ranks test), indicating that the observed differences were not due to random genetic drift. This result suggests that PEPCK-M may be a candidate gene which contains genetic variants affecting MD susceptibility. Variations in gluconeogenesis may affect the interplay between proliferation of neoplasia and host metabolism.

Herpesvirus infection prevents activation of cytoplasmic cholesteryl esterase in arterial smooth muscle cells.

Herpesvirus infection has been shown to alter the cholesteryl ester cycle in avian arterial smooth muscle cells, resulting in cytoplasmic cholesteryl ester accumulation (Hajjar, D. P., Falcone, D. J., Fabricant, C. G., and Fabricant, J. (1985) J. Biol. Chem. 260, 6124-6128). In this study, we attempted to define some of the regulatory mechanisms associated with the control of cytoplasmic cholesteryl esterase in Marek's disease herpesvirus (MDV)-infected cells. We found that cholesteryl esterase activity in MDV-infected cells could not be activated by dibutyryl cyclic AMP, dibutyryl cyclic AMP added together with protein kinase, or agonists of adenylate cyclase. Activation of cytoplasmic cholesteryl esterase activity occurred in uninfected cells and in cells infected with a control virus, turkey herpesvirus. Furthermore, the rate of cholesterol efflux from arterial smooth muscle cells challenged with dibutyryl cyclic AMP was unchanged in MDV-infected cells as compared to uninfected or turkey herpesvirus-infected cells in which efflux was increased. We propose that the reduced cytoplasmic cholesteryl esterase activity in lipid-laden, herpesvirus-infected cells is due partly to its inability to be activated by the cyclic AMP-protein kinase mechanism. This may contribute to the pathologic changes seen in MDV-infected arterial cells, including accumulation of intracellular cholesteryl esters.

Virus-induced atherosclerosis. Herpesvirus infection alters aortic cholesterol metabolism and accumulation.

Infection of normocholesterolemic, specific-pathogen-free chickens with Marek's disease herpesvirus (MDV) has been shown histologically to lead to chronic atherosclerosis like that in humans. The development of herpesvirus-induced atherosclerosis in vivo and the presence of specific Marek's antigen within aortic cells suggested that MDV infection may modify lipid metabolism and lead to significant lipid accumulation. Experiments reported herein were designed to determine the types and quantity of lipid present in aortas from MDV-infected and uninfected chickens between 2 and 8 months of age following infection and assess one possible mechanism of lipid accumulation by evaluating the effect of MDV infection on aortic cholesterol and cholesteryl ester (CE) metabolism. Chromatographic-fluorometric analyses indicated that at 4 and 8 months of age after MDV inoculation, MDV-infected animals had a significant (P less than 0.05) two-fold to threefold increase in total aortic lipid accumulation characterized by significant increases in cholesterol, CE, triacylglycerol, and phospholipid as compared with aortas from uninfected animals. At 8 months of age, similar increases in aortic lipid accumulation were observed in MDV-infected animals as compared with those animals vaccinated with turkey herpesvirus and later challenged with MDV. CE synthetic activity was increased significantly by 50% at 4 months of age in the MDV-infected group as compared with the uninfected group, which could explain the initial increase in CE accumulation. By 8 months of age, the authors also observed a twofold increase in CE synthetic activity and a 30% and 80% reduction in lysosomal and cytoplasmic CE hydrolytic activities, respectively, in aortas of MDV-infected chickens as compared to controls. Moreover, infection with MDV blocked the activation of cytoplasmic CE hydrolytic activity by dibutyryl cyclic AMP or exogenous cyclic AMP-dependent protein kinase. Taken together, these results suggest that lipid accretion in aortas of MDV-infected chickens results, in part, from alterations in cholesterol/CE metabolism during early stages of the disease. These findings support the hypothesis that human atherosclerosis may result from specific herpesvirus infection which can alter lipid metabolism and lead to lipid accretion.

Catalase depression in malignant liver from chickens with myeloblastosis and Marek's disease.

In rapidly frozen livers from chickens affected with myeloblastosis and Marek's disease and from unaffected control birds there exists a strong correlation between catalase activity and catalase Electron Paramagnetic Resonance (EPR) signal intensities. The diseased chickens had activities and signals reduced to as little as 10% of control values. There were no changes in the EPR parameters in diseased liver and the data support the hypothesis that the lowering in activity is due to lowered catalase levels rather than to catalase inhibition. The rate of transformation of catalase to catalase-formate in liver was studied by freeze-clamping liver in anaesthetised chickens, then warming to 37 degrees for 1 or 2 minutes anaerobiosis, and then refreezing. The only difference of significance in this transformation between diseased and normal livers was the greater percentage of total catalase present as catalase-formate (approximately + 15%) in aerobic diseased liver, which may indicate a lowered production of hydrogen peroxide, relative to formate, in these livers. The rate of transformation was far faster in chickens (t1/2 less than 1 min) than in the rat (t1/2 = 7.7 min).

[Genetic polymorphism of alkaline phosphatase and the resistance to Marek's disease virus]. / Genetichen polimorfizum na alkalnata fosfataza i ustoichivost na virusa na bolestta na Marek.

Experiments were carried out with a total of 222 birds of the 5-A, 6-E, Ya-73, LL, and LS lines of the White Leghorn breed to find whether or not there existed any correlation between the alkaline phosphatase allels and the resistance to Marek's disease. The polymorphism of alkaline phosphatase was evaluated in the blood plasma of birds through horizontal electrophoresis in starch gel after G a hn e [3]. The resistance of the five egg laying lines of birds was found to be associated with the Akps allel, and their susceptibility - with the AkpF allel. No mortality with the homozygous gene type SS was established in the investigated lines except for a birds of the LL line. It was found that there existed full agreement of the results from the studies on broiler and laying lines concerning the exclusive resistance of birds of Akp SS gene type. This made it reasonable to believe that the indirect selection by resistance to the Marek's disease virus through the use of the Akps allel as a genetic marker was promising.

[Relationship between the genetic polymorphism of alkaline phosphatase and the resistance of broiler poultry to Marek's disease virus]. / Zavisimost mezhdu genetichniia polimorfizum na alkalnata fosfataza i ustoichivostta na ptitsite broilerno napravlenie kum virusa na bolestta na Marek.

Studied was the polymorphism of alkaline phosphatase in blood plasma samples taken from 507 poulets and cocks of lines 66 and 77 of the Cornish breed, and lines 88 and 99 of the White Plymouth Rock breed. The birds were divided into three groups to test their resistance to Marek's disease: (1) controls, (2) infected with the virus of Marek's disease with 3 subgroups--resistant birds, slightly susceptible ones, and strongly susceptible ones, and (3) contacts, with two subgroups--survivals and birds that died. The blood plasma alkaline phosphatase was determined through horizontal electrophoresis on a starch gel, employing the method of Gahne. It was found that the alkaline phosphatase genetype FF frequency was lower with lines 66 and 77 than with line 88 and especially with line 99 of the White Plymouth Rock breed which proved most susceptible to the virus of Marek's disease. In the homozygotic alkaline phosphatase genetype SS none of the investigated lines showed any mortality. The resistance of broiler birds to Marek's disease was governed by the Akps allele, while the susceptibility was governed by the Akpf one. The former could be used as a genetic marker in the selection of initial lines of broiler birds by resistance, and the latter could be used as a marker in the selection by susceptibility.