Retroviral vector-based RNA interference against Marek's disease virus and avian leukosis virus

Chen, Mo.

January 2008

Thesis (Ph. D.)--Michigan State University. Microbiology and Molecular Genetics, 2008. / Title from PDF t.p. (Proquest, viewed on Aug. 20, 2009) Includes bibliographical references. Also issued in print.

Nuclear Factor kappa B is central to Marek's Disease herpesvirus induced neoplastic transformation of CD30 expressing lymphocytes in-vivo

Kumar, Shyamesh, Kunec, Dusan, Buza, Joram, Chiang, Hsin-I, Zhou, Huaijun, Subramaniam, Sugalesini, Pendarvis, Ken, Cheng, Hans, Burgess, Shane

January 2012

BACKGROUND:Marek's Disease (MD) is a hyperproliferative, lymphomatous, neoplastic disease of chickens caused by the oncogenic Gallid herpesvirus type 2 (GaHV-2 / MDV). Like several human lymphomas the neoplastic MD lymphoma cells overexpress the CD30 antigen (CD30hi) and are in minority, while the non-neoplastic cells (CD30lo) form the majority of population. MD is a unique natural in-vivo model of human CD30hi lymphomas with both natural CD30hi lymphomagenesis and spontaneous regression. The exact mechanism of neoplastic transformation from CD30lo expressing phenotype to CD30hi expressing neoplastic phenotype is unknown. Here, using microarray, proteomics and Systems Biology modeling / we compare the global gene expression of CD30lo and CD30hi cells to identify key pathways of neoplastic transformation. We propose and test a specific mechanism of neoplastic transformation, and genetic resistance, involving the MDV oncogene Meq, host gene products of the Nuclear Factor Kappa B (NF-kappaB) family and CD30 / we also identify a novel Meq protein interactome.RESULTS:Our results show that a) CD30lo lymphocytes are pre-neoplastic precursors and not merely reactive lymphocytes / b) multiple transformation mechanisms exist and are potentially controlled by Meq / c) Meq can drive a feed-forward cycle that induces CD30 transcription, increases CD30 signaling which activates NF-kappaB, and, in turn, increases Meq transcription / d) Meq transcriptional repression or activation of the CD30 promoter generally correlates with polymorphisms in the CD30 promoter distinguishing MD-lymphoma resistant and susceptible chicken genotypes e) MDV oncoprotein Meq interacts with proteins involved in physiological processes central to lymphomagenesis.CONCLUSIONS:In the context of the MD lymphoma microenvironment (and potentially in other CD30hi lymphomas as well), our results show that the neoplastic transformation is a continuum and the non-neoplastic cells are actually pre-neoplastic precursor cells and not merely immune bystanders. We also show that NF-kappaB is a central player in MDV induced neoplastic transformation of CD30-expressing lymphocytes in vivo. Our results provide insights into molecular mechanisms of neoplastic transformation in MD specifically and also herpesvirus induced lymphoma in general.

Marek's disease

Lymphomas

Meq

NF-κB

Genetic resistance

CD30

Proteomics

Characterization of the Meq oncoproteins of Marek's disease virus vaccine strain CVI988/Rispens

Ajithdoss, Dharani K.

2009 May 1900

Marek?s disease virus serotype-1 (MDV-1) causes T cell lymphomas in chickens. Vaccines prepared from attenuated CVI988/Rispens MDV-1 strain currently offer the best protection. Although attenuated CVI988 is non-oncogenic, it codes for two forms of the MDV-1 oncoprotein Meq (CVI-Meq and CVI-L Meq). In this study, both CVI-Meq proteins, like the Meq protein of Md5 (a very virulent oncogenic strain), transformed Rat-2 and NIH3T3 cells. Both CVI-Meq and CVI-L Meq proteins activated the meq promoter only in the presence of chicken c-Jun (CK-Jun) whereas Md5-Meq activated the same promoter irrespective of CK-Jun co-expression. However, all three Meq proteins bound the meq promoter regardless of whether CK-Jun was co-expressed. We constructed three chimeric Meq proteins, namely, Md5-CVI-Meq, CVI-Md5-Meq, and Md5-CVI-L by exchanging domains between Md5 meq and CVI meq genes. Although these chimeric Meq proteins transactivated the meq promoter, the activation was significantly less than Md5-Meq. The current study indicated amino acid residues at positions 71 and 320 were important for Md5-Meq increase transcription of its own promoter. All three Meq proteins activated the MDV gB, MMP-3 and Bcl-2 promoters and suppressed transcription from the MDV pp38/pp14 bidirectional promoter. CVI-Meq protein in the context of other Md5 genes caused tumors only in 6% of chickens when compared to parental rMd5 (a very virulent strain), which induced lymphomas in 100% of chickens, (Reddy and Lupiani, unpublished data). Taking advantage of these two different phenotypes, we constructed two chimeric Meq proteins, Md5/CVI-Meq and CVI/Md5-Meq, by exchanging DNA binding and transactivation domains between Md5-Meq and CVI-Meq to understand the role of the DNA binding and the transactivation domains of Meq in transformation. rMd5-Md5/CVI-Meq virus caused 100% mortality in chickens and T lymphomas were found at high frequency in the peripheral nerves and various organs such as the heart, spleen, kidney, and gonads. On the other hand, rMd5-CVI/Md5-Meq induced disease in 36% of chickens on average and lesions were primarily in the nerves. Very rarely, lesions were present in the spleen and heart and no tumors were present in the kidney or gonads. Our results suggest that both the DNA binding domain and transactivation domain of Meq could cooperatively determine the nature of lymphomas in chickens.

Chickens

lymphoma

Marek's disease virus

CVI988

Meq

transformation

transactivation

Characterization of a bacterial artificial chromosome (BAC)-based infectious clone of a low passage Marek's disease virus (MDV) vaccine strain, CVI988

McDowell, Erin.

January 2009

Thesis (M.S.)--University of Delaware, 2009. / Principal faculty advisor: Mark Parcells, Dept. of Animal & Food Sciences. Includes bibliographical references.

Association of markers in genes of the growth hormone axis with the viral load in lymphoid tissues of chickens infected with Marek's disease virus

Linher, Katja.

January 2000

Vaccination against Marek's disease (MD) is greatly enhanced by host genetic resistance. Genes of the growth hormone (GH) axis have been reported to affect the ontogeny and effector functions of cells of the immune system. Two strains of White Leghorn chickens bred for contrasting homozygous markers in the GH and GH receptor (GHR) genes were challenged with MDV. Contrasts for the significant interaction between marker genotype and tissue indicated that the GH/GHR marker genotype caused a shift in the distribution of the viral load in lymphoid tissues in the two strains. The analysis suggests that genetic variations in genes of the GH axis may differentially affect the host response to MDV replication in lymphoid tissues. Regarding the early time course of infection, at day 6 the viral load was highest in the thymus, while at day 10, it was highest in the spleen, indicating that the virus may have accumulated in the spleen or was continuing to replicate in this tissue. (Abstract shortened by UMI.)

Natural immunity.

Identification of genetic markers associated with Marek's disease resistance in chickens

Masilamani, Twinkle Jasmine

January 2003

Marek's disease (MD) is a highly contagious and economically important disease in the poultry industry. It is caused by an oncogenic avian herpes virus. The ability of the virus to evolve into new strains is a continual threat. Vaccination, proper management and genetic resistance are required to completely eliminate the pathogen. The discovery of several markers associated with MD resistance shows that genetic selection for resistance is feasible. Our objective was to identify markers in QTL regions that are associated with MD viraemia. The markers analysed were in the ODC gene, the GH gene and two chemokine genes, all of which are candidate genes for immune responsiveness. A database in a commercial strain of White Leghorn chickens was created. Heterozygous males and homozygous females were identified. The offspring were challenged with MD virus and spleen and thymus samples were collected six days after infection. The viral titre was quantified using competitive PCR. The data was analysed using non-parametric statistics. We found that the paternal alleles of a Hindlll RFLP in the ODC gene were associated with differences in MD viraemia in one of the six sire families analysed. In addition, a Sacl RFLP located in the GH gene also segregated for alleles, which affected MD viraemia. The analysis of the ODC gene was extended to include a second RFLP at a Msp\ site. Together with the Hindlll RFLP it defines three different haplotypes. One genotypic class AB (Hindlll (+/-), Mspl (+/+)) was associated with low vireamia in the thymus and the genotype BB (Hindlll (-/-), Mspl (+/+)) with high viraemia in the spleen. The result suggests that genetic variations in the ODC and GH gene affect MD viraemia. However, we cannot exclude that the observed effects might be due to linkage disequilibrium with adjacent genes. In the latter case, chromosome 3 and chromosome 1, which harbour the ODC and GH gene respectively, must segregate for regions that affect viraemia. The markers identified in this analysis can be used in marker assisted selection.

Natural immunity.

Association of markers in genes of the growth hormone axis with the viral load in lymphoid tissues of chickens infected with Marek's disease virus

Linher, Katja.

January 2000

No description available.

Natural immunity.

Identification of genetic markers associated with Marek's disease resistance in chickens

Masilamani, Twinkle Jasmine

January 2003

No description available.

Natural immunity.

Mechanisms of Genetic Resistance and Neoplastic Transformation in Marek's Disease

Kumar, Shyamesh

09 December 2011

Marek’s disease (MD) of chickens is an economically important, contagious, neoplastic disease caused by Gallid herpesvirus type 2. All chicken are susceptible to MDV infection and neoplastic transformation, but, only susceptible genotypes develop gross lymphomas. Lymphomas regress in resistant genotypes from 21 days post infection (dpi). The central aims of this study were to understand the mechanisms of non-MHC associated genetic resistance and the molecular pathways of neoplastic transformation. We hypothesized that, a) in resistant chickens at 21 dpi the tissue microenvironment is compatible with cell mediated immunity but in susceptible lines antagonistic to cell mediated immunity, b) resistant genotypes present immunogenic peptides on their MHC class I which while the peptides presented by susceptible genotypes do not induce CTL immunity resulting in tumor progression. We used inbred, MHC homozygous MD resistant (L6) and susceptible (L7) chickens and reductionist methods to test our hypotheses. Our results indicated that the tumor microenvironment is pro T-regulatory in both resistant and susceptible genotypes, and, the host immune response (pro Th-1 in resistant and pro Th-2/T-reg in susceptible) influences the tumor regression or progression. Statistical analysis of MHC class I bound peptides from resistant and susceptible genotypes confirmed that they present the same peptides and perhaps genes outside the MHC locus play an important role in determining resistance. Next, using Systems Biology tools like genomics, proteomics, Gene Ontology modeling and pathway analysis we compared the transcriptome and proteome of neoplastically transformed cells (CD30hi) and non-neoplastically transformed cells (CD30lo) which are the two components of tumor microenvironment. We demonstrated that: a) in situ, CD30lo cells are pre-neoplastic and the proteome involved in transformation and potential mechanisms that may be controlled by MDV oncogene Meq; b) Meq can drive a feed forward loop that induces CD30 transcription and overexpression, increased CD30 signaling, which then activates NFêB and, in turn, increases Meq transcription; c) Meq transcriptional repression or activation from the CD30 promoter generally correlates with a polymorphism in the CD30 promoter between MD-resistant and -susceptible chicken genotypes and so a herpesvirus has evolved to utilize NFêB as a direct transcriptional activator for its oncogene.

Meq

Hodgkin's Lymphoma

CD30

Marek's Disease

tumor resistance

lymphoma

Functional analysis of Meq, a Marek's disease virus (MDV)bZIP protein associated with T cell transformation

Qian, Zheng

January 1996

No description available.

Biology, Molecular

Meq

Marek's disease virus(MDV)

T cell transformation