@phdthesis{Valchanova2006, author = {Valchanova, Stamatova Ralitsa}, title = {Functional analysis of the murine cytomegalovirus genes m142 and m143}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-20215}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2006}, abstract = {Human cytomegalovirus (HCMV) infection causes clinical symptoms in immunocompromised individuals such as transplantant recipients and AIDS patients. The virus is also responsible for severe complications in unborn children and young infants. The species specificity of HCMV prevents the direct study of mechanisms controlling the infection in animal models. Instead, the murine cytomegalovirus (MCMV) is used as a model system. Human and murine CMVs have large double-stranded DNA genomes, encoding nearly 170 genes. About 30\% of the genes are committed to essential tasks of the virus. The remaining genes are involved in virus pathogenesis or host interaction and are dispensable for virus replication. The CMV genes are classified in gene families, based on sequence homology. In the present work, the function of two genes of the US22 gene family was analyzed. The MCMV genes m142 and m143 are the only members of this family that are essential for virus replication. These genes also differ from the remaining ten US22 gene family members in that they lack 1 of 4 conserved sequence motifs that are characteristic of this family. The same conserved motif is missing in the HCMV US22 family members TRS1 and IRS1, suggesting a possible functional homology. To demonstrate an essential role of m142 and m143, the genes were deleted from the MCMV genome, and the mutants were reconstituted on complementing cells. Infection of non-complementing cells with the deletion mutants did not result in virus replication. Virus growth was rescued by reinsertion of the corresponding genes. Cells infected with the viral deletion mutants synthesized reduced amounts of viral DNA, and viral late genes were not expressed. However, RNA analyses showed that late transcripts were present, excluding a role of m142 and m143 in regulation of gene transcription. Metabolic labelling experiments showed that total protein synthesis at late times postinfection was impaired in cells infected with deletion mutants. Moreover, the dsRNA-dependent protein kinase R (PKR) and its target protein, the translation initiation factor 2\&\#945; (eIF2\&\#945;) were phosphorylated in these cells. This suggested that the m142 and m143 are required for blocking the PKR-mediated shut-down of protein synthesis. Expression of the HCMV gene TRS1, a known inhibitor of PKR activation, rescued the replication of the deletion mutants, supporting the observation that m142 and m143 are required to inhibit this innate immune response of the host cell.}, subject = {Maus}, language = {en} } @phdthesis{Jurak2006, author = {Jurak, Igor}, title = {The molecular mechanism of the Cytomegalovirus species specificity}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-19233}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2006}, abstract = {Viruses have undergone a coevolution with their hosts, resulting in a specific adaptation to them. Consequently, many viruses have a limited host range. Occasionally, viruses acquire an adaptive mutation, which allows infection and replication in a different species as shown recently for the human immunodeficiency virus and influenza virus. Cross-species infections are responsible for the majority of emerging and re-emerging viral diseases. However, little is known about the mechanisms that restrict viruses to a certain host species, and the factors viruses need to cross the species barrier and replicate in a different host. Cytomegaloviruses are prototypes of the beta-herpesvirus subfamily and are highly species specific. They replicate only in cells of their own or a closely related species. The molecular mechanism underlying their species specificity is poorly understood and was investigated in this study. An initial observation showed that murine cytomegalovirus (MCMV) can replicate in human 293 and 911 cells, but not in any other human cells tested. Both cell lines are transformed with adenoviral E1 genes that encode a transcriptional transactivator (E1A) and two suppressors of apoptosis (E1B-55k and E1B-19k). This has led to the hypothesis that these functions are required for MCMV replication in human cells. Further analysis revealed that normal human cells died rapidly after infection of caspase-9-mediated apoptosis. Apoptosis induced by MCMV can be suppressed by broad-spectrum caspase inhibitors, and virus replication can be rescued, indicating a major role of caspases in this process. Furthermore, over-expression of a mitochondria-localized inhibitor of apoptosis, a Bcl-2-like protein, prevented apoptosis induced by this virus. Human cells resistant to apoptosis allowed also an efficient MCMV replication. The important role of Bcl-2-like proteins for cytomegalovirus cross-species infections was subsequently confirmed by inserting the corresponding genes, and other inhibitors of apoptosis and control genes into the MCMV genome. Only recombinant viruses expressing a Bcl-2-like protein were able to replicate in human cells. A single gene of human cytomegalovirus encoding a mitochondrial inhibitor of apoptosis was sufficient to allow MCMV replication in human cells. Moreover, the same principle facilitated replication of the rat cytomegalovirus in human cells. Thus, induction of apoptosis limits rodent cytomegalovirus cross-species infection.}, subject = {Cytomegalie-Virus}, language = {en} }