Replication of human cytomegalovirus is limited at the level of nucleocytoplasmic transport of viral capsids, a process that requires the disassembly of the nuclear lamina. Deletion of the protein kinase gene UL97 from the viral genome showed that the activity of pUL97 plays an important role for viral capsid egress. Here, we report that p32, a novel cellular interactor of the viral kinase pUL97, promotes the accumulation of pUL97 at the nuclear membrane by recruiting the p32-pUL97 complex to the lamin B receptor. Transfection of active pUL97, but not a catalytically inactive mutant, induced a redistribution of lamina components as demonstrated for recombinant lamin B receptor-green fluorescent protein and endogenous lamins A and C. Consistent with this, p32 itself and lamins were phosphorylated by pUL97. Importantly, overexpression of p32 in human cytomegalovirus-infected cells resulted in increased efficiency of viral replication and release of viral particles. Thus, it is highly suggestive that the cellular protein p32 recruits pUL97 to induce a dissolution of the nuclear lamina thereby facilitating the nuclear export of viral capsids.The transport of macromolecules in eukaryotic cells is subject to a strict compartmentalization into nucleus and cytoplasm. Exchange reactions between the two compartments are mediated through the nuclear pore complex, and thus the integrity of the nuclear envelope, composed of membrane and lamina constituents, is crucial for intracellular transport pathways. The nuclear lamina, underlining the inner nuclear membrane, contains a variable number of lamin isoforms (which are members of the intermediate filament family of cytoskeletal proteins) and forms a rigid, proteinaceous meshwork. During infection with herpesviruses, the nuclear lamina represents a barrier to the nucleocytoplasmic transport of viral capsids (1). Because of the large size of herpesviral capsids (ϳ120 nm), which does not allow their direct cytoplasmic release through nuclear pores, the structural destabilization of the nuclear lamina is an important prerequisite of virus budding. Lamina destabilization requires site-specific phosphorylation of lamins and lamin-binding membrane proteins. Phosphorylation leads to lamin depolymerization and may also permit their release from lamin-binding membrane proteins, including the lamin B receptor (LBR) 2 (2, 3). Protein kinase C and Cdc2 have been identified as kinases phosphorylating lamins during mitosis (3, 4). Interestingly, protein kinase C is involved in the dissolution of the nuclear lamina in cells infected with murine cytomegalovirus (5). In addition to cellular protein kinases, the activity of virus-encoded protein kinases has been suspected as an important additional critical factor for nuclear export of herpesviruses, such as herpes simplex virus type 1 (HSV-1) and pseudorabies virus (6, 7). Concerning the replication of human cytomegalovirus (HCMV), which is a major human pathogenic herpesvirus, little information has been published on destabilization of the n...
Kaposi's sarcoma (KS) is an endothelial cell-derived tumor. Investigations of the molecular mechanisms of KS pathogenesis and the identification of drugs for treatment of KS depend critically on valid cell-culture models. Two major immortalized cell lines are available for KS research. Recently, the KS cell line KS Y-1 has been shown to be cross-contaminated with the T24 urinary bladder cancer cell line (ATCC HTB-4). Here, we show by short tandem repeat profiling that the second KS cell line, SLK, is indistinguishable from the clear-cell renal-cell carcinoma cell line Caki-1. Immunocytochemical detection of cytokeratin expression confirmed the epithelial-cell origin of SLK cells. Our findings indicate that SLK cells are not of endothelial origin and should not be used in future studies as a model for KS-derived endothelial tumor cells. We suggest that in the future, more attention needs to be paid to the authenticity of cells in lines derived from human tissues.
The human cytomegalovirus-encoded protein kinase pUL97 is a determinant of efficient virus replication and fulfils several regulatory functions. In particular, pUL97 interacts with and phosphorylates viral and cellular proteins. Substrate phosphorylation has regulatory consequences on viral replicative stages such as DNA synthesis, transcription and nuclear capsid egress. pUL97, in accordance with related herpesviral protein kinases, possesses strong autophosphorylation activity. Here, we demonstrate that pUL97 shows a pronounced potential to self-interact. Self-interaction of pUL97 is not dependent on its kinase activity, as seen with a catalytically inactive point mutant. The property of self-interaction maps to the amino acid region 231-280 which is separable from the postulated kinase domain. The detection of high-molecular-mass complexes of pUL97 suggests the formation of dimers and oligomers. Importantly, the analysis of pUL97 mutants by in vitro kinase assays demonstrated a correlation between self-interaction and protein kinase activity, i.e. all mutants lacking the ability to self-interact were negative or reduced in their kinase activity. Thus, our findings provide novel insights into the pUL97 structure-activity relationship suggesting an importance of self-interaction for pUL97 functionality.
Human herpesvirus 8 (HHV-8) is the etiological agent of Kaposi's sarcoma (KS).
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