Host cell killing by the West Nile Virus NS2B-NS3 proteolytic complex: NS3 alone is sufficient to recruit caspase-8-based apoptotic pathway.

The West Nile Virus (WNV) non-structural proteins 2B and 3 (NS2B-NS3) constitute the proteolytic complex that mediates the cleavage and processing of the viral polyprotein. NS3 recruits NS2B and NS5 proteins to direct protease and replication activities. In an effort to investigate the biology of the viral protease, we cloned cDNA encoding the NS2B-NS3 proteolytic complex from brain tissue of a WNV-infected dead crow, collected from the Lower Merion area (Merion strain). Expression of the NS2B-NS3 gene cassette induced apoptosis within 48 h of transfection. Electron microscopic analysis of NS2B-NS3-transfected cells revealed ultra-structural changes that are typical of apoptotic cells including membrane blebbing, nuclear disintegration and cytoplasmic vacuolations. The role of NS3 or NS2B in contributing to host cell apoptosis was examined. NS3 alone triggers the apoptotic pathways involving caspases-8 and -3. Experimental results from the use of caspase-specific inhibitors and caspase-8 siRNA demonstrated that the activation of caspase-8 was essential to initiate apoptotic signaling in NS3-expressing cells. Downstream of caspase-3 activation, we observed nuclear membrane ruptures and cleavage of the DNA-repair enzyme, PARP in NS3-expressing cells. Nuclear herniations due to NS3 expression were absent in the cells treated with a caspase-3 inhibitor. Expression of protease and helicase domains themselves was sufficient to trigger apoptosis generating insight into the apoptotic pathways triggered by NS3 from WNV.

Expression and evolutionary analysis of West Nile virus (Merion strain).

The authors report a new strain of West Nile virus (WNV) with the expression analysis of its individual open reading frames. Since its sudden appearance in the summer of 1999 in New York City, the virus has spread rapidly across the continental United States into Canada and Mexico. Besides, its rapid transmission by various vectors, the spread of this virus through organ transplantation, blood transfusion, and mother-child transmission through breast milk is of concern. In order to understand molecular variations of WNV in North America and to generate new tools for understanding WNV biology, a complete clone of WNV has been constructed. Investigations so far have focused only on half of its genes products and a detailed molecular and cell biological aspects on all of WNV gene have yet to be clearly established. The open reading frames of WNV were recovered through an reverse transcriptase-polymerase chain reaction (RT-PCR)-PCR using brain tissue from a dead crow collected in Merion, PA, and cloned into a mammalian expression vector. The deduced amino acid sequences of individual open reading frames were analyzed to determine various structural motifs and functional domains. Expression analysis shows that in neuronal cells, C, NS1, and NS5 proteins are nuclear localized whereas the rest of the antigens are confined to the cytoplasm when they are expressed in the absence of other viral antigens. This is the first report that provides an expression analysis as well as intracellular distribution pattern for all of WNV gene products, cloned from an infected bird. Evolutionary analysis of Merion strain sequences indicates that this strain is distinct phylogenetically from the previously reported WNV strains.

Carboxyl terminus of hVIP/mov34 is critical for HIV-1-Vpr interaction and glucocorticoid-mediated signaling.

Human immunodeficiency virus, type 1 (HIV-1) vpr is a highly conserved gene among lentiviruses. The diverse functions of Vpr support interactions of this HIV accessory protein with host cell partners of important pathways. hVIP/mov34 (human Vpr Interacting Protein) is one of these identified Vpr ligands. hVIP is a 34-kDa member of the eIF3 family that is vital for early embryonic development in transgenic mice and important in cell cycle regulation. Its interaction with Vpr, however, is not yet clearly defined. Therefore, we constructed a panel of deletion mutants of this cytoplasmic cellular ligand to map the protein domain that mediates its interaction with Vpr. We observed that the carboxyl-terminal region of hVIP is critical for its interaction with Vpr. In the absence of Vpr or HIV infection, full-length hVIP is expressed in the cytoplasm. The cytoplasmic localization pattern of full-length hVIP protein, however, is shifted to a clear nuclear localization pattern in cells expressing both hVIP and Vpr. In contrast, Vpr did not alter the localization pattern of hVIP mutants, which have their carboxyl-terminal domain deleted. The movement of hVIP supported prior work that suggested that Vpr triggers activation of the GR receptor complex. In fact, we also observed that dexamethasone moves hVIP into the nucleus and that glucocorticoid antagonists inhibit this effect. Interestingly, the expression of an hVIP carboxyl-terminal mutant, which is not responsive to Vpr, is also not responsive to dexamethasone. These data illustrate that the carboxyl-terminal domain of hVIP is critical for mediating hVIP-Vpr interaction as well as for its glucocorticoid response. These results support the view that hVIP is a member of the complex array of nucleocytoplasmic shuttling proteins that are regulated by HIV infection and glucocorticoids.