Growth of infectious salmon anaemia virus in CHSE-214 cells and evidence for phenotypic differences between virus strains.
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Infectious salmon anaemia virus (ISAV) is a new orthomyxovirus-like virus. Thirteen isolates of ISAV (11 from Canada, one from Norway and one from Scotland) were studied for their replication in the CHSE-214 cell line compared with that in the SHK-1 cell line. All isolates replicated in SHK-1 cells, producing CPE between 3 and 12 days post-inoculation (p.i.). Six Canadian isolates also replicated in CHSE-214 cells, with production of CPE between 4 and 17 days p.i. Analysis of a one-step growth curve of ISAV in CHSE-214 cells showed that progeny virions remained predominantly cell-associated, accounting for the focalized nature of the CPE in the cell monolayer. One isolate (HKS 36) replicated in CHSE-214 cells, as shown by positive RT-PCR results of blind passages, but was non-cytopathic. All of the isolates were analysed for genetic heterogeneity by RT-PCR and RFLP with EcoRI and XhoI in a fraction of genome segment 2. The Canadian isolates showed a different RFLP profile to those of isolates Glesvaer/2/90 from Norway and 390/98 from Scotland. Structural proteins of four isolates, 'Back Bay 98', RPC/NB-877, RPC/NB-049 and Glesvaer/2/90, were examined further by SDS-PAGE. All viruses showed four major polypeptides, designated here as VP1-VP4, in Coomassie blue-stained gels. In isolates Glesvaer/2/90 and RPC/NB-877, these viral proteins had estimated molecular masses of 74, 53, 46 and 26.5 kDa, respectively. Viral proteins in isolates 'Back Bay 98' and RPC/NB-049 were of similar sizes, except that VP3 was 43 kDa. Taken together, these results show that there are phenotypic differences among strains of ISAV. (+info)
Complete genomic RNA sequence of western equine encephalitis virus and expression of the structural genes.
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The complete nucleotide sequence of the 71V-1658 strain of western equine encephalitis virus (WEE) was determined (minus 25 nucleotides from the 5' end). A 5' RACE reaction was used to sequence the 5' terminus from WEE strain CBA87. The deduced WEE genome was 11508 nucleotides in length, excluding the 5' cap nucleotide and 3' poly(A) tail. The nucleotide composition was 28% A, 25% C, 25% G and 22% U. Comparison with partial WEE sequences of strain 5614 (nsP2-nsP3 of the nonstructural region) and strain BFS1703 (26S structural region) revealed comparatively little variation; a total of 149 nucleotide differences in 8624 bases (1.7% divergence), of which only 28% (42 nucleotides) altered the encoded amino acids. Comparison of deduced nsP1 and nsP4 amino acid sequences from WEE with the corresponding proteins from eastern equine encephalitis virus (EEE) yielded identities of 84.9 and 83.8%, respectively. Previously uncharacterized stem-loop structures were identified in the nontranslated terminal regions. A cDNA clone of the 26S region encoding the structural polyprotein of WEE strain 71V-1658 was placed under the control of a cytomegalovirus promoter and transfected into tissue culture cells. The viral envelope proteins were functionally expressed in tissue culture, as determined by histochemical staining with monoclonal antibodies that recognize WEE antigens, thus, forming the initial step in the investigation of subunit vaccines to WEE. (+info)
Interactions in vivo between the proteins of infectious bursal disease virus: capsid protein VP3 interacts with the RNA-dependent RNA polymerase, VP1.
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Little is known about the intermolecular interactions between the viral proteins of infectious bursal disease virus (IBDV). By using the yeast two-hybrid system, which allows the detection of protein-protein interactions in vivo, all possible interactions were tested by fusing the viral proteins to the LexA DNA-binding domain and the B42 transactivation domain. A heterologous interaction between VP1 and VP3, and homologous interactions of pVP2, VP3, VP5 and possibly VP1, were found by co-expression of the fusion proteins in Saccharomyces cerevisiae. The presence of the VP1-VP3 complex in IBDV-infected cells was confirmed by co-immunoprecipitation studies. Kinetic analyses showed that the complex of VP1 and VP3 is formed in the cytoplasm and eventually is released into the cell-culture medium, indicating that VP1-VP3 complexes are present in mature virions. In IBDV-infected cells, VP1 was present in two forms of 90 and 95 kDa. Whereas VP3 initially interacted with both the 90 and 95 kDa proteins, later it interacted exclusively with the 95 kDa protein both in infected cells and in the culture supernatant. These results suggest that the VP1-VP3 complex is involved in replication and packaging of the IBDV genome. (+info)
Emergence of porcine reproductive and respiratory syndrome virus deletion mutants: correlation with the porcine antibody response to a hypervariable site in the ORF 3 structural glycoprotein.
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By using porcine immune sera to select a library of phage-displayed random peptides, we identified an antigenic sequence (RKASLSTS) in the C-terminus of the ORF 3 structural glycoprotein of European-type porcine reproductive and respiratory syndrome virus (PRRSV). Through the use of overlapping reading frames, the same PRRSV genetic locus codes for the ORF 3 "RKASLSTS" sequence, and a previously described ORF 4 epitope (Meulenberg, J. J. M., Van Nieuwstadt, A. P., Van Essen-Zandbergen, A., and Langeveld, J. P. M., 1997, J. Virol. 71, 6061-6067). Sequence analysis identified naturally occurring deletion mutants at this ORF 34 site. Phylogenetic analysis showed the presence of a highly accurate ORF 3 molecular clock, according to which deletion mutants and nondeleted viruses evolved at differing speeds. Furthermore, deletion mutants and nondeleted viruses evolved as separate lineages. These distinctions suggested that deletion mutants were a hitherto unrecognized subtype of European-type PRRSV. Currently, deletion mutants appear to be outcompeting nondeleted viruses in the field, highlighting the importance of the porcine antibody response against the minor structural glycoproteins of European-type PRRSV for viral evolution. (+info)
Cytoplasm-to-nucleus translocation of a herpesvirus tegument protein during cell division.
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We have previously shown that the herpes simplex virus tegument protein VP22 localizes predominantly to the cytoplasm of expressing cells. We have also shown that VP22 has the unusual property of intercellular spread, which involves the movement of VP22 from the cytoplasm of these expressing cells into the nuclei of nonexpressing cells. Thus, VP22 can localize in two distinct subcellular patterns. By utilizing time-lapse confocal microscopy of live cells expressing a green fluorescent protein-tagged protein, we now report in detail the intracellular trafficking properties of VP22 in expressing cells, as opposed to the intercellular trafficking of VP22 between expressing and nonexpressing cells. Our results show that during interphase VP22 appears to be targeted exclusively to the cytoplasm of the expressing cell. However, at the early stages of mitosis VP22 translocates from the cytoplasm to the nucleus, where it immediately binds to the condensing cellular chromatin and remains bound there through all stages of mitosis and chromatin decondensation into the G(1) stage of the next cycle. Hence, in VP22-expressing cells the subcellular localization of the protein is regulated by the cell cycle such that initially cytoplasmic protein becomes nuclear during cell division, resulting in a gradual increase over time in the number of nuclear VP22-expressing cells. Importantly, we demonstrate that this process is a feature not only of VP22 expressed in isolation but also of VP22 expressed during virus infection. Thus, VP22 utilizes an unusual pathway for nuclear targeting in cells expressing the protein which differs from the nuclear targeting pathway used during intercellular trafficking. (+info)
RANTES binding and down-regulation by a novel human herpesvirus-6 beta chemokine receptor.
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The human herpesvirus 6 (HHV-6) U51 gene defines a new family of betaherpesvirus-specific genes encoding multiple transmembrane glycoproteins with similarity to G protein-coupled receptors, in particular, human chemokine receptors. These are distinct from the HHV-6 U12 and HCMV US28 family. In vitro transcription and translation as well as transient cellular expression of U51 showed properties of a multiple transmembrane protein with a 30-kDa monomer as well as high m.w. aggregates or oligomers. Transient cellularly expressed U51 also appeared to form dimeric intermediates. Despite having only limited sequence similarity to chemokine receptors, U51 stably expressed in cell lines showed specific binding of the CC chemokine RANTES and competitive binding with other beta chemokines, such as eotaxin; monocyte chemoattractant protein 1, 3, and 4; as well as the HHV-8 chemokine vMIPII. In epithelial cells already secreting RANTES, U51 expression resulted in specific transcriptional down-regulation. This correlated with reduced secretion of RANTES protein into the culture supernatants. Regulation of RANTES levels may alter selective recruitment of circulating inflammatory cells that the virus can infect and thus could mediate the systemic spread of the virus from initial sites of infection in epithelia. Alternatively, chemokine regulation could modulate a protective inflammatory response to aid the spread of virus by immune evasion. Such mimicry, by viral proteins, of host receptors leading to down-regulation of chemokine expression is a novel immunomodulatory mechanism. (+info)
Characterization of an overexpressed spindle protein during a baculovirus infection.
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The nucleopolyhedrovirus CfDEFNPV contains a gene encoding a viral protein, which accumulates as bipyramidal inclusion bodies (spindles) in the cytoplasm of infected cells. The spindles appear as early as 24 h postinfection, approximately 1 day earlier than viral occlusion bodies (OBs). Purification and characterization of the spindle protein was complicated by the fact that the OBs copurified with the spindles. We therefore modified CfDEFNPV by replacing the polyhedrin gene (plh) with a cassette containing the green fluorescent protein (GFP) gene. The recombinant virus did not produce OBs; however, the synthesis and morphogenesis of the spindles were not altered. When analyzed by SDS-PAGE, the spindles produced a 50-kDa protein, which was termed spindlin. Tunicamycin inhibition and endoglycosidase studies showed that spindlin was glycosylated. The N-terminus of spindlin was sequenced and its gene (gp50) was located on the viral genome. The gene was cloned and sequenced. Homologs of gp50 were found in several baculoviruses as well as in entomopoxviruses (EPV). In the latter virus, the homologous gene is that of fusolin, which also encodes a protein that forms spindle-shaped inclusion bodies in the cytoplasm of infected cells. Immunoblot analysis indicated that spindlin and fusolin were not serologically related, even though they share conserved polypeptide domains. Sequence analysis showed that gp50 of CfDEFNPV contains two late promoter motifs (TTAAG) in its 5' flanking region. Both were used, but the proximal motif (-14 to -18 nt relative to the ATG) was the primary sequence from which most of the mRNA was initiated. When gp50 was cloned in a heterologous baculovirus expression system, spindlin was synthesized, although the spindles were irregular in shape. This suggested that the spindle structure may be species-specific or it may require more than one gene product for its morphogenesis. (+info)
Genetic analysis of the cell-to-cell movement of beet yellows closterovirus.
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A beet yellows closterovirus (BYV) variant expressing green fluorescent protein and leaves of BYV local lesion host Claytonia perfoliata were used to reveal genetic requirements for BYV cell-to-cell movement in leaf epidermis and mesophyll. A series of mutations targeting genes that are not involved in amplification of the viral positive-strand RNA was analyzed. The products of genes coding for a 6-kDa hydrophobic protein (p6) and a 64-kDa protein (p64), as well as for minor and major capsid proteins, were found to be essential for intercellular translocation of BYV. In a previous work, we have demonstrated that the BYV HSP70-homolog (HSP70h) also plays a critical role in viral movement (V. V. Peremyslov, Y. Hagiwara, and V. V. Dolja, 1999, Proc. Natl. Acad. Sci. USA, 96, 14771-14776). Altogether, a unique protein quintet including three dedicated movement proteins (p6, p64, and HSP70h) and two structural proteins is required to potentiate the cell-to-cell movement of a closterovirus. The corresponding BYV genes are clustered in a block that is conserved among diverse representatives of the family Closteroviridae. (+info)