The generation of infectious rabies virus (RV), a non‐segmented negative‐stranded RNA virus of the Rhabdoviridae family, entirely from cloned cDNA is described. Simultaneous intracellular expression of genetically marked full‐length RV antigenome‐like T7 RNA polymerase transcripts and RV N, P and L proteins from transfected plasmids resulted in formation of transcriptionally active nucleocapsids and subsequent assembly and budding of infectious rabies virions. In addition to authentic RV, two novel infectious RVs characterized by predicted transcription patterns were recovered from modified cDNA. Deletion of the entire non‐translated pseudogene region, which is conserved in all naturally occurring RVs, did not impair propagation of the resulting virus in cell culture. This indicates that non‐essential genetic material might be present in the genomes of non‐segmented RNA viruses. The introduction of a functional extra cistron border into the genome of another virus resulted in the transcription of an additional polyadenylated mRNA containing pseudogene sequences. The possibility of manipulating the RV genome by recombinant DNA techniques using the described procedure‐‐potentially applicable also for other negative‐stranded viruses‐‐greatly facilitates the investigation of RV genetics, virus‐host interactions and rabies pathogenesis and provides a tool for the design of new generations of live vaccines.
Budding of enveloped viruses from cellular membranes is believed to de pend on the presence of transmembrane spike proteins interacting with cytoplasmic virus components. To address the mechanism of rhabdovirus budding, we generated rabies virus mutants deficient for the glycoprotein G or the G cytoplasmic tail. We found that spikeless rhabdovirus particles were released from cells infected with the G-deficient mutant, demonstrating that a viral surface protein is not required to drive the budding process. However, particle production is enhanced approximately 6-fold and 30-fold in the presence of tailless G or G, respectively. This reveals that G also possesses an intrinsic and independent exocytosis activity. We propose a model according to which efficient budding of rhabdoviruses is achieved by a concerted action of both core and spike proteins.
The isolation, cultivation and characterization of three chicken astroviruses (CAstV) isolates are described. They are antigenically related to each other but unrelated to avian nephritis virus (ANV) and duck hepatitis virus type 2 (DVH2) in neutralization, immunofluorescence and gel diffusion tests. CAstV, ANV and DVH2 all grew well in the LMH cell line, which was used for assay and serological tests. Serological surveys in 1982 and 2001 showed that antibody to CAstV virus was widespread in broiler and broiler breeder flocks and present in some turkey flocks. Infection of 1-day-old specific pathogen free chicks with one isolate in the laboratory resulted in mild diarrhoea and some distention of the small intestine. The virus could be isolated in high titres from all parts of the small intestine but rarely from other organs. Electron microscopic examination of purified particles of this agent revealed the presence of clusters of small round viruses with a diameter ranging from 25 to 30 nm. The amino acid sequence derived from the relatively conserved non-structural polyprotein region of this virus shows 62% identity with the corresponding region of turkey astrovirus 2, 58% identity with turkey astrovirus 1, 55% identity with avian nephritis virus and 33% identity with sheep astroviruses. Taken together, the results indicate that the agent is a new chicken astrovirus belonging to the family Astroviridae.
Newcastle disease virus (NDV)-expressing avian influenza virus (AIV) hemagglutinin (HA) of subtype H5 was constructed by reverse genetics. A cloned full-length copy of the genome of the lentogenic NDV strain Clone 30 was used for insertion of the ORF encoding the HA of the highly pathogenic AIV isolate A͞chicken͞ Italy͞8͞98 (H5N2) in the intergenic region between the NDV fusion and hemagglutinin-neuraminidase (HN) genes. Remarkably, two species of HA transcripts were detected in cells infected with the resultant NDVH5. In a second recombinant (NDVH5m), a NDV transcription termination signal-like sequence located within the HA ORF was eliminated by silent mutations. Consequently, NDVH5m produced 2.7-fold more full-length HA transcripts, expressed higher levels of HA, and also incorporated more HA protein into its envelope than NDVH5. NDVH5m stably expressed the modified HA gene for 10 egg passages and both recombinants were found innocuous after intracerebral inoculation of 1-day-old chickens. Immunization of chickens with NDVH5m induced NDVand AIVH5-specific antibodies and protected chickens against clinical disease after challenge with a lethal dose of velogenic NDV or highly pathogenic AIV, respectively. Remarkably, shedding of influenza virus was not observed. Furthermore, immunization with NDVH5m permitted serological discrimination of vaccinated and AIV field virus-infected animals based on antibodies against the nucleoprotein of AIV. Therefore, recombinant NDVH5m is suitable as a bivalent vaccine against NDV and AIV and may be used as marker vaccine for the control of avian influenza.vaccine ͉ recombinant Newcastle disease virus ͉ reverse genetics ͉ fowl plague
Newcastle disease virus (NDV) edits its P-gene mRNA by inserting a nontemplated G residue(s) at a conserved editing site (3-UUUUUCCC-template strand). In the wild-type virus, three amino-coterminal P-gene-derived proteins, P, V, and W, are produced at frequencies of approximately 68, 29, and 2%, respectively. By applying the reverse genetics technique, editing-defective mutants were generated in cell culture. Compared to the wild-type virus, mutants lacking either six nucleotides of the conserved editing site or the unique C-terminal part of the V protein produced as much as 5,000-fold fewer infectious progeny in vitro or 200,000-fold fewer in 6-day-old embryonated chicken eggs. In addition, both mutants were unable to propagate in 9-to 11-day-old embryonated specific-pathogen-free (SPF) chicken eggs. In contrast, a mutant (NDV-P1) with one nucleotide substitution (UUCUUCCC) grew in eggs, albeit with a 100-fold-lower infectious titer than the parent virus. The modification in the first two mutants described above led to complete abolition of V expression, whereas in NDV-P1 the editing frequency was reduced to less than 2%, and as a result, V was expressed at a 20-fold-lower level. NDV-P1 showed markedly attenuated pathogenicity for SPF chicken embryos, unlike currently available ND vaccine strains. These findings indicate that the V protein of NDV has a dual function, playing a direct role in virus replication as well as serving as a virulence factor. Administration of NDV-P1 to 18-day-old embryonated chicken eggs hardly affected hatchability. Hatched chickens developed high levels of NDV-specific antibodies and were fully protected against lethal challenge, demonstrating the potential use of editing-defective recombinant NDV as a safe embryo vaccine.Newcastle disease virus (NDV) belongs to the genus Rubulavirus within the family Paramyxoviridae. Recent findings, however, have indicated that NDV is only distantly related to other members of the genus Rubulavirus, and it has been suggested that NDV should be assigned to a new genus within the subfamily Paramyxovirinae (6). NDV isolates are further categorized based on pathogenicity for chickens into velogenic, mesogenic, and lentogenic strains corresponding to high-, moderate-, and low-virulence strains, respectively. The molecular basis for this distinction lies mainly in the amino acid sequence of the protease cleavage site of the fusion (F) protein (14, 25). The precursor fusion glycoprotein F0 has to be cleaved into F1 and F2 for the progeny virus to be infectious and to be able to undergo multiple rounds of replication. Recently, experimental evidence for the presence of a direct correlation between the sequence of the cleavage site and NDV virulence was provided by changing the protease cleavage site of a lentogenic strain of NDV (GGRQGR7 L) into the consensus cleavage site of a velogenic strain (GRRQRR7 F). A dramatic increase in virulence of the genetically modified virus indicated that the key determinant for NDV virulence is the cleavage efficiency of t...
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