Rescue of the prototypic Arenavirus LCMV entirely from plasmid

We document a helper-independent reverse genetics system for rescuing infectious arenaviruses from cloned cDNAs. We constructed plasmids containing full-length cDNAs of the antigenomic (ag) L and S segments of the Armstrong (ARM) strain of the prototypic Arenavirus lymphocytic choriomeningitis virus (LCMV) flanked at their 5'- and 3'-termini by the T7 RNA polymerase (T7RP) promoter and ribozyme sequences, respectively. These plasmids directed intracellular synthesis of viral L and S ag RNA species in cells expressing plasmid-supplied T7RP. Co-expression of plasmid-supplied LCMV trans-acting factors, nucleoprotein (NP) and polymerase (L), resulted in replication and expression of L and S ag and genome RNA species, and generation of LCMV infectious progeny termed rT7/LCMV. The recombinant rT7/LCMV was unequivocally identified based on a genetic tag introduced in the recombinant S segment. In addition, rT7/LCMV exhibited growth and biological properties predicted for an ARM-like LCMV. To our knowledge, this is the first documented Arenavirus rescue, as well as of an ambisense negative strand (NS) RNA virus, entirely from cloned cDNAs. Our results extend the use of reverse genetic approaches for DNA-mediated virus rescue to all known virus families with NS RNA genome.     

Infectious RNA transcripts from Ross River virus cDNA clones and the construction and characterization of defined chimeras with Sindbis virus.

We have constructed a full-length cDNA clone of the virulent T48 strain of Ross River virus, a member of the alphavirus genus. Infectious RNA can be transcribed from this clone using SP6 or T7 RNA polymerase. The rescued virus has properties indistinguishable from those of the T48 strain of Ross River virus. We have used this clone, together with a full-length cDNA clone of Sindbis virus, to construct chimeric plasmids in which the 5' and the 3' nontranslated regions of the Sindbis and Ross River genomes were exchanged. The nontranslated regions of the two viral genomes differ in both size and sequence although they maintain specific conserved sequence elements. Virus was recovered from all four chimeras. Chimeras containing heterologous 3' nontranslated regions had replicative efficiencies equal to those of the parents. In contrast, the chimeras containing heterologous 5' nontranslated regions were defective in RNA synthesis and virus production, and the severity of the defect was dependent upon the host. Replication of a virus containing a heterologous 5' nontranslated region may be inefficient due to the formation of defective protein-RNA complexes, whereas, the presumptive complexes formed between host or virus proteins and the 3' nontranslated region to promote RNA synthesis appear to function normally in the chimeras.     

Alfalfa mosaic virus temperature-sensitive mutants. V. The nucleotide sequence of TBTS 7 RNA 3 shows limited nucleotide changes and evidence for heterologous recombination

Nucleotide sequence determination of the coat protein cistron of the alfalfa mosaic virus (AIMV) temperature-sensitive mutant, Tbts 7 (uv) revealed a small number of point mutations of which only one results in the replacement of an amino acid: the asparagine residue at position 126 is replaced by an aspartate residue. RNA transcribed in vitro from a Tbts 7 cDNA 4 clone directed the production in vitro of a polypeptide which shows the same altered electrophoretic mobility in SDS-polyacrylamide gels as the Tbts 7 coat protein. Nucleotide sequence analysis of the 32-kDa open reading frame revealed some base changes, but none of these lead to changes in the primary structure of the protein. The 5'-terminal sequence of Tbts 7 RNA 3 was analyzed by cDNA cloning. At least three different types of nontranslated leader sequences were found, indicating considerable heterogeneity at the 5' end of the mutant RNA 3. The results indicated that the low abundance of RNA 3-containing particles in Tbts 7 virus preparations might be due to malfunctioning of the 5' terminus of Tbts 7 RNA 3 during replication.     

Recovery of infectious classical swine fever virus (CSFV) from full-length genomic cDNA clones by a swine kidney cell line expressing bacteriophage T7 RNA polymerase

A new method for the recovery of infectious classical swine fever virus (CSFV) from full-length genomic cDNA clones of the C-strain was developed. Classical reverse genetics is based on transfection of in vitro transcribed RNA to target cells to recover RNA viruses. However, the specific infectivity of such in vitro transcribed RNA in swine kidney cells is usually low. To improve reverse genetics for CSFV, a stable swine kidney cell line was established that expresses cytoplasmic bacteriophage T7 RNA polymerase (SK6.T7). A 200-fold increased virus titre was obtained from SK6.T7 cells transfected with linearized full-length cDNA compared to in vitro transcribed RNA, whereas transfection of circular full-length cDNA resulted in 20-fold increased virus titres. Viruses generated on the SK6.T7 cells are indistinguishable from the viruses generated by the classical reverse genetic procedures. These results show the improved recovery of infectious CSFV directly from full-length cDNAs. Furthermore, the reverse genetic procedures are simplified to a faster, one step protocol. We conclude that the SK6.T7 cell line will be a valuable tool for recovering mutant CSFV and will contribute to future pestivirus research.     

Recovery of duck hepatitis A virus 3 from a stable full-length infectious cDNA clone

Recently, duck hepatitis A virus 3 (DHAV-3) with genetically distinct characteristics from DHAV-1 and DHAV-2 was recognized in South Korea and China. In this short communication, we successfully constructed a stable full-length infectious cDNA clone derived from DHAV-3 by solving instability of cloned full-length cDNA in Escherichia coli (E. coli). The cDNA fragments amplified from the genome of DHAV-3 were assembled and inserted into a low-copy-number plasmid. Finally, a full-length cDNA clone containing an engineered SacII site that served as a genetic marker was obtained. The cDNA clone showed stable by serial passages in E. coli when propagated at 25°C under low level of antibiotic selection. BHK-21 cells were transfected with transcribed RNA from the full-length cDNA clone; infectious viral particles were rescued, showing its fatality to 10-day-old duck embryos. The results indicated that the constructed full-length cDNA clone of DHAV-3 is infectious. By various virological assays, our results indicated that the rescued virus exhibited similar biological properties with the parental virus. Animal experiments revealed that the rescued virus retained the high pathogenicity to 1-day-old ducklings and could induce a fatal hepatitis indistinguishable from its parental virus. Our present studies provide a useful tool for future research on genomic functions and molecular pathogenesis of DHAV-3.     

Initiation of Sendai virus multiplication from transfected cDNA or RNA with negative or positive sense

Background: The mononegavirus superfamily (Mononegavirales) comprises three families, Rhabdoviridae, Paramyxoviridae and Filoviridae. These viruses possess a single stranded negative sense RNA as the genome. Recent success in the recovery of infectious virus from a transfected cDNA of mononegaviruses including Sendai virus, a prototypic paramyxovirus, is opening the possibility of their genetic engineering. However, infectious viruses have been recovered only by initiating the infectious cycle with cDNA directing the synthesis of antigenomic positive sense (+) RNA. Starting with genomic negative sense (?) RNA has been unsuccessful. Furthermore, the recovery efficiency has often been extremely low. Results: We describe here an analogous system that allows recovery of Sendai virus at a high rate, from cells in which the transfected cDNA and plasmids to support the synthesis of viral nucleocapsid protein and RNA polymerases are coexpressed by vaccinia virus-driven bacteriophage T7 polymerase. Our system was able to recover the virus from cDNA directing not only (+)RNA but also (?)RNA. Moreover, using this system, we succeeded in recovery of the virus by transfection of in vitro synthesized (+)RNA or (?)RNA. This improved virus recovery appeared to be accomplished by supplying the supporting plasmids at an optimal ratio and by minimizing the cytopathic effect of the vaccinia virus by specific inhibitors. In addition, it was probably critical that our cDNAs were constructed to generate viral authentic RNAs without adding T7 promoter-specific nucleotides to the 5′ ends. An immediate application of the system was demonstrated by the creation of a candidate vaccine strain with a predetermined attenuating mutation in the cleavage-activation site of the viral fusion glycoprotein. Conclusion: We have established methods which greatly improve the recovery of Sendai virus from cDNA. There is essentially no absolute obstacle to recovery of the virus from the (?)RNA template. Even the complete full length RNA chain in the naked form appears to be properly encapsidated to become a functional template.     

A simple method for developing an infectious cDNA clone of Japanese encephalitis virus

Flavivirus cDNA clones frequently demonstrate genetic instability in transformed bacteria, which hampers the construction and manipulation of cDNAs for infectious flaviviruses. In this study, we developed a stable, full-length cDNA clone, pJEHEN, of a GI JEV strain HEN0701 using a medium-copy-number pBR322 vector and propagating cDNA clones at room temperature. The virus vJEHEN recovered from the infectious clone was indistinguishable from the parent virus HEN0701 with respect to plaque morphology, growth kinetics, and virulence characteristics. A T-to-A silent mutation of nucleotide 24 of the NS2a gene was introduced into the infectious cDNA clone to eliminate frameshifting. The rescued mutant virus vJETA did not express NS1′ in infected cells and showed reduced growth and neurovirulence in mice. This convenient method for the construction and manipulation of infectious JEV cDNA clones may be of use in further studies to improve our understanding of the molecular mechanisms responsible for JEV replication and pathogenesis.