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. 1996 Feb;70(2):763–770. doi: 10.1128/jvi.70.2.763-770.1996

Infectious RNA transcribed from an engineered full-length cDNA template of the genome of a pestivirus.

R J Moormann 1, H G van Gennip 1, G K Miedema 1, M M Hulst 1, P A van Rijn 1
PMCID: PMC189877  PMID: 8551613

Abstract

Infectious RNA was transcribed for the first time from a full-length cDNA template of the plus-strand RNA genome of a pestivirus. The genome of the C strain, which is a vaccine strain of classical swine fever virus, was sequenced and used to synthesize the template. The cDNA sequence of the C strain was found to be 12,311 nucleotides in length and contained one large open reading frame encoding a polyprotein of 3,898 amino acids. Although there were mostly only small differences between the sequence of the C strain and the published sequences of strains Alfort and Brescia, there was one notable insertion of 13 nucleotides, TTTTCTTTTTTTT, in the 3' noncoding region of the C strain. Furthermore, we showed that the sequences at the 5' and 3' termini of the C strain are highly conserved among pestiviruses. We found that the infectivity of the in vitro transcripts of DNA copies pPRKflc-113 and pPRKflc-133 depended on the correctness of the nucleotide sequence. The in vitro transcripts of pPRKflc-133 were infectious, whereas those of pPRKflc-113 were not. In fact, only 5 amino acids among the complete amino acid sequence determined this difference in infectivity. However, virus FLc-133, which was generated from pPRKflc-133, cannot be differentiated from native C-strain virus. Therefore, we exchanged the region encoding the antigenic N-terminal half of envelope protein E2 in pPRKflc-133 with the equivalent region of strain Brescia. The resulting hybrid virus, FLc-h6, could be differentiated from the C strain and from FLc-133 with monoclonal antibodies directed against envelope proteins Erns and E2 of strain Brescia and the C strain. To be suitable for further vaccine development, viruses generated from pPRKflc-133 should grow at least as well as native C-strain virus. In fact, we found that FLc-133, hybrid virus FLc-h6, and the C strain grew equally well. We concluded that pPRKflc-133 is an excellent tool for developing a classical swine fever marker vaccine and may prove valuable for studying the replication, virulence, cell and host tropism, and pathogenesis of classical swine fever virus.

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Selected References

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