The 19-kDa capsid protein (CP) of Soil-borne wheat mosaic furovirus (SBWMV) is encoded in the 5'-terminal region of RNA2. In addition to CP, two CP-related proteins are translated from SBWMV RNA2: (1) a 24-kDa protein (N-CP) with an N-terminal 40-amino-acid extension initiated at an upstream in-frame CUG codon; and (2) an 83-kDa protein (CP-RT) with an about 580-amino-acid, C-terminal extension by partial translational readthrough at the UGA termination codon at the end of the CP gene. We examined requirements for N-CP and CP-RT on virion formation and systemic infection in wheat plants using full-length cDNA clones, from which infectious RNA can be transcribed in vitro. RNA2 mutants, which could not synthesize N-CP, CP-RT, or either infected wheat plants systemically in combination with the wild-type RNA1 transcripts, produced rod-shaped virus particles in uninoculated upper leaves. Original mutations which abolished translation of N-CP and CP-RT were confirmed on RNA2 extracted from purified virus from the upper leaves by nucleotide sequence analysis. These results indicate that neither N-terminal nor C-terminal extensions to the CP are required for virion formation and systemic infection of SBWMV in wheat plants.
The appearance of de novo deletion mutations in the readthrough (RT) region (nucleotide positions 861-2591) downstream of the capsid protein (CP) gene of a Japanese strain of Soil-borne wheat mosaic virus RNA2 was examined using infectious transcripts. Mutant RNA2s with different deletions predominated in independent serial passage experiments but all best-adapted mutants retained the 3'-terminal portion of the RT gene in frame with the CP gene. The longest best-adapted mutation deleted the 1434 nucleotides between positions 1061 and 2494. When the RT protein was truncated by insertion of a termination codon plus an additional nucleotide to give a +1 frame-shift, after serial passages the progeny viruses regained the ability to express the C-terminal region of RT by an internal deletion. The 5' terminus of the p19 subgenomic RNA was identified at position 2598 and an essential transcription signal for this mRNA mapped between positions 2534 and 2563. A mutant in which this essential promoter element has been deleted cannot transcribe the p19 subgenomic RNA and has lost infectivity in planta. These results indicate that the 3'-terminal region of the RT gene has a major function in cis for expression of p19, which is essential for infecting plants. A reason for retaining the RT C-terminal region in stable deletion mutants is still unknown.
Soil-borne wheat mosaic virus (SBWMV), the type species of the genus Furovirus, has a plus-sense bipartite RNA genome. Japanese and US strains of SBWMV are genetically distantly related, despite their biologically identical properties. Here we report formation of a pseudorecombinant virus consisting of RNA1 from a Japanese strain and RNA2 from a US strain, using infectious in vitro transcripts for both strains. Full-length infectious cDNA clones for a Japanese strain were previously constructed (Yamamiya and Shirako [38]). For RNA1 of a US strain, due to instability of full-length cDNA clones in Escherichia coli cells, it was necessary to prepare a full-length template DNA for in vitro transcription by combining overlapping 5'-terminal and 3'-terminal cDNAs individually cloned in two plasmids, whereas for RNA2 a full-length cDNA clone was the template. For infectivity assays, Chenopodium quinoa, a local lesion host, and wheat, a systemic host, were used. A mixture of Japanese RNA1 transcripts and US RNA2 transcripts caused formation of local lesions on C. quinoa leaves and systemic infection to wheat plants. The nucleotide sequence of the progeny viral RNA2 was identical to that of the US RNA2. The reciprocal combination was not infectious to either host. These results confirm that the Japanese and US SBWMV are genetically distantly related strains belonging to a single species.
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