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J Virol. 1992 May; 66(5): 3069-3076

Coding capacity determines in vivo accumulation of a defective RNA of clover yellow mosaic virus.

Department of Biochemistry, University of Western Ontario, London, Canada.

ABSTRACT

Naturally occurring defective RNAs (D RNAs) derived from the potexvirus clover yellow mosaic virus (CYMV) contain large internal deletions yet maintain a single open reading frame (ORF) representing the in-frame fusion of 5' and 3' terminal ORFs. Capped transcripts of the prototype 1.2-kb D RNA of CYMV were synthesized in vitro and used to inoculate broad bean plants. Progeny D RNA accumulated only if synthetic D RNA transcripts were coinoculated with CYMV RNA. Several experiments showed that helper-dependent accumulation of the D RNA in vivo depended on the maintenance of its encoded fusion ORF. (i) D RNAs with six-residue deletions introduced early in the fusion ORF accumulated, whereas those with four-residue out-of-frame deletions at the same sites were nonviable. (ii) Analysis of D RNAs containing termination codons at different locations showed that only the most 3' stop codon (maintaining over 93% of the fusion ORF) was permissive for D RNA accumulation. (iii) D RNAs with small in-frame deletions and insertions in their 3' coding regions were viable. (iv) Nonviable D RNAs containing disrupted fusion ORFs could not be complemented by the presence in the infection of a D RNA encoding a complete fusion ORF. Taken together, the results indicate that the process of translation, rather than the encoded product, modulates an event(s) which influences the propagation and/or accumulation of this RNA in vivo. This represents a unique requirement among plant virus D RNAs.

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