Interactions between tombusviruses and satellite RNAs of tomato bushy stunt virus: a defect in sat RNA B1 replication maps to ORF1 of a helper virus.

The biological properties of two recently described satellite RNAs of tomato bushy stunt virus (TBSV) were analyzed in natural and experimental hosts. Full-length cDNA clones were constructed for sat RNAs B1(822 nt) and B10 (612 nt) and used in inoculations with satellite-free transcripts of different tombusviruses. In all virus-host combinations tested, TBSV sat RNA B10 drastically reduced the accumulation of viral genomic RNA and attenuated symptoms. In contrast, sat RNA B1 caused a less marked reduction of viral RNA level and did not have any effect on symptoms. Experiments with Nicotiana benthamiana protoplasts showed that the differential effects of sat RNAs B1 and B10 on TBSV titer were related to differential abilities to interfere with virus replication. Three tombusviruses tested were able to maintain both sat RNAs in N. benthamiana plants, although carnation Italian ringspot virus (CIRV) was a poor helper for sat RNA B1. Using chimeric viruses, a strong determinant for low sat RNA B1 accumulation was mapped to the 5'-terminal part of the genome of CIRV. The poor helper activity of CIRV was shown to be due to low sat RNA B1 replication. A single-nucleotide mutation in the start codon of CIRV ORF1 restored the ability to replicate sat RNA B1 to high levels. This mutant encodes an ORF1 that is 22 amino acids shorter at the N-terminus than the wild-type virus.

New satellite RNAs, but no DI RNAs, are found in natural populations of tomato bushy stunt tombusvirus.

A collection of 57 field isolates of the tombusvirus tomato bushy stunt virus was obtained from eggplant and tomato during 1994-1997 and was examined for the presence of defective interfering (DI) RNA species by Northern blot hybridization and RT-PCR. No DI RNA species were detected associated with any of the field TBSV isolates. However, serial passaging of two field isolates in Nicotiana clevelandii at high multiplicity of infection resulted in the rapid generation of DI-like RNA species, indicating that the absence of DI RNAs in natural populations of the virus was not due to the inability of the TBSV field isolates to generate them in a suitable host. The results indicate that DI RNAs may not play a role in modulating natural TBSV infections in the hosts examined. In 4 of 57 isolates analyzed we have detected less than full-length RNAs and we show here that they are true satellite RNAs. Two different satellite RNA species were detected, named TBSV sat RNAs B1 (822 nt) and B10 (612 nt). TBSV sat RNAs lack significant open reading frames and do not present sequence homology except in a central box that is also conserved in TBSV-Ch genomic RNA and in all the DI RNAs derived from it. TBSV sat RNA B10 attenuated the symptoms induced by the helper virus in N. clevelandii while sat RNA B1 did not modify the symptoms. This is the first report of sat RNAs associated with TBSV and the first time that sat RNAs are associated with natural tombusvirus infections.