Cucumber mosaic virus Isolates from Greek Legumes are Associated with Satellite RNAs that are Necrogenic for Tomato.

Worldwide, Cucumber mosaic virus (CMV) is the causal agent of many economically important diseases. Based on immunological or molecular analysis, three distinct subgroups of CMV isolates can be identified (IA, IB, and II). In addition, some CMV isolates are associated with satellite RNAs (satRNAs), a type of noncoding transcript that may alter the symptoms of CMV infections. This study presents an analysis of CMV isolates occurring in legumes in Greece in respect to their genetic diversity, and the presence and diversity of their satRNA. Phylogenetic analysis of the CMV coat protein sequence of 18 legume and 5 tomato CMV isolates collected throughout Greece classified them within subgroups IA and IB, with a limited genetic diversity. The CMV satRNAs found in nine field legumes exhibiting mild symptoms and in one tomato with a necrotic syndrome contained a functional necrogenic motif; therefore, they were grouped within the necrogenic group of CMV-satRNAs. The necrotic phenotype was expressed in all legume CMV isolates containing necrogenic satRNAs when mechanically inoculated onto tomato plants. To our knowledge, this is the first observation that legumes host necrogenic CMV-satRNAs. The possible role of legumes in the epidemiology of CMV and necrogenic satRNA complex is discussed.

The presence of high-molecular-weight viral RNAs interferes with the detection of viral small RNAs.

Viral small interfering RNA (siRNA) accumulation in plants is reported to exhibit a strong strand polarity bias, with plus (+) strand siRNAs dominating over minus (-) strand populations. This is of particular interest, as siRNAs processed from double-stranded RNA would be expected to accumulate equivalent amounts of both species. Here, we show that, as reported, (-) strand viral siRNAs are detected at much lower levels than (+) strand-derived species using standard Northern hybridization approaches. However, when total RNA is spiked with in vitro-transcribed antisense viral genomic RNA, (-) strand viral siRNAs are detected at increased levels equivalent to those of (+) strand siRNA. Our results suggest that (+) and (-) strand viral siRNAs accumulate to equivalent levels; however, a proportion of the (-) strand siRNAs are sequestered from the total detectable small RNA population during gel electrophoresis by hybridizing to the high-molecular-weight sense strand viral genomic RNA. Our findings provide a plausible explanation for the observed strand bias of viral siRNA accumulation, and could have wider implications in the analysis of both viral and nonviral small RNA accumulation.

Variation analysis of two cucumber mosaic viruses and their associated satellite RNAs from sugar beet in China.

Two cucumber mosaic virus (CMV) isolates XJ1 and XJ2 were obtained from sugar beet showing yellow mosaic symptom in Shihezi, Xinjiang Uigur municipality of China. The coat protein gene of the two CMV isolates and their associated satellite RNAs were amplified by reverse transcriptase polymerase chain reaction (RT-PCR) and were cloned and sequenced. Comparison of CP gene sequences showed that XJ1 and XJ2 have the highest sequence identity with that of CMV-Danshen (97.8%) and CMV-SD (98.7%), respectively. Two types of satellite RNAs (XJs1 and XJs2) were found to be associated with the two CMV isolates consisting of 384 nucleotides and 336 nucleotides, respectively. Sequence comparisons revealed that XJs1 and XJs2 were most closely related to CS2-sat and CS1-sat, respectively, with 98.9% and 98.5% nucleotide sequence identity. Phylogenetic analysis of nucleotide sequence and deduced amino acid sequence of coat protein gene revealed that XJ1 and XJ2 belong to subgroup IB but there exist some variation between them. Parallel analyses of nucleotide sequence of XJsl and XJs2 suggested that these two satellite RNAs probably originated from China.

Structural analysis of a necrogenic strain of cucumber mosaic cucumovirus satellite RNA in planta.

Structural studies of plant viral RNA molecules have been based on in vitro chemical and enzymatic modification. That approach, along with mutational analysis, has proven valuable in predicting structural models for some plant viruses such as tobacco mosaic tobamovirus and brome mosaic bromovirus. However, in planta conditions may be dramatically different from those found in vitro. In this study we analyzed the structure of cucumber mosaic cucumovirus satellite RNA (sat RNA) strain D4 in vivo and compared it to the structures found in vitro and in purified virions. Following a methodology developed to determine the structure of 18S rRNA within intact plant tissues, different patterns of adenosine and cytosine modification were found for D4-sat RNA molecules in vivo, in vitro, and in virions. This chemical probing procedure identifies adenosine and cytosine residues located in unpaired regions of the RNA molecules. Methylation data, a genetic algorithm in the STAR RNA folding program, and sequence alignment comparisons of 78 satellite CMV RNA sequences were used to identify several helical regions located at the 5' and 3' ends of the RNA molecule. Data from previous mutational and sequence comparison studies between satellite RNA strains inducing necrosis in tomato plants and those strains not inducing necrosis allowed us to identify one helix and two tetraloop regions correlating with the necrogenicity syndrome.