cis-active sequences near the 5'-termini of beet necrotic yellow vein virus RNAs 3 and 4

Beet Necrotic Yellow Vein Virus Noncoding RNA Production Depends on a 5'→3' Xrn Exoribonuclease Activity

The RNA3 species of the beet necrotic yellow vein virus (BNYVV), a multipartite positive-stranded RNA phytovirus, contains the 'core' nucleotide sequence required for its systemic movement in Beta macrocarpa. Within this 'core' sequence resides a conserved "coremin" motif of 20 nucleotides that is absolutely essential for long-distance movement. RNA3 undergoes processing steps to yield a noncoding RNA3 (ncRNA3) possessing "coremin" at its 5' end, a mandatory element for ncRNA3 accumulation. Expression of wild-type (wt) or mutated RNA3 in Saccharomyces cerevisiae allows for the accumulation of ncRNA3 species. Screening of S.cerevisiae ribonuclease mutants identified the 5'-to-3' exoribonuclease Xrn1 as a key enzyme in RNA3 processing that was recapitulated both in vitro and in insect cell extracts. Xrn1 stalled on ncRNA3-containing RNA substrates in these decay assays in a similar fashion as the flavivirus Xrn1-resistant structure (sfRNA). Substitution of the BNYVV-RNA3 'core' sequence by the sfRNA sequence led to the accumulation of an ncRNA species in yeast in vitro but not in planta and no viral long distance occurred. Interestingly, XRN4 knockdown reduced BNYVV RNA accumulation suggesting a dual role for the ribonuclease in the viral cycle.

Ins and Outs of Multipartite Positive-Strand RNA Plant Viruses: Packaging versus Systemic Spread

Viruses possessing a non-segmented genome require a specific recognition of their nucleic acid to ensure its protection in a capsid. A similar feature exists for viruses having a segmented genome, usually consisting of viral genomic segments joined together into one viral entity. While this appears as a rule for animal viruses, the majority of segmented plant viruses package their genomic segments individually. To ensure a productive infection, all viral particles and thereby all segments have to be present in the same cell. Progression of the virus within the plant requires as well a concerted genome preservation to avoid loss of function. In this review, we will discuss the "life aspects" of chosen phytoviruses and argue for the existence of RNA-RNA interactions that drive the preservation of viral genome integrity while the virus progresses in the plant.

Beet necrotic yellow vein virus subgenomic RNA3 is a cleavage product leading to stable non-coding RNA required for long-distance movement

Beet necrotic yellow vein virus (BNYVV) is a multipartite RNA virus. BNYVV RNA3 does not accumulate in non-host transgenic Arabidopsis thaliana plants when expressed using a 35S promoter. However, a 3'-derivative species has been detected in transgenic plants and in transient expression assays conducted in Nicotiana benthamiana and Beta macrocarpa. The 3'-derivative species is similar to the previously reported subgenomic RNA3 produced during virus infection. 5' RACE revealed that the truncated forms had identical 5' ends. The 5' termini carried the coremin motif also present on BNYVV RNA5, beet soil-borne mosaic virus RNA3 and 4, and cucumber mosaic virus group 2 RNAs. This RNA3 species lacks a m(7)Gppp at the 5' end of the cleavage products, whether expressed transiently or virally. Mutagenesis revealed the importance of the coremin sequence for both long-distance movement and stabilization of the cleavage product in vivo and in vitro. The isolation of various RNA3 5'-end products suggests the existence of a cleavage between nt 212 and 1234 and subsequent exonucleolytic degradation, leading to the accumulation of a non-coding RNA. When RNA3 was incubated in wheatgerm extracts, truncated forms appeared rapidly and their appearance was protein- and divalent ion-dependent.

Beet soil-borne mosaic virus RNA-3 is replicated and encapsidated in the presence of BNYVV RNA-1 and -2 and allows long distance movement in Beta macrocarpa

Beet soil-borne mosaic virus (BSBMV) and Beet necrotic yellow vein virus (BNYVV) belong to the Benyvirus genus. BSBMV has been reported only in the United States, while BNYVV has a worldwide distribution. Both viruses are vectored by Polymyxa betae and possess similar host ranges, particle number and morphology. BNYVV and BSBMV are not serologically related but they have similar genomic organizations. Field isolates usually consist of four RNA species but some BNYVV isolates contain a fifth RNA. RNAs 1 and 2 are essential for infection and replication while RNAs 3 and 4 play important roles in plant and vector interactions, respectively. Nucleotide and amino acid analyses revealed that BSBMV and BNYVV are sufficiently different to be classified as two species. Complementary base changes found within the BSBMV RNA-3 5' UTR made it resemble to BNYVV 5' RNA-3 structure whereas the 3' UTRs of both species were more conserved. cDNA clones were obtained, and allowed complete copies of BSBMV RNA-3 to be trans-replicated, trans-encapsidated by the BNYVV viral machinery. Long-distance movement was observed indicating that BSBMV RNA-3 could substitute BNYVV RNA-3 for systemic spread, even though the p29 encoded by BSBMV RNA-3 is much closer to the RNA-5-encoded p26 than to BNYVV RNA-3-encoded p25. Competition occurred when BSBMV RNA-3-derived replicons were used together with BNYVV-derived RNA-3 but not when the RNA-5-derived component was used. Exploitation of the similarities and divergences between BSBMV and BNYVV should lead to a better understanding of molecular interactions between Benyviruses and their hosts.

Use of a Beet necrotic yellow vein virus RNA-5-derived replicon as a new tool for gene expression

A new gene-expression system based on RNA-5 of Beet necrotic yellow vein virus (BNYVV) was constructed to allow the expression of recombinant proteins in virally infected cells. Replication and expression levels of the RNA-5-based replicon containing the green fluorescence protein (GFP) gene were compared with those obtained with the well-characterized RNA-3-derived replicon (Rep-3). When RNA-3 and/or RNA-4 BNYVV RNAs were added to the inoculum, the expression levels of RNA-5-encoded GFP were considerably reduced. To a lesser extent, RNA-3-derived GFP expression was also affected by the presence of RNA-4 and -5. Both RNA-3- and RNA-5-derived molecules were able to express proteins within the same infected cells. Together with Rep-3, the RNA-5-derived replicon thus provides a new tool for the co-expression of different recombinant proteins. In Beta macrocarpa, Rep-5-GFP was able to move in systemic tissues in the presence of RNA-3 and thus provides a new expression system that is not restricted to the inoculated leaves.

Comparison of the beet necrotic yellow vein virus P75 nucleotide sequences of Belgian type A and type B sources

RNA-2 P75 open reading frame sequencing was conducted on BNYVV-infected sugar beet plants originating from 10 Belgian sources and was compared with sequences originating from France, Kazakhstan, Japan and China. This allowed the characterization of types A and B in Belgium. Sequence analysis confirmed that type A is intermediate between types P and B. The analysis of nucleotide sequences of the capsid protein epitopes and of different motifs involved in the transmission of the virus to the plant by Polymyxa betae reveals that they are well conserved among the different sequences analysed. In silico analysis showed that a potential dimerization/dsRNA-binding domain is present on P75. Finally, in order to compare the different BNYVV types, a real-time quantitative (RT)-PCR targeting the readthrough domain of P75 was developed and assessed over a period of 40 days on BNYVV susceptible sugar beet cv. Cadyx.

Cell-to-cell movement of beet necrotic yellow vein virus: I. Heterologous complementation experiments provide evidence for specific interactions among the triple gene block proteins

Cell-to-cell movement of beet necrotic yellow vein virus (BNYVV) requires three proteins encoded by a triple gene block (TGB) on viral RNA 2. A BNYVV RNA 3-derived replicon was used to express movement proteins to functionally substitute for the BNYVV TGB proteins was tested by coinoculation of TGB-defective BNYVV with the various replicons to Chenopodium quinoa. Trans-heterocomplementation was successful with the movement protein (P30) of tobacco mosaic virus but not with the tubule-forming movement proteins of alfalfa mosaic virus and grapevine fanleaf virus. Trans-complementation of BNYVV movement was also observed when all three TGB proteins of the distantly related peanut clump virus were supplied together but not when they were substituted for their BNYVV counterparts one by one. When P30 was used to drive BNYVV movement in trans, accumulation of the first TGB protein of BNYVV was adversely affected by null mutations in the second and third TGB proteins. Taken together, these results suggest that highly specific interactions among cognate TGB proteins are important for their function and/or stability in planta.

Conformation of the 3'-end of beet necrotic yellow vein benevirus RNA 3 analysed by chemical and enzymatic probing and mutagenesis

Secondary structure-sensitive chemical and enzymatic probes have been used to produce a model for the folding of the last 68 residues of the 3'-non-coding region of beet necrotic yellow vein benevirus RNA 3. The structure consists of two stem-loops separated by a single-stranded region. RNA 3-derived transcripts were produced containing mutations which either disrupted base pairing in the helices or maintained the helices but with alterations in the base pairing scheme. Other mutants contained substitutions in single-stranded regions (loops or bulged sequences). With a few exceptions all three types of mutation abolished RNA 3 replication in vivo, suggesting that both secondary structure and specific sequences are required for efficient recognition of the 3'-terminal region of RNA 3 by viral RNA-dependent RNA polymerase.

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.

Long sequences in the 5' noncoding region of plum pox virus are not necessary for viral infectivity but contribute to viral competitiveness and pathogenesis

The 5'-terminal 31 nucleotides of the 146-nucleotides-long 5' noncoding region of plum pox potyvirus (PPV) are highly conserved in all the members of the Potyvirus genus. To map the sequences of the 5' noncoding region that are necessary in vivo for infectivity, we have constructed a nested set of substitution and deletion mutants. While we were not able to infect Nicotiana clevelandii plants with full-length PPV transcripts bearing mutations in the 5'-terminal 35 nucleotides of the viral genome, the deletion of long sequences located between nucleotides 39 and 145 did not alter either the rate of infection or viral accumulation. Nevertheless, these mutants were not able to compete with the wild-type strain in coinoculation experiments. Plants infected with a PPV mutant that lacked nucleotides 127 to 145 showed a very mild symptomathology; the wild-type symptom severity was recovered after spontaneous second-site mutations.

The 5' nontranslated region of potato virus X RNA affects both genomic and subgenomic RNA synthesis

A tobacco protoplast system was developed to analyze cis-acting sequences required for potato virus X (PVX) replication. Protoplasts inoculated with transcripts derived from a PVX cDNA clone or from clones containing mutations in their 5' nontranslated regions (NTRs) were assayed for RNA production by S1 nuclease protection assays. A time course of plus- and minus-strand-RNA accumulation indicated that both minus- and plus-strand PVX RNAs were detectable at 0.5 h postinoculation. Although minus-strand RNAs accumulated more rapidly than plus-strand RNAs, maximum levels of plus-strand RNAs were 40- to 80-fold higher. On the basis of these data, time points were chosen for determination of RNA levels in protoplasts inoculated with PVX clones containing deletions or an insertion in their 5' NTRs. Deletions of more than 12 nucleotides from the 5' end, internal deletions, and one insertion in the 5' NTR resulted in substantially decreased levels of plus-strand-RNA production. In contrast, all modified transcripts were functional for minus-strand-RNA synthesis, suggesting that elements in the 5' NTR were not essential for minus-strand-RNA synthesis. Further analysis of the 5' NTR deletion mutants indicated that all mutations that decreased genomic plus-strand-RNA synthesis also decreased synthesis of the two major subgenomic RNAs. These data indicate that cis-acting elements from different regions of the 5' NTR are required for plus-strand-RNA synthesis and that this process may be linked to synthesis of subgenomic RNAs.

Comparison of the replication of positive-stranded RNA viruses of plants and animals

It is clear from the experimental data that there are some similarities in RNA replication for all eukaryotic positive-stranded RNA viruses—that is, the mechanism of polymerization of the nucleotides is probably similar for all. It is noteworthy that all mechanisms appear to utilize host membranes as a site of replication. Membranes appear to function not only as a way of compartmentalizing virus RNA replication but also appear to have a central role in the organization and functioning of the replication complex, and further studies in this area are needed. Within virus supergroups, similarities are evident between animal and plant viruses—for example, in the nature and arrangements of replication genes and in sequence similarities of functional domains. However, it is also clear that there has been considerable divergence, even within supergroups. For example, the animal alpha-viruses have evolved to encode proteinases which play a central controlling function in the replication cycle, whereas this is not common in the plant alpha-like viruses and even when it occurs, as in the tymoviruses, the strategies that have evolved appear to be significantly different. Some of the divergence could be host-dependent and the increasing interest in the role of host proteins in replication should be fruitful in revealing how different systems have evolved. Finally, there are virus supergroups that appear to have no close relatives between animals and plants, such as the animal coronavirus-like supergroup and the plant carmo-like supergroup.

Genetic elements of plant viruses as tools for genetic engineering

Viruses have developed successful strategies for propagation at the expense of their host cells. Efficient gene expression, genome multiplication, and invasion of the host are enabled by virus-encoded genetic elements, many of which are well characterized. Sequences derived from plant DNA and RNA viruses can be used to control expression of other genes in vivo. The main groups of plant virus genetic elements useful in genetic engineering are reviewed, including the signals for DNA-dependent and RNA-dependent RNA synthesis, sequences on the virus mRNAs that enable translational control, and sequences that control processing and intracellular sorting of virus proteins. Use of plant viruses as extrachromosomal expression vectors is also discussed, along with the issue of their stability.

A conserved, precise RNA encapsidation pattern in Tobamovirus particles

The bidirectional RNA encapsidation pathway in nine sequenced Type 1 Tobamovirus genomes will result in RNA-coat protein assembly, up to and including the first transcribed G, adjacent to the 5'-cap structure (m7 Gppp). This precision is highly conserved, despite wide interstrain variations in the absolute position of the phase-determining core of the origin-of-assembly sequence (Gxx)n and in overall genome length (6311-6507 nts). A Type 2 Tobamovirus genome did not comply with this pattern. All genomes had a statistically significant bias for G at every third (or 3n) position, resulting in a preponderance of GNN codons and hence a high Val, Ala, Gly, Asp, Glu content, at least in the large (126/183 kDa) and amino-coterminal replicase protein genes. Contrary to predictions from the X-ray fibre diffraction structure of tobacco mosaic virus (TMV, U1 strain), only one (pepper mild mottle virus) of the nine Type 1 Tobamoviruses positioned the preferred G-repeat in the most favourable (5') position of the trinucleotide binding site on each coat protein (CP) subunit. In all but one of the eight remaining Type 1 Tobamovirus genomes, G would predominate in the CP 3'-site. The significance of these observations for TMV particle assembly, disassembly and host cell interactions are discussed.

Detection by immunogold labelling of P75 readthrough protein near an extremity of beet necrotic yellow vein virus particles

RNA 2 of beet necrotic yellow vein virus carries the cistron for the 21 kd coat protein at its 5'-extremity. During translation, the coat protein cistron termination codon is suppressed about 10% of the time so that translation continues into the adjacent open reading frame to produce a 75 kd species, known as P75, which contains the coat protein sequence at its N-terminus. Immunoblotting experiments with a P75-specific antiserum showed that P75 is present in only trace amounts in purified virus preparations. Electron microscopic visualization of immunogold-labelled virions in crude tissue extracts has provided evidence for an association between P75 and at least a fraction of the BNYVV particles, with P75 being predominantly located near one end of the rod-shaped virions. This finding is discussed in the context of the current model for the role of P75 in virus assembly and vector transmission.

Artificial defective interfering RNAs derived from RNA 2 of beet necrotic yellow vein virus

Long internal deletions were introduced into cloned cDNA of beet necrotic yellow vein virus RNAs 1-4 and transcripts containing the deletions were tested for their ability to inhibit replication of viral RNA in Chenopodium quinoa protoplasts and plants. No inhibition was observed with the deletion mutants based on RNAs 1, 3 and 4 but the RNA 2 deletion mutants all provoked a dramatic inhibition of synthesis of viral RNAs 1 and 2.

The secondary structure of the 5'-noncoding region of beet necrotic yellow vein virus RNA 3: evidence for a role in viral RNA replication

Secondary structure-sensitive chemical and enzymatic probes have been used to produce a model for the folding of the first 312 residues of the long 5'-noncoding region of beet necrotic yellow vein virus RNA 3. The structure consists of two major domains, one of which includes long distance base-pairing interactions between two short sequence elements (Box I and Box II) situated between positions 237 and 292 and complementary elements (Box I' and II') near the 5'-terminus. Previous studies have shown that base pairing between these sequence elements (in either the plus-strand or minus-strand RNA) is important for RNA 3 accumulation during infection. RNA 3 transcripts were produced containing mutations which preferentially disrupted Box II-II' base pairing in either the plus- or minus-strand. In infection experiments, transcripts with mutations which disrupted the Box II-II' interaction in the plus-strand structure replicated less efficiently than mutants in which the Box II-II' interaction was disrupted in the minus-strand. These findings indicate that the complex 5'-proximal plus-strand structure to which the Box II-II' interaction contributes comprises at least part of the promoter for plus-strand RNA synthesis.

Mapping the promoter for subgenomic RNA synthesis on beet necrotic yellow vein virus RNA 3

During infection of Tetragonia expansa leaves, RNA 3 of the quadripartite genome of beet necrotic yellow vein virus directs synthesis of a subgenomic RNA (RNA 3sub) which corresponds to the 3'-terminal 600 residues of the RNA 3 molecule. Biologically active run-off transcripts have been prepared from full-length cDNA of RNA 3 cloned behind a bacteriophage T7-RNA polymerase promoter. RNA 3 transcripts carrying deletions in the vicinity of the RNA 3sub initiation site were produced by site-directed mutagenesis at the cDNA level and then tested for their capacity to direct RNA 3sub synthesis in infected leaves. The cis-acting domain essential for normal levels of RNA 3sub production in planta (the 'core' promoter) did not extend in the 5'-direction beyond position -16 relative to the RNA 3sub transcription initiation site. The 3'-boundary of the core promoter domain was located somewhere between positions +100 and +208. Displacement of the promoter domain to an upstream site in RNA 3 produced a new subgenomic RNA starting at or near the predicted upstream site.