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 inNicotiana clevelandiiat 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 inN. clevelandiiwhile 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.     

Defective-interfering RNAs and elevated temperatures inhibit replication of tomato bushy stunt virus in inoculated protoplasts

Tomato bushy stunt virus (TBSV) genomic RNA and one of its defective interfering (DI) RNAs were inoculated in various combinations to protoplasts of Nicotiana benthamiana. Ethidium bromide staining of electrophoretically separated RNAs from infected protoplasts, incorporation of [3H]uridine into TBSV and DI RNAs, and Northern hybridization at different times after inoculation clearly demonstrated reduced accumulation of genomic RNA in the presence of DI RNA. Accumulation of genomic RNA was very rapid between 3 and 9 hr postinfection. The presence of equimolar amounts of genomic and DI RNA in the inoculum resulted in a 65% suppression of genomic RNA accumulation. Suppression of genomic RNA was mediated by a reduction in the rate at which genomic RNA accumulated. Analysis of protoplasts inoculated with increasing ratios of DI:genomic RNA suggested that DI RNA-mediated suppression of genomic RNA synthesis results from competition for factors essential for viral replication. Incubation of protoplasts at different temperatures also had a profound effect on replication of both genomic and DI RNAs. Both replicated well at 27 degrees but were barely detectable at 32 degrees. Suppression of genomic RNA synthesis by DI RNA was similar at all temperatures tested. Thus, this study suggests that DI suppression of TBSV symptoms in whole plants and symptom attenuation at elevated temperatures are primarily the result of reduced viral replication.     

3'-Terminal RNA secondary structures are important for accumulation of tomato bushy stunt virus DI RNAs

The plus-strand RNA genome of tomato bushy stunt virus (TBSV) contains a 351-nucleotide (nt)-long 3'-untranslated region. We investigated the role of the 3'-proximal 130 nt of this sequence in viral RNA accumulation within the context of a TBSV defective interfering (DI) RNA. Sequence comparisons between different tombusviruses revealed that the 3' portion of the 130-nt sequence is highly conserved and deletion analysis confirmed that this segment is required for accumulation of DI RNAs in protoplasts. Computer-aided sequence analysis and in vitro solution structure probing indicated that the conserved sequence consists of three stem-loop (SL) structures (5'-SL3-SL2-SL1-3'). The existence of SLs 1 and 3 was also supported by comparative secondary structure analysis of sequenced tombusvirus genomes. Formation of the stem regions in all three SLs was found to be very important, and modification of the terminal loop sequences of SL1 and SL2, but not SL3, decreased DI RNA accumulation in vivo. For SL3, alterations to an internal loop resulted in significantly reduced DI RNA levels. Collectively, these data indicate that all three SLs are functionally relevant and contribute substantially to DI RNA accumulation. In addition, secondary structure analysis of other tombusvirus replicons and related virus genera revealed that a TBSV satellite RNA and members of the closely related genus Aureusvirus (family Tombusviridae) share fundamental elements of this general structural arrangement. Thus, this secondary structure model appears to extend beyond tombusvirus genomes. These conserved 3'-terminal RNA elements likely function in vivo by promoting and/or regulating minus-strand synthesis.     

Silencing of NbXrn4 facilitates the systemic infection of Tobacco mosaic virus in Nicotiana benthamiana

The 5'-3' exoribonucleases (Xrns) play key roles in degradation and processing pathways of several classes of RNAs including mRNA, rRNA, miRNA and other small RNAs. Recent work revealed that the cytoplasmic Xrn (Xrn1p in yeast and Xrn4 in plants) affected the stability of the viral RNA of tombusviruses in yeast and plants, which indicates that the cytoplasmic Xrn might be involved in plant defense against virus by degrading viral RNA. Here, we demonstrated that silencing of Nicotiana benthamiana cytoplasmic Xrn4 facilitated both local and systemic infection of Tobacco mosaic virus (TMV) in N. benthamiana. The results support the suggestion that cytoplasmic Xrn4 participates in the viral defense system of plants.     

Mutational analysis of the monopartite geminivirus beet curly top virus.

Mutants of the monopartite geminivirus beet curly top virus have been screened for infectivity and symptom development in Nicotiana benthamiana and Beta vulgaris, for replication competence in N. benthamiana leaf discs, and for transmission by the leafhopper Circulifer tenellus. Disruption of open reading frame (ORF) V2 by the introduction of a termination codon resulted in symptomless infection of N. benthamiana associated with low levels of virus and reduced single-stranded (ss) DNA and prevented systemic infection of B. vulgaris. Reduced levels of ssDNA were produced by the mutant in N. benthamiana leaf discs, suggesting that V2 affects the synthesis or accumulation of this viral DNA form. Mutants in which ORF C2 had been truncated by the introduction of termination codons or by frame-shifting remained highly infectious and induced severe symptoms in both N. benthamiana and B. vulgaris. Similarly, a mutant containing a termination codon within ORF C3 was highly infectious and induced severe symptoms in N. benthamiana although infectivity in B. vulgaris was greatly reduced, symptoms were extremely mild, and virus levels were low. A synergistic effect of a double mutation in ORFs C2 and C3, manifested by the inability of mutants to systemically infect N. benthamiana and the production of reduced amounts of ssDNA in N. benthamiana leaf discs, suggests that both ORFs are functional in this host. A mutant containing a termination codon within the 5' terminus of ORF C4 produced severe symptoms in both N. benthamiana and B. vulgaris resembling those induced by wild-type virus. Comparison with the phenotypes of previously characterized ORF C4 mutants suggests that a conserved core sequence of this ORF is an important symptom determinant. ORF C2, C3, and C4 mutants produced virus particles and were transmitted by C. tenellus, eliminating agroinoculation as a contributory factor to the mutant phenotypes. Our results are compared with those derived from mutagenesis studies on related bipartite geminiviruses.     

Expression of the Arabidopsis Xrn4p 5'-3' exoribonuclease facilitates degradation of tombusvirus RNA and promotes rapid emergence of viral variants in plants

Rapid RNA virus evolution is a major problem due to the devastating diseases caused by human, animal and plant-pathogenic RNA viruses. A previous genome-wide screen for host factors affecting recombination in Tomato bushy stunt tombusvirus (TBSV), a small monopartite plant virus, identified Xrn1p 5'-3' exoribonuclease of yeast, a model host, whose absence led to increased appearance of recombinants [Serviene, E., Shapka, N., Cheng, C.P., Panavas, T., Phuangrat, B., Baker, J., Nagy, P.D., (2005). Genome-wide screen identifies host genes affecting viral RNA recombination. Proc. Natl. Acad. Sci. U. S. A. 102 (30), 10545-10550]. In this paper, we tested if over-expression of Xrn1p in yeast or expression of the analogous Xrn4p cytoplasmic 5'-3' exoribonuclease, which has similar function in RNA degradation in Arabidopsis as Xrn1p in yeast, in Nicotiana benthamiana could affect the accumulation of tombusvirus RNA. We show that over-expression of Xrn1p led to almost complete degradation of TBSV RNA replicons in yeast, suggesting that Xrn1p is involved in TBSV degradation. Infection of N. benthamiana expressing AtXrn4p with Cucumber necrosis tombusvirus (CNV) led to enhanced viral RNA degradation, suggesting that the yeast and the plant cytoplasmic 5'-3' exoribonuclease play similar roles. We also observed rapid emergence of novel CNV genomic RNA variants formed via deletions of 5' terminal sequences in N. benthamiana expressing AtXrn4p. Three of the newly emerging 5' truncated CNV variants were infectious in N. benthamiana protoplasts, whereas one CNV variant caused novel symptoms and moved systemically in N. benthamiana plants. Altogether, this paper establishes that a single plant gene can contribute to the emergence of novel viral variants.     

Replication of heterologous combinations of helper and defective RNA of citrus tristeza virus

Citrus tristeza virus (CTV) populations are among the more complex of plant RNA viruses with unusual mixtures of strains and defective RNAs (dRNAs). Citrus plants infected with different CTV isolates contain multiple dRNA molecules that differ in size and relative abundance within and between isolates. Additionally, we found mixtures of heterologous dRNAs in populations. To examine the replication of CTV dRNAs, the protoplast system had to be extended to support helper-assisted amplification of input dRNAs. The use of freshly extracted sap of CTV-infected tissue as inoculum increased the infection of Nicotiana benthamiana protoplasts sufficiently to result in accumulation of high levels of CTV RNAs as well as dRNAs within 2 or 3 days postinoculation. A series of dRNA-like molecules, each with a single large internal deletion, were created from an infectious cDNA clone of the CTV T36 isolate and examined for amplification in N. benthamiana protoplasts using a CTV deletion mutant as the helper virus. Of 12 synthetic dRNAs, only three with sizes of 3650, 3819, and 4460 nucleotides were efficiently replicated. CTV dRNA replication did not appreciably affect levels of accumulation of the genomic or the subgenomic RNAs of the helper virus. To investigate the maintenance of dRNAs in CTV populations, we examined heterologous interactions between dRNAs and helper viruses. Wild-type populations of heterologous strains T68 and T3, as well as the homologous T36, supported replication of synthetic T36 dRNAs. Replacement in the T36 dRNA of the 5' region, which is most variable among CTV strains, with the corresponding sequences from VT, T68, T3, or T30 resulted in chimeric dRNAs that failed to be replicated by the T36 helpers but were replicated to detectable levels by the T68 helper. The differential specificities of different CTV replicase complexes with dRNA replication signals is one possible factor that affects the maintenance of dRNA population structures.     

Mutations that alter a repeated ACCA element located at the 5' end of the Potato virus X genome affect RNA accumulation

The repeated ACCA or AC-rich sequence and structural (SL1) elements in the 5' non-translated region (NTR) of the Potato virus X (PVX) RNA play vital roles in the PVX life cycle by controlling translation, RNA replication, movement, and assembly. It has already been shown that the repeated ACCA or AC-rich sequence affect both gRNA and sgRNA accumulation, while not affecting minus-strand RNA accumulation, and are also required for host protein binding. The functional significance of the repeated ACCA sequence elements in the 5' NTR region was investigated by analyzing the effects of deletion and site-directed mutations on PVX replication in Nicotiana benthamiana plants and NT1 protoplasts. Substitution (ACCA into AAAA or UUUU) mutations introduced in the first (nt 10-13) element in the 5' NTR of the PVX RNA significantly affected viral replication, while mutations introduced in the second (nt 17-20) and third (nt 20-23) elements did not. The fourth (nt 29-32) ACCA element weakly affected virus replication, whereas mutations in the fifth (nt 38-41) significantly reduced virus replication due to the structure disruption of SL1 by AAAA and/or UUUU substitutions. Further characterization of the first ACCA element indicated that duplication of ACCA at nt 10-13 (nt 10-17, ACCAACCA) caused severe symptom development as compared to that of wild type, while deletion of the single element (nt 10-13), DeltaACCA) or tripling of this element caused reduced symptom development. Single- and double-nucleotide substitutions introduced into the first ACCA element revealed the importance of CC located at nt positions 11 and 12. Altogether, these results indicate that the first ACCA element is important for PVX replication.     

Molecular cloning and complete nucleotide sequence of carnation Italian ringspot tombusvirus genomic and defective interfering RNAs

Summary The complete sequences of genomic and defective interfering (DI) RNAs of carnation Italian ringspot tombusvirus (CIRV) were determined. The genome (4760 nt) has an organization identical to that reported for other tombusviruses except that the pre-readthrough domain of the viral replicase encoded by the 5-proximal open reading frame (ORF) is larger. In particular, the N-terminal region of this protein differs from the corresponding region of the other members of the genusTombusvirus andCarmovirus. Two DI RNAs were found in infected tissues whose sequences were completely derived from genomic RNA. The smaller molecule (474 nt) is contained completely within the larger molecule (656 nt), which suggests that it is derived from the larger one.The nucleotide sequence data reported in this paper will appear in the EMBL, GenBank and DDBJ Nucleotide Database under the accession number X85215.     

Translation elongation factor 1A is a component of the tombusvirus replicase complex and affects the stability of the p33 replication co-factor

Host RNA-binding proteins are likely to play multiple, integral roles during replication of plus-strand RNA viruses. To identify host proteins that bind to viral RNAs, we took a global approach based on the yeast proteome microarray, which contains 4080 purified yeast proteins. The biotin-labeled RNA probes included two distantly related RNA viruses, namely Tomato bushy stunt virus (TBSV) and Brome mosaic virus (BMV). Altogether, we have identified 57 yeast proteins that bound to TBSV RNA and/or BMV RNA. Among the identified host proteins, eleven bound to TBSV RNA and seven bound to BMV RNA with high selectivity, whereas the remaining 39 host proteins bound to both viral RNAs. The interaction between the TBSV replicon RNA and five of the identified host proteins was confirmed via gel-mobility shift and co-purification experiments from yeast. Over-expression of the host proteins in yeast, a model host for TBSV, revealed 4 host proteins that enhanced TBSV replication as well as 14 proteins that inhibited replication. Detailed analysis of one of the identified yeast proteins binding to TBSV RNA, namely translation elongation factor eEF1A, revealed that it is present in the highly purified tombusvirus replicase complex. We also demonstrate binding of eEF1A to the p33 replication protein and a known cis-acting element at the 3′ end of TBSV RNA. Using a functional mutant of eEF1A, we provide evidence on the involvement of eEF1A in TBSV replication.     

De novo generation of defective interfering RNAs of tomato bushy stunt virus by high multiplicity passage

Defective interfering (DI) RNAs were generated de novo in each of 12 independent isolates of tomato bushy stunt virus (TBSV) upon serial passage at high multiplicities of infection (m.o.i.) in plants, but not in any of 4 additional isolates after 11 serial passages at low m.o.i. The DI RNAs were detected in RNA isolated from virus particles and in 2.3 M LiCl-soluble RNA fractions isolated from inoculated leaves. Symptom attenuation leading to persistent infections was closely correlated with the passage in which DIs first developed. Comparisons of nucleotide sequences of 10 cDNA clones from 2 DI RNA populations and with a previously characterized TBSV DI RNA revealed the same four regions of sequence from the TBSV genome were strictly conserved in each of the DI RNAs: the virus 5' leader sequence of 168 bases; a region of approximately 200-250 bases from the viral polymerase gene; approximately 70 bases from the 3' terminus of the viral p19 and p22 genes; and approximately 130 bases from the 3' terminal noncoding region. Conservation of the sequence motif present in all of the DIs suggests that there might be a common mechanism of DI formation as well as selection pressure to maintain sequences essential for replication and encapsidation.     

Yeast as a model host to study replication and recombination of defective interfering RNA of Tomato bushy stunt virus

Defective interfering (DI) RNA associated with Tomato bushy stunt virus (TBSV), which is a plus-strand RNA virus, requires p33 and p92 proteins of TBSV or the related Cucumber necrosis virus (CNV), for replication in plants. To test if DI RNA can replicate in a model host, we coexpressed TBSV DI RNA and p33/p92 of CNV in yeast. We show evidence for replication of DI RNA in yeast, including (i) dependence on p33 and p92 for DI replication; (ii) presence of active CNV RNA-dependent RNA polymerase in isolated membrane-containing preparations; (iii) increasing amount of DI RNA(+) over time; (iv) accumulation of (-)stranded DI RNA; (v) presence of correct 5' and 3' ends in DI RNA; (vi) inhibition of replication by mutations in the replication enhancer; and (vii) evolution of DI RNA over time, as shown by sequence heterogeneity. We also produced evidence supporting the occurrence of DI RNA recombinants in yeast. In summary, development of yeast as a host for replication of TBSV DI RNA will facilitate studies on the roles of viral and host proteins in replication/recombination.     

Structural and mutational analyses of cis-acting sequences in the 5'-untranslated region of satellite RNA of bamboo mosaic potexvirus

The satellite RNA of Bamboo mosaic virus (satBaMV) contains on open reading frame for a 20-kDa protein that is flanked by a 5'-untranslated region (UTR) of 159 nucleotides (nt) and a 3'-UTR of 129 nt. A secondary structure was predicted for the 5'-UTR of satBaMV RNA, which folds into a large stem-loop (LSL) and a small stem-loop. Enzymatic probing confirmed the existence of LSL (nt 8-138) in the 5'-UTR. The essential cis-acting sequences in the 5'-UTR required for satBaMV RNA replication were determined by deletion and substitution mutagenesis. Their replication efficiencies were analyzed in Nicotiana benthamiana protoplasts and Chenopodium quinoa plants coinoculated with helper BaMV RNA. All deletion mutants abolished the replication of satBaMV RNA, whereas mutations introduced in most of the loop regions and stems showed either no replication or a decreased replication efficiency. Mutations that affected the positive-strand satBaMV RNA accumulation also affected the accumulation of negative-strand RNA; however, the accumulation of genomic and subgenomic RNAs of BaMV were not affected. Moreover, covariation analyses of natural satBaMV variants provide substantial evidence that the secondary structure in the 5'-UTR of satBaMV is necessary for efficient replication.     

Modular arrangement of viral cis-acting RNA domains in a tombusvirus satellite RNA

Satellite (sat) RNAs are parasitic sub-viral RNA replicons found associated with certain positive-strand RNA viruses. Typical sat RNAs, such as those associated with members of the genus Tombusvirus, share little or no sequence identity with their helper virus genomes. Here, we have investigated a tombusvirus sat RNA and determined that it contains two functionally-relevant higher-order RNA domains, a T-shaped domain and a downstream domain, that are similar to elements shown previously to be present in the 5' untranslated regions (UTRs) of tombusvirus genomes. Although the two sat RNA domains showed only limited sequence identity with their viral counterparts, they were able to adopt comparably-folded RNA secondary structures. Interestingly, the relative spacing between the domains in the viral and satellite contexts was notably different. In the viral 5' UTR, the two domains are adjacent and separated by a small hairpin, however, in the sat RNA they are separated by a 137-nt long segment. Despite this distal modular arrangement, the two domains were found to be united spatially in the sat RNA through the formation of an RNA-RNA bridge. This co-localization facilitated an important inter-domain interaction and was essential for efficient helper-mediated sat RNA accumulation in protoplasts. These results indicate that the tombusvirus sat RNA and helper genome contain structurally and functionally equivalent RNA domains. It is proposed that the limited sequence identity observed between these corresponding higher-order RNA structures is related to a strategy that reduces the induction of gene silencing, which presumably would be detrimental to both viral and sat RNA replicons.     

The nucleotide sequence and genome organization of Sclerophthora macrospora virus A

Sclerophthora macrospora virus A (SmV A) found in S. macrospora, the pathogenic fungus responsible for downy mildew of gramineous plants, is a small icosahedral virus containing three segments (RNAs 1, 2, and 3) of the positive-strand ssRNA genome. In the present study we report the complete nucleotide sequence of the SmV A genome. The viral genome RNA 1 consists of 2928 nucleotides (nt) and has two open reading frames (ORFs 1a and 1b). ORF 1a contains the motifs of RNA-directed RNA polymerase (RdRp). The function of ORF 1b is unknown. RNA 2 consists of 1981 nt and single ORF (ORF 2). ORF 2 encodes a capsid protein. RNA 3 consists of 977 nt but not any ORFs, suggesting it as a satellite RNA. The deduced amino acid sequence of ORF 1a shows some similarity to those of RdRp of certain positive-strand RNA viruses, especially to the members of the family Nodaviridae, and that of ORF 2 to CP of the members in the family Tombusviridae. The nucleotide sequence of RNA 3 shows a 40-nucleotide length of partial similarity to S. macrospora virus B (SmV B) RNA. The capsid of SmV A is composed of two capsid proteins, CP 1 (p43) and CP 2 (p39), both encoded in ORF 2. CP 2 is apparently derived from CP 1 via proteolytic cleavage at the N-terminus. The genome organization of SmV A is characteristic and distinct from those of other known fungal RNA viruses, including SmV B. These results suggest that SmV A should be classified into a new group of mycoviruses.