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

Biochemical Characterization of a Non-G4-Type RNA Aptamer That Lights Up a GFP-like Fluorogenic Ligand

The 17-3 RNA aptamer recognizes DMHBI and induces its fluorescence. We showed that the 17-3 RNA aptamer predominantly induced emission of the phenolate form of DMHBI. We also demonstrated that the active structure of the minimal form of the 17-3 aptamer possessed three stem elements and two large loop elements, which we named Karashi and its sequence-optimized variant, Jigarashi, respectively. Chemical modification experiments suggested that the two loop regions formed tertiary interactions and/or non-Watson-Crick base pairs, and no remarkable structural alterations occurred upon DMHBI binding. AlphaFold3 also predicted a tertiary structure of the ligand-free form of Jigarashi RNA, which was consistent with the results of chemical modification experiments.

Intragenomic Long-Distance RNA-RNA Interactions in Plus-Strand RNA Plant Viruses

Plant viruses that contain positive-strand RNA genomes represent an important class of pathogen. The genomes of these viruses harbor RNA sequences and higher-order RNA structures that are essential for the regulation of viral processes during infections. In recent years, it has become increasingly evident that, in addition to locally positioned RNA structures, long-distance intragenomic interactions, involving nucleotide base pairing over large distances, also contribute significantly to the control of various viral events. Viral processes that are modulated by such interactions include genome replication, translation initiation, translational recoding, and subgenomic mRNA transcription. Here, we review the structure and function of different types of long-distance RNA–RNA interactions, herein termed LDRIs, present in members of the family Tombusviridae and other plus-strand RNA plant viruses.

A 3'-end structure in RNA2 of a crinivirus is essential for viral RNA synthesis and contributes to replication-associated translation activity

The terminal ends in the genome of RNA viruses contain features that regulate viral replication and/or translation. We have identified a Y-shaped structure (YSS) in the 3' terminal regions of the bipartite genome of Lettuce chlorosis virus (LCV), a member in the genus Crinivirus (family Closteroviridae). The YSS is the first in this family of viruses to be determined using Selective 2'-Hydroxyl Acylation Analyzed by Primer Extension (SHAPE). Using luciferase constructs/replicons, in vivo and in vitro assays showed that the 5' and YSS-containing 3' terminal regions of LCV RNA1 supported translation activity. In contrast, similar regions from LCV RNA2, including those upstream of the YSS, did not. LCV RNA2 mutants with nucleotide deletions or replacements that affected the YSS were replication deficient. In addition, the YSS of LCV RNA1 and RNA2 were interchangeable without affecting viral RNA synthesis. Translation and significant replication were observed for specific LCV RNA2 replicons only in the presence of LCV RNA1, but both processes were impaired when the YSS and/or its upstream region were incomplete or altered. These results are evidence that the YSS is essential to the viral replication machinery, and contributes to replication enhancement and replication-associated translation activity in the RNA2 replicons.

Biologically-supported structural model for a viral satellite RNA

Satellite RNAs (satRNAs) are a class of small parasitic RNA replicon that associate with different viruses, including plus-strand RNA viruses. Because satRNAs do not encode a polymerase or capsid subunit, they rely on a companion virus to provide these proteins for their RNA replication and packaging. SatRNAs recruit these and other required factors via their RNA sequences and structures. Here, through a combination of chemical probing analysis of RNA structure, phylogenetic structural comparisons, and viability assays of satRNA mutants in infected cells, the biological importance of a deduced higher-order structure for a 619 nt long tombusvirus satRNA was assessed. Functionally-relevant secondary and tertiary RNA structures were identified throughout the length of the satRNA. Notably, a 3′-terminal segment was found to adopt two mutually-exclusive RNA secondary structures, both of which were required for efficient satRNA accumulation. Accordingly, these alternative conformations likely function as a type of RNA switch. The RNA switch was also found to engage in a required long-range kissing-loop interaction with an upstream sequence. Collectively, these results establish a high level of conformational complexity within this small parasitic RNA and provide a valuable structural framework for detailed mechanistic studies.

Pelarspovirus, a proposed new genus in the family Tombusviridae

Currently, the family Tombusviridae encompasses thirteen viral genera that contain single-stranded, positive-sense RNA genomes and isometric virions; the exception being the genus Umbravirus, whose members do not encode a coat protein (CP). A new genus, tentatively named Pelarspovirus, is proposed to be added to this family and would include five members, with Pelargonium line pattern virus recommended as the type species. Viruses assigned to this proposed genus have monopartite genomes encoding five open reading frames (ORFs) that include two 5'-proximal replication proteins, two centrally located movement proteins (MP1 and MP2) and a 3'-proximal CP that, at least for pelargonium line pattern virus (PLPV), has been shown to act also as suppressor of RNA silencing. Distinguishing characteristics of these viruses include i) production of a single, tricistronic subgenomic RNA for expression of MP and CP genes, ii) presence of a non-AUG start codon (CUG or GUG) initiating the MP2 ORF, iii) absence of AUG codons in any frame between the AUG initiation codons of MP1 and CP genes, and iv) sequence-based phylogenetic clustering of all encoded proteins in separate clades from those of other family members.

Construction of a synthetic infectious cDNA clone of Grapevine Algerian latent virus (GALV-Nf) and its biological activity in Nicotiana benthamiana and grapevine plants

BACKGROUND

Grapevine Algerian latent virus (GALV) is a tombusvirus first isolated in 1989 from an Algerian grapevine (Vitis spp.) plant and more recently from water samples and commercial nipplefruit and statice plants. No further reports of natural GALV infections in grapevine have been published in the last two decades, and artificial inoculations of grapevine plants have not been reported. We developed and tested a synthetic GALV construct for the inoculation of Nicotiana benthamiana plants and different grapevine genotypes to investigate the ability of this virus to infect and spread systemically in different hosts.

METHODS

We carried out a phylogenetic analysis of all known GALV sequences and an epidemiological survey of grapevine samples to detect the virus. A GALV-Nf clone under the control of the T7 promoter was chemically synthesized based on the full-length sequence of the nipplefruit isolate GALV-Nf, the only available sequence at the time the project was conceived, and the infectious transcripts were tested in N. benthamiana plants. A GALV-Nf-based binary vector was then developed for the agroinoculation of N. benthamiana and grapevine plants. Infections were confirmed by serological and molecular analysis and the resulting ultrastructural changes were investigated in both species.

RESULTS

Sequence analysis showed that the GALV coat protein is highly conserved among diverse isolates. The first epidemiological survey of cDNAs collected from 152 grapevine plants with virus-like symptoms did not reveal the presence of GALV in any of the samples. The agroinoculation of N. benthamiana and grapevine plants with the GALV-Nf binary vector promoted efficient infections, as revealed by serological and molecular analysis. The GALV-Nf infection of grapevine plants was characterized in more detail by inoculating different cultivars, revealing distinct patterns of symptom development. Ultrastructural changes induced by GALV-Nf in N. benthamiana were similar to those induced by tombusviruses in other hosts, but the cytopathological alterations in grapevine plants were less severe.

CONCLUSIONS

This is the first report describing the development of a synthetic GALV-Nf cDNA clone, its artificial transmission to grapevine plants and the resulting symptoms and cytopathological alterations.

Construction and characterization of an aureusvirus defective RNA

Defective RNAs (D RNAs) are small RNA replicons derived from viral RNA genomes. No D RNAs have been found associated with members of the plus-strand RNA virus genus Aureusvirus (family Tombusviridae). Accordingly, we sought to construct a D RNA for the aureusvirus Cucumber leaf spot virus (CLSV) using the known structure of tombusvirus defective interfering RNAs as a guide. An efficiently accumulating CLSV D RNA was generated that contained four non-contiguous regions of the viral genome and this replicon was used as a tool to studying viral cis-acting RNA elements. The results of structural and functional analyses indicated that CLSV contains counterparts for several of the major RNA elements found in tombusviruses. However, although similar, the CLSV D RNA and its components are distinct and provide insights into RNA-based specificity and mechanisms of function.

Replication of Plant Viruses

Viruses replicate using both their own genetic information and host cell components and machinery. The different genome types have different replication pathways which contain controls on linking the process with translation and movement around the cell as well as not compromising the infected cell. This chapter discusses the replication mechanisms, faults in replication and replication of viruses co-infecting cells.

Viruses replicate using both their own genetic information and host cell components and machinery. The different genome types have different replication pathways which contain controls on linking the process with translation and movement around the cell as well as not compromising the infected cell. This chapter discusses the replication mechanisms, faults in replication and replication of viruses coinfecting cells.

Global organization of a positive-strand RNA virus genome

The genomes of plus-strand RNA viruses contain many regulatory sequences and structures that direct different viral processes. The traditional view of these RNA elements are as local structures present in non-coding regions. However, this view is changing due to the discovery of regulatory elements in coding regions and functional long-range intra-genomic base pairing interactions. The ∼4.8 kb long RNA genome of the tombusvirus tomato bushy stunt virus (TBSV) contains these types of structural features, including six different functional long-distance interactions. We hypothesized that to achieve these multiple interactions this viral genome must utilize a large-scale organizational strategy and, accordingly, we sought to assess the global conformation of the entire TBSV genome. Atomic force micrographs of the genome indicated a mostly condensed structure composed of interconnected protrusions extending from a central hub. This configuration was consistent with the genomic secondary structure model generated using high-throughput selective 2′-hydroxyl acylation analysed by primer extension (i.e. SHAPE), which predicted different sized RNA domains originating from a central region. Known RNA elements were identified in both domain and inter-domain regions, and novel structural features were predicted and functionally confirmed. Interestingly, only two of the six long-range interactions known to form were present in the structural model. However, for those interactions that did not form, complementary partner sequences were positioned relatively close to each other in the structure, suggesting that the secondary structure level of viral genome structure could provide a basic scaffold for the formation of different long-range interactions. The higher-order structural model for the TBSV RNA genome provides a snapshot of the complex framework that allows multiple functional components to operate in concert within a confined context.

The genomes of many important pathogenic viruses are made of RNA. These genomes encode viral proteins and contain regulatory sequences and structures. In some viruses, distant regions of the RNA genome can interact with each other via base pairing, which suggests that certain genomes may take on well-defined conformations. This concept was investigated using a tombusvirus RNA genome that contains several long-range RNA interactions. The results of microscopic and biochemical analyses indicated a compact genome conformation with structured regions radiating from a central core. The structural model was compatible with some, but not all, long-range interactions, suggesting that the genome is a dynamic molecule that assumes different conformations. The analysis also revealed new structural features of the genome, some of which were shown to be functionally relevant. This study advances our understanding of the role played by global structure in virus genome function and provides a model to further investigate its in role virus reproduction. We anticipate that organizational principles revealed by this investigation will be applicable to other viruses.

Multifaceted regulation of translational readthrough by RNA replication elements in a tombusvirus

Translational readthrough of stop codons by ribosomes is a recoding event used by a variety of viruses, including plus-strand RNA tombusviruses. Translation of the viral RNA-dependent RNA polymerase (RdRp) in tombusviruses is mediated using this strategy and we have investigated this process using a variety of in vitro and in vivo approaches. Our results indicate that readthrough generating the RdRp requires a novel long-range RNA-RNA interaction, spanning a distance of ∼3.5 kb, which occurs between a large RNA stem-loop located 3'-proximal to the stop codon and an RNA replication structure termed RIV at the 3'-end of the viral genome. Interestingly, this long-distance RNA-RNA interaction is modulated by mutually-exclusive RNA structures in RIV that represent a type of RNA switch. Moreover, a different long-range RNA-RNA interaction that was previously shown to be necessary for viral RNA replicase assembly was also required for efficient readthrough production of the RdRp. Accordingly, multiple replication-associated RNA elements are involved in modulating the readthrough event in tombusviruses and we propose an integrated mechanistic model to describe how this regulatory network could be advantageous by (i) providing a quality control system for culling truncated viral genomes at an early stage in the replication process, (ii) mediating cis-preferential replication of viral genomes, and (iii) coordinating translational readthrough of the RdRp with viral genome replication. Based on comparative sequence analysis and experimental data, basic elements of this regulatory model extend to other members of Tombusviridae, as well as to viruses outside of this family.

Viruses use many different strategies to produce their proteins and some viral proteins are made with terminal extensions that confer unique properties. The polymerase that replicates the RNA genomes of tombusviruses is an extended version of another viral protein and is generated by a process called translational readthrough. We have determined the regulatory mechanism that modulates the production of this viral polymerase. Our results show that control of the readthrough process is complex and involves both local structures and long-range interactions within the viral genome. This system is also integrated with viral RNA replication elements and this allows the virus to coordinate polymerase production with genome replication. This regulatory scheme appears to represent a common tactic used by a variety of viruses.

Evolution of a helper virus-derived, ribosome binding translational enhancer in an untranslated satellite RNA of Turnip crinkle virus

SatC is a noncoding subviral RNA associated with Turnip crinkle virus (TCV). A 100-nt stretch in the 3' UTR of TCV contains three hairpins and two pseudoknots that fold into a tRNA-shaped structure (TSS) that binds 80S ribosomes. The 3' half of satC is derived from TCV and contains 6-nt differences in the TSS-analogous region. SatC binds poorly to 80S ribosomes, and molecular modeling that predicted the 3D structure of the TSS did not predict a similar structure for satC. When the satC TSS region was step-wise converted to the original TCV TSS bases, ribosome binding increased to TCV TSS levels without significantly affecting satC replication. However, mutant satC was less fit when accumulating in plants and gave rise to numerous second site changes that weakened one of two satC conformations. These results suggest that minor changes from the original TCV sequence in satC reflect requirements other than elimination of ribosome binding.

Properties of a novel satellite RNA associated with tomato bushy stunt virus infections

The biological and molecular properties of a novel satellite RNA (satRNA L) associated with tomato bushy stunt virus (TBSV) are described. satRNA L consisted of a linear single-stranded RNA of 615 nt, lacked significant open reading frames (ORFs) and had no sequence identity with the helper genome other than in the 5'-proximal 7 nt and in a central region that is also conserved in all tombusvirus genomic, defective interfering and satellite RNAs. Secondary-structure analysis showed the presence of high-order domains similar to those described for other tombusvirus RNAs. Shorter-than-unit-length molecules were shown not to be related to a silencing mechanism. satRNA L did not modify the symptoms induced by TBSV under any of the temperature conditions tested. A full-length cDNA clone was constructed and used in co-inoculations with transcripts of carnation Italian ringspot virus (CIRV) and cymbidium ringspot virus (CymRSV). CIRV, but not CymRSV, supported the replication of satRNA L. Using CIRV-CymRSV hybrid infectious clones, two regions were identified as possible determinants of the different ability to support satRNA L replication. The first region was in the 5'-untranslated region, which folds differently in CymRSV in comparison with CIRV and TBSV; the second region was in the ORF1-encoded protein where a more efficient satRNA L-binding domain is suggested to be present in CIRV.

Complete nucleotide sequence and genome organization of Calibrachoa mottle virus (CbMV)--a new species in the genus Carmovirus of the family Tombusviridae

Complete genomic sequence of the viral RNA of Calibrachoa mottle virus (CbMV) has been determined. The CbMV genome has a positive-sense single-stranded RNA of 3919 nucleotides in length and encodes five open reading frames (ORFs). ORF1 encodes a protein with predicted molecular weight of 28 kDa (p28). ORF2 extends through the amber stop codon of ORF1 to give a protein with a predicted molecular weight of 87 kDa (p87). The readthrough domain of p87 contains the GDD motif common to RNA-dependent RNA polymerases (RdRp). ORF3 and ORF4 encode two small overlapping polypeptides of 8 kDa (p8) and 9 kDa (p9), respectively. The 3'-proximal ORF5 encodes a capsid protein (CP) of 37 kDa (p37). The untranslated 5'- and 3'-terminal regions are composed of 34 and 234 non-coding nucleotides, respectively. Comparisons of amino acid sequences of the ORFs of CbMV with members of Tombusviridae show that CbMV is closely related to members of the genus Carmovirus. Phylogenetic analyses based on the amino acid sequences of RdRp and coat protein and nucleotide sequences of the whole genome reveal that CbMV forms a subgroup with several carmoviruses. Therefore, the genome organization, physico-chemical properties, sequence alignments and phylogenetic analysis support the classification of CbMV as a new species in the genus Carmovirus, family Tombusviridae.

Replication of Tomato bushy stunt virus RNA in a plant in vitro system

An ideal system to investigate individual determinants of the replication process of (+)-strand RNA viruses is a cell-free extract that supports viral protein and RNA synthesis in a synchronized manner. Here, we applied a translation/replication system based on cytoplasmic extracts of Nicotiana tabacum cells to Tomato bushy stunt virus (TBSV) RNA. In vitro translated TBSV proteins p33 and p92 form viral replicase, which, in the same reaction, accomplishes the entire replication cycle on exogenous TBSV DI or full-length RNA. Tests of mutant TBSV RNAs confirmed the template specificity of the in vitro replication reaction. Complementation experiments ascertained the significance of an earlier identified TBSV host factor. Interestingly, formation of the viral replicase occurs also in the absence of concurrent protein synthesis demonstrating that translation and RNA replication are not functionally linked in this system. Our studies with cell-free extracts of a plant host thus confirmed earlier findings and enabled novel insights into the TBSV RNA replication process.

Structural and functional analyses of the 3' untranslated region of Bamboo mosaic virus satellite RNA

The 3'-untranslated region (UTR) of RNA genomes of viruses and satellite RNAs plays essential roles in viral replication and transcription. The structural features of the 3'-UTR of the satellite RNA of Bamboo mosaic virus (satBaMV) involved in its replication were analyzed in this study. By the use of enzymatic probing, the secondary structure of satBaMV 3'-UTR was confirmed to comprise two small stem-loops (SLA and SLB), one large stem-loop (SLC), and a poly(A) tail of mainly 75-200 adenylate residues, which is similar to those on the genomic RNA of the helper virus, BaMV. Five sets of mutants of satBaMV were constructed to analyze the biological functions of the structural elements of the 3'-UTR. The data revealed that both the polyadenylation signal and poly(A) tail are required for satBaMV RNA replication. The structural conservation of SLA, SLB, and SLC is also important for efficient satBaMV accumulation, whereas the nucleotides in these regions may also possess sequence-specific functions. In contrast to the requirement for the accumulation of BaMV genomic RNA, mutations in the conserved hexanucleotide (ACCUAA) in the loop region of SLC had limited effect on the accumulation of satBaMV RNA. In addition, replacing the 5'-, 3'-UTR, or both regions of satBaMV by those of BaMV greatly decreased the accumulation of satBaMV RNA. Taken together, these data indicate that satBaMV might have adopted a 3'-UTR structure similar to that of BaMV but may have evolved distinct features for its efficient replication.

Higher-order RNA structural requirements and small-molecule induction of tombusvirus subgenomic mRNA transcription

Subgenomic (sg) mRNAs are small viral messages that are synthesized by polycistronic positive-strand RNA viruses to allow for the translation of certain viral proteins. Tombusviruses synthesize two such sg mRNAs via a premature termination mechanism. This transcriptional process involves the viral RNA-dependent RNA polymerase terminating minus-strand RNA synthesis prematurely at internal RNA signals during copying of the viral genome. The 3'-truncated minus-strand RNAs generated by the termination events then serve as templates for sg mRNA transcription. A higher-order RNA structure in the viral genome, located just upstream from the termination site, is a critical component of the RNA-based polymerase attenuation signal. Here, we have analyzed the role of this RNA structure in mediating efficient sg mRNA2 transcription. Our results include the following: (i) we define the minimum overall thermodynamic stability required for an operational higher-order RNA attenuation structure; (ii) we show that the distribution of stability within an attenuation structure affects its function; (iii) we establish that an RNA quadruplex structure can act as an effective attenuation structure; (iv) we prove that the higher-order RNA structure forms and functions in the plus strand; (v) we provide evidence that a specific attenuation structure-binding protein factor is not required for transcription; (vi) we demonstrate that sg mRNA transcription can be controlled artificially through small-molecule activation using RNA aptamer technology. These findings provide important new insights into the premature termination mechanism and present a novel approach to regulate the transcriptional process.

Complete nucleotide sequence of Nootka lupine vein-clearing virus

The complete genome sequence of Nootka lupine vein-clearing virus (NLVCV) was determined to be 4,172 nucleotides in length containing four open reading frames (ORFs) with a similar genetic organization of virus species in the genus Carmovirus, family Tombusviridae. The order and gene product size, starting from the 5'-proximal ORF consisted of: (1) polymerase/replicase gene, ORF1 (p27) and ORF1RT (readthrough) (p87), (2) movement proteins ORF2 (p7) and ORF3 (p9), and, (3) the 3'-proximal coat protein ORF4, (p37). The genomic 5'- and 3'-proximal termini contained a short (59 nt) and a relatively longer 405 nt untranslated region, respectively. The longer replicase gene product contained the GDD motif common to RNA-dependent RNA polymerases. Phylogenetically, NLVCV formed a subgroup with the following four carmoviruses when separately comparing the amino acids of the coat protein or replicase protein: Angelonia flower break virus (AnFBV), Carnation mottle virus (CarMV), Pelargonium flower break virus (PFBV), and Saguaro cactus virus (SgCV). Whole genome nucleotide analysis (percent identities) among the carmoviruses with NLVCV suggested a similar pattern. The species demarcation criteria in the genus Carmovirus for the amino acid sequence identity of the polymerase (<52%) and coat (<41%) protein genes restricted NLVCV as a distinct species, and instead, placed it as a tentative strain of CarMV, PFBV, or SgCV when both the polymerase and CP were used as the determining factors. In contrast, the species criteria that included different host ranges with no overlap and lack of serology relatedness between NLVCV and the carmoviruses, suggested that NLVCV was a distinct species. The relatively low cutoff percentages allowed for the polymerase and CP genes to dictate the inclusion/exclusion of a distinct carmovirus species should be reevaluated. Therefore, at this time we have concluded that NLVCV should be classified as a tentative new species in the genus Carmovirus, family Tombusviridae.

A multicomponent RNA-based control system regulates subgenomic mRNA transcription in a tombusvirus

During infections, positive-strand RNA tombusviruses transcribe two subgenomic (sg) mRNAs that allow for the expression of a subset of their genes. This process is thought to involve an unconventional mechanism involving the premature termination of the virally encoded RNA-dependent RNA polymerase while it is copying the virus genome. The 3' truncated minus strands generated by termination are then used as templates for sg mRNA transcription. In addition to requiring an extensive network of long-distance RNA-RNA interactions (H.-X. Lin and K. A. White, EMBO J. 23:3365-3374, 2004), the transcription of tombusvirus sg mRNAs also involves several additional RNA structures. In vivo analysis of these diverse RNA elements revealed that they function at distinct steps in the process by facilitating the formation or stabilization of the long-distance interactions, modulating minus-strand template production, or promoting the initiation of sg mRNA transcription. All of the RNA elements characterized could be readily incorporated into a premature termination model for sg mRNA transcription. Overall, the analyses revealed a complex system that displays a high level of structural integration and functional coordination. This multicomponent RNA-based control system may serve as a useful paradigm for understanding related transcriptional processes in other positive-sense RNA viruses.

Conformational organization of the 3' untranslated region in the tomato bushy stunt virus genome

The 3' untranslated regions (UTRs) of positive-strand RNA viruses often form complex structures that facilitate various viral processes. We have examined the RNA conformation of the 352 nucleotide (nt) long 3' UTR of the Tomato bushy stunt virus (TBSV) genome with the goal of defining both local and global structures that are important for virus viability. Gel mobility analyses of a 3'-terminal 81 nt segment of the 3' UTR revealed that it is able to form a compact RNA domain (or closed conformation) that is stabilized by a previously proposed tertiary interaction. RNA-RNA gel shift assays were used to provide the first physical evidence for the formation of this tertiary interaction and revealed that it represents the dominant or "default" structure in the TBSV genome. Further analysis showed that the tertiary interaction involves five base pairs, each of which contributes differently to overall complex stability. Just upstream from the 3'-terminal domain, a long-distance RNA-RNA interaction involving 3' UTR sequences was found to be required for efficient viral RNA accumulation in vivo and to also contribute to the formation of the 3'-terminal domain in vitro. Collectively, these results provide a comprehensive overview of the conformational and functional organization of the 3' UTR of the TBSV genome.

Structures required for poly(A) tail-independent translation overlap with, but are distinct from, cap-independent translation and RNA replication signals at the 3' end of Tobacco necrosis virus RNA

Tobacco necrosis necrovirus (TNV) RNA lacks both a 5' cap and a poly(A) tail but is translated efficiently, owing in part to a Barley yellow dwarf virus (BYDV)-like cap-independent translation element (BTE) in its 3' untranslated region (UTR). Here, we identify sequence downstream of the BTE that is necessary for poly(A) tail-independent translation in vivo by using RNA encoding a luciferase reporter gene flanked by viral UTRs. Deletions and point mutations caused loss of translation that was restored by adding a poly(A) tail, and not by adding a 5' cap. The two 3'-proximal stem-loops in the viral genome contribute to poly(A) tail-independent translation, as well as RNA replication. For all necroviruses, we predict a conserved 3' UTR secondary structure that includes the BTE at one end of a long helical axis and the stem-loops required for poly(A) tail-independent translation and RNA replication at the other end. This work shows that a viral genome can harbor distinct cap- and poly(A) tail-mimic sequences in the 3' UTR.

Insights into the selective pressures restricting Pelargonium flower break virus genome variability: Evidence for host adaptation

The molecular diversity of Pelargonium flower break virus (PFBV) was assessed using a collection of isolates from different geographical origins, hosts, and collecting times. The genomic region examined was 1,828 nucleotides (nt) long and comprised the coding sequences for the movement (p7 and p12) and the coat (CP) proteins, as well as flanking segments including the entire 3' untranslated region (3' UTR). Some constraints limiting viral heterogeneity could be inferred from sequence analyses, such as the conservation of the amino acid sequences of p7 and of the shell domain of the CP, the maintenance of a leucine zipper motif in p12, and the preservation of a particular folding in the 3' UTR. A remarkable covariation, involving five specific amino acid sites, was found in the CP of isolates largely propagated in the local lesion host Chenopodium quinoa and in the progeny of a PFBV variant subjected to serial passages in this host. Concomitant with this covariation, up to 30 nucleotide substitutions in a 1,428-nt region of the viral RNA could be attributable to C. quinoa-specific adaptation, representing one of the most outstanding cases of host-driven genome variation for a plant virus. Globally, the results indicate that the selective pressures exerted by the host play a critical role in shaping PFBV populations and that these populations are likely being selected for at both protein and RNA levels.

A cis-replication element functions in both orientations to enhance replication of Turnip crinkle virus

Turnip crinkle virus (TCV) (family Tombusviridae, genus Carmovirus) is a positive-sense RNA virus containing a 4054-base genome. Previous results indicated that insertion of Hairpin 4 (H4) into a TCV-associated satellite RNA enhanced replication 6-fold in vivo (Nagy, P., Pogany, J., Simon, A. E., 1999. EMBO J. 18:5653-5665). A detailed structural and functional analysis of H4 has now been performed to investigate its role in TCV replication. RNA structural probing of H4 in full-length TCV supported the sequence forming hairpin structures in both orientations in vitro. Deletion and mutational analyses determined that H4 is important for efficient accumulation of TCV in protoplasts, with a 98% reduction of genomic RNA levels when H4 was deleted. In vitro transcription using p88 [the TCV RNA-dependent RNA polymerase] demonstrated that H4 in its plus-sense orientation [H4(+)] caused a nearly 2-fold increase in RNA synthesis from a core hairpin promoter located on TCV plus-strands. H4 in its minus-sense orientation [H4(-)] stimulated RNA synthesis by 100-fold from a linear minus-strand promoter. Gel mobility shift assays indicated that p88 binds H4(+) and H4(-) with equal affinity, which was substantially greater than the binding affinity to the core promoters. These results support roles for H4(+) and H4(-) in TCV replication by enhancing syntheses of both strands through attracting the RdRp to the template.

Use of double-stranded RNA templates by the tombusvirus replicase in vitro: Implications for the mechanism of plus-strand initiation

Plus-stranded RNA viruses replicate efficiently in infected hosts producing numerous copies of the viral RNA. One of the long-standing mysteries in RNA virus replication is the occurrence and possible role of the double-stranded (ds)RNA formed between minus- and plus-strands. Using the partially purified Cucumber necrosis virus (CNV) replicase from plants and the recombinant RNA-dependent RNA polymerase (RdRp) of Turnip crinkle virus (TCV), in this paper, we demonstrate that both CNV replicase and the related TCV RdRp can utilize dsRNA templates to produce viral plus-stranded RNA in vitro. Sequence and structure of the dsRNA around the plus-strand initiation site had a significant effect on initiation, suggesting that initiation on dsRNA templates is a rate-limiting step. In contrast, the CNV replicase could efficiently synthesize plus-strand RNA on partial dsRNAs that had the plus-strand initiation promoter "exposed", suggesting that the polymerase activity of CNV replicase is strong enough to unwind extended dsRNA regions in the template during RNA synthesis. Based on the in vitro data, we propose that dsRNA forms might have functional roles during tombus- and carmovirus replication and the AU-rich nature of the terminus could be important for opening the dsRNA structure around the plus-strand initiation promoter for tombus- and carmoviruses and possibly many other positive-strand RNA viruses.

Infectious cDNA transcripts of Maize necrotic streak virus: infectivity and translational characteristics

Maize necrotic streak virus (MNeSV) is a unique member of the family Tombusviridae that is not infectious by leaf rub inoculation and has a coat protein lacking the protruding domain of aureusviruses, carmoviruses, and tombusviruses (Louie et al., Plant Dis. 84, 1133-1139, 2000). Completion of the MNeSV sequence indicated a genome of 4094 nt. RNA blot and primer extension analysis identified subgenomic RNAs of 1607 and 781 nt. RNA and protein sequence comparisons and RNA secondary structure predictions support the classification of MNeSV as the first monocot-infecting tombusvirus, the smallest tombusvirus yet reported. Uncapped transcripts from cDNAs were infectious in maize (Zea mays L.) protoplasts and plants. Translation of genomic and subgenomic RNA transcripts in wheat germ extracts indicated that MNeSV has a 3' cap-independent translational enhancer (3'CITE) located within the 3' 156 nt. The sequence, predicted structure, and the ability to function in vitro differentiate the MNeSV 3'CITE from that of Tomato bushy stunt virus.

Yeast as a model host to dissect functions of viral and host factors in tombusvirus replication

RNA replication is the central process during the infectious cycles of plus-stranded RNA viruses. Development of yeast as a model host and powerful in vitro assays with purified replicase complexes, together with reverse genetic approaches make tombusviruses, small plant RNA viruses, excellent systems to study fundamental aspects of viral RNA replication. Accordingly, in vitro approaches have led to the identification of protein-RNA interactions that are essential for template selection for replication and assembly of the functional viral replicase complexes. Moreover, genome-wide approaches and proteomics analyses have identified a new set of host proteins that affected tombusvirus replication. Overall, rapid progress in tombusvirus replication has revealed intriguing and complex nature of virus-host interactions, which make robust replication of tombusviruses possible. The knowledge obtained will likely stimulate development of new antiviral methods as well as other approaches that could make tombusviruses useful tools in biotechnological applications.

Structure and prevalence of replication silencer-3' terminus RNA interactions in Tombusviridae

Tombusviridae is a large positive-strand RNA virus family. Tomato bushy stunt virus (TBSV), the type virus of this family, has a genome ending with AGCCC(-OH), termed the 3'-complementary silencer sequence (3'CSS). The 3'CSS is able to base pair with a complementary internally-located sequence, 5'GGGCU, called the replication silencer element (RSE). In TBSV, previous compensatory mutational analysis of the RSE-3'CSS interaction showed it to be functionally important for viral RNA synthesis both in vitro and in vivo. However, these investigations also revealed that the RSE and 3'CSS are very sensitive to nucleotide changes, even when base pairing potential between the two elements is maintained. Consequently, an alternative investigative approach was used in this study where the wild-type sequences of these elements were preserved and their surrounding contexts were modified. Results from these analyses, using a TBSV DI RNA, revealed important new structural requirements necessary for the RSE and 3'CSS to operate in vivo. Collectively, the data suggest that accessibility of the elements and their proximity to adjoining stem structures are important functional parameters. Based on these findings, a working structural model for the TBSV RSE-3'CSS interaction is proposed that involves coaxial stacking of adjacent helices at either end of the RSE-3'CSS interaction. Components of this structural model are extendable to potential RSE-3'CSS interactions that were identified throughout Tombusviridae by comparative sequence analysis. This survey also revealed a significant level of diversity and modularity with respect to RSEs, 3'CSSs and their structural contexts and, moreover, suggests that RSE-3'CSS interactions are prevalent in Tombusviridae and related viruses.

Kinetics and functional studies on interaction between the replicase proteins of Tomato Bushy Stunt Virus: requirement of p33:p92 interaction for replicase assembly

The assembly of the functional replicase complex via protein:protein and RNA:protein interactions among the viral-coded proteins, host factors and the viral RNA on cellular membranes is a key step in the replication process of plus-stranded RNA viruses. In this work, we have characterized essential interactions between p33:p33 and p33:p92 replication proteins of Tomato bushy stunt virus (TBSV), a tombusvirus with a non-segmented, plus-stranded RNA genome. Surface plasmon resonance (SPR) measurements with purified recombinant p33 and p92 demonstrate that p33 interacts with p92 in vitro and that the interaction requires the S1 subdomain, whereas the S2 subdomain plays lesser function. Kinetic SPR analyses showed that binding of S1 subdomain to the C-terminal half of p33 takes place with moderate binding affinity in the nanomolar range whereas S2 subdomain binds to p33 with micromolar affinity. Using mutated p33 and p92 proteins, we identified critical amino acid residues within the p33:p92 interaction domain that play essential role in replication and the assembly of the tombusviral replicase. In addition, we show that interaction takes place between replication proteins of TBSV and the closely related Cucumber necrosis virus but not between TBSV and the more distantly related Turnip crinkle virus, suggesting that selective protein interactions might prevent the assembly of chimeric replicases carrying replication proteins from different viruses during mixed infections.

Role of an internal and two 3'-terminal RNA elements in assembly of tombusvirus replicase

Plus-strand RNA virus replication requires the assembly of the viral replicase complexes on intracellular membranes in the host cells. The replicase of Cucumber necrosis virus (CNV), a tombusvirus, contains the viral p33 and p92 replication proteins and possible host factors. In addition, the assembly of CNV replicase is stimulated in the presence of plus-stranded viral RNA (Z. Panaviene et al., J. Virol. 78:8254-8263, 2004). To define cis-acting viral RNA sequences that stimulate replicase assembly, we performed a systematic deletion approach with a model tombusvirus replicon RNA in Saccharomyces cerevisiae, which also coexpressed p33 and p92 replication proteins. In vitro replicase assays performed with purified CNV replicase preparations from yeast revealed critical roles for three RNA elements in CNV replicase assembly: the internal p33 recognition element (p33RE), the replication silencer element (RSE), and the 3'-terminal minus-strand initiation promoter (gPR). Deletion or mutagenesis of these elements reduced the activity of the CNV replicase to a minimal level. In addition to the primary sequences of gPR, RSE, and p33RE, formation of two alternative structures among these elements may also play a role in replicase assembly. Altogether, the role of multiple RNA elements in tombusvirus replicase assembly could be an important factor to ensure fidelity of template selection during replication.

Tomato bushy stunt virus: a resilient model system to study virus-plant interactions

SUMMARY Taxonomy: Tomato bushy stunt virus (TBSV) (Fig. 1) is the type species of the plant-infecting Tombusvirus genus in the family Tombusviridae. Physical properties: TBSV virions are non-enveloped icosahedral T = 3 particles assembled from 180 coat protein subunits (42 kDa) whose arrangement causes a granular appearance on the surface structure. The particles are approximately 33 nm in diameter and composed of 17% ribonucleic acid and 83% protein. Encapsidated within the virion is the TBSV genome that consists of a positive-sense single-stranded RNA of approximately 4.8 kb, which lacks the 5'-cap or 3'-poly(A) tail typical for eukaryotic mRNAs.

HOST RANGE

In nature, TBSV has a fairly restricted host range, mostly encompassing a few dicotyledonous species in separate families, and affected agricultural crops comprise primarily vegetables. The experimental host range is broad, with over 120 plant species in more than 20 different families reported to be susceptible although in most plants the infection often remains localized around the site of entry. The differences between hosts with regards to requirements for cell-to-cell and long-distance movement have led to the development of TBSV as an attractive model system to obtain general insights into RNA transport through plants.

SYMPTOMS

SYMPTOMS induced by TBSV are largely dependent on the host genotype; they can vary from necrotic and chlorotic lesions, to a systemic mild or severe mosaic, or they may culminate in a lethal necrosis. The original TBSV isolates from tomato plants caused a mottle, crinkle and downward curling of leaves with the youngest leaves exhibiting tip necrosis upon systemic infection. Tomato fruit yield can be greatly reduced by virus infection. Plants may be stunted and a proliferation of lateral shoots leads to a bushy appearance of the infected tomato plants, hence the nomenclature of the pathogen. Useful sites: http://image.fs.uidaho.edu/vide/descr825.htm; http://www.ictvdb.rothamsted.ac.uk/ICTVdB/74010001.htm (general information); http://mmtsb.scripps.edu/viper/info_page.php?vipPDB=2tbv (structural information).

Structural and functional analysis of the cis-acting elements required for plus-strand RNA synthesis of Bamboo mosaic virus

Bamboo mosaic virus (BaMV) has a single-stranded positive-sense RNA genome. The secondary structure of the 3'-terminal sequence of the minus-strand RNA has been predicted by MFOLD and confirmed by enzymatic structural probing to consist of a large, stable stem-loop and a small, unstable stem-loop. To identify the promoter for plus-strand RNA synthesis in this region, transcripts of 39, 77, and 173 nucleotides (Ba-39, Ba-77, and Ba-173, respectively) derived from the 3' terminus of the minus-strand RNA were examined by an in vitro RNA-dependent RNA polymerase assay for the ability to direct RNA synthesis. Ba-77 and Ba-39 appeared to direct the RNA synthesis efficiently, while Ba-173 failed. Ba-77/delta5, with a deletion of the 3'-terminal UUUUC sequence in Ba-77, directed the RNA synthesis only to 7% that of Ba-77. However, Ba-77/delta16 and Ba-77/delta31, with longer deletions but preserving the terminal UUUUC sequence of Ba-77, restored the template activity to about 60% that of the wild type. Moreover, mutations that changed the sequence in the stem of the large stem-loop interfered with the efficiency of RNA synthesis and RNA accumulation in vivo. The mutant with an internal deletion in the region between the terminal UUUUC sequence and the large stem-loop reduced the viral RNA accumulation in protoplasts, but mutants with insertions did not. Taken together, these results suggest that three cis-acting elements in the 3' end of the minus-strand RNA, namely, the terminal UUUUC sequence, the sequence in the large stem-loop, and the distance between these two regions, are involved in modulating the efficiency of BaMV plus-strand viral RNA synthesis.

The p92 polymerase coding region contains an internal RNA element required at an early step in Tombusvirus genome replication

The replication of positive-strand RNA viral genomes involves various cis-acting RNA sequences. Generally, regulatory RNA sequences are present at or near genomic termini; however, internal replication elements (IREs) also exist. Here we report the structural and functional characterization of an IRE present in the readthrough portion of the p92 polymerase gene of Tomato bushy stunt virus. Analysis of this element in the context of a noncoding defective interfering RNA revealed a functional core structure composed of two noncontiguous segments of sequence that interact with each other to form an extended helical conformation. IRE activity required maintenance of several base-paired sections as well as two distinct structural features: (i) a short, highly conserved segment that can potentially form two different and mutually exclusive structures and (ii) an internal loop that contains a critical CC mismatch. The IRE was also shown to play an essential role within the context of the viral genome. In vivo analysis with novel RNA-based temperature-sensitive genomic mutants and translationally active subgenomic viral replicons revealed the following about the IRE: (i) it is active in the positive strand, (ii) it is dispensable late in the viral RNA replication process, and (iii) it is functionally inhibited by active translation over its sequence. Together, these results suggest that IRE activity is required in the cytosol at an early step in the viral replication process, such as template recruitment and/or replicase complex assembly.

Specific binding of tombusvirus replication protein p33 to an internal replication element in the viral RNA is essential for replication

The mechanism of template selection for genome replication in plus-strand RNA viruses is poorly understood. Using the prototypical tombusvirus, Tomato bushy stunt virus (TBSV), we show that recombinant p33 replicase protein binds specifically to an internal replication element (IRE) located within the p92 RNA-dependent RNA polymerase coding region of the viral genome. Specific binding of p33 to the IRE in vitro depends on the presence of a C.C mismatch within a conserved RNA helix. Interestingly, the absence of the p33:p33/p92 interaction domain in p33 prevented specific but allowed nonspecific RNA binding, suggesting that a multimeric form of this protein is involved in the IRE-specific interaction. Further support for the selectivity of p33 binding in vitro was provided by the inability of the replicase proteins of the closely related Turnip crinkle virus and distantly related Hepatitis C virus to specifically recognize the TBSV IRE. Importantly, there was also a strong correlation between p33:IRE complex formation in vitro and viral replication in vivo, where mutations in the IRE that disrupted selective p33 binding in vitro also abolished TBSV RNA replication both in plant and in Saccharomyces cerevisiae cells. Based on these findings and the other known properties of p33 and the IRE, it is proposed that the p33:IRE interaction provides a mechanism to selectively recruit viral RNAs into cognate viral replicase complexes. Since all genera in Tombusviridae encode comparable replicase proteins, these results may be relevant to other members of this large virus family.

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.

Importance of sequence and structural elements within a viral replication repressor

Efficient replication of plus-strand RNA viruses requires a 3' proximal core promoter and an increasingly diverse inventory of supporting elements such as enhancers, repressors, and 5' terminal sequences. While core promoters have been well characterized, much less is known about structure-functional relationships of these supporting elements. Members of the genus Carmovirus family Tombusviridae contain a hairpin (H5) proximal to the core promoter that functions as a repressor of minus-strand synthesis in vitro through an interaction between its large symmetrical internal loop (LSL) and 3' terminal bases. Turnip crinkle virus satellite RNA satC with the H5 of carmovirus Japanese iris necrosis virus or Cardamine chlorotic fleck virus (CCFV) did not accumulate to detectable levels even though 3' end base-pairing would be maintained. Replacement of portions of the satC H5 with analogous portions from CCFV revealed that the cognate LSL and lower stem were of greater importance for satC accumulation than the upper stem. In vivo selex of the H5 upper stem and terminal GNRA tetraloop revealed considerable plasticity in the upper stem, including the presence of three- to six-base terminal loops, allowed for H5 function. In vivo selex of the lower stem revealed that both a stable stem and specific base pairs contributed to satC fitness. Surprisingly, mutations in H5 had a disproportionate effect on plus-strand accumulation that was unrelated to the stability of the mutant plus-strands. In addition, fitness to accumulate in plants did not always correlate with enhanced ability to accumulate in protoplasts, suggesting that H5 may be multifunctional.

Structural properties of a multifunctional T-shaped RNA domain that mediate efficient tomato bushy stunt virus RNA replication

In positive-strand RNA viruses, 5' untranslated regions (5' UTRs) mediate many essential viral processes, including genome replication. Previously, we proposed that the 5'-terminal portion of the genomic leader sequence of Tomato bushy stunt virus (TBSV) forms an RNA structure containing a 3-helix junction, termed the T-shaped domain (TSD). In the present study, we have carried out structure-function analysis of the proposed TSD and have confirmed an important role for this domain in mediating efficient viral RNA amplification. Using a model TBSV defective interfering RNA replicon and a protoplast system, we demonstrated that various TSD subelements contribute to the efficiency of viral RNA replication. In particular, the stabilities of all three stems (S1, S2, and S4) forming the 3-helix junction are important, while stem-loop 3-a terminal extension of S2-is largely dispensable. Additionally, some of the sequences forming the 3-helix junction are required in an identity-dependent manner. Thus, both secondary structure and nucleotide identity are important for TSD-mediated viral RNA replication. Importantly, these results are fully consistent with the dual functions we defined previously for the sequences corresponding to loops 3 and 4, respectively, in facilitating 5' cap- and 3' poly(A) tail-independent translation of the genome by forming a loop-loop interaction with the 3'-proximal translational enhancer and in mediating viral RNA replication through formation of a pseudoknot with the adjacent downstream RNA domain. Also, since comparable TSDs and associated interactions are predicted in the 5' UTRs of all sequenced Aureusvirus genomes, members of at least one other genus in the family Tombusviridae appear to utilize this type of multifunctional RNA domain.

Expression of tombusvirus open reading frames 1 and 2 is sufficient for the replication of defective interfering, but not satellite, RNA

Yeast cells co-expressing the replication proteins p36 and p95 of Carnation Italian ringspot virus (CIRV) support the RNA-dependent replication of several defective interfering (DI) RNAs derived from either the genome of CIRV or the related Cymbidium ringspot virus (CymRSV), but not the replication of a satellite RNA (sat RNA) originally associated with CymRSV. DI, but not sat RNA, was replicated in yeast cells co-expressing both DI and sat RNA. Using transgenic Nicotiana benthamiana plants constitutively expressing CymRSV replicase proteins (p33 and p92), or transiently expressing either these proteins or CIRV p36 and p95, it was shown that expression of replicase proteins alone was also not sufficient for the replication of sat RNA in plant cells. However, it was also shown that replicating CIRV genomic RNA deletion mutants encoding only replicase proteins could sustain replication of sat RNA in plant cells. These results suggest that sat RNA has a replication strategy differing from that of genomic and DI RNAs, for it requires the presence of a cis-replicating genome acting as a trans-replication enhancer.

Analysis of a viral replication repressor: sequence requirements for a large symmetrical internal loop

Nearly all members of the Carmovirus genus contain a structurally conserved 3' proximal hairpin (H5) with a large internal symmetrical loop (LSL). H5 has been identified as a repressor of minus-strand synthesis in a satellite RNA (satC), which shares partial sequence similarity with its helper virus Turnip crinkle virus (TCV). Repression was due to sequestration of the 3' end mediated by base pairing between 3' end sequence and the 3' side of the LSL (G. Zhang, J. Zhang and A. E. Simon, J. Virol., in press). Single site mutational analysis and in vivo genetic selection (SELEX) of the 14 base satC H5 LSL indicated specific sequences in the middle and upper regions on both sides of the LSL are necessary for robust satC accumulation in plants and protoplasts. Fitness of wild-type satC and satC LSL mutants to accumulate in plants, however, did not necessarily correlate with the ability of these RNAs to replicate in protoplasts. This suggests that the LSL might be involved in processes in addition to repression of minus-strand synthesis.

Interaction between the replicase proteins of Tomato Bushy Stunt virus in vitro and in vivo

Tomato bushy stunt virus (TBSV), a tombusvirus with a non-segmented, plus-stranded RNA genome, codes for p33 and p92 replicase proteins. The sequence of p33 overlaps with the N-terminal domain of p92, which also contains the signature motifs of RNA-dependent RNA polymerases (RdRps) in its non-overlapping C-terminal portion. In this research, we demonstrate in vitro interactions between p33:p33 and p33:p92 using surface plasmon resonance analysis with purified recombinant p33 and p92. The sequence in p33 involved in the above protein-protein interactions was mapped to the C-terminal region, which also contains an RNA-binding site. Using the yeast two-hybrid assay, we confirmed that two short regions within p33 could promote p33:p33 and p33:p92 interactions in vivo. Mutations in either p33 or p92 within the short regions involved in p33:p33 and p33:p92 interactions decreased the replication of a TBSV defective interfering RNA in yeast, a model host, supporting the significance of these protein interactions in tombusvirus replication.

Purification of the cucumber necrosis virus replicase from yeast cells: role of coexpressed viral RNA in stimulation of replicase activity

Purified recombinant viral replicases are useful for studying the mechanism of viral RNA replication in vitro. In this work, we obtained a highly active template-dependent replicase complex for Cucumber necrosis tombusvirus (CNV), which is a plus-stranded RNA virus, from Saccharomyces cerevisiae. The recombinant CNV replicase showed properties similar to those of the plant-derived CNV replicase (P. D. Nagy and J. Pogany, Virology 276:279-288, 2000), including the ability (i). to initiate cRNA synthesis de novo on both plus- and minus-stranded templates, (ii). to generate replicase products that are shorter than full length by internal initiation, and (iii). to perform primer extension from the 3' end of the template. We also found that isolation of functional replicase required the coexpression of the CNV p92 RNA-dependent RNA polymerase and the auxiliary p33 protein in yeast. Moreover, coexpression of a viral RNA template with the replicase proteins in yeast increased the activity of the purified CNV replicase by 40-fold, suggesting that the viral RNA might promote the assembly of the replicase complex and/or that the RNA increases the stability of the replicase. In summary, this paper reports the first purified recombinant tombusvirus replicase showing high activity and template dependence, a finding that will greatly facilitate future studies on RNA replication in vitro.

Repression and derepression of minus-strand synthesis in a plus-strand RNA virus replicon

Plus-strand viral RNAs contain sequences and structural elements that allow cognate RNA-dependent RNA polymerases (RdRp) to correctly initiate and transcribe asymmetric levels of plus and minus strands during RNA replication. cis-acting sequences involved in minus-strand synthesis, including promoters, enhancers, and, recently, transcriptional repressors (J. Pogany, M. R. Fabian, K. A. White, and P. D. Nagy, EMBO J. 22:5602-5611, 2003), have been identified for many viruses. A second example of a transcriptional repressor has been discovered in satC, a replicon associated with turnip crinkle virus. satC hairpin 5 (H5), located proximal to the core hairpin promoter, contains a large symmetrical internal loop (LSL) with sequence complementary to 3'-terminal bases. Deletion of satC 3'-terminal bases or alteration of the putative interacting bases enhanced transcription in vitro, while compensatory exchanges between the LSL and 3' end restored near-normal transcription. Solution structure analysis indicated that substantial alteration of the satC H5 region occurs when the three 3'-terminal cytidylates are deleted. These results indicate that H5 functions to suppress synthesis of minus strands by sequestering the 3' terminus from the RdRp. Alteration of a second sequence strongly repressed transcription in vitro and accumulation in vivo, suggesting that this sequence may function as a derepressor to free the 3' end from interaction with H5. Hairpins with similar sequence and/or structural features that contain sequence complementary to 3'-terminal bases, as well as sequences that could function as derepressors, are located in similar regions in other carmoviruses, suggesting a general mechanism for controlling minus-strand synthesis in the genus.

5'-3' RNA-RNA interaction facilitates cap- and poly(A) tail-independent translation of tomato bushy stunt virus mrna: a potential common mechanism for tombusviridae

Tomato bushy stunt virus (TBSV) is the prototypical member of the genus Tombusvirus in the family Tombusviridae. The (+)-strand RNA genome of TBSV lacks both a 5' cap and a 3' poly(A) tail and instead contains a 3'-terminal RNA sequence that acts as a cap-independent translational enhancer (3' CITE). In this study, we have determined the RNA secondary structure of the translation-specific central segment of the 3' CITE, termed region 3.5 (R3.5). MFOLD structural modeling combined with solution structure mapping and comparative sequence analysis indicate that R3.5 adopts a branched structure that contains three major helices. Deletion and substitution studies revealed that two of these extended stem-loop (SL) structures are essential for 3' CITE activity in vivo. In particular, the terminal loop of one of these SLs, SL-B, was found to be critical for translation. Compensatory mutational analysis showed that SL-B functions by base pairing with another SL, SL3, in the 5' untranslated region of the TBSV genome. Thus, efficient translation of TBSV mRNA in vivo requires a 5'-3' RNA-RNA interaction that effectively circularizes the message. Similar types of interactions are also predicted to occur in TBSV subgenomic mRNAs between their 5' untranslated regions and the 3' CITE, and both genomic and subgenomic 5'-3' interactions are well conserved in all members of the genus Tombusvirus. In addition, a survey of other genera in Tombusviridae revealed the potential for similar 5'-3' RNA-RNA-based interactions in their viral mRNAs, suggesting that this mechanism extends throughout this large virus family.

Prediction of consensus RNA secondary structures including pseudoknots

Most functional RNA molecules have characteristic structures that are highly conserved in evolution. Many of them contain pseudoknots. Here, we present a method for computing the consensus structures including pseudoknots based on alignments of a few sequences. The algorithm combines thermodynamic and covariation information to assign scores to all possible base pairs, the base pairs are chosen with the help of the maximum weighted matching algorithm. We applied our algorithm to a number of different types of RNA known to contain pseudoknots. All pseudoknots were predicted correctly and more than 85 percent of the base pairs were identified.

Advances in the molecular biology of tombusviruses: gene expression, genome replication, and recombination

The tombusviruses are among the most extensively studied messenger-sensed RNA plant viruses. Over the past decade, there have been numerous important advances in our understanding of the molecular biology of members in this genus. Unlike most other RNA viruses, the synthesis of tombusvirus proteins has been found to involve an atypical translational mechanism related to the uncapped and nonpolyadenylated nature of their genomes. Tombusviruses also appear to employ an unusual mechanism for transcription of the sg mRNAs that template translation of a subset of their viral proteins. In addition to these new insights into tombusvirus gene expression, there has also been significant progress made in our understanding of tombusvirus RNA replication. These studies have been facilitated greatly by small genome-derived RNA replicons, referred to as defective interfering RNAs. In addition, the development of an in vitro system to study viral RNA synthesis has allowed for dissection of some of the steps involved in the replication process. Another exciting recent advance has been the creation of yeast-based systems that support amplification of tombusvirus RNA replicons and will allow the identification of host factors involved in viral RNA synthesis. Lastly, the recombinogenic nature of tombusvirus genomes has made them ideal systems for studying RNA-RNA recombination and genetic rearrangements, both in vivo and in vitro. In this review, we compile recent information on each of the aforementioned processes-translation, transcription, replication and recombination-and discuss the significance of the results.

A replication silencer element in a plus-strand RNA virus

Replication represents a key step in the infectious cycles of RNA viruses. Here we describe a regulatory RNA element, termed replication silencer, that can down-regulate complementary RNA synthesis of a positive-strand RNA virus via an RNA-RNA interaction. This interaction occurs between the 5-nucleotide-long, internally positioned replication silencer and the extreme 3'-terminus of the viral RNA comprising part of the minimal minus-strand initiation promoter. Analysis of RNA synthesis in vitro, using model defective interfering (DI) RNA templates of tomato bushy stunt virus and a partially purified, RNA-dependent RNA polymerase preparation from tombusvirus-infected plants, revealed that this interaction inhibits minus-strand synthesis 7-fold. This functional interaction was supported further by: (i) RNA structure probing; (ii) phylogenetic analysis; (iii) inhibition of activity by short complementary DNAs; and (iv) compensatory mutational analysis. The silencer was found to be essential for accumulation of DI RNAs in protoplasts, indicating that it serves an important regulatory role(s) in vivo. Because similar silencer-promoter interactions are also predicted in other virus genera, this type of RNA-based regulatory mechanism may represent a widely utilized strategy for modulating replication.