The role of the pseudoknot at the 3' end of turnip yellow mosaic virus RNA in minus-strand synthesis by the viral RNA-dependent RNA polymerase

The Functional Roles of the Cis-acting Elements in Bamboo mosaic virus RNA Genome

Bamboo mosaic virus (BaMV), which belongs to the genus Potexvirus in the family Alphaflexiviridae, has a single-stranded positive-sense RNA genome that is approximately 6400 nucleotides (nts) in length. Positive-sense RNA viruses can use genomic RNA as a template for translation and replication after entering a suitable host cell. Furthermore, such viral RNA is recognized by capsid protein for packaging and by viral movement protein(s) or the movement protein complex for cell-to-cell and systemic movement. Hence, viral RNA must contain signals for different functions to complete the viral infection cycle. In this review, we examine various cis-acting elements in the genome of BaMV. The highly structured 3' untranslated region (UTR) of the BaMV genomic RNA plays multiple roles in the BaMV infection cycle, including targeting chloroplasts for RNA replication, providing an initiation site for the synthesis of minus-strand RNA, signaling for polyadenylation, and directing viral long-distance movement. The nt at the extreme 3' end and the structure of the 3'-terminus of minus-strand RNA are involved in the initiation of plus-strand genomic RNA synthesis. Both these regions have been mapped and reported to interact with the viral-encoded RNA-dependent RNA polymerase. Moreover, the sequences upstream of open reading frames (ORFs) 2, 3, and 5 are involved in regulating subgenomic RNA synthesis. The cis-acting elements that were identified in BaMV RNA are discussed and compared with those of other potexviruses.

A domain-based model for predicting large and complex pseudoknotted structures

Pseudoknotted structures play important structural and functional roles in RNA cellular functions at the level of transcription, splicing and translation. However, the problem of computational prediction for large pseudoknotted folds remains. Here we develop a domain-based method for predicting complex and large pseudoknotted structures from RNA sequences. The model is based on the observation that large RNAs can be separated into different structural domains. The basic idea is to first identify the domains and then predict the structures for each domain. Assembly of the domain structures gives the full structure. The use of the domain-based approach leads to a reduction of computational time by a factor of about ~N ( 2) for an N-nt sequence. As applications of the model, we predict structures for a variety of RNA systems, such as regions in human telomerase RNA (hTR), internal ribosome entry site (IRES) and HIV genome. The lengths of these sequences range from 200-nt to 400-nt. The results show good agreements with the experiments.

SARNA-Predict: accuracy improvement of RNA secondary structure prediction using permutation-based simulated annealing

Ribonucleic acid (RNA), a single-stranded linear molecule, is essential to all biological systems. Different regions of the same RNA strand will fold together via base pair interactions to make intricate secondary and tertiary structures that guide crucial homeostatic processes in living organisms. Since the structure of RNA molecules is the key to their function, algorithms for the prediction of RNA structure are of great value. In this article, we demonstrate the usefulness of SARNA-Predict, an RNA secondary structure prediction algorithm based on Simulated Annealing (SA). A performance evaluation of SARNA-Predict in terms of prediction accuracy is made via comparison with eight state-of-the-art RNA prediction algorithms: mfold, Pseudoknot (pknotsRE), NUPACK, pknotsRG-mfe, Sfold, HotKnots, ILM, and STAR. These algorithms are from three different classes: heuristic, dynamic programming, and statistical sampling techniques. An evaluation for the performance of SARNA-Predict in terms of prediction accuracy was verified with native structures. Experiments on 33 individual known structures from eleven RNA classes (tRNA, viral RNA, antigenomic HDV, telomerase RNA, tmRNA, rRNA, RNaseP, 5S rRNA, Group I intron 23S rRNA, Group I intron 16S rRNA, and 16S rRNA) were performed. The results presented in this paper demonstrate that SARNA-Predict can out-perform other state-of-the-art algorithms in terms of prediction accuracy. Furthermore, there is substantial improvement of prediction accuracy by incorporating a more sophisticated thermodynamic model (efn2).

Multi-domain packing in the aminoacylatable 3' end of a plant viral RNA

Turnip yellow mosaic virus (TYMV) contains a tRNA-like structure (TLS) in its 3' untranslated region (3' UTR). This highly structured element induces valylation of the viral RNA by host cell enzymes and is important for virus proliferation. Directly upstream of the TYMV TLS is an upstream pseudoknot domain (UPD) that has been considered to be structurally distinct from the TLS. However, using a combination of functional, biochemical, and biophysical assays, we show that the entire 3' UTR of the viral genome is a single structured element in the absence of cellular protein. This packing architecture stabilizes the RNA structure and creates a better substrate for aminoacylation, and thus the UPD and TLS are functionally and structurally coupled. It has been proposed that the TYMV TLS acts as a molecular switch between translation and replication. Our results suggest that this putative switch could be based on structural changes within the global architecture of the UTR induced by interactions with the ribosome. The TYMV TLS.UPD might demonstrate how RNA structural plasticity can play a role in regulation of biological processes.

Predicting structures and stabilities for H-type pseudoknots with interhelix loops

RNA pseudoknots play a critical role in RNA-related biology from the assembly of ribosome to the regulation of viral gene expression. A predictive model for pseudoknot structure and stability is essential for understanding and designing RNA structure and function. A previous statistical mechanical theory allows us to treat canonical H-type RNA pseudoknots that contain no intervening loop between the helices (see S. Cao and S.J. Chen [2006] in Nucleic Acids Research, Vol. 34; pp. 2634-2652). Biologically significant RNA pseudoknots often contain interhelix loops. Predicting the structure and stability for such more-general pseudoknots remains an unsolved problem. In the present study, we develop a predictive model for pseudoknots with interhelix loops. The model gives conformational entropy, stability, and the free-energy landscape from RNA sequences. The main features of this new model are the computation of the conformational entropy and folding free-energy base on the complete conformational ensemble and rigorous treatment for the excluded volume effects. Extensive tests for the structural predictions show overall good accuracy with average sensitivity and specificity equal to 0.91 and 0.91, respectively. The theory developed here may be a solid starting point for first-principles modeling of more complex, larger RNAs.

Reinitiated viral RNA-dependent RNA polymerase resumes replication at a reduced rate

RNA-dependent RNA polymerases (RdRP) form an important class of enzymes that is responsible for genome replication and transcription in RNA viruses and involved in the regulation of RNA interference in plants and fungi. The RdRP kinetics have been extensively studied, but pausing, an important regulatory mechanism for RNA polymerases that has also been implicated in RNA recombination, has not been considered. Here, we report that RdRP experience a dramatic, long-lived decrease in its elongation rate when it is reinitiated following stalling. The rate decrease has an intriguingly weak temperature dependence, is independent of both the nucleotide concentration during stalling and the length of the RNA transcribed prior to stalling; however it is sensitive to RNA structure. This allows us to delineate the potential factors underlying this irreversible conversion of the elongation complex to a less active mode.

In vitro replication of Bamboo mosaic virus satellite RNA

An in vitro system was applied to analyze the replication of a satellite RNA of Bamboo mosaic virus (BaMV), designated satBaMV RNA, using solubilized membrane-bound RNA-dependent RNA polymerase (RdRp) complexes isolated from BaMV-infected Nicotiana benthamiana. After removal of endogenous templates, the RdRp complexes of BaMV catalyzed RNA synthesis upon the addition of the full-length positive (+)- or negative (-)-strand satBaMV RNA transcripts used as templates. Both (+)- and (-)-satBaMV RNA products were detected when only the (+)-satBaMV RNA was used as a template in the in vitro RdRp assays, which further demonstrated the capability of the RdRp preparation to complete the replication cycles of satBaMV RNAs. In addition, use of 5' rapid amplification of cDNA ends and DNA sequencing showed that the BaMV RdRp preparation could specifically recognize the promoter sequences in the (-)-satBaMV RNA for accurate initiation of (+)-satBaMV RNA synthesis. The results suggested that the same enzyme complexes could be used for the replication of both BaMV genomic and satBaMV RNAs. The soluble and template-dependent RdRp could be further used in mechanistic studies, such as those analyzing the cis-elements and candidate host factors required for satBaMV RNA replication in vitro.

HotKnots: heuristic prediction of RNA secondary structures including pseudoknots

We present HotKnots, a new heuristic algorithm for the prediction of RNA secondary structures including pseudoknots. Based on the simple idea of iteratively forming stable stems, our algorithm explores many alternative secondary structures, using a free energy minimization algorithm for pseudoknot free secondary structures to identify promising candidate stems. In an empirical evaluation of the algorithm with 43 sequences taken from the Pseudobase database and from the literature on pseudoknotted structures, we found that overall, in terms of the sensitivity and specificity of predictions, HotKnots outperforms the well-known Pseudoknots algorithm of Rivas and Eddy and the NUPACK algorithm of Dirks and Pierce, both based on dynamic programming approaches for limited classes of pseudoknotted structures. It also outperforms the heuristic Iterated Loop Matching algorithm of Ruan and colleagues, and in many cases gives better results than the genetic algorithm from the STAR package of van Batenburg and colleagues and the recent pknotsRG-mfe algorithm of Reeder and Giegerich. The HotKnots algorithm has been implemented in C/C++ and is available from http://www.cs.ubc.ca/labs/beta/Software/HotKnots.

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.

Feline calicivirus VP2 is essential for the production of infectious virions

The third open reading frame (ORF3) located at the 3' end of the genomic RNA of feline calicivirus (FCV) encodes a small (12.2-kDa) minor structural protein of 106 amino acids designated VP2. Point mutations and deletions were introduced into an infectious FCV cDNA clone in order to evaluate the functional importance of ORF3 and its encoded protein, VP2. Deletion of the entire ORF3 sequence was lethal for the virus, and evidence was found for strong selective pressure to produce the VP2 protein. Extended deletions in the 5' end and small deletions in the 3' end of ORF3, as well as the introduction of stop codons into the ORF3 sequence, were tolerated by the viral replication machinery, but infectious virus could not be recovered. Infectious virus particles could be rescued from a full-length FCV cDNA clone encoding a nonfunctional VP2 when VP2 was provided in trans from a eukaryotic expression plasmid. Our data indicate that VP2, a protein apparently unique to the caliciviruses, is essential for productive replication that results in the synthesis and maturation of infectious virions and that the ORF3 nucleotide sequence itself overlaps a cis-acting RNA signal at the genomic 3' end.

Design, implementation and evaluation of a practical pseudoknot folding algorithm based on thermodynamics

BACKGROUND

The general problem of RNA secondary structure prediction under the widely used thermodynamic model is known to be NP-complete when the structures considered include arbitrary pseudoknots. For restricted classes of pseudoknots, several polynomial time algorithms have been designed, where the O(n6)time and O(n4) space algorithm by Rivas and Eddy is currently the best available program.

RESULTS

We introduce the class of canonical simple recursive pseudoknots and present an algorithm that requires O(n4) time and O(n2) space to predict the energetically optimal structure of an RNA sequence, possible containing such pseudoknots. Evaluation against a large collection of known pseudoknotted structures shows the adequacy of the canonization approach and our algorithm.

CONCLUSIONS

RNA pseudoknots of medium size can now be predicted reliably as well as efficiently by the new algorithm.

The 5'-proximal hairpin of turnip yellow mosaic virus RNA: its role in translation and encapsidation

The RNA genome of turnip yellow mosaic virus (TYMV) consists of more than 6,000 nucleotides. During a study of the roles of the two hairpins located in its 90-nucleotide 5' untranslated region, it was observed that stabilization of the 5'-proximal hairpin leads to a delay in the development of symptoms on plants. This delay in symptom development for both locally and systemically infected leaves was found to be dependent on a change in the free energy of the hairpin caused by introduced mutations. A protoplast transfection assay revealed that the accumulation of plus-strand full-length RNA and subgenomic RNA, as well as protein expression levels, was affected by hairpin stability. Stabilization of this hairpin inhibited translation. A model is proposed in which a destabilized 5'-proximal hairpin allows maximal translation of the viral proteins. It is suggested that this hairpin may exist in close proximity to the 5' cap as long as its stability is low enough to enable translation. However, at an acidic pH, the hairpin structure becomes more stable and is functionally transformed into the initiation signal for viral packaging. Slightly acidic conditions can be found in chloroplasts, where TYMV assembly is driven by a low pH generated by active photosynthesis.

Cis-acting regulatory elements in the potato virus X 3' non-translated region differentially affect minus-strand and plus-strand RNA accumulation

The 72nt 3' non-translated region (NTR) of potato virus X (PVX) RNA is identical in all sequenced PVX strains and contains sequences that are conserved among all potexviruses. Computer folding of the 3' NTR sequence predicted three stem-loop structures (SL1, SL2, and SL3 in the 3' to 5' direction), which generally were supported by solution structure analyses. The importance of these sequence and/or structural elements to PVX RNA accumulation was further analyzed by inoculation of Nicotiana tabacum (NT-1) protoplasts with PVX transcripts containing mutations in the 3' NTR. Analyses of RNA accumulation by S(1) nuclease protection indicated that multiple sequence elements throughout the 3' NTR were important for minus-strand RNA accumulation. Formation of SL3 was required for accumulation of minus-strand RNA, whereas SL1 and SL2 formation were less important. However, sequences within all of these predicted structures were required for minus-strand RNA accumulation, including a conserved hexanucleotide sequence element in the loop of SL3, and the CU nucleotide in a U-rich sequence within SL2. In contrast, 13 nucleotides that were predicted to reside in SL1 could be deleted without any significant reduction in minus or plus-strand RNA levels. Potential polyadenylation signals (near upstream elements; NUEs) in the 3' NTR of PVX RNA were more important for plus-strand RNA accumulation than for minus-strand RNA accumulation. In addition, one of these NUEs overlapped with other sequence required for optimal minus-strand RNA levels. These data indicate that the PVX 3' NTR contains multiple, overlapping elements that influence accumulation of both minus and plus-strand RNA.

The partial purified RNA-dependent RNA polymerases from bamboo mosaic potexvirus and potato virus X infected plants containing the template-dependent activities

RNA-dependent RNA polymerases (RdRp) isolated from bamboo mosaic potexvirus (BaMV) and potato virus X infected Nicotiana benthamiana plants and solubilized with the detergent NP-40, generated a full-length genomic and two subgenomic double-stranded RNAs of respective viruses in an in vitro RdRp assay containing endogenous RNA templates. Template-dependent and species-specific RdRp activity could be detected after the removal of endogenous RNA templates. The 3' untranslated regions (UTR) containing a stretch of 40 adenylate residues were shown to be an efficient exogenous RNA template for in vitro RdRp reactions. Solution hybridization and nuclease digestion studies revealed that the products transcribed in vitro were minus-sense. Besides using the 3' UTR for minus-sense RNA synthesis, the BaMV RdRp can also recognize 3' terminal 77 nucleotides of the minus-strand for plus-sense RNA synthesis. Promoter studies with BaMV RdRp showed that domain D containing the potexviral hexamer motif of the 3' UTR would be the major contributor of minus-sense RNA synthesis in vitro. On the other hand, the pseudoknot domain containing the poly(A) sequences would be sufficient for minus-sense RNA synthesis.

In vitro RNA synthesis from exogenous dengue viral RNA templates requires long range interactions between 5'- and 3'-terminal regions that influence RNA structure

Viral replicases of many positive-strand RNA viruses are membrane-bound complexes of cellular and viral proteins that include viral RNA-dependent RNA polymerase (RdRP). The in vitro RdRP assay system that utilizes cytoplasmic extracts from dengue viral-infected cells and exogenous RNA templates was developed to understand the mechanism of viral replication in vivo. Our results indicated that in vitro RNA synthesis at the 3'-untranslated region (UTR) required the presence of the 5'-terminal region (TR) and the two cyclization (CYC) motifs suggesting a functional interaction between the TRs. In this study, using a psoralen-UV cross-linking method and an in vitro RdRP assay, we analyzed structural determinants for physical and functional interactions. Exogenous RNA templates that were used in the assays contained deletion mutations in the 5'-TR and substitution mutations in the 3'-stem-loop structure including those that would disrupt the predicted pseudoknot structure. Our results indicate that there is physical interaction between the 5'-TR and 3'-UTR that requires only the CYC motifs. RNA synthesis at the 3'-UTR, however, requires long range interactions involving the 5'-UTR, CYC motifs, and the 3'-stem-loop region that includes the tertiary pseudoknot structure.

Role of the 3' tRNA-like structure in tobacco mosaic virus minus-strand RNA synthesis by the viral RNA-dependent RNA polymerase In vitro

A template-dependent RNA polymerase has been used to determine the sequence elements in the 3' untranslated region of tobacco mosaic virus RNA that are required for promotion of minus-strand RNA synthesis and binding to the RNA polymerase in vitro. Regions which were important for minus-strand synthesis were domain D1, which is equivalent to a tRNA acceptor arm; domain D2, which is similar to a tRNA anticodon arm; an upstream domain, D3; and a central core, C, which connects domains D1, D2, and D3 and determines their relative orientations. Mutational analysis of the 3'-terminal 4 nucleotides of domain D1 indicated the importance of the 3'-terminal CA sequence for minus-strand synthesis, with the sequence CCCA or GGCA giving the highest transcriptional efficiency. Several double-helical regions, but not their sequences, which are essential for forming pseudoknot and/or stem-loop structures in domains D1, D2, and D3 and the central core, C, were shown to be required for high template efficiency. Also important were a bulge sequence in the D2 stem-loop and, to a lesser extent, a loop sequence in a hairpin structure in domain D1. The sequence of the 3' untranslated region upstream of domain D3 was not required for minus-strand synthesis. Template-RNA polymerase binding competition experiments showed that the highest-affinity RNA polymerase binding element region lay within a region comprising domain D2 and the central core, C, but domains D1 and D3 also bound to the RNA polymerase with lower affinity.

Full-length tobacco mosaic virus RNAs and defective RNAs have different 3' replication signals

The viral replicase complex of positive-stranded RNA viruses interacts with cis-acting elements that are usually located at the termini of the viral RNAs. On comparison of the replication requirement of a tobacco mosaic virus (TMV)-based defective RNA (dRNA) and its helper virus, we found different requirements for replication of TMV RNAs in cis and in trans. The level of replication of full-length TMV RNA decreased substantially in the absence of pseudoknot (pk) 1 and/or 2, whereas identical deletions in dRNAs did not affect their replication. However, pk3 was required for replication of both full-length TMV RNAs and dRNAs. The requirements for homologous sequences were greater for dRNA replication than for replication of full-length TMV RNAs. Defective RNAs with heterologous 3' nontranslated regions (NTRs) failed to be replicated or replicated minimally, whereas replication of similarly mutated full-length RNAs was much less affected. Increasing amounts of contiguous heterologous sequences in the dRNAs compensated for the impaired interactions between the replicase and 3' NTR. The precision requirement appeared to involve the terminal 28 nucleotides, specifically the pseudoknot in the aminoacyl acceptor arm of the tRNA like structure, which was important in replication of both dRNAs and full-length TMV RNAs.

Evidence for phosphorylation and ubiquitinylation of the turnip yellow mosaic virus RNA-dependent RNA polymerase domain expressed in a baculovirus-insect cell system

All RNA viruses known to date encode an RNA-dependent RNA polymerase (RdRp) that is required for replication of the viral genome. We have expressed and purified the turnip yellow mosaic virus (TYMV) RdRp in insect cells using a recombinant baculovirus, either in its native form, or fused to an hexa-histidine tag. Phosphorylation of the protein was demonstrated by labelling experiments in vivo, as well as phosphatase treatment of the purified protein in vitro. Phospho amino acid analysis and immunoblotting experiments identified serine and threonine residues as being the subject of phosphorylation. Peptide mass mapping using MS analysis of a protein digest revealed that phosphorylation sites are localized within a putative PEST sequence [a sequence rich in proline (P), glutamic acid (E), serine (S) and threonine (T) residues] in the N-terminal region of the protein. Using monoclonal antibodies specific for ubiquitin conjugates, we were able to demonstrate that the TYMV RdRp is conjugated to ubiquitin molecules when expressed in insect cells. These observations suggest that the TYMV RdRp may be processed selectively by the ubiquitin/proteasome degradation system upon phosphorylation of the PEST sequence.

In vitro transcription by the turnip yellow mosaic virus RNA polymerase: a comparison with the alfalfa mosaic virus and brome mosaic virus replicases

Recently, we showed that the main determinant in the tRNA-like structure of turnip yellow mosaic virus RNA to initiate minus-strand synthesis in vitro is the 3' ACCA end. By mutational analysis of the 3'-terminal hairpin, we show here that only a non-base-paired ACCA end is functional and that the stability of the wild-type 3'-proximal hairpin is the most favorable, in that it has the lowest DeltaG value and a high transcription efficiency. With a nested set of RNA fragments, we show that the minimum template length is 9 nucleotides and that transcription is improved with increasing the length of the template. The results also suggest that proper base stacking contributes to efficient transcription initiation. Internal initiation is shown to take place on every NPyCPu sequence of a nonstructured template. However, the position of the internal initiation site in the template is important, and competition between the different sites takes place. Internal initiation was also studied with the RNA-dependent RNA polymerase of brome mosaic virus (BMV) and alfalfa mosaic virus (AlMV). The BMV polymerase can start internally on ACCA sequences, though inefficiently. Unexpectedly, the polymerases of both AlMV and BMV can start efficiently on an internal AUGC sequence.

Sequence and structural elements at the 3' terminus of bovine viral diarrhea virus genomic RNA: functional role during RNA replication

Bovine viral diarrhea virus (BVDV), a member of the genus Pestivirus in the family Flaviviridae, has a positive-stranded RNA genome consisting of a single open reading frame and untranslated regions (UTRs) at the 5' and 3' ends. Computer modeling suggested the 3' UTR comprised single-stranded regions as well as stem-loop structures-features that were suspected of being essentially implicated in the viral RNA replication pathway. Employing a subgenomic BVDV RNA (DI9c) that was shown to function as an autonomous RNA replicon (S.-E. Behrens, C. W. Grassmann, H. J. Thiel, G. Meyers, and N. Tautz, J. Virol. 72:2364-2372, 1998) the goal of this study was to determine the RNA secondary structure of the 3' UTR by experimental means and to investigate the significance of defined RNA motifs for the RNA replication pathway. Enzymatic and chemical structure probing revealed mainly the conserved terminal part (termed 3'C) of the DI9c 3' UTR containing distinctive RNA motifs, i.e., a stable stem-loop, SL I, near the RNA 3' terminus and a considerably less stable stem-loop, SL II, that forms the 5' portion of 3'C. SL I and SL II are separated by a long single-stranded intervening sequence, denoted SS. The 3'-terminal four C residues of the viral RNA were confirmed to be single stranded as well. Other intramolecular interactions, e.g., with upstream DI9c RNA sequences, were not detected under the experimental conditions used. Mutagenesis of the DI9c RNA demonstrated that the SL I and SS motifs do indeed play essential roles during RNA replication. Abolition of RNA stems, which ought to maintain the overall folding of SL I, as well as substitution of certain single-stranded nucleotides located in the SS region or SL I loop region, gave rise to DI9c derivatives unable to replicate. Conversely, SL I stems comprising compensatory base exchanges turned out to support replication, but mostly to a lower degree than the original structure. Surprisingly, replacement of a number of residues, although they were previously defined as constituents of a highly conserved stretch of sequence of the SS motif, had little effect on the replication ability of DI9c. In summary, these results indicate that RNA structure as well as sequence elements harbored within the 3'C region of the BVDV 3' UTR create a common cis-acting element of the replication process. The data further point at possible interaction sites of host and/or viral proteins and thus provide valuable information for future experiments intended to identify and characterize these factors.

Primary and secondary structural elements required for synthesis of barley yellow dwarf virus subgenomic RNA1

Barley yellow dwarf luteovirus (BYDV) generates three 3'-coterminal subgenomic RNAs (sgRNAs) in infected cells. The promoter of sgRNA1 is a putative hot spot for RNA recombination in luteovirus evolution. The sgRNA1 transcription start site was mapped previously to either nucleotide 2670 or nucleotide 2769 of BYDV genomic RNA (gRNA) in two independent studies. Our data support the former initiation site. The boundaries of the sgRNA1 promoter map between nucleotides 2595 and 2692 on genomic RNA. Computer prediction, phylogenetic comparison, and structural probing revealed two stem-loops (SL1 and SL2) in the sgRNA1 promoter region on the negative strand. Promoter function was analyzed by inoculating protoplasts with a full-length infectious clone of the BYDV genome containing mutations in the sgRNA promoter. Because the promoter is located in an essential coding region of the replicase gene, we duplicated it in a nonessential part of the genome from which a new sgRNA was expressed. Mutational analysis revealed that secondary structure, but not the nucleotide sequence, was important at the base of SL1. Regions with both RNA primary and secondary structural features that contributed to transcription initiation were found at the top of SL1. Primary sequence, but not the secondary structure, was required in SL2, which includes the initiation site. Disruption of base pairing near the sgRNA1 start site increased the level of transcription three- to fourfold. We propose that both primary and secondary structures of the sgRNA1 promoter of BYDV play unique roles in sgRNA1 promoter recognition and transcription initiation.

FUNCTIONS OF THE 3'-UNTRANSLATED REGIONS OF POSITIVE STRAND RNA VIRAL GENOMES

Positive strand RNA viral genomes are unique in the viral world in serving a dual role as mRNA and replicon. Since the origin of the minus-strand RNA replication intermediate is at the 3'-end of the genome, the 3'-untranslated region (UTR) clearly plays a role in viral RNA replication. The messenger role of this same RNA likely places functional demands on the 3'-UTR to serve roles typical of cellular mRNAs, including the regulation of RNA stability and translation. Current understanding indicates varied roles for positive strand RNA viral 3'-UTRs, with the dominant roles differing between viruses. Three case studies are discussed: turnip yellow mosaic virus RNA, whose 3' tRNA mimicry is thought to negatively regulate minus strand synthesis; brome mosaic virus, whose 3'-UTR contains a unique promoter element directing minus strand synthesis; and tobacco mosaic virus, whose 3'-UTR contains an enhancer of translational expression.

Specific site selection in RNA resulting from a combination of nonspecific secondary structure and -CCR- boxes: initiation of minus strand synthesis by turnip yellow mosaic virus RNA-dependent RNA polymerase

A turnip yellow mosaic virus RNA-dependent RNA polymerase activity was used to study the template requirements for in vitro minus strand synthesis, which is initiated specifically opposite the 3'-CCA that terminates the 3'-tRNA-like structure. A deletion survey confirmed earlier results suggesting the absence of minus strand promoter elements upstream of the pseudoknotted acceptor stem and 3'-terminus. Reiteration of this 27-nt domain provided two competing initiation sites. By varying the added downstream element, it was shown that the pseudoknotted domain could be functionally replaced by various simple stem/loops, although with some decrease in activity. The addition of varying numbers of consecutive -CCA- triplets to the 3' end of the tRNA-like structure resulted in accurate initiation from each added triplet. A similar spectrum of initiations occurred with an unstructured RNA consisting of 12 consecutive -CCA- triplets and no additional viral sequence. Substitution mutations revealed no influence on minus strand synthesis of the identity of the nucleotide immediately upstream of a -CC- initiation site, but a preference for a purine immediately downstream. The introduction of secondary structure into the linear template showed that the usage of potential -CCR- initiation sites is influenced by nonspecific secondary structure. We conclude that specificity arises from the requirement that a -CCR- sequence be sterically accessible. This mechanism is only applicable to interactions that do not involve RNA unwinding during site selection, but may be used commonly in positive strand RNA virus replication and be applicable to other RNA-protein interactions.

Analysis of sequences and predicted structures required for viral satellite RNA accumulation by in vivo genetic selection

In vivo genetic selection was used to study the sequences and structures required for accumulation of subviral sat-RNA C associated with turnip crinkle virus (TCV). This technique is advantageous over site-specific mutagenesis by allowing side-by-side selection from numerous sequence possibilities as well as sequence evolution. A 22 base hairpin and 6 base single-stranded tail located at the 3'-terminus of sat-RNA C were previously identified as the promoter for minus strand synthesis. Approximately 50% of plants co-inoculated with TCV and sat-RNA C containing randomized sequence in place of the 22 base hairpin accumulated sat-RNA in uninoculated leaves. The 22 base region differed in sat-RNA accumulating in all infected plants, but nearly all were predicted to fold into a hairpin structure that maintained the 6 base tail as a single-stranded sequence. Two additional rounds of sat-RNA amplification led to four sequence family 'winners', with three families containing multiple variants, indicating that evolution of these sequences was occurring in plants. Three of the four sequence family winners had the same 3 bp at the base of the stem as wild-type sat-RNA C. Two of the winners shared 15 of 22 identical bases, including the entire stem region and extending two bases into the loop. These results demonstrate the utility of the in vivo selection approach by showing that both sequence and structure contribute to a more active 3'-end region for accumulation of sat-RNA C.

Minimal template requirements for initiation of minus-strand synthesis in vitro by the RNA-dependent RNA polymerase of turnip yellow mosaic virus

From mutational analysis of the 3'-terminal hairpin of turnip yellow mosaic virus (TYMV) RNA and use of nonstructured C-rich RNA templates, we conclude that the main determinant in the tRNA-like structure of TYMV RNA for initiation of minus-strand synthesis by the viral RNA-dependent RNA polymerase (RdRp) is the non-base-paired 3' ACC(A) end. Base pairing of this 3' end reduces the transcription efficiency drastically, and deletion of only the 3'-terminal A residue results in a fivefold drop in efficiency. The two C residues of the 3' ACCA end are required for efficient transcription, as shown by substitution mutations. However, the 5' A residue is not specifically involved in initiation of transcription, as shown by substitution mutations. Furthermore, the hairpin stem and loop upstream of the 3' ACCA end also do not interact with the RdRp in a base-specific way. However, for efficient transcription, the hairpin stem should be at least five bp in length, while the calculated deltaG value should be less than -10.5 kcal/mol. Unexpectedly, the use of nonstructured C-rich RNA templates showed that the RdRp can start internally on an NCCN or NUCN sequence. Therefore, a possible function of the tRNA-like structure of TYMV RNA may be to prevent internal initiation of minus-strand synthesis.