A second functional RNA domain in the 5' UTR of the Tomato bushy stunt virus genome: intra- and interdomain interactions mediate viral RNA replication

The 5' untranslated regions (UTRs) of (+)-strand RNA viruses play a variety of roles in the reproductive cycles of these infectious agents. Tomato bushy stunt virus (TBSV) belongs to this class of RNA virus and is the prototype member of the genus Tombusvirus. Previous studies have demonstrated that a T-shaped domain (TSD) forms in the 5' half of the TBSV 5' UTR and that it plays a central role in viral RNA replication. Here we have extended our structure-function analysis to the 3' half of the 5' UTR. Investigation of this region in the context of a model viral replicon (i.e., a TBSV-derived defective interfering [DI] RNA) revealed that this segment contains numerous functionally relevant structural features. In vitro solution structure probing along with comparative and computer-aided RNA secondary structure analyses predicted the presence of a simple stem loop (SL5) followed by a more complex downstream domain (DSD). Both structures were found to be essential for efficient DI RNA accumulation when tested in a plant protoplast system. For SL5, maintenance of the base of its stem was the principal feature required for robust in vivo accumulation. In the DSD, both helical and unpaired regions containing conserved sequences were necessary for efficient DI RNA accumulation. Additionally, optimal DI RNA accumulation required a TSD-DSD interaction mediated by a pseudoknot. Modifications that reduced accumulation did not appreciably affect DI RNA stability in vivo, indicating that the DSD and SL5 act to facilitate viral RNA replication.     

An RNA domain within the 5' untranslated region of the tomato bushy stunt virus genome modulates viral RNA replication

The terminal half of the 5' untranslated region (UTR) in the (+)-strand RNA genome of tomato bushy stunt virus was analyzed for possible roles in viral RNA replication. Computer-aided thermodynamic analysis of secondary structure, phylogenetic comparisons for base-pair covariation, and chemical and enzymatic solution structure probing were used to analyze the 78 nucleotide long 5'-terminal sequence. The results indicate that this sequence adopts a branched secondary structure containing a three-helix junction core. The T-shaped domain (TSD) formed by this terminal sequence is closed by a prominent ten base-pair long helix, termed stem 1 (S1). Deletion of either the 5' or 3' segment forming S1 (coordinates 1-10 or 69-78, respectively) in a model subviral RNA replicon, i.e. a prototypical defective interfering (DI) RNA, reduced in vivo accumulation levels of this molecule approximately 20-fold. Compensatory-type mutational analysis of S1 within this replicon revealed a strong correlation between formation of the predicted S1 structure and efficient DI RNA accumulation. RNA decay studies in vivo did not reveal any notable changes in the physical stabilities of DI RNAs containing disrupted S1s, thus implicating RNA replication as the affected process. Further investigation revealed that destabilization of S1 in the (+)-strand was significantly more detrimental to DI RNA accumulation than (-)-strand destabilization, therefore S1-mediated activity likely functions primarily via the (+)-strand. The essential role of S1 in DI RNA accumulation prompted us to examine the 5'-proximal secondary structure of a previously identified mutant DI RNA, RNA B, that lacks the 5' UTR but is still capable of low levels of replication. Mutational analysis of a predicted S1-like element present within a cryptic 5'-terminal TSD confirmed the importance of the former in RNA B accumulation. Collectively, these data support a fundamental role for the TSD, and in particular its S1 subelement, in tombusvirus RNA replication.     

A defective interfering RNA that contains a mosaic of a plant virus genome

A symptom-modulating RNA associated with tomato bushy stunt virus (TBSV) was investigated with respect to physical and biological properties. Linear RNA of approximately 396 nucleotides was packaged in viral coat protein and was dependent on TBSV for replication. Coinoculation of the small RNA with TBSV resulted in the attenuation of TBSV-induced symptoms and depression of virus synthesis in whole plants. Nucleotide sequence analysis revealed that the symptom-modulating RNA was derived from 5', 3', and internal segments of the TBSV genome. The identification of this symptom-modulating RNA as a co-linear deletion mutant of the helper virus genome establishes it as the first definitive defective interfering RNA (DI RNA) to be identified in association with a plant virus.     

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.     

FUSE binding protein 1 interacts with untranslated regions of Japanese encephalitis virus RNA and negatively regulates viral replication

The untranslated regions (UTRs) located at the 5' and 3' ends of the Japanese encephalitis virus (JEV) genome, a positive-sense RNA, are involved in viral translation, the initiation of RNA synthesis, and the packaging of nascent virions. The cellular and viral proteins that participate in these processes are expected to interact with the UTRs. In this study, we used biotinylated RNA-protein pulldown and liquid chromatography-mass spectrometry/mass spectrometry (LC-MS/MS) analyses to identify that the far upstream element (FUSE) binding protein 1 (FBP1) binds with JEV 5' and 3' UTRs. The impact of FBP1 on JEV infection was determined in cells with altered FBP1 expression. JEV replication was enhanced by knockdown and reduced by the overexpression of FBP1, indicating a negative role for FBP1 in JEV infection. FBP1, a nuclear protein, was redistributed to the perinuclear region and appeared as cytoplasmic foci that partially colocalized with JEV RNA in the early stage of JEV infection. By using a JEV replicon reporter assay, FBP1 appeared to suppress JEV protein expression mediated by the 5' and 3' UTRs. Thus, we suggest that FBP1 binds with the JEV UTR RNA and functions as a host anti-JEV defense molecule by repressing viral protein expression.     

The combined effect of environmental and host factors on the emergence of viral RNA recombinants

Viruses are masters of evolution due to high frequency mutations and genetic recombination. In spite of the significance of viral RNA recombination that promotes the emergence of drug-resistant virus strains, the role of host and environmental factors in RNA recombination is poorly understood. Here we report that the host Met22p/Hal2p bisphosphate-3'-nucleotidase regulates the frequency of viral RNA recombination and the efficiency of viral replication. Based on Tomato bushy stunt virus (TBSV) and yeast as a model host, we demonstrate that deletion of MET22 in yeast or knockdown of AHL, SAL1 and FRY1 nucleotidases/phosphatases in plants leads to increased TBSV recombination and replication. Using a cell-free TBSV recombination/replication assay, we show that the substrate of the above nucleotidases, namely 3'-phosphoadenosine-5'-phosphate pAp, inhibits the activity of the Xrn1p 5'-3' ribonuclease, a known suppressor of TBSV recombination. Inhibition of the activity of the nucleotidases by LiCl and NaCl also leads to increased TBSV recombination, demonstrating that environmental factors could also affect viral RNA recombination. Thus, host factors in combination with environmental factors likely affect virus evolution and adaptation.     

Three-dimensional structure of a flavivirus dumbbell RNA reveals molecular details of an RNA regulator of replication

Mosquito-borne flaviviruses (MBFVs) including dengue, West Nile, yellow fever, and Zika viruses have an RNA genome encoding one open reading frame flanked by 5′ and 3′ untranslated regions (UTRs). The 3′ UTRs of MBFVs contain regions of high sequence conservation in structured RNA elements known as dumbbells (DBs). DBs regulate translation and replication of the viral RNA genome, functions proposed to depend on the formation of an RNA pseudoknot. To understand how DB structure provides this function, we solved the x-ray crystal structure of the Donggang virus DB to 2.1Å resolution and used structural modeling to reveal the details of its three-dimensional fold. The structure confirmed the predicted pseudoknot and molecular modeling revealed how conserved sequences form a four-way junction that appears to stabilize the pseudoknot. Single-molecule FRET suggests that the DB pseudoknot is a stable element that can regulate the switch between translation and replication during the viral lifecycle by modulating long-range RNA conformational changes.     

The hepatitis C virus RNA 3'-untranslated region strongly enhances translation directed by the internal ribosome entry site

The positive-strand RNA genome of the hepatitis C virus (HCV) is flanked by 5'- and 3'-untranslated regions (UTRs). Translation of the viral RNA is directed by the internal ribosome entry site (IRES) in the 5'-UTR, and subsequent viral RNA replication requires sequences in the 3'-UTR and in the 5'-UTR. Addressing previous conflicting reports on a possible function of the 3'-UTR for RNA translation in this study, we found that reporter construct design is an important parameter in experiments testing 3'-UTR function. A translation enhancer function of the HCV 3'-UTR was detected only after transfection of monocistronic reporter RNAs or complete RNA genomes having a 3'-UTR with a precise 3' terminus. The 3'-UTR strongly stimulates HCV IRES-dependent translation in human hepatoma cell lines but only weakly in nonliver cell lines. The variable region, the poly(U . C) tract, and the most 3' terminal stem-loop 1 of the highly conserved 3' X region contribute significantly to translation enhancement, whereas stem-loops 2 and 3 of the 3' X region are involved only to a minor extent. Thus, the signals for translation enhancement and for the initiation of RNA minus-strand synthesis in the HCV 3'-UTR partially overlap, supporting the idea that these sequences along with viral and possibly also cellular factors may be involved in an RNA 3'-5' end interaction and a switch between translation and RNA replication.     

An internally located RNA hairpin enhances replication of Tomato bushy stunt virus RNAs

Defective interfering (DI) RNAs of Tomato bushy stunt virus (TBSV), a plus-sense RNA virus, comprise four conserved noncontiguous regions (I through IV) derived from the viral genome. Region III, a 70-nucleotide-long sequence corresponding to a genomic segment located 378 nucleotides upstream of the 3' terminus of the genome, has been found to enhance DI RNA accumulation by approximately 10-fold in an orientation-independent manner (D. Ray and K. A. White, Virology 256:162-171, 1999). In this study, a more detailed structure-function analysis of region III was conducted. RNA secondary-structure analyses indicated that region III contains stem-loop structures in both plus and minus strands. Through deletion analyses of a DI RNA, a primary determinant of region III activity was mapped to the 5'-proximal 35-nucleotide segment. Compensatory-type mutational analyses showed that a stem-loop structure in the minus strand of this subregion was required for enhanced DI RNA replication. The same stem-loop structure was also found to function in a position-independent manner in a DI RNA (albeit at reduced levels) and to be important for efficient accumulation within the context of the TBSV genome. Taken together, these observations suggest that the 5'-proximal segment of region III is a modular RNA replication element that functions primarily through the formation of an RNA hairpin structure in the minus strand.     

An RNA stem-loop within the bovine coronavirus nsp1 coding region is a cis-acting element in defective interfering RNA replication

Higher-order cis-acting RNA replication structures have been identified in the 3'- and 5'-terminal untranslated regions (UTRs) of a bovine coronavirus (BCoV) defective interfering (DI) RNA. The UTRs are identical to those in the viral genome, since the 2.2-kb DI RNA is composed of only the two ends of the genome fused between an internal site within the 738-nucleotide (nt) 5'-most coding region (the nsp1, or p28, coding region) and a site just 4 nt upstream of the 3'-most open reading frame (ORF) (the N gene). The joined ends of the viral genome in the DI RNA create a single continuous 1,635-nt ORF, 288 nt of which come from the 738-nt nsp1 coding region. Here, we have analyzed features of the 5'-terminal 288-nt portion of the nsp1 coding region within the continuous ORF that are required for DI RNA replication. We observed that (i) the 5'-terminal 186 nt of the nsp1 coding region are necessary and sufficient for DI RNA replication, (ii) two Mfold-predicted stem-loops within the 186-nt sequence, named SLV (nt 239 to 310) and SLVI (nt 311 to 340), are supported by RNase structure probing and by nucleotide covariation among closely related group 2 coronaviruses, and (iii) SLVI is a required higher-order structure for DI RNA replication based on mutation analyses. The function of SLV has not been evaluated. We conclude that SLVI within the BCoV nsp1 coding region is a higher-order cis-replication element for DI RNA and postulate that it functions similarly in the viral genome.     

Specific interaction between the classical swine fever virus NS5B protein and the viral genome.

The NS5B protein of the classical swine fever virus (CSFV) is the RNA-dependent RNA polymerase of the virus and is able to catalyze the viral genome replication. The 3' untranslated region is most likely involved in regulation of the Pestivirus genome replication. However, little is known about the interaction between the CSFV NS5B protein and the viral genome. We used different RNA templates derived from the plus-strand viral genome, or the minus-strand viral genome and the CSFV NS5B protein obtained from the Escherichia coli expression system to address this problem. We first showed that the viral NS5B protein formed a complex with the plus-strand genome through the genomic 3' UTR and that the NS5B protein was also able to bind the minus-strand 3' UTR. Moreover, it was found that viral NS5B protein bound the minus-strand 3' UTR more efficiently than the plus-strand 3' UTR. Further, we observed that the plus-strand 3' UTR with deletion of CCCGG or 21 continuous nucleotides at its 3' terminal had no binding activity and also lost the activity for initiation of minus-strand RNA synthesis, which similarly occurred in the minus-strand 3' UTR with CATATGCTC or the 21 nucleotide fragment deleted from the 3' terminal. Therefore, it is indicated that the 3' CCCGG sequence of the plus-strand 3' UTR, and the 3' CATATGCTC fragment of the minus-strand are essential to in vitro synthesis of the minus-strand RNA and the plus-strand RNA, respectively. The same conclusion is also appropriate for the 3' 21 nucleotide terminal site of both the 3' UTRs.     

Inhibition of RNA Recruitment and Replication of an RNA Virus by Acridine Derivatives with Known Anti-Prion Activities

Background

Small molecule inhibitors of RNA virus replication are potent antiviral drugs and useful to dissect selected steps in the replication process. To identify antiviral compounds against Tomato bushy stunt virus (TBSV), a model positive stranded RNA virus, we tested acridine derivatives, such as chlorpromazine (CPZ) and quinacrine (QC), which are active against prion-based diseases.

Methodology/Principal Findings

Here, we report that CPZ and QC compounds inhibited TBSV RNA accumulation in plants and in protoplasts. In vitro assays revealed that the inhibitory effects of these compounds were manifested at different steps of TBSV replication. QC was shown to have an effect on multiple steps, including: (i) inhibition of the selective binding of the p33 replication protein to the viral RNA template, which is required for recruitment of viral RNA for replication; (ii) reduction of minus-strand synthesis by the tombusvirus replicase; and (iii) inhibition of translation of the uncapped TBSV genomic RNA. In contrast, CPZ was shown to inhibit the in vitro assembly of the TBSV replicase, likely due to binding of CPZ to intracellular membranes, which are important for RNA virus replication.

Conclusion/Significance

Since we found that CPZ was also an effective inhibitor of other plant viruses, including Tobacco mosaic virus and Turnip crinkle virus, it seems likely that CPZ has a broad range of antiviral activity. Thus, these inhibitors constitute effective tools to study similarities in replication strategies of various RNA viruses.     

A Primary Determinant of Cap-Independent Translation Is Located in the 3′-Proximal Region of the Tomato Bushy Stunt Virus Genome

Tomato bushy stunt virus (TBSV) is a positive-strand RNA virus and is the prototype member of the genus Tombusvirus. The genomes of members of this genus are not polyadenylated, and prevailing evidence supports the absence of a 5' cap structure. Previously, a 167-nucleotide-long segment (region 3.5) located near the 3' terminus of the TBSV genome was implicated as a determinant of translational efficiency (S.K. Oster, B. Wu and K. A. White, J. Virol. 72:5845-5851, 1998). In the present report, we provide evidence that a 3'-proximal segment of the genome, which includes region 3.5, is involved in facilitating cap-independent translation. Our results indicate that (i) a 5' cap structure can substitute functionally for the absence of region 3.5 in viral and chimeric reporter mRNAs in vivo; (ii) deletion of region 3.5 from viral and chimeric mRNAs has no appreciable effect on message stability; (iii) region 3.5 represents part of a larger 3' proximal element, designated as the 3' cap-independent translational enhancer (3'CITE), that is required for proficient cap-independent translation; (iv) the 3'CITE also facilitates cap-dependent translation; (v) none of the major viral proteins are required for 3'CITE activity; and (vi) no significant 3'CITE-dependent stimulation of translation was observed when mRNAs were tested in vitro in wheat germ extract under various assay conditions. This latter property distinguishes the 3'CITE from other characterized plant viral 3'-proximal cap-independent translational enhancers. Additionally, because the 3'CITE overlaps with cis-acting replication signals, it could potentially participate in regulating the initiation of genome replication.     

A stem-loop motif formed by the immediate 5' terminus of the bovine viral diarrhea virus genome modulates translation as well as replication of the viral RNA

Bovine viral diarrhea virus (BVDV), a Pestivirus member of the Flaviviridae family, has a positive-stranded RNA genome which consists of a single open reading frame (ORF) and untranslated regions (UTRs) at the 5' and 3' ends. The 5' UTR harbors extensive RNA structure motifs; most of them were shown to contribute to an internal ribosomal entry site (IRES), which mediates cap-independent translation of the ORF. The extreme 5'-terminal region of the BVDV genome had so far been believed not to be required for IRES function. By structure probing techniques, we initially verified the existence of a computer-predicted stem-loop motif at the 5' end of the viral genome (hairpin Ia) as well as at the 3' end of the complementary negative-strand replication intermediate [termed hairpin Ia (-)]. While the stem of this structure is mainly constituted of nucleotides that are conserved among pestiviruses, the loop region is predominantly composed of variable residues. Taking a reverse genetics approach to a subgenomic BVDV replicon RNA (DI9c) which could be equally employed in a translation as well as replication assay system based on BHK-21 cells, we obtained the following results. (i) Proper folding of the Ia stem was found to be crucial for efficient translation. Thus, in the context of an authentic replication-competent viral RNA, the 5'-terminal motif operates apparently as an integral functional part of the ribosome entry. (ii) An intact loop structure and a stretch of nucleotide residues that constitute a portion of the stem of the Ia or the Ia (-) motif, respectively, were defined to represent important determinants of the RNA replication pathway. (iii) Formation of the stem structure of the Ia (-) motif was determined to be not critical for RNA replication. In summary, our findings affirmed that the 5'-terminal region of the BVDV genome encodes a bifunctional secondary structure motif which may enable the viral RNA to switch from the translation to the replicative cycle and vice versa.     

cis-Acting packaging signals in the influenza virus PB1, PB2, and PA genomic RNA segments

The influenza A virus genome consists of eight negative-sense RNA segments. The cis-acting signals that allow these viral RNA segments (vRNAs) to be packaged into influenza virus particles have not been fully elucidated, although the 5' and 3' untranslated regions (UTRs) of each vRNA are known to be required. Efficient packaging of the NA, HA, and NS segments also requires coding sequences immediately adjacent to the UTRs, but it is not yet known whether the same is true of other vRNAs. By assaying packaging of genetically tagged vRNA reporters during plasmid-directed influenza virus assembly in cells, we have now mapped cis-acting sequences that are sufficient for packaging of the PA, PB1, and PB2 segments. We find that each involves portions of the distal coding regions. Efficient packaging of the PA or PB1 vRNAs requires at least 40 bases of 5' and 66 bases of 3' coding sequences, whereas packaging of the PB2 segment requires at least 80 bases of 5' coding region but is independent of coding sequences at the 3' end. Interestingly, artificial reporter vRNAs carrying mismatched ends (i.e., whose 5' and 3' ends are derived from different vRNA segments) were poorly packaged, implying that the two ends of any given vRNA may collaborate in forming specific structures to be recognized by the viral packaging machinery.     

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.     

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.     

The 5'-terminal region of the Aichi virus genome encodes cis-acting replication elements required for positive- and negative-strand RNA synthesis

Aichi virus is a member of the family Picornaviridae. It has already been shown that three stem-loop structures (SL-A, SL-B, and SL-C, from the 5' end) formed at the 5' end of the genome are critical elements for viral RNA replication. In this study, we further characterized the 5'-terminal cis-acting replication elements. We found that an additional structural element, a pseudoknot structure, is formed through base-pairing interaction between the loop segment of SL-B (nucleotides [nt] 57 to 60) and a sequence downstream of SL-C (nt 112 to 115) and showed that the formation of this pseudoknot is critical for viral RNA replication. Mapping of the 5'-terminal sequence of the Aichi virus genome required for RNA replication using a series of Aichi virus-encephalomyocarditis virus chimera replicons indicated that the 5'-end 115 nucleotides including the pseudoknot structure are the minimum requirement for RNA replication. Using the cell-free translation-replication system, we examined the abilities of viral RNAs with a lethal mutation in the 5'-terminal structural elements to synthesize negative- and positive-strand RNAs. The results showed that the formation of three stem-loops and the pseudoknot structure at the 5' end of the genome is required for negative-strand RNA synthesis. In addition, specific nucleotide sequences in the stem of SL-A or its complementary sequences at the 3' end of the negative-strand were shown to be critical for the initiation of positive-strand RNA synthesis but not for that of negative-strand synthesis. Thus, the 5' end of the Aichi virus genome encodes elements important for not only negative-strand synthesis but also positive-strand synthesis.