A Viral Noncoding RNA Generated by cis-Element-Mediated Protection against 5'->3' RNA Decay Represses both Cap-Independent and Cap-Dependent Translation

Positive-strand RNA viruses use diverse mechanisms to regulateviral and host gene expression for ensuring their efficientproliferation or persistence in the host. We found that a smallviral noncoding RNA (0.4 kb), named SR1f, accumulated in Redclover necrotic mosaic virus (RCNMV)-infected plants and protoplastsand was packaged into virions. The genome of RCNMV consistsof two positive-strand RNAs, RNA1 and RNA2. SR1f was generatedfrom the 3' untranslated region (UTR) of RNA1, which containsRNA elements essential for both cap-independent translationand negative-strand RNA synthesis. A 58-nucleotide sequencein the 3' UTR of RNA1 (Seq1f58) was necessary and sufficientfor the generation of SR1f. SR1f was neither a subgenomic RNAnor a defective RNA replicon but a stable degradation productgenerated by Seq1f58-mediated protection against 5' $->$ 3' decay.SR1f efficiently suppressed both cap-independent and cap-dependenttranslation both in vitro and in vivo. SR1f trans inhibitednegative-strand RNA synthesis of RCNMV genomic RNAs via repressionof replicase protein production but not via competition of replicaseproteins in vitro. RCNMV seems to use cellular enzymes to generateSR1f that might play a regulatory role in RCNMV infection. Ourresults also suggest that Seq1f58 is an RNA element that protectsthe 3'-side RNA sequences against 5' $->$ 3' decay in plant cellsas reported for the poly(G) tract and stable stem-loop structurein Saccharomyces cerevisiae.

INTRODUCTION

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INTRODUCTION

Many lines of recent evidence indicate that noncoding RNAs includingmicroRNAs and small interfering RNAs play an important rolein the control of gene expression in diverse cellular processesand in defense responses against molecular parasites such asviruses and transposons. Viruses also use many different typesof RNAs in trans for regulating the expression of their owngenomes or host genomes temporally and spatially to ensure efficientvirus proliferation and/or latency in host cells. These RNAsinclude subgenomic RNAs (sgRNAs), viral genomic RNA itself,and many types of noncoding viral RNAs.

For example, the adenovirus virus-associated RNAs (VA RNAs)(23) are small noncoding RNA transcripts. They inhibit the activationof RNA-induced protein kinase and thereby interfere with theactivation of the interferon-induced cellular antiviral defensesystems (38). VA RNAs also interfere with RNA interference pathwaysby acting as substrates for Dicer and suppressing the activityof Dicer probably involved in cellular antiviral mechanisms(2, 55). Epstein-Barr virus-encoded RNAs (EBERs) (56) inhibitRNA-induced protein kinase as VA RNAs (38). They also are knownto encode microRNAs, which are thought to work for persistentinfection (28). On the other hand, recently, EBERs have beenreported to be recognized by RIG-I, a cytosolic protein witha DexD/H box RNA helicase domain that recognizes viral RNA inmammalian cells, and to activate signaling to induce type Iinterferon (35). Thus, associations of viral small RNAs withvirus infection are complicated.

sgRNAs also function as riboregulators in viral gene expressionin addition to their original roles as mRNAs used for proteinproduction. For example, a Flock house virus sgRNA trans activatesthe replication of genomic RNA (9). In Barley yellow dwarf virus(BYDV), sgRNA2 encoding a small open reading frame (ORF) ofunknown function acts in trans to suppress the translation ofreplicase genes from genomic RNA but permits the translationof structural genes from sgRNA1 (40). Furthermore, Red clovernecrotic mosaic virus (RCNMV) genomic RNA2 is required in transfor the synthesis of sgRNA from genomic RNA1 (42).

RCNMV is a member of the genus Dianthovirus in the family Tombusviridae.Its genome is divided into two RNA molecules, RNA1 and RNA2(Fig. 1A) (11, 12, 30), each of which has no cap structure atthe 5' end and no poly(A) tail at the 3' end (21, 25). RNA2is a monocistronic RNA that encodes a 35-kDa protein requiredfor viral cell-to-cell movement in plants (21, 51). RNA1 encodesputative RNA replicase components, a 27-kDa protein (p27), andan 88-kDa protein (p88). p88, containing an RNA-dependent RNApolymerase motif (19), is produced by programmed –1 ribosomalframeshifting (16, 17, 52) and is required in cis for the replicationof RNA1 (29). RNA1 also encodes a 37-kDa coat protein (CP) thatis expressed from CP sgRNA (57). The transcription of CP sgRNArequires intermolecular interaction between RNA1 and RNA2 asdescribed above. The 3' UTR of RNA1 contains RNA elements (3'TE-DR1)essential for cap-independent translation (27) and also containsthe promoter for negative-strand RNA synthesis (14).

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FIG. 1. A small RNA is generated from the 3'-proximal region of RNA1 and packaged into virions in RCNMV-infected cells. (A) Schematic representation of viral RNAs of RCNMV. The genome is shown as horizontal lines with coding regions depicted as open boxes with the assigned viral protein designated. CP sgRNA and a small RNA (SR1f) are shown as thick horizontal lines below the genome diagram. The gray boxes indicate 3'TE-DR1. The regions covered by RNA probes are shown as thin arrows. MP, movement protein. (B) Accumulations of RNA1, CP sgRNA, and a small RNA (SR1f) in BY-2 protoplasts. Inoculated protoplasts were incubated at 17°C for the indicated times. Total RNAs extracted from protoplasts and purified virions were separated by gel electrophoresis and blotted onto a membrane. The top left, top right, and bottom panels show membranes hybridized with the DIG-labeled RNA probes specific for the 5' UTR, middle region, and 3' region, respectively. hpi, hours postinfection. (C) Accumulations of negative-strand RNA1 and CP sgRNA in BY-2 protoplasts. The same set of membranes shown in the bottom panel in panel B was hybridized with the DIG-labeled RNA probe specific for negative-strand RNA1.

We noticed that a large amount of small viral RNAs (0.4 kb)accumulated in RCNMV-infected plants and protoplasts duringour RCNMV study. Here, we analyzed the origin, generation mechanisms,and possible functions of this small RNA in vivo and in vitro.Our results show that (i) the small RNA (defined here as SR1f)consists of nearly the entire 3' UTR of RNA1; (ii) SR1f is notan sgRNA but a degradation intermediate generated by cis-RNAelement-mediated protection against 5' $->$ 3' decay, and a 58-nucleotide(nt) sequence (Seq1f58) is necessary and sufficient for protectionagainst 5' $->$ 3' decay; and (iii) SR1f trans inhibits both cap/poly(A)-dependentand 3'TE-DR1-mediated cap-independent translation in vivo andin vitro, resulting in a decrease in negative-strand RNA synthesisof RCNMV genomic RNAs. Our results also suggest that Seq1f58is a cis-acting RNA element that confers resistance to RNA against5' $->$ 3' decay in plant cells as the poly(G) tract and stable stem-loopstructures reported in Saccharomyces cerevisiae RNAs.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Plasmid constructions. pUCR1 and pRC2|G are full-length cDNA clones of RNA1 and RNA2of the RCNMV Australian strain, respectively (44, 54). pCR-R1and pSC-R1 are full-length cDNA clones of RNA1 of Carnationring spot virus (CRSV) (41) and Sweet clover necrotic mosaicvirus (SCNMV) (10), respectively, which were kindly providedby S. A. Lommel (North Carolina State University) and C. Hiruki(University of Alberta), respectively. Constructs describedpreviously that were used in this study include the following:pUCR1- ${Delta}$ CP (44), pUCR1-d3'SLA (14), pUCR1-d3'SLB (14), pUCR1-d3'SLC(14), pUCR1-d3'SLD (14), pUCR1-d3'SLE (14), pUCR1-d3'SLF (14),pR1-5'-XbS (27), and pLUCpA60 (27). Escherichia coli DH5 ${alpha}$ wasused for the construction of all plasmids, except for pSSL-luc.All constructs were verified by sequencing. The primers usedare listed in Table 1.

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TABLE 1. List of primers and their sequences used for PCR to generate constructs described in the text

(i) pUCR1-p27fs. pUCR1 was cut at an EcoRI site in the p27 ORF, end filled withT4 DNA polymerase, and relegated.

(ii) pUCR1-d3'SLA-L. Two DNA fragments were amplified from pUCR1 using two primerpairs, A1+3380 plus d3'-2ii– and M4 plus d3'-2ii+. Then,a PCR fragment was amplified from a mixture of these two fragmentsusing the primer pair A1+3380 plus M4, digested with MluI andSmaI, and inserted into the corresponding region in the 3' UTRof pUCR1.

(iii) pUCR1-m1, pUCR1-m2, pUCR1-m3, pUCR1-m4, pUCR1-m5, pUCR1-m6, pUCR1-m7, pUCR1-m8, pUCR1-m9, pUCR1-m10, pUCR1-m11, pUCR1-m12, pUCR1-m13, pUCR1-m14, and pUCR1-m1/m3. DNA fragments were amplified by PCR from pUCR1. The primer pairsused were AC1+3036 plus one each of the following: m1–,m2–, m3–, m4–, m5–, m6–, m7–,m8–, m9–, m10–, m11–, m12–, m13–,m14–, and m1/m3–. Another primer, 3'R/C1, was usedtogether with one each of the following: m1+, m2+, m3+, m4+,m5+, m6+, m7+, m8+, m9+, m10+, m11+, m12+, m13+, m14+, and m1/m3+.Each recombinant PCR product was amplified with the primer pairAC1+3036 and 3'R/C1, digested with MluI and SmaI, and insertedinto the corresponding region in the 3' UTR of pUCR1.

(iv) pUCR1-m1/d3'SLF. Two DNA fragments were amplified from pUCR1-d3'SLF using twoprimer pairs, AC1+3115 plus m1– and Aus4291– plusm1+. Then, a PCR fragment was amplified from a mixture of thesetwo fragments using the primer pair AC1+3115 plus Aus4291–,digested with MluI and SmaI, and inserted into the correspondingregion in the 3' UTR of pUCR1.

(v) pA1-R-Luc-A1. Two DNA fragments were amplified by PCR from pR1-5'-XbS usingtwo primer pairs, SacI/T7 plus 5'A1/R-Luc/L and R-Luc/3'A1/Rplus 3'A1end/L. Other DNA fragments were amplified from pSP64-RLUC(27) using the primer pair 5'A1/R-Luc/R and R-Luc/3'A1/L. Theseamplified DNA fragments were mixed and further amplified byPCR using the primer pair SacI/T7 plus 3'A1end/L. The amplifiedDNA fragment was digested with SacI and SacII and used to replacethe corresponding region of pR1-5'-XbS.

(vi) pAR/1f/FA and pAR/m1/FA. DNA fragments were amplified by PCR from pA1-RLuc-A1, and theprimer pairs used were SacI/T7 plus one each of the following:R-1f– and R-m1–, respectively. Another primer, 1fNcoI–,was used together with one each of the following: R-1f+ andR-m1+, respectively. These recombinant PCR products were amplifiedwith the primer pair SacI/T7/R plus 1fNco1–, digestedwith SacI and NcoI, and used to replace the corresponding regionof pR1-5'-XbS, respectively.

(vii) pR/1f/F and pR/m1/F. To construct pR/1f/F and pR/m1/F, DNA fragments were amplifiedby PCR using the primer pairs pR/1f/F+ plus pR/1f/F– frompAR/1f/FA and pAR/m1/FA, respectively. These fragments weredigested with HindIII and AccI and used to replace the correspondingregion of p3'-8 (27), respectively.

(viii) p1f-Luc and pm1-Luc. To construct p1f-Luc and pm1-Luc, DNA fragments were amplifiedfrom pUCR1 using two primer pairs, 1fNco1– plus T7/TC5'and 1fNco1– plus 1fm1+, respectively. These amplifiedfragments were digested with SacI and NcoI and used to replacethe corresponding region of pR1-5'-XbS.

(ix) pSSL/R1-5'-XbS. A DNA fragment was amplified from pR1-5'-XbS using the primerpair SSL/A1/R plus 3'R/C1. To complete the DNA fragments containingthe T7 promoter and the SacI site, this DNA fragment was amplifiedby PCR again with the primer pair T7/9/SSL/R plus 3'R/C1. Thefinal amplified product was digested with SacI and SacII andused to replace the corresponding region of pR1-5'-XbS.

(x) pSSL-Luc. Two DNA fragments of the 5' UTR of RCNMV RNA1 with a stablestem-loop structure and Luc ORF with the 3'UTR of RNA1 wereamplified by PCR from pR1-5'-XbS using two primer pairs, SacI/T7plus A1/SSL/2L and SSL/14/Luc/2R plus 3'R/C1, respectively.Both DNA fragments were used as a template for the PCR and wereamplified using primers SacI/T7 and 3'R/C1. The final amplifiedproduct was digested by EcoRV and SacII and used to replacethe corresponding region of pSSL/R1-5'-XbS. Because we failedto construct this plasmid with the expected sequences in thestable stem-loop site using the E. coli DH5 ${alpha}$ strain, this plasmidwas amplified in the E. coli stbl4 strain (Invitrogen ElectroMAXStbl4 cells). E. coli was cultured in a Tris-borate medium at30°C.

(xi) pSR1f and pSR1f/TE-Lm1. DNA fragments were amplified from pUCR1 and pRC1mL1 (27) byusing the primer pair T7/TC5' plus M4. The PCR products weredigested with SacI and SmaI and used to replace the correspondingregions of pUC118.

(xii) pSR1f-m1. A DNA fragment was amplified from pUCR1 by using the primerpair 1b-m1(+) plus M4. The PCR product was digested with SacIand SmaI and used to replace the corresponding region of pUC118.

(xiii) pBSRC1/5'P. pBSRC1/5'P was generated by ligating the SacI/XhoI fragmentof pUCR1 into EcoRV/XhoI-digested pBluescript II KS(+) (Stratagene,La Jolla, CA) in antisense orientation behind the T3 promoter.DNA fragments with incompatible ends were ligated after bluntingwith T4 DNA polymerase.

(xiv) pBSRC1/midP. pBSRC1/midP was generated by ligating the PstI/XhoI fragmentof pUCR1 into PstI/XhoI-digested pBluescript II KS(+) (Stratagene)in antisense orientation behind the T7 promoter.

(xv) pBSCR1P. pBSCR1P was generated by ligating the HindIII/BamHI fragmentof pCR-R1 into HindIII/BamHI-digested pBluescript II KS(+).

(xvi) pR-lucN. A PCR fragment was amplified from pA1-R-luc-A1 by using theprimer pair T7NSR+ plus RSmaI–. The PCR product was digestedwith SacI and SmaI and used to replace the corresponding regionof pUC118.

RNA preparation. All RNA transcripts except for CRSV RNA1, R/1f/F, and R/m1/Fwere synthesized in vitro from XmaI-linearized plasmids withT7 RNA polymerase. CRSV RNA1 was synthesized from HindIII-linearizedpCR-R1 with T7 polymerase. R/1f/F and R/m1/F were synthesizedfrom AccI-linearized plasmids with T7 polymerase. All transcriptswere purified with a Sephadex G-50 fine column (GE HealthcareUK, Ltd., Buckinghamshire, United Kingdom). The RNA concentrationwas determined spectrophotometrically and its integrity verifiedby 1% agarose gel electrophoresis. All transcripts are namedfor their parent plasmids minus the "pUC," "p," or "pLUC" prefix.Capped transcripts were prepared using the ScriptCap m⁷G cappingsystem (Epicentre Biotechnologies, Madison, WI) to achieve efficientcapping rates.

Protoplast experiments. Tobacco BY-2 protoplast experiments were performed as previouslydescribed (14). Briefly, RNA1 (1.1 pmol) with or without RNA2(2.9 pmol) was suspended in 0.2 ml cold morpholineethanesulfonicacid buffer and mixed with 0.6 ml of BY-2 protoplast solution(1.67 x 10⁶ cells/ml) before electroporation using a Pulse ControllerPlus (Bio-Rad). Protoplasts were incubated at 17°C for 18h in the dark. Total RNAs were subjected to Northern blot analysis,as previously described (14). In the SR1f competition assay,approximately 8 pmol of R1-5'-XbS or pA60(+) was electroporatedwith an eightfold molar excess of SR1f or SR1f/TE-Lm1 into BY-2protoplasts. The protoplasts were incubated at 17°C in thedark for 6 h. The cells were lysed in passive lysis buffer (Promega)and subjected to one freeze-thaw cycle. Aliquots of the celllysate were assayed with the luciferase reporter assay system(Promega).

Evacuolated BY-2 protoplast lysate (BYL) experiments. Preparation of the cell extracts of evacuolated BY-2 protoplastsand the in vitro translation/replication reaction were describedpreviously (14, 18). In the luciferase assays, aliquots of sampleswere diluted with 100-fold passive lysis buffer (Promega), andaliquots of these samples were assayed with the luciferase reporterassay system (Promega). See the figure legends for more informationon each experiment.

Inoculation of Nicotiana benthamiana plants. The inoculation of N. benthamiana plants was performed as previouslydescribed (25), except for using uncapped transcripts.

Northern and Western blot analysis. Total RNAs extracted from N. benthamiana plants, BY-2 protoplasts,and BYL were subjected to Northern blot analysis, as previouslydescribed (14, 25). The digoxigenin (DIG)-labeled RNA probesspecific to the 3' UTRs of RCNMV RNA1 (RNA1/3'P), the negative-strandRNAs of RCNMV RNA1, the 3' UTRs of RCNMV RNA2, the negative-strandRNAs of RCNMV RNA2, and the firefly luciferase ORF (F-Luc probe)have been described previously (14, 25-27). The DIG-labeledRNA probes specific to the 5' region of RCNMV RNA1 (RNA1/5'P)and the middle region of RCNMV RNA1 (RNA1/MidP) were transcribedfrom SmaI-linearized pBSRC1/5'P with T3 RNA polymerase and fromXhoI-linearized pBSRC1/midP with T7 RNA polymerase, respectively.The DIG-labeled RNA probe for the Renilla luciferase ORF (R-Lucprobe) was transcribed from SmaI-linearized pR-lucN with T7RNA polymerase. The DIG-labeled RNA probe for the region betweennt 3673 and the 3' end (nt 3890) of RCNMV RNA1 (3' UTR shortprobe) was transcribed from BstPI-linearized pSRT1 (27) withT7 RNA polymerase. The DIG-labeled RNA probe for CRSV RNA1 wastranscribed from BamHI-linearized pBSCR1P with T7 RNA polymerase.The RNA signals were detected with a luminescent image analyzer(LAS 1000 Plus; Fuji Photo Film, Japan).

Western blot analysis was performed as described previously(44). The signals were detected with a luminescent-image analyzer(LAS 1000 Plus; Fuji Photo Film, Japan), and the signal intensitieswere quantified with the Image Gauge program (Fuji Photo Film,Japan).

Determination of the 5' and 3'ends of SR1f by primer extension and 3'-RACE. The purification of RCNMV SR1f by electrophoresis through adenaturing polyacrylamide gel was performed as described previously(36). Oligonucleotide primer A5'RACE-3621 was used for 5'-endsequencing of SR1f. Sequencing reactions and treatment of theprimer extension products with terminal deoxynucleotidyl transferasewere performed as described previously (1), except for usingSuperScript III reverse transcriptase (Invitrogen, Carlsbad,CA). The 3'-rapid amplification of cDNA ends (RACE) was doneas described previously (25).

RESULTS

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RESULTS

A small RNA is generated from the 3'-proximal region of RNA1 and packaged into virions in RCNMV-infected cells. Northern blot analysis using a probe complementary to the 3'region of RCNMV RNA1 revealed that infected plants and protoplastscontain a large amount of a 400-base RNA (termed SR1f) in additionto the viral genomic and sgRNAs (Fig. 1B). To identify SR1fand to study the biological roles of SR1f, we first investigatedwhether SR1f might contain any regions other than the 3' UTRof RNA1. Tobacco BY-2 protoplasts were inoculated with in vitrotranscripts of RCNMV RNA1 and RNA2, or RNA1 alone, and totalRNA was analyzed by Northern blotting using RNA probes thatspecifically hybridized to the 5'-proximal (RNA1/5'P), the middle(RNA1/MidP), or the 3'-proximal regions (RNA1/3'P) of RNA1 (Fig.1A). SR1f was detected only with RNA1/3'P (Fig. 1B), suggestingthat SR1f consists mainly of the 3'-proximal region of RNA1.SR1f, unlike CP sgRNA, accumulated in protoplasts inoculatedwith RNA1 alone (Fig. 1B), indicating no requirement for RNA2in its generation. This suggests that the mechanism that generatesSR1f is different from the mechanism that generates CP sgRNA,which requires an intermolecular interaction between RNA1 andRNA2 (42, 46). Time course experiments consistently showed thatSR1f started to accumulate after the initial detection of RNA1or CP sgRNA. It is noteworthy that a small RNA similar in sizeto SR1f was detected in purified virions, whereas CP sgRNA wasnot (Fig. 1B), suggesting that SR1f is packaged into virions.To determine the precise 5' and 3' ends of SR1f, we used a primerextension analysis and a 3'-RACE analysis, respectively. Becausepurified RCNMV virions contain a small RNA that is probablyidentical to SR1f, as shown in Fig. 1B, we used virion RNAsdirectly or after separation on a 5% polyacrylamide gel containing8 M urea as the template for the analysis. These analyses indicatedthat SR1f had a 3' end coterminal with RNA1 consisting of 431nt (data not shown). These results also suggested that SR1fis unlikely to be an RNA replicon.

Negative-strand RNAs of SR1f are not detected in BY-2 protoplasts. Next, we analyzed the accumulation of negative-strand viralRNAs using full-length genomic RNA1 as a probe. Negative-strandRNAs corresponding to RNA1 or CP sgRNA were detected in protoplastsinoculated with RNA1 and RNA2 (Fig. 1C), supporting a modelinvolving the premature termination mechanism that generatesCP sgRNA (42). In contrast, no negative-strand RNA correspondingto the small RNA was detected. Thus, SR1f could be a transcriptsynthesized from negative-strand RNA1 by an internal initiationmechanism (24) or a degradation intermediate generated by self-cleavageor cleavage by endo- or exoribonucleases.

SR1f is not a transcript but a degradation intermediate of RNA1. To investigate the mechanism that generates SR1f, we used BYL,which were initially developed for the study of tobamovirustranslation and replication (18). BYL is a powerful tool foranalysis of the translation and replication mechanisms of RCNMV(14, 26, 29). BYL reflects the cap-independent translation activityof RCNMV RNA1 with a series of mutations in the 3' UTR in BY-2protoplasts (14, 26). Furthermore, in BYL, several RNA virusescan replicate (18), and negative-strand RNAs of RCNMV are easilydetected following the translation of viral replication proteins(14, 29). Therefore, we used BYL to investigate the timing ofthe accumulation of SR1f and the generation mechanism of SR1f.First, we incubated uncapped RNA1 in BYL and analyzed the accumulationsof p27, positive- and negative-strand RNA1, and SR1f at differenttime points after incubation, using Western and Northern blotting,respectively. p27 started to be detected 30 min after incubation,and negative-strand RNA1 started to be detected at 120 min (Fig.2). Surprisingly, SR1f was detected 5 min after incubation orearlier (Fig. 2; data not shown). This suggested no link betweenviral RNA replication and the generation of SR1f. To test this,we used an RNA1 mutant (R1-p27fs) that does not produce functionalreplication proteins. SR1f accumulated with the incubation ofR1-p27fs to a level similar to that after the incubation ofwild-type RNA1 in BYL (Fig. 2). The stability of R1-p27fs wasnot significantly different from that of RNA1 (Fig. 2). Theseresults indicated that viral replication proteins were not necessaryfor the generation of SR1f. Thus, SR1f is not a transcript buta degradation intermediate of RNA1.

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FIG. 2. SR1f is not a transcript but a degradation intermediate of RNA1. Time course analysis of the accumulations of viral replicase proteins (p27) and viral RNAs in BYL incubated with RNA1 and R1-p27fs. RNA1 or R1-p27fs (2 pmol) was incubated in 110 µl of BYL translation reaction mixture at 17°C. At different times after incubation, 10-µl aliquots were used for Northern and Western blotting, respectively.

Fifty-eight nucleotides in the 3' UTR of RNA1 are necessary and sufficient for the generation and accumulation of SR1f. To define the nucleotide sequences required for the generationand accumulation of SR1f, RNA1 mutants with deletions or nucleotidesubstitutions (Fig. 3A and C) were incubated in BYL and theaccumulation of SR1f was analyzed by Northern blotting (Fig.3B and D). Nucleotide sequences from nt 3460 to 3503 in RNA1,except for five nucleotides from nt 3470 to 3474, were essentialfor the accumulation of SR1f (Fig. 3). We will refer below tothe 58 nt from nt 3460 to 3517 of RNA1 as Seq1f58; this is acore nucleotide sequence required for SR1f generation (Fig.4A).

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FIG. 3. Essential regions required for the generation of SR1f. (A) Schematic representation of deleted regions in the CP ORF and the 3' UTR of RCNMV RNA1. The boldface lines indicate virus-derived sequences with the nucleotide numbers at the 5' and 3' ends. The bent lines indicate deleted regions. The Gs in the open boxes show the nucleotide residue in the 5' end of SR1f. (B) Accumulation of small RNAs (SR1f) generated from RNA1 deletion mutants in BYL at 0.2 and 60 min after incubation. Genome RNAs and small RNAs (SR1f) were detected by RNA1/3'P. (C) Schematic representation of nucleotide substitution mutations in the 3' UTR of RNA1. Italics in the open boxes show altered sequences. (D) Accumulation of small RNAs (SR1f) generated from RNA1 mutants in BYL at 0.2 and 60 min after incubation. Genome RNAs and small RNAs (SR1f) were detected by the 3' UTR short probe.

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FIG. 4. Seq1f58 is sufficient for the accumulation of its downstream nonviral RNA fragments. (A) Schematic representation of the essential nucleotide sequences required for the accumulation of SR1f (Seq1f58). The G's in the open boxes indicate the nucleotide residue at the 5' end of SR1f. The nucleotide sequence in the gray shaded box indicates the essential nucleotide sequence required for the accumulation of SR1f. A secondary structure of Seq1f58 was predicted by using mfold (version 2.3) (50, 58) at 17°C. (B) Schematic representation of dicistronic mRNA. Seq1f58 was inserted between two different reporter ORFs, Renilla luciferase and firefly luciferase (R/1f/F). R/1f/F is 2,677 nt in length. The number of nucleotide residues from the 5' end to just before the first guanine residue in the Seq1f58 is 962, and the number from the first guanine residue in the Seq1f58 to the 3' end is 1,715. The filled and open triangles show Seq1f58 and Seq1f58 with the m1 mutation (Seq1f58-m1), respectively. The regions covered by RNA probes are shown as thin arrows. (C) Accumulation of degradation intermediates derived from R/1f/F or R/m1/F in BYL at 0.2 and 60 min after incubation. R/m1/F has the m1 mutation in Seq1f58. R/1f/F or R/m1/F (0.55 pmol) was incubated in 50 µl BYL at 17°C. Total RNA was extracted at 0.2 min and 60 min after incubation and used for Northern blotting with DIG-labeled RNA probes specific for the F-Luc ORF and R-Luc ORF. The sizes of the bands are indicated on the right or the left side. The asterisks indicate an unexpected band which was detected by both the R-Luc and F-Luc probes at 0.2 or 60 min after incubation.

In addition, we examined whether the 5'-proximal stem structurepredicted in Seq1f58 (Fig. 4A) is important for the generationof SR1f by introducing compensatory mutations into R1-m1. ThisRNA1 mutant, R1-m1/m3, with the stem structure restored, failedto accumulate SR1f (data not shown). This suggested that nucleotidesequences in the stem rather than the predicted structure mightbe important for the generation of SR1f.

Next, to examine whether Seq1f58 would be sufficient for thegeneration and accumulation of its downstream nonviral RNA fragmentscontaining Seq1f58, we designed a dicistronic RNA (R/1f/F),in which Seq1f58 was inserted between two different ORFs encodingRenilla luciferase (R-Luc) and firefly luciferase (F-Luc), respectively(Fig. 4B). If Seq1f58 works, an RNA fragment of 1,715 nt, whichcontains both Seq1f58 and the F-luc ORF, should be detected.As a control, we used R/m1/F, which has an m1 mutation in Seq1f58(Fig. 3C and Fig. 4A). This mutation in RNA1 caused a loss ofability to accumulate SR1f (Fig. 3D and 4A). As expected, RNAfragments with a size of 1,715 nt were detected on incubationwith R/1f/F but not after incubation with R/m1/F in BYL usinga probe for the F-Luc ORF (Fig. 4C). On the other hand, degradationintermediates (962 nt) were not detectable using a probe forthe R-Luc ORF on the inoculation of R/1f/F (Fig. 4C). Theseresults indicated that Seq1f58 is sufficient for the accumulationof the 3' portion of the transcript, suggesting that Seq1f58protects its downstream nucleotide sequences from 5' $->$ 3' decay.

Seq1f58 protects its downstream nucleotide sequences from 5' $->$ 3' decay. If Seq1f58 could protect its downstream nucleotide sequencesfrom 5' $->$ 3' decay, then SR1f must be more stable than SR1f derivativeswith mutations in Seq1f58. To test this, we compared the stabilitiesof in vitro-transcribed SR1f and SR1f-m1 that had the m1 mutationin Seq1f58. The half-life of SR1f was longer than 240 min, whereasthat of SR1f/m1 was shorter than 15 min (Fig. 5A). This resultsuggested that wild-type Seq1f58 stabilizes SR1f by protectingagainst 5' $->$ 3' exoribonucleases.

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FIG. 5. Seq1f58 protects its downstream nucleotide sequences from 5' $->$ 3' decay. (A) Stability of SR1f and mutant SR1f (SR1f-m1) in BYL. The filled and open triangles with bold lines indicate SR1f and SR1f-m1, respectively. SR1f or SR1f-m1 (4.3 pmol) was incubated in 100 µl of BYL at 17°C. Total RNA was extracted at the indicated times and used for Northern blotting with the 3' UTR short probe. The signal intensities were quantified with the Image Gauge program (Fuji Photo Film, Japan). RNA half-life (t 1/2) was calculated with Microsoft Excel. (B) Stability of mRNAs with different RNA structures at the 5' UTRs in BYL. mRNAs (0.53 pmol) were incubated in 30 µl of BYL at 17°C. Total RNA was extracted at the indicated times after incubation and used for Northern blotting with RNA1/3'P. For other conditions, refer to the legend of panel A. (C) Accumulations of degradation intermediates from AR/1f/FA and AR/m1/FA. RNAs were extracted at the indicated times and subjected to Northern blotting with the 3' UTR short probe. Schematic representations of RNAs with Seq1f58 and its mutant (AR/1f/FA and AR/m1/FA) are shown above. AR/1f/FA is an R/1f/F derivative with the 5' and 3' UTRs of RCNMV RNA1. AR/m1/FA has an m1 mutation in Seq1f58. The filled and open triangles indicate Seq1f58 and Seq1f58-m1, respectively. The bold gray lines indicate nonviral sequences. The bold dark lines show the 5' and 3' UTRs of RCNMV RNA1. The rectangles with broken lines show the R-luc and F-luc ORFs.

To further confirm that Seq1f58 stabilizes its downstream RNAsequences, we compared the stabilities of RNAs with differentRNA structures in the 5' UTR but with the same 3'UTR (Fig. 5B).R1-5'-XbS was a reporter Luc mRNA with the 5' and 3' UTRs ofRNA1 (27). SSL-luc had a stable stem-loop structure in the 5'UTR. 1f-luc and m1-luc had Seq1f58 with or without the m1 mutationas the 5' UTR, respectively. Uncapped transcripts of these fourRNAs and capped R1-5'-XbS were incubated in BYL, and accumulationsof full-length transcripts were monitored by Northern blottingusing a probe specific to the 3' UTR of RNA1. 1f-luc was themost stable (half-life, 30 min) among the uncapped transcriptstested, although the stability was less than that of cappedR1-5'-XbS (half-life, 60 min) (Fig. 5B). These results indicatedthat Seq1f58 at the 5' end confers stability to the 3' portionof the transcript.

Next, to examine whether the 5'-proximal Seq1f58 would stall5' $->$ 3' exoribonucleases and consequently decrease the accumulationof 3'-proximal RNA fragments, we used an RNA with two Seq1f58sequences (AR/1f/FA) (Fig. 5C). As expected, the accumulationof 3'-proximal RNA fragments was lower in AR/1f/FA than in AR/m1/FA,which had the m1 mutation in the 5'-proximal Seq1f58 (Fig. 5C).

In addition, the accumulation of SR1f was lower with the incubationof capped RNA1 than with uncapped RNA1 in BYL (data not shown).This suggested that the presence of either cap structure orSeq1f58 at the upstream region of the second Seq1f58 decreasedthe generation of SR1f from the downstream Seq1f58. Therefore,we concluded that Seq1f58 protects its downstream RNA sequencesfrom degradation by 5' $->$ 3' exoribonucleases. SR1f is likely aleftover of the activity of 5' $->$ 3' exoribonucleases.

SR1f-like small RNAs are generated from the 3' UTR of other dianthovirus RNA1. To investigate whether SR1f-like RNA would be generated fromRNA1s of other dianthoviruses, we incubated in vitro-transcribedRNA1s of CRSV and SCNMV in BYL. SR1f-like RNAs were detectedusing probes specific to their 3' UTRs (Fig. 6A). These smallRNAs were also detected in N. benthamiana and cowpea protoplastsinfected with these viruses (data not shown). Comparing theessential sequences in Seq1f58 with the corresponding sequencesof CRSV and SCNMV, 28 out of 43 nt (65%) were identical (Fig.6B). These results suggest that the SR1f-like RNAs detectedafter the incubation of CRSV and SCNMV RNA1 are also degradationintermediates like SR1f.

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FIG. 6. SR1f-like RNAs are generated from the 3' UTRs of other dianthoviruses. (A) Accumulations of SR1f and SR1f-like small RNAs generated from RCNMV, CRSV, and SCNMV RNA1 in BYL at 0.2 and 60 min after incubation. Genome RNAs and small RNAs were detected by mixed probes, which are specific to the 3' UTRs of RNA1 of these viruses. (B) Comparison of the essential sequences for the accumulation of SR1f in RCNMV RNA1 with the corresponding sequences of two other dianthoviruses.

SR1f trans inhibits both cap-independent and cap-poly(A)-dependent translation in vitro and in vivo. SR1f does not contain any protein-coding regions but containsRNA elements required for both cap-independent translation (14,27) and negative-strand RNA synthesis (14). These RNA elementscontained in SR1f may function as riboregulators of translationand RNA synthesis. First, we investigated the effects of SR1fon 3'TE-DR1-mediated cap-independent translation in vitro usingR1-5'-XbS (see Fig. 5). The addition of in vitro-transcribedSR1f suppressed the translational activity of R1-5'-XbS in BYL(Fig. 7A). However, SR1f/TE-Lm1, which possesses a defective3'TE-DR1, did not effectively inhibit the translational activityof R1-5'-XbS (Fig. 7A). This inhibition was dependent on theconcentrations of SR1f added. A fivefold molar excess of SR1finhibited the translational activity of R1-5'-XbS by 50% (Fig.7A), whereas the same molar excess of SR1f/TE-Lm1 did not inhibitbut rather upregulated the translational activity of R1-5'-XbS(Fig. 7A). We also tested whether SR1f affects cap-dependenttranslation using capped mRNA with poly(A) pA60(+) in BYL (Fig.7B). A fourfold molar excess of SR1f inhibited the translationalactivity of pA60(+) by 95%, while the same molar excess of SR1f/TE-Lm1did not effectively inhibit the translational activity of pA60(+)(Fig. 7B).

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FIG. 7. Effects of SR1f on cap-dependent and cap-independent translation in BYL and BY-2 protoplasts. (A and B) SR1f trans inhibited cap-independent and cap-dependent translation in BYL. R1-5'-XbS (2.7 pmol) and pA60(+) (2.5 pmol) were incubated with the indicated amount of SR1f or SR1f/TE-Lm1 in 25 µl of BYL at 17°C for 120 min. The luciferase activity of R1-5'-XbS or pA60(+) with no competitor was defined as 100%. The error bars indicate standard deviations. (C and D) BY-2 protoplasts were inoculated with R1-5'-XbS (8 pmol) and pA60(+) (8 pmol) with an eightfold molar excess of SR1f or SR1f/TE-Lm1. The luciferase activities of R1-5'-XbS and pA60(+) without competitor were defined as 100%, respectively. The error bars indicate standard deviations.

Next, to investigate whether SR1f would trans inhibit translationin vivo, BY-2 protoplasts were inoculated with R1-5'-XbS orpA60(+) together with eightfold molar excesses of SR1f or SR1f/TE-Lm1.SR1f inhibited the translational activity of R1-5'-XbS and pA60(+)by 40% and 60%, respectively, whereas SR1f/TE-Lm1 did not effectivelyinhibit the translational activity of either R1-5'-XbS or pA60(+)(Fig. 7C and D).

Together, these results indicated that SR1f, which has a functional3'TE-DR1, suppressed both 3'TE-DR1-mediated cap-independenttranslation and cap/poly(A)-dependent canonical translationin vitro and in vivo. Interestingly, the results also suggestthat SR1f suppresses cap-poly(A)-dependent canonical translationmore efficiently than that of 3'TE-DR1-mediated cap-independenttranslation (Fig. 7).

SR1f trans inhibits negative-strand RNA synthesis via the repression of replicase protein production but not via the competition of replicase proteins for cis elements in vitro. Next, we tested the ability of SR1f to inhibit negative-strandRNA synthesis of RCNMV genomic RNAs, RNA1 and RNA2, in BYL.To distinguish the effects of SR1f supplied in trans from thoseof SR1f generated de novo from RNA1 during incubation, we usedR1-m1 that generates no SR1f (Fig. 3C and 4A) in place of wild-typeRNA1. Note that R1-m1 translated p27 efficiently and accumulatedsimilar levels of negative-strand RNAs as wild-type RNA1 inBYL (data not shown). R1-m1 and RNA2 were incubated with a fivefoldmolar excess of SR1f or SR1f/TE-Lm1 in BYL. SR1f decreased theaccumulation of p27 by approximately 30% and inhibited the negative-strandRNA synthesis of RNA1 and RNA2 by 60% and 80%, respectively(Fig. 8). SR1f/TE-Lm1 did not inhibit p27 accumulation, whereasit decreased the accumulation of negative-strand RNA of bothRNA1 and RNA2 by 40% (Fig. 8). Therefore, these results alsosuggested that SR1f might compete with RNA1 and RNA2 for negative-strandRNA synthesis, because SR1f contains promoter sequences in the3' end conserved between RNA1 and RNA2, which are essentialfor negative-strand RNA synthesis (14, 48; M. An, H.-O. Iwakawa,and T. Okuno, unpublished data). These elements could recruitviral or host proteins required for negative-strand RNA synthesis,although p88 is required in cis for the replication of RNA1(14). To examine whether SR1f would trans inhibit negative-strandRNA synthesis of RCNMV genomic RNAs by the competition of replicaseproteins via these RNA elements, we separated the replicationphase from the translation phase in BYL and analyzed the effectsof SR1f on negative-strand RNA synthesis. First, an RNA1 mutant(R1-m1/d3'SLF) that lacks RNA elements required for SR1f generationand negative-strand RNA synthesis was incubated in BYL for 120min for the production of viral replicase proteins (p27 andp88). Then, cycloheximide (CHX) and RNA2 with or without a fivefoldmolar excess of SR1f were added and incubated for an additional120 min. The use of RNA2 allowed us to minimize the possibleeffects of the interaction between translation factors and RNA2,because RNA2 does not function as an effective mRNA in BYL andin protoplasts unlike RNA1; the cap-independent translationof RNA2 is strongly linked to RNA2 replication (26). The additionof SR1f did not decrease the accumulation of negative-strandRNAs of RNA2 (Fig. 9), suggesting that SR1f alone does not interactwith replication factors and that the decrease in negative-strandRNA synthesis by either SR1f or SR1f/TE-Lm1 (Fig. 8) was notcaused by the competition of replicase proteins (Fig. 8). Theincrease observed in the accumulation of negative-strand RNA2in the presence of SR1f (Fig. 8 and 9C) could probably be attributedto the stabilization of input RNA2 by SR1f. These results suggestthat SR1f trans inhibits negative-strand RNA synthesis of RCNMVvia the repression of replicase protein production but not viathe competition of replicase proteins by its promoter sequence.

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FIG. 8. SR1f trans inhibits negative-strand RNA synthesis of RNA1 and RNA2 in BYL. Accumulations of p27, positive-strand R1-m1, SR1f or SR1f/TE-Lm1, negative-strand R1-m1, positive-strand RNA2, and negative-strand RNA2 in BYL (25 µl) incubated with R1-m1, RNA2 (0.75 pmol), and a fivefold molar excess of SR1f or SR1f/TE-Lm1 at 17°C for 240 min (left panel). Total RNAs and proteins were extracted at 240 min after incubation and used for Northern and Western blotting, respectively. Quantification of the accumulations of p27 and negative-strand RNAs of R1-m1 and RNA2 was performed with the Image Gauge program (Fuji Photo Film, Tokyo, Japan) (right panel). Accumulations of p27, the negative-strand RNAs of R1-m1, and RNA2 in BYL incubated with R1-m1 and RNA2 were defined as 100%. The error bars indicate standard deviations.

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FIG. 9. SR1f does not decrease the accumulation of negative-strand RNA2 in BYL when the replication phase is separated from the translation phase. (A) First, an RNA1 mutant (R1/m1/d3'SLF) that lacks RNA elements required for negative-strand RNA synthesis and SR1f generation was incubated in BYL at 17°C for 120 min for the production of replicase proteins (thin horizontal arrow). Then, cycloheximide (CHX) was added to shut off the translation of R1/m1/d3'SLF, and RNA2 was incubated with or without a fivefold molar excess of SR1f in BYL at 17°C for an additional 120 min (bold horizontal arrow). (B and C) Total RNA was extracted at the indicated times and used for Northern blotting to detect positive- and negative-strand RNA2. The time when CHX was added was defined as 0 min. The Image Gauge program (Fuji Photo Film, Tokyo, Japan) was used for the quantification of negative-strand RNA2. The error bars indicate standard deviations.

In addition, SR1f/TE-Lm1 or both SR1f and SR1f/TE-Lm1 couldalso affect frameshift efficiency for p88 production, becauseaccumulations of negative-strand RNAs in both RNA1 and RNA2were lower than the control despite the same level of p27 accumulation(Fig. 8).

SR1f is not essential for replication and cell-to-cell or long-distance movement. To investigate the biological functions of SR1f in RCNMV infection,first we tested RNA1 mutants with nucleotide substitutions betweennt 3460 and 3495 in Seq1f58 (see Fig. 3) for the ability toreplicate in single cells. To test this, BY-2 protoplasts wereinoculated with RNA1s, and viral RNA accumulation was analyzedat 18 h after inoculation. All RNA1 mutants tested underwentreplication but less efficiently than wild-type RNA1 (Fig. 10).This indicated that SR1f was not essential for the replicationof RNA1. In addition, we failed to observe any associationsbetween the accumulated levels of viral genomic RNAs and theability to generate viral small RNAs. This result confirmedour previous results that the 5'-proximal region including Seq1f58in the 3' UTR of RNA1 contains cis-acting RNA elements requiredfor the efficient replication of RNA1 (14).

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FIG. 10. Accumulations of RNA1 mutants with nucleotide substitutions in the 3' UTR of RNA1 (Fig. 3C) in BY-2 protoplasts. Inoculated protoplasts were incubated at 17°C for 18 h. Total RNA was extracted from protoplasts and used for Northern blotting with the 3' UTR short probe. For other conditions, refer to the legend for Fig. 1.

Finally, to investigate the functions of SR1f in the infectionof plants, we inoculated N. benthamiana plants with severalSR1f-deficient RNA1 mutants including R1-m1 together with RNA2and analyzed viral RNAs in inoculated and uninoculated upperleaves by Northern blotting 10 days after inoculation. Systemicmosaic symptoms were induced, and viral RNA1 and RNA2 accumulatedin both the inoculated and uninoculated upper leaves in theplants inoculated with SR1f-deficient RNA1 mutants, althoughthe accumulated levels of viral RNA were lower than those seenfollowing inoculation with wild-type RNAs (Fig. 11; data notshown). These results indicate that SR1f is not essential forvirus cell-to-cell and long-distance movement in N. benthamiana.

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FIG. 11. Accumulations of RNA1, RNA2, and SR1f in inoculated (I) and uninoculated (U) upper leaves of N. benthamiana plants. The plants were inoculated with in vitro RNA transcripts and maintained at 17°C for 10 days. For other conditions, refer to the legend for Fig. 1.

DISCUSSION

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DISCUSSION

Possible mechanisms for the generation of SR1f in the host cell. Previously, we have predicted that SR1f would be an sgRNA, becauseSR1f accumulates abundantly in host cells following the accumulationof genomic RNAs during RCNMV infection, although it is packagedinto virions unlike CP sgRNA. The present results show thatSR1f is not an sgRNA but a degradation intermediate of RNA1(Fig. 2). As far as we are aware, this is the first report ofa virus-derived degradation intermediate that accumulates abundantlyin the host cells, suppresses both cap-independent and cap-dependenttranslation, and is packaged into virions. Our results indicatedthat an RNA fragment of 58-nt sequences (Seq1f58) in the 3'UTR of RNA1 plays an essential role in the generation and accumulationof SR1f by conferring stability to its downstream nucleotidesequences (Fig. 4 and 5). The lack of generation of SR1f fromRNA1 in the absence of plant extracts (BYL) or in boiled BYLsuggests the requirement of cellular proteins for the generationof SR1f (H.-O. Iwakawa and T. Okuno, unpublished results). Seq1f58may protect its downstream nucleotide sequences from 5' $->$ 3' exoribonucleases,resulting in the accumulation of SR1f (Fig. 5), although wecannot rule out the possible involvement of endoribonucleasesin the early step of SR1f generation, followed by digestionof the 5' portion of the RNA with 3' $->$ 5' or 5' $->$ 3' exoribonucleasesor both. However, we think that endoribonucleases are not mainlyinvolved in the initial step of SR1f generation, because theinsertion of Seq1f58 upstream of SR1f decreased the accumulationlevel of SR1f (Fig. 5C).

An important question is how Seq1f58 protects its downstreamnucleotide sequences from degradation. In yeast, poly(G) tractsor a highly stable RNA structure protects its downstream nucleotidesequences from a 5' $->$ 3' exoribonuclease (XRN1p), resulting inthe accumulation of the 3' portion of the RNA (31, 49). However,poly(G) tracts do not work effectively as a 5' $->$ 3' exoribonucleasestopper in higher eukaryotes, including plants, except for theinterior of chloroplasts (7, 8, 15). Plant ribonucleases includingXRNs may be more robust than those of yeast, or additional proteinssuch as RNA helicases might help those plant enzymes to functionby resolving the structures formed by poly(G) sequences so thatthey can progress through the structure (15).

Unlike Seq1f58, a stable stem-loop structure ( ${Delta}$ G = –47.88kcal/mol at 17°C) did not stabilize RNA in BYL (Fig. 5B),suggesting that strong secondary structures alone are insufficientto protect RNA from 5' $->$ 3' exoribonucleases. The predicted secondarystructure of Seq1f58 (Fig. 4A) was not as strong ( ${Delta}$ G = –28.83kcal/mol at 17°C). Furthermore, compensatory mutations introducedinto R1-m1 to restore the predicted stem structure failed togenerate SR1f from the RNA1 mutant (R1-m1/m3). These resultssuggest that the strength of the RNA secondary structures atthe 5' end is not a main factor required for the Seq1f58-mediatedstabilization of its downstream nucleotide sequences but ratherthat host factors, which might bind to Seq1f58, are involvedin the generation and stabilization of its downstream nucleotidesequences. Thus, our results suggest that Seq1f58 is a novelRNA cis element that can stabilize its downstream nucleotidesequences in plant cells similar to the poly(G) tract in yeast.

Possible functions of SR1f in RCNMV infection. SR1f started to accumulate later than the genomic and CP sgRNAsin RCNMV-infected BY-2 protoplasts. This suggests a possiblerole for SR1f in the later stage of virus infection. SR1f containsno ORF initiated with an AUG start codon, suggesting that SR1fdoes not function as mRNA. At present, we do not know the realroles of SR1f in RCNMV infection. However, the present resultsobtained with protoplasts and BYL in vitro systems present severalpossible functions of SR1f as a noncoding RNA which may be involvedin the regulation of viral gene expression, because SR1f transinhibited 3'TE-DR1-mediated cap-independent translation bothin vivo and in vitro (Fig. 7).

Translational control of virus gene expression by viral smallRNAs has been reported for BYDV. A small RNA transcript referredto as sgRNA2, which contains a BYDV-like cap-independent translationelement (BTE) and a function-unknown small ORF, is generatedin BYDV-infected cells (39). sgRNA2 is thought to be a riboregulatorthat functions as a switch from the early to late stages ofgene expression, because sgRNA2 inhibits the translation ofgenomic RNA that encodes replicase proteins much more stronglythan the translation of sgRNA1 that encodes a structural protein(40). BTE interacts specifically with the cap-binding initiationfactor complexes eIF4F and eIFiso4F in wheat germ extract (47).Interestingly, RCNMV 3'TE-DR1 contains the same core 17-nt sequenceas BTE (27). This suggests that the inhibition of 3'TE-DR1-mediatedcap-independent translation by SR1f could likely result fromthe sequestration of translation initiation factors such aseIF4F and eIFiso4F. The inhibition of translation by sgRNA2does not require the translation of a small ORF. Therefore,sgRNA2 and SR1f may be functionally similar in that both inhibitviral protein synthesis, although their mechanisms of generationdiffer.

Interestingly, SR1f trans inhibited cap/poly(A)-dependent translationmore effectively than 3'TE-DR1-mediated cap-independent translationboth in vivo and in vitro (Fig. 7). The suppression of hostprotein synthesis may provide a favorable environment for RCNMVin viral protein synthesis and RNA replication in host cellsas reported for many animal viruses (3).

Viral RNA fragments are reported to accumulate in flavivirus(West Nile virus and Japanese encephalitis virus)-infected cells(20, 22, 37, 45). These RNAs are categorized into two types:one type contains the 3'-end sequence of genomic RNA (20, 37),and the other contains negative-sense RNA complementary to the5'- and the 3'-end sequences of genomic RNA. Although the generationmechanism of the former type of positive-sense small RNA remainsunclear, it is possible that the small RNA is generated by cis-element-mediatedprotection against RNases as with RCNMV SR1f, because a stem-loopstructure predicted at the 5' end of the small RNA may protectRNA from 5' $->$ 3' exoribonucleases in animal cells (20, 37). Becauseanother stem-loop structure at the 3' end of flavivirus genomicRNA interacts with both viral and cellular proteins, and isrequired for RNA replication (4-6, 43), the small RNA of flavivirusmay function as a negative regulator of RNA replication.

Small RNAs similar to SR1f have been observed for other dianthoviruses,including CRSV, SCNMV, and the Canadian strain of RCNMV (Fig.6; data not shown). Furthermore, the cap-independent translationenhancer elements with the core 17 nt of RCNMV are conservedamong these dianthoviruses (27, 34, 53; H. Nagano and T. Okuno,unpublished results). These imply that the small RNAs are importantfor the survival of dianthoviruses in nature. To survive andto evolve, viruses must have long-term fitness in both currenthosts and new hosts. Moreover, they need the ability to be transmittedto their hosts, the ability to compete or cooperate with otherviruses in mixed infections in the hosts, the ability to minimizedamage to the hosts, and the ability to replicate efficientlyand infect the host systemically (33). Therefore, these smallRNAs of dianthoviruses might play important roles in any ofthese situations.

In addition to translational control, the presence of the smallRNAs in virions may imply some roles for the RNA in the packagingof viral RNAs to form virions. Moreover, packaging the smallRNA may alter the physical properties of the virions, whichwill affect virion stability and transmission efficiency througheither biological or nonbiological means, including vectorsfor their survival in nature, although little information isavailable on the transmission of dianthoviruses by vectors (13).A correlation between the ability of satellite RNA to stimulatethe encapsidation of groundnut rosette umbravirus (GRV) by groundnutrosette assistor luteovirus CP and its capacity to promote aphidtransmission of GRV has been reported (32).

Novel aspects of our results are as follows: (i) the RNA fragment(SR1f) containing most of the 3' UTR of RCNMV RNA1 accumulatesstably and is packaged into virions in RCNMV-infected cells;(ii) SR1f is not an sgRNA but a degradation intermediate generatedby cis-RNA element-mediated protection against 5' $->$ 3' decay, anda 58-nt sequence (Seq1f58) is necessary and sufficient for theprotection against 5' $->$ 3' decay; (iii) SR1f trans inhibits bothcap/poly(A)-dependent and 3'TE-DR1-mediated cap-independenttranslation in vivo and in vitro; and (iv) SR1f trans inhibitsnegative-strand RNA synthesis of RCNMV in vitro by repressingreplicase protein production but not by competing with RCNMVRNAs for replicase proteins through cis-acting replication elements.

SR1f seems to play important roles in RCNMV infection and survival,although the precise roles of SR1f in RCNMV infection in natureremains to be solved.

ACKNOWLEDGMENTS

We thank S. A. Lommel for the RNA1 and RNA2 cDNA clones of RCNMVAustralian strain and the RNA1 cDNA clone of CRSV.

This work was supported in part by grants-in-aid (13306005 and18208004) from the Japan Society for the Promotion of Science;by a grant-in-aid for scientific research on priority area "SpatiotemporalNetwork of RNA Information Flow" from the Ministry of Education,Culture, Sports, Science and Technology, Japan; and in partby a grant-in-aid for JSPS fellows.

FOOTNOTES

* Corresponding author. Mailing address: Sakyo-Ku, Kitashirakawa, Kyoto 606-8502, Japan. Phone and fax: 81-75-753-6131. E-mail: okuno{at}kais.kyoto-u.ac.jp

Published ahead of print on 13 August 2008.

Present address: Laboratory Animal Research Center, Instituteof Medical Science, The University of Tokyo, 4-6-1 Shirokanedai,Minato-ku, Tokyo 108-8639, Japan.

REFERENCES

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