Plant Virus-Derived Small Interfering RNAs Originate Predominantly from Highly Structured Single-Stranded Viral RNAs

RNA silencing is conserved in a broad range of eukaryotes andincludes the phenomena of RNA interference in animals and posttranscriptionalgene silencing (PTGS) in plants. In plants, PTGS acts as anantiviral system; a successful virus infection requires suppressionor evasion of the induced silencing response. Small interferingRNAs (siRNAs) accumulate in plants infected with positive-strandRNA viruses and provide specificity to this RNA-mediated defense.We present here the results of a survey of virus-specific siRNAscharacterized by a sequence analysis of siRNAs from plants infectedwith Cymbidium ringspot tombusvirus (CymRSV). CymRSV siRNA sequenceshave a nonrandom distribution along the length of the viralgenome, suggesting that there are hot spots for virus-derivedsiRNA generation. CymRSV siRNAs bound to the CymRSV p19 suppressorprotein have the same asymmetry in strand polarity as the sequencedsiRNAs and are imperfect double-stranded RNA duplexes. Moreover,an analysis of siRNAs derived from two other nonrelated positive-strandRNA viruses showed that they displayed the same asymmetry asCymRSV siRNAs. Finally, we show that Tobacco mosaic virus (TMV)carrying a short inverted repeat of the phytoene desaturase(PDS) gene triggered more accumulation of PDS siRNAs than thecorresponding antisense PDS sequence. Taken together, theseresults suggest that virus-derived siRNAs originate predominantlyby direct DICER cleavage of imperfect duplexes in the most foldedregions of the positive strand of the viral RNA.

INTRODUCTION

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Introduction

Eukaryotic organisms have developed a highly adaptable and specificmechanism to protect their genomes against aberrant endogenousor exogenous RNA molecules. This phenomenon, referred to asRNA silencing, is an ancient defense mechanism induced by double-strandedRNAs (dsRNAs) that leads to homology-dependent degradation oftarget RNAs. RNA silencing is conserved across kingdoms andis manifested as quelling in fungi, RNA interference (RNAi)in animals, and cosuppression or posttranscriptional gene silencing(PTGS) in plants. The unifying feature of RNA silencing is thepresence of 21- to 26-nucleotide (nt) small interfering RNAs(siRNAs) (17, 18, 40). In addition, biochemical and geneticanalyses have shown that the core mechanisms of RNA silencingare shared among different eukaryotes (5, 20, 32, 40, 55, 60).RNA silencing is induced by dsRNAs or structured single-strandedRNAs (ssRNAs) that are processed into siRNAs by RNase III-likeenzymes such as DICER (6, 37). siRNAs guide the sequence-specificdegradation of target mRNAs by the RNA-induced silencing complex(RISC) (19). The RISC mediates the cleavage of a target mRNAwhen there is perfect or nearly perfect base pairing betweenthe mRNA and a short guide RNA and mediates translation repressionwhen there is partial complementarity (3, 10, 13, 23). siRNAscan also guide another effector complex, namely, the RNA-inducedinitiation of transcriptional gene silencing (RITS) complex,to direct the chromatin modification of homologous DNA sequences(53).

In addition to siRNAs, there are other short regulatory RNAsin the RNA silencing machinery called micro-RNAs (miRNAs), whichare the products of endogenous noncoding genes. Mature miRNAsare derived by DICER-mediated cleavage from an inverted-repeatmRNA precursor harboring short dsRNA stem-loops (2, 7, 25, 26,28, 35, 43). Importantly, miRNAs are encoded by genes distinctfrom those encoding the mRNAs whose expression they control,while siRNAs are generally derived from the same RNAs that aretargeted by RNA silencing. A third class of small RNAs, theso-called trans-acting siRNAs, are distinct from miRNAs in thatthey are likely derived from long dsRNAs produced by an RNA-dependentRNA polymerase; they also appear to be different from exogenoussiRNAs, as they primarily repress the expression of other genesrather than their own expression (39, 52).

Regardless of their origins, the occurrence of dsRNAs in thecytoplasm of plant cells induces PTGS. It has been demonstratedthat RNA-dependent RNA polymerase is also involved in PTGS (11,36), presumably by converting target ssRNAs into dsRNAs, whichare then processed by DICER to generate siRNAs (58). Remarkably,PTGS can generate mobile silencing signals with sequence-specificinformation that spread from cell to cell through plasmodesmata(short-distance movement) and systemically through the vascularsystem (phloem-mediated long-distance movement) to differentorgans of the plant (21, 33).

An important characteristic of RNA silencing in plants is theinvolvement of two functionally distinct siRNA species thatlikely arise from separate DICER-like activities (17, 48, 50).The 21-nt siRNAs are sufficient for RISC-mediated cleavage oftarget transcripts and are believed to be involved in short-distancesignaling, while the 25-nt siRNAs are associated with DNA methylationand the systemic spread of silencing (17, 21).

Plant viruses are known as strong inducers as well as targetsof PTGS. During a virus infection, the accumulation of 21-ntdouble-stranded siRNAs is observed in local and systemic tissues(18, 49), indicating the activation of PTGS. Elevated siRNAlevels are correlated with a reduction in viral titer, and insome cases, immunity or recovery in upper noninoculated leaves(41, 49). Thus, PTGS acts as an RNA-mediated defense responseto protect plants against viral infection (34, 54, 57). Consequently,to counteract RNA silencing, many plant viruses have evolvedproteins that suppress various steps of the silencing machinery(29, 47, 48, 56). It is not clear how most viral suppressorproteins counteract silencing at the molecular level. The tombusviral19-kDa silencing suppressor protein p19 represents an exception.Indeed, recent advances in our understanding of the molecularmechanism underlying p19's suppressive activity revealed thatp19 specifically binds 21-nt double-stranded siRNAs in vitroand in vivo, preventing siRNA incorporation into effector complexessuch as the RISC (27, 48). The three-dimensional X-ray crystalstructure of a p19-siRNA complex revealed that a p19 dimer actsas a caliper, binding the ends of the siRNA duplex while measuringits length (51, 59).

Cymbidium ringspot virus (CymRSV) is a member of the Tombusvirusgenus containing a positive single-stranded RNA genome withfive open reading frames (ORFs) (44). It is widely assumed thatpositive-strand RNA viruses replicate their genomes via dsRNAintermediates that may activate the siRNA-generating machinery(1). However, the existence of long viral dsRNA intermediatesand their accessibility for DICER cleavage have not been provenexperimentally. In addition, our recent studies suggested thathighly structured viral RNAs might also be processed into siRNAsin virus-infected plants (24, 49).

The work presented here addresses the origins and molecularnature of virus-derived siRNAs and reports the development ofcloning and sequencing approaches to characterize viral siRNAsaccumulating in infected plants. Based on our findings, we suggestthat virus-derived siRNAs are predominantly produced by directDICER cleavage of imperfect duplexes originating from highlybase-paired structures from the positive-strand viral genomicRNA.

MATERIALS AND METHODS

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Materials and Methods

Plasmid constructs, in vitro RNA transcription, and plant inoculation. The infectious cDNA clones of CymRSV, i.e., Cym19stop, TMV.hpPDS₆₀,TMV.PDSas₁₁₀, and PVX, were reported previously (9, 12, 24,49). A full-length infectious clone of the tobacco mosaic virus(TMV) legume strain will be described elsewhere.

In vitro transcription of the previously mentioned viral constructsfrom linearized DNA templates and the inoculation of RNA transcriptsonto Nicotiana benthamiana plants were performed as describedearlier (49). TMV-derived plasmids were linearized with SmaI,and in vitro RNA transcripts were capped with a cap analogue(New England Biolabs, Hitchin, United Kingdom) as previouslyreported (24).

RNA extraction and analysis. The total RNA was extracted from 100 mg of leaf tissue (12).Briefly, the homogenized plant materials were resuspended in600 µl of extraction buffer (0.1 M glycine-NaOH, pH 9.0,100 mM NaCl, 10 mM EDTA, 2% sodium dodecyl sulfate, and 1% sodiumlauroylsarcosine) and mixed with an equal volume of phenol.The aqueous phase was treated with equal volumes of phenol andchloroform, precipitated with ethanol, and resuspended in sterilewater. RNA gel blot analysis of high-molecular-weight RNAs wasperformed as described previously (12).

Detection, isolation, labeling, and sequencing of virus-derived siRNAs. RNA gel blot analysis of siRNAs was performed as described previously(49). For preparations of labeled viral siRNAs, 15 to 20 µgof total RNA from virus-infected plants was subjected to electrophoresisthrough a 12% denaturing polyacrylamide gel, followed by stainingwith a 1x Tris-borate-EDTA, 0.5 µg/ml ethidium bromidesolution for 20 min. ss- and dsRNAs were visualized with UVlight and excised from the gel. The gel slices were crushed,covered with 2 volumes of elution buffer (80% formamide, 40mM PIPES, pH 6.4, 1 mM EDTA, and 400 mM NaCl), and incubatedovernight. The gel residues were pelleted by centrifugation,and the supernatants were ethanol precipitated. The purifiedsiRNAs (approximately 1 µg) were dephosphorylated andsubsequently labeled in 10-µl reaction mixtures in thepresence of [ ${gamma}$ -³²P]ATP and RNasin with 8 U of T4 polynucleotidekinase. The labeled virus-specific siRNAs were used for hybridization(49).

Purified siRNAs were cloned according to the original siRNAcloning protocol as described previously (14), with some minormodifications. Briefly, denaturing gel-purified viral dephosphorylatedsmall RNAs were ligated to 3'-terminal adapter oligonucleotides.The ligation products were 5' end labeled with [ ${gamma}$ -³²P]ATP andrecovered after migration in a sequencing gel (8% polyacrylamide,8 M urea). 5' adapters were then ligated to the phosphorylatedintermediate products. These ligation products were then gelpurified, excised, and eluted as previously described (14).After reverse transcription-PCR amplification, the oligonucleotide-linkedcDNAs were cloned as concatemers into the pBluescript SK(+)vector. The recombinant clones were randomly selected and sequenced.

IP. For immunoprecipitation (IP), 2 g of CymRSV- or Cym19stop-infectedN. benthamiana leaves showing systemic symptoms were collectedat 6 days postinoculation and used to prepare extracts in IPbuffer (30 mM HEPES-KOH, pH 7.5, 100 mM NaCl, 66 mM KCl, 1 mMMgCl₂, 1 mM dithiothreitol, 0.2 mM phenylmethylsulfonyl fluoride),and the extracts were then centrifuged at 15,000 x g for 10min. IPs were performed at 41°C for 3 to 5 h. Beads werecentrifuged and washed in 1x IP buffer two times. Input extractsand IP eluates were used for Western blotting analysis and RNAisolation. RNA molecules were separated in a sequencing gel(12% polyacrylamide, 8 M urea), blotted, and hybridized withan appropriate probe.

RESULTS AND DISCUSSION

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Results and Discussion

The majority of viral siRNAs are derived from viral positive-strand RNA. To evaluate the polarity of siRNAs in virus-infected plants,we extracted total RNAs from systemically infected leaves ofCymRSV-infected N. benthamiana plants at 7 days postinoculation.The extracted RNA samples were separated by 8% denaturing polyacrylamidegel electrophoresis (PAGE), blotted, and hybridized with a coatprotein (CP) probe (48) representing the central part of thevirus genome. CP-specific siRNAs accumulated to a relativelyhigh level and comigrated exclusively with a 21-mer RNA oligonucleotide(not shown). The purified siRNAs were cloned and sequenced todetermine their exact size as well as the origin of CymRSV-specificsiRNAs. Random sequencing of a total of 70 clones identified228 siRNAs homologous to the sequence of the CymRSV genome (seeTable S1 in the supplemental material). Eight siRNAs containingnonviral sequences were not analyzed further. The nucleotidesequences of the virus-derived siRNAs were derived from regionsalong the length (4,733 nt) of the viral genome (Fig. 1A). Asize distribution analysis of the CymRSV siRNAs confirmed thatthese RNAs belonged to the short siRNA fraction, with an averagesize of 20 to 21 nucleotides (Fig. 1B).

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FIG. 1. Origin and characterization of siRNAs derived from CymRSV. (A) Schematic representation of CymRSV genome (top). Each of the shaded boxes represents a viral ORF. The position of each siRNA sequence is represented by a small circle alongside the viral genome. Circles above the genome bar, siRNAs derived from the positive viral strand; circles below the genome bar, siRNAs derived from the negative viral strand. siRNAs with the same sequences are indicated as chains of connected circles. (B) Size distribution of sequenced siRNAs. Numbers below the columns indicate the sizes of virus-specific siRNAs, and numbers above the columns indicate the numbers of siRNAs of different sizes.

The most accepted virus-induced RNA silencing model (1, 54,57) suggests that a DICER-like enzyme generates siRNAs fromdouble-stranded replicative intermediates of RNA viruses, andthus the expected ratio between positive- and negative-strand-derivedsiRNAs should be 1:1. However, sequencing of the cloned siRNAsindicated that 80% of viral siRNAs were derived from the positive-strandviral RNA, reinforcing our previous observations of the natureof virus-derived siRNAs (49). In addition, the sequences of228 siRNAs homologous to the CymRSV genomic RNA revealed that194 virus-specific siRNA clones could be assigned to severalclusters that likely represent hot spots for siRNA production(Fig. 1A). These results suggest that siRNAs in the CymRSV systemare predominantly processed by DICER cleavage of imperfect duplexes,which can be formed from the positive-strand viral RNA. Thisprocess resembles the production of short-lived, imperfectlypairing, double-stranded intermediates during miRNA generation(4, 8). The preferential incorporation of positive-strand siRNAsinto the RISC cannot explain this asymmetric accumulation becausethe sequence composition of siRNAs does not display a significantlyreduced stability profile at the 5' end (see Table S1 in thesupplemental material). This observation of asymmetry contrastswith other recent interpretations in which siRNAs were thoughtto arise from dsRNAs that were produced either by viral transcriptionevents or by the action of host RNA-dependent RNA polymerase(1, 54, 57).

Virus-derived double-stranded siRNAs are imperfect duplexes. The finding that virus-derived siRNAs are asymmetric raisedthe question of whether these siRNAs are present in infectedcells in a ss- or dsRNA form. To determine the structure ofviral siRNAs, we examined the mobilities of these moleculesunder native nondenaturing conditions. RNA extracts of CymRSV-infectedtissues were separated by 10% native PAGE along with both single-strandedand double-stranded 21-nt synthetic siRNAs. The results presentedin Fig. 2A indicate that only one additional low-molecular-weightRNA fraction could be detected in virus-infected N. benthamianaplants compared to the noninfected plant extract. This low-molecular-weightRNA fraction comigrated with siRNA duplexes, strongly suggestingthat it was composed of a double-stranded siRNA. Northern hybridizationof the same samples confirmed that this double-stranded siRNAwas derived from CymRSV RNA (27; data not shown).

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FIG. 2. Analysis of CymRSV siRNA composition. (A) RNA samples were extracted from CymRSV-infected plants and separated in a 10% native polyacrylamide gel alongside with both single-stranded and double-stranded 21-nt synthetic siRNAs. (B) RNase A digestion assay with purified CymRSV-specific siRNA (CymRSV siRNA_nat) under nondenaturing conditions. Synthetic double-stranded siRNAs (control) and CymRSV siRNA_nat were incubated in high (2x SSC)- and low (0.1x SSC)-salt buffer in the presence of increasing RNase A concentrations. (C) The CymRSV siRNA_nat shown in panel A was labeled and used as a probe in a Northern blot experiment to hybridize both negative- and positive-strand transcripts for the CymRSV coat protein (CP). A ³²P-labeled, PCR-amplified DNA fragment containing the CP region was also used as a probe to show the amount of loaded CymRSV CP transcript.

If viral siRNAs are mostly derived from highly structured regionsof the positive-strand viral RNA, then these double-strandedsiRNAs (Fig. 2A) should contain non-base-paired nucleotides,which are nuclease sensitive. To confirm this hypothesis, weperformed RNase A digestion to assess whether these moleculeswere perfect or imperfect duplexes. Perfect dsRNAs are resistantto RNase A in a high salt buffer (2x SSC [1x SSC is 0.15 M NaClplus 0.015 M sodium citrate]), while imperfect dsRNAs with mismatchesare rapidly degraded under the same conditions (45). The double-strandedsiRNA fraction purified from the native gel (CymRSV siRNA_nat)was sensitive to RNase A, indicating the presence of mismatchesbetween the two viral siRNA strands (Fig. 2B, top panel). Incontrast, control synthetic perfectly double-stranded siRNAswere completely resistant to RNase A, even at a high nucleaseconcentration and in high-salt buffer (Fig. 2B, bottom panel).In addition, labeled CymRSV-derived small RNAs isolated by nativePAGE (CymRSV siRNA_nat) hybridized more intensively to the negative-strandcoat protein (CP) transcript than to the corresponding positive-strandtranscript (Fig. 2C). The finding that virus-derived siRNAsare imperfect dsRNAs is consistent with the model that viralsiRNAs are processed from highly base-paired structures. Theseobservations also corroborate our previous results that artificiallyextended base-paired structures imbedded in viral ssRNAs giverise to correspondingly high levels of siRNAs. Together, theseobservations suggest that highly structured regions within viralssRNAs are able to trigger RNA silencing (49).

p19-bound siRNAs have predominantly positive-strand polarity. We recently reported that the majority of virus-specific siRNAsare bound by p19 in tombusvirus-infected plants. These p19-boundsiRNAs are double-stranded and can efficiently trigger the sequence-specificdegradation of CymRSV viral RNA in a Drosophila melanogasterembryo extract (27). To test whether p19-bound double-strandedviral siRNAs also have an asymmetric composition with respectto strand specificity, we analyzed the ratio of positive tonegative strands in p19-bound siRNAs. RNAs were extracted fromanti-p19-immunoprecipitated p19-siRNA complexes derived fromCymRSV-infected plants (27) and subsequently analyzed by Northernhybridization using strand-specific probes. As expected fromthe sequence analysis of siRNAs, the majority of p19-bound siRNAsoriginated from the positive strand of the viral RNA (Fig. 3),further supporting the model that CymRSV siRNAs originate fromhighly structured viral RNA regions. An alternative explanationfor the specific accumulation of positive-strand siRNAs couldbe that the positive strand of a perfect double-stranded siRNAis preferentially incorporated into the RISC or other effectorcomplexes instead of the negative strand, with the latter beingrapidly eliminated by cellular nucleases. However, our previousobservation that p19 sequesters siRNAs before their incorporationinto the RISC, when they are still double-stranded siRNAs (27),strongly argues against this alternative model.

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FIG. 3. Analysis of CymRSV p19-bound siRNA polarity. RNA samples were extracted from CymRSV-infected plants or from immunoprecipitates (anti-p19 IP) by use of a p19 antibody. Lanes 1, input RNA from protein extract used for IP; lanes 2, RNA extract from IP using preimmune antiserum; lanes 3 to 5, 2, 4, and 6 µl of RNA extract, respectively, from anti-p19 IP; lanes 6, 20 pM 46-mer RNA oligonucleotide containing positive-strand sequence for CymRSV CP; lanes 7, 20 pM 46-mer RNA oligonucleotide containing negative-strand sequence for CymRSV CP; lanes 8 to 10, 2, 4, and 6 µl of RNA extract, respectively, from CymRSV-infected plants. The membrane was hybridized with CymRSV positive-strand (left) and negative-strand (right) ${alpha}$ -³²P-labeled RNA transcripts.

The preferential accumulation of positive-strand siRNAs is a general characteristic of positive-strand RNA viruses. To investigate whether the characteristics of CymRSV siRNAsreflect the general rule for virus-derived siRNA generationin virus-infected plants, we also included two other nonrelatedpositive-strand RNA viruses, Potato virus X (PVX) (9) and TMV(46), in our analysis. As with CymRSV, infections of N. benthamianaplants with PVX and TMV resulted in the appearance of singlesiRNA fractions of 21 to 22 nt (Fig. 4A). To analyze whetherPVX- and TMV-derived siRNAs are also asymmetric, we inducedthe transcription of the CP-encoding regions of the two viruseswith both positive and negative polarities. These transcriptswere then subjected to Northern hybridization and probed with5'-labeled siRNAs isolated from either PVX- or TMV-infectedplants. In both cases, the majority of the labeled virus-specificsiRNAs hybridized more strongly to the negative transcript,indicating that similar to the case with CymRSV, PVX and TMVsiRNAs are derived mainly from viral RNAs with a positive polarity(Fig. 4B).

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FIG. 4. Identification of polarity of 21-nt siRNAs accumulating in PVX- and TMV-infected plants. (A) Accumulation of virus-specific high-molecular-weight genomic RNAs and siRNAs. The left (PVX) and right (TMV) panels show the viral RNAs (top) and siRNAs (bottom) in RNA extracts of virus-infected tissues. High-molecular-weight RNA extracts were separated in ethidium bromide-stained agarose gels, and virus-specific siRNAs were separated by 10% denaturing PAGE and hybridized with appropriate virus-specific probes. RNA oligonucleotide size markers were run along with the siRNAs. m, mock-infected control plants. (B) Known amounts of positive and negative strands of PVX and TMV RNAs were in vitro transcribed, subjected to Northern blotting, and then hybridized with 5'-end-labeled virus-specific siRNAs (panel A). As a loading control for in vitro-generated transcripts, the same membrane was hybridized with a ³²P-labeled PCR-amplified DNA fragment derived from PVX or TMV as indicated. Numbers above the lanes indicate the quantities of loaded RNA in ng. "+" and "–" indicate the polarities of the loaded viral RNA transcripts. M, control RNA sample extracted from a healthy plant; G, CymRSV genomic transcript.

It was recently reported that the expression of a host genefragment as a short inverted repeat from TMV leads to more efficientsilencing of the cognate mRNA than the expression of a similarsequence in just the sense or antisense orientation (24). Tobetter understand this observation at the molecular level, wecompared the siRNA accumulation in plants infected with a viralvector carrying a hairpin structure to that in plants infectedwith an antisense sequence. To this end, viral transcripts carrying60-bp inverted repeats (TMV.hpPDS₆₀) or the corresponding antisensesequence (TMV.PDSas₁₁₀) homologous to the endogenous phytoenedesaturase (PDS) gene (24) were used to inoculate N. benthamianaplants. RNAs were extracted from TMV-infected leaves showingthe white coloration characteristic of the photobleaching phenotypeobserved for PDS-silenced plants and then analyzed for bothviral RNA accumulation and virus-derived siRNA composition (Fig.5). The photobleaching phenotype of PDS-silenced plants wasmore pronounced with the TMV.hpPDS₆₀ hairpin construct thanin plants infected with the TMV.PDSas₁₁₀ antisense construct(Fig. 5A), in spite of similar viral RNA accumulation in virus-infectedplants (Fig. 5B, top panel). More importantly, the siRNA accumulationoriginating from the hairpin sequence was significantly higherfor both the plus (12 times) and minus (5 times) polaritiesthan that from the antisense sequence containing the 60-nt sequenceof the corresponding hairpin construct (Fig. 5B, bottom panels).

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FIG. 5. Accumulation of PDS-specific siRNAs in TMV vector-infected plants carrying hairpin (TMV.hpPDS₆₀) and antisense (TMV.PDSas₁₁₀) PDS sequences, as previously described (24). (A) Virus-infected plants developing photobleached white leaves typical of PDS-silenced plants at 3 weeks postinoculation. The genome organization of TMV viral vectors is represented schematically, with colored boxes representing the different viral ORFs. Open arrows show the positions and orientations of inserted sequences in the TMV genome. (B) RNA gel blot analysis of viral RNAs extracted at 2 weeks postinoculation from plants infected with the TMV.hpPDS₆₀ hairpin or TMV.PDSas₁₁₀ antisense construct. RNAs were separated in 1.2% denaturing agarose gels, blotted, and hybridized with a TMV.hpPDS₆₀ probe. PDS-specific siRNAs were separated by 10% denaturing PAGE and hybridized with a labeled 60-mer oligonucleotide corresponding to the sense and antisense counterparts of the PDS cDNA from the TMV.hpPDS₆₀ construct. TMV, wild-type virus-infected RNA extract. One, 5, and 25 pM 60-mer sense (s) and antisense (as) PDS oligonucleotides, indicated by open arrows, were used to control the specificity of the probes.

Taken together, these results strongly suggest that one or moreof the plant-encoded DICER-like enzymes are able to recognizehighly structured regions within viral ssRNAs and process theminto siRNAs. This property resembles the DICER-like activityinvolved in the generation of miRNAs from short-hairpin precursors(16, 22, 30, 38, 42, 58), although recent data indicate thatsiRNAs and miRNAs require different DICER-like activities inplants (15, 50, 58). The discrete size (21 nt) of virus-derivedsiRNAs, however, suggests that one of the still unidentifiedplant DICERs has evolved specifically to process highly structuredviral RNAs and is likely a key player in the PTGS-mediated antiviraldefense. A recent report demonstrated that an Arabidopsis dcl2mutant transiently accumulated lower levels of Turnip crinklevirus-derived siRNAs than did wild-type plants (58). However,there is likely to be some degree of redundancy because dcl1,dcl2, and dcl3 mutants were not defective in siRNA productionwhen they were infected with other viruses.

The fact that plant DICER-like proteins generate predominantlypositive-strand siRNAs makes the siRNA-based antiviral surveillancesystem more effective since the siRNAs potentially target thenegative viral strand for RISC-mediated cleavage, which is requiredfor replication and is much less abundant than the positive-strandviral RNA. In further support of this model, it was reportedthat transgenic plants expressing a positive-strand viral sequencespecifically target the negative-strand RNA of TMV. This suggeststhat the transgenically expressed sense viral sequence can beprocessed into positive-strand siRNAs, which in turn specificallytarget the negative-strand viral RNA replicative intermediatefor degradation (31). Since the sense siRNAs derived from foldedRNA are partially complementary to the positive-strand viralRNA, positive siRNAs could also guide the translational repressionof viral RNA in a manner analogous to miRNA-mediated translationalcontrol, which relies on only partial complementarity betweenthe miRNA and the target. This type of gene silencing is commonin animal systems (2, 5) but also seems to operate in plants(3, 10). Further experiments are required to address whetherthis additional level of control occurs.

ACKNOWLEDGMENTS

We thank Daniel Silhavy, György Szittya, Gábor Giczey,and Alan Herr for critical readings of and helpful commentson the manuscript.

L.L. is a recipient of a Bolyai János Fellowship. Thisresearch was supported by grants from the Hungarian ScientificResearch Fund (OTKA; T046728), the "RIBOREG" EU project (LSHG-CT-2003503022),and the Scientia Amabilis Foundation.

FOOTNOTES

* Corresponding author. Mailing address: Agricultural Biotechnology Center, Plant Biology Institute, P. O. Box 411, H-2101 Gödöllö, Hungary. Phone: 36-28-526-155. Fax: 36-28-526-145. E-mail: burgyan{at}abc.hu.

Supplemental material for this article may be found at http://jvi.asm.org/.

Present address: The Sainsbury Laboratory, John Innes Centre,Colney, Norwich NR4 7UH, United Kingdom.

REFERENCES

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