Initiation of Genomic Plus-Strand RNA Synthesis from DNA and RNA Templates by a Viral RNA-Dependent RNA Polymerase

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Journal of Virology, August 1999, p. 6415-6423, Vol. 73, No. 8
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Initiation of Genomic Plus-Strand RNA Synthesis from DNA and RNA Templates by a Viral RNA-Dependent RNA Polymerase

K. Sivakumaran and C. Cheng Kao^*

Department of Biology, Indiana University, Bloomington, Indiana 47405

Received 2 November 1998/Accepted 23 April 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

In contrast to the synthesis of minus-strand genomic and plus-strand subgenomic RNAs, the requirements for brome mosaic virus(BMV) genomic plus-strand RNA synthesis in vitro have not beenpreviously reported. Therefore, little is known about the biochemicalrequirements for directing genomic plus-strand synthesis. UsingDNA templates to characterize the requirements for RNA-dependentRNA polymerase template recognition, we found that initiationfrom the 3' end of a template requires one nucleotide 3' of theinitiation nucleotide. The addition of a nontemplated nucleotideat the 3' end of minus-strand BMV RNAs led to initiation of genomicplus-strand RNA in vitro. Genomic plus-strand initiation was specificsince cucumber mosaic virus minus-strand RNA templates were unableto direct efficient synthesis under the same conditions. In addition,mutational analysis of the minus-strand template revealed thatthe $-$ 1 nontemplated nucleotide, along with the +1 cytidylate and+2 adenylate, is important for RNA-dependent RNA polymerase interaction.Furthermore, genomic plus-strand RNA synthesis is affected bysequences 5' of the initiationsite.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Replication of the viral genome is an essential feature of viral pathogenesis. In RNA viruses whose genomes can be translateddirectly after entry into the cell, the genomic plus-strand RNAserves as the template for minus-strand synthesis. The minus-strandRNA then serves as the template for generating multiple copiesof genomic and, where applicable, subgenomic plus-strand RNAs(4). Our laboratory studies viral RNA replication in bromemosaic virus (BMV) as a model system. BMV is a plant-infectingtripartite plus-strand RNA virus and is the type member of thebromovirus group of plant viruses of the alphavirus-like superfamily(8). BMV has three genomic RNAs, which are designated RNA1(3.2 kb), RNA2 (2.8 kb), and RNA3 (2.1 kb). RNA1 and RNA2 aremonocistronic and encode the 1a protein and 2a protein, whichare essential for the replication of the BMV genome (2). RNA3is dicistronic and encodes the 3a movement protein and the coatprotein.

Replication of viral RNA is facilitated by the RNA-dependent RNA polymerase (RdRp), a complex composed of 1a, 2a, and unidentifiedcellular proteins. The BMV RdRp can accurately initiate minus-strandRNA synthesis from input plus-strand templates and can initiatethe synthesis of subgenomic plus-strand RNA products from inputminus-strand templates (1, 9, 12, 14, 15, 21, 22).In contrast, little is known about sequence and structural elementsrequired for directing genomic plus-strand RNA synthesis, in largepart because an in vitro assay for initiation of BMV genomic RNAsynthesis was not previously reported. In this work, our studiesof RNA synthesis from DNA templates led us to propose that BMVgenomic plus-strand RNA synthesis require a nontemplated nucleotide.The addition of this nucleotide to the 3' end of BMV minus-strandRNAs led to the initiation of genomic plus-strand RNAs in vitro.We also present detailed analyses of the sequence requirementsnecessary for accurate initiation of genomic plus-strand RNAsyntheses.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Synthesis of DNA and RNA templates for the RdRp assay. Synthetic deoxyoligonucleotides used as template for RdRp assays were purchased from Operon Technology. All oligonucleotideswere quantified by spectrophotometry, adjusted to the desiredconcentration, and visually inspected after being stained withtoluidine blue after gel electrophoresis. RNA templates were madeby PCR and used for in vitro transcription. One of the PCR primerscontained a T7 promoter to allow transcription directly from thePCR products. Typically, each of 30 PCR cycles consisted of 30s of denaturation at 94°C, annealing at 5°C before the lowestoligonucleotide melting temperature (T_m), and elongation at 72°C.PCR products were purified by standard methods (20) followedby in vitro transcription (Ampliscribe; Epicentre). Transcriptswere purified by anion-exchange chromatography on Qiagen Tip-20columns as specified by the manufacturer. The concentration ofRdRp templates was determined by toluidine blue staining followingdenaturing polyacrylamide gel electrophoresis (PAGE) and byspectrophotometry.

RdRp activity assays. BMV RdRp was prepared from infected barley as described by Sun et al. (26). Standard RdRp activity assay mixtures consistedof 40-µl solutions containing 20 mM sodium glutamate (pH 8.2),4 mM MgCl₂, 12 mM dithiothreitol, 0.5% (vol/vol) Triton X-100,2 mM MnCl₂, 200 µM ATP, 500 µM GTP, 200 µM UTP, 242 nM [ $alpha$ -³²P]CTP (400 Ci/mmol, 10 mCi/ml; Amersham), the desired amount oftemplate, and 5-10 µl of RdRp. Following incubation for 90 minat 30°C, the reaction products were extracted with phenol-chloroform(1:1, vol/vol) and precipitated with 6 volumes of ethanol, 10µg of glycogen, and 0.4 M (final concentration) ammoniumacetate.

Products of the RdRp reactions were digested with 2.5 U of S1 nuclease for 10 min at 30°C in the buffer supplied by the manufacturer(Promega). Denaturing loading buffer (45% [vol/vol] deionizedformamide, 1.5% [vol/vol] glycerol, 0.04% [wt/vol] bromophenolblue, 0.04% [vol/vol] xylene cyanol) was added to the S1-treatedproducts. The samples were heated at 90°C for 3 min and then analyzedby PAGE on 10% acrylamide gels containing 7 M urea. All the gelswere exposed to film at $-$ 80°C, and the amount of label incorporatedinto newly synthesized RNAs was determined with a PhosphorImager(MolecularDynamics).

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

DNA templates for RNA synthesis. While RNA is the preferred template for the BMV RdRp, accurate initiation of RNA synthesis can use DNA templates (23). Initiationof RNA synthesis from a DNA template can take place from eithera penultimate cytidylate or an internal cytidylate in processesresembling the synthesis of genomic minus-strand and subgenomicRNAs. Furthermore, the interaction between RdRp and DNA, as measuredby a template competition assay, is remarkably similar to theinteraction between RdRp and RNA (23). The ease of manipulationof DNA templates through standard chemical synthesis makes DNAan attractive substitute for determining the requirements forRNA synthesis from RNAtemplates.

To examine synthesis from DNA templates, deoxyoligonucleotide d( $-$ 1/13) was used as the prototype. d( $-$ 1/13) contains the sequencecomplementary to the template for the BMV subgenomic RNA (nucleotides[nt] 1241 to 1252 of BMV RNA3). This template directs the synthesisof two products of 13 and 14 nt; the latter is the result of nontemplatednucleotide addition by the BMV RdRp (21). The $-$ 1 nt is a guanylate,which, along with the initiation cytidylate (+1), has previouslybeen demonstrated to be necessary for RNA synthesis (23). Twoguanylates were added at the 5' end to allow transcription initiationby T7 polymerase and to direct the incorporation of radiolabeledcytidylates.

The requirements for the initiation of RNA synthesis from the penultimate nucleotide were examined first. Consistent withthe report of Siegel et al. (23), the removal of the 3'-terminalguanylate reduced RNA synthesis to 10% of that for d( $-$ 1/13) (Fig.1A, lane 1). However, the $-$ 1 guanylate can be replaced with auridylate, cytidylate, or adenylate and RNA synthesis is thenbetween 38 to 63% of that for d( $-$ 1/13) (lanes 3 to 5). Additionof a cytidylate at the $-$ 1 position should place a potential initiationnucleotide at both the 3' terminus and the penultimate position.However, initiation still took place from the penultimate cytidylateas judged by the mobility of the resultant RNA. The addition oftwo nucleotides (3' AG) 3' of the initiation cytidylate decreasedRNA synthesis to 33%. However, the resulting products were indistinguishablein size from those produced by d( $-$ 1/13), suggesting that initiationstill took place from the authentic cytidylate. Addition of 3nt (3' AAG) 3' of the initiation cytidylate resulted in synthesisat 14% of that from d( $-$ 1/13). These results indicate that thepenultimate cytidylate is the preferred nucleotide for initiationand that additional sequence 3' of the initiation nucleotide canaffect the efficiency of RNA synthesis.

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FIG. 1. Synthesis of plus-strand RNA by using DNA templates. (A) Template d( $-$ 1/13) containing the sequence complementary to nt 1241 to 1252 of BMV RNA3 are shown with the initiation cytidylate indicated by an arrow. Changes of the 3' ends of d( $-$ 1/13), the +2 adenylate, the +3 uridylate, and the +4 adenylate were used for RNA synthesis by BMV RdRp. The changes are indicated above the autoradiogram of the RdRp products. The positions of the 13- and 14-nt products are shown on the left. The reaction products were separated by denaturing PAGE (12% polyacrylamide) and visualized by autoradiography. (B) Summary of the effect of nucleotide changes focusing on the 3' end of the initiation site. All results presented were from at least three independent trials. (C) Summary of the effect of nucleotide changes at positions +2, +3, and +4 in d( $-$ 1/13). (D) Effect of changes to a guanylate in the first six positions in d( $-$ 1/13) on plus-strand RNA synthesis.

Replacement of nucleotides at positions +2 to +7. The sequence immediately 5' of the initiation site is rich in A and U nucleotides. Marsh et al. (14) have proposed thatthis sequence contributes to efficient RNA synthesis. All possiblechanges of nucleotides from positions +2 to +4 were made to examinethe requirements for RNA synthesis (Fig. 1A, lanes 8 to 16). Replacementof the +2 adenylate with uridylate resulted in synthesis at levelssimilar to that for d( $-$ 1/13). However, changing the +2 adenylateto a guanylate or a cytidylate reduced synthesis to less than30% of that for d( $-$ 1/13) (Fig. 1C). Transition from uridylateto cytidylate at the +3 position was acceptable for RNA synthesiswhile transversion to purines decreased RNA synthesis to lessthan 20% of that for d( $-$ 1/13) (Fig. 1A, lanes 1 to 13). Changingadenylate to either uridylate or cytidylate at the +4 positionresulted in levels of RNA synthesis similar to those for d( $-$ 1/13),while a change to a guanylate decreased RNA synthesis to 21% (Fig.1A, lanes 14 to 16; Fig. 1C).

The presence of guanylates at positions +1 to +4 was detrimental for efficient RNA synthesis (Fig. 1D). To examine this correlationfurther, positions +5 and +6, normally uridylates, were individuallychanged to guanylate. A change of U to G at +5 yielded the sameRNA synthesis as for d( $-$ 1/13), while a change of U to G at +6resulted in 40% of the synthesis for d( $-$ 1/13). A change of A toG at +7 also resulted in the same level of synthesis as for d( $-$ 1/13)(data not shown). These results suggest that the presence of aguanylate at the first four positions of the template would decreasethe efficiency of RNA synthesis but that this requirement maybe relaxed starting at the +5position.

Interaction between DNA template and RdRp. Changes at various positions along the DNA template could affect either the ability of the template to interact stably withRdRp or the efficiency of nucleotide incorporation into the nascentRNA. We used a template competition assay (21) to distinguishbetween these two possibilities. The reaction mixture containslimiting amounts of RdRp, a reference RNA, r( $-$ 20/15), which directsthe synthesis of a 15-nt product, and various concentrations ofthe competitor template. Many of the competitor templates chosenfor this analysis were observed to decrease RNA synthesis (Fig.2). For simplicity, the experiments described below used r( $-$ 20/15)as the reference template. Competitor d( $-$ 1/13) at fivefold molarexcess reduced synthesis from r( $-$ 20/15) to 60%. A more severereduction was observed when d( $-$ 1/13) was present at 10-fold molarexcess of r( $-$ 20/15). Removal of the $-$ 1 nucleotide resulted ina template that could no longer compete with r( $-$ 20/15) for RNAsynthesis even at 10-fold molar excess (Fig. 2). The ability toinhibit RNA synthesis was partially restored when the $-$ 1 nucleotideof the template was a cytidylate, consistent with its being amore effective template. When the initiation nucleotide was atthe fourth position from the 3' end due to the addition of 3'AAG, the ability to inhibit synthesis was again reduced.

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FIG. 2. Effect of nucleotide changes in d( $-$ 1/13) on the ability of the resultant DNA template to compete for RdRp. An RNA template, r( $-$ 20/15), directing the synthesis of a 15-nt product, was used as a reference. The amounts of RNA synthesis generated from r( $-$ 20/15) in the presence of the different competitors are listed as percentages relative to synthesis in the absence of competitor. DNA competitors were used at 5- and 10-fold molar excess with respect to r( $-$ 20/15). All results were from at least three independent trials. ND, not determined.

To determine whether the initiating cytidylate is also involved in the stable interaction with RdRp, competitors were testedin molar excess of the reference template. At fivefold molar excess,a change of the cytidylate to a guanylate (+1C/G) reduced theability of the template to stably interact with RdRp. A significantdecrease in synthesis occurred when +1C/G was present at 10-foldmolar excess, suggesting that the ability of the template to interactwith RdRp is partially retained. Previous studies with the BMVsubgenomic RNA promoter showed that a change of the initiationnucleotide was able to reduce, but not abolish, stable interactionwith RdRp (21).

In contrast to the importance of the $-$ 1 and +1 positions, changes in upstream positions along the template had less dramaticeffect on the stable interaction with RdRp. Although some nucleotidesubstitutions at the +2 position reduced the ability to directRNA synthesis, their ability to compete for interaction with RdRpwere similar to that of wild-type (wt) d( $-$ 1/13) (Fig. 1C) (24).Similarly, changes at position +3 or +6 did not significantlyaffect the ability of the template to interact with RdRp (Fig.2).

A more quantitative analysis of the interaction between DNA templates and the BMV RdRp was performed. DNA competitor was addedin increasing molar amounts relative to r( $-$ 20/15) to determinethe concentration of the competitor DNA required to reduce synthesisby 50% (IC₅₀). Lower IC₅₀s indicate that the competitor can interactmore stably with RdRp. The IC₅₀ of wt d( $-$ 1/13) was 175 nM. Anoligonucleotide with deoxythymidines instead of deoxyuridine hada similar IC₅₀ value of 150 nM (Fig. 3). These results show thatthe C-5 methyl group that distinguishes thymines from uracilsdoes not have a detectable effect on the ability of the DNA templateto interact with RdRp. Consistent with the inhibition assay resultsshown in Fig. 2, removal of the 3'-terminal guanylate or changingof the initiation cytidylate to a guanylate raised the IC₅₀ toca. 1 mM. These results indicate that the primary determinantsfor RdRp-DNA template interaction lie within nt $-$ 1 and +1. Additionalsequence upstream of the initiation site must affect RNA synthesisat a level beyond stable interaction with the BMV RdRp.

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FIG. 3. Concentration of DNA templates needed to reduce RNA synthesis from r( $-$ 20/15) by 50%. The percentage of synthesis from r( $-$ 20/15) directing the synthesis of a 15-nt product was measured in the presence of increasing amounts of competitor DNA. The IC₅₀s are given within the boxed region. The results for d( $-$ 1/13)dT were not plotted, to reduce the complexity of the figure.

Synthesis of genomic plus-strand RNAs from minus-strand endscripts. The results of the DNA template studies described above suggest that an additional nucleotide 3' of the initiation cytidylatemay be required. Siegel et al. (21) have demonstrated that BMVRdRp could add a nontemplated nucleotide at the 3' end of an RNAmolecule. Since the presence of this nontemplate nucleotide inthe minus-strand RNA would not direct the incorporation of anextra nucleotide in the viral RNAs, it may have been missed inroutine analyses of viralsequences.

We wanted to examine the requirements for the initiation of BMV genomic plus-strand RNA synthesis by using RNA templates.Short RNAs of 58, 46, and 51 nt, each with an extra 3' guanylate,were generated to correspond to the minus strand of BMV RNA1,RNA2, and RNA3, respectively. These short transcripts were termed"endscripts," since they represented the minus-strand 3' endsof BMV RNAs (Fig. 4B). All three endscripts should contain thecomplete stem-loop structure observed to be required for plus-strandgenomic RNA synthesis in vivo (18). By using a standard RdRpassay, we observed that endscripts B2( $-$ )46G, B1( $-$ )58G, and B3( $-$ )51Gwere all able to direct plus-strand synthesis (Fig. 4C, lanes1 and 2, 5 and 6, and 9 and 10, respectively). A high-resolutiongel shows that these bands may be composed of fragments of twodistinct sizes, possibly due to nontemplated terminal nucleotideaddition by the BMV RdRp (24). As a control for the specificityof RNA synthesis, we tested endscripts of the minus strand ofcucumber mosaic virus (CMV) RNA2 and RNA3, i.e., CMV2( $-$ )G andCMV3( $-$ )G, respectively. CMV2( $-$ )G, of 64-nt, was able to directsynthesis at only 10% of B2( $-$ )46G, and CMV3( $-$ )G, of 54 nt, wasunable to direct any synthesis of discrete RNA products by theBMV RdRp (Fig. 4C, lanes 13 to 16). The synthesis from BMV endscriptis thus species specific. To determine whether initiation of BMVendscripts took place from the penultimate cytidylate, the +1cytidylate was mutated to a guanylate in all three BMV endscripts.These mutants were greatly reduced in their ability to directplus-strand synthesis (Fig. 4C, lanes 3 and 4, 7 and 8, and 11and 12), indicating that genomic plus-strand RNA synthesis isinitiated from the cytidylate presumed to be used in vivo (2).A smear, presumed to be misinitiated RNAs, is observed in laneswith mutant B3( $-$ )51G endscripts (lanes 11 and 12). Initiationof genomic plus-strand RNA is approximately one-third of initiationof a 46-nt RNA from the subgenomic promoter (1). However, theseresults clearly indicate that in vitro BMV RdRp is able to specificallydistinguish BMV promoters and initiate genomic plus-strand synthesis.

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FIG. 4. Initiation of genomic plus-strand RNAs directed by minus-strand endscripts. (A) Comparison of the 3' sequences of BMV and CMV minus-strand RNAs. The nontemplated guanylate added to each template is shown in bold type. The initiation cytidylate is denoted by an arrow. (B) Predicted secondary structures of the 3' ends of BMV RNA1, RNA2, and RNA3, i.e., B1( $-$ )58G, B2( $-$ )46G, and B3( $-$ )51G, respectively. The structure predictions were generated by the MFOLD program (10). (C) Initiation of genomic plus-strand RNAs from minus-strand endscripts. RdRp reaction products were separated by denaturing PAGE (12% polyacrylamide) and visualized by autoradiography. The amounts of RNA synthesized from various templates relative to B2( $-$ )46G (% Syn) are shown at the bottom of the autoradiogram. The results presented are an average from three independent trials. The sizes of the RNA products are indicated on the side of the autoradiogram. The symbol $phi$ represents the products of a control reaction with no added template. Endscripts that are initiation competent are indicated by +, while initiation-incompetent endscripts are indicated by $-$ . C2( $-$ )G and C3( $-$ )G are endscripts of CMV RNA2 and CMV RNA3, respectively. (D) Synthesis of a 200-nt genomic plus-strand RNA. The endscript with a guanylate replacing the +1 cytidylate is indicated by +1c/g. $-$ G denotes a 200-nt endscript without the designed nontemplated guanylate; +G denotes a 200-nt endscript with a guanylate at the 3' end of the RNA. RNA synthesis from B2( $-$ )200+G, B2( $-$ )200 $Delta$ -1, and B2( $-$ )200+1C/G was 100, 27, and 0% respectively. The results presented are an average from three independent trials. M denotes a reaction designed to produce a molecular mass marker of 203 nt.

Next, we wanted to determine whether it was possible to generate longer fragments of genomic plus-strand RNAs by using minus-strandendscripts. Two endscripts were made: B2( $-$ ), of 200 nt, lackinga designed 3'-terminal nontemplated guanylate, and B2( $-$ )200G,containing a $-$ 1 guanylate. B2( $-$ )200G was able to direct efficientsynthesis of a product of the expected length in comparison tothe molecular mass marker (Fig. 4D, lanes 1 and 5). In four independentexperiments, synthesis from B2( $-$ )200 was at 30% of that from B2( $-$ )200G(Fig. 4D) (24). The synthesis observed in the absence of a 3'nontemplated nucleotide might be due to addition of an extra nucleotide(s)by the T7 polymerase during transcription (6, 17). To confirmthat initiation of the 200-nt product took place from the penultimatecytidylate, the +1 cytidylate was mutated to a guanylate. Thismutant endscript was unable to direct plus-strand synthesis (Fig.4D, lane 3). In addition to the 200-nt product, a prominent 100-ntproduct was observed. The 100-nt RNA appears to be due to internalinitiation of synthesis, since mutation of the +1 cytidylate didnot affect its synthesis (Fig. 4D). Since shorter endscripts aremore conducive to analysis of template requirements, all experimentsdescribed below were performed with the B2( $-$ )46G as theprototype.

Effect of nucleotide changes near the initiation cytidylate. In addition to the $-$ 1 position, we wanted to determine the effect of changes at +1, +2, and +3 on RNA synthesis. Consistentwith previous observations, changing the +1 cytidylate to a guanylatewas detrimental and virtually abolished RNA synthesis (Fig. 5A,lane 3). Changing the +2 adenylate to a guanylate reduced synthesisto 8% of that of the wt (lane 4). These results are comparableto observations made with DNA templates containing identical changesat the +1 and +2 positions (Fig. 1C). However, changing the +3uridylate to an adenylate did not affect RNA synthesis from anRNA template, which is in contrast to what was observed when aDNA template with the identical nucleotide change was used asthe template (compare Fig. 1A, lane 12, and Fig. 5A, lanes 1 and5). The lack of a 2' OH and/or the presence of a 5'-methyl groupat specific positions may combine to alter the interaction betweenthe template and RdRp.

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FIG. 5. The effects of nucleotide changes near the initiation cytidylate on RNA synthesis. (A) Effect of nucleotide changes near the initiation cytidylate. Changes from B2( $-$ )46G (top sequence) are indicated in bold type. $-$ indicates the absence of the $-$ 1 nucleotide. (B) Effects of the identity of the 3' nontemplated nucleotide on genomic plus-strand initiation. The initiation cytidylate is indicated by an arrow. Substitutions of the 3' nontemplated nucleotide is indicated in bold type. The synthesis directed by the different endscripts is given as a percentage relative to B2( $-$ )46G. The results presented are from three independent trials.

Effect of the minus-strand 3' end on RNA synthesis. To further analyze the effect of the 3' nontemplated nucleotide on RNA synthesis, we generated endscripts containing different3' nucleotides. The absence of a nontemplated nucleotide at the3' end significantly reduced RNA synthesis (Fig. 5A, lane 2).The $-$ 1 guanylate could be replaced by a uridylate, adenylate,or cytidylate with only moderate reduction of the levels of plus-strandsynthesis (Fig. 5B, lanes 1 to 4). These results indicate thatwhile the 3' nontemplated nucleotide is necessary for efficientRNA synthesis, the identity of the nucleotide at this positionis not crucial. However, the addition of two nucleotides (3' AG)or three nucleotides (3' AAG) 3' of the initiating cytidylatereduced plus-strand RNA synthesis to less than 15% of wt (24),indicating that the BMV RdRp prefers the initiating cytidylateto be at the penultimate position in an RNAtemplate.

The nucleotide changes could affect either the stability of interaction with RdRp and/or the ability to direct synthesis byRdRp. To distinguish between these two possibilities, we carriedout competition assays with r( $-$ 20/15) as the reference template.As a nonspecific competitor, a 53-nt RNA unrelated to BMV (PCRII/53)was used. PCRII/53 caused a slight decrease in synthesis fromthe reference RNA r( $-$ 20/15), to 66%, when present at 250 nM, thehighest concentration tested, suggesting that there is limitednonspecific RdRp-RNA interaction (Table 1). The B2( $-$ )46G endscriptwas a more effective competitor, reducing synthesis from r( $-$ 20/15)with an IC₅₀ of 120 nM (Table 1). This concentration is similarto the 175 nM obtained with the DNA template, d( $-$ 1/13) (Fig. 3).Removal of the $-$ 1 nucleotide at the 3' end ( $Delta$ $-$ 1) or changing the+1 cytidylate to a guanylate (+1C/G) decreased the competitivenessof these RNAs (Table 1); they were unable to inhibit RNA synthesisfrom the reference template to less than 50%, even at the highestconcentration tested (24). Therefore, the IC₅₀s of these RNAsare listed as >250 nM. Changes at the +2 position (+2A/G) alsoresulted in a slight reduction in the ability of the templateto interact with the RdRp complex, but not to the degree observedfor changes at $-$ 1 or +1 positions (Table 1). Changes at the +3position (+3U/A) yielded an IC₅₀ similar to that of wt B2( $-$ )46G(Table 1). Competition assays using CMV2( $-$ )G and CMV3( $-$ )G endscriptsshowed that BMV RdRp does not bind to CMV minus strand templates(24). This is not surprising since the 3' sequence (3' GCA)in the CMV RNA was identical to the BMV 3' sequence (Fig. 4A).However, the inability of BMV RdRp to direct efficient RNA synthesisby using CMV templates suggests that in addition to the 3' nucleotides,upstream sequences are required for efficient RNA synthesis.

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TABLE 1. Mutations in endscripts can affect the ability to interact with RdRp

To examine the spatial relationship between the 3' initiation site and upstream sequences, endscripts containing one, two,or three initiation sites (C₊₁A₊₂U₊₃) were constructedand assayed (Fig. 6). Endscript containing two initiation sitesgenerated products of 46 and 49 nt, corresponding to initiationfrom the authentic and the second initiation sites, respectively.In terms of abundance relative to B2( $-$ )46G, the 49-nt RNA wasat 89% while the 46-mer was at 25% (Fig. 6). When three initiationsites were present, products of 52, 49, and 46 nt correspondingto initiation from all three potential sites were observed at69, 43, and 19%, respectively. Since the 3'-terminal initiationsite always yields the largest amount of product, this resultconfirms our previous observation that RdRp has a preference forthe penultimate cytidylate (Fig. 6). However, it is also interestingthat in the presence of additional initiation sites, the authenticinitiation site is still used. This observation suggests thatan appropriate spacing between the 3' initiation site and sequencesor structure requiring the sequence 5' of the initiation sitemay influence the efficiency of plus-strand RNA synthesis.

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FIG. 6. Effect of multiple initiation sites on RNA synthesis. The authentic initiation site is indicated by an arrow in the first construct marked 1. Additional initiation sites added to the 3' end of B2( $-$ )46G are indicated by arrows 2 and 3. The three initiation sites should generate products of 46, 49, and 52 nt. RNA synthesis directed by the different initiation sites from their respective templates are presented relative to initiation from cytidylate 1 in B2( $-$ )46G. Products initiated from the three potential initiation sites are indicated on the right as 1, 2, and 3 respectively.

5' requirements to initiate plus-strand RNA synthesis. The B2( $-$ )46G endscript is predicted to fold into a stable stem-loop structure whose subdomains we named L1, L2, A1, and A2(Fig. 7A). To determine whether RNA structures or sequences 5'of the initiation site were important for directing plus-strandsynthesis, a set of deletions were constructed and tested. Deletionof nucleotides originally in positions 3 to 11, expected to perturbthe A2 stem, reproducibly increased synthesis to 200% of thatfor wt B2( $-$ )46G (compare Fig. 7B lanes 1 and 2 with lanes 5 and6). Deletion of nucleotides originally in positions 17 to 26,expected to disrupt the L1 loop, resulted in an RNA that directed70% of wt RNA synthesis (lanes 9 and 10). In both cases, initiationtook place from the authentic +1 cytidylate, since a change toa guanylate resulted in RNAs that failed to direct synthesis (lanes7 and 8 and lanes 11 and 12). The large amount of RNA synthesisfrom templates with the L1 deletion was probably due to replacementof the L1 loop region with 5' sequence, as we demonstrate below.

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FIG. 7. Requirements for plus-strand RNA synthesis. (A) The predicted secondary structure of B2( $-$ )46G with the stems (A1 and A2) and loops (L1 and L2) indicated by brackets. The initiation cytidylate is denoted by an arrow. (B) Analysis of the sequence in the predicted stem-loop region. The templates used in the specified reactions are indicated at the top of the autoradiogram. Endscripts that have a +1 are indicated by +, while endscripts with changes of the initiation cytidylate to a guanylate are indicated by $-$ . The sizes of the RdRp products are denoted on the right. The amounts of plus-strand synthesis directed by B2( $-$ ) $Delta$ 3-11 and B2( $-$ ) $Delta$ 17-26 were 200 and 70%, respectively, compared to synthesis directed by B2( $-$ )46G after correcting for the number of CMP units incorporated. The results presented are an average from three independent trials. (C) Additional analysis of sequences required for efficient RNA synthesis. The templates used and whether they can direct the initiation of RNA synthesis (+ or $-$ ) are indicated at the top of the autoradiogram. The sizes of the RNA products are denoted on the right of the autoradiogram. The amounts of synthesis, after adjusting to the number of radiolabelled CMP units incorporated, from B2( $-$ )26G, B2( $-$ )26TV, B2( $-$ )22G, and B2( $-$ )16G were 100, 17, 22, and 5% respectively. (D) Alignment of the sequences in B2( $-$ )26G, B2( $-$ ) $Delta$ 3-11 (deletion of A2 stem region), B2( $-$ ) $Delta$ 17-26 (deletion of L1 loop region), and B2( $-$ )26TV (transversion of nt 17 to 24). The two guanylates as well as the two adenylates putatively required for efficient synthesis are shown in bold type.

To determine further the effect of 5' sequences, endscripts with 5' truncations were made and tested. When the template sequencewas reduced to 26 nt in B2( $-$ )26G, molar amounts of plus-strandRNA synthesis remained comparable to those from B2( $-$ )46G (Fig.7C, lanes 4 and 5). However, a further deletion of 4 and 10 ntin endscripts B2( $-$ )22G and B2( $-$ )16G, respectively, reduced RNAsynthesis to 22 and 5%, respectively (lanes 10 and 11 and lanes13 and 14). These results suggest that nt 17 to 26 may be requiredfor efficient synthesis. To confirm this without changing thelength of the RNAs, transversion of nt 17 to 24 in the contextof the 26-mer, B2( $-$ )26TV, was tested and found to result in only17% synthesis in comparison to B2( $-$ )26G (lanes 7 and 8). In allcases, initiation took place from the authentic +1 cytidylate,since a mutation at the initiation cytidylate failed to directRNA synthesis (lanes 3, 6, 9, 12, and 15). The results indicatethat positions 17 to 26 contain an element(s) important for RNAsynthesis.

The deletion of nt 17 to 26 in the context of B2( $-$ )46G reduced synthesis to 70% of wt. This is unexpected because transversionof the same sequence in the context of B2( $-$ )26G reduced synthesisto 17% of wt. The incongruity of these results prompted us toexamine more closely the sequence in the 5' portion of B2( $-$ ) $Delta$ 3-11and B2( $-$ ) $Delta$ 17-26. Despite our changes, both endscripts containsequences that are similar between nt 17 to 26. For example, bothB2( $-$ ) $Delta$ 3-11 and B2( $-$ ) $Delta$ 17-26 contain the two guanylates that arenaturally present in B2( $-$ )46 and both contain two adenylates 4or 5 nt 3' of the guanylates (Fig. 7D). Furthermore, these twoadenylates are absent in the nonfunctional template B2( $-$ )26TV.Stawicki and Kao (25) have demonstrated that RdRp can have acertain amount of flexibility in adjusting to minor spatial perturbationsthat may allow the recognition of the two adenylates in B2( $-$ ) $Delta$ 17-26despite the 1-nt difference in their spacing. Presently we donot have any experimental evidence to show that the two adenylatesor the 5' guanylates are directly interacting with RdRp. However,the similarity in the 5' sequences in B2( $-$ ) $Delta$ 3-11 and B2( $-$ ) $Delta$ 17-26may explain the observations that both efficiently directed RNAsynthesis.

Since the 5' end affects initiation of RNA synthesis, we asked whether sequence from positions 17 to 26 is sufficient forinteraction with RdRp. To address this question, an RNA containingB2( $-$ ) nucleotides 11 to 26 and an RNA of the same length withthe transversions at positions 17 to 26 were chemically synthesizedfor use in template competition assays. Addition of either oligonucleotideto 10-fold molar excess with respect to the reference RNA r( $-$ 20/15)failed to reduce RNA synthesis. As controls, assays carried outin parallel with competitor B2( $-$ )26G or B2( $-$ )26TV were able tocompete efficiently (24). These results indicate that nucleotidesin the region from positions 11 to 26 in the absence of the 3'sequence are not sufficient for stable interaction withRdRp.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

We have demonstrated for the first time accurate in vitro initiation of genomic plus-strand RNA synthesis by BMV RdRp. Theuse of DNA templates that mimicked the 3' end of the BMV RNA minusstrand allowed us to determine that the recognition of minus-strandtemplates by RdRp in vitro required a nontemplated nucleotide.Addition of this nontemplated nucleotide to the 3' ends of theminus strands of all three BMV RNAs allowed accurate initiationof genomic plus-strand RNAs in a species-specific manner. Finally,efficient RNA synthesis is affected by the sequence 5' of theinitiationsite.

Comparison of synthesis from RNA and DNA templates. RNA synthesis directed by DNA templates is about 8% as efficient as RNA synthesis with RNA templates (23). However, therequirements for template recognition by RdRp were similar forboth DNA and RNA templates. We found that the +1 initiation cytidylate,the +2 adenylate, and the nontemplated $-$ 1 nucleotide were importantfor RNA synthesis and recognition of the RNA by RdRp. However,at the +3 position, a U-to-A change is tolerated in an RNA templatebut not in a DNA template. This result may indicate that the 2'hydroxyls in the initiation site contribute to stable RdRp-templateinteraction and that its absence in DNA templates forces RdRpto require additional upstream contactsites.

Despite slight differences in the use of DNA and RNA templates by BMV RdRp, DNA templates can be useful in establishing conditionsfor studies of RdRp-RNA interaction. Working with DNA has manytechnical advantages. For example, DNAs longer than 100 nt canbe chemically synthesized with precise ends whereas chemical synthesisof RNA is presently inefficient for stretches longer than 40 nt.Furthermore, RNA templates generated by T7 RNA polymerase oftencontain additional nucleotides at the 3' termini due to the propensityof T7 RNA polymerase to add nontemplated nucleotides (6). Lastly,a wider range of modified nucleotides is available as deoxynucleotides,allowing a more in-depth probing of the nucleotide moieties requiredfor the RdRp-RNAinteraction.

RdRp-template interaction. RNA synthesis from the end of a template requires 1 nt 3' of the initiation nucleotide. We observed this requirement for theinitiation of plus-strand RNA synthesis from both DNA and RNAtemplates (Fig. 1 and 5A). There is precedence that a nontemplatednucleotide may be a general requirement for RNA synthesis. Thisrequirement was observed with BMV minus-strand RNA synthesis fromthe tRNA-like promoter (26). A nontemplated nucleotide at the3' end of the minus strand has been found in CMV and Semliki Forestvirus (7, 29). A nontemplated guanylate is required for theproduction of CMV-associated satellite RNA (CARNA5) (30). InCMV, Semliki Forest virus, and CARNA5, the extra nucleotide atthe 3' end was a guanylate, and the results of the in vitro experimentswith BMV endscripts suggest that there is a preference for a guanylatefor initiation of plus-strand RNAsynthesis.

The nontemplated nucleotide may be added by the terminal transferase activity in the RdRp complex. Such an activity appearsto be present in many polymerases, including those from BMV (21),poliovirus (16), vaccinia virus (3), and bovine viral diarrheavirus NS5B (31). The hepatitis C virus NS5B may be an exceptionin that the terminal nucleotide transferase activity observedin some preparations of the hepatitis C virus RdRp may be dueto a cellular protein (13).

The extranucleotide 3' of the initiating cytidylate provides stability in the RdRp-RNA interaction. Templates lacking thenontemplate nucleotide were reduced in both RNA synthesis andthe ability to compete for interaction with RdRp (Fig. 2 and Table1). While the nontemplated nucleotide may bond with RdRp, thebonds are not base specific, since nucleotides other than guanylateswere capable of directing efficient RNA initiation. However, theredo appear to be constraints in the number of residues 3' of theinitiation cytidylate, since more than one nontemplated nucleotidereduced RNA synthesis and interaction with RdRp. We note thatthe recombinant RdRp of bovine viral diarrhea virus does not appearto require any nucleotide 3' of the initiation nucleotide forefficient RNA synthesis (11), suggesting that the steric constraintsof catalytic pockets of different RdRps mayvary.

Role of 5' sequences. The 3' ends of BMV and CMV RNAs have identical sequences (Fig. 4A). However, the CMV RNAs are poor templates for RNA synthesis,indicating that additional sequence 5' of the initiation siteare important for efficient synthesis, and may confer specificityin viral RNA synthesis. The 5' sequences may affect synthesisby three possible mechanisms: (i) modulation of abortive synthesis,(ii) antitermination of RNA synthesis (5, 19), or (iii) directinitiation at the 3' end (but not RdRp binding). It is possiblethat BMV RdRp will abort synthesis when using non-BMV templates.However, since abortive synthesis usually terminates before thefirst 10 phosphodiester bonds are formed (27, 28), we speculatethat the BMV sequence between nt 17 and 26 may not be directlyinvolved in abortive synthesis but could be inducing elongationor affectinginitiation.

Pogue and Hall (18), have suggested that the putative plus-strand stem-loop structure and the ICR2-like sequences presentwithin the loop region are important for genomic plus-strand synthesis.When a putative plus-strand stem-loop structure was disrupted,RNA replication was greatly reduced (18), whereas disruptionof the putative minus-strand stem-loop structure was not correlatedwith effects on viral replication (18). These results led Pogueand Hall to propose that the plus-strand RNA is involved in additionalrounds of plus-strand RNA synthesis. We have demonstrated thataccurate initiation of plus-strand RNA synthesis could take placefrom minus-strand templates in the absence of plus-strand RNAs(and the ICR-like sequences). In addition, disrupting the predictedA2 stem structure does not affect the ability of the templateto direct RNA synthesis. While our results do not rule out possiblecontributions of the plus-strand RNA in vivo, they raise the possibilitythat the results of Pogue and Hall (18) reflect some requirementsother than those required for initiation of genomic plus-strandRNA synthesis. Our data further suggests that the sequence complementaryto ICR2, nt 17 to 24, is involved in RNA synthesis. Transversionof the sequence complementary to ICR2, in the context of a 26-ntminus-strand RNA, or the deletion of this sequence greatly reducedthe ability of the template to direct synthesis (Fig. 7C). Takentogether, these observations suggest that the minimal promotersequence required for directing plus-strand initiation shouldbe present within the first 26 nt of the minus-strandRNA.

The initiation of genomic plus-strand RNA in vitro completes the last class of RNA promoters used by the BMV RdRp. Synthesisof genomic plus-strand RNA from endscripts was about one-thirdas productive as synthesis directed by a subgenomic plus-strandpromoter. We would rank the amount of RNA synthesized from thethree BMV promoters from most to least efficient as follows: subgenomicRNA > genomic plus-strand RNA > minus-strand RNA. This relativeabundance suggests that different viral RNA promoters have inherentlydifferent abilities to interact with RdRp and/or direct nucleotidepolymerization. More work is needed to understand the mechanismof asymmetric RNA synthesis in a viralinfection.

	ACKNOWLEDGMENTS

We thank members of the IU Cereal Killer group for helpful discussions during the course of thiswork.

Funding was provided by NSF grantMCB9507344.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Biology, Indiana University, Jordan Hall 138, Bloomington, IN 47405.Phone: (812) 855-7959. Fax: (812) 855-6705. E-mail: ckao{at}bio.indiana.edu.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Adkins, S., R. W. Siegel, J. H. Sun, and C. C. Kao. 1997. Minimal templates directing accurate initiation of subgenomic RNA synthesis in vitro by the brome mosaic virus RNA-dependent RNA polymerase. RNA 3:634-647[Abstract].

2. Ahlquist, P. 1992. Bromovirus RNA replication and transcription. Curr. Opin. Genet. Dev. 2:71-76[Medline].

3. Brown, M., J. W. Dorson, and F. J. Bollum. 1973. Terminal riboadenylate transferase: a poly(A) polymerase in purified vaccinia virus. J. Virol. 12:203-208[Abstract/Free Full Text].

4. Buck, K. W. 1996. Comparison of the replication of positive-strand RNA viruses of plants and animals. Adv. Virus Res. 47:159-251[Medline].

5. Burns, C. M., L. V. Richardson, and J. P. Richardson. 1998. Combinatorial effects of NusA on transcription elongation and Rho-dependent termination in Escherichia coli. J. Mol. Biol. 278:307-316[Medline].

6. Cazenave, C., and O. C. Uhlenbeck. 1994. RNA template-directed RNA synthesis by T7 RNA polymerase. Proc. Natl. Acad. Sci. USA 91:6972-6976[Abstract/Free Full Text].

7. Collmer, C. W., and J. M. Kaper. 1985. Double-stranded RNAs of cucumber mosaic virus and its satellite contain an unpaired terminal guanosine: implications for replication. Virology 145:249-259.

8. Goldbach, R., O. LeGall, and J. Wellink. 1991. Alpha-like viruses in plants. Semin. Virol. 2:19-25.

9. Hardy, S. F., T. L. German, L. S. Loesch-Fries, and T. C. Hall. 1979. Highly active template-specific RNA-dependent RNA polymerase from barley leaves infected with brome mosaic virus. Proc. Natl. Acad. Sci. USA 76:4956-4960[Abstract/Free Full Text].

10. Jaeger, J. A., D. H. Turner, and M. Zuker. 1989. Improved predictions of secondary structures for RNA. Proc. Natl. Acad. Sci. USA 86:7706-7710[Abstract/Free Full Text].

11. Kao, C. C., F. Del Vecchio, and W. Zhong. 1999. De novo initiation of RNA synthesis by a recombinant Flaviridae RNA-dependent RNA polymerase. Virology 253:1-7[Medline].

12. Kao, C. C., and J.-H. Sun. 1996. Initiation of minus-strand RNA synthesis by the brome mosaic virus RNA-dependent RNA polymerase: use of oligoribonucleotide primers. J. Virol. 70:6826-6830[Abstract/Free Full Text].

13. Lohmann, V., F. Korne, U. Herian, and U. Bartenschlager. 1997. Biochemical properties of hepatitis C virus NS5B RNA-dependent RNA polymerase and identification of amino acid sequence motifs essential for enzymatic activity. J. Virol. 71:8416-8428[Abstract].

14. Marsh, L. E., T. W. Dreher, and T. C. Hall. 1988. Mutational analysis of the core and modulator sequences of the BMV RNA3 subgenomic promoter. Nucleic Acids Res. 16:981-995[Abstract/Free Full Text].

15. Miller, W. A., T. W. Dreher, and T. C. Hall. 1985. Synthesis of brome mosaic virus subgenomic RNA in vitro by internal initiation on ( $-$ )-sense genomic RNA. Nature 313:68-70[Medline].

16. Neufeld, K. L., J. M. Galarza, O. C. Richards, D. F. Summers, and E. Ehrenfeld. 1994. Identification of terminal adenylyl transferase activity of the polyovirus polymerase 3D^pol. J. Virol. 68:5811-5818[Abstract/Free Full Text].

17. Pleiss, J. P., M. L. Derrick, and O. C. Uhlenbeck. 1998. T7 RNA polymerase produces 5' end heterogeneity during in vitro transcription from certain templates. RNA 4:1313-1317[Abstract].

18. Pogue, G. P., and T. C. Hall. 1992. The requirement for a 5' stem-loop structure in brome mosaic virus replication supports a new model for viral positive-strand RNA initiation. J. Virol. 66:674-684[Abstract/Free Full Text].

19. Richardson, J. P. 1996. Structural organization of transcription termination factor Rho. J. Biol. Chem. 271:1251-1254[Free Full Text].

20. Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. Molecular cloning: a laboratory manual. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.

21. Siegel, R. W., S. Adkins, and C. C. Kao. 1997. Sequence-specific recognition of a subgenomic promoter by a viral RNA polymerase. Proc. Natl. Acad. Sci. USA 94:11238-11243[Abstract/Free Full Text].

22. Siegel, R. W., L. Bellon, L. Beigelman, and C. C. Kao. 1998. Moieties in an RNA promoter specifically recognized by a viral RNA-dependent RNA polymerase. Proc. Natl. Acad. Sci. USA 95:11613-11618[Abstract/Free Full Text].

23. Siegel, R. W., L. Bellon, L. Beigelman, and C. C. Kao. 1999. Use of DNA, RNA, and chimeric templates by a viral RNA-dependent RNA polymerase: evolutionary implications for the transition from the RNA to the DNA world. J. Virol. 73:6424-6429[Abstract/Free Full Text].

24. Sivakumaran, K., and C. C. Kao. Unpublished data.

25. Stawicki, S. S., and C. C. Kao. 1999. Spatial perturbations within an RNA promoter specifically recognized by a viral RNA-dependent RNA polymerase (RdRp) reveal that RdRp can adjust its promoter binding sites. J. Virol. 73:198-204[Abstract/Free Full Text].

26. Sun, J.-H., S. Adkins, G. Faurote, and C. C. Kao. 1996. Initiation of ( $-$ )-strand RNA synthesis catalyzed by the BMV RNA-dependent RNA polymerase: synthesis of oligonucleotides. Virology 226:1-12[Medline].

27. Sun, J. H., and C. C. Kao. 1997. RNA synthesis by the brome mosaic virus RNA-dependent RNA polymerase: transition from initiation to elongation. Virology 233:63-73[Medline].

28. Sun, J. H., and C. C. Kao. 1997. Characterization of RNA products associated with or aborted by a viral RNA-dependent RNA polymerase. Virology 236:348-353[Medline].

29. Wengler, G., G. Wengler, and H. J. Gross. 1979. Replicative form of Semliki Forest virus RNA contains an unpaired guanosine. Nature (London) 282:754-756[Medline].

30. Wu, G., and J. M. Kaper. 1994. Requirement of 3'-terminal guanosine in ( $-$ )-stranded RNA for in vitro replication of cucumber mosaic virus satellite RNA by viral RNA-dependent RNA polymerase. J. Mol. Biol. 238:655-657[Medline].

31. Zhong, W., L. L. Gutshall, and A. M. Del Vecchio. 1998. Identification and characterization of an RNA-dependent RNA polymerase activity within the nonstructural protein 5B region of bovine viral diarrhea virus. J. Virol. 72:9365-9369[Abstract/Free Full Text].

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1.	Adkins, S., R. W. Siegel, J. H. Sun, and C. C. Kao. 1997. Minimal templates directing accurate initiation of subgenomic RNA synthesis in vitro by the brome mosaic virus RNA-dependent RNA polymerase. RNA 3:634-647[Abstract].
2.	Ahlquist, P. 1992. Bromovirus RNA replication and transcription. Curr. Opin. Genet. Dev. 2:71-76[Medline].
3.	Brown, M., J. W. Dorson, and F. J. Bollum. 1973. Terminal riboadenylate transferase: a poly(A) polymerase in purified vaccinia virus. J. Virol. 12:203-208[Abstract/Free Full Text].
4.	Buck, K. W. 1996. Comparison of the replication of positive-strand RNA viruses of plants and animals. Adv. Virus Res. 47:159-251[Medline].
5.	Burns, C. M., L. V. Richardson, and J. P. Richardson. 1998. Combinatorial effects of NusA on transcription elongation and Rho-dependent termination in Escherichia coli. J. Mol. Biol. 278:307-316[Medline].
6.	Cazenave, C., and O. C. Uhlenbeck. 1994. RNA template-directed RNA synthesis by T7 RNA polymerase. Proc. Natl. Acad. Sci. USA 91:6972-6976[Abstract/Free Full Text].
7.	Collmer, C. W., and J. M. Kaper. 1985. Double-stranded RNAs of cucumber mosaic virus and its satellite contain an unpaired terminal guanosine: implications for replication. Virology 145:249-259.
8.	Goldbach, R., O. LeGall, and J. Wellink. 1991. Alpha-like viruses in plants. Semin. Virol. 2:19-25.
9.	Hardy, S. F., T. L. German, L. S. Loesch-Fries, and T. C. Hall. 1979. Highly active template-specific RNA-dependent RNA polymerase from barley leaves infected with brome mosaic virus. Proc. Natl. Acad. Sci. USA 76:4956-4960[Abstract/Free Full Text].
10.	Jaeger, J. A., D. H. Turner, and M. Zuker. 1989. Improved predictions of secondary structures for RNA. Proc. Natl. Acad. Sci. USA 86:7706-7710[Abstract/Free Full Text].
11.	Kao, C. C., F. Del Vecchio, and W. Zhong. 1999. De novo initiation of RNA synthesis by a recombinant Flaviridae RNA-dependent RNA polymerase. Virology 253:1-7[Medline].
12.	Kao, C. C., and J.-H. Sun. 1996. Initiation of minus-strand RNA synthesis by the brome mosaic virus RNA-dependent RNA polymerase: use of oligoribonucleotide primers. J. Virol. 70:6826-6830[Abstract/Free Full Text].
13.	Lohmann, V., F. Korne, U. Herian, and U. Bartenschlager. 1997. Biochemical properties of hepatitis C virus NS5B RNA-dependent RNA polymerase and identification of amino acid sequence motifs essential for enzymatic activity. J. Virol. 71:8416-8428[Abstract].
14.	Marsh, L. E., T. W. Dreher, and T. C. Hall. 1988. Mutational analysis of the core and modulator sequences of the BMV RNA3 subgenomic promoter. Nucleic Acids Res. 16:981-995[Abstract/Free Full Text].
15.	Miller, W. A., T. W. Dreher, and T. C. Hall. 1985. Synthesis of brome mosaic virus subgenomic RNA in vitro by internal initiation on ( $-$ )-sense genomic RNA. Nature 313:68-70[Medline].
16.	Neufeld, K. L., J. M. Galarza, O. C. Richards, D. F. Summers, and E. Ehrenfeld. 1994. Identification of terminal adenylyl transferase activity of the polyovirus polymerase 3D^pol. J. Virol. 68:5811-5818[Abstract/Free Full Text].
17.	Pleiss, J. P., M. L. Derrick, and O. C. Uhlenbeck. 1998. T7 RNA polymerase produces 5' end heterogeneity during in vitro transcription from certain templates. RNA 4:1313-1317[Abstract].
18.	Pogue, G. P., and T. C. Hall. 1992. The requirement for a 5' stem-loop structure in brome mosaic virus replication supports a new model for viral positive-strand RNA initiation. J. Virol. 66:674-684[Abstract/Free Full Text].
19.	Richardson, J. P. 1996. Structural organization of transcription termination factor Rho. J. Biol. Chem. 271:1251-1254[Free Full Text].
20.	Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. Molecular cloning: a laboratory manual. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
21.	Siegel, R. W., S. Adkins, and C. C. Kao. 1997. Sequence-specific recognition of a subgenomic promoter by a viral RNA polymerase. Proc. Natl. Acad. Sci. USA 94:11238-11243[Abstract/Free Full Text].
22.	Siegel, R. W., L. Bellon, L. Beigelman, and C. C. Kao. 1998. Moieties in an RNA promoter specifically recognized by a viral RNA-dependent RNA polymerase. Proc. Natl. Acad. Sci. USA 95:11613-11618[Abstract/Free Full Text].
23.	Siegel, R. W., L. Bellon, L. Beigelman, and C. C. Kao. 1999. Use of DNA, RNA, and chimeric templates by a viral RNA-dependent RNA polymerase: evolutionary implications for the transition from the RNA to the DNA world. J. Virol. 73:6424-6429[Abstract/Free Full Text].
24.	Sivakumaran, K., and C. C. Kao. Unpublished data.
25.	Stawicki, S. S., and C. C. Kao. 1999. Spatial perturbations within an RNA promoter specifically recognized by a viral RNA-dependent RNA polymerase (RdRp) reveal that RdRp can adjust its promoter binding sites. J. Virol. 73:198-204[Abstract/Free Full Text].
26.	Sun, J.-H., S. Adkins, G. Faurote, and C. C. Kao. 1996. Initiation of ( $-$ )-strand RNA synthesis catalyzed by the BMV RNA-dependent RNA polymerase: synthesis of oligonucleotides. Virology 226:1-12[Medline].
27.	Sun, J. H., and C. C. Kao. 1997. RNA synthesis by the brome mosaic virus RNA-dependent RNA polymerase: transition from initiation to elongation. Virology 233:63-73[Medline].
28.	Sun, J. H., and C. C. Kao. 1997. Characterization of RNA products associated with or aborted by a viral RNA-dependent RNA polymerase. Virology 236:348-353[Medline].
29.	Wengler, G., G. Wengler, and H. J. Gross. 1979. Replicative form of Semliki Forest virus RNA contains an unpaired guanosine. Nature (London) 282:754-756[Medline].
30.	Wu, G., and J. M. Kaper. 1994. Requirement of 3'-terminal guanosine in ( $-$ )-stranded RNA for in vitro replication of cucumber mosaic virus satellite RNA by viral RNA-dependent RNA polymerase. J. Mol. Biol. 238:655-657[Medline].
31.	Zhong, W., L. L. Gutshall, and A. M. Del Vecchio. 1998. Identification and characterization of an RNA-dependent RNA polymerase activity within the nonstructural protein 5B region of bovine viral diarrhea virus. J. Virol. 72:9365-9369[Abstract/Free Full Text].