Leader Proteinase of the Beet Yellows Closterovirus: Mutation Analysis of the Function in Genome Amplification

doi:10.1128/JVI.74.20.9766-9770.2000

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Journal of Virology, October 2000, p. 9766-9770, Vol. 74, No. 20
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Leader Proteinase of the Beet Yellows Closterovirus: Mutation Analysis of the Function in Genome Amplification

Chih-Wen Peng¹ and Valerian V. Dolja¹^,²^,^*

Department of Botany and Plant Pathology¹ and Center for Gene Research and Biotechnology,² Oregon State University, Corvallis, Oregon 97331

Received 9 March 2000/Accepted 19 July 2000

	ABSTRACT

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The beet yellows closterovirus leader proteinase (L-Pro) possesses a C-terminal proteinase domain and a nonproteolytic N-terminaldomain. It was found that although L-Pro is not essential forbasal-level replication, deletion of its N-terminal domain resultedin a 1,000-fold reduction in RNA accumulation. Mutagenic analysisof the N-terminal domain revealed its structural flexibility exceptfor the 54-codon-long, 5'-terminal element in the correspondingopen reading frame that is critical for efficient RNA amplificationat both RNA and proteinlevels.

	TEXT

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Viral proteases belong to several structural prototypes; some are unique, whereas others share structural motifs with cellularenzymes (4). In particular, papain-like cysteine proteinasesare found in diverse families of positive-strand RNA viruses infectingplants, fungi, and animals (9, 13-15, 23, 25, 30). Oneclass of these proteinases, exemplified by nsP2 of animal alphaviruses,is responsible for processing the nonstructural polyprotein andis intimately involved in RNA replication (31). Similarly, papain-likeproteinases encoded by plant tymoviruses and related viruses areinvolved in the processing of replication-associated polyproteins(6, 17). Proteinases of another class that typically cleaveonly in cis at their C termini are called leader proteinases (L-proteinases).Examples of these are found in animal arteriviruses (30) andaphthoviruses (15, 28), as well as in plant potyviruses (7)and fungal hypoviruses (25). In addition to autocatalytic processing,several L-proteinases were reported to function in various processesof virus-host interaction (8, 15, 20, 21, 28, 32).

Members of the Closteroviridae family of positive-strand RNA viruses possess 15- to 20-kb genomes encapsidated into filamentousvirions (5). Computer-assisted analysis revealed that closterovirusesbelong to a Sindbis virus-like superfamily (23). Although thegene content varies among closteroviruses, two genome blocks areconserved among all members (11, 33). The first, 5'-terminalblock is represented by open reading frames (ORFs) 1a and 1b,the latter of which encodes RNA polymerase (1, 18, 22).In beet yellows virus (BYV), a prototype closterovirus, ORF 1acodes for a polyprotein that possesses a papain-like L-proteinase(L-Pro), a putative methyltransferase domain, an RNA helicasedomain, and a large interdomain region which is unique to closteroviruses(Fig. 1). The second, quintuple, gene block encompasses ORFs encodingproteins responsible for virus assembly (2) and cell-to-cellmovement (3, 27).

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FIG. 1. Genomic map of BYV (top) and diagram of the cDNA clone of the mini-BYV genome, pBYV-GUS-p21, tagged by insertion of the GUS gene (bottom). Boxes represent BYV ORFs 1a to 8 encoding L-Pro, replication-associated proteins possessing putative methyltransferase (MET), RNA helicase (HEL), and RNA polymerase (POL) domains, 6-kDa protein (p6), HSP70 homolog (HSP70h), 64-kDa protein (p64), minor capsid protein (CPm), major capsid protein (CP), 20-kDa protein (p20), and 21-kDa protein (p21). Each curved arrow designates the self-processing site for the BYV L-Pro. Arrows marked CP and p21 on the pBYV-GUS-p21 map show approximate positions of the 5' termini of the subgenomic RNAs expressing GUS and p21 and driven by the CP and p21 promoters, respectively. fs, the frameshift mutation inactivating BYV replicase (26). Selected restriction endonuclease sites are shown below the pBYV-GUS-p21 diagram. Arrows marked SP6 and T7 show positions and orientations of the corresponding RNA polymerase promoters.

The BYV L-Pro provides a dual function in viral genome amplification. Autocatalytic cleavage at the C terminus of L-Pro isessential for virus viability, whereas the nonproteolytic, N-terminaldomain is required for efficient RNA accumulation (26). Thisfunctional profile is reminiscent of that described for the potyvirusleader proteinase HC-Pro (12, 20).

In this study, we expand the functional analysis of L-Pro by using a mini-BYV genome that lacks six virus genes which aresuperfluous for genome amplification (16, 26). This BYV variantretains ORFs 1a and 1b and a 3'-terminal ORF encoding a 21-kDaprotein (p21), which functions as an activator of genome amplification(Fig. 1 and reference 26). To provide a sensitive marker forgenome replication and expression, a reporter gene encoding bacterial $beta$ -glucuronidase (GUS) was engineered into this BYV variant, creatingBYV-GUS-p21 (16).

To further explore structure-function relationships in the L-Pro molecule, we generated 17 mutants (Fig. 2). Analysis of themutant phenotypes revealed high tolerance to structural changesin most of the N-terminal domain. In contrast, a 54-codon-long,5'-terminal region of ORF 1a was found to be critical for virusviability. In addition, we demonstrated that although L-Pro isnot essential for basal-level genome amplification, its activityincreases this level 1,000-fold.

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FIG. 2. Mutagenic analysis of the function of the N-terminal and proteinase domains of L-Pro in BYV genome amplification. The 5'-terminal part of the BYV genome including the noncoding leader region (L), L-Pro coding region (box), and part of the methyltransferase domain (Met) is shown in the middle. Asterisks, translation start codons; G-G, scissile glycine-glycine bond cleaved by L-Pro. Vertical lines mark sites of the alanine-scanning mutations A1 to A12. N-ATG, mutant in which the original start codon was replaced with ACA and an artificial start codon was introduced at the indicated position; S-1 and DELL, mutants in which in-frame deletions were introduced in the L-Pro coding region; N-ATG- $Delta$ N and N-ATG- $Delta$ ALL, mutants in which deletions were introduced into the L-Pro coding region possessing an artificial start codon.

Generation of BYV mutants. All mutations in the L-Pro coding region were generated using plasmid p5'BYV and site-directed mutagenesis as described elsewhere(24, 26). Each mutation was verified by nucleotide sequencing;the full-length clones of the mutant BYV genomes were engineeredby cloning the NheI-EagI fragments of the modified p5'BYV variantsinto appropriately digested pBYV-GUS-p21 (Fig. 1). The latterplasmid represented the mini-BYV genome in which six viral geneswere replaced by a reporter GUS gene (16).

In the DELL (deletion of leader) mutant, the entire region coding for L-Pro was deleted in frame except for the start codonof ORF 1a. This codon was fused with the first glycine codon ofthe BYV replicase (Fig. 2), resulting in the formation of a replicasethat differed from the proteolytically processed, wild-type replicaseonly by the presence of an N-terminal methionine. The S-1 mutationresulted in the in-frame deletion of ORF 1a codons 2 through 54(Fig. 2). Mutant N-ATG (new ATG codon) was generated by changingthe ORF 1a start codon to ACA (using the mutagenic oligonucleotide5'-GCTATCGACACACCATTCTTGAACG; changed nucleotides are inboldface), by replacing the G residue downstream from the startcodon with C (to disrupt its favorable context), and by engineeringa new ORF 1a start codon in place of codon 57 (using the oligonucleotide5'-CTTCTCTGTCCCGGACATGGTCTTTTTGAACGCG; threenucleotides surrounding ATG were changed to ensure the optimalcontext for translation). The N-ATG- $Delta$ N mutant was derived fromthe N-ATG variant via deletion of codons 58 through 442 (originalnumbering); mutant ORF 1a encoded only the C-terminal, proteinasedomain of L-Pro (Fig. 2). In another derivative of the N-ATG mutant,N-ATG- $Delta$ ALL, the entire region coding for L-Pro was deleted. Inthis mutant, the modified ORF 1a produced an unchanged BYV replicasewhich would be translated from the artificial ATG (Fig. 2). Twelvealanine-scanning mutations (A1 to A12) were introduced throughoutthe N-terminal domain of L-Pro (Fig. 2). In each of these mutants,three consecutive charged or polar amino acid residues were replacedwith three alanine residues (Table 1). The nucleotide sequencesof the corresponding mutagenic oligonucleotides are availableupon request. The replication-deficient fs variant, harboringa frameshift mutation upstream of the RNA helicase domain, wasdescribed previously (26). The corresponding mutant region offs was cloned into pBYV-GUS-p21 by using unique restriction endonucleasesites XbaI and SnaBI (Fig. 1).

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TABLE 1. GUS activity in BYV variants with alanine-scanning mutations in L-Pro at 4 days after transfection of protoplasts

Protoplast transfection and analysis of mutant phenotypes. The mutant BYV-GUS-p21 variants were characterized using transfection of the protoplasts as described previously (12). Eachtransfection sample contained ~4 × 10⁶ cells. The capped RNA transcripts were derived using SP6 RNApolymerase (Epicentre) and SmaI-linearized plasmid DNA (Fig. 1).Protoplasts were propagated for 86 h; GUS activity was assayedas described elsewhere (10) and expressed as a percentage ofthat of the BYV-GUS-p21 variant (positive control). The mock-transfectedprotoplasts were used as a negative control. Each variant wascharacterized using at least four independent transfections; meansand standard deviations were used to compare GUS activity. TheRNA samples were isolated using TRIZOL (Gibco-BRL); Northern hybridizationanalysis was conducted as described elsewhere (26). The ³²P-labeled, single-stranded, negative-polarity RNA probe was generatedusing T7 RNA polymerase and NsiI-linearized plasmid p3'BYV (Fig.1 and reference 26). This probe was complementary to the ~4003'-terminal nucleotides of the BYV RNA. The radiolabeled hybridizationproducts were detected and quantified using a PhosphorImager (MolecularDynamics); the means and standard deviations from four independentexperiments were used to characterize each variant. In vitro translationswere conducted using wheat germ extracts (Promega), [³⁵S]cysteine, and XbaI-linearized variants of p5'BYV exactly asdescribed elsewhere (26).

The 5'-terminal region of ORF 1a is critical for RNA replication and L-Pro function. To determine the role that each of the L-Pro domains plays in BYV RNA amplification, a series of mutations was introducedinto the region of ORF 1a encoding L-Pro. The previously generatedcDNA clone encompassing a mini-BYV genome containing the GUS ORFwas used for this purpose (Fig. 1 and reference 16). The cappedRNA transcripts derived from linearized pBYV-GUS-p21 variantswere transfected into tobacco protoplasts. The GUS assays wereused as a sensitive surrogate marker for quantification of thelevels of genome amplification. In our previous work we demonstratedthat cleavage between L-Pro and the remainder of the ORF 1a productis essential for virus viability, whereas the N-terminal, nonproteolyticdomain functions as an activator of genome amplification (26).However, it was not known if release of the mature replicase isthe only function of L-Pro that is essential for RNA replication,and if the proteinase domain provides any additional activityrequired for efficient RNA accumulation. To address these questions,we generated a mutant called DELL, in which the complete L-ProORF except for the start codon was deleted such that the translationof mutant RNA would result in production of mature, unchangedreplicase (Fig. 2). Protoplast transfection experiments revealedthat the DELL variant produced no detectable GUS activity (Table2) and accumulated no virus-specific RNA (Fig. 3, lane DELL).In fact, this mutant was indistinguishable from the replication-deficientfs mutant expressing nonfunctional replicase (Table 2; Fig. 3,lane fs; reference 26).

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TABLE 2. Comparison between GUS activity and accumulation of genomic RNA in BYV variants at 4 days after transfection of protoplasts

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FIG. 3. Northern analysis of the RNA accumulation in protoplasts transfected with parental and mutant BYV variants. Lane GUS-p21, parental BYV-GUS-p21 variant. Other lanes represent the mutants marked at the top and mock-transfected protoplasts (lane Mock). Arrows mark the positions of genomic RNA and subgenomic RNAs (sgRNAs) encoding GUS and p21, as well as of background bands corresponding to plant rRNAs (26). The membrane was overexposed to visualize low levels of BYV RNA accumulation detected in N-ATG and A1 mutants.

One possible interpretation of the inability of the DELL variant to replicate is that the function of the proteolytic domainis not limited to a single autocatalytic cleavage at the C terminusof L-Pro but may also involve cleavage(s) elsewhere in the replicase.An alternative explanation would be that the noncatalytic, N-terminaldomain is indispensable for virus viability. However, we haveshown earlier that a mutant, called 1-4, lacking most of the N-terminaldomain and retaining its very N-terminal, 54-amino-acid-long peptidewas viable but accumulated ~5 times less RNA than the wild-typevirus (26). Thus, complete loss of viability in the DELL mutantcould be attributed to loss of either the 54-codon-long RNA regionor a region encoding the proteinasedomain.

To test the role of the 5'-proximal region of ORF 1a in RNA amplification, we generated a mutant (S-1) in which codons 2 to54 were deleted in frame to result in expression of the truncatedL-Pro possessing most of the N-terminal domain and a completeproteinase domain (Fig. 2). Unexpectedly, the S-1 mutant was nonviable(Table 2; Fig. 3, lane S-1). This result could be due to theindispensability of the short N-terminal peptide for L-Pro functionor to a critical role played by the deleted RNA region (e.g.,in RNA folding or interaction with thereplicase).

To distinguish between these two possibilities, we generated a double-point mutant, N-ATG, in which the original start codonof ORF 1a was replaced with the ACA and an artificial start codonwas engineered in place of codon 57 of ORF 1a (Fig. 2). As expected,in vitro translation of the N-ATG RNA yielded a truncated L-Pro.This mutant product accumulated in vitro to a level similar tothat of the nonmutant L-Pro, indicating that no significant changesin translational and proteolytic activity occurred due to thetransfer of the start codon to the downstream location (data notshown).

In protoplast transfection experiments, the N-ATG variant was viable, although it produced only 2.5% of the GUS activity ofthe parental variant (Table 2). Northern hybridization analysisyielded similar results (Table 2; Fig. 3, lane N-ATG), once againindicating that the GUS activity accurately reflects RNA accumulation.The phenotype exhibited by the N-ATG mutant is indicative of amajor defect in RNA amplification. Comparison of the phenotypesof the S-1 and N-ATG mutants suggests that the 5'-terminal, 54-codon-longregion of ORF 1a provides a dual function. At the RNA level, thisregion is indispensable for virus viability, likely due to itsrole in overall RNA folding or its function as a cis-replicationalsignal. At the protein level, the peptide encoded in this regionplays an important role in the L-Pro function in accumulationof viralRNA.

Roles played by each of the L-Pro domains in RNA accumulation. The viability of the N-ATG variant allowed us to revisit the problem of the relative functional importance of the N-terminaland proteinase domains for BYV RNA accumulation. To this end,we engineered two deletion mutants based on the N-ATG variant.In mutant N-ATG- $Delta$ N, an artificial start codon was fused with theproteinase domain to result in expression of L-Pro variant lackingall of its N-terminal domain but possessing a proteinase domain(Fig. 2). In vitro translation experiments using the mutant mRNArevealed formation of the expected ~16-kDa proteinase domain thatefficiently released itself from the downstream protein product(not shown). This result was in agreement with our previous workdemonstrating that the N-terminal domain is not required for theproteolytic activity of the C-terminal domain (26).

In mutant N-ATG- $Delta$ ALL, the same artificial start codon was placed immediately upstream of the first codon of the putative methyltransferasedomain. This mutant was designed to express intact replicase inthe absence of L-Pro expression (Fig. 2). Protoplast transfectionexperiments demonstrated that the N-ATG- $Delta$ N variant was viable,although it produced only ~0.1% of the GUS activity found in parentalvariant (Table 2). This result emphasized the importance of theN-terminal domain for RNA amplification: in its absence, onlya low, basal level of viral RNA was produced. The level of GUSactivity in protoplasts transfected with the N-ATG- $Delta$ ALL variantwas indistinguishable from that found in N-ATG- $Delta$ N variant (Table2). This result can be interpreted to mean that in the absenceof a need for the proteolytic release of the replicase N terminus,the proteinase domain provides no other activity in genome amplification.Alternatively, strong debilitation of genome amplification afterdeletion of the N-terminal domain could itself be a rate-limitingevent masking the need in a proteinasedomain.

It should be emphasized that although the GUS activity measured in N-ATG- $Delta$ N and N-ATG- $Delta$ ALL variants was only 0.1% of thatfound in parental BYV-GUS-p21, it was ~100-fold higher than thebackground GUS activity detected in the replication-deficientfs variant. This result confirmed that low GUS activity detectedin the N-ATG- $Delta$ N and N-ATG- $Delta$ ALL mutants was due to amplificationand transcription of the viral RNA rather than to direct translationof the input RNAtranscripts.

Alanine-scanning mutagenesis of the N-terminal domain. To further examine the functional significance of the different regions in the N-terminal L-Pro domain, we generated 12 alanine-scanningmutations, designated A1 to A12 and located through the entiredomain's length (Fig. 2). In each of these mutants, three adjacentcodons specifying charged or polar amino acid residues were replacedwith alanine codons (Table 1). These mutations were expectedto affect the L-Pro function in RNA amplification by disruptingthe electrostatic and/or hydrophilic interactions within the L-Promolecule or between L-Pro and its putative protein partners. Surprisingly,the effects of 11 out of 12 alanine-scanning mutations on GUSaccumulation were relatively weak. The levels of GUS activitydetected in protoplasts were from 63 to 128% of that found inthe parental variant (Table 1). Statistical analysis of the datarevealed that these mutants were not significantly different fromthe nonmutant variant (P > 0.1), except for mutant A7 (P < 0.001).In contrast, mutant A1 accumulated only ~1% of the GUS activityfound in a nonmutant variant (Table 1). This result was alsoconfirmed by Northern hybridization analysis (Fig. 3, lane A1).Since A1 was the only alanine-scanning mutation located withinthe limits of the N-terminal, 54-residue-long peptide, this resultfurther emphasized the particular significance of this N-terminalregion in L-Pro function. It is also possible that A1 mutationaffected replication due to disturbance in the overall foldingof the 5'-terminal RNAregion.

Tagged mini-BYV variant as a model system. In this work, we used GUS activity as a surrogate marker of BYV genome amplification. Since GUS activity is a final resultof viral genome replication, transcription of a subgenomic RNA,and its translation, we wished to investigate whether the levelof GUS activity is an accurate measure of genome amplification.More specifically, we determined whether the mutations in L-Procould selectively affect the processes of transcription or translationwithout affecting genomic RNA accumulation. Northern hybridizationanalyses demonstrated that the GUS-negative fs, DELL, and S-1mutants failed to accumulate any detectable viral RNA, indicatingthat each of these mutations blocked accumulation of viral RNA.Comparative analyses of the relative levels of GUS activity andRNA accumulation for mutants A1 and N-ATG revealed similarly lowlevels of replication between the two types of assay. It shouldbe noted that the sensitivity of GUS assays is much higher thanthat of Northern analysis. Quantification of RNA levels lowerthan 1% of the wild-type level was impractical due to the backgroundsignal. On the other hand, the high signal-to-background ratioof the GUS assays allowed confident measurements of enzymaticactivity at levels of 0.001% of the wild-type level. These resultsestablished the GUS-tagged mini-BYV genome as an adequate modelwith which to study amplification of BYV RNA. An additional benefitof using the mini-BYV variant is the relative ease of manipulationof the truncated genome. A similar minimal replicon was engineeredrecently for another closterovirus, citrus tristeza virus (29).

Structure-function relationships in the L-Pro molecule. The GUS-tagged mini-BYV was used to reveal the roles played by each of two major domains of BYV L-Pro in genome amplification.As we demonstrated previously, the cleavage mediated by the C-terminalproteinase domain is essential for virus viability, whereas theN-terminal L-Pro domain acts as an activator of RNA amplification(26). However, it was not known if L-Pro is essential for RNAreplication, nor were the specific roles played by each of theL-Pro domains understood. The data presented in this work demonstratethat mutant N-ATG- $Delta$ ALL, expressing none of the L-Pro domains,is capable of replicating in tobacco protoplasts, albeit to avery low level. The results indicate that L-Pro is not necessaryfor basal-level replication. On the other hand, a 1,000-fold decreasein RNA accumulation exhibited by the L-Pro null mutant stressesthe importance of L-Pro for efficient amplification of the closterovirusgenome.

The identical phenotypes of the mutants lacking the N-terminal domain only and those lacking both N-terminal and proteinasedomains suggested that the proteinase itself plays no specificrole in the enhancement of genome amplification. Previous workwith potyvirus HC-Pro, which also possesses a C-terminal papain-likeproteinase domain, suggested that either this domain itself orthe cis cleavage mediated by this domain is indispensable forviral viability (19). Since we were able to generate a viableBYV mutant in which the need for cis cleavage was abolished, wepropose that the major function of the proteinase domain is tocleave between the L-Pro and bona fide replicase. However, extremedebilitation of genome amplification in the absence of the N-terminaldomain of L-Pro could interfere with our ability to detect possibleadditional functions provided by the proteinasedomain.

Mutation analysis of the N-terminal domain revealed its unexpected structural flexibility. Indeed, 11 out of 12 alanine-scanningmutations introduced into this domain had no major effect on RNAaccumulation. Computer analysis suggested that the N-terminaldomain of L-Pro possesses a nonglobular, elongated structure,in contrast to the globular proteinase domain (A. R. Mushegianand V. V. Dolja, unpublished data). This type of structure mayaccount for the unusual tolerance of the former domain to mutations.Alternatively, this domain may be required for other than genomeamplification phases of the virus life cycle. The only regionin which an alanine-scanning mutation was not tolerated was thevery N-terminal region of L-Pro. The A1 mutation, which changedamino acids 39 to 41, resulted in a 100-fold reduction in RNAaccumulation. A similar level of genome amplification was obtainedwith the mutant in which the ORF 1a start codon was engineered~50 codons downstream from its natural position. In contrast,deletion of the ~50-codon-long RNA segment completely abolishedgenome amplification, indicating that this region of ORF 1a functionsnot only as a coding sequence but also as, or as part of, thecis element required for RNA replication. Understanding of themultiple roles played by the L-Pro-encoding region will permitus to investigate the molecular mechanisms involved in activationof genome amplification mediated by this important part of theBYVgenome.

	ACKNOWLEDGMENTS

We thank Yuka Hagiwara for participation in an initial step of this study, Arcady Mushegian for help with computer analysisof amino acid sequences, and George Rohrman and Theo Dreher forcritical reading of the manuscript. We are grateful to JonathanReed for excellent technicalassistance.

This work was supported by grants from the U.S. Department of Agriculture (NRICGP 97-35303-4515) and National Institutes ofHealth (R1GM53190B) to V.V.D.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Botany and Plant Pathology, Oregon State University, Cordley Hall 2082,Corvallis, OR 97330. Phone: (541) 737-5472. Fax: (541) 737-3573.E-mail: doljav{at}bcc.orst.edu.

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27. Peremyslov, V. V., Y. Hagiwara, and V. V. Dolja. 1999. HSP70 homolog functions in cell-to-cell movement of a plant virus. Proc. Natl. Acad. Sci. USA 96:14771-14776[Abstract/Free Full Text].

28. Piccone, M. E., E. Rieder, P. W. Mason, and M. J. Grubman. 1995. The foot-and-mouth disease virus leader proteinase gene is not required for viral replication. J. Virol. 69:5376-5382[Abstract].

29. Satyanarayana, T., S. Gowda, V. P. Boyko, M. R. Albiach-Marti, M. Mawassi, J. Navas-Castillo, A. V. Karasev, V. Dolja, M. E. Hilf, D. J. Lewandowski, P. Moreno, M. Bar-Joseph, S. M. Garnsey, and W. O. Dawson. 1999. An engineered closterovirus RNA replicon and analysis of heterologous terminal sequences for replication. Proc. Natl. Acad. Sci. USA 96:7433-7438[Abstract/Free Full Text].

30. Snijder, E. J., and J. M. Meulenberg. 1998. The molecular biology of arteriviruses. J. Gen. Virol. 79:961-979[Medline].

31. Strauss, J. H., and E. G. Strauss. 1994. The alphaviruses: gene expression, replication, and evolution. Microbiol. Rev. 58:491-562[Abstract/Free Full Text].

32. Suzuki, N., B. Chen, and D. L. Nuss. 1999. Mapping of a hypovirus p29 protease symptom determinant domain with sequence similarity to potyvirus HC-Pro protease. J. Virol. 73:9478-9484[Abstract/Free Full Text].

33. Zhu, H.-Y., K.-S. Ling, D. E. Goszczynski, J. R. McFerson, and D. Gonsalves. 1998. Nucleotide sequence and genome organization of grapevine leafroll-associated virus-2 are similar to beet yellows virus, the closterovirus type member. J. Gen. Virol. 79:1289-1298[Abstract].

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27.	Peremyslov, V. V., Y. Hagiwara, and V. V. Dolja. 1999. HSP70 homolog functions in cell-to-cell movement of a plant virus. Proc. Natl. Acad. Sci. USA 96:14771-14776[Abstract/Free Full Text].
28.	Piccone, M. E., E. Rieder, P. W. Mason, and M. J. Grubman. 1995. The foot-and-mouth disease virus leader proteinase gene is not required for viral replication. J. Virol. 69:5376-5382[Abstract].
29.	Satyanarayana, T., S. Gowda, V. P. Boyko, M. R. Albiach-Marti, M. Mawassi, J. Navas-Castillo, A. V. Karasev, V. Dolja, M. E. Hilf, D. J. Lewandowski, P. Moreno, M. Bar-Joseph, S. M. Garnsey, and W. O. Dawson. 1999. An engineered closterovirus RNA replicon and analysis of heterologous terminal sequences for replication. Proc. Natl. Acad. Sci. USA 96:7433-7438[Abstract/Free Full Text].
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32.	Suzuki, N., B. Chen, and D. L. Nuss. 1999. Mapping of a hypovirus p29 protease symptom determinant domain with sequence similarity to potyvirus HC-Pro protease. J. Virol. 73:9478-9484[Abstract/Free Full Text].
33.	Zhu, H.-Y., K.-S. Ling, D. E. Goszczynski, J. R. McFerson, and D. Gonsalves. 1998. Nucleotide sequence and genome organization of grapevine leafroll-associated virus-2 are similar to beet yellows virus, the closterovirus type member. J. Gen. Virol. 79:1289-1298[Abstract].