Localization of the Single-Stranded RNA-Binding Domains of Bluetongue Virus Nonstructural Protein NS2

The S2 gene of bluetongue virus, serotype 17, has been cloned,and the nonstructural protein NS2 has been expressed. Syntheticpeptides matching regions within the amino acid sequence ofNS2 were used to map three single-stranded RNA (ssRNA)-bindingregions within the protein. A prokaryotic expression systemwas then used to generate a series of deletion mutants withthe ssRNA-binding domains of NS2 removed, singly and in differentcombinations. These truncated proteins were expressed on a largescale and purified to near homogeneity. The affinity of eachtruncated protein towards ssRNA was then assayed by electrophoreticmobility shift assays. As a result, the three ssRNA-bindingdomains of BTV nonstructural protein NS2 have been conclusivelylocalized, and removal of these three domains completely abrogatesthe ability of NS2 to bind to ssRNA.

INTRODUCTION

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Introduction

Bluetongue virus (BTV) is a member of the Reoviridae familyand is the prototype virus of the Orbivirus genus (9, 25). Transmittedby biting midges of the Culicoides genus, BTV is a pathogenof wild and domestic ruminants (1). The BTV genome consistsof 10 double-stranded RNA (dsRNA) segments, which encode 11viral proteins (19, 20). These genomic segments are enclosedby a double-shelled capsid, composed of seven structural proteins(24). Additionally, four nonstructural proteins have been identifiedinside BTV-infected cells (5). The role of each of the nonstructuralproteins within the viral life cycle has not been conclusivelydetermined, but they are presumed to be involved with the varioussteps of viral morphogenesis.

The 41-kDa nonstructural protein NS2 binds single-stranded RNA(ssRNA), is associated with the viral inclusion bodies, andis the only phosphorylated BTV protein (7). Similar ssRNA-bindingproteins, such as the ${varphi}$ NS of reovirus and the NS35 (NSP2) ofrotavirus, appear to be a common feature of the members of thefamily Reoviridae (6, 11). They are suspected to be involvedin the transport and condensation of the viral mRNAs, but theirprecise functions have not yet been established. Therefore,this study focused upon the ssRNA-binding domains of NS2 ofBTV serotype 17 in order to more fully elucidate the roles ofthis protein within the replication of BTV.

MATERIALS AND METHODS

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Materials and Methods

Preparation of viral dsRNA. A seed stock for U.S. BTV serotype 17 (BTV-17) was obtainedfrom the USDA Arthropod-Borne Animal Disease Research Laboratory,and then propagated and plaque purified as described by Kowalikand Li (12). Viral particles were purified on sucrose gradients(13), and then total dsRNA was extracted with sodium dodecylsulfate (SDS)-KCl (16).

Cloning of BTV cDNAs. A full-length cDNA for the BTV-17 S2 gene was generated fromthe purified BTV dsRNA by the Clamp-R method (13) of reversetranscription-PCR (RT-PCR). "Anchored" primer pairs [S2EXP(+)(5'-TCC-CCC-GGG-ATC-CAT-GGA-GCA-AAA-GCA-A-3') and S2EXP(-) (5'-CGG-GAT-CCC-GGG-GTA-AGT-GTA-AAA-TCC-C-3')],complementary to the termini of the S2 gene and containing anovel BamHI restriction site (26), were used to amplify thefull-length S2 cDNA by PCR. A Techne PHC-3 Thermal Cycler wasused for all PCRs.

The PCR product and the cloning vector pGEX2T (Pharmacia) weredigested with BamHI (overnight digestion), and then the 5' endsof the linearized vector were dephosphorylated by incubationwith calf intestinal alkaline phosphatase. The BTV-17 S2 insertwas ligated into the vector at a ratio of 8:1 by incubationwith T4 DNA ligase. After ligation, 10 µl of the reactionmix was transformed to the XL-1 Blue strain of Escherichia coli(Stratagene) by the heat shock-calcium method adapted from Hanahan(3). Colonies were checked for the presence of plasmids containingthe inserted gene by the procedure of Mangalathu and Bassett(17), and clones containing the inserted gene in the correctorientation were isolated.

Construction of BTV-17 S2 deletion mutants. The S2 ${Delta}$ 68 mutation was generated by digesting the full-lengthpGEX2T-B17S2 clone with StyI (restriction site at position 778within the S2 sequence) and HindIII (site at position 944).Klenow fragment (5 U/µl; New England BioLabs) was thenused to create blunt ends at each site by incubation with 33µM deoxynucleoside triphosphates (dNTPs) for 15 min at25°C. The ends were then ligated together with the 168-bpregion removed.

The S2 ${Delta}$ N mutation was created by digestion of the full-lengthpGEX2T-B17S2 clone with EcoRI (restriction site at position219 within the S2 sequence). The digested DNA was run on a 0.7%agarose gel along with DNA size markers, and a 904-bp band wascut out of the gel and purified with QuicKit GlasPac (NationalScientific Supply). This DNA was then inserted into the EcoRIsite of pGEX2T.

Primers S267(3) (5'-GAT-CTG-CAG-ATA-ATT-TGA-TCT-CA-3') and S267(5)(5'-TAC-TGC-AGT-TAG-CGC-CAC-GGC-T-3') were designed to flankthe ${Delta}$ 67 region within the S2 sequence and introduced anchoredPstI restriction sites. PCR amplification with the full-lengthS2 gene as a template was performed with the primers S2EXP(+)and S267(3), producing a 476-bp fragment, and S2EXP(-) and S267(5),producing a 605-bp fragment. The PCR products were digestedwith PstI, ligated together, and then digested with BamHI andelectrophoresed on a 0.7% agarose gel. A band of 1,081 bp wascut out of the gel and ligated into pGEX2T at the BamHI site.

All other deletion mutants were generated by the techniquesdescribed above in different combinations. Inserts were checkedby digestion with the appropriate enzymes, followed by electrophoresison a 1% agarose gel along with DNA size markers. Orientationswere confirmed by digestion with EcoRV (which has restrictionsites at positions 238 and 478 within the S2 sequence and atposition 4095 within pGEX2T). The clones pGEX2T-B17S2 ${Delta}$ 67, pGEX2T-B17S2 ${Delta}$ 68,and pGEX2T-B17S2 ${Delta}$ 67/68 were confirmed by sequencing (Utah StateUniversity Biotechnology Center).

Upon isolation of each deletion mutant, plasmid DNA for eachwas purified from 100 ml of culture, aliquoted to microcentrifugetubes, and stored at -20°C.

Expression of intact and truncated B17 NS2 proteins. Each clone to be expressed was freshly transformed into theTOPP-Purple strain of E. coli (Stratagene) and grown into mid-logphase in 2-liter cultures. Isopropyl-ß-D-thio-galactopyranoside(IPTG; Alexis Biochemicals) was then added to a final concentrationof 2 mM to induce protein expression. After 4 h, the cells wereharvested by centrifugation at 5,000 x g for 10 min with 1-literbottles in a KA-9 rotor within a Sorvall RC-5B centrifuge. Cellpellets were transferred to 50-ml centrifuge tubes and storedat -80°C and then resuspended in 20 ml of phosphate-bufferedsaline (PBS; 137 mM NaCl, 2.7 mM KCl, 4.3 mM Na₂HPO₄ ·7H₂O, and 1.4 mM KH₂PO₄ [pH 7.4]) and kept on ice. Lysozyme(500 mg) was added along with DNase I (50 mg), and the cellswere lysed with a VirSonic-50 probe sonicator (Virtis). Thecells were sonicated three times for 30 s each at 80% outputpower. The tubes were centrifuged at 4,000 x g for 10 min topellet insoluble debris, and supernatants were stored at 4°C.

Protein analysis by SDS-PAGE and immunoblot assays. Cell lysates were analyzed by discontinuous SDS-polyacrylamidegel electrophoresis (PAGE) (10% polyacrylamide) by the methodof Laemmli (14). Gels were stained with Coomassie blue R250(Sigma), or, alternately, proteins were transferred to nitrocellulosemembranes from gels by a diffusional "sandwich" blot technique(4). After electrophoresis, SDS-PAGE gels were placed betweentwo nitrocellulose membranes and compressed within a sandwichapparatus. This sandwich was then soaked for at least 24 h ina tank containing 25 mM Tris-HCl (pH 8.0), 192 mM glycine, and20% methanol. The membranes were removed from the tank and blockedwith 3% bovine serum albumin (BSA) in TBST buffer (10 mM Tris-HCl[pH 8.0], 150 mM NaCl, 0.05% Tween 20) for 30 min. Each blotwas then probed with antisera against bluetongue proteins, dilutedin TBST at a ratio of 1:1,000 for polyclonal or oligoclonalantibodies or 1:5,000 for monoclonal antibodies. After incubationfor 30 min on a rocking platform, the membranes were washedwith TBST (three times for 5 min each), and then the appropriatesecondary antibody (anti-rabbit or anti-mouse) conjugated toalkaline phosphatase (AP) was added at a 1:5,000 dilution. Themembranes were incubated for another 30 min and then washedthree times with TBST for 5 min each. Finally, the AP substratesolution was added for color development.

Purification of intact and truncated NS2 proteins. Since the pGEX expression system was used, all proteins wereproduced as a fusion to glutathione S-transferase (GST) (21).An initial, partial purification was performed by anion-exchangechromatography with a POROS-20Q (quaternary amine) column onthe BioCAD Perfusion Chromatography Workstation (PerSeptiveBiosystems). Using isoelectric points predicted by ExPaSy foreach deletion protein, the purification profile was run foreach protein at pH 7.5 (to give each a net negative charge),at a flow rate of 20 ml/min, in 50 mM Tris-HCl buffer. Witha double-step NaCl gradient elution, peaks were detected atA₂₈₀ with a UV monitor, collected (1.5-ml fractions), and analyzedby SDS-PAGE. The characteristic peak fraction for each proteinwas then collected and pooled for further purification.

Each partially purified protein in the NS2 deletion series wasdialyzed in PBS buffer to remove NaCl and then added to a columncontaining 10 ml of glutathione-conjugated Sepharose 4B (Amersham)in PBS, with the EconoSystem chromatography apparatus (Bio-Rad).With a flow rate of 1 ml/min, the resin was washed with at least10 column volumes of PBS to remove unbound proteins, and thenthe GST fusion protein was eluted by the addition of 20 mM glutathione(reduced form) in 50 mM Tris-HCl (pH 8.0) plus 100 mM NaCl.Fractions were collected and analyzed at A₂₈₀ in a spectrophotometer,and one peak was found to contain the desired GST fusion protein.The purification was repeated for each expressed protein inthe deletion series, and then the concentration of each wasdetermined by bicinchoninic acid assay (Pierce). Each proteinwas analyzed by SDS-PAGE, and the identity of each was confirmedby immunodetection.

In vitro transcription for synthesis of ³²P-labeled BTV-17 S2 ssRNA transcripts. The cDNA of BTV-17 S2 was cloned into the PstI site of the pGEM4Zvector (Promega). Recombinant plasmids with the inserted S2gene in both orientations were obtained and then transformedinto the XL-1 Blue strain of E. coli. Purified plasmids werelinearized by either BamHI or HindIII digestion. BTV-17 S2 ssRNAtranscripts were then transcribed and labeled by ³²P in vitrowith SP6 polymerase, as described by Hayama and Li (4, 18).Transcripts (both plus and minus sense) were treated with RNase-freeDNase I, followed by phenol-CHCl₃ extraction and isopropanolprecipitation. A positive-sense BTV-11 S3 transcript was preparedin the same manner (by E. Hayama) and provided for use in dotblot analysis.

Dot blot analysis for ssRNA-binding activity of NS2 synthetic peptides. Eight oligopeptides were designed, according to the deducedamino acid sequence of the serotype 17 NS2 protein (26). Thepeptides were chosen at locations with clusters of positivelycharged amino acids and at regions with predicted surface accessibilityby GCG software (Genetics Computer Group, Madison, Wis.). Thepeptides were synthesized in the multiple-antigen peptide (MAP)format at the Utah StateUniversity Biotechnology Center, witheight identical oligopeptides connected to a lysine core (22).After each synthetic peptide was dissolved in PBS at 1 µg/µl,each peptide was then dot blotted onto a nitrocellulose membranein twofold serial dilutions from 5 µg. The membrane wasblocked for 30 min at room temperature in Denhardt’s solution(0.02% Ficoll 400, 0.02% polyvinylpyrrolidone, 0.02% BSA). Themembrane was incubated with 2 µg of ³²P-labeled BTV-11S3 transcript for 30 min and then washed three times with Denhardt’ssolution. After the membrane was air dried, it was exposed toKodak film for 24 h for autoradiography.

EMSAs for intact and truncated NS2 proteins. Purified NS2 was analyzed for its ability to bind to both positive-and negative-sense BTV-17 S2 ssRNA transcripts by electrophoreticmobility shift assays (EMSAs) (2, 4). One microgram of proteinwas mixed with 0.4 µg of each ³²P-labeled S2 transcriptand then run on a 4% polyacrylamide gel. The gel was vacuumdried on filter paper and exposed to Kodak film for 24 h, andthen the film was developed.

After each of the NS2 proteins in the deletion series was purifiedto near homogeneity, each was examined for its ability to bindssRNA by EMSA. ssRNA size markers (New England BioLabs) wereused at 1 µg per assay and mixed with each protein (0,2, 4, 6, or 8 µg per assay) in 0.5x Tris-borate-EDTA (TBE).The tubes were incubated for 5 min at room temperature, andthen loading buffer (0.1% bromphenol blue, 0.1% xylene cyanole,15% Ficoll 400, in 0.5x TBE buffer) was added. Each assay wasanalyzed by electrophoresis on a 1% agarose gel stained withethidium bromide (EtBr; 0.05 µg/ml). All buffers wereprepared with diethyl pyrocarbonate-treated double-distilledH₂O (ddH₂O) to eliminate potential RNase activity.

RESULTS

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Results

Peptide mapping of ssRNA-binding domains. Eight NS2 sequence-specific synthetic oligopeptides were assayedfor their ability to bind to ssRNA. The peptides were appliedto a membrane that was then probed with a ³²P-labeled BTV-11S3 positive-sense transcript, of which we had an abundant supply(courtesy of E. Hayama). Peptides N, 67, and 68 showed ssRNA-bindingactivity (Fig. 1), while the other five peptides did not demonstrateany affinity towards ssRNA. Identical results were found inEMSAs with yeast ssRNAs (data not shown). The sequences of eachpeptide and their corresponding locations within NS2 are shownin Fig. 2.

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FIG. 1. Dot blot analysis of ssRNA binding by synthetic NS2 peptides. Each synthetic peptide derived from the amino acid sequence of NS2 was applied to a nitrocellulose membrane in twofold dilutions from 5 µg. The membrane was probed with 2 µg of ³²P-labeled BTV-11 S3 (positive sense) ssRNA and then exposed to film for 24 h.

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FIG. 2. Synthetic peptides derived from the amino acid sequence of NS2. Peptide sequences were chosen within the amino acid sequence of NS2 serotype 17 and then synthesized in the MAP format. All are shown in their positions relative to the full-length NS2 protein.

Construction of S2 deletions. A series of deletions corresponding to the N, 67, and 68 domainswere constructed within the BTV (serotype 17) S2 gene and insertedinto the pGEX2T vector. Each deletion construct was designedto maintain the frame of the open reading frame (ORF) aroundthe removed portion of the gene. All constructs were generatedin the XL-1 Blue strain of E. coli. After selection for thepresence of inserts by restriction digests and agarose gel electrophoresis,each clone was checked for the correct orientation of the insert.

Expression and purification of the NS2-GST fusion proteins. A schematic diagram is shown in Fig. 3 for all constructs withinthe NS2 deletion series. The sizes for each of the intact ortruncated NS2 proteins are predicted in Table 1.

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FIG. 3. Schematic diagram of all members of the NS2 deletion series. All constructs were expressed as carboxyl-terminal fusions to GST (not shown). The amino acids flanking each deletion site are indicated. The oligopeptides corresponding to each deleted region are shown below.

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TABLE 1. Predicted sizes of each NS2 deletion mutant and corresponding protein^a

Each truncated NS2 protein was expressed within and isolatedfrom the XL-1 Blue strain of E. coli. However, we have foundthat the TOPP-Purple strain produced a higher yield of the proteinfor each transformed plasmid construct. Therefore, each plasmidwas transformed to the TOPP-Purple strain and plated on Luria-Bertaniagar. Colonies were picked from the plates and grown overnightfor each round of expression on a 2-liter scale. When cellswere in the mid-log phase of growth, expression of the fusionprotein was induced by the addition of IPTG. A prior time coursestudy established that optimal protein expression occurred at4 h postinduction, so all induced cells were harvested 4 h afterthe addition of IPTG. The overexpressed fusion proteins accumulatedwithin the bacterial cells, allowing isolation and concentrationby centrifugation into a cell pellet.

Initial attempts to purify the NS2-GST fusion proteins by affinitychromatography, with glutathione-conjugated agarose beads ("G-beads"),were unsuccessful in isolating the proteins to homogeneity.An alternate purification strategy was therefore devised, utilizinga preliminary ion-exchange chromatography step. The BioCAD systemprovided a means for purification with a high flow rate, usingPOROS Perfusion beads containing an ion-exchange matrix. Sincethe isoelectric point for each fusion protein in the NS2 deletionseries was predicted to be within a 5.4 to 5.6 range, a bufferin the pH 7.0 to 7.5 range, which would impart a net negativecharge upon each protein, was chosen. Therefore, a POROS-Q (quaternaryamine, an anion-exchanger) column was used with the BioCAD workstationfor the purification of each protein. A double-step salt gradientwas designed within an anion-exchange profile to optimize theresolution of the peaks eluted from the column, and a similarchromatogram was seen for each protein in the deletion series.Multiple purification runs were done for each protein, and fractionswere collected over the elution gradient. The truncated proteinswere not always found within the same elution fractions (dueto the slight differences in predicted pI), but a characteristic"shape" was always observed for the elution profile, allowingcollection of each truncated NS2 protein in one peak fraction.The eluted peaks were analyzed by SDS-PAGE, and those containingthe desired proteins were pooled. A total of 60 ml (40 fractions)was collected for each protein, and the samples were storedat 4°C.

After this partial purification based on charge, affinity chromatographywas again attempted. All samples were dialyzed in PBS to removethe salt from the anion-exchange elution gradient, and then6 ml was applied to a column containing glutathione conjugatedto Sepharose 4B rather than agarose. This resin allowed a higherflow rate for washing away unbound proteins and had been refinedfor a very specific affinity towards GST fusions by the manufacturer(Amersham). Using an EconoSystem chromatography apparatus, thecolumn was washed by at least 10 column volumes of PBS. Boundproteins were then eluted by a "step" gradient of 20 mM glutathionein 50 mM Tris-HCl (pH 8) plus 100 mM NaCl. The extra washing,higher glutathione concentration, and presence of salt in theelution buffer resolved the eluted GST fusion proteins downto single bands per peak (as measured at A₂₈₀), as shown bySDS-PAGE (Fig. 4). Peak fractions for each intact or truncatedNS2 protein (and a GST control) were collected and analyzedby SDS-PAGE (Fig. 5) and were found to be of the correct sizerelative to size markers run in the same gel. Immunoblottingwas performed after SDS-PAGE, and the blots were probed by oligoclonalantibodies generated by peptides 67 (Fig. 6A) and 68 (Fig. 6B)and by a series of monoclonal antibodies produced against NS2(Fig. 6C). Immunodetection confirmed that the purified bandswere members of the NS2 deletion series (Fig. 6C). The oligoclonalantibodies specific to regions 67 and 68 did not react withthose truncated NS2 proteins in which the corresponding regionswere deleted (Fig. 6A, lanes 6, 8, 9, and 11, and B, lanes 7,8, 10, and 11, respectively).

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FIG. 4. SDS-PAGE and immunoblot analysis of purified NS2. Samples (50 µl) were taken from cell lysate, from purified fractions after anion-exchange chromatography, or from fractions after affinity chromatography with glutathione-Sepharose 4B. Ten microliters of each sample was loaded per well of a 10% gel. The gels were stained with Coomassie blue (A) or blotted to nitrocellulose membranes (B) and probed with an oligoclonal antibody generated from NS2 peptide 67. The primary antibody was used at a 1:1,000 dilution, and the secondary antibody (conjugated to AP) was used at 1:5,000.

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FIG. 5. SDS-PAGE analysis of purified intact and truncated NS2 proteins. Samples (50 µl) were taken from each purified fraction, and 50 µl of loading buffer was added. The samples were boiled, and 10 µl was added to the wells of a 10% polyacrylamide discontinuous SDS-PAGE. All GST fusion proteins are shown relative to prestained BenchMark size markers (lane 1).

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FIG. 6. Immunoblot analysis of purified intact and truncated NS2 proteins. Nitrocellulose membrane blots, corresponding to the SDS-PAGE shown in Fig. 5, were probed with antibodies against NS2. Oligoclonal antibodies generated by peptide 67 (A) or peptide 68 (B) were used at a 1:1,000 dilution. A mixture of monoclonal antibodies (C) was used at a dilution of 1:5,000 for each (B87.29.7, B87.29.4, F13.20.2, and F12.17.2, all reacting against unknown epitopes within NS2). Appropriate secondary antibodies (anti-rabbit or anti-mouse), conjugated to AP, were used at a 1:5,000 dilution.

ssRNA-binding assays for the purified intact and truncated NS2 proteins. Upon purification to near homogeneity, each NS2-GST fusion proteinwas dialyzed against PBS (three buffer changes over 2 days,4°C) to remove salt from the elution step. The decisionwas made to assay the intact fusion proteins for affinity towardsssRNA, due to the difficulty in completely removing the GSTportion of the protein by thrombin digestion. Prior experimentsshowed incomplete cleavage of NS2 from GST, even with extendedincubation times and high concentrations of thrombin. GST hasa negligible effect upon the behavior of a fusion protein (10).In the studies presented here, GST alone had no affinity towardsssRNA, and GST conjugated to NS2 was found to have no effecton the ability of NS2 to bind to ssRNA.

Earlier studies have shown nonspecific binding to poly(U)-Sepharoseby NS2 isolated from cells infected by BTV (23). NS2 producedby recombinant baculovirus and purified from insect cells alsoexhibited nonspecific affinity towards ssRNA. Recombinant NS2produced as a GST fusion protein showed the same ssRNA-bindingactivity towards both positive- and negative-sense viral ssRNAtranscripts (Fig. 7).

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FIG. 7. Affinity of NS2 for positive- and negative-sense BTV-17 (B17) S2 ssRNA transcripts. EMSAs were used to show binding of 1 µg of GST/NS2 to 0.4 µg of ³²P-labeled plus-sense BTV-17 S2 ssRNA (lanes 2 and 3) and to 0.4 µg of ³²P-labeled negative-sense BTV-17 S2 ssRNA (lanes 5 and 6). The mobility of the radiolabeled ssRNA transcripts was retarded at the wells of the PAGE gel when the NS2 protein was present, while unbound ssRNAs are shown in lanes 1 and 4.

In order to establish the general ssRNA-binding activity ofeach intact or truncated NS2 protein, EMSAs were performed foreach purified fusion protein. An ssRNA size ladder, a commercialproduct generated by in vitro transcription from seven differentDNA templates (500 to 9,000 bp), was first used for the EMSAs.The denaturing sample buffer accompanying the size markers contained7 M urea, which would potentially disrupt the interaction ofthe truncated proteins with the ssRNA, so it was not used. Allassays were performed in 0.5x TBE buffer, and all reagents wereprepared with diethyl pyrocarbonate-treated ddH₂O. In accordancewith the manufacturer’s recommendation, 1 µg (0.5µg/µl) of ssRNA was used per assay, for optimalviewing with EtBr staining. After incubation with each protein,samples were analyzed by agarose gel electrophoresis. Affinitytowards ssRNA resulted in the formation of a protein-RNA complex,which inhibited the ability of the RNA to move within the gel.Therefore, ssRNA binding by each protein was determined by thedegree of retarded movement of the ssRNA in the gel as the proteinconcentration was increased.

The results show complete retardation of 1 µg of the ssRNAsize markers by the NS2 fusion protein at 6 µg, but noinhibition of mobility by the ${Delta}$ 67/68/N protein (Fig. 8A) overthe same concentration range. With these three ssRNA-bindingdomains removed, NS2 completely lost its affinity towards ssRNA.This confirms the importance of these three domains towardsbinding ssRNA, but the affinity for ssRNA shown by each truncatedprotein may also be affected by the conformational changes resultingfrom the deletion of each domain.

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FIG. 8. EMSA for NS2 and truncated NS2 proteins with ssRNA size markers. The ssRNA markers (9,000, 7,000, 5,000, 3,000, 2,000, 1,000, and 500 bases) were used at 1 µg per assay, with each purified fusion protein added at 0, 2, 4, 6, or 8 µg per sample. Retardation of ssRNA mobility was demonstrated by the retention of movement relative to the loading wells (shown at the top of each panel). The 3,000-base ssRNA size marker is highlighted in each gel. Panel A shows the intact NS2 protein and the triple deletion ${Delta}$ 67/68/N, panel B shows the single deletions ${Delta}$ 67 and ${Delta}$ 68, panel C shows the single deletion ${Delta}$ N and the double mutant ${Delta}$ 67/68, panel D shows the double deletions ${Delta}$ 67/N and ${Delta}$ 68/N, and panel E shows the control proteins GST and BSA.

Those proteins with the deletion of a single binding domain,either ${Delta}$ N, ${Delta}$ 67, or ${Delta}$ 68, still demonstrated the ability to bindssRNA, but showed less affinity than intact NS2 (Fig. 8B and C).At 8 µg, all three single-deletion proteins couldcompletely retard the RNA. The ${Delta}$ 67 mutant appeared to have slightlygreater affinity for the ssRNA size markers than did the ${Delta}$ N or ${Delta}$ 68 mutants. This suggests a weaker contribution of the 67 regionto ssRNA binding by NS2 relative to the other two domains.

The double-deletion proteins ${Delta}$ 67/68, ${Delta}$ 67/N, and ${Delta}$ 68/N demonstratedless binding to ssRNA than the single-deletion forms, and 8µg did not completely inhibit ssRNA mobility (Fig. 8C and D).The truncated ${Delta}$ 67/68 protein showed lower affinity forthe RNA markers than did the ${Delta}$ 67/N or ${Delta}$ 68/N proteins. This mightindicate not only differences in the affinity of each regiontowards ssRNA, but a cooperative or sequential role for eachdomain in binding to ssRNA by the intact NS2 protein.

The GST (purified in the same manner as all the other fusionproteins) and BSA control proteins demonstrated no affinitytowards the ssRNA markers (Fig. 8E).

Similar results were demonstrated in assays performed with yeastssRNA (data not shown). It was necessary to use 10 µgof yeast ssRNA per assay for visualization with EtBr, and theyeast RNA (primarily tRNAs) was seen on agarose gels in the $~$ 100- to 200-bp range. Intact NS2 was able to bind the ssRNAin an apparent "double-stepwise" manner, with 80 µg ofprotein completely inhibiting mobility in the gel. This againseems to indicate cooperative or interactive binding betweendomains, with differential affinity towards ssRNA. ${Delta}$ 67/68/N showedno retardation of the yeast ssRNA in the gel over the concentrationrange assayed.

The deletions of a single binding domain, ${Delta}$ N, ${Delta}$ 67, and ${Delta}$ 68, resultedin a reduced affinity towards yeast ssRNA. The retardation ofthe yeast RNA within the gel also demonstrated a stepwise bindingpattern. The truncated ${Delta}$ 67 protein had a slightly greater affinitytowards the RNA than those of the other two single-deletionproteins.

Removal of two binding domains produced a further reductionin the affinity towards the yeast ssRNA. The ${Delta}$ 67/68, ${Delta}$ 67/N, and ${Delta}$ 68/N proteins could not completely retard the movement of theRNA even at 80 µg, but a double-step binding pattern wasstill observed in the gels. The ${Delta}$ 68/N mutant showed slightlyless affinity towards the yeast ssRNA (i.e., not as much RNAwas held in the gel wells at a high protein concentration),but much more RNA was bound in the first step, as compared tothe patterns shown by the ${Delta}$ 67/68 and ${Delta}$ 67/N proteins. This againimplies some degree of differential affinity and cooperativeinteraction between ssRNA-binding domains. In this case, removalof the 67 region has less of an effect on the overall affinitytowards ssRNA, but removal of the other two domains affectsthe stepwise binding pattern shown towards the yeast ssRNA.

The control proteins GST and BSA again demonstrated no affinitytowards the yeast ssRNA. The abilities of all of the intactor truncated NS2 proteins to bind the two types of ssRNAs testedare summarized in Table 2.

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TABLE 2. Summary of ssRNA binding by intact or truncated NS2 proteins

DISCUSSION

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Discussion

Nonstructural proteins play key roles within the replicativecycle of viruses. While encoded by the viral genome and producedwithin infected cells, NS proteins are not part of the virionsand do not move with the viral particles into subsequent hostcells. At each round of infection, however, nonstructural proteinsare vital for regulating different mechanisms of the host cellor for assisting in the assembly of progeny virions (15).

The nonstructural protein NS2 has been proposed to fulfill sucha role within the BTV replication and assembly process. Priorinvestigations have established the affinity of NS2 towardsssRNA, its oligomerization, and its presence at the VIB matrix(7, 8). These findings suggest that BTV NS2 is interacting withthe viral mRNAs at the sites of assembly of new viral core particles.The presence and function of NS2 at the VIBs had not been conclusivelyexplained, however.

Our peptide mapping established three regions within the aminoacid sequence of NS2 that could bind ssRNA in vitro, indicatingthat synthetic oligopeptides corresponding to these regionscould "mimic" the nonspecific affinity for ssRNA shown by thenative NS2 protein. Specifically, peptide N (EQKQRRFTKN, residuepositions 2 to 11), 67 (DIREL-RQKIKNERE, positions 153 to 166),and 68 (EKVAKQIKLKDER, positions 274 to 286) were found to bindssRNA, out of eight peptides chosen for their charged natureand predicted surface accessibility. The designation "N" wasrelated to the N-terminal region of the NS2 protein, and thenomenclature for the peptides 67 and 68 was based on the orderin which a series of peptides were synthesized for various regions,predicted as antigenic epitopes or as highly charged domains,within all 11 of the bluetongue proteins. The NS2 peptides wereproduced in the MAP format and were found to have affinity forboth positive- and negative-strand BTV transcripts, yeast tRNAs,and poly(U)-Sepharose. The same three peptides demonstratedno affinity for dsRNA, ssDNA, or dsDNA, however. Peptides werealso used to generate anti-BTV oligoclonal antibodies in rabbits,as well as for the investigation of the affinity of severalBTV proteins towards different nucleic acid species.

In the present study, three ssRNA-binding domains have beenlocalized within NS2. Removal of each domain reduced the affinityof NS2 towards ssRNA, and the deletion of all three domainscompletely eliminated the ability of NS2 to bind to ssRNA. Differentdegrees of affinity towards ssRNA were also observed among thedifferent truncated proteins, indicating that each of thesethree domains has differential affinity. The deleted regionswere of different sizes, and the degree of reduced affinitytowards ssRNA did not seem to correspond to the size of eachdeletion. It seems unlikely that the effect is due simply toan alteration in the conformation of each truncated protein,but this possibility can’t be completely ruled out.

A stepwise binding pattern was observed for yeast ssRNA in EMSAs.As protein concentrations were increased, intermediate complexescould be seen before there was complete retardation of ssRNAmobility. This pattern was observed to different degrees foreach truncated NS2 protein (except for ${Delta}$ 67/68/N, which did notbind to the yeast ssRNA). This might further indicate a differentialaffinity by each domain towards the ssRNA or a sequential bindingto ssRNA by the three ssRNA-binding domains. The pattern mayalso be an artifact related to the use of yeast single-strandedtRNA for the assays, since it was not seen as readily with thessRNA size markers. It also remains to be determined if NS2binds to three mRNAs, one by each ssRNA-binding domain, or toone mRNA by all three domains.

All intact and truncated NS2 proteins used for this projectwere produced by a prokaryotic expression system. Since BTVinfects mammalian cells, experiments are in progress to examinehow and where intact and truncated NS2 molecules are expressedinside of eukaryotic cells. We will also investigate the effectof heterologously expressed NS2 upon viral replication in cellsthat are infected by BTV. The presence or absence of the ssRNA-bindingdomains of NS2 will allow further elucidation of the role ofthis nonstructural protein within the BTV viral life cycle.

ACKNOWLEDGMENTS

We thank I-Jen Huang for construction of the initial pGEX2T-B17S2clone, and Emiko Hayama for production of the ³²P-labeled BTV-11S3 transcripts.

This work was supported in part by Utah Agricultural ExperimentStation Project 537 and USDA grant 90-37266-5567.

FOOTNOTES

* Corresponding author. Mailing address: Department of Biology, Utah State University, 5305 Old Main Hill, Logan, UT 84322-5305. Phone: (435) 797-1914. Fax: (435) 797-1575. E-mail: josephli{at}biology.usu.edu.

This article has been approved as AES paper 7331.

REFERENCES

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