Respiratory Syncytial Virus M2-1 Protein Requires Phosphorylation for Efficient Function and Binds Viral RNA during Infection

doi:10.1128/JVI.75.24.12188-12197.2001

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Journal of Virology, December 2001, p. 12188-12197, Vol. 75, No. 24
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.24.12188-12197.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.

Respiratory Syncytial Virus M2-1 Protein Requires Phosphorylation for Efficient Function and Binds Viral RNA during Infection

Tara L. Cartee and Gail W. Wertz^*

Department of Microbiology, University of Alabama School of Medicine, Birmingham, Alabama 35294

Received 18 June 2001/Accepted 14 September 2001

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

The M2-1 protein of respiratory syncytial (RS) virus is a transcriptional processivity and antitermination factor. The M2-1protein has a Cys3His1 zinc binding motif which is essential forfunction, is phosphorylated, and has been shown to interact withthe RS virus nucleocapsid (N) protein. In the work reported here,we determined the sites at which the M2-1 protein was phosphorylatedand investigated the importance of these phosphorylated residuesfor M2-1 function in transcription. By combining protease digestion,matrix-assisted laser desorption ionization-time of flight massspectrometry, and site-directed mutagenesis, we identified thephosphorylated residues as serines 58 and 61, not threonine 56and serine 58 as previously reported. Serines 58 and 61 and thesurrounding amino acids are in a consensus sequence for phosphorylationby casein kinase I. Consistent with this, we showed that the unphosphorylatedM2-1 protein synthesized in Escherichia coli could be phosphorylatedin vitro by casein kinase I. The effect of eliminating phosphorylationby site-specific mutagenesis of serines 58 and 61 on the functionof the M2-1 protein in transcription of RS virus subgenomic repliconswas assayed. The activities of the M2-1 protein phosphorylationmutants in transcriptional antitermination were tested over arange of concentrations and were found to be substantially inhibitedat all concentrations. The data show that phosphorylation is importantfor the M2-1 protein function in transcription. However, mutationof the M2-1 phosphorylation sites did not interfere with the abilityof the M2-1 protein to interact with the N protein in transfectedcells. The interaction of the M2-1 and N proteins in cotransfectedcells was found to be sensitive to RNase A, indicating that theM2-1-N protein interaction was mediated via RNA. Furthermore,the M2-1 protein was shown to bind monocistronic and polycistronicRS virus mRNAs duringinfection.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Respiratory syncytial (RS) virus is an important human pathogen that causes lower respiratory tract infection in children.RS virus is a member of the genus Pneumovirus in the family Paramyxoviridae.Members of this family are nonsegmented, negative-sense, single-strandedRNA viruses. The RS virus genome contains 10 genes, encoding atleast 11 proteins (6, 7). Three of the RS virus gene productsare essential for RNA replication: the nucleocapsid (N) protein,which encapsidates the viral genome, and the large polymeraseprotein (L) and the phosphoprotein (P), which comprise the viralRNA-dependent RNA polymerase (RdRp) (13, 32, 36).

In contrast to replication, efficient transcription of RS mRNAs requires an additional gene product, the M2-1 protein. TheM2-1 protein is encoded by the first of two open reading frames(ORFs) of the M2 gene (5, 8). The second ORF of the M2 geneencodes the M2-2 protein. The M2-1 protein is a basic phosphoproteinof 194 amino acids that functions in transcription as a processivityfactor and an antiterminator (4, 16). M2-1 colocalizes withthe N protein in cytoplasmic inclusions and interacts with theN protein, as assayed by coimmunoprecipitation with a monoclonalantibody (MAb) to M2-1 (12, 15). There is a conserved Cys3His1motif, predicted to bind zinc, at the amino terminus of the M2-1protein, and maintenance of the predicted zinc coordinating residuesis essential for the function of the protein (15). Mutationof the cysteine or histidine residues of this motif results ina loss of M2-1 phosphorylation, loss of the M2-1-N interaction,and loss of M2-1 transcriptional activity (15). Although, ithas not been directly demonstrated that this motif in M2-1 bindszinc, it is apparent that maintenance of the motif is requiredfor activity. The M2-1 protein in RS virus-infected cells existsin different phosphorylation states, resulting in its migrationas at least two bands by reducing sodium dodecyl sulfate-polyacrylamidegel electrophoresis (SDS-PAGE) (15, 23, 30); the slower-migratingspecies contains the majority of the phosphorylated form, andthe faster-migrating species lacks significant phosphorylation.The sites of M2-1 phosphorylation were recently reported as threonine56 and serine 58 (9). The contribution of phosphorylation tothe function of M2-1 has not beeninvestigated.

As with other negative-strand viruses, transcription of RS viral genes is obligatorily sequential. The RdRp enters at or nearthe 3' end of the genome, and genes are transcribed in order fromthe 3' to the 5' end of the genome (10). Attenuation occursat each gene junction, resulting in a gradient of mRNA synthesissuch that genes nearest the 3' end of the genome are transcribedmore abundantly than those near the 5' end (2, 10). The junctionsbetween RS virus genes contain semiconserved gene end and conservedgene start sequences separated by nonconserved intergenic sequencesof various lengths (3). The gene end sequence contains thesignals for the RS virus RdRp to polyadenylate and terminate synthesisof the mRNA (3, 19, 21). However, the efficiency of terminationat the various RS virus gene junctions differs (14). The conservedgene start sequence signals initiation of a new mRNA (20). Inorder to initiate synthesis of the new mRNA, the RdRp must firstterminate synthesis of the upstream message (17, 21).

The M2-1 protein functions as both a transcriptional processivity factor and an antiterminator (4, 16). The M2-1 processivityfunction prevents intragenic termination, allowing the synthesisof full-length mRNAs (11), and the antitermination functioncauses the RdRp to ignore the semiconserved gene end sequence(14, 16), resulting in the synthesis of polycistronic RNAsobserved in infection. The relative contributions of processivityand antitermination to the function of M2-1 have not been clearlydiscriminated. Both of these features of M2-1 may be necessaryto allow deeper access of the RS virus RdRp on the genomic template,which is potentially important, given that pneumovirus genomesare longer and contain more genes than those of most paramyxovirusmembers. In addition, the various RS virus genes respond differentlyto the M2-1 protein (11, 14). This differential sensitivitymay represent a mechanism by which the virus further regulatesthe expression of certain geneproducts.

In the work reported here, we first determined the number and location of phosphorylated residues in the M2-1 protein, andour results show that serines 58 and 61 are phosphorylated, incontrast to a previous report (9). We next examined the effectof eliminating phosphorylation, by site-specific mutagenesis ofindividual sites or sites in combination, on the function of theM2-1 protein as a transcriptional antiterminator and on its interactionwith the N protein. Our data show that phosphorylation is importantfor the M2-1 protein function in transcription. Further, we showthat the M2-1 protein binds viral mRNAs in infected cells andthat the interaction of the M2-1 and N proteins in transfectedcells is mediated byRNA.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

cDNA constructs. The RS virus-specific plasmids pN, pP, pL, pM2ORF1, pC7S, pF/M2, and pM/SH have been previously described (14-16, 36).

A cDNA designed to express a carboxy-terminal six-histidine-tagged M2-1 protein (pM2-6His) was generated by PCR of pM2ORF1using a set of three nested primers to add nucleotides encodinga thrombin cleavage site and a six-His tag to the 5' end of thegenomic M2-1 coding sequence. The KpnI- and BamHI-digested PCRproduct was cloned into the respective sites in pGEM3 (Promega)oriented for expression by the T7 promoter. This construct containsthe following 12 amino acids attached to the carboxy terminusof M2-1: LVPRGSHHHHHH. This construct was tested for its transcriptionalactivity, phosphorylation state, and ability to interact withthe N protein and was found to have wild-type (wt) activity inallrespects.

cDNAs expressing mutant M2-1 proteins (pS58A, pS61A, pT56A, and pT56AS58A) were generated in a wt pM2ORF1 background usingQuikchange (Stratagene) with complementary mutagenicprimers.

A cDNA encoding a glutathione S-transferase (GST)-tagged M2-1 protein (GST-M2) was generated for expression in Escherichiacoli. An M2-1 PCR product from pM2ORF1 was cloned into the EcoRI-and BamHI-digested pGEX-1 $lambda$ T (Pharmacia-Biotech). This was designedto produce a fusion protein that contained GST at the amino terminusand the M2-1 protein at the carboxy terminus, with a thrombincleavage site between them. Thrombin cleavage of the fusion proteinresulted in the addition of two amino acids, a glycine and a serine,to the amino terminus of the M2-1protein.

Nucleotide sequencing of all of the engineered cDNA constructs was performed by the University of Alabama at Birmingham (UAB)Automated DNA Sequence Core Facility on a Perkin-Elmer AppliedBiosystems 377sequencer.

Cells, virus, and cDNA transfections. HEp-2 cells were grown in minimal essential medium (Gibco) supplemented with 5% fetal calf serum. Human RS virus strain A2or cDNA clones derived from human RS virus strain A2 were usedin all experiments. RS virus infections of HEp-2 cells were carriedout at a multiplicity of infection (MOI) of 10. Virus was allowedto adsorb for 1.5 h, and then minimal essential medium with 2%fetal calf serum was added. Plasmids encoding RS virus proteinsor subgenomic replicons were transfected with Lipofectin intoHEp-2 cells previously infected with vTF7-3 or MVA-T7 as describedpreviously (14, 15).

M2-6His expression and MALDI-TOF analysis. The M2-1 protein with a six-His tag (M2-6His) was expressed from vTF7-3-infected (MOI = 5) HEp-2 cells transfected with 14µg of pM2-6His in 100-mm-diameter dishes. Cells were harvested18 h posttransfection (p.t.) by freeze-thaw in native bindingbuffer (20 mM sodium phosphate, 500 mM sodium chloride, 10 mMimidazole, pH 7.8). The clarified lysate from one 100-mm-diameterdish was incubated with 30 µl of nickel-nitriloacetic acid (NiNTA)beads (Qiagen) for 30 min and then washed three times with nativewash buffer (20 mM sodium phosphate, 500 mM sodium chloride, 20mM imidazole, pH 6.0). The NiNTA beads were boiled in denaturingsample buffer, and the partially purified protein was separatedby electrophoresis on an SDS-11% polyacrylamide gel. The bandscorresponding to the M2-6His protein were excised from the gel,and the gel slice containing M2-6His was destained (25 mM ammoniumbicarbonate, 50% acetonitrile), dried, and then cleaved with trypsin,Lys C, or cyanogen bromide (CNBr; Roche). The trypsin used inthese experiments contained chymotrypsin activity, as it consistentlycleaved M2-1 at amino acid 83. Trypsin and Lys C digestions wereperformed in 25 mM ammonium bicarbonate. Peptides were extractedthree times (50% acetonitrile, 10% formic acid), dried, dissolvedin extraction buffer, and diluted 1:10 in $alpha$ cyano-4-hydroxycinnamicacid (Sigma). CNBr cleavage of M2-1 protein and extraction ofpeptides were performed in 50% formic acid followed by dilutionin sinapinac acid (Sigma). The resultant peptides from the digestionswere analyzed by matrix-assisted laser desorption ionization-timeof flight mass spectrometry (MALDI-TOF MS) performed by the UABComprehensive Cancer Center Mass Spectrometry Shared Facilityon a Voyager Elite MALDI-TOF spectrometer (PerSeptive Biosystems)in linear mode. A portion of the cleaved sample was treated with1 U of calf intestinal phosphatase (CIP; Pharmacia Biotech) for30 min at 37°C and analyzed. Uncleaved protein was prepared andextracted as for trypsin and Lys C digestions, except the proteinwas diluted in sinapinac acid as thematrix.

The phosphorylated 53-to-83 peptide was recovered from the protease digestion using an immobilized metal affinity chromatographytip (NEST Group). The negative charge of the phosphates allowedbinding to the positively charged column. The column was stripped(50 mM EDTA, 1 M NaCl) and charged with 100 mM ferric chloridein 0.1 M acetic acid. The peptides were eluted with 0.1% ammoniumacetate (pH 9.5). The eluted peptide was digested with carboxypeptidaseY using the Sequazyme C-Peptide Sequencing Kit (PerSeptive Biosystems)according to the manufacturer's instructions. The resultant fragmentswere analyzed by MALDI-TOF MS as described above to confirm theidentity of thefragment.

Protein labeling and immunoprecipitation. Expression of the wt or mutant M2-1 protein without histidine tags was assayed by transfecting 5 µg of the appropriate plasmid,using Lipofectin, into vTF7-3-infected HEp-2 cells in 60-mm-diameterdishes. Analysis of N protein interaction with M2-1 protein wasperformed by transfecting 5 µg of pN alone or with 5 µg of M2-1-encodingplasmid into vTF7-3-infected HEp-2 cells. RS virus-infected ortransfected cells, following incubation at 37°C for 20 or 17 h,respectively, were treated with either cysteine- and methionine-deficientor phosphate-deficient medium for 30 min. The infected or transfectedcells were labeled for 3 h using 66 µCi of [³⁵S]methionine and [³⁵S]cysteine (Trans ³⁵S label; ICN) per ml or 100 µCi of inorganic [³³P]phosphate (ICN) per ml. Cytoplasmic extracts were prepared asdescribed previously (28).

Immunoprecipitations were performed using an anti-M2-1 monoclonal antibody (MAb), ICI3, and protein G-Sepharose (Pharmacia-Biotech).To reduce nonspecific background, the lysates were preclearedwith a vaccinia virus polyclonal antibody (indicated in the figurelegends). RNase A (Sigma), proteinase K (Sigma), DNase RQI (Promega),and protein phosphatase lambda ( $lambda$ -PPase; New England Biolabs)treatments were performed on the immunoprecipitated protein (indicatedin the figure legends). Treatment of the M2-1-N interaction withthese reagents was followed by two washes with wash buffer (150mM NaCl, 10 mM Tris HCl, 1% NP-40, 0.5% deoxycholate, 0.1% SDS).The immunoprecipitated proteins were analyzed by electrophoresison an SDS-11% polyacrylamide gel and detected by autoradiography.The percent M2-1-N interaction was determined by densitometricanalysis of an autoradiogram. The background of the N-only lanewas subtracted from each of the cotransfected lanes. Then, a ratioof N to M2-1 was calculated for each lane and compared to thewt M2-1-N interaction by dividing each by the wt ratio, whichset the wt interaction to 100%.

GST-M2 protein purification and in vitro phosphorylation. pGST-M2 encoding the cDNA for expression of the GST-M2 fusion protein was transformed into BL21-DE3 cells. Cultures were grownin Luria broth to an optical density of 0.6 and then induced withisopropyl $beta$ -D-thiogalactoside at a final concentration of 0.1mM for 2 h. The cells were lysed by sonication in phosphate-bufferedsaline (PBS; 140 mM NaCl, 2.7 mM KCl, 10 mM Na₂HPO₄, 1.8 mM KH₂PO₄,pH 7.3). The extract was incubated with glutathione-Sepharose4B beads (Pharmacia-Biotech) and washed with PBS in the presenceof 20 µg of phenylmethlysulfonyl fluoride/ml, and M2-1 was freedfrom the column by thrombin cleavage (50 U/ml; Pharmacia Biotech)in PBS for 2 h. The eluted protein was analyzed for purity bySDS-PAGE followed by staining with GelCode Blue(Pierce).

The ability of the M2-1 protein to be phosphorylated by casein kinase I (CKI; New England Biolabs) was assayed by incubationin the presence of CKI (60 U) and [ $gamma$ -³³P]ATP (0.6 µCi; NEN) followed by electrophoresis on an SDS-11%polyacrylamide gel, staining with GelCode Blue, andautoradiography.

RNA synthesis. RNA synthesis was analyzed in either RS virus-infected HEp-2 cells or MVA-T7-infected HEp-2 cells transfected with plasmidsexpressing subgenomic replicons. HEp-2 cells infected with RSvirus in 100-mm-diameter dishes were incubated at 37°C for 20h. Before being labeled, infected cells were pretreated with actinomycinD (Act D; 10 µg/ml; Sigma) for 30 min. RS virus-infected cellswere labeled for 5.5 h with 100 µCi of inorganic [³³P]phosphate per ml in the presence of Act D. Transfections withsubgenomic replicons were performed as previously described (14),except that the following amounts of plasmids were used: 4 µgof pF/M2 or pM/SH, 1.5 µg of pN, 0.75 µg of pP, 0.25 µg of pL,and various amounts of M2-1-encoding plasmid. Cytoplasmic extractswere prepared from the infected and transfected cells (28),and RNAs were phenol extracted, ethanol precipitated, separatedon a 1.75% agarose-6 M urea gel (34), and detected by fluorographyas previously described (24). Quantitation of the RNAs was performedas previously described (14).

Viral RNA coimmunoprecipitations were performed as described in "Protein labeling and immunoprecipitation" above, with MAbsto M2-1 (ICI3; a gift of G. Toms) and N and F proteins (MAb 15and MAb 19; gifts of G. Taylor). The inorganic [³³P]phosphate-labeled RNAs were released from the coimmunoprecipitationreaction mixture by boiling it in NTE (100 mM NaCl, 1 mM EDTA,10 mM Tris) with 0.5% SDS. RNAs were analyzed by phenol extraction,ethanol precipitation, and separation on agarose-ureagels.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Mapping of phosphorylated residues. Initially, mutagenesis was performed to determine the site(s) of phosphorylation of the M2-1 protein. Several sites were chosenfor mutagenesis based on similarity with consensus protein kinaseC (PKC) and CKII phosphorylation motifs. The potential residues(serines 2 and 108 and threonines 69, 181, 193, and 194) wereindividually changed to alanine. None of these mutants displayedany change in phosphorylation state (R. Hardy, unpublished data).Since the mutagenesis of potential consensus sites had not revealedthe phosphorylation sites, we sought instead to map regions ofthe M2-1 protein that were phosphorylated by combining proteasedigestion with MALDI-TOF MS analysis. This technique allows thedetection of posttranslational modifications, such as phosphorylation,based on an increase in the mass of the modified fragment (25).Each single phosphorylation event should result in an 80-Da increasein the mass of a peptide. A six-histidine-tagged M2-1 protein,M2-6His, was expressed in HEp-2 cells from pM2-6His, partiallypurified, and separated by SDS-PAGE, and bands corresponding tothe M2-6His protein were excised; cleaved with trypsin, Lys C,or CNBr; and analyzed by MALDI-TOF. The CNBr cleavages were performedon only the slower-migrating species of M2-6His (the phosphorylatedform), whereas the protease digestions were performed on a gelslice containing both species of the protein. The cleavage reactionswere analyzed for fragments with the expected mass for unphosphorylatedand phosphorylated fragments. CNBr cleavage of the phosphorylated(slower-migrating) form of M2-6His resulted in fragments correspondingto amino acids 100 to 206 and 51 to 206. The 100-to-206 fragmentwas the expected mass for the unphosphorylated fragment, whichindicated that the carboxy-terminal half of the M2-1 protein wasnot phosphorylated. The fragment corresponding to amino acids51 to 206 was observed as the expected mass plus approximately160 Da, indicating that the M2-1 protein was phosphorylated attwo locations between amino acids 51 and 100 (data notshown).

Trypsin and Lys C digestions were performed on M2-6His to further narrow the location of the phosphorylation sites. Representativedata for M2-6His cleaved with trypsin are shown in Fig. 1A. Twosets of fragments were observed, one peptide corresponding toamino acids 53 to 83 and one peptide corresponding to amino acids53 to 92, each of which was phosphorylated zero, one, or two times(Fig. 1A, top, and Table 1). Treatment with CIP prior to analysisby MALDI-TOF resulted in the disappearance of the fragments increasedin mass by 80 and 160 Da, confirming that the increased mass wasdue to phosphorylation of the 53-to-83 and 53-to-92 peptides (Fig.1A, bottom). A summary of the phosphorylated fragments, observedwith Lys C or trypsin cleavage, is shown in Table 1. All of thephosphorylated fragments shown in Table 1 were sensitive to phosphatasetreatment. No phosphorylated fragments were observed elsewherein the M2-1 protein. Amino acids 1 to 28 of M2-6His were not observedamong any of the proteolytic fragments from any of the digests,making it difficult to rule out the possibility that M2-1 wasnot phosphorylated in that region, but subsequent mutagenesisshowed that the phosphorylation sites resided elsewhere.

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FIG. 1. MALDI-TOF analysis of M2-6His digestion products. (A) Representative trypsin digestion of M2-6His, identifying phosphorylated peptides. M2-6His was transfected into vTF7-3-infected HEp-2 cells. After partial purification with NiNTA beads, the M2-1 protein was separated by electrophoresis on an SDS-11% polyacrylamide gel, stained, excised from the gel, destained, dried, and cleaved with trypsin. The resultant peptides were analyzed by MALDI-TOF in linear mode (top). A duplicate sample was treated with CIP (1 U) for 30 min at 30°C and analyzed (bottom). In the bottom graph, a mass calibration standard (mass standard) was added to the reaction prior to analysis. (B) Potential phosphorylation sites between amino acids 53 and 68 of the M2-1 protein. Mutagenesis was performed on the residues that are underlined and in boldface.

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TABLE 1. Characteristics of phosphorylated fragments observed with Lys C or trypsin cleavage

The identity of the peptide containing residues 53 to 83 was confirmed by isolation of the phosphorylated peptide on an immobilizedmetal affinity column followed by carboxypeptidase cleavage andMALDI-TOF analysis. Carboxypeptidase cleavage resulted in a seriesof fragments corresponding to amino acids 53 to 68, 71, 72, 73,76, 77, 78, or 82. Each of these fragments was the expected massplus approximately 160 Da, indicating that the two phosphorylatedresidues were not located C terminally of the arginine at position68 (data not shown), narrowing the two phosphorylation sites toamino acids 53 to68.

Identification of phosphorylation sites. To further investigate the sites of phosphorylation in the M2-1 protein, site-directed mutagenesis was performed on residuesthat could act as potential phosphate acceptors between aminoacids 53 and 68, as shown in Fig. 1B. Serines 58 and 61 whichwere in a consensus sequence for phosphorylation by CKI, and threonine56, which was in a consensus sequence for phosphorylation by CKII,were individually changed to alanine (S58A, S61A, and T56A) bysite-specific mutagenesis of pM2-ORF1. In addition, a double mutantwas made in which threonine 56 and serine 58 were both changedto alanine (T56A S58A). These plasmids were individually transfectedinto vTF7-3-infected HEp-2 cells. The cells from duplicate transfectionswere labeled with [³⁵S]methionine and [³⁵S]cysteine or with inorganic [³³P]phosphate. The labeled proteins were immunoprecipitated withan anti-M2-1 MAb, ICI3, which has been shown to recognize thedifferent phosphoforms of M2-1 (15). Analysis by SDS-PAGE showedthat wt M2-1 migrated as two bands, differentiated by their phosphorylationstates (15). The slower-migrating form was predominant, andlabeling with ³³P indicated that this form was phosphorylated (Fig. 2A, lanes3 and 4). Treatment of wt M2-1 with $lambda$ -PPase resulted in a changein mobility to the faster-migrating form and loss of ³³P incorporation (Fig. 2A, lanes 13 and 14), confirming that theobserved change in mobility and inorganic [³³P]phosphate incorporation were due to phosphorylation. In contrastto wt M2-1, the S58A mutant migrated predominantly as the fasterform with a loss of the majority of the ³³P incorporation, indicating a lack of phosphorylation (Fig. 2A,lanes 7 and 8). The S61A mutant resulted in a change in the distributionof the two bands, which correlated with a decrease in the phosphorylatedform (Fig. 2A, lanes 5 and 6). The double mutant, T56A S58A, hadthe same phenotype as the S58A single mutant (Fig. 2A, lanes 9and 10). The T56A mutant was wt in its phosphorylation pattern(Fig. 2A, lanes 11 and 12), which indicated that threonine 56was not one of the phosphorylated residues. A large amount ofa ³³P-labeled material coimmunoprecipitated with M2-1 and the mutantM2-1 proteins, as indicated by the labeled material migratingat the top of each ³³P-labeled lane (Fig. 2A). The identification of this materialis discussed below.

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FIG. 2. Expression of M2-1 protein phosphorylation mutants. (A) Analysis of mutant proteins. HEp-2 cells, infected with vTF7-3, were either mock transfected or transfected with 5 µg of plasmids expressing M2-1 or the indicated phosphorylation mutants (S58A, S61A, T56A, or T56A S58A). The cells were labeled with either [³⁵S]methionine and [³⁵S]cysteine (³⁵S) or inorganic [³³P]phosphate (³³P) for 3 h at 17 h p.t. Cytoplasmic extracts were prepared and precleared. Then proteins were immunoprecipitated with MAb ICI3, separated by SDS-PAGE, and subjected to autoradiography. After immunoprecipitation, the samples in lanes 13 and 14 were treated with 200 U of $lambda$ -PPase for 30 min at 30°C. The bracket indicates the position of the ³³P-labeled coimmunoprecipitated material. (B) RS virus proteins. RS virus-infected (RS inf.) HEp-2 cells, harvested 24 h post infection, were prepared and immunoprecipitated as described for panel A, except the lysate was not precleared. (C) In vitro CKI phosphorylation of M2-1 protein. M2-1 protein produced in E. coli was incubated with CKI and [ $gamma$ -³³P]ATP for 30 min at 37°C. The protein was separated by SDS-PAGE on an 11% polyacrylamide gel and Coomassie stained (left) or subjected to autoradiography (right).

As mentioned previously, analysis of the amino acid sequence surrounding the phosphorylated residues indicated that serine58 was a potential site for phosphorylation by CKI. The consensussequence for CKI phosphorylation is an acidic residue followedby any two or three amino acids and then the phosphorylatableserine or threonine. The acidic residue can be an aspartic acid,glutamic acid, phosphoserine, or phosphothreonine (29). Phosphorylationat serine 58 provided a phosphoserine at that position and createda potential CKI phosphoacceptor site at serine 61. Thus, CKI phosphorylationat serine 61 is predicted to be dependent upon prior phosphorylationof serine 58, explaining the lack of phosphorylation of the S58Asinglemutant.

To test whether CKI could phosphorylate the M2-1 protein, an unphosphorylated M2-1 was produced in E. coli as a GST-M2 fusion.Thrombin cleavage of GST-M2, while it was bound on the column,allowed elution of M2-1 and retention of GST. Incubation of thepurified M2-1 with CKI and [ $gamma$ -³³P]ATP resulted in a change in migration to a slower-migratingspecies, which incorporated ³³P (Fig. 2C). Additionally, MALDI-TOF analysis of the bacteriallyexpressed M2-1 protein after incubation with CKI indicated thatthe increase in mass was consistent with two phosphorylation events.Trypsin cleavage followed by MALDI-TOF analysis located the phosphorylationsites in the bacterially expressed M2-1, which had been incubatedwith CKI, to amino acids 53 to 92, which overlapped with the CKIsites predicted by sequence analysis (data not shown). NeitherCKII nor PKC, which were also tested, phosphorylated M2-1 (Hardy,unpublished).

Effect of phosphorylation mutants on antitermination. The M2-1 protein has been characterized as a transcription factor that increases processivity and decreases termination withingenes and at the semiconserved gene end termination sequences,resulting in increased production of full-length monocistronicand dicistronic mRNAs (14, 16). The significance of phosphorylationof the M2-1 protein in transcription has not been investigated.The effect of phosphorylation on M2-1 function as an antiterminatorwas assayed using a dicistronic subgenomic replicon, pF/M2, whichcontained the F/M2 gene junction in its authentic upstream anddownstream sequence context (14). The F/M2 replicon was chosenbecause of the sensitivity of the F/M2 gene junction to the actionof the M2-1 protein (14). Previous work has shown that RS virusgenes respond differently to the presence of M2-1 (14). Somegenes, such as the SH gene, terminate efficiently in the absenceor presence of M2-1, while others terminate inefficiently in thepresence of M2-1. In the F/M2 replicon, there is a 15-fold increasein the percentage of full-length bicistronic readthrough productsin the presence of M2-1 (14). The mRNA products transcribedby the F/M2 replicon have been described previously and are shownschematically in Fig. 3A (14). Transcription from this repliconresults in the synthesis of two discrete mRNAs: mRNA1, producedfrom the upstream gene, and mRNA2, produced from the downstreamgene. Three RNA products, resulting from the failure of the polymeraseto terminate at the gene ends, thereby generating polycistronicor readthrough RNAs, are produced in increased amounts in thepresence of M2-1. Readthrough (r/t) A is produced by the failureto terminate at the end of mRNA2. R/t B results from the failureto terminate at the F/M2 gene junction. R/t C is produced by thefailure to terminate at both the F/M2 gene junction and the mRNA2gene end. A stop codon was introduced into the M2 coding sequencein the F/M2 replicon to ensure that the replicon did not producea truncated M2-1 protein, which could potentially obscure theeffects of the phosphorylation mutants. MVA-infected HEp-2 cellswere transfected with pN, pP, pL, pF/M2, and increasing amountsof wt or mutant M2-1 plasmids. The effect of the M2-1 proteinon transcriptional antitermination was measured by calculatingthe percentage of readthrough products, using molar amounts ofthe RNAs obtained from densitometry (14). The amounts of RNAcorresponding to r/t B, r/t C, and mRNA1 that were determinedby densitometric analysis were normalized to the uridine contentof each. The percent readthrough that occurred was calculatedby dividing the amount of RNAs that initiated at the first genestart but failed to terminate at the first gene end (r/t B andr/t C) by the total amount of RNA that initiated at the firstgene start (mRNA1, r/t B, and r/t C). The following equation wasused: percent readthrough = 100 × (r/t B + r/t C)/(mRNA1 + r/tB + r/t C) (14). In the absence of M2-1, low levels of readthroughproducts, only about 6%, were observed (Fig. 3B, lane 1, and C).In the presence of wt M2-1, the levels of polycistronic readthroughRNA (r/t A, r/t B, and r/t C) increased significantly (Fig. 3B,lanes 2, 3, and 4). This occurred even at low levels of inputplasmid (Fig. 3B, compare lanes 1 and 2, r/t B and r/t C). Asreported previously, M2-1 protein rapidly reaches maximal transcriptionalantitermination activity at input plasmid levels between 0.1 and0.3 µg (16, 17). The S58A, S61A, and T56A S58A mutants alldisplayed reduced ability as antiterminators at low levels ofinput plasmid (Fig. 3B, lanes 5, 8, and 11, and C). At higherlevels of input plasmid, they regained some activity, suggestingthe mutants were less efficient but not completely impaired inactivity (Fig. 3B, lanes 7, 10, and 13, and C). The activity ofthe S58A, S61A, and T56A S58A mutants remained below that of thewt at all three input plasmid levels. The S61A mutant, which wasnot as impaired as the S58A and T56A S58A mutants, reached readthroughlevels of about 55% (Fig. 3C). The T56A S58A double mutant wasreproducibly the least efficient antiterminator. This inefficiencywas not due to the mutation at threonine 56, as the T56A singlemutant, whose phosphorylation was not affected (Fig. 2A, lanes11 and 12), showed an RNA synthesis pattern identical to thatof the wt protein (Fig. 3B, lanes 14 to 16). To test whether theresults were specific to the F/M2 gene junction, assays were carriedout with a replicon containing the M/SH gene junction, pM/SH (14),and a similar loss of transcriptional activity was observed (datanot shown).

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FIG. 3. Effect of M2-1 protein phosphorylation mutations on transcription. (A) Diagram of F/M2 replicon containing the authentic F/M2 gene junction and the expected products of transcription. (B) MVA-T7-infected HEp-2 cells were transfected with pF/M2, pN, pP, pL, and increasing amounts of M2-1 wt or mutant plasmids (0.15 to 0.6 µg), pT56A, pS58A, pS61A, or pT56AS58A. The cells were labeled for 5.5 h at 17 h p.t. with [³H]uridine in the presence of Act D. The purified RNAs were visualized by separation on an agarose-urea gel followed by fluorography. (C) Quantitation of percent readthrough products at each amount of input plasmid. Percent readthrough was determined by densitometric analysis and conversion to molar amounts of RNA based upon [³H]uridine incorporation. Rep, replication; le, leader; tr, trailer; ig, intergenic; AAAn, polyadenylate.

M2-1 interaction with RNA. As indicated in the discussion of Fig. 2A, a large amount of ³³P-labeled material, which migrated diffusely at the top of thegel, was coimmunoprecipitated with M2-1 protein or its phosphorylationmutants (Fig. 2A and Fig. 4A, lanes 2, 4, and 5). This representeda significant interaction, as it was not present in the immunoprecipitatedmock-transfected lane (Fig. 4A, lane 1). To determine the natureof the coimmunoprecipitated component, the samples were treatedwith DNase RQI, proteinase K, RNase A, or $lambda$ -PPase prior to PAGE.Digestion with $lambda$ -PPase, proteinase K, and DNase RQI did not affectthe material coimmunoprecipitated by an M2-1-specific MAb (Fig.2A, lane 14, and 4B, lanes 5 and 6). However, digestion with RNaseA following immunoprecipitation resulted in the disappearanceof this material (Fig. 4B, lane 7), suggesting the coimmunoprecipitatedmaterial was RNA. The ³³P-labeled material was also coimmunoprecipitated with M2-1 inthe context of an RS virus infection, as well as in the transfectionsshown, where it was again susceptible to RNase A digestion (Fig.4B, lanes 1 and 2). These results suggest that the M2-1 proteinwas interacting with RNA, which was coimmunoprecipitated withthe M2-1 protein.

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FIG. 4. RNA is coimmunoprecipitated with the M2-1 protein. (A) HEp-2 cells infected with vTF7-3 were either mock transfected or transfected with 5 µg of pM2-ORF1 or plasmids expressing mutant M2-1 proteins. The cells were labeled for 3 h at 17 h p.t. with inorganic [³³P]phosphate. Immunoprecipitations were performed using MAb ICI3. The immunoprecipitated proteins were analyzed by SDS-PAGE on an 11% polyacrylamide gel followed by autoradiography. (B) Digestion of ³³P-labeled component. Transfected (lane 3, mock; lanes 4 to 7, 5 µg of pM2-ORF1) and infected (lanes 1 and 2) cells were prepared as for panel A, except 5 µg of proteinase K (Prot K), 5 µg of RNase A, or 1 U of DNase RQI was added after immunoprecipitation as indicated, followed by incubation for 30 min at 37°C.

A previously characterized mutant, C7S, which contains a cysteine-to-serine change in one of the proposed zinc binding residues,was unable to coimmunoprecipitate RNA (Fig. 4A, lane 3). Previouswork has shown that this mutant has lost its ability to functionin transcription (15), indicating the need for maintenance ofthe zinc binding domain for function. It is also not efficientlyphosphorylated, which we have attributed to improper folding dueto disruption of the Cys3His1 motif, and as a result, very little³³P-labeled protein was present in the ³³P-labeled sample (Fig. 4A, lane 3) (15). However, duplicatesamples labeled with [³⁵S]methionine and [³⁵S]cysteine showed that levels of the C7S protein were similarto those in wt M2-1, providing evidence that the lack of an interactionwith RNA was due to the disruption of the Cys3His1 motif and notto a lack of C7S protein (data notshown).

The above-mentioned coimmunoprecipitation experiments (Fig. 4) were performed under conditions where all the RNAs in the transfectedor infected cells were labeled. We next examined the ability ofthe M2-1 protein to interact with RS virus RNAs in infected cellsin the presence of Act D, which limits labeling to RNAs producedby the RS virus RdRp. HEp-2 cells were infected with RS virus,and RNAs were labeled with inorganic [³³P]phosphate. The cytoplasmic extracts were immunoprecipitatedwith MAbs to RS virus M2-1, N, or F protein, and the coimmunoprecipitatedRNAs were extracted and analyzed by agarose-urea gel electrophoresisadjacent to total cytoplasmic RNA from an RS virus infection.The anti-M2-1 MAb, ICI3, predominately coimmunoprecipitated RNAsthat comigrated with RS virus monocistronic and polycistronicmRNAs (Fig. 5, compare lanes 2 and 3). Upon longer exposure ofthe film, a genomic band was also detected (data not shown). Ascontrols, MAbs to RS virus N protein or F protein, MAb 15 andMAb 19, respectively, were used to immunoprecipitate duplicatesamples. RS virus genomic RNA was primarily coimmunoprecipitatedby the anti-N MAb, as expected, since the genome is encapsidatedwith N protein (Fig. 5, lane 5) (36). The anti-F MAb did notimmunoprecipitate any detectable RNA (Fig. 5, lane 7). In addition,immunoprecipitation of lysate from uninfected cells showed nodetectable RNAs (Fig. 5, lanes 4, 6, and 8). In similar experimentswhere Act D was omitted so both cellular and viral RNAs were labeled,RS viral RNAs were still coimmunoprecipitated, although it wasclear that cellular RNAs, in particular rRNAs, were also coimmunoprecipitated(data not shown). These results indicated that during RS virusinfection, M2-1 protein can associate with RS virus mRNA in aninteraction strong enough to withstand the multiple manipulationsand washings associated with the immunoprecipitation procedure.It could be argued that M2-1 interacts with RNA through interactionwith another viral protein; however, the coimmunoprecipitationexperiment from transfected cells (Fig. 4) and a recently publishedreport (9) both showed that M2-1 interacted with RNA in theabsence of the other viral proteins. However, it is possible thatother viral proteins play a role in determining the specificityof the interaction of M2-1 with RNA.

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FIG. 5. Analysis of coimmunoprecipitated RNA from an RSV infection. HEp-2 cells in 100-mm-diameter dishes were infected with RS virus (MOI = 10). The cells were labeled in the presence of Act D at 17 h postinfection for 5 h with inorganic [³³P]phosphate. Cytoplasmic extracts were prepared, and lysates were either immunoprecipitated with MAbs to the M2-1, N, or F protein or analyzed for total RNA. RNAs were released from the immunoprecipitation mixture by boiling it in NTE. Immunoprecipitated and total RS virus RNAs were purified by phenol extraction and ethanol precipitation, followed by separation on an agarose-urea gel and fluorography. The locations of the various RS virus monocistronic and polycistronic RNAs are indicated on the left. +, present; $-$ , absent.

M2-1 interaction with N protein. Previous work has shown that M2-1 interacts with the N protein in cotransfected cells (12, 15). To assay whether phosphorylationwas necessary for the interaction, the phosphorylation mutantswere tested for the ability to interact with the N protein. Plasmidsexpressing the M2-1 protein or the M2-1 phosphorylation mutantsand N protein were cotransfected into HEp-2 cells, which werelabeled with [³⁵S]methionine and [³⁵S]cysteine. The lysates were immunoprecipitated with the anti-M2-1MAb, ICI3. In the presence of wt M2-1 protein, a significant amountof N protein was coimmunoprecipitated (Fig. 6). The previouslycharacterized C7S mutant is unable to interact with N and thuscoimmunoprecipitated very little N protein, as expected (Fig.6). The two phosphorylation mutants, S58A and S61A, coimmunoprecipitatedlevels of N similar to that coimmunoprecipitated by wt M2-1 (Fig.6). In addition, treatment of the immunoprecipitated materialwith $lambda$ -PPase did not affect the ability of M2-1 to coimmunoprecipitateN (Fig. 6). These results suggest that phosphorylation of theM2-1 protein was not necessary for interaction with the N protein.It was suggested previously that the M2-1-N interaction may bemediated via another component because of a lack of interactionwhen the proteins were synthesized in vitro using rabbit reticulocytelysate (12). Since the results of the previous experiments indicatedthat M2-1 interacts with RNA, we tested whether RNA could mediatethe M2-1-N interaction. Treatment of the M2-1-N protein interactionwith RNase A followed by washing reduced the amount of coimmunoprecipitatedN to background levels (5% of the wt interaction) (Fig. 6). Thesedata indicated that the interaction between M2-1 and N in cotransfectedcells was mediated via RNA. Thus, the experiments assessing theability of the M2-1 phosphorylation mutants to interact with theN protein may instead be an indirect reflection of their abilityto interact with RNA.

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FIG. 6. M2-1 protein-N protein interaction is unaffected by phosphorylation but is sensitive to RNase A digestion. HEp-2 cells infected with vTF7-3 were transfected with 5 µg of the indicated plasmid(s). The cells were labeled 17 h p.t. for 3 h with [³⁵S]methionine and [³⁵S]cysteine and immunoprecipitated with ICI3. RNase A (5 µg) and $lambda$ -PPase (200 U) were added as indicated, and samples were incubated at 37 or 30°C, respectively, for 30 min. Control samples for the RNase A and $lambda$ PPase reactions were treated identically to the digested samples, except that the RNase A and $lambda$ PPase were omitted. The treated and control samples were washed to remove any released protein and analyzed by electrophoresis on an 11% polyacrylamide gel. The percent M2-1-N interaction normalized to the wt interaction was quantified by densitometric analysis of autoradiograms for each sample.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

We examined the sites of phosphorylation and the role that phosphorylation plays in the function of the M2-1 protein in transcriptionand interaction with viral RNA. The M2-1 protein was found byproteolytic digestion and site-directed mutagenesis to be phosphorylatedat serine 58 and serine 61. Serines 58 and 61 lie in the consensussequence for phosphorylation by CKI and are conserved in human,bovine, and ovine RS virus and in turkey rhinotracheitis virus(1, 8, 26, 29, 35, 37). The conservation of theseresidues suggests a functional role for M2-1 phosphorylation.Phosphorylation of serine 58 creates a new CKI site at serine61. The disruption of serine 58 should prevent phosphorylationat serine 61, which would result in the loss of both phosphorylationsites, which is consistent with our results. Based on sequenceanalysis, mutation at serine 61 would be expected to affect phosphorylationat only that site and not at serine 58, explaining why the S61Amutant retains ³³P incorporation. The above observations are consistent with ourresults. In addition, bacterially expressed M2-1 protein was shownto be phosphorylated twice by CKI on a fragment correspondingto amino acids 53 to 92, which contains the phosphorylation sitesdetermined by site-directed mutagenesis, serine 58 and serine61. A recent report concluded that threonine 56 and serine 58were the main phosphorylation sites in M2-1 (9). These workersanalyzed M2-1 phosphorylation in the context of a double mutantin which threonine 56 and serine 58 were both changed to alanine(9). The protein also contained an internal deletion betweenamino acids 110 and 166. This mutant lost 98% of its phosphorylationcompared to the parent protein. The result observed from the doublemutant can be attributed solely to the mutation at serine 58,because of its ability to affect the potential phosphorylationof serine 61. As shown in the results of this paper, the T56Asingle mutant is unaltered in its phosphorylation state comparedto the wt protein, and this mutation has no effect on M2-1 function.Therefore, threonine 56 does not substantially contribute to thephosphorylation of M2-1 or to its function. Our results show thatserines 58 and 61 are the major phosphorylation sites. It shouldbe noted that M2-1 may contain an additional minor phosphorylationsite, as the S58A and T56A S58A mutants both show very low levelsof ³³Pincorporation.

Mutation of the phosphorylated residues, serines 58 and 61, to alanine resulted in a decrease in the efficiency of M2-1 proteintranscriptional antitermination activity, as assayed by the effecton transcription of a subgenomic replicon containing the F/M2gene junction. Increasing the level of input mutant M2-1-encodingplasmids allowed a low level of increase in transcriptional antiterminationactivity, but never to a level equivalent to that seen with wtM2-1 protein, suggesting the mutant proteins are inefficient antiterminators.The defect in antitermination does not appear to be due to aninability to bind RNA, as the phosphorylation mutants coimmunoprecipitatedRNA as well as the wt protein. Rather, the defect may be in RNAbinding specificity or in the ability to function once bound toRNA. It is interesting that during an RS virus infection, theunphosphorylated form of M2-1 is the predominant form of the protein.This differs from conditions under which M2-1 is transfected byitself, where the phosphorylated form is predominant, an observationthat may suggest that control over the extent of M2-1 phosphorylationexists during infection. Previous analyses have indicated thatthe presence of other RS virus proteins, such as the P protein,affect the level of M2-1 phosphorylation (Hardy, unpublished)(9). There are numerous examples of prokaryotic and eukaryotictranscription factors that use phosphorylation as a means to positivelyor negatively control activity (18, 31). In addition, theM2-1 protein is not the only RS virus protein whose function istied to phosphorylation, as phosphorylation of the RS virus Pprotein increases its efficiency in transcription and replication(27, 33). However, it remains to be determined whether M2-1function during RS virus infection is regulated by phosphorylationor whether the different phosphoforms of M2-1 have additionalfunctions as yet undetermined. In addition, further work is necessaryand is under way to determine if the processivity activity ofM2-1 is also affected byphosphorylation.

The ability of M2-1 to coimmunoprecipitate RNA from transfected cells led to the discoveries that during infection M2-1 canassociate with RS virus mRNAs and that the previously observedinteraction between the M2-1 and N proteins in cotransfected cellswas mediated via RNA. The results from the M2-1-N interactionexperiment indicated that the M2-1 and N proteins were interactingby binding to the same RNA (Fig. 6), yet immunoprecipitation fromRS virus-infected cells with the N MAb showed that the N proteininteracted with genomic RNA, as expected for the nucleocapsidprotein (Fig. 5, lane 5), while the M2-1 MAb predominately coimmunoprecipitatedmRNA (Fig. 5, lane 3). The analysis of the M2-1-N interaction(Fig. 6) was performed in transfected cells and not in the contextof an RS virus infection, and it is likely that the M2-1 and Nproteins, like many other RNA binding proteins, were binding RNAspromiscuously in the absence of their natural substrates, possiblyby binding the mRNAs produced from the M2-1- and N-encoding plasmids,as they were the only RS virus RNAs present in thecells.

In separate work, Cuesta et al. also recently reported that M2-1 is an RNA binding protein (9). They concluded that theM2-1 protein bound specifically to the antigenomic leader sequenceof the RS virus RNA and nonspecifically to "long" RNAs. Our resultsshow that during RS virus infection, M2-1 interacts predominatelywith viral mRNAs, which do not contain the leader sequence. Clearly,further work is necessary to analyze the specificity of RNA bindingby M2-1 and to determine whether other viral proteins are involvedin determining the specificity of M2-1 interaction withRNA.

The observation that the M2-1 protein interacts with RNA is consistent with the fact that many proteins that function in transcriptionand contain zinc binding motifs also bind nucleic acids. M2-1protein contains a Cys3His1 zinc binding motif at its amino terminus.The best-described member of the Cys3His1 class of zinc fingersis tristetraprolin (TTP), an RNA binding protein whose function,like that of M2-1, is dependent upon the integrity of its Cys3His1motif. Mutation of a single zinc-coordinating residue in TTP resultsin a loss of RNA binding (22). It is interesting that the C7Smutant, which is defective in antitermination (15), is alsodefective in RNA binding, as assayed by immunoprecipitation (Fig.4A, lane3).

In conclusion, we have demonstrated that M2-1 is phosphorylated at serines 58 and 61. Phosphorylation is required for theefficient transcriptional function of M2-1, as mutation of serines58 and 61 results in a severe decrease of antitermination activity.We have also shown that M2-1 is associated with viral monocistronicand polycistronic mRNA during RS virus infection. Maintenanceof the Cys3His1 motif, but not phosphorylation, is required forinteraction with RNA. In addition, the interaction between theM2-1 and N proteins is mediated viaRNA.

	ACKNOWLEDGMENTS

We thank the members of the Wertz and Ball laboratories for their advice and constructive criticism, Richard Hardy for providingthe preliminary work for these studies, Xiaoling Tang for technicalsupport, and Lori Coward for performing the MALDI-TOFanalysis.

This work was supported by Public Health Service grant A120181 from the NIH to G.W.W. and Predoctoral Training in Cell andMolecular Biology grant 5T32GMZ8111 for support of T.L.C. Themass spectrometer was purchased with funds from an NIH SharedInstrumentation Grant (S10RR11329) and from a Howard Hughes MedicalInstitute infrastructure support grant to UAB. Operation of theShared Facility has been supported in part by an NCI Core ResearchSupport Grant to the UAB Comprehensive Cancer Center (P30 CA13148-27).

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Microbiology, University of Alabama School of Medicine, BBRB Box 17,Room 366, 845 19th St. South, Birmingham, AL 35294. Phone: (205)934-0877. Fax: (205) 934-1636. E-mail: gail_wertz{at}microbio.uab.edu.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Alansari, H., and L. N. Potgieter. 1994. Molecular cloning and sequence analysis of the phosphoprotein, nucleocapsid protein, matrix protein and 22K (M2) protein of the ovine respiratory syncytial virus. J. Gen. Virol. 75:3597-3601[Abstract/Free Full Text].

2. Barik, S. 1992. Transcription of human respiratory syncytial virus genome RNA in vitro: requirement of cellular factor(s). J. Virol. 66:6813-6818[Abstract/Free Full Text].

3. Collins, P. L., L. E. Dickens, A. Buckler-White, R. A. Olmsted, M. K. Spriggs, E. Camargo, and K. V. Coelingh. 1986. Nucleotide sequences for the gene junctions of human respiratory syncytial virus reveal distinctive features of intergenic structure and gene order. Proc. Natl. Acad. Sci. USA 83:4594-4598[Abstract/Free Full Text].

4. Collins, P. L., M. G. Hill, J. Cristina, and H. Grosfeld. 1996. Transcription elongation factor of respiratory syncytial virus, a nonsegmented negative-strand RNA virus. Proc. Natl. Acad. Sci. USA 93:81-85[Abstract/Free Full Text].

5. Collins, P. L., M. G. Hill, and P. R. Johnson. 1990. The two open reading frames of the 22K mRNA of human respiratory syncytial virus: sequence comparison of antigenic subgroups A and B and expression in vitro. J. Gen. Virol. 71:3015-3020[Abstract/Free Full Text].

6. Collins, P. L., Y. T. Huang, and G. W. Wertz. 1984. Identification of a tenth mRNA of respiratory syncytial virus and assignment of polypeptides to the 10 viral genes. J. Virol. 49:572-578[Abstract/Free Full Text].

7. Collins, P. L., and G. W. Wertz. 1983. cDNA cloning and transcriptional mapping of nine polyadenylylated RNAs encoded by the genome of human respiratory syncytial virus. Proc. Natl. Acad. Sci. USA 80:3208-3212[Abstract/Free Full Text].

8. Collins, P. L., and G. W. Wertz. 1985. The envelope-associated 22K protein of human respiratory syncytial virus: nucleotide sequence of the mRNA and a related polytranscript. J. Virol. 54:65-71[Abstract/Free Full Text].

9. Cuesta, I., X. Geng, A. Asenjo, and N. Villanueva. 2000. Structural phosphoprotein M2-1 of the human respiratory syncytial virus is an RNA binding protein. J. Virol. 74:9858-9867[Abstract/Free Full Text].

10. Dickens, L. E., P. L. Collins, and G. W. Wertz. 1984. Transcriptional mapping of human respiratory syncytial virus. J. Virol. 52:364-369[Abstract/Free Full Text].

11. Fearns, R., and P. L. Collins. 1999. Role of the M2-1 transcription antitermination protein of respiratory syncytial virus in sequential transcription. J. Virol. 73:5852-5864[Abstract/Free Full Text].

12. Garcia, J., B. Garcia-Barreno, A. Vivo, and J. A. Melero. 1993. Cytoplasmic inclusions of respiratory syncytial virus-infected cells: formation of inclusion bodies in transfected cells that coexpress the nucleoprotein, the phosphoprotein, and the 22K protein. Virology 195:243-247[CrossRef][Medline].

13. Grosfeld, H., M. G. Hill, and P. L. Collins. 1995. RNA replication by respiratory syncytial virus (RSV) is directed by the N, P, and L proteins; transcription also occurs under these conditions but requires RSV superinfection for efficient synthesis of full-length mRNA. J. Virol. 69:5677-5686[Abstract].

14. Hardy, R. W., S. B. Harmon, and G. W. Wertz. 1999. Diverse gene junctions of respiratory syncytial virus modulate the efficiency of transcription termination and respond differently to M2-mediated antitermination. J. Virol. 73:170-176[Abstract/Free Full Text].

15. Hardy, R. W., and G. W. Wertz. 2000. The Cys(3)-His(1) motif of the respiratory syncytial virus M2-1 protein is essential for protein function. J. Virol. 74:5880-5885[Abstract/Free Full Text].

16. Hardy, R. W., and G. W. Wertz. 1998. The product of the respiratory syncytial virus M2 gene ORF1 enhances readthrough of intergenic junctions during viral transcription. J. Virol. 72:520-526[Abstract/Free Full Text].

17. Harmon, S. B., A. G. Megaw, and G. W. Wertz. 2001. RNA sequences involved in transcriptional termination of respiratory syncytial virus. J. Virol. 75:36-44[Abstract/Free Full Text].

18. Hunter, T., and M. Karin. 1992. The regulation of transcription by phosphorylation. Cell 70:375-387[CrossRef][Medline].

19. Jacques, J. P., and D. Kolakofsky. 1991. Pseudo-templated transcription in prokaryotic and eukaryotic organisms. Genes Dev. 5:707-713[Free Full Text].

20. Kuo, L., R. Fearns, and P. L. Collins. 1997. Analysis of the gene start and gene end signals of human respiratory syncytial virus: quasi-templated initiation at position 1 of the encoded mRNA. J. Virol. 71:4944-4953[Abstract].

21. Kuo, L., H. Grosfeld, J. Cristina, M. G. Hill, and P. L. Collins. 1996. Effects of mutations in the gene-start and gene-end sequence motifs on transcription of monocistronic and dicistronic minigenomes of respiratory syncytial virus. J. Virol. 70:6892-6901[Abstract/Free Full Text].

22. Lai, W. S., E. Carballo, J. R. Strum, E. A. Kennington, R. S. Phillips, and P. J. Blackshear. 1999. Evidence that tristetraprolin binds to AU-rich elements and promotes the deadenylation and destabilization of tumor necrosis factor alpha mRNA. Mol. Cell. Biol. 19:4311-4323[Abstract/Free Full Text].

23. Lambert, D. M., J. Hambor, M. Diebold, and B. Galinski. 1988. Kinetics of synthesis and phosphorylation of respiratory syncytial virus polypeptides. J. Gen. Virol. 69:313-323[Abstract/Free Full Text].

24. Laskey, R. A. 1980. The use of intensifying screens or organic scintillators for visualizing radioactive molecules resolved by gel electrophoresis. Methods Enzymol. 65:363-371[Medline].

25. Liao, P. C., J. Leykam, P. C. Andrews, D. A. Gage, and J. Allison. 1994. An approach to locate phosphorylation sites in a phosphoprotein: mass mapping by combining specific enzymatic degradation with matrix-assisted laser desorption/ionization mass spectrometry. Anal. Biochem. 219:9-20[CrossRef][Medline].

26. Ling, R., A. J. Easton, and C. R. Pringle. 1992. Sequence analysis of the 22K, SH and G genes of turkey rhinotracheitis virus and their intergenic regions reveals a gene order different from that of other pneumoviruses. J. Gen. Virol. 73:1709-1715[Abstract/Free Full Text].

27. Mazumder, B., and S. Barik. 1994. Requirement of casein kinase II-mediated phosphorylation for the transcriptional activity of human respiratory syncytial viral phosphoprotein P: transdominant negative phenotype of phosphorylation-defective P mutants. Virology 205:104-111[CrossRef][Medline].

28. Pattnaik, A. K., and G. W. Wertz. 1990. Replication and amplification of defective interfering particle RNAs of vesicular stomatitis virus in cells expressing viral proteins from vectors containing cloned cDNAs. J. Virol. 64:2948-2957[Abstract/Free Full Text].

29. Pinna, L. A., and M. Ruzzene. 1996. How do protein kinases recognize their substrates? Biochim. Biophys. Acta 1314:191-225[Medline].

30. Routledge, E. G., M. M. Willcocks, L. Morgan, A. C. Samson, R. Scott, and G. L. Toms. 1987. Heterogeneity of the respiratory syncytial virus 22K protein revealed by Western blotting with monoclonal antibodies. J. Gen. Virol. 68:1209-1215[Abstract/Free Full Text]. (Erratum, 68:2272.)

31. Rutberg, B. 1997. Antitermination of transcription of catabolic operons. Mol. Microbiol. 23:413-421[CrossRef][Medline].

32. Stec, D. S., M. G. Hill, and P. L. Collins. 1991. Sequence analysis of the polymerase L gene of human respiratory syncytial virus and predicted phylogeny of nonsegmented negative-strand viruses. Virology 183:273-287[CrossRef][Medline].

33. Villanueva, N., R. Hardy, A. Asenjo, Q. Yu, and G. Wertz. 2000. The bulk of the phosphorylation of human respiratory syncytial virus phosphoprotein is not essential but modulates viral RNA transcription and replication. J. Gen. Virol. 81:129-133[Abstract/Free Full Text].

34. Wertz, G. W., and N. Davis. 1981. Characterization and mapping of RNase III cleavage sites in VSV genome RNA. Nucleic Acids Res. 9:6487-6503[Abstract/Free Full Text].

35. Yu, Q., P. J. Davis, T. D. Brown, and D. Cavanagh. 1992. Sequence and in vitro expression of the M2 gene of turkey rhinotracheitis pneumovirus. J. Gen. Virol. 73:1355-1363[Abstract/Free Full Text].

36. Yu, Q., R. W. Hardy, and G. W. Wertz. 1995. Functional cDNA clones of the human respiratory syncytial (RS) virus N, P, and L proteins support replication of RS virus genomic RNA analogs and define minimal trans-acting requirements for RNA replication. J. Virol. 69:2412-2419[Abstract].

37. Zamora, M., and S. K. Samal. 1992. Sequence analysis of M2 mRNA of bovine respiratory syncytial virus obtained from an F-M2 dicistronic mRNA suggests structural homology with that of human respiratory syncytial virus. J. Gen. Virol. 73:737-741[Abstract/Free Full Text].

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1.	Alansari, H., and L. N. Potgieter. 1994. Molecular cloning and sequence analysis of the phosphoprotein, nucleocapsid protein, matrix protein and 22K (M2) protein of the ovine respiratory syncytial virus. J. Gen. Virol. 75:3597-3601[Abstract/Free Full Text].
2.	Barik, S. 1992. Transcription of human respiratory syncytial virus genome RNA in vitro: requirement of cellular factor(s). J. Virol. 66:6813-6818[Abstract/Free Full Text].
3.	Collins, P. L., L. E. Dickens, A. Buckler-White, R. A. Olmsted, M. K. Spriggs, E. Camargo, and K. V. Coelingh. 1986. Nucleotide sequences for the gene junctions of human respiratory syncytial virus reveal distinctive features of intergenic structure and gene order. Proc. Natl. Acad. Sci. USA 83:4594-4598[Abstract/Free Full Text].
4.	Collins, P. L., M. G. Hill, J. Cristina, and H. Grosfeld. 1996. Transcription elongation factor of respiratory syncytial virus, a nonsegmented negative-strand RNA virus. Proc. Natl. Acad. Sci. USA 93:81-85[Abstract/Free Full Text].
5.	Collins, P. L., M. G. Hill, and P. R. Johnson. 1990. The two open reading frames of the 22K mRNA of human respiratory syncytial virus: sequence comparison of antigenic subgroups A and B and expression in vitro. J. Gen. Virol. 71:3015-3020[Abstract/Free Full Text].
6.	Collins, P. L., Y. T. Huang, and G. W. Wertz. 1984. Identification of a tenth mRNA of respiratory syncytial virus and assignment of polypeptides to the 10 viral genes. J. Virol. 49:572-578[Abstract/Free Full Text].
7.	Collins, P. L., and G. W. Wertz. 1983. cDNA cloning and transcriptional mapping of nine polyadenylylated RNAs encoded by the genome of human respiratory syncytial virus. Proc. Natl. Acad. Sci. USA 80:3208-3212[Abstract/Free Full Text].
8.	Collins, P. L., and G. W. Wertz. 1985. The envelope-associated 22K protein of human respiratory syncytial virus: nucleotide sequence of the mRNA and a related polytranscript. J. Virol. 54:65-71[Abstract/Free Full Text].
9.	Cuesta, I., X. Geng, A. Asenjo, and N. Villanueva. 2000. Structural phosphoprotein M2-1 of the human respiratory syncytial virus is an RNA binding protein. J. Virol. 74:9858-9867[Abstract/Free Full Text].
10.	Dickens, L. E., P. L. Collins, and G. W. Wertz. 1984. Transcriptional mapping of human respiratory syncytial virus. J. Virol. 52:364-369[Abstract/Free Full Text].
11.	Fearns, R., and P. L. Collins. 1999. Role of the M2-1 transcription antitermination protein of respiratory syncytial virus in sequential transcription. J. Virol. 73:5852-5864[Abstract/Free Full Text].
12.	Garcia, J., B. Garcia-Barreno, A. Vivo, and J. A. Melero. 1993. Cytoplasmic inclusions of respiratory syncytial virus-infected cells: formation of inclusion bodies in transfected cells that coexpress the nucleoprotein, the phosphoprotein, and the 22K protein. Virology 195:243-247[CrossRef][Medline].
13.	Grosfeld, H., M. G. Hill, and P. L. Collins. 1995. RNA replication by respiratory syncytial virus (RSV) is directed by the N, P, and L proteins; transcription also occurs under these conditions but requires RSV superinfection for efficient synthesis of full-length mRNA. J. Virol. 69:5677-5686[Abstract].
14.	Hardy, R. W., S. B. Harmon, and G. W. Wertz. 1999. Diverse gene junctions of respiratory syncytial virus modulate the efficiency of transcription termination and respond differently to M2-mediated antitermination. J. Virol. 73:170-176[Abstract/Free Full Text].
15.	Hardy, R. W., and G. W. Wertz. 2000. The Cys(3)-His(1) motif of the respiratory syncytial virus M2-1 protein is essential for protein function. J. Virol. 74:5880-5885[Abstract/Free Full Text].
16.	Hardy, R. W., and G. W. Wertz. 1998. The product of the respiratory syncytial virus M2 gene ORF1 enhances readthrough of intergenic junctions during viral transcription. J. Virol. 72:520-526[Abstract/Free Full Text].
17.	Harmon, S. B., A. G. Megaw, and G. W. Wertz. 2001. RNA sequences involved in transcriptional termination of respiratory syncytial virus. J. Virol. 75:36-44[Abstract/Free Full Text].
18.	Hunter, T., and M. Karin. 1992. The regulation of transcription by phosphorylation. Cell 70:375-387[CrossRef][Medline].
19.	Jacques, J. P., and D. Kolakofsky. 1991. Pseudo-templated transcription in prokaryotic and eukaryotic organisms. Genes Dev. 5:707-713[Free Full Text].
20.	Kuo, L., R. Fearns, and P. L. Collins. 1997. Analysis of the gene start and gene end signals of human respiratory syncytial virus: quasi-templated initiation at position 1 of the encoded mRNA. J. Virol. 71:4944-4953[Abstract].
21.	Kuo, L., H. Grosfeld, J. Cristina, M. G. Hill, and P. L. Collins. 1996. Effects of mutations in the gene-start and gene-end sequence motifs on transcription of monocistronic and dicistronic minigenomes of respiratory syncytial virus. J. Virol. 70:6892-6901[Abstract/Free Full Text].
22.	Lai, W. S., E. Carballo, J. R. Strum, E. A. Kennington, R. S. Phillips, and P. J. Blackshear. 1999. Evidence that tristetraprolin binds to AU-rich elements and promotes the deadenylation and destabilization of tumor necrosis factor alpha mRNA. Mol. Cell. Biol. 19:4311-4323[Abstract/Free Full Text].
23.	Lambert, D. M., J. Hambor, M. Diebold, and B. Galinski. 1988. Kinetics of synthesis and phosphorylation of respiratory syncytial virus polypeptides. J. Gen. Virol. 69:313-323[Abstract/Free Full Text].
24.	Laskey, R. A. 1980. The use of intensifying screens or organic scintillators for visualizing radioactive molecules resolved by gel electrophoresis. Methods Enzymol. 65:363-371[Medline].
25.	Liao, P. C., J. Leykam, P. C. Andrews, D. A. Gage, and J. Allison. 1994. An approach to locate phosphorylation sites in a phosphoprotein: mass mapping by combining specific enzymatic degradation with matrix-assisted laser desorption/ionization mass spectrometry. Anal. Biochem. 219:9-20[CrossRef][Medline].
26.	Ling, R., A. J. Easton, and C. R. Pringle. 1992. Sequence analysis of the 22K, SH and G genes of turkey rhinotracheitis virus and their intergenic regions reveals a gene order different from that of other pneumoviruses. J. Gen. Virol. 73:1709-1715[Abstract/Free Full Text].
27.	Mazumder, B., and S. Barik. 1994. Requirement of casein kinase II-mediated phosphorylation for the transcriptional activity of human respiratory syncytial viral phosphoprotein P: transdominant negative phenotype of phosphorylation-defective P mutants. Virology 205:104-111[CrossRef][Medline].
28.	Pattnaik, A. K., and G. W. Wertz. 1990. Replication and amplification of defective interfering particle RNAs of vesicular stomatitis virus in cells expressing viral proteins from vectors containing cloned cDNAs. J. Virol. 64:2948-2957[Abstract/Free Full Text].
29.	Pinna, L. A., and M. Ruzzene. 1996. How do protein kinases recognize their substrates? Biochim. Biophys. Acta 1314:191-225[Medline].
30.	Routledge, E. G., M. M. Willcocks, L. Morgan, A. C. Samson, R. Scott, and G. L. Toms. 1987. Heterogeneity of the respiratory syncytial virus 22K protein revealed by Western blotting with monoclonal antibodies. J. Gen. Virol. 68:1209-1215[Abstract/Free Full Text]. (Erratum, 68:2272.)
31.	Rutberg, B. 1997. Antitermination of transcription of catabolic operons. Mol. Microbiol. 23:413-421[CrossRef][Medline].
32.	Stec, D. S., M. G. Hill, and P. L. Collins. 1991. Sequence analysis of the polymerase L gene of human respiratory syncytial virus and predicted phylogeny of nonsegmented negative-strand viruses. Virology 183:273-287[CrossRef][Medline].
33.	Villanueva, N., R. Hardy, A. Asenjo, Q. Yu, and G. Wertz. 2000. The bulk of the phosphorylation of human respiratory syncytial virus phosphoprotein is not essential but modulates viral RNA transcription and replication. J. Gen. Virol. 81:129-133[Abstract/Free Full Text].
34.	Wertz, G. W., and N. Davis. 1981. Characterization and mapping of RNase III cleavage sites in VSV genome RNA. Nucleic Acids Res. 9:6487-6503[Abstract/Free Full Text].
35.	Yu, Q., P. J. Davis, T. D. Brown, and D. Cavanagh. 1992. Sequence and in vitro expression of the M2 gene of turkey rhinotracheitis pneumovirus. J. Gen. Virol. 73:1355-1363[Abstract/Free Full Text].
36.	Yu, Q., R. W. Hardy, and G. W. Wertz. 1995. Functional cDNA clones of the human respiratory syncytial (RS) virus N, P, and L proteins support replication of RS virus genomic RNA analogs and define minimal trans-acting requirements for RNA replication. J. Virol. 69:2412-2419[Abstract].
37.	Zamora, M., and S. K. Samal. 1992. Sequence analysis of M2 mRNA of bovine respiratory syncytial virus obtained from an F-M2 dicistronic mRNA suggests structural homology with that of human respiratory syncytial virus. J. Gen. Virol. 73:737-741[Abstract/Free Full Text].