Critical Residues for GTP Methylation and Formation of the Covalent m7GMP-Enzyme Intermediate in the Capping Enzyme Domain of Bamboo Mosaic Virus

Open reading frame 1 of Bamboo mosaic virus (BaMV), a Potexvirusin the alphavirus-like superfamily, encodes a 155-kDa replicaseresponsible for the formation of the 5' cap structure and replicationof the viral RNA genome. The N-terminal domain of the viralreplicase functions as an mRNA capping enzyme, which exhibitsboth GTP methyltransferase and S-adenosylmethionine (AdoMet)-dependentguanylyltransferase activities. We mutated each of the fourconserved amino acids among the capping enzymes of members withinalphavirus-like superfamily and a dozen of other residues togain insight into the structure-function relationship of theviral enzyme. The mutant enzymes were purified and subsequentlycharacterized. H68A, the mutant enzyme bearing a substitutionat the conserved histidine residue, has an $~$ 10-fold increasein GTP methyltransferase activity but completely loses the abilityto form the covalent m⁷GMP-enzyme intermediate. High-pressureliquid chromatography analysis confirmed the production of m⁷GTPby the GTP methyltransferase activity of H68A. Furthermore,the produced m⁷GTP sustained the formation of the m⁷GMP-enzymeintermediate for the wild-type enzyme in the presence of S-adenosylhomocysteine(AdoHcy), suggesting that the previously observed AdoMet-dependentguanylation of the enzyme using GTP results from reactions ofGTP methylation and subsequently guanylation of the enzyme usingm⁷GTP. Mutations occurred at the other three conserved residues(D122, R125, and Y213), and H66 resulted in abolition of activitiesfor both GTP methylation and formation of the covalent m⁷GMP-enzymeintermediate. Mutations of amino acids such as K121, C234, D310,W312, R316, K344, W406, and K409 decreased both activities byvarious degrees, and the extents of mutational effects followsimilar trends. The affinity to AdoMet of the various BaMV cappingenzymes, except H68A, was found in good correlations with notonly the magnitude of GTP methyltransferase activity but alsothe capability of forming the m⁷GMP-enzyme intermediate. Takentogether with the AdoHcy dependence of guanylation of the enzymeusing m⁷GTP, a basic working mechanism, with the contents ofcritical roles played by the binding of AdoMet/AdoHcy, of theBaMV capping enzyme is proposed and discussed.

INTRODUCTION

Top

Introduction

Bamboo mosaic virus (BaMV), a member of the Potexvirus group,has a positive-strand RNA genome ( $~$ 6.4 kb) with a 5' m⁷G(5')ppp(5')Gcap structure and a 3' poly(A) tail (16). The 4.1-kb open readingframe 1 of BaMV encodes a 155-kDa polypeptide that has beenpostulated to be involved in the replication of the viral genomeand the formation of cap structure at the 5' ends of viral transcripts.Recently, biochemical studies demonstrated that the N-terminal442 amino acids of the 155-kDa viral protein possess both enzymaticactivities of GTP methyltransferase and S-adenosylmethionine(AdoMet)-dependent guanylyltransferase (13, 14). Residues 514to 892 contain nucleoside triphosphate-binding and helicase-likemotifs, and a recombinant protein containing this region notonly has nucleoside triphosphatase activities but also has anRNA 5'-triphosphatase activity that specifically cleaves the ${gamma}$ phosphate off from the 5' end of nascent RNA (14). The C-terminal472 amino acids specifically recognize the 3'-untranslated regionof BaMV genome (8) and can perform RNA-dependent RNA synthesis(12). According to these observations, formation of the 5' capin RNA transcripts of BaMV requires the sequential actions ofthe methyltransferase to transfer a methyl group from AdoMetto N7 position of GTP, followed by the guanylyltransferase activityto transfer the m⁷GMP moiety of the m⁷GTP to the 5'-diphosphateterminus of the viral RNA. Cap formation by BaMV is thereforedistinct from that of eukaryotic cellular systems in which the5'-diphosphate end of RNA is capped first by GTP:mRNA guanylyltransferase,and then the G(5')ppp(5')G cap of RNA is methylated by RNA (guanine-N7)methyltransferase (22, 25). The BaMV capping apparatus is alsocompletely different from that of eukaryotic cellular systemswith regard to protein primary sequence and genetic organization.The RNA 5'-triphosphatase activity of BaMV is recruited fromthe central helicase-like domain, and both the methyltransferaseand guanylyltransferase activities are executed by a singlecapping enzyme domain located at the N terminus of the 155-kDaviral protein. In contrast, cellular guanylyltransferase andmethyltransferase, from fungi, plants, or metazoans, are encodedby separate polypeptides, and each of the enzymes is structurallyconserved during evolution (26).

The order of the cap formation found in BaMV has been demonstratedin other members of the alphavirus-like superfamily, such asSemliki Forest virus (1, 10), Hepatitis E virus (20), Tobaccomosaic virus (21), and Brome mosaic virus (3, 9). Therefore,it is likely that the capping enzymes within the alphavirus-likesuperfamily have the same catalytic mechanism in spite of thefact that only limited amino acid identities are conserved (24).Elucidating the structure-function relationship of this classof capping enzyme is necessary for completely understandingthe viral replication and translation. As a first step towardunderstanding the capping enzyme domain of BaMV, site-directedmutagenesis was performed, and the roles of several key aminoacid residues are discussed here.

MATERIALS AND METHODS

Top

Materials and Methods

Chemicals. General chemicals and nucleotides such as GTP, GDP, GMP, m⁷GTP,m⁷GDP, S-adenosylhomocysteine (AdoHcy), and guanylylimidodiphosphate(GIDP) were purchased from Sigma. Guanosine-5'-[( ${alpha}$ ,ß)-methyleno]triphosphate(GpCpp), and guanosine-5'-[(ß, ${gamma}$ )-methyleno]triphosphate(GppCp)were from Jena Bioscience, whereas AdoMet was from BoehringerMannheim. Ado[methyl-³H]Met and [ ${alpha}$ -³²P]GTP are products of NEN.[ ${alpha}$ -³²P]m⁷GTP, synthesized by H68A mutant in the presence of [ ${alpha}$ -³²P]GTPand AdoMet, were purified by high-pressure liquid chromatography(HPLC) by using an anion exchanger (SAX column, 250 by 4.6 mm)from Phenomenex. Elution was performed at a flow rate of 1 mlmin^-1 with a 26-min linear gradient (40 to 500 mM) of KH₂PO₄(pH 5.5), with detection at 254 nm.

Plasmids. The BaMV capping enzyme domain with a C-terminal hexahistidinetag was produced in Saccharomyces cerevisiae harboring expressionvector pYEB3H as described previously (14). Expression vectorsfor producing mutant capping enzymes were generated from pYEB3Hby a PCR-based method (14) in which a pair of 5'-phosphorylateddivergent primer with one of the primers containing mutagenicnucleotides at its 5' end was used in amplification reactions.The desired mutations were confirmed by nucleotide sequencing.

Protein expression and purification. The expression and purification of the BaMV capping enzyme wasdescribed previously (14). Briefly, the viral proteins fromthe membrane fraction of the recombinant yeast cells, whichhad been cultured in a galactose-containing medium, were solubilizedin Sarkosyl buffer (50 mM Tris-HCl [pH 8.0], 150 mM NaCl, 5mM ß-2-mercaptoethanol [ß-2ME], 0.3% SarkosylNL30, and 10% glycerol). The protein was then purified withNi²⁺-nitrilotriacetic acid resin and finally dialyzed in Sarkosylbuffer. Protein concentrations were detemined by comparing theintensity of the Coomassie blue-stained protein band followingsodium dodecyl sulfate-12% polyacrylamide gel electrophoresis(SDS-12% PAGE) with that of bovine serum albumin by using animaging densitometer.

Activity assay. Formation of the covalent m⁷GMP-enzyme intermediate was usedas an indication of guanylyltransferase activity. The standardreaction was carried out at 30°C for 80 min in a 20-µlsolution that contained 0.1 µg of the viral enzyme, 0.3µM [ ${alpha}$ -³²P]GTP (3,000 Ci/mmol), 50 mM Tris (pH 8.0), 5 mMdithiothreitol, 2 mM MgCl_2, 10 mM KCl, 1.2% n-octyl-ß-D-glucopyranoside,and 100 µM AdoMet, unless otherwise stated. The reactionwas stopped by adding SDS to a final concentration of 2%, followedby 3 min of boiling. The reaction mixture was resolved by SDS-10%PAGE, and radiolabeled proteins were visualized by autoradiographyor using a phosphorimager. The fraction of radiolabeled proteinmolecules was quantified as pixels against a standard curveof predetermined amounts of [ ${alpha}$ -³²P]GTP versus their respectivepixels determined by using a phosphorimager and by using theassumption that a protein molecule can be labeled only by onemolecule of m⁷GMP. The assay conditions for AdoHcy-dependentguanylation of the enzyme using m⁷GTP was basically same asthat described above, except that AdoMet was replaced by AdoHcyand [ ${alpha}$ -³²P]GTP was replaced by [ ${alpha}$ -³²P]m⁷GTP. Methyltransferaseactivity was measured by the monitoring the transfer of [³H]methylfrom Ado[methyl-³H]Met to methyl acceptors (15). Reaction wascarried out at 30°C for 30 min in a 50-µl solutionthat contained 0.5 µg of the viral enzyme, 37 mM Tris(pH 8.0), 110 mM NaCl, 3.7 mM ß-2ME, 1.2% n-octyl-ß-D-glucopyranoside,0.22% Sarkosyl NL30, 7.4% glycerol, 2.75 µCi of Ado[methyl-³H]Met(70 Ci/mmol), and 10 mM methyl acceptor. SDS (12 µl of10% solution) and 60 µl of 2 M NH₄Cl were added to terminatethe reactions, and the mixture were extracted with three 250-µlvolumes of phenol. A 100-µl aliquot of the aqueous phasewas then mixed with 5 ml of scintillation cocktail solution,and the amount of the radiolabeled acceptor was determined byscintillation counting.

UV-cross-linking of Ado[methyl-³H]Met to the viral enzymes. The UV cross-linking reaction was adapted from that of Luongoet al. (17) and performed by irradiating a 20-µl solutionon ice that contained 0.15 µg of the viral enzyme, 2.75µCi of S-Ado[methyl-³H]Met (70 Ci/mmol), 25 mM Tris (pH8.0), 75 mM NaCl, 2.5 mM ß-2ME, 0.15% Sarkosyl NL30,5% glycerol, 2 mM EDTA, and 2 mM dithiothreitol by using a single15-W germicidal UV lamp held at a distance of 10 cm for 30 min.The resulting products were analyzed by SDS-10% PAGE and visualizedby fluorography. [ ${gamma}$ -³²P]GTP or [ ${alpha}$ -³²P]GTP, instead of S-Ado[methyl-³H]Met,was used in the reaction buffer for GTP-binding assay, and theresults were visualized by autoradiography.

RESULTS

Top

Results

Mutation of the capping enzyme domain of BaMV replicase. Previous studies demonstrated that the N-terminal 442 aminoacids of the BaMV replicase, expressed in S. cerevesiae, exhibitedboth GTP methyltransferase and AdoMet-dependent guanylyltransferaseactivities (13, 14). The sequence of capped mRNA formation inBaMV was proposed to be: (i) the methylation of GTP; (ii) formationof a covalent m⁷GMP-enzyme intermediate; and (iii) transguanylationof m⁷GMP to the 5' end of diphosphate RNA from the covalentintermediate (14). In the present study, we used mutationalanalysis to define amino acid residues critical for the BaMVcapping enzyme activities. The residues indicated in Fig. 1were mutated to alanine. They contain amino acids conservedin the methyltransferase domain among members of alphavirus-likesuperfamily: H68, D122, R125, and Y213. Lysine residues at positions121, 218, 344, and 389 were also selected as targets becausethey are within sequences similar to KxDG and KDLS motifs, whichmay, respectively, link covalently to GMP during guanyl transferby mRNA capping enzymes of vaccinia virus (23), Chlorella virus(7), and S. cerevisiae (6) or the mRNA capping enzyme in reovirus(18, 19). In addition, we mutated the sole cysteine residue,C234, in the BaMV capping enzyme, since the palmitoylated cysteineresidues in the Semliki Forest virus capping enzyme enhancethe binding of the protein to membrane (11). Several tryptophans(W312, W377, and W406) were also mutated in the present studybecause they may participate in AdoMet binding as in the caseof cytosine-DNA methyltransferase (5).

View larger version (27K):
[in this window]
[in a new window]
FIG. 1. Primary and predicted secondary structures of the BaMV capping enzyme. The secondary structures were predicted at the PSIPRED Protein Structure Prediction Server (http://bioinf.cs.ucl.ac.uk/psipred/psiform.html). The rectangle and arrow symbolize the ${alpha}$ -helix and ß-strand, respectively. Amino acid sequences encompassing the conserved residues of several capping enzyme domains of viruses within alphavirus-like superfamily are aligned. BaMV, BMV, TMV, HEV, SFV, and AMV are abbreviations for Bamboo mosaic virus, Brome mosaic virus, Tobacco mosaic virus, Hepatitis E virus, Semliki Forest virus, and Alfalfa mosaic virus, respectively. The residues denoted by asterisk were subjected to mutational analysis in the present study.

All proteins were purified based on a previously defined protocol,which includes steps of ultracentrifugation, detergent extraction,and metal-affinity chromatography (14) (Fig. 2A). The minorprotein band immediately below the major band resulted fromthe degraded form of the viral enzyme according to Western blottinganalysis (data not shown). All mutant proteins, including C234A,retained association with yeast membranes as strongly as thewild-type protein in a manner resistant to sequential extractionwith alkaline (Na₂CO₃, pH 11.8) and high-salt (1 M NaCl) buffers(data not shown). Membrane association thus does not requireC234. We also found no indication of palmitoylation of the BaMVcapping enzyme when the recombinant yeast cells were grown inmedium containing [³H]palmitic acid (data not shown).

View larger version (35K):
[in this window]
[in a new window]
FIG. 2. Protein purification and formation of the covalent m⁷GMP-enzyme intermediate. (A) The yeast-expressed viral capping enzymes were purified through steps of membrane separation, ionic detergent extraction, and metal affinity chromatography as described in Materials and Methods. Each of the purified enzymes (0.2 µg) was resolved on SDS-PAGE (10% acrylamide) and stained by Coomassie blue. (B) The formation of the m⁷GMP-enzyme intermediate was assayed by incubating the various enzymes with [ ${alpha}$ -³²P]GTP and AdoMet as described in Materials and Methods.

Mutational effects on the formation of the covalent m⁷GMP-enzyme intermediate with GTP and AdoMet. Formation of the covalent intermediate was examined by incubatingthe enzymes with [ ${alpha}$ -³²P]GTP in the presence of AdoMet. It shouldbe noted that GTP methyltransferase activity might be a prerequisitefor the formation of the covalent m⁷GMP-enzyme intermediateunder the reaction conditions. The apparent effects of mutationscan be roughly grouped into three categories (Fig. 2B): (i)abolishment of the activity (in proteins with mutations at residueH66, H68, D122, R125, or Y213), (ii) decreases of activity invarious extents (in proteins with mutation at K121, C234, D310,W312, R316, K344, W406, or K409), and (iii) minor effects onthe activity (mutation at K218, W377, or K389).

The amounts of radiolabeled protein were quantified over an80-min period to carefully calculate the formation rate of thecovalent m⁷GMP-protein intermediate. The accumulation of radiolabeledwild-type protein increased linearly throughout the reaction,with a total yield of 0.3% of the input protein in an hour period(Fig. 3). The rates of mutant proteins were determined as wasthe case in wild type (Fig. 4A), and the relative activitiesof various BaMV capping enzymes are illustrated in Fig. 4B andalso shown in Table 1. Mutation at any of the conserved residuesfound in alphaviral capping enzymes (H68, D122, R125, or Y213)or at the nonconserved residue H66 completely inactivated theformation of covalent intermediate. Mutation at W406 remained $~$ 1% activity of the wild type, whereas the activity for thosemutations at K218, K409, R316, W312, C234, K344, K121, or D310decreased from $~$ 2- to 20-fold. Mutations at W377 or K389 didnot have obvious effects.

View larger version (24K):
[in this window]
[in a new window]
FIG. 3. Time course of the formation of the covalent m⁷GMP-enzyme intermediate of the wild-type enzyme. The activity assays were carried out at 30°C by incubating the wild-type enzyme with [ ${alpha}$ -³²P]GTP and AdoMet for various times as described in Materials and Methods. (A) The reaction products were analyzed by SDS-PAGE (on 10% acrylamide), followed by autoradiography. (B) The amount of [ ${alpha}$ -³²P]GMP linked to enzyme was quantified according to a standard curve of predetermined amounts of [ ${alpha}$ -³²P]GTP versus their respective pixels by phosphorimager. The molar ratios of protein molecule that got radiolabeled are indicated in the ordinate, and the reaction times are indicated in the abscissa.

View larger version (30K):
[in this window]
[in a new window]
FIG. 4. Effects of mutations on the formation of the covalent m⁷GMP-enzyme intermediate and the AdoMet-binding ability. (A) The reaction rates of guanylation of the enzymes in the presence of [ ${alpha}$ -³²P]GTP and AdoMet were determined from time course studies. The data of H66A, H68A, D122A, R125A, and Y213A are omitted because of their disabilities. (B) The relative activities of various mutants compared to the wild type are illustrated. The data are means of three independent experiments. (C) The binding strength of various BaMV enzymes to AdoMet was assayed by a UV cross-linking reaction as described in Materials and Methods.

View this table:
[in this window]
[in a new window]
TABLE 1. Mutational effects on GTP methylation, guanylation of the protein, and AdoMet-binding ability

The binding activity of mutant proteins to [ ${gamma}$ -³²P]GTP, [ ${alpha}$ -³²P]GTP,or Ado[methyl-³H]Met were analyzed by UV cross-linking experiments.The results for GTP-binding ability are as yet unavailable,despite extensive efforts. The presumed effects on AdoMet bindingappear to correlate roughly with the rates of forming the m⁷GMP-enzymeintermediate (Fig. 4C and Table 1). For instance, no obviousAdoMet binding could be detected on mutants incapable of formingthe covalent intermediate such as H66A, D122A, R125A, and Y213A.An exception to this is the protein H68A, which binds AdoMetin a similar strength as the wild type.

Effects of mutations on methyltransferase activity. The methyltransferase activities of the various recombinantBaMV proteins were determined by the transfer of ³H-methyl groupfrom Ado[methyl-³H]Met to GTP (Fig. 5). Mutations at H66, D122,R125, or Y213 resulted in barely detectable activities, whereasmutations at K218, K389, or W377 had activities comparable tothat of wild type. Mutant proteins with intermediate GTP methyltransferaseactivities exhibited a trend that correlated well with theirabilities on formation of the covalent m⁷GMP-protein intermediate(K409A > R316A > W312A > C234A > K344A > W406A ${approx}$ D310A) (Fig. 4 and 5).

View larger version (15K):
[in this window]
[in a new window]
FIG. 5. Effects of mutations on the GTP methyltransferase activity. The activity of transferring a methyl group from AdoMet to GTP was assayed as described in Materials and Methods. The activity of the wild type (WT) (5,500 ± 260 cpm) against background (1,900 ± 250 cpm) is referred to as 100% activity. The data are means of three independent experiments.

The H68A mutant is interesting in that it had an $~$ 10-fold increasein GTP methyltransferase activity (Fig. 5), although it wasunable to form the covalent m⁷GMP-protein intermediate (Fig.2 and 4). The increase of the apparent GTP methyltransferaseactivity of H68A may be attributed to an increase of the activityitself and/or an accumulation of m⁷GTP due to an inability ofH68A to carry out the next transguanylation reaction. The specificityof methyl acceptors catalyzed by H68A was investigated (Fig.6). Similar to wild type, H68A preferred to use GTP and itsnonhydrolyzable analogues (GIDP, GpCpp, and GppCpp) as methylacceptors (Fig. 6). Other ribo- and deoxyribonucleotides, includingdGTP, were poor substrates. We noted that H68A and the wild-typeprotein had similar substrate preferences for methylation, withH68A being more active with all of the usable substrates. Thegreater activities of H68A than the wild type on methylatingGIDP, GpCpp, and GppCp suggest that the methyltransferase activityof H68A actually increased.

View larger version (16K):
[in this window]
[in a new window]
FIG. 6. Substrate specificity of the methyltransferase activity. Various nucleotide analogs of GTP were used as acceptors of methyl group under the reaction conditions of methyltransferase as described in Materials and Methods. GIDP, GpCpp, and GppCp are nonhydrolyzable analogues of GTP. The data in the figure are results after subtraction of the backgrounds (1,900 ± 250 cpm). Bars: ${square}$ , wild-type enzyme; , H68A. The data are means of three independent experiments.

Identification of m⁷GTP from the reaction products of H68A. The increase of GTP methytransferaes activity of H68A promptedus to analyze the products of reactions with [ ${alpha}$ -³²P]GTP and AdoMetas substrates. Abundant products of H68A migrated to the sameposition in a thin-layer chromatograph, as did m⁷GTP (Fig. 7).The amount of this product increased with the reaction timesof up to 120 min (Fig. 8A). The percentage of conversion from[ ${alpha}$ -³²P]GTP to [ ${alpha}$ -³²P]m⁷GTP was determined by counting the radioactivitiesof the respective spots with a scintillation counter, and theresult shows 50% of GTP being transformed to m⁷GTP in 2 h (Fig.8B). The production of m⁷GTP depended on the presence of AdoMetbut was largely unaffected by the presence of 5 mM EDTA anddid not require exogenously provided Mg²⁺ (Fig. 8C). The identityof m⁷GTP was confirmed by HPLC analysis by using an anion-exchangecolumn (SAX; Phenomenex). The retention time (19 min) was thesame as that of the m⁷GTP standard (Fig. 9), suggesting thatH68A did indeed produce m⁷GTP.

View larger version (72K):
[in this window]
[in a new window]
FIG. 7. Product analysis of the reactions containing various BaMV capping enzymes, [ ${alpha}$ -³²P]GTP, and AdoMet by TLC. Reactions were based on a standard assay for the formation of the covalent m⁷GMP-enzyme intermediate as described in Materials and Methods. At the ends, proteins were removed by phenol-chloroform extraction, and products in the aqueous phase were spotted onto a polyethyleneimine-cellulose TLC plate, developed with 1.2 M LiCl₂, and visualized by autoradiography. The nucleotide standards were visualized by UV (254 nm) illumination, and arrows indicate their migration positions.

View larger version (17K):
[in this window]
[in a new window]
FIG. 8. Production of m⁷GTP by H68A. (A) Reactions containing H68A, [ ${alpha}$ -³²P]GTP, and AdoMet were carried out for various times under standard assay conditions for the formation of the covalent m⁷GMP-enzyme intermediate. The reaction products were analyzed by TLC. (B) The fraction of conversion was determined by comparing the amounts of [ ${alpha}$ -³²P]m⁷GTP produced with that of residual [ ${alpha}$ -³²P]GTP. (C) AdoMet, AdoHcy, MgCl₂, and EDTA were included at different combinations, as indicated in the reaction mixture. The final concentrations of AdoMet and AdoHcy were 100 µM, whereas Mg²⁺ and EDTA, where present, were at 5 mM. Arrows indicate the migration positions of standards m⁷GTP, GDP, and GTP on the TLC plate.

View larger version (24K):
[in this window]
[in a new window]
FIG. 9. Separation of the reaction products of H68A by HPLC. The reaction of H68A with [ ${alpha}$ -³²P]GTP and AdoMet and the operation conditions of HPLC were as described in Materials and Methods. (A) Elution profile of a mixture of m⁷GTP and m⁷GDP standards. (B) Elution profile of the reaction products of H68A. To obtain enough m⁷GTP for UV detection, the reaction products for HPLC analysis were a mixture of reactions with 0.3 µM [ ${alpha}$ -³²P]GTP and 0.1 mM AdoMet and with 1 mM GTP and 1 mM AdoMet. The solid line follows the absorption of 254 nm, whereas the dotted line denotes radioactivity. (C) The eluants after HPLC separation were examined by TLC. Arrows on the left side of the TLC plate indicate the migration positions of m⁷GTP and GTP standards.

Mutational effects on the formation of the covalent m⁷GMP-enzyme intermediate with m⁷GTP and AdoHcy. In the proposed model of mRNA capped pathway in BaMV, m⁷GTPis first formed by the GTP methyltransferase activity, and thenthe m⁷GMP portion of m⁷GTP is transferred by guanylyltransferaseactivity to the 5' end of diphosphate RNA via a covalent intermediateof enzyme and m⁷GMP. According to this model, the BaMV cappingenzyme could use m⁷GTP directly for forming the cap structure.This hypothesis was tested by incubating the wild-type enzymewith [ ${alpha}$ -³²P]m⁷GTP purified from the reaction products of H68Aby HPLC as described above. The covalent intermediate was observedin a reaction that required AdoHcy and used m⁷GTP as the substrate(Fig. 10, lane 2). AdoMet could not replace AdoHcy in this particularprotein guanylation reaction (Fig. 10, lane 1). m⁷GTP and GTPdecreased the reaction (Fig. 10, lanes 3 and 4) presumably bycompeting for access to the active site. The requirement ofAdoHcy for the formation of the covalent intermediate when m⁷GTPwas used as the substrate raised a question as to whether AdoMetand GTP could be formed during the reaction by AdoHcy acceptinga methyl group from m⁷GTP. We did not observe such a reversereaction by thin-layer chromatography (TLC) analysis of thereaction mixture of the wild-type capping enzyme, [ ${alpha}$ -³²P]m⁷GTP,and AdoHcy (data not shown). Therefore, the AdoHcy-dependentguanylation of the enzyme using m⁷GTP might represent the firsthalf reaction of m⁷GTP guanylyltransferase of the BaMV cappingenzyme following the catalysis of m⁷GTP formation. Since theformation of the covalent m⁷GMP-enzyme intermediate could beassayed directly with m⁷GTP as the substrate, mutant enzymesthat had impaired activity of forming the covalent intermediateusing GTP and AdoMet were incubated with [ ${alpha}$ -³²P]m⁷GTP in thepresence of AdoHcy to determine whether the impairments resultedfrom defects of GTP methylation or transguanylation of m⁷GMPfrom m⁷GTP to the enzyme. The proteins with mutation at H66,H68, D122, R125, or Y213 were unable to form the covalent complexin the presence of m⁷GTP and AdoHcy (data not shown). Mutationsof other tested residues reduced the activity of forming thecovalent intermediate, and the adversely affected degree wasin the order of K121 > W406 > K344, D310 > C234 >W312, R316 > K218 (Fig. 11 and Table 1), which was roughlycomparable to the adverse effects on GTP methyltransferase activity.

View larger version (35K):
[in this window]
[in a new window]
FIG. 10. Reaction conditions for the formation of the covalent m⁷GMP-enzyme intermediate when m⁷GTP was used as the substrate. The reactions, catalyzed by the wild-type enzyme, were carried out at 30°C for 80 min under conditions similar to those for the standard assay for the formation of the m⁷GMP-enzyme intermediate, except that [ ${alpha}$ -³²P]GTP was replaced by [ ${alpha}$ -³²P]m⁷GTP, and AdoMet, AdoHcy, GTP, and m⁷GTP (each 100 µM) were included in the reaction mixture at different combinations as indicated.

View larger version (39K):
[in this window]
[in a new window]
FIG. 11. Effects of mutations on the formation of the covalent m⁷GMP-enzyme intermediate. The reactions containing various BaMV capping enzymes, [ ${alpha}$ -³²P]m⁷GTP, and AdoHcy were carried out as described in Materials and Methods. [ ${alpha}$ -³²P]m⁷GTP was purified by HPLC from the reaction mixture of H68A, [ ${alpha}$ -³²P]GTP, and AdoMet.

DISCUSSION

Top

Discussion

Eukaryotic mRNA is capped at the 5' end by an m⁷GMP moiety.This cap structure plays an important role in translation andmRNA stability. Crystal structures of the mRNA capping enzymeof chlorella virus have provided insights into the moleculardetails of the capping process of mRNA and clearly demonstratedthat the lysine of KxDG motif links to GMP during transguanylation(7). The knowledge gained from chlorella virus capping enzymemay not be helpful in understanding the capping mechanism inviruses of alphavirus-like superfamily owing to the absenceof both sequence similarity and the KxDG motif and to the presenceof a GTP methyltransferase activity, a finding characteristicof the capping enzymes in the alphavirus-like superfamily. Asan initial characterization of the functions of critical aminoacids of the BaMV capping enzyme, 16 residues were individuallysubstituted with alanine in the present study. The mutationaleffects on enzymatic properties are summarized in Table 1.

Based on the biochemical effects the mutants were classifiedinto four groups. The first group includes mutations at H66,D122, R125, and Y213, which apparently affected activities ofboth the GTP methyltransferase and the formation of the covalentm⁷GMP-enzyme intermediate. D122, R125, and Y213 define residuesconserved among alphavirus-like methyltransferases (24). Thecritical roles of the corresponding residues (or some of them)in the enzymes of Semliki Forest virus (2), Sindbis virus (27),and Brome mosaic virus (3, 4) have been demonstrated recently.Although H66 is not a conserved residue, it is as essentialas D122, R125, and Y213 for the catalytic function of the BaMVcapping enzyme. The second group is characterized by H68, inwhich the GTP methyltransferase activity increased by almostan order of magnitude, but the transguanylation activity wasabolished. The production of m⁷GTP by H68A was confirmed byHPLC analysis, and the purified m⁷GTP was able to label thewild-type BaMV capping enzyme in the presence of AdoHcy. Theactivity of H68A strongly supports the idea that the activityof AdoMet-dependent guanylyltransferase results from sequentialactivities of GTP methyltransferase and m⁷GTP guanylyltransferase.The unique properties of H68A also suggest that the conservedH68 residue may form a phosphoamide bond to m⁷GMP during thecatalytic pathway of transguanylation. Nonetheless, structuralevidence such as peptide mapping is needed to test this hypothesisin the future. Amino acids of the third group (K121, C234, D310,W312, R316, K344, W406, and K409) are important, but not essential,for both activities of the GTP methyltransferase and the formationof the m⁷GMP-enzyme intermediate. The residual activities uponmutation are in a range of from $~$ 2 to 60%. In general, the extentsof mutational effects on the two activities among these aminoacids follow similar trends. Lastly, mutations at K218, W377,and K389 caused insignificant changes in enzymatic activities.

The results summarized above not only confirm the essentialroles of the conserved residues but also illustrate the criticalroles of the neighboring amino acids such as H66 and K121. Besides,the present study also identifies several important residues,such as C234, D310, W312, R316, K344, and W406. The amino acidsegments encompassing H66 to H68, K121 to R125, Y213, and D310to R316 may form part of the active site. The results also indicatethe great importance of KDLA (amino acids 121 to 124) and KLDS(amino acids 344 to 347) motifs; nonetheless, their specificactivities remained to be determined before a comparison tothe KDLS motif of reovirus mRNA capping enzyme is possible.

It was surprising to find that AdoHcy was needed for transferof m⁷GMP from m⁷GTP to the enzyme. We hypothesize that AdoHcyinduces a conformational change in the protein essential foreither better binding to m⁷GTP or the catalysis of m⁷GMP transfer.AdoMet is likely to have the same role, raising the questionof why it was unable to replace Adottcy. We propose that AdoMetand m⁷GTP could not bind simultaneously to the enzyme due toa steric hindrance between the methyl groups of the two substrates.This explanation is based on a reasonable assumption that thebinding sites of AdoMet/AdoHcy and GTP/m⁷GTP are close to eachother. In support of this model, comparisons of the enzymaticproperties of the various mutants of the BaMV capping enzymes,except H68A, show that the affinity to AdoMet correlates notonly with the GTP methyltransferase activity but also with theability to form the m⁷GMP-enzyme adduct with either GTP-AdoMetor m⁷GTP-AdoHcy as substrates. This observation seems to disprovea second possible explanation of two separate sites for AdoMetand AdoHcy. In conclusion, a working model for formation ofcapped RNA in BaMV is proposed (Fig. 12) in which the bindingpockets of AdoMet/AdoHcy and GTP/m⁷GTP are adjacent or evenoverlapped with some critical amino acids participating in thebinding of the two substrates simultaneously. Binding of AdoMetmay cause a conformational change in the protein that may enhancethe binding of GTP or bring the two substrates to closer proximity,facilitating the transfer of the methyl moiety from AdoMet toGTP. Subsequently, the m⁷GMP moiety of m⁷GTP is transientlytransferred to an unidentified active-site residue, whereasAdoHcy remains in the active site, keeping the enzyme in theright conformation. In the last step, the m⁷GMP is in turn transferredfrom the active-site residue to the 5'-diphosphate end of nascentRNA. According to this model, a mutation that greatly impairsthe binding ability to AdoMet would also impair its abilityto bind AdoHcy and consequently reduce the activities of notonly GTP methyltransferase but also m⁷GTP guanylyltransferase.Nonetheless, biophysical and/or structural studies are necessaryto validate and further elaborate on this model.

View larger version (32K):
[in this window]
[in a new window]
FIG. 12. Schematic representation of the formation of capped RNA in BaMV. The proposed mechanism includes (step 1) binding of GTP and AdoMet, (step 2) transfer of methyl group from AdoMet to GTP, (step 3) formation of a phosphoamide bond between m⁷GMP and an active-site residue, and (step 4) transfer of m⁷GMP to the 5'-diphosphate end of viral RNAs.

ACKNOWLEDGMENTS

This study was supported by grants NSC 90-2313-B-005-088 andNSC 91-2313-B-005-084 from the National Science Council of theRepublic of China.

FOOTNOTES

* Corresponding author. Mailing address: Graduate Institute of Biotechnology, National Chung Hsing University, 250 Kuo-Kuang Rd., Taichung, Taiwan 40227, Republic of China. Phone: 886-4-22840328. Fax: 886-4-22853527. E-mail: mhmeng{at}dragon.nchu.edu.tw.

REFERENCES

Top