Catalytic activity of vaccinia mRNA capping enzyme subunits coexpressed in Escherichia coli

RNA triphosphatase, RNA guanylyltransferase, and RNA (guanine-7)-methyltransferase activities are associated with the vaccinia virus mRNA capping enzyme, a heterodimeric protein containing polypeptides of Mr 95,000 and Mr 31,000. The genes encoding the large and small subunits (corresponding to the D1 and the D12 ORFs, respectively, of the viral genome) were coexpressed in Escherichia coli BL21 (DE3) under the control of a bacteriophage T7 promoter. Guanylyltransferase activity (assayed as the formation of a covalent enzyme-guanylate complex) was detected in soluble lysates of these bacteria. A 1000-fold purification of the guanylyltransferase was achieved by ammonium sulfate precipitation and chromatography using phosphocellulose and SP5PW columns. Partially purified guanylytransferase synthesized GpppA caps when provided with 5'-triphosphate-terminated poly(A) as a cap acceptor. In the presence of AdoMet the enzyme catalyzed concomitant cap methylation with 99% efficiency. Inclusion of S-adenosyl methionine increased both the rate and extent of RNA capping, permitting quantitative modification of RNA 5' ends. Guanylyltransferase sedimented as a single component of 6.5 S during further purification in a glycerol gradient; this S value is identical with that of the heterodimeric capping enzyme from vaccinia virions. Electrophoretic analysis showed a major polypeptide of Mr 95,000 cosedimenting with the guanylyltransferase. RNA triphosphatase activity cosedimented exactly with guanylyltransferase. Methyltransferase activity was associated with guanylyltransferase and was also present in less rapidly sedimenting fractions. The methyltransferase activity profile correlated with the presence of a Mr 31,000 polypeptide. These results indicate that the D1 and D12 gene products are together sufficient to catalyze all three enzymatic steps in cap synthesis. A model for the domain structure of this enzyme is proposed.     

Modification of RNA by mRNA guanylyltransferase and mRNA (guanine-7-)methyltransferase from vaccinia virions.

A purified enzyme system isolated from vaccinia virus cores has been shown to modify the 5' termini of viral mRNA and synthetic poly(A) and poly(G) to form the structures m7G(5')pppA- and m7G(5')pppG-. The enzyme system has both guanylyltransferase and methyltransferase activities. The GTP:mRNA guanylyltransferase activity incorporates GMP into the 5' terminus via a 5'-5' triphosphate bond. The properties of this reaction are: (a) of the four nucleoside triphosphates only GTP is a donor, (b) mRNA with two phosphates at the 5' terminus is an acceptor while RNA with a single 5'-terminal phosphate is not, (c) Mg2+ is required, (d) the pH optimum is 7.8, (e) PP1 is a strong inhibitor, and (f) the reverse reaction, namely the formation of GTP from PP1 and RNA containing the 5'-terminal structure G(5')pppN-, readily occurs. The S-adenosylmethionine:mRNA(guanine-7-)methyltransferase activity catalyzes the methylation of the 5'-terminal guanosine. This reaction exhibits the following characteristics: (a) mRNA with the 5'-terminal sequences G(5')pppA- and G(5')pppG- are acceptors, (b) only position 7 of the terminal guanosine is methylated; internal or conventional 5'-terminal guanosine residues are not methylated, (c) the reaction is not dependent upon GTP or divalent cations, (d) optimal activity is observed in a broad pH range around neutrality, (e) the reaction is inhibited by S-adenosylhomocysteine. Both the guanylyltransferase and methyltransferase reactions exhibit bisubstrate kinetics and proceed via a sequential mechanism. The reactions may be summarized: (see article).     

RNA capping by HeLa cell RNA guanylyltransferase. Characterization of a covalent protein-guanylate intermediate

RNA capping by partially purified HeLa cell GTP:RNA guanylyltransferase has been shown to occur in the following sequence of two partial reactions involving a covalent protein-guanylate intermediate: (i) E(P68) + GTP in equilibrium E(P68-GMP) + PPi (ii) E(P68-GMP) + ppRNA in equilibrium GpppRNA + E(P68) Initially, the enzyme reacts with GTP in the absence of an RNA cap acceptor to form a covalent protein-guanylate complex. This complex consists of a GMP residue linked via a phosphoamide bond to a Mr = 68,000 protein. The enzyme then transfers the guanylate residue from the Mr = 68,000 polypeptide to the 5' end of diphosphate-terminated poly(a) to yield the capped derivative GpppA(pA)n. Both partial reactions have been shown to be reversible. In the reverse of Reaction i, E(P68--GMP) reacts with PPi to regenerate GTP. In the reverse of Reaction ii, the enzyme catalyzes the transfer of the 5'-GMP from capped RNA to the Mr = 68,000 protein to form protein-guanylate complex. A divalent cation is required for both partial reactions. The Mr = 68,000 protein is presumed to be a subunit of the HeLa guanylyltransferase. This interpretation is consistent with the sedimentation coefficient of 4.2 S of the native enzyme. Preliminary studies of RNA guanylyltransferase from mouse myeloma tumors suggest a similar mechanism of transguanylylation involving a Mr = 68,000 protein-guanylate complex. These data, in conjunction with previous studies of vaccinia virus guanylyltransferase (Shuman, S., and Hurwitz, J. (1981) Proc. Natl. Acad. Sci. U. S. A. 78, 187-191) suggests that covalent GMP-enzyme intermediates may be a general feature of the RNA capping reaction.     

Methyltransferase and subunit association domains of vaccinia virus mRNA capping enzyme.

RNA triphosphatase, RNA guanylyltransferase, and RNA (guanine-N7-)-methyltransferase activities are associated with the vaccinia virus mRNA capping enzyme, a heterodimeric protein containing polypeptides of M(r) 95,000 and 31,000. Although the RNA triphosphatase and RNA guanylyltransferase domains have been localized to a M(r) 59,000 fragment of the capping enzyme large subunit, the location of the methyltransferase domain within the protein and the catalytic role of individual subunits in methyl group transfer remain unclear. In the present work, through the study of methyltransferase activity of truncated forms of capping enzyme translated in vitro in a rabbit reticulocyte lysate, we have localized the methyltransferase domain to a complex consisting of the small subunit and the carboxyl-terminal portion of the large subunit. The M(r) 31,000 subunit translated alone was not sufficient for methyltransferase activity. This requirement for both subunits may explain the tight physical association of the two polypeptides in vivo. We have recreated the association of the large and small enzyme subunits in vitro through the translation of synthetic mRNAs encoding the two polypeptides. Study of the ability of deleted versions of the large subunit to bind the small subunit, as detected by co-immunoprecipitation, defined a 347-amino acid carboxyl-terminal region of the large subunit that was sufficient for heterodimerization. Colocalization within the large subunit of the methyltransferase and subunit association domains suggests that dimerization of the subunits may be required for methyltransferase activity.     

Mutational analysis of the RNA triphosphatase component of vaccinia virus mRNA capping enzyme.

Vaccinia virus mRNA capping enzyme is a multifunctional protein with RNA triphosphatase, RNA guanylyltransferase, and RNA (guanine-7-) methyltransferase activities. The enzyme is a heterodimer of 95- and 33-kDa subunits encoded by the vaccinia virus D1 and D12 genes, respectively. The N-terminal 60-kDa of the D1 subunit (from residues 1 to 545) is an autonomous domain which catalyzes the triphosphatase and guanylyltransferase reactions. Mutations in the D1 subunit that specifically inactivate the guanylyltransferase without affecting the triphosphatase component have been described (P. Cong and S. Shuman, Mol. Cell. Biol. 15:6222-6231, 1995). In the present study, we identified two alanine-cluster mutations of D1(1-545), R77A-K79A and E192A-E194A, that selectively inactivated the triphosphatase, but not the guanylyltransferase. Concordant mutational inactivation of RNA triphosphatase and nucleoside triphosphatase functions (to approximately 1% of wild-type specific activity) suggests that both gamma-phosphate cleavage reactions occur at a single active site. The R77A-K79A and E192A-E194A mutant enzymes were less active than wild-type D1(1-545) in the capping of triphosphate-terminated poly(A) but could be complemented in vitro by D1(1-545)-K260A, which is inert in nucleotidyl transfer but active in gamma-phosphate cleavage. Whereas wild-type D1(1-545) formed only the standard GpppA cap, the R77A-K79A and E192A-E194A enzymes synthesized an additional dinucleotide, GppppA. This finding illuminates a novel property of the vaccinia virus capping enzyme, the use of triphosphate RNA ends as an acceptor for nucleotidyl transfer when gamma-phosphate cleavage is rate limiting.     

Messenger RNA guanylyltransferase from Saccharomyces cerevisiae. Large scale purification, subunit functions, and subcellular localization

Messenger RNA capping enzyme (GTP:mRNA guanylyltransferase) purified from yeast Saccharomyces cerevisiae consisted of two polypeptides (45 and 39 kDa) and possessed two enzymatic activities, i.e. mRNA guanylyltransferase and RNA 5'-triphosphatase (Itoh, N., Mizumoto, K., and Kaziro, Y. (1984) J. Biol. Chem. 259, 13923-13929). In this paper, we describe an improved procedure suitable for the large scale purification of the enzyme. The steps include glass beads disruption of the cells and several ion-exchange and affinity column chromatographies. The enzyme was purified from kilogram quantities of yeast cells to apparent homogeneity. The purified enzyme had an approximate Mr of 180,000 and consisted of two heterosubunits of 80 and 52 kDa and had the same two enzymatic activities as above. We consider that this is the more intact form of the enzyme. Using the in situ assays on sodium dodecyl sulfate-polyacrylamide gels, RNA 5'-triphosphatase, and mRNA guanylyltransferase activities were located on the 80- and 52-kDa chains, respectively. In agreement with this, the 52-kDa enzyme-[32P]GMP complex was formed on incubation of the enzyme with [alpha-32P]GTP. Guinea pig antisera against purified yeast capping enzyme recognized both 80- and 52-kDa chains in Western blot analysis. The antibody did not cross-react with the enzymes from rat liver. Artemia salina, or vaccinia virus. Nuclear localization of the enzyme was demonstrated by immunofluorescence microscopy.     

Domain structure of vaccinia virus mRNA capping enzyme. Activity of the Mr 95,000 subunit expressed in Escherichia coli

The D1 gene encoding the large subunit of vaccinia virus mRNA capping enzyme was expressed in Escherichia coli BL21(DE3) under the control of a bacteriophage T7 promoter. Guanylyltransferase activity (assayed as the formation of a covalent enzyme-guanylate complex) was detected in soluble lysates of these bacteria. Two major species of protein-GMP complex were formed, one of Mr 95,000 (corresponding in size to the D1 gene product) and one of Mr 60,000. Partial purification of the guanylyltransferase was effected by ammonium sulfate precipitation and ion-exchange chromatography. The expressed large subunit synthesized GpppA caps when provided with 5'-triphosphate-terminated poly(A) as a cap acceptor, but was unable to catalyze cap methylation in the presence of S-adenosylmethionine. Thus, the small capping enzyme subunit was shown to be dispensable for guanylylation, but required for cap methylation of RNA. The Mr 95,000 and Mr 60,000 protein-GMP forming activities were resolved during centrifugation in a glycerol gradient; the two forms sedimented at 5.5 S and 4.4 S, respectively, consistent with each enzyme form being a monomer. Either species catalyzed GMP transfer to an RNA acceptor. The isolated Mr 95,000 guanylyltransferase could be converted to an active Mr 60,000 form in vitro by limited proteolysis with trypsin. Expression of carboxyl-deleted forms of the D1 gene product in E. of carboxyl-deleted forms of the D1 gene product in E. coli further localized the guanylyltransferase domain to the amino two-thirds of the Mr 95,000 polypeptide.     

mRNA guanylyltransferase and mRNA (guanine-7-)-methyltransferase from vaccinia virions. Donor and acceptor substrate specificites.

Characterization of the donor and acceptor specificities of mRNA guanylyltransferase and mRNA (guanine-7-)-methyltransferase isolated from vaccinia virus cores has enabled us to discriminate between alternative reaction sequences leading to the formation of the 5'-terminal m7G(5')pppN-structure. The mRNA guanylyltransferase catalyzes the transfer of a residue of GMP from GTP to acceptors which possess a 5'-terminal diphosphate. A diphosphate-terminated polyribonucleotide is preferred to a mononucleoside diphosphate as an acceptor suggesting that the guanylyltransferase reaction occurs after initiation of RNA synthesis. Although all of the homopolyribonucleotides tested (pp(A)n, pp(G)n, pp(I)n, pp(U)n, and pp(C)n) are acceptors for the mRNA guanylyltransferase indicating lack of strict sequence specificity, those containing purines are preferred. Only GTP and dGTP are donors in the reaction; 7-methylguanosine (m7G) triphosphate specifically is not a donor indicating that guanylylation must precede guanine-7-methylation. The preferred acceptor of the mRNA (guanine-7-)-methyltransferase is the product of the guanylyltransferase reaction, a polyribonucleotide with the 5'-terminal sequence G(5')pppN-. The enzyme can also catalyze, but less efficiently methylation of the following: dinucleoside triphosphates with the structure G(5')pppN, GTP, dGTP, ITP, GDP, GMP, and guanosine. The enzyme will not catalyze the transfer of methyl groups to ATP, XTP, CTP, UTP, or to guanosine-containing compounds with phosphate groups in either positions 2' or 3' or in 3'-5' phosphodiester linkages. The latter specificity provides an explanation for the absence of internal 7-methylguanosine in mRNA. In the presence of PPi, the mRNA guanylyltransferase catalyzes the pyrophosphorolysis of the dinucleoside triphosphate G(5')pppA, but not of m7G(5')pppA. Since PPi is generated in the process of RNA chain elongation, stabilization of the 5'-terminal sequences of mRNA is afforded by guanine-7-methylation.     

Purification of mRNA guanylyltransferase and mRNA (guanine-7-) methyltransferase from vaccinia virions.

The sequences m7G(5')pppGm-and m7G(5')pppAm-are located at the 5' termini of vaccinia mRNAs. Two novel enzymatic activities have been purified from vaccinia virus cores which modify the 5' terminus of unmethylated mRNA. One activity transfers GMP from GTP to mRNA and is designated a GTP: mRNA guanylyltransferase. The second activity transfers a methyl group from S-adenosylmethionine to position 7 of the added guanosine and is designated a S-adenosylmethionine: mRNA (guanine-7-)methyltransferase. Advantage was taken of the selective binding of these activities to homopolyribonucleotides relative to DNA to achieve a 200-fold increase in specific activity. The guanylyl- and methyltransferase remained inseparable during chromatography on DNA-agarose, poly(U)-Sepharose, poly(A)-Sepharose, and Sephadex G-200 and during sedimentation through sucrose density gradients suggesting they were associated. A Stokes radius of 5.0 nm, an S20,w of 6.0 and a molecular weight of 127,000 were obtained by gel filtration on Sephadex G-200 and sedimentation in sucrose density gradients. Under denaturing conditions of sodium dodecyl sulfate-polyacrylamide gel electrophoresis two major polypeptides were detected in purified enzyme preparations. Their molecular weights of 95,000 and 31,400 suggested they were polypeptide components of the 127,000 molecular weight enzyme system.     

Kinetic and thermodynamic characterization of the RNA guanylyltransferase reaction

An RNA guanylyltransferase activity is involved in the synthesis of the cap structure found at the 5' end of eukaryotic mRNAs. The RNA guanylyltransferase activity is a two-step ping-pong reaction in which the enzyme first reacts with GTP to produce the enzyme-GMP covalent intermediate with the concomitant release of pyrophosphate. In the second step of the reaction, the GMP moiety is then transferred to a diphosphorylated RNA. Both reactions were previously shown to be reversible. In this study, we report a biochemical and thermodynamic characterization of both steps of the reaction of the RNA guanylyltransferase from Paramecium bursaria Chlorella virus 1, the prototype of a family of viruses infecting green algae. Using a combination of real-time fluorescence spectroscopy, radioactive kinetic assays, and inhibition assays, the complete kinetic parameters of the RNA guanylyltransferase were determined. We produced a thermodynamic scheme for the progress of the reaction as a function of the energies involved in each step. We were able to demonstrate that the second step comprises the limiting steps for both the direct and reverse overall reactions. In both cases, the binding to the RNA substrates is the step requiring the highest energy and generating unstable intermediates that will promote the catalytic activites of the enzyme. This study reports the first thorough kinetic and thermodynamic characterization of the reaction catalyzed by an RNA capping enzyme.     

Association of an RNA 5'-triphosphatase activity with RNA guanylyltransferase partially purified from rat liver nuclei.

An RNA 5'-triphosphatase activity hydrolyzing gamma-phosphate from pppN-RNA was found to be associated with mRNA guanylyltransferase partially purified from rat liver nuclei. The activity specifically removed 32P as inorganic phosphate from [gamma-32P]pppA(pA)n, but not from [beta-32P]pppA(pA)n or from [gamma-32P]ATP. Free SH group(s) were required for its activity, and the reaction was inhibited by N-ethylmaleimide. Divalent cations were not required, but were rather inhibitory for the reaction. The RNA 5'-triphosphatase activity could not be separated from the guanylyltransferase activity through successive chromatographies on Sephadex G-150, CM-Sephadex and blue dextran-Sepharose columns. Both activities remained physically associated during sedimentation in glycerol density gradients after high salt treatment. The heat stability of the RNA 5'-triphosphatase activity was almost identical with that of the guanylyltransferase activity. These results indicate that the 69000 mol. wt. protein purified from rat liver nuclei as guanylyltransferase possesses both mRNA capping and RNA 5'-triphosphatase activities.     

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 Potexvirus in the alphavirus-like superfamily, encodes a 155-kDa replicase responsible for the formation of the 5' cap structure and replication of the viral RNA genome. The N-terminal domain of the viral replicase functions as an mRNA capping enzyme, which exhibits both GTP methyltransferase and S-adenosylmethionine (AdoMet)-dependent guanylyltransferase activities. We mutated each of the four conserved amino acids among the capping enzymes of members within alphavirus-like superfamily and a dozen of other residues to gain insight into the structure-function relationship of the viral enzyme. The mutant enzymes were purified and subsequently characterized. H68A, the mutant enzyme bearing a substitution at the conserved histidine residue, has an approximately 10-fold increase in GTP methyltransferase activity but completely loses the ability to form the covalent m(7)GMP-enzyme intermediate. High-pressure liquid chromatography analysis confirmed the production of m(7)GTP by the GTP methyltransferase activity of H68A. Furthermore, the produced m(7)GTP sustained the formation of the m(7)GMP-enzyme intermediate for the wild-type enzyme in the presence of S-adenosylhomocysteine (AdoHcy), suggesting that the previously observed AdoMet-dependent guanylation of the enzyme using GTP results from reactions of GTP methylation and subsequently guanylation of the enzyme using m(7)GTP. Mutations occurred at the other three conserved residues (D122, R125, and Y213), and H66 resulted in abolition of activities for both GTP methylation and formation of the covalent m(7)GMP-enzyme intermediate. Mutations of amino acids such as K121, C234, D310, W312, R316, K344, W406, and K409 decreased both activities by various degrees, and the extents of mutational effects follow similar trends. The affinity to AdoMet of the various BaMV capping enzymes, except H68A, was found in good correlations with not only the magnitude of GTP methyltransferase activity but also the capability of forming the m(7)GMP-enzyme intermediate. Taken together with the AdoHcy dependence of guanylation of the enzyme using m(7)GTP, a basic working mechanism, with the contents of critical roles played by the binding of AdoMet/AdoHcy, of the BaMV capping enzyme is proposed and discussed.     

Characterization of the AdoMet-dependent guanylyltransferase activity that is associated with the N terminus of bamboo mosaic virus replicase

Bamboo mosaic virus (BaMV), a member of the potexvirus group, infects primarily members of the Bambusoideae. Open reading frame 1 (ORF1) of BaMV encodes a 155-kDa polypeptide that has long been postulated to be a replicase involved in the replication and formation of the cap structure at the 5' end of the viral genome. To identify and characterize the enzymatic activities associated with the N-terminal domain of the BaMV ORF1 protein, the intact replicase and two C-terminally truncated proteins were expressed in Saccharomyces cerevisiae. All three versions of BaMV ORF1 proteins could be radiolabeled by [alpha-(32)P]GTP, which is a characteristic of guanylyltransferase activity. The presence of S-adenosylmethionine (AdoMet) was essential for this enzymatic activity. Thin-layer chromatography analysis suggests that the radiolabeled moiety linked to the N-terminal domain of the BaMV ORF1 protein is m(7)GMP. The N-terminal domain also exhibited methyltransferase activity that catalyzes the transfer of the [(3)H]methyl group from AdoMet to GTP or guanylylimidodiphosphate. Therefore, during cap structure formation in BaMV, methylation of GTP may occur prior to transguanylation as for alphaviruses and brome mosaic virus. This study establishes the association of RNA capping activity with the N-terminal domain of the replicase of potexviruses and further supports the idea that the reaction sequence of RNA capping is conserved throughout the alphavirus-like superfamily of RNA viruses.     

Analysis of RNA binding by the dengue virus NS5 RNA capping enzyme

Flaviviruses are small, capped positive sense RNA viruses that replicate in the cytoplasm of infected cells. Dengue virus and other related flaviviruses have evolved RNA capping enzymes to form the viral RNA cap structure that protects the viral genome and directs efficient viral polyprotein translation. The N-terminal domain of NS5 possesses the methyltransferase and guanylyltransferase activities necessary for forming mature RNA cap structures. The mechanism for flavivirus guanylyltransferase activity is currently unknown, and how the capping enzyme binds its diphosphorylated RNA substrate is important for deciphering how the flavivirus guanylyltransferase functions. In this report we examine how flavivirus NS5 N-terminal capping enzymes bind to the 5' end of the viral RNA using a fluorescence polarization-based RNA binding assay. We observed that the K(D) for RNA binding is approximately 200 nM Dengue, Yellow Fever, and West Nile virus capping enzymes. Removal of one or both of the 5' phosphates reduces binding affinity, indicating that the terminal phosphates contribute significantly to binding. RNA binding affinity is negatively affected by the presence of GTP or ATP and positively affected by S-adensyl methoninine (SAM). Structural superpositioning of the dengue virus capping enzyme with the Vaccinia virus VP39 protein bound to RNA suggests how the flavivirus capping enzyme may bind RNA, and mutagenesis analysis of residues in the putative RNA binding site demonstrate that several basic residues are critical for RNA binding. Several mutants show differential binding to 5' di-, mono-, and un-phosphorylated RNAs. The mode of RNA binding appears similar to that found with other methyltransferase enzymes, and a discussion of diphosphorylated RNA binding is presented.