Active site localization in a viral mRNA capping enzyme

Capping of reovirus mRNAs is catalyzed by a guanylyltransferase that corresponds to virion structural polypeptide lambda 2. It forms a phosphoamide linked enzyme-pG covalent complex as an intermediate in the capping reaction. The nucleotide attachment site on lambda 2 was localized to a region between amino acids 213 and 269 by incubating virus particles with [alpha-32P]GTP followed by proteolytic cleavage and analysis of the resulting fragments using sequence-directed antibodies as probes. The 213-269 region contains as potential GMP acceptors a single lysine, 1 arginine, and 4 histidine residues, as deduced from the nucleotide sequence of the L2 gene encoding lambda 2. Digestion of 32P-labeled capping intermediate with alkali after oxidation and beta-elimination yielded phospholysine as the only phosphoamino acid, localizing the active site to a region in lambda 2 that includes the lysine at position 226.     

Synthesis of Gp4N and Gp3N compounds by guanylyltransferase purified from yeast

Guanylyltransferase that catalyzes mRNA capping by the reaction, ppNpN + GTP----GpppNpN was purified from S. cerevisiae. The enzyme forms a nucleotidyl intermediate by phosphoamide linkage of GMP. Two guanylylated polypeptides of MR approximately 52,000 and 46,000 were obtained, the latter apparently by proteolysis of the larger component. Both forms transferred the covalently bound GMP to ppApG, yielding GpppApG. Dinucleoside tri- and tetraphosphates of the type Gp3N and Gp4N were also produced by using ribonucleoside 5'-di and triphosphates as acceptors. The purified yeast guanylyltransferase contained little or no RNA 5'-triphosphatase or methyltransferase.     

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.     

A conserved motif in region v of the large polymerase proteins of nonsegmented negative-sense RNA viruses that is essential for mRNA capping

Nonsegmented negative-sense (NNS) RNA viruses cap their mRNA by an unconventional mechanism. Specifically, 5′ monophosphate mRNA is transferred to GDP derived from GTP through a reaction that involves a covalent intermediate between the large polymerase protein L and mRNA. This polyribonucleotidyltransferase activity contrasts with all other capping reactions, which are catalyzed by an RNA triphosphatase and guanylyltransferase. In these reactions, a 5′ diphosphate mRNA is capped by transfer of GMP via a covalent enzyme-GMP intermediate. RNA guanylyltransferases typically have a KxDG motif in which the lysine forms this covalent intermediate. Consistent with the distinct mechanism of capping employed by NNS RNA viruses, such a motif is absent from L. To determine the residues of L protein required for capping, we reconstituted the capping reaction of the prototype NNS RNA virus, vesicular stomatitis virus, from highly purified components. Using a panel of L proteins with single-amino-acid substitutions to residues universally conserved among NNS RNA virus L proteins, we define a new motif, GxxT[n]HR, present within conserved region V of L protein that is essential for this unconventional mechanism of mRNA cap formation.     

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.     

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.     

Functional analysis of the conserved histidine residue of Bamboo mosaic virus capping enzyme in the activity for the formation of the covalent enzyme-m7GMP intermediate

The alphavirus-like mRNA capping enzyme of Bamboo mosaic virus (BaMV) exhibits an AdoMet-dependent guanylyltransferase activity by which the methyl group of AdoMet is transferred to GTP, leading to the formation of m(7)GTP, and the m(7)GMP moiety is next transferred to the 5' end of ppRNA via a covalent enzyme-m(7)GMP intermediate. The function of the conserved H68 of the BaMV capping enzyme in the intermediate formation was analyzed by mutagenesis in this study. The nature of the bond linking the enzyme and m(7)GMP was changed in the H68C mutant protein, strongly suggesting that H68 covalently binds to m(7)GMP in the intermediate.     

Studies on the mechanism of action of histone kinase dependent on adenosine 3':5'-monophosphate. Evidence for involvement of histidine and lysine residues in the phosphotransferase reaction.

The reaction of the phosphate residue transfer catalysed by histone kinase dependent on adenosine 3':5'-monophosphate (cyclic AMP) was studied. The phosphotransferase reaction was shown to obey the mechanism of ping-pong bi-bi type. After incubation of the catalytic subunit of histone kinase with [gamma-32P]ATP the incorporation of one mole of [32P]phosphage per mole of protein was observed. The tryptic [32P]phosphohistidine-containing peptide was isolated and its N-terminus and amino acid composition were determined. The 2',3'-dialdehyde derivative of ATP (oATP) was used as the affinity label for the catalytic subunit of cyclic-AMP-dependent histone kinase. The inhibitor formed an alidmine bond with epsilon-amino group of the lysine residue of the active site and was irreversibly bound to the enzyme after reduction by sodium borohydride with concurrent irreversible inactivation of the enzyme. After inactivation, about one mole of 14C-labelled inhibitor was incorporated per mole of the enzyme. ATP effectively protected the catalytic subunit of histone kinase against inactivation by oATP. Tryptic digestion of the enzyme-inhibitor complex led to the isolation of the 14C-labelled peptide of the active site of histone kinase. Basing on these results, the role of histidine and lysine residues in the active site of the catalytic subunit of histone kinase was suggested.     

Covalent guanylyl intermediate formed by HeLa cell mRNA capping enzyme.

Guanylyltransferase, an enzyme that catalyzes formation of mRNA 5'-terminal caps, was isolated from HeLa cell nuclei. The partially purified preparation, after incubation with [alpha-32P]GTP, yielded a single radiolabeled polypeptide by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The guanylylated product was stable at neutral and alkaline pHs and had a pI of 4 by isoelectric focusing. An apparent molecular weight of approximately 68,000 was estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing conditions. The formation of a covalently linked, radiolabeled GMP-protein complex and the associated release of PPi required the presence of [alpha-32P]GTP and divalent cations and incubation between pH 7 and 9. Reaction with [beta-32P]GTP, [alpha-32P]CTP, [alpha-32P]UTP, or [alpha-32P]ATP did not label the approximately 68,000-dalton polypeptide. Phosphoamide linkage of the GMP-enzyme complex was indicated by its sensitivity to cleavage by acidic hydroxylamine or HCl and not by NaOH or alkaline phosphatase. Both formation of the GMP-enzyme intermediate and synthesis of cap structures of type GpppApG from GTP and ppApG were remarkably temperature independent; the rates of enzyme activity at 0 to 4 degrees C were 30% or more of those obtained at 37 degrees C. Radiolabeled GMP-enzyme complex, isolated by heparin-Sepharose chromatography from reaction mixtures, functioned effectively as a GMP donor for cap synthesis with 5'-diphosphorylated oligo- and polynucleotide acceptors. Alternatively, protein-bound GMP could be transferred to PPi to form GTP. The formation of a guanylylated enzyme intermediate appears to be characteristic of viral and cellular guanylyltransferases that modify eucaryotic mRNA 5' termini.     

The biosynthesis of hypusine (N epsilon-(4-amino-2-hydroxybutyl)lysine). Alignment of the butylamine segment and source of the secondary amino nitrogen

The unusual amino acid hypusine is produced in a single protein of mammalian cells by a novel posttranslational event in which a lysine residue is conjugated with the four-carbon moiety from the polyamine spermidine to form an intermediate deoxyhypusine, and in which this intermediate is subsequently hydroxylated. Specifically isotopically labeled precursors of hypusine were used to identify the biosynthetic origin of some of the atoms of hypusine and thus to provide further insight into the mechanism of this in vivo chemical modification reaction. Radiolabel from [1,4-3H] putrescine, [1,8-3H]spermidine, and [5-3H]spermidine entered hypusine during growth of Chinese hamster ovary cells. The occurrence of this label at positions 1 and 4, at position 4, and at position 1, respectively, in the 4-amino-2-hydroxybutyl portion of hypusine revealed an alignment of atoms identical to that in the butylamine segment of spermidine. Growth of cells with [epsilon-15N]lysine as the source of lysine yielded hypusine enriched in 15N, whereas only isotope-free hypusine during growth by [4-15N]spermidine. These was found in cells whose spermidine was replaced during growth by [4-15N]spermidine. These findings are in accordance with a proposal that the first phase of hypusine biosynthesis, the production of intermediate deoxyhypusine, occurs through transfer of the butylamine moiety from spermidine to the epsilon-amino nitrogen of protein-bound lysine. The technique of thermospray high-performance liquid chromatography/mass spectrometry provided positive identification of 15N in hypusine through final separation and on-column direct analysis of this amino acid. Methods of preparation are given for spermidine of high specific radioactivity, labeled specifically at position 5 with 3H, and for spermidine with 15N at the 4-position.     

Trypanosoma brucei encodes a bifunctional capping enzyme essential for cap 4 formation on the spliced leader RNA

The 5' end of kinetoplastid mRNA possesses a hypermethylated cap 4 structure, which is derived from standard m7GpppN (cap 0) with additional methylations at seven sites within the first four nucleosides on the spliced leader RNA. In addition to TbCe1 guanylyltransferase and TbCmt1 (guanine N-7) methyltransferase, Trypanosoma brucei encodes a second cap 0 forming enzyme. TbCgm1 (T. brucei cap guanylyltransferase-methyltransferase) is a novel bifunctional capping enzyme consisting of an amino-terminal guanylyltransferase domain and a carboxyl-terminal methyltransferase domain. Recombinant TbCgm1 transfers the GMP to spliced leader RNA (SL RNA) via a covalent enzyme-GMP intermediate, and methylates the guanine N-7 position of the GpppN-terminated RNA to form cap 0 structure. The two domains can function autonomously in vitro. TbCGM1 is essential for parasite growth. Silencing of TbCGM1 by RNA interference increased the abundance of uncapped SL RNA and lead to accumulation of hypomethylated SL RNA. In contrast, silencing of TbCE1 and TbCMT1 did not affect parasite growth or SL RNA capping. We conclude that TbCgm1 specifically cap SL RNA, and cap 0 is a prerequisite for subsequent methylation events leading to the formation of mature SL RNA.     

Mutational analysis of a mammalian reovirus mRNA capping enzyme

The amino-terminal 42-kDa region of the 144-kDa mammalian reovirus lambda 2 protein is a guanylyltransferase. It catalyzes the transfer of GMP from GTP to the 5' end of 5' -diphosphorylated mRNA via a phosphoamide with Lys-190. This amino acid is located at the base of a deep cleft. Based on sequence comparisons, the Kx[V/L/I]S motif is present in all known and proposed guanylyltransferases of the family Reoviridae. The requirement for this conserved sequence and other regions of the enzyme was analyzed by site-directed mutagenesis. Based on the enzymatic activity of the mutants, Lys-190 and Asp-191 are the only amino acids of the (190)KDLS sequence that are necessary for enzymatic activity. Since Asp-191 has its side chain oriented away from the cleft, most likely it plays an indirect role in forming a functional guanylyltransferase.     

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.     

Nucleophile in the active site of Escherichia coli galactose-1-phosphate uridylyltransferase: degradation of the uridylyl-enzyme intermediate to N3-phosphohistidine.

The [32P]uridylyl-enzyme intermediate form of Escherichia coli galactose-1-P uridylyltransferase can be converted to a [32P]phosphoryl-enzyme by first cleaving the ribosyl ring with NaIO4 and then heating at pH 10.5 and 50 degrees C for 1 h. After alkaline hydrolysis of the [32P]phosphoryl-enzyme the major radioactive product is N3-[32P]phosphohistidine. A lesser amount of 32Pi is also produced as a side product of the hydrolysis of N3-[32P]phosphohistidine. No N1-phosphohistidine, N-phospholysine, or phosphoarginine can be detected in these hydrolysates. It is concluded that the nucleophile in galactose-1-P uridylyltransferase to which the uridylyl group is bonded in the uridylyl-enzyme intermediate is imidazole N3 of a histidine residue. This degradation procedure should have general applicability in the degradation and characterization of nucleotidyl-proteins.     

Dihydroxypropylation of amino groups of proteins: use of glyceraldehyde as a reversible agent for reductive alkylation

The mode of derivatization of amino groups of proteins by glyceraldehyde, an aldotriose, depends on the presence or absence of reducing agent. In the presence of sodium cyanoborohydride, the Schiff base adducts of the aldehyde with the amino groups are reduced, and dihydroxypropylation of amino groups takes place (reductive mode). The reductively glycated lysine residue, N epsilon-(2,3-dihydroxypropyl)lysine, is a substituted alpha-amino alcohol. This alpha-amino alcoholic function of the derivatized lysine should be susceptible to periodate oxidation, and this oxidation is anticipated to result in the regeneration of the lysine residue. This aspect has been now investigated. Indeed, on mild periodate oxidation (15 mM periodate, 15 min at room temperature) of dihydroxypropylated ribonuclease A, nearly 95% of its N epsilon-(2,3-dihydroxypropyl)lysine residues were regenerated to lysine residues. The removal of the dihydroxypropyl groups by periodate oxidation could be accomplished within a wide pH range with little variation in the recovery of lysines. The possible usefulness of this reversible chemical modification procedure in the primary structural studies of proteins was investigated with a tryptic peptide of dihydroxypropylated streptococcal M5 protein, namely, DHP-T4. This 12-residue tryptic peptide contains one internal N epsilon-(dihydroxypropyl)lysine. The dihydroxypropylated peptide released most of its dihydroxypropyl groups on mild periodate oxidation. Redigestion of the periodate-treated peptide with trypsin generated the two expected peptides, demonstrating the generation of a trypsin-susceptible site. Reductive dihydroxypropylation of amino groups of RNase A resulted in the loss of its enzyme activity, the extent of inactivation increasing with the concentration of the glyceraldehyde used.(ABSTRACT TRUNCATED AT 250 WORDS)