Yeast mRNA cap methyltransferase is a 50-kilodalton protein encoded by an essential gene

tRNA m7G methyltransferase Trm8p/Trm82p: evidence linking activity to a growth phenotype and implicating Trm82p in maintaining levels of active Trm8p

We show that Saccharomyces cerevisiae strains lacking Trm8p/Trm82p tRNA m7G methyltransferase are temperature-sensitive in synthetic media containing glycerol. Bacterial TRM8 orthologs complement the growth defect of trm8-Delta, trm82-Delta, and trm8-Delta trm82-Delta double mutants, suggesting that bacteria employ a single subunit for Trm8p/Trm82p function. The growth phenotype of trm8 mutants correlates with lack of tRNA m7G methyltransferase activity in vitro and in vivo, based on analysis of 10 mutant alleles of trm8 and bacterial orthologs, and suggests that m7G modification is the cellular function important for growth. Initial examination of the roles of the yeast subunits shows that Trm8p has most of the functions required to effect m7G modification, and that a major role of Trm82p is to maintain cellular levels of Trm8p. Trm8p efficiently cross-links to pre-tRNAPhe in vitro in the presence or absence of Trm82p, in addition to its known residual tRNA m7G modification activity and its SAM-binding domain. Surprisingly, the levels of Trm8p, but not its mRNA, are severely reduced in a trm82-Delta strain. Although Trm8p can be produced in the absence of Trm82p by deliberate overproduction, the resulting protein is inactive, suggesting that a second role of Trm82p is to stabilize Trm8p in an active conformation.

Human mRNA cap methyltransferase: alternative nuclear localization signal motifs ensure nuclear localization required for viability

A characteristic feature of gene expression in eukaryotes is the addition of a 5'-terminal 7-methylguanine cap (m7GpppN) to nascent pre-mRNAs in the nucleus catalyzed by capping enzyme and cap methyltransferase. Small interfering RNA (siRNA) knockdown of cap methyltransferase in HeLa cells resulted in apoptosis as measured by terminal deoxynucleotidyltransferase-mediated dUTP-tetramethylrhodamine nick end labeling assay, demonstrating the importance of mRNA 5'-end methylation for mammalian cell viability. Nuclear localization of cap methyltransferase is mediated by interaction with importin-alpha, which facilitates its transport and selective binding to transcripts containing 5'-terminal GpppN. The methyltransferase 96-144 region has been shown to be necessary for importin binding, and N-terminal fusion of this sequence to nonnuclear proteins proved sufficient for nuclear localization. The targeting sequence was narrowed to amino acids 120 to 129, including a required 126KRK. Although full-length methyltransferase (positions 1 to 476) contains the predicted nuclear localization signals 57RKRK, 80KKRK, 103KKRKR, and 194KKKR, mutagenesis studies confirmed functional motifs only at positions 80, 103, and the previously unrecognized 126KRK. All three motifs can act as alternative nu clear targeting signals. Expression of N-truncated cap methyltransferase (120 to 476) restored viability of methyltransferase siRNA knocked-down cells. However, an enzymatically active 144-476 truncation mutant missing the three nuclear localization signals was mostly cytoplasmic and ineffective in preventing siRNA-induced loss of viability.

Encephalitozoon cuniculi mRNA cap (guanine N-7) methyltransferase: methyl acceptor specificity, inhibition BY S-adenosylmethionine analogs, and structure-guided mutational analysis

The Encephalitozoon cuniculi mRNA cap (guanine N-7) methyltransferase Ecm1 has been characterized structurally but not biochemically. Here we show that purified Ecm1 is a monomeric protein that catalyzes methyl transfer from S-adenosylmethionine (AdoMet) to GTP. The reaction is cofactor-independent and optimal at pH 7.5. Ecm1 also methylates GpppA, GDP, and dGTP but not ATP, CTP, UTP, ITP, or m(7)GTP. The affinity of Ecm1 for the cap dinucleotide GpppA (K 0.1 mm) is higher than that for GTP (K(m) 1 mm) or GDP (K(m) 2.4 mm). Methylation of GTP by Ecm1 in the presence of 5 microm AdoMet is inhibited by the reaction product AdoHcy (IC(50) 4 microm) and by substrate analogs sinefungin (IC(50) 1.5 microm), aza-AdoMet (IC(50) 100 microm), and carbocyclic aza-AdoMet (IC(50) 35 microm). The crystal structure of an Ecm1.aza-AdoMet binary complex reveals that the inhibitor occupies the same site as AdoMet. Structure-function analysis of Ecm1 by alanine scanning and conservative substitutions identified functional groups necessary for methyltransferase activity in vivo. Amino acids Lys-54, Asp-70, Asp-78, and Asp-94, which comprise the AdoMet-binding site, and Phe-141, which contacts the cap guanosine, are essential for cap methyltransferase activity in vitro.

A function of yeast mRNA cap methyltransferase, Abd1, in transcription by RNA polymerase II

Capping enzymes bind the phosphorylated pol II CTD permitting cotranscriptional capping of nascent pre-mRNAs. We asked whether these interactions influence pol II function using ChIP in ts mutants of yeast capping enzymes. Pol II occupancy at the 5' ends of PGK1, ENO2, GAL1, and GAL10 was reduced by inactivation of the methyltransferase, Abd1, but not the guanylyltransferase, Ceg1, suggesting that Abd1 contributes to stable promoter binding. At other genes, Abd1 inactivation increased the 5':3' ratio of pol II density in the promoter-proximal region and caused Ser5 hyperphosphorylation of the pol II CTD. These results suggest an additional role for Abd1 in the promoter clearance and/or promoter-proximal elongation steps of transcription. The transcriptional functions of Abd1 are independent of methyltransferase activity. Manipulation of transcription by Abd1 may enhance cotranscriptional capping and also act as a checkpoint to ensure that a nascent transcript has a cap before it can be completed.

Structure and mechanism of mRNA cap (guanine-N7) methyltransferase

A suite of crystal structures is reported for a cellular mRNA cap (guanine-N7) methyltransferase in complex with AdoMet, AdoHcy, and the cap guanylate. Superposition of ligand complexes suggests an in-line mechanism of methyl transfer, albeit without direct contacts between the enzyme and either the N7 atom of guanine (the attacking nucleophile), the methyl carbon of AdoMet, or the sulfur of AdoMet/AdoHcy (the leaving group). The structures indicate that catalysis of cap N7 methylation is accomplished by optimizing proximity and orientation of the substrates, assisted by a favorable electrostatic environment. The enzyme-ligand structures, together with new mutational data, fully account for the biochemical specificity of the cap guanine-N7 methylation reaction, an essential and defining step of eukaryotic mRNA synthesis.

Yeast-based genetic system for functional analysis of poxvirus mRNA cap methyltransferase

Structural differences between poxvirus and human mRNA capping enzymes recommend cap formation as a target for antipoxviral drug discovery. Genetic and pharmacologic analysis of the poxvirus capping enzymes requires in vivo assays in which the readout depends on the capacity of the viral enzyme to catalyze cap synthesis. Here we have used the budding yeast Saccharomyces cerevisiae as a genetic model for the study of poxvirus cap guanine-N7 methyltransferase. The S. cerevisiae capping system consists of separate triphosphatase (Cet1), guanylyltransferase (Ceg1), and methyltransferase (Abd1) components. All three activities are essential for cell growth. We report that the methyltransferase domain of vaccinia virus capping enzyme (composed of catalytic vD1-C and stimulatory vD12 subunits) can function in lieu of yeast Abd1. Coexpression of both vaccinia virus subunits is required for complementation of the growth of abd1Delta cells. Previously described mutations of vD1-C and vD12 that eliminate or reduce methyltransferase activity in vitro either abolish abd1Delta complementation or elicit conditional growth defects. We have used the yeast complementation assay as the primary screen in a new round of alanine scanning of the catalytic subunit. We thereby identified several new amino acids that are critical for cap methylation activity in vivo. Studies of recombinant proteins show that the lethal vD1-C mutations do not preclude heterodimerization with vD12 but either eliminate or reduce cap methyltransferase activity in vitro.

mRNA capping enzyme requirement for Caenorhabditis elegans viability

Capping of the initiated 5' ends of RNA polymerase II products is evolutionarily and functionally conserved from yeasts to humans. The m(7)GpppN cap promotes RNA stability, processing, transport, and translation. Deletion of capping enzymes in yeasts was shown to be lethal due to rapid exonucleolytic degradation of uncapped transcripts or failure of capped but unmethylated RNA to initiate protein synthesis. Using RNA interference and Caenorhabditis elegans we have found that RNA capping is also essential for metazoan viability. C. elegans bifunctional capping enzyme was cloned, and capping activity by the expressed protein as well as growth complementation of yeast deletion strains missing either RNA triphosphatase or guanylyltransferase required terminal sequences not present in the previously isolated cel-1 clone. By RNA interference analysis we show that cel-1 is required for embryogenesis. cel-1(RNAi) embryos formed cytoplasmic granules characteristic of a phenocluster of RNA processing genes and died early in development.

Dual roles for Spt5 in pre-mRNA processing and transcription elongation revealed by identification of Spt5-associated proteins

During transcription elongation, eukaryotic RNA polymerase II (Pol II) must contend with the barrier presented by nucleosomes. The conserved Spt4-Spt5 complex has been proposed to regulate elongation through nucleosomes by Pol II. To help define the mechanism of Spt5 function, we have characterized proteins that coimmunopurify with Spt5. Among these are the general elongation factors TFIIF and TFIIS as well as Spt6 and FACT, factors thought to regulate elongation through nucleosomes. Spt5 also coimmunopurified with the mRNA capping enzyme and cap methyltransferase, and spt4 and spt5 mutations displayed genetic interactions with mutations in capping enzyme genes. Additionally, we found that spt4 and spt5 mutations lead to accumulation of unspliced pre-mRNA. Spt5 also copurified with several previously unstudied proteins; we demonstrate that one of these is encoded by a new member of the SPT gene family. Finally, by immunoprecipitating these factors we found evidence that Spt5 participates in at least three Pol II complexes. These observations provide new evidence of roles for Spt4-Spt5 in pre-mRNA processing and transcription elongation.

Deletion of individual mRNA capping genes is unexpectedly not lethal to Candida albicans and results in modified mRNA cap structures

Eukaryotic mRNAs are modified at the 5' end with a cap structure. In fungal cells, the formation of the mRNA cap structure is catalyzed by three enzymes: triphosphatase, guanylyltransferase, and methyltransferase. Fungal capping enzymes have been proposed to be good antifungal targets because they differ significantly from their human counterparts and the genes encoding these enzymes are essential in Saccharomyces cerevisiae. In the present study, Candida albicans null mutants were constructed for both the mRNA triphosphatase-encoding gene (CET1) and the mRNA methyltransferase encoding gene (CCM1), proving that these genes are not essential in C. albicans. Heterozygous deletions were generated, but no null mutants were isolated for the guanylyltransferase-encoding gene (CGT1), indicating that this gene probably is essential in C. albicans. Whereas these results indicate that Cet1p and Ccm1p are not ideal molecular targets for development of anticandidal drugs, they do raise questions about the capping of mRNA and translation initiation in this fungus. Southern blot analysis of genomic DNA indicates that there are not redundant genes for CET1 and CCM1 and analysis of mRNA cap structures indicate there are not alternative pathways compensating for the function of CET1 or CCM1 in the null mutants. Instead, it appears that C. albicans can survive with modified mRNA cap structures.

Two proteins that form a complex are required for 7-methylguanosine modification of yeast tRNA

7-methylguanosine (m7G) modification of tRNA occurs widely in eukaryotes and bacteria, is nearly always found at position 46, and is one of the few modifications that confers a positive charge to the base. Screening of a Saccharomyces cerevisiae genomic library of purified GST-ORF fusion proteins reveals two previously uncharacterized proteins that copurify with m7G methyltransferase activity on pre-tRNA(Phe). ORF YDL201w encodes Trm8, a protein that is highly conserved in prokaryotes and eukaryotes and that contains an S-adenosylmethionine binding domain. ORF YDR165w encodes Trm82, a less highly conserved protein containing putative WD40 repeats, which are often implicated in macromolecular interactions. Neither protein has significant sequence similarity to yeast Abd1, which catalyzes m7G modification of the 5' cap of mRNA, other than the methyltransferase motif shared by Trm8 and Abd1. Several lines of evidence indicate that both Trm8 and Trm82 proteins are required for tRNA m7G-methyltransferase activity: Extracts derived from strains lacking either gene have undetectable m7G methyltransferase activity, RNA from strains lacking either gene have much reduced m7G, and coexpression of both proteins is required to overproduce activity. Aniline cleavage mapping shows that Trm8/Trm82 proteins modify pre-tRNAPhe at G46, the site that is modified in vivo. Trm8 and Trm82 proteins form a complex, as affinity purification of Trm8 protein causes copurification of Trm82 protein in approximate equimolar yield. This functional two-protein family appears to be retained in eukaryotes, as expression of both corresponding human proteins, METTL1 and WDR4, is required for m7G-methyltransferase activity.

Comparative genomics and evolution of proteins involved in RNA metabolism

RNA metabolism, broadly defined as the compendium of all processes that involve RNA, including transcription, processing and modification of transcripts, translation, RNA degradation and its regulation, is the central and most evolutionarily conserved part of cell physiology. A comprehensive, genome-wide census of all enzymatic and non-enzymatic protein domains involved in RNA metabolism was conducted by using sequence profile analysis and structural comparisons. Proteins related to RNA metabolism comprise from 3 to 11% of the complete protein repertoire in bacteria, archaea and eukaryotes, with the greatest fraction seen in parasitic bacteria with small genomes. Approximately one-half of protein domains involved in RNA metabolism are present in most, if not all, species from all three primary kingdoms and are traceable to the last universal common ancestor (LUCA). The principal features of LUCA's RNA metabolism system were reconstructed by parsimony-based evolutionary analysis of all relevant groups of orthologous proteins. This reconstruction shows that LUCA possessed not only the basal translation system, but also the principal forms of RNA modification, such as methylation, pseudouridylation and thiouridylation, as well as simple mechanisms for polyadenylation and RNA degradation. Some of these ancient domains form paralogous groups whose evolution can be traced back in time beyond LUCA, towards low-specificity proteins, which probably functioned as cofactors for ribozymes within the RNA world framework. The main lineage-specific innovations of RNA metabolism systems were identified. The most notable phase of innovation in RNA metabolism coincides with the advent of eukaryotes and was brought about by the merge of the archaeal and bacterial systems via mitochondrial endosymbiosis, but also involved emergence of several new, eukaryote-specific RNA-binding domains. Subsequent, vast expansions of these domains mark the origin of alternative splicing in animals and probably in plants. In addition to the reconstruction of the evolutionary history of RNA metabolism, this analysis produced numerous functional predictions, e.g. of previously undetected enzymes of RNA modification.

RNA triphosphatase is essential in Schizosaccharomyces pombe and Candida albicans

BACKGROUND

The first two steps in the capping of cellular mRNAs are catalyzed by the enzymes RNA triphosphatase and RNA guanylyltransferase. Although structural and mechanistic differences between fungal and mammalian RNA triphosphatases recommend this enzyme as a potential antifungal target, it has not been determined if RNA triphosphatase is essential for the growth of fungal species that cause human disease.

RESULTS

We show by classical genetic methods that the triphosphatase (Pct1) and guanylyltransferase (Pce1) components of the capping apparatus in the fission yeast Schizosaccharomyces pombe are essential for growth. We were unable to disrupt both alleles of the Candida albicans RNA triphosphatase gene CaCET1, implying that the RNA triphosphatase enzyme is also essential for growth of C. albicans, a human fungal pathogen.

CONCLUSIONS

Our results provide the first genetic evidence that cap synthesis is essential for growth of an organism other than Saccharomyces cerevisiae and they validate RNA triphosphatase as a target for antifungal drug discovery.

Effects of alanine cluster mutations in the D12 subunit of vaccinia virus mRNA (guanine-N7) methyltransferase

The (guanine-N7)-methyltransferase domain of the vaccinia virus mRNA capping enzyme is a heterodimer composed of a catalytic subunit D1(498-844) bound to a stimulatory subunit D12. To identify structural elements of the 287-amino-acid D12 subunit that participate in binding and activation of the catalytic subunit, we introduced 12 double-alanine mutations at vicinal residues that are conserved in the D12 homologs of other vertebrate poxviruses. His-tagged D12 mutants were coexpressed in bacteria with the D1(498-544) subunit, and the recombinant D1(498-844)/His-D12 heterodimers were purified. Eight of the mutants (K111A-R112A, N120A-N121A, N126A-N127A, F141A-R142A, K223A-D224A, H260A-S261A, E275A-N276A, and R280A-R281A) had no significant effect on methyltransferase activity. Three of the mutants (L61A-K62A, F176A-K177A, and F245A-L246A) displayed an intermediate level of cap methylation (35-50% of wild-type activity). Only one mutation, N42A-Y43A, elicited a significant loss of the methyltransferase activation function (<20% of the wild-type activity). Nine of the D12-Ala/Ala proteins were produced individually in bacteria and tested for reconstitution of methyltransferase activity in vitro by mixing with the catalytic subunit. K111A-R112A, N120A-N121A, F176A-K177A, F245A-L246A, and L61A-K62A displayed diminished affinity for the D1 catalytic subunit. N42A-Y43A was uniquely defective in its ability to activate cap methylation by the catalytic subunit. Our results suggest that the methyltransferase activation function of D12, though clearly dependent on the physical interaction with D1, also requires constituents of D12 that are engaged specifically in catalysis.

Characterization of the mRNA capping apparatus of Candida albicans

The mRNA capping apparatus of the pathogenic fungus Candida albicans consists of three components: a 520- amino acid RNA triphosphatase (CaCet1p), a 449-amino acid RNA guanylyltransferase (Cgt1p), and a 474-amino acid RNA (guanine-N7-)-methyltransferase (Ccm1p). The fungal guanylyltransferase and methyltransferase are structurally similar to their mammalian counterparts, whereas the fungal triphosphatase is mechanistically and structurally unrelated to the triphosphatase of mammals. Hence, the triphosphatase is an attractive antifungal target. Here we identify a biologically active C-terminal domain of CaCet1p from residues 202 to 520. We find that CaCet1p function in vivo requires the segment from residues 202 to 256 immediately flanking the catalytic domain from 257 to 520. Genetic suppression data implicate the essential flanking segment in the binding of CaCet1p to the fungal guanylyltransferase. Deletion analysis of the Candida guanylyltransferase demarcates an N-terminal domain, Cgt1(1-387)p, that suffices for catalytic activity in vitro and for cell growth. An even smaller domain, Cgt1(1-367)p, suffices for binding to the guanylyltransferase docking site on yeast RNA triphosphatase. Deletion analysis of the cap methyltransferase identifies a C-terminal domain, Ccm1(137-474)p, as being sufficient for cap methyltransferase function in vivo and in vitro. Ccm1(137-474)p binds in vitro to synthetic peptides comprising the phosphorylated C-terminal domain of the largest subunit of RNA polymerase II. Binding is enhanced when the C-terminal domain is phosphorylated on both Ser-2 and Ser-5 of the YSPTSPS heptad repeat. We show that the entire three-component Saccharomyces cerevisiae capping apparatus can be replaced by C. albicans enzymes. Isogenic yeast cells expressing "all-Candida" versus "all-mammalian" capping components can be used to screen for cytotoxic agents that specifically target the fungal capping enzymes.

Cap methyltransferase selective binding and methylation of GpppG-RNA are stimulated by importin-alpha

We screened a human cDNA library for proteins that bind mRNA cap methyltransferase (MT) and isolated nuclear transporter importin-alpha (Impalpha). This direct association was confirmed by glutathione S-transferase (GST) pulldown, coimmunoprecipitation, and nuclear colocalization. In gel shift assays, MT selectively bound RNA containing 5'-terminal GpppG, and binding was inhibited by GpppG and not by m(7)GpppC. Impalpha markedly enhanced MT binding to GpppG-RNA and stimulated MT activity. MT/RNA/Impalpha complexes were dissociated by importin-beta, which also blocked the stimulation of cap methylation by Impalpha. The presence of RanGTP but not RanGDP prevented these effects of importin-beta. These findings indicate that importins play a novel role in mRNA biogenesis at the level of cap methylation.

The essential interaction between yeast mRNA capping enzyme subunits is not required for triphosphatase function in vivo

The Saccharomyces cerevisiae mRNA capping enzyme consists of two subunits: an RNA 5'-triphosphatase (Cet1) and an mRNA guanylyltransferase (Ceg1). In yeast, the capping enzyme is recruited to the RNA polymerase II (Pol II) transcription complex via an interaction between Ceg1 and the phosphorylated carboxy-terminal domain of the Pol II largest subunit. Previous in vitro experiments showed that the Cet1 carboxy-terminal region (amino acids 265 to 549) carries RNA triphosphatase activity, while the region containing amino acids 205 to 265 of Cet1 has two functions: it mediates dimerization with Ceg1, but it also allosterically activates Ceg1 guanylyltransferase activity in the context of Pol II binding. Here we characterize several Cet1 mutants in vivo. Mutations or deletions of Cet1 that disrupt interaction with Ceg1 are lethal, showing that this interaction is essential for proper capping enzyme function in vivo. Remarkably, the interaction region of Ceg1 becomes completely dispensable when Ceg1 is substituted by the mouse guanylyltransferase, which does not require allosteric activation by Cet1. Although no interaction between Cet1 and mouse guanylyltransferase is detectable, both proteins are present at yeast promoters in vivo. These results strongly suggest that the primary physiological role of the Ceg1-Cet1 interaction is to allosterically activate Ceg1, rather than to recruit Cet1 to the Pol II complex.

Structure-function analysis of yeast mRNA cap methyltransferase and high-copy suppression of conditional mutants by AdoMet synthase and the ubiquitin conjugating enzyme Cdc34p

Here we present a genetic analysis of the yeast cap-methylating enzyme Abd1p. To identify individual amino acids required for Abd1p function, we introduced alanine mutations at 35 positions of the 436-amino acid yeast protein. Two new recessive lethal mutations, F256A and Y330A, were identified. Alleles F256L and Y256L were viable, suggesting that hydrophobic residues at these positions sufficed for Abd1p function. Conservative mutations of Asp-178 established that an acidic moiety is essential at this position (i.e. , D178E was viable whereas D178N was not). Phe-256, Tyr-330, and Asp-178 are conserved in all known cellular cap methyltransferases. We isolated temperature-sensitive abd1 alleles and found that abd1-ts cells display a rapid shut-off of protein synthesis upon shift to the restrictive temperature, without wholesale reduction in steady-state mRNA levels. These in vivo results are consistent with classical biochemical studies showing a requirement for the cap methyl group in cap-dependent translation. We explored the issue of how cap methylation might be regulated in vivo by conducting a genetic screen for high-copy suppressors of the ts growth defect of abd1 mutants. The identification of the yeast genes SAM2 and SAM1, which encode AdoMet synthase, as abd1 suppressors suggests that Abd1p function can be modulated by changes in the concentration of its substrate AdoMet. We also identified the ubiquitin conjugating enzyme Cdc34p as a high-copy abd1 suppressor. We show that mutations of Cdc34p that affect its ubiquitin conjugation activity or its capacity to interact with the E3-SCF complex abrogate its abd1 suppressor function. Moreover, the growth defect of abd1 mutants is exacerbated by cdc34-2. These findings suggest a novel role for Cdc34p in gene expression and engender a model whereby cap methylation or cap utilization is negatively regulated by a factor that is degraded when Cdc34p is overexpressed.

Hsl7p, the yeast homologue of human JBP1, is a protein methyltransferase

The yeast protein Hsl7p is a homologue of Janus kinase binding protein 1, JBP1, a newly characterized protein methyltransferase. In this report, Hsl7p also is shown to be a methyltransferase. It can be crosslinked to [(3)H]S-adenosylmethionine and exhibits in vitro protein methylation activity. Calf histones H2A and H4 and bovine myelin basic protein were methylated by Hsl7p, whereas histones H1, H2B, and H3 and bovine cytochrome c were not. We demonstrated that JBP1 can complement Saccharomyces cerevisiae with a disrupted HSL7 gene as judged by a reduction of the elongated bud phenotype, and a point mutation in the JBP1 S-adenosylmethionine consensus binding sequence eliminated all complementation by JBP1. Therefore, we conclude the yeast protein Hsl7p is a sequence and functional homologue of JBP1. These data provide evidence for an intricate link between protein methylation and macroscopic changes in yeast morphology.

A yeast-based genetic system for functional analysis of viral mRNA capping enzymes

Virus-encoded mRNA capping enzymes are attractive targets for antiviral therapy, but functional studies have been limited by the lack of genetically tractable in vivo systems that focus exclusively on the RNA-processing activities of the viral proteins. Here we have developed such a system by engineering a viral capping enzyme-vaccinia virus D1(1-545)p, an RNA triphosphatase and RNA guanylyltransferase-to function in the budding yeast Saccharomyces cerevisiae in lieu of the endogenous fungal triphosphatase (Cet1p) and guanylyltransferase (Ceg1p). This was accomplished by fusion of D1(1-545)p to the C-terminal guanylyltransferase domain of mammalian capping enzyme, Mce1(211-597)p, which serves as a vehicle to target the viral capping enzyme to the RNA polymerase II elongation complex. An inactivating mutation (K294A) of the mammalian guanylyltransferase active site in the fusion protein had no impact on genetic complementation of cet1Deltaceg1Delta cells, thus proving that (i) the viral guanylyltransferase was active in vivo and (ii) the mammalian domain can serve purely as a chaperone to direct other proteins to the transcription complex. Alanine scanning had identified five amino acids of vaccinia virus capping enzyme-Glu37, Glu39, Arg77, Glu192, and Glu194-that are essential for gamma phosphate cleavage in vitro. Here we show that the introduction of mutation E37A, R77A, or E192A into the fusion protein abrogates RNA triphosphatase function in vivo. The essential residues are located within three motifs that define a family of viral and fungal metal-dependent phosphohydrolases with a distinctive capacity to hydrolyze nucleoside triphosphates to nucleoside diphosphates in the presence of manganese or cobalt. The acidic residues Glu37, Glu39, and Glu192 likely comprise the metal-binding site of vaccinia virus triphosphatase, insofar as their replacement by glutamine abolishes the RNA triphosphatase and ATPase activities.

Single allele knock-out of Candida albicans CGT1 leads to unexpected resistance to hygromycin B and elevated temperature

Almost all eukaryotic mRNAs are capped at their 5'-terminus. Capping is crucial for stability, processing, nuclear export and efficient translation of mRNA. We studied the phenotypic effects elicited by depleting a Candida albicans strain of mRNA 5'-guanylyltransferase (mRNA capping enzyme; CGT1). Construction of a Cgt1-deficient mutant was achieved by URA-blaster-mediated genetic disruption of one allele of the CGT1 gene, which was localized on chromosome III. The resulting heterozygous mutant exhibited an aberrant colony morphology resembling the 'irregular wrinkle' phenotype typically obtained from a normal C. albicans strain upon mild UV treatment. Its level of CGT1 mRNA was reduced two- to fivefold compared to the parental strain. Proteome analysis revealed a large number of differentially expressed proteins confirming the expected pleiotropic effect of CGT1 disruption. The disrupted strain was significantly more resistant to hygromycin B, an antibiotic which decreases translational fidelity, and showed increased resistance to heat stress. Proteome analysis revealed a 50-fold overexpression of Ef-1alphap and a more than sevenfold overexpression of the cell-wall heat-shock protein Ssa2p. Compared to a reference strain, the cgt1/CGT1 heterozygote was equally virulent for mice and guinea pigs when tested in an intravenous infection model of disseminated candidiasis.

Viral and cellular mRNA capping: past and prospects

This chapter focuses on the history of the discovery of cap and an update of research on viral and cellular-messenger RNA (mRNA) capping. Cap structures of the type m⁷ GpppN(m)pN(m)p are present at the 5′ ends of nearly all eukaryotic cellular and viral mRNAs. A cap is added to cellular mRNA precursors and to the transcripts of viruses that replicate in the nucleus during the initial phases of transcription and before other processing events, including internal N⁶A methylation, 3′-poly (A) addition, and exon splicing. Despite the variations on the methylation theme, the important biological consequences of a cap structure appear to correlate with the N⁷-methyl on the 5′-terminal G and the two pyrophosphoryl bonds that connect m⁷G in a 5′–5′ configuration to the first nucleotide of mRNA. In addition to elucidating the biochemical mechanisms of capping and the downstream effects of this 5′- modification on gene expression, the advent of gene cloning has made available an ever-increasing amount of information on the proteins responsible for producing caps and the functional effects of other cap-related interactions. Genetic approaches have demonstrated the lethal consequences of cap failure in yeasts, and complementation studies have shown the evolutionary functional conservation of capping from unicellular to metazoan organisms.

The Candida albicans gene for mRNA 5-cap methyltransferase: identification of additional residues essential for catalysis

The 5'-cap structure of eukaryotic mRNA is methylated at the terminal guanosine by RNA (guanine-N7-)-methyltransferase (cap MTase). Saccharomyces cerevisiae ABD1 (ScABD1) and human hMet (also called CMT1) genes are responsible for this enzyme. The ABD1 homologue was cloned from the pathogenic fungus Candida albicans and named C. albicans ABD1 (CaABD1). When expressed as a fusion with glutathione S-transferase (GST), CaAbd1p displayed cap MTase activity in vitro and rescued S. cerevisiae abd1delta null mutants, indicating that CaABD1 specifies an active cap MTase. Although the human cap MTase binds to the human capping enzyme (Hce1p), which possesses both mRNA guanylyltransferase (mRNA GTase) and mRNA 5'-triphosphatase (mRNA TPase) activities, yeast two-hybrid analysis demonstrated that in yeast neither mRNA GTase nor mRNA TPase physically interacted with the Abd1 protein. Comparison of the amino acid sequences of known and putative cap MTases revealed a highly conserved amino acid sequence motif, Phe/Val-Leu-Asp/Glu-Leu/Met-Xaa-Cys-Gly-Lys-Gly-Gly-Asp-Leu-Xaa-Lys, which encompasses the sequence motif characteristic of divergent methyltransferases. Mutations in CaAbd1p of leucine at the second and the twelfth positions (so far uncharacterized) to alanine severely diminished the enzyme activity and the functionality in vivo, whereas those of leucine at the fourth, cysteine at the sixth, lysine at the eighth, and glycine at the tenth positions did not. Furthermore, valine substitution for the twelfth, but not for the second, leucine in that motif abolished the activity and functionality of CaAbd1p. Thus, it appears that leucine at the second and the twelfth positions in the motif, together with a previously identified acidic residue in the third, glycine at the sixth and glutamic acid at the eleventh positions, play important roles in the catalysis, and that side chain length is crucial for the activity at the twelfth position in the motif.

Characterization of human, Schizosaccharomyces pombe, and Candida albicans mRNA cap methyltransferases and complete replacement of the yeast capping apparatus by mammalian enzymes

Human and fission yeast cDNAs encoding mRNA (guanine-N7) methyltransferase were identified based on similarity of the human (Hcm1p; 476 amino acids) and Schizosaccharomyces pombe (Pcm1p; 389 amino acids) polypeptides to the cap methyltransferase of Saccharomyces cerevisiae (Abd1p). Expression of PCM1 or HCM1 in S. cerevisiae complemented the lethal phenotype resulting from deletion of the ABD1 gene, as did expression of the NH2-terminal deletion mutants PCM1(94-389) and HCM1(121-476). The CCM1 gene encoding Candida albicans cap methyltransferase (Ccm1p; 474 amino acids) was isolated from a C. albicans genomic library by selection for complementation of the conditional growth phenotype of S. cerevisiae abd1-ts mutants. Human cap methyltransferase was expressed in bacteria, purified, and characterized. Recombinant Hcm1p catalyzed quantitative S-adenosylmethionine-dependent conversion of GpppA-capped poly(A) to m7GpppA-capped poly(A). We identified by alanine-scanning mutagenesis eight amino acids (Asp-203, Gly-207, Asp-211, Asp-227, Arg-239, Tyr-289, Phe-291, and Phe-354) that are essential for human cap methyltransferase function in vivo. All eight residues are conserved in other cellular cap methyltransferases. Five of the mutant human proteins (D203A, R239A, Y289A, F291A, and F354A) were expressed in bacteria and found to be defective in cap methylation in vitro. Concordance of mutational effects on Hcm1p, Abd1p, and vaccinia capping enzyme underscores a conserved structural basis for cap methylation in DNA viruses, yeast, and metazoans. This is in contrast to the structural and mechanistic divergence of the RNA triphosphatase components of the yeast and metazoan capping systems. Nevertheless, we demonstrate that the entire three-component yeast capping apparatus, consisting of RNA 5'-triphosphatase (Cet1p), RNA guanylyltransferase (Ceg1p), and Abd1p could be replaced in vivo by the two-component mammalian apparatus consisting of a bifunctional triphosphatase-guanylyltransferase Mce1p and the methyltransferase Hcm1(121-476)p. Isogenic yeast strains with fungal versus mammalian capping systems should facilitate rational screens for antifungal drugs that target cap formation in vivo.

A Saccharomyces cerevisiae RNA 5'-triphosphatase related to mRNA capping enzyme

The Saccharomyces cerevisiae mRNA capping enzyme consists of two subunits: the RNA 5'-triphosphatase (Cet1) and the mRNA guanylyltransferase (Ceg1). Using computer homology searching, a S. cerevisiae gene was identified that encodes a protein resembling the C-terminal region of Cet1. Accordingly, we designated this gene CTL1 (capping enzyme RNAtriphosphatase-like 1). CTL1 is not essential for cell viability and no genetic or physical interactions with the capping enzyme genes were observed. The protein is found in both the nucleus and cytoplasm. Recombinant Ctl1 protein releases gamma-phosphate from the 5'-end of RNA to produce a diphosphate terminus. The enzyme is specific for polynucleotide RNA in the presence of magnesium, but becomes specific for nucleotide triphosphates in the presence of manganese. Ctl1 is the second member of the yeast RNA triphosphatase family, but is probably involved in an RNA processing event other than mRNA capping.

S-Adenosylmethionine-dependent methylation in Saccharomyces cerevisiae. Identification of a novel protein arginine methyltransferase

We used sequence motifs conserved in S-adenosylmethionine-dependent methyltransferases to identify 26 putative methyltransferases from the complete genome of the yeast Saccharomyces cerevisiae. Seven sequences with the best matches to the methyltransferase consensus motifs were selected for further study. We prepared yeast disruption mutants of each of the genes encoding these sequences, and we found that disruption of the YJL125c gene is lethal, whereas disruptions of YCR047c and YDR140w lead to slow growth phenotypes. Normal growth was observed when the YDL201w, YDR465c, YHR209w, and YOR240w genes were disrupted. Initial analysis of protein methylation patterns of all mutants by amino acid analysis revealed that the YDR465c mutant has a defect in the methylation of the delta-nitrogen atom of arginine residues. We propose that YDR465c codes for the methyltransferase responsible for this recently characterized type of protein methylation, and we designate the enzyme as Rmt2 (protein arginine methyltransferase). In addition, we show that the methylation of susceptible residues in Rmt2 substrates is likely to take place on nascent polypeptide chains and that these substrates exist in the cell as fully methylated species. Interestingly, Rmt2 has 27% sequence identity over 138 amino acids to the mammalian guanidinoacetate N-methyltransferase, an enzyme responsible for methylating the delta-nitrogen of the small molecule guanidinoacetate.

RNA 5'-triphosphatase, nucleoside triphosphatase, and guanylyltransferase activities of baculovirus LEF-4 protein

Autographa californica nuclear polyhedrosis virus late and very late mRNAs are transcribed by an RNA polymerase consisting of four virus-encoded polypeptides: LEF-8, LEF-9, LEF-4, and p47. The 464-amino-acid LEF-4 subunit contains the signature motifs of GTP:RNA guanylyltransferases (capping enzymes). Here, we show that the purified recombinant LEF-4 protein catalyzes two reactions involved in RNA cap formation. LEF-4 is an RNA 5'-triphosphatase that hydrolyzes the gamma phosphate of triphosphate-terminated RNA and a guanylyltransferase that reacts with GTP to form a covalent protein-guanylate adduct. The RNA triphosphatase activity depends absolutely on a divalent cation; the cofactor requirement is satisfied by either magnesium or manganese. LEF-4 also hydrolyzes ATP to ADP and Pi (Km = 43 microM ATP; Vmax = 30 s-1) and GTP to GDP and Pi. The LEF-4 nucleoside triphosphatase (NTPase) is activated by manganese or cobalt but not by magnesium. The RNA triphosphatase and NTPase activities of baculovirus LEF-4 resemble those of the vaccinia virus and Saccharomyces cerevisiae mRNA capping enzymes. We suggest that these proteins comprise a novel family of metal-dependent triphosphatases.

Cloning and characterization of three human cDNAs encoding mRNA (guanine-7-)-methyltransferase, an mRNA cap methylase

The mRNA cap structure is synthesized by a series of reactions catalyzed by capping enzyme and mRNA (guanine-7-)-methyltransferase. mRNA (guanine-7-)-methyltransferase catalyzes the methylation of GpppN- at the guanine N7 position, which is an essential step for gene expression in eukaryotic cells. Here we isolated three human cDNAs encoding mRNA (guanine-7-)-methyltransferase termed hCMT1a, hCMT1b and hCMT1c. hCMT1a and hCMT1b encode 476 and 504 amino acids, respectively, and differ only at the region coding for the C-terminal portion of the enzyme after amino acid residue 465. The third cDNA hCMT1c seems to encode the same polypeptide as hCMT1a, however, the 3'-noncoding region of hCMT1c contains sequences corresponding to part of the C-terminal coding and noncoding regions of hCMT1b thus consisting of a mosaic of hCMT1a and hCMT1b. RT-PCR showed that all 3 types of mRNAs were expressed in every tissue examined. Comparison of the deduced amino acid sequences with those of other viral and cellular enzymes showed the regions which are highly conserved among mRNA (guanine-7-)-methyltransferases. The recombinant hCMT1a expressed in E. coli exhibited mRNA (guanine-7-)-methyltransferase activity. On the other hand, neither mRNA (guanine-7-)-methyltransferase nor mRNA (nucleoside-2'-O-)-methyltransferase activity was detected with the recombinant hCMT1b protein. Although the biological significance of the expression of these three mRNA (guanine-7-)-methyltransferase mRNA species remains unknown at present, the nucleotide sequences suggest that they are produced by alternative RNA splicing.

Binding site for S-adenosyl-L-methionine in a central region of mammalian reovirus lambda2 protein. Evidence for activities in mRNA cap methylation

One or more proteins in mammalian reovirus core particles mediate two RNA methylation activities, (guanosine-7-N)-methyltransferase and (guanosine-2'-O)-methyltransferase, that contribute to forming the 5' cap 1 structure on viral mRNA. We used UV irradiation to identify core proteins that bind S-adenosyl-L-methionine (SAM), the methyl-group donor for both methyltransferases. A [methyl-3H]SAM-binding site was observed among the reovirus lambda proteins; was shown to be specific by competition with low levels of S-adenosyl-L-homocysteine, the product of methyl-group transfer from SAM; and was subsequently localized to protein lambda2. lambda2 mediates the guanylyltransferase reaction in cap formation and was previously proposed to mediate one or both methylation reactions as well. SAM binding was demonstrated for both lambda2 in cores and lambda2 expressed in insect cells from a recombinant baculovirus. Using three different methods to cleave lambda2, a binding site for SAM was tentatively localized to a central region of lambda2, between residues 792 and 1100, which includes a smaller region with sequence similarity to the SAM-binding pocket of other methyltransferases. Alanine substitutions at positions 827 and 829 within this predicted binding region greatly reduced the capacity of baculovirus-expressed lambda2 protein to undergo UV cross-linking to SAM but had no effects on either the guanylyltransferase activity of this protein or its conformation as judged by partial proteolysis, suggesting that one or both of these residues is essential for SAM binding. Based on these findings, we propose that the two methyltransferase activities involved in mRNA capping by reovirus cores utilize a single SAM-binding pocket within a central region of lambda2.

Characterization of a baculovirus-encoded RNA 5'-triphosphatase

Autographa californica nuclear polyhedrosis virus (AcNPV) encodes a 168-amino-acid polypeptide that contains the signature motif of the superfamily of protein phosphatases that act via a covalent cysteinyl phosphate intermediate. The sequence of the AcNPV phosphatase is similar to that of the RNA triphosphatase domain of the metazoan cellular mRNA capping enzyme. Here, we show that the purified recombinant AcNPV protein is an RNA 5'-triphosphatase that hydrolyzes the gamma-phosphate of triphosphate-terminated poly(A); it also hydrolyzes ATP to ADP and GTP to GDP. The phosphatase sediments as two discrete components in a glycerol gradient: a 9.5S oligomer and 2.5S putative monomer. The 2.5S form of the enzyme releases 32Pi from 1 microM gamma-32P-labeled triphosphate-terminated poly(A) with a turnover number of 52 min-1 and converts ATP to ADP with Vmax of 8 min-1 and Km of 25 microM ATP. The 9.5S oligomeric form of the enzyme displays an initial pre-steady-state burst of ADP and Pi formation, which is proportional to and stoichiometric with the enzyme, followed by a slower steady-state rate of product formation (approximately 1/10 of the steady-state rate of the 2.5S enzyme). We surmise that the oligomeric enzyme is subject to a rate-limiting step other than reaction chemistry and that this step is either distinct from or slower than the rate-limiting step for the 2.5S enzyme. Replacing the presumptive active site nucleophile Cys-119 by alanine abrogates RNA triphosphatase and ATPase activity. Our findings raise the possibility that baculoviruses encode enzymes that cap the 5' ends of viral transcripts synthesized at late times postinfection by a virus-encoded RNA polymerase.

Recombinant human mRNA cap methyltransferase binds capping enzyme/RNA polymerase IIo complexes

Guanine N-7 methylation is an essential step in the formation of the m7GpppN cap structure that is characteristic of eukaryotic mRNA 5' ends. The terminal 7-methylguanosine is recognized by cap-binding proteins that facilitate key events in gene expression including mRNA processing, transport, and translation. Here we describe the cloning, primary structure, and properties of human RNA (guanine-7-)methyltransferase. Sequence alignment of the 476-amino acid human protein with the corresponding yeast ABD1 enzyme demonstrated the presence of several conserved motifs known to be required for methyltransferase activity. We also identified a Drosophila open reading frame that encodes a putative RNA (guanine-7-)methyltransferase and contains these motifs. Recombinant human methyltransferase transferred a methyl group from S-adenosylmethionine to GpppG 5'ends, which are formed on RNA polymerase II transcripts by the sequential action of RNA 5'-triphosphatase and guanylyltransferase activities in the bifunctional mammalian capping enzyme. Binding studies demonstrated that the human cap methyltransferase associated with recombinant capping enzyme. Consistent with selective capping of RNA polymerase II transcripts, methyltransferase also formed ternary complexes with capping enzyme and the elongating form of RNA polymerase II.

Trypanosome capping enzymes display a novel two-domain structure

The ubiquitous m7G cap of eukaryotic mRNAs and of precursors to the spliceosomal small nuclear RNAs (snRNAs) is the result of an essential RNA modification acquired during transcript elongation. In trypanosomes, the m7G cap is restricted to the spliced leader (SL) RNA and the precursors of U2, U3, and U4 snRNAs. mRNA capping in these organisms occurs posttranscriptionally by trans splicing, which transfers the capped SL sequence to the 5' ends of all mRNAs. The SL cap is the most elaborate cap structure known in nature and has been shown to consist of an m7G residue followed by four methylated nucleotides. Using Crithidia fasciculata, we have characterized and purified the guanylyltransferase (capping enzyme), which transfers GMP from GTP to the diphosphate end of RNA. The corresponding gene codes for a protein of 697 amino acids, with the carboxy-terminal half of the C. fasciculata guanylyltransferase containing the six signature motifs previously identified in yeast capping enzymes. The amino-terminal half contains a domain that displays no resemblance to any other domain associated with capping enzymes. Intriguingly, this region harbors a consensus sequence for a phosphate-binding loop which is found in ATP- and GTP-binding proteins. This two-domain structure is also present in the Trypanosoma brucei capping enzyme, which shows 44% overall identity with the C. fasciculata capping enzyme. Thus, this structure appears to be common to all trypanosomatid protozoa and defines a novel class of capping enzymes.

Accelerated mRNA decay in conditional mutants of yeast mRNA capping enzyme

Current models of mRNA decay in yeast posit that 3' deadenylation precedes enzymatic removal of the 5' cap, which then exposes the naked end to 5' exonuclease action. Here, we analyzed gene expression in Saccharomyces cerevisiae cells bearing conditional mutations of Ceg1 (capping enzyme), a 52 kDa protein that transfers GMP from GTP to the 5' end of mRNA to form the GpppN cap structure. Shift of ceg1 mutants to restrictive temperature elicited a rapid decline in the rate of protein synthesis, which correlated with a sharp reduction in the steady-state levels of multiple individual mRNAs. ceg1 mutations prevented the accumulation of SSA1 and SSA4 mRNAs that were newly synthesized at the restrictive temperature. Uncapped poly(A)+ SSA4 mRNA accumulated in cells lacking the 5' exoribonuclease Xrn1. These findings provide genetic evidence for the long-held idea that the cap guanylate is critical for mRNA stability. The deadenylation-decapping-degradation pathway appears to be short-circuited when Ceg1 is inactivated.

Effects of deletion mutations in the yeast Ces1 protein on cell growth and morphology and on high copy suppression of mutations in mRNA capping enzyme and translation initiation factor 4A

The homologous Saccharomyces cerevisiae genes CES1 and CES4 act as high copy suppressors of temperature-sensitive mutations of Ceg1p, the yeast mRNA capping enzyme. Neither CES1 nor CES4 is essential for cell growth. We find that a double deletion mutant (Delta ces1 Delta ces4 ) grows at 25-37 degrees C, but not at 16 degrees C. Delta ces1 Delta ces4 cells display gross defects in cell shape and budding even at permissive temperatures. Functional analysis of CES1 deletion mutants defines a 145 amino acid C-terminal segment of the 915 amino acid Ces1 protein that is necessary and sufficient to complement the Delta ces1 Delta ces 4 cold-sensitive phenotype, to restore normal morphology and to suppress the temparature-sensitive mutant ceg1-25 . A 147 amino acid C-terminal segment of the 942 amino acid Ces4 protein is sufficient to carry out these same functions. Within this carboxyl domain Ces1p and Ces4p are 80% identical to one another. We report isolation of CES1 in a separate screen for high copy suppression of a temperature-sensitive mutation (A79V) of the yeast translation initiation factor Tif1p (eIF-4A). Deletion of the N-terminal 249 amino acids of Ces1p abolished tif1-A79V suppressor function. CES4 on a multicopy plasmid was unable to suppress tif1-A79V . We surmise that whereas the carboxyl domains of Ces1p and Ces4p are functionally redundant in controlling cell morphology and in suppressing ceg1-25 , full-length Ces1p and Ces4p evince distinct genetic interactions that are likely mediated by their N-terminal segments.

5'-Capping enzymes are targeted to pre-mRNA by binding to the phosphorylated carboxy-terminal domain of RNA polymerase II

We have investigated the role of the RNA Polymerase II (Pol II) carboxy-terminal domain (CTD) in mRNA 5' capping. Transcripts made in vivo by Pol II with a truncated CTD had a lower proportion of capped 5' ends than those made by Pol II with a full-length CTD. In addition, the enzymes responsible for cap synthesis, RNA guanylyltransferase, and RNA (guanine-7)-methyltransferase bound directly to the phosphorylated, but not to the nonphosphorylated, form of the CTD in vitro. These results suggest that: (1) Pol II-specific capping of nascent transcripts in vivo is enhanced by recruitment of the capping enzymes to the CTD and (2) capping is co-ordinated with CTD phosphorylation.

Structure-function analysis of the triphosphatase component of vaccinia virus mRNA capping enzyme

The N-terminal 60 kDa (amino acids 1 to 545) of the D1 subunit of vaccinia virus mRNA capping enzyme is an autonomous bifunctional domain with triphosphatase and guanylyltransferase activities. We previously described two alanine cluster mutations, R77 to A (R77A)-K79A and E192A-E194A, which selectively inactivated the triphosphatase component. Here, we characterize the activities of 11 single alanine mutants-E37A, E39A, Q60A, E61A, T67A, T69A, K75A, R77A, K79A, E192A, and E194A-and a quadruple mutant in which four residues (R77, K79, E192, and E194) were replaced by alanine. We report that Glu-37, Glu-39, Arg-77, Glu-192, and Glu-194 are essential for gamma-phosphate cleavage. The five essential residues are conserved in the capping enzymes of Shope fibroma virus, molluscum contagiosum virus, and African swine fever virus. Probing the structure of D1(1-545) by limited V8 proteolysis suggested a bipartite subdomain structure. The essential residue Glu-192 is the principal site of V8 cleavage. Secondary cleavage by V8 occurs at the essential residue Glu-39. The triphosphatase-defective quadruple mutant transferred GMP to the triphosphate end of poly(A) to form a tetraphosphate cap structure, GppppA. We report that GppppA-capped RNA is a poor substrate for cap methylation by the vaccinia virus and Saccharomyces cerevisiae RNA (guanine-7) methyltransferases. The transcription termination factor activity of the D1-D12 capping enzyme heterodimer was not affected by mutations that abrogated ATPase activity. Thus, the capping enzyme is not responsible for the requirement for ATP hydrolysis during transcription termination.

Phylogeny of mRNA capping enzymes

The m7GpppN cap structure of eukaryotic mRNA is formed cotranscriptionally by the sequential action of three enzymes: RNA triphosphatase, RNA guanylyltransferase, and RNA (guanine-7)-methyltransferase. A multifunctional polypeptide containing all three active sites is encoded by vaccinia virus. In contrast, fungi and Chlorella virus encode monofunctional guanylyltransferase polypeptides that lack triphosphatase and methyltransferase activities. Transguanylylation is a two-stage reaction involving a covalent enzyme-GMP intermediate. The active site is composed of six protein motifs that are conserved in order and spacing among yeast and DNA virus capping enzymes. We performed a structure-function analysis of the six motifs by targeted mutagenesis of Ceg1, the Saccharomyces cerevisiae guanylyltransferase. Essential acidic, basic, and aromatic functional groups were identified. The structural basis for covalent catalysis was illuminated by comparing the mutational results with the crystal structure of the Chlorella virus capping enzyme. The results also allowed us to identify the capping enzyme of Caenorhabditis elegans. The 573-amino acid nematode protein consists of a C-terminal guanylyltransferase domain, which is homologous to Ceg1 and is strictly conserved with respect to all 16 amino acids that are essential for Ceg1 function, and an N-terminal phosphatase domain that bears no resemblance to the vaccinia triphosphatase domain but, instead, has strong similarity to the superfamily of protein phosphatases that act via a covalent phosphocysteine intermediate.

The role of the cap structure in RNA processing and nuclear export

The cap structure that is characteristic of all polymerase-II-transcribed RNAs has been shown to play an important role in many aspects of RNA metabolism including RNA processing, RNA nuclear transport, and translation initiation. The effects of the cap structure on these different processes is mediated by proteins that recognise and bind to it, and are therefore generically called cap-binding proteins. For example, the cap-binding protein eIF4E, in a complex with other proteins, mediates the effect of the cap on the initiation of translation. EIF-4E is predominantly localised in the cytoplasm. In the last five years, it has been demonstrated that a second cap-binding protein complex, which is mainly localised in the nucleus, mediates the stimulatory effects of the cap in nuclear processes such as pre-mRNA splicing, RNA 3'-end formation, and RNA nuclear export. The purpose of this review is to summarise our current knowledge on the role of the cap structure and of the cap-binding protein complex in nuclear RNA metabolism and present evidence that at least some processes may be coupled in vivo.

An RNA 5'-triphosphatase related to the protein tyrosine phosphatases

mRNA capping requires the sequential action of three enzymatic activities: RNA triphosphatase, guanylyl-transferase, and methyltransferase. Here we characterize a gene (CEL-1) believed to encode the C. elegans capping enzyme. CEL-1 has a C-terminal domain containing motifs found in yeast and vaccinia virus capping enzyme guanylyltransferases. The N-terminal domain of CEL-1 has RNA triphosphatase activity. Surprisingly, this domain does not resemble the vaccinia virus capping enzyme but does have significant sequence similarity to the protein tyrosine phosphatase (PTP) enzyme family. However, CEL-1 has no detectable PTP activity. The mechanism of the RNA triphosphatase is similar to that of PTPs: the active site contains a conserved nucleophilic cysteine required for activity. These results broaden the superfamily of PTP-like phosphatases to include enzymes with RNA substrates.

Structure-function analysis of the mRNA cap methyltransferase of Saccharomyces cerevisiae

The Saccharomyces cerevisiae mRNA cap methylating enzyme is a 436-amino acid protein encoded by the essential ABD1 gene. To identify structural features of ABD1 required for enzyme function, we introduced alanine mutations at 19 positions within a 205-amino acid region of similarity to the methyltransferase domain of the vaccinia capping enzyme. Three new recessive lethal mutations, E170A, D194A, and R206A, were identified. Structure-function relationships were clarified by introducing conservative substitutions at Glu-170, Asp-194, and Arg-206, and at Tyr-254 (an essential residue identified previously). Alleles E170D and D194E were viable, whereas E170Q and D194N were lethal; hence, acidic side chains were critical at both positions. R206K was viable, suggesting that a basic residue sufficed. Y254S was lethal, whereas Y254F was viable, albeit slow growing; thus, an aromatic side chain was important. The ABD1 mutations that were deleterious in vivo elicited catalytic defects in vitro. By studying the effects of amino- and carboxyl-terminal deletions, we defined a fully active catalytic domain of ABD1 from residues 130 to 426. Residues 110-129 were dispensable for methyltransferase activity in vitro, but essential for function in vivo. This analysis allowed us to delineate a subfamily of ABD1-like proteins within the superfamily of AdoMet-dependent methyltransferases. In addition, we identify a candidate Caenorhabditis elegans gene encoding a putative cap methyltransferase. All residues essential for ABD1 activity are conserved in the C. elegans homologue.

Expression and characterization of an RNA capping enzyme encoded by Chlorella virus PBCV-1

We report that the A103R protein of Chlorella virus PBCV-1 is an mRNA capping enzyme that catalyzes the transfer of GMP from GTP to the 5' diphosphate end of RNA. This is a two-step reaction in which the enzyme first condenses with GTP to form a covalent enzyme-GMP intermediate and then transfers the GMP to an RNA acceptor to form a GpppN cap. Purified recombinant Al03R is a 38-kDa monomer that lacks RNA (guanine-7-) methyltransferase activity. With respect to its size, amino acid sequence, and biochemical properties, A103R is more closely related to the yeast RNA guanylyltransferases than it is to the multifunctional capping enzymes coded for by other large DNA viruses--the poxviruses and African swine fever virus. We surmise that in order to cap its transcripts, PBCV-l must either encode additional 5' processing activities or else rely on the host alga to provide these functions.

Mutational analysis of the Saccharomyces cerevisiae ABD1 gene: cap methyltransferase activity is essential for cell growth

RNA (guanine-7-)-methyltransferase is the enzyme responsible for methylating the 5' cap structure of eukaryotic mRNA. The Saccharomyces cerevisiae enzyme is a 436-amino-acid protein encoded by the essential ABD1 gene. In this study, deletion and point mutations in ABD1 were tested for the ability to support growth of an abd1 null strain. Elimination of 109 amino acids from the N terminus had no effect on cell viability, whereas a more extensive N-terminal deletion of 155 residues was lethal, as was a C-terminal deletion of 55 amino acids. Alanine substitution mutations were introduced at eight conserved residues within a 206-amino-acid region of similarity between ABD1 and the methyltransferase domain of the vaccinia virus capping enzyme. ABD1 alleles H253A (encoding a substitution of alanine for histidine at position 253), T282A, E287A, E361A, and Y362A were viable, whereas G174A, D178A, and Y254A were either lethal or severely defective for growth. Alanine-substituted and amino-truncated ABD1 proteins were expressed in bacteria, purified, and tested for cap methyltransferase activity in vitro. Mutations that were viable in yeast cells had either no effect or only a moderate effect on the specific methyltransferase activity of the mutated ABD1 protein, whereas mutations that were deleterious in vivo yielded proteins that were catalytically defective in vitro. These findings substantiate for the first time the long-held presumption that cap methylation is an essential function in eukaryotic cells.