Structure and mechanism of yeast RNA triphosphatase: an essential component of the mRNA capping apparatus

RNA triphosphatase is an essential mRNA processing enzyme that catalyzes the first step in cap formation. The 2.05 A crystal structure of yeast RNA triphosphatase Cet1p reveals a novel active site fold whereby an eight-stranded beta barrel forms a topologically closed triphosphate tunnel. Interactions of a sulfate in the center of the tunnel with a divalent cation and basic amino acids projecting into the tunnel suggest a catalytic mechanism that is supported by mutational data. Discrete surface domains mediate Cet1p homodimerization and Cet1p binding to the guanylyltransferase component of the capping apparatus. The structure and mechanism of fungal RNA triphosphatases are completely different from those of mammalian mRNA capping enzymes. Hence, RNA triphosphatase presents an ideal target for structure-based antifungal drug discovery.     

Importance of homodimerization for the in vivo function of yeast RNA triphosphatase

Saccharomyces cerevisiae RNA triphosphatase Cet1 is an essential component of the yeast mRNA capping apparatus. The active site of Cet1 resides within a topologically closed hydrophilic beta-barrel (the triphosphate tunnel) that is supported by a globular hydrophobic core. The homodimeric quaternary structure of Cet1 is formed by a network of contacts between the partner protomers. By studying the effects of alanine-cluster mutations, we highlight the contributions of two separate facets of the crystallographic dimer interface to Cet1 function in vivo. One essential facet of the interface entails hydrophobic cross-dimer interactions of Cys(330) and Val(331) and a cross-dimer hydrogen bond of Asp(280) with the backbone amide of Gln(329). The second functionally relevant dimer interface involves hydrophobic side-chain interactions of Phe(272) and Leu(273). Ala-cluster mutations involving these residues elicited lethal or severe temperature-sensitive phenotypes that were suppressed completely by fusion of the mutated triphosphatases to the guanylyltransferase domain of mammalian capping enzyme. The recombinant D279A-D280A and F272A-L273A proteins retained phosphohydrolase activity but sedimented as monomers. These results indicate that a disruption of the dimer interface is uniquely deleterious when the yeast RNA triphosphatase must function in concert with the endogenous yeast guanylyltransferase. We also identify key residue pairs in the hydrophobic core of the Cet1 protomer that support the active site tunnel and stabilize the triphosphatase in vivo.     

Chlorella virus RNA triphosphatase. Mutational analysis and mechanism of inhibition by tripolyphosphate

Chlorella virus RNA triphosphatase (cvRtp1) is the smallest member of a family of metal-dependent phosphohydrolases that includes the RNA triphosphatases of fungi, protozoa, poxviruses, and baculoviruses. The primary structure of cvRtp1 is more similar to that of the yeast RNA triphosphatase Cet1 than it is to the RNA triphosphatases of other DNA viruses. To evaluate the higher order structural similarities between cvRtp1 and the fungal enzymes, we performed an alanine scan of individual residues of cvRtp1 that were predicted, on the basis of the crystal structure of Cet1, to be located at or near the active site. Twelve residues (Glu(24), Glu(26), Asp(64), Arg(76), Lys(90), Glu(112), Arg(127), Lys(129), Arg(131), Asp(142), Glu(163), and Glu(165)) were deemed essential for catalysis by cvRtp1, insofar as their replacement by alanine reduced phosphohydrolase activity to <5% of the wild-type value. Structure-activity relationships were elucidated by introducing conservative substitutions at the essential positions. The mutational results suggest that the active site of cvRtp1 is likely to adopt a tunnel fold like that of Cet1 and that a similar constellation of side chains within the tunnel is responsible for metal binding and reaction chemistry. Nonetheless, there are several discordant mutational effects in cvRtp1 versus Cet1, which suggest that different members of the phosphohydrolase family vary in their reliance on certain residues within the active site tunnel. We found that tripolyphosphate and pyrophosphate were potent competitive inhibitors of cvRtp1 (K(i) = 0.6 microm tripolyphosphate and 2.4 microm pyrophosphate, respectively), whereas phosphate had little effect. cvRtp1 displayed a weak intrinsic tripolyphosphatase activity (3% of its ATPase activity) but was unable to hydrolyze pyrophosphate.     

Homodimeric quaternary structure is required for the in vivo function and thermal stability of Saccharomyces cerevisiae and Schizosaccharomyces pombe RNA triphosphatases

Saccharomyces cerevisiae Cet1 and Schizosaccharomyces pombe Pct1 are the essential RNA triphosphatase components of the mRNA capping apparatus of budding and fission yeast, respectively. Cet1 and Pct1 share a baroque active site architecture and a homodimeric quaternary structure. The active site is located within a topologically closed hydrophilic beta-barrel (the triphosphate tunnel) that rests on a globular core domain (the pedestal) composed of elements from both protomers of the homodimer. Earlier studies of the effects of alanine cluster mutations at the crystallographic dimer interface of Cet1 suggested that homodimerization is important for triphosphatase function in vivo, albeit not for catalysis. Here, we studied the effects of 14 single-alanine mutations on Cet1 activity and thereby pinpointed Asp280 as a critical side chain required for dimer formation. We find that disruption of the dimer interface is lethal in vivo and renders Cet1 activity thermolabile at physiological temperatures in vitro. In addition, we identify individual residues within the pedestal domain (Ile470, Leu519, Ile520, Phe523, Leu524, and Ile530) that stabilize Cet1 in vivo and in vitro. In the case of Pct1, we show that dimerization depends on the peptide segment 41VPKIEMNFLN50 located immediately prior to the start of the Pct1 catalytic domain. Deletion of this peptide converts Pct1 into a catalytically active monomer that is defective in vivo in S. pombe and hypersensitive to thermal inactivation in vitro. Our findings suggest an explanation for the conservation of quaternary structure in fungal RNA triphosphatases, whereby the delicate tunnel architecture of the active site is stabilized by the homodimeric pedestal domain.     

Structure-function analysis of Trypanosoma brucei RNA triphosphatase and evidence for a two-metal mechanism

Trypanosoma brucei RNA triphosphatase TbCet1 is a 252-amino acid polypeptide that catalyzes the first step in mRNA cap formation. By performing an alanine scan of TbCet1, we identified six amino acids that are essential for triphosphatase activity (Glu-52, Arg-127, Glu-168, Arg-186, Glu-216, and Glu-218). These results consolidate the proposal that protozoan, fungal, and Chlorella virus RNA triphosphatases belong to a single family of metal-dependent NTP phosphohydrolases with a unique tunnel active site composed of eight beta strands. Limited proteolysis of TbCet1 suggests that the hydrophilic N terminus is surface-exposed, whereas the catalytic core domain is tightly folded with the exception of a protease-sensitive loop (76WKGRRARKT84) between two of the putative tunnel strands. The catalytic domain of TbCet1 is extraordinarily thermostable. It remains active after heating for 2 h at 75 degrees C. Analysis by zonal velocity sedimentation indicates that TbCet1 is a monomeric enzyme, unlike fungal RNA triphosphatases, which are homodimers. We show that tripolyphosphate is a potent competitive inhibitor of TbCet1 (Ki 1.4 microm) that binds more avidly to the active site than the ATP substrate (Km 25 microm). We present evidence of synergistic activation of the TbCet1 triphosphatase by manganese and magnesium, consistent with a two-metal mechanism of catalysis. Our findings provide new insight to the similarities (in active site tertiary structure and catalytic mechanism) and differences (in quaternary structure and thermal stability) among the different branches of the tunnel enzyme family.     

Mapping the triphosphatase active site of baculovirus mRNA capping enzyme LEF4 and evidence for a two-metal mechanism

The 464-amino acid baculovirus LEF4 protein is a bifunctional mRNA capping enzyme with triphosphatase and guanylyltransferase activities. The N-terminal half of LEF4 constitutes an autonomous triphosphatase catalytic domain. The LEF4 triphosphatase belongs to a family of metal-dependent phosphohydrolases, which includes the RNA triphosphatases of fungi, protozoa, Chlorella virus and poxviruses. The family is defined by two glutamate-containing motifs (A and C), which form a metal-binding site. Most of the family members resemble the fungal and Chlorella virus enzymes, which have a complex active site located within the hydrophilic interior of a topologically closed eight stranded β barrel (the so-called ‘triphosphate tunnel’). Here we probed whether baculovirus LEF4 is a member of the tunnel subfamily, via mutational mapping of amino acids required for triphosphatase activity. We identified four new essential side chains in LEF4 via alanine scanning and illuminated structure–activity relationships by conservative substitutions. Our results, together with previous mutational data, highlight five acidic and four basic amino acids that are likely to comprise the LEF4 triphosphatase active site (Glu9, Glu11, Arg51, Arg53, Glu97, Lys126, Arg179, Glu181 and Glu183). These nine essential residues are conserved in LEF4 orthologs from all strains of baculoviruses. We discerned no pattern of clustering of the catalytic residues of the baculovirus triphosphatase that would suggest structural similarity to the tunnel proteins (exclusive of motifs A and C). However, there is similarity to the active site of vaccinia RNA triphosphatase. We infer that the baculovirus and poxvirus triphosphatases are a distinct lineage within the metal-dependent RNA triphosphatase family. Synergistic activation of the LEF4 triphosphatase by manganese and magnesium suggests a two-metal mechanism of γ phosphate hydrolysis.     

Characterization of Candida albicans RNA triphosphatase and mutational analysis of its active site

The RNA triphosphatase component (CaCet1p) of the mRNA capping apparatus of the pathogenic fungus Candida albicans differs mechanistically and structurally from the RNA triphosphatase of mammals. Hence, CaCet1p is an attractive antifungal target. Here we identify a C-terminal catalytic domain of CaCet1p from residue 257 to 520 and characterize a manganese-dependent and cobalt-dependent NTPase activity intrinsic to CaCet1p. The NTPase can be exploited to screen in vitro for inhibitors. The amino acids that comprise the active site of CaCet1p were identified by alanine-scanning mutagenesis, which was guided by the crystal structure of the homologous RNA triphosphatase from Saccharomyces cerevisiae (Cet1p). Thirteen residues required for the phosphohydrolase activity of CaCet1p (Glu287, Glu289, Asp363, Arg379, Lys396, Glu420, Arg441, Lys443, Arg445, Asp458, Glu472, Glu474 and Glu476) are located within the hydrophilic interior of an eight-strand β barrel of Cet1p. Each of the eight strands contributes at least one essential amino acid. The essential CaCet1p residues include all of the side chains that coordinate manganese and sulfate (i.e., γ phosphate) in the Cet1p product complex. These results suggest that the active site structure and catalytic mechanism are conserved among fungal RNA triphosphatases.     

Trypanosoma brucei RNA triphosphatase. Antiprotozoal drug target and guide to eukaryotic phylogeny.

The mRNA capping apparatus of the protozoan parasite Trypanosoma brucei consists of separately encoded RNA triphosphatase and RNA guanylyltransferase enzymes. The triphosphatase TbCet1 is a member of a new family of metal-dependent phosphohydrolases that includes the RNA triphosphatases of fungi and the malaria parasite Plasmodium falciparum. The protozoal/fungal enzymes are structurally and mechanistically unrelated to the RNA triphosphatases of metazoans and plants. These results highlight the potential for discovery of broad spectrum antiprotozoal and antifungal drugs that selectively block the capping of pathogen-encoded mRNAs. We propose a scheme of eukaryotic phylogeny based on the structure of RNA triphosphatase and its physical linkage to the guanylyltransferase component of the capping apparatus.     

Characterization of a trifunctional mimivirus mRNA capping enzyme and crystal structure of the RNA triphosphatase domain

The RNA triphosphatase (RTPase) components of the mRNA capping apparatus are a bellwether of eukaryal taxonomy. Fungal and protozoal RTPases belong to the triphosphate tunnel metalloenzyme (TTM) family, exemplified by yeast Cet1. Several large DNA viruses encode metal-dependent RTPases unrelated to the cysteinyl-phosphatase RTPases of their metazoan host organisms. The origins of DNA virus RTPases are unclear because they are structurally uncharacterized. Mimivirus, a giant virus of amoeba, resembles poxviruses in having a trifunctional capping enzyme composed of a metal-dependent RTPase module fused to guanylyltransferase (GTase) and guanine-N7 methyltransferase domains. The crystal structure of mimivirus RTPase reveals a minimized tunnel fold and an active site strikingly similar to that of Cet1. Unlike homodimeric fungal RTPases, mimivirus RTPase is a monomer. The mimivirus TTM-type RTPase-GTase fusion resembles the capping enzymes of amoebae, providing evidence that the ancestral large DNA virus acquired its capping enzyme from a unicellular host.     

An essential surface motif (WAQKW) of yeast RNA triphosphatase mediates formation of the mRNA capping enzyme complex with RNA guanylyltransferase

Saccharomyces cerevisiae RNA triphosphatase (Cet1p) and RNA guanylyltransferase (Ceg1p) interact in vivo and in vitro to form a bifunctional mRNA capping enzyme complex. Cet1p binding to Ceg1p stimulates the guanylyltransferase activity of Ceg1p. Here we localize the guanylyltransferase-binding and guanylyltransferase-stimulation functions of Cet1p to a 21-amino acid segment from residues 239 to 259. The guanylyltransferase-binding domain is located on the protein surface, as gauged by protease sensitivity, and is conserved in the Candida albicans RNA triphosphatase CaCet1p. Alanine-cluster mutations of a WAQKW motif within this segment abolish guanylyltransferase-binding in vitro and Cet1p function in vivo, but do not affect the triphosphatase activity of Cet1p. Proteolytic footprinting experiments provide physical evidence that Cet1p interacts with the C-terminal domain of Ceg1p. Trypsin-sensitive sites of Ceg1p that are shielded from proteolysis when Ceg1p is bound to Cet1p are located between nucleotidyl transferase motifs V and VI.     

Yeast-like mRNA capping apparatus in Giardia lamblia

A scheme of eukaryotic phylogeny has been suggested based on the structure and physical linkage of the RNA triphosphatase and RNA guanylyltransferase enzymes that catalyze mRNA cap formation. Here we show that the unicellular pathogen Giardia lamblia encodes an mRNA capping apparatus consisting of separate triphosphatase and guanylyltransferase components, which we characterize biochemically. We also show that native Giardia mRNAs have blocked 5'-ends and that 7-methylguanosine caps promote translation of transfected mRNAs in Giardia in vivo. The Giardia triphosphatase belongs to the tunnel family of metal-dependent phosphohydrolases that includes the RNA triphosphatases of fungi, microsporidia, and protozoa such as Plasmodium and Trypanosoma. The tunnel enzymes adopt a unique active-site fold and are structurally and mechanistically unrelated to the cysteine-phosphatase-type RNA triphosphatases found in metazoans and plants, which comprise part of a bifunctional triphosphataseguanylyltransferase fusion protein. All available evidence now points to the separate tunnel-type triphosphatase and guanylyltransferase as the aboriginal state of the capping apparatus. We identify a putative tunnel-type triphosphatase and a separate guanylyltransferase encoded by the red alga Cyanidioschyzon merolae. These findings place fungi, protozoa, and red algae in a common lineage distinct from that of metazoa and plants.     

The archaeal triphosphate tunnel metalloenzyme SaTTM defines structural determinants for the diverse activities in the CYTH protein family

CYTH proteins make up a large superfamily that is conserved in all three domains of life. These enzymes have a triphosphate tunnel metalloenzyme (TTM) fold, which typically results in phosphatase functions, e.g., RNA triphosphatase, inorganic polyphosphatase, or thiamine triphosphatase. Some CYTH orthologs cyclize nucleotide triphosphates to 3′,5′-cyclic nucleotides. So far, archaeal CYTH proteins have been annotated as adenylyl cyclases, although experimental evidence to support these annotations is lacking. To address this gap, we characterized a CYTH ortholog, SaTTM, from the crenarchaeote Sulfolobus acidocaldarius. Our in silico studies derived ten major subclasses within the CYTH family implying a close relationship between these archaeal CYTH enzymes and class IV adenylyl cyclases. However, initial biochemical characterization reveals inability of SaTTM to produce any cyclic nucleotides. Instead, our structural and functional analyses show a classical TTM behavior, i.e., triphosphatase activity, where pyrophosphate causes product inhibition. The Ca²⁺-inhibited Michaelis complex indicates a two-metal-ion reaction mechanism analogous to other TTMs. Cocrystal structures of SaTTM further reveal conformational dynamics in SaTTM that suggest feedback inhibition in TTMs due to tunnel closure in the product state. These structural insights combined with further sequence similarity network–based in silico analyses provide a firm molecular basis for distinguishing CYTH orthologs with phosphatase activities from class IV adenylyl cyclases.     

An essential function of Saccharomyces cerevisiae RNA triphosphatase Cet1 is to stabilize RNA guanylyltransferase Ceg1 against thermal inactivation.

Saccharomyces cerevisiae RNA triphosphatase (Cet1) and RNA guanylyltransferase (Ceg1) interact in vivo and in vitro to form a bifunctional mRNA capping enzyme complex. Here we show that the guanylyltransferase activity of Ceg1 is highly thermolabile in vitro (98% loss of activity after treatment for 10 min at 35 degrees C) and that binding to recombinant Cet1 protein, or a synthetic peptide Cet1(232-265), protects Ceg1 from heat inactivation at physiological temperatures. Candida albicans guanylyltransferase Cgt1 is also thermolabile and is stabilized by binding to Cet1(232-265). In contrast, Schizosaccharomyces pombe and mammalian guanylyltransferases are intrinsically thermostable in vitro and they are unaffected by Cet1(232-265). We show that the requirement for the Ceg1-binding domain of Cet1 for yeast cell growth can be circumvented by overexpression in high gene dosage of a catalytically active mutant lacking the Ceg1-binding site (Cet1(269-549)) provided that Ceg1 is also overexpressed. However, such cells are unable to grow at 37 degrees C. In contrast, cells overexpressing Cet1(269-549) in single copy grow at all temperatures if they express either the S. pombe or mammalian guanylyltransferase in lieu of Ceg1. Thus, the cell growth phenotype correlates with the inherent thermal stability of the guanylyltransferase. We propose that an essential function of the Cet1-Ceg1 interaction is to stabilize Ceg1 guanylyltransferase activity rather than to allosterically regulate its activity. We used protein-affinity chromatography to identify the COOH-terminal segment of Ceg1 (from amino acids 245-459) as an autonomous Cet1-binding domain. Genetic experiments implicate two peptide segments, (287)KPVSLYVW(295) and (337)WQNLKNLEQPLN(348), as likely constituents of the Cet1-binding site on Ceg1.     

Mutational analysis of baculovirus phosphatase identifies structural residues important for triphosphatase activity in vitro and in vivo

Baculovirus phosphatase (BVP) and mammalian capping enzyme (Mce1) are members of the RNA triphosphatase branch of the cysteine phosphatase superfamily. Although RNA triphosphatases have a core alpha/beta fold similar to other cysteine phosphatases, there is little conservation of primary structure outside of the cysteine-containing P-loop motif, HCxxxxxR(S/T), that comprises the active site. However, there is extensive primary structure conservation between members of the RNA triphosphatase branch, whether from cellular or viral sources and whether they are bifunctional capping enzymes such as Mce1 or monofunctional RNA phosphatases such as BVP. To evaluate the functional significance of such sequence conservation, we performed a mutational analysis of 14 residues of BVP. We identified three side chains (Trp6, Lys25, and Arg153) as essential for triphosphatase activity in vitro, i.e., W6A, K25A, and R153A were <0.1% as active as wild-type BVP, and were unable to complement a yeast RNA triphosphatase null mutant in vivo. Six other BVP residues (Thr62, Tyr67, Tyr68, Lys82, Glu158, and Arg159) were deemed functionally important, i.e., Ala mutations reduced triphosphatase activity to <20% of wild-type. On the basis of the locations of the equivalent amino acids in the Mce1 crystal structure, we surmise that the essential/important BVP residues ensure proper conformation of the catalytic P-loop (e.g., Arg153 and Tyr68) or other elements of the tertiary structure. Our results highlight a conserved Trp6-Lys25 pi-cation pair essential for BVP function.     

Structure and mechanism of the RNA triphosphatase component of mammalian mRNA capping enzyme

The 5' capping of mammalian pre-mRNAs is initiated by RNA triphosphatase, a member of the cysteine phosphatase superfamily. Here we report the 1.65 A crystal structure of mouse RNA triphosphatase, which reveals a deep, positively charged active site pocket that can fit a 5' triphosphate end. Structural, biochemical and mutational results show that despite sharing an HCxxxxxR(S/T) motif, a phosphoenzyme intermediate and a core alpha/beta-fold with other cysteine phosphatases, the mechanism of phosphoanhydride cleavage by mammalian capping enzyme differs from that used by protein phosphatases to hydrolyze phosphomonoesters. The most significant difference is the absence of a carboxylate general acid catalyst in RNA triphosphatase. Residues conserved uniquely among the RNA phosphatase subfamily are important for function in cap formation and are likely to play a role in substrate recognition.     

Inhibition of a metal-dependent viral RNA triphosphatase by decavanadate

Paramecium bursaria chlorella virus, a large DNA virus that replicates in unicellular Chlorella-like algae, encodes an RNA triphosphatase which is involved in the synthesis of the RNA cap structure found at the 5' end of the viral mRNAs. The Chlorella virus RNA triphosphatase is the smallest member of the metal-dependent RNA triphosphatases that include enzymes from fungi, DNA viruses, protozoans and microsporidian parasites. In the present study, we investigated the ability of various vanadate oxoanions to inhibit the phosphohydrolase activity of the enzyme. Fluorescence spectroscopy and CD studies were used to directly monitor the binding of decavanadate to the enzyme. Moreover, competition assays show that decavanadate is a potent non-competitive inhibitor of the phosphohydrolase activity, and mutagenesis studies indicate that the binding of decavanadate does not involve amino acids located in the active site of the enzyme. In order to provide additional insight into the relationship between the enzyme structure and decavanadate binding, we correlated the effect of decavanadate binding on protein structure using both CD and guanidinium chloride-induced denaturation as structural indicators. Our data indicated that no significant modification of the overall protein architecture was occurring upon decavanadate binding. However, both fluorescence spectroscopy and CD experiments clearly revealed that the binding of decavanadate to the enzyme significantly decreased the structural stability of the enzyme. Taken together, these studies provide crucial insights into the inhibition of metal-dependent RNA triphosphatases by decavanadate.     

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.     

Characterization of Schizosaccharomyces pombe RNA triphosphatase

RNA triphosphatase catalyzes the first step in mRNA cap formation which entails the cleavage of the β–γ phosphoanhydride bond of triphosphate-terminated RNA to yield a diphosphate end that is then capped with GMP by RNA guanylyltransferase. Here we characterize a 303 amino acid RNA triphosphatase (Pct1p) encoded by the fission yeast Schizosaccharomyces pombe. Pct1p hydrolyzes the γ phosphate of triphosphate-terminated poly(A) in the presence of magnesium. Pct1p also hydrolyzes ATP to ADP and P_i in the presence of manganese or cobalt (K_m = 19 µM ATP; k_cat = 67 s^–1). Hydrolysis of 1 mM ATP is inhibited with increasing potency by inorganic phosphate (I_0.5 = 1 mM), pyrophosphate (I_0.5 = 0.4 mM) and tripolyphosphate (I_0.5 = 30 µM). Velocity sedimentation indicates that Pct1p is a homodimer. Pct1p is biochemically and structurally similar to the catalytic domain of Saccharomyces cerevisiae RNA triphosphatase Cet1p. Mechanistic conservation between Pct1p and Cet1p is underscored by a mutational analysis of the putative metal-binding site of Pct1p. Pct1p is functional in vivo in S.cerevisiae in lieu of Cet1p, provided that it is coexpressed with the S.pombe guanylyltransferase. Pct1p and other yeast RNA triphosphatases are completely unrelated, mechanistically and structurally, to the metazoan RNA triphosphatases, suggesting an abrupt evolutionary divergence of the capping apparatus during the transition from fungal to metazoan species.     

Structure-function analysis of T4 RNA ligase 2

Bacteriophage T4 RNA ligase 2 (Rnl2) exemplifies a polynucleotide ligase family that includes the trypanosome RNA-editing ligases and putative RNA ligases encoded by eukaryotic viruses and archaea. Here we analyzed 12 individual amino acids of Rnl2 that were identified by alanine scanning as essential for strand joining. We determined structure-activity relationships via conservative substitutions and examined mutational effects on the isolated steps of ligase adenylylation and phosphodiester bond formation. The essential residues of Rnl2 are located within conserved motifs that define a superfamily of nucleotidyl transferases that act via enzyme-(lysyl-N)-NMP intermediates. Our mutagenesis results underscore a shared active site architecture in Rnl2-like ligases, DNA ligases, and mRNA capping enzymes. They also highlight two essential signature residues, Glu(34) and Asn(40), that flank the active site lysine nucleophile (Lys(35)) and are unique to the Rnl2-like ligase family.