The HD domain of the Escherichia coli tRNA nucleotidyltransferase has 2',3'-cyclic phosphodiesterase, 2'-nucleotidase, and phosphatase activities

In all mature tRNAs, the 3'-terminal CCA sequence is synthesized or repaired by a template-independent nucleotidyltransferase (ATP(CTP):tRNA nucleotidyltransferase; EC 2.7.7.25). The Escherichia coli enzyme comprises two domains: an N-terminal domain containing the nucleotidyltransferase activity and an uncharacterized C-terminal HD domain. The HD motif defines a superfamily of metal-dependent phosphohydrolases that includes a variety of uncharacterized proteins and domains associated with nucleotidyltransferases and helicases from bacteria, archaea, and eukaryotes. The C-terminal HD domain in E. coli tRNA nucleotidyltransferase demonstrated Ni(2+)-dependent phosphatase activity toward pyrophosphate, canonical 5'-nucleoside tri- and diphosphates, NADP, and 2'-AMP. Assays with phosphodiesterase substrates revealed surprising metal-independent phosphodiesterase activity toward 2',3'-cAMP, -cGMP, and -cCMP. Without metal or in the presence of Mg(2+), the tRNA nucleotidyltransferase hydrolyzed 2',3'-cyclic substrates with the formation of 2'-nucleotides, whereas in the presence of Ni(2+), the protein also produced some 3'-nucleotides. Mutations at the conserved His-255 and Asp-256 residues comprising the C-terminal HD domain of this protein inactivated both phosphodiesterase and phosphatase activities, indicating that these activities are associated with the HD domain. Low concentrations of the E. coli tRNA (10 nm) had a strong inhibiting effect on both phosphatase and phosphodiesterase activities. The competitive character of inhibition by tRNA suggests that it might be a natural substrate for these activities. This inhibition was completely abolished by the addition of Mg(2+), Mn(2+), or Ca(2+), but not Ni(2+). The data suggest that the phosphohydrolase activities of the HD domain of the E. coli tRNA nucleotidyltransferase are involved in the repair of the 3'-CCA end of tRNA.     

Closely related CC- and A-adding enzymes collaborate to construct and repair the 3'-terminal CCA of tRNA in Synechocystis sp. and Deinococcus radiodurans

The 3'-terminal CCA sequence of tRNA is faithfully constructed and repaired by the CCA-adding enzyme (ATP(CTP):tRNA nucleotidyltransferase) using CTP and ATP as substrates but no nucleic acid template. Until recently, all CCA-adding enzymes from all three kingdoms appeared to be composed of a single kind of polypeptide with dual specificity for adding both CTP and ATP; however, we recently found that in Aquifex aeolicus, which lies near the deepest root of the eubacterial 16 S rRNA-based phylogenetic tree, CCA addition represents a collaboration between closely related CC-adding and A-adding enzymes (Tomita, K. and Weiner, A. M. (2001) Science 294, 1334-1336). Here we show that in Synechocystis sp. and Deinococcus radiodurans, as in A. aeolicus, CCA is added by homologous CC- and A-adding enzymes. We also find that the eubacterial CCA-, CC-, and A-adding enzymes, as well as the related eubacterial poly(A) polymerases, each fall into phylogenetically distinct groups derived from a common ancestor. Intriguingly, the Thermatoga maritima CCA-adding enzyme groups with the A-adding enzymes, suggesting that these distinct tRNA nucleotidyltransferase activities can intraconvert over evolutionary time.     

Schizosaccharomyces pombe contains separate CC- and A-adding tRNA nucleotidyltransferases

A specific cytidine-cytidine-adenosine (CCA) sequence is required at the 3′-terminus of all functional tRNAs. This sequence is added during tRNA maturation or repair by tRNA nucleotidyltransferase enzymes. While most eukaryotes have a single enzyme responsible for CCA addition, some bacteria have separate CC- and A-adding activities. The fungus, Schizosaccharomyces pombe, has two genes (cca1 and cca2) that are thought, based on predicted amino acid sequences, to encode tRNA nucleotidyltransferases. Here, we show that both genes together are required to complement a Saccharomyces cerevisiae strain bearing a null mutation in the single gene encoding its tRNA nucleotidyltransferase. Using enzyme assays we show further that the purified S. pombe cca1 gene product specifically adds two cytidine residues to a tRNA substrate lacking this sequence while the cca2 gene product specifically adds the terminal adenosine residue thereby completing the CCA sequence. These data indicate that S. pombe represents the first eukaryote known to have separate CC- and A-adding activities for tRNA maturation and repair. In addition, we propose that a novel structural change in a tRNA nucleotidyltransferase is responsible for defining a CC-adding enzyme.     

Poly(A) polymerase I of Escherichia coli: characterization of the catalytic domain, an RNA binding site and regions for the interaction with proteins involved in mRNA degradation

Poly(A) polymerase I (PAP I) of Escherichia coli is a member of the nucleotidyltransferase (Ntr) superfamily that includes the eukaryotic PAPs and all the known tRNA CCA-adding enzymes. Five highly conserved aspartic acids in the putative catalytic site of PAP I were changed to either alanine or proline, demonstrating their importance for polymerase activity. A glycine that is absolutely conserved in all Ntrs was also changed yielding a novel mutant protein in which ATP was wastefully hydrolysed in a primer-independent reaction. This is the first work to characterize the catalytic site of a eubacterial PAP and, despite the conservation of certain sequences, we predict that the overall architecture of the eukaryotic and eubacterial active sites is likely to be different. Binding sites for RNase E, a component of the RNA degradosome, and RNA were mapped by North-western and Far-western blotting using truncated forms of PAP I. Additional protein-protein interactions were detected between PAP I and CsdA, RhlE and SrmB, suggesting an unexpected connection between PAP I and these E. coli DEAD box RNA helicases. These results show that the functional organization of PAP I is similar to the eukaryotic PAPs with an N-terminal catalytic domain, a C-terminal RNA binding domain and sites for the interaction with other protein factors.     

The Bacillus subtilis Nucleotidyltransferase Is a tRNA CCA-Adding Enzyme

There has been increased interest in bacterial polyadenylation with the recent demonstration that 3′ poly(A) tails are involved in RNA degradation. Poly(A) polymerase I (PAP I) of Escherichia coli is a member of the nucleotidyltransferase (Ntr) family that includes the functionally related tRNA CCA-adding enzymes. Thirty members of the Ntr family were detected in a search of the current database of eubacterial genomic sequences. Gram-negative organisms from the β and γ subdivisions of the purple bacteria have two genes encoding putative Ntr proteins, and it was possible to predict their activities as either PAP or CCA adding by sequence comparisons with the E. coli homologues. Prediction of the functions of proteins encoded by the genes from more distantly related bacteria was not reliable. The Bacillus subtilis papS gene encodes a protein that was predicted to have PAP activity. We have overexpressed and characterized this protein, demonstrating that it is a tRNA nucleotidyltransferase. We suggest that the papS gene should be renamed cca, following the notation for its E. coli counterpart. The available evidence indicates that cca is the only gene encoding an Ntr protein, despite previous suggestions that B. subtilis has a PAP similar to E. coli PAP I. Thus, the activity involved in RNA 3′ polyadenylation in the gram-positive bacteria apparently resides in an enzyme distinct from its counterpart in gram-negative bacteria.     

Hfq stimulates the activity of the CCA-adding enzyme

Background  

The bacterial Sm-like protein Hfq is known as an important regulator involved in many reactions of RNA metabolism. A prominent function of Hfq is the stimulation of RNA polyadenylation catalyzed by E. coli poly(A) polymerase I (PAP). As a member of the nucleotidyltransferase superfamily, this enzyme shares a high sequence similarity with an other representative of this family, the tRNA nucleotidyltransferase that synthesizes the 3'-terminal sequence C-C-A to all tRNAs (CCA-adding enzyme). Therefore, it was assumed that Hfq might not only influence the poly(A) polymerase in its specific activity, but also other, similar enzymes like the CCA-adding enzyme.     

Poly(C) synthesis by class I and class II CCA-adding enzymes

The CCA-adding enzymes [ATP(CTP):tRNA nucleotidyl transferases], which catalyze synthesis of the conserved CCA sequence to the tRNA 3' end, are divided into two classes. Recent studies show that the class II Escherichia coli CCA-adding enzyme synthesizes poly(C) when incubated with CTP alone, but switches to synthesize CCA when incubated with both CTP and ATP. Because the poly(C) activity can shed important light on the mechanism of the untemplated synthesis of CCA, it is important to determine if this activity is also present in the class I CCA enzymes, which differ from the class II enzymes by significant sequence divergence. We show here that two members of the class I family, the archaeal Sulfolobus shibatae and Methanococcus jannaschii CCA-adding enzymes, are also capable of poly(C) synthesis. These two class I enzymes catalyze poly(C) synthesis and display a response of kinetic parameters to the presence of ATP similar to that of the class II E. coli enzyme. Thus, despite extensive sequence diversification, members of both classes employ common strategies of nucleotide addition, suggesting conservation of a mechanism in the development of specificity for CCA. For the E. coli enzyme, discrimination of poly(C) from CCA synthesis in the intact tRNA and in the acceptor-TPsiC domain is achieved by the same kinetic strategy, and a mutation that preferentially affects addition of A76 but not poly(C) has been identified. Additionally, we show that enzymes of both classes exhibit a processing activity that removes nucleotides in the 3' to 5' direction to as far as position 74.     

A single catalytically active subunit in the multimeric Sulfolobus shibatae CCA-adding enzyme can carry out all three steps of CCA addition

The CCA-adding enzyme ATP(CTP):tRNA nucleotidyltransferase builds and repairs the 3'-terminal CCA sequence of tRNA. Although this unusual RNA polymerase has no nucleic acid template, it can construct the CCA sequence one nucleotide at a time using CTP and ATP as substrates. We found previously that tRNA does not translocate along the enzyme during CCA addition (Yue, D., Weiner, A. M., and Maizels, N. (1998) J. Biol. Chem. 273, 29693-29700) and that a single nucleotidyltransferase motif adds all three nucleotides (Shi, P.-Y., Maizels, N., and Weiner, A. M. (1998) EMBO J. 17, 3197-3206). Intriguingly, the CCA-adding enzyme from the archaeon Sulfolobus shibatae is a homodimer that forms a tetramer upon binding two tRNAs. We therefore asked whether the active form of the S. shibatae enzyme might have two quasi-equivalent active sites, one adding CTP and the other ATP. Using an intersubunit complementation approach, we demonstrate that the dimer is active and that a single catalytically active subunit can carry out all three steps of CCA addition. We also locate one UV light-induced tRNA cross-link on the enzyme structure and provide evidence suggesting the location of another. Our data rule out shuttling models in which the 3'-end of the tRNA shuttles from one quasi-equivalent active site to another, demonstrate that tRNA-induced tetramerization is not required for CCA addition, and support a role for the tail domain of the enzyme in tRNA binding.     

The Streptomyces coelicolor polynucleotide phosphorylase homologue, and not the putative poly(A) polymerase, can polyadenylate RNA

A protein containing a nucleotidyltransferase motif characteristic of poly(A) polymerases has been proposed to polyadenylate RNA in Streptomyces coelicolor (P. Bralley and G. H. Jones, Mol. Microbiol. 40:1155-1164, 2001). We show that this protein lacks poly(A) polymerase activity and is instead a tRNA nucleotidyltransferase that repairs CCA ends of tRNAs. In contrast, a Streptomyces coelicolor polynucleotide phosphorylase homologue that exhibits polyadenylation activity may account for the poly(A) tails found in this organism.     

Metal-ion-dependent catalysis and specificity of CCA-adding enzymes: a comparison of two classes

The CCA-adding enzymes [ATP(CTP):tRNA nucleotidyl transferases] catalyze synthesis of the conserved and essential CCA sequence to the tRNA 3' end. These enzymes are divided into two classes of distinct structures that differ in the overall orientation of the head to tail domains. However, the catalytic core of the two classes is conserved and contains three carboxylates in a geometry commonly found in DNA and RNA polymerases that use the two-metal-ion mechanism for phosphoryl transfer. Two important aspects of the two-metal-ion mechanism are tested here for CCA enzymes: the dependence on metal ions for catalysis and for specificity of nucleotide addition. Using the archaeal Sulfolobus shibabae enzyme as an example of the class I, and the bacterial Escherichia coli enzyme as an example of the class II, we show that both enzymes depend on metal ions for catalysis, and that both use primarily Mg2+ and Mn2+ as the "productive" metal ions, but several other metal ions such as Ca2+ as the "nonproductive" metal ions. Of the two productive metal ions, Mg2+ specifically promotes synthesis of the correct CCA, whereas Mn2+ preferentially accelerates synthesis of the noncognate CCC and poly(C). Thus, despite evolution of structural diversity of two classes, both classes use metal ions to determine catalysis and specificity. These results provide critical insights into the catalytic mechanism of CCA synthesis to allow the two classes to be related to each other, and to members of the larger family of DNA and RNA polymerases.     

Fold recognition,homology modeling,docking simulations,kinetics analysis and mutagenesis of ATP/CTP:tRNA nucleotidyltransferase from Methanococcus jannaschii

ATP/CTP:tRNA nucleotidyltransferases (NTases) and poly(A) polymerases (PAPs) belong to the same superfamily and their catalytic domains are remotely related. Based on the results of fold-recognition analysis and comparison of secondary structure patterns, we predicted that these two NTase families share three domains, corresponding to "palm," "fingers," and "fingernails" in the PAP crystal structure. A homology model of tRNA NTase from Methanococcus jannaschii was constructed. Energy minimization calculations of enzyme-nucleotide complexes and computer-aided docking of nucleotides onto the enzyme's surface were carried out to explore possible ATP and CTP binding sites. Theoretical models were used to guide experimental analysis. Recombinant His-tagged enzyme was expressed in Escherichia coli, and kinetic properties were characterized. The apparent K(M) for CTP was determined to be 38 microM, and the apparent K(M) for ATP was 21 microM. Three mutations of basic amino acids to alanine were created in a highly conserved region predicted to be in the vicinity of the nucleotide binding site. A deletion was also constructed to remove the C-terminal structural domain defined by the model; it retained about 1% of wild type enzymatic activity using CTP as co-substrate, confirming that detectable catalytic activity is exhibited by the N-terminal domain, as defined by the model. Our results suggest a mechanism of differential ATP and CTP binding, which explains how the tRNA NTase, having only one catalytic site, utilizes different nucleotide triphosphates depending on the nature of the tRNA substrate.     

A top-half tDNA minihelix is a good substrate for the eubacterial CCA-adding enzyme.

The CCA-adding enzyme [ATP(CTP):tRNA nucleotidyltransferase] catalyzes the addition and regeneration of the 3'-terminal CCA sequence of tRNAs. We show that the CCA-adding enzyme will specifically add a CCA terminus to synthetic full-length tDNA and to DNA oligonucleotides corresponding to the "top half" of tRNA-the acceptor stem and TpsiC stem-loop of tRNA. CCA addition to the top half tDNA minihelices requires a 2' as well as a 3' OH at the 3' terminus of the tDNA. Addition also depends on the length of the base paired stem, and is facilitated by, but is not dependent upon, the presence of a TpsiC loop. These results provide further evidence for independent functions of the top and bottom halves of tRNA, and support the hypothesis that these two structurally distinct and functionally independent domains evolved independently.     

Effects of lymphocyte activation on transfer RNAs

The influences of mitogen activation on the functional capacity of rat splenic tRNAs were evaluated. The specific amino acid acceptor activity, pmol of a specific amino acid accepted per nmol of tRNA, of isolated splenic tRNAs from in vivo Concanavalin A (37 h)-treated rats were up to 8 times the specific amino acid acceptor activities of splenic tRNAs from control rats. Control splenic tRNAs were treated with purified liver tRNA nucleotidyltransferase in vitro to repair the 3'[CCA] terminus of tRNAs, and subsequently assayed in an aminoacylation reaction. The specific amino acid acceptor activities were slightly increased over those tRNAs not repaired with tRNA nucleotidyltransferase, indicating the presence of a low level of defective but repairable tRNAs in the control rat spleen. Furthermore, our results indicate that cyclosporin A (inhibitor of lymphocyte activation) blocks the Concanavalin A stimulation of tRNA charging ranging from 16 to 93%.     

Divergent evolutions of trinucleotide polymerization revealed by an archaeal CCA-adding enzyme structure

CCA-adding enzyme [ATP(CTP):tRNA nucleotidyltransferase], a template-independent RNA polymerase, adds the defined 'cytidine-cytidine-adenosine' sequence onto the 3' end of tRNA. The archaeal CCA-adding enzyme (class I) and eubacterial/eukaryotic CCA-adding enzyme (class II) show little amino acid sequence homology, but catalyze the same reaction in a defined fashion. Here, we present the crystal structures of the class I archaeal CCA-adding enzyme from Archaeoglobus fulgidus, and its complexes with CTP and ATP at 2.0, 2.0 and 2.7 A resolutions, respectively. The geometry of the catalytic carboxylates and the relative positions of CTP and ATP to a single catalytic site are well conserved in both classes of CCA-adding enzymes, whereas the overall architectures, except for the catalytic core, of the class I and class II CCA-adding enzymes are fundamentally different. Furthermore, the recognition mechanisms of substrate nucleotides and tRNA molecules are distinct between these two classes, suggesting that the catalytic domains of class I and class II enzymes share a common origin, and distinct substrate recognition domains have been appended to form the two presently divergent classes.