Crystal structure of Staphylococcus aureus tRNA adenosine deaminase TadA in complex with RNA

Bacterial tRNA adenosine deaminases (TadAs) catalyze the hydrolytic deamination of adenosine to inosine at the wobble position of tRNA(Arg2), a process that enables this single tRNA to recognize three different arginine codons in mRNA. In addition, inosine is also introduced at the wobble position of multiple eukaryotic tRNAs. The genes encoding these deaminases are essential in bacteria and yeast, demonstrating the importance of their biological activity. Here we report the crystallization and structure determination to 2.0 A of Staphylococcus aureus TadA bound to the anticodon stem-loop of tRNA(Arg2) bearing nebularine, a non-hydrolyzable adenosine analog, at the wobble position. The cocrystal structure reveals the basis for both sequence and structure specificity in the interactions of TadA with RNA, and it additionally provides insight into the active site architecture that promotes efficient hydrolytic deamination.     

Enzymes assembled from Aquifex aeolicus and Escherichia coli leucyl-tRNA synthetases

Aquifex aeolicus alphabeta-LeuRS is the only known heterodimeric LeuRS, while Escherichia coli LeuRS is a canonical monomeric enzyme. By using the genes encoding A. aeolicus and E. coli LeuRS as PCR templates, the genes encoding the alpha and beta subunits from A. aeolicus alphabeta-LeuRS and the equivalent amino- and carboxy-terminal parts of E. coli LeuRS (identified as alpha' and beta') were amplified and recombined using suitable plasmids. These recombinant plasmids were transformed or cotransformed into E. coli to produce five monomeric and five heterodimeric LeuRS mutants. Seven of these were successfully overexpressed in vivo and purified, while three dimeric mutants with the beta' part of E. coli LeuRS were not successfully expressed. The seven purified mutants catalyzed amino acid activation, although several exhibited reduced aminoacylation properties. Removal of the last 36 residues of the alpha subunit of the A. aeolicus enzyme was determined to be deleterious for tRNA charging. Indeed, subunit exchange showed that the cross-species-specific recognition of A. aeolicus tRNA(Leu) occurs at the alpha subunit. None of the mixed E. coli-A. aeolicus enzymes were as thermostable as the native alphabeta-LeuRS. However, the fusion of the two alpha and beta peptides from A. aeolicus as a single chain analogous to canonical LeuRS resulted in a product more resistant to heat denaturation than the original enzyme.     

The 1.14 A crystal structure of yeast cytosine deaminase: evolution of nucleotide salvage enzymes and implications for genetic chemotherapy

Cytosine deaminase (CD) catalyzes the deamination of cytosine and is only present in prokaryotes and fungi, where it is a member of the pyrimidine salvage pathway. The enzyme is of interest both for antimicrobial drug design and gene therapy applications against tumors. The structure of Saccharomyces cerevisiae CD has been determined in the presence and absence of a mechanism-based inhibitor, at 1.14 and 1.43 A resolution, respectively. The enzyme forms an alpha/beta fold similar to bacterial cytidine deaminase, but with no similarity to the alpha/beta barrel fold used by bacterial cytosine deaminase or mammalian adenosine deaminase. The structures observed for bacterial, fungal, and mammalian nucleic acid deaminases represent an example of the parallel evolution of two unique protein folds to carry out the same reaction on a diverse array of substrates.     

Leucyl-tRNA synthetase consisting of two subunits from hyperthermophilic bacteria Aquifex aeolicus

In a hyperthermophilic bacterium, Aquifex aeolicus, leucyl-tRNA synthetase (LeuRS) consists of two non-identical polypeptide subunits (alpha and beta), different from the canonical LeuRS, which has a single polypeptide chain. By PCR, using genome DNA of A. aeolicus as a template, genes encoding the alpha and beta subunits were amplified and cloned in Escherichia coli. The alpha subunit could not be expressed stably in vivo, whereas the beta subunit was overproduced and purified by a simple procedure. The beta subunit was inactive in catalysis but was able to bind tRNA(Leu). Interestingly, the heterodimer alphabeta-LeuRS could be overproduced in E. coli cells containing both genes and was purified to 95% homogeneity as a hybrid dimer. The kinetics of A. aeolicus LeuRS in pre-steady and steady states and cross-recognition of LeuRS and tRNA(Leu) from A. aeolicus and E. coli were studied. Magnesium concentration, pH value, and temperature aminoacylation optima were determined to be 12 mm, 7.8, and 70 degrees C, respectively. Under optimal conditions, A. aeolicus alphabeta-LeuRS is stable up to 65 degrees C.     

The beta subunit of Aquifex aeolicus leucyl-tRNA synthetase is responsible for cognate tRNA recognition

The active form of the leucyl-tRNA synthetase from an extreme thermophile Aquifex aeolicus has a heterodimeric (alpha/beta type) quaternary structure that is unique among class I aminoacyl-tRNA synthetases. In an attempt to clarify the individual roles of each subunit in the function of leucyl-tRNA synthetase, several elementary activities were separately measured using each of the subunits alone or the reconstructed alpha/beta complex. It was found that the beta subunit alone is capable of recognizing its cognate tRNA, while the leucyl-adenylate formation and the overall leucyl-tRNA formation are detected only when both of the subunit proteins coexisted.     

Crystal structure of the tRNA processing enzyme RNase PH from Aquifex aeolicus

RNase PH is one of the exoribonucleases that catalyze the 3' end processing of tRNA in bacteria. RNase PH removes nucleotides following the CCA sequence of tRNA precursors by phosphorolysis and generates mature tRNAs with amino acid acceptor activity. In this study, we determined the crystal structure of Aquifex aeolicus RNase PH bound with a phosphate, a co-substrate, in the active site at 2.3-A resolution. RNase PH has the typical alpha/beta fold, which forms a hexameric ring structure as a trimer of dimers. This ring structure resembles that of the polynucleotide phosphorylase core domain homotrimer, another phosphorolytic exoribonuclease. Four amino acid residues, Arg-86, Gly-124, Thr-125, and Arg-126, of RNase PH are involved in the phosphate-binding site. Mutational analyses of these residues showed their importance in the phosphorolysis reaction. A docking model with the tRNA acceptor stem suggests how RNase PH accommodates substrate RNAs.     

Stereochemistry of internucleotidic bond formation by tRNA nucleotidyltransferase from baker's yeast.

Isomer A of adenosine 5'-O-(1-thiotriphosphate) (ATP alpha S) is a substrate for tRNA nucleotidyltransferase from baker's yeast, whereas isomer B is a competitive inhibitor. The tRNA resulting from this reaction has a phosphorothioate instead of a phosphate diester linkage at the last internucleotidic linkage between cytidine and adenosine. On limited digestion of this tRNA with RNase A, one can isolate cytidine 2',3'-cyclic phosphorothioate which can be deaminated to uridine 2',3'-cyclic phosphorothioate. It can be shown that this compound is the endo isomer and that, therefore, the phosphorothioate diester bond in the tRNA must have had the R configuration. This result indicates that no racemization during the condensation of ATP alpha S, isomer A, onto the tRNA had occurred. Whether inversion or retention of configuration had taken place awaits elucidation of the absolute configuration of isomer A of ATP alpha S.     

Human adenosine deaminase. cDNA and complete primary amino acid sequence

A previously cloned partial adenosine deaminase cDNA insert (0.8 kilobase) was used to clone additional nucleotide sequences from human HPB ALL cDNA libraries. cDNA encompassing the entire coding, and 3'-untranslated regions as well as nearly all of the 5'-untranslated region was obtained. The complete amino acid sequence of the enzyme deduced from the cDNA sequence and protein sequencing consists of 362 amino acids, excluding the initiator Met, and accounts for Mr = 40,638. Secondary structure predictions assign adenosine deaminase to the alpha/beta class of proteins. Northern blot analysis with a cDNA probe showed adenosine deaminase mRNA to be present in normal to above normal amounts in B-lymphoblasts derived from adenosine deaminase-deficient patients with severe combined immunodeficiency disease. Knowledge of the cDNA and primary amino acid sequence of adenosine deaminase will be pivotal in further defining the genetic abnormality and its functional consequences in adenosine deaminase expression defects.     

Analysis of a multicomponent thermostable DNA polymerase III replicase from an extreme thermophile

This report takes a proteomic/genomic approach to characterize the DNA polymerase III replication apparatus of the extreme thermophile, Aquifex aeolicus. Genes (dnaX, holA, and holB) encoding the subunits required for clamp loading activity (tau, delta, and delta') were identified. The dnaX gene produces only the full-length product, tau, and therefore differs from Escherichia coli dnaX that produces two proteins (gamma and tau). Nonetheless, the A. aeolicus proteins form a taudeltadelta' complex. The dnaN gene encoding the beta clamp was identified, and the taudeltadelta' complex is active in loading beta onto DNA. A. aeolicus contains one dnaE homologue, encoding the alpha subunit of DNA polymerase III. Like E. coli, A. aeolicus alpha and tau interact, although the interaction is not as tight as the alpha-tau contact in E. coli. In addition, the A. aeolicus homologue to dnaQ, encoding the epsilon proofreading 3'-5'-exonuclease, interacts with alpha but does not form a stable alpha.epsilon complex, suggesting a need for a brace or bridging protein to tightly couple the polymerase and exonuclease in this system. Despite these differences to the E. coli system, the A. aeolicus proteins function to yield a robust replicase that retains significant activity at 90 degrees C. Similarities and differences between the A. aeolicus and E. coli pol III systems are discussed, as is application of thermostable pol III to biotechnology.     

High-level expression and single-step purification of leucyl-tRNA synthetase from Aquifex aeolicus

Aquifex aeolicus leucyl-tRNA synthetase is the only known heterodimeric LeuRS, consisting of two subunits with molecular masses of 74.0 and 33.5 kDa, and named alphabeta-LeuRS. The gene encoding alpha subunit was cloned into pSBET-b vector. Synthetic oligonucleotide encoding six histidine residues was also inserted in front of alpha subunit. PSBET-b vector contains argU gene, which encodes a rare Escherichia coli tRNA(Arg)(AGA/AGG). The argU gene helps A. aeolicus LeuRS, which contains AGA/AGG codons in exceptionally high frequency, express well in E. coli. The gene encoding beta subunit was inserted into pET-15b vector. E. coli BL21-CodonPlus (DE3) cells were transformed with the two recombinant plasmids to produce alphabeta-LeuRS with a His6 tag at the N-terminus of alpha subunit. The enzyme was purified by affinity chromatography on Ni-NTA Superflow. About 7 mg purified alphabeta-LeuRS was obtained from 250 ml culture. The His6-tag at the N-terminus did not affect the aminoacylation activity of the enzyme.     

Alanyl-tRNA synthetase crystal structure and design for acceptor-stem recognition

Early work on aminoacylation of alanine-specific tRNA (tRNA(Ala)) by alanyl-tRNA synthetase (AlaRS) gave rise to the concept of an early "second genetic code" imbedded in the acceptor stems of tRNAs. A single conserved and position-specific G:U base pair in the tRNA acceptor stem is the key identity determinant. Further understanding has been limited due to lack of a crystal structure of the enzyme. We determined a 2.14 A crystal structure of the 453 amino acid catalytic fragment of Aquifex aeolicus AlaRS. It contains the catalytic domain characteristic of class II synthetases, a helical domain with a hairpin motif critical for acceptor-stem recognition, and a C-terminal domain of a mixed alpha/beta fold. Docking of tRNA(Ala) on AlaRS shows critical contacts with the three domains, consistent with previous mutagenesis and functional data. It also suggests conformational flexibility within the C domain, which might allow for the positional variation of the key G:U base pair seen in some tRNA(Ala)s.     

Solution structure of the ribosome recycling factor from Aquifex aeolicus

The solution structure of ribosome recycling factor (RRF) from hyperthermophilic bacterium, Aquifex aeolicus, was determined by heteronuclear multidimensional NMR spectroscopy. Fifteen structures were calculated using restraints derived from NOE, J-coupling, and T1/T2 anisotropies. The resulting structure has an overall L-shaped conformation with two domains and is similar to that of a tRNA molecule. The domain I (corresponding to the anticodon stem of tRNA) is a rigid three alpha-helix bundle. Being slightly different from usual coiled-coil arrangements, each helix of domain I is not twisted but straight and parallel to the main axis. The domain II (corresponding to the portion with the CCA end of tRNA) is an alpha/beta domain with an alpha-helix and two beta-sheets, that has some flexible regions. The backbone atomic root-mean-square deviation (rmsd) values of both domains were 0.7 A when calculated separately, which is smaller than that of the molecule as a whole (1.4 A). Measurement of 15N-[1H] NOE values show that the residues in the corner of the L-shaped molecule are undergoing fast internal motion. These results indicate that the joint region between two domains contributes to the fluctuation in the orientation of two domains. Thus, it was shown that RRF remains the tRNA mimicry in solution where it functions.     

Two distinct domains of the beta subunit of Aquifex aeolicus leucyl-tRNA synthetase are involved in tRNA binding as revealed by a three-hybrid selection

The Aquifex aeolicus alphabeta-LeuRS is the only known heterodimeric class Ia aminoacyl-tRNA synthetase. In this study, we investigated the function of the beta subunit which is believed to bind tRNA(Leu). A yeast three-hybrid system was constructed on the basis of the interaction of the beta subunit with its cognate tRNA(Leu). Then, seven mutated beta subunits exhibiting impaired tRNA binding capacities were selected out from a randomly mutated library. Two mutations were identified in the class Ia-helix-bundle-domain, which might interact with the D-hairpin of the tRNA analogous to other class Ia tRNA:synthetases complexes. The five other mutations were found in the LeuRS-specific C-terminal domain of which the folding is still unknown. tRNA affinity measurements and kinetic analyses performed on the isolated beta subunits and on the co-expressed alphabeta-heterodimers showed for all the mutants an effect in tRNA affinity in the ground state. In addition, an effect on the transition state of the aminoacylation reaction was observed for a 21-residues deletion mutant of the C-terminal end. These results show that the genetic approach of the three hybrid system is widely applicable and is a powerful tool for the investigation of tRNA:synthetase interactions.     

Crystal structure of alpha-amino-beta-carboxymuconate-epsilon-semialdehyde decarboxylase: insight into the active site and catalytic mechanism of a novel decarboxylation reaction

Alpha-amino-beta-carboxymuconate-epsilon-semialdehyde decarboxylase (ACMSD) is a widespread enzyme found in many bacterial species and all currently sequenced eukaryotic organisms. It occupies a key position at the branching point of two metabolic pathways: the tryptophan to quinolinate pathway and the bacterial 2-nitrobenzoic acid degradation pathway. The activity of ACMSD determines whether the metabolites in both pathways are converted to quinolinic acid for NAD biosynthesis or to acetyl-CoA for the citric acid cycle. Here we report the first high-resolution crystal structure of ACMSD from Pseudomonas fluorescens which validates our previous predictions that this enzyme is a member of the metal-dependent amidohydrolase superfamily of the (beta/alpha)(8) TIM barrel fold. The structure of the enzyme in its native form, determined at 1.65 A resolution, reveals the precise spatial arrangement of the active site metal center and identifies a potential substrate-binding pocket. The identity of the native active site metal was determined to be Zn. Also determined was the structure of the enzyme complexed with cobalt at 2.50 A resolution. The hydrogen bonding network around the metal center suggests that Arg51 and His228 may play important roles in catalysis. The metal center configuration of PfACMSD is very similar to that of Zn-dependent adenosine deaminase and Fe-dependent cytosine deaminase, suggesting that ACMSD may share certain similarities in its catalytic mechanism with these enzymes. These data enable us to propose possible catalytic mechanisms for ACMSD which appear to be unprecedented among all currently characterized decarboxylases.     

Crystal structure of trbp111: a structure-specific tRNA-binding protein

Trbp111 is a 111 amino acid Aquifex aeolicus structure-specific tRNA-binding protein that has homologous counterparts distributed throughout evolution. A dimer is the functional unit for binding a single tRNA. Here we report the 3D structures of the A.aeolicus protein and its Escherichia coli homolog at resolutions of 2.50 and 1.87 A, respectively. The structure shows a symmetrical dimer of two core domains and a central dimerization domain where the N- and C-terminal regions of Trbp111 form an extensive dimer interface. The core of the monomer is a classical oligonucleotide/oligosaccharide-binding (OB) fold with a five-stranded ss-barrel and a small capping helix. This structure is similar to that seen in the anticodon-binding domain of three class II tRNA synthetases and several other proteins. Mutational analysis identified sites important for interactions with tRNA. These residues line the inner surfaces of two clefts formed between the ss-barrel of each monomer and the dimer interface. The results are consistent with a proposed model for asymmetrical docking of the convex side of tRNA to the dimer.     

Discrimination between initiation and elongation of protein biosynthesis in yeast: identity assured by a nucleotide modification in the initiator tRNA.

Cytoplasmic initiator tRNAs from plants and fungi possess an unique 2'-phosphoribosyl residue at position 64 of their sequence. In yeast tRNA(iMet), this modified nucleotide located in the T-stem of the tRNA is a 2'-1'-(beta-O-ribofuranosyl-5'-phosphoryl)-adenosine. The phosphoribosyl residue of this modified nucleoside was removed chemically by treatment involving periodate oxidation of tRNA(iMet) and regeneration of the 3'-terminal adenosine with ATP (CTP):tRNA nucleotidyl transferase. The role of phosphoribosylation at position 64 for interaction with elongation factor eEF-1 alpha and initiation factor 2 (eIF-2) was investigated in the homologous yeast system. Whereas the 5'-phosphoribosyl residue prevents the binding of Met-tRNA(iMet) to eEF-1 alpha, it does not influence the interaction with eIF-2. After removal of the ribosyl group, the demodified initiator tRNA showed binding to eEF-1 alpha, but no change was detected with respect to the interaction with the initiation factor eIF-2. This observation is interpreted to mean that a single modification of an eucaryotic initiator tRNA in yeast serves as a negative discriminant for eEF-1 alpha, thus preventing the initiator tRNA(iMet) from entering the elongation cycle of protein biosynthesis.     

Substrate tRNA recognition mechanism of a multisite-specific tRNA methyltransferase, Aquifex aeolicus Trm1, based on the X-ray crystal structure

Archaeal and eukaryotic tRNA (N(2),N(2)-guanine)-dimethyltransferase (Trm1) produces N(2),N(2)-dimethylguanine at position 26 in tRNA. In contrast, Trm1 from Aquifex aeolicus, a hyper-thermophilic eubacterium, modifies G27 as well as G26. Here, a gel mobility shift assay revealed that the T-arm in tRNA is the binding site of A. aeolicus Trm1. To address the multisite specificity, we performed an x-ray crystal structure study. The overall structure of A. aeolicus Trm1 is similar to that of archaeal Trm1, although there is a zinc-cysteine cluster in the C-terminal domain of A. aeolicus Trm1. The N-terminal domain is a typical catalytic domain of S-adenosyl-l-methionine-dependent methyltransferases. On the basis of the crystal structure and amino acid sequence alignment, we prepared 30 mutant Trm1 proteins. These mutant proteins clarified residues important for S-adenosyl-l-methionine binding and enabled us to propose a hypothetical reaction mechanism. Furthermore, the tRNA-binding site was also elucidated by methyl transfer assay and gel mobility shift assay. The electrostatic potential surface models of A. aeolicus and archaeal Trm1 proteins demonstrated that the distribution of positive charges differs between the two proteins. We constructed a tRNA-docking model, in which the T-arm structure was placed onto the large area of positive charge, which is the expected tRNA-binding site, of A. aeolicus Trm1. In this model, the target G26 base can be placed near the catalytic pocket; however, the nucleotide at position 27 gains closer access to the pocket. Thus, this docking model introduces a rational explanation of the multisite specificity of A. aeolicus Trm1.