Structure of crystalline D-Tyr-tRNA(Tyr) deacylase. A representative of a new class of tRNA-dependent hydrolases.

Cell growth inhibition by several d-amino acids can be explained by an in vivo production of d-aminoacyl-tRNA molecules. Escherichia coli and yeast cells express an enzyme, d-Tyr-tRNA(Tyr) deacylase, capable of recycling such d-aminoacyl-tRNA molecules into free tRNA and d-amino acid. Accordingly, upon inactivation of the genes of the above deacylases, the toxicity of d-amino acids increases. Orthologs of the deacylase are found in many cells. In this study, the crystallographic structure of dimeric E. coli d-Tyr-tRNA(Tyr) deacylase at 1.55 A resolution is reported. The structure corresponds to a beta-barrel closed on one side by a beta-sheet lid. This barrel results from the assembly of the two subunits. Analysis of the structure in relation with sequence homologies in the orthologous family suggests the location of the active sites at the carboxy end of the beta-strands. The solved structure markedly differs from those of all other documented tRNA-dependent hydrolases.

Recognition of tRNAs by Methionyl-tRNA transformylase from mammalian mitochondria.

Protein synthesis involves two methionine-isoaccepting tRNAs, an initiator and an elongator. In eubacteria, mitochondria, and chloroplasts, the addition of a formyl group gives its full functional identity to initiator Met-tRNA(Met). In Escherichia coli, it has been shown that the specific action of methionyl-tRNA transformylase on Met-tRNA(f)(Met) mainly involves a set of nucleotides in the acceptor stem, particularly a C(1)A(72) mismatch. In animal mitochondria, only one tRNA(Met) species has yet been described. It is admitted that this species can engage itself either in initiation or elongation of translation, depending on the presence or absence of a formyl group. In the present study, we searched for the identity elements of tRNA(Met) that govern its formylation by bovine mitochondrial transformylase. The main conclusion is that the mitochondrial formylase preferentially recognizes the methionyl moiety of its tRNA substrate. Moreover, the relatively small importance of the tRNA acceptor stem in the recognition process accounts for the protection against formylation of the mitochondrial tRNAs that share with tRNA(Met) an A(1)U(72) motif.

The many routes of bacterial transfer RNAs after aminoacylation.

Subsequent to their aminoacylation, tRNAs are subject to specific maturation and/or correction processes. Aminoacylated tRNAs ready for use in translation are then specifically channelled to the ribosomal A or P sites. Structural and biochemical studies have opened the way towards furthering our understanding of these routes to the ribosome, which involve a strict distinction between initiator and elongator tRNAs.

Crystal structure of Escherichia coli methionyl-tRNA synthetase highlights species-specific features.

The 3D structure of monomeric C-truncated Escherichia coli methionyl-tRNA synthetase, a class 1 aminoacyl-tRNA synthetase, has been solved at 2.0 A resolution. Remarkably, the polypeptide connecting the two halves of the Rossmann fold exposes two identical knuckles related by a 2-fold axis but with zinc in the distal knuckle only. Examination of available MetRS orthologs reveals four classes according to the number and zinc content of the putative knuckles. Extreme cases are exemplified by the MetRS of eucaryotic or archaeal origin, where two knuckles and two metal ions are expected, and by the mitochondrial enzymes, which are predicted to have one knuckle without metal ion.

Receptor site for the 5'-phosphate of elongator tRNAs governs substrate selection by peptidyl-tRNA hydrolase.

Eubacterial peptidyl-tRNA hydrolase (PTH) recycles all N-blocked aminoacyl-tRNA molecules but initiator formyl-methionyl-tRNAfMet, the acceptor helix of which is characterized by a 1-72 mismatch. Positive selection by PTH of noninitiator tRNA molecules with a full 1-72 base pair is abolished, however, upon the removal of the 5'-phosphate. The tRNA 5'-phosphate plays therefore the role of a relay between the enzyme and the status of the 1-72 base pair. In this study, the receptor site for the 5'-phosphate of elongator peptidyl-tRNAs and the position at the surface of PTH of the 3'-end of complexed peptidyl-tRNA are identified by site-directed mutagenesis experiments. The former site comprehends two cationic side chains (K105 and R133) which are likely to clamp the phosphate. The second corresponds to a four asparagine cluster (N10, N21, N68, and N114). By using these two positional constraints, the acceptor arm of elongation factor Tu-bound Phe-tRNAPhe could be docked to PTH. Contacts involve the acceptor and TPsiC stems. By comparing the obtained 3D model to that of EF-Tu:Phe-tRNAPhe crystalline complex in which the 5'-phosphate of the ligand also lies between a K and an R side chain, we propose that, in both systems, the capacity of the 5'-phosphate of a tRNA to reach or not a receptor site is the main identity element governing generic selection of elongator tRNAs. On the other hand, while the 1-72 mismatch acts as an antideterminant for PTH or EF-Tu recognition, it behaves as a positive determinant for the formylation of initiator Met-tRNAfMet.

Crystallization and preliminary X-ray analysis of Escherichia coli methionyl-tRNAMet(f) formyltransferase complexed with formyl-methionyl-tRNAMet(f).

The structure of methionyl-tRNAfMet(f) formyltransferase from E. coli, a monomeric protein of 34 kDa, has previously been determined at 2.0 A resolution. In the present work, this enzyme was crystallized as a complex with its macromolecular product, the initiator formyl-methionyl-tRNAfMet(f) (25 kDa). Polyethylene glycol 5000 monomethylether was used as a precipitating agent. The crystals are orthorhombic and have unit-cell parameters a = 201.7, b = 68.1, c = 86.4 A. They belong to space group P21212 and diffract to 2.8 A resolution. The structure is being solved with the help of a mercury derivative.

Crystal structure of methionyl-tRNAfMet transformylase complexed with the initiator formyl-methionyl-tRNAfMet.

The crystal structure of Escherichia coli methionyl-tRNAfMet transformylase complexed with formyl-methionyl-tRNAfMet was solved at 2.8 A resolution. The formylation reaction catalyzed by this enzyme irreversibly commits methionyl-tRNAfMet to initiation of translation in eubacteria. In the three-dimensional model, the methionyl-tRNAfMet formyltransferase fills in the inside of the L-shaped tRNA molecule on the D-stem side. The anticodon stem and loop are away from the protein. An enzyme loop is wedged in the major groove of the acceptor helix. As a result, the C1-A72 mismatch characteristic of the initiator tRNA is split and the 3' arm bends inside the active centre. This recognition mechanism is markedly distinct from that of elongation factor Tu, which binds the acceptor arm of aminoacylated elongator tRNAs on the T-stem side.

Crystal structure at 1.2 A resolution and active site mapping of Escherichia coli peptidyl-tRNA hydrolase.

Peptidyl-tRNA hydrolase activity from Escherichia coli ensures the recycling of peptidyl-tRNAs produced through abortion of translation. This activity, which is essential for cell viability, is carried out by a monomeric protein of 193 residues. The structure of crystalline peptidyl-tRNA hydrolase could be solved at 1.2 A resolution. It indicates a single alpha/beta globular domain built around a twisted mixed beta-sheet, similar to the central core of an aminopeptidase from Aeromonas proteolytica. This similarity allowed the characterization by site-directed mutagenesis of several residues of the active site of peptidyl-tRNA hydrolase. These residues, strictly conserved among the known peptidyl-tRNA hydrolase sequences, delineate a channel which, in the crystal, is occupied by the C-end of a neighbouring peptidyl-tRNA hydrolase molecule. Hence, several main chain atoms of three residues belonging to one peptidyl-tRNA hydrolase polypeptide establish contacts inside the active site of another peptidyl-tRNA hydrolase molecule. Such an interaction is assumed to represent the formation of a complex between the enzyme and one product of the catalysed reaction.

General structure/function properties of microbial methionyl-tRNA synthetases.

Alignment of the sequences of methionyl-tRNA synthetases from various microbial sources shows low levels of identities. However, sequence identities are clustered in a limited number of sites, most of which contain peptide patterns known to support the activity of the Escherichia coli enzyme. In the present study, site-directed mutagenesis was used to probe the role of these conserved residues in the case of the Bacillus stearothermophilus methionyl-tRNA synthetase. The B. stearothermophilus enzyme was chosen in this study because it can be produced as an active truncated monomeric form, similar to the monomeric derivative of E. coli methionyl-tRNA synthetase produced by mild proteolysis. The two core enzyme molecules share only 27% identical residues. The results allowed the identification of the binding sites for ATP, methionine and tRNA, as well as that responsible for the tight binding of the zinc ion to the enzyme. It is concluded that the thermostable synthetase adopts a three-dimensional folding very similar to that of the E. coli one. Therefore, the two methionyl-tRNA synthetase sequences, although significantly different, maintain a common scaffold with the functionally important residues exposed at constant positions. Sequence alignments suggest that the above conclusion can be generalized to the known methionyl-tRNA synthetases from various sources.

Adenosine conformations of nucleotides bound to methionyl tRNA synthetase by transferred nuclear Overhauser effect spectroscopy.

The conformations of MgATP and AMP bound to a monomeric tryptic fragment of methionyl tRNA synthetase have been investigated by two-dimensional proton transferred nuclear Overhauser effect spectroscopy (TRNOESY). The sample protocol was chosen to minimize contributions from adventitious binding of the nucleotides to the observed NOE. The experiments were performed at 500 MHz on three different complexes, E.MgATP, E.MgATP.L-methioninol, and E.AMP.L-methioninol. A starter set of distances obtained by fitting NOE build-up curves (not involving H5' and H5") were used to determine a CHARMm energy-minimized structure. The positioning of the H5' and H5" protons was determined on the basis of a conformational search of the torsion angle to obtain the best fit with the observed NOEs for their superposed resonance. Using this structure, a relaxation matrix was set up to calculate theoretical build-up curves for all of the NOEs and compare them with the observed curves. The final structures deduced for the adenosine moieties in the three complexes are very similar, and are described by a glycosidic torsion angle (chi) of 56 degrees +/- 5 degrees and a phase angle of pseudorotation (P) in the range of 47 degrees to 52 degrees, describing a 3(4)T-4E sugar pucker. The glycosidic torsion angle, chi, deduced here for this adenylyl transfer enzyme and those determined previously for three phosphoryl transfer enzymes (creatine kinase, arginine kinase, and pyruvate kinase), and one pyrophosphoryl enzyme (PRibPP synthetase), are all in the range 52 degrees +/- 8 degrees. The narrow range of values suggests a possible common motif for the recognition and binding of the adenosine moiety at the active sites of ATP-utilizing enzymes, irrespective of the point of cleavage on the phosphate chain.

Crystallization and preliminary X-ray analysis of Escherichia coli peptidyl-tRNA hydrolase.

Peptidyl-tRNA hydrolase from Escherichia coli, a monomer of 21 kDa, was overexpressed from its cloned gene pth and crystallized by using polyethylene glycol as precipitant. The crystals are orthorhombic and have unit cell parameters a = 47.24 A, b = 63.59 A, and c = 62.57 A. They belong to space group P2(1)2(1)2(1) and diffract to better than 1.2 A resolution. The structure is being solved by multiple isomorphous replacement.

Structure of crystalline Escherichia coli methionyl-tRNA(f)Met formyltransferase: comparison with glycinamide ribonucleotide formyltransferase.

Formylation of the methionyl moiety esterified to the 3' end of tRNA(f)Met is a key step in the targeting of initiator tRNA towards the translation start machinery in prokaryotes. Accordingly, the presence of methionyl-tRNA(f)Met formyltransferase (FMT), the enzyme responsible for this formylation, is necessary for the normal growth of Escherichia coli. The present work describes the structure of crystalline E.coli FMT at 2.0 A, resolution. The protein has an N-terminal domain containing a Rossmann fold. This domain closely resembles that of the glycinamide ribonucleotide formyltransferase (GARF), an enzyme which, like FMT, uses N-10 formyltetrahydrofolate as formyl donor. However, FMT can be distinguished from GARF by a flexible loop inserted within its Rossmann fold. In addition, FMT possesses a C-terminal domain with a beta-barrel reminiscent of an OB fold. This latter domain provides a positively charged side oriented towards the active site. Biochemical evidence is presented for the involvement of these two idiosyncratic regions (the flexible loop in the N-terminal domain, and the C-terminal domain) in the binding of the tRNA substrate.

Interplay of methionine tRNAs with translation elongation factor Tu and translation initiation factor 2 in Escherichia coli.

According to their role in translation, tRNAs specifically interact either with elongation factor Tu (EFTu) or with initiation factor 2 (IF2). We here describe the effects of overproducing EFTu and IF2 on the elongator versus initiator activities of various mutant tRNAMet species in vivo. The data obtained indicate that the selection of a tRNA through one or the other pathway of translation depends on the relative amounts of the translational factors. A moderate overexpression of EFTu is enough to lead to a misappropriation of initiator tRNA in the elongation process, whereas overproduced IF2 allows the initiation of translation to occur with unformylated tRNA species. In addition, we report that a strain devoid of formylase activity can be cured by the overproduction of tRNAMetf. The present study brings additional evidence for the importance of formylation in defining tRNAMetf initiator identity, as well as a possible explanation for the residual growth of bacterial strains lacking a functional formylase gene such as observed in Guillon, J. M., Mechulam, Y., Schmitter, J.-M., Blanquet, S., and Fayat, G. (1992) J. Bacteriol. 174, 4294-4301.

Crystallization and preliminary X-ray analysis of Escherichia coli methionyl-tRNA(fMet) formyltransferase.

Methionyl-tRNA(fMet) formyltransferase from Escherichia coli, a monomer of 34kDa, was overexpressed from its cloned gene fmt (Guillon, J.M., Mechulam, Y., Schmitter, J.M., Blanquet, S., and Fayat, G., J. Bacteriol. 174:4294-4301, 1992) and crystallized using ammonium sulphate as precipitant. The crystals are trigonal and have unit cell parameters a = b = 151.0 A, c = 81.8 A. They belong to space group P3(2)21 and diffract to 2.0 A resolution. The structure is being solved by multiple isomorphous replacement.

Molecular recognition governing the initiation of translation in Escherichia coli. A review.

Selection of the proper start codon for the synthesis of a polypeptide by the Escherichia coli translation initiation apparatus involves several macromolecular components. These macromolecules interact in a specific and concerted manner to yield the translation initiation complex. This review focuses on recent data concerning the properties of the initiator tRNA and of enzymes and factors involved in the translation initiation process. The three initiation factors, as well as methionyl-tRNA synthetase and methionyl-tRNA(f)Met formyltransferase are described. In addition, the tRNA recognition properties of EF-Tu and peptidyl-tRNA hydrolase are considered. Finally, peptide deformylase and methionine aminopeptidase, which catalyze the amino terminal maturation of nascent polypeptides, can also be associated to the translation initiation process.

Transition state stabilization by the 'high' motif of class I aminoacyl-tRNA synthetases: the case of Escherichia coli methionyl-tRNA synthetase.

Methionyl-tRNA synthetase belongs to the class I aminoacyl-tRNA synthetase family characterized both by a catalytic center built around a Rossmann Fold and by the presence of the two peptidic marker sequences HIGH and KMSKS. In this study, the role of the 21HLGH24 motif of Escherichia coli methionyl-tRNA synthetase was studied in a systematic fashion by site-directed mutagenesis. It is shown that the two histidine residues play a crucial role in the catalysis of the methionyl adenylate formation by participating in the stabilisation of the ATP phosphate chain during the transition state. Moreover, the results suggest the involvement of the epsilon-imino group of histidine 21 and of the delta-imino group of histidine 24. Notably, the substitution of either the leucine or the glycine residue of the HLGH motif by alanine had no effect on the catalysis. From the data and from other studies with class I aminoacyl-tRNA synthetases, concomitant positive contributions of the HIGH and KMSKS sequences to reach the transition state of aminoacyl adenylate formation can be envisaged.

Crucial role of an idiosyncratic insertion in the Rossman fold of class 1 aminoacyl-tRNA synthetases: the case of methionyl-tRNA synthetase.

A few aminoacyl-tRNA synthetases are characterized by their ability to tightly bind a zinc atom. In the case of Escherichia coli methionyl-tRNA synthetase, a peptide of 21 residues (138--163) having a stable 3-D structure in solution is responsible for zinc binding [Fourmy, D., Meinnel, T., Mechulam, Y., & Blanquet, S. (1993) J. Mol. Biol. 231, 1066--1077; Fourmy, D., Dardel, F., & Blanquet, S. (1993) J. Mol. Biol. 231, 1078--1089]. This peptide, which belongs to a region connecting the two halves of the nucleotide-binding domain of methionyl-tRNA synthetase, is likely to form a modular domain close to the active center of the enzyme. In this study, two residues of the zinc-binding module, Asp138 and Arg139, are shown to contribute to the stabilization of the transition state of the reaction leading to the activation of methionine. Moreover, another residue, Phe135, located at the surface of the zinc-binding domain, is found to possibly guide the tRNA acceptor stem toward the active site of the enzyme during catalysis. The available data indicate an important functional role for the zinc-binding module of methionyl-tRNA synthetase, as well as for other modules connecting conserved secondary structure elements in the aminoacyl-tRNA synthetase family. The relation between the occurrence of such variable peptide modules and the expression of both substrate specificity and catalytic efficiency is discussed.

Methionyl-tRNA synthetase needs an intact and mobile 332KMSKS336 motif in catalysis of methionyl adenylate formation.

The family of aminoacyl-tRNA synthetases may be split into two classes according to the occurrence of specific combinations of peptide motifs. This study deals with the functional role of the KMSKS motif, which, in association with the HIGH motif, defines class 1 aminoacyl-tRNA synthetases. Each residue in the 332KMSKS336 sequence of Escherichia coli methionyl-tRNA synthetase, as well as R337 and the two surrounding G330 and G338 residues, were mutagenized. The comparison of the kinetic and equilibrium parameters of the methionine activation reaction sustained by the resulting variants enables the following conclusions to be drawn. (1) Mutation of all the residues studied strongly destabilizes the transition state for the formation of methionyl adenylate whilst changing moderately the stability of the ground state ternary complex enzyme, methionine: ATP-Mg2+. The consequences of the mutations are also reflected at the level of the stability of the ground state enzyme, methionyl adenylate:PPi-Mg2+ complex which is systematically decreased. (2) The substitution with alanine of any one of the three basic residues K332, K335 and R337 destabilizes the transition state by more than 3.2 kcal/mol, while substitution of the non-basic residues M333, S334 or S336 destabilizes it by at most 2.5 kcal/mol. Such a difference may reflect different modes of action of the residues, with the basic ones directly interacting with the beta and gamma phosphates of the ATP-Mg2+ substrate and the non-basic ones playing a structural role and/or participating in mobility of the enzyme region carrying the motif. (3) Modification of G330 or G338 to a proline markedly decreases the kinetic rate of methionyl adenylate formation. This behaviour suggests that the flexibility of the KMSKS loop in the structure of methionyl-tRNA synthetase is required to reach the transition state during formation of methionyl adenylate.

Two acidic residues of Escherichia coli methionyl-tRNA synthetase act as negative discriminants towards the binding of non-cognate tRNA anticodons.

Escherichia coli methionyl-tRNA synthetase recognizes its cognate tRNAs according to the sequence of the CAU anticodon. In order to identify residues of methionyl-tRNA synthetase involved in tRNA anticodon recognition, enzyme variants created by cassette mutagenesis were genetically screened for their acquired ability to charge tRNA(mMet) derivatives with an ochre or an amber anticodon and, consequently, to cause the suppression of a stop codon in an indicator gene. The selected enzymes are called suppressors. Mutations were firstly directed towards the region of the synthetase encompassing residues 451 to 467. Several dozens of suppressor enzymes were compared. Statistical analysis of the mutations suggested that the substitution of an Asp side-chain at position 456 was sufficient to render possible the charging of the ochre or amber suppressor tRNAs. Point mutants at this position were therefore constructed. Their behaviour demonstrated that various tRNA(Met) derivatives having a non-Met anticodon could be aminoacylated in vitro provided only that the side-chain of residue 456 was no longer acidic. In turn, the Asp456 residue is not essential to the CAU anticodon recognition, since its substitution does not impair the aminoacylation of wild-type tRNA(Met). The analysis was enlarged to a second region from residue 437 to residue 454. The mutagenesis highlighted two other positions, one of which, Asn452, appeared involved in wild-type tRNA(Met) binding. The second position, Asp449, plays a role very similar to that of Asp456. It is concluded that both Asp449 and 456 behave as "antideterminants", contributing together to the rejection by the enzyme of tRNAs carrying non-Met anticodons. Finally, it is shown that the activities of some particular methionyl-tRNA synthetase variants, which have been made indifferent to the sequence of the anticodon of a tRNA(Met), are tightly dependent on the presence of the nucleotide determinants specific to the acceptor stem of tRNA(Met).