Role for a conserved structural motif in assembly of a class I aminoacyl-tRNA synthetase active site

The catalytic domains of class I aminoacyl-tRNA synthetases are built around a conserved Rossmann nucleotide binding fold, with additional polypeptide domains responsible for tRNA binding or hydrolytic editing of misacylated substrates. Structural comparisons identified a conserved motif bridging the catalytic and anticodon binding domains of class Ia and Ib enzymes. This stem contact fold (SCF) has been proposed to globally orient each enzyme's cognate tRNA by interacting with the inner corner of the L-shaped tRNA. Despite the structural similarity of the SCF among class Ia/Ib enzymes, the sequence conservation is low. We replaced amino acids of the MetRS SCF with portions of the structurally similar glutaminyl-tRNA synthetase (GlnRS) motif or with alanine residues. Chimeric variants retained significant tRNA methionylation activity, indicating that structural integrity of the helix-turn-strand-helix motif contributes more to tRNA aminoacylation than does amino acid identity. In contrast, chimeras were significantly reduced in methionyl adenylate synthesis, suggesting a role for the SCF in formation of a structured active site domain. A highly conserved aspartic acid within the MetRS SCF is proposed to make an electrostatic interaction with an active site lysine; these residues were replaced with alanines or conservative substitutions. Both methionyl adenylate formation and methionine transfer were impaired, and activity was not significantly recovered by making the compensatory double substitution.     

Adaptation to tRNA acceptor stem structure by flexible adjustment in the catalytic domain of class I tRNA synthetases

Class I aminoacyl-tRNA synthetases (aaRSs) use a Rossmann-fold domain to catalyze the synthesis of aminoacyl-tRNAs required for decoding genetic information. While the Rossmann-fold domain is conserved in evolution, the acceptor stem near the aminoacylation site varies among tRNA substrates, raising the question of how the conserved protein fold adapts to RNA sequence variations. Of interest is the existence of an unpaired C-A mismatch at the 1-72 position unique to bacterial initiator tRNA(fMet) and absent from elongator tRNAs. Here we show that the class I methionyl-tRNA synthetase (MetRS) of Escherichia coli and its close structural homolog cysteinyl-tRNA synthetase (CysRS) display distinct patterns of recognition of the 1-72 base pair. While the structural homology of the two enzymes in the Rossmann-fold domain is manifested in a common burst feature of aminoacylation kinetics, CysRS discriminates against unpaired 1-72, whereas MetRS lacks such discrimination. A structure-based alignment of the Rossmann fold identifies the insertion of an α-helical motif, specific to CysRS but absent from MetRS, which docks on 1-72 and may discriminate against mismatches. Indeed, substitutions of the CysRS helical motif abolish the discrimination against unpaired 1-72. Additional structural alignments reveal that with the exception of MetRS, class I tRNA synthetases contain a structural motif that docks on 1-72. This work demonstrates that by flexible insertion of a structural motif to dock on 1-72, the catalytic domain of class I tRNA synthetases can acquire structural plasticity to adapt to changes at the end of the tRNA acceptor stem.     

A recurrent general RNA binding domain appended to plant methionyl-tRNA synthetase acts as a cis-acting cofactor for aminoacylation

The cDNA encoding rice methionyl-tRNA synthetase was isolated. The protein exhibited a C-terminal polypeptide appended to a classical MetRS domain. This supplementary domain is related to endothelial monocyte activating polypeptide II (EMAPII), a cytokine produced in mammals after cleavage of p43, a component of the multisynthetase complex. It is also related to Arc1p and Trbp111, two tRNA binding proteins. We expressed rice MetRS and a derivative with a deletion of its EMAPII-like domain. Band-shift analysis showed that this extra-domain provides MetRS with non-specific tRNA binding properties. The EMAPII-like domain contributed a 10-fold decrease in K:(M) for tRNA in the aminoacylation reaction catalyzed by the native enzyme, as compared with the C-terminally truncated MetRS. Consequently, the EMAPII domain provides MetRS with a better catalytic efficiency at the free tRNA concentration prevailing in vivo. This domain binds the acceptor minihelix of tRNA(Met) and facilitates its aminoacylation. These results suggest that the EMAPII module could be a relic of an ancient tRNA binding domain that was incorporated into primordial synthetases for aminoacylation of RNA minihelices taken as the ancestor of modern tRNA.     

Three-dimensional structure of methionyl-tRNA synthetase from Pyrococcus abyssi

In class 1 aminoacyl-tRNA synthetases, methionyl-tRNA synthetases (MetRS) are homodimers or monomers depending on the presence or absence of a domain appended at the C-side of the polypeptide chain. Beyond this C-domain, all MetRS display a highly conserved catalytic core with a Rossmann fold, the two halves of which are linked by a connective peptide (CP). Three-dimensional folding of CP and its putative zinc content have served as a basis to propose a division of the MetRS family into four subgroups. All subgroups but one, which is predicted to display two zincs per MetRS polypeptide, have been characterized. In the present study, the 3D structure of MetRS from Pyrococcus abyssi could be solved at 2.9 A resolution. The data obtained and atomic absorption spectroscopic measurements establish the presence of two metal ions per polypeptide chain. This finding brings strong support to the above classification. In the crystal, the C-terminal dimerization domain is disordered. This observation is thought to reflect marked flexibility of the two core moieties with respect to the C-domains in the dimer. Gel shift experiments were performed with the isolated C-terminal dimerization domain and a core monomeric MetRS, both derived from the P. abyssi enzyme. Complex formation between the C-domain and the core enzyme could not be evidenced. Moreover, association of tRNA(Met) to the core enzyme is enhanced in the presence of the C-domain. Together, these experiments suggest positive control in trans by the C-domain on recognition of tRNA by the core moiety of MetRS.     

Limited set of amino acid residues in a class Ia aminoacyl-tRNA synthetase is crucial for tRNA binding

The aim of this work was to characterize crucial amino acids for the aminoacylation of tRNA(Arg) by yeast arginyl-tRNA synthetase. Alanine mutagenesis was used to probe all the side chain mediated interactions that occur between tRNA(Arg2)(ICG) and ArgRS. The effects of the substitutions were analyzed in vivo in an ArgRS-knockout strain and in vitro by measuring the aminoacylation efficiencies for two distinct tRNA(Arg) isoacceptors. Nine mutants that generate lethal phenotypes were identified, suggesting that only a limited set of side chain mediated interactions is essential for tRNA recognition. The majority of the lethal mutants was mapped to the anticodon binding domain of ArgRS, a helix bundle that is characteristic for class Ia synthetases. The alanine mutations induce drastic decreases in the tRNA charging rates, which is correlated with a loss in affinity in the catalytic site for ATP. One of those lethal mutations corresponds to an Arg residue that is strictly conserved in all class Ia synthetases. In the known crystallographic structures of complexes of tRNAs and class Ia synthetases, this invariant Arg residue stabilizes the idiosyncratic conformation of the anticodon loop. This paper also highlights the crucial role of the tRNA and enzyme plasticity upon binding. Divalent ions are also shown to contribute to the induced fit process as they may stabilize the local tRNA-enzyme interface. Furthermore, one lethal phenotype can be reverted in the presence of high Mg(2+) concentrations. In contrast with the bacterial system, in yeast arginyl-tRNA synthetase, no lethal mutation has been found in the ArgRS specific domain recognizing the Dhu-loop of the tRNA(Arg). Mutations in this domain have no effects on tRNA(Arg) aminoacylation, thus confirming that Saccharomyces cerevisiae and other fungi belong to a distinct class of ArgRS.     

Class I tyrosyl-tRNA synthetase has a class II mode of cognate tRNA recognition

Bacterial tyrosyl-tRNA synthetases (TyrRS) possess a flexibly linked C-terminal domain of approximately 80 residues, which has hitherto been disordered in crystal structures of the enzyme. We have determined the structure of Thermus thermophilus TyrRS at 2.0 A resolution in a crystal form in which the C-terminal domain is ordered, and confirm that the fold is similar to part of the C-terminal domain of ribosomal protein S4. We have also determined the structure at 2.9 A resolution of the complex of T.thermophilus TyrRS with cognate tRNA(tyr)(G Psi A). In this structure, the C-terminal domain binds between the characteristic long variable arm of the tRNA and the anti-codon stem, thus recognizing the unique shape of the tRNA. The anticodon bases have a novel conformation with A-36 stacked on G-34, and both G-34 and Psi-35 are base-specifically recognized. The tRNA binds across the two subunits of the dimeric enzyme and, remarkably, the mode of recognition of the class I TyrRS for its cognate tRNA resembles that of a class II synthetase in being from the major groove side of the acceptor stem.     

Using molecular dynamics to map interaction networks in an aminoacyl-tRNA synthetase

Long-range functional communication is a hallmark of many enzymes that display allostery, or action-at-a-distance. Many aminoacyl-tRNA synthetases can be considered allosteric, in that their trinucleotide anticodons bind the enzyme at a site removed from their catalytic domains. Such is the case with E. coli methionyl-tRNA synthase (MetRS), which recognizes its cognate anticodon using a conserved tryptophan residue 50 A away from the site of tRNA aminoacylation. The lack of details regarding how MetRS and tRNA(Met) interact has limited efforts to deconvolute the long-range communication that occurs in this system. We have used molecular dynamics simulations to evaluate the mobility of wild-type MetRS and a Trp-461 variant shown previously by experiment to be deficient in tRNA aminoacylation. The simulations reveal that MetRS has significant mobility, particularly at structural motifs known to be involved in catalysis. Correlated motions are observed between residues in distant structural motifs, including the active site, zinc binding motif, and anticodon binding domain. Both mobility and correlated motions decrease significantly but not uniformly upon substitution at Trp-461. Mobility of some residues is essentially abolished upon removal of Trp-461, despite being tens of Angstroms away from the site of mutation and solvent exposed. This conserved residue does not simply participate in anticodon binding, as demonstrated experimentally, but appears to mediate the protein's distribution of structural ensembles. Finally, simulations of MetRS indicate that the ligand-free protein samples conformations similar to those observed in crystal structures with substrates and substrate analogs bound. Thus, there are low energetic barriers for MetRS to achieve the substrate-bound conformations previously determined by structural methods.     

Complementation of yeast Arc1p by the p43 component of the human multisynthetase complex does not require its association with yeast MetRS and GluRS

Yeast Arc1p, human p43 and plant methionyl-tRNA synthetase (MetRS) possess an EMAPII-like domain capable of non-specific interactions with tRNA. Arc1p interacts with MetRS (MES1) and GluRS and operates as a tRNA-interacting factor (tIF) in trans of these two synthetases. In plant MetRS, the EMAPII-like domain is fused to the catalytic core of the synthetase and acts as a cis-acting tIF for aminoacylation. We observed that the catalytic core of plant MetRS expressed from a centromeric plasmid cannot complement a yeast arc1(-) mes1(-) strain. Overexpression of the mutant enzyme from a high-copy number plasmid restored cell growth, suggesting that deletion of its C-terminal tIF domain was responsible for the poor aminoacylation efficiency of that enzyme in vivo. Accordingly, expression of full-size plant MetRS from a centromeric plasmid, but also of fusion proteins between its catalytic core and the EMAPII-like domains of yeast Arc1p or of human p43 restored cell viability. These data showed that homologous tIF domains from different origins are interchangeable and may act indifferently in trans or in cis of the catalytic domain of a synthetase. Unexpectedly, co-expression of Arc1p with the catalytic core of plant MetRS restored cell viability as well, even though Arc1p did not associate with plant MetRS. Because Arc1p also interacts with yeast GluRS, restoration of cell growth could be due at least in part to its role of cofactor for that enzyme. However, co-expression of human p43, a tIF that did not associate with plant MetRS or with yeast GluRS and MetRS, also restored cell viability of a yeast strain that expressed the catalytic core of plant MetRS. These results show that p43 and Arc1p are able to facilitate tRNA aminoacylation in vivo even if they do not interact physically with the synthetases. We propose that p43/Arc1p may be involved in sequestering tRNAs in the cytoplasm of eukaryotic cells, thereby increasing their availability for protein synthesis.     

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.     

The crystal structure of a Thermus thermophilus tRNA(Gly) acceptor stem microhelix at 1.6 Å resolution

tRNAs are aminoacylated with the correct amino acid by the cognate aminoacyl-tRNA synthetase. The tRNA/synthetase systems can be divided into two classes: class I and class II. Within class I, the tRNA identity elements that enable the specificity consist of complex sequence and structure motifs, whereas in class II the identity elements are assured by few and simple determinants, which are mostly located in the tRNA acceptor stem. The tRNA(Gly)/glycyl-tRNA-synthetase (GlyRS) system is a special case regarding evolutionary aspects. There exist two different types of GlyRS, namely an archaebacterial/human type and an eubacterial type, reflecting the evolutionary divergence within this system. We previously reported the crystal structures of an Escherichia coli and of a human tRNA(Gly) acceptor stem microhelix. Here we present the crystal structure of a thermophilic tRNA(Gly) aminoacyl stem from Thermus thermophilus at 1.6? resolution and provide insight into the RNA geometry and hydration.     

The fidelity of the translation of the genetic code.

Aminoacyl-tRNA synthetases play a central role in maintaining accuracy during the translation of the genetic code. To achieve this challenging task they have to discriminate against amino acids that are very closely related not only in structure but also in chemical nature. A 'double-sieve' editing model was proposed in the late seventies to explain how two closely related amino acids may be discriminated. However, a clear understanding of this mechanism required structural information on synthetases that are faced with such a problem of amino acid discrimination. The first structural basis for the editing model came recently from the crystal structure of isoleucyl-tRNA synthetase, a class I synthetase, which has to discriminate against valine. The structure showed the presence of two catalytic sites in the same enzyme, one for activation, a coarse sieve which binds both isoleucine and valine, and another for editing, a fine sieve which binds only valine and rejects isoleucine. Another structure of the enzyme in complex with tRNA showed that the tRNA is responsible for the translocation of the misactivated amino-acid substrate from the catalytic site to the editing site. These studies were mainly focused on class I synthetases and the situation was not clear about how class II enzymes discriminate against similar amino acids. The recent structural and enzymatic studies on threonyl-tRNA synthetase, a class II enzyme, reveal how this challenging task is achieved by using a unique zinc ion in the active site as well as by employing a separate domain for specific editing activity. These studies led us to propose a model which emphasizes the mirror symmetrical approach of the two classes of enzymes and highlights that tRNA is the key player in the evolution of these class of enzymes.     

Comparison of the Intrinsic Dynamics of Aminoacyl-tRNA Synthetases

Aminoacyl-tRNA synthetases (AARSs) are an important family of enzymes that catalyze tRNA aminoacylation reaction (Ibba and Soll in Annu Rev Biochem 2000, 69:617–650) [1]. AARSs are grouped into two broad classes (class I and II) based on sequence/structural homology and mode of their interactions with the tRNA molecule (Ibba and Soll in Annu Rev Biochem 2000, 69:617–650) [1]. As protein dynamics play an important role in enzyme function, we explored the intrinsic dynamics of these enzymes using normal mode analysis and investigated if the two classes and six subclasses (Ia–c and IIa–c) of AARSs exhibit any distinct patterns of motion. The present study found that the intrinsic dynamics-based classification of these enzymes is similar to that obtained based on sequence/structural homology for most enzymes. However, the classification of seryl-tRNA synthetase was not straightforward; the internal mobility patterns of this enzyme are comparable to both IIa and IIb AARSs. This study revealed only a few general mobility patterns in these enzymes—(1) the insertion domain is generally engaged in anticorrelated motion with respect to the catalytic domain for both classes of AARSs and (2) anticodon binding domain dynamics are partly correlated and partly anticorrelated with respect to other domains for class I enzymes. In most of the class II AARSs, the anticodon binding domain is predominately engaged in anticorrelated motion with respect to the catalytic domain and correlated to the insertion domain. This study supports the notion that dynamic-based classification could be useful for functional classification of proteins.     

Methionyl-tRNA synthetase.

Methionyl-tRNA synthetase (MetRS) belongs to the family of 20 enzymes essential for protein biosynthesis. It links covalently methionine with its cognate tRNA. Crystal structures solved for bacterial MetRSs have given a number of interesting insights into enzyme architecture and methionylation catalysis. A comparison of sequences of MetRSs belonging to all kingdoms of life, as well as numerous biochemical and genetic studies have revealed the presence of various additional domains appended to the catalytic core of synthetase. They are responsible for interactions with tRNA and proteins. Tertiary structure of C-terminal tRNA-binding appendices can be deduced from those determined for their homologues: tRNA binding protein 111 and endothelial monocyte-activating polypeptide II. Contacts between MetRS and other proteins could be mediated not only by noncatalytic peptides but also by structural elements present in the catalytic core, e.g. Arg-Gly-Asp (RGD) motifs. Additional activities involve MetRS in the maintenance of translational fidelity and in coordination of ribosome biogenesis with protein synthesis.     

Activation of methionine by Escherichia coli methionyl-tRNA synthetase

In the present work, we have examined the function of three amino acid residues in the active site of Escherichia coli methionyl-tRNA synthetase (MetRS) in substrate binding and catalysis using site-directed mutagenesis. Conversion of Asp52 to Ala resulted in a 10,000-fold decrease in the rate of ATP-PPi exchange catalyzed by MetRS with little or no effect on the Km's for methionine or ATP or on the Km for the cognate tRNA in the aminoacylation reaction. Substitution of the side chain of Arg233 with that of Gln resulted in a 25-fold increase in the Km for methionine and a 2000-fold decrease in kcat for ATP-PPi exchange, with no change in the Km for ATP or tRNA. These results indicate that Asp52 and Arg233 play important roles in stabilization of the transition state for methionyl adenylate formation, possibly directly interacting with complementary charged groups (ammonium and carboxyl) on the bound amino acid. Primary sequence comparisons of class I aminoacyl-tRNA synthetases show that all but one member of this group of enzymes has an aspartic acid residue at the site corresponding to Asp52 in MetRS. The synthetases most closely related to MetRS (including those specific for Ile, Leu, and Val) also have a conserved arginine residue at the position corresponding to Arg233, suggesting that these conserved amino acids may play analogous roles in the activation reaction catalyzed by each of these enzymes. Trp305 is located in a pocket deep within the active site of MetRS that has been postulated to form the binding cleft for the methionine side chain.(ABSTRACT TRUNCATED AT 250 WORDS)     

Crystal structure of histidyl-tRNA synthetase from Escherichia coli complexed with histidyl-adenylate.

The crystal structure at 2.6 A of the histidyl-tRNA synthetase from Escherichia coli complexed with histidyl-adenylate has been determined. The enzyme is a homodimer with a molecular weight of 94 kDa and belongs to the class II of aminoacyl-tRNA synthetases (aaRS). The asymmetric unit is composed of two homodimers. Each monomer consists of two domains. The N-terminal catalytic core domain contains a six-stranded antiparallel beta-sheet sitting on two alpha-helices, which can be superposed with the catalytic domains of yeast AspRS, and GlyRS and SerRS from Thermus thermophilus with a root-mean-square difference on the C alpha atoms of 1.7-1.9 A. The active sites of all four monomers are occupied by histidyl-adenylate, which apparently forms during crystallization. The 100 residue C-terminal alpha/beta domain resembles half of a beta-barrel, and provides an independent domain oriented to contact the anticodon stem and part of the anticodon loop of tRNA(His). The modular domain organization of histidyl-tRNA synthetase reiterates a repeated theme in aaRS, and its structure should provide insight into the ability of certain aaRS to aminoacylate minihelices and other non-tRNA molecules.     

A novel anti-tumor cytokine contains an RNA binding motif present in aminoacyl-tRNA synthetases

Endothelial monocyte-activating polypeptide II (EMAP II) is a novel pro-apoptotic cytokine that shares sequence homology with the C-terminal regions of several tRNA synthetases. Pro-EMAP II, the precursor of EMAP II, is associated with the multi-tRNA synthetase complex and facilitates aminoacylation activity. The structure of human EMAP II, solved at 1.8 A resolution, revealed the oligomer-binding fold for binding different tRNAs and a domain that is structurally homologous to other chemokines. The similar structures to the RNA binding motif of EMAP II was previously observed in the anticodon binding domain of yeast Asp-tRNA synthetase (AspRSSC) and the B2 domain of Thermus thermophilus Phe-tRNA synthetase. The RNA binding pattern of EMAP II is likely to be nonspecific, in contrast to the AspRSSC. The peptide sequence that is responsible for cytokine activity is located, for the most part, in the beta1 strand. It is divided into two regions by a neighboring loop.     

Evolutionary coadaptation of the motif 2--acceptor stem interaction in the class II prolyl-tRNA synthetase system

Known crystal structures of class II aminoacyl-tRNA synthetases complexed to their cognate tRNAs reveal that critical acceptor stem contacts are made by the variable loop connecting the beta-strands of motif 2 located within the catalytic core of class II synthetases. To identify potential acceptor stem contacts made by Escherichia coli prolyl-tRNA synthetase (ProRS), an enzyme of unknown structure, we performed cysteine-scanning mutagenesis in the motif 2 loop. We identified an arginine residue (R144) that was essential for tRNA aminoacylation but played no role in amino acid activation. Cross-linking experiments confirmed that the end of the tRNA(Pro) acceptor stem is proximal to this motif 2 loop residue. Previous work had shown that the tRNA(Pro) acceptor stem elements A73 and G72 (both strictly conserved among bacteria) are important recognition elements for E. coli ProRS. We carried out atomic group "mutagenesis" studies at these two positions of E. coli tRNA(Pro) and determined that major groove functional groups at A73 and G72 are critical for recognition by ProRS. Human tRNA(Pro), which lacks these elements, is not aminoacylated by the bacterial enzyme. An analysis of chimeric tRNA(Pro) constructs showed that, in addition to A73 and G72, transplantation of the E. coli tRNA(Pro) D-domain was necessary and sufficient to convert the human tRNA into a substrate for the bacterial synthetase. In contrast to the bacterial system, base-specific acceptor stem recognition does not appear to be used by human ProRS. Alanine-scanning mutagenesis revealed that motif 2 loop residues are not critical for tRNA aminoacylation activity of the human enzyme. Taken together, our results illustrate how synthetases and tRNAs have coadapted to changes in protein-acceptor stem recognition through evolution.     

Crystal structure of a prokaryotic aspartyl tRNA-synthetase.

The crystal structure of Thermus thermophilus aspartyl tRNA-synthetase (AspRS) refined at 2.5 A resolution is described. This molecular structure is a textbook illustration of the modular organization of aminoacyl-tRNA synthetases. In addition to the three domains found in yeast AspRS, each monomer exhibits a module specific to prokaryotic enzymes, which corresponds to a helix-turn-helix motif in yeast AspRS, a domain implicated in the stabilization of the complex with tRNA. Its topology matches that of the histidine-containing phosphocarrier HPr which has been linked recently to another group of proteins containing the ferredoxin fold. We propose a more extensive alignment of these folds, which involves a circular permutation of the sequences and changes the point of entry of the whole domain. The C-terminal extension, another prokaryotic characteristic, leads to a significant increase in the network of interaction at the dimer interface. Some potential communication pathways suggest how a transfer of information between the two active sites of the homodimer might occur. Most of the residues involved belong to the class II-specific motifs in correlation with the dimeric state of nearly all class II enzymes. The T. thermophilus enzyme exhibits some features not found in any of the six other known AspRSs from mesophilic organisms.