Interaction of aminoacyl-tRNA synthetases with tRNA: General principles and distinguishing characteristics of the high-molecular-weight substrate recognition

This review summarizes results of numerous (mainly functional) studies that have been accumulated over recent years on the problem of tRNA recognition by aminoacyl-tRNA synthetases. Development and employment of approaches that use synthetic mutant and chimeric tRNAs have demonstrated general principles underlying highly specific interaction in different systems. The specificity of interaction is determined by a certain number of nucleotides and structural elements of tRNA (constituting the set of recognition elements or specificity determinants), which are characteristic of each pair. Crystallographic structures available for many systems provide the details of the molecular basis of selective interaction. Diversity and identity of biochemical functions of the recognition elements make substantial contribution to the specificity of such interactions.     

Discovery of two distinct aminoacyl-tRNA synthetase complexes anchored to the Plasmodium surface tRNA import protein

Aminoacyl-tRNA synthetases (aaRSs) attach amino acids to their cognate transfer RNAs. In eukaryotes, a subset of cytosolic aaRSs is organized into a multisynthetase complex (MSC), along with specialized scaffolding proteins referred to as aaRS-interacting multifunctional proteins (AIMPs). In Plasmodium, the causative agent of malaria, the tRNA import protein (tRip), is a membrane protein that participates in tRNA trafficking; we show that tRip also functions as an AIMP. We identified three aaRSs, the glutamyl-tRNA synthetase (ERS), glutaminyl-tRNA synthetase (QRS), and methionyl-tRNA synthetase (MRS), which were specifically coimmunoprecipitated with tRip in Plasmodium berghei blood stage parasites. All four proteins contain an N-terminal glutathione-S-transferase (GST)–like domain that was demonstrated to be involved in MSC assembly. In contrast to previous studies, further dissection of GST-like interactions identified two exclusive heterotrimeric complexes: the Q-complex (tRip–ERS–QRS) and the M-complex (tRip–ERS–MRS). Gel filtration and light scattering suggest a 2:2:2 stoichiometry for both complexes but with distinct biophysical properties and mutational analysis further revealed that the GST-like domains of QRS and MRS use different strategies to bind ERS. Taken together, our results demonstrate that neither the singular homodimerization of tRip nor its localization in the parasite plasma membrane prevents the formation of MSCs in Plasmodium. Besides, the extracellular localization of the tRNA-binding module of tRip is compensated by the presence of additional tRNA-binding modules fused to MRS and QRS, providing each MSC with two spatially distinct functions: aminoacylation of intraparasitic tRNAs and binding of extracellular tRNAs. This unique host–pathogen interaction is discussed.     

Mitochondrial aminoacyl-tRNA synthetase single-nucleotide polymorphisms that lead to defects in refolding but not aminoacylation

Defects in organellar translation are the underlying cause of a number of mitochondrial diseases, including diabetes, deafness, encephalopathy, and other mitochondrial myopathies. The most common causes of these diseases are mutations in mitochondria-encoded tRNAs. It has recently become apparent that mutations in nuclear-encoded components of the mitochondrial translation machinery, such as aminoacyl-tRNA synthetases (aaRSs), can also lead to disease. In some cases, mutations can be directly linked to losses in enzymatic activity; however, for many, their effect is unknown. To investigate how aaRS mutations impact function without changing enzymatic activity, we chose nonsynonymous single-nucleotide polymorphisms (nsSNPs) that encode residues distal from the active site of human mitochondrial phenylalanyl-tRNA synthetase. The phenylalanyl-tRNA synthetase variants S57C and N280S both displayed wild-type aminoacylation activity and stability with respect to their free energies of unfolding, but were less stable at low pH. Mitochondrial proteins undergo partial unfolding/refolding during import, and both S57C and N280S variants retained less activity than wild type after refolding, consistent with their reduced stability at low pH. To examine possible defects in protein folding in other aaRS nsSNPs, we compared the refolding of the human mitochondrial leucyl-tRNA synthetase variant H324Q to that of wild type. The H324Q variant had normal activity prior to unfolding, but displayed a refolding defect resulting in reduced aminoacylation compared to wild type after renaturation. These data show that nsSNPs can impact mitochondrial translation by changing a biophysical property of a protein (in this case refolding) without affecting the corresponding enzymatic activity.     

Mutant enzymes and tRNAs as probes of the glutaminyl-tRNA synthetase: tRNA interaction

This paper focuses on several aspects of the specificity of mutants of Escherichia coli glutaminyl-tRNA synthetase (GlnRS) and tRNA^Gln. Temperature-sensitive mutants located in glnS, the gene for GlnRS, have been described previously. The mutations responsible for the temperature-sensitive phenotype were analyzed, and pseudorevertants of these mutants isolated and characterized. The nature of these mutations is discussed in terms of their location in the three-dimensional structure of the tRNA^Gln: GlnRS complex. In order to characterize the specificity of the aminoacylation reaction, mutant tRNA^Gln species were synthesized with either a 2′-deoxy AMP or 3′-deoxy AMP as their 3′-terminal nucleotide. Subsequent assays for aminoacylation and ATP/PP_i exchange activity established the esterification of glutamine to the 2′-hydroxyl of the terminal adenosine: there is no glutaminylation of the 3′-OH group. This correlates with the classification of GlnRS as a class I aminoacyl-tRNA synthetase. Mutations in tRNA^Gln are discussed which affect the recognition of GlnRS and the current concept of glutamine identity in E coli is reviewed.     

Searching tRNA sequences for relatedness to aminoacyl-tRNA synthetase families

tRNA sequences were analyzed for sequence features correlated with known classes of aminoacyl-tRNA synthetase enzymes. The tRNAs were searched for distinguishing nucleotides anywhere in their sequences. The analyses did not find nucleotides predictive of synthetase class membership. We conclude that such nucleotides never existed in tRNA sequences or that they existed and were lost from many of the tRNA sequences during evolution.Based on a presentation made at a workshop—Aminoacyl-tRNA Synthetases and the Evolution of the Genetic Code—held at Berkeley, CA, July 17–20, 1994 Correspondence to: H.B. Nicholas, Jr.     

tRNA discrimination by T. thermophilus phenylalanyl-tRNA synthetase at the binding step

The extent of tRNA recognition at the level of binding by Thermus thermophilus phenylalanyl-tRNA synthetase (PheRS), one of the most complex class II synthetases, has been studied by independent measurements of the enzyme association with wild-type and mutant tRNA(Phe)s as well as with non-cognate tRNAs. The data obtained, combined with kinetic data on aminoacylation, clearly show that PheRS exhibits more tRNA selectivity at the level of binding than at the level of catalysis. The anticodon nucleotides involved in base-specific interactions with the enzyme prevail both in the initial binding recognition and in favouring aminoacylation catalysis. Tertiary nucleotides of base pair G19-C56 and base triple U45-G10-C25 contribute primarily to stabilization of the correctly folded tRNA(Phe) structure, which is important for binding. Other nucleotides of the central core (U20, U16 and of the A26-G44 tertiary base pair) are involved in conformational adjustment of the tRNA upon its interaction with the enzyme. The specificity of nucleotide A73, mutation of which slightly reduces the catalytic rate of aminoacylation, is not displayed at the binding step. A few backbone-mediated contacts of PheRS with the acceptor and anticodon stems revealed in the crystal structure do not contribute to tRNA(Phe) discrimination, their role being limited to stabilization of the complex. The highest affinity of T. thermophilus PheRS for cognate tRNA, observed for synthetase-tRNA complexes, results in 100-3000-fold binding discrimination against non-cognate tRNAs.     

A N-H nuclear magnetic resonance study on the interaction between isoleucine tRNA and isoleucyl-tRNA synthetase from Escherichia coli

Imino ¹⁵N and ¹H resonances of Escherichia coli tRNA_l^Ile were observed in the absence and presence of E coli isoleucyl-tRNA synthetase. Upon complex formation of tRNA_l^Ile with isoleucyl-tRNA synthetase, some imino ¹⁵N-¹H resonances disappeared, and some others were significantly broadened and/or shifted in the ¹H chemical shift, while the others were observed at the same ¹⁵H-¹H chemical shifts. It was indicated that the binding of tRNA_l^Ile with IleRS affect the following four regions: the anticodon stem, the junction of the acceptor and T stems, the middle of the D stem, and the region where the tertiary base pair connects the T, D, and extra loops. This result is consistent with those of chemical footprinting and site-directed mutagenesis studies. Taken together, these three independent results reveal the recognition mechanism of tRNA_l^Ile by IleRS: IleRS recognizes all the identity determinants distributed throughout the tRNA_l^Ile molecule, which induces changes in the secondary and tertiary structures of tRNA_l^Ile.     

Crystal structure of human cytosolic aspartyl‐tRNA synthetase,a component of multi‐tRNA synthetase complex

Human cytosolic aspartyl‐tRNA synthetase (DRS) catalyzes the attachment of the amino acid aspartic acid to its cognate tRNA and it is a component of the multi‐tRNA synthetase complex (MSC) which has been known to be involved in unexpected signaling pathways. Here, we report the crystal structure of DRS at a resolution of 2.25 Å. DRS is a homodimer with a dimer interface of 3750.5 Ų which comprises 16.6% of the monomeric surface area. Our structure reveals the C‐terminal end of the N‐helix which is considered as a unique addition in DRS, and its conformation further supports the switching model of the N‐helix for the transfer of tRNA^Asp to elongation factor 1α. From our analyses of the crystal structure and post‐translational modification of DRS, we suggest that the phosphorylation of Ser146 provokes the separation of DRS from the MSC and provides the binding site for an interaction partner with unforeseen functions.Proteins 2013; 81:1840–1846. © 2013 Wiley Periodicals, Inc.     

A new mechanism of post-transfer editing by aminoacyl-tRNA synthetases: catalysis of hydrolytic reaction by bacterial-type prolyl-tRNA synthetase

Aminoacyl tRNA synthetases are enzymes that specifically attach amino acids to cognate tRNAs for use in the ribosomal stage of translation. For many aminoacyl tRNA synthetases, the required level of amino acid specificity is achieved either by specific hydrolysis of misactivated aminoacyl-adenylate intermediate (pre-transfer editing) or by hydrolysis of the mischarged aminoacyl-tRNA (post-transfer editing). To investigate the mechanism of post-transfer editing of alanine by prolyl-tRNA synthetase from the pathogenic bacteria Enterococcus faecalis, we used molecular modeling, molecular dynamic simulations, quantum mechanical (QM) calculations, site-directed mutagenesis of the enzyme, and tRNA modification. The results support a new tRNA-assisted mechanism of hydrolysis of misacylated Ala-tRNA^Pro. The most important functional element of this catalytic mechanism is the 2′-OH group of the terminal adenosine 76 of Ala-tRNA^Pro, which forms an intramolecular hydrogen bond with the carbonyl group of the alanine residue, strongly facilitating hydrolysis. Hydrolysis was shown by QM methods to proceed via a general acid-base catalysis mechanism involving two functionally distinct water molecules. The transition state of the reaction was identified. Amino acid residues of the editing active site participate in the coordination of substrate and both attacking and assisting water molecules, performing the proton transfer to the 3′-O atom of A76.     

Structural analysis of the multienzyme aminoacyl-tRNA synthetase complex: a three-domain model based on reversible chemical crosslinking.

A subset of eukaryotic aminoacyl-tRNA synthetases (a-RS) are contained in a multienzyme complex for which little structural detail is known. Three reversible chemical crosslinking reagents have been used to investigate the arrangement of polypeptides within this particle as isolated from rabbit reticulocytes. Identification of the crosslinked protein pairs was accomplished by two-dimensional SDS diagonal gel electrophoresis. Seventeen neighboring protein pairs have been identified. Eight are seen with at least two reagents: K-RS:p38, D-RS:K-RS, R-RS dimer, K-RS dimer, K-RS:Q-RS, E/P-RS:K-RS, E/P-RS:I-RS, and Q-RS with one of the nonsynthetase proteins. Nine more are observed with one reagent: D-RS dimer, R-RS:p43, D-RS:Q-RS, D-RS:M-RS, K-RS:L-RS, I-RS:R-RS, D-RS:E/P-RS, I-RS:Q-RS, I-RS:L-RS. One trimeric association is seen: E/P-RS:I-RS:L-RS. The observed neighboring protein pairs suggest that the polypeptides within the aminoacyl-tRNA synthetase complex are distributed in three structural domains of similar mass. These can be arranged in a U-shaped particle in which each "arm" is considered a domain and the third forms the "base" of the structure. The arms have been termed domain I (D-RS, M-RS, Q-RS) and domain II (K-RS, R-RS), with domain III (E/P-RS, I-RS, L-RS) assigned to the base. The smaller proteins (p38, p43) may bridge the domains. This proposed spatial relationship of these domains, as well as their compositions, are consistent with earlier studies. Thus, this study provides an initial three-dimensional working model of the arrangement of polypeptides within the multienzyme aminoacyl-tRNA synthetase complex.     

Escherichia coli glutaminyl-tRNA synthetase is electrostatically optimized for binding of its cognate substrates

Natural evolution has resulted in protein molecules displaying a wide range of binding properties that include extremes of affinity and specificity. A detailed understanding of the principles underlying protein structure-function relationships, particularly with respect to binding properties, would greatly enhance molecular engineering and ligand design studies. Here, we have analyzed the interactions of an aminoacyl-tRNA synthetase for which strong evolutionary pressure has enforced high specificity for substrate binding and catalysis. Electrostatic interactions have been identified as one efficient mechanism for enhancing binding specificity; as such, the effects of charged and polar groups were the focus of this study. The binding of glutaminyl-tRNA synthetase from Escherichia coli to several ligands, including the natural substrates, was analyzed. The electrostatic complementarity of the enzyme to its ligands was assessed using measures derived from affinity optimization theory. The results were independent of the details of the calculational parameters, including the value used for the protein dielectric constant. Glutamine and ATP, two of the natural ligands, were found to be extremely complementary to their binding sites, particularly in regions seen to make electrostatic interactions in the structure. These data suggest that the optimization of electrostatic interactions has played an important role in guiding the evolution of this enzyme. The results also show that the enzyme is able to effectively select for high affinity and specificity for the same chemical moieties both in the context of smaller substrates, and in that of a larger reactive intermediate. The regions of greatest non-complementarity between the enzyme and ligands are the portions of the ligand that make few polar contacts with the binding site, as well as the sites of chemical reaction, where overly strong electrostatic binding interactions with the substrate could hinder catalysis. The results also suggest that the negative charge on the phosphorus center of glutaminyl-adenylate plays an important role in the tight binding of this intermediate, and thus that adenylate analogs that preserve the negative charge in this region may bind substantially tighter than analogs where this group is replaced with a neutral group, such as the sulfamoyl family, which can make similar hydrogen bonds but is uncharged.     

Enzymatic mechanism of tRNA (mU54)methyltransferase

tRNA (m⁵U54)methyltransferase (RUMT) catalyzes the methylation of uridine 54 of transfer RNA by S-adenosyl-l-methionine. In this report, we present the enzymatic mechanism of RUMT, including the stereochemical course of the methylation reaction, and discuss RUMT-tRNA recognition. As part of its enzymatic mechanism, we postulate that RUMT catalyzes the disruption of RNA-RNA contacts. We also show that many nucleotide substitutions can be made in the T-loop of tRNA without affecting RUMT binding, indicating that the recognition of the T-loop by RUMT is not stringent.     

Influence of the conserved active site residues of histidyl tRNA synthetase on the mechanism of aminoacylation reaction

The relation between the conservation of active site residues and the molecular mechanism of aminoacylation reaction is an unexplored problem. In the present paper, the influences of the conserved active site residues on the reaction mechanism as well as the electrostatic potential near the reaction center are analyzed for Histidyl tRNA synthetase from Escherichia coli, Thermus thermophilus and Staphylococcus aureus. While the primary structures show both convergence as well as divergence, the secondary level structures of the active sites of the three species show considerable conservation in the respective structural organizations. The conserved active site residues near the reaction center, which have a major role in the reaction mechanism and catalysis, retain their specific position and orientation relative to the substrate in the three species. In order to understand the influence of different conserved and nonconserved residues near the reaction center, two different models are considered. First, a large model of active site with the substrates, Mg²⁺ ions and water is constructed in which the first shell residues (including both conserved as well as nonconserved) near the reaction center are studied. From the large model, a smaller model is constructed for reaction path modeling individually for three species. Validation of the smaller model is carried out by comparing the energy surfaces of large and small models as a function of reaction coordinates. Further, the electrostatic potential near the reaction center for the large and small model are compared. The transition state structures of the activation step of aminoacylation reaction for E. coli, T. thermophilus and S. aureus are calculated using the combined ab-initio/semi-empirical calculation. The similarity of the energy profiles as a function of the relevant reaction coordinate and the orientation of the catalytic residue, Arg259, indicate that the reaction mechanisms are identical which are guided by the strikingly similar structural pattern formed by conserved residues for three species. The energy surfaces have close resemblance in three species and present a clear perspective that how the reaction proceeds with the aid of different conserved residues. The study of electrostatic potential confirms this view. The present study provides an understanding of the relationship between the conservation of residues and the efficient reaction mechanism of aminoacylation reaction.     

Disease-associated mutations in a bifunctional aminoacyl-tRNA synthetase gene elicit the integrated stress response

Aminoacyl-tRNA synthetases (ARSs) catalyze the charging of specific amino acids onto cognate tRNAs, an essential process for protein synthesis. Mutations in ARSs are frequently associated with a variety of human diseases. The human EPRS1 gene encodes a bifunctional glutamyl-prolyl-tRNA synthetase (EPRS) with two catalytic cores and appended domains that contribute to nontranslational functions. In this study, we report compound heterozygous mutations in EPRS1, which lead to amino acid substitutions P14R and E205G in two patients with diabetes and bone diseases. While neither mutation affects tRNA binding or association of EPRS with the multisynthetase complex, E205G in the glutamyl-tRNA synthetase (ERS) region of EPRS is defective in amino acid activation and tRNA^Glu charging. The P14R mutation induces a conformational change and altered tRNA charging kinetics in vitro. We propose that the altered catalytic activity and conformational changes in the EPRS variants sensitize patient cells to stress, triggering an increased integrated stress response (ISR) that diminishes cell viability. Indeed, patient-derived cells expressing the compound heterozygous EPRS show heightened induction of the ISR, suggestive of disruptions in protein homeostasis. These results have important implications for understanding ARS-associated human disease mechanisms and development of new therapeutics.     

Effect of calcium-binding protein regucalcin on hepatic protein synthesis: Inhibition of aminoacyl-tRNA synthetase activity

The effect of regucalcin, a calcium-binding protein isolated from rat liver cytosol, onin vitro protein synthesis in the 5500g supernatant fraction of rat liver homogenate was investigated. Addition of Ca²⁺ up to 5.0 M in the reaction mixture caused a significant decrease in protein synthesis. This decrease was saturated at 10 M Ca²⁺. The Ca²⁺ effect was not reversed by the presence of regucalcin (2.0 M); the protein caused a remarkable decrease in hepatic protein synthesis, and it enhanced significantly the Ca^2– effect. Meanwhile, calmodulin (2.5-20 g/ml), a calcium-binding protein, did not have an appreciable effect on the Ca²⁺ (10 M)-induced decrease in hepatic protein synthesis. [³H]Leucyl-tRNA synthetase activity in the 105000g supernatant fraction (cytosol) of liver homogenate was markedly decreased by addition of Ca²⁺ (1.0–50 M). This decrease was not reversed by the presence of regucalcin (2.0 M); the protein (1.0–2.0 M) caused a remarkable decrease in the enzyme activity. The present results suggest that regucalcin can regulate protein synthesis in liver cells.     

Electrostatic recognition in substrate binding to serine proteases

Serine proteases of the Chymotrypsin family are structurally very similar but have very different substrate preferences. This study investigates a set of 9 different proteases of this family comprising proteases that prefer substrates containing positively charged amino acids, negatively charged amino acids, and uncharged amino acids with varying degree of specificity. Here, we show that differences in electrostatic substrate preferences can be predicted reliably by electrostatic molecular interaction fields employing customized GRID probes. Thus, we are able to directly link protease structures to their electrostatic substrate preferences. Additionally, we present a new metric that measures similarities in substrate preferences focusing only on electrostatics. It efficiently compares these electrostatic substrate preferences between different proteases. This new metric can be interpreted as the electrostatic part of our previously developed substrate similarity metric. Consequently, we suggest, that substrate recognition in terms of electrostatics and shape complementarity are rather orthogonal aspects of substrate recognition. This is in line with a 2‐step mechanism of protein‐protein recognition suggested in the literature.     

Cocrystallization of Lysyl–tRNA synthetase from Thermus thermophilus with its cognate tRNAlys and with Escherichia coli tRNAlys

Lysyl-tRNA synthetase from Thermus thermophilus has been cocrystallized with either its cognate tRNA^lYS or Escherichia coli tRNA^lys using ammonium sulfate as precipitant. The crystals grow from solutions containing a 1:2.5 stoichiometry of synthetase dimer to tRNA in 18–22% ammonium sulfate in 50 mM Tris-maleate buffer at pH 7.5. Both complexes form square prismatic, tetragonal crystals with very similar unit cell parameters (a = b = 233 Å, c = 119 Å) and diffract to at least 2.7 Å resolution. However the homocomplex is of space group P42₁2 and the heterocomplex of space group I422. © 1995 Wiley-Liss, Inc.     

家蚕氨酰-tRNA合成酶基因分析

为了探讨家蚕氨酰-tRNA合成酶(BmaaRS)基因的数目、种类、结构及起源, 利用家蚕基因组数据和EST数据进行了BmaaRS基因的电子克隆, 结果表明, 家蚕核基因组中含有2套不同的aaRS核基因, 分别编码线粒体和细胞质BmaaRS, 但编码线粒体BmSerRS的基因有2个, 可能缺少编码细胞质的BmHisRS基因和编码线粒体的BmGlnRS、BmLysRS、BmGlyRS和BmThrRS基因, 这些基因的功能可能由具有相似功能的其他蛋白完成, 或通过某个BmaaRS基因的可变剪接分别形成不同功能的BmaaRS。EST证据表明, BmaaRS基因存在不同形式的可变剪接; BmaaRS氨基酸序列的相似性及二、三级结构分析表明部分BmaaRS存在结构域的扩增, 有些不同的BmaaRS具有相同结构域, 相同功能的BmaaRS具有相似的三级结构; 进化分析表明, BmaaRS为2套不同来源的BmaaRS基因编码, 细胞质和线粒体BmaaRS的起源不同。