A bridge between the aminoacylation and editing domains of leucyl-tRNA synthetase is crucial for its synthetic activity

Leucyl-tRNA synthetases (LeuRSs) catalyze the linkage of leucine with tRNA^Leu. LeuRS contains a catalysis domain (aminoacylation) and a CP1 domain (editing). CP1 is inserted 35 Å from the aminoacylation domain. Aminoacylation and editing require CP1 to swing to the coordinated conformation. The neck between the CP1 domain and the aminoacylation domain is defined as the CP1 hairpin. The location of the CP1 hairpin suggests a crucial role in the CP1 swing and domain–domain interaction. Here, the CP1 hairpin of Homo sapiens cytoplasmic LeuRS (hcLeuRS) was deleted or substituted by those from other representative species. Lack of a CP1 hairpin led to complete loss of aminoacylation, amino acid activation, and tRNA binding; however, the mutants retained post-transfer editing. Only the CP1 hairpin from Saccharomyces cerevisiae LeuRS (ScLeuRS) could partly rescue the hcLeuRS functions. Further site-directed mutagenesis indicated that the flexibility of small residues and the charge of polar residues in the CP1 hairpin are crucial for the function of LeuRS.     

Crystal Structures of the Human and Fungal Cytosolic Leucyl-tRNA Synthetase Editing Domains: A Structural Basis for the Rational Design of Antifungal Benzoxaboroles

Leucyl-tRNA synthetase (LeuRS) specifically links leucine to the 3′ end of tRNA^leu isoacceptors. The overall accuracy of the two-step aminoacylation reaction is enhanced by an editing domain that hydrolyzes mischarged tRNAs, notably ile-tRNA^leu. We present crystal structures of the editing domain from two eukaryotic cytosolic LeuRS: human and fungal pathogen Candida albicans. In comparison with previous structures of the editing domain from bacterial and archeal kingdoms, these structures show that the LeuRS editing domain has a conserved structural core containing the active site for hydrolysis, with distinct bacterial, archeal, or eukaryotic specific peripheral insertions. It was recently shown that the benzoxaborole antifungal compound AN2690 (5-fluoro-1,3-dihydro-1-hydroxy-1,2-benzoxaborole) inhibits LeuRS by forming a covalent adduct with the 3′ adenosine of tRNA^leu at the editing site, thus locking the enzyme in an inactive conformation. To provide a structural basis for enhancing the specificity of these benzoxaborole antifungals, we determined the structure at 2.2 Å resolution of the C. albicans editing domain in complex with a related compound, AN3018 (6-(ethylamino)-5-fluorobenzo[c][1,2]oxaborol-1(3H)-ol), using AMP as a surrogate for the 3′ adenosine of tRNA^leu. The interactions between the AN3018-AMP adduct and C. albicans LeuRS are similar to those previously observed for bacterial LeuRS with the AN2690 adduct, with an additional hydrogen bond to the extra ethylamine group. However, compared to bacteria, eukaryotic cytosolic LeuRS editing domains contain an extra helix that closes over the active site, largely burying the adduct and providing additional direct and water-mediated contacts. Small differences between the human domain and the fungal domain could be exploited to enhance fungal specificity.     

Modular pathways for editing non-cognate amino acids by human cytoplasmic leucyl-tRNA synthetase

To prevent potential errors in protein synthesis, some aminoacyl-transfer RNA (tRNA) synthetases have evolved editing mechanisms to hydrolyze misactivated amino acids (pre-transfer editing) or misacylated tRNAs (post-transfer editing). Class Ia leucyl-tRNA synthetase (LeuRS) may misactivate various natural and non-protein amino acids and then mischarge tRNA^Leu. It is known that the fidelity of prokaryotic LeuRS depends on multiple editing pathways to clear the incorrect intermediates and products in the every step of aminoacylation reaction. Here, we obtained human cytoplasmic LeuRS (hcLeuRS) and tRNA^Leu (hctRNA^Leu) with high activity from Escherichia coli overproducing strains to study the synthetic and editing properties of the enzyme. We revealed that hcLeuRS could adjust its editing strategy against different non-cognate amino acids. HcLeuRS edits norvaline predominantly by post-transfer editing; however, it uses mainly pre-transfer editing to edit α-amino butyrate, although both amino acids can be charged to tRNA^Leu. Post-transfer editing as a final checkpoint of the reaction was very important to prevent mis-incorporation in vitro. These results provide insight into the modular editing pathways created to prevent genetic code ambiguity by evolution.     

Isolated CP1 domain of Escherichia coli leucyl-tRNA synthetase is dependent on flanking hinge motifs for amino acid editing activity

Protein synthesis and its fidelity rely upon the aminoacyl-tRNA synthetases. Leucyl-tRNA synthetase (LeuRS), isoleucyl-tRNA synthetase (IleRS), and valyl-tRNA synthetase (ValRS) have evolved a discrete editing domain called CP1 that hydrolyzes the respective incorrectly misaminoacylated noncognate amino acids. Although active CP1 domain fragments have been isolated for IleRS and ValRS, previous reports suggested that the LeuRS CP1 domain required idiosyncratic adaptations to confer editing activity independent of the full-length enzyme. Herein, characterization of a series of rationally designed Escherichia coli LeuRS fragments showed that the beta-strands, which link the CP1 domain to the aminoacylation core of LeuRS, are required for editing of mischarged tRNALeu. Hydrolytic activity was also enhanced by inclusion of short flexible peptides that have been called "hinges" at the end of both LeuRS beta-strands. We propose that these long beta-strand extensions of the LeuRS CP1 domain interact specifically with the tRNA for post-transfer editing of misaminoacylated amino acids.     

Modulation of Aminoacylation and Editing Properties of Leucyl-tRNA Synthetase by a Conserved Structural Module

A conserved structural module following the KMSKS catalytic loop exhibits α-α-β-α topology in class Ia and Ib aminoacyl-tRNA synthetases. However, the function of this domain has received little attention. Here, we describe the effect this module has on the aminoacylation and editing capacities of leucyl-tRNA synthetases (LeuRSs) by characterizing the key residues from various species. Mutation of highly conserved basic residues on the third α-helix of this domain impairs the affinity of LeuRS for the anticodon stem of tRNA^Leu, which decreases both aminoacylation and editing activities. Two glycine residues on this α-helix contribute to flexibility, leucine activation, and editing of LeuRS from Escherichia coli (EcLeuRS). Acidic residues on the β-strand enhance the editing activity of EcLeuRS and sense the size of the tRNA^Leu D-loop. Incorporation of these residues stimulates the tRNA-dependent editing activity of the chimeric minimalist enzyme Mycoplasma mobile LeuRS fused to the connective polypeptide 1 editing domain and leucine-specific domain from EcLeuRS. Together, these results reveal the stem contact-fold to be a functional as well as a structural linker between the catalytic site and the tRNA binding domain. Sequence comparison of the EcLeuRS stem contact-fold domain with editing-deficient enzymes suggests that key residues of this module have evolved an adaptive strategy to follow the editing functions of LeuRS.     

Recognition of tRNALeu by Aquifex aeolicus leucyl-tRNA synthetase during the aminoacylation and editing steps

Recognition of tRNA by the cognate aminoacyl-tRNA synthetase during translation is crucial to ensure the correct expression of the genetic code. To understand tRNA^Leu recognition sets and their evolution, the recognition of tRNA^Leu by the leucyl-tRNA synthetase (LeuRS) from the primitive hyperthermophilic bacterium Aquifex aeolicus was studied by RNA probing and mutagenesis. The results show that the base A73; the core structure of tRNA formed by the tertiary interactions U8–A14, G18–U55 and G19–C56; and the orientation of the variable arm are critical elements for tRNA^Leu aminoacylation. Although dispensable for aminoacylation, the anticodon arm carries discrete editing determinants that are required for stabilizing the conformation of the post-transfer editing state and for promoting translocation of the tRNA acceptor arm from the synthetic to the editing site.     

Coexistence of bacterial leucyl-tRNA synthetases with archaeal tRNA binding domains that distinguish tRNALeu in the archaeal mode

Leucyl-tRNA (transfer RNA) synthetase (LeuRS) is a multi-domain enzyme, which is divided into bacterial and archaeal/eukaryotic types. In general, one specific LeuRS, the domains of which are of the same type, exists in a single cell compartment. However, some species, such as the haloalkaliphile Natrialba magadii, encode two cytoplasmic LeuRSs, NmLeuRS1 and NmLeuRS2, which are the first examples of naturally occurring chimeric enzymes with different domains of bacterial and archaeal types. Furthermore, N. magadii encodes typical archaeal tRNA^Leus. The tRNA recognition mode, aminoacylation and translational quality control activities of these two LeuRSs are interesting questions to be addressed. Herein, active NmLeuRS1 and NmLeuRS2 were successfully purified after gene expression in Escherichia coli. Under the optimized aminoacylation conditions, we discovered that they distinguished cognate NmtRNA^Leu in the archaeal mode, whereas the N-terminal region was of the bacterial type. However, NmLeuRS1 exhibited much higher aminoacylation and editing activity than NmLeuRS2, suggesting that NmLeuRS1 is more likely to generate Leu-tRNA^Leu for protein biosynthesis. Moreover, using NmLeuRS1 as a model, we demonstrated misactivation of several non-cognate amino acids, and accuracy of protein synthesis was maintained mainly via post-transfer editing. This comprehensive study of the NmLeuRS/tRNA^Leu system provides a detailed understanding of the coevolution of aminoacyl-tRNA synthetases and tRNA.     

Characterization of benzoxaborole-based antifungal resistance mutations demonstrates that editing depends on electrostatic stabilization of the leucyl-tRNA synthetase editing cap

The broad-spectrum benzoxaborole antifungal AN2690 blocks protein synthesis by inhibiting leucyl-tRNA synthetase (LeuRS) via a novel oxaborole tRNA trapping mechanism in the editing site. Herein, one set of resistance mutations is at Asp487 outside the LeuRS hydrolytic editing pocket, in a region of unknown function. It is located within a eukaryote/archaea specific insert I4, which forms part of a cap over a benzoxaborole-AMP that is bound in the LeuRS CP1 domain editing active site. Mutational and biochemical analysis at Asp487 identified a salt bridge between Asp487 and Arg316 in the hinge region of the I4 cap of yeast LeuRS that is critical for tRNA deacylation. We hypothesize that this electrostatic interaction stabilizes the cap during binding of the editing substrate for hydrolysis.     

Functional segregation of a predicted "hinge" site within the beta-strand linkers of Escherichia coli leucyl-tRNA synthetase

Some aminoacyl-tRNA synthetases (AARSs) employ an editing mechanism to ensure the fidelity of protein synthesis. Leucyl-tRNA synthetase (LeuRS), isoleucyl-tRNA synthetase (IleRS), and valyl-tRNA synthetase (ValRS) share a common insertion, called the CP1 domain, which is responsible for clearing misformed products. This discrete domain is connected to the main body of the enzyme via two beta-strand tethers. The CP1 hydrolytic editing active site is located approximately 30 A from the aminoacylation active site in the canonical core of the enzyme, requiring translocation of mischarged amino acids for editing. An ensemble of crystal and cocrystal structures for LeuRS, IleRS, and ValRS suggests that the CP1 domain rotates via its flexible beta-strand linkers relative to the main body along various steps in the enzyme's reaction pathway. Computational analysis suggested that the end of the N-terminal beta-strand acted as a hinge. We hypothesized that a molecular hinge could specifically direct movement of the CP1 domain relative to the main body. We introduced a series of mutations into both beta-strands in attempts to hinder movement and alter fidelity of LeuRS. Our results have identified specific residues within the beta-strand tethers that selectively impact enzyme activity, supporting the idea that beta-strand orientation is crucial for LeuRS canonical core and CP1 domain functions.     

A Flexible peptide tether controls accessibility of a unique C-terminal RNA-binding domain in leucyl-tRNA synthetases

A unique C-terminal domain extension is required by most leucyl-tRNA synthetases (LeuRS) for aminoacylation. In one exception, the enzymatic activity of yeast mitochondrial LeuRS is actually impeded by its own C-terminal domain. It was proposed that the yeast mitochondrial LeuRS has compromised its aminoacylation activity to some extent and adapted its C terminus for a second role in RNA splicing, which is also essential. X-ray crystal structures of the LeuRS-tRNA complex show that the 60 residue C-terminal domain is tethered to the main body of the enzyme via a flexible peptide linker and allows interactions with the tRNA^Leu elbow. We hypothesized that this short peptide linker would facilitate rigid body movement of the C-terminal domain as LeuRS transitions between an aminoacylation and editing complex or, in the case of yeast mitochondrial LeuRS, an RNA splicing complex. The roles of the C-terminal linker peptide for Escherichia coli and yeast mitochondrial LeuRS were investigated via deletion mutagenesis as well as by introducing chimeric swaps. Deletions within the C-terminal linker of E. coli LeuRS determined that its length, rather than its sequence, was critical to aminoacylation and editing activities. Although deletions in the yeast mitochondrial LeuRS peptide linker destabilized the protein in general, more stable chimeric enzymes that contained an E. coli LeuRS C-terminal domain showed that shortening its tether stimulated aminoacylation activity. This suggested that limiting C-terminal domain accessibility to tRNA^Leu facilitates its role in protein synthesis and may be a unique adaptation of yeast mitochondrial LeuRS that accommodates its second function in RNA splicing.     

Defects in Transient tRNA Translocation Bypass tRNA Synthetase Quality Control Mechanisms

Quality control mechanisms during protein synthesis are essential to fidelity and cell survival. Leucyl-tRNA synthetase (LeuRS) misactivates non-leucine amino acids including isoleucine, methionine, and norvaline. To prevent translational errors, mischarged tRNA products are translocated 30Å from the canonical aminoacylation core to a hydrolytic editing-active site within a completely separate domain. Because it is transient, the tRNA translocation mechanism has been difficult to isolate. We have identified a “translocation peptide” within Escherichia coli LeuRS. Mutations in the translocation peptide cause tRNA to selectively bypass the editing-active site, resulting in mischarging that is lethal to the cell. This bypass mechanism also rescues aminoacylation of an editing site mutation that hydrolyzes correctly charged Leu-tRNA^Leu. Thus, these LeuRS mutants charge tRNA^Leu but fail to translocate these products to the hydrolytic site, where they are cleared to guard against genetic code ambiguities.Quality control during translation depends on the family of aminoacyl-tRNA synthetases (aaRSs),² which is responsible for the first step of protein synthesis. Each aaRS selectively aminoacylates just one of the 20 standard amino acids to its cognate tRNA (1). About half of this family of enzymes ensures fidelity by employing a “double sieve model” that relies on two active sites (2, 3). One sieve is synthetic and produces charged tRNA. The other is a hydrolytic editing-active site that clears mistakes. Defects in the editing mechanism cause cell death (4, 5) and also neurological disease in mammals (6).The aminoacylation site in the ancient canonical core of the aaRS activates its cognate amino acid but can also misactivate structurally similar amino acids (1). The editing-active site blocks the correctly charged amino acid (7, 8) and hydrolyzes mischarged amino acids from the tRNA. Amino acid editing destroys mistakes before they can be incorporated by the ribosome, which would result in the production of statistical proteins (1).Amino acid proofreading requires that the charged tRNA transiently migrates between two enzyme domains that are responsible for aminoacylation and editing. For leucyl-tRNA synthetase (LeuRS) and the homologous isoleucyl-(IleRS) and valyl-tRNA synthetases (ValRS), the editing domain resides in a structural insertion called CP1 (9) that splits the Rossmann ATP binding fold. The insert folds independent of the canonical core (10–12). The isolated CP1 domains from LeuRS, ValRS, and IleRS can independently and specifically hydrolyze mischarged amino acid from its cognate tRNA (13–15).The aminoacylation and editing-active sites of LeuRS are separated by about 30 Å. Thus, the charged 3′ end of the tRNA must be faithfully translocated a significant distance for proofreading and then hydrolysis if it is mischarged (16). It has also been suggested that the tRNA 3′ end binds initially near the editing-active site and requires translocation to the aminoacylation site (17).We hypothesized that flexible molecular hinges might facilitate conformational changes between the aminoacylation and the editing complexes (18). Two putative hinge sites were predicted by computational analysis of Thermus thermophilus LeuRS. One hinge at Ser-227 was located in the N-terminal β-strand that links the aminoacylation and CP1 editing domains (18). Mutations at the predicted hinge site in the β-strand linker of Escherichia coli LeuRS abolished aminoacylation activity and significantly decreased amino acid editing activity (18).A second hinge site at Glu-393 was identified in a flexible peptide within the CP1 domain of T. thermophilus LeuRS (18). Here, we describe results at a homologous Asp-391 site in E. coli LeuRS that demonstrate that this hinge comprises a portion of a translocation peptide. Unlike the predicted β-strand hinge mutation, the aminoacylation and editing activities of the CP1 domain-based hinge mutants in LeuRS were intact. Surprisingly however, mutations within the translocation peptide yield mischarged tRNA despite a robust deacylation activity. We hypothesize that impairing the LeuRS translocation peptide causes the charged tRNA 3′ end to bypass the editing sieve prior to product release. Defects in the translocation peptide and its mechanism result in amino acid toxicities that are lethal to the cell.     

Kinetic Origin of Substrate Specificity in Post-Transfer Editing by Leucyl-tRNA Synthetase

The intrinsic editing capacities of aminoacyl-tRNA synthetases ensure a high-fidelity translation of the amino acids that possess effective non-cognate aminoacylation surrogates. The dominant error-correction pathway comprises deacylation of misaminoacylated tRNA within the aminoacyl-tRNA synthetase editing site. To assess the origin of specificity of Escherichia coli leucyl-tRNA synthetase (LeuRS) against the cognate aminoacylation product in editing, we followed binding and catalysis independently using cognate leucyl- and non-cognate norvalyl-tRNA^Leu and their non-hydrolyzable analogues. We found that the amino acid part (leucine versus norvaline) of (mis)aminoacyl-tRNAs can contribute approximately 10-fold to ground-state discrimination at the editing site. In sharp contrast, the rate of deacylation of leucyl- and norvalyl-tRNA^Leu differed by about 10⁴-fold. We further established the critical role for the A76 3′-OH group of the tRNA^Leu in post-transfer editing, which supports the substrate-assisted deacylation mechanism. Interestingly, the abrogation of the LeuRS specificity determinant threonine 252 did not improve the affinity of the editing site for the cognate leucine as expected, but instead substantially enhanced the rate of leucyl-tRNA^Leu hydrolysis. In line with that, molecular dynamics simulations revealed that the wild-type enzyme, but not the T252A mutant, enforced leucine to adopt the side-chain conformation that promotes the steric exclusion of a putative catalytic water. Our data demonstrated that the LeuRS editing site exhibits amino acid specificity of kinetic origin, arguing against the anticipated prominent role of steric exclusion in the rejection of leucine. This feature distinguishes editing from the synthetic site, which relies on ground-state discrimination in amino acid selection.     

tRNA-dependent Pre-transfer Editing by Prokaryotic Leucyl-tRNA Synthetase

To prevent genetic code ambiguity due to misincorporation of amino acids into proteins, aminoacyl-tRNA synthetases have evolved editing activities to eliminate intermediate or final non-cognate products. In this work we studied the different editing pathways of class Ia leucyl-tRNA synthetase (LeuRS). Different mutations and experimental conditions were used to decipher the editing mechanism, including the recently developed compound AN2690 that targets the post-transfer editing site of LeuRS. The study emphasizes the crucial importance of tRNA for the pre- and post-transfer editing catalysis. Both reactions have comparable efficiencies in prokaryotic Aquifex aeolicus and Escherichia coli LeuRSs, although the E. coli enzyme favors post-transfer editing, whereas the A. aeolicus enzyme favors pre-transfer editing. Our results also indicate that the entry of the CCA-acceptor end of tRNA in the editing domain is strictly required for tRNA-dependent pre-transfer editing. Surprisingly, this editing reaction was resistant to AN2690, which inactivates the enzyme by forming a covalent adduct with tRNA^Leu in the post-transfer editing site. Taken together, these data suggest that the binding of tRNA in the post-transfer editing conformation confers to the enzyme the capacity for pre-transfer editing catalysis, regardless of its capacity to catalyze post-transfer editing.     

C-terminal Domain of Leucyl-tRNA Synthetase from Pathogenic Candida albicans Recognizes both tRNASer and tRNALeu

Leucyl-tRNA synthetase (LeuRS) is a multidomain enzyme that catalyzes Leu-tRNA^Leu formation and is classified into bacterial and archaeal/eukaryotic types with significant diversity in the C-terminal domain (CTD). CTDs of both bacterial and archaeal LeuRSs have been reported to recognize tRNA^Leu through different modes of interaction. In the human pathogen Candida albicans, the cytoplasmic LeuRS (CaLeuRS) is distinguished by its capacity to recognize a uniquely evolved chimeric tRNA^Ser (CatRNA^Ser(CAG)) in addition to its cognate CatRNA^Leu, leading to CUG codon reassignment. Our previous study showed that eukaryotic but not archaeal LeuRSs recognize this peculiar tRNA^Ser, suggesting the significance of their highly divergent CTDs in tRNA^Ser recognition. The results of this study provided the first evidence of the indispensable function of the CTD of eukaryotic LeuRS in recognizing non-cognate CatRNA^Ser and cognate CatRNA^Leu. Three lysine residues were identified as involved in mediating enzyme-tRNA interaction in the leucylation process: mutation of all three sites totally ablated the leucylation activity. The importance of the three lysine residues was further verified by gel mobility shift assays and complementation of a yeast leuS gene knock-out strain.     

The CP2 domain of leucyl-tRNA synthetase is crucial for amino acid activation and post-transfer editing

Leucyl-tRNA synthetase (LeuRS) has an insertion domain, called connective peptide 2 (CP2), either directly preceding or following the editing domain (CP1 domain), depending on the species. The global structures of the CP2 domains from all LeuRSs are similar. Although the CP1 domain has been extensively explored to be responsible for hydrolysis of mischarged tRNALeu, the role of the CP2 domain remains undefined. In the present work, deletion of the CP2 domain of Giardia lamblia LeuRS (GlLeuRS) showed that the CP2 domain is indispensable for amino acid activation and post-transfer editing and that it contributes to LeuRS-tRNALeu binding affinity. In addition, its functions are conserved in both eukaryotic/archaeal and prokaryotic LeuRSs from G. lamblia, Pyrococcus horikoshii (PhLeuRS), and Escherichia coli (EcLeuRS). Alanine scanning and site-directed mutagenesis assays of the CP2 domain identified several residues that are crucial for its various functions. Data from the chimeric mutants, which replaced the CP2 domain of GlLeuRS with either PhLeuRS or EcLeuRS, showed that the CP2 domain of PhLeuRS but not that of EcLeuRS can partially restore amino acid activation and post-transfer editing functions, suggesting that the functions of the CP2 domain are dependent on its location in the primary sequence of LeuRS.     

Molecular modeling study of the editing active site of Escherichia coli leucyl-tRNA synthetase: two amino acid binding sites in the editing domain

Aminoacyl-tRNA synthetases (aaRSs) strictly discriminate their cognate amino acids. Some aaRSs accomplish this via proofreading and editing mechanisms. Mursinna and coworkers recently reported that substituting a highly conserved threonine (T252) with an alanine within the editing domain of Escherichia coli leucyl-tRNA synthetase (LeuRS) caused LeuRS to cleave its cognate aminoacylated leucine from tRNA(Leu) (Mursinna et al., Biochemistry 2001;40:5376-5381). To achieve atomic level insight into the role of T252 in LeuRS and the editing reaction of aaRSs, a series of molecular modeling studies including homology modeling and automated docking simulations were carried out. A 3D structure of E. coli LeuRS was constructed via homology modeling using the X-ray structure of Thermus thermophilus LeuRS as a template because the E. coli LeuRS structure is not available from X-ray or NMR studies. However, both the X-ray T. thermophilus and homology-modeled E. coli structures were used in our studies. Amino acid binding sites in the proposed editing domain, which is also called the connective polypeptide 1 (CP1) domain, were investigated by automated docking studies. The root mean square deviation (RMSD) for backbone atoms between the X-ray and homology-modeled structures was 1.18 A overall and 0.60 A for the editing (CP1) domain. Automated docking studies of a leucine ligand into the editing domain were performed for both structures: homology structure of E. coli LeuRS and X-ray structure of T. thermophilus LeuRS for comparison. The results of the docking studies suggested that there are two possible amino acid binding sites in the CP1 domain for both proteins. The first site lies near a threonine-rich region that includes the highly conserved T252 residue, which is important for amino acid discrimination. The second site is located in a flexible loop region surrounded by residues E292, A293, M295, A296, and M298. The important T252 residue is at the bottom of the first binding pocket.     

Aminoacylation and translational quality control strategy employed by leucyl-tRNA synthetase from a human pathogen with genetic code ambiguity

Aminoacyl-tRNA synthetases should ensure high accuracy in tRNA aminoacylation. However, the absence of significant structural differences between amino acids always poses a direct challenge for some aminoacyl-tRNA synthetases, such as leucyl-tRNA synthetase (LeuRS), which require editing function to remove mis-activated amino acids. In the cytoplasm of the human pathogen Candida albicans, the CUG codon is translated as both Ser and Leu by a uniquely evolved CatRNA^Ser(CAG). Its cytoplasmic LeuRS (CaLeuRS) is a crucial component for CUG codon ambiguity and harbors only one CUG codon at position 919. Comparison of the activity of CaLeuRS-Ser⁹¹⁹ and CaLeuRS-Leu⁹¹⁹ revealed yeast LeuRSs have a relaxed tRNA recognition capacity. We also studied the mis-activation and editing of non-cognate amino acids by CaLeuRS. Interestingly, we found that CaLeuRS is naturally deficient in tRNA-dependent pre-transfer editing for non-cognate norvaline while displaying a weak tRNA-dependent pre-transfer editing capacity for non-cognate α-amino butyric acid. We also demonstrated that post-transfer editing of CaLeuRS is not tRNA^Leu species-specific. In addition, other eukaryotic but not archaeal or bacterial LeuRSs were found to recognize CatRNA^Ser(CAG). Overall, we systematically studied the aminoacylation and editing properties of CaLeuRS and established a characteristic LeuRS model with naturally deficient tRNA-dependent pre-transfer editing, which increases LeuRS types with unique editing patterns.     

An aminoacyl-tRNA synthetase with a defunct editing site

Many aminoacyl-tRNA synthetases (aaRSs) contain two active sites, a synthetic site catalyzing aminoacyl-adenylate formation and tRNA aminoacylation and a second editing or proofreading site that hydrolyzes misactivated adenylates or mischarged tRNAs. The combined activities of these two sites lead to rigorous accuracy in tRNA aminoacylation, and both activities are essential to LeuRS and other aaRSs. Here, we describe studies of the human mitochondrial (hs mt) LeuRS indicating that the two active sites of this enzyme have undergone functional changes that impact how accurate aminoacylation is achieved. The sequence of the hs mt LeuRS closely resembles a bacterial LeuRS overall but displays significant variability in regions of the editing site. Studies comparing Escherichia coli and hs mt LeuRS reveal that the proofreading activity of the mt enzyme is disrupted by these sequence changes, as significant levels of Ile-tRNA(Leu) are formed in the presence of high concentrations of the noncognate amino acid. Experiments monitoring deacylation of Ile-tRNA(Leu) and misactivated adenylate turnover revealed that the editing active site is not operational. However, hs mt LeuRS has weaker binding affinities for both cognate and noncognate amino acids relative to the E. coli enzyme and an elevated discrimination ratio. Therefore, the enzyme achieves fidelity using a more specific synthetic active site that is not prone to errors under physiological conditions. This enhanced specificity must compensate for the presence of a defunct editing site and ensures translational accuracy.     

Modulation of substrate specificity within the amino acid editing site of leucyl-tRNA synthetase

The aminoacyl-tRNA synthetases covalently link transfer RNAs to their cognate amino acids. Some of the tRNA synthetases have evolved editing mechanisms to ensure fidelity in this first step of protein synthesis. The amino acid editing site for leucyl- (LeuRS) and isoleucyl- (IleRS) tRNA synthetases reside within homologous CP1 domains. In each case, a threonine-rich peptide and a second conserved GTG region that are separated by about 100 amino acids comprise parts of the hydrolytic editing site. While a number of sites are conserved between these two enzymes and likely confer a commonality to the mechanisms, some positions are idiosyncratic to LeuRS or IleRS. Herein, we provide evidence that a conserved arginine and threonine at respective sites in LeuRS and IleRS diverged to confer amino acid substrate recognition. This site complements other sites in the amino acid binding pocket of the editing active site of Escherichia coli LeuRS, including Thr252 and Val338, which collectively fine-tune amino acid specificity to confer fidelity.     

Oxidation alters the architecture of the phenylalanyl-tRNA synthetase editing domain to confer hyperaccuracy

High fidelity during protein synthesis is accomplished by aminoacyl-tRNA synthetases (aaRSs). These enzymes ligate an amino acid to a cognate tRNA and have proofreading and editing capabilities that ensure high fidelity. Phenylalanyl-tRNA synthetase (PheRS) preferentially ligates a phenylalanine to a tRNA^Phe over the chemically similar tyrosine, which differs from phenylalanine by a single hydroxyl group. In bacteria that undergo exposure to oxidative stress such as Salmonella enterica serovar Typhimurium, tyrosine isomer levels increase due to phenylalanine oxidation. Several residues are oxidized in PheRS and contribute to hyperactive editing, including against mischarged Tyr-tRNA^Phe, despite these oxidized residues not being directly implicated in PheRS activity. Here, we solve a 3.6 Å cryo-electron microscopy structure of oxidized S. Typhimurium PheRS. We find that oxidation results in widespread structural rearrangements in the β-subunit editing domain and enlargement of its editing domain. Oxidization also enlarges the phenylalanyl-adenylate binding pocket but to a lesser extent. Together, these changes likely explain why oxidation leads to hyperaccurate editing and decreased misincorporation of tyrosine. Taken together, these results help increase our understanding of the survival of S. Typhimurium during human infection.