Crystal structure of human mitochondrial PheRS complexed with tRNA(Phe) in the active "open" state

Monomeric human mitochondrial phenylalanyl-tRNA synthetase (PheRS), or hmPheRS, is the smallest known enzyme exhibiting aminoacylation activity. HmPheRS consists of only two structural domains and differs markedly from heterodimeric eukaryotic cytosolic and bacterial analogs both in the domain organization and in the mode of tRNA binding. Here, we describe the first crystal structure of mitochondrial aminoacyl-tRNA synthetase (aaRS) complexed with tRNA at a resolution of 3.0 Å. Unlike bacterial PheRSs, the hmPheRS recognizes C74, the G1–C72 base pair, and the “discriminator” base A73, proposed to contribute to tRNA^Phe identity in the yeast mitochondrial enzyme. An interaction of the tRNA acceptor stem with the signature motif 2 residues of hmPheRS is of critical importance for the stabilization of the CCA-extended conformation and its correct placement in the synthetic site of the enzyme. The crystal structure of hmPheRS–tRNA^Phe provides direct evidence that the formation of the complex with tRNA requires a significant rearrangement of the anticodon-binding domain from the “closed” to the productive “open” state. Global repositioning of the domain is tRNA modulated and governed by long-range electrostatic interactions.     

Idiosyncrasy and identity in the prokaryotic Phe-system: crystal structure of E. coli phenylalanyl-tRNA synthetase complexed with phenylalanine and AMP

The crystal structure of Phenylalanyl‐tRNA synthetase from E. coli (EcPheRS), a class II aminoacyl‐tRNA synthetase, complexed with phenylalanine and AMP was determined at 3.05 Å resolution. EcPheRS is a (αβ)₂ heterotetramer: the αβ heterodimer of EcPheRS consists of 11 structural domains. Three of them: the N‐terminus, A1 and A2 belong to the α‐subunit and B1‐B8 domains to the β subunit. The structure of EcPheRS revealed that architecture of four helix‐bundle interface, characteristic of class IIc heterotetrameric aaRSs, is changed: each of the two long helices belonging to CLM transformed into the coil‐short helix structural fragments. The N‐terminal domain of the α‐subunit in EcPheRS forms compact triple helix domain. This observation is contradictory to the structure of the apo form of TtPheRS, where N‐terminal domain was not detected in the electron density map. Comparison of EcPheRS structure with TtPheRS has uncovered significant rearrangements of the structural domains involved in tRNA^Phe binding/translocation. As it follows from modeling experiments, to achieve a tighter fit with anticodon loop of tRNA, a shift of ～5 Å is required for C‐terminal domain B8, and of ～6 to 7 Å for the whole N terminus. EcPheRSs have emerged as an important target for the incorporation of novel amino acids into genetic code. Further progress in design of novel compounds is anticipated based on the structural data of EcPheRS.     

Kinetic and structural changes in HsmtPheRS,induced by pathogenic mutations in human FARS2

Mutations in the mitochondrial aminoacyl‐tRNA synthetases (mtaaRSs) can cause profound clinical presentations, and have manifested as diseases with very selective tissue specificity. To date most of the mtaaRS mutations could be phenotypically recognized, such that clinicians could identify the affected mtaaRS from the symptoms alone. Among the recently reported pathogenic variants are point mutations in FARS2 gene, encoding the human mitochondrial PheRS. Patient symptoms range from spastic paraplegia to fatal infantile Alpers encephalopathy. How clinical manifestations of these mutations relate to the changes in three‐dimensional structures and kinetic characteristics remains unclear, although impaired aminoacylation has been proposed as possible etiology of diseases. Here, we report four crystal structures of HsmtPheRS mutants, and extensive MD simulations for wild‐type and nine mutants to reveal the structural changes on dynamic trajectories of HsmtPheRS. Using steady‐state kinetic measurements of phenylalanine activation and tRNA^Phe aminoacylation, we gained insight into the structural and kinetic effects of mitochondrial disease‐related mutations in FARS2 gene.     

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.     

Lipid II-independent trans Editing of Mischarged tRNAs by the Penicillin Resistance Factor MurM

Streptococcus pneumoniae is a causative agent of nosocomial infections such as pneumonia, meningitis, and septicemia. Penicillin resistance in S. pneumoniae depends in part upon MurM, an aminoacyl-tRNA ligase that attaches l-serine or l-alanine to the stem peptide lysine of Lipid II in cell wall peptidoglycan. To investigate the exact substrates the translation machinery provides MurM, quality control by alanyl-tRNA synthetase (AlaRS) was investigated. AlaRS mischarged serine and glycine to tRNA^Ala, as observed in other bacteria, and also transferred alanine, serine, and glycine to tRNA^Phe. S. pneumoniae tRNA^Phe has an unusual U4:C69 mismatch in its acceptor stem that prevents editing by phenylalanyl-tRNA synthetase (PheRS), leading to the accumulation of misaminoacylated tRNAs that could serve as substrates for translation or for MurM. Although the peptidoglycan layer of S. pneumoniae tolerates a combination of both branched and linear muropeptides, deletion of MurM results in a reversion to penicillin sensitivity in strains that were previously resistant. However, because MurM is not required for cell viability, the reason for its functional conservation across all strains of S. pneumoniae has remained elusive. We now show that MurM can directly function in translation quality control by acting as a broad specificity lipid-independent trans editing factor that deacylates tRNA. This activity of MurM does not require the presence of its second substrate, Lipid II, and can functionally substitute for the activity of widely conserved editing domain homologues of AlaRS, termed AlaXPs proteins, which are themselves absent from S. pneumoniae.     

Processing of plant mitochondrial tRNAGly and tRNASer(GCU) is independent of RNA editing

The genes encoding pea and potato mitochondrial tRNA^Gly and pea mitochondrial tRNA^Ser(GCU) were analyzed with particular respect to their expression. Secondary-structure models deduced from the identical potato and pea tRNA^Gly gene sequences revealed A₇:C₆₆ mismatches in the seventh base pair at the base of the acceptor stems of both tRNAs. Sequence analyses of tRNA^Gly cDNA clones showed that these mispairings are not corrected by C₆₆ to U₆₆ conversions, as observed in plant mitochondrial tRNA^Phe. Likewise, a U₆:C₆₇ mismatch identified in the acceptor stem of the pea tRNA^Ser(GCU) is not altered by RNA editing to a mismatched U:U pair, which is created by RNA editing in Oenothera mitochondrial tRNA^Cys. In vitro processing reactions with the respective tRNA^Gly and tRNA^Ser(GCU) precursors show that such conversions are not necessary for 5′ and 3′ end maturation of these tRNAs. These results demonstrate that not all C:A (A:C) or U:C (C:U) mismatches in double-stranded regions of tRNAs are altered by RNA editing. An RNA editing event in plant mitochondrial tRNAs is thus not generally indicated by the presence of a mismatch but may depend on additional parameters. Received: 18 July 1997 / Accepted: 3 November 1997     

Processing of plant mitochondrial tRNAGly and tRNASer(GCU) is independent of RNA editing

The genes encoding pea and potato mitochondrial tRNA^Gly and pea mitochondrial tRNA^Ser(GCU) were analyzed with particular respect to their expression. Secondary-structure models deduced from the identical potato and pea tRNA^Gly gene sequences revealed A₇:C₆₆ mismatches in the seventh base pair at the base of the acceptor stems of both tRNAs. Sequence analyses of tRNA^Gly cDNA clones showed that these mispairings are not corrected by C₆₆ to U₆₆ conversions, as observed in plant mitochondrial tRNA^Phe. Likewise, a U₆:C₆₇ mismatch identified in the acceptor stem of the pea tRNA^Ser(GCU) is not altered by RNA editing to a mismatched U:U pair, which is created by RNA editing in Oenothera mitochondrial tRNA^Cys. In vitro processing reactions with the respective tRNA^Gly and tRNA^Ser(GCU) precursors show that such conversions are not necessary for 5′ and 3′ end maturation of these tRNAs. These results demonstrate that not all C:A (A:C) or U:C (C:U) mismatches in double-stranded regions of tRNAs are altered by RNA editing. An RNA editing event in plant mitochondrial tRNAs is thus not generally indicated by the presence of a mismatch but may depend on additional parameters.     

Loss of editing activity during the evolution of mitochondrial phenylalanyl-tRNA synthetase

Accurate selection of amino acids is essential for faithful translation of the genetic code. Errors during amino acid selection are usually corrected by the editing activity of aminoacyl-tRNA synthetases such as phenylalanyl-tRNA synthetases (PheRS), which edit misactivated tyrosine. Comparison of cytosolic and mitochondrial PheRS from the yeast Saccharomyces cerevisiae suggested that the organellar protein might lack the editing activity. Yeast cytosolic PheRS was found to contain an editing site, which upon disruption abolished both cis and trans editing of Tyr-tRNA(Phe). Wild-type mitochondrial PheRS lacked cis and trans editing and could synthesize Tyr-tRNA(Phe), an activity enhanced in active site variants with improved tyrosine recognition. Possible trans editing was investigated in isolated mitochondrial extracts, but no such activity was detected. These data indicate that the mitochondrial protein synthesis machinery lacks the tyrosine proofreading activity characteristic of cytosolic translation. This difference between the mitochondria and the cytosol suggests that either organellar protein synthesis quality control is focused on another step or that translation in this compartment is inherently less accurate than in the cytosol.     

Thiolated tRNAs of Trypanosoma brucei Are Imported into Mitochondria and Dethiolated after Import

All mitochondrial tRNAs in Trypanosoma brucei derive from cytosolic tRNAs that are in part imported into mitochondria. Some trypanosomal tRNAs are thiolated in a compartment-specific manner. We have identified three proteins required for the thio modification of cytosolic tRNA^Gln, tRNA^Glu, and tRNA^Lys. RNA interference-mediated ablation of these proteins results in the cytosolic accumulation non-thio-modified tRNAs but does not increase their import. Moreover, in vitro import experiments showed that both thio-modified and non-thio-modified tRNA^Glu can efficiently be imported into mitochondria. These results indicate that unlike previously suggested the cytosol-specific thio modifications do not function as antideterminants for mitochondrial tRNA import. Consistent with these results we showed by using inducible expression of a tagged tRNA^Glu that it is mainly the thiolated form that is imported in vivo. Unexpectedly, the imported tRNA becomes dethiolated after import, which explains why the non-thiolated form is enriched in mitochondria. Finally, we have identified two genes required for thiolation of imported tRNA^Trp whose wobble nucleotide is subject to mitochondrial C to U editing. Interestingly, down-regulation of thiolation resulted in an increase of edited tRNA^Trp but did not affect growth.     

N7-Methylguanine at position 46 (m7G46) in tRNA from Thermus thermophilus is required for cell viability at high temperatures through a tRNA modification network

N⁷-methylguanine at position 46 (m⁷G46) in tRNA is produced by tRNA (m⁷G46) methyltransferase (TrmB). To clarify the role of this modification, we made a trmB gene disruptant (ΔtrmB) of Thermus thermophilus, an extreme thermophilic eubacterium. The absence of TrmB activity in cell extract from the ΔtrmB strain and the lack of the m⁷G46 modification in tRNA^Phe were confirmed by enzyme assay, nucleoside analysis and RNA sequencing. When the ΔtrmB strain was cultured at high temperatures, several modified nucleotides in tRNA were hypo-modified in addition to the lack of the m⁷G46 modification. Assays with tRNA modification enzymes revealed hypo-modifications of Gm18 and m¹G37, suggesting that the m⁷G46 positively affects their formations. Although the lack of the m⁷G46 modification and the hypo-modifications do not affect the Phe charging activity of tRNA^Phe, they cause a decrease in melting temperature of class I tRNA and degradation of tRNA^Phe and tRNA^Ile. ³⁵S-Met incorporation into proteins revealed that protein synthesis in ΔtrmB cells is depressed above 70°C. At 80°C, the ΔtrmB strain exhibits a severe growth defect. Thus, the m⁷G46 modification is required for cell viability at high temperatures via a tRNA modification network, in which the m⁷G46 modification supports introduction of other modifications.     

NSUN3 and ABH1 modify the wobble position of mt‐tRNAMet to expand codon recognition in mitochondrial translation

Mitochondrial gene expression uses a non‐universal genetic code in mammals. Besides reading the conventional AUG codon, mitochondrial (mt‐)tRNA^Met mediates incorporation of methionine on AUA and AUU codons during translation initiation and on AUA codons during elongation. We show that the RNA methyltransferase NSUN3 localises to mitochondria and interacts with mt‐tRNA^Met to methylate cytosine 34 (C34) at the wobble position. NSUN3 specifically recognises the anticodon stem loop (ASL) of the tRNA, explaining why a mutation that compromises ASL basepairing leads to disease. We further identify ALKBH1/ABH1 as the dioxygenase responsible for oxidising m⁵C34 of mt‐tRNA^Met to generate an f⁵C34 modification. In vitro codon recognition studies with mitochondrial translation factors reveal preferential utilisation of m⁵C34 mt‐tRNA^Met in initiation. Depletion of either NSUN3 or ABH1 strongly affects mitochondrial translation in human cells, implying that modifications generated by both enzymes are necessary for mt‐tRNA^Met function. Together, our data reveal how modifications in mt‐tRNA^Met are generated by the sequential action of NSUN3 and ABH1, allowing the single mitochondrial tRNA^Met to recognise the different codons encoding methionine.     

Variations during leaf development of the relative amounts of two bean (Phaseolus vulgaris) chloroplast tRNAsPhe which differ in their minor nucleotide content

Bean (Phaseolus vulgaris cv. Saxa) chloroplasts contain two tRNA^Phe species, namely tRNA^Phe1 and tRNA^Phe2. By sequence determination, we show that tRNA^Phe2 is identical to the previously sequenced tRNA^Phe1 except for two undermodified nucleotides. By reversed-phase chromatography analyses, we demonstrate that the relative amounts of these two chloroplast tRNAs^Phe vary during leaf development: in etiolated leaves the undermodified tRNA^Phe2 only represents 15% of total chloroplast tRNA^Phe, during development and greening it increases to reach 60% in 8-day-old leaves, and it then decreases to 9% in senescing leaves.     

Isolation and chromatographic behaviour of phenylalanine tRNA from barley embryos

Two fractions of phenylalanine tRNA (tRNA^Phe₁ and tRNA^Phe₂) were purified by BD-cellulose and RPC-5 chromatography of crude tRNA isolated from barley embryos. Successive RPC-5 rechromatography runs of tRNA^Phe₂ showed its conversion into more stable tRNA^Phe₁, suggesting that the two fractions have essentially the same primary structure. Both tRNA^Phe₁ and tRNA^Phe₂ had about the same acceptor activity, but tRNA^Phe₂ was aminoacylated much faster than tRNA^Phe₁. RPC-5 chromatography of crude aminoacylated tRNA showed higher contents of phe-tRNA^Phe₂ than of phe-tRNA^Phe₁ but the ratio of these two fractions estimated by relative fluorescence intensity was about 1. Fluorescence spectra of tRNA^Phe from barley embryos suggest that it contains Y base similar to Y_w from wheat tRNA^Phe.     

Selection of tRNA charging quality control mechanisms that increase mistranslation of the genetic code

Mistranslation can follow two events during protein synthesis: production of non-cognate amino acid:transfer RNA (tRNA) pairs by aminoacyl-tRNA synthetases (aaRSs) and inaccurate selection of aminoacyl-tRNAs by the ribosome. Many aaRSs actively edit non-cognate amino acids, but editing mechanisms are not evolutionarily conserved, and their physiological significance remains unclear. To address the connection between aaRSs and mistranslation, the evolutionary divergence of tyrosine editing by phenylalanyl-tRNA synthetase (PheRS) was used as a model. Certain PheRSs are naturally error prone, most notably a Mycoplasma example that displayed a low level of specificity consistent with elevated mistranslation of the proteome. Mycoplasma PheRS was found to lack canonical editing activity, relying instead on discrimination against the non-cognate amino acid by kinetic proofreading. This mechanism of discrimination is inadequate for organisms where translation is more accurate, as Mycoplasma PheRS failed to support Escherichia coli growth. However, minor changes in the defunct editing domain of the Mycoplasma enzyme were sufficient to restore E. coli growth, indicating that translational accuracy is an evolutionarily selectable trait.     

Age-dependent changes in the specificity of tRNA methyltransferases in the cerebellum of the icteric and nonicteric Gunn rat

The activity of tRNA methyltransferases present in the cerebellum of 6- and 21-day-old nonicteric and icteric Gunn rats was compared using purifiedE. coli tRNAs as substrates. At 6 days the tRNA methyltransferases of the icteric animals were significantly more effective in methylating tRNA^Glu ₂ and tRNA^Phe than were those of their nonicteric counterparts. This relationship reversed itself at 21 days. The action of the tRNA methyltransferases from the 6-day-old icteric animals led to higher proportions of 1-methyladenine in tRNA^Glu ₂ and tRNA^Phe than were obtained using the corresponding enzymes of the nonicteric animals. The proportion ofN ²-methylguanine was also higher, yet only in tRNA^fMet and not in tRNA^Phe. The study reveals much more extensive fluctuations in the activity and in the substrate recognition specificity among the cerebellar tRNA methyltransferases of the icteric than among those of the nonicteric controls during the crucial 6–21 day period of cerebellar development.     

Mutation in MTO1 involved in tRNA modification impairs mitochondrial RNA metabolism in the yeast Saccharomyces cerevisiae

The yeast MTO1 gene encodes an evolutionarily conserved protein for the biosynthesis of the 5-carboxymethylaminomethyl group of cmnm⁵s²U in the wobble position of mitochondrial tRNA. However, mto1 null mutant expressed the respiratory deficient phenotype only when coupled with the C1409G mutation of mitochondrial 15S rRNA. To further understand the role of MTO1 in mitochondrial RNA metabolism, the yeast mto1 null mutants carrying either wild-type (P^S) or 15S rRNA C1409G allele (P^R) have been characterized by examining the steady-state levels, aminoacylation capacity of mitochondrial tRNA, mitochondrial gene expression and petite formation. The steady-state levels of tRNA^Lys, tRNA^Glu, tRNA^Gln, tRNA^Leu, tRNA^Gly, tRNA^Arg and tRNA^Phe were decreased significantly while those of tRNA^Met and tRNA^His were not affected in the mto1 strains carrying the P^S allele. Strikingly, the combination of the mto1 and C1409G mutations gave rise to the synthetic phenotype for some of the tRNAs, especially in tRNA^Lys, tRNA^Met and tRNA^Phe. Furthermore, the mto1 strains exhibited a marked reduction in the aminoacylation levels of mitochondrial tRNA^Lys, tRNA^Leu, tRNA^Arg but almost no effect in those of tRNA^His. In addition, the steady-state levels of mitochondrial COX1, COX2, COX3, ATP6 and ATP9 mRNA were markedly decreased in mto1 strains. These data strongly indicate that unmodified tRNA caused by the deletion of MTO1 gene caused the instability of mitochondrial tRNAs and mRNAs and an impairment of aminoacylation of mitochondrial tRNAs. Consequently, the deletion of MTO1 gene acts in synergy with the 15S rRNA C1409G mutation, leading to the loss of COX1 synthesis and subsequent respiratory deficient phenotype.     

Phenylalanyl-tRNA synthetase editing defects result in efficient mistranslation of phenylalanine codons as tyrosine

Translational quality control is monitored at several steps, including substrate selection by aminoacyl-tRNA synthetases (aaRSs), and discrimination of aminoacyl-tRNAs by elongation factor Tu (EF-Tu) and the ribosome. Phenylalanyl-tRNA synthetase (PheRS) misactivates Tyr but is able to correct the mistake using a proofreading activity named editing. Previously we found that overproduction of editing-defective PheRS resulted in Tyr incorporation at Phe-encoded positions in vivo, although the misreading efficiency could not be estimated. This raised the question as to whether or not EF-Tu and the ribosome provide further proofreading mechanisms to prevent mistranslation of Phe codons by Tyr. Here we show that, after evading editing by PheRS, Tyr-tRNA(Phe) is recognized by EF-Tu as efficiently as the cognate Phe-tRNA(Phe). Kinetic decoding studies using full-length Tyr-tRNA(Phe) and Phe-tRNA(Phe), as well as a poly(U)-directed polyTyr/polyPhe synthesis assay, indicate that the ribosome lacks discrimination between Tyr-tRNA(Phe) and Phe-tRNA(Phe). Taken together, these data suggest that PheRS editing is the major proofreading step that prevents infiltration of Tyr into Phe codons during translation.     

Sequences of initiator and elongator methionine tRNAs in bean mitochondria

Summary Two bean mitochondria methionine transfer RNAs, purified by RPC-5 chromatography and two-dimensional gel electrophoresis, have been sequenced usingin vitro post-labeling techniques.One of these tRNAs^Met has been identified by formylation using anE. coli enzyme as the mitochondrial tRNA_F ^Met. It displays strong structural homologies with prokaryotic and chloroplast tRNA_F ^Met sequences (70.1–83.1%) and with putative initiator tRNA_m ^Met genes described for wheat, maize andOenothera mitochondrial genomes (88.3–89.6%).The other tRNA^Met, which is the mitochondrial elongator tRNA_F ^Met, shows a high degree of sequence homology (93.3–96%& with chloroplast tRNA_m ^Met, but a weak homology (40.7%) with a sequenced maize mitochondrial putative elongator tRNA_m ^Met gene.Bean mitochondrial tRNA_F ^Met and tRNA_m ^Met were hybridized to Southern blots of the mitochondrial genomes of wheat and maize, whose maps have been recently published (15, 22), in order to locate the position of their genes.