Dual Targeting of a tRNAAsp Requires Two Different Aspartyl-tRNA Synthetases in Trypanosoma brucei

The mitochondrion of the parasitic protozoon Trypanosoma brucei does not encode any tRNAs. This deficiency is compensated for by partial import of nearly all of its cytosolic tRNAs. Most trypanosomal aminoacyl-tRNA synthetases are encoded by single copy genes, suggesting the use of the same enzyme in the cytosol and in the mitochondrion. However, the T. brucei genome encodes two distinct genes for eukaryotic aspartyl-tRNA synthetase (AspRS), although the cell has a single tRNA^Asp isoacceptor only. Phylogenetic analysis showed that the two T. brucei AspRSs evolved from a duplication early in kinetoplastid evolution and also revealed that eight other major duplications of AspRS occurred in the eukaryotic domain. RNA interference analysis established that both Tb-AspRS1 and Tb-AspRS2 are essential for growth and required for cytosolic and mitochondrial Asp-tRNA^Asp formation, respectively. In vitro charging assays demonstrated that the mitochondrial Tb-AspRS2 aminoacylates both cytosolic and mitochondrial tRNA^Asp, whereas the cytosolic Tb-AspRS1 selectively recognizes cytosolic but not mitochondrial tRNA^Asp. This indicates that cytosolic and mitochondrial tRNA^Asp, although derived from the same nuclear gene, are physically different, most likely due to a mitochondria-specific nucleotide modification. Mitochondrial Tb-AspRS2 defines a novel group of eukaryotic AspRSs with an expanded substrate specificity that are restricted to trypanosomatids and therefore may be exploited as a novel drug target.In most animal and fungal mitochondria, the total set of tRNAs required for translation is encoded on the mitochondrial genome and thus of bacterial evolutionary origin. The aminoacyl-tRNA synthetases (aaRSs)² responsible for charging of mitochondrial tRNAs are always nuclear encoded and need to be imported into mitochondria. We therefore expect to find two sets of aaRSs, one for cytosolic aminoacyl-tRNA synthesis and a second one, of bacterial evolutionary origin, for aminoacylation of mitochondrial tRNAs (1, 2).In most cells, however, some aaRSs are targeted to both the cytosol as well as to mitochondria (3). In Saccharomyces cerevisiae, for example, four aaRSs are double-targeted to both compartments, indicating that they are able to aminoacylate tRNAs of both eukaryotic and bacterial evolutionary origin (4–6). In plants, the situation is more complex, since protein synthesis occurs in three compartments: the cytosol, the mitochondria, and the plastids. A recent analysis in Arabidopsis has shown that, rather than having three unique sets of aaRSs specific for the three translation systems, more than 15 aaRSs were dually targeted to the mitochondria and the plastid (7). Moreover, there is at least one aaRS that is shared between all three compartments. In summary, these examples indicate that the overlap between the different sets of aaRSs used in the various translation systems is variable and can be extensive.Most eukaryotes, except many animals and fungi, lack a variable number of mitochondrial tRNA genes. Mitochondrial translation in these organisms depends on import of a small fraction of the corresponding nucleus-encoded cytosolic tRNAs (8–10). As a consequence, imported tRNAs are always of eukaryotic evolutionary origin. An intriguing situation is found in trypanosomatids (such as Trypanosoma brucei and Leishmania spp.), where all mitochondrial tRNA genes have apparently been lost and all mitochondrial tRNAs are imported from the cytosol. In these organisms, all mitochondrial tRNAs derive from cytosolic tRNAs (11). It is therefore reasonable to assume that trypanosomal aaRSs are dually targeted to the cytosol and the mitochondrion. For the T. brucei glutaminyl-tRNA synthetase (GlnRS) and the glutamyl-tRNA synthetase, the dual localization has been shown experimentally (12). Moreover, dual targeting of essentially all aaRSs is suggested by the fact that the genome of T. brucei and other trypanosomatids encodes only 23 distinct aaRSs, fewer than any other eukaryote that has a mitochondrial translation system (13). Unexpectedly, two distinct genes were found for the tryptophanyl-tRNA synthetase (TrpRS), the lysyl-tRNA synthetase and the aspartyl-tRNA synthetase (AspRS). A recent study has shown that the two trypanosomal TrpRSs are required for cytosolic and mitochondrial tryptophanyl-tRNA formation (14). Trypanosomal tRNA^Trp is imported to the mitochondria, where it undergoes C to U editing at the wobble nucleotide and is thiolated at position 33. The RNA editing is required to decode the reassigned mitochondrial tryptophan codon UGA (14–16). Both nucleotide modifications are antideterminants for the cytosolic TrpRS (14). As we concluded previously (14), the presence of a second TrpRS with expanded substrate specificity is required to efficiently aminoacylate imported, mature tRNA^Trp in trypanosomal mitochondria.The present study focuses on the characterization and functional analysis of another pair of duplicated trypanosomal aaRSs, the AspRSs. We show that the two enzymes are individually essential for normal growth of insect stage T. brucei. We also demonstrate that the two trypanosomal AspRSs are of eukaryotic evolutionary origin and that the aminoacylation of the cytosolic and mitochondrial tRNA^Asp species requires these two distinct AspRSs.     

Chimeric human mitochondrial PheRS exhibits editing activity to discriminate nonprotein amino acids

Mitochondria are considered as the primary source of reactive oxygen species (ROS) in nearly all eukaryotic cells during respiration. The harmful effects of these compounds range from direct neurotoxicity to incorporation into proteins producing aberrant molecules with multiple physiological problems. Phenylalanine exposure to ROS produces multiple oxidized isomers: tyrosine, Levodopa, ortho‐Tyr, meta‐Tyr (m‐Tyr), and so on. Cytosolic phenylalanyl‐tRNA synthetase (PheRS) exerts control over the translation accuracy, hydrolyzing misacylated products, while monomeric mitochondrial PheRS lacks the editing activity. Recently we showed that “teamwork” of cytosolic and mitochondrial PheRSs cannot prevent incorporation of m‐Tyr and l ‐Dopa into proteins. Here, we present human mitochondrial chimeric PheRS with implanted editing module taken from EcPheRS. The monomeric mitochondrial chimera possesses editing activity, while in bacterial and cytosolic PheRSs this type of activity was detected for the (αβ)₂ architecture only. The fusion protein catalyzes aminoacylation of tRNA^Phe with cognate phenylalanine and effectively hydrolyzes the noncognate aminoacyl‐tRNAs: Tyr‐tRNA^Phe and m‐Tyr‐tRNA^Phe.     

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.     

The mitochondrial tRNAs of Trypanosoma brucei are nuclear encoded

The mitochondrial DNA of Trypanosoma brucei is organized as a catenated network of maxicircles and minicircles. The maxicircles are equivalent to the typical mitochondrial genome except that the genes for the mitochondrial tRNAs have not been identified by sequence analysis of the maxicircle DNA. The apparent absence of tRNA genes in the maxicircle DNA suggests that the mitochondrial tRNAs are encoded by either the minicircle or the nuclear DNA. In order to determine their genomic origin, we isolated and identified the mitochondrial tRNAs of T. brucei. We show that these mitochondrial tRNAs are truly mitochondrially located in vivo and that they are free from detectable contamination by cytosolic RNAs. By hybridization analysis, using mitochondrial tRNAs as the probe, we determined that the mitochondrial tRNAs are encoded by nuclear DNA. This implies that RNAs, like proteins, are imported into the mitochondria. We investigated the relationship between the cytosolic and the mitochondrial tRNA genes and show that there are unique cytosolic tRNA genes, unique mitochondrial tRNA genes, and tRNA genes which appear to be shared and whose products are therefore targeted to both the cytosol and the mitochondrion.     

Human Tyrosine tRNA Is Also Internally Cleavable by E. coli Ribonuclease P RNA Ribozyme in Vitro

Transfer RNA is an essential molecule for biological system, and each tRNA molecule commonly has a cloverleaf structure. Previously, we experimentally showed that some Drosophila tRNA (tRNA^Ala, tRNA^His, and tRNA_i ^Met) molecules fit to form another, non-cloverleaf, structure in which the 3'-half of the tRNA molecules forms an alternative hairpin, and that the tRNA molecules are internally cleaved by the catalytic RNA of bacterial ribonuclease P (RNase P). Until now, the hyperprocessing reaction of tRNA has only been reported with Drosophila tRNAs. This time, we applied the hyperprocessing reaction to one of human tRNAs, human tyrosine tRNA, and we showed that this tRNA was also hyperprocessed by E. coli RNase P RNA. This tRNA is the first example for hyperprocessed non-Drosophila tRNAs. The results suggest that the hyperprocessing reaction can be a useful tool to detect destablized tRNA molecules from any species.     

Gross map location of Escherichia coli transfer RNA genes.

Chromosomal locations of Escherichia coli genes specifying more than 20 different transfer RNA species were determined by utilizing two different methods. One was based upon gene dosage effects caused by F′ factors. In 15 different F′ strains and their corresponding F^? strains, relative contents of individual tRNAs were measured after separating the tRNAs by two-dimensional polyacrylamide gel electrophoresis. Approximate doubling of the content of particular tRNA was found in individual F′ strains, as showing gross map location of the tRNA gene. The other method was based on the amplified synthesis of tRNAs occurring after prophage induction of λ lysogens. Synthesis of individual tRNAs was measured after the induction of λ phages integrated at five different bacterial sites. Characteristic overproduction of different tRNAs was observed in individual prophage strains. This finding also gave approximate map locations of tRNA genes close to the prophage sites. The mapping data obtained by the two methods were consistent with each other and also with the reported positions in the cases where previously mapped. On the basis of map location of the tRNA_f1^Met gene newly determined, the λ-transducing phage carrying the tRNA_f1^Met gene was found.     

Nuclear-encoded mitochondrial tRNAs of Trypanosoma brucei have a modified cytidine in the anticodon loop.

The mitochondrial genome of Trypanosoma brucei does not appear to encode any tRNA genes. Isolated organellar tRNAs hybridize to nuclear DNA, suggesting that they are synthesized in the nucleus and subsequently imported into the mitochondrion. Most imported tRNAs have cytosolic counterparts, showing identical mobility on two-dimensional polyacrylamide gels. We have compared three nuclear-encoded mitochondrial tRNAs (tRNA(Lys), tRNA(Leu), tRNA(Tyr)) with their cytosolic isoforms by direct enzymatic sequence analysis. Our findings indicate that the primary sequences of the mitochondrial and the corresponding cytosolic tRNAs are identical. However, we have identified a mitochondrion-specific nucleotide modification of each tRNA which is localized to a conserved cytidine residue at the penultimate position 5' of the anticodon. The modification present in mature mitochondrial tRNA(Tyr) was not found in a mutant tRNA(Tyr) defective in splicing in either cytosolic or mitochondrial fractions. The mutant tRNA(Tyr) has been expressed in transformed cells and its import into mitochondria has been demonstrated, suggesting that the modified cytidine residue is not required for import and therefore may be involved in adapting imported tRNAs to specific requirements of the mitochondrial translation machinery.     

Plant nuclear tRNAMet genes are ubiquitously interrupted by introns

We have isolated three independent clones for nuclear elongator tRNA^Met genes from an Arabidopsis DNA library using a tRNA^Met-specific probe generated by PCR. Each of the coding sequences for tRNA^Met in these clones is identical and is interrupted by an identical 11 bp long intervening sequence at the same position in the anticodon loop of the tRNA. Their sequences differ at two positions from the intron in a soybean counterpart. Southern analysis of Arabidopsis DNA demonstrates that a gene family coding for tRNA^Met is dispersed at at least eight loci in the genome. The unspliced precursor tRNA^Met intermediate was detected by RNA analysis using an oligonucleotide probe complementary to the putative intron sequence. In order to know whether introns commonly interrupt plant tRNA^Met genes, their coding sequences were PCR-amplified from the DNAs of eight phylogenetically separate plant species. All 53 sequences determined contain 10 to 13 bp long intervening sequences, always positioned one base downstream from the anticodon. They can all be potentially folded into the secondary structure characteristic for plant intron-containing precursor tRNAs. Surprisingly, GC residues are always present at the 5-distal end of each intron.     

A yeast arginine specific tRNA is a remnant aspartate acceptor

High specificity in aminoacylation of transfer RNAs (tRNAs) with the help of their cognate aminoacyl-tRNA synthetases (aaRSs) is a guarantee for accurate genetic translation. Structural and mechanistic peculiarities between the different tRNA/aaRS couples, suggest that aminoacylation systems are unrelated. However, occurrence of tRNA mischarging by non-cognate aaRSs reflects the relationship between such systems. In Saccharomyces cerevisiae, functional links between arginylation and aspartylation systems have been reported. In particular, it was found that an in vitro transcribed tRNA^Asp is a very efficient substrate for ArgRS. In this study, the relationship of arginine and aspartate systems is further explored, based on the discovery of a fourth isoacceptor in the yeast genome, tRNA₄^Arg. This tRNA has a sequence strikingly similar to that of tRNA^Asp but distinct from those of the other three arginine isoacceptors. After transplantation of the full set of aspartate identity elements into the four arginine isoacceptors, tRNA₄^Arg gains the highest aspartylation efficiency. Moreover, it is possible to convert tRNA₄^Arg into an aspartate acceptor, as efficient as tRNA^Asp, by only two point mutations, C38 and G73, despite the absence of the major anticodon aspartate identity elements. Thus, cryptic aspartate identity elements are embedded within tRNA₄^Arg. The latent aspartate acceptor capacity in a contemporary tRNA^Arg leads to the proposal of an evolutionary link between tRNA₄^Arg and tRNA^Asp genes.     

Quaternary structure of the yeast Arc1p-aminoacyl-tRNA synthetase complex in solution and its compaction upon binding of tRNAs

In the yeast Saccharomyces cerevisiae, the aminoacyl-tRNA synthetases (aaRS) GluRS and MetRS form a complex with the auxiliary protein cofactor Arc1p. The latter binds the N-terminal domains of both synthetases increasing their affinity for the transfer-RNA (tRNA) substrates tRNA^Met and tRNA^Glu. Until now, structural information was available only on the enzymatic domains of the individual aaRSs but not on their complexes with associated cofactors. We have analysed the yeast Arc1p-complexes in solution by small-angle X-ray scattering (SAXS). The ternary complex of MetRS and GluRS with Arc1p, displays a peculiar extended star-like shape, implying possible flexibility of the complex. We reconstituted in vitro a pentameric complex and demonstrated by electrophoretic mobility shift assay that the complex is active and contains tRNA^Met and tRNA^Glu, in addition to the three protein partners. SAXS reveals that binding of the tRNAs leads to a dramatic compaction of the pentameric complex compared to the ternary one. A hybrid low-resolution model of the pentameric complex is constructed rationalizing the compaction effect by the interactions of negatively charged tRNA backbones with the positively charged tRNA-binding domains of the synthetases.     

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.     

A critical role of water in the specific cleavage of the anticodon loop of some eukaryotic methionine initiator tRNAs

We have noticed that during a long storage and handling, the plant methionine initiator tRNA is spontaneously hydrolyzed within the anticodon loop at the C34-A35 phosphodiester bond. A literature search indicated that there is also the case for human initiator tRNA^Met but not for yeast tRNA^Met _i or E. coli tRNA^Met _f. All these tRNAs have an identical nucleotide sequence of the anticodon stems and loops with only one difference at position 33 within the loop. It means that cytosine 33 (C33) makes the anticodon loop of plant and human tRNA^Met _i susceptible to the specific cleavage reaction. Using crystallographic data of tRNA^Met _f of E. coli with U33, we modeled the anticodon loop of this tRNA with C33. We found that C33 within the anticodon loop creates a pocket that can accomodate a hydrogen bonded water molecule that acts as a general base and catalyzes a hydrolysis of C-A bond. We conclude that a single nucleotide change in the primary structure of tRNA^Met _i made changes in hydration pattern and readjustment in hydrogen bonding which lead to a cleavage of the phosphodiester bond.     

Analysis of genomic tRNA revealed presence of novel genomic features in cyanobacterial tRNA

Transfer RNAs (tRNA) are important molecules that involved in protein translation machinery and acts as a bridge between the ribosome and codon of the mRNA. The study of tRNA is evolving considerably in the fields of bacteria, plants, and animals. However, detailed genomic study of the cyanobacterial tRNA is lacking. Therefore, we conducted a study of cyanobacterial tRNA from 61 species. Analysis revealed that; cyanobacteria contain thirty-six to seventy-eight tRNA gens per genome that encodes for 20 tRNA isotypes. The number of iso-acceptors (anti-codons) ranged from thirty-two to forty-three per genome. tRNA^Ile with anti-codon AAU, GAU, and UAU was reported to be absent from the genome of Gleocapsa PCC 73,106 and Xenococcus sp. PCC 7305. Instead, they were contained anti-codon CAU that is common to tRNA^Met and tRNA^Ile as well. The iso-acceptors ACA (tRNA^Cys), ACC (tRNA^Gly), AGA, ACU (tRNA^Ser), AAA (tRNA^Phe), AGG (tRNA^Pro), AAC (tRNA^Val), GCG (tRNA^Arg), AUG (tRNA^His), and AUC (tRNA^Asp) were absent from the genome of cyanobacterial lineages studied so far. A few of the cyanobacterial species encode suppressor tRNAs, whereas none of the species were found to encode a selenocysteine iso-acceptor. Cyanobacterial species encode a few putative novel tRNAs whose functions are yet to be elucidated.     

与耳聋相关的线粒体tRNA突变

线粒体tRNA基因突变是导致感音神经性耳聋的原因之一．有些tRNA突变可直接造成耳聋的发生,称之为原发突变．如tRNA^Leu(UUR) A3243G等突变与综合征型耳聋相关,而tRNA^Ser(UCN) T7511C等突变则与非综合征型耳聋相关．此外,继发突变如tRNA^Thr G15927A等突变则对原发突变起协同作用,影响耳聋的表型表达．这些突变可引起tRNA二级结构改变,从而影响线粒体蛋白质合成,降低细胞内ATP的产生,由此引起的线粒体功能障碍可导致耳聋的发生．主要讨论与耳聋相关的线粒体tRNA突变及其致聋机理．     

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.     

Two isoaccepting seryl tRNAs coded by separate mitochondrial genes in yeast

Summary In S. cerevisiae four isoacceptor mitochondrial tRNAs for serine have been separated by reversed phase chromatography. At least two of these species are products of different genes. In this work the deletion mapping technique has been used to locate two genes for tRNA^ser. The gene for tRNA^ser previously localized in the oli I region of the mitochondrial genome has been found to code for tRNA _ser ² , and another gene coding for tRNA _ser ¹ has been detected in the region where most of other tRNA genes are found. Results of fine mapping experiments allowed to localize this gene in the proximity of the gene for tRNA^arg.     

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.     

Sequences of three transfer RNAs from mosquito mitochondria

The sequences of three transfer RNAs from mosquito cell mitochondria, tRNA_UCG^Arg, tRNA_GUC^Asp, and tRNA_GAU^Ile, determined using a combination of rapid ladder and fingerprinting procedures are reported. These were compared with hamster mitochondrial tRNA_UCG^Arg and tRNA_GUC^Asp determined similarly, and a bovine mitochondrial tRNA_GAU^Ile determined using a somewhat different approach. The primary sequences of the mosquito tRNAs were 35 to 65% homologous to the corresponding mammalian mitochondrial species, and bore little homology to “conventional” (bacterial or eucaryotic cytoplasmic) tRNA. The modification status of the mosquito mitochondrial tRNAs resembled that of mammalian mitochondrial tRNA. The results contribute to the generalization that metazoan mitochondrial tRNA constitutes a distinctive, albeit loosely structured, phylogenetic group.     

Recognition of tRNAGln by Helicobacter pylori GluRS2—a tRNAGln-specific glutamyl-tRNA synthetase

Accurate aminoacylation of tRNAs by the aminoacyl-tRNA synthetases (aaRSs) plays a critical role in protein translation. However, some of the aaRSs are missing in many microorganisms. Helicobacter pylori does not have a glutaminyl-tRNA synthetase (GlnRS) but has two divergent glutamyl-tRNA synthetases: GluRS1 and GluRS2. Like a canonical GluRS, GluRS1 aminoacylates tRNA^Glu1 and tRNA^Glu2. In contrast, GluRS2 only misacylates tRNA^Gln to form Glu-tRNA^Gln. It is not clear how GluRS2 achieves specific recognition of tRNA^Gln while rejecting the two H. pylori tRNA^Glu isoacceptors. Here, we show that GluRS2 recognizes major identity elements clustered in the tRNA^Gln acceptor stem. Mutations in the tRNA anticodon or at the discriminator base had little to no impact on enzyme specificity and activity.