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Mitochondrial tRNA import is widespread, but mechanistic insights of how tRNAs are translocated across mitochondrial membranes remain scarce. The parasitic protozoan T. brucei lacks mitochondrial tRNA genes. Consequently, it imports all organellar tRNAs from the cytosol. Here we investigated the connection between tRNA and protein translocation across the mitochondrial inner membrane. Trypanosomes have a single inner membrane protein translocase that consists of three heterooligomeric submodules, which all are required for import of matrix proteins. In vivo depletion of individual submodules shows that surprisingly only the integral membrane core module, including the protein import pore, but not the presequence-associated import motor are required for mitochondrial tRNA import. Thus we could uncouple import of matrix proteins from import of tRNAs even though both substrates are imported into the same mitochondrial subcompartment. This is reminiscent to the outer membrane where the main protein translocase but not on-going protein translocation is required for tRNA import. We also show that import of tRNAs across the outer and inner membranes are coupled to each other. Taken together, these data support the 'alternate import model', which states that tRNA and protein import while mechanistically independent use the same translocation pores but not at the same time.

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Orthogonal aminoacyl-tRNA synthetase/tRNA pairs have emerged as powerful means of site-specifically introducing non-standard amino acids into proteins in vivo. Using amino acids with crosslinking moieties this method allows the identification of transient protein-protein interactions. Here we have introduced a previously characterized evolved tyrosyl-tRNA synthetase/suppressor tRNATyr pair from E. coli into the parasitic protozoan Trypanosoma brucei. Upon addition of a suitable non-standard amino acid the suppressor tRNATyr was charged and allowed translation of a green fluorescent protein whose gene contained a nonsense mutation. - T. brucei is unusual in that its mitochondrion lacks tRNA genes indicating that all its organellar tRNAs are imported from the cytosol. Expression of the bacterial tyrosyl-tRNA synthetase in our system is tetracycline-inducible. We have therefore used it to demonstrate that cytosolic aminoacylation of the suppressor tRNATyr induces its import into the mitochondrion.

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This corrects the article DOI: 10.1038/ncomms13707.

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Mitochondrial protein import is essential for all eukaryotes. Here we show that the early diverging eukaryote Trypanosoma brucei has a non-canonical inner membrane (IM) protein translocation machinery. Besides TbTim17, the single member of the Tim17/22/23 family in trypanosomes, the presequence translocase contains nine subunits that co-purify in reciprocal immunoprecipitations and with a presequence-containing substrate that is trapped in the translocation channel. Two of the newly discovered subunits are rhomboid-like proteins, which are essential for growth and mitochondrial protein import. Rhomboid-like proteins were proposed to form the protein translocation pore of the ER-associated degradation system, suggesting that they may contribute to pore formation in the presequence translocase of T. brucei. Pulldown of import-arrested mitochondrial carrier protein shows that the carrier translocase shares eight subunits with the presequence translocase. This indicates that T. brucei may have a single IM translocase that with compositional variations mediates import of presequence-containing and carrier proteins.

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Aminoacyl-tRNA synthetases (aaRSs) are ubiquitous and ancient enzymes, mostly known for their essential role in generating aminoacylated tRNAs. During the last two decades, many aaRSs have been found to perform additional and equally crucial tasks outside translation. In metazoans, aaRSs have been shown to assemble, together with non-enzymatic assembly proteins called aaRSs-interacting multifunctional proteins (AIMPs), into so-called multi-synthetase complexes (MSCs). Metazoan MSCs are dynamic particles able to specifically release some of their constituents in response to a given stimulus. Upon their release from MSCs, aaRSs can reach other subcellular compartments, where they often participate to cellular processes that do not exploit their primary function of synthesizing aminoacyl-tRNAs. The dynamics of MSCs and the expansion of the aaRSs functional repertoire are features that are so far thought to be restricted to higher and multicellular eukaryotes. However, much can be learnt about how MSCs are assembled and function from apparently 'simple' organisms. Here we provide an overview on the diversity of these MSCs, their composition, mode of assembly and the functions that their constituents, namely aaRSs and AIMPs, exert in unicellular organisms.

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Yeast mitochondrial Gln-mtRNAGln is synthesized by the transamidation of mischarged Glu-mtRNAGln by a non-canonical heterotrimeric tRNA-dependent amidotransferase (AdT). The GatA and GatB subunits of the yeast AdT (GatFAB) are well conserved among bacteria and eukaryota, but the GatF subunit is a fungi-specific ortholog of the GatC subunit found in all other known heterotrimeric AdTs (GatCAB). Here we report the crystal structure of yeast mitochondrial GatFAB at 2.0 Å resolution. The C-terminal region of GatF encircles the GatA-GatB interface in the same manner as GatC, but the N-terminal extension domain (NTD) of GatF forms several additional hydrophobic and hydrophilic interactions with GatA. NTD-deletion mutants displayed growth defects, but retained the ability to respire. Truncation of the NTD in purified mutants reduced glutaminase and transamidase activities when glutamine was used as the ammonia donor, but increased transamidase activity relative to the full-length enzyme when the donor was ammonium chloride. Our structure-based functional analyses suggest the NTD is a trans-acting scaffolding peptide for the GatA glutaminase active site. The positive surface charge and novel fold of the GatF-GatA interface, shown in this first crystal structure of an organellar AdT, stand in contrast with the more conventional, negatively charged bacterial AdTs described previously.

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Mitochondria originate from the α-proteobacterial domain of life. Since this unique event occurred, mitochondrial genomes of protozoans, fungi, plants and metazoans have highly derived and diverged away from the common ancestral DNA. These resulting genomes highly differ from one another, but all present-day mitochondrial DNAs have a very reduced coding capacity. Strikingly however, ATP production coupled to electron transport and translation of mitochondrial proteins are the two common functions retained in all mitochondrial DNAs. Paradoxically, most components essential for these two functions are now expressed from nuclear genes. Understanding how mitochondrial translation evolved in various eukaryotic models is essential to acquire new knowledge of mitochondrial genome expression. In this review, we provide a thorough analysis of the idiosyncrasies of mitochondrial translation as they occur between organisms. We address this by looking at mitochondrial codon usage and tRNA content. Then, we look at the aminoacyl-tRNA-forming enzymes in terms of peculiarities, dual origin, and alternate function(s). Finally we give examples of the atypical structural properties of mitochondrial tRNAs found in some organisms and the resulting adaptive tRNA-protein partnership.

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Helicobacter pylori catalyzes Asn-tRNA(Asn) formation by use of the indirect pathway that involves charging of Asp onto tRNA(Asn) by a non-discriminating aspartyl-tRNA synthetase (ND-AspRS), followed by conversion of the mischarged Asp into Asn by the GatCAB amidotransferase. We show that the partners of asparaginylation assemble into a dynamic Asn-transamidosome, which uses a different strategy than the Gln-transamidosome to prevent the release of the mischarged aminoacyl-tRNA intermediate. The complex is described by gel-filtration, dynamic light scattering and kinetic measurements. Two strategies for asparaginylation are shown: (i) tRNA(Asn) binds GatCAB first, allowing aminoacylation and immediate transamidation once ND-AspRS joins the complex; (ii) tRNA(Asn) is bound by ND-AspRS which releases the Asp-tRNA(Asn) product much slower than the cognate Asp-tRNA(Asp); this kinetic peculiarity allows GatCAB to bind and transamidate Asp-tRNA(Asn) before its release by the ND-AspRS. These results are discussed in the context of the interrelation between the Asn and Gln-transamidosomes which use the same GatCAB in H. pylori, and shed light on a kinetic mechanism that ensures faithful codon reassignment for Asn.

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In many bacteria and archaea, an ancestral pathway is used where asparagine and glutamine are formed from their acidic precursors while covalently linked to tRNA(Asn) and tRNA(Gln), respectively. Stable complexes formed by the enzymes of these indirect tRNA aminoacylation pathways are found in several thermophilic organisms, and are called transamidosomes. We describe here a transamidosome forming Gln-tRNA(Gln) in Helicobacter pylori, an ε-proteobacterium pathogenic for humans; this transamidosome displays novel properties that may be characteristic of mesophilic organisms. This ternary complex containing the non-canonical GluRS2 specific for Glu-tRNA(Gln) formation, the tRNA-dependent amidotransferase GatCAB and tRNA(Gln) was characterized by dynamic light scattering. Moreover, we observed by interferometry a weak interaction between GluRS2 and GatCAB (K(D) = 40 ± 5 µM). The kinetics of Glu-tRNA(Gln) and Gln-tRNA(Gln) formation indicate that conformational shifts inside the transamidosome allow the tRNA(Gln) acceptor stem to interact alternately with GluRS2 and GatCAB despite their common identity elements. The integrity of this dynamic transamidosome depends on a critical concentration of tRNA(Gln), above which it dissociates into separate GatCAB/tRNA(Gln) and GluRS2/tRNA(Gln) complexes. Ester bond protection assays show that both enzymes display a good affinity for tRNA(Gln) regardless of its aminoacylation state, and support a mechanism where GluRS2 can hydrolyze excess Glu-tRNA(Gln), ensuring faithful decoding of Gln codons.

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Genomic studies revealed the absence of glutaminyl-tRNA synthetase and/or asparaginyl-tRNA synthetase in many bacteria and all known archaea. In these microorganisms, glutaminyl-tRNA(Gln) (Gln-tRNA(Gln)) and/or asparaginyl-tRNA(Asn) (Asn-tRNA(Asn)) are synthesized via an indirect pathway involving side chain amidation of misacylated glutamyl-tRNA(Gln) (Glu-tRNA(Gln)) and/or aspartyl-tRNA(Asn) (Asp-tRNA(Asn)) by an amidotransferase. A series of chloramphenicol analogs have been synthesized and evaluated as inhibitors of Helicobacter pylori GatCAB amidotransferase. Compound 7a was identified as the most active competitive inhibitor of the transamidase activity with respect to Asp-tRNA(Asn) (K(m)=2µM), with a K(i) value of 27µM.

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Faithful translation of the genetic code is mainly based on the specificity of tRNA aminoacylation catalyzed by aminoacyl-tRNA synthetases. These enzymes are comprised of a catalytic core and several appended domains. Bacterial glutamyl-tRNA synthetases (GluRS) contain five structural domains, the two distal ones interacting with the anticodon arm of tRNA(Glu). Thermus thermophilus GluRS requires the presence of tRNA(Glu) to bind ATP in the proper site for glutamate activation. In order to test the role of these two distal domains in this mechanism, we characterized the in vitro properties of the C-truncated Escherichia coli GluRSs N(1-313) and N(1-362), containing domains 1-3 and 1-4, respectively, and of their N-truncated complements GluRSs C(314-471) (containing domains 4 and 5) and C(363-471) (free domain 5). These C-truncated GluRSs are soluble, aminoacylate specifically tRNA(Glu), and require the presence of tRNA(Glu) to catalyze the activation of glutamate, as does full-length GluRS(1-471). The k(cat) of tRNA glutamylation catalyzed by N(1-362) is about 2000-fold lower than that catalyzed by the full-length E. coli GluRS(1-471). The addition of free domain 5 (C(363-471)) to N(1-362) strongly stimulates this k(cat) value, indicating that covalent connectivity between N(1-362) and domain 5 is not required for GluRS activity; the hyperbolic relationship between domain 5 concentration and this stimulation indicates that these proteins and tRNA(Glu) form a productive complex with a K(d) of about 100 microM. The K(d) values of tRNA(Glu) interactions with the full-length GluRS and with the truncated GluRSs N(1-362) and free domain 5 are 0.48, 0.11, and about 1.2 microM, respectively; no interaction was detected between these two complementary truncated GluRSs. These results suggest that in the presence of these truncated GluRSs, tRNA(Glu) is positioned for efficient aminoacylation by the two following steps: first, it interacts with GluRS N(1-362) via its acceptor-TPsiC stem loop domain and then with free domain 5 via its anticodon-Dstem-biloop domain, which appeared later during evolution. On the other hand, tRNA glutamylation catalyzed by N(1-313) is not stimulated by its complement C(314-471), revealing the importance of the covalent connectivity between domains 3 and 4 for GluRS aminoacylation activity. The K(m) values of N(1-313) and N(1-362) for each of their substrates are similar to those of full-length GluRS. These C-truncated GluRSs recognize only tRNA(Glu). These results confirm the modular nature of GluRS and support the model of a "recent" fusion of domains 4 and 5 to a proto-GluRS containing the catalytic domain and able to recognize its tRNA substrate(s).

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HPr is a protein of the phosphoenolpyruvate:sugar phosphotransferase transport system (PTS). In gram-positive bacteria, HPr can be phosphorylated on Ser-46 by the kinase/phosphorylase HprK/P and on His-15 by phospho-enzyme I (EI~P) of the PTS. In vitro studies with purified HPrs from Bacillus subtilis, Enterococcus faecalis, and Streptococcus salivarius have indicated that the phosphorylation of one residue impedes the phosphorylation of the other. However, a recent study showed that while the rate of Streptococcus salivarius HPr phosphorylation by EI~P is reduced at acidic pH, the phosphorylation of HPr(Ser-P) by EI~P, generating HPr(Ser-P)(His~P), is stimulated. This suggests that HPr(Ser-P)(His~P) synthesis may occur in acidogenic bacteria unable to maintain their intracellular pH near neutrality. Consistent with this hypothesis, significant amounts of HPr(Ser-P)(His~P) have been detected in some streptococci. The present study was aimed at determining whether the capacity to synthesize HPr(Ser-P)(His~P) is common to streptococcal species, as well as to lactococci, which are also unable to maintain their intracellular pH near neutrality in response to a decrease in extracellular pH. Our results indicated that unlike Staphylococcus aureus, B. subtilis, and E. faecalis, all the streptococcal and lactococcal species tested were able to synthesize large amounts of HPr(Ser-P)(His~P) during growth. We also showed that Streptococcus salivarius IIABLMan, a protein involved in sugar transport by the PTS, could be efficiently phosphorylated by HPr(Ser-P)(His~P).

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The trimeric GatCAB aminoacyl-tRNA amidotransferases catalyze the amidation of Asp-tRNAAsn and/or Glu-tRNAGln to Asn-tRNAAsn and/or Gln-tRNAGln, respectively, in bacteria and archaea lacking an asparaginyl-tRNA synthetase and/or a glutaminyl-tRNA synthetase. The two misacylated tRNA substrates of these amidotransferases are formed by the action of nondiscriminating aspartyl-tRNA synthetases and glutamyl-tRNA synthetases. We report here that the presence of a physiological concentration of a nondiscriminating aspartyl-tRNA synthetase in the transamidation assay decreases the Km of GatCAB for Asp-tRNAAsn. These conditions, which were practical for the testing of potential inhibitors of GatCAB, also allowed us to discover and characterize two novel inhibitors, aspartycin and glutamycin. These analogues of the 3'-ends of Asp-tRNA and Glu-tRNA, respectively, are competitive inhibitors of the transamidase activity of Helicobacter pylori GatCAB with respect to Asp-tRNAAsn, with Ki values of 134 microM and 105 microM, respectively. Although the 3' end of aspartycin is similar to the 3' end of Asp-tRNAAsn, this analogue was neither phosphorylated nor transamidated by GatCAB. These novel inhibitors could be used as lead compounds for designing new types of antibiotics targeting GatCABs, since the indirect pathway for Asn-tRNAAsn or Gln-tRNAGln synthesis catalyzed by these enzymes is not present in eukaryotes and is essential for the survival of the above-mentioned bacteria.

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The aminoacyl-beta-ketophosphonate-adenosines (aa-KPA) are stable analogs of the aminoacyl adenylates, which are high-energy intermediates in the formation of aminoacyl-tRNA catalyzed by aminoacyl-tRNA synthetases (aaRS). We have synthesized glutamyl-beta-ketophosphonate-adenosine (Glu-KPA) and glutaminyl-beta-ketophosphonate-adenosine (Gln-KPA), and have tested them as inhibitors of their cognate aaRS, and of a non-cognate aaRS. Glu-KPA is a competitive inhibitor of Escherichia coli glutamyl-tRNA synthetase (GluRS) with a K(i) of 18microM with respect to its substrate glutamate, and binds at one site on this monomeric enzyme; the non-cognate Gln-KPA also binds this GluRS at one site, but is a much weaker (K(i)=2.9mM) competitive inhibitor. By contrast, Gln-KPA inhibits E. coli glutaminyl-tRNA synthetase (GlnRS) by binding competitively but weakly at two distinct sites on this enzyme (average K(i) of 0.65mM); the non-cognate Glu-KPA shows one-site weak (K(i)=2.8mM) competitive inhibition of GlnRS. These kinetic results indicate that the glutamine and the AMP modules of Gln-KPA, connected by the beta-ketophosphonate linker, cannot bind GlnRS simultaneously, and that one Gln-KPA molecule binds the AMP-binding site of GlnRS through its AMP module, whereas another Gln-KPA molecule binds the glutamine-binding site through its glutamine module. This model suggests that similar structural constraints could affect the binding of Glu-KPA to the active site of mammalian cytoplasmic GluRSs, which are evolutionarily much closer to bacterial GlnRS than to bacterial GluRS. This possibility was confirmed by the fact that Glu-KPA inhibits bovine liver GluRS 145-fold less efficiently than E. coli GluRS by competitive weak binding at two distinct sites (average K(i)=2.6mM). Moreover, these kinetic differences reveal that the active sites of bacterial GluRSs and mammalian cytoplasmic GluRSs have substantial structural differences that could be further exploited for the design of better inhibitors specific for bacterial GluRSs, promising targets for antimicrobial therapy.

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