The N-terminal domain of mammalian Lysyl-tRNA synthetase is a functional tRNA-binding domain.

Lysyl-tRNA synthetase from higher eukaryotes possesses a lysine-rich N-terminal polypeptide extension appended to a classical prokaryotic-like LysRS domain. Band shift analysis showed that this extra domain provides LysRS with nonspecific tRNA binding properties. A N-terminally truncated derivative of LysRS, LysRS-DeltaN, displayed a 100-fold lower apparent affinity for tRNA(3)Lys and a 3-fold increase in K(m) for tRNA(3)Lys in the aminoacylation reaction, as compared with the native enzyme. The isolated N-domain of LysRS also displayed weak affinity for tRNA, suggesting that the catalytic and N-domains of LysRS act synergistically to provide a high affinity binding site for tRNA. A more detailed analysis revealed that LysRS binds and specifically aminoacylates an RNA minihelix mimicking the amino acid acceptor stem-loop structure of tRNA(3)Lys, whereas LysRS-DeltaN did not. As a consequence, merging an additional RNA-binding domain into a bacterial-like LysRS increases the catalytic efficiency of the enzyme, especially at the low concentration of deacylated tRNA prevailing in vivo. Our results provide new insights into tRNA(Lys) channeling in eukaryotic cells and shed new light on the possible requirement of native LysRS for triggering tRNA(3)Lys packaging into human immunodeficiency virus, type 1 viral particles.     

Identity elements for specific aminoacylation of a tRNA by mammalian lysyl-tRNA synthetase bearing a nonspecific tRNA-interacting factor

Mammalian lysyl-tRNA synthetase (LysRS) has an N-terminal polypeptide chain extension appended to a prokaryotic-like synthetase domain. This extension, termed a tRNA-interacting factor (tIF), possesses a RNA-binding motif [KxxxK(K/R)xxK] that binds nonspecifically the acceptor TPsiC stem-loop domain of tRNA and provides a potent tRNA binding capacity to this enzyme. Consequently, native LysRS aminoacylates a RNA minihelix mimicking the amino acid acceptor stem-loop domain of tRNA(3)(Lys). Here, examination of minihelix recognition showed that mammalian LysRS aminoacylates RNA minihelices without specificity of sequence, revealing that none of the nucleotides from the acceptor TPsiC stem-loop domain are essential determinants of tRNA(Lys) acceptor identity. To test whether the tIF domain reduces the specificity of the synthetase with regard to complete tRNA molecules, aminoacylation of wild-type and mutant noncognate tRNAs by wild-type or N-terminally truncated LysRS was examined. The presence of the UUU anticodon of tRNA(Lys) appeared to be necessary and sufficient to transform yeast tRNA(Asp) or tRNA(i)(Met) into potent lysine acceptor tRNAs. Thus, nonspecific RNA-protein interactions between the acceptor stem of tRNA and the tIF domain do not relax the tRNA specificity of mammalian LysRS. The possibility that interaction of the full-length cognate tRNA with the synthetase is required to induce the catalytic center of the enzyme into a productive conformation is discussed.     

Functional association between three archaeal aminoacyl-tRNA synthetases

Aminoacyl-tRNA synthetases (aaRSs) are responsible for attaching amino acids to their cognate tRNAs during protein synthesis. In eukaryotes aaRSs are commonly found in multi-enzyme complexes, although the role of these complexes is still not completely clear. Associations between aaRSs have also been reported in archaea, including a complex between prolyl-(ProRS) and leucyl-tRNA synthetases (LeuRS) in Methanothermobacter thermautotrophicus that enhances tRNA(Pro) aminoacylation. Yeast two-hybrid screens suggested that lysyl-tRNA synthetase (LysRS) also associates with LeuRS in M. thermautotrophicus. Co-purification experiments confirmed that LeuRS, LysRS, and ProRS associate in cell-free extracts. LeuRS bound LysRS and ProRS with a comparable K(D) of about 0.3-0.9 microm, further supporting the formation of a stable multi-synthetase complex. The steady-state kinetics of aminoacylation by LysRS indicated that LeuRS specifically reduced the Km for tRNA(Lys) over 3-fold, with no additional change seen upon the addition of ProRS. No significant changes in aminoacylation by LeuRS or ProRS were observed upon the addition of LysRS. These findings, together with earlier data, indicate the existence of a functional complex of three aminoacyl-tRNA synthetases in archaea in which LeuRS improves the catalytic efficiency of tRNA aminoacylation by both LysRS and ProRS.     

Transfer RNA recognition by class I lysyl-tRNA synthetase from the Lyme disease pathogen Borrelia burgdorferi

Borrelia burgdorferi and other spirochetes contain a class I lysyl-tRNA synthetase (LysRS), in contrast to most eubacteria that have a canonical class II LysRS. We analyzed tRNA(Lys) recognition by B. burgdorferi LysRS, using two complementary approaches. First, the nucleotides of B. burgdorferi tRNA(Lys) in contact with B. burgdorferi LysRS were determined by enzymatic footprinting experiments. Second, the kinetic parameters for a series of variants of the B. burgdorferi tRNA(Lys) were then determined during aminoacylation by B. burgdorferi LysRS. The identity elements were found to be mostly located in the anticodon and in the acceptor stem. Transplantation of the identified identity elements into the Escherichia coli tRNA(Asp) scaffold endowed lysylation activity on the resulting chimera, indicating that a functional B. burgdorferi lysine tRNA identity set had been determined.     

Efficient aminoacylation of tRNA(Lys,3) by human lysyl-tRNA synthetase is dependent on covalent continuity between the acceptor stem and the anticodon domain

In this work, we probe the role of the anticodon in tRNA recognition by human lysyl-tRNA synthetase (hLysRS). Large decreases in aminoacylation efficiency are observed upon mutagenesis of anticodon positions U35 and U36 of human tRNA(Lys,3). A minihelix derived from the acceptor-TPsiC stem-loop domain of human tRNA(Lys,3)was not specifically aminoacylated by the human enzyme. The presence of an anticodon-derived stem-loop failed to stimulate aminoacylation of the minihelix. Thus, covalent continuity between the acceptor stem and anticodon domains appears to be an important requirement for efficient charging by hLysRS. To further examine the mechanism of communication between the critical anticodon recognition elements and the catalytic site, a two piece semi-synthetic tRNA(Lys, 3)construct was used. The wild-type semi-synthetic tRNA contained a break in the phosphodiester backbone in the D loop and was an efficient substrate for hLysRS. In contrast, a truncated variant that lacked nucleotides 8-17 in the D stem-loop displayedseverely reduced catalytic efficiency. The elimination of key tRNA tertiary structural elements has little effect on anticodon-dependent substrate binding but severely impacts formation of the proper transition state for catalysis. Taken together, our studies provide new insights into human tRNA structural requirements for effective transmission of the anticodon recognition signal to the distal acceptor stem domain.     

Functional dissection of the eukaryotic-specific tRNA-interacting factor of lysyl-tRNA synthetase

In the cytoplasm of higher eukaryotic cells, aminoacyl-tRNA synthetases (aaRSs) have polypeptide chain extensions appended to conventional prokaryotic-like synthetase domains. The supplementary domains, referred to as tRNA-interacting factors (tIFs), provide the core synthetases with potent tRNA-binding capacities, a functional requirement related to the low concentration of free tRNA prevailing in the cytoplasm of eukaryotic cells. Lysyl-tRNA synthetase is a component of the multi-tRNA synthetase complex. It exhibits a lysine-rich N-terminal polypeptide extension that increases its catalytic efficiency. The functional characterization of this new type of tRNA-interacting factor has been conducted. Here we describe the systematic substitution of the 13 lysine or arginine residues located within the general RNA-binding domain of hamster LysRS made of 70 residues. Our data show that three lysine and one arginine residues are major building blocks of the tRNA-binding site. Their mutation into alanine led to a reduced affinity for tRNA(3)(Lys) or minimalized tRNA mimicking the acceptor-TPsiC stem-loop of tRNA(3)(Lys) and a decrease in catalytic efficiency similar to that observed after a complete deletion of the N-terminal domain. Moreover, covalent continuity between the tRNA-binding and core domain is a prerequisite for providing LysRS with a tRNA binding capacity. Thus, our results suggest that the ability of LysRS to promote tRNA(Lys) networking during translation or to convey tRNA(3)(Lys) into the human immunodeficiency virus type 1 viral particles rests on the addition in evolution of this tRNA-interacting factor.     

Evidence for breaking domain-domain functional communication in a synthetase-tRNA complex

We report here evidence for mutations that break domain-domain functional communication in a synthetase-tRNA complex. Each synthetase is roughly divided into two major domains that are paralleled by the two arms of the L-shaped tRNA structure. The active-site-containing domain interacts with the acceptor arm of the tRNA. The second domain frequently interacts with the anticodon-containing arm. By an induced-fit mechanism, contacts with the anticodon can activate formation of a robust transition state at a site over 70 A away. This induced-fit-based activation is thought to occur through domain-domain signaling and is seen by the enhancement of aminoacylation of the anticodon-containing full tRNA versus a substrate based on the acceptor arm alone. Here we describe a rationally designed mutant methionyl-tRNA synthetase containing two point substitutions at sites that potentially link an anticodon-binding motif to the catalytic domain. The double mutation had no effect on interactions with either the isolated acceptor arm or the anticodon stem-loop. In contrast to interactions with the separate pieces, the mutant enzyme was severely impaired for binding the native tRNA and lost much of its ability to enhance the rate of charging of the full tRNA over that of a substrate based on the acceptor arm alone. We propose that these residues are part of a network for facilitating domain-domain communication for formation of an active synthetase-tRNA complex by induced fit.     

Anticodon recognition and discrimination by the alpha-helix cage domain of class I lysyl-tRNA synthetase

Aminoacyl-tRNA synthetases are normally found in one of two mutually exclusive structural classes, the only known exception being lysyl-tRNA synthetase which exists in both classes I (LysRS1) and II (LysRS2). Differences in tRNA acceptor stem recognition between LysRS1 and LysRS2 do not drastically impact cellular aminoacylation levels, focusing attention on the mechanism of tRNA anticodon recognition by LysRS1. On the basis of structure-based sequence alignments, seven tRNALys anticodon variants and seven LysRS1 anticodon binding site variants were selected for analysis of the Pyrococcus horikoshii LysRS1-tRNALys docking model. LysRS1 specifically recognized the bases at positions 35 and 36, but not that at position 34. Aromatic residues form stacking interactions with U34 and U35, and aminoacylation kinetics also identified direct interactions between Arg502 and both U35 and U36. Tyr491 was also found to interact with U36, and the Y491E variant exhibited significant improvement compared to the wild type in aminoacylation of a tRNALysUUG mutant. Refinement of the LysRS1-tRNALys docking model based upon these data suggested that anticodon recognition by LysRS1 relies on considerably fewer interactions than that by LysRS2, providing a structural basis for the more significant role of the anticodon in tRNA recognition by the class II enzyme. To date, only glutamyl-tRNA synthetase (GluRS) has been found to contain an alpha-helix cage anticodon binding domain homologous to that of LysRS1, and these data now suggest that specificity for the anticodon of tRNALys could have been acquired through relatively few changes to the corresponding domain of an ancestral GluRS enzyme.     

A preferential role for lysyl-tRNA4 in the synthesis of diadenosine 5',5'-P1,P4-tetraphosphate by an arginyl-tRNA synthetase-lysyl-tRNA synthetase complex from rat liver

The synthesis of diadenosine 5',5'-P1,P4-tetraphosphate (Ap4A) can be catalyzed in vitro by a tetrameric tRNA synthetase complex from rat liver containing two lysyl-tRNA synthetase and two arginyl-tRNA synthetase subunits. This reaction required ATP, AMP, 50-100 microM zinc, and inorganic pyrophosphatase. We show here that AMP can be omitted from the reaction and that the zinc levels can be markedly reduced provided catalytic amounts of tRNA(Lys) are added to the reaction mixture. Ap4A synthesis with purified tRNA(Lys) isoacceptors showed that the minor species, tRNA(4Lys), was 3-fold more active than either of the two major tRNA(Lys) species, tRNA(2Lys) and tRNA(5Lys). No activity could be demonstrated with tRNA(Lys) from Escherichia coli or with tRNA(Lys) or tRNA(Phe) from yeast. Aminoacylation of tRNA(4Lys) was strictly required as determined by the fact that Ap4A synthesis was not observed until aminoacylation was nearly complete, inhibitors of aminoacylation blocked Ap4A synthesis, and there was a strict requirement for added lysine. None of the above observations could be demonstrated, however, when lysyl-tRNA(Lys) was directly supplied to the reaction mixture. Optimum Ap4A synthesis was obtained by the addition of 1 mol of tRNA(Lys)/mol of the synthetase complex. This reaction is unique because it does not require the prior formation of an aminoacyl-AMP intermediate and because it can actively synthesize Ap4A at physiological zinc concentrations. The preferential role for tRNA(4Lys) in Ap4A synthesis is consistent with its prior implication in cell division.     

Misacylation of tRNALys with noncognate amino acids by lysyl-tRNA synthetase.

Lysyl-tRNA synthetase (LysRS), a class II enzyme whose major function is to provide Lys-tRNALys for protein synthesis, also catalyzes aminoacylation of tRNALys with arginine, threonine, methionine, leucine, alanine, serine, and cysteine. The limited selectivity in the tRNA aminoacylation reaction appears to be due to inefficient editing of some amino acids (Met, Leu, Cys, Ala, Thr) by a pre-transfer mechanism or the absence of editing of other amino acids (Arg and Ser). Purified Arg-tRNALys, Thr-tRNALys, and Met-tRNALys were essentially not deacylated by LysRS, indicating that the enzyme does not possess a post-transfer editing mechanism. However, LysRS possesses an efficient pre-transfer editing mechanism which prevents misacylation of tRNALys with ornithine. A novel feature of this editing reaction is that ornithine lactam is formed by the facile cyclization of ornithyl adenylate.     

A recurrent general RNA binding domain appended to plant methionyl-tRNA synthetase acts as a cis-acting cofactor for aminoacylation

The cDNA encoding rice methionyl-tRNA synthetase was isolated. The protein exhibited a C-terminal polypeptide appended to a classical MetRS domain. This supplementary domain is related to endothelial monocyte activating polypeptide II (EMAPII), a cytokine produced in mammals after cleavage of p43, a component of the multisynthetase complex. It is also related to Arc1p and Trbp111, two tRNA binding proteins. We expressed rice MetRS and a derivative with a deletion of its EMAPII-like domain. Band-shift analysis showed that this extra-domain provides MetRS with non-specific tRNA binding properties. The EMAPII-like domain contributed a 10-fold decrease in K:(M) for tRNA in the aminoacylation reaction catalyzed by the native enzyme, as compared with the C-terminally truncated MetRS. Consequently, the EMAPII domain provides MetRS with a better catalytic efficiency at the free tRNA concentration prevailing in vivo. This domain binds the acceptor minihelix of tRNA(Met) and facilitates its aminoacylation. These results suggest that the EMAPII module could be a relic of an ancient tRNA binding domain that was incorporated into primordial synthetases for aminoacylation of RNA minihelices taken as the ancestor of modern tRNA.     

Divergence in noncognate amino acid recognition between class I and class II lysyl-tRNA synthetases

Lysine insertion during coded protein synthesis requires lysyl-tRNA(Lys), which is synthesized by lysyl-tRNA synthetase (LysRS). Two unrelated forms of LysRS are known: LysRS2, which is found in eukaryotes, most bacteria, and a few archaea, and LysRS1, which is found in most archaea and a few bacteria. To compare amino acid recognition between the two forms of LysRS, the effects of l-lysine analogues on aminoacylation were investigated. Both enzymes showed stereospecificity toward the l-enantiomer of lysine and discriminated against noncognate amino acids with different R-groups (arginine, ornithine). Lysine analogues containing substitutions at other positions were generally most effective as inhibitors of LysRS2. For example, the K(i) values for aminoacylation of S-(2-aminoethyl)-l-cysteine and l-lysinamide were over 180-fold lower with LysRS2 than with LysRS1. Of the other analogues tested, only gamma-aminobutyric acid showed a significantly higher K(i) for LysRS2 than LysRS1. These data indicate that the lysine-binding site is more open in LysRS2 than in LysRS1, in agreement with previous structural studies. The physiological significance of divergent amino acid recognition was reflected by the in vivo resistance to growth inhibition imparted by LysRS1 against S-(2-aminoethyl)-l-cysteine and LysRS2 against gamma-aminobutyric acid. These differences in resistance to naturally occurring noncognate amino acids suggest the distribution of LysRS1 and LysRS2 contributes to quality control during protein synthesis. In addition, the specific inhibition of LysRS1 indicates it is a potential drug target.     

Mutation and evolution of the magnesium-binding site of a class II aminoacyl-tRNA synthetase

Aminoacyl-tRNA synthetases contain one or three Mg(2+) ions in their catalytic sites. In addition to their role in ATP binding, these ions are presumed to play a role in catalysis by increasing the electropositivity of the alpha-phosphate and stabilizing the pentavalent transition state. In the class II aaRS, two highly conserved carboxylate residues have been shown to participate with Mg(2+) ions in binding and coordination. It is shown here that these carboxylate residues are absolutely required for the activity of Saccharomyces cerevisiae aspartyl-tRNA synthetase. Mutants of these residues exhibit pleiotropic effects on the kinetic parameters suggesting an effect at an early stage of the aminoacylation reaction, such as the binding of ATP, Mg(2+), aspartic acid, or the amino acid activation. Despite genetic selections in an APS-knockout yeast strain, we were unable to select a single active mutant of these carboxylate residues. Nevertheless, we isolated an intragenic suppressor from a combinatorial library. The active mutant showed a second substitution close to the first one, and exhibited a significant increase of the tRNA aminoacylation rate. Structural analysis suggests that the acceptor stem of the tRNA might be repositioned to give a more productive enzyme:tRNA complex. Thus, the initial defect of the activation reaction was compensated by a significant increase of the aminoacylation rate that led to cellular complementation.     

Activation of the pyrrolysine suppressor tRNA requires formation of a ternary complex with class I and class II lysyl-tRNA synthetases

Monomethylamine methyltransferase of the archaeon Methanosarcina barkeri contains a rare amino acid, pyrrolysine, encoded by the termination codon UAG. Translation of this UAG requires the aminoacylation of the corresponding amber suppressor tRNAPyl. Previous studies reported that tRNAPyl could be aminoacylated by the synthetase-like protein PylS. We now show that tRNAPyl is efficiently aminoacylated in the presence of both the class I LysRS and class II LysRS of M. barkeri, but not by either enzyme acting alone or by PylS. In vitro studies show that both the class I and II LysRS enzymes must bind tRNAPyl in order for the aminoacylation reaction to proceed. Structural modeling and selective inhibition experiments indicate that the class I and II LysRSs form a ternary complex with tRNAPyl, with the aminoacylation activity residing in the class II enzyme.     

Ribosome association primes the stringent factor Rel for tRNA-dependent locking in the A-site and activation of (p)ppGpp synthesis

In the Gram-positive Firmicute bacterium Bacillus subtilis, amino acid starvation induces synthesis of the alarmone (p)ppGpp by the RelA/SpoT Homolog factor Rel. This bifunctional enzyme is capable of both synthesizing and hydrolysing (p)ppGpp. To detect amino acid deficiency, Rel monitors the aminoacylation status of the ribosomal A-site tRNA by directly inspecting the tRNA’s CCA end. Here we dissect the molecular mechanism of B. subtilis Rel. Off the ribosome, Rel predominantly assumes a ‘closed’ conformation with dominant (p)ppGpp hydrolysis activity. This state does not specifically select deacylated tRNA since the interaction is only moderately affected by tRNA aminoacylation. Once bound to the vacant ribosomal A-site, Rel assumes an ‘open’ conformation, which primes its TGS and Helical domains for specific recognition and stabilization of cognate deacylated tRNA on the ribosome. The tRNA locks Rel on the ribosome in a hyperactivated state that processively synthesises (p)ppGpp while the hydrolysis is suppressed. In stark contrast to non-specific tRNA interactions off the ribosome, tRNA-dependent Rel locking on the ribosome and activation of (p)ppGpp synthesis are highly specific and completely abrogated by tRNA aminoacylation. Binding pppGpp to a dedicated allosteric site located in the N-terminal catalytic domain region of the enzyme further enhances its synthetase activity.     

Methionyl-tRNA synthetase from Caenorhabditis elegans: a specific multidomain organization for convergent functional evolution

Methionyl-tRNA synthetase (MetRS) is a multidomain protein that specifically binds tRNAMet and catalyzes the synthesis of methionyl-tRNAMet. The minimal, core enzyme found in Aquifex aeolicus is made of a catalytic domain, which catalyzes the aminoacylation reaction, and an anticodon-binding domain, which promotes tRNA-protein association. In eukaryotes, additional domains are appended in cis or in trans to the core enzyme and increase the stability of the tRNA-protein complexes. Eventually, as observed for MetRS from Homo sapiens, the C-terminal appended domain causes a slow release of aminoacyl-tRNA and establishes a limiting step in the global aminoacylation reaction. Here, we report that MetRS from the nematode Caenorhabditis elegans displays a new type of structural organization. Its very C-terminal appended domain is related to the oligonucleotide binding-fold-based tRNA-binding domain (tRBD) recovered at the C-terminus of MetRS from plant, but, in the nematode enzyme, this domain is separated from the core enzyme by an insertion domain. Gel retardation and tRNA aminoacylation experiments show that MetRS from nematode is functionally related to human MetRS despite the fact that their appended tRBDs have distinct structural folds, and are not orthologs. Thus, functional convergence of human and nematode MetRS is the result of parallel and convergent evolution that might have been triggered by the selective pressure to invent processivity of tRNA handling in translation in higher eukaryotes.