Affinity labelling of tryptophanyl-transfer RNA synthetase

A double affinity-labelling approach has been developed in order to convert an oligomeric enzyme with multiple active centres into a single-site enzyme.Tryptophanyl-transfer RNA synthetase (EC 6.1.1.2) from beef pancreas is a symmetric dimer, α₂ An ATP analogue, γ-(p-azidoanilide)-ATP does not serve as a substrate for enzymatic aminoacylation of tRNA^Trp but acts as an effective competitive inhibitor in the absence of photochemical reaction, with K₁ = 1 × 10^?3m (K_mfor ATP = 2 × 10^?4m). The covalent photoaddition of azido-ATP³ results in complete loss of enzymatic activity in both the ATP-[³²P]pyrophosphate exchange reaction and tRNA aminoacylation. ATP completely protects the enzyme against inactivation. However, covalent binding of azido-ATP is also observed outside the active centres. The difference between covalent binding of the azido-ATP in the absence and presence of ATP corresponds to 2 moles of the ATP analogue per mole of the enzyme.Two binding sites for tRNA^Trp have been found from complex formation at pH 5.8 in the presence of Mg²⁺. The two tRNA molecules bind, with K_dis = 3.6 × 10^?8m and K_dis = 0.9 × 10^?6m, respectively, pointing to a strong negative co-operativity between the binding sites for tRNA.N-chlorambucilyl-tryptophanyl-tRNA^Trp and TRSase form a complex with K_dis = 5.5 × 10^?8m at pH 5.8 in the presence of 10 mm-Mg²⁺. This value is similar to the value of K_dis for tryptophanyl-tRNA of 4.8 × 10^?8m. Under the same conditions a 1:1 complex (in mol) is formed between the enzyme and Trp-tRNA or N-chlorambucilyl-Trp-tRNA. On incubation, a covalent bond is formed between N-chlorambucilyl-Trp-tRNA and TRSase; 1 mole of affinity reagent alkylates 1 mole of enzyme independently of the concentration of the modifier. The alkylation reaction is completely inhibited by the presence of tRNA^Trp whereas the tRNA devoid of tRNA^Trp does not affect the rate of alkylation. In the presence of either ATP or tryptophan, or a mixture of the two, the alkylation reaction is inhibited even though these ligands have no effect on the complex formation between TRSase and the tRNA analogue. Photoaddition of the azido-ATP completely prevents the reaction of the enzyme with the tRNA analogue, although the non-covalent complex formation is not affected.Exhaustive alkylation of TRSase partially inhibits the reaction of ATP [³²P]pyrophosphate exchange and completely blocks the aminoacylation of tRNA^Trp. Cleavage of the tRNA which is covalently bound to TRSase restores both the ATP-[³²P]pyrophosphate exchange and aminoacylation activity.The TRSase which is covalently-bound to R-Trp-tRNA is able to incorporate only one ATP molecule per dimeric enzyme into the active centre. This doubly modified enzyme is completely enzymatically inactive. Removal of the tRNA residue from the doubly modified enzyme results in the formation of the derivative with one blocked ATP site. Therefore, a “single-site” TRSase may be generated either by alkylation of the enzyme with Cl-R-Trp-tRNA or after the removal of covalently bound tRNA from the doubly labelled protein.Tryptophanyl-tRNA synthetase containing blocked ATP and/or tRNA binding site(s) seems to bo a useful tool for investigation of negative co-operativity and may help in the elucidation of the structure function relationships between the active centres.     

Temperature dependence of the aminoacylation of tRNA by Bacillus stearothermophilus aminoacyl-tRNA synthetases

Valine specific transfer RNA (tRNA^Val) was isolated from Bacillus stearothermophilus and Escherichia coli by chromatography on benzoylated DEAE–cellulose (BD–cellulose). Likewise isoleucine specific transfer RNA (tRNA^Ile) was isolated from B. stearothermophilus and from Mycoplasma sp. Kid. The thermal denaturation profiles (melting curves) of the two tRNA^Val species in the presence of Mg^{+ +} were nearly identical. However, the T_m for the Kid tRNA^Ile was about 10°C lower than that for the B. stearothermophilus tRNA^Ile. A nuclease and tRNA-free aminoacyl-tRNA synthetase (AA-tRNA synthetase) preparation from B. stearothermophilus was able to function efficiently at temperatures up to 80°C in the aminoacylation of all four tRNA species. Determination of the amino acid-acceptor activity of each tRNA species as a function of temperature of the aminoacylation reaction showed in each case a strong correlation between the loss of acceptor activity and the thermal denaturation profile of the tRNA. Evidence is presented that the loss in acceptor activity is most likely due to a change in structure of the tRNA as opposed to denaturation of the enzyme. These results further support the idea that correct secondary and/or tertiary structure must be maintained for tRNA to be active as a substrate for the AA-tRNA synthetase.     

Stimulation of valyl- and isoleucyl-tRNA synthetase reactions by polyamines

The aminoacylation of tRNA catalysed by valyl-tRNA synthetase (EC 6.1.1.9) and isoleucyl-tRNA synthetase (EC 6.1.1.5) fromMycobacterium smegmatis is dependent on the presence of divalent metal ions. Polyamines alone, in the absence of metal ions, do not bring about aminoacylation. In the presence of suboptimal concentrations of Mg²⁺, polyamines significantly stimulate the reaction. Of the cations tested, only Mn²⁺, Co²⁺ and Ca²⁺ can partially substitute for Mg²⁺ in aminoacylation, and spermine stimulates aminoacylation in the presence of these cations also. At neutral pH, spermine deacylates nonenzymatically aminoacyl tRNA. AMP and pyrophosphate-dependent enzymatic deacylation of aminoacyl-tRNA (reverse reaction) is also stimulated by spermine. The inhibitory effect of high concentration of KC1 on aminoacylation is counteracted, by spermine. The low level of activity between pH 8.5–9.0 at 1.2 mM Mg²⁺ is restored to normal level on the addition of spermine. The inhibitory effect of high pH on aminoacylation in the presence of low concentration of Mg²⁺ is also prevntedvby spemine.     

Evidence for Late Resolution of the AUX Codon Box in Evolution

Recognition strategies for tRNA aminoacylation are ancient and highly conserved, having been selected very early in the evolution of the genetic code. In most cases, the trinucleotide anticodons of tRNA are important identity determinants for aminoacylation by cognate aminoacyl-tRNA synthetases. However, a degree of ambiguity exists in the recognition of certain tRNA^Ile isoacceptors that are initially transcribed with the methionine-specifying CAU anticodon. In most organisms, the C34 wobble position in these tRNA^Ile precursors is rapidly modified to lysidine to prevent recognition by methionyl-tRNA synthetase (MRS) and production of a chimeric Met-tRNA^Ile that would compromise translational fidelity. In certain bacteria, however, lysidine modification is not required for MRS rejection, indicating that this recognition strategy is not universally conserved and may be relatively recent. To explore the actual distribution of lysidine-dependent tRNA^Ile rejection by MRS, we have investigated the ability of bacterial MRSs from different clades to differentiate cognate tRNA_CAU^Met from near-cognate tRNA_CAU^Ile. Discrimination abilities vary greatly and appear unrelated to phylogenetic or structural features of the enzymes or sequence determinants of the tRNA. Our data indicate that tRNA^Ile identity elements were established late and independently in different bacterial groups. We propose that the observed variation in MRS discrimination ability reflects differences in the evolution of genetic code machineries of emerging bacterial clades.     

A continuous tyrosyl-tRNA synthetase assay that regenerates the tRNA substrate

Tyrosyl-tRNA synthetase catalyzes the attachment of tyrosine to the 3′ end of tRNA^Tyr, releasing AMP, pyrophosphate, and l-tyrosyl-tRNA as products. Because this enzyme plays a central role in protein synthesis, it has garnered attention as a potential target for the development of novel antimicrobial agents. Although high-throughput assays that monitor tyrosyl-tRNA synthetase activity have been described, these assays generally use stoichiometric amounts of tRNA, limiting their sensitivity and increasing their cost. Here, we describe an alternate approach in which the Tyr-tRNA product is cleaved, regenerating the free tRNA substrate. We show that cyclodityrosine synthase from Mycobacterium tuberculosis can be used to cleave the l-Tyr-tRNA product, regenerating the tRNA^Tyr substrate. Because tyrosyl-tRNA synthetase can use both l- and d-tyrosine as substrates, we replaced the cyclodityrosine synthase in the assay with d-tyrosyl-tRNA deacylase, which cleaves d-Tyr-tRNA. This substitution allowed us to use the tyrosyl-tRNA synthetase assay to monitor the aminoacylation of tRNA^Tyr by d-tyrosine. Furthermore, by making Tyr-tRNA cleavage the rate-limiting step, we are able to use the assay to monitor the activities of cyclodityrosine synthetase and d-tyrosyl-tRNA deacylase. Specific methods to extend the tyrosyl-tRNA synthetase assay to monitor both the aminoacylation and post-transfer editing activities in other aminoacyl-tRNA synthetases are discussed.     

EFFECTS OF CHRONIC ETHANOL INGESTION ON BRAIN AMINOACYL-tRNA SYNTHETASES AND tRNA

The effects of chronic ethanol ingestion on the in vivo aminoacylation of brain transfer RNA (tRNA) were examined in C57BL/6J mice. A pronounced inhibition in the formation of [¹⁴C]leucy]-tRNA and [¹⁴C]phenylalanyl-tRNA was observed in the ethanol drinking mice. Properties of aminoacyl-tRNA synthetases and tRNA were examined following their separation and isolation on a DEAE-cellulose column. Synthesis of [¹⁴C]leucyl-tRNA was found to have a complete dependence on ATP and Mg²⁺. Incubations were carried out by cross-matching tRNA from control rat brain with synthetases obtained from the brains of control or ethanol-drinking mice. Under these conditions, a decreased ability for aminoacylation could be demonstrated when the source of enzyme was derived from ethanol-treated brain. The data indicate that the major effect of ethanol ingestion on the aminoacylation reaction is exerted on aminoacyl-tRNA synthetases.     

The characterization of the RNAs and aminoacyl-tRNA synthetases of the blue-green alga, Anacystis nidulans

The tRNA and aminoacyl-tRNA synthetases of the blue-green alga, Anacystis nidulans have been isolated and studied. The distribution of some algal tRNA species on BD-cellulose chromatography has been determined. One tRNA^Met species has been isolated in 80% purity by a single chromatography on a BD-cellulose column developed with a modified salt gradient. The number of different tRNA isoacceptors for Met, Ser, and Leu has been ascertained by RPC-5 chromatography. The recognition of algal tRNAs by the homologous algal synthetase preparation as well as the heterologous Escherichia coli preparation was studied by the aminoacylation tests. Since all of the isoaccepting species of the tRNAs tested behaved almost identically in presence of the two enzyme preparations, a conservation of the recognition site during the evolutionary divergence of bacteria and algae is strongly suggested.     

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.     

A single glutamyl-tRNA synthetase aminoacylates tRNAGlu and tRNAGln in Bacillus subtilis and efficiently misacylates Escherichia coli tRNAGln1 in vitro.

In the presence or absence of its regulatory factor, the monomeric glutamyl-tRNA synthetase from Bacillus subtilis can aminoacylate in vitro with glutamate both tRNAGlu and tRNAGln from B. subtilis and tRNAGln1 but not tRNAGln2 or tRNAGlu from Escherichia coli. The Km and Vmax values of the enzyme for its substrates in these homologous or heterologous aminoacylation reactions are very similar. This enzyme is the only aminoacyl-tRNA synthetase reported to aminoacylate with normal kinetic parameters two tRNA species coding for different amino acids and to misacylate at a high rate a heterologous tRNA under normal aminoacylation conditions. The exceptional lack of specificity of this enzyme for its tRNAGlu and tRNAGln substrates, together with structural and catalytic peculiarities shared with the E. coli glutamyl- and glutaminyl-tRNA synthetases, suggests the existence of a close evolutionary linkage between the aminoacyl-tRNA synthetases specific for glutamate and those specific for glutamine. A comparison of the primary structures of the three tRNAs efficiently charged by the B. subtilis glutamyl-tRNA synthetase with those of E. coli tRNAGlu and tRNAGln2 suggests that this enzyme interacts with the G64-C50 or G64-U50 in the T psi stem of its tRNA substrates.     

In vivo identification of essential nucleotides in tRNALeu to its functions by using a constructed yeast tRNALeu knockout strain

The fidelity of protein biosynthesis requires the aminoacylation of tRNA with its cognate amino acid catalyzed by aminoacyl-tRNA synthetase with high levels of accuracy and efficiency. Crucial bases in tRNA^Leu to aminoacylation or editing functions of leucyl-tRNA synthetase have been extensively studied mainly by in vitro methods. In the present study, we constructed two Saccharomyces cerevisiae tRNA^Leu knockout strains carrying deletions of the genes for tRNA^Leu(GAG) and tRNA^Leu(UAG). Disrupting the single gene encoding tRNA^Leu(GAG) had no phenotypic consequence when compared to the wild-type strain. While disrupting the three genes for tRNA^Leu(UAG) had a lethal effect on the yeast strain, indicating that tRNA^Leu(UAG) decoding capacity could not be compensated by another tRNA^Leu isoacceptor. Using the triple tRNA knockout strain and a randomly mutated library of tRNA^Leu(UAG), a selection to identify critical tRNA^Leu elements was performed. In this way, mutations inducing in vivo decreases of tRNA levels or aminoacylation or editing ability by leucyl-tRNA synthetase were identified. Overall, the data showed that the triple tRNA knockout strain is a suitable tool for in vivo studies and identification of essential nucleotides of the tRNA.     

Divergence of glutamate and glutamine aminoacylation pathways: Providing the evolutionary rationale for mischarging

Aminoacyl-tRNA for protein synthesis is produced through the action of a family of enzymes called aminoacyl-tRNA synthetases. A general rule is that there is one aminoacyl-tRNA synthetase for each of the standard 20 amino acids found in all cells. This is not universal, however, as a majority of prokaryotic organisms and eukaryotic organelles lack the enzyme glutaminyl-tRNA synthetase, which is responsible for forming Gln-tRNA^Gln in eukaryotes and in Gram-negative eubacteria. Instead, in organisms lacking glutaminyl-tRNA synthetase, Gln-tRNA^Gln is provided by misacylation of tRNA^Gln with glutamate by glutamyl-tRNA synthetase, followed by the conversion of tRNA-bound glutamate to glutamine by the enzyme Glu-tRNA^Gln amidotransferase. The fact that two different pathways exist for charging glutamine tRNA indicates that ancestral prokaryotic and eukaryotic organisms evolved different cellular mechanisms for incorporating glutamine into proteins. Here, we explore the basis for diverging pathways for aminoacylation of glutamine tRNA. We propose that stable retention of glutaminyl-tRNA synthetase in prokaryotic organisms following a horizontal gene transfer event from eukaryotic organisms (Lamour et al. 1994) was dependent on the evolving pool of glutamate and glutamine tRNAs in the organisms that acquired glutaminyl-tRNA synthetase by this mechanism. This model also addresses several unusual aspects of aminoacylation by glutamyl- and glutaminyl-tRNA synthetases that have been observed.Based on a presentation made at a workshop—Aminoacyl-tRNA Synthetases and the Evolution of the Genetic Code—held at Berkeley, CA, July 17–20, 1994 Correspondence to: D. Söll     

Isoleucyl transfer ribonucleic acid synthetase. Steady-state kinetic analysis.

A steady-state kinetic analysis was conducted of the overall aminoacylation reaction catalyzed by isoleucyl-tRNA synthetase. The patterns of Lineweaver-Burk plots obtained indicated that tRNA adds to the enzyme only after isoleucyl adenylate formation and pyrophosphate release. These kinetic patterns were consistent with the bi-uni-uni-bi Ping Pong mechanism generally accepted for this aminoacyl-tRNA synthetase, but they could also be accommodated by a mechanism in which a second molecule of L-isoleucine added to the enzyme between isoleucyl adenylate formation and aminoacylation of tRNA [Fersht, A.R., & Kaethner, M.M. (1976) Biochemistry 15, 818]. The values of the kinetic parameters favor the latter mechanism. The results of this kinetic analysis indicated that the affinity of isoleucyl-tRNA synthetase for Mg.ATP was enhanced upon binding of L-isoleucine and vice versa. It also indicated that the affinity of the enzyme for L-isoleucine is decreased upon binding tRNA and vice versa. The values of dissociation constants calculated for each of the substrates by this study generally compared well with those determined by other authors using a variety of kinetic and equilibrium methods.     

tRNA aminoacylation by arginyl-tRNA synthetase: induced conformations during substrates binding

The 2.2 A crystal structure of a ternary complex formed by yeast arginyl-tRNA synthetase and its cognate tRNA(Arg) in the presence of the L-arginine substrate highlights new atomic features used for specific substrate recognition. This first example of an active complex formed by a class Ia aminoacyl-tRNA synthetase and its natural cognate tRNA illustrates additional strategies used for specific tRNA selection. The enzyme specifically recognizes the D-loop and the anticodon of the tRNA, and the mutually induced fit produces a conformation of the anticodon loop never seen before. Moreover, the anticodon binding triggers conformational changes in the catalytic center of the protein. The comparison with the 2.9 A structure of a binary complex formed by yeast arginyl-tRNA synthetase and tRNA(Arg) reveals that L-arginine binding controls the correct positioning of the CCA end of the tRNA(Arg). Important structural changes induced by substrate binding are observed in the enzyme. Several key residues of the active site play multiple roles in the catalytic pathway and thus highlight the structural dynamics of the aminoacylation reaction.     

Aminoacylation of RNA Minihelices: Implications for tRNA Synthetase Structural Design and Evolution

Abstract

The genetic code is based on the aminoacylation of tRNA with amino acids catalyzed by the aminoacyl-tRNA synthetases. The synthetases are constructed from discrete domains and all synthetases possess a core catalytic domain that catalyzes amino acid activation, binds the acceptor stem of tRNA, and transfers the amino acid to tRNA. Fused to the core domain are additional domains that mediate RNA interactions distal to the acceptor stem. Several synthetases catalyze the aminoacylation of RNA oligonucleotide substrates that recreate only the tRNA acceptor stems. In one case, a relatively small catalytic domain catalyzes the aminoacylation of these substrates independent of the rest of the protein. Thus, the active site domain may represent a primordial synthetase in which polypeptide insertions that mediate RNA acceptor stem interactions are tightly integrated with determinants for aminoacyl adenylate synthesis. The relationship between nucleotide sequences in small RNA oligonucleotides and the specific amino acids that are attached to these oligonucleotides could constitute a second genetic code.     

Exit Strategies for Charged tRNA from GluRS

For several class I aminoacyl-tRNA synthetases (aaRSs), the rate-determining step in aminoacylation is the dissociation of charged tRNA from the enzyme. In this study, the following factors affecting the release of the charged tRNA from aaRSs are computationally explored: the protonation states of amino acids and substrates present in the active site, and the presence and the absence of AMP and elongation factor Tu.Through molecular modeling, internal pK_a calculations, and molecular dynamics simulations, distinct, mechanistically relevant post-transfer states with charged tRNA bound to glutamyl-tRNA synthetase from Thermus thermophilus (Glu-tRNA^Glu) are considered. The behavior of these nonequilibrium states is characterized as a function of time using dynamical network analysis, local energetics, and changes in free energies to estimate transitions that occur during the release of the tRNA. The hundreds of nanoseconds of simulation time reveal system characteristics that are consistent with recent experimental studies.Energetic and network results support the previously proposed mechanism in which the transfer of amino acid to tRNA is accompanied by the protonation of AMP to H-AMP. Subsequent migration of proton to water reduces the stability of the complex and loosens the interface both in the presence and in the absence of AMP. The subsequent undocking of AMP or tRNA then proceeds along thermodynamically competitive pathways. Release of the tRNA acceptor stem is further accelerated by the deprotonation of the α-ammonium group on the charging amino acid. The proposed general base is Glu41, a residue binding the α-ammonium group that is conserved in both structure and sequence across nearly all class I aaRSs. This universal handle is predicted through pK_a calculations to be part of a proton relay system for destabilizing the bound charging amino acid following aminoacylation. Addition of elongation factor Tu to the aaRS·tRNA complex stimulates the dissociation of the tRNA core and the tRNA acceptor stem.     

Gain of C-Ala enables AlaRS to target the L-shaped tRNAAla

Unlike many other aminoacyl-tRNA synthetases, alanyl-tRNA synthetase (AlaRS) retains a conserved prototype structure throughout biology. While Caenorhabditis elegans cytoplasmic AlaRS (CeAlaRS_c) retains the prototype structure, its mitochondrial counterpart (CeAlaRS_m) contains only a residual C-terminal domain (C-Ala). We demonstrated herein that the C-Ala domain from CeAlaRS_c robustly binds both tRNA and DNA. It bound different tRNAs but preferred tRNA^Ala. Deletion of this domain from CeAlaRS_c sharply reduced its aminoacylation activity, while fusion of this domain to CeAlaRS_m selectively and distinctly enhanced its aminoacylation activity toward the elbow-containing (or L-shaped) tRNA^Ala. Phylogenetic analysis showed that CeAlaRS_m once possessed the C-Ala domain but later lost most of it during evolution, perhaps in response to the deletion of the T-arm (part of the elbow) from its cognate tRNA. This study underscores the evolutionary gain of C-Ala for docking AlaRS to the L-shaped tRNA^Ala.     

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

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