Recognition of acceptor-stem structure of tRNA(Asp) by Escherichia coli aspartyl-tRNA synthetase

Protein-RNA recognition between aminoacyl-tRNA synthetases and tRNA is highly specific and essential for cell viability. We investigated the structure-function relationships involved in the interaction of the Escherichia coli tRNA(Asp) acceptor stem with aspartyl-tRNA synthetase. The goal was to isolate functionally active mutants and interpret them in terms of the crystal structure of the synthetase-tRNA(Asp) complex. Mutants were derived from Saccharomyces cerevisiae tRNA(Asp), which is inactive with E. coli aspartyl-tRNA synthetase, allowing a genetic selection of active tRNAs in a tRNA(Asp) knockout strain of E. coli. The mutants were obtained by directed mutagenesis or library selections that targeted the acceptor stem of the yeast tRNA(Asp) gene. The mutants provide a rich source of tRNA(Asp) sequences, which show that the sequence of the acceptor stem can be extensively altered while allowing the tRNA to retain substantial aminoacylation and cell-growth functions. The predominance of tRNA backbone-mediated interactions observed between the synthetase and the acceptor stem of the tRNA in the crystal and the mutability of the acceptor stem suggest that many of the corresponding wild-type bases are replaceable by alternative sequences, so long as they preserve the initial backbone structure of the tRNA. Backbone interactions emerge as an important functional component of the tRNA-synthetase interaction.

Nucleo-mitochondrial interactions in Saccharomyces cerevisiae: characterization of a nuclear gene suppressing a defect in mitochondrial tRNA(Asp) processing

We utilized the heat-sensitive mutant strain (Ts932), bearing a mutation at position 61 in the mitochondrial tRNA(Asp) gene, to identify nuclear genes involved in tRNA biogenesis; this mutant is defective in 3'-end processing and consequently in the production of mature mitochondrial tRNA(Asp). We transformed this strain with a yeast nuclear library and we isolated among other suppressors, an unknown, non-essential gene (called SMM1, corresponding to open reading frame YNR015w), which restored the growth on glycerol and a normal amount of processed tRNA(Asp) in the mutant. The gene contains a domain highly conserved in evolution from bacteria to human and its product has been recently shown to have dihydrouridine synthase activity.

The affinity of magnesium binding sites in the Bacillus subtilis RNase P x pre-tRNA complex is enhanced by the protein subunit

The RNA subunit of bacterial ribonuclease P (RNase P) requires high concentrations of magnesium ions for efficient catalysis of tRNA 5'-maturation in vitro. The protein component of RNase P, required for cleavage of precursor tRNA in vivo, enhances pre-tRNA binding by directly contacting the 5'-leader sequence. Using a combination of transient kinetics and equilibrium binding measurements, we now demonstrate that the protein component of RNase P also facilitates catalysis by specifically increasing the affinities of magnesium ions bound to the RNase P x pre-tRNA(Asp) complex. The protein component does not alter the number or apparent affinity of magnesium ions that are either diffusely associated with the RNase P RNA polyanion or required for binding mature tRNA(Asp). Nor does the protein component alter the pH dependence of pre-tRNA(Asp) cleavage catalyzed by RNase P, providing further evidence that the protein component does not directly stabilize the catalytic transition state. However, the protein subunit does increase the affinities of at least four magnesium sites that stabilize pre-tRNA binding and, possibly, catalysis. Furthermore, this stabilizing effect is coupled to the P protein/5'-leader contact in the RNase P holoenzyme x pre-tRNA complex. These results suggest that the protein component enhances the magnesium affinity of the RNase P x pre-tRNA complex indirectly by binding and positioning pre-tRNA. Furthermore, RNase P is inhibited by cobalt hexammine (K(I) = 0.11 +/- 0.01 mM) while magnesium, manganese, cobalt, and zinc compete with cobalt hexammine to activate RNase P. These data are consistent with the hypothesis that catalysis by RNase P requires at least one metal-water ligand or one inner-sphere metal contact.

Binding of tobramycin leads to conformational changes in yeast tRNA(Asp) and inhibition of aminoacylation

Aminoglycosides inhibit translation in bacteria by binding to the A site in the ribosome. Here, it is shown that, in yeast, aminoglycosides can also interfere with other processes of translation in vitro. Steady-state aminoacylation kinetics of unmodified yeast tRNA(Asp) transcript indicate that the complex between tRNA(Asp) and tobramycin is a competitive inhibitor of the aspartylation reaction with an inhibition constant (K(I)) of 36 nM. Addition of an excess of heterologous tRNAs did not reverse the charging of tRNA(Asp), indicating a specific inhibition of the aspartylation reaction. Although magnesium ions compete with the inhibitory effect, the formation of the aspartate adenylate in the ATP-PP(i) exchange reaction by aspartyl-tRNA synthetase in the absence of the tRNA is not inhibited. Ultraviolet absorbance melting experiments indicate that tobramycin interacts with and destabilizes the native L-shaped tertiary structure of tRNA(Asp). Fluorescence anisotropy using fluorescein-labelled tobramycin reveals a stoichiometry of one molecule bound to tRNA(Asp) with a K(D) of 267 nM. The results indicate that aminoglycosides are biologically effective when their binding induces a shift in a conformational equilibrium of the RNA.

Construction of an Escherichia coli knockout strain for functional analysis of tRNA(Asp)

The specific aminoacylation of tRNA is critical for translation of the genetic code. A molecular description of aminoacylation requires knowledge of the relevant three-dimensional structures, biochemical parameters and the structure-function relationship of the synthetase and its substrate tRNA. Extensive structural and biochemical data are available on the aspartic acid system of Escherichia coli, but there is a paucity of cellular functional data. We have developed a system to overcome this deficiency by engineering an E. coli knockout tRNA(Asp) strain, thereby allowing a penetrating analysis of tRNA(Asp) structure and function under conditions that prevail in the cell.

Plasmid systems to study RNA function in Escherichia coli

Determining the functional activity of an essential RNA in vivo presents special challenges. We have devised an in vivo analysis of alternative forms of an essential tRNA gene in Escherichia coli knockout cells using either a plasmid switch or a regulated two-plasmid system. The model system is presented together with a description of the new plasmids and procedures necessary to effect these analyses. The system is readily adaptable to non-essential RNAs.

Transfer RNA(Ala) recognizes transfer-messenger RNA with specificity; a functional complex prior to entering the ribosome?

tmRNA (SsrA or 10Sa RNA) functions as both a transfer RNA and a messenger RNA, rescues stalled ribosomes and clears the cell of incomplete polypeptides. We report that native Escherichia coli tmRNA interacts specifically with native or synthetic E.coli tRNA alanine (tRNA(Ala)) in vitro, alanine being the first codon of the tmRNA internal open reading frame. Aminoacylatable RNA microhelices also bind tmRNA. Complex formation was monitored by gel retardation assays combined with structural probes. Nucleotides from the acceptor stem of tRNA(Ala) are essential for complex formation with tmRNA. tRNA(Ala) isoacceptors recognize tmRNA with different affinities, with an important contribution from tRNA(Ala) post-transcriptional modifications. The most abundant tRNA(Ala) isoacceptor in vivo binds tmRNA with the highest affinity. A complex between tRNA(Ala) and tmRNA might involve up to 140 tmRNA molecules out of 500 present per E.coli cell. Our data suggest that tmRNA interacts with the tRNA that decodes the resume codon prior to entering the ribosome. Biological implications of promoting specific complexes between tmRNA and aminoacylatable RNAs are discussed, with emphasis on primitive versions of the translation apparatus.

Human anti-asparaginyl-tRNA synthetase autoantibodies (anti-KS) increase the affinity of the enzyme for its tRNA substrate

Autoantibodies directed against specific human aminoacyl-tRNA synthetases have been associated with a clinical picture including myositis, arthritis, interstitial lung disease and other features that has been referred to as the "anti-synthetase syndrome". Anti-asparaginyl-tRNA synthetase autoantibodies (anti-KS), the most recently described anti-synthetase autoantibodies, are directed against human cytosolic asparaginyl-tRNA synthetase and neutralize specifically its activity. Here we show that these antibodies recognize two epitopes on the human enzyme, an N-terminal epitope reactive in immunoblot experiments and a heat-labile epitope in the catalytic domain. In contrast to the well studied anti-Jo-1 autoantibodies anti-KS when bound to the synthetase increase the affinity of the synthetase for its tRNA substrate and prevent aminoacylation without interfering with the amino acid activation step.

Simultaneous binding of two proteins to opposite sides of a single transfer RNA

Transfer RNA (tRNA) is a small nucleic acid (typically 76 nucleotides) that forms binary complexes with proteins, such as aminoacyl tRNA synthetases (RS) and Trbp111. The latter is a widely distributed structure-specific tRNA-binding protein that is incorporated into cell signaling molecules. The structure of Trbp111 was modeled onto to the outer, convex side of the L-shaped tRNA. Here we present RNA footprints that are consistent with this model. This binding mode is in contrast to that of tRNA synthetases, which bind to the inside, or concave side, of tRNA. These opposite locations of binding for these two proteins suggest the possibility of a ternary complex. The formation of a tRNA synthetase--tRNA--Trbp111 ternary complex was detected by two independent methods. The results indicate that the tRNA is sandwiched between the two protein molecules. A thermodynamic and functional analysis is consistent with the tRNA retaining its native structure in the ternary complex. These results may have implications for how the translation apparatus is linked to other cellular machinery.

Covariation of a specificity-determining structural motif in an aminoacyl-tRNA synthetase and a tRNA identity element

Transfer RNA (tRNA) identity determinants help preserve the specificity of aminoacylation in vivo, and prevent cross-species interactions. Here, we investigate covariation between the discriminator base (N73) element in histidine tRNAs and residues in the histidyl-tRNA synthetase (HisRS) motif 2 loop. A model of the Escherichia coli HisRS--tRNA(His) complex predicts an interaction between the prokaryotic conserved glutamine 118 of the motif 2 loop and cytosine 73. The substitution of Gln 118 in motif 2 with glutamate decreased discrimination between cytosine and uracil some 50-fold, but left overall rates of adenylation and aminoacylation unaffected. By contrast, substitutions at neighboring Glu 115 and Arg 121 affected both adenylation and aminoacylation, consistent with their predicted involvement in both half-reactions. Additional evidence for the involvement of the motif 2 loop was provided by functional analysis of a hybrid Saccharomyces cerevisiae-- E. coli HisRS possessing the 11 amino acid motif 2 loop of the yeast enzyme. Despite an overall decreased activity of nearly 1000-fold relative to the E. coli enzyme, the chimera nevertheless exhibited a modest preference for the yeast tRNA(His) over the E. coli tRNA, and preferred wild-type yeast tRNA(His) to a variant with C at the discriminator position. These experiments suggest that part of, but not all of, the specificity is provided by the motif 2 loop. The close interaction between enzyme loop and RNA sequence elements suggested by these experiments reflects a covariation between enzyme and tRNA that may have acted to preserve aminoacylation fidelity over evolutionary time.

Metabolism of D-aminoacyl-tRNAs in Escherichia coli and Saccharomyces cerevisiae cells

In Escherichia coli, tyrosyl-tRNA synthetase is known to esterify tRNA(Tyr) with tyrosine. Resulting d-Tyr-tRNA(Tyr) can be hydrolyzed by a d-Tyr-tRNA(Tyr) deacylase. By monitoring E. coli growth in liquid medium, we systematically searched for other d-amino acids, the toxicity of which might be exacerbated by the inactivation of the gene encoding d-Tyr-tRNA(Tyr) deacylase. In addition to the already documented case of d-tyrosine, positive responses were obtained with d-tryptophan, d-aspartate, d-serine, and d-glutamine. In agreement with this observation, production of d-Asp-tRNA(Asp) and d-Trp-tRNA(Trp) by aspartyl-tRNA synthetase and tryptophanyl-tRNA synthetase, respectively, was established in vitro. Furthermore, the two d-aminoacylated tRNAs behaved as substrates of purified E. coli d-Tyr-tRNA(Tyr) deacylase. These results indicate that an unexpected high number of d-amino acids can impair the bacterium growth through the accumulation of d-aminoacyl-tRNA molecules and that d-Tyr-tRNA(Tyr) deacylase has a specificity broad enough to recycle any of these molecules. The same strategy of screening was applied using Saccharomyces cerevisiae, the tyrosyl-tRNA synthetase of which also produces d-Tyr-tRNA(Tyr), and which, like E. coli, possesses a d-Tyr-tRNA(Tyr) deacylase activity. In this case, inhibition of growth by the various 19 d-amino acids was followed on solid medium. Two isogenic strains containing or not the deacylase were compared. Toxic effects of d-tyrosine and d-leucine were reinforced upon deprivation of the deacylase. This observation suggests that, in yeast, at least two d-amino acids succeed in being transferred onto tRNAs and that, like in E. coli, the resulting two d-aminoacyl-tRNAs are substrates of a same d-aminoacyl-tRNA deacylase.

Ribonuclease P: a ribonucleoprotein enzyme

The ribonucleoprotein ribonuclease P catalyzes the hydrolysis of a specific phosphodiester bond in precursor tRNA to form the mature 5' end of tRNA. Recent studies have shed light on the structures of RNase-P-RNA-P-protein and RNase-P-RNA-precursor-tRNA complexes, as well as on the positions of catalytic metal ions, emphasizing the importance of the structure to the catalytic function.

Evaluation of uranyl photocleavage as a probe to monitor ion binding and flexibility in RNAs

In order to evaluate uranyl photocleavage as a tool to identify and characterize structural and dynamic properties in RNA, we compared uranyl cleavage sites in five RNA molecules with known X-ray structures, namely the hammerhead and hepatitis delta virus ribozymes, the P4-P6 domain of the Tetrahymena group I intron, as well as tRNA(Phe) and tRNA(Asp) from yeast. Uranyl photocleavage was observed at specific positions in all molecules investigated. In order to characterize the sites, photocleavage was performed in the absence and in increasing amounts of MgCl(2). Uranyl photocleavage correlates well with sites of low calculated accessibility, suggesting that uranyl ions bind in tight RNA pockets formed by close approach of phosphate groups. RNA foldings require ion binding, usually magnesium ions. Thus, upon the adoption of the native structure, uranyl ions can no longer bind well except in flexible and open to the solvent regions that can undergo induced-fit without disrupting the native fold. Uranyl photocleavage was compared to N-ethyl-N-nitrosourea and lead-induced cleavages in the context of the three-dimensional X-ray structures. Overall, the regions protected from ENU attack are sites of uranyl cleavage, indicating sites of low accessibility which can form ion binding sites. On the contrary, lead cleavages occur at flexible and accessible sites and correlate with the unspecific cleavages prevalent in dynamic and open regions. Applied in a magnesium-dependent manner, and only in combination with other backbone probing agents such as N-ethyl-N-nitrosourea, lead and Fenton cleavage, uranyl probing has the potential to reveal high-affinity metal ion environments, as well as regions involved in conformational transitions.

The free yeast aspartyl-tRNA synthetase differs from the tRNA(Asp)-complexed enzyme by structural changes in the catalytic site, hinge region, and anticodon-binding domain

Aminoacyl-tRNA synthetases catalyze the specific charging of amino acid residues on tRNAs. Accurate recognition of a tRNA by its synthetase is achieved through sequence and structural signalling. It has been shown that tRNAs undergo large conformational changes upon binding to enzymes, but little is known about the conformational rearrangements in tRNA-bound synthetases. To address this issue the crystal structure of the dimeric class II aspartyl-tRNA synthetase (AspRS) from yeast was solved in its free form and compared to that of the protein associated to the cognate tRNA(Asp). The use of an enzyme truncated in N terminus improved the crystal quality and allowed us to solve and refine the structure of free AspRS at 2.3 A resolution. For the first time, snapshots are available for the different macromolecular states belonging to the same tRNA aminoacylation system, comprising the free forms for tRNA and enzyme, and their complex. Overall, the synthetase is less affected by the association than the tRNA, although significant local changes occur. They concern a rotation of the anticodon binding domain and a movement in the hinge region which connects the anticodon binding and active-site domains in the AspRS subunit. The most dramatic differences are observed in two evolutionary conserved loops. Both are in the neighborhood of the catalytic site and are of importance for ligand binding. The combination of this structural analysis with mutagenesis and enzymology data points to a tRNA binding process that starts by a recognition event between the tRNA anticodon loop and the synthetase anticodon binding module.

An intermediate step in the recognition of tRNA(Asp) by aspartyl-tRNA synthetase

The crystal structures of aspartyl-tRNA synthetase (AspRS) from Thermus thermophilus, a prokaryotic class IIb enzyme, complexed with tRNA(Asp) from either T. thermophilus or Escherichia coli reveal a potential intermediate of the recognition process. The tRNA is positioned on the enzyme such that it cannot be aminoacylated but adopts an overall conformation similar to that observed in active complexes. While the anticodon loop binds to the N-terminal domain of the enzyme in a manner similar to that of the related active complexes, its aminoacyl acceptor arm remains at the entrance of the active site, stabilized in its intermediate conformational state by non-specific interactions with the insertion and catalytic domains. The thermophilic nature of the enzyme, which manifests itself in a very low kinetic efficiency at 17 degrees C, the temperature at which the crystals were grown, is in agreement with the relative stability of this non-productive conformational state. Based on these data, a pathway for tRNA binding and recognition is proposed.

Thermus thermophilus contains an eubacterial and an archaebacterial aspartyl-tRNA synthetase

Thermus thermophilus possesses two aspartyl-tRNA synthetases (AspRSs), AspRS1 and AspRS2, encoded by distinct genes. Alignment of the protein sequences with AspRSs of other origins reveals that AspRS1 possesses the structural features of eubacterial AspRSs, whereas AspRS2 is structurally related to the archaebacterial AspRSs. The structural dissimilarity between the two thermophilic AspRSs is correlated with functional divergences. AspRS1 aspartylates tRNA(Asp) whereas AspRS2 aspartylates tRNA(Asp), and tRNA(Asn) with similar efficiencies. Since Asp bound on tRNA(Asn) is converted into Asn by a tRNA-dependent aspartate amidotransferase, AspRS2 is involved in Asn-tRNA(Asn) formation. These properties relate functionally AspRS2 to archaebacterial AspRSs. The structural basis of the dual specificity of T. thermophilus tRNA(Asn) was investigated by comparing its sequence with those of tRNA(Asp) and tRNA(Asn) of strict specificity. It is shown that the thermophilic tRNA(Asn) contains the elements defining asparagine identity in Escherichia coli, part of which being also the major elements of aspartate identity, whereas minor elements of this identity are missing. The structural context that permits expression of aspartate and asparagine identities by tRNA(Asn) and how AspRS2 accommodates tRNA(Asp) and tRNA(Asn) will be discussed. This work establishes a distinct structure-function relationship of eubacterial and archaebacterial AspRSs. The structural and functional properties of the two thermophilic AspRSs will be discussed in the context of the modern and primitive pathways of tRNA aspartylation and asparaginylation and related to the phylogenetic connexion of T. thermophilus to eubacteria and archaebacteria.

Decreased aminoacylation of mutant tRNAs in MELAS but not in MERRF patients

Mutations in human mitochondrial tRNA genes are associated with a number of multisystemic disorders. Using an assay that combines tRNA oxidation and circularization we have determined the relative amounts and states of aminoacylation of mutant and wild-type tRNAs in tissue samples from patients with MELAS syndrome (mito- chondrial myopathy, encephalopathy, lactic acidosis, stroke-like episodes) and MERRF syndrome (myoclonus epilepsy with ragged red fibers), respectively. In most, but not all, biopsies from MELAS patients carrying the A3243G substitution in the mitochondrial tRNA(Leu(UUR))gene, the mutant tRNA is under-represented among processed and/or aminoacylated tRNAs. In contrast, in biopsies from MERRF patients harboring the A8344G substitution in the tRNA(Lys)gene neither the relative abundance nor the aminoacylation of the mutated tRNA is affected. Thus, whereas the A3243G mutation may contribute to the pathogenesis of MELAS by reducing the amount of aminoacylated tRNA(Leu), the A8344G mutation does not affect tRNA(Lys)function in the same way.

Specific inactivation of Escherichia coli tRNA(Phe) by antisense DNA-treatment under Mg2+-deficient conditions

The preparation of an Escherichia coli tRNA mixture lacking several specific species may be useful for applications ranging from cell-free protein preparation to protein engineering. We have already demonstrated that tRNA(Asp) can be inactivated, or 'knocked out', with practical specificity by an antisense strategy. In the present study, we synthesized five tRNA(Phe)-targeted antisense oligonucleotides and tested if this tRNA can also be inactivated specifically. The salt conditions used previously for the tRNA(Asp) inactivation were not applicable to tRNA(Phe). Instead, Mg2+-deficient conditions were found to be useful for the inactivation of tRNAPhe by the antisense oligonucleotides. These conditions were also applicable to the inactivation of tRNA(Asp). The susceptibility to the antisense DNAs can change drastically, depending on the concentration of Mg2+.

Synthesis of aspartyl-tRNA(Asp) in Escherichia coli--a snapshot of the second step

The 2.4 A crystal structure of the Escherichia coli aspartyl-tRNA synthetase (AspRS)-tRNA(Asp)-aspartyl-adenylate complex shows the two substrates poised for the transfer of the aspartic acid moiety from the adenylate to the 3'-hydroxyl of the terminal adenosine of the tRNA. A general molecular mechanism is proposed for the second step of the aspartylation reaction that accounts for the observed conformational changes, notably in the active site pocket. The stabilization of the transition state is mediated essentially by two amino acids: the class II invariant arginine of motif 2 and the eubacterial-specific Gln231, which in eukaryotes and archaea is replaced by a structurally non-homologous serine. Two archetypal RNA-protein modes of interactions are observed: the anticodon stem-loop, including the wobble base Q, binds to the N-terminal beta-barrel domain through direct protein-RNA interactions, while the binding of the acceptor stem involves both direct and water-mediated hydrogen bonds in an original recognition scheme.

Mimics of yeast tRNAAsp and their recognition by aspartyl-tRNA synthetase

Assuming that the L-shaped three-dimensional structure of tRNA is an architectural framework allowing the proper presentation of identity nucleotides to aminoacyl-tRNA synthetases implies that altered and/or simplified RNA architectures can fulfill this role and be functional substrates of these enzymes, provided they contain correctly located identity elements. In this work, this paradigm was submitted to new experimental verification. Yeast aspartyl-tRNA synthetase was the model synthetase, and the extent to which the canonical structural framework of cognate tRNAAsp can be altered without losing its ability to be aminoacylated was investigated. Three novel architectures recognized by the synthetase were found. The first resembles that of metazoan mitochondrial tRNASer lacking the D-arm. The second lacks both the D- and T-arms, and the 5'-strand of the amino acid acceptor arm. The third structure is a construct in which the acceptor and anticodon helices are joined by two connectors. Aspartylation specificity of these RNAs is verified by the loss of aminoacylation activity upon mutation of the putative identity residues. Kinetic data indicate that the first two architectures are mimics of the whole tRNAAsp molecule, while the third one behaves as an aspartate minihelix mimic. Results confirm the primordial role of the discriminator nucleotide G73 in aspartylation and demonstrate that neither a helical structure in the acceptor domain nor the presence of a D- or T-arm is mandatory for specific aspartylation, but that activity relies on the presence of the cognate aspartate GUC sequence in the anticodon loop.

Yeast aspartyl-tRNA synthetase residues interacting with tRNA(Asp) identity bases connectively contribute to tRNA(Asp) binding in the ground and transition-state complex and discriminate against non-cognate tRNAs

Crystallographic studies of the aspartyl-tRNA synthetase-tRNA(Asp)complex from yeast identified on the enzyme a number of residues potentially able to interact with tRNA(Asp). Alanine replacement of these residues (thought to disrupt the interactions) was used in the present study to evaluate their importance in tRNA(Asp)recognition and acylation. The results showed that contacts with the acceptor A of tRNA(Asp)by amino acid residues interacting through their side-chain occur only in the acylation transition state, whereas those located near the G73 discriminator base occur also during initial binding of tRNA(Asp). Interactions with the anticodon bases provide the largest free energy contribution to stability of the enzyme-tRNA complex in its ground state. These contacts also favour catalysis, by acting connectively with each other and with those of G73, as shown by multiple mutant analysis. This implies structural communication transmitting the anticodon recognition signal to the distally located acylation site. This signal might be conveyed via tRNA(Asp)as suggested by the observed conformational change of this molecule upon interaction with AspRS. From binding free energy values corresponding to the different AspRS-tRNA(Asp)interaction domains, it might be concluded that upon complex formation, the anticodon interacts first. Finally, acylation efficiencies of AspRS mutants in the presence of pure tRNA(Asp)and non-fractionated tRNAs indicate that residues involved in the binding of identity bases also discriminate against non-cognate tRNAs.

Pseudouridine synthetase Pus1 of Saccharomyces cerevisiae: kinetic characterisation, tRNA structural requirement and real-time analysis of its complex with tRNA

Pseudouridine synthetase Pus1 from Saccharomyces cerevisiae is a multisite-specific enzyme that catalyses the formation of pseudouridine residues at different positions in several tRNA transcripts. Recombinant Pus1, tagged with six histidine residues at its N terminus was expressed in Escherichia coli and purified. Transcripts of yeast tRNAValand intronless yeast tRNAIlewere used as substrates to measure pseudouridine formation at position 27. The catalytic parameters Kmand kcatfor tRNAValand tRNAIlewere 420(+/-100) nM and 0.4(+/-0.1) min-1, 740(+/-100) nM and 0.5(+/-0.1) min-1, respectively. Pus1 possesses a general affinity for tRNA, irrespective of whether they are substrates. Its equilibrium dissociation constant ranges from 15 nM for the substrate yeast tRNAValand non-substrate yeast intronless tRNAPhe, to 150 nM for the substrate yeast intronless tRNAIle. The difference in the affinity for the different tRNA species is not reflected in the specific activity of the enzyme, indicating that the binding of Pus1 to tRNA is not the kinetically limiting step. The importance of tertiary base-pairs was investigated with several variants of yeast tRNAs. Although dispensable for activity, both the presence of a D-stem-loop and the presence of a G26.A44 base-pair, near the target uridine U27, are important elements for Pus1 tRNA high affinity recognition. The presence of a G26.A44 base-pair in tRNA increases its association constant rate with Pus1 (ka) by a factor of approximately 100, resulting in a decrease of the overall equilibrium dissociation constant (Kd). The dissociation rate (kd) is the same, independent of the presence of a G26.A44 base-pair in the tRNA. A model describing the interaction of Pus1 with tRNA is proposed.

Active site mapping of yeast aspartyl-tRNA synthetase by in vivo selection of enzyme mutations lethal for cell growth

The active site of yeast aspartyl-tRNA synthetase has been characterised by structural and functional approaches. However, residues or structural elements that indirectly contribute to the active site organisation have still to be described. They have not been assessed by simple analysis of structural data or site-directed mutagenesis analysis, since rational targetting has proven difficult. Here, we attempt to locate these functional features by using a genetic selection method to screen a randomly mutated yeast AspRS library for mutations lethal for cell growth. This approach is an efficient method to map the active site residues, since of the 23 different mutations isolated, 13 are in direct contact with the substrates. Most of the mutations are located in a 15 A radius sphere around the ATP molecule, where they affect the very conserved residues of the class-defining motifs. The results also showed the importance of the dimer interface for the enzyme activity: a single mutation of the invariant proline residue of motif 1 led to a structural defect inactivating the enzyme. From in vivo complementation studies it appeared that the enzyme activity can be recovered by reconstitution of an intact interface through the formation of heterodimers. We also show that a single mutation affecting an interaction with G34 of the tRNA can inactivate the enzyme by inducing a relaxation of the tRNA recognition specificity. Finally, several mutants whose functional importance could not be assessed from the structural data were selected, demonstrating the importance of this type of approach in the context of a structure-function relationship study.

A cytotoxic ribonuclease targeting specific transfer RNA anticodons

The carboxyl-terminal domain of colicin E5 was shown to inhibit protein synthesis of Escherichia coli. Its target, as revealed through in vivo and in vitro experiments, was not ribosomes as in the case of E3, but the transfer RNAs (tRNAs) for Tyr, His, Asn, and Asp, which contain a modified base, queuine, at the wobble position of each anticodon. The E5 carboxyl-terminal domain hydrolyzed these tRNAs just on the 3' side of this nucleotide. Tight correlation was observed between the toxicity of E5 and the cleavage of intracellular tRNAs of this group, implying that these tRNAs are the primary targets of colicin E5.

Transfer RNA modification enzymes from Pyrococcus furiosus: detection of the enzymatic activities in vitro

The modification patterns of in vitro transcripts of two yeast Saccharomyces cerevisiae tRNAs (tRNAPheand tRNAAsp) and one archaeal Haloferax volcanii tRNA (tRNAIle) were investigated in the cell-free extract of Pyrococcus furiosus supplemented with S -adenosyl-l-methionine (AdoMet). The results indicate that the enzymatic formation of 11 distinct modified nucleotides corresponding to 12 enzymatic activities can be detected in vitro. They correspond to the formation of pseudouridines (Psi) at positions 39 and 55, 2' -O- ribose methylations at positions 6 (Am) and 56 (Cm), base methylations at positions 10 (m2G), 26 (m22G), 37 (m1G), 49 (m5C), 54 (m5U) and 58 (m1A) and both the deamination and methylation of adenosine into m1I at position 57. Most of the detected modified nucleotides are common modifications found in other phylogenetic groups, while Am6, Cm56and m1I57are specific modifications found exclusively in Archaea. It is also shown that the enzymatic formation of m5C49, m5U54, Psi55and m1I57does not depend on the three-dimensional architecture of the tRNA substrate, since these modi-fications also occur in fragmented tRNAs as substrate.