Enzymatic Aminoacylation of tRNAArg Using Recombinant Arg-tRNA Synthetase

This chapter describes the preparation of pre-charged Arg-tRNA that can be used in arginylation reaction. While in a typical arginylation reaction arginyl-tRNA synthetase (RARS) is normally included as a component of the reaction and continually charges tRNA during arginylation, it is sometimes necessary to separate the charging and the arginylation step, in order to perform each reaction under controlled conditions, e.g., for measuring the kinetics or determining the effect of different compounds and chemicals on the reaction. In such cases, tRNA^Arg can be pre-charged with Arg and purified away from the RARS enzyme prior to arginylation.

Synthesis of Stably Charged Arg-tRNAArg for Structural Analysis

Posttranslational protein arginylation catalyzed by arginyl transferases is a mechanism to regulate multiple physiological processes. This protein arginylation reaction uses a charged Arg-tRNAArg as the donor of arginine (Arg). The inherent instability of the ester linkage of the arginyl group to the tRNA, which is sensitive to hydrolysis at the physiological pH, makes it difficult to obtain structural information on how the arginyl transfer reaction is catalyzed. Here, we describe a methodology to synthesize stably charged Arg-tRNAArg that would facilitate structural analysis. In the stably charged Arg-tRNAArg, the ester linkage is replaced with an amide linkage, which is resistant to hydrolysis even at alkaline pH.

tRNA deamination by ADAT requires substrate-specific recognition mechanisms and can be inhibited by tRFs

Adenosine deaminase acting on transfer RNA (ADAT) is an essential eukaryotic enzyme that catalyzes the deamination of adenosine to inosine at the first position of tRNA anticodons. Mammalian ADATs modify eight different tRNAs, having increased their substrate range from a bacterial ancestor that likely deaminated exclusively tRNA^Arg Here we investigate the recognition mechanisms of tRNA^Arg and tRNA^Ala by human ADAT to shed light on the process of substrate expansion that took place during the evolution of the enzyme. We show that tRNA recognition by human ADAT does not depend on conserved identity elements, but on the overall structural features of tRNA. We find that ancestral-like interactions are conserved for tRNA^Arg, while eukaryote-specific substrates use alternative mechanisms. These recognition studies show that human ADAT can be inhibited by tRNA fragments in vitro, including naturally occurring fragments involved in important regulatory pathways.

The absence of A-to-I editing in the anticodon of plant cytoplasmic tRNA (Arg) ACG demands a relaxation of the wobble decoding rules

It is a prevalent concept that, in line with the Wobble Hypothesis, those tRNAs having an adenosine in the first position of the anticodon become modified to an inosine at this position. Sequencing the cDNA derived from the gene coding for cytoplasmic tRNA (Arg) ACG from several higher plants as well as mass spectrometric analysis of the isoacceptor has revealed that for this kingdom an unmodified A in the wobble position of the anticodon is the rule rather than the exception. In vitro translation shows that in the plant system the absence of inosine in the wobble position of tRNA (Arg) does not prevent decoding. This isoacceptor belongs to the class of tRNA that is imported from the cytoplasm into the mitochondria of higher plants. Previous studies on the mitochondrial tRNA pool have demonstrated the existence of tRNA (Arg) ICG in this organelle. In moss the mitochondrial encoded distinct tRNA (Arg) ACG isoacceptor possesses the I34 modification. The implication is that for mitochondrial protein biosynthesis A-to-I editing is necessary and occurs by a mitochondrion-specific deaminase after import of the unmodified nuclear encoded tRNA (Arg) ACG.

Arabidopsis tRNA adenosine deaminase arginine edits the wobble nucleotide of chloroplast tRNAArg(ACG) and is essential for efficient chloroplast translation

RNA editing changes the coding/decoding information relayed by transcripts via nucleotide insertion, deletion, or conversion. Editing of tRNA anticodons by deamination of adenine to inosine is used both by eukaryotes and prokaryotes to expand the decoding capacity of individual tRNAs. This limits the number of tRNA species required for codon-anticodon recognition. We have identified the Arabidopsis thaliana gene that codes for tRNA adenosine deaminase arginine (TADA), a chloroplast tRNA editing protein specifically required for deamination of chloroplast (cp)-tRNAArg(ACG) to cp-tRNAArg(ICG). Land plant TADAs have a C-terminal domain similar in sequence and predicted structure to prokaryotic tRNA deaminases and also have very long N-terminal extensions of unknown origin and function. Biochemical and mutant complementation studies showed that the C-terminal domain is sufficient for cognate tRNA deamination both in vitro and in planta. Disruption of TADA has profound effects on chloroplast translation efficiency, leading to reduced yields of chloroplast-encoded proteins and impaired photosynthetic function. By contrast, chloroplast transcripts accumulate to levels significantly above those of wild-type plants. Nevertheless, absence of cp-tRNAArg(ICG) is compatible with plant survival, implying that two out of three CGN codon recognition occurs in chloroplasts, though this mechanism is less efficient than wobble pairing.

Mitochondrial myopathy associated with a novel mutation in mtDNA

A 6-year-old boy had progressive muscle weakness since age 4 and emotional problems diagnosed as Asperger syndrome. His mother and two older siblings are in good health and there is no family history of neuromuscular disorders. Muscle biopsy showed ragged-red and cytochrome coxidase (COX)-negative fibers. Respiratory chain activities were reduced for all enzymes containing mtDNA-encoded subunits, especially COX. Sequence analysis of the 22 tRNA genes revealed a novel G10406A base substitution, which was heteroplasmic in multiple tissues of the patient by RFLP analysis (muscle, 96%; urinary sediment, 94%; cheek mucosa, 36%; blood, 29%). The mutation was not detected in any accessible tissues from his mother or siblings. It appears that this mutation arose de novo in the proband, probably early in embryogenesis.

Crystallization and preliminary X-ray diffraction analysis of E. coli arginyl-tRNA synthetase in complex form with a tRNAArg

Amino acids are building blocks of proteins, while aminoacyl-tRNA synthetases (aaRSs) catalyze the first reaction in such building: the biosynthesis of proteins. The E. coli arginyl-tRNA synthetase (ArgRS) has been crystallized in complex form with tRNA(Arg) (B. stearothermophilus), at pH 5.6 using ammonium sulfate as a precipitating agent. Two crystal forms have been identified based on unit cell dimension. The complete data sets from both crystal forms have been collected with a primitive hexagonal space group. A data set of Form II crystals at 3.2 A and 94% completeness has been obtained, with unit cell parameters a = b = 98.0 A, c = 463.2 A, and alpha = beta = 90 degrees , gamma = 120 degrees , being different from a = b = 110.8 A, c = 377.8 A for form I. The structure determination will demonstrate the interaction of these two macromolecules to understand the special mechanism of ArgRS that requires the presence of tRNA for amino acid activation. Such complex structure also provides a wide opening for inhibitor search using bioinformatics.

Molecular dissection of arginyltransferases guided by similarity to bacterial peptidoglycan synthases

Post-translational protein arginylation is essential for cardiovascular development and angiogenesis in mice and is mediated by arginyl-transfer RNA-protein transferases Ate1-a functionally conserved but poorly understood class of enzymes. Here, we used sequence analysis to detect the evolutionary relationship between the Ate1 family and bacterial FemABX family of aminoacyl-tRNA-peptide transferases, and to predict the functionally important residues in arginyltransferases, which were then used to construct a panel of mutants for further molecular dissection of mouse Ate1. Point mutations of the residues in the predicted regions of functional importance resulted in changes in enzymatic activity, including complete inactivation of mouse Ate1; other mutations altered its substrate specificity. Our results provide the first insights into the mechanisms of Ate1-mediated arginyl transfer reaction and substrate recognition, and define a new protein superfamily called Dupli-GNAT to reflect its origin by the duplication of the GNAT acetyltransferase domain.

The La protein functions redundantly with tRNA modification enzymes to ensure tRNA structural stability

Although the La protein stabilizes nascent pre-tRNAs from nucleases, influences the pathway of pre-tRNA maturation, and assists correct folding of certain pre-tRNAs, it is dispensable for growth in both budding and fission yeast. Here we show that the Saccharomyces cerevisiae La shares functional redundancy with both tRNA modification enzymes and other proteins that contact tRNAs during their biogenesis. La is important for growth in the presence of mutations in either the arginyl tRNA synthetase or the tRNA modification enzyme Trm1p. In addition, two pseudouridine synthases, PUS3 and PUS4, are important for growth in strains carrying a mutation in tRNA(Arg)(CCG) and are essential when La is deleted in these strains. Depletion of Pus3p results in accumulation of the aminoacylated mutant tRNA(Arg)(CCG) in nuclei, while depletion of Pus4p results in decreased stability of the mutant tRNA. Interestingly, the degradation of mutant unstable forms of tRNA(Arg)(CCG) does not require the Trf4p poly(A) polymerase, suggesting that yeast cells possess multiple pathways for tRNA decay. These data demonstrate that La functions redundantly with both tRNA modifications and proteins that associate with tRNAs to achieve tRNA structural stability and efficient biogenesis.

Structure of a purine-purine wobble base pair in the decoding center of the ribosome

Here we report the crystal structures of I.C and I.A wobble base pairs in the context of the ribosomal decoding center, clearly showing that the I.A base pair is of an I(anti).A(anti) conformation, as predicted by Crick. Additionally, the structures enable the observation of changes in the anticodon to allow purine-purine base pairing, the 'widest' base pair geometry allowed in the wobble position.

A yeast arginine specific tRNA is a remnant aspartate acceptor

High specificity in aminoacylation of transfer RNAs (tRNAs) with the help of their cognate aminoacyl-tRNA synthetases (aaRSs) is a guarantee for accurate genetic translation. Structural and mechanistic peculiarities between the different tRNA/aaRS couples, suggest that aminoacylation systems are unrelated. However, occurrence of tRNA mischarging by non-cognate aaRSs reflects the relationship between such systems. In Saccharomyces cerevisiae, functional links between arginylation and aspartylation systems have been reported. In particular, it was found that an in vitro transcribed tRNAAsp is a very efficient substrate for ArgRS. In this study, the relationship of arginine and aspartate systems is further explored, based on the discovery of a fourth isoacceptor in the yeast genome, tRNA4Arg. This tRNA has a sequence strikingly similar to that of tRNAAsp but distinct from those of the other three arginine isoacceptors. After transplantation of the full set of aspartate identity elements into the four arginine isoacceptors, tRNA4Arg gains the highest aspartylation efficiency. Moreover, it is possible to convert tRNA4Arg into an aspartate acceptor, as efficient as tRNAAsp, by only two point mutations, C38 and G73, despite the absence of the major anticodon aspartate identity elements. Thus, cryptic aspartate identity elements are embedded within tRNA4Arg. The latent aspartate acceptor capacity in a contemporary tRNAArg leads to the proposal of an evolutionary link between tRNA4Arg and tRNAAsp genes.

Limited set of amino acid residues in a class Ia aminoacyl-tRNA synthetase is crucial for tRNA binding

The aim of this work was to characterize crucial amino acids for the aminoacylation of tRNA(Arg) by yeast arginyl-tRNA synthetase. Alanine mutagenesis was used to probe all the side chain mediated interactions that occur between tRNA(Arg2)(ICG) and ArgRS. The effects of the substitutions were analyzed in vivo in an ArgRS-knockout strain and in vitro by measuring the aminoacylation efficiencies for two distinct tRNA(Arg) isoacceptors. Nine mutants that generate lethal phenotypes were identified, suggesting that only a limited set of side chain mediated interactions is essential for tRNA recognition. The majority of the lethal mutants was mapped to the anticodon binding domain of ArgRS, a helix bundle that is characteristic for class Ia synthetases. The alanine mutations induce drastic decreases in the tRNA charging rates, which is correlated with a loss in affinity in the catalytic site for ATP. One of those lethal mutations corresponds to an Arg residue that is strictly conserved in all class Ia synthetases. In the known crystallographic structures of complexes of tRNAs and class Ia synthetases, this invariant Arg residue stabilizes the idiosyncratic conformation of the anticodon loop. This paper also highlights the crucial role of the tRNA and enzyme plasticity upon binding. Divalent ions are also shown to contribute to the induced fit process as they may stabilize the local tRNA-enzyme interface. Furthermore, one lethal phenotype can be reverted in the presence of high Mg(2+) concentrations. In contrast with the bacterial system, in yeast arginyl-tRNA synthetase, no lethal mutation has been found in the ArgRS specific domain recognizing the Dhu-loop of the tRNA(Arg). Mutations in this domain have no effects on tRNA(Arg) aminoacylation, thus confirming that Saccharomyces cerevisiae and other fungi belong to a distinct class of ArgRS.

The tRNA-Interacting Factor p43 Associates with Mammalian Arginyl-tRNA Synthetase but Does Not Modify Its tRNA Aminoacylation Properties

Arginyl-tRNA synthetase (ArgRS) is one of the nine synthetase components of a multienzyme complex containing three auxiliary proteins as well. We previously established that the N-terminal moiety of the auxiliary protein p43 associates with the N-terminal, eukaryotic-specific polypeptide extension of ArgRS. Because p43 is homologous to Arc1p, a yeast general RNA-binding protein that associates with MetRS and GluRS and plays the role of tRNA-binding cofactor in the aminoacylation reaction, we analyzed the functional significance of p43-ArgRS association. We had previously showed that full-length ArgRS, corresponding to the ArgRS species associated within the multisynthetase complex, and ArgRS with a deletion of 73 N-terminal amino acid residues, corresponding to a free species of ArgRS, both produced in yeast, have similar catalytic parameters (Lazard, M., Kerjan, P., Agou, F., and Mirande, M. (2000) J. Mol. Biol. 302, 991-1004). However, a recent study had suggested that association of p43 to ArgRS reduces the apparent K(M) of ArgRS to tRNA (Park, S. G., Jung, K. H., Lee, J. S., Jo, Y. J., Motegi, H., Kim, S., and Shiba, K. (1999) J. Biol. Chem. 274, 16673-16676). In this study, we analyzed in detail, by gel retardation assays and enzyme kinetics, the putative role of p43 as a tRNA-binding cofactor of ArgRS. The association of p43 with ArgRS neither strengthened tRNA-binding nor changed kinetic parameters in the amino acid activation or in the tRNA aminoacylation reaction. Furthermore, selective removal of the C-terminal RNA-binding domain of p43 from the multisynthetase complex did not affect kinetic parameters for ArgRS. Therefore, p43 has a dual function. It promotes association of ArgRS to the complex via its N-terminal domain, but its C-terminal RNA-binding domain may act as a tRNA-interacting factor for an as yet unidentified component of the complex.

Novel methyltransferase for modified uridine residues at the wobble position of tRNA

We have identified a novel tRNA methyltransferase in Saccharomyces cerevisiae that we designate Trm9. This enzyme, the product of the YML014w gene, catalyzes the esterification of modified uridine nucleotides, resulting in the formation of 5-methylcarbonylmethyluridine in tRNA(Arg3) and 5-methylcarbonylmethyl-2-thiouridine in tRNA(Glu). In intact yeast cells, disruption of the TRM9 gene results in the complete loss of these modified wobble bases and increased sensitivity at 37 degrees C to paromomycin, a translational inhibitor. These results suggest a role for this potentially reversible methyl esterification reaction when cells are under stress.

A yeast knockout strain to discriminate between active and inactive tRNA molecules

Here we report the construction of a yeast genetic screen designed to identify essential residues in tRNA(Arg). The system consists of a tRNA(Arg) knockout strain and a set of vectors designed to rescue and select for variants of tRNA(Arg). By plasmid shuffling we selected inactive tRNA mutants that were further analyzed by northern blotting. The mutational analysis focused on the tRNA D and anticodon loops that contact the aminoacyl-tRNA synthetase. The anticodon triplet was excluded from the analysis because of its role in decoding the Arg codons. Most of the inactivating mutations are residues involved in tertiary interactions. These mutations had dramatic effects on tRNA(Arg) abundance. Other inactivating mutations were located in the anticodon loop, where they did not affect transcription and aminoacylation but probably altered interaction with the translation machinery. No lethal effects were observed when residues 16, 20 and 38 were individually mutated, despite the fact that they are involved in sequence-specific interactions with the aminoacyl-tRNA synthetase. However, the steady-state levels of the aminoacylated forms of U20A and U20G were decreased by a factor of 3.5-fold in vivo. This suggests that, unlike in the Escherichia coli tRNA(Arg):ArgRS system where residue 20 (A) is a major identity element, in yeast this position is of limited consequence.

A candidate prostate cancer susceptibility gene encodes tRNA 3' processing endoribonuclease

tRNA 3' processing endoribonuclease (3' tRNase) is an enzyme responsible for the removal of a 3' trailer from precursor tRNA (pre-tRNA). We purified approximately 85 kDa 3' tRNase from pig liver and determined its partial sequences. BLAST search of them suggested that the enzyme was the product of a candidate human prostate cancer susceptibility gene, ELAC2, the biological function of which was totally unknown. We cloned a human ELAC2 cDNA and expressed the ELAC2 protein in Escherichia coli. The recombinant ELAC2 was able to cleave human pre-tRNA(Arg) efficiently. The 3' tRNase activity of the yeast ortholog YKR079C was also observed. The C-terminal half of human ELAC2 was able to remove a 3' trailer from pre-tRNA(Arg), while the N-terminal half failed to do so. In the human genome exists a gene, ELAC1, which seems to correspond to the C-terminal half of 3' tRNase from ELAC2. We showed that human ELAC1 also has 3'-tRNase activity. Furthermore, we examined eight ELAC2 variants that seem to be associated with the occurrence of prostate cancer for 3'-tRNase activity. Seven ELAC2 variants which contain one to three amino acid substitutions showed efficient 3'-tRNase activities, while one truncated variant, which lacked a C-terminal half region, had no activity.

Structural and mutational studies of the recognition of the arginine tRNA-specific major identity element, A20, by arginyl-tRNA synthetase

Arginyl-tRNA synthetase (ArgRS) recognizes two major identity elements of tRNA(Arg): A20, located at the outside corner of the L-shaped tRNA, and C35, the second letter of the anticodon. Only a few exceptional organisms, such as the yeast Saccharomyces cerevisiae, lack A20 in tRNA(Arg). In the present study, we solved the crystal structure of a typical A20-recognizing ArgRS from Thermus thermophilus at 2.3 A resolution. The structure of the T. thermophilus ArgRS was found to be similar to that of the previously reported S. cerevisiae ArgRS, except for short insertions and a concomitant conformational change in the N-terminal domain. The structure of the yeast ArgRS.tRNA(Arg) complex suggested that two residues in the unique N-terminal domain, Tyr(77) and Asn(79), which are phylogenetically invariant in the ArgRSs from all organisms with A20 in tRNA(Arg)s, are involved in A20 recognition. However, in a docking model constructed based on the yeast ArgRS.tRNA(Arg) and T. thermophilus ArgRS structures, Tyr(77) and Asn(79) are not close enough to make direct contact with A20, because of the conformational change in the N-terminal domain. Nevertheless, the replacement of Tyr(77) or Asn(79) by Ala severely reduced the arginylation efficiency. Therefore, some conformational change around A20 is necessary for the recognition. Surprisingly, the N79D mutant equally recognized A20 and G20, with only a slight reduction in the arginylation efficiency as compared with the wild-type enzyme. Other mutants of Asn(79) also exhibited broader specificity for the nucleotide at position 20 of tRNA(Arg). We propose a model of A20 recognition by the ArgRS that is consistent with the present results of the mutational analyses.

The inhibitory effect of the autoantigen La on in vitro 3' processing of mammalian precursor tRNAs

Mammalian tRNA 3' processing endoribonuclease (3' tRNase) can remove a 3' trailer from various precursor (pre)-tRNAs. We investigated what effect the autoantigen La has on 3' processing, since the La protein is known to bind to a 3'-terminal uridine tract of pre-tRNAs. We tested sixteen different pre-tRNA(Arg) substrates containing various 3' trailers with or without a 5' leader sequence for in vitro processing by pig 3' tRNase, and for gel-retardation in the presence or absence of human La protein. The R-TUUU series consists of four pre-tRNAs containing 6, 8, 11 and 15 nt 3' trailers ending with UUU and no 5' leader, while the R-TAGC series consists of the same four pre-tRNAs as R-TUUU except that the terminal sequence is AGC. The R-6LTUUU and R-6LTAGC series are derived from R-TUUU and R-TAGC, respectively, by adding a 6 nt 5' leader. La differentially inhibited their processing and bound to the pre-tRNAs; the 50 % inhibitory concentrations for the R-TUUU, R-TAGC, R-6LTUUU, and R-6LTAGC series were 82 to >850, >850, 2 to 292 and 573 to 785 nM, respectively, and the dissociation constants were 10 to 840, >850, 3 to 203 and 155 to 520 nM, respectively. These results indicate that both the terminal sequence UUU and the 5' leader contribute to more severe inhibition of 3' processing via tighter interaction with La. With respect to the R-TUUU and R-6LTUUU series, on the whole, the La inhibition was enhanced as the 3' trailer lengths decreased. Taken together, our results suggest that the La protein sterically hinders 3' tRNase from binding a pre-tRNA molecule probably near the cleavage site.

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.

Cotranscription of 5S rRNA-tRNA(Arg)(ACG) from Brassica napus chloroplasts and processing of their intergenic spacer

S1 mapping showed that at least a significant portion of the 5S rRNA and tRNA(Arg)(ACG) is co-transcribed in canola chloroplast, making trnR the last gene transcribed in an operon of which the final sequence is 5'-16S-tRNA(Ile)-tRNA(Ala)-23S-4.5S-5S-tRNA(Arg)-3'. Various RNA termini representing RNA processing sites at several parts of the 5S rRNA-tRNA(Arg) area were detected. This gene spacer is substantially conserved among various species compared here, and a secondary structure model for this chloroplast region in canola applies to other plant sequences. The conservation of this intergenic sequence suggests a functional role, possibly by providing recognition structures for endogenous RNases involved in its maturing process.

A cytotoxic ribonuclease which specifically cleaves four isoaccepting arginine tRNAs at their anticodon loops

Colicin D has long been thought to stop protein synthesis in infected Escherichia coli cells by inactivating ribosomes, just like colicin E3. Here, we show that colicin D specifically cleaves tRNAs(Arg) including four isoaccepting molecules both in vivo and in vitro. The cleavage occurs in vitro between positions 38 and 39 in an anticodon loop with a 2',3'-cyclic phosphate end, and is inhibited by a specific immunity protein. Consistent with the cleavage of tRNAs(Arg), the RNA fraction of colicin-treated cells significantly reduced the amino acid-accepting activity only for arginine. Furthermore, we generated a single mutation of histidine in the C-terminal possible catalytic domain, which caused the loss of the killing activity in vivo together with the tRNA(Arg)-cleaving activity both in vivo and in vitro. These findings show that colicin D directly cleaves cytoplasmic tRNAs(Arg), which leads to impairment of protein synthesis and cell death. Recently, we found that colicin E5 stops protein synthesis by cleaving the anticodons of specific tRNAs for Tyr, His, Asn, and Asp. Despite these apparently similar actions on tRNAs and cells, colicins D and E5 not only exhibit no sequence homology but also have different molecular mechanisms as to both substrate recognition and catalytic reaction.

Crystallization and preliminary X-ray crystallographic analysis of yeast arginyl-tRNA synthetase-yeast tRNAArg complexes

Three different crystal forms of complexes between arginyl-tRNA synthetase from the yeast Saccharomyces cerevisae (yArgRS) and the yeast second major tRNA(Arg) (tRNA(Arg)(ICG)) isoacceptor have been crystallized by the hanging-drop vapour-diffusion method in the presence of ammonium sulfate. Crystal form II, which diffracts beyond 2.2 A resolution at the European Synchrotron Radiation Facility ID14-4 beamline, belongs to the orthorhombic space group P2(1)2(1)2, with unit-cell parameters a = 129.64, b = 107.47, c = 71. 38 A. This crystal form presents the highest resolution obtained for an active form of an aminoacyl-tRNA synthetase-tRNA complex. The estimated V(m) of 2.6 A(3) Da(-1) indicates one molecule of complex in the asymmetric unit. The three crystal forms were solved by the molecular-replacement method using the coordinates of the free yArgRS.

Selection of cleavage site by mammalian tRNA 3' processing endoribonuclease

Mammalian tRNA 3' processing endoribonuclease (3' tRNase) removes 3' trailers from pre-tRNAs by cleaving the RNA immediately downstream of the discriminator nucleotide. Although 3' tRNase can recognize and cleave any target RNA that forms a pre-tRNA-like complex with another RNA, in some cases cleavage occurs at multiple sites near the discriminator. We investigated what features of pre-tRNA determine the cleavage site using various pre-tRNAArg variants and purified pig enzyme. Because the T stem-loop and the acceptor stem plus a 3' trailer are sufficient for recognition by 3' tRNase, we constructed variants that had additions and/or deletions of base-pairs in the T stem and/or the acceptor stem. Pre-tRNAs lacking one and two acceptor stem base-pairs were cleaved one and two nucleotides and two and three nucleotides, respectively, downstream of the discriminator. On the other hand, pre-tRNA variants containing extra acceptor stem base-pairs were cleaved only after the discriminator. The cleavage site was shifted to one and two nucleotides downstream of the discriminator by deleting one base-pair from the T stem, but was not changed by additional base-pairs in the T stem. Pre-tRNA variants that contained an eight base-pair acceptor stem plus a six base-pair T stem, an eight base-pair acceptor stem plus a four base-pair T stem, or a six base-pair acceptor stem plus a six base-pair T stem were all cleaved after the original nucleotide. In general, pre-tRNA variants containing a total of more than 11 bp in the acceptor stem and the T stem were cleaved only after the discriminator, and pre-tRNA variants with a total of N bp (N is less than 12) were cleaved 12-N and 13-N nt downstream of the discriminator. Cleavage efficiency of the variants decreased depending on the degree of structural changes from the authentic pre-tRNA. This suggests that the numbers of base-pairs of both the acceptor stem and the T stem are important for recognition and cleavage by 3' tRNase.

Complementation of the growth defect of an rnpA49 mutant of Escherichia coli by overexpression of arginine tRNA(CCG)

We previously found that overexpression of arginine tRNA(CCG) from Brevibacterium albidum complements the rnpA49 mutation, which is responsible for the thermosensitivity of Escherichia coli RNase P function. In this present work, we show that the E. coli homologue tRNA also complements the same mutation, but other tRNAs do not. These results suggest that the rnpA49 mutation causes a major cellular defect in an RNase P reaction to generate the mature arginine tRNA(CCG).

Cloning of the gene for inorganic pyrophosphatase from a thermoacidophilic archaeon, Sulfolobus sp. strain 7, and overproduction of the enzyme by coexpression of tRNA for arginine rare codon

The gene encoding an extremely stable inorganic pyrophosphatase from Sulfolobus sp. strain 7, a thermoacidophilic archaeon, was cloned and sequenced. An open reading frame consisted of 516 base pairs coding for a protein of 172-amino acid residues. The deduced sequence was supported by partial amino acid sequence analyses. All the catalytically important residues were conserved. A unique 17-base-pair sequence motif was found to be repeated four times in frame in the gene, encoding a cluster of acidic amino acids essential for the function. Although the codon usage of the gene was quite different from that of Escherichia coli, the gene was effectively expressed in E. coli. Coexpression of tRNA(Arg), cognate for the rare codon AGA in E. coli, however, further improved the production of the enzyme, which occupied more than 85% of the soluble proteins obtained after removal of heat denatured E. coli proteins.

L-arginine recognition by yeast arginyl-tRNA synthetase

The crystal structure of arginyl-tRNA synthetase (ArgRS) from Saccharomyces cerevisiae, a class I aminoacyl-tRNA synthetase (aaRS), with L-arginine bound to the active site has been solved at 2.75 A resolution and refined to a crystallographic R-factor of 19.7%. ArgRS is composed predominantly of alpha-helices and can be divided into five domains, including the class I-specific active site. The N-terminal domain shows striking similarity to some completely unrelated proteins and defines a module which should participate in specific tRNA recognition. The C-terminal domain, which is the putative anticodon-binding module, displays an all-alpha-helix fold highly similar to that of Escherichia coli methionyl-tRNA synthetase. While ArgRS requires tRNAArg for the first step of the aminoacylation reaction, the results show that its presence is not a prerequisite for L-arginine binding. All H-bond-forming capability of L-arginine is used by the protein for the specific recognition. The guanidinium group forms two salt bridge interactions with two acidic residues, and one H-bond with a tyrosine residue; these three residues are strictly conserved in all ArgRS sequences. This tyrosine is also conserved in other class I aaRS active sites but plays several functional roles. The ArgRS structure allows the definition of a new framework for sequence alignments and subclass definition in class I aaRSs.

Wheat cytoplasmic arginine tRNA isoacceptor with a U*CG anticodon is an efficient UGA suppressor in vitro

Many RNA viruses express part of their genomic information by read-through over internal termination codons. We have recently characterized tobacco cytoplasmic (cyt) and chloroplast (chl) tRNACmCATrp and tRNAGCACys as natural suppressor tRNAs that are able to read the leaky UGA codon in RNA-1 of tobacco rattle virus, albeit with different efficiencies. Here we have identified a third natural UGA suppressor in plants. We have purified and sequenced four cyt tRNAArg isoacceptors with ICG, CCG, U*CG and CCU anticodons from wheat germ. With the exception of tRNAICGArg, these are the first sequences of plant tRNAsArg. In order to study the potential suppressor activity of wheat tRNAsArg we have used in vitro synthesized mRNA transcripts in which different viral read-through regions had been placed. In vitro translation was carried out in a homologous wheat germ extract. We found that tRNAU*CGArg is an efficient UGA suppressor in vitro, whereas the other three tRNAArg isoacceptors exhibit no or very low suppressor activity. Interaction of tRNAU*CGArg with the UGA codon requires a G:U base pair at the third anticodon position. This is the first time that an arginine-accepting tRNA has been characterized as a natural UGA suppressor. A remarkable feature of cyt tRNAU*CGArg is its ability to misread the UGA at the end of the coat protein cistron in RNA-1 of pea enation mosaic virus, which is not accomplished by cyt tRNACmCATrp or cyt tRNAGCACys, due to an unfavourable codon context.

Evolution of a transfer RNA gene through a point mutation in the anticodon

The transfer RNA (tRNA) multigene family comprises 20 amino acid-accepting groups, many of which contain isoacceptors. The addition of isoacceptors to the tRNA repertoire was critical to establishing the genetic code, yet the origin of isoacceptors remains largely unexplored. A model of tRNA evolution, termed "tRNA gene recruitment," was formulated. It proposes that a tRNA gene can be recruited from one isoaccepting group to another by a point mutation that concurrently changes tRNA amino acid identity and messenger RNA coupling capacity. A test of the model showed that an Escherichia coli strain, in which the essential tRNAUGUThr gene was inactivated, was rendered viable when a tRNAArg with a point mutation that changed its anticodon from UCU to UGU (threonine) was expressed. Insertion of threonine at threonine codons by the "recruited" tRNAArg was corroborated by in vitro aminoacylation assays showing that its specificity had been changed from arginine to threonine. Therefore, the recruitment model may account for the evolution of some tRNA genes.

Mirror image alternative interaction patterns of the same tRNA with either class I arginyl-tRNA synthetase or class II aspartyl-tRNA synthetase

Gene cloning, overproduction and an efficient purification protocol of yeast arginyl-tRNA synthetase (ArgRS) as well as the interaction patterns of this protein with cognate tRNAArgand non-cognate tRNAAspare described. This work was motivated by the fact that the in vitro transcript of tRNAAspis of dual aminoacylation specificity and is not only aspartylated but also efficiently arginylated. The crystal structure of the complex between class II aspartyl-tRNA synthetase (AspRS) and tRNAAsp, as well as early biochemical data, have shown that tRNAAspis recognized by its variable region side. Here we show by footprinting with enzymatic and chemical probes that transcribed tRNAAspis contacted by class I ArgRS along the opposite D arm side, as is homologous tRNAArg, but with idiosyncratic interaction patterns. Besides protection, footprints also show enhanced accessibility of the tRNAs to the structural probes, indicative of conformational changes in the complexed tRNAs. These different patterns are interpreted in relation to the alternative arginine identity sets found in the anticodon loops of tRNAArgand tRNAAsp. The mirror image alternative interaction patterns of unmodified tRNAAspwith either class I ArgRS or class II AspRS, accounting for the dual identity of this tRNA, are discussed in relation to the class defining features of the synthetases. This study indicates that complex formation between unmodified tRNAAspand either ArgRS and AspRS is solely governed by the proteins.

Three modified nucleosides present in the anticodon stem and loop influence the in vivo aa-tRNA selection in a tRNA-dependent manner

In Salmonella typhimurium seven tRNA species specific for leucine, proline and arginine have 1-methylguanosine (m1G) next to and 3' of the anticodon (position 37 of tRNA), five tRNA species specific for phenylalanine, serine, tyrosine, cysteine and tryptophan have 2-methylthio-N-6-(cis-hydroxy)isopentenyladenosine (ms2io6A) in the same position of the tRNA, and four tRNA species, specific for leucine and proline, have pseudouridine (Psi) as the last 3' nucleotide in the anticodon loop (position 38) or in the anticodon stem (positions 39 and 40). Mutants deficient in the synthesis of these modified nucleosides have been used to study their role in the first step of translation elongation, i.e. the aa-tRNA selection step in which the ternary complex (EF-Tu-GTP-aa-tRNA) binds at the cognate codon in the A-site on the mRNA programmed ribosome. We have found that the Psi present in the anticodon loop (position 38) stimulates the selection of tRNA specific for leucine whereas Psi in the anticodon stem did not affect the selection of tRNA specific for proline. The m1G37 strongly stimulates the rate of selection of the three tRNA species specific for proline and one tRNA species specific for arginine but has only minor or no effect on the selection of the three tRNA species specific for leucine. Likewise, the ms2io6A, present in the same position as m1G37 but in another subset of tRNA species, stimulates the selection of tRNA specific for tyrosine, stimulates to some extent also tRNA species specific for cysteine and tryptophan, but has no influence on the rate of selection of tRNA specific for phenylalanine. We conclude that function of m1G and ms2io6A present next to and 3' of the anticodon influences the in vivo aa-tRNA selection in a tRNA-dependent manner.

Distribution of both lengths and 5' terminal nucleotides of mammalian pre-tRNA 3' trailers reflects properties of 3' processing endoribonuclease

Mammalian tRNA 3'processing endoribonuclease (3'tRNase) removes 3'extra nucleotides after the discriminator from tRNA precursors. Here I examined how the length of a 3'trailer and the nucleotides on each side of the cleavage site affected 3'processing efficiency. I performed in vitro 3'processing reactions of pre-tRNAArgs with various 3'trailers or various discriminator nucleotides using 3'tRNase purified from mouse FM3A cells or pig liver. On the whole, the efficiency of pre- tRNAArg3'processing by mammalian 3'tRNase decreased as the 3'trailer became longer, except in the case of a 3'trailer composed of CC, CCA or CCA plus 1 or 2 nucleotides, which was not able to be removed at all. The distribution of 3'trailer lengths deduced from mammalian nuclear tRNA genomic sequences reflects this property of 3'tRNase. The cleavage efficiency of pre-tRNAArgs varied depending on the 5'end nucleotide of a 3'trailer in the order G approximately A > U > C. This effect of the 5'end nucleotide was independent of the discriminator nucleotides. The distribution of the 5'end nucleotides of mammalian pre-tRNA 3'trailers reflects this differential 3'processing efficiency.

Primary sequence of mitochondrial tRNA(Arg) of a nematode Ascaris suum: occurrence of unmodified adenosine at the first position of the anticodon

Mitochondrial tRNA(Arg) from a nematode, Ascaris suum, was purified and sequenced at the RNA level. An unmodified adenosine was found to exist at the anticodon first position, suggesting that, contrary to the conventional wobble rule, the anticodon ACG of the tRNA can translate all the CGN codons.

Arginine aminoacylation identity is context-dependent and ensured by alternate recognition sets in the anticodon loop of accepting tRNA transcripts

Yeast arginyl-tRNA synthetase recognizes the non-modified wild-type transcripts derived from both yeast tRNA(Arg) and tRNA(Asp) with equal efficiency. It discriminates its cognate natural substrate, tRNA(Arg), from non-cognate tRNA(Asp) by a negative discrimination mechanism whereby a single methyl group acts as an anti-determinant. Considering these facts, recognition elements responsible for specific arginylation in yeast have been searched by studying the in vitro arginylation properties of a series of transcripts derived from yeast tRNA(Asp), considered as an arginine isoacceptor tRNA. In parallel, experiments on similar tRNA(Arg) transcripts were performed. Unexpectedly, in the tRNA(Arg) context, arginylation is basically linked to the presence of residue C35, whereas in the tRNA(Asp) context, it is deeply related to that of C36 and G37 but is insensitive to the nucleotide at position 35. Each of these nucleotides present in one host, is absent in the other host tRNA. Thus, arginine identity is dependent on two different specific recognition sets according to the tRNA framework investigated.

A cluster of transfer RNA genes (TRM1, TRR3, and TRAN) on the short arm of human chromosome 6

We have isolated two lambda clones that contain three transfer RNA (tRNA) genes (TRM1, TRR3, and TRAN). Both clones map to the same region (6p21.2-p22.3) of the short arm of chromosome 6. One clone contains a methionine tRNA gene and also an arginine tRNA gene, the first such human gene to be described. The other clone contains an alanine tRNA gene, again the first such human gene to be reported, and it differs from the species of human alanine tRNA transcripts sequenced to date. These clones have been used to investigate the structure of this tRNA gene cluster. The results of both conventional and pulsed-field gel analysis suggest that the alanine tRNA gene is a member of a low-copy repeat series at this location. The other clone is not located within this domain and appears to be a unique segment of DNA. Nevertheless, we also show that at least half of the methionine tRNA genes are located on the short arm of this chromosome, and if these are also located at 6p21.2-p22.3, this would constitute another major tRNA locus in human.

NMR studies of the effects of the 5'-phosphate group on conformational properties of 5-methylaminomethyluridine found in the first position of the anticodon of Escherichia coli tRNA(Arg)4

5-Methylaminomethyluridine (mnm5U) exists in the first position of the anticodon (position 34) of Escherichia coli tRNA4Arg for codons AGA/AGG. In the present study, the temperature dependence of the ribose-puckering equilibrium of pmnm5U was analyzed by proton NMR spectroscopy. Thus, the enthalpy difference (delta H) between the C2'-endo and C3'-endo forms was obtained at 0.65 kcal.mol-1. By comparison of the delta H values of pU and pmnm5U, the 5-substitution was found to increase the relative stability of the C3'-endo form over the C2'-endo form significantly (by 0.56 kcal.mol-1). Furthermore, this conformational "rigidity" was concluded to depend on the 5'-phosphate group, because nucleoside U exhibits only a negligible change in the ribose-puckering equilibrium upon the 5-methylaminomethyl substitution. Further NMR analyses and molecular dynamics calculations revealed that interactions between the 5-methylaminomethyl and 5'-phosphate groups of pmnm5U restrict the conformation about the glycosidic bond to a low anti form, enhancing steric repulsion between the 2-carbonyl and 2'-hydroxyl groups in the C2'-endo form. This intrinsic conformational rigidity of the mnm5U residue in position 34 may contribute to the correct codon recognition.

Localization and expression of the closely linked cyanelle genes for RNase P RNA and two transfer RNAs

The genomic region encoding the RNA subunit of the cyanelle RNase P has been characterized. rnpB, which has no homologue in chloroplasts, is flanked by two tRNA genes on the complementary DNA strand. Transcriptional control elements of all three genes have been experimentally determined. Comparison of the sequenced region with the corresponding loci of chloroplast genomes from vascular plants suggests that major inversions may have led to a possible loss or severe truncation of the RNase P RNA coding region during the course of plastid evolution.

Conversion of mammalian tRNA 3' processing endoribonuclease to four-base-recognizing RNA cutters

The spermidine-dependent, sequence-specific endoribonuclease (RNase 65) activities in mammalian cell extracts require both protein and 3' truncated tRNA, species of which direct their substrate sequence specificity. Computer analysis for searching possible base pairing between substrate RNAs and their corresponding 3' truncated tRNA, suggested a unified model for substrate recognition mechanism, in which a four-nucleotide (nt) sequence in the target tRNAs 1 nt upstream of their cleavage site, base pairs with the 5' terminal 4 nt sequence of their corresponding 3' truncated tRNA. This model was supported by experiments with several RNA substrates containing a substituted nucleotide in the target 4 nt sequence. In this model, the tRNA substrates and their corresponding 3' truncated tRNA form a complex resembling a 5' processed tRNA precursor containing a 3' trailer, suggesting that the protein component of RNase 65 is identical to tRNA 3' processing endoribonuclease (3' tRNase). Actually, 3' tRNase purified from pig liver cleaved the target RNAs at the expected sites only in the presence of their corresponding 3' truncated tRNA. These results show that the 3' tRNase can be converted to 4 nt specific RNA cutters using the 3' truncated tRNAs.

The decoding region of 16S RNA; a cross-linking study of the ribosomal A, P and E sites using tRNA derivatized at position 32 in the anticodon loop

A photo-reactive diazirine derivative was attached to the 2-thiocytidine residue at position 32 of tRNA(Arg)I from Escherichia coli. This modified tRNA was bound under suitable conditions to the A, P or E site of E.coli ribosomes. After photo-activation of the diazirine label, the sites of cross-linking to 16S rRNA were identified by our standard procedures. Each of the three tRNA binding sites showed a characteristic pattern of cross-linking. From tRNA at the A site, a major cross-link was observed to position 1378 of the 16S RNA, and a minor one to position 936. From the P site, there were major cross-links to positions 693 and to 957 and/or 966, as well as a minor cross-link to position 1338. The E site bound tRNA showed major cross-links to position 693 (identical to that from the P site) and to positions 1376/1378 (similar, but not identical, to the cross-link observed from the A site). Immunological analysis of the concomitantly cross-linked ribosomal proteins indicated that S7 was the major target of cross-linking from all three tRNA sites, with S11 as a minor product. The results are discussed in terms of the overall topography of the decoding region of the 30S ribosomal subunit.

[Nucleotide sequence and organization of tRNA-Gly (UCC), tRNA-Arg (UCU), and alpha-subunits of CF1ATPase in chloroplast DNA of Allium porrum]

The nucleotide sequence of 1029 bp BamHI-fragment of leek chloroplast DNA (Allium porrum, fam. Liliaceae) has been determined. The fragment contains the 3'-terminal part of the tRNA-Gly (UCC) gene, the tRNA-Arg (UCU) gene and the 3'-terminal domain of the CF1ATPase alpha-subunit gene. The gene arrangement and the nucleotide sequence of this fragment are similar to those of the tobacco chloroplast DNA but differ significantly from that of other monocots in which the region containing these genes underwent extensive recombination.

A functional mutant of tRNA(2Arg) with ten extra nucleotides in its TFC arm

An unusual, spontaneously arising mutant of Escherichia coli tRNA(2Arg) has been deduced to have two extra nucleotides in its anticodon loop and a duplication of ten nucleotide residues in the TFC loop. This conclusion is based on its gene sequence, Northern blot analysis of isolated tRNA and the size of the in vitro-processed tRNA product. In vitro analyses showed that the mutant precursor is processed normally, albeit inefficiently, to a mature tRNA species 12 nucleotides longer than the wild-type. In addition, the mature tRNA functions as a frameshift suppressor in vivo. Several related mutants with more conservative changes within the gene sequence were similarly shown to be accurately processed, albeit with varying degrees of efficiency less than that of the wild-type. These results indicate that in spite of the high degree of evolutionary conservation of the tertiary structure of tRNAs, and the fact that no such naturally-occurring variant has been found, a greatly enlarged tRNA is capable of functioning in protein synthesis. The data also indicate that recognition sites for correct processing of precursor tRNAs may be unexpectedly tolerant of unusual context, and may depend on some specific features of the tertiary structure rather than the overall structure for accurate processing.

A modified uridine in the first position of the anticodon of a minor species of arginine tRNA, the argU gene product, from Escherichia coli

The argU (dnaY) gene product, a minor tRNA(Arg), from Escherichia coli has the anticodon N*CU with an unidentified modified nucleoside N* in position 34 [Kiesewetter, S., Fisher, W. & Sprinzl, M. (1987) Nucleic Acids Res. 15, 3184]. In the present study, argU tRNA was purified from E. coli A19 strain and nucleoside N* was characterized by the TLC and HPLC analyses. Nucleoside N* was found to be different from any naturally occurring modified nucleosides. From unfractionated E. coli tRNA species, nucleoside N* was prepared in an amount sufficient for 1H-NMR experiments. By the analyses of one-dimensional and two-dimensional NMR spectra, nucleoside N* was suggested to be 5-methylaminomethyluridine (mnm5U), which was confirmed by comparison with a chemically synthesized preparation of mnm5U. Thus, the occurrence of mnm5U in mature tRNA was found for the first time. Further, the modification of U(34) to mnm5U in this tRNA was found to contribute to the strict recognition of two degenerate codons terminating in A and G.

Clustering of modified nucleotides at the functional center of bacterial ribosomal RNA

An aryl trifluoromethyl diazirine photoreactive derivative was attached to the 2-thiocytidine residue at position 32 of tRNA(IArg) and this derivatized tRNA was bound to Escherichia coli 70S ribosomes. After irradiation at 350 nm the site of cross-linking to the 16S RNA was analyzed by our standard procedures and found to lie within the secondary structural element comprising bases 956-983; this region contains two modified nucleotides at positions 966 and 967. Similarly, an aryl azido photoreactive derivative was attached to the phenylalanine residue of Phe-tRNA(Phe), and the derivatized aminoacyl tRNA was bound to the ribosome either at the A- or the P-site. In both cases, after irradiation at 250 nm, the cross-link site was localized to position 2439 of the 23S RNA; in the secondary structure of the latter the neighboring nucleotide 2442 is base-paired to a modified nucleotide at position 2069. Taken together with other cross-linking data, these results now directly implicate a total of 27 out of the 29 modified nucleotides in E. coli 16S and 23S RNA as lying within or close to the functional center of the ribosome.

Self-splicing introns in tRNA genes of widely divergent bacteria

The organization of eukaryotic genes into exons separated by introns has been considered as a primordial arrangement but because it does not exist in eubacterial genomes it may be that introns are relatively recent acquisitions. A self-splicing group I intron has been found in cyanobacteria at the same position of the same gene (that encoding leucyl transfer RNA, UAA anticodon) as a similar group I intron of chloroplasts, which indicates that this intron predates the invasion of eukaryotic cells by cyanobacterial endosymbionts. But it is not clear from this isolated example whether introns are more generally present in different genes or in more diverse branches of the eubacteria. Many mitochondria have intron-rich genomes and were probably derived from the alpha subgroup of the purple bacteria (or Proteobacteria), so ancient introns might also have been retained in these bacteria. We describe here the discovery of two small (237 and 205 nucleotides) self-splicing group I introns in members of two proteobacterial subgroups, Agrobacterium tumefaciens (alpha) and Azoarcus sp. (beta). The introns are inserted in genes for tRNA(Arg) and tRNA(Ile), respectively, after the third anticodon nucleotide. Their occurrence in different genes of phylogenetically diverse bacteria indicates that group I introns have a widespread distribution among eubacteria.