Oxidation of 4-thiouridine in intact Escherichia coli tRNAs.

Treatment of intact tRNAs from Escherichia coli B with mild oxidizing agents, such as KI-I₂, appears to quantitatively oxidize the 4-thiouridine present in these molecules to the disulfide form as judged by the loss of absorbance near 330 nm. Chromatography of these oxidized tRNAs on Sephadex G-75 did not reveal tRNA dimers or larger aggregates, suggesting intra- rather than intermolecular disulfide-bond formation. Enzymatic hydrolyses of both unlabeled and ³⁵S-labeled oxidized tRNAs followed by chromatography on columns of Sephadex G-25 indicated that 4-thiouridine did form covalent linkages with some component(s) in the tRNA that were reversible upon reduction. It was not clear whether 4-thiouridine formed disulfides only with itself, other sulfurcontaining nucleosides, or some non-sulfur-containing component. Data presented suggest that an earlier report on the isolation of 4-thiouridylate disulfide from oxidized tRNAs of E. coli was an artifact, resulting from oxidation of the thionucleotide during chromatography on Bio-Gel.     

Pathogenic mutations in antisense mitochondrial tRNAs

Pathogenic mutations in mitochondrial tRNAs are 6.5 times more frequent than in other mitochondrial genes. This suggests that tRNA mutations perturb more than one function. A potential additional tRNA gene function is that of templating for antisense tRNAs. Pathogenic mutations weaken cloverleaf secondary structures of sense tRNAs. Analyses here show similar effects for most antisense tRNAs, especially after adjusting for associations between sense and antisense cloverleaf stabilities. These results imply translational activity by antisense tRNAs. For sense tRNAs Ala and Ser UCN, pathogenicity associates as much with sense as with antisense cloverleaf formation. For tRNA Pro, pathogenicity seems associated only with antisense, not sense tRNA cloverleaf formation. Translational activity by antisense tRNAs is expected for the 11 antisense tRNAs processed by regular sense RNA maturation, those recognized by their cognate amino acid’s tRNA synthetase, and those forming relatively stable cloverleaves as compared to their sense counterpart. Most antisense tRNAs probably function routinely in translation and extend the tRNA pool (extension hypothesis); others do not (avoidance hypothesis). The greater the expected translational activity of an antisense tRNA, the more pathogenic mutations weaken its cloverleaf secondary structure. Some evidence for RNA interference, a more classical role for antisense tRNAs, exists only for tRNA Ser UCN. Mutation pathogenicity probably frequently results from a mixture of effects due to sense and antisense tRNA translational activity for many mitochondrial tRNAs. Genomic studies should routinely explore for translational activity by antisense tRNAs.     

Structure-specific tRNA-binding protein from the extreme thermophile Aquifex aeolicus.

The genome of the bacterium Aquifex aeolicus encodes a polypeptide which is related to a small portion of a sequence found in one prokaryotic and two eukaryotic tRNA synthetases. It also is related to a portion of Arc1p, a tRNA-binding protein believed to be important for nuclear trafficking of tRNAs. Here we cloned, expressed and purified the 111 amino acid polypeptide (designated Trbp111) and showed by ultracentrifugation analysis that it is a stable dimer in solution. The protein was also crystallized in a monoclinic lattice. X-ray diffraction analysis at 2.8 A resolution revealed a prominent non-crystallographic 2-fold axis, consistent with the presence of a symmetric homodimeric structure. Band-shift analysis with polyacrylamide gels showed that the dimer binds tRNAs, but not RNA duplexes, RNA hairpins, single-stranded RNA nor 5S rRNA. Complex formation with respect to tRNA is non-specific, with a single tRNA bound per dimer. Thus, Trbp111 is a structure-specific tRNA-binding protein. These results and other considerations raise the possibility that Trbp111 is a tRNA-specific chaperone which stabilizes the native L-shaped fold in the extreme thermophile and which has been incorporated into much larger tRNA-binding proteins of higher organisms.     

Avoidance of antisense, antiterminator tRNA anticodons in vertebrate mitochondria

Protein synthesis (translation) stops at stop codons, codons not complemented by tRNA anticodons. tRNAs matching stops, antitermination (Ter) tRNAs, prevent translational termination, producing dysfunctional proteins. Genomes avoid tRNAs with anticodons whose complement (the anticodon of the ‘antisense’ tRNA) matches stops. This suggests that antisense tRNAs, which also form cloverleaves, are occasionally expressed. Mitochondrial antisense tRNA expression is plausible, because both DNA strands are transcribed as single RNAs, and tRNA structures signal RNA maturation. Results describe potential antisense Ter tRNAs in mammalian mitochondrial genomes detected by tRNAscan-SE, and evidence for adaptations preventing translational antitermination: genomes possessing Ter tRNAs use less corresponding stop codons; antisense Ter tRNAs form weaker cloverleaves than homologuous non-Ter antisense tRNAs; and genomic stop codon usages decrease with stabilities of codon-anticodon interactions and of Ter tRNA cloverleaves. This suggests that antisense tRNAs frequently function in translation. Results suggest that opposite strand coding is exceptional in modern genes, yet might be frequent for mitochondrial tRNAs. This adds antisense tRNA templating to other mitochondrial tRNA functions: sense tRNA templating, formation and regulation of secondary (light strand DNA) replication origins. Antitermination probably affects mitochondrial degenerative diseases and ageing: pathogenic mutations are twice as frequent in tRNAs with antisense Ter anticodons than in other tRNAs, and species lacking mitochondrial antisense Ter tRNAs have longer mean maximal lifespans than those possessing antisense Ter tRNAs.     

Mapping and cloning of Neurospora crassa mitochondrial transfer RNA genes.

We have obtained collections of recombinant Escherichia coli plasmids containing restriction fragments of Neurospora crassa mitochondrial DNA cloned into pBR322. By hybridization of 32P end-labeled total mitochondrial tRNAs and seven different purified tRNAs to restriction digests of mitochondrial DNA and of recombinant plasmids carrying specific restriction fragments, we have located the tRNA genes on the mitochondrial DNA. We have found that the mitochondrial tRNA genes are present in two major clusters, one between the two ribosomal RNA genes and the second closely following the large rRNA gene. Only one of the two DNA strands within these clusters codes for tRNAs. All of the genes for the seven specific purified tRNAs examined--those for alanine, formylmethionine, leucine 1, leucine 2, threonine, tyrosine, and valine--lie within these clusters. Interestingly, the formylmethionine tRNA hybridizes to two loci within one of these gene clusters. We have obtained a fairly detailed restriction map of part of this cluster and have shown that the two "putative" genes for formylmethionine tRNA are not arranged in tandem but are separated by more than 900 base pairs and by at least two other tRNA genes, those for alanine and for leucine 1 tRNAs.     

High-resolution phosphorus nuclear magnetic resonance spectroscopy of transfer ribonucleic acids: multiple conformations in the anticodon loop

The temperature dependence of the 31P NMR spectra of yeast phenylalanine tRNA, E. coli tyrosine, glutamate (2), and formylmethionine tRNA is presented. The major difference between the 31P NMR spectra of the different acceptor tRNAs is in the main cluster region between -0.5 and -1.3 ppm. This confirms an earlier assignment of the main cluster region to the undistorted phosphate diesters in the hairpin loops and helical stems. In addition the 31P NMR spectra for all tRNAs reveal approximately 16 nonhelical diester signals spread over approximately 7 ppm besides the downfield terminal 3'-phosphate monoester. In the presence of 10 mM Mg2+ most scattered and main cluster signals do not shift between 22 and 66 degrees C, thus supporting our earlier hypothesis that 31P chemical shifts are sensitive to phosphate ester torsional and bond angles. At greater than 70 degrees C, all of the signals merge into a single random-coil conformation signal. A number of the scattered peaks are shifted (0.2-1.7 ppm) and broadened between 22 and 66 degrees C in the presence of Mg2+ and spermine as a result of a conformational transition in the anticodon loop. The 31P NMR spectrum of the dimer formed between yeast tRNAPhe and E. coli tRNA 2Glu is reported. This dimer simulates codon-anticodon interaction since the anticodon triplets of the two tRNAs are complementary. Evidence is presented that the anticodon-anticodon interaction alters the anticodon conformation and partially disrupts the tertiary structure of the tRNA.     

tRNA accumulation and suppression of the bldA phenotype during development in Streptomyces coelicolor

Streptomyces coelicolor undergoes distinct morphological changes as it grows on solid media where spores differentiate into vegetative and aerial mycelium that is followed by the production of spores. Deletion of bldA, encoding the rare tRNA(Leu) UAA, blocks development at the stage of vegetative mycelium formation. From previous data it appears that tRNA(Leu) UAA accumulates relatively late during growth while two other tRNAs do not. Here, we studied the expression of 17 different tRNAs including bldA tRNA, and the RNA subunit of the tRNA processing endoribonuclease RNase P. Our results showed that all selected tRNAs and RNase P RNA increased with time during development. However, accumulation of bldA tRNA and another rare tRNA(Leu) isoacceptor started at an earlier stage compared with the other tRNAs. We also introduced the bldA tRNA anticodon (UAA) into other tRNAs and introduced these into a bldA deletion strain. In particular, one such mutant tRNA derived from the tRNA(Leu) CAA isoacceptor suppressed the bldA phenotype. Thus, the bldA tRNA scaffold is not critical for function as a regulator of S. coelicolor cell differentiation. Further substitution experiments, in which the 5'- and 3'-flanking regions of the suppressor tRNA were changed, indicated that these regions were important for the suppression.     

Optimization of the hybridization-based method for purification of thermostable tRNAs in the presence of tetraalkylammonium salts

We found that both tetramethylammonium chloride (TMA-Cl) and tetra-ethylammonium chloride (TEA-Cl), which are used as monovalent cations for northern hybridization, drastically destabilized the tertiary structures of tRNAs and enhanced the formation of tRNA•oligoDNA hybrids. These effects are of great advantage for the hybridization-based method for purification of specific tRNAs from unfractionated tRNA mixtures through the use of an immobilized oligoDNA complementary to the target tRNA. Replacement of NaCl by TMA-Cl or TEA-Cl in the hybridization buffer greatly improved the recovery of a specific tRNA, even from unfractionated tRNAs derived from a thermophile. Since TEA-Cl destabilized tRNAs more strongly than TMA-Cl, it was necessary to lower the hybridization temperature at the sacrifice of the purity of the recovered tRNA when using TEA-Cl. Therefore, we propose two alternative protocols, depending on the desired properties of the tRNA to be purified. When the total recovery of the tRNA is important, hybridization should be carried out in the presence of TEA-Cl. However, if the purity of the recovered tRNA is important, TMA-Cl should be used for the hybridization. In principle, this procedure for tRNA purification should be applicable to any small-size RNA whose gene sequence is already known.     

Insertional Editing of Mitochondrial tRNAs of Physarum polycephalum and Didymium nigripes

tRNAs encoded on the mitochondrial DNA of Physarum polycephalum and Didymium nigripes require insertional editing for their maturation. Editing consists of the specific insertion of a single cytidine or uridine relative to the mitochondrial DNA sequence encoding the tRNA. Editing sites are at 14 different locations in nine tRNAs. Cytidine insertion sites can be located in any of the four stems of the tRNA cloverleaf and usually create a G·C base pair. Uridine insertions have been identified in the T loop of tRNA^Lys from Didymium and tRNA^Glu from Physarum. In both tRNAs, the insertion creates the GUUC sequence, which is converted to GTΨC (Ψ = pseudouridine) in most tRNAs. This type of tRNA editing is different from other, previously described types of tRNA editing and resembles the mRNA and rRNA editing in Physarum and Didymium. Analogous tRNAs in Physarum and Didymium have editing sites at different locations, indicating that editing sites have been lost, gained, or both since the divergence of Physarum and Didymium. Although cDNAs derived from single tRNAs are generally fully edited, cDNAs derived from unprocessed polycistronic tRNA precursors often lack some of the editing site insertions. This enrichment of partially edited sequences in unprocessed tRNAs may indicate that editing is required for tRNA processing or at least that RNA editing occurs as an early event in tRNA synthesis.     

The contacts of yeast tRNA(Ser) with seryl-tRNA synthetase studied by footprinting experiments

Yeast tRNA(Ser) is a member of the class II tRNAs, whose characteristic is the presence of an extended variable loop. This additional structural feature raises questions about the recognition of these class II tRNAs by their cognate synthetase and the possibility of the involvement of the extra arm in the recognition process. A footprinting study of yeast tRNA(Ser) complexed with its cognate synthetase, yeast seryl-tRNA synthetase (an alpha 2 dimer), was undertaken. Chemical (ethylnitrosourea) and enzymatic (nucleases S1 and V1) probes were used in the experiments. A map of the contact points between the tRNA and the synthetase was established and results were analyzed with respect to a three-dimensional model of yeast tRNA(Ser). Regions in close vicinity with the synthetase are clustered on one face of tRNA. The extra arm, which is strongly protected from chemical modifications, appears as an essential part of the contact area. The anticodon triplet and a large part of the anticodon arm are, in contrast, still accessible to the probes when the complex is formed. These results are discussed in the context of the recognition of tRNAs in the aminoacylation reaction.     

Crystal structure of the tRNA 3' processing endoribonuclease tRNase Z from Thermotoga maritima

The maturation of the tRNA 3' end is catalyzed by a tRNA 3' processing endoribonuclease named tRNase Z (RNase Z or 3'-tRNase) in eukaryotes, Archaea, and some bacteria. The tRNase Z generally cuts the 3' extra sequence from the precursor tRNA after the discriminator nucleotide. In contrast, Thermotoga maritima tRNase Z cleaves the precursor tRNA precisely after the CCA sequence. In this study, we determined the crystal structure of T. maritima tRNase Z at 2.6-A resolution. The tRNase Z has a four-layer alphabeta/betaalpha sandwich fold, which is classified as a metallo-beta-lactamase fold, and forms a dimer. The active site is located at one edge of the beta-sandwich and is composed of conserved motifs. Based on the structure, we constructed a docking model with the tRNAs that suggests how tRNase Z may recognize the substrate tRNAs.     

Analysis of the functional modules of the tRNA 3' endonuclease (tRNase Z)

tRNA 3' processing is one of the essential steps during tRNA maturation. The tRNA 3'-processing endonuclease tRNase Z was only recently isolated, and its functional domains have not been identified so far. We performed an extensive mutational study to identify amino acids and regions involved in dimerization, tRNA binding, and catalytic activity. 29 deletion and point variants of the tRNase Z enzyme were generated. According to the results obtained, variants can be sorted into five different classes. The first class still had wild type activity in all three respects. Members of the second and third class still formed dimers and bound tRNAs but had reduced catalytic activity (class two) or no catalytic activity (class three). The fourth class still formed dimers but did not bind the tRNA and did not process precursors. Since this class still formed dimers, it seems that the amino acids mutated in these variants are important for RNA binding. The fifth class did not have any activity anymore. Several conserved amino acids could be mutated without or with little loss of activity.     

MIST,a Novel Approach to Reveal Hidden Substrate Specificity in Aminoacyl-tRNA Synthetases

Aminoacyl-tRNA synthetases (AARSs) constitute a family of RNA-binding proteins, that participate in the translation of the genetic code, by covalently linking amino acids to appropriate tRNAs. Due to their fundamental importance for cell life, AARSs are likely to be one of the most ancient families of enzymes and have therefore been characterized extensively. Paradoxically, little is known about their capacity to discriminate tRNAs mainly because of the practical challenges that represent precise and systematic tRNA identification. This work describes a new technical and conceptual approach named MIST (Microarray Identification of Shifted tRNAs) designed to study the formation of tRNA/AARS complexes independently from the aminoacylation reaction. MIST combines electrophoretic mobility shift assays with microarray analyses. Although MIST is a non-cellular assay, it fully integrates the notion of tRNA competition. In this study we focus on yeast cytoplasmic Arginyl-tRNA synthetase (yArgRS) and investigate in depth its ability to discriminate cellular tRNAs. We report that yArgRS in submicromolar concentrations binds cognate and non-cognate tRNAs with a wide range of apparent affinities. In particular, we demonstrate that yArgRS binds preferentially to type II tRNAs but does not support their misaminoacylation. Our results reveal important new trends in tRNA/AARS complex formation and potential deep physiological implications.     

The chloroplast-derived trnW and trnM-e genes are not expressed in Arabidopsis mitochondria

Depending on their genetic origin, plant mitochondrial tRNAs are classified into three categories: the "native" and "chloroplast-like" mitochondrial-encoded tRNAs and the imported nuclear-encoded tRNAs. The number and identity of tRNAs in each category change from one plant specie to another. As some plant mitochondrial trn genes were found to be not expressed, and as all Arabidopsis thaliana mitochondrial trn genes are known, we systematically tested the expression of A. thaliana mitochondrial trn genes. Both the "chloroplast-like" trnW and trnM-e genes were found to be not expressed. These exceptions are remarkable since trnW and trnM-e are expressed in the mitochondria of other land plants. Whereas we could not conclude which tRNA(Met) compensates the lack of expression of trnM-e, we showed that the cytosolic tRNA(Trp) is present in A. thaliana mitochondria, thus compensating the absence of expression of the mitochondrial-encoded trnW.     

In vitro hyperprocessing of Drosophila tRNAs by the catalytic RNA of RNase P the cloverleaf structure of tRNA is not always stable?

We have previously reported that the catalytic RNA subunit of RNase P of Escherichia coli (M1 RNA) cleaves Drosophila initiator methionine tRNA (tRNA(Met)i) within the mature tRNA sequence to produce specific fragments. This cleavage was dependent on the occurrence of an altered conformation of the tRNA substrate. We call this further cleavage hyperprocessing. In the present paper, to search for another tRNA that can be hyperprocessed in vitro, we used total mature tRNAs from Drosophila as substrates for the in vitro M1 RNA reaction. We found that some tRNAs can be hyperprocessed by M1 RNA and that two such tRNAs are an alanine tRNA and a histidine tRNA. Using mutant substrates of these tRNAs, we also show that the hyperprocessing by M1 RNA is dependent on the occurrence of altered conformations of these tRNAs. The altered conformations were very similar to that of tRNA(Met)i. We show here that M1 RNA can be used as a powerful tool to detect the alternative conformation of tRNAs. The relationship between these hyperprocessing reactions and stability of the tRNA structure will also be discussed.     

Insights into catalysis by a knotted TrmD tRNA methyltransferase

The crystal structure of Escherichia coli tRNA (guanosine-1) methyltransferase (TrmD) complexed with S-adenosyl homocysteine (AdoHcy) has been determined at 2.5A resolution. TrmD, which methylates G37 of tRNAs containing the sequence G36pG37, is a homo-dimer. Each monomer consists of a C-terminal domain connected by a flexible linker to an N-terminal AdoMet-binding domain. The two bound AdoHcy moieties are buried at the bottom of deep clefts. The dimer structure appears integral to the formation of the catalytic center of the enzyme and this arrangement strongly suggests that the anticodon loop of tRNA fits into one of these clefts for methyl transfer to occur. In addition, adjacent hydrophobic sites in the cleft delineate a defined pocket, which may accommodate the GpG sequence during catalysis. The dimer contains two deep trefoil peptide knots and a peptide loop extending from each knot embraces the AdoHcy adenine ring. Mutational analyses demonstrate that the knot is important for AdoMet binding and catalytic activity, and that the C-terminal domain is not only required for tRNA binding but plays a functional role in catalytic activity.     

Identification of nuclear encoded precursor tRNAs within the mitochondrion of Trypanosoma brucei.

RNAs that function in mitochondria are typically encoded by the mitochondrial DNA. However, the mitochondrial tRNAs of Trypanosoma brucei are encoded by the nuclear DNA and therefore must be imported into the mitochondrion. It is becoming evident that RNA import into mitochondria is phylogenetically widespread and is essential for cellular processes, but virtually nothing is known about the mechanism of RNA import. We have identified and characterized mitochondrial precursor tRNAs in T. brucei. The identification of mitochondrially located precursor tRNAs clearly indicates that mitochondrial tRNAs are imported as precursors. The mitochondrial precursor tRNAs hybridize to cloned nuclear tRNA genes, label with [alpha-32P]CTP using yeast tRNA nucleotidyltransferase and in isolated mitochondria via an endogenous nucleotidyltransferase-like activity, and are processed to mature tRNAs by Escherichia coli and yeast mitochondrial RNase P. We show that T. brucei mitochondrial extract contains an RNase P activity capable of processing a prokaryotic tRNA precursor as well as the T. brucei tRNA precursors. Precursors for tRNA(Asn) and tRNA(Leu) were detected on Northern blots of mitochondrial RNA, and the 5' ends of these RNAs were characterized by primer extension analysis. The structure of the precursor tRNAs and the significance of nuclear encoded precursor tRNAs within the mitochondrion are discussed.