Construction of Escherichia coli amber suppressor tRNA genes. III. Determination of tRNA specificity

Using synthetic oligonucleotides, we have constructed a collection of Escherichia coli amber suppressor tRNA genes. In order to determine their specificities, these tRNAs were each used to suppress an amber (UAG) nonsense mutation in the E. coli dihydrofolate reductase gene fol. The mutant proteins were purified and subjected to N-terminal sequence analysis to determine which amino acid had been inserted by the suppressor tRNAs at the position of the amber codon. The suppressors can be classified into three groups on the basis of the protein sequence information. Class I suppressors, tRNA(CUAAla2), tRNA(CUAGly1), tRNA(CUAHisA), tRNA(CUALys) and tRNA(CUAProH), inserted the predicted amino acid. The class II suppressors, tRNA(CUAGluA), tRNA(CUAGly2) and tRNA(CUAIle1) were either partially or predominantly mischarged by the glutamine aminoacyl tRNA synthetase. The class III suppressors, tRNA(CUAArg), tRNA(CUAAspM), tRNA(CUAIle2), tRNA(CUAThr2), tRNA(CUAMet(m)) and tRNA(CUAVal) inserted predominantly lysine.     

A cluster of nine tRNA genes between ribosomal gene operons in Bacillus subtilis.

A cluster of nine tRNA genes located in the 1-kb region between ribosomal operons rrnJ and rrnW in Bacillus subtilis has been cloned and sequenced. This cluster contains the genes for tRNA(UACVal), tRNA(UGUThr), tRNA(UUULys), tRNA(UAGLeu). tRNA(GCCGly), tRNA(UAALeu), tRNA(ACGArg), tRNA(UGGPro), and tRNA(UGCAla). The newly discovered tRNA gene cluster combines features of the 3'-end of trnI, a cluster of 6 tRNA genes between ribosomal operons rrnI and rrnH, and of the 5'-end of trnB, a cluster of 21 tRNA genes found immediately 3' to rrnB. Neither the tRNA(UAGLeu) gene nor its product has been found previously in B. subtilis. With the discovery of this new set of tRNA genes, a total of 60 such genes have now been found in B. subtilis. These known genes account for almost all of the tRNA hybridizing restriction fragments of the B. subtilis genome. The 60 known tRNA genes of B. subtilis code for only 28 different anticodons, compared with a total of 41 different anticodons for 78 tRNA genes in Escherichia coli. This may indicate that B. subtilis does not need as many anticodons because of more flexible translation rules, similar to the situation in Mycoplasma capricolum.     

Sequence evidence in the archaeal genomes that tRNAs emerged through the combination of ancestral genes as 5' and 3' tRNA halves

The discovery of separate 5' and 3' halves of transfer RNA (tRNA) molecules-so-called split tRNA-in the archaeal parasite Nanoarchaeum equitans made us wonder whether ancestral tRNA was encoded on 1 or 2 genes. We performed a comprehensive phylogenetic analysis of tRNAs in 45 archaeal species to explore the relationship between the three types of tRNAs (nonintronic, intronic and split). We classified 1953 mature tRNA sequences into 22 clusters. All split tRNAs have shown phylogenetic relationships with other tRNAs possessing the same anticodon. We also mimicked split tRNA by artificially separating the tRNA sequences of 7 primitive archaeal species at the anticodon and analyzed the sequence similarity and diversity of the 5' and 3' tRNA halves. Network analysis revealed specific characteristics of and topological differences between the 5' and 3' tRNA halves: the 5' half sequences were categorized into 6 distinct groups with a sequence similarity of >80%, while the 3' half sequences were categorized into 9 groups with a higher sequence similarity of >88%, suggesting different evolutionary backgrounds of the 2 halves. Furthermore, the combinations of 5' and 3' halves corresponded with the variation of amino acids in the codon table. We found not only universally conserved combinations of 5'-3' tRNA halves in tRNA(iMet), tRNA(Thr), tRNA(Ile), tRNA(Gly), tRNA(Gln), tRNA(Glu), tRNA(Asp), tRNA(Lys), tRNA(Arg) and tRNA(Leu) but also phylum-specific combinations in tRNA(Pro), tRNA(Ala), and tRNA(Trp). Our results support the idea that tRNA emerged through the combination of separate genes and explain the sequence diversity that arose during archaeal tRNA evolution.     

The length of the aminoacyl-acceptor stem of the selenocysteine-specific tRNA(Sec) of Escherichia coli is the determinant for binding to elongation factors SELB or Tu

Mutations in selC, which reduce the 8-base pair aminoacyl-acceptor helix to the canonical 7-base pair length (tRNA(Sec)(delAc] or which replace the extra arm of tRNA(Sec) by that of a serine acceptor tRNA species (tRNA(Sec)(ExS), block the function in selenoprotein synthesis in vivo (Baron, C., Heider, J., and B?ck, A. (1990) Nucleic Acids Res. 18, 6761-6766). tRNA(Sec), tRNA(Sec)(delAc), and tRNA(Sec)(ExS) were purified and analyzed for their interaction with purified seryl-tRNA synthetase, selenocysteine synthase and translation factors SELB and EF-Tu. It was found that seryl-tRNA synthetase displays 10-fold impaired Km and Kcat values for tRNA(Sec) in comparison to tRNA(Ser), decreasing the overall charging efficiency (Kcat/Km) of tRNA(Sec) to 1% of that characteristic for tRNA(Ser). tRNA(Sec)(ExS) was a less efficient substrate for the enzyme (Kcat/Km 0.2% of the tRNA(Ser) value) whereas the tRNA(Ser)(delAc) variant was charged with an approximately 2-3-fold improved rate compared to wild-type tRNA(Sec). Both mutant tRNA variants, when charged with L-serine, were able to interact with selenocysteine synthase to give rise to selenocysteyl-tRNA with tRNA(Sec)(ExS) being as efficient as wild-type tRNA(Sec). Seryl-tRNA(Sec)(delAc), on the other hand, was selenylated very slowly. Reduction of the length of the aminoacyl-acceptor stem to 7 base pairs prevented the interaction with translation factor SELB but allowed binding to EF-Tu, irrespective of whether tRNA(Sec)(delAc) was charged with serine or selenocysteine. The aminoacyl-acceptor helix of tRNA(Sec), therefore, is a major determinant directing binding to SELB and precluding interaction with EF-Tu.     

Mutations in mitochondrial tRNA genes: a frequent cause of neuromuscular diseases.

We have sequenced the tRNA genes of mtDNA from patients with chronic progressive external ophthalmoplegia (CPEO) without detectable mtDNA deletions. Four point mutations were identified, located within highly conserved regions of mitochondrial tRNA genes, namely tRNA(Leu)(UAG), tRNA(Ser)(GCU), tRNA(Gly) and tRNA(Lys). One of these mutations (tRNA(Leu)(UAG)) was found in four patients with different forms of mitochondrial myopathy. An accumulation of three different tRNA point mutations (tRNA(Leu)(UAG)), tRNA(Ser)(GCU) and tRNA(Gly) was observed in a single patient, suggesting that mitochondrial tRNA genes represent hotspots for point mutations causing neuromuscular diseases.     

The role of isoacceptor transfer RNAs in regulation of age-related changes in the rate of protein synthesis

In cell-free protein-synthesizing systems containing an S30 extract from liver and brain cortex tissues of 22-day-old fetuses and of male WAG rats (1-900 days old), the minimal rate of protein synthesis was observed in the fetuses, while the maximal one - in 7-day-old animals. The difference in the rates of protein synthesis correlated with the minimal concentration of total tRNA in the former group and with its maximal concentration in the latter. In fetal tissues, an addition to cell-free systems of total tRNA isolated from homologous tissues of 7-day-old animals augmented protein synthesis up to a level observed in 7-day-old animals, whereas in the tissues of animals belonging to other age groups total tRNA had a far less pronounced stimulating effect which decreased with age. Fractionation of total tRNA and analysis of effects of individual tRNAs on protein synthesis demonstrated that the stimulating influence was induced by tRNA(2Arg), tRNA(4Arg) and tRNA(2Val) from brain cortex and by tRNA(2Leu), tRNA(5Leu), tRNA(2Val), tRNA(1Met) and tRNA(2Met) from liver.     

Codon reading patterns in Saccharomyces cerevisiae mitochondria based on sequences of mitochondrial tRNAs

The sequences of Saccharomyces cerevisiae mitochondrial tRNA Arg1, tRNA Arg2, tRNA Gly, tRNA Lys2, tRNA Leu amd tRNA Pro are reported. Special structural features were found in tRNA Pro, which has A8, C21, A48 instead of the constant residues U8, A21 and pyrimidine 48, and in tRNA Lys2, which has a U excluded from base-paring and bulging out from the TpsiC stem. The tRNA Arg1, tRBA Lys2 and tRNA Leu, which belong to two-codon families ending in a purine, have a modified uridine in the wobble position, which prevents misreading of C and U. It is likely to be 5-carboxymethylaminomethyluridine. tRNA Gly and tRNA Pro have an unmodified uridine in the wobble position allowing the reading of all four codons of a four-codon family. However, tRNA Arg2, which is a minor species and belongs to the CGN four-codon family, has an unmodified A in the wobble position. This unusual feature raises the problem of the mechanism by which the codons CGA, CGG and CGC are recognized.     

Diversity of tRNA genes in eukaryotes

We compare the diversity of chromosomal-encoded transfer RNA (tRNA) genes from 11 eukaryotes as identified by tRNAScan-SE of their respective genomes. They include the budding and fission yeast, worm, fruit fly, fugu, chicken, dog, rat, mouse, chimp and human. The number of tRNA genes are between 170 and 570 and the number of tRNA isoacceptors range from 41 to 55. Unexpectedly, the number of tRNA genes having the same anticodon but different sequences elsewhere in the tRNA body (defined here as tRNA isodecoder genes) varies significantly (10–246). tRNA isodecoder genes allow up to 274 different tRNA species to be produced from 446 genes in humans, but only up to 51 from 275 genes in the budding yeast. The fraction of tRNA isodecoder genes among all tRNA genes increases across the phylogenetic spectrum. A large number of sequence differences in human tRNA isodecoder genes occurs in the internal promoter regions for RNA polymerase III. We also describe a systematic, ligation-based method to detect and quantify tRNA isodecoder molecules in human samples, and show differential expression of three tRNA isodecoders in six human tissues. The large number of tRNA isodecoder genes in eukaryotes suggests that tRNA function may be more diverse than previously appreciated.     

End processing precedes mitochondrial importation and editing of tRNAs in Leishmania tarentolae

All mitochondrial tRNAs in Leishmania tarentolae are encoded in the nuclear genome and imported into the mitochondrion from the cytosol. One imported tRNA (tRNA(Trp)) is edited by a C to U modification at the first position of the anticodon. To determine the in vivo substrates for mitochondrial tRNA importation as well as tRNA editing, we examined the subcellular localization and extent of 5'- and 3'-end maturation of tRNA(Trp)(CCA), tRNA(Ile)(UAU), tRNA(Gln)(CUG), tRNA(Lys)(UUU), and tRNA(Val)(CAC). Nuclear, cytosolic, and mitochondrial fractions were obtained with little cross-contamination, as determined by Northern analysis of specific marker RNAs. tRNA(Gln) was mainly cytosolic in localization; tRNA(Ile) and tRNA(Lys) were mainly mitochondrial; and tRNA(Trp) and tRNA(Val) were shared between the two compartments. 5'- and 3'-extended precursors of all five tRNAs were present only in the nuclear fraction, suggesting that the mature tRNAs represent the in vivo substrates for importation into the mitochondrion. Consistent with this model, T7-transcribed mature tRNA(Ile) underwent importation in vitro into isolated mitochondria more efficiently than 5'-extended precursor tRNA(Ile). 5'-Extended precursor tRNA(Trp) was found to be unedited, which is consistent with a mitochondrial localization of this editing reaction. T7-transcribed unedited tRNA(Trp) was imported in vitro more efficiently than edited tRNA(Trp), suggesting the presence of importation determinants in the anticodon.     

Genomic heterogeneity in a natural archaeal population suggests a model of tRNA gene disruption

Understanding the mechanistic basis of the disruption of tRNA genes, as manifested in the intron-containing and split tRNAs found in Archaea, will provide considerable insight into the evolution of the tRNA molecule. However, the evolutionary processes underlying these disruptions have not yet been identified. Previously, a composite genome of the deep-branching archaeon Caldiarchaeum subterraneum was reconstructed from a community genomic library prepared from a C. subterraneum-dominated microbial mat. Here, exploration of tRNA genes from the library reveals that there are at least three types of heterogeneity at the tRNA(Thr)(GGU) gene locus in the Caldiarchaeum population. All three involve intronic gain and splitting of the tRNA gene. Of two fosmid clones found that encode tRNA(Thr)(GGU), one (tRNA(Thr-I)) contains a single intron, whereas another (tRNA(Thr-II)) contains two introns. Notably, in the clone possessing tRNA(Thr-II), a 5' fragment of the tRNA(Thr-I) (tRNA(Thr-F)) gene was observed 1.8-kb upstream of tRNA(Thr-II). The composite genome contains both tRNA(Thr-II) and tRNA(Thr-F), although the loci are >500 kb apart. Given that the 1.8-kb sequence flanked by tRNA(Thr-F) and tRNA(Thr-II) is predicted to encode a DNA recombinase and occurs in six regions of the composite genome, it may be a transposable element. Furthermore, its dinucleotide composition is most similar to that of the pNOB8-type plasmid, which is known to integrate into archaeal tRNA genes. Based on these results, we propose that the gain of the tRNA intron and the scattering of the tRNA fragment occurred within a short time frame via the integration and recombination of a mobile genetic element.     

Differential annotation of tRNA genes with anticodon CAT in bacterial genomes

We have developed three strategies to discriminate among the three types of tRNA genes with anticodon CAT (tRNA(Ile), elongator tRNA(Met) and initiator tRNA(fMet)) in bacterial genomes. With these strategies, we have classified the tRNA genes from 234 bacterial and several organellar genomes. These sequences, in an aligned or unaligned format, may be used for the identification and annotation of tRNA (CAT) genes in other genomes. The first strategy is based on the position of the problem sequences in a phenogram (a tree-like network), the second on the minimum average number of differences against the tRNA sequences of the three types and the third on the search for the highest score value against the profiles of the three types of tRNA genes. The species with the maximum number of tRNA(fMet) and tRNA(Met) was Photobacterium profundum, whereas the genome of one Escherichia coli strain presented the maximum number of tRNA(Ile) (CAT) genes. This last tRNA gene and tilS, encoding an RNA-modifying enzyme, are not essential in bacteria. The acquisition of a tRNA(Ile) (TAT) gene by Mycoplasma mobile has led to the loss of both the tRNA(Ile) (CAT) and the tilS genes. The new tRNA has appropriated the function of decoding AUA codons.     

The first human genes for tRNA(ArgICG), tRNA(GlyUCC), and tRNA(ThrIGU) and more tRNA(Val) pseudogenes: expression and pre-tRNA maturation in HeLa cell-free extracts.

A functional tRNA(Val) gene, which codes for the major tRNA(ValIAC) isoacceptor species, and three new tRNA(Val) pseudogenes have been isolated from human genomic DNA. Two tRNA(Val) pseudogenes and a tRNA(Val) variant gene were found to be associated with tRNA genes encoding tRNA(ArgICG), tRNA(GlyUCC), and tRNA(ThrIGU), respectively, on distinct DNA fragments. All tRNA genes, including the pseudogenes, are actively transcribed in HeLa nuclear extract. Pre-tRNAs of tRNA(Val), tRNA(Arg), tRNA(Thr), and tRNA(Gly) genes are correctly processed to mature-sized tRNAs, whereas the three tRNA(Val) pseudogenes yield stable pre-tRNAs in vitro. These findings reveal that, together with the three known pseudogenes, half of the members of the human tRNA(Val) gene family are pseudogenes, all of which are active in homologous nuclear extracts in vitro and presumably also in vivo.     

Sequence dependence of tRNA(Gly) import into tobacco mitochondria

Plant mitochondrial genomes lack a number of tRNA genes and the corresponding tRNAs, which are nuclear-encoded, are imported from the cytosol. We show that specific import of tRNA(Gly) isoacceptors occurs in tobacco mitochondria: tRNA(Gly)(UCC) and tRNA(Gly)(CCC) are cytosolic and mitochondrial, while tRNA(Gly)(GCC) is found only in the cytosol. Exchange of sequences between tRNA(Gly)(UCC) and tRNA(Gly)(GCC) shows that the anticodon and D-domain are essential for tRNA(Gly)(UCC) import. However the reverse mutations in tRNA(Gly)(GCC) are not sufficient to promote its import into tobacco mitochondria.