Nucleotide sequences of three tRNA genes encoded in Tetrahymena mitochondrial DNA.

Nucleotide sequences of three cloned restriction fragments of Tetrahymena mtDNA which showed hybridization with mitochondrial tRNA have been determined. EcoRI fragment 5 (4.1 kbp) contains the tRNAphe gene sequence with anticodon GAA; Hind III fragment 6 (2.0 kbp) the tRNAhis with anticodon GTG; and EcoRI fragment 7 (1.9 kbp) the tRNAtrp with anticodon TCA. The CCA end is not encoded. All three tRNAs show usual features with common invariant and semi-invariant bases and can be folded into a cloverleaf structure with standard loops and regular base pairs in the stems. However, some minor irregular features are present including several GT pairs and an unmatched TT in the stems, and TCC instead of T psi C. All exhibit high G+C contents (about 50%); in contrast, the flanking regions are extremely A+T rich (about 80%). Several short coding frames can be deduced in these sequences, but their significance is not known.     

Higher-order structure of bovine mitochondrial tRNA(SerUGA): chemical modification and computer modeling.

On the basis of enzymatic probing and phylogenetic comparison, we have previously proposed that mammalian mitochondrial tRNA(sSer) (anticodon UGA) possess a slightly altered cloverleaf structure in which only one nucleotide exists between the acceptor stem and D stem (usually two nucleotides) and the anticodon stem consists of six base pairs (usually five base pairs) [Yokogawa et al. (1991) Nucleic Acids Res. 19, 6101-6105]. To ascertain whether such tRNA(sSer) can be folded into a normal L-shaped tertiary structure, the higher-order structure of bovine mitochondrial tRNA(SerUGA) was examined by chemical probing using dimethylsulfate and diethylpyrocarbonate, and on the basis of the results a tertiary structure model was obtained by computer modeling. It was found that a one-base-pair elongation in the anticodon stem was compensated for by multiple-base deletions in the D and extra loop regions of the tRNA(SerUGA), which resulted in preservation of an L-shaped tertiary structure similar to that of conventional tRNAs. By summarizing the findings, the general structural requirements of mitochondrial tRNAs necessary for their functioning in the mitochondrial translation system are considered.     

A novel cloverleaf structure found in mammalian mitochondrial tRNA(Ser) (UCN).

Bovine mitochondrial tRNA(Ser) (UCN) has been thought to have two U-U mismatches at the top of the acceptor stem, as inferred from its gene sequence. However, this unusual structure has not been confirmed at the RNA level. In the course of investigating the structure and function of mitochondrial tRNAs, we have isolated the bovine liver mitochondrial tRNA(Ser) (UCN) and determined its complete sequence including the modified nucleotides. Analysis of the 5'-terminal nucleotide and enzymatic determination of the whole sequence of tRNA(Ser) (UCN) revealed that the tRNA started from the third nucleotide of the putative tRNA(Ser) (UCN) gene, which had formerly been supposed. Enzymatic probing of tRNA(Ser) (UCN) suggests that the tRNA possesses an unusual cloverleaf structure with the following characteristics. (1) There exists only one nucleotide between the acceptor stem with 7 base pairs and the D stem with 4 base pairs. (2) The anticodon stem seems to consist of 6 base pairs. Since the same type of cloverleaf structure as above could be constructed only for mitochondrial tRNA(Ser) (UCN) genes of mammals such as human, rat and mouse, but not for those of non-mammals such as chicken and frog, this unusual secondary structure seems to be conserved only in mammalian mitochondria.     

Genes encoding threonine tRNAs with the anticodon CGU from Escherichia coli and Pseudomonas aeruginosa

Homologous genes for threonine tRNAs with the anticodon CGU have been identified in the region of the proBA operon of Escherichia coli and downstream from the fimbrial subunit gene of Pseudomonas aeruginosa. tRNAs with the anticodon CGU have not previously been identified from either of these bacterial species. Sequence analyses have shown that these genes are similar to other bacterial tRNA genes, and that the predicted structure conforms to the standard cloverleaf model, including retention of all invariant and semi-invariant bases. Analysis of upstream sequences suggests that these genes have associated promoters and are probably expressed in vivo.     

Tumor mitochondrial transfer ribonucleic acids: the nucleotide sequence of Morris hepatoma 5123D mitochondrial tRNA GUC Asp

A mitochondrial aspartate tRNA (anticodon GUC) was isolated from a transplantable rat tumor, Morris hepatoma 5123D, and sequenced. The sequence, pGAGAUAUUm(1)AGUAAAAUAAUUACA psi AACCUUGUCAAGGUUAAGUUAUAGACUUAAAUCUAUAUAUCUUACCAOH, can be arranged in a cloverleaf structure. The RNA exhibits a number of unusual features, such as lack of the constant -G-G- and -T-psi-C- sequences in loops I and IV, respectively, small size of these loops, lack of the constant G.C base pair adjacent to loop IV, predominance of A.U base pairs in general, and presence of m1A in position 9. The RNA exhibits 82 and 70% homology with the DNA-derived putative sequences of human placenta and beef heart mitochondrial tRNA Asp, respectively, and bears little resemblance to other sequenced aspartate tRNAs of non-mitochondrial origin.     

Yeast mitochondrial tRNAIle and tRNAMetm: nucleotide sequence and codon recognition patterns.

The nucleotide sequence of yeast mitochondrial isoleucine- and methionine-elongator tRNA have been determined. Interestingly, long stretches of almost identical nucleotide sequences are found within these two tRNAs and also within the yeast mt tRNAMetf, suggesting that the 3 tRNAs may have arisen from a common ancestor. Both mt tRNAMetm and tRNAIle contain all the structural characteristics which are present in the standard cloverleaf, except that the mt tRNAMetm contains an extra unpaired nucleotide within the base-paired T psi C stem. This rather unusual feature may have an influence on the decoding properties of the C-A-U anticodon of mt tRNAMetm by conferring the ability to translate not only the codon A-U-G but also A-U-A.     

Mamit-tRNA, a database of mammalian mitochondrial tRNA primary and secondary structures

Mamit-tRNA (http://mamit-tRNA.u-strasbg.fr), a database for mammalian mitochondrial genomes, has been developed for deciphering structural features of mammalian mitochondrial tRNAs and as a helpful tool in the frame of human diseases linked to point mutations in mitochondrial tRNA genes. To accommodate the rapid growing availability of fully sequenced mammalian mitochondrial genomes, Mamit-tRNA has implemented a relational database, and all annotated tRNA genes have been curated and aligned manually. System administrative tools have been integrated to improve efficiency and to allow real-time update (from GenBank Database at NCBI) of available mammalian mitochondrial genomes. More than 3000 tRNA gene sequences from 150 organisms are classified into 22 families according to the amino acid specificity as defined by the anticodon triplets and organized according to phylogeny. Each sequence is displayed linearly with color codes indicating secondary structural domains and can be converted into a printable two-dimensional (2D) cloverleaf structure. Consensus and typical 2D structures can be extracted for any combination of primary sequences within a given tRNA specificity on the basis of phylogenetic relationships or on the basis of structural peculiarities. Mamit-tRNA further displays static individual 2D structures of human mitochondrial tRNA genes with location of polymorphisms and pathology-related point mutations. The site offers also a table allowing for an easy conversion of human mitochondrial genome nucleotide numbering into conventional tRNA numbering. The database is expected to facilitate exploration of structure/function relationships of mitochondrial tRNAs and to assist clinicians in the frame of pathology-related mutation assignments.     

Genes for tRNAAsp,tRNAPro, tRNATyr and two tRNAsSer in wheat mitochondrial DNA

We have begun a systematic search for potential tRNA genes in wheat mtDNA, and present here the sequences of regions of the wheat mitochondrial genome that encode genes for tRNA^Asp (anticodon GUC), tRNA^Pro (UGG), tRNA^Tyr (GUA), and two tRNAs^Ser (UGA and GCU). These genes are all solitary, not immediately adjacent to other tRNA or known protein coding genes. Each of the encoded tRNAs can assume a secondary structure that conforms to the standard cloverleaf model, and that displays none of the structural aberrations peculiar to some of the corresponding mitochondrial tRNAs from other eukaryotes. The wheat mitochondrial tRNA sequences are, on average, substantially more similar to their eubacterial and chloroplast counterparts than to their homologues in fungal and animal mitochondria. However, an analysis of regions 150 nucleotides upstream and 100 nucleotides downstream of the tRNA coding regions has revealed no obvious conserved sequences that resemble the promoter and terminator motifs that regulate the expression of eubacterial and some chloroplast tRNA genes. When restriction digests of wheat mtDNA are probed with ³²P-labelled wheat mitochondrial tRNAs, <20 hybridizing bands are detected, whether enzymes with 4 bp or 6 bp recognition sites are used. This suggests that the wheat mitochondrial genome, despite its large size, may carry a relatively small number of tRNA genes.     

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.     

Novel transfer RNAs that are active in Escherichia coli.

Many of the mammalian mitochondrial tRNAs contain significant nucleotide deletions in the dihydrouridine (D) stem or T psi C stem, so that they cannot fold into the canonical cloverleaf structure. This suggests that alternative forms and shapes are possible for a mitochondrial tRNA that functions in the specialized translational apparatus of the mammalian mitochondria. The question of whether significant structural alterations may be accommodated by a bacterial protein synthesis machinery, such as in Escherichia coli, is unanswered. In this work, all but ten positions in the gene for the 76-nucleotide coding sequence of an E. coli amber suppressor tRNA were permuted and screened for biological activity in vivo. Sequence analysis of a collection of biologically active variants established that many have unusual structures that include base-pair mismatches in helical stems, substitutions of normally conserved bases, and deletions. Independent mutations were obtained that weaken base pairs or tertiary interactions that normally stabilize the coaxial stacking of the D and anticodon stems, suggesting that the translational apparatus can accommodate considerable flexibility in this part of the molecule. The results demonstrate the capacity of the bacterial protein synthetic apparatus to accommodate altered tRNA structures that are not represented by any naturally occurring tRNAs.     

Mitochondrial tRNAs as light strand replication origins: Similarity between anticodon loops and the loop of the light strand replication origin predicts initiation of DNA replication

Stem-loop hairpins formed by mitochondrial light strand replication origins (OL) and by heavy strand DNA coding for tRNAs that form OL-like structures initiate mitochondrial replication. The loops are recognized by one of the two active sites of the vertebrate mitochondrial gamma polymerase, which are homologuous to the active sites of class II amino-acyl tRNA synthetases. Therefore, the polymerase site recognizing the OL loop could recognize tRNA anticodon loops and sequence similarity between anticodon and OL loops should predict initiation of DNA replication at tRNAs. Strengths of genome-wide deamination gradients starting at tRNA genes estimate extents by which replication starts at that tRNA. Deaminations (A→G and C→T) occur proportionally to time spent single stranded by heavy strand DNA during mitochondrial light strand replication. Results show that deamination gradients starting at tRNAs are proportional to sequence similarity between OL and tRNA loops: most for anticodon-, least D-, intermediate for TψC-loops, paralleling tRNA synthetase recognition interactions with these tRNA loops. Structural and sequence similarities with regular OLs predict OL function, loop similarity is dominant in most tRNAs. Analyses of sequence similarity and structure independently substantiate that DNA sequences coding for mitochondrial tRNAs sometimes function as alternative OLs. Pathogenic mutations in anticodon loops increase similarity with the human OL loop, non-pathogenic polymorphisms do not. Similarity/homology alignment hypotheses are experimentally testable in this system.     

The gene for tRNA(Lys) is encoded in the rapeseed (Brassica napus L.) mitochondrial DNA.

The nucleotide sequence of the gene coding for tRNA(Lys) and its flanking regions from the rapeseed mitochondrial genome are presented and compared with other known tRNA(Lys) genes from plant mitochondria. This tRNA sequence can be folded into the standard cloverleaf structure model. Also, this tRNA sequence shows less similarity with its chloroplast counterparts and therefore appears to be 'native' mitochondrial tRNA.     

Mitochondrial sequence evolution in spiders: intraspecific variation in tRNAs lacking the TPsiC Arm

Analyses of mitochondrial DNA sequences from three species of Habronattus jumping spiders (Chelicerata: Arachnida: Araneae) reveal unusual inferred tRNA secondary structures and gene arrangements, providing new information on tRNA evolution within chelicerate arthropods. Sequences from the protein-coding genes NADH dehydrogenase subunit 1 (ND1), cytochrome oxidase subunit I (COI), and subunit II (COII) were obtained, along with tRNA, tRNA, and large-subunit ribosomal RNA (16S) sequences; these revealed several peculiar features. First, inferred secondary structures of tRNA and, likely, tRNA, lack the TPsiC arm and the variable arm and therefore do not form standard cloverleaf structures. In place of these arms is a 5-6-nt T arm-variable loop (TV) replacement loop such as that originally described from nematode mitochondrial tRNAs. Intraspecific variation occurs in the acceptor stem sequences in both tRNAs. Second, while the proposed secondary structure of the 3' end of 16S is similar to that reported for insects, the sequence at the 5' end is extremely divergent, and the entire gene is truncated about 300 nt with respect to Drosophila yakuba. Third, initiation codons appear to consist of ATY (ATT and ATC) and TTG for ND1 and COII, respectively. Finally, Habronattus shares the same ND1-tRNA-16S gene arrangement as insects and crustaceans, thus illustrating variation in a tRNA gene arrangement previously proposed as a character distinguishing chelicerates from insects and crustaceans.     

Improved systematic tRNA gene annotation allows new insights into the evolution of mitochondrial tRNA structures and into the mechanisms of mitochondrial genome rearrangements

Transfer RNAs (tRNAs) are present in all types of cells as well as in organelles. tRNAs of animal mitochondria show a low level of primary sequence conservation and exhibit 'bizarre' secondary structures, lacking complete domains of the common cloverleaf. Such sequences are hard to detect and hence frequently missed in computational analyses and mitochondrial genome annotation. Here, we introduce an automatic annotation procedure for mitochondrial tRNA genes in Metazoa based on sequence and structural information in manually curated covariance models. The method, applied to re-annotate 1876 available metazoan mitochondrial RefSeq genomes, allows to distinguish between remaining functional genes and degrading 'pseudogenes', even at early stages of divergence. The subsequent analysis of a comprehensive set of mitochondrial tRNA genes gives new insights into the evolution of structures of mitochondrial tRNA sequences as well as into the mechanisms of genome rearrangements. We find frequent losses of tRNA genes concentrated in basal Metazoa, frequent independent losses of individual parts of tRNA genes, particularly in Arthropoda, and wide-spread conserved overlaps of tRNAs in opposite reading direction. Direct evidence for several recent Tandem Duplication-Random Loss events is gained, demonstrating that this mechanism has an impact on the appearance of new mitochondrial gene orders.