Processing of plant mitochondrial tRNAGly and tRNASer(GCU) is independent of RNA editing

The genes encoding pea and potato mitochondrial tRNA^Gly and pea mitochondrial tRNA^Ser(GCU) were analyzed with particular respect to their expression. Secondary-structure models deduced from the identical potato and pea tRNA^Gly gene sequences revealed A₇:C₆₆ mismatches in the seventh base pair at the base of the acceptor stems of both tRNAs. Sequence analyses of tRNA^Gly cDNA clones showed that these mispairings are not corrected by C₆₆ to U₆₆ conversions, as observed in plant mitochondrial tRNA^Phe. Likewise, a U₆:C₆₇ mismatch identified in the acceptor stem of the pea tRNA^Ser(GCU) is not altered by RNA editing to a mismatched U:U pair, which is created by RNA editing in Oenothera mitochondrial tRNA^Cys. In vitro processing reactions with the respective tRNA^Gly and tRNA^Ser(GCU) precursors show that such conversions are not necessary for 5′ and 3′ end maturation of these tRNAs. These results demonstrate that not all C:A (A:C) or U:C (C:U) mismatches in double-stranded regions of tRNAs are altered by RNA editing. An RNA editing event in plant mitochondrial tRNAs is thus not generally indicated by the presence of a mismatch but may depend on additional parameters. Received: 18 July 1997 / Accepted: 3 November 1997     

Studies on the ribothymidine content of specific rat and human tRNAs: a postulated role for 5-methyl cytosine in the regulation of ribothymidine biosynthesis.

Total mammalian tRNAs contain on the average less than one mole of ribothymidine per mole of tRNA. Mammalian tRNAs can be grouped into at least four classes, depending upon their ribothymidine content at position 23 from the 3′ terminus. Class A contains tRNA in which a nucleoside other than uridine replaces ribothymidine (tRNA_i^Met); Class B contains tRNA in which one mole of a modified uridine (rT, ψ, or 2′-O-methylribothymidine) is found per mole of tRNA (tRNA^Ser, tRNA^Trp, and tRNA^Lys, respectively). Class C contains tRNA in which there is a partial conversion of uridine to ribothymidine (tRNA^Phe, tRNA₁^Gly, tRNA₂^Gly); Class D contains tRNA which totally lacks ribothymidine (tRNA^Val). Only those tRNAs in Class C are acceptable substrates for $\text{E.}\text{coli}$ uridine methylase, under the conditions used in these studies. These observations cannot be adequately explained solely on the basis of the presence or absence of a specific “universal” nucleoside other than U or rT at position 23 from the 3′ terminus. However, correlations can be made between the ribothymidine and 5-methylcytosine content of eucaryotic tRNA. We postulate that the presence of one or more 5-methylcytosines in and adjacent to loop III (minor loop) in individual tRNAs act to regulate the amount of ribothymidine formed by uridine methylase. Several experiments are proposed as tests for this hypothesis.     

Position 34 of tRNA is a discriminative element for m5C38 modification by human DNMT2

Dnmt2, a member of the DNA methyltransferase superfamily, catalyzes the formation of 5-methylcytosine at position 38 in the anticodon loop of tRNAs. Dnmt2 regulates many cellular biological processes, especially the production of tRNA-derived fragments and intergenerational transmission of paternal metabolic disorders to offspring. Moreover, Dnmt2 is closely related to human cancers. The tRNA substrates of mammalian Dnmt2s are mainly detected using bisulfite sequencing; however, we lack supporting biochemical data concerning their substrate specificity or recognition mechanism. Here, we deciphered the tRNA substrates of human DNMT2 (hDNMT2) as tRNA^Asp(GUC), tRNA^Gly(GCC) and tRNA^Val(AAC). Intriguingly, for tRNA^Asp(GUC) and tRNA^Gly(GCC), G34 is the discriminator element; whereas for tRNA^Val(AAC), the inosine modification at position 34 (I34), which is formed by the ADAT2/3 complex, is the prerequisite for hDNMT2 recognition. We showed that the C³²U³³(G/I)³⁴N³⁵ (C/U)³⁶A³⁷C³⁸ motif in the anticodon loop, U11:A24 in the D stem, and the correct size of the variable loop are required for Dnmt2 recognition of substrate tRNAs. Furthermore, mammalian Dnmt2s possess a conserved tRNA recognition mechanism.     

Codon recognition mechanisms in plant chloroplasts

In chloroplasts, all 61 sense codons are found in chloroplast (cp) DNA sequences coding for proteins. However among the sequenced cp tRNAs or tRNA genes, tRNAs with anticodons complementary to codons CUU/C (Leu), CCU/C (Pro), GCU/C (Ala) and CGC/A/G (Arg) [or CGC/A (Arg) in Marchantia] have not been found. In this paper we show that cp tRNA^Ala(U^*GC), cp tRNA^Pro(U^*GG) and cp tRNA^Arg(ICG) are able to decode the corresponding four-codon family. In the case of leucine codons CUU/C, we show that U:U and U:C wobble mechanisms can operate to allow the reading of these codons by cp tRNA^Leu (UAm⁷G).     

Thiolated tRNAs of Trypanosoma brucei Are Imported into Mitochondria and Dethiolated after Import

All mitochondrial tRNAs in Trypanosoma brucei derive from cytosolic tRNAs that are in part imported into mitochondria. Some trypanosomal tRNAs are thiolated in a compartment-specific manner. We have identified three proteins required for the thio modification of cytosolic tRNA^Gln, tRNA^Glu, and tRNA^Lys. RNA interference-mediated ablation of these proteins results in the cytosolic accumulation non-thio-modified tRNAs but does not increase their import. Moreover, in vitro import experiments showed that both thio-modified and non-thio-modified tRNA^Glu can efficiently be imported into mitochondria. These results indicate that unlike previously suggested the cytosol-specific thio modifications do not function as antideterminants for mitochondrial tRNA import. Consistent with these results we showed by using inducible expression of a tagged tRNA^Glu that it is mainly the thiolated form that is imported in vivo. Unexpectedly, the imported tRNA becomes dethiolated after import, which explains why the non-thiolated form is enriched in mitochondria. Finally, we have identified two genes required for thiolation of imported tRNA^Trp whose wobble nucleotide is subject to mitochondrial C to U editing. Interestingly, down-regulation of thiolation resulted in an increase of edited tRNA^Trp but did not affect growth.     

Combination of the Loss of cmnmU34 with the Lack of sU34 Modifications of tRNA, tRNA, and tRNA Altered Mitochondrial Biogenesis and Respiration

Yeast Saccharomyces cerevisiae MTO2, MTO1, and MSS1 genes encoded highly conserved tRNA modifying enzymes for the biosynthesis of carboxymethylaminomethyl (cmnm)⁵s²U₃₄ in mitochondrial tRNA^Lys, tRNA^Glu, and tRNA^Gln. In fact, Mto1p and Mss1p are involved in the biosynthesis of the cmnm⁵ group (cmnm⁵U₃₄), while Mto2p is responsible for the 2-thiouridylation (s²U₃₄) of these tRNAs. Previous studies showed that partial modifications at U₃₄ in mitochondrial tRNA enabled mto1, mto2, and mss1 strains to respire. In this report, we investigated the functional interaction between MTO2, MTO1, and MSS1 genes by using the mto2, mto1, and mss1 single, double, and triple mutants. Strikingly, the deletion of MTO2 was synthetically lethal with a mutation of MSS1 or deletion of MTO1 on medium containing glycerol but not on medium containing glucose. Interestingly, there were no detectable levels of nine tRNAs including tRNA^Lys, tRNA^Glu, and tRNA^Gln in mto2/mss1, mto2/mto1, and mto2/mto1/mss1 strains. Furthermore, mto2/mss1, mto2/mto1, and mto2/mto1/mss1 mutants exhibited extremely low levels of COX1 and CYTB mRNA and 15S and 21S rRNA as well as the complete loss of mitochondrial protein synthesis. The synthetic enhancement combinations likely resulted from the completely abolished modification at U₃₄ of tRNA^Lys, tRNA^Glu, and tRNA^Gln, caused by the combination of eliminating the 2-thiouridylation by the mto2 mutation with the absence of the cmnm⁵U₃₄ by the mto1 or mss1 mutation. The complete loss of modifications at U₃₄ of tRNAs altered mitochondrial RNA metabolisms, causing a degradation of mitochondrial tRNA, mRNA, and rRNAs. As a result, failures in mitochondrial RNA metabolisms were responsible for the complete loss of mitochondrial translation. Consequently, defects in mitochondrial protein synthesis caused the instability of their mitochondrial genomes, thus producing the respiratory-deficient phenotypes. Therefore, our findings demonstrated a critical role of modifications at U₃₄ of tRNA^Lys, tRNA^Glu, and tRNA^Gln in maintenance of mitochondrial genome, mitochondrial RNA stability, translation, and respiratory function.     

Involvement of glycine transfer ribonucleic acids in development of the posterior silk gland of Bombyx mori

Glycine transfer RNAs from the two physiological phases, V-2, the stage of maximum growth, and V-5, the stage of maximum fibroin production, during the development of the posterior silk gland of Bombyx mori were examined. The tRNAs from both phases could be fractionated into two major isoaccepting species on a benzoylated DEAE-cellulose column. No significant qualitative differences were observed among the tRNAs, but the total amount of the isoaccepting species of tRNA^Gly in each gland of V-5 stage was 6-fold higher than the amount of tRNA^Gly in the V-2 gland. The codon recognition properties of the tRNA^Gly species were examined. It was found that tRNA^Gly₁ responded to the copolymer (G:U) preferentially while tRNA^Gly_II recognized the copolymer (A:G). The ratio between the extent of incorporation of labeled glycine from glycyl-tRNA^Gly₁ and glycyl-tRNA^Gly_II into protein in a cell-free system utilizing polysomes from the V-5 glands was similar to the relative abundance of the isoaccepting species present in the glands at that time. It also reflected the ratio between the corresponding codons assigned for glycine based on the sequence analysis of fibroin-mRNA [Suzuki, Y., and Brown, D. D. (1972) J. Mol. Biol.63: 409]. These results suggest that the abundance of tRNA^Gly in the posterior silk gland and the changes in the relative amounts of the isoaccepting species are quite specific for the development of the gland.     

Mutation in MTO1 involved in tRNA modification impairs mitochondrial RNA metabolism in the yeast Saccharomyces cerevisiae

The yeast MTO1 gene encodes an evolutionarily conserved protein for the biosynthesis of the 5-carboxymethylaminomethyl group of cmnm⁵s²U in the wobble position of mitochondrial tRNA. However, mto1 null mutant expressed the respiratory deficient phenotype only when coupled with the C1409G mutation of mitochondrial 15S rRNA. To further understand the role of MTO1 in mitochondrial RNA metabolism, the yeast mto1 null mutants carrying either wild-type (P^S) or 15S rRNA C1409G allele (P^R) have been characterized by examining the steady-state levels, aminoacylation capacity of mitochondrial tRNA, mitochondrial gene expression and petite formation. The steady-state levels of tRNA^Lys, tRNA^Glu, tRNA^Gln, tRNA^Leu, tRNA^Gly, tRNA^Arg and tRNA^Phe were decreased significantly while those of tRNA^Met and tRNA^His were not affected in the mto1 strains carrying the P^S allele. Strikingly, the combination of the mto1 and C1409G mutations gave rise to the synthetic phenotype for some of the tRNAs, especially in tRNA^Lys, tRNA^Met and tRNA^Phe. Furthermore, the mto1 strains exhibited a marked reduction in the aminoacylation levels of mitochondrial tRNA^Lys, tRNA^Leu, tRNA^Arg but almost no effect in those of tRNA^His. In addition, the steady-state levels of mitochondrial COX1, COX2, COX3, ATP6 and ATP9 mRNA were markedly decreased in mto1 strains. These data strongly indicate that unmodified tRNA caused by the deletion of MTO1 gene caused the instability of mitochondrial tRNAs and mRNAs and an impairment of aminoacylation of mitochondrial tRNAs. Consequently, the deletion of MTO1 gene acts in synergy with the 15S rRNA C1409G mutation, leading to the loss of COX1 synthesis and subsequent respiratory deficient phenotype.     

Crystal structure of human selenocysteine tRNA

Selenocysteine (Sec) is the 21st amino acid in translation. Sec tRNA (tRNA^Sec) has an anticodon complementary to the UGA codon. We solved the crystal structure of human tRNA^Sec. tRNA^Sec has a 9-bp acceptor stem and a 4-bp T stem, in contrast with the 7-bp acceptor stem and the 5-bp T stem in the canonical tRNAs. The acceptor stem is kinked between the U6:U67 and G7:C66 base pairs, leading to a bent acceptor-T stem helix. tRNA^Sec has a 6-bp D stem and a 4-nt D loop. The long D stem includes unique A14:U21 and G15:C20a pairs. The D-loop:T-loop interactions include the base pairs G18:U55 and U16:U59, and a unique base triple, U20:G19:C56. The extra arm comprises of a 6-bp stem and a 4-nt loop. Remarkably, the D stem and the extra arm do not form tertiary interactions in tRNA^Sec. Instead, tRNA^Sec has an open cavity, in place of the tertiary core of a canonical tRNA. The linker residues, A8 and U9, connecting the acceptor and D stems, are not involved in tertiary base pairing. Instead, U9 is stacked on the first base pair of the extra arm. These features might allow tRNA^Sec to be the target of the Sec synthesis/incorporation machineries.     

Recognition of altered E. coli formylmethionine transfer RNA by bacterial T factor

Treatment of $\text{E.}\text{coli}$ formylmethionine tRNA with sodium bisulfite produces six C → U base changes in the tRNA structure. Four of these modifications have no effect on the ability of tRNA_f^Met to be aminoacylated or formylated. Prior to bisulfite treatment, Met-tRNA_f^Met is not able to form a ternary complex with bacterial T factor and GTP, as measured by Sephadex G-50 gel filtration. After bisulfite treatment, a large portion of the modified tRNA is bound as T-GTP-Met-tRNA_f^Met. Formylation of bisulfite-modified Met-tRNA_f^Met completely eliminates T factor binding. Unmodified tRNA_f^Met is unique among the tRNAs sequenced to date in having a non-hydrogen-bonded base at the 5′ terminus. Bisulfite-catalyzed conversion of this unpaired C₁ to U₁ results in formation of a normal U₁-A₇₃ base pair at the end of the acceptor stem. It is likely that this structural alteration is responsible for the recognition of bisulfite-modified Met-tRNA_f^Met by T factor.     

Striking differences in mitochondrial tRNA import between different plant species

A systematic comparison of the tRNAs imported into the mitochondria of larch, maize and potato reveals considerable differences among the three species. Larch mitochondria import at least eleven different tRNAs (more than half of those tested) corresponding to ten different amino acids. For five of these tRNAs [tRNA^Phe(GAA), tRNA^Lys(CUU), tRNA^Pro(UGG), tRNA^Ser(GCU) and tRNA^Ser(UGA)] this is the first report of import into mitochondria in any plant species. There are also differences in import between relatively closely related plants; wheat mitochondria, unlike maize mitochondria import tRNA^His, and sunflower mitochondria, unlike mitochondria from other angiosperms tested, import tRNA^Ser(GCU) and tRNA^Ser(UGA). These results suggest that the ability to import each tRNA has been acquired independently at different times during the evolution of higher plants, and that there are few apparent restrictions on which tRNAs can or cannot be imported. The implications for the mechanisms of mitochondrial tRNA Import in plants are discussed.     

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.     

Editing corrects mispairing in the acceptor stem of bean and potato mitochondrial phenylalanine transfer RNAs.

Editing is a general event in plant mitochondrial messenger RNAs, but has never been detected in a plant mitochondrial transfer RNA (tRNA). We demonstrate here the occurrence of a tRNA editing event in higher plant mitochondria: in both bean and potato, the C encoded at position 4 in the mitochondrial tRNA(Phe)(GAA) gene is converted into a U in the mature tRNA. This nucleotide change corrects the mismatched C4-A69 base-pair which appears when folding the gene sequence into the cloverleaf structure and it is consistent with the fact that C to U transitions constitute the common editing events affecting plant mitochondrial messenger RNAs. The tRNA(Phe)(GAA) gene is located upstream of the single copy tRNA(Pro)(UGG) gene in both the potato and the bean mitochondrial DNAs. The sequences of potato and bean tRNA(Pro)(UGG) genes are colinear with the sequence of the mature bean mitochondrial tRNA(Pro)(UGG), demonstrating that this tRNA is not edited. A single copy tRNA(Ser)(GCU) gene was found upstream of the tRNA(Phe) gene in the potato mitochondrial DNA. A U6-U67 mismatched base-pair appears in the cloverleaf folding of this gene and is maintained in the mature potato mitochondrial tRNA(Ser)(GCU), which argues in favour of the hypothesis that the editing system of plant mitochondria can only perform C to U or occasionally U to C changes.     

Human Cells Have a Limited Set of tRNA Anticodon Loop Substrates of the tRNA Isopentenyltransferase TRIT1 Tumor Suppressor

Human TRIT1 is a tRNA isopentenyltransferase (IPTase) homologue of Escherichia coli MiaA, Saccharomyces cerevisiae Mod5, Schizosaccharomyces pombe Tit1, and Caenorhabditis elegans GRO-1 that adds isopentenyl groups to adenosine 37 (i6A37) of substrate tRNAs. Prior studies indicate that i6A37 increases translation fidelity and efficiency in codon-specific ways. TRIT1 is a tumor suppressor whose mutant alleles are associated with cancer progression. We report the systematic identification of i6A37-containing tRNAs in a higher eukaryote, performed using small interfering RNA knockdown and other methods to examine TRIT1 activity in HeLa cells. Although several potential substrates contained the IPTase recognition sequence A36A37A38 in the anticodon loop, only tRNA^SerAGA, tRNA^SerCGA, tRNA^SerUGA, and selenocysteine tRNA with UCA (tRNA^[Ser]SecUCA) contained i6A37. This subset is a significantly more restricted than that for two distant yeasts (S. cerevisiae and S. pombe), the only other organisms comprehensively examined. Unlike the fully i6A37-modified tRNAs for Ser, tRNA^[Ser]SecUCA is partially (∼40%) modified. Exogenous selenium and other treatments that decreased the i6A37 content of tRNA^[Ser]SecUCA led to increased levels of the tRNA^[Ser]SecUCA. Of the human mitochondrion (mt)-encoded tRNAs with A36A37A38, only mt tRNAs tRNA^SerUGA and tRNA^TrpUCA contained detectable i6A37. Moreover, while tRNA^Ser levels were unaffected by TRIT1 knockdown, the tRNA^[Ser]SecUCA level was increased and the mt tRNA^SerUGA level was decreased, suggesting that TRIT1 may control the levels of some tRNAs as well as their specific activity.