Differential localization of nuclear-encoded tRNAs between the cytosol and mitochondrion in Leishmania tarentolae

All mitochondrial tRNAs of the kinetoplastid protozoan Leishmania tarentolae are encoded in the nucleus and are imported from the cytosol into the mitochondrion. We previously reported the partitioning of five tRNAs and found that all were shared between the two compartments to different extents. To increase our knowledge of the tRNAs of this organism, and to attempt to understand the signals involved in their subcellular localization, a method to RT-PCR amplify new tRNAs was developed. Various tRNAs were 3' polyadenylated and reverse transcribed with a sequence-tagged primer. The cDNA was tagged by ligation to an anchor oligonucleotide, and the resulting double-tagged cDNA was amplified by PCR. Four new tRNAs were obtained, bringing to 20 the total number of L. tarentolae tRNAs identified to date. The subcellular localization of 17 tRNAs was quantitatively analyzed by two-dimensional gel electrophoresis and northern hybridization. In general, the previously suggested operational classification of tRNAs into three groups (mainly cytosolic, mainly mitochondrial, and shared between the two compartments) is still valid, but the relative abundance of each tRNA in the cytosol or mitochondrion varied greatly as did the level of expression.     

Sequences of halobacterial tRNAs and the paucity of U in the first position of their anticodons

The sequence of three tRNAs from Halobacterium cutirubrum have been determined. The sequences of tRNAValGAC and tRNAValCAC differ by only one nucleotide which is in the 5' terminal anticodon position. These tRNAs as well as that of tRNAAlaCGC are compared to other known halobacterial tRNAs. An observed paucity (or absence) of U in the first anticodon position is unique to archaebacterial tRNAs and may be indicative of unusual decoding properties of these organisms.     

tRNAs as regulators in gene expression

Transfer RNAs (tRNAs) hold a central place in protein synthesis by interpreting the genetic information stored in DNA into the amino acid sequence of protein, thus functioning as “adaptor” molecules. In recent years, however, various studies have shown that tRNAs have additional functions beyond participating in protein synthesis. When suffering from certain nutritional stresses, tRNAs change the level of aminoacylation to became uncharged, and these uncharged tRNAs act as effector molecules to regulate global gene expression, so that the stressed organism copes with the adverse environmental stresses. In budding yeast and certain mammalian cells, the retrograde movement of mature tRNAs from cytoplasm to nucleus serves as a mechanism for the surveillance system within the nucleus to continue monitoring the integrity of tRNAs. On the other hand, this retrograde action effectively reduces the global protein synthesis level under conditions of nutritional starvation. Quite recently, various publications have shown that tRNAs are not stable molecules in an absolute sense. Under certain physiological or environmental stresses, they are specifically cleaved into fragments of different lengths in the anticodon loop or anticodon left arm. These cleavages are not a meaningless random degradation phenomenon. Instead, a novel class of signal molecules such as tRNA halves or sitRNAs may be produced, which are closely correlated with the modulation of global gene expression. Investigation of the regulatory functions of tRNAs is a frontier, which seeks to reveal the structural and functional diversity of tRNAs as well as their vital functions during the expression of genetic information. Supported by National Natural Science Foundation of China (Grant Nos. 30870530 and 30570398) and the National Key Basic Research Program of China (Grant No. 2005CB724600)     

The mitochondrial tRNAs of Trypanosoma brucei are nuclear encoded

The mitochondrial DNA of Trypanosoma brucei is organized as a catenated network of maxicircles and minicircles. The maxicircles are equivalent to the typical mitochondrial genome except that the genes for the mitochondrial tRNAs have not been identified by sequence analysis of the maxicircle DNA. The apparent absence of tRNA genes in the maxicircle DNA suggests that the mitochondrial tRNAs are encoded by either the minicircle or the nuclear DNA. In order to determine their genomic origin, we isolated and identified the mitochondrial tRNAs of T. brucei. We show that these mitochondrial tRNAs are truly mitochondrially located in vivo and that they are free from detectable contamination by cytosolic RNAs. By hybridization analysis, using mitochondrial tRNAs as the probe, we determined that the mitochondrial tRNAs are encoded by nuclear DNA. This implies that RNAs, like proteins, are imported into the mitochondria. We investigated the relationship between the cytosolic and the mitochondrial tRNA genes and show that there are unique cytosolic tRNA genes, unique mitochondrial tRNA genes, and tRNA genes which appear to be shared and whose products are therefore targeted to both the cytosol and the mitochondrion.     

Universal rules and idiosyncratic features in tRNA identity.

Correct expression of the genetic code at translation is directly correlated with tRNA identity. This survey describes the molecular signals in tRNAs that trigger specific aminoacylations. For most tRNAs, determinants are located at the two distal extremities: the anticodon loop and the amino acid accepting stem. In a few tRNAs, however, major identity signals are found in the core of the molecule. Identity elements have different strengths, often depend more on k cat effects than on K m effects and exhibit additive, cooperative or anti-cooperative interplay. Most determinants are in direct contact with cognate synthetases, and chemical groups on bases or ribose moieties that make functional interactions have been identified in several systems. Major determinants are conserved in evolution; however, the mechanisms by which they are expressed are species dependent. Recent studies show that alternate identity sets can be recognized by a single synthetase, and emphasize the importance of tRNA architecture and anti-determinants preventing false recognition. Identity rules apply to tRNA-like molecules and to minimalist tRNAs. Knowledge of these rules allows the manipulation of identity elements and engineering of tRNAs with switched, altered or multiple specificities.     

Isolation and characterization of genomic mouse DNA clones containing sequences homologous to tRNAs and 5S rRNA.

We have cloned and characterized three fragments of Balb/c mouse DNA which hybridize to mouse cell tRNAs. Fractionation of the tRNAs which hybridize to these clones reveals that two of the clones, lambda Mt-4A and lambda Mt-6A hybridize to only one or two tRNAs, while one clone, lambda Mt-4B, hybridizes to at least seven tRNAs. Two of the tRNAs were identified as tRNAProCCG and tRNAGlyGGA, and others have been identified as tRNAs which are selectively encapsidated into virions of murine leukemia virus and avian reticuloendotheliosis virus. The DNA sequences of putative genes for tRNAProCCG and tRNAGlyGGA, plus flanking regions, were determined. A clone of Balb/c mouse DNA which selectively hybridized to 5S rRNA was also isolated and partially characterized.     

Comparison of dissimilarity patterns of E coli, yeast and mammalian tRNAs.

A number of experimental approaches have been developed for identification of recognition (identity) sites in tRNAs. Along with them a theoretical methodology has been proposed by McClain et al that is based on concomitant analysis of all tRNA sequences from a given species. This approach allows an evaluation of nucleotide combinations present in isoacceptor tRNAs specific for the given amino acid, and not present in equivalent positions in cloverleaf structure in other tRNAs of the same organism. These elements predicted from computer analysis of the databank could be tested experimentally for their participation in forming recognition sites. The correlation between theoretical predictions and experimental data appeared promising. The aim of the present work consisted of introducing further improvements into McClain's procedure by: i), introducing into analysis a variable region in tRNAs which had not been previously considered; to accomplish this, 'normalization' of variable nucleotides was suggested, based on primary and tertiary structures of tRNAs; ii), developing a new procedure for comparison of patterns for synonymous and non-synonymous tRNAs from different organisms; iii), analysis of 3- and 4-positional contacts between tRNAs and enzymes in addition to a formerly used 2-positional model. A systematic application of McClain's procedure to mammalian, yeast and E coli tRNAs led to the following results: i), imitancy patterns for non-synonymous tRNAs of any amino acid specificity and from any organisms analysed so far overlap by no more than 30%, providing a structural basis for discrimination with high fidelity between cognate and non-cognate tRNAs; ii), the predicted identity sites are non-randomly distributed within tRNA molecules; the dominant role is ascribed to only two regions--anticodon and amino acid stem which are located far apart from one another at extremes of all tRNA molecules; iii), the imitancy patterns for synonymous tRNAs in lower (yeast) and higher (mammalian) eukaryotes are similar but not identical; iv), distribution of predicted identity sites in the cloverleaf structure in prokaryotes and eukaryotes is essentially different: in eubacterial tRNAs the major role in recognition plays anticodon and/or amino acid acceptor stem, whereas in eukaryotic (both unicellular and multicellular) tRNAs the remaining part of the molecules is also involved in recognition; v), the imitancy patterns of synonymous tRNAs from prokaryotes and eukaryotes are dissimilar, this observation leads to the prediction that the tRNA identity sites for the same amino acid in prokaryotes and eukaryotes may differ.     

Selective utilization of 2-thioribothymidine- and ribothymidine-containing tRNAs by the protein synthetic systems of Thermus thermophilus HB 8 depending on the environmental temperature

An extreme thermophile, Thermus thermophilus HB 8, contains two types of tRNAs, T- and S2T-containing tRNAs. Their relative content changes depend on the growth temperature of the bacterial cells (1-3). To elucidate the reason why the extreme thermophile possesses the two types of tRNAs, an attempt was made to clarify how these tRNAs are utilized in in vivo protein synthetic systems of the bacteria cultured at different temperatures. First, a method was developed to isolate active polysomes from the thermophile cells cultured at 55 degrees C, 65 degrees C, and 77 degrees C. Then, tRNAs were separated from the polysomes and the T- and S2T-contents of the tRNAs were determined by HPLC. The relative content of S2T-tRNAs in the polysomes from 77 degrees C cells was much higher than that in bulk tRNAs from whole cells cultured at the same temperature, but the situation was reversed in 50 degrees C cells. These results clearly show that the protein synthetic systems of the thermophile have some selection mechanism to utilize either T- or S2T-containing tRNAs preferentially depending on the environmental temperature.     

Crystallization of transfer ribonucleic acids

A compilation of crystallization experiments of tRNAs published in literature as well as original results are given and discussed in this paper. Up to now 17 different tRNA species originating from Escherichia coli and from the yeast Saccharomyces cerevisiae have been crystallized. All structural tRNA families are represented, namely the tRNAs with large or small extra-loops and among them the initiator tRNAs. The tRNAs with small variable loops (4 to 5 nucleotides), e.g. tRNAAsp and tRNAPhe, yield the best diffracting crystals. Crystalline polymorphism is a common feature; about 100 different crystal forms have been observed, but only 6 among them enabled structure determination studies by X-ray diffraction. Crystallization strongly depends upon experimental parameters such as the presence of polyamines and magnesium as well as upon the purity and the molecular integrity of the tRNAs. Crystals are usually obtained by vapour diffusion methods using salts (e.g. ammonium sulfate), organic solvents (e.g. isopropanol, dioxane or 2-methyl-2,4-pentane diol) or polyethylene glycol as precipitants. A methodological strategy for crystallyzing new tRNA species is described.     

The anticodon and the D-domain sequences are essential determinants for plant cytosolic tRNA(Val) import into mitochondria

In higher plants, one-third to one-half of the mitochondrial tRNAs are encoded in the nucleus and are imported into mitochondria. This process appears to be highly specific for some tRNAs, but the factors that interact with tRNAs before and/or during import, as well as the signals present on the tRNAs, still need to be identified. The rare experiments performed so far suggest that, besides the probable implication of aminoacyl-tRNA synthetases, at least one additional import factor and/or structural features shared by imported tRNAs must be involved in plant mitochondrial tRNA import. To look for determinants that direct tRNA import into higher plant mitochondria, we have transformed BY2 tobacco cells with Arabidopsis thaliana cytosolic tRNA(Val)(AAC) carrying various mutations. The nucleotide replacements introduced in this naturally imported tRNA correspond to the anticodon and/or D-domain of the non-imported cytosolic tRNA(Met-e). Unlike the wild-type tRNA(Val)(AAC), a mutant tRNA(Val) carrying a methionine CAU anticodon that switches the aminoacylation of this tRNA from valine to methionine is not present in the mitochondrial fraction. Furthermore, mutant tRNAs(Val) carrying the D-domain of the tRNA(Met-e), although still efficiently recognized by the valyl-tRNA synthetase, are not imported any more into mitochondria. These data demonstrate that in plants, besides identity elements required for the recognition by the cognate aminoacyl-tRNA synthetase, tRNA molecules contain other determinants that are essential for mitochondrial import selectivity. Indeed, this suggests that the tRNA import mechanism occurring in plant mitochondria may be different from what has been described so far in yeast or in protozoa.     

Nucleotide sequence of Neurospora crassa cytoplasmic initiator tRNA.

Initiator methionine tRNA from the cytoplasm of Neurospora crassa has been purified and sequenced. The sequence is: pAGCUGCAUm1GGCGCAGCGGAAGCGCM22GCY*GGGCUCAUt6AACCCGGAGm7GU (or D) - CACUCGAUCGm1AAACGAG*UUGCAGCUACCAOH. Similar to initiator tRNAs from the cytoplasm of other eukaryotes, this tRNA also contains the sequence -AUCG- instead of the usual -TphiCG (or A)- found in loop IV of other tRNAs. The sequence of the N. crassa cytoplasmic initiator tRNA is quite different from that of the corresponding mitochondrial initiator tRNA. Comparison of the sequence of N. crassa cytoplasmic initiator tRNA to those of yeast, wheat germ and vertebrate cytoplasmic initiator tRNA indicates that the sequences of the two fungal tRNAs are no more similar to each other than they are to those of other initiator tRNAs.     

Changes in transfer ribonucleic acids of Bacillus subtilis during different growth phases

The transfer ribonucleic acids (tRNAs) of B. subtilis at different growth phases are examined for changes in the composition and the methylation of minor constituents. The composition of the tRNAs indicates about equal amounts of adenosine and uridine, and of guanosine and cytidine. About 3-4 residues are present as modified bases in the average tRNA molecule. The net composition of tRNAs appears to remain unaltered during different growth phases. In vitro methylation of tRNAs indicates lack of methyl groups in both exponentially growing cells and spores. In vivo methylation studies show tRNA methylation occurs during the stationary phase in the absence of net tRNA synthesis. Thus, both in vitro and in vivo methylation indicates that the tRNAs in exponentially growing cells do not contain their full complement of modified bases. More complete modification is noted in tRNAs from stationary cells or spores. Hence, tRNA modifications in general are preserved with fidelity even in the dormant spore but the possibility is left open that specific modifications of selected isoacceptors of tRNAs may occur.     

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.