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.     

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.     

Primary and spatial structure of tRNA

The recent achievements in studying of structure of tRNA are considered in the present paper. A brief analysis of the new methods for sequencing tRNA was carried out. Due to the development of these methods about 300 tRNA primary structures have been determined. Comparison of the primary tRNA structures gives us the possibility to divide them into seven classes: prokaryotic initiator tRNAs and eukaryotic initiator tRNAs; prokaryotic elongator tRNAs and eukaryotic elongator tRNAs; archaebacterial tRNAs; and mitochondrial tRNAs of lower and higher eukaryotes. Structural properties of the tRNAs of each of these classes are discussed. The second part of the paper is devoted to the three-dimensional structure of tRNA. Recent data in this field obtained by X-ray crystallographic technique as well as by high-resolution NMR and chemical modification methods are reviewed.     

Another cut for lysine tRNA: application of the hyperprocessing reaction reveals another stabilization strategy in metazoan lysine tRNAs

Recently, we revealed that the cloverleaf structure of some eukaryotic tRNAs is not always stable in vitro, and the denatured structures of these tRNAs are sometimes detected in bacterial RNase P reactions. We have designated the unusual internal cleavage reaction of these tRNAs as hyperprocessing. We have developed this hyperprocessing strategy as a useful tool for examining the stability of the tRNA cloverleaf structure. There are some common features in such unstable, hyperprocessible tRNAs, and the criteria for the hyperprocessing reaction of tRNA are extracted. Metazoan initiator methionine tRNAs and lysine tRNAs commonly fit the criteria, and are predicted to be hyperprocessible. The RNase P reactions of two metazoan lysine tRNAs from Homo sapiens and Caenorhabditis elegans, which fit the criteria, resulted in resistance to the internal cleavage reaction, while one bacterial lysine tRNA from Acholeplasma laidlawii, which also fits the criteria, was internally cleaved by the RNase P. The results showed that the metazoan lysine tRNAs examined are very stable without base modifications even under in vitro conditions. We also examined the 3'-half short construct of the human lysine tRNA, and the results showed that this RNA was internally cleaved by the enzyme. The results indicated that the human lysine tRNA has the ability to be hyperprocessed but is structurally stabilized in spite of lacking base modifications. A comparative study suggested, moreover, that the acceptor-stem bases should take part in the stabilization of metazoan lysine tRNAs. Our data strongly suggest that the cloverleaf shape of other metazoan lysine tRNAs should also be stabilized by means of similar strategies to in the case of human tRNA(Lys3).     

Chromatographic Analyses of Isoaccepting tRNAs from Avian Myeloblastosis Virus

Avian myeloblastosis virus (AMV) 4S RNA was tested for amino acid acceptor activity for 18 of the 20 amino acids. A nonrandom distribution of viral tRNAs was found compared with tRNA from normal liver or from AMV-infected leukemic myeloblasts, confirming previous reports. Methionine and proline tRNAs were considerably enriched, whereas glutamic acid, glutamine, serine, tyrosine, and valine tRNAs were markedly depleted in AMV relative to homologous cellular tRNAs. The seven AMV tRNAs with the greatest amino acid acceptance capacities, which were in order methionine, proline, lysine, arginine, histidine, isoleucine, and threonine tRNAs, were compared with homologous tRNAs from leukemic myeloblasts and liver by reversed-phase 5 chromatography. Of the 25 isoaccepting chromatographic fractions identified, no tRNA species unique to AMV was detected. Only methionyl-tRNA showed a substantial quantitative variation in isoaccepting species compared with the host cell. Thus, viral selectivity for amino acid-specific tRNAs is not, generally, paralleled by selectivity for individual isoaccepting tRNA species. Qualitative differences in arginyl- and histidyl-tRNA isoaccepting species were discovered in virus and leukemic myeloblasts compared with liver. This indicates the existence of structural differences in these tRNA species which could be related to virus replication or expression.     

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.     

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.     

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.     

Cytosolic yeast tRNA(His) is covalently modified when imported into mitochondria of Trypanosoma brucei.

The mitochondrial genome of Trypanosoma brucei does not encode any tRNAs. Instead, mitochondrial tRNAs are synthesized in the nucleus and subsequently imported into mitochondria. The great majority of mitochondrial tRNAs have cytosolic counterparts showing identical primary sequences. The only difference found between mitochondrial and cytosolic isotypes of the tRNAs are mitochondria-specific nucleotide modifications which appear to be a common feature of imported tRNAs in trypanosomes. In this study, a mutated yeast cytosolic tRNAHis was expressed in trypanosomes and its import phenotype was analyzed by cell fractionation and nuclease treatment of intact mitochondria. Furthermore, cytosolic and mitochondrial isotypes of the yeast tRNA(His) were specifically labeled and analyzed by limited alkaline hydrolysis. These experiments revealed the presence of mitochondria-specific nucleotide modifications in the yeast tRNA(His). The positions of the modifications were determined by direct enzymatic sequencing of the tRNA(His) and shown to correspond to the ultimate and penultimate nucleotides before the anticodon, the same relative positions which are modified in the mitochondrial isotype of trypanosomal tRNA(Tyr). The results demonstrate that covalent modification of tRNAs; in trypanosomal mitochondria can be used, in analogy to processing of precursor proteins during mitochondrial protein import, as a marker for import of both endogenous and heterologous tRNAs.     

Levels of tRNAs in bacterial cells as affected by amino acid usage in proteins.

Transfer RNAs of Mycoplasma capricolum were separated by two-dimensional polyacrylamide gel electrophoresis, and the relative abundance of each of the 28 known tRNA species was measured. There existed a correlation between the relative amount of isoacceptor tRNAs and the frequency in choosing synonymous codons that could be translated by the isoacceptors. Furthermore, it was observed that the total amount of tRNAs for a particular amino acid was paralleled by the composition of the amino acid in ribosomal proteins. A similar relationship was obtained from reexamination of the previous data on Escherichia coli tRNAs, suggesting that the amount of tRNAs for an amino acid is affected by the usage of the amino acid in proteins.     

tRNAs are imported into mitochondria of Trypanosoma brucei independently of their genomic context and genetic origin.

The mitochondrial genome of Trypanosoma brucei does not encode any identifiable tRNAs. Instead, mitochondrial tRNAs are synthesized in the nucleus and subsequently imported into mitochondria. In order to analyse the signals which target the tRNAs into the mitochondria, an in vivo import system has been developed: tRNA variants were expressed episomally and their import into mitochondria assessed by purification and nuclease treatment of the mitochondrial fraction. Three tRNA genes were tested in this system: (i) a mutated version of the trypanosomal tRNA(Tyr); (ii) a cytosolic tRNA(His) of yeast; and (iii) a human cytosolic tRNA(Lys). The tRNAs were expressed in their own genomic context, or containing various lengths of the 5'-flanking sequence of the trypanosomal tRNA(Tyr) gene. In all cases efficient import of each of the tRNAs was observed. We independently confirmed the mitochondrial import of the yeast tRNA(His), since in organello [alpha-32P]ATP-labelling of the 3'-end of the tRNA was inhibited by carboxyatractyloside, a highly specific inhibitor of the mitochondrial adenine nucleotide translocator. Import of heterologous tRNAs in their own genomic contexts supports the conclusion that no specific targeting signals are necessary to import tRNAs into mitochondria of T. brucei, but rather that the tRNA structure itself is sufficient to specify import.     

Mitochondrial tRNAs in the lower fungus Spizellomyces punctatus: tRNA editing and UAG 'stop' codons recognized as leucine.

The mitochondrial DNA of the chytridiomycete fungus Spizellomyces punctatusen codes only eight tRNAs, although a minimal set of 24-25 tRNAs is normally found in fungi. One of these tRNAs has a CAU anticodon and is structurally related to leucine tRNAs, which would permit the translation of the UAG 'stop' codons that occur in most of its protein genes. The predicted structures of all S. punctatus tRNAs have the common feature of containing one to three mis-pairings in the first three positions of their acceptor stems. Such mis-pairing is expected to impair proper folding and processing of tRNAs from their precursors. Five of these eight RNAs were shown to be edited at the RNA level, in the 5'portion of the molecules. These changes include both pyrimidine to purine and A to G substitutions that restore normal pairing in the acceptor stem. Editing was not found at other positions of the tRNAs, or in the mitochondrial mRNAs of S. punctatus. While tRNA editing has not been observed in other fungi, the editing pattern inS.punctatus is virtually identical to that described in the amoeboid protozoan Acanthamoeba castellanii. If this type of mitochondrial tRNA editing has originated from their common ancestor, one has to assume that it was independently lost in plants, animals and in most fungi. Alternatively, editing might have evolved independently, or the genes coding for the components of the editing machinery were laterally transferred.     

Transfer RNAs of potato (Solanum tuberosum) mitochondria have different genetic origins.

Total transfer RNAs were extracted from highly purified potato mitochondria. From quantitative measurements, the in vivo tRNA concentration in mitochondria was estimated to be in the range of 60 microM. Total potato mitochondrial tRNAs were fractionated by two-dimensional polyacrylamide gel electrophoresis. Thirty one individual tRNAs, which could read all sense codons, were identified by aminoacylation, sequencing or hybridization to specific oligonucleotides. The tRNA population that we have characterized comprises 15 typically mitochondrial, 5 'chloroplast-like' and 11 nuclear-encoded species. One tRNA(Ala), 2 tRNAs(Arg), 1 tRNA(Ile), 5 tRNAs(Leu) and 2 tRNAs(Thr) were shown to be coded for by nuclear DNA. A second, mitochondrial-encoded, tRNA(Ile) was also found. Five 'chloroplast-like' tRNAs, tRNA(Trp), tRNA(Asn), tRNA(His), tRNA(Ser)(GGA) and tRNA(Met)m, presumably transcribed from promiscuous chloroplast DNA sequences inserted in the mitochondrial genome, were identified, but, in contrast to wheat (1), potato mitochondria do not seem to contain 'chloroplast-like' tRNA(Cys) and tRNA(Phe). The two identified tRNAs(Val), as well as the tRNA(Gly), were found to be coded for by the mitochondrial genome, which again contrasts with the situation in wheat, where the mitochondrial genome apparently contains no tRNA(Val) or tRNA(Gly) gene (2).     

ISOACCEPTOR tRNAs FOR GLUTAMATE, GLUTAMINE, ASPARTATE AND ASPARAGINE IN CALF BRAIN

Abstract— Glutamyl, glutaminyl. aspartyl and asparaginyl tRNAs of calf brain were analysed by reverse phase chromatography for isoacceptor tRNAs. The radioactivity profiles revealed two peaks for gluta-mate. three for glutamine, two for aspartate and one for asparagine. Comparison of brain tRNAs with tRNAs from other sources showed that glutamate and aspartate tRNAs of brain closely resembled a majority of other tRNAs in the number and relative abundance of isoacceptors. Glutamine and asparagine tRNAs from different sources exhibited more marked differences.     

The T-stem determines the cytosolic or mitochondrial localization of trypanosomal tRNAsMet

The mitochondrion of Trypanosoma brucei lacks tRNA genes. Organellar translation therefore depends on import of cytosolic, nucleus-encoded tRNAs. Except for the cytosol-specific initiator tRNA(Met), all trypanosomal tRNAs function in both the cytosol and the mitochondrion. The initiator tRNA(Met) is closely related to the imported elongator tRNA(Met). Thus, the distinct localization of the two tRNAs(Met) must be specified by the 26 nucleotides, which differ between the two molecules. Using transgenic T. brucei cell lines and subsequent cell fractionation, we show that the T-stem is both required and sufficient to specify the localization of the tRNAs(Met). Furthermore, it was shown that the tRNA(Met) T-stem localization determinants are also functional in the context of two other tRNAs. In vivo analysis of the modified nucleotides found in the initiator tRNA(Met) indicates that the T-stem localization determinants do not require modified nucleotides. In contrast, import of native tRNAs(Met) into isolated mitochondria suggests that nucleotide modifications might be involved in regulating the extent of import of elongator tRNA(Met).     

Macromolecular recognition through electrostatic repulsion.

In the process of genetic translation, each aminoacyl-tRNA synthetase specifically aminoacylates its cognate tRNAs and rejects the 19 other species of tRNAs. A decrease in the specificity of this reaction can result in misincorporations of amino acids into proteins and be deleterious to the cell. In the case of tyrosyl-tRNA synthetase from Bacillus stearothermophilus, the change of residue Glu152 into Ala results in erroneous interactions with non-cognate tRNAs. To analyse how Glu152 contributes to the discrimination between tRNAs by tyrosyl-tRNA synthetase, 11 changes to this residue were created by mutagenesis. The misaminoacylations of tRNA(Phe) and tRNA(Val) with tyrosine in vitro (on a scale going from 1 to 30) and the toxicity of tyrosyl-tRNA synthetase in vivo (on a scale from 1 to 10(7)) increased in a correlated way when the nature of the side chain in position 152 varied from negatively charged to uncharged then to positively charged. The aminoacylation of tRNA(Tyr) was unaffected by the mutations. The results show that the role of Glu152 in the discrimination between tRNAs is purely negative, that it acts by electrostatic repulsion of non-cognate tRNAs and that this mechanism has been conserved throughout evolution.