Mitochondrial tRNA import: are there distinct mechanisms?

Sequence information from an increasing number of complete mitochondrial genomes indicates that a large number of evolutionary distinct organisms import nucleus-encoded tRNAs. In the past five years, much research has been initiated on the features of imported tRNAs, the mechanism and the energetics of the process as well as on the components of the import machinery. In summary, these studies show that the import systems of different species exhibit some unique features, suggesting that more than one mechanism might exist to import tRNAs.     

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.     

Codon recognition patterns as deduced from sequences of the complete set of transfer RNA species in Mycoplasma capricolum. Resemblance to mitochondria

The nucleotide sequences of the complete set of tRNA species in Mycoplasma capricolum, a derivative of Gram-positive eubacteria, have been determined. This bacterium represents the first genetic system in which the sequences of all the tRNA species have been determined at the RNA level. There are 29 tRNA species: three for Leu, two each for Arg, Ile, Lys, Met, Ser, Thr and Trp, and one each for the other 12 amino acids as judged from aminoacylation and the anticodon nucleotide sequences. The number of tRNA species is the smallest among all known genetic systems except for mitochondria. The tRNA anticodon sequences have revealed several features characteristic of M. capricolum. (1) There is only one tRNA species each for Ala, Gly, Leu, Pro, Ser and Val family boxes (4-codon boxes), and these tRNAs all have an unmodified U residue at the first position of the anticodon. (2) There are two tRNAThr species having anticodons UGU and AGU; the first positions of these anticodons are unmodified. (3) There is only one tRNA with anticodon ICG in the Arg family box (CGN); this tRNA can translate codons CGU, CGC and CGA. No tRNA capable of translating codon CGG has been detected, suggesting that CGG is an unassigned codon in this bacterium. (4) A tRNATrp with anticodon UCA is present, and reads codon UGA as Trp. On the basis of these and other observations, novel codon recognition patterns in M. capricolum are proposed. A comparatively small total, 13, of modified nucleosides is contained in all M. capricolum tRNAs. The 5' end nucleoside of the T psi C-loop (position 54) of all tRNAs is uridine, not modified to ribothymidine. The anticodon composition, and hence codon recognition patterns, of M. capricolum tRNAs resemble those of mitochondrial tRNAs.     

The mitochondrial genome of Saprolegnia ferax: organization, gene content and nucleotide sequence

The mitochondrial genome of the peronosporomycete water mold Saprolegnia ferax has been characterized as a 46 930 bp circle containing an 8618 bp large inverted repeat (LIR). Eighteen reading frames encode identified subunits of respiratory complexes I, III, IV and V; 16 encode polypeptides of small and large mitoribosome subunits; and one encodes a subunit of the sec-independent protein translocation pathway. Of four additional putative reading frames three are homologues of those found in the related Phytophthora infestans genome. Protein encoding loci in the tightly compacted genome typically are arranged in operon-like clusters including three abutting and two overlapping pairs of reading frames. Translational RNAs include the mitochondrial small and large subunit rRNAs and 25 tRNA species. No tRNAs are encoded to enable translation of any threonine or the arginine CGR codons. The LIR separates the molecule into 19 274 bp large and 10 420 bp small single copy regions, and it encodes intact duplicate copies of four reading frames encoding known proteins, both rRNAs, and five tRNAs. Partial 3' sequences of three additional reading frames are duplicated at single copy sequence junctions. Active recombination between LIR elements generates two distinctive gene orders and uses the duplicated 3' sequences to maintain intact copies of the partially duplicated loci.     

Diversity and similarity in the tRNA world: Overall view and case study on malaria-related tRNAs

Transfer RNAs (tRNAs) are ancient macromolecules that have evolved under various environmental pressures as adaptors in translation in all forms of life but also towards alternative structures and functions. The present knowledge on both “canonical” and “deviating” signature motifs retrieved from vertical and horizontal sequence comparisons is briefly reviewed. Novel characteristics, proper to tRNAs from a given translation system, are revealed by a case study on the nuclear and organellar tRNA sets from malaria-related organisms. Unprecedented distinctive features for Plasmodium falciparum apicoplastic tRNAs appear, which provide novel routes to be explored towards anti-malarial drugs. The ongoing high-throughput sequencing programs are expected to allow for further horizontal comparisons and to reveal other signatures of either full or restricted sets of tRNAs.     

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).     

Nucleotide sequences of two serine tRNAs with a GGA anticodon: the structure-function relationships in the serine family of E. coli tRNAs.

We have determined the nucleotide sequence of the major species of E. coli tRNASer and of a minor species having the same GGA anticodon. These two tRNAs should recognize the UCC and UCU codons, the most widely used codons for serine in the highly expressed genes of E. coli. The two sequences differ in only one position of the D-loop. Neither tRNA has a modified adenosine in the position 3'-adjacent to the anticodon. This can be rationalized on the basis of a structural constraint in the anticodon stem and may be related to optimization of the codon-anticodon interaction. Comparison of all E.coli serine tRNAs (and that encoded by bacteriophage T4) reveals characteristic (possibly functional) features. Evolutionary analysis suggests an eubacterial origin of the T4 tRNASer gene and the existence of a recent common ancestor for the tRNASerGGA and tRNASerGUC genes.     

Nucleotide sequence of a spinach chloroplast proline tRNA.

The nucleotide sequence of a spinach chloroplast proline tRNA (sp. chl. tRNApro) has been determined. This tRNA shows more overall homology to phage T4 proline tRNA (61% homology) than to eukaryotic proline tRNAs (53% homology) or mitochondrial proline tRNAs (36-49% homology). Sp. chl. tRNApro, like all other chloroplast tRNAs sequenced, contains a methylated GG sequence in the dihyrouridine loop and lacks unusual structural features which have been found in many mitochondrial tRNAs.     

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.     

Suppression of amber codons in vivo as evidence that mutants derived from Escherichia coli initiator tRNA can act at the step of elongation in protein synthesis

The absence of a Watson-Crick base pair at the end of the amino acid acceptor stem is one of the features which distinguishes prokaryotic initiator tRNAs as a class from all other tRNAs. We show that this structural feature prevents Escherichia coli initiator tRNA from acting as an elongator in protein synthesis in vivo. We generated a mutant of E. coli initiator tRNA in which the anticodon sequence is changed from CAU to CUA (the T35A36 mutant). This mutant tRNA has the potential to read the amber termination codon UAG. We then coupled this mutation to others which change the C1.A72 mismatch at the end of the acceptor stem to either a U1:A72 base pair (T1 mutant) or a C1:G72 base pair (G72 mutant). Transformation of E. coli CA274 (HfrC Su- lacZ125am trpEam) with multicopy plasmids carrying the mutant initiator tRNA genes show that mutant tRNAs carrying changes in both the anticodon sequence and the acceptor stem suppress amber codons in vivo, whereas mutant tRNA with changes in the anticodon sequence alone does not. Mutant tRNAs with the above anticodon sequence change are aminoacylated with glutamine in vitro. Measurement of kinetic parameters for aminoacylation by E. coli glutaminyl-tRNA synthetase show that both the nature of the base pair at the end of the acceptor stem and the presence or absence of a base pair at this position can affect aminoacylation kinetics. We discuss the implications of this result on recognition of tRNAs by E. coli glutaminyl-tRNA synthetase.     

Transfer RNA recognition by aminoacyl-tRNA synthetases

The aminoacyl-tRNA synthetases are an ancient group of enzymes that catalyze the covalent attachment of an amino acid to its cognate transfer RNA. The question of specificity, that is, how each synthetase selects the correct individual or isoacceptor set of tRNAs for each amino acid, has been referred to as the second genetic code. A wealth of structural, biochemical, and genetic data on this subject has accumulated over the past 40 years. Although there are now crystal structures of sixteen of the twenty synthetases from various species, there are only a few high resolution structures of synthetases complexed with cognate tRNAs. Here we review briefly the structural information available for synthetases, and focus on the structural features of tRNA that may be used for recognition. Finally, we explore in detail the insights into specific recognition gained from classical and atomic group mutagenesis experiments performed with tRNAs, tRNA fragments, and small RNAs mimicking portions of tRNAs.     

Messenger ribonucleic acid of the lipoprotein of the Escherichia coli outer membrane. II. The complete nucleotide sequence

The complete nucleotide sequence of the mRNA for the outer membrane lipoprotein from Escherichia coli has been determined. All the ribonuclease T1 and ribonuclease A fragments obtained from the mRNA were connected with DNA sequencing of restriction endonuclease fragments of the cloned lipoprotein gene. The mRNA consists of 322 nucleotides, and there are 38 and 50 nucleotides in the 5' and 3' end untranslated regions, respectively. The mRNA has several unique features: (a) Out of 50 possible codons for 15 amino acids in the prolipoprotein only 25 codons are used, and all of these appear to be read by the major isoaccepting species of tRNAs for individual amino acids. (b) In the first 64 nucleotides from the 5' end, there are no obvious secondary structures. On the other hand, between the 65th nucleotide and the 3' end, 85% of the nucleotides are involved in the formation of secondary structures, with nine stable stem-and-loop structures. (c) There are many repeating sequences including one repeat of 40 nucleotides. (d) There are a few other features which could be important for efficient translation of the mRNA.     

Mature methyl-deficient tRNA isolated from a mammary adenocarcinoma

A transplantable rat tumor, mammary adenocarcinoma 13762, accumulates tRNA which can be methylated in vitro by mammalian tRNA (adenine-1) methyltransferase. This unusual ability of the tumor RNA to serve as substrate for a homologous tRNA methylating enzyme is correlated with unusually low levels of the A₅₈-specific adenine-1 methyltransferase. The nature of the methyl-accepting RNA has been examined by separating tumor tRNA on two-dimensional polyacrylamide gels. Comparisons of ethidium bromide-stained gels of tumor vs. liver tRNA show no significant quantitative differences and no accumulation of novel tRNAs or precursor tRNAs in adenocarcinoma RNA. Two-dimensional separations of tumor RNA after in vitro [¹⁴C]methylation using purified adenine-1 methyltransferase indicate that about 25% of the tRNA species are strongly methyl-accepting RNAs. Identification of six of the tRNAs separated on two-dimensional gels has been carried out by hybridization of cloned tRNA genes to Northern blots. Three of these, tRNA^Lys3, tRNA^Gln and tRNA^Met_i, are among the adenocarcinoma methyl-accepting RNAs. The other three RNAs, all of which are leucine-specific tRNAs, show no methyl-accepting properties. Our results suggest that low levels of a tRNA methyltransferase in the adenocarcinoma cause selected species of tRNA to escape the normal A₅₈ methylation, resulting in the appearance of several mature tRNAs which are deficient in 1-methyladenine. The methyl-accepting tRNAs from the tumor appear as ethidium bromide-stained spots of similar intensity to those seen for RNA from rat liver; therefore, methyladenine deficiency does not seem to impair processing of these tRNAs.     

Evolutionary constraints on the plastid tRNA set decoding methionine and isoleucine

The plastid (chloroplast) genomes of seed plants typically encode 30 tRNAs. Employing wobble and superwobble mechanisms, most codon boxes are read by only one or two tRNA species. The reduced set of plastid tRNAs follows the evolutionary trend of organellar genomes to shrink in size and coding capacity. A notable exception is the AUN codon box specifying methionine and isoleucine, which is decoded by four tRNA species in nearly all seed plants. However, three of these four tRNA genes were lost from the genomes of some parasitic plastid-containing lineages, possibly suggesting that less than four tRNA species could be sufficient to decode the triplets in the AUN box. To test this hypothesis, we have performed knockout experiments for the four AUN-decoding tRNAs in tobacco (Nicotiana tabacum) plastids. We find that all four tRNA genes are essential under both autotrophic and heterotrophic growth conditions, possibly suggesting tRNA import into plastids of parasitic plastid-bearing species. Phylogenetic analysis of the four plastid tRNA genes reveals striking conservation of all those bacterial features that are involved in discrimination between the different tRNA species containing CAU anticodons.     

Nucleotide sequence of the mitochondrial structural genes for cysteine-tRNA and histidine-tRNA of yeast.

We have determined the nucleotide sequence of a segment of Saccharomyces cerevisiae mtDNA that contains the structural genes for a cysteine-tRNA and a histidine-tRNA. The genes are approximately 85 bp apart, they do not contain intervening sequences or sequences coding for the 3'-CCA terminus and they are surrounded by nearly pure AT segments. The tRNAs deduced are very AT-rich, 74 and 75 nucleotides long, respectively, and contain one or more unusual features not found in tRNAs from other sources.     

Identification of novel genomic islands associated with small RNAs

Genome evolution in prokaryotes is assisted by integration of gene pools from phages and plasmids. Regions downstream of tRNAs and tmRNAs are considered as hot spots for the integration of these gene pools or genomic islands. Till date, genomic islands have been identified only at tRNA/tmRNA genes in the enterobacterial genomes. Present work reports 10 distinct small RNAs as potent integration sites for genomic islands. A known tool tRNAcc 1.0 has been used to identify genomic islands associated with small RNAs c0362, oxyS, ryaA, rybB, rybD, ryeB, ryeE, rtT, sraE and tmRNA. The coordinates of 25 such small RNA associated genomic islands in three E. coli (strains: CFT073, EDL933 and K12) and Shigella flexneri (strain: 301) genomes are presented. Moreover cross-verification of the genomic sequences encoded within the identified genomic islands in horizontal gene transfer database, GenBank annotation features and atypical sequence compositions support our results. Again, all of the identified 25 genomic integration sites do exhibit genomic block rearrangements with respect to the associated small RNA. Similar to tRNAs/tmRNAs, the downstream regions of the small RNAs are found to be hotspots of integration.     

tRNAscan-SE 2.0: improved detection and functional classification of transfer RNA genes

tRNAscan-SE has been widely used for transfer RNA (tRNA) gene prediction for over twenty years, developed just as the first genomes were decoded. With the massive increase in quantity and phylogenetic diversity of genomes, the accurate detection and functional prediction of tRNAs has become more challenging. Utilizing a vastly larger training set, we created nearly one hundred specialized isotype- and clade-specific models, greatly improving tRNAscan-SE’s ability to identify and classify both typical and atypical tRNAs. We employ a new comparative multi-model strategy where predicted tRNAs are scored against a full set of isotype-specific covariance models, allowing functional prediction based on both the anticodon and the highest-scoring isotype model. Comparative model scoring has also enhanced the program''s ability to detect tRNA-derived SINEs and other likely pseudogenes. For the first time, tRNAscan-SE also includes fast and highly accurate detection of mitochondrial tRNAs using newly developed models. Overall, tRNA detection sensitivity and specificity is improved for all isotypes, particularly those utilizing specialized models for selenocysteine and the three subtypes of tRNA genes encoding a CAU anticodon. These enhancements will provide researchers with more accurate and detailed tRNA annotation for a wider variety of tRNAs, and may direct attention to tRNAs with novel traits.     

Search for characteristic structural features of mammalian mitochondrial tRNAs

A number of mitochondrial (mt) tRNAs have strong structural deviations from the classical tRNA cloverleaf secondary structure and from the conventional L-shaped tertiary structure. As a consequence, there is a general trend to consider all mitochondrial tRNAs as "bizarre" tRNAs. Here, a large sequence comparison of the 22 tRNA genes within 31 fully sequenced mammalian mt genomes has been performed to define the structural characteristics of this specific group of tRNAs. Vertical alignments define the degree of conservation/variability of primary sequences and secondary structures and search for potential tertiary interactions within each of the 22 families. Further horizontal alignments ascertain that, with the exception of serine-specific tRNAs, mammalian mt tRNAs do fold into cloverleaf structures with mostly classical features. However, deviations exist and concern large variations in size of the D- and T-loops. The predominant absence of the conserved nucleotides G18G19 and T54T55C56, respectively in these loops, suggests that classical tertiary interactions between both domains do not take place. Classification of the tRNA sequences according to their genomic origin (G-rich or G-poor DNA strand) highlight specific features such as richness/poorness in mismatches or G-T pairs in stems and extremely low G-content or C-content in the D- and T-loops. The resulting 22 "typical" mammalian mitochondrial sequences built up a phylogenetic basis for experimental structural and functional investigations. Moreover, they are expected to help in the evaluation of the possible impacts of those point mutations detected in human mitochondrial tRNA genes and correlated with pathologies.