Study of yeast mitochondrial tRNAs by two-dimensional polyacrylamide gel electrophoresis: characterization of isoaccepting species and search for imported cytoplasmic tRNAs.

By two-dimensional polyacrylamide gel electrophoresis, yeast mitochondrial tRNA is fractionated into 27 major species. All but 6 of them migrate distinctly from cytoplasmic tRNAs. Migration of mitochondrial DNA-coded mitochondrial tRNAs shows the occurence of only one cytoplasmic tRNA in mitochondria. Several mitochondrial tRNA spots are identified on the electrophoregrams, some of them show isoaccepting species (Val, Ser, Met, Leu). It is suggested that there are sufficient mitochondrial tRNA genes on yeast mitochondrial DNA to allow mitochondrial protein biosynthesis by the mitochondrial tRNAs alone. Guanosine + Cytidine content and rate base composition are reported for some individual species. Mitochondrial tRNAPhe lacks Ribothymidine.     

Identification of nuclear encoded precursor tRNAs within the mitochondrion of Trypanosoma brucei.

RNAs that function in mitochondria are typically encoded by the mitochondrial DNA. However, the mitochondrial tRNAs of Trypanosoma brucei are encoded by the nuclear DNA and therefore must be imported into the mitochondrion. It is becoming evident that RNA import into mitochondria is phylogenetically widespread and is essential for cellular processes, but virtually nothing is known about the mechanism of RNA import. We have identified and characterized mitochondrial precursor tRNAs in T. brucei. The identification of mitochondrially located precursor tRNAs clearly indicates that mitochondrial tRNAs are imported as precursors. The mitochondrial precursor tRNAs hybridize to cloned nuclear tRNA genes, label with [alpha-32P]CTP using yeast tRNA nucleotidyltransferase and in isolated mitochondria via an endogenous nucleotidyltransferase-like activity, and are processed to mature tRNAs by Escherichia coli and yeast mitochondrial RNase P. We show that T. brucei mitochondrial extract contains an RNase P activity capable of processing a prokaryotic tRNA precursor as well as the T. brucei tRNA precursors. Precursors for tRNA(Asn) and tRNA(Leu) were detected on Northern blots of mitochondrial RNA, and the 5' ends of these RNAs were characterized by primer extension analysis. The structure of the precursor tRNAs and the significance of nuclear encoded precursor tRNAs within the mitochondrion are discussed.     

Yeast mitochondrial methionine initiator tRNA: characterization and nucleotide sequence.

Two methionine tRNAs from yeast mitochondria have been purified. The mitochondrial initiator tRNA has been identified by formylation using a mitochondrial enzyme extract. E. coli transformylase however, does not formylate the yeast mitochondrial initiator tRNA. The sequence was determined using both 32P-in vivo labeled and 32P-end labeled mt tRNAf(Met). This tRNA, unlike N. crassa mitochondrial tRNAf(Met), has two structural features typical of procaryotic initiator tRNAs: (i) it lacks a Watson-Crick base-pair at the end of the acceptor stem and (ii) has a T-psi-C-A sequence in loop IV. However, both yeast and N. crassa mitochondrial initiator tRNAs have a U11:A24 base-pair in the D-stem unlike procaryotic initiator tRNAs which have A11:U24. Interestingly, both mitochondrial initiator tRNAs, as well as bean chloroplast tRNAf(Met), have only two G:C pairs next to the anticodon loop, unlike any other initiator tRNA whatever its origin. In terms of overall sequence homology, yeast mitochondrial tRNA(Met)f differs from both procaryotic or eucaryotic initiator tRNAs, showing the highest homology with N. crassa mitochondrial initiator tRNA.     

Deletion of the MTO2 gene related to tRNA modification causes a failure in mitochondrial RNA metabolism in the yeast Saccharomyces cerevisiae

We report here the characterization of the yeast mto2 null mutants carrying wild-type mitochondrial DNA or 15S rRNA C1049G allele. The amounts of mitochondrial tRNA(Lys), tRNA(Glu), tRNA(Gln), tRNA(Leu), tRNA(Gly) and tRNA(Met) were markedly decreased but those of tRNA(Arg) and tRNA(His) were not affected in mto2 strains. The mto2 strains exhibited significant reduction in the aminoacylation of tRNA(Lys), tRNA(Leu) but almost no effect in those of tRNA(His). Interestingly, the strain carrying the C1049G allele exhibited an impairment of aminoacylation of those tRNAs. Furthermore, the steady-state levels of mitochondrial mRNA CYTB, COX1, COX2, COX3, and ATP6 were markedly decreased in mto2 strains. These data strongly indicate that unmodified tRNA caused by the deletion of MTO2 caused the instability of mitochondrial tRNAs and mRNAs and impairment of aminoacylation of tRNAs.     

Characterization of a yeast mitochondrial locus necessary for tRNA biosynthesis. Deletion mapping and restriction mapping studies

Yeast mitochondrial DNA codes for a complete set of tRNAs. Although most components necessary for the biosynthesis of mitochondrial tRNA are coded by nuclear genes, there is one genetic locus on mitochondrial DNA necessary for the synthesis of mitochondrial tRNAs other than the mitochondrial tRNA genes themselves. Characterization of mutants by deletion mapping and restriction enzyme mapping studies has provided a precise location of this yeast mitochondrial tRNA synthesis locus. Deletion mutants retaining various segments of mitochondrial DNA were examined for their ability to synthesize tRNAs from the genes they retain. A subset of these strains was also tested for the ability to provide the tRNA synthesis function in complementation tests with deletion mutants unable to synthesize mature mitochondrial tRNAs. By correlating the tRNA synthetic ability with the presence or absence of certain wild-type restriction fragments, we have confined the locus to within 780 base pairs of DNA located between the tRNAMetf gene and tRNAPro gene, at 29 units on the wild-type map. Heretofore, no genetic function or gene product had been localized in this area of the yeast mitochondrial genome.     

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).     

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).     

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.     

O-ribosyl-phosphate purine as a constant modified nucleotide located at position 64 in cytoplasmic initiator tRNAs(Met) of yeasts.

The unknown modified nucleotide G*, isolated from both Schizosaccharomyces pombe and Torulopsis utilis initiator tRNAs(Met), has been identified as an O-ribosyl-(1"----2')-guanosine-5"-phosphate, called Gr(p), by means of HPLC, UV-absorption, mass spectrometry and periodate oxidation procedures. By comparison with the previously published structure of Ar(p) isolated from Saccharomyces cerevisiae initiator tRNA(Met), the (1"----2')-glycosidic bond in Gr(p) has been postulated to have a beta-spatial conformation. The modified nucleotide Gr(p) is located at position 64 in the tRNA(Met) molecules, i.e. at the same position as Ar(p). Since we have also characterized Gr(p) in Candida albicans initiator tRNA(Met), the phosphoribosylation of purine 64 can be considered as a constant nucleotide modification in the cytoplasmic initiator tRNAs(Met) of all yeast species so far sequenced. Precise evidence for the presence of Gr(p) in initiator tRNAs(Met) of several plants is also reported.     

Regulation of tRNA Bidirectional Nuclear-Cytoplasmic Trafficking in Saccharomyces cerevisiae

tRNAs in yeast and vertebrate cells move bidirectionally and reversibly between the nucleus and the cytoplasm. We investigated roles of members of the β-importin family in tRNA subcellular dynamics. Retrograde import of tRNA into the nucleus is dependent, directly or indirectly, upon Mtr10. tRNA nuclear export utilizes at least two members of the β-importin family. The β-importins involved in nuclear export have shared and exclusive functions. Los1 functions in both the tRNA primary export and the tRNA reexport processes. Msn5 is unable to export tRNAs in the primary round of export if the tRNAs are encoded by intron-containing genes, and for these tRNAs Msn5 functions primarily in their reexport to the cytoplasm. The data support a model in which tRNA retrograde import to the nucleus is a constitutive process; in contrast, reexport of the imported tRNAs back to the cytoplasm is regulated by the availability of nutrients to cells and by tRNA aminoacylation in the nucleus. Finally, we implicate Tef1, the yeast orthologue of translation elongation factor eEF1A, in the tRNA reexport process and show that its subcellular distribution between the nucleus and cytoplasm is dependent upon Mtr10 and Msn5.     

Interaction of elongation factor Tu from Escherichia coli with aminoacyl-tRNA carrying a fluorescent reporter group on the 3' terminus

Transfer ribonucleic acids containing 2-thiocytidine in position 75 ([s2C]tRNAs) were prepared by incorporation of the corresponding cytidine analogue into 3'-shortened tRNA using ATP(CTP):tRNA nucleotidyltransferase. [s2C]tRNA was selectively alkylated with fluorescent N-iodoacetyl-N'-(5-sulfo-1-naphthyl)ethylenediamine (1,5-I-AEDANS) on the 2-thiocytidine residue. The product [AEDANS-s2C]aminoacyl-tRNA, forms a ternary complex with Escherichia coli elongation factor Tu and GTP, leading to up to 130% fluorescence enhancement of the AEDANS chromophore. From fluorescence titration experiments, equilibrium dissociation constants of 0.24 nM, 0.22 nM and 0.60 nM were determined for yeast [AEDANS-s2C]Tyr-tRNATyr, yeast Tyr-tRNATyr, and the homologous E. coli Phe-tRNAPhe, respectively, interacting with E. coli elongation factor Tu.GTP. The measurement of the association and dissociation rates of the interaction of [AEDANS-s2C]Tyr-tRNATyr with EF-Tu.GTP and the temperature dependence of the resulting dissociation constants gave values of 55 J mol-1 K-1 for delta S degrees' and -34.7 kJ mol-1 for delta H degrees' of this reaction.     

Evidence for two types of complexes formed by yeast tyrosyl-tRNA synthetase with cognate and non-cognate tRNA. Effect of ribonucleoside triphosphates

Polyacrylamide gel electrophoresis at pH 8.3 was used to detect and quantitate the formation of the yeast tyrosyl-tRNA synthetase (an alpha 2-type enzyme) complex with its cognate tRNA. Electrophoretic mobility of the complex is intermediate between the free enzyme and free tRNA; picomolar quantities can be readily detected by silver staining and quantitated by densitometry of autoradiograms when [32P]tRNA is used. Two kinds of complexes of Tyr-tRNA synthetase with yeast tRNA(Tyr) were detected. A slower-moving complex is formed at ratios of tRNA(Tyr)/enzyme less than or equal to 0.5; it is assigned the composition tRNA.(alpha 2)2. At higher ratios, a faster-moving complex is formed, approaching saturation at tRNA(Tyr)/enzyme = 1; any excess of tRNA(Tyr) remains unbound. This complex is assigned the composition tRNA.alpha 2. The slower, i.e. tRNA.(alpha 2)2 complex, but not the faster complex, can be formed even with non-cognate tRNAs. Competition experiments show that the affinity of the enzyme towards tRNA(Tyr) is at least 10-fold higher than that for the non-cognate tRNAs. ATP and GTP affect the electrophoretic mobility of the enzyme and prevent the formation of tRNA.(alpha 2)2 complexes both with cognate and non-cognate tRNAs, while neither tyrosine, as the third substrate of Tyr tRNA synthetase, nor AMP, AMP/PPi, or spermidine, have such effects. Hence, the ATP-mediated formation of the alpha 2 structure parallels the increase in specificity of the enzyme towards its cognate tRNA.     

Isolation of yeast tRNALeu genes. DNA sequence of a cloned tRNALeu3 gene.

A library of cloned yeast DNA fragments generated by digestion of yeast DNA with the restriction endonuclease Bam HI has been screened by colony hybridization to total yeast [32P]tRNA. Four hundred colonies carrying yeast tRNA genes were isolated. By hybridization to 125I-tRNALeu3, we have isolated from this collection 14 colonies carrying fragments containing yeast tRNALeu genes. The size of the yeast Bam HI inserts ranged from 2.45 x 10(6) to 14 x 10(6) daltons. One of these fragments was mapped in detail by restriction endonuclease digestion and hybridization to 125I-tRNALeu3. The presence of a tRNALeu3 gene was confirmed by DNA sequence. The results indicate that the tRNALeu3 coding region is not co-linear with the tRNALeu3. An intervening tract of 33 base pairs interrupts the coding sequences 1 base pair past the anticodon coding region. The putative structure of a tRNALeu3 precursor is deduced in which the anticodon base pairs with residues from the intervening sequence.     

tRNA genes and the genetic code

The genetic code describes translational assignments between codons and amino acids. tRNAs and aminoacyl-tRNA synthetases (aaRSs) are those molecules by means of which these assignments are established. Any aaRS recognizes its tRNAs according to some of their nucleotides called identity elements (IEs). Let a 1Mut-similarity Sim (1Mut) be the average similarity between such tRNA genes whose codons differ by one point mutation. We showed that: (1) a global maximum of Sim (1Mut) is reached at the standard genetic code 27 times for 4 sets of IEs of tRNA genes of eukaryotic species, while it is so only 5 times for similarities Sim (C&R) between all tRNA genes whose codons lie in the same column or row of the code. Therefore, point mutations of anticodons were tested by nature to recruit tRNAs from one isoaccepting group to another, (2) because plain similarities Sim (all) between tRNA genes of species within any of the three domains of life are higher than between tRNA genes of species belonging to different domains, tRNA genes retained information about early evolution of cells, (3) we searched the order of tRNAs in which they were most probably assigned to their codons and amino acids. The beginning Ala, (Val), Pro, Ile, Lys, Arg, Trp, Met, Asp, Cys, (Ser) of our resulting chronology lies under a plateau on a graph of Sim (1Mut,IE)(univ.ancestors) plotted over this chronology for a set S(IE) of all IEs of tRNA genes, whose universal ancestors were separately computed for each codon. This plateau has remained preserved along the whole line of evolution of the code and is consistent with observations of Ribas de Pouplana and Schimmel [2001. Aminoacy1-tRNA synthetases: potential markers of genetic code development. Trends Biochem. Sci. 26, 591-598] that specific pairs of aaRSs-one from each of their two classes-can be docked simultaneously onto the acceptor stem of tRNA and hence an interaction existed between their ancestors using a reduced code, (4) sharpness of a local maximum of Sim (1Mut) at the standard code is almost 100% along our chronologies.     

Cytidines in tRNAs that are required intact by ATP/CTP:tRNA nucleotidyltransferases from Escherichia coli and Saccharomyces cerevisiae.

Individual species of tRNA from Escherichia coli were treated with hydrazine/3 M NaCl to modify cytidine residues. The chemically modified tRNAs were used as substrate for ATP/CTP: tRNA nucleotidyltransferases from E. coli and yeast, with [alpha-32P]ATP as cosubstrate. tRNAs that were labeled were analyzed for their content of modified cytidines. Cytidines at positions 74 and 75 were found to be required chemically intact for interaction with both enzymes. C56 was also required intact by the E. coli enzyme in all tRNAs, and by the yeast enzyme in several instances. C61 was found to be important in seven of 14 tRNAs with the E. coli enzyme but only in four of 13 tRNAs with that from yeast. Our results support a model in which nucleotidyltransferase extends from the 3' end of its tRNA substrate across the top of the stacked array of bases in the accepter- and psi-stems to the corner of the molecule where the D- and psi-loops are juxtaposed.     

Effect of zinc ions on tRNA structure: imino proton NMR spectroscopy

The structure of tRNA in solution was explored by NMR spectroscopy to evaluate the effect of divalent cations, especially zinc, which has a profound effect on the chromatographic behaviour of tRNAs in certain systems. The divalent ions Mg2+ and Zn2+ have specific effects on the imino proton region of the 1H NMR spectrum of valine transfer RNA (tRNA(Val] of Escherichia coli and of phenylalanine transfer RNA (tRNA(Phe] of yeast. The dependence of the imino proton spectra of the two tRNAs was examined as a function of Zn2+ concentration. In both tRNAs the tertiary base pair (G-15).(C-48) was markedly affected by Zn2+ (shifted downfield possibly by as much as 0.4 ppm); this is the terminal base pair in the augmented dihydrouridine helix (D-helix). Base pair (U-8).(A-14) in yeast tRNA(Phe) or (s4U-8).(A-14) in tRNA1(Val), which are stacked on (G-15).(C-48), was not affected by Zn2+, except when 1-2 Mg2+ ions per tRNA were also present. Another imino proton that may be affected by Zn2+ in both tRNAs is that of the tertiary base pair (G-19).(C-46). The assignment of this resonance in yeast tRNA(Phe) is tentative since it is located in the region of highly overlapping resonances between 12.6 and 12.3 ppm. This base pair helps to anchor the D-loop to the T psi C loop.(ABSTRACT TRUNCATED AT 250 WORDS)