Translational nonsense codon suppression as indicator for functional pre-tRNA splicing in transformed Arabidopsis hypocotyl-derived calli

The transient expression of three novel plant amber suppressors derived from a cloned Nicotiana tRNA^Ser(CGA), an Arabidopsis intron-containing tRNA^Tyr(GTA) and an Arabidopsis intron-containing tRNA^Met(CAT) gene, respectively, was studied in a homologous plant system that utilized the Agro bacterium-mediated gene transfer to Arabidopsis hypocotyl explants. This versatile system allows the detection of β-glucuronidase (GUS) activity by histochemical and enzymatic analyses. The activity of the suppressors was demonstrated by the ability to suppress a premature amber codon in a modified GUS gene. Co-transformation of Arabidopsis hypocotyls with the amber suppressor tRNA^Ser gene and the GUS reporter gene resulted in ~10% of the GUS activity found in the same tissue transformed solely with the functional control GUS gene. Amber suppressor tRNAs derived from intron-containing tRNA^Tyr or tRNA^Met genes were functional in vivo only after some additional gene manipulations. The G3:C70 base pair in the acceptor stem of tRNA^Met(CUA) had to be converted to a G3:U70 base pair, which is the major determinant for alanine tRNA identity. The inability of amber suppressor tRNA^Tyr to show any activity in vivo predominantly results from a distorted intron secondary structure of the corresponding pre-tRNA that could be cured by a single nucleotide exchange in the intervening sequence. The improved amber suppressors tRNA^Tyr and tRNA^Met were subsequently employed for studying various aspects of the plant-specific mechanism of pre-tRNA splicing as well as for demonstrating the influence of intron-dependent base modifications on suppressor activity.     

Mitochondrial tyrosyl transfer ribonucleic Acid in soybean seedlings

Soybean seedlings were examined for the presence of mitochondrial tRNA. Tyrosyl transfer tRNAs from whole cells, from a well characterized mitochondrial preparation, and from a snake venom phosphodiesterase-treated mitochondrial preparation, were compared by reverse phase chromatography. It was concluded that none of the three previously reported tRNA^Tyr species were mitochondrial. Rather, a fourth tRNA^Tyr species, eluting somewhat later, was of mitochondrial origin. Mitochondrial tRNA^Tyr was chromatographically similar to Escherichia coli tRNA^Tyr.     

The molecular basis for the differential translation of TMV RNA in tobacco protoplasts and wheat germ extracts

Translation of tobacco mosaic virus (TMV) RNA in tobacco protoplasts yields the 17.5-K coat protein, a 126-K protein and a 183-K protein which is generated by an efficient readthrough over the UAG termination codon at the end of the 126-K cistron. In wheat germ extracts, however, only the 5'-proximal 126-K cistron is translated whereas the 183-K readthrough protein is not synthesized. Purification and sequence analysis of the endogenous tyrosine tRNAs revealed that the uninfected tobacco plant contains two tRNAs^Tyr, both with GΨA anticodons which stimulate the UAG readthrough in vitro and presumably in vivo. In contrast, ˜85% of the tRNA^Tyr from wheat germ contains a QΨA anticodon and ˜15% has a GΨA anticodon. Otherwise the sequences of tRNAs^Tyr from wheat germ and tobacco are identical. UAG readthrough and hence synthesis of the 183-K protein is only stimulated by tRNA^Tyr_GΨA and not at all by tRNA^Tyr_QΨA. The tRNAs^Tyr from wheat leaves were also sequenced. This revealed that adult wheat contains tRNA^Tyr_GΨA only. This is very much in contrast to the situation in animals, where Q-containing tRNAs are characteristic for adult tissues whereas Q deficiency is typical for the neoplastic and embryonic state.     

Biochemical characterization of the mitochondrial tRNASer(UCN) T7511C mutation associated with nonsyndromic deafness

We report here the biochemical characterization of the deafness-associated mitochondrial tRNA^Ser(UCN) T7511C mutation, in conjunction with homoplasmic ND1 T3308C and tRNA^Ala T5655C mutations using cybrids constructed by transferring mitochondria from lymphoblastoid cell lines derived from an African family into human mtDNA-less (ρ°) cells. Three cybrids derived from an affected matrilineal relative carrying the homoplasmic T7511C mutation, exhibited ~75% decrease in the tRNA^Ser(UCN) level, compared with three control cybrids. This amount of reduction in the tRNA^Ser(UCN) level is below a proposed threshold to support a normal rate of mitochondrial protein synthesis in lymphoblastoid cell lines. This defect is likely a primary contributor to ~52% reduction in the rate of mitochondrial protein synthesis and marked defects in respiration and growth properties in galactose-containing medium. Interestingly, the T5655C mutation produces ~50% reduction in the tRNA^Ala level in mutant cells. Strikingly, the T3308C mutation causes a significant decrease both in the amount of ND1 mRNA and co-transcribed tRNA^Leu(UUR) in mutant cells. Thus, mitochondrial dysfunctions caused by the T5655C and T3308C mutations may modulate the phenotypic manifestation of the T7511C mutation. These observations imply that a combination of the T7511C mutation with two mtDNA mutations accounts for the high penetrance of deafness in this family.     

Structural basis for recognition of cognate tRNA by tyrosyl-tRNA synthetase from three kingdoms

The specific aminoacylation of tRNA by tyrosyl-tRNA synthetases (TyrRSs) relies on the identity determinants in the cognate tRNA^Tyrs. We have determined the crystal structure of Saccharomyces cerevisiae TyrRS (SceTyrRS) complexed with a Tyr-AMP analog and the native tRNA^Tyr(GΨA). Structural information for TyrRS–tRNA^Tyr complexes is now full-line for three kingdoms. Because the archaeal/eukaryotic TyrRSs–tRNA^Tyrs pairs do not cross-react with their bacterial counterparts, the recognition modes of the identity determinants by the archaeal/eukaryotic TyrRSs were expected to be similar to each other but different from that by the bacterial TyrRSs. Interestingly, however, the tRNA^Tyr recognition modes of SceTyrRS have both similarities and differences compared with those in the archaeal TyrRS: the recognition of the C1-G72 base pair by SceTyrRS is similar to that by the archaeal TyrRS, whereas the recognition of the A73 by SceTyrRS is different from that by the archaeal TyrRS but similar to that by the bacterial TyrRS. Thus, the lack of cross-reactivity between archaeal/eukaryotic and bacterial TyrRS-tRNA^Tyr pairs most probably lies in the different sequence of the last base pair of the acceptor stem (C1-G72 vs G1-C72) of tRNA^Tyr. On the other hand, the recognition mode of Tyr-AMP is conserved among the TyrRSs from the three kingdoms.     

Sequence-specific recognition of colicin E5, a tRNA-targeting ribonuclease

Colicin E5 is a novel Escherichia coli ribonuclease that specifically cleaves the anticodons of tRNA^Tyr, tRNA^His, tRNA^Asn and tRNA^Asp. Since this activity is confined to its 115 amino acid long C-terminal domain (CRD), the recognition mechanism of E5-CRD is of great interest. The four tRNA substrates share the unique sequence UQU within their anticodon loops, and are cleaved between Q (modified base of G) and 3′ U. Synthetic minihelix RNAs corresponding to the substrate tRNAs were completely susceptible to E5-CRD and were cleaved in the same manner as the authentic tRNAs. The specificity determinant for E5-CRD was YGUN at −1 to +3 of the ‘anticodon’. The YGU is absolutely required and the extent of susceptibility of minihelices depends on N (third letter of the anticodon) in the order A > C > G > U accounting for the order of susceptibility tRNA^Tyr > tRNA^Asp > tRNA^His, tRNA^Asn. Contrastingly, we showed that GpUp is the minimal substrate strictly retaining specificity to E5-CRD. The effect of contiguous nucleotides is inconsistent between the loop and linear RNAs, suggesting that nucleotide extension on each side of GpUp introduces a structural constraint, which is reduced by a specific loop structure formation that includes a 5′ pyrimidine and 3′ A.     

UAG readthrough during TMV RNA translation: isolation and sequence of two tRNAs with suppressor activity from tobacco plants

The hypothetical replicase or replicase subunit cistron in the 5'-proximal part of tobacco mosaic virus (TMV) RNA yields a major 126-K protein and a minor 183-K `readthrough' protein in vivo and in vitro. Two natural suppressor tRNAs were purified from uninfected tobacco plants on the basis of their ability to promote readthrough over the corresponding UAG termination codon in vitro. In a reticulocyte lysate the yield of 183-K readthrough protein increases from ˜10% in the absence of added tobacco plant tRNA up to ˜35% in the case of pure tRNA^Tyr added. Their amino acid acceptance and anticodon sequence (GψA) identifies the two natural suppressor tRNAs as the two normal major cytoplasmic tyrosine-specific tRNAs. tRNA^Tyr₁ has an A:U pair at the base of the TψC stem and an unmodified G₁₀, whereas tRNA^Tyr₂ contains a G:C pair in the corresponding location and m²G in position 10. This is the first case that, in a higher eukaryote, the complete structure is known of both the natural suppressor tRNAs and the corresponding viral RNA on which they exert their function. The corresponding codon-anticodon interaction, which is not in accordance with the wobble hypothesis, and the possible biological significance of the readthrough phenomenon is discussed.     

Relative stabilities of RNA/DNA hybrids: effect of RNA chain length in competitive hybrization

Escherichia coli DNA and fragmented rRNA were used as a model system to study the effect of RNA fragment size in hybridization-competition experiments. Though no difference in hybridization rates was observed, the relative stabilities of the RNA/DNA hybrids were found to be largely affected by the fragment size of the RNA molecule. Intact rRNA was shown to replace shorter homologous rRNA sequences in their hybrids, the rate of the displacement being dependent on the molecular size of the RNA fragments. Hybridization-competition experiments between molecules of different lengths are expected to be complicated by the displacement reaction. The synthesis of tRNA^Tyr-like sequences transcribed in vitro on φ80psu₃⁺ bacteriophage DNA was measured by hybridization competition assays. Indirect competition with labelled E. coli tRNA^Tyr hybridization revealed that the in vitro-synthesized RNA contained significant amounts of tRNA^Tyr; these sequences could not, however, be detected by the direct competition method in which labelled in vitro-synthesized RNA competes with E. coli tRNA^Tyr for hybridization to φ80psu₃⁺ DNA. These contradictory results can be traced to the differences in size of the competing molecules in the hybridization-competition reaction. Indeed, in vitro-transcribed tRNA^Tyr-like sequences, longer than mature tRNA, were found to displace efficiently E. coli tRNA^Tyr from its hybrids with φ80psu₃⁺ DNA. These findings explain why such sequences could not be detected by direct competition with E. coli tRNA^Tyr.     

Functional replacement of the endogenous tyrosyl-tRNA synthetase–tRNATyr pair by the archaeal tyrosine pair in Escherichia coli for genetic code expansion

Non-natural amino acids have been genetically encoded in living cells, using aminoacyl-tRNA synthetase–tRNA pairs orthogonal to the host translation system. In the present study, we engineered Escherichia coli cells with a translation system orthogonal to the E. coli tyrosyl-tRNA synthetase (TyrRS)–tRNA^Tyr pair, to use E. coli TyrRS variants for non-natural amino acids in the cells without interfering with tyrosine incorporation. We showed that the E. coli TyrRS–tRNA^Tyr pair can be functionally replaced by the Methanocaldococcus jannaschii and Saccharomyces cerevisiae tyrosine pairs, which do not cross-react with E. coli TyrRS or tRNA^Tyr. The endogenous TyrRS and tRNA^Tyr genes were then removed from the chromosome of the E. coli cells expressing the archaeal TyrRS–tRNA^Tyr pair. In this engineered strain, 3-iodo-l-tyrosine and 3-azido-l-tyrosine were each successfully encoded with the amber codon, using the E. coli amber suppressor tRNATyr and a TyrRS variant, which was previously developed for 3-iodo-l-tyrosine and was also found to recognize 3-azido-l-tyrosine. The structural basis for the 3-azido-l-tyrosine recognition was revealed by X-ray crystallography. The present engineering allows E. coli TyrRS variants for non-natural amino acids to be developed in E. coli, for use in both eukaryotic and bacterial cells for genetic code expansion.     

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.     

Nuclear tRNATyr genes are highly amplified at a single chromosomal site in the genome of Arabidopsis thaliana

Summary We have examined the organization of tRNA^Tyr genes in three ecotypes of Arabidopsis thaliana, a plant with an extremely small genome of 7 × 107 bp. Three tRNA^Tyr gene-containing EcoRI fragments of 1.5 kb and four fragments of 0.6, 1.7, 2.5 and 3.7 kb were cloned from A. thaliana cv. Columbia (Col-O) DNA and sequenced. All EcoRl fragments except those of 0.6 and 2.5 kb comprise an identical arrangement of two tRNA^Tyr genes flanked by a tRNA^Ser gene. The three tRNA genes have the same polarity and are separated by 250 and 370 bp, respectively. The tRNA^Tyr genes encode the known cytoplasmic tRNA_GA ^Tyr. Both genes contain a 12 by long intervening sequence. Densitometric evaluation of the genomic blot reveals the presence of at least 20 copies, including a few multimers, of the 1.5 kb fragment in Col-O DNA, indicating a multiple amplification of this unit. Southern blots of EcoRl-digested DNA from the other two ecotypes, cv. Landsberg (La-O) and cv. Niederzenz (Nd-O) also show 1.5 kb units as the major hybridizing bands. Several lines of evidence support the idea of a strict tandem arrangement of this 1.5 kb unit: (i) Sequence analysis of the EcoRI inserts of 2.5 and 0.6 kb reveals the loss of an EcoRI site between 1.5 kb units and the introduction of a new EcoRI site in a 1.5 kb dimer. (ii) Complete digestion of Col-O DNA with restriction enzymes which cleave only once within the 1.5 kb unit also produces predominantly 1.5 kb fragments. (iii) Partial digestion with EcoRI shows that the 1.5 kb fragments indeed arise from the regular spacing of the restriction sites. The high degree of sequence homology among the 1.5 kb units, ranging from 92% to 99%, suggests that the tRNA^Ser/tRNA^Tyr cluster evolved 1–5 million years ago, after the Brassicaceae diverged from the other flowering plants about 5–10 million years ago.     

The preparation and properties of a stable mercury derivative of transfer RNAs from Escherichia coli

Further investigations into the properties of the mercury derivative formed by the reaction of 4-thiouridine-containing tRNAs and pentafluorophenylmercury chloride have been carried out. tRNA^fMet (which contains only one 4-thiouridine residue) has been isolated by a one-step column Chromatographic procedure from unfractionated Escherichia coli tRNA and has been shown to react with the mercury compound to give a derivative which has similar properties to those previously reported for the corresponding mercury derivative of tRNA^Tyr which contains two adjacent 4-thiouridine residues. The mercury derivative of tRNA^Tyr appears to be a competitive inhibitor of tRNA^Tyr in the aminoacylation reaction (tRNA^TyrK_m = 0.42 μM, mercury derivative of tRNA^TyrK_i = 0.11 μM). The mercury derivative of Tyr-tRNA^Tyr can be made, but only by the reaction of the mercury compound with the aminoacylated tRNA.     

Cloning of the yeast tyrosine transfer RNA genes in bacteriophage lambda.

Lambda bacteriophage containing yeast tyrosine transfer RNA genes were prepared by molecular recombination. These phage were identified by hybridization of ¹²⁵I-labeled yeast tRNA^Tyr to plaques from lambda-yeast recombinant phage pools. The cloned yeast EcoRI fragments that hybridize to ¹²⁵I-labeled tRNA^Tyr were compared in size with the fragments in total yeast DNA that hybridize to the same probe. These comparisons indicate that seven of the eight different tRNA^Tyr genes have been isolated. Unambiguous evidence that these seven fragments contain tRNA^Tyr coding regions was obtained by showing that they hybridize to aminoacylated [^3H]Tyr-tRNA^Tyr. Only one of the fragments hybridizes to ³²P-labeled total yeast tRNA in the presence of competing unlabeled tRNA^Tyr; the tRNA^Tyr genes, therefore, are not predominantly organized into heteroclusters of tRNA genes.     

The complete nucleotide sequence of the mitochondrial genome of sugar beet (Beta vulgaris L.) reveals a novel gene for tRNA(Cys)(GCA)

We determined the complete nucleotide sequence of the mitochondrial genome of an angiosperm, sugar beet (Beta vulgaris cv TK81-O). The 368 799 bp genome contains 29 protein, five rRNA and 25 tRNA genes, most of which are also shared by the mitochondrial genome of Arabidopsis thaliana, the only other completely sequenced angiosperm mitochondrial genome. However, four genes identified here (namely rps13, trnF-GAA, ccb577 and trnC2-GCA) are missing in Arabidopsis mitochondria. In addition, four genes found in Arabidopsis (ccb228, rpl2, rpl16 and trnY2-GUA) are entirely absent in sugar beet or present only in severely truncated form. Introns, duplicated sequences, additional reading frames and inserted foreign sequences (chloroplast, nuclear and plasmid DNA sequences) contribute significantly to the overall size of the sugar beet mitochondrial genome. Nevertheless, 55.6% of the genome has no obvious features of information. We identified a novel tRNA^Cys gene (trnC2-GCA) which shows no sequence homology with any tRNA^Cys genes reported so far in higher plants. Intriguingly, this tRNA gene is actually transcribed into a mature tRNA, whereas the native tRNA^Cys gene (trnC1-GCA) is most likely a pseudogene.     

Plant mitochondria use two pathways for the biogenesis of tRNAHis

All tRNA^His possess an essential extra G_–1 guanosine residue at their 5′ end. In eukaryotes after standard processing by RNase P, G_–1 is added by a tRNA^His guanylyl transferase. In prokaryotes, G_–1 is genome-encoded and retained during maturation. In plant mitochondria, although trnH genes possess a G_–1 we find here that both maturation pathways can be used. Indeed, tRNA^His with or without a G_–1 are found in a plant mitochondrial tRNA fraction. Furthermore, a recombinant Arabidopsis mitochondrial RNase P can cleave tRNA^His precursors at both positions G₊₁ and G_–1. The G_–1 is essential for recognition by plant mitochondrial histidyl-tRNA synthetase. Whether, as shown in prokaryotes and eukaryotes, the presence of uncharged tRNA^His without G_–1 has a function or not in plant mitochondrial gene regulation is an open question. We find that when a mutated version of a plant mitochondrial trnH gene containing no encoded extra G is introduced and expressed into isolated potato mitochondria, mature tRNA^His with a G_–1 are recovered. This shows that a previously unreported tRNA^His guanylyltransferase activity is present in plant mitochondria.     

Mechanism of suppression in Drosophila: II. Enzymatic discrimination of wild-type and suppressor tyrosine transfer RNA

Previous studies had shown that two principle forms of tyrosine transfer RNA of Drosophila melanogaster were present in wild-type adult flies but that the second form was virtually absent in a suppressor mutant, su(s)². Current results are at variance with the previous ones, in that the suppressor mutant has significant amounts of the second form of tRNA^Tyr. A second chromatography system for separating these forms of tRNA^Tyr is described, RPC-5, and is compared to the system used previously, RPC-2. Both systems indicate that wild-type flies contain the two forms of tRNA^Tyr in a ratio of $\text{40}\text{60}$, the suppressor mutant in a ratio of $\text{60}\text{40}$. The difference between current and previous results can be attributed to the procedures used in the preparation of the enzyme that is used as a source of tyrosyl-tRNA ligase. The enzyme activity can be separated into two fractions on DEAE-cellulose chromatography. With suppressor tRNA as substrate, one enzyme fraction charges both forms of tRNA^Tyr but the second enzyme fraction charges the first form preferentially or nearly exclusively in some cases, as was seen in the previous experiments. With wild-type tRNA as substrate both enzyme fractions charge both forms of tRNA^Tyr. Storage results in the loss of the enzyme's ability to discriminate against the second form of tRNA^Tyr from the suppressor mutant, while the enzymatic activity is retained. We postulate that the su(s)⁺ locus produces an enzyme that modifies the second isoacceptor of tRNA^Tyr and that, when such modification fails to occur (as in the su(s)² mutant), the tRNA is unable to accept tyrosine from one form of tyrosyl-tRNA ligase. How the discrimination against the second isoacceptor by the ligase may be important metabolically is not apparent.     

Deficiency of the tRNATyr:Ψ35-synthase aPus7 in Archaea of the Sulfolobales order might be rescued by the H/ACA sRNA-guided machinery

Up to now, Ψ formation in tRNAs was found to be catalysed by stand-alone enzymes. By computational analysis of archaeal genomes we detected putative H/ACA sRNAs, in four Sulfolobales species and in Aeropyrum pernix, that might guide Ψ35 formation in pre-tRNA^Tyr(GUA). This modification is achieved by Pus7p in eukarya. The validity of the computational predictions was verified by in vitro reconstitution of H/ACA sRNPs using the identified Sulfolobus solfataricus H/ACA sRNA. Comparison of Pus7-like enzymes encoded by archaeal genomes revealed amino acid substitutions in motifs IIIa and II in Sulfolobales and A. pernix Pus7-like enzymes. These conserved RNA:Ψ-synthase- motifs are essential for catalysis. As expected, the recombinant Pyrococcus abyssi aPus7 was fully active and acted at positions 35 and 13 and other positions in tRNAs, while the recombinant S. solfataricus aPus7 was only found to have a poor activity at position 13. We showed that the presence of an A residue 3′ to the target U residue is required for P. abyssi aPus7 activity, and that this is not the case for the reconstituted S. solfataricus H/ACA sRNP. In agreement with the possible formation of Ψ35 in tRNA^Tyr(GUA) by aPus7 in P. abyssi and by an H/ACA sRNP in S. solfataricus, the A36G mutation in the P. abyssi tRNA^Tyr(GUA) abolished Ψ35 formation when using P. abyssi extract, whereas the A36G substitution in the S. solfataricus pre-tRNA^Tyr did not affect Ψ35 formation in this RNA when using an S. solfataricus extract.