Splicing of Arabidopsis tRNAMet precursors in tobacco cell and wheat germ extracts

Intron-containing tRNA genes are exceptional within nuclear plant genomes. It appears that merely two tRNA gene families coding for tRNA^Tyr _{G A} and elongator tRNA^Met _CmAU contain intervening sequences. We have previously investigated the features required by wheat germ splicing endonuclease for efficient and accurate intron excision from Arabidopsis pre-tRNA^Tyr. Here we have studied the expression of an Arabidopsis elongator tRNA^Met gene in two plant extracts of different origin. This gene was first transcribed either in HeLa or in tobacco cell nuclear extract and splicing of intron-containing tRNA^Met precursors was then examined in wheat germ S23 extract and in the tobacco system. The results show that conversion of pre-tRNA^Met to mature tRNA proceeds very efficiently in both plant extracts. In order to elucidate the potential role of specific nucleotides at the 3 and 5 splice sites and of a structured intron for pre-tRNA^Met splicing in either extract, we have performed a systematic survey by mutational analyses. The results show that cytidine residues at intron-exon boundaries impair pre-tRNA^Met splicing and that a highly structured intron is indispensable for pre-tRNA^Met splicing. tRNA precursors with an extended anticodon stem of three to four base pairs are readily accepted as substrates by wheat and tobacco splicing endonuclease, whereas pre-tRNA molecules that can form an extended anticodon stem of only two putative base pairs are not spliced at all. An amber suppressor, generated from the intron-containing elongator tRNA^Met gene, is efficiently processed and spliced in both plant extracts.     

Identification of transfer RNA suppressors in Escherichia coli. II. Duplicate genes for tRNA2Gln.

The number of gene copies for tRNA₂^Gln in λpsu⁺2 was determined by genetic and biochemical studies. The transducing phage stimulates the production of the su⁺2 (amber suppressor) and su°2 glutamine tRNAs and methionine tRNA_m. When the su⁺2 amber suppressor was converted to an ochre suppressor by single-base mutation, the phage stimulated ochre-suppressing tRNA₂^Gln, instead of the amber-suppressing tRNA₂^Gln. From the transducing phage carrying the ochre-suppressing allele, strains carrying both ochre and amber suppressors were readily obtainable. These phages stimulated both ochre-suppressing and amber-suppressing tRNA₂^Gln, but not the non-suppressing form. We conclude that the original transducing phage carries two tRNA₂^Gln genes, one su⁺2 and one su°2. The transducing phage carrying two suppressors, ochre and amber, segregates one-gene derivatives that encode only one or the other type of suppressor tRNA. These derivatives apparently arise by unequal recombination involving the two glutamine tRNA genes in the parental phage. This segregation is not accompanied by the loss of the tRNA_m^Met gene. Based on these results, it is suggested that Escherichia coli normally carries in tandem two identical genes specifying tRNA₂^Gln at 15 minutes on the bacterial chromosome. su⁺2 mutants may arise by single-base mutations in the anticodon region of either of these two, leaving the other intact. By double mutations, tRNA₂^Gln genes could also become ochre suppressors. A tRNA_m^Met gene is located near, but not between, these two tRNA₂^Gln genes.     

Plant nuclear tRNAMet genes are ubiquitously interrupted by introns

We have isolated three independent clones for nuclear elongator tRNA^Met genes from an Arabidopsis DNA library using a tRNA^Met-specific probe generated by PCR. Each of the coding sequences for tRNA^Met in these clones is identical and is interrupted by an identical 11 bp long intervening sequence at the same position in the anticodon loop of the tRNA. Their sequences differ at two positions from the intron in a soybean counterpart. Southern analysis of Arabidopsis DNA demonstrates that a gene family coding for tRNA^Met is dispersed at at least eight loci in the genome. The unspliced precursor tRNA^Met intermediate was detected by RNA analysis using an oligonucleotide probe complementary to the putative intron sequence. In order to know whether introns commonly interrupt plant tRNA^Met genes, their coding sequences were PCR-amplified from the DNAs of eight phylogenetically separate plant species. All 53 sequences determined contain 10 to 13 bp long intervening sequences, always positioned one base downstream from the anticodon. They can all be potentially folded into the secondary structure characteristic for plant intron-containing precursor tRNAs. Surprisingly, GC residues are always present at the 5-distal end of each intron.     

Transfer RNA-mediated suppression of amber stop codons in transgenic Arabidopsis thaliana

An artificial amber suppressor tRNA^Leu gene (supL.) was physically linked to a mutated gus reporter gene, p35S-gus(amL), which was inactivated by an amber stop codon (amL). Upon introduction into Arabidopsis thaliana, the presence of the supL. gene was found to be correlated with cytotoxic effects observed during tissue culture and in mature plants. Those primary transformants that displayed cytotoxic symptoms were shown by X-Gluc staining to express GUS as a result of amber stop codon suppression in vivo. Phenotypically normal lines were found by RT-PCR to express supL. GUS activity above background level was barely detectable in these plants, indicating a low level expression of supL. However, the remaining suppressor activity was still sufficient to transactivate an amber-mutated male sterility gene, pA9-barnase(amL1) when combined within the same plant by crossing. The suppressor tRNA^Leu gene may thus be used in transgenic plants for gene transactivation.     

Screening system for orthogonal suppressor tRNAs based on the species-specific toxicity of suppressor tRNAs

Incorporation of unnatural amino acids into proteins in vivo, known as expanding the genetic code, is a useful technology in the pharmaceutical and biotechnology industries. This procedure requires an orthogonal suppressor tRNA that is uniquely acylated with the desired unnatural amino acid by an orthogonal aminoacyl-tRNA synthetase. In order to enhance the numbers and types of suppressor tRNAs available for engineering genetic codes, we have developed a convenient screening system to generate suppressor tRNAs with good orthogonality from the available library of suppressor tRNA mutants. While developing an amber suppressor tRNA, we discovered that amber suppressor tRNA with poor orthogonality inhibited the growth rate of the host, indicating that suppressor tRNA demonstrates a species-specific toxicity to host cells. We verified this species-specific toxicity using amber suppressor tRNA mutants from prokaryotes, eukaryotes, and archaea. We also confirmed that adding terminal CCA to Methanococcus jannaschii tRNA^Tyr mutant is important to its toxicity against Escherichia coli. Further, we compared the toxicity of the suppressor tRNA toward the host with differing copy numbers. Using the combined toxicity of suppressor tRNA toward the host with blue–white selection, we developed a convenient screening system for orthogonal suppressor tRNA that could serve as a general platform for generating tRNA/aaRS pairs and thereby obtained three suppressor tRNA mutants with high orthogonality from the tRNA library derived from Mj tRNA^Tyr.     

Transactivation of a target gene using a suppressor tRNA in transgenic tobacco plants

The abundance of tRNAs, together with their central role in translation, has generated considerable interest in the use of tRNA genes for biotechnological applications. One such application is the use of suppressor tRNAs to transactivate target genes containing premature stop codons. Previous work has shown that such systems can work in transient expression experiments in plant protoplasts; here these experiments are extended to show that suppression of stop codons can occur in whole plants. Transgenic tobacco plants homozygous for a modified tRNA^Leu gene expressing a strong amber suppressor tRNA, and plants carrying a β-glucuronidase (gus) gene inactivated by a premature amber stop codon have been obtained. When the two types of plants are crossed, many of the F₁ hybrids show significant GUS activity. The GUS activity is dependent on the presence of both the suppressor tRNA gene and the gus gene. Tobacco plants carrying the suppressor tRNA gene are phenotypically normal, fertile and the gene shows normal Mendelian inheritance. The potential applications of such a system are discussed.     

Identification of transfer RNA suppressors in Escherichia coli. I. Amber suppressor su+2, an anticodon mutant of tRNA2Gln.

In order to isolate the gene for amber suppressor su⁺2 (SupE) in Escherichia coli, a non-defective su⁺2-transducing phage lambda was isolated in three steps: first, deletion derivatives of F′su⁺2 gal (λ) were selected, linking su⁺2 to the right-hand prophage attachment site, att^λPB′; second, these F′-factors were relysogenized by λ and defective transducing phages, λdsu⁺2, were produced by induction; and third, non-defective λpsu⁺2 transducing phages were produced by recombination of λdsu⁺2 isolates with λ. Upon infection by λpsu⁺2, the production of transferRNAs accepting glutamine and methionine was markedly stimulated. Fingerprint analysis of these tRNAs revealed that they consisted of normal tRNA₂^Gln, mutant tRNA₂^Gln and tRNA_m^Met. The mutant tRNA₂^Gln carried a singlebase alteration from G to A at the 3′-end of the anticodon. The production of tRNA₁^Gln was not stimulated by the infection of λpsu⁺2. We conclude that the wild-type allele of su⁺2 (SupE) is the structural gene for tRNA₂^Gln, and the su⁺2 amber suppressor was derived by a single base mutation, changing the anticodon from CUG to CUA, in one of the multi-copy genes for tRNA₂^Gln. The fact that λpsu⁺2 also induces the production of tRNA_m^Met suggests that this tRNA is encoded in the same chromosomal region of E. coli as is tRNA₂^Gln.     

Serine-inserting UAA suppression mediated by yeast tRNASer

The number of loci that give rise to serine-inserting UAA suppressors in the yeast Saccharomyces cerevisiae was determined by examining over 100 of the revertants that suppressed the two UAA markers his4-1176 and leu2-1: the his4-1176 marker is suppressed by serine-inserting but not by tyrosine- or leueine-inserting suppressors and the leu2-1 marker is suppressed by all UAA suppressors. The suppressors could be assigned to one or other of the four loci: SUP16 and SUP17. which were previously known to yield serine-inserting suppressors, and SUP19 and SUP22. The chromosomal map position of SUP19 suggested that it may be allelic to the previously reported suppressor SUP20, while the SUP22 suppressor has not been described. Representatives of all of the four suppressors were found to insert serine at the UAA site in iso-1-cytochrome c from suppressed cyc1-72 strains. The degree of suppression by the serine-inserting suppressors was SUP16 > SUP17 > SUP19 > SUP22. The efficiency of suppression of each of the four serine suppressors was increased by the chromosomal mutation sal and by the cytoplasmic determinant ψ⁺. Read-through of the synthetase gene of the RNA bacteriophage Qβ in a cell-free system was used to demonstrate that tRNA^Ser from SUP16, SUP17 and SUP19 strains can translate UAA codons. In contrast, tRNA^Ser or total tRNA from SUP22 strains had no suppressing activity. The results suggest that the three loci SUP16, SUP17 and SUP19 encode iso-accepting species of tRNA^Ser, and that the UAA suppression is mediated by mutationally altered tRNA molecules. The mechanism of SUP22 suppression remains unknown.     

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.     

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.     

Recessive lethality of yeast strains carrying the SUP61 suppressor results from loss of a transfer RNA with a unique decoding function

A serine-inserting ochre suppressor (SUP61) and its amber allele (SUP-RL1) in the yeast Saccharomyces cerevisiae can only be derived from or maintained in diploid strains heterozygous for the suppressor transfer RNA locus (Brandriss et al., 1975). Two models have been proposed to account for this recessive lethal phenotype. In one, lethality results from the presence of the altered gene product; excessive suppression could interfere with the proper termination of translation. In the second model, lethality is due to the loss of the wild-type function; the suppressor mutation could alter an essential gene that is present in only a single copy in the haploid genome. We have tested a set of specific genetic and biochemical predictions which uniquely distinguish these models.We first isolated several mutant strains carrying second-site mutations which lie within, or are closely linked to, the SUP61 locus. Despite the absence of any biologically detectable suppressor activity, these mutants still give rise to only two viable spores per tetrad. As in the parent, lethality is absolutely correlated with the segregation of the SUP61 allele, and thus it cannot be due solely to suppression.To demonstrate that the SUP61 mutation alters an essential function in haploid cells, a cloned copy of the wild-type gene (sup⁺) was introduced into a diploid containing SUP61 by transformation. Following sporulation, the transformant gave rise to four viable spores per tetrad. We have shown by hybridization analysis that the two spores per tetrad which have suppressor function contain the cloned sup⁺ gene and plasmid DNA integrated in tandem with the SUP61 gene.Piper (1978) has shown that the amber suppressor SUP-RL1 is derived from a tRNA_UCG^Ser gene. More recently, we and others (Etcheverry et al., 1979; Olson et al., 1981; Broach et al., 1981) have provided evidence that the gene coding for this tRNA species exists in only a single copy per haploid genome. Our ability to “cure” the recessive lethal phenotype of SUP61 now allows the conclusion that the gene altered by the suppressor mutation codes for the only isoaccepting species of tRNA^Ser which can decode UCG codons in vivo.     

The tRNATyr multigene family of Nicotiana rustica: genome organization,sequence analyses and expression in vitro

Tobacco tRNA^Tyr genes are mainly organized as a dispersed multigene family as shown by hybridization with a tRNA^Tyr-specific probe to Southern blots of Eco RI-digested DNA. A Nicotiana genomic library was prepared by Eco RI digestion of nuclear DNA, ligation of the fragments into the vector gtWES·B and in vitro packaging. The phage library was screened with a 5-labelled synthetic oligonucleotide complementary to nucleotides 18 to 37 of cytoplasmic tobacco tRNA^Tyr. Eleven hybridizing Eco RI fragments ranging in size from 1.7 to 7.5 kb were isolated from recombinant lambda phage and subcloned into pUC19 plasmid. Four of the sequenced tRNA^Tyr genes code for the known tobacco tRNA₁ ^Tyr (GA) and seven code for tRNA₂ ^Tyr (GA). The two tRNA species differ in one nucleotide pair at the basis of the TC stem. Only one tRNA^Tyr gene (pNtY5) contains a point mutation (T54A54). Comparison of the intervening sequences reveals that they differ considerably in length and sequence. Maturation of intron-containing pre-tRNAs was studied in HeLa and wheat germ extracts. All pre-tRNAs^Tyr-with one exception-are processed and spliced in both extracts. The tRNA^Tyr gene encoded by pNtY5 is transcribed efficiently in HeLa extract but processing of the pre-tRNA is impaired.     

Cytokinin-Active Ribonucleosides in Phaseolus RNA: II. DISTRIBUTION IN tRNA SPECIES FROM ETIOLATED P. VULGARIS L. SEEDLINGS

The distribution of cytokinin-active ribonucleosides in tRNA species from etiolated Phaseolus vulgaris L. seedlings has been examined. Phaseolus tRNA was fractionated by benzoylated diethylaminoethyl-cellulose and RPC-5 chromatography, and the distribution of cytokinin activity was compared with the distribution of tRNA species expected to correspond to codons beginning with U. Phaseolus tRNA^Cys, tRNA^Trp, tRNA^Tyr, a major peak of tRNA^Phe, and a large fraction of tRNA^Leu were devoid of cytokinin activity in the tobacco bioassay. Cytokinin activity was associated with all fractions containing tRNA^Ser species and with minor tRNA^Leu species. In addition, several anomalous peaks of cytokinin activity that could not be directly attributed to U group tRNA species were detected.     

C-terminal Domain of Leucyl-tRNA Synthetase from Pathogenic Candida albicans Recognizes both tRNASer and tRNALeu

Leucyl-tRNA synthetase (LeuRS) is a multidomain enzyme that catalyzes Leu-tRNA^Leu formation and is classified into bacterial and archaeal/eukaryotic types with significant diversity in the C-terminal domain (CTD). CTDs of both bacterial and archaeal LeuRSs have been reported to recognize tRNA^Leu through different modes of interaction. In the human pathogen Candida albicans, the cytoplasmic LeuRS (CaLeuRS) is distinguished by its capacity to recognize a uniquely evolved chimeric tRNA^Ser (CatRNA^Ser(CAG)) in addition to its cognate CatRNA^Leu, leading to CUG codon reassignment. Our previous study showed that eukaryotic but not archaeal LeuRSs recognize this peculiar tRNA^Ser, suggesting the significance of their highly divergent CTDs in tRNA^Ser recognition. The results of this study provided the first evidence of the indispensable function of the CTD of eukaryotic LeuRS in recognizing non-cognate CatRNA^Ser and cognate CatRNA^Leu. Three lysine residues were identified as involved in mediating enzyme-tRNA interaction in the leucylation process: mutation of all three sites totally ablated the leucylation activity. The importance of the three lysine residues was further verified by gel mobility shift assays and complementation of a yeast leuS gene knock-out strain.     

Processing of plant mitochondrial tRNAGly and tRNASer(GCU) is independent of RNA editing

The genes encoding pea and potato mitochondrial tRNA^Gly and pea mitochondrial tRNA^Ser(GCU) were analyzed with particular respect to their expression. Secondary-structure models deduced from the identical potato and pea tRNA^Gly gene sequences revealed A₇:C₆₆ mismatches in the seventh base pair at the base of the acceptor stems of both tRNAs. Sequence analyses of tRNA^Gly cDNA clones showed that these mispairings are not corrected by C₆₆ to U₆₆ conversions, as observed in plant mitochondrial tRNA^Phe. Likewise, a U₆:C₆₇ mismatch identified in the acceptor stem of the pea tRNA^Ser(GCU) is not altered by RNA editing to a mismatched U:U pair, which is created by RNA editing in Oenothera mitochondrial tRNA^Cys. In vitro processing reactions with the respective tRNA^Gly and tRNA^Ser(GCU) precursors show that such conversions are not necessary for 5′ and 3′ end maturation of these tRNAs. These results demonstrate that not all C:A (A:C) or U:C (C:U) mismatches in double-stranded regions of tRNAs are altered by RNA editing. An RNA editing event in plant mitochondrial tRNAs is thus not generally indicated by the presence of a mismatch but may depend on additional parameters.