Effect of photochemical crosslink S4U(8)-C(13) on suppressor activity of su+ tRNATrp from Escherichia coli.

Readthrough in vitro of the Qβ coat protein terminator codon UGA has been used as an assay for suppression by UGA-suppressor tRNA^Trp. When the tRNA is covalently crosslinked between 4-thiouracil(8) and cytosine(13) by irradiation at 334 nm, it is found that UGA suppression by this assay is reduced to the low level characteristic of the wild type tRNA^Trp. In contrast, crosslinking has little effect on incorporation of tryptophan in response to UGG codons. Thus, incorporation of tryptophan during translation of R17 messenger RNA is unaffected by photochemical crosslinking. Furthermore, dilution experiments using R17 mRNA in which tryptophan incorporation is dependent on precharged suppressor Trp-tRNA show that the crosslinked species competes well with non-irradiated tRNA. These results further emphasize the influence on tRNA-ribosome interactions of the region in tRNA around the dihydrouridine arm, where the mutation, in the suppressor is found and the photochemical crosslink is introduced.     

Dual specificity of su+7 tRNA. Evidence for translational discrimination

The su⁺7 amber suppressor of Escherichia coli is a mutant tRNA^Trp that translates UAG codons as glutamine. Nevertheless, the purified su⁺7 tRNA can be charged with either glutamine or tryptophan. Aminoacylation kinetics in vitro suggest that the tRNA should be acylated with equal amounts of glutamine and tryptophan in vivo. The predominance of the glutamine specificity of the suppressor is therefore potentially anomalous. We can find no selective deacylation of tryptophanyl-su⁺7 tRNA by glutaminyl-tRNA synthetase, tryptophanyl-tRNA synthetase, or any other cellular element. Furthermore, as predicted, nearly equal amounts of glutaminyl and tryptophanyl-su⁺7 tRNA are actually detected in aminoacyl-tRNA extracted from growing cells. We conclude that the translational apparatus somehow discriminates against tryptophanyl-su⁺7 tRNA at a step after synthesis of the two aminoacyl-tRNAs.     

Discrimination between aminoacyl groups on su+ 7 tRNA by elongation factor Tu

The su⁺7 nonsense suppressor of Escherichia coli is a mutant tRNA^Trp that can be aminoacylated with either tryptophan or glutamine. We have compared the ternary complexes of glutaminyl and tryptophanyl-su⁺7 tRNA with elongation factor Tu and GTP. Glutaminyl-su⁺7 tRNA binds more strongly than tryptophanyl-su⁺7 tRNA to EF Tu · GTP. The greatest distinction between the two species of the tRNA is seen in their dissociation rates from the complex, which differ by as much as fivefold. The distinction is affected by pH values around neutrality. These results show that EF Tu can distinguish between two aminoacyl-tRNAs which differ only in the aminoacyl group. The implications for the unusual amino acid specificity of su⁺7 tRNA are discussed.     

Ribonucleic acid-permeable mutant of Escherichia coli

An RNA-permeable mutant was isolated from a tryptophan amber auxotrophic strain of Escherichia coli after mutagenesis with N-methyl-N'-nitro-N-nitrosoguanidine. The rationale of the isolation was based on the suppression of an amber mutation. A strain was selected, which could grow in minimal medium supplemented with transfer RNA prepared from an suI-carrying strain but not from an su⁻ strain. This mutant incorporated³H-labeled bulk RNA into the cells at a rate 40 times higher than did the parent strain. The level of tryptophan requirement, susceptibility to the lytic action of lysozyme and RNase activity in the culture medium of the mutant strain did not differ from those of the parent strain. The mutant strain incorporated ³H-labeled ribosomal RNA equally as well as it incorporated ³H-labeled transfer RNA and the incorporation was competitively inhibited by any species of cold RNA. However, the fate of ³H-labeled rRNA after incorporation resulted in degradation to yield acid-soluble fragments whereas tRNA after incorporation remained intact in the cell.     

A single mutational modification of a tryptophan-specific transfer RNA permits aminoacylation by glutamine and translation of the codon UAG

In this work we show that the wild-type (su^?7) progenitor of the recessivelethal suppressors of UAG (su⁺7(UAG)) and of UAA/G (su⁺7(UAA/G)) is the structural gene for transfer RNA^Trp, the adaptor for translating the codon UGG. The su⁺7(UAG) suppressor form of the tRNA has a C for U substitution in the middle base of the anticodon; in the su⁺7(UAA/G) suppressor tRNA both C residues of the anticodon are replaced by U. Our data establish that the mutational change altering the tRNA^Trp to a UAG suppressor is accompanied by a loss of tryptophan-accepting specificity and the acquisition of glutamine-acceptor activity.     

Mutational alterations of tryptophan-specific transfer RNA that generate translation suppressors of the UAA, UAG and UGA nonsense codons

The recessive lethal amber suppressor su⁺7(UAG-1) in Escherichia coli inserts glutamine in response to the UAG codon. The genetic analysis presented in this paper shows that the su^?7 precursor allele can give rise to suppressors of the UGA codon as well as of the UAG codon. This observation suggests that the su^?7 gene normally codes for transfer RNA^Trp, a tRNA whose anticodon can be modified by single base changes to forms that can translate either UAG or UGA. The chemical findings presented in the accompanying paper (Yaniv et al., 1974) are wholly in accord with this interpretation. Thus, a single base substitution in the anticodon sequence of a tRNA can affect both the coding specificity of the molecule and also the amino acid acceptor specificity.     

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.     

Human Cells Have a Limited Set of tRNA Anticodon Loop Substrates of the tRNA Isopentenyltransferase TRIT1 Tumor Suppressor

Human TRIT1 is a tRNA isopentenyltransferase (IPTase) homologue of Escherichia coli MiaA, Saccharomyces cerevisiae Mod5, Schizosaccharomyces pombe Tit1, and Caenorhabditis elegans GRO-1 that adds isopentenyl groups to adenosine 37 (i6A37) of substrate tRNAs. Prior studies indicate that i6A37 increases translation fidelity and efficiency in codon-specific ways. TRIT1 is a tumor suppressor whose mutant alleles are associated with cancer progression. We report the systematic identification of i6A37-containing tRNAs in a higher eukaryote, performed using small interfering RNA knockdown and other methods to examine TRIT1 activity in HeLa cells. Although several potential substrates contained the IPTase recognition sequence A36A37A38 in the anticodon loop, only tRNA^SerAGA, tRNA^SerCGA, tRNA^SerUGA, and selenocysteine tRNA with UCA (tRNA^[Ser]SecUCA) contained i6A37. This subset is a significantly more restricted than that for two distant yeasts (S. cerevisiae and S. pombe), the only other organisms comprehensively examined. Unlike the fully i6A37-modified tRNAs for Ser, tRNA^[Ser]SecUCA is partially (∼40%) modified. Exogenous selenium and other treatments that decreased the i6A37 content of tRNA^[Ser]SecUCA led to increased levels of the tRNA^[Ser]SecUCA. Of the human mitochondrion (mt)-encoded tRNAs with A36A37A38, only mt tRNAs tRNA^SerUGA and tRNA^TrpUCA contained detectable i6A37. Moreover, while tRNA^Ser levels were unaffected by TRIT1 knockdown, the tRNA^[Ser]SecUCA level was increased and the mt tRNA^SerUGA level was decreased, suggesting that TRIT1 may control the levels of some tRNAs as well as their specific activity.     

The effect of an Escherichia coli regulatory mutation on transfer RNA structure.

The trpX mutation in Escherichia coli reduces trp operon attenuation in strains carrying wild-type tRNA^Trp. The trpX^? phenotype is alleviated (attenuation is restored) in UGA-suppressor tRNA^Trp-carrying strains (Yanofsky &; Soll, 1977).The tRNA from various trpX^? strains was characterized biochemically. Sequence analyses of wild-type tRNA^Trp and UGA suppressor tRNA^Trp, both derived from trpX^? strains, reveal an unmodified A in the position (adjacent to the anticodon) normally occupied by the hypermodified base ms²i⁶A.In addition, several tRNAs from trpX^? cells were characterized by RPC-5 column chromatography. We find that only tRNAs normally having ms²i⁶A exhibit altered elution profiles when compared to the homologous tRNAs from trpX^? cells. Introduction of the UGA suppressor into trpX^? cells does not restore normal Chromatographic behavior. These results suggest that the trpX gene product is necessary for the synthesis of ms²i⁶A. Thus, we propose that miaA (for the first gene involved in ms²i⁶A synthesis) replaces the trpX designation.The results reported here are discussed with regard to a model proposed by Lee &; Yanofsky (1977) in which efficient translation of the tandem trp codons in the leader sequence RNA is required for normal attenuation of the trp operon.     

Structure and properties of a bovine liver UGA suppressor serine tRNA with a tryptophan anticodon

A bovine liver serine tRNA with a variety of unusual features has been sequenced and characterized. This tRNA is aminoacylated with serine, although it has a tryptophan anticodon CmCA. In ribosome binding assays, this tRNA (tRNA_CmCA^Ser) binds to the termination codon UGA and shows little or no binding in response to a variety of other codons including those for tryptophan and serine. The unusual codon recognition properties of this molecule were confirmed in an in vitro assay where this tRNA suppressed UGA termination. This is the first naturally occurring eucaryotic suppressor tRNA to be so characterized. Other unusual features, possibly related to the ability of this tRNA to read UGA, are the presence of two extra nucleotides, compared to all other tRNAs, between the universal residues U at position 8 and A at position 14 and the presence of an extra unpaired nucleotide within the double-stranded loop IV stem. This tRNA is also the largest eucaryotic tRNA sequenced to date (90 nucleotides). Despite its size, however, it contains only six modified residues. tRNA_CmCA^Ser shows extremely low homology to other mammalian serine (47–52% homology) or tryptophan (49% homology) tRNAs.     

Analysis of specific misreading in Escherichia coli

The pattern of specific misreading by nonsense suppressors has been investigated using nonsense mutants in the rIIB gene of phage T4 and in the lacZ gene of Escherichia coli. It is shown that a su⁺ transfer RNA which reads UAG also misreads UAA but not UGA, a su⁺ tRNA which reads UAA (while it also reads UAG by wobble) misreads UGA and a su⁺ tRNA which reads UGA also probably misreads UAA but not UAG.These specific types of errors in translation occur in the absence of streptomycin. The addition of the drug raises their level without altering the pattern described. A ribosomal mutation str A reduces the level of specific misreading; by contrast, a ram mutation strongly increases this level. In all cases the specific pattern is not affected.The rate of specific misreading of nonsense codons in different cases ranges from less than 0.001% to more than 3%. Since the frequency of misreading is sitespecific (unpublished observations), the rates obtained cannot be extrapolated to any other codon at any other site.     

Thiolated tRNAs of Trypanosoma brucei Are Imported into Mitochondria and Dethiolated after Import

All mitochondrial tRNAs in Trypanosoma brucei derive from cytosolic tRNAs that are in part imported into mitochondria. Some trypanosomal tRNAs are thiolated in a compartment-specific manner. We have identified three proteins required for the thio modification of cytosolic tRNA^Gln, tRNA^Glu, and tRNA^Lys. RNA interference-mediated ablation of these proteins results in the cytosolic accumulation non-thio-modified tRNAs but does not increase their import. Moreover, in vitro import experiments showed that both thio-modified and non-thio-modified tRNA^Glu can efficiently be imported into mitochondria. These results indicate that unlike previously suggested the cytosol-specific thio modifications do not function as antideterminants for mitochondrial tRNA import. Consistent with these results we showed by using inducible expression of a tagged tRNA^Glu that it is mainly the thiolated form that is imported in vivo. Unexpectedly, the imported tRNA becomes dethiolated after import, which explains why the non-thiolated form is enriched in mitochondria. Finally, we have identified two genes required for thiolation of imported tRNA^Trp whose wobble nucleotide is subject to mitochondrial C to U editing. Interestingly, down-regulation of thiolation resulted in an increase of edited tRNA^Trp but did not affect growth.     

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.     

Inhibition of yeast tRNATrp aminoacylation by 4-methyltryptophan

The effect of the tryptophan analogue 4-methyltryptophan in Saccharomyces cerevisiae has been investigated. 4-Methyltryptophan inhibits the aminoacylation of tryptophan specific transfer ribonucleic acid (tRNA^Trp). The mode of inhibition is competitive and the analogue is not charged onto tRNA^Trp. Thus 4-methyltryptophan application depletes the cells from charged tRNA^Trp. As a consequence cell growth and protein synthesis are strongly reduced. 4-Methyltryptophan is degraded efficiently in culture media inoculated with the wild type strain; the effects of 4-methyltryptophan were therefore found to be transient.     

The Nature of the Nucleotide at the 5' Side of the tRNA Su9 Anticodon Affects UGA Suppression in Escherichia coli

In Escherichia coli a UGA codon can be efficiently suppressedby a suppressor tRNA^Trp called Su9. Here, we show that the levelof UGA suppression is determined by the nature of the nucleotideat the 5' side of the anticodon of the suppressor (position33). UGA suppression occurs when a pyrimidine residue is locatedin position 33 of the tRNA, and suppression is more efficientwith a U than with a C in this position. On the other hand,when a purine residue is located at this position UGA suppressionis extremely low. These results show that in the case of tRNASu9, the UGA codon context effect does not require base pairingbetween the nucleotide at the 3' side of the codon and the 5'side of the anticodon.     

Regulation of the Escherichiacoli tryptophan operon by readthrough of UGA termination codons

The regulation of the synthesis of $\text{trp}$ operon enzymes was studied in streptomycin-resistant $\text{Escherichia}\text{coli}$ mutants temperature-sensitive for UGA suppression by normal tRNA^Trp. Our mutants carry a $\text{trp}\text{R}{}^{\mathrm{+}}$ allele that when transferred to a different genetic background causes repression of trp operon enzyme synthesis at both low (35°C) and high (42°C) temperatures; however, in our mutants with an excess of tryptophan and at increased temperatures $\text{trp}$ enzyme synthesis is derepressed. Based on our results and the sequence data of the $\text{trp}$R gene [Singleton et al. (1980) Nucleic Acids Res., 8, 1551–1560], we offer a model for the involvement of the limited misreading of UGA codons by normal charged tRNA^Trp in the autogenous regulation of the $\text{trp}$R gene expression. The UGA readthrough process may be a regulatory amplifier of the effect of tryptophan starvation.