A temperature-sensitive mutant of Escherichia coli that shows enhanced misreading of UAG/A and increased efficiency for some tRNA nonsense suppressors

Summary A spontaneous mutant was isolated that harbors a weak suppressing activity towards a UAG mutation, together with an inability to grow at 43° C in rich medium. The mutation is shown to be associated with an increased misreading of UAG at certain codon contexts and UAA. UGA, missense or frameshift mutations do not appear to be misread to a similar extent. The mutation gives an increased efficiency to several amber tRNA suppressors with-out increasing their ambiguity towards UAA. The ochre suppressors SuB and Su5 are stimulated in their reading of both UAG and UAA with preference for UAG. An opal suppressor is not affected. The effect of the mutation on the efficiency of amber and ochre suppressors is dependent on the codon context of the nonsense codon.The mutated gene (uar) has been mapped and found to be recessive both with respect to suppressor-enhancing ability as well as for temperature sensitivity. The phenotype is partly suppressed by the ochre suppressor SuC. It is suggested that uar codes for a protein, which is involved in translational termination at UAG and UAA stop codons.     

Molecular cloning and nucleotide sequencing of the gene for E. coli cAMP receptor protein.

The crp gene of E. coli, which codes for cAMP receptor protein (CRP), has been cloned in the plasmid pBR322 on the basis of a genetic complementation. One of the recombinant plasmids, pHA1, was shown to direct the synthesis of CRP in a cell-free system. The location of the crp gene was determined by constructing subclones carrying various portions of pHA1. The nucleotide sequence of the crp gene has been determined. The coding region consists of 627 base pairs (bp), which specify a protein of 209 amino acids. The predicted amino acid sequence from the DNA sequence is consistent with the amino acid sequence partially known and the amino acid composition of CRP. After the coding region, there is a G-C rich inverted repeat sequence followed by a run of Ts, which could be a terminator of the crp gene. A possible promoter sequence was found about 180 bp upstream from the initiation codon and was shown to act as a promoter in vitro and in vivo. There are two dyad symmetry regions in a 167 bp leader sequence.     

Glutamine is incorporated at the nonsense codons UAG and UAA in a suppressor-free Escherichia coli strain

Readthrough of the nonsense codons UAG, UAA, and UGA is seen in Escherichia coli strains lacking tRNA suppressors. Earlier results indicate that UGA is miscoded by tRNA(Trp). It has also been shown that tRNA(Tyr) and tRNA(Gln) are involved in UAG and UAA decoding in several eukaryotic viruses as well as in yeast. Here we have investigated which amino acid(s) is inserted in response to the nonsense codons UAG and UAA in E. coli. To do this, the stop codon in question was introduced into the staphylococcal protein A gene. Protein A binds to IgG, which facilitates purification of the readthrough product. We have shown that the stop codons UAG and UAA direct insertion of glutamine, indicating that tRNA(Gln) can read the two codons. We have also confirmed that tryptophan is inserted in response to UGA, suggesting that it is read by tRNA(Trp).     

Recognition of translational termination signals

Ribosomes can specifically shift at certain codons so that the mRNA is read in two different reading frames. To determine if frameshifting occurs at the level of termination, polymers of defined sequence containing AUG, a coding sequence and an in- or out-of-phase nonsense codon were used to bind a termination substrate or to program synthesis and release of dipeptides in a highly purified in vitro translation system. fMet-tRNA bound to ribosomes with AUGUAA, AUGUAAn, AUGUUU, AUGUUA or AUGUAn was not a substrate for release factor RF-1. In contrast, AUGU1UAA, AUGU3UAAn, AUGU4UAAn, AUGU5UAAn effected RF-1-dependent release of fMet from ribosomes. This suggests that nonsense codons can stimulate release whether they occur in- or out-of-phase. Addition of exogenous UAA and RF-1 stimulated release with all oligonucleotides tested. Propagation restricted the RF-1-dependent recognition of out-of-phase nonsense codons but did not restrict recognition of in-phase UAA in AUGU3UAAn. Release of dipeptides from ribosomes programmed with AUGU4UAAn occurred without EF-G and with a mutant lacking EF-G activity, suggesting that out-of-phase termination can occur prior to translocation outside the ribosomal A-site. We propose that the ribosome X RF complex is required to complete proteins, but is also able to frameshift at a nonsense codon resulting in occasional out-of-phase termination of protein synthesis.     

Reversion of trpA nonsense mutations by deletion of the chain-termination codons

This paper describes a novel mechanism for reversion of nonsense mutations in the trpA gene of Escherichia coli. This mechanism, deletion of the nonsense codon, was discovered in the course of selecting for missense revertants of trpA(UGA211) and for catalytically active tryptophan synthetase alpha chain revertants of trpA(UAA234) and trpA(UAG234). Each type of revertant trpA was cloned and its DNA sequence determined. trpA(UGA211) gave rise to two previously unidentified types of missense revertant. The first type was expected, namely trpA(CGA211), the result of a base substitution event. The other type, representing approximately 1% of the missense revertants, was unexpected on the basis of single base substitutions and an understanding of which amino acids are functional at alpha chain position 211. It was found to be the result of a 21 base-pair deletion of a region containing codon 211. The tryptophan-independent revertants of both position 234 nonsense mutants occurred at a frequency of approximately 2 per 10(9) viable cells. They were identical in that they both resulted from a 3 base-pair deletion, namely deletion of the chain-terminating codon at position 234. One of them, however, also displayed an A instead of the normal G in the third position of codon 235. The revertants were characterized according to growth in different media and tryptophan synthetase assays performed on crude extracts. These types of mutants should prove interesting and important for the elucidation of alpha chain structure-function relationships, for insight into the assembly and interaction of subunits in this model multienzyme complex, and for the study of mechanisms by which deletions can be generated.     

The influence of the reading context upon the suppression of nonsense codons

Summary We have examined the response of phage T4 nonsense mutations located at various sites within the same cistron to different suppression agents. A wide range of suppression efficiency is found for both ochre (UAA) and amber (UAG) mutations under conditions where suppression provides a measurement of the amount of chain propagation past the mutated site. We have established a relationship between our measurement-the size of the phage yield-and the amount of rIIB product present in the infection. Our data suggest that the 1000-fold range of variations in yields observed in the rIIB cistron corresponds to a 30-fold range of variation in the level of rIIB product, i.e. in the relative frequency of chain propagation past the various nonsense codons included in our test.From the parallelism of response of any particular mutant to very different suppression mechanisms we conclude that the efficiency of suppression is site specific, that is to say, that the main factor determining the frequency of chain propagation at a nonsense codon by any type of suppression mechanism is the nucleotide sequence adjacent to the nonsense codon (reading context).We propose that the recognition of a natural termination signal involves a sequence longer than a nonsense codon and that nonsense codons outside of their natural environment induce variable termination rates which are reflected in the suppression potential.     

Cloning and sequencing of Pseudomonas genes encoding vanillate demethylase.

A 2,598-base-pair (bp) SalI-HincII DNA fragment has been cloned which codes for vanillate demethylase, the enzyme responsible for the demethylation of vanillate (3-methoxy-4-hydroxybenzoate) to protocatechuate (3,4-dihydroxybenzoate). Complementation and insertional inactivation experiments have shown that this fragment carries two genes (vanA and vanB) which are predominantly cotranscribed from a promoter upstream of vanA. Nucleotide sequencing of the SalI-HincII fragment confirmed the genetic data: two open reading frames of 987 and 942 bp were present in the transcribed orientation. These had a very high G + C content in the third base of each codon, which is characteristic of Pseudomonas chromosomal genes. Expression of the genes in Escherichia coli with the T7 RNA polymerase-promoter system gave rise to two polypeptides of 36 and 33 kilodaltons which could be identified by deletion analysis as the products of vanA and vanB, respectively. A search of the protein sequence data bank indicated that the vanB gene product was related to the ferredoxin family.     

The influence of the reading context upon the suppression of nonsense codons

Summary One of the basic assumptions of the current views of the genetic code is that the translation machinery reads the messenger RNA one nucleotide triplet codon at a time and that the meaning of a particular codon should not be effected by the surrounding nucleotide sequence (the reading context). Reexamination of existing data shows that this assumption does not hold for the case of suppression of the nonsense codons UAG (amber) and UAA (ochre).The efficiency of amino acid insertion in response to these nonsense codons appears to strongly depend on their location within the message. It is suggested that the translation machinery may interact with a nucleotide sequence longer than three nucleotides when involved in a chain termination reaction.     

Three Tetrahymena tRNA(Gln) isoacceptors as tools for studying unorthodox codon recognition and codon context effects during protein synthesis in vitro.

Three glutamine tRNA isoacceptors are known in Tetrahymena thermophila. One of these has the anticodon UmUG which reads the two normal glutamine codons CAA and CAG, whereas the two others with CUA and UmUA anticodons recognize UAG and UAA, respectively, which serve as termination codons in other organisms. We have employed these tRNA(Gln)-isoacceptors as tools for studying unconventional base interactions in a mRNA- and tRNA-dependent wheat germ extract. We demonstrate here (i) that tRNA(Gln)UmUG suppresses the UAA as well as the UAG stop codon, involving a single G:U wobble pair at the third anticodon position and two simultaneous wobble base pairings at the first and third position, respectively, and (ii) that tRNA(Gln)CUA, in addition to its cognate codon UAG, reads the UAA stop codon which necessitates a C:A mispairing in the first anticodon position. These unorthodox base interactions take place in a codon context which favours readthrough in tobacco mosaic virus (TMV) or tobacco rattle virus (TRV) RNA, but are not observed in a context that terminates zein and globin protein synthesis. Furthermore, our data reveal that wobble or mispairing in the middle position of anticodon-codon interactions is precluded in either context. The suppressor activities of tRNAs(Gln) are compared with those of other known naturally occurring suppressor tRNAs, i.e., tRNA(Tyr)G psi A and tRNA(Trp)CmCA. Our results indicate that a 'leaky' context is neither restricted to a single stop codon nor to a distinct tRNA species.     

Role of the IS50 R proteins in the promotion and control of Tn5 transposition

IS50R, the inverted repeat sequence of Tn5 which is responsible for supplying functions that promote and control Tn5 transposition, encodes two polypeptides that differ at their N terminus. Frameshift, in-frame deletion, nonsense, and missense mutations within the N terminus of protein 1 (which is not present in protein 2) were isolated and characterized. The properties of these mutations demonstrate that protein 1 is absolutely required for Tn5 transposition. None of these mutations affected the inhibitory activity of IS50, confirming that protein 2 is sufficient to mediate inhibition of Tn5 transposition. The effects on transposition of increasing the amount of protein 2 (the inhibitor) relative to protein 1 (the transposase) were also analyzed. Relatively large amounts of protein 2 were required to see a significant decrease in the transposition frequency of an element. In addition, varying the co-ordinate synthesis of the IS50 R proteins over a 30-fold range had little effect on the transposition frequency. These studies suggest that neither the wild-type synthesis rate of protein 2 relative to protein 1 nor the amount of synthesis of both IS50 R proteins is the only factor responsible for controlling the transposition frequency of a wild-type Tn5 element in Escherichia coli.     

Frameshift suppression through inactivation of translation termination in yeast Saccharomyces cerevisiae: significance of the local context

Site-directed mutagenesis and nucleotide sequence analysis were used to study the roles of the global and local contexts in suppression of the lys2-90 frameshift (FS) mutation in Saccharomyces cerevisiae. Global context features established for the LYS2 mRNA region containing the extra T (lys2-90) were similar to those characteristic of regions involved in translational frameshifting. These were a potential ability of the region to form a pseudoknot and the presence of heptanucleotide CUU UGA C with the "hungry" UGA nonsense codon in the pseudoknot. Some local context features proved to be essential for the phenotypic expression of FS suppression as a result of translational frameshifting. Two amino acid substitutions determined by the nucleotide sequence between the extra U and the UGA nonsense codon lacked expression. A dependence was observed between the efficiency of FS suppression and the type of the nonsense codon located at a particular position downstream of the extra nucleotide (UGA > UAG > UAA). When translation termination was inactivated, nonsense suppression and FS suppression correlated with each other. These results suggest that translational frameshifting, which underlies suppression in the case of inactivation of translation termination, most likely takes place on the nonsense codon arising as a result of insertion of an extra nucleotide.     

Characterization of the transposon carrying the STII gene of enterotoxigenic Escherichia coli

Summary The Escherichia coli enterotoxin STII gene is carried by Tn4521. The terminal repeats of Tn4521 are composed of IS2 sequences; however, neither repeat is a complete IS2. In order to determine how this seemingly defective transposon could transpose, mutations were generated within Tn4521 to determine the regions essential for transposition. The left terminal repeat region was found to be non-essential, but the right terminal repeat area was demonstrated to be crucial for transposition. Within the right terminal repeat area is an open reading frame (ORF), capable of encoding a 159 amino acid protein, which was shown by frameshift mutation analysis to be required for transposition. This protein may be the transposase of Tn4521. A pair of 11 bp repeat sequences flanking the ORF was also found to be important. The right 11 bp repeat is part of the left IS2 terminal sequence, and the left 11 bp repeat is located about 300 bp upstream from the right IS2 terminal sequence located within the right terminal repeat region. The results of this study suggest that Tn4521 is a functional transposon and that the sequence including this pair of 11 bp sequences plus the intervening sequence is a transposable element which may be responsible for Tn4521 transposition.     

In vitro suppression of a nonsense mutant of Drosophila melanogaster.

When RNA isolated from the Drosophila melanogaster alcohol dehydrogenase (ADH) negative mutant CyOnB was translated "in vitro" in the presence of yeast opal suppressor tRNA, a wild type size ADH protein was obtained in addition to the mutant gene product. This identifies the CyOnB mutant as an opal (UGA) nonsense mutant. From the molecular weight of the mutant protein, and from the known sequence of the ADH gene (Benyajati et al., Proc.Natl.Acad.Sci. USA 78, 2717-2721, 1981), we conclude that the tryptophan codon UGG in position 234 has been changed into a UGA nonsense codon in the CyOnB mutant. Furthermore, we show that the UAA stop codon of the wild type ADH gene is resistant to suppression by a yeast ochre suppressor tRNA. This is in contrast to the high efficiency of suppression of the CyOnB UGA nonsense codon, despite an almost identical codon context.     

Ribosomes containing the C1054-deletion mutation in E. coli 16S rRNA act as suppressors at all three nonsense codons.

It was established some time ago that the deletion of base C1054 in E. coli 16S rRNA specifically affects UGA-dependent termination of translation. Based on this observation, a model for the termination event was proposed in which the UGA nonsense codon on the mRNA base-pairs with a complementary motif in 'helix 34' of the 16S rRNA, thus potentially providing a recognition signal for the binding of the release factor. This model has been re-examined here and evidence is presented which demonstrates that ribosomes containing the C1054 delta mutation enhance the activity of suppressors of both UAG and UAA termination codons introduced into the host. The results do not support the nonsense codon-16S rRNA base pairing model, and rather imply a more general involvement of 'helix 34' in the translation termination reactions.     

Construction and testing of a bacterial luciferase reporter gene system forin Vivo measurement of nonsense suppression inStreptomyces

A reporter gene system, based on luciferase genes from Vibrio harvei, was constructed for measurement of translation nonsense suppression in Streptomyces. Using the site-directed mutagenesis the TCA codon in position 13 of the luxB gene was replaced by all of the three stop codons individually. By cloning of luxA and luxB genes under the control of strong constitutive Streptomyces promoter ermE* in plasmid pUWL201 we created Wluxl with the wild-type sequence and pWlux2, pWlux3 and pWlux4 plasmids containing TGA-, TAG- and TAA-stop codons, respectively. Streptomyces lividans TK 24 was transformed with the plasmids and the reporter system was tested by growth of the strain in the presence of streptomycin as a translation accuracy modulator. Streptomycin increased nonsense suppression on UAA nearly 10-fold and more than 20-fold on UAG. On the other hand, UGA, the most frequent stop signal in Streptomyces, the effect was negligible.     

Rationalization and prediction of selective decoding of pseudouridine-modified nonsense and sense codons

A stop or nonsense codon is an in-frame triplet within a messenger RNA that signals the termination of translation. One common feature shared among all three nonsense codons (UAA, UAG, and UGA) is a uridine present at the first codon position. It has been recently shown that the conversion of this uridine into pseudouridine (Ψ) suppresses translation termination, both in vitro and in vivo. Furthermore, decoding of the pseudouridylated nonsense codons is accompanied by the incorporation of two specific amino acids in a nonsense codon-dependent fashion. Ψ differs from uridine by a single N1H group at the C5 position; how Ψ suppresses termination and, more importantly, enables selective decoding is poorly understood. Here, we provide molecular rationales for how pseudouridylated stop codons are selectively decoded. Our analysis applies crystal structures of ribosomes in varying states of translation to consider weakened interaction of Ψ with release factor; thermodynamic and geometric considerations of the codon-anticodon base pairs to rank and to eliminate mRNA-tRNA pairs; the mechanism of fidelity check of the codon-anticodon pairing by the ribosome to evaluate noncanonical codon-anticodon base pairs and the role of water. We also consider certain tRNA modifications that interfere with the Ψ-coordinated water in the major groove of the codon-anticodon mini-helix. Our analysis of nonsense codons enables prediction of potential decoding properties for Ψ-modified sense codons, such as decoding ΨUU potentially as Cys and Tyr. Our results provide molecular rationale for the remarkable dynamics of ribosome decoding and insights on possible reprogramming of the genetic code using mRNA modifications.     

Construction, expression, and function of a new yeast amber suppressor, tRNATrpA

The number of different tRNA species in Saccharomyces cerevisiae known to be capable of suppressing termination of translation at UAG, UAA, and UGA codons is limited to those which insert tyrosine, leucine, and serine. Suppressor tRNAs that insert other amino acids, even those whose anticodons differ from the expected recognition sequences for nonsense codons by a single nucleotide, have never been identified via classical genetic analysis. We have used site-directed mutagenesis to convert the anticodon of a cloned tRNATrp gene from CCA to CTA with the expectation that this gene would produce tRNA molecules capable of interacting with the UAG terminator codon. We show that this form of the gene can be transcribed and spliced in vitro to produce mature tRNA with the expected base sequence. The putative suppressor gene has been introduced into several S. cerevisiae host strains using the centromere vector YCp19. Efficient suppression of amber mutations met8-1, tyr7-1, and lys2-801 results from the presence of the CTA form of tDNATrp. Two UAA mutants, leu2-1 and ade2-101, and the UGA marker his4-260 are not suppressed.