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.     

Evidence that the supE44 Mutation of Escherichia coli Is an Amber Suppressor Allele of glnX and that It Also Suppresses Ochre and Opal Nonsense Mutations

Translational readthrough of nonsense codons is seen not only in organisms possessing one or more tRNA suppressors but also in strains lacking suppressors. Amber suppressor tRNAs have been reported to suppress only amber nonsense mutations, unlike ochre suppressors, which can suppress both amber and ochre mutations, essentially due to wobble base pairing. In an Escherichia coli strain carrying the lacZU118 episome (an ochre mutation in the lacZ gene) and harboring the supE44 allele, suppression of the ochre mutation was observed after 7 days of incubation. The presence of the supE44 lesion in the relevant strains was confirmed by sequencing, and it was found to be in the duplicate copy of the glnV tRNA gene, glnX. To investigate this further, an in vivo luciferase assay developed by D. W. Schultz and M. Yarus (J. Bacteriol. 172:595-602, 1990) was employed to evaluate the efficiency of suppression of amber (UAG), ochre (UAA), and opal (UGA) mutations by supE44. We have shown here that supE44 suppresses ochre as well as opal nonsense mutations, with comparable efficiencies. The readthrough of nonsense mutations in a wild-type E. coli strain was much lower than that in a supE44 strain when measured by the luciferase assay. Increased suppression of nonsense mutations, especially ochre and opal, by supE44 was found to be growth phase dependent, as this phenomenon was only observed in stationary phase and not in logarithmic phase. These results have implications for the decoding accuracy of the translational machinery, particularly in stationary growth phase.Translation termination is mediated by one of the three stop codons (UAA, UAG, or UGA). When such stop codons arise in coding sequences due to mutations, referred to as nonsense mutations, they lead to abrupt arrest of the translation process. However, the termination efficiency of such nonsense codons is not 100%, as certain tRNAs have the ability to read these nonsense codons. Genetic code ambiguity is seen in several organisms. Stop codons have been shown to have alternate roles apart from translation termination. In organisms from all three domains of life, UGA encodes selenocysteine through a specialized mechanism. In Methanosarcinaceae, UAG encodes pyrrolysine (3). UAA and UAG are read as glutamine codons in some green algae and ciliates such as Tetrahymena and Diplomonads (24), and UAG alone encodes glutamine in Moloney murine leukemia virus (32). UGA encodes cysteine in Euplotes; tryptophan in some ciliates, Mycoplasma species, Spiroplasma citri, Bacillus, and tobacco rattle virus; and an unidentified amino acid in Pseudomicrothorax dubius and Nyctotherus ovalis (30). In certain cases the context of the stop codon in translational readthrough has been shown to play a role; for example, it has been reported that in vitro in tobacco mosaic virus, UAG and UAA are misread by tRNA^Tyr in a highly context-dependent manner (34, 9).Termination suppressors are of three types, i.e., amber, ochre, and opal suppressors, which are named based on their ability to suppress the three stop codons. Amber suppressors can suppress only amber codons, whereas ochre suppressors can suppress ochre codons (by normal base pairing) as well as amber codons (by wobbling) and opal suppressors can read opal and UGG tryptophan codon in certain cases. As described by Sambrook et al. (27), a few amber suppressors can also suppress ochre mutations by wobbling. The suppression efficiency varies among these suppressors, with amber suppressors generally showing increased efficiency over ochre and opal suppressors. supE44, an amber suppressor tRNA, is an allele of and is found in many commonly used strains of Escherichia coli K-12. Earlier studies have shown that supE44 is a weak amber suppressor and that its efficiency varies up to 35-fold depending on the reading context of the stop codon (8).Translational accuracy depends on several factors, which include charging of tRNAs with specific amino acids, mRNA decoding, and the presence of antibiotics such as streptomycin and mutations in ribosomal proteins which modulate the fidelity of the translational machinery. Among these, mRNA decoding errors have been reported to occur at a frequency ranging from about 10⁻³ to 10⁻⁴ per codon. Translational misreading errors also largely depend on the competition between cognate and near-cognate tRNA species. Poor availability of cognate tRNAs increases misreading (18).Several studies with E. coli and Saccharomyces cerevisiae have shown the readthrough of nonsense codons in suppressor-free cells. In a suppressor-free E. coli strain, it has been shown in vitro that glutamine is incorporated at the nonsense codons UAG and UAA (26). It has been reported that overexpression of wild-type tRNA^Gln in yeast suppresses amber as well as ochre mutations (25). In this study, we have confirmed the presence of an amber suppressor mutation in the glnX gene in a supE44 strain by sequence analysis. This was done essentially because we observed that supE44 could also suppress lacZ ochre mutations, albeit inefficiently. On further investigation using an in vivo luciferase reporter assay system for tRNA-mediated nonsense suppression (28), we found that the efficiency of suppression of amber lesion by supE44 is significantly higher than that reported previously in the literature. An increased ability to suppress ochre and opal nonsense mutations was observed in cells bearing supE44 compared to in the wild type. Such an effect was observed only in the stationary phase and was abolished in logarithmic phase.     

Missense and nonsense suppressors derived from a glycine tRNA by nucleotide insertion and deletion in vivo

Summary Beginning with a missense suppressor tRNA and a nonsense suppressor tRNA, both in Escherichia coli and each containing an extra nucleotide in the anticodon loop, we generated new suppressors in vivo by spontaneous deletion of specific nucleotides from the anticodon loop. In one experiment, the new suppressor was generated by a double mutational event, base substitution and nucleotide deletion. A novel ochre suppressor is also described. It is very efficient in nonsense suppression but has no ms²i⁶ modification of the A residue on the 3 side of the anticodon. The results have important implications for tRNA structure-function relationships, tRNA recognition by tRNA-modifying enzymes, mechanisms of deletion mutation, and tRNA evolution.A preliminary report of these results was presented at the EMBO Workshop on Accuracy, Grignon, France, September 1–6, 1981     

Characterization of missense suppressors of a double mutant of the tryptophan synthetase alpha chain of Escherichia coli.

Summary Eight suppressors of trpA218, a missense double mutant of trpA, the gene for the tryptophan synthetase alpha chain of Escherichia coli, have been further characterized genetically, physiologically and biochemically. trpA218 possesses an inactive alpha chain that contains leucine (instead of phenylalanine) at position 22 and serine (instead of glycine) at position 211. Replacement of either mutant amino acid by the corresponding wild type amino acid leads to an active alpha chain. To determine whether each trpA218 suppressor (Su218) affects the 22 or 211 position, a substitute trpA218 was constructed. Whereas the original double mutant possesses a Ser211 specified by the codon AGU, we constructed a trpA(Leu22-Ser211) in which the Ser211 codon is UCG. All eight Su218s failed to suppress the new double mutant. The suppressors fall into two classes according to growth in various media. Six of the eight map in the region of glyV, a gene for the GGU/C-reading glycine tRNA. After reversed phase column chromatography of radioactively labeled glycyl-tRNA, the suppressor tRNAs exhibited altered profiles that were similarly different from the parental tRNA in all eight cases. These results suggest that there are several classes of Su218, that all of them suppress the serine codon AGU (or AGC) corresponding to position 211, and that at least six of the eight are mutationally altered glycine tRNAs.A preliminary report of portions of this work was presented at the spring meeting of the Texas Branch of the American Society for Microbiology, College Station, Texas, March, 1975     

Patterns of Genetic and Phenotypic Suppression of lys2 Mutations in the Yeast SACCHAROMYCES CEREVISIAE

A total of 358 lys2 mutants of Saccharomyces cerevisiae have been characterized for suppressibility by the following suppressors: UAA and UAG suppressors that insert tyrosine, serine or leucine; a putative UGA suppressor; an omnipotent suppressor SUP46; and a frameshift suppressor SUF1–1. In addition, the lys2 mutants were examined for phenotypic suppression by the aminoglycoside antibiotic paromomycin, for osmotic remediability and for temperature sensitivity. The mutants exhibited over 50 different patterns of suppression and most of the nonsense mutants appeared similar to nonsense mutants previously described. A total of 24% were suppressible by one or more of the UAA suppressors, 4% were suppressible by one or more of the UAG suppressors, while only one was suppressible by the UGA suppressor and only one was weakly suppressible by the frameshift suppressor. One mutant responded to both UAA and UAG suppressors, indicating that UAA or UAG mutations at certain rare sites can be exceptions to the specific action of UAA and UAG suppressors. Some of the mutants appeared to require certain types of amino acid replacements at the mutant sites in order to produce a functional gene product, while others appeared to require suppressors that were expressed at high levels. Many of the mutants suppressible by SUP46 and paromomycin were not suppressible by any of the UAA, UAG or UGA suppressors, indicating that omnipotent suppression and phenotypic suppression need not be restricted to nonsense mutations. All of the mutants suppressible by SUP46 were also suppressible by paromomycin, suggesting a common mode of action of omnipotent suppression and phenotypic misreading.     

Isolation of Lactococcus lactis nonsense suppressors and construction of a food-grade cloning vector

Nonsense suppressor strains of Lactococcus lactis were isolated using plasmids containing nonsense mutations or as revertants of a nonsense auxotrophic mutant. The nonsense suppressor gene was cloned from two suppressor strains and the DNA sequence determined. One suppressor is an ochre suppressor with an altered tRNA_gin and the other an amber suppressor with an altered tRNA_ser. The nonsense suppressors allowed isolation of nonsense mutants of a lytic bacteriophage and suppressible auxotrophic mutants of L. lactis MG1363. A food-grade cloning vector based totally on DNA from Lactococcus and a synthetic polylinker with 11 unique restriction sites was constructed using the ochre suppressor as a selectable marker. Selection, following etectroporation of a suppressible purine auxotroph, can be done on purine-free medium. The pepN gene from L. lactis Wg2 was subcloned resulting in a food-grade plasmid giving a four- to fivefold increase in lysine aminopeptidase activity.     

Release factor competition is equivalent at strong and weakly suppressed nonsense codons

Summary We have compared the competition between strong or weak suppressor tRNAs and translational release factors (RF) at nonsense codons in the lacI gene of Escherichia coli. Using the F'lacIZ fusions developed by Miller and coworkers, UAG, UAA, and UGA codons at positions 189 and 220 were efficiently suppressed by plasmid-borne tRNAtrp suppressors cognate to each nonsense triplet. Introduction of a compatible RF 1 plasmid competed at UAG and UAA but not UGA codons. An RF2 expressing plasmid competed at UAA and UGA but had little effect at UAG. Release factor competition against weak suppressors was measured using combinations of noncognate suppressors and nonsense codons. In each case, release factor plasmids behaved identically towards poorly suppressed codons as they did when the same codons were efficiently suppressed. The implications for these studies on the role of release factors in nonsense suppression context effects are discussed.     

Isolation of lysine codon suppressors inEscherichia coli

Starting with anEscherichia coli strain containingglyT56, a glycine transfer RNA suppressor of the arginine codons AGA and AGG, and atrpA mutant containing lysine at position 211 of the tryptophan synthetase alpha chain, we have isolated AAG-suppressors that fall into two classes. In class 1 are dominant suppressors that arose with the simultaneous loss ofglyT56 activity. They are approximately 50% cotransducible withargE, as isglyT, and appear to be derived fromglyT56. Class 2 suppressors, located betweenpurE andtrp on theE. coli map, are not near any glycine tRNA genes, and may represent novel missense suppressors.     

Genetic and Physiological Characterization of met15 Mutants of SACCHAROMYCES CEREVISIAE: a Selective System for Forward and Reverse Mutations

One hundred and thirty-three spontaneous and induced mutants of the met15 locus in Saccharomyces cerevisiae were characterized with respect to temperature sensitivity, osmotic remediability, interallelic complementation, and suppressibility by amber and ochre suppressors. Forty mutants are osmotic remedial; 17 of these, and no others, are also temperature-sensitive. Seven of 133 mutations are suppressible by an amber suppressor and 11 are suppressible by an ochre suppressor. Seventy percent of the mutants exhibited interallelic complementation, suggesting that the functional gene product of the met15 gene is a multimeric protein. Relative map positions of 30 met15 were estimated from the frequencies of X-ray-induced mitotic reversion of various heteroallelic diploids. All complementing nonsense mutations are located near one end of the gene in contrast to other nonsense mutations which span most of the gene, thus relating the direction of translation of the mRNA with respect to the fine-structure map. Recombination studies indicated that two of 30 mutants contained deletions of the entire met15 locus.—It was established that a variety of mutational types, including missense, nonsense, and deletions, are recovered with this unique system in which both forward and reverse mutations can be selected on the basis of methyl mercury resistance and methionine requirement of the met15 mutants.     

Reversion of nonsense mutants induced by 4-nitroquinoline-1-oxide in Schizosaccharomyces pombe.

We have studied the reversion of 8 nonsense alleles located in 7 different genes of Schizosaccharomyces pombe using 4-nitroquinoline-1-oxide (NQO) as a mutagenic agent. The nonsense mutants of S. pombe have been classified according to their suppressibility by defined opal and ochre suppressors into a class of efficiently suppressed opal and a class of inefficiency suppressed ochre mutants. The UGA alleles tested all revert consistently with NQO, in agreement with the high specificity of this mutagen for G-residues reported for bacteria and yeast. The UAA alleles show a lack or a low level of reversion with NQO. This low level of reversion is due to the low level of non-G-specific transversions at A sites of the UAA triplet. Within each class of nonsense mutants the extent of induction is site-dependent. We conclude that NQO acts predominantly on G-residues in S. pombe.     

Isolation and characterization of context mutations affecting the suppressibility of nonsense mutations

Summary Secondary mutations which increase the efficiency of suppression of nonsense mutations in the rHB cistron of bacteriophage T4 have been isolated. These secondary mutations, called context mutations, map at sites very close to the nonsense codon, possibly on the promotor distal side. In context-nonsense double mutants, the amount of suppressed gene product is increased approximately 10-fold. The context mutations examined can act on the UAA (ochre) nonsense allele as well as on the UAG (amber) nonsense allele at a given site. These context mutations affect all suppression mechanisms analyzed (genetic suppressors. 5-fluorouracil suppression and spontaneous suppression).We suggest that context mutations affect information which is significant to the termination of polypeptide chains. According to our view, context mutations change the immediate neighborhood of nonsense mutations and so reduce the degree of resemblance to the sequences normally used for the termination of translation.     

Analysis of ultraviolet light-induced suppressor mutations in the strain of Escherichia coli K-12 AB1157: an implication for molecular mechanisms of UV mutagenesis

Summary Genetic analysis of histidine independent (His⁴) revertants induced by ultraviolet light in the his-4 E. coli strain AB1157 was carried out: 83% carried ochre (UAA) suppressor mutations and 17% carried back mutations to his ⁺ or (intragenic?) suppressors not detectably separable from his-4. Using the specialized transducing psu 2int ^– phage, which carries supE-supB, it was determined that 87% of the ochre suppressors mapped in the supE-supB region. We were able to deduce that 56% of these affected tRNA ₁ ^Gln by a CAATAA change in the tRNA gene while 31% affected tRNA ₂ ^Gln by TAGTAA change. Although we were unable to deduce the base substitution of the remaining 13%, the results indicated that most of the suppressor mutations are caused by a G:C to A:T transition.These results suggest that the high incidence of supE-supB region suppressor mutation in E. coli by UV would be a reflection of the general feature of UV mutagenesis; i.e. preferential induction of G:C to A:T transition in repairing nonparing DNA lesions.     

Differentiation between Amber and Ochre Mutants of Yeast by Reversion with 4-Nitroquinoline-1-Oxide

4-nitroquinoline-1-oxide (NQO) induces high frequencies of intragenic revertants of amber (UAG) but not ochre (UAA) mutants of yeast. Distinction of the amber and ochre codons was made with well-characterized nonsense mutants of the iso-1-cytochrome c gene (cyc1 mutants) as well as with nonsense mutants having nutritional requirements. Thus the NQO-induced reversion frequencies corroborated the assignments that were based on the pattern of amino acid replacements in intragenic revertants and on the speficity of suppression. It was concluded from these results and from the results of a previous investigation with other cyc1 mutants (Prakash, Stewart and Sherman 1974) that NQO induces transversions of G:C base pairs at many sites and that the specificity is not strongly influenced by neighboring base pairs in at least the strains examined in these studies. NQO was previously shown to induce G:C → A:T transitions at least at one site and this and the previous study established that it does not significantly mutate A:T base pairs at numerous sites. Thus NQO can be used to selectively mutate G:C base pairs and to determine if the pathways of reverse mutations involve G:C base pairs. Suppressors that act on either amber or ochre mutants were induced with NQO, indicating that they can arise by mutations of G:C base pairs.     

Polarity of localised conversion in Streptococcus pneumoniae transformation

Summary Localised conversion in pneumococcal transformation is a process that spans a few nucleotides when the 5-ATTAAT/3-TAAGTA configuration occurs at the pairing step. It was first observed in two-point crosses between an amiA mutation (amiA36) carrying this sequence and other closely linked mutants of the locus. The yield of the amiA resistance allele conversion to wild type is 20%. In order to characterize this process, which differs from longpatch conversion by the length of DNA repair, gene requirements and sequence specificity, we devised expreriments to detect the reciprocal conversion, AmiA⁺ to AmiA^r. For this purpose we examined the suppressibility by a pneumococcal informational suppressor of several nonsense mutations at the locus. Amber (UAG) and ochre (UAA) mutations are suppressed whereas UGA is not suppressed. In this genetic background, where amiA36 is partly suppressed, it was possible to select for double mutants in a cross between amiA36 and a closely linked non-suppressible marker. Direct isolation of such double mutants was also performed without any screening in crosses between amiA36 and the same linked marker in cloned DNA. The frequency of double mutants was very low (1/175) suggesting that there is no conversion of wild-type to mutant alleles. Thus conversion is a polarized process changing specifically A to C.     

Depletion in the levels of the release factor eRF1 causes a reduction in the efficiency of translation termination in yeast

In Saccharomyces cerevisiae, translation termination is mediated by a complex of two proteins, eRF1 and eRF3, encoded by the SUP45and SUP35 genes, respectively. Mutations in the SUP45 gene were selected which enhanced suppression by the weak ochre (UAA) suppressor tRNA^SerSUQ5. In each of four such allo-suppressor alleles examined, an in-frame ochre (TAA) mutation was present in the SUP45 coding region; therefore each allele encoded both a truncated eRF1 protein and a full-length eRF1 polypeptide containing a serine missense substitution at the premature UAA codon. The full-length eRF1 generated by UAA read-through was present at sub-wild-type levels. In an suq5⁺ (i.e. non-suppressor) background none of the truncated eRF1 polypeptides were able to support cell viability, with the loss of only 27 amino acids from the C-terminus being lethal. The reduced eRF1 levels in these sup45 mutants did not lead to a proportional reduction in the levels of ribosome-bound eRF3, indicating that eRF3 can bind the ribosome independently of eRF1. A serine codon inserted in place of the premature stop codon at codon 46 in the sup45–22 allele did not generate an allosuppressor pheno-type, thereby ruling out this‘missense’mutation as the cause of the allosuppressor phenotype. These data indicate that the cellular levels of eRF1 are important for ensuring efficient translation termination in yeast.     

Nonsense Mutants in the rII A Cistron of Bacteriophage T4

After in vitro treatment of bacteriophage T4 with hydroxylamine (HA), 54 nonsense mutants in the rII A cistron were isolated. These mutants were characterized by growth on suppressor strains of Escherichia coli, and the mutational sites were mapped in the rII A cistron. Twenty-five (9 sites) were amber (UAG), 20 (6 sites) were opal (UGA), and 9 (6 sites) were ochre (UAA). Mapping experiments further indicated that there were three closely linked pairs of amber and opal mutations, conceivably involving mutations occurring in adjacent nucleotides. Based on the specificity of HA mutagenesis (GC → AT), the amino acid codons in which the mutations occurred have been inferred. It is suggested that the three amber-opal pairs arose in tryptophan codons (UGG) and the six ochre mutants arose in glutamine codons (CAA). The six unpaired ambers and the three unpaired opals have been tentatively assigned to glutamine codons (CAG) and arginine codons (CGA), respectively, in the wild-type phage.     

Inhibition of Growth by Amber Suppressors in Yeast

Strains of the yeast Saccharomyces cerevisiae that contain highly efficient amber (UAG) suppressors grow poorly on nutrient medium, while normal or nearly normal growth rates are observed when these strains lose the supressors or when the suppressors are mutated to lower efficiencies. The different growth rates account for the accumulation of mutants with lowered efficiencies in cultures of strains with highly efficient amber suppressors. Genetic analyses indicate that one of the mutations with a lowered efficiency of suppression is caused by an intragenic mutation of the amber supressor. The inhibition of growth caused by excessive suppression is expected to be exacerbated when appropriate suppressors are combined together in haploid cells if two suppressors act with a greater efficiency than a single suppressor. Such retardation of growth is observed with combinations of two UAA (ochre) suppressors (Gilmore 1967) and with combinations of two UAG suppressors when the efficiencies of each of the suppressors are within a critical range. In contrast, combinations of a UAA suppressor and a UAG suppressor do not affect growth rate. Apparently while either excessive UAA or excessive UAG suppression is deleterious to yeast, a moderate level of simultaneous UAA and UAG suppression is not.     

lamB mutations in E. coli K12: Growth of λ host range mutants and effect of nonsense suppressors

Summary Over sixty EMS induced mutations affecting gene lamB, presumably the structural gene for the receptor in Escherichia coli K12, were examined for growth of host range mutants and effect of nonsense suppressors. By the first criterion the mutations could be grouped in three classes. Bacteria with class I mutations allow growth of mutants with extended host range (noted h) of the type already described (Appleyard, Mac Gregor and Baird, 1956). Bacteria with class II mutations allow growth of h mutants with still more extended host range (noted hh ^*). No host range mutants of could be found which would grow on bacteria with class III mutations. Using nonsense suppressors it was found that class I and II consist of missense mutations, while class III consists of nonsense mutations. Exceptions are likely to exist (especially in class III) but were not found among the mutations tested. These observations are briefly discussed in terms of outer membrane protein integration and of phage receptor interaction.     

Mutagenesis in Escherichia coli. V. Attempted interconversion of ochre and amber suppressors and mutational instability due to an ochre suppressor

Summary A possible quantitative system for the interconversion of ochre and amber suppressors was studied in Escherichia coli WU36-10, a strain in which a leucine requirement is suppressed by amber suppressors and a tyrosine requirement is suppressed by ochre suppressors. The conversion of am Sup-2⁺ to oc Sup-2⁺ occurred at rates similar to those for the de novo induction of such suppressors, both spontaneously and after ultraviolet or gamma irradiation. Both induction and conversion of suppressors showed the phenomenon of mutation frequency decline after ultraviolet light. Conversions in the opposite direction from oc Sup-2⁺ to am Sup-2⁺ were, however, not detected in unmutagenised populations of oc Sup-2⁺ strains derived either by conversion from an am Sup-2⁺ strain or de novo from the parental WU36-10, nor were they detected after treatment with ultraviolet light, gamma radiation or 2-aminopurine. If the conversion of oc Sup-2⁺ to am Sup-2⁺ occurs at all, it is at a rate very considerably lower than that for the conversion of am Sup-2⁺ to oc Sup-2⁺. Some Tyr⁺ oc Sup-2⁺ mutants demonstrated mutation rates c. 100 times greater than those of WU36-10 for mutation to Leu⁺ spontaneously and after ultraviolet or gamma radiation. Possible explanations of this are discussed.