Nonsense suppression in a multiauxotrophic derivative of Escherichia coli 15T-: identification and consequences of an amber triplet in the deoxyribomutase gene

Previously, arginine revertants of Escherichia coli WWU, a derivative of E. coli 15T(-), have been subdivided by two independent methods: (i) the streak morphology on nutrient agar, and (ii) the pattern of phage growth using amber and ochre mutants of bacteriophage T4. In the first assay, revertants were subdivided into two classes according to the appearance of streaks after incubation on nutrient agar, a thick, even line of growth defining normal revertants and a thin, irregular line defining aberrant revertants. In the second assay, revertants were classified by the suppressors they contained. The present work demonstrates that revertants containing an amber suppressor show the aberrant morphology and are also able to catabolize thymidine for energy and carbon. This is in contrast to the parent WWU containing no suppressor, which shows a normal morphology and cannot utilize thymidine as an energy source. Revertants containing no suppressor, isolated specifically for their ability to catabolize thymidine, show an aberrant morphology. Together, these results indicate that the aberrant morphology results from suppression of an amber triplet in a gene of the thymidine catabolic pathway. Enzyme assays show the amber triplet to be in the gene specifying deoxyribomutase. It is suggested that the aberrant arginine revertants are analogous to high thymine-requiring mutants and that, in general, high and low thymine-requiring mutants differ from one another in their ability to catabolize deoxyribose-1-phosphate.     

supN ochre suppressor gene in Escherichia coli codes for tRNALys.

We describe the cloning and nucleotide sequence of a new tRNALys gene, lysV, in Escherichia coli. An ochre suppressor allele of this gene, supN, codes for a tRNALys with anticodon UUA, presumably derived by a single base change from a wild-type UUU anticodon. The sequence of the supN tRNALys is identical to the sequence of ochre suppressor tRNAs encoded by mutant alleles at the lysT locus. This locus, which contains the two previously known tRNALys genes of E. coli, is located far from the lysV locus on the chromosome.     

Suppression of amber codons in vivo as evidence that mutants derived from Escherichia coli initiator tRNA can act at the step of elongation in protein synthesis

The absence of a Watson-Crick base pair at the end of the amino acid acceptor stem is one of the features which distinguishes prokaryotic initiator tRNAs as a class from all other tRNAs. We show that this structural feature prevents Escherichia coli initiator tRNA from acting as an elongator in protein synthesis in vivo. We generated a mutant of E. coli initiator tRNA in which the anticodon sequence is changed from CAU to CUA (the T35A36 mutant). This mutant tRNA has the potential to read the amber termination codon UAG. We then coupled this mutation to others which change the C1.A72 mismatch at the end of the acceptor stem to either a U1:A72 base pair (T1 mutant) or a C1:G72 base pair (G72 mutant). Transformation of E. coli CA274 (HfrC Su- lacZ125am trpEam) with multicopy plasmids carrying the mutant initiator tRNA genes show that mutant tRNAs carrying changes in both the anticodon sequence and the acceptor stem suppress amber codons in vivo, whereas mutant tRNA with changes in the anticodon sequence alone does not. Mutant tRNAs with the above anticodon sequence change are aminoacylated with glutamine in vitro. Measurement of kinetic parameters for aminoacylation by E. coli glutaminyl-tRNA synthetase show that both the nature of the base pair at the end of the acceptor stem and the presence or absence of a base pair at this position can affect aminoacylation kinetics. We discuss the implications of this result on recognition of tRNAs by E. coli glutaminyl-tRNA synthetase.     

Leucine tRNA family of Escherichia coli: nucleotide sequence of the supP(Am) suppressor gene.

We describe the cloning and the DNA sequence of an amber suppressor allele of the Escherichia coli leuX (supP) gene. The suppressor allele codes for a tRNA with anticodon CUA, presumably derived by a single base change from a CAA anticodon. The mature coding sequence of the leuX gene is preceded by a putative Pribnow box sequence (TATAAT) and followed by a termination signal. The sequence of the leuX-coded tRNA is compared with the sequences of the four remaining tRNALeu isoacceptors of E. coli and with two tRNALeu species from bacteriophage T4 and T5. The conserved nucleotides in these seven tRNAs recognized by E. coli leucyl-tRNA synthetase are located mainly in the aminoacyl stem and in the D-stem/loop region.     

In vitro reconstitution of anticodon nuclease from components encoded by phage T4 and Escherichia coli CTr5X.

During phage T4 infection of Escherichia coli strains containing the prr locus the host tRNALys undergoes cleavage-ligation in reactions catalyzed by anticodon nuclease, polynucleotide kinase and RNA ligase. Known genetic determinants of anticodon nuclease are prr, which restricts T4 mutants lacking polynucleotide kinase or RNA ligase, and stp, the T4 suppressor of prr encoded restriction. The present communication describes an in vitro anticodon nuclease assay in which the specific cleavage of tRNALys is driven by an extract from E. coli prrr (restrictive) cells infected by phage T4. The in vitro anticodon nuclease reaction requires factor(s) encoded by prr, is stimulated by a synthetic Stp polypeptide and appears to require additional T4 induced factor(s) distinct from Stp.     

Suppression of Amber and Ochre Mutants in Salmonella typhimurium by a Mutant F′-1-gal Factor Carrying an Ochre Suppressor Gene

A Salmonella typhimurium strain was given the amber mutation hisC527 by transduction, made galactose-negative by mutation, then infected with the F'-1-gal factor. Of 107 spontaneous and mutagen-induced histidine-independent mutants tested, 3 proved to result from suppressor mutations within the F' factor. The mutant F' factors, when transferred to S. typhimurium and E. coli auxotrophs, suppressed amber and ochre but not UGA or missense mutants, and are inferred to carry ochre suppressor genes. Attempts to isolate an F' amber suppressor mutant were unsuccessful. A suppressor F' factor was transferred to 14 rough mutants which had been isolated from LT2 hisC527 (amber) by selection for resistance to phage P22.c2. One rough mutant was partly suppressed, as shown by its acquisition of O agglutinability and by alterations in its phage resistance pattern. Phage P22h grown on the suppressed mutant contransduced its rf. gene with cysE(+) and with pyrE(+), and the affected locus is inferred to be rfaL. Both the original and the mutant F' factors conferred resistance to the rough-specific phage Br60, which is therefore "female-specific."     

Nucleotide and deduced amino acid sequence of stp: the bacteriophage T4 anticodon nuclease gene

Pre-existing host tRNAs are reprocessed during bacteriophage T4 infection of certain Escherichia coli strains. In this pathway, tRNALys is cleaved 5' to the wobble base by anticodon nuclease and is later restored in polynucleotide kinase and RNA ligase reactions. Anticodon nuclease depends on prr, a locus found only in host strains that restrict T4 mutants lacking polynucleotide kinase and RNA ligase; and on stp, the T4 suppressor of prr restriction. stp was cloned and the nucleotide sequences of its wild-type and mutant alleles determined. Their comparison defined an stp open reading frame of 29 codons at 162.8 to 9 kb of T4 DNA (1 kb = 10(3) base-pairs). We suggest that stp encodes a subunit of anticodon nuclease, perhaps one that harbors the catalytic site; while additional subunits, such as a putative prr gene product, impart protein folding environment and tRNA substrate recognition.     

Suppression of amber and ochre rII mutants of bacteriophage T4 by streptomycin

Orias, E. (University of California, Santa Barbara), and T. K. Gartner. Suppression of amber and ochre rII mutants of bacteriophage T4 by streptomycin. J. Bacteriol. 91:2210-2215. 1966.-Streptomycin-induced suppression of amber and ochre rII mutants of phage T4 was studied in a streptomycin-sensitive strain of Escherichia coli and four nearly isogenic streptomycin-resistant derivatives of this strain, in the presence and in the absence of an ochre suppressor. Most of the 12 rII mutants tested were suppressed by streptomycin in the streptomycin-sensitive su(-) strain. This streptomycin-induced suppression in the su(-) strain was eliminated by the independent action of at least two of the four nonidentical mutations to streptomycin resistance. In two of the su(+)str-r strains, streptomycin markedly augmented the suppression caused by the ochre suppressor. In those su(-)str-r hosts in which significant streptomycin-induced suppression could be measured, the amber mutants were more suppressible than the ochre mutants.     

Characterization of amber and ochre suppressors in Salmonella typhimurium.

Amber and ochre suppressor mutations in Salmonella typhimurium were selected. The amino acid insertions directed by the suppressors were inferred from suppression patterns of Escherichia coli lacI amber mutations. These amber mutations only respond to nonsense suppressors that direct the insertion of particular amino acids. Four Salmonella amber suppressors characterized insert serine, glutamine, tyrosine, and (probably) leucine. Of the three ochre suppressors characterized, two direct the insertion of tyrosine and one directs that of lysine. Of the three amber and two ochre suppressors which have been mapped by phage P22 cotransduction, all are located in the same relative position on the Salmonella map as the analogous E. coli suppressors are on the E. coli map.     

Site-specific mutagenesis of Escherichia coli gltT yields a weak, glutamic acid-inserting ochre suppressor

Of all the Escherichia coli tRNA genes that can give rise to an amber or an ochre suppressor by a single-nucleotide mutation, only the tRNAGlu genes have not been observed to do so. A study of the relationship between the sequences of tRNAs and the codons they translate predicts that the ochre suppressor derived from tRNAGlu would function very poorly on the ribosome. We have used site-specific mutagenesis to create the gene for such a tRNA in order to test this prediction. We cloned the tRNAGlu-Suoc gene into a high copy number plasmid, under control of the lacUV5 promoter. The mutant tRNA suppresses both amber and ochre nonsense mutations. As predicted, it is less efficient than other suppressors expressed under similar conditions.     

Bacteriophage T4 anticodon nuclease, polynucleotide kinase and RNA ligase reprocess the host lysine tRNA.

Host tRNAs cleaved near the anticodon occur specifically in T4-infected Escherichia coli prr strains which restrict polynucleotide kinase (pnk) or RNA ligase (rli) phage mutants. The cleavage products are transient with wt but accumulate in pnk- or rli- infections, implicating the affected enzymes in repair of the damaged tRNAs. Their roles in the pathway were elucidated by comparing the mutant infection intermediates with intact tRNA counterparts before or late in wt infection. Thus, the T4-induced anticodon nuclease cleaves lysine tRNA 5' to the wobble position, yielding 2':3'-P greater than and 5'-OH termini. Polynucleotide kinase converts them into a 3'-OH and 5' P pair joined in turn by RNA ligase. Presumably, lysine tRNA depletion, in the absence of polynucleotide kinase and RNA ligase mediated repair, underlies prr restriction. However, the nuclease, kinase and ligase may benefit T4 directly, by adapting levels or decoding specificities of host tRNAs to T4 codon usage.     

Synthesis of an ochre suppressor tRNA gene and expression in mammalian cells.

We have used site-specific mutagenesis to change the anticodon of a Xenopus laevis tyrosine tRNA gene so that it would recognize ochre codons. This tRNA gene is expressed when amplified in monkey cells as part of a SV40 recombinant and efficiently suppresses termination at both the ochre codon separating the adenovirus 2 hexon gene from a 23-kd downstream gene and the ochre codon at the end of the NS1 gene of influenza virus A/Tex/1/68. Termination at an amber codon of a NS1 gene of another influenza virus strain was not suppressed by the (Su+) ochre gene suggesting that in mammalian cells amber codons are not recognized by ochre suppressor tRNAs. Finally, microinjection into mammalian cells of both (Su+) ochre tRNA genes and selectible genes containing ochre nonsense mutations gives rise to colonies under selective conditions. We conclude that it should be possible to isolate a wide assortment of mammalian cell lines with ochre suppressor activity.     

Specific Suppression of Mutations in Genes 46 and 47 by das, a New Class of Mutations in Bacteriophage T4D

Mutants in T4 genes 46 and 47 exhibit early cessation of deoxyribonucleic acid (DNA) synthesis ("DNA arrest") and decreased synthesis of late proteins and phage. In addition, mutants in genes 46 and 47 fail to degrade host DNA to acidsoluble products. It is shown here that this complex phenotype can be partially suppressed by mutation of a T4 gene external to genes 46 and 47 which has been named das for "DNA arrest suppressor." The das mutations were discovered as third-site mutations in spontaneous pseudorevertants of [46, 47] mutants; the pseudorevertants make small plaques on Escherichia coli B, whereas [46, 47] mutants make none. The [das, 46, 47] triple mutant exhibits increased DNA, late protein, and viable phage production compared to the double mutant [46, 47]. The [das, 46, 47] mutant also degrades more of the host DNA to acid-soluble products than does the [46, 47] mutant. The suppressor effect of the das mutation appears to be gene-specific: it suppresses both amber and temperature-sensitive mutations in genes 46 and 47 and does not suppress amber mutations in any of the other genes tested. The [das] single mutants make normal-sized plaques on E. coli B and exhibit nearly normal host DNA degradation, DNA synthesis, late protein synthesis, and viable phage production. The das mutations either define a new gene between genes 33 and 34 or are special mutations within gene 33.     

Mutation in the D arm enables a suppressor with a CUA anticodon to read both amber and ochre codons in Escherichia coli

Su9 of Escherichia coli differs from tRNATrp by only a G to A transition in the D arm, yet has an enhanced ability to translate UGA by an unusual C X A wobble pairing. In order to examine the effects of this mutation on translation of the complementary and wobble codons in vivo, we constructed the gene for an amber (UAG) suppressing variant of Su9, trpT179, by making the additional nucleotide change required for an amber suppressor anticodon. The resultant suppressor tRNA, Su79, is a very strong amber suppressor. Furthermore, the D arm mutation enables Su79 to suppress ochre (UAA) codons by C X A wobble pairing. These data demonstrate that the effect of the D arm mutation on wobble pairing is not restricted to a CCA anticodon. The effect extends to the CUA anticodon of Su79, thereby creating a new type of ochre suppressor. The new coding activity of Su79 cannot be explained by alterations in the level of aminoacylation, steady-state tRNA concentration, or nucleotide modification. The A24 mutation could permit unorthodox wobble pairings by generally enhancing tRNA efficiency at all codons or by altering codon specificity.     

The host-dependent restriction of growth of an RNA coliphage FI.

Phage FIC is a spontaneous host-dependent mutant of phage FI which is classified into the fourth group of RNA Escherichia coli phages (RNA coliphages). The mutant phage (FIC) grows normally in E. coli strain Q13 (permissive host), but poorly in strain A/lambda (non-permissive host) (9). Attempts to elucidate the regulatory mechanism of growth of the mutant phage in the non-permissive host revealed the following: (a) growth of the mutant phage was specifically restricted in E. coli strains that have certain suppressor genes for amber mutation; (b) the mutant phage RNA (FIC-RNA) could not produce progeny in the spheroplasts of the non-permissive host; (c) adsorption of the mutant phage to, and penetration of the mutant phage RNA into, the non-permissive host were normal; and (d) biosynthesis of the phage-specific late protein and RNA did not occur in the non-permissive host. Based on these results we conclude that phage FIC is a spontaneous azure-type mutant of the fourth group of RNA coliphage FI.     

Protein engineering with synthetic Escherichia coli amber suppressor genes

We have constructed synthetic genes encoding different Escherichia coli suppressor tRNAs for use in amino acid substitution studies and protein engineering. We used oligonucleotides to assemble the genes for different tRNAs with the anticodon 5' CTA 3'. The suppressor genes are expressed from a synthetic promoter derived from the promoter sequence of the E. coli lipoprotein gene. The genes have been used to suppress an amber mutation in a protein coding sequence, and the resulting altered protein has been subjected to sequence analysis to determine the nature of the amino acid inserted at the amber site. Twelve amino acids can now be added in response to the amber codon. We have employed these suppressors to study amino acid substitutions in the lac repressor.     

Complete set of orthogonal 21st aminoacyl-tRNA synthetase-amber, ochre and opal suppressor tRNA pairs: concomitant suppression of three different termination codons in an mRNA in mammalian cells

We describe the generation of a complete set of orthogonal 21st synthetase-amber, ochre and opal suppressor tRNA pairs including the first report of a 21st synthetase-ochre suppressor tRNA pair. We show that amber, ochre and opal suppressor tRNAs, derived from Escherichia coli glutamine tRNA, suppress UAG, UAA and UGA termination codons, respectively, in a reporter mRNA in mammalian cells. Activity of each suppressor tRNA is dependent upon the expression of E.coli glutaminyl-tRNA synthetase, indicating that none of the suppressor tRNAs are aminoacylated by any of the twenty aminoacyl-tRNA synthetases in the mammalian cytoplasm. Amber, ochre and opal suppressor tRNAs with a wide range of activities in suppression (increases of up to 36, 156 and 200-fold, respectively) have been generated by introducing further mutations into the suppressor tRNA genes. The most active suppressor tRNAs have been used in combination to concomitantly suppress two or three termination codons in an mRNA. We discuss the potential use of these 21st synthetase-suppressor tRNA pairs for the site-specific incorporation of two or, possibly, even three different unnatural amino acids into proteins and for the regulated suppression of amber, ochre and opal termination codons in mammalian cells.     

A nucleotide change in the anticodon of an Escherichia coli serine transfer RNA results in supD-amber suppression.

The tRNAs specified by the wild type and amber suppressor alleles of the Escherichia coli supD gene have been identified, and their primary structures determined. The sequences differ by a single nucleotide in the middle of the anticodon. A CUA anticodon allows the suppressor tRNA to read the UAG stop codon; the CGA anticodon in the minor serine tRNA species from which the suppressor is derived is specific for the serine codon UCG.     

Transmission of bacteriophage T4 amber mutants. I. Temperature sensitivity of gene 26 T4 phage mutant amN131 multiplication in Escherichia coli B cells]

When studying the single cycle of the multiplication of gene 26 mutant amN131 of phage T4, like in temperature shift experiments, the yield of this mutant in non-permissive host depends greatly on the temperature. The burts size of phage in Escherichia coli B is found to be 3.3 phage particles at 25 degrees C, 1.6 at 30 degrees C, 0.051 at 37 degrees C and 0.0007 at 41 degrees C. In the case of permissive host (E. coli CR-63) the burst size per cell decreases from 158 to 49 phage particles at the same temperature interval. The results of the single-burst experiments indicate, that when the incubation temperature increases, the number of E. coli B cells, in which the phage particles maturate, also decreases. It results in the dependence of the transmission coefficient value on the temperature. The transmission coefficient in the conditions favourable for the maturation of the phage is found to be 0.80. It is shown by several methods that the temperature sensitivity of the multiplication of the mutant amN131 in bacterial cells is entirely due to amber mutation in genome of the phage. Therefore the amber mutants having high temperature sensitivity when maturating in non-permissive host cells exist among ordinary amber mutants of phage T4.     

Mitochondrial assembly in respiration-deficient mutants of Saccharomyces cerevisiae. IV. Effects of nuclear amber suppressors on the accumulation of a mitochondrially made subunit of cytochrome c oxidase.

Earlier studies from this laboratory have shown that cytochrome c oxidase from bakers' yeast contains seven subunits, three of which are made in the mitochondrion (Mason, T. L., and Schatz, G. (1973) J. Biol. Chem. 248, 1355). Moreover, a cytochrome c oxidase-less yeast mutant (pet 494-1) was isolated which lacked one of the mitochondrially made subunits (Ebner, E., Mason, T. L., and Schatz, G. (1973) J. Biol. Chem. 248, 5369). Surprisingly, the mutated gene was localized in the nucleus. The results presented here demonstrate that this mutant phenotype can be suppressed by nuclear amber suppressors which affect translation on cytoplasmic ribosomes. This fact was established by two methods, (a) By constructing pet 494-1 strains possessing various amber and ochre markers, isolating respiring revertants from these strains, and demonstrating co-reversion of the amber (but not of the ochre) markers. (b) By coupling the pet 494-1 allele with the well characterized amber suppressor gene SUP 4-3. These data show that suppressor genes located on nuclear chromosomes may control the accumulation of a mitochondrially synthesized polypeptide. The present results also allow some tentative conclusions about the mechanism of the pet 494 mutation. Because it is highly unlikely that the cytoplasmic and the mitochondrial translation system share a common suppressor, the pet 494 locus probably does not code for the missing mitochondrially made subunit, but for a cytoplasmically made protein. This as yet unidentified protein seems to control the synthesis or the integration of the mitochondrially made subunit. Nuclear suppressor genes may thus be useful tools for studying the role of cytoplasmic protein synthesis in mitochondrial formation.