Adjacent effect on suppression efficiency. II. Study on ochre and amber mutants of T4 phage lysozyme

Dissecting the Contribution of Release Factor Interactions to Amber Stop Codon Reassignment Efficiencies of the Methanocaldococcus jannaschii Orthogonal Pair

Non-canonical amino acids (ncAAs) are finding increasing use in basic biochemical studies and biomedical applications. The efficiency of ncAA incorporation is highly variable, as a result of competing system composition and codon context effects. The relative quantitative contribution of the multiple factors affecting incorporation efficiency are largely unknown. This manuscript describes the use of green fluorescent protein (GFP) reporters to quantify the efficiency of amber codon reassignment using the Methanocaldococcus jannaschii orthogonal pair system, commonly employed for ncAA incorporation, and quantify the contribution of release factor 1 (RF1) to the overall efficiency of amino acid incorporation. The efficiencies of amber codon reassignments were quantified at eight positions in GFP and evaluated in multiple combinations. The quantitative contribution of RF1 competition to reassignment efficiency was evaluated through comparisons of amber codon suppression efficiencies in normal and genomically recoded Escherichia coli strains. Measured amber stop codon reassignment efficiencies for eight single stop codon GFP variants ranged from 51 to 117% in E. coli DH10B and 76 to 104% in the RF1 deleted E. coli C321.ΔA.exp. Evaluation of efficiency changes in specific sequence contexts in the presence and absence of RF1 suggested that RF1 specifically interacts with +4 Cs and that the RF1 interactions contributed approximately half of the observed sequence context-dependent variation in measured reassignment efficiency. Evaluation of multisite suppression efficiencies suggests that increasing demand for translation system components limits multisite incorporation in cells with competing RF1.

A little gene with big effects: a serT mutant is defective in flgM gene translation

A conditional-lethal mutant was isolated as having a flagellar regulatory phenotype at 30 degrees C and being unable to grow at 42 degrees C. Chromosomal mapping localized the mutation to the serT gene, which encodes an essential serine tRNA species (tRNA((cmo)5UGA)(Ser)). DNA sequence analysis revealed the mutation to be a single base change in G:A at position 10 of the serT gene that lies within the D-stem of the essential tRNA((cmo)5)UGA(Ser) species. tRNA((cmo)5)UGA(Ser) recognizes UCA, UCG, and UCU codons, but UCU is also recognized by tRNA(GGA)(Ser) and UCG by tRNA(CGA)(Ser). No other tRNAs are known to read the UCA codon. Thus, the UCA codon is specifically recognized by tRNA((cmo)5)UGA(Ser). We show that the anti-sigma(28) activity of FlgM is defective in the serT mutant strain. The serT allele causes a 10-fold increase in sigma(28)-dependent fliC promoter transcription, indicating a defect in FlgM anti-sigma(28) activity in the presence of the serT mutation. The flgM gene contains only one UCA codon. Changing the UCA of flgM to ACG reversed the effect of the serT allele. Implications for context effects in regulation of gene expression are discussed.

The signal for translational readthrough of a UGA codon in Sindbis virus RNA involves a single cytidine residue immediately downstream of the termination codon

The nucleotide sequences surrounding termination codons influence the efficiency of translational readthrough. In this report, we examined the sequence requirement for efficient readthrough of the UGA codon in the Sindbis virus genomic RNA which regulates production of the putative viral RNA polymerase, nsP4. The UGA codon and its neighboring nucleotide sequences were subcloned into a heterologous coding context, and readthrough efficiency was measured by cell-free translation of RNA transcripts in rabbit reticulocyte lysates. The CUA codon immediately downstream of the UGA codon was found to be sufficient for efficient translational readthrough. Further mutagenesis of residues in the CUA triplet demonstrated that mutations at the second or third residues following the UGA codon (U and A, respectively) had little effect on readthrough efficiency. In contrast, replacement of the cytidine residue immediately downstream of the UGA codon with any of the other three nucleotides (U, A, or G) dramatically reduced the readthrough efficiency from approximately 10% to less than 1%. These results show that a simple sequence context can allow efficient readthrough of UGA codons in a mammalian translation system. Interestingly, compilation studies of nucleotide sequences surrounding eukaryotic termination codons indicate a strong bias against cytidine residues immediately 3' to UGA termination codons. Taken together with our results, this bias may reflect a selective pressure for efficient translation termination for most eukaryotic gene products.

Termination of translation in bacteria may be modulated via specific interaction between peptide chain release factor 2 and the last peptidyl-tRNA(Ser/Phe)

The 5' context of 671 Escherichia coli stop codons UGA and UAA has been compared with the context of stop-like codons (UAC, UAU and CAA for UAA; UGG, UGC, UGU and CGA for UGA). We have observed highly significant deviations from the expected nucleotide distribution: adenine is over-represented whereas pyrimidines are under-represented in position -2 upstream from UAA. Uridine is over-represented in position -3 upstream from UGA. Lysine codons are preferable immediately prior to UAA. A complete set of codons for serine and the phenylalanine UUC codon are preferable immediately 5' to UGA. This non-random codon distribution before stop codons could be considered as a molecular device for modulation of translation termination. We have found that certain fragment of E. coli release factor 2 (RF2) (amino acids 93-114) is similar to the amino acid sequences of seryl-tRNA synthetase (positions 10-19 and 80-93) and of beta (small) subunit (positions 72-94) of phenylalanyl-tRNA synthetase from E. coli. Three-dimensional structure of E. coli seryl-tRNA synthetase is known [1]: Its N-terminus represents an antiparallel alpha-helical coiled-coil domain and contains a region homologous to RF2. On the basis of the above-mentioned results we assume that a specific interaction between RF2 and the last peptidyl-tRNA(Ser/Phe) occurs during polypeptide chain termination in prokaryotic ribosomes.

Influence of codon context on UGA suppression and readthrough

We studied the influence of the codon context on UGA suppression by a suppressor tRNA and on UGA readthrough by a normal tRNA in Escherichia coli. This was done by a series of constructs where only the immediate context of the TGA codon was varied by only one nucleotide at a time. For both UGA suppression and UGA readthrough the codon context had a similar influence according to the following rules. (1) The nature of the nucleotide immediately adjacent to the 3' side of the UGA is an important determinant; at that position the level of UGA translation is influenced by the nucleotides in the order A greater than G greater than C greater than U. (2) At extremely high or low levels of UGA translation this influence of the adjacent 3' nucleotide is not seen. (3) In all cases, the nature of both the nucleotide immediately adjacent to the 5' side of the codon and that following the base adjacent to the 3' side of the codon have little effect, if any, on UGA translation. The varying influence of the codon context effect on UGA translation is discussed in relation to its role in gene expression.

Codon context

The analysis of coding sequences reveals nonrandomness in the context of both sense and stop codons. Part of this is related to nucleotide doublet preference, seen also in non-coding sequences and thought to arise from the dependence of mutational events on surrounding sequence. Another nonrandom context element, relating the wobble nucleotides of successive codons, is observed even when doublet preference, codon usage and bias in amino acid doublets are all allowed for. Several phenomena related to protein synthesis have been shown in vivo to be affected by the nucleotide sequence around codons. Thus, nonsense and missense suppression, elongation rate, precision of tRNA selection and polypeptide chain termination are all affected by codon context. At present, it remains unclear how these phenomena may influence the evolution of nonrandomness in the context of codons in natural sequences.

Third position base changes in codons 5' and 3' adjacent UGA codons affect UGA suppression in vivo

The base sequence around nonsense codons affects the efficiency of nonsense codon suppression. Published data, comparing different nonsense sites in a mRNA, implicate the two bases downstream of the nonsense codon as major determinants of suppression efficiency. However, the results we report here indicate that the nature of the contiguous upstream codon can also affect nonsense suppression, as can the third (wobble) base of the contiguous downstream codon. These conclusions are drawn from experiments in which the two Ser codons UCU233 and UCG235 in a nonsense mutant form (UGA234) of the trpA gene in Escherichia coli have been replaced with other Ser codons by site-directed mutagenesis. Suppression of these trpA mutants has been studied in the presence of a UGA nonsense suppressor derived from glyT. We speculate that the non-site-specific effects of the two adjacent downstream bases may be largely at the level of the termination process, whereas more site-specific or codon-specific effects may operate primarily on the activity of the suppressor tRNA.

Construction of Escherichia coli amber suppressor tRNA genes. II. Synthesis of additional tRNA genes and improvement of suppressor efficiency

Using synthetic oligonucleotides, we have constructed 17 tRNA suppressor genes from Escherichia coli representing 13 species of tRNA. We have measured the levels of in vivo suppression resulting from introducing each tRNA gene into E. coli via a plasmid vector. The suppressors function at varying efficiencies. Some synthetic suppressors fail to yield detectable levels of suppression, whereas others insert amino acids with greater than 70% efficiency. Results reported in the accompanying paper demonstrate that some of these suppressors insert the original cognate amino acid, whereas others do not. We have altered some of the synthetic tRNA genes in order to improve the suppressor efficiency of the resulting tRNAs. Both tRNA(CUAHis) and tRNA(CUAGlu) were altered by single base changes, which generated -A-A- following the anticodon, resulting in a markedly improved efficiency of suppression. The tRNA(CUAPro) was inactive, but a hybrid suppressor tRNA consisting of the tRNA(CUAPhe) anticodon stem and loop together with the remainder of the tRNA(Pro) proved highly efficient at suppressing nonsense codons. Protein chemistry results reported in the accompanying paper show that the altered tRNA(CUAHis) and the hybrid tRNA(CUAPro) insert only histidine and proline, respectively, whereas the altered tRNA(CUAGlu) inserts principally glutamic acid but some glutamine. Also, a strain deficient in release factor I was employed to increase the efficiency of weak nonsense suppressors.

Functional interactions in vivo between suppressor tRNA and mutationally altered ribosomal protein S4

Ribosomal mutants (rpsD) which are associated with a generally increased translational ambiguity were investigated for their effects in vivo on individual tRNA species using suppressor tRNAs as models. It was found that nonsense suppression is either increased, unaffected or decreased depending on the codon context and the rpsD allele involved as well as the nature of the suppressor tRNA. Missense suppression of AGA and AGG by glyT(SuAGA/G) tRNA as well as UGG by glyT(SuUGG-8) tRNA is unaffected whereas suppression of UGG by glyT(SuUGA/G) or glyV(SuUGA/G) tRNA is decreased in the presence of an rpsD mutation. The effects on suppressor tRNA are thus not correlated with the ribosomal ambiguity (Ram) phenotype of the rpsD mutants used in this study. It is suggested that the mutationally altered ribosomes are changed in functional interactions with the suppressor tRNA itself rather than with the competing translational release factor(s) or cognate aminoacyl tRNA. The structure of suppressor tRNA, particularly the anticodon loop, and the suppressed codon as well as the codon context determine the allele specific functional interactions with these ribosomal mutations.

Influence of modification next to the anticodon in tRNA on codon context sensitivity of translational suppression and accuracy

Effects on translation in vivo by modification deficiencies for 2-methylthio-N6-isopentenyladenosine (ms2i6A) (Escherichia coli) or 2-methylthio-N6-(4-hydroxyisopentenyl)adenosine (ms2io6A) (Salmonella typhimurium) in tRNA were studied in mutant strains. These hypermodified nucleosides are present on the 3' side of the anticodon (position 37) in tRNA reading codons starting with uridine. In E. coli, translational error caused by tRNA was strongly reduced in the case of third-position misreading of a tryptophan codon (UGG) in a particular codon context but was not affected in the case of first-position misreading of an arginine codon (CGU) in another codon context. Misreading of UGA nonsense codons at two different positions was codon context dependent. The efficiencies of some tRNA nonsense suppressors were decreased in a tRNA-dependent manner. Suppressor tRNA which lacks ms2i6A-ms2io6A becomes more sensitive to codon context. Our results therefore indicate that, besides improving translational efficiency, ms2i6A37 and ms2io6A37 modifications in tRNA are also involved in decreasing the intrinsic codon reading context sensitivity of tRNA. Possible consequences for regulation of gene expression are discussed.

Undermodification in the first position of the anticodon of supG-tRNA reduces translational efficiency

Two mutants of Escherichia coli, trmC1 and trmC2, which are both defective in the synthesis of 5-methylaminomethyl-2-thiouridine (mnm5s2U) were utilized to study the function of this complex modified nucleoside. Transfer RNAs specific for glutamine, glutamic acid and lysine as well as a specific ochre suppressor derived from lysine tRNA (tRNAUAAlys encoded by the supG allele), contain this modified nucleoside at position 34 (the wobble position). It was found that two different undermodified derivatives of mnm5s2U were present in the two trmC mutants, which suggests that the two mutations affect two different enzymatic activities. Using the lacI-Z fusion system (Miller and Albertini 1983), we found that the efficiency of supG-mediated suppression was reduced to 30%-90% of the wild-type value in the trmC mutants. The modification-deficient supG-tRNA in the mutants showed a higher sensitivity to codon context than the normal tRNAUAAlys.

Codon context effects in missense suppression

After our first observation of codon context effects in missense suppression ( Murgola & Pagel , 1983), we measured the suppression of missense mutations at two positions in trpA in Escherichia coli. The suppressible codons in the trpA messenger RNA were the lysine codons, AAA and AAG, and the glutamic acid codons, GAA and GAG. The mRNA sites of the codons correspond to amino acids 211 and 234 of the trpA polypeptide, positions at which glycine is the wild-type amino acid. Our data demonstrated codon context effects with both pairs of codons. The results indicate that suppression of AAA and AAG by mutant lysine transfer RNAs was more efficient at 211 than at 234, whereas suppression of GAA and GAG by two different mutant glycine tRNAs was more efficient at 234 than at 211. In general, the context effects were more pronounced with GAG and AAG than with GAA and AAA. (In some instances it appeared that suppression of GAA or AAA at a given position was more effective than suppression of GAG or AAG.) By contrast, no context effects were observed with a glyT suppressor of AAA and AAG, a glyT GAA/G-suppressor, and a glyU suppressor of GAG. Our observation of this phenomenon in missense suppression demonstrates that codon context can affect polypeptide elongation and that the effects can be different depending on the codons and tRNAs examined. It is suggested that tRNA-tRNA interaction on the ribosome is involved in the observed context effects.

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

A spontaneous mutant was isolated that harbors a weak suppressing activity towards a UAG mutation, together with an inability to grow at 43 degrees 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 without 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.

Context effects: translation of UAG codon by suppressor tRNA is affected by the sequence following UAG in the message

The efficiency of various suppressor tRNAs in reading the UAG amber codon has been measured at 42 sites in the lacI gene. Results indicate that: (1) for all suppressors, efficiency is not an a priori value; rather, it is determined at each site by the specific reading context of the suppressed codon; (2) the degree of sensitivity to context effects differs among suppressors. Most affected is amber suppressor supE (su2), whose activity varies over a 20-fold range depending on context; (3) context effects are produced by residues present at the 3' side of the UAG codon. The most important role appears to be played by the base that is immediately adjacent to the codon. When this base is a purine, the amber codon is suppressed more efficiently than when a pyrimidine is in the same position. Superimposed on this initial pattern, the influence of bases further downstream to the UAG triplet can be detected also. The possibility is discussed that context effects are produced by the whole codon following UAG in the message.

Effects of surrounding sequence on the suppression of nonsense codons

Using a lacI-Z fusion system, we have determined the efficiency of suppression of nonsense codons in the I gene of Escherichia coli by assaying beta-galactosidase activity. We examined the efficiency of four amber suppressors acting on 42 different amber (UAG) codons at known positions in the I gene, and the efficiency of a UAG suppressor at 14 different UGA codons. The largest effects were found with the amber suppressor supE (Su2), which displayed efficiencies that varied over a 35-fold range, and with the UGA suppressor, which displayed a 170-fold variation in efficiency. Certain UGA sites were so poorly suppressed (less than 0.2%) by the UGA suppressor that they were not originally detected as nonsense mutations. Suppression efficiency can be correlated with the sequence on the 3' side of the codon being suppressed, and in many cases with the first base on the 3' side. In general, codons followed by A or G are well suppressed, and codons followed by U or C are poorly suppressed. There are exceptions, however, since codons followed by CUG or CUC are well suppressed. Models explaining the effect of the surrounding sequence on suppression efficiency are considered in the Discussion and in the accompanying paper.

Unusual suppression properties of lysogens containing derivatives of phi 80 psu3+

Nonsense codon suppressing lysogens of E. coli have been made using phi 80 psu3+-A2 and phi 80 psuoc+-A2, heat-sensitive amber and ochre suppressing derivatives, respectively, of bacteriophage phi 80. The various lysogens selected differ in strength of suppression as well as in heat sensitivity of suppressor function. Heat-resistant derivatives, some still carrying the A2 mutation, can be selected from the heat sensitive parents. Mapping experiments indicate that the phi 80 derivatives integrate at the tyrTV locus, which contains two copies of tRNA1Tyr. The origin of the various suppressor phenotypes appears to be related to the great variety of distinctive recombination events possible either between the incoming tRNA1Tyr gene and the host copies, or among the three copies of this gene in the lysogens.

Usage of the three termination codons in a single eukaryotic cell, the Xenopus laevis oocyte

Oocytes from Xenopus laevis were injected with purified amber (UAG), ochre (UAA), and opal (UGA) suppressor tRNAs from yeasts. The radioactively labeled proteins translated from the endogenous mRNAs were then separated on two-dimensional gels. All three termination codons are used in a single cell, the Xenopus laevis oocyte. But a surprisingly low number of readthrough polypeptides were observed from the 600 mRNAs studied in comparison to uninjected oocytes. The experimental data are compared with the conclusions obtained from the compilation of all available termination sequences on eukaryotic and prokaryotic mRNAs. This comparison indicates that the apparent resistance of natural termination codons against readthrough, as observed by the microinjection experiments, cannot be explained by tandem or very close second stop codons. Instead it suggests that specific context sequences around the termination codons may play a role in the efficiency of translation termination.

UGA suppression by normal tRNA Trp in Escherichia coli: codon context effects

The nucleotide sequences at the 3' side of in-phase UGA termination codons in mRNAs of various prokaryotic genes were re-examined. An adenine (A) residue is found to be adjacent to the 3' side of UGA in mRNAs which code for readthrough proteins by the suppression of UGA by normal Escherichia coli tRNA Trp. It is suggested that the nature of the nucleotide following a UGA codon determines whether the UGA signals inefficiently or efficiently the termination of polypeptide chain synthesis: an A residue at this position permits the UGA readthrough process.

The influence of codon context on genetic code translation

A class of mutations that increase the deficiency of a suppressor tRNA in translating a particular amber codon has been characterized. The increased efficiency is due to a mutation resulting in a change in the mRNA that affects the nucleotide adjacent to the 3' side of the UAG triplet. Thus the interaction of tRNA with mRNA is influenced by mRNA sequences outside the triplet codon.

High efficiency temperature-sensitive amber suppressor strains of Escherichia coli K12: construction and characterization of recombinant strains with suppressor-enhancing mutations

A set of eight strains combining the supD43,74 ts1 suppressor gene with alleles of three suppressor-enhancing (sue) genes have been constructed and characterized. The sue mutations work cooperatively to raise suppressor activity and together raise the activity of the supD43,74-encoded suppressor 40-fold. These strains further expand the utility of the ts suppressor system by providing as much as 100% suppressor activity at temperatures at or below 20 degrees C to as little as 0.015% suppressor activity at 43 degrees C.

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

Secondary mutations which increase the efficiency of suppression of nonsense mutations in the rIIB 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.

Effect of neighboring nucleotide sequences on suppression efficiency in amber mutants of T4 phage lysozyme

Variations in suppression efficiency were observed among nonsense mutations at different locations within the lysozyme gene (e) of T4 phage. The present experiments using three amber mutants in lysozyme gene indicate such variations presumably depend upon the base sequences neighboring to the nonsense mutations.

Intragenic mutational spectra and hot spots

In this review we outline the various factors which may contribute to the non-randomness of intragenic mutational spectra and the occurrence of hot spots. These factors include sample size limitation, particularly for sites of low mutability, and possible regions of low recombination potential. In addition, the nature of the gene product places great restraint on the detectability of either frameshift and premature chain-terminating mutations on one hand, or of the majority of missense mutations on the other. The nature of the Genetic Code itself also limits the mutational spectrum in so far as specific base pair substitutions lead only to a limited number of detectable amino acid replacements. Mutational hot spots may be a special example of the influence of neighbouring base pairs in the mutability of any given base pair. This is apparently true for frameshift mutations which tend to occur in runs of repeated base pairs or base pair doublets. Neighbouring base effects could operate not only at the level of initial reactivity with a mutagen, but also subsequently at the levels of DNA repair, recombination or replication. In some cases rare or modified bases may be responsible for neighbour effects. We suggest specific experimental approaches which seem likely to aid in the elucidation of these problems.