Translational frameshifts induced by mutant species of the polypeptide chain elongation factor Tu of Escherichia coli

Translational frameshifts, both +1 and -1, are promoted by mutations in tufA and tufB, the two genes encoding the polypeptide chain elongation factor (EF) Tu of Escherichia coli. Strains harboring the mutant EF-Tu(Ala375----Thr) encoded by either tufA or tufB or by both, display a linear relationship between the frequency of frameshifting and the concentration of mutant EF-Tu, relative to the total amount of EF-Tu. A second mutant species, EF-TuB(Gly222----Asp), also promotes frameshifting. The frequency is strikingly enhanced by the combined action of EF-TuA(Ala375----Thr) and EF-TuB(Gly222----Asp) and exceeds by far the total contribution of the two mutant EF-Tus studied separately. These observations raise the question whether the formation of each peptide bond under conditions that no frameshifting occurs also requires the combined action of two EF-Tu molecules, in this case not differing functionally.     

The interaction between aminoacyl-tRNA and the mutant elongation factors Tu AR and B0

The binding of Tyr-[AEDANS-s2C]tRNA(Tyr) (Tyr-tRNA(Tyr) modified at the penultimate cytidine residue with a thio group at position 2 of the pyrimidine ring, to which an N-(acetylaminoethyl)-5-naphthylamine-1-sulfonic acid fluorescence group is attached) to mutant elongation factor (EF)-Tu species from E. coli, EF-TuAR (Ala-375----Thr) and EF-TuBO (Gly-222----Asp), both complexed to GTP, was investigated in absence of kirromycin by measuring the change in fluorescence of the modified tRNA induced by complex formation. The calculated dissociation constant in the case of EF-TuAR is about 4 nM and in the case of EF-TuB0, about 1 nM. These values are higher than that of wild-type EF-Tu, which was 0.24 nM measured with the same system. The affinity between either EF-TuB0.kirromycin.GDP or EF-TuB0.kirromycin.GTP on the one hand, and a mixture of aminoacyl-tRNAs on the other, was measured with zone-interference gel electrophoresis. The dissociation constants are 20 microM and 7 microM, respectively, a factor of about two higher than in the case of wild-type EF-Tu.kirromycin. These findings provide a clue for the observed increase in translational errors in strains carrying the mutations. Furthermore, the experiments with EF-TuB0.kirromycin deepen our understanding of the effects of the B0 mutation on the kirromycin phenotype of the mutant cells concerned.     

Effects of the mutation glycine-222----aspartic acid on the functions of elongation factor Tu

We have studied the properties of a mutant elongation factor Tu, encoded by tufB (EF-TuBo), in which Gly-222 is replaced by Asp. For its purification from the kirromycin-resistant EF-Tu encoded by tufA (EF-TuAr), a method was developed by exploiting the different affinities to kirromycin of the two factors and the competition between kirromycin and elongation factor Ts (EF-Ts) for binding to EF-Tu. The resulting EF-TuBo kirromycin and EF-TuAr EF-Ts complexes are separated by chromatography on diethylaminoethyl-Sephadex A-50. For the first time we have succeeded in obtaining a tufB product in homogeneous form. Compared with wild-type EF-Tu, EF-TuBo displays essentially the same affinity for GDP and GTP, with only the dissociation rate of EF-Tu GTP being slightly faster. Protection of amino-acyl-tRNA (aa-tRNA) against nonenzymatic deacylation by different EF-Tu species indicates that conformational alterations occur in the ternary complex EF-TuBo GTP aa-tRNA. However, the most dramatic modification is found in the EF-TuBo interaction with the ribosome. Its activity in poly(Phe) synthesis as well as in the GTPase activity associated with the interaction of its ternary complex with the ribosome mRNA complex requires higher Mg2+ concentrations than wild-type EF-Tu (Mg2+ optimum at 10-14 vs. 6 mM), even if EF-TuBo can sustain enzymatic binding of aa-tRNA to ribosomes at low Mg2+. The anomalous behavior of EF-TuBo is reflected in a remarkable increase of the fidelity in poly(Phe) synthesis, especially at high Mg2+ concentrations.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mutant forms of tufA and tufB independently suppress nonsense mutations

The level of nonsense suppression in Salmonella typhimurium carrying error-enhancing mutations in either or both of the genes coding for the elongation factor EF-Tu has been measured. Suppression of both UGA and UAG is observed. There is no significant suppression of any of six UAA sites tested. Nonsense suppression does not require that both genes for EF-Tu be mutant. Strains carrying one mutant and one wild-type tuf gene suppress nonsense mutations. The level of suppression increases approximately additively when both tuf genes are mutant. It is suggested that these mutant forms of EF-Tu act independently of each other to suppress nonsense mutations. Suppression is not observed at all UGA and UAG sites, but instead shows a strong site specificity.     

Interaction of a selenocysteine-incorporating tRNA with elongation factor Tu from E.coli.

Selenocysteine-incorporating tRNA(Sec)(UCA), the product of selC, was isolated from E.coli and aminoacylated with serine. The equilibrium dissociation constant for the interaction of Ser-tRNA(Sec)(UCA) with elongation factor Tu.GTP was determined to be 5.0 +/- 2.5 x 10(-8) M. Compared with the dissociation constants of the two elongator Ser-tRNA(Ser) species (Kd = 7 x 10(-10) M), the selenocysteine-incorporating UGA suppressor tRNA has an almost hundred fold weaker affinity for EF-Tu.GTP. This suggests a mechanism by which the Ser-tRNA(Sec) is prevented in recognition of UGA codons. This tRNA is not bound to EF-Tu.GTP and is converted to selenocysteinyl-tRNA(Sec). We also demonstrate the lack of an efficient interaction of Sec-tRNA(Sec)(UCA) with EF-Tu.GTP. The results of this work are in support of a mechanism by which the selenocysteine incorporation at UGA nonsense codons is mediated by an elongation factor other than EF-Tu.GTP.     

Specific alterations of the EF-Tu polypeptide chain considered in the light of its three-dimensional structure

Specific alterations of the elongation factor Tu (EF-Tu) polypeptide chain have been identified in a number of mutant species of this elongation factor. In two species, Ala-375, located on domain II, was found by amino acid analysis to be replaced by Thr and Val, respectively. These replacements substantially lower the affinity of EF-Tu.GDP for the antibiotic kirromycin. Since kirromycin can be cross-linked to Lys-357, also located on domain II but structurally very far from Ala-375, these data suggest that the replacements alter the relative position of domains I and II. The Ala-375 replacements also lower the dissociation rates of the binary complexes EF-Tu.GTP and the binding constants for EF-Tu.GTP and Phe-tRNA. It is conceivable that these effects are also mediated by movements of domains I and II relative to each other. Replacement of Gly-222 by Asp has been found in another mutant by DNA sequence analysis of the cloned tufB gene, coding for this mutant EF-Tu. Gly-222 is part of a structural domain, characteristic for a variety of nucleotide binding enzymes. Its replacement by Asp does not abolish the ability of EF-Tu to sustain protein synthesis. It increases the dissociation rate of EF-Tu.GTP by approximately 30%. In the presence of kirromycin this mutant species of EF-Tu.GDP does not bind to the ribosome, in contrast to its wild-type counterpart. A possible explanation is now open for experimental verification.     

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.     

5' contexts of Escherichia coli and human termination codons are similar.

The nearest 5' context of 2559 human stop codons was analysed in comparison with the same context of stop-like codons (UGG, UGC, UGU, CGA for UGA; CAA, UAU, UAC for UAA; and UGG, UAU, UAC, CAG for UAG). The non-random distribution of some nucleotides upstream of the stop codons was observed. For instance, uridine is over-represented in position -3 upstream of UAG. Several codons were shown to be over-represented immediately upstream of the stop codons: UUU(Phe), AGC(Ser), and the Lys and Ala codon families before UGA; AAG(Lys), GCG(Ala), and the Ser and Leu codon families before UAA; and UCA(Ser), AUG(Met), and the Phe codon family before UAG. In contrast, the Thr and Gly codon families were under-represented before UGA, while ACC(Thr) and the Gly codon family were under-represented before UAG and UAA respectively. In an earlier study, uridine was shown to be over-represented in position -3 before UGA in Escherichia coli [Arkov,A.L., Korolev,S.V. and Kisselev,L.L. (1993) Nucleic Acids Res., 21,2891-2897]. In that study, the codons for Lys, Phe and Ser were shown to be over-represented immediately upstream of E. coli stop codons. Consequently, E. coli and human termination codons have similar 5' contexts. The present study suggests that the 5' context of stop codons may modulate the efficiency of peptide chain termination and (or) stop codon readthrough in higher eukaryotes, and that the mechanisms of such a modulation in prokaryotes and higher eukaryotes may be very similar.     

Mutant EF-Tu species reveal novel features of the enacyloxin IIa inhibition mechanism on the ribosome

For clarification of the action of a new antibiotic, the analysis of resistant mutants is often indispensable. For enacyloxin IIa we discovered four resistant elongation factor Tu (EF-Tu) species in Escherichia coli with the mutations Q124K, G316D, Q329H, and A375T, respectively. They revealed that enacyloxin IIa sensitivity is dominant in a mixed population of resistant and wild-type EF-Tus. This points to an inhibition mechanism in which EF-Tu is the dominant target of enacyloxin IIa and in which a ribosome with a sensitive EF-Tu blocks mRNA translation for upstream ribosomes with resistant EF-Tus, a mechanism similar to that of the unrelated antibiotic kirromycin. Remarkably, the same mutations are also linked to kirromycin resistance, though the order of their levels of resistance is different from that for enacyloxin IIa. Among the mutant EF-Tus, three different resistance mechanisms can be distinguished: (i) by obstructing enacyloxin IIa binding to EF-Tu. GTP; (ii) by enabling the release of enacyloxin IIa after GTP hydrolysis; and (iii) by reducing the affinity of EF-Tu.GDP. enacyloxin IIa for aminoacyl-tRNA at the ribosomal A-site, which then allows the release of EF-Tu.GDP.enacyloxin IIa. Ala375 seems to contribute directly to enacyloxin IIa binding at the domain 1-3 interface of EF-Tu.GTP, a location that would easily explain the pleiotropic effects of enacyloxin IIa on the functioning of EF-Tu.     

Influence of the last amino acid in the nascent peptide on EF-Tu during decoding

The last two amino acids of the nascent peptide at the ribosomal P-site influence the efficiency of termination readthrough at the stop codon UGA (Mottagui-Tabar et al (1994) EMBO J 13, 249–257; Björnsson et al (1996) EMBO J 15, 1696–1704). Here we analyze this effect on readthrough by wild type or a UGA suppressor form (Su9) of tRNA^Trp by varying the codons at positions −1 and −2 at the 5′ side of UGA. Strains with wild-type or mutant (ArBr) forms of elongation factor Tu (EF-Tu) were analyzed (Vijgenboom et al (1985) EMBO J 4, 1049–1052). The effect on readthrough by changing these −1 and −2 codons is different on the two forms of tRNA^Trp and is also dependent on the structure of EF-Tu. Readthrough by the tRNA^Trp-derived suppressor, but not wild-type tRNA^Trp, is sensitive to the van der Waals volume of the last amino acid in the nascent peptide. Together with mutant EF-Tu, both forms of tRNA^Trp are sensitive. The data suggest that the C-terminal amino acid in the nascent peptide is in a functional interaction with the EF-Tu ternary complex. This interaction is changed by mutation in tRNA^Trp at position 24 or in EF-Tu at position 375. No indication of a changed interaction between the mutant EF-Tu and the penultimate amino acid could be found. Mutant forms of RF2 (Mikuni et al (1991) Biochimie 73, 1509–1516) and ribosomal proteins S4 and S12 (Fáxen et al (1988) J Bacteriol 170, 3756–3760) were found not to be altered in sensitivity to the last two amino acids in the nascent peptide.     

The structural and functional basis for the kirromycin resistance of mutant EF-Tu species in Escherichia coli.

A structural and functional understanding of resistance to the antibiotic kirromycin in Escherichia coli has been sought in order to shed new light on the functioning of the bacterial elongation factor Tu (EF-Tu), in particular its ability to act as a molecular switch. The mutant EF-Tu species G316D, A375T, A375V and Q124K, isolated by M13mp phage-mediated targeted mutagenesis, were studied. In this order the mutant EF-Tu species showed increasing resistance to the antibiotic as measured by poly(U)-directed poly(Phe) synthesis and intrinsic GTPase activities. The K'd values for kirromycin binding to mutant EF-Tu.GTP and EF-Tu.GDP increased in the same order. All mutation sites cluster in the interface of domains 1 and 3 of EF-Tu.GTP, not in that of EF-Tu.GDP. Evidence is presented that kirromycin binds to this interface of wild-type EF-Tu.GTP, thereby jamming the conformational switch of EF-Tu upon GTP hydrolysis. We conclude that the mutations result in two separate mechanisms of resistance to kirromycin. The first inhibits access of the antibiotic to its binding site on EF-Tu.GTP. A second mechanism exists on the ribosome, when mutant EF-Tu species release kirromycin and polypeptide chain elongation continues.     

Mutants of elongation factor Tu promote ribosomal frameshifting and nonsense readthrough.

This is the first report of ribosomal frameshifting promoted by mutants of the elongation factor Tu (EF-Tu). EF-Tu mutants can suppress both -1 and +1 frameshift mutations. The level of nonsense readthrough is also increased at some UGA (this paper) and UAG (Hughes, 1987) sites by these mutants. Suppression occurs when a mutant tuf allele is paired with a wild-type copy of the other tuf gene but is most efficient when both tuf genes are mutant. Frameshifting mediated by the tuf alleles studied, tufA8 and tufB103, is not general; indeed most frameshift mutations are not suppressed. Several possible mechanisms by which mutant EF-Tu may cause frameshifting are discussed.     

Base 2661 in Escherichia coli 23S rRNA influences the binding of elongation factor Tu during protein synthesis in vivo.

The binding of the EF-Tu.GTP.aminoacyl-tRNA ternary complex (EF, elongation factor) to the ribosome is known to be strengthened by a 2661G-to-C mutation in 23S ribosomal RNA, whereas the binding to normal ribosomes is weakened if the factor is in an appropriate mutant form (Aa). In this report we describe the mutual effects by the 2661C alteration in 23S rRNA and EF-Tu(Aa) on bacterial viability and translation efficiency in strains with normal or mutationally altered ribosomes. The rrnB(2661C) allele on a multicopy plasmid was introduced by transformation into Escherichia coli K-12 strains, harbouring either the wild-type or the mutant gene (tufA) for EF-Tu as well as normal or mutant ribosomal protein S12 (rpsL). Together with wild-type EF-Tu, the 2661C mutant ribosomes decreased the translation elongation rate in a rpsL+ strain or a non-restrictive rpsL224 strain. This reduction was not seen in strains which harbored EF-Tu(Aa) instead of EF-Tu(As) (As, wild-type form). Nonsense codon suppression by tyrT(Su3) suppressor tRNA was reduced by 2661C in a rpsL224 strain in the presence of EF-Tu(As) but not in the presence of EF-Tu(Aa). The lethal effect obtained by the combination of 2661C and a restrictive ribosomal protein S12 mutation (rpsL282) disappeared if EF-Tu(As) was replaced by EF-Tu(Aa) in the strain. In such a viable strain, 2661C had no effect on either the translation elongation rate or nonsense codon suppression. Our data suggest that the G base at position 2661 in 23S rRNA is important for binding of EF-Tu during protein synthesis in vivo. The interaction between this base and EF-Tu is strongly influenced by the structure of ribosomal protein S12.     

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).     

The influence of different modifications of elongation factor Tu from Escherichia coli on ternary complex formation investigated by fluorescence spectroscopy.

A fluorescence titration assay was used to detect the effects of various modifications of E.coli elongation factor Tu on the formation of the ternary complex with aminoacyl-tRNAs. The treatment of EF-Tu.GDP with TPCK, an analogue of the 3'terminus of aminoacyl-tRNA, was found to have no influence on the conversion of EF-Tu.GDP to 'active' EF-Tu.GTP, but does decrease the affinity of the activated protein for yeast aminoacyl-tRNA by more than three orders of magnitude. Modification of the elongation factor by limited cleavage with trypsin, leading to the excision of amino acid residues 45-58, has only a minor influence on ternary complex formation. The equilibrium dissociation constant of the ternary complex with this trypsin-treated EF-Tu.GTP and E.coli Phe-tRNA(Phe) is only one order of magnitude higher than that of the ternary complex with native EF-Tu. Mutations in the amino acid residues 222 and 375 of EF-Tu also have little effect on ternary complex formation. Compared with TPCK-treated EF-Tu, the affinities of the two mutant species, designated EF-tuAR and EF-TuBO respectively, for [AEDANS-s2C]Tyr-tRNA(Tyr) are only slightly reduced and in the same range as trypsin-cleaved EF-Tu.     

Role of cysteine residues in glutathione synthetase from Escherichia coli B. Chemical modification and oligonucleotide site-directed mutagenesis

Escherichia coli B glutathione synthetase is composed of four identical subunits; each subunit contains 4 cysteine residues (Cys-122, -195, -222, and -289). We constructed seven different mutant enzymes containing 3, 2, or no cysteine residues/subunit by replacement of cysteine codons with those of alanine in the gsh II gene using site-directed mutagenesis. Three mutant enzymes, Ala289, Ala222/289, Cys-free (Ala122/195/222/289), in which cysteine at residue 289 was replaced with alanine, were not inactivated by 5,5'-dithiobis(2-nitrobenzoate) (DTNB), while the other four mutants retaining Cys-289 were inactivated at the wild-type rate. From these selective inactivations of mutant enzymes by DTNB, the sulfhydryl group modified by DTNB was unambiguously identified as Cys-289. In this way, Cys-289 was found to be also a target of modification with 2-nitrothiocyanobenzoate and N-ethylmaleimide, while Cys-195 was of p-chloromercuribenzoate. These results suggest that both Cys-195 and Cys-289 were not essential for the activity of the glutathione synthetase, but chemical modification of either one of the two sulfhydryl groups resulted in complete loss of the activity. Replacement of Cys-122 to Ala-122 enhanced the reactivity of Cys-289 with sulfhydryl reagents.     

Cumulative stabilizing effects of glycine to alanine substitutions in Bacillus subtilis neutral protease.

Oligonucleotide-directed mutagenesis has been used to replace glycine residues by alanine in neutral protease from Bacillus subtilis. One Gly to Ala substitution (G147A) was located in a helical region of the protein, while the other (G189A) was in a loop. The effects of mutational substitutions on the functional, conformational and stability properties of the enzyme have been investigated using enzymatic assays and spectroscopic measurements. Single substitutions of both Gly147 and Gly189 with Ala residues affect the enzyme kinetic properties using synthetic peptides as substrates. When Gly replacements were concurrently introduced at both positions, the kinetic characteristics of the double mutant were roughly intermediate between those of the two single mutants, and similar to those of the wild-type protease. Both mutants G147A and G189A were found to be more stable towards irreversible thermal inactivation/unfolding than the wild-type species. Moreover, the stabilizing effect of the Gly to Ala substitution was roughly additive in the double mutant G147A/G189A, which shows a 3.2 degrees C increase in Tm with respect to the wild-type protein. These findings indicate that the Gly to Ala substitution can be used as a strategy to stabilize globular proteins. The possible mechanisms of protein stabilization are also discussed.     

HU-1 mutants of Escherichia coli deficient in DNA binding

We constructed four mutants of the Escherichia coli hupB gene, encoding HU-1 protein, by synthetic oligodeoxyribonucleotide-directed, site-specific mutagenesis on M13mp18 vectors. The HupBR45 protein contained alterations of Arg58----Gly and Arg61----Gly, and the HupBF3, HupBK2 and HupBA1 proteins contained Phe47----Thr, Lys37----Gln and Ala30----Asp alterations, respectively. HupBF3 and HupBR45 were unable to maintain normal cell growth in a hupA-hupB-himA triple mutant at 42 degrees C, mini-F or RSF1010 proliferation, or Mu phage development in a hupA-hupB double mutant, whereas HupBA1 and HupBK2 supported these cellular activities. DNA-affinity column chromatography showed that the HupBF3 and HupBR45 had reduced affinities to DNA. These observations indicate that two highly conserved Arg residues in the arm structure of the C-terminal half of the HU-1 molecule and a Phe residue in the short beta-sheet connecting the two halves of the molecule are important for the DNA-binding ability and biological functions of this protein.