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.     

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.     

Conformational change of elongation factor Tu (EF-Tu) induced by antibiotic binding. Crystal structure of the complex between EF-Tu.GDP and aurodox

Aurodox is a member of the family of kirromycin antibiotics, which inhibit protein biosynthesis by binding to elongation factor Tu (EF-Tu). We have determined the crystal structure of the 1:1:1 complex of Thermus thermophilus EF-Tu with GDP and aurodox to 2.0-A resolution. During its catalytic cycle, EF-Tu adopts two strikingly different conformations depending on the nucleotide bound: the GDP form and the GTP form. In the present structure, a GTP complex-like conformation of EF-Tu is observed, although GDP is bound to the nucleotide-binding site. This is consistent with previous proposals that aurodox fixes EF-Tu on the ribosome by locking it in its GTP form. Binding of EF-Tu.GDP to aminoacyl-tRNA and mutually exclusive binding of kirromycin and elongation factor Ts to EF-Tu can be explained on the basis of the structure. For many previously observed mutations that provide resistance to kirromycin, it can now be understood how they prevent interaction with the antibiotic. An unexpected feature of the structure is the reorientation of the His-85 side chain toward the nucleotide-binding site. We propose that this residue stabilizes the transition state of GTP hydrolysis, explaining the acceleration of the reaction by kirromycin-type antibiotics.     

The binding of kirromycin to elongation factor Tu. Structural alterations are responsible for the inhibitory action.

The influence of kirromycin on the elongation factor Tu (EF-Tu) in its binary and ternary complexes was investigated. The equilibrium constant for the binding of the antibiotic to EF-Tu . GDP and EF-Tu . GTP was determined by circular dichroism titrations to be 4 x 10(6) M-1, and to EF-Tu . GTP . aa-tRNA by a combination of circular dichroism titrations and hydrolysis protection experiments to be 2 x 10(6) M-1. In the presence of kirromycin the binding of aminoacyl-tRNAs to EF-Tu . GTP is weakened by a factor of two. The antibiotic changes the conformation of the ternary complex in such a way that the aminoacyl moiety of the aminoacyl-tRNA is more accessible to the non-enzymatic hydrolysis. It is concluded that this structural alteration is responsible for the inhibitory action of the antibiotic.     

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)     

Altered regulation of the guanosine 5'-triphosphate activity in a kirromycin-resistant elongation factor Tu

In the preceding article a mutant elongation factor Tu (EF-TuD2216) resistant to the action of kirromycin was found to display a spontaneous guanosine 5'-triphosphatase (GTPase) activity, i.e., in the absence of aminoacyl transfer ribonucleic acid (tRNA) and ribosome-messenger RNA. This is the first example of an Ef-Tu supporting GTPase activity in the absence of macromolecular effectors and/or kirromycin. In this study we show that this activity is elicited by increasing NH4+ concentrations. As additional effect, the mutation caused an increased affinity of EF-Tu for GTP. Ammonium dependence of the GTPase activity an increased affinity for GTP are two properties also found with wild-type EF-Tu in the presence of kirromycin [Fasano, O., Burns, W., Crechet, J.-B., Sander, G., & Parmeggiani, A. (1978) Eur. J. Biochem. 89, 557-565; Sander, G., Okonek, M., Crechet, J.-B., Ivell, R., Bocchini, V., & Parmeggiani, A. (1979) FEBS Lett. 98, 111-114]. Therefore, both binding of kirromycin to wild-type EF-Tu and acquisition of kirromycin resistance introduce functionally related modifications. Kirromycin at high concentrations (0.1 mM) does not interact with mutant EF-TuD2216.GDP but still does with EF-TuD2216.GTP in agreement with our previous finding that EF-Tu.GTP is the preferential target of the antibiotic in the wild type [Fasano, O., Bruns, W., Crechet, J.-B., Sander, G., & Parmeggiani, A. (1978) Eur. J. Biochem. 89, 557-565). The GTPase activity of mutant EF-Tu in the presence of aminoacyl-tRNA and ribosome.mRNA is much higher than with wild-type EF-Tu and also much less dependent on the presence of mRNA. Miscoding for leucine, measured as poly(U)-directed poly(phenyl-alanine/leucine) synthesis at increasing Mg2+ concentrations, is identical for both wild-type and mutant EF-Tu.     

Pulvomycin-resistant mutants of E.coli elongation factor Tu.

This paper reports the generation of Escherichia coli mutants resistant to pulvomycin. Together with targeted mutagenesis of the tufA gene, conditions were found to overcome membrane impermeability, thereby allowing the selection of three mutants harbouring elongation factor (EF)-Tu Arg230-->Cys, Arg333-->Cys or Thr334-->Ala which confer pulvomycin resistance. These mutations are clustered in the three-domain junction interface of the crystal structure of the GTP form of Thermus thermophilus EF-Tu. This result shares similarities with kirromycin resistance; kirromycin-resistant mutations cluster in the domain 1-3 interface. Since both interface regions are involved in the EF-Tu switch mechanism, we propose that pulvomycin and kirromycin both act by specifically disturbing the allosteric changes required for the switch from EF-Tu-GTP to EF-Tu-GDP. The three-domain junction changes dramatically in the switch to EF-Tu.GDP; in EF-Tu.GDP this region forms an open hole. Structural analysis of the mutation positions in EF-Tu.GTP indicated that the two most highly resistant mutants, R230C and R333C, are part of an electrostatic network involving numerous residues. All three mutations appear to destabilize the EF-Tu.GTP conformation. Genetic and protein characterizations show that sensitivity to pulvomycin is dominant over resistance. This appears to contradict the currently accepted model of protein synthesis inhibition by pulvomycin.     

The elongation factor Tu.kirromycin complex has two binding sites for tRNA molecules

The interaction of the polypeptide chain elongation factor Tu (EF-Tu) with the antibiotic kirromycin and tRNA has been studied by measuring the extent of protein modification with N-tosyl-L-phenylalanine chloromethylketone (TPCK) and N-ethylmaleimide (NEM). Kirromycin protects both EF-Tu.GDP and EF-Tu.GTP against modification with TPCK. Binding of aminoacyl-tRNA added at increasing concentrations to a solution of 40 microM EF-Tu.GDP.kirromycin complex re-exposes the TPCK target site on the protein. However, when the aminoacyl-tRNA concentration is raised beyond 20 microM, TPCK labeling drops again and is blocked completely at approximately 300 microM aminoacyl-tRNA. By contrast, addition of uncharged tRNA or N- acetylaminoacyl -tRNA enhances TPCK labeling of the protein over the entire tRNA concentration range studied. These data strongly suggest that kirromycin induces in EF-Tu.GDP an additional tRNA binding site that can bind uncharged tRNA, aminoacyl-tRNA, and N- acetylaminoacyl -tRNA. Support for this assumption is provided by measuring the modification of EF-Tu.GDP with the sulfhydryl reagent NEM. Moreover, NEM modification also indicates an additional tRNA binding site on EF-Tu.GTP.kirromycin, which could not be detected with TPCK. Mapping of the tryptic peptides of EF-Tu.GDP labeled with [14C]TPCK revealed only one target site for this agent, i.e., cysteine-81. Modification occurred at the same site in the presence and in the absence of kirromycin and uncharged tRNA.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of the antibiotic pulvomycin on the elongation factor Tu-dependent reactions. Comparison with other antibiotics

The antibiotic pulvomycin is an inhibitor of protein synthesis that prevents the formation of the ternary complex between elongation factor (EF-) Tu.GTP and aminoacyl-tRNA. In this report, novel aspects of its action on EF-Tu are described. Pulvomycin markedly affects the equilibrium and kinetics of the EF-Tu-nucleotide interaction, particularly of the EF-Tu.GTP complex. The binding affinity of EF-Tu for GTP is increased 1000 times, mainly as the consequence of a dramatic decrease in the dissociation rate of this complex. In contrast, the affinity for GDP is decreased 10-fold due to a marked increase in the dissociation rate of EF-Tu.GDP (25-fold) that mimics the action of EF-Ts, the GDP/GTP exchange factor of EF-Tu. The effects of pulvomycin and EF-Ts can coexist and are simply additive, supporting the conclusion that these two ligands interact with different sites of EF-Tu. This is further confirmed on native PAGE by the ability of EF-Tu to bind the EF-Ts and the antibiotic simultaneously. Pulvomycin enhances the intrinsic EF-Tu GTPase activity, like kirromycin, though to a much more modest extent. As with kirromycin, this stimulation depends on the concentration and nature of the monovalent cations, Li(+) being the most effective one, followed by Na(+), K(+), and NH(4)(+). In the presence of pulvomycin (in contrast to kirromycin), aa-tRNA and/or ribosomes do not enhance the GTPase activity of EF-Tu. The property of pulvomycin to modify selectively the conformation(s) of EF-Tu is also supported by its effect on heat- and urea-dependent denaturation, and tryptic digestion of the protein. Specific differences and similarities between the action of pulvomycin and the other EF-Tu-specific antibiotics are described and discussed.     

Enacyloxin IIa pinpoints a binding pocket of elongation factor Tu for development of novel antibiotics

Elongation factor (EF-) Tu.GTP is the carrier of aminoacyl-tRNA to the programmed ribosome. Enacyloxin IIa inhibits bacterial protein synthesis by hindering the release of EF-Tu.GDP from the ribosome. The crystal structure of the Escherichia coli EF-Tu.guanylyl iminodiphosphate (GDPNP).enacyloxin IIa complex at 2.3 A resolution presented here reveals the location of the antibiotic at the interface of domains 1 and 3. The binding site overlaps that of kirromycin, an antibiotic with a structure that is unrelated to enacyloxin IIa but that also inhibits EF-Tu.GDP release. As one of the major differences, the enacyloxin IIa tail borders a hydrophobic pocket that is occupied by the longer tail of kirromycin, explaining the higher binding affinity of the latter. EF-Tu.GDPNP.enacyloxin IIa shows a disordered effector region that in the Phe-tRNAPhe.EF-Tu (Thermus aquaticus).GDPNP.enacyloxin IIa complex, solved at 3.1 A resolution, is stabilized by the interaction with tRNA. This work clarifies the structural background of the action of enacyloxin IIa and compares its properties with those of kirromycin, opening new perspectives for structure-guided design of novel antibiotics.     

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.     

Structure-function relationships in the GTP binding domain of EF-Tu: mutation of Val20, the residue homologous to position 12 in p21.

Val20 of elongation factor Tu (EF-Tu), one of the best-characterized GTP binding proteins, is a variable residue within the consensus motif G-X-X-X-X-G-K involved in the interaction with the phosphates of GDP/GTP. To investigate the structure-function relationships of EF-Tu, which is widely used as a model protein, Val20 has been substituted by Gly using oligonucleotide-directed mutagenesis. The most important effects are: (i) a strong reduction of the intrinsic GTPase activity, (ii) a remarkable enhancement of the association and dissociation rates of EF-TuGly20-GDP, mimicking the effect of elongation factor Ts (EF-Ts) and (iii) the inability of ribosomes to influence the intrinsic GTPase of EF-Tu uncoupled from poly(Phe) synthesis. EF-TuGly20 can sustain poly(Phe) synthesis, albeit at a much lower rate than wild-type EF-TuVal20. As with the latter, poly(Phe) synthesis by EF-TuGly20 is inhibited by the antibiotic kirromycin, but differs remarkably in that it is largely independent of the presence of EF-Ts. According to primary sequence alignment, position 20 is homologous to position 12 of ras protein p21. As in p21, this position in EF-Tu is critical, influencing specifically the GDP/GTP interaction as well as other functions. The effect of the mutation displays diversities but also similarities with the situation reported for p21 having the corresponding residues in position 12. The differences observed with two homologous residues, Gly20 and Gly12 in EF-Tu and p21 respectively, show the importance of a variable residue in a consensus element in defining specific functions of GTP binding proteins.     

GE2270A-resistant mutations in elongation factor Tu allow productive aminoacyl-tRNA binding to EF-Tu.GTP.GE2270A complexes

The antibiotic GE2270A prevents stable complex formation between elongation factor Tu (EF-Tu) and aminoacyl-tRNA (aatRNA). In Escherichia coli we characterized two mutant EF-Tu species with either G257S or G275A that lead to high GE2270A resistance in poly(Phe) synthesis, which at least partially explains the high resistance of EF-Tu1 from GE2270A producer Planobispora rosea to its own antibiotic. Both E. coli mutants were unexpectedly found to bind GE2270A nearly as well as wild-type (wt) EF-Tu in their GTP-bound conformations. Both G257S and G275A are in or near the binding site for the 3' end of aatRNA. The G257S mutation causes a 2.5-fold increase in affinity for aatRNA, whereas G275A causes a 40-fold decrease. In the presence of GE2270A, wt EF-Tu shows a drop in aatRNA affinity of at least four orders of magnitude. EF-Tu[G275S] and EF-Tu[G275A] curtail this drop to about two or one order, respectively. It thus appears that the resistance mutations do not prevent GE2270A from binding to EF-Tu.GTP and that the mutant EF-Tus may accommodate GE2270A and aatRNA simultaneously. Interestingly, in their GDP-bound conformations the mutant EF-Tus have much less affinity for GE2270A than wt EF-Tu. The latter is explained by a recent crystal structure of the EF-Tu.GDP.GE2270A complex, which predicts direct steric problems between GE2270A and the mutated G257S or G275A. These mutations may cause a dislocation of GE2270A in complex with GTP-bound EF-Tu, which then no longer prevents aatRNA binding as in the wt situation. Altogether, the data lead to the following novel resistance scenario. Upon arrival of the mutant EF-Tu.GTP.GE2270.aatRNA complex at the ribosomal A-site, the GTPase centre is triggered. The affinities of aatRNA and GE2270A for the GDP-bound EF-Tu are negligible; the former stays at the A-site for subsequent interaction with the peptidyltransferase centre and the latter two dissociate from the ribosome.     

Substitution of Val20 by Gly in elongation factor Tu. Effects on the interaction with elongation factors Ts, aminoacyl-tRNA and ribosomes

Substitution of V20 by G in the consensus element G18HVDHGK24 of EF-Tu (referred to as EF-TuG20) strongly influences the interaction with GDP as well as the GTPase activity [Jacquet, E. & Parmeggiani, A. (1988) EMBO J. 7, 2861-2867]. In an extension of this work we describe additional properties of the mutated factor, paying particular attention to the interaction with the macromolecular ligands. Our results show that the conformational transitions induced by the mutation strongly favor the regeneration of the active complex EF-TuG20.GTP, almost as effectively as with wild-type EF-Tu in the presence of elongation factor Ts. Addition of elongation factor Ts further enhances the rate of the GDP to GTP exchange of the mutated factor. Remarkably, EF-TuG20.GDP can support the enzymatic binding of aminoacyl-tRNA to ribosome.mRNA at low MgCl2 concentration, an effect that with wild-type EF-Tu can only occur in the presence of kirromycin. Our results show that EF-TuG20.GDP shares common features with the GTP-like conformation induced by kirromycin on wild-type EF-Tu. The ability of the ribosome to activate the EF-TuG20 center for GTP hydrolysis is strongly decreased, while the stimulation by aminoacyl-tRNA is conserved. The ribosomal activity is partially restored by addition of aminoacyl-tRNA plus poly(U), showing that codon/anticodon interaction contribute to correct the anomalous interaction between ternary complex and ribosomes. The impaired activity of EF-TuG20 in poly(Phe) synthesis is related to the degree of defective GTP hydrolysis and, most interestingly, it is characterized by a striking increase of the fidelity of translation at high MgCl2 concentration. This effect probably depends on a more selective recognition of the ternary complex by ribosome.mRNA, as a consequence of a longer pausing of EF-TuG20 on the ribosome. In conclusion, position 20 in EF-Tu is important for coordinating the allosteric mechanisms controlling the action of EF-Tu and its ligands.     

tRNA Dissociation from EF-Tu after GTP Hydrolysis: Primary Steps and Antibiotic Inhibition

In each round of ribosomal translation, the translational GTPase elongation factor Tu (EF-Tu) delivers a transfer RNA (tRNA) to the ribosome. After successful decoding, EF-Tu hydrolyzes GTP, which triggers a conformational change that ultimately results in the release of the tRNA from EF-Tu. To identify the primary steps of these conformational changes and how they are prevented by the antibiotic kirromycin, we employed all-atom explicit-solvent molecular dynamics simulations of the full ribosome-EF-Tu complex. Our results suggest that after GTP hydrolysis and P_i release, the loss of interactions between the nucleotide and the switch 1 loop of EF-Tu allows domain D1 of EF-Tu to rotate relative to domains D2 and D3 and leads to an increased flexibility of the switch 1 loop. This rotation induces a closing of the D1-D3 interface and an opening of the D1-D2 interface. We propose that the opening of the D1-D2 interface, which binds the CCA tail of the tRNA, weakens the crucial EF-Tu-tRNA interactions, which lowers tRNA binding affinity, representing the first step of tRNA release. Kirromycin binds within the D1-D3 interface, sterically blocking its closure, but does not prevent hydrolysis. The resulting increased flexibility of switch 1 explains why it is not resolved in kirromycin-bound structures.     

The elongation factor Tu binds aminoacyl-tRNA in the presence of GDP

Escherichia coli elongation factor (EF-Tu) binds aminoacyl-tRNAs (aa-tRNA) not only in the presence of GTP but also in the presence of GDP. Complex formation leads to a protection of the aa-tRNA against nonenzymatic deacylation and digestion by pancreatic ribonuclease, as well as to a protection of EF-Tu against proteolysis by trypsin. The equilibrium constant for the binding of Phe-tRNAPheyeast for example to EF-Tu.GDP has been determined to be 0.7 X 10(5) M-1 which is 2 orders of magnitude lower than the equilibrium constant for Phe-tRNAPheyeast binding to EF-Tu.GTP. In the presence of kirromycin, aminoacyl-tRNA binding to EF-Tu.GDP is not affected as much: Phe-tRNAPheyeast is bound with an equilibrium constant of 3 X 10(5) M-1. While there is also a measurable interaction between EF-Tu.GTP and tRNA, such an interaction cannot be detected with EF-Tu.GDP and tRNA, not even at millimolar concentrations. A so far undetected complex formation between aminoacyl-tRNA and EF-Tu.GTP in the presence of pulvomycin, however, could be detected. The results are discussed in terms of the structural requirements of ternary complex formation and in the light of proofreading schemes involving A-site binding on the E. coli ribosome.     

A signal relay between ribosomal protein S12 and elongation factor EF-Tu during decoding of mRNA

Codon recognition by aminoacyl-tRNA on the ribosome triggers a process leading to GTP hydrolysis by elongation factor Tu (EF-Tu) and release of aminoacyl-tRNA into the A site of the ribosome. The nature of this signal is largely unknown. Here, we present genetic evidence that a specific set of direct interactions between ribosomal protein S12 and aminoacyl-tRNA, together with contacts between S12 and 16S rRNA, provide a pathway for the signaling of codon recognition to EF-Tu. Three novel amino acid substitutions, H76R, R37C, and K53E in Thermus thermophilus ribosomal protein S12, confer resistance to streptomycin. The streptomycin-resistance phenotypes of H76R, R37C, and K53E are all abolished by the mutation A375T in EF-Tu. A375T confers resistance to kirromycin, an antibiotic freezing EF-Tu in a GTPase activated state. H76 contacts aminoacyl-tRNA in ternary complex with EF-Tu and GTP, while R37 and K53 are involved in the conformational transition of the 30S subunit occurring upon codon recognition. We propose that codon recognition and domain closure of the 30S subunit are signaled through aminoacyl-tRNA to EF-Tu via these S12 residues.     

New antibiotic that acts specifically on the GTP-bound form of elongation factor Tu.

The new thiazolyl peptide antibiotic GE2270 A, isolated from Planobispora rosea strain ATCC 53773, is shown to inhibit bacterial protein biosynthesis in vitro by affecting specifically the GTP-bound form of elongation factor Tu (EF-Tu). The 'off' rate of EF-Tu.GTP is slowed down 400-fold, locking GTP on EF-Tu, whereas EF-Tu.GDP is unaffected. Therefore, on the EF-Tu.guanine nucleotide interaction, GE2270 A mimicks the effect of aa-tRNA. In line with this, the binding of aa-tRNA to EF-Tu.GTP is hindered by the antibiotic, as shown by the absence of a stable ternary complex and the inhibition of the enzymatic binding of aa-tRNA to the ribosome. This blocks the elongation cycle. GE2270 A does not essentially modify the intrinsic GTPase activity of EF-Tu, but impairs the stimulation by ribosomes of this reaction. The negative effect of GE2270 A on the EF-Tu.GTP interaction with aa-tRNA bears similarities with that of the structurally unrelated pulvomycin, whereas marked differences were found by comparing the effects of these two antibiotics on EF-Tu.GDP. This work emphasizes the varieties of the transitional conformations which tune the EF-Tu interaction with GTP and GDP.