Relevance of histidine-84 in the elongation factor Tu GTPase activity and in poly(Phe) synthesis: its substitution by glutamine and alanine

Weakening the IF2-fMet-tRNA Interaction Suppresses the Lethal Phenotype Caused by GTPase Inactivation

Substitution of the conserved Histidine 448 present in one of the three consensus elements characterizing the guanosine nucleotide binding domain (IF2 G2) of Escherichia coli translation initiation factor IF2 resulted in impaired ribosome-dependent GTPase activity which prevented IF2 dissociation from the ribosome, caused a severe protein synthesis inhibition, and yielded a dominant lethal phenotype. A reduced IF2 affinity for the ribosome was previously shown to suppress this lethality. Here, we demonstrate that also a reduced IF2 affinity for fMet-tRNA can suppress this dominant lethal phenotype and allows IF2 to support faithful translation in the complete absence of GTP hydrolysis. These results strengthen the premise that the conformational changes of ribosome, IF2, and fMet-tRNA occurring during the late stages of translation initiation are thermally driven and that the energy generated by IF2-dependent GTP hydrolysis is not required for successful translation initiation and that the dissociation of the interaction between IF2 C2 and the acceptor end of fMet-tRNA, which represents the last tie anchoring the factor to the ribosome before the formation of an elongation-competent 70S complex, is rate limiting for both the adjustment of fMet-tRNA in a productive P site and the IF2 release from the ribosome.

Differential Contribution of Protein Factors and 70S Ribosome to Elongation

The growth of the polypeptide chain occurs due to the fast and coordinated work of the ribosome and protein elongation factors, EF-Tu and EF-G. However, the exact contribution of each of these components in the overall balance of translation kinetics remains not fully understood. We created an in vitro translation system Escherichia coli replacing either elongation factor with heterologous thermophilic protein from Thermus thermophilus. The rates of the A-site binding and decoding reactions decreased an order of magnitude in the presence of thermophilic EF-Tu, indicating that the kinetics of aminoacyl-tRNA delivery depends on the properties of the elongation factor. On the contrary, thermophilic EF-G demonstrated the same translocation kinetics as a mesophilic protein. Effects of translocation inhibitors (spectinomycin, hygromycin B, viomycin and streptomycin) were also similar for both proteins. Thus, the process of translocation largely relies on the interaction of tRNAs and the ribosome and can be efficiently catalysed by thermophilic EF-G even at suboptimal temperatures.

Translational GTPase BipA Is Involved in the Maturation of a Large Subunit of Bacterial Ribosome at Suboptimal Temperature

BPI-inducible protein A (BipA), a highly conserved paralog of the well-known translational GTPases LepA and EF-G, has been implicated in bacterial motility, cold shock, stress response, biofilm formation, and virulence. BipA binds to the aminoacyl-(A) site of the bacterial ribosome and establishes contacts with the functionally important regions of both subunits, implying a specific role relevant to the ribosome, such as functioning in ribosome biogenesis and/or conditional protein translation. When cultured at suboptimal temperatures, the Escherichia coli bipA genomic deletion strain (ΔbipA) exhibits defects in growth, swimming motility, and ribosome assembly, which can be complemented by a plasmid-borne bipA supplementation or suppressed by the genomic rluC deletion. Based on the growth curve, soft agar swimming assay, and sucrose gradient sedimentation analysis, mutation of the catalytic residue His78 rendered plasmid-borne bipA unable to complement its deletion phenotypes. Interestingly, truncation of the C-terminal loop of BipA exacerbates the aforementioned phenotypes, demonstrating the involvement of BipA in ribosome assembly or its function. Furthermore, tandem mass tag-mass spectrometry analysis of the ΔbipA strain proteome revealed upregulations of a number of proteins (e.g., DeaD, RNase R, CspA, RpoS, and ObgE) implicated in ribosome biogenesis and RNA metabolism, and these proteins were restored to wild-type levels by plasmid-borne bipA supplementation or the genomic rluC deletion, implying BipA involvement in RNA metabolism and ribosome biogenesis. We have also determined that BipA interacts with ribosome 50S precursor (pre-50S), suggesting its role in 50S maturation and ribosome biogenesis. Taken together, BipA demonstrates the characteristics of a bona fide 50S assembly factor in ribosome biogenesis.

Peculiarities in Activation of Hydrolytic Activity of Elongation Factors

Translational GTPases (trGTPases) belong to the family of G proteins and play key roles at all stages of protein biosynthesis on the ribosome. Unidirectional and cyclic functioning of G proteins is ensured by their ability to switch between the active and inactive states due to GTP hydrolysis accelerated by the auxiliary GTPase-activating proteins. Although trGTPases interact with the ribosomes in different conformational states, they bind to the same conserved region, which, unlike in classical GTPase-activating proteins, is represented by ribosomal RNA. The resulting catalytic sites have almost identical structure in all elongation factors suggesting a common mechanism of GTP hydrolysis. However, fine details of the activated state formation and significantly different rates of GTP hydrolysis indicate the existence of distinctive features upon GTP hydrolysis catalyzed by the different factors. Here, we present a contemporary view on the mechanism of GTPase activation and GTP hydrolysis by the elongation factors EF-Tu, EF-G, and SelB based on the analysis of structural, biochemical, and bioinformatics data.

Review: Translational GTPases

Translational GTPases (trGTPases) play key roles in facilitating protein synthesis on the ribosome. Despite the high degree of evolutionary conservation in the sequences of their GTP-binding domains, the rates of GTP hydrolysis and nucleotide exchange vary broadly between different trGTPases. EF-Tu, one of the best-characterized model G proteins, evolved an exceptionally rapid and tightly regulated GTPase activity, which ensures rapid and accurate incorporation of amino acids into the nascent chain. Other trGTPases instead use the energy of GTP hydrolysis to promote movement or to ensure the forward commitment of translation reactions. Recent data suggest the GTPase mechanism of EF-Tu and provide an insight in the catalysis of GTP hydrolysis by its unusual activator, the ribosome. Here we summarize these advances in understanding the functional cycle and the regulation of trGTPases, stimulated by the elucidation of their structures on the ribosome and the progress in dissecting the reaction mechanism of GTPases. © 2016 Wiley Periodicals, Inc. Biopolymers 105: 463-475, 2016.

EF-Tu from the enacyloxin producing Frateuria W-315 strain: Structure/activity relationship and antibiotic resistance

In this report, we have demonstrated that the poly(U)-dependent poly(Phe) synthesis activity of elongator factor Tu (EF-Tu) from the enacyloxin producing strain Frateuria sp. W-315 is inhibited by the antibiotic similarly to that of Escherichia coli EF-Tu. The inhibitory effect of enacyloxin observed in a purified system was the same as that obtained with an S30 extract from E. coli or Frateuria sp. W-315, respectively, suggesting that antibiotic resistance of enacyloxin producing Frateuria sp. W-315 is not due neither to EF-Tu nor to other components of the translation machinery but to a still unknown mechanism. The EF-Tu gene, as PCR amplified from Frateuria W-315 genomic DNA and sequenced represented an ORF of 1191 nucleotides corresponding to 396 amino acids. This protein is larger than the product of tufA from E. coli by only two amino acid residues. Alignment of the amino acid sequence of EF-Tu from E. coli with those of Frateuria and Ralstonia solanacearum indicates on average 80% identical amino acid residues and 9.7% conservative replacements between EF-Tu Frateuria and EF-Tu E. coli, on one hand, and 97% identity and 1.7% conservative replacement between EF-Tu Frateuria and EF-Tu Ralstonia solanacearum, on the other hand. These strong primary structure similarities between EF-Tu from different origins are consistent with the fact that this factor is essential for the translation process in all kingdoms of life. Comparison of the effects of antibiotics on EF-Tu Frateuria and EF-Tu E. coli revealed that enacyloxin, kirromycin and pulvomycin exert a stronger stimulation of the GDP dissociation rate on EF-Tu Frateuria, while the effects of the antibiotics on the GDP association rate were comparable for the two EF-Tu species. Different mutants of EF-Tu E. coli were constructed with the help of site directed mutagenesis by changing one or several residues of EF-Tu E. coli by the corresponding residues of EF-Tu Frateuria. The single A45K substitution did not modify the intrinsic GTPase activity of EF-Tu E. coli. In contrast, a 2-3 fold stimulation of the intrinsic GTPase activity was observed with the single A42E, F46Y, Q48E and the double F46Y/Q48E substitution. Finally, up to a 7 fold stimulation was observed with the quadruple substitution (mutant A42E/A45K/F46Y/Q48E.

A conserved histidine in switch-II of EF-G moderates release of inorganic phosphate

Elongation factor G (EF-G), a translational GTPase responsible for tRNA-mRNA translocation possesses a conserved histidine (H91 in Escherichia coli) at the apex of switch-II, which has been implicated in GTPase activation and GTP hydrolysis. While H91A, H91R and H91E mutants showed different degrees of defect in ribosome associated GTP hydrolysis, H91Q behaved like the WT. However, all these mutants, including H91Q, are much more defective in inorganic phosphate (Pi) release, thereby suggesting that H91 facilitates Pi release. In crystal structures of the ribosome bound EF-G•GTP a tight coupling between H91 and the γ-phosphate of GTP can be seen. Following GTP hydrolysis, H91 flips ~140° in the opposite direction, probably with Pi still coupled to it. This, we suggest, promotes Pi to detach from GDP and reach the inter-domain space of EF-G, which constitutes an exit path for the Pi. Molecular dynamics simulations are consistent with this hypothesis and demonstrate a vital role of an Mg²⁺ ion in the process.

Activation of GTP hydrolysis in mRNA-tRNA translocation by elongation factor G

During protein synthesis, elongation of the polypeptide chain by each amino acid is followed by a translocation step in which mRNA and transfer RNA (tRNA) are advanced by one codon. This crucial step is catalyzed by elongation factor G (EF-G), a guanosine triphosphatase (GTPase), and accompanied by a rotation between the two ribosomal subunits. A mutant of EF-G, H91A, renders the factor impaired in guanosine triphosphate (GTP) hydrolysis and thereby stabilizes it on the ribosome. We use cryogenic electron microscopy (cryo-EM) at near-atomic resolution to investigate two complexes formed by EF-G H91A in its GTP state with the ribosome, distinguished by the presence or absence of the intersubunit rotation. Comparison of these two structures argues in favor of a direct role of the conserved histidine in the switch II loop of EF-G in GTPase activation, and explains why GTP hydrolysis cannot proceed with EF-G bound to the unrotated form of the ribosome.

Modeling the mechanisms of biological GTP hydrolysis

Enzymes that hydrolyze GTP are currently in the spotlight, due to their molecular switch mechanism that controls many cellular processes. One of the best-known classes of these enzymes are small GTPases such as members of the Ras superfamily, which catalyze the hydrolysis of the γ-phosphate bond in GTP. In addition, the availability of an increasing number of crystal structures of translational GTPases such as EF-Tu and EF-G have made it possible to probe the molecular details of GTP hydrolysis on the ribosome. However, despite a wealth of biochemical, structural and computational data, the way in which GTP hydrolysis is activated and regulated is still a controversial topic and well-designed simulations can play an important role in resolving and rationalizing the experimental data. In this review, we discuss the contributions of computational biology to our understanding of GTP hydrolysis on the ribosome and in small GTPases.

Ribosome-induced tuning of GTP hydrolysis by a translational GTPase

GTP hydrolysis by elongation factor Tu (EF-Tu), a translational GTPase that delivers aminoacyl-tRNAs to the ribosome, plays a crucial role in decoding and translational fidelity. The basic reaction mechanism and the way the ribosome contributes to catalysis are a matter of debate. Here we use mutational analysis in combination with measurements of rate/pH profiles, kinetic solvent isotope effects, and ion dependence of GTP hydrolysis by EF-Tu off and on the ribosome to dissect the reaction mechanism. Our data suggest that--contrary to current models--the reaction in free EF-Tu follows a pathway that does not involve the critical residue H84 in the switch II region. Binding to the ribosome without a cognate codon in the A site has little effect on the GTPase mechanism. In contrast, upon cognate codon recognition, the ribosome induces a rearrangement of EF-Tu that renders GTP hydrolysis sensitive to mutations of Asp21 and His84 and insensitive to K(+) ions. We suggest that Asp21 and His84 provide a network of interactions that stabilize the positions of the γ-phosphate and the nucleophilic water, respectively, and thus play an indirect catalytic role in the GTPase mechanism on the ribosome.

The interface between Escherichia coli elongation factor Tu and aminoacyl-tRNA

Nineteen of the highly conserved residues of Escherichia coli (E. coli) Elongation factor Tu (EF-Tu) that form the binding interface with aa-tRNA were mutated to alanine to better understand how modifying the thermodynamic properties of EF-Tu–tRNA interaction can affect the decoding properties of the ribosome. Comparison of ΔΔG^o values for binding EF-Tu to aa-tRNA show that the majority of the interface residues stabilize the ternary complex and their thermodynamic contribution can depend on the tRNA species that is used. Experiments with a very tight binding mutation of tRNA^Tyr indicate that interface amino acids distant from the tRNA mutation can contribute to the specificity. For nearly all of the mutations, the values of ΔΔG^o were identical to those previously determined at the orthologous positions of Thermus thermophilus (T. thermophilus) EF-Tu indicating that the thermodynamic properties of the interface were conserved between distantly related bacteria. Measurement of the rate of GTP hydrolysis on programmed ribosomes revealed that nearly all of the interface mutations were able to function in ribosomal decoding. The only interface mutation with greatly impaired GTPase activity was R223A which is the only one that also forms a direct contact with the ribosome. Finally, the ability of the EF-Tu interface mutants to destabilize the EF-Tu–aa-tRNA interaction on the ribosome after GTP hydrolysis were evaluated by their ability to suppress the hyperstable T1 tRNA^Tyr variant where EF-Tu release is sufficiently slow to limit the rate of peptide bond formation (k_pep) . In general, interface mutations that destabilize EF-Tu binding are also able to stimulate k_pep of T1 tRNA^Tyr, suggesting that the thermodynamic properties of the EF-Tu–aa-tRNA interaction on the ribosome are quite similar to those found in the free ternary complex.

Energetics of activation of GTP hydrolysis on the ribosome

Several of the steps in protein synthesis on the ribosome utilize hydrolysis of guanosine triphosphate (GTP) as the driving force. This reaction is catalyzed by translation factors that become activated upon binding to the ribosome. The recently determined crystal structure of an elongation factor-Tu ternary complex bound to the ribosome allows the energetics of GTP activation to be explored by computer simulations. A central problem regards the role of the universally conserved histidine, which has been proposed to act as a general base for guanosine triphosphate hydrolysis. Here we report a detailed energetic and structural analysis of different possible protonation states that could be involved in activation of the reaction. We show that the histidine cannot act as a general base, but must be protonated and in its active conformation to promote GTP hydrolysis. We further show that the sarcin-ricin loop of the ribosome spontaneously drives the histidine into the correct conformation for GTP activation.

Mechanism of activation of elongation factor Tu by ribosome: catalytic histidine activates GTP by protonation

Elongation factor Tu (EF-Tu) is central to prokaryotic protein synthesis as it has the role of delivering amino-acylated tRNAs to the ribosome. Release of EF-Tu, after correct binding of the EF-Tu:aa-tRNA complex to the ribosome, is initiated by GTP hydrolysis. This reaction, whose mechanism is uncertain, is catalyzed by EF-Tu, but requires activation by the ribosome. There have been a number of mechanistic proposals, including those spurred by a recent X-ray crystallographic analysis of a ribosome:EF-Tu:aa-tRNA:GTP-analog complex. In this work, we have investigated these and alternative hypotheses, using high-level quantum chemical/molecular mechanical simulations for the wild-type protein and its His85Gln mutant. For both proteins, we find previously unsuggested mechanisms as being preferred, in which residue 85, either His or Gln, directly assists in the reaction. Analysis shows that the RNA has a minor catalytic effect in the wild-type reaction, but plays a significant role in the mutant by greatly stabilizing the reaction's transition state. Given the similarity between EF-Tu and other members of the translational G-protein family, it is likely that these mechanisms of ribosome-activated GTP hydrolysis are pertinent to all of these proteins.

Steric complementarity in the decoding center is important for tRNA selection by the ribosome

Accurate tRNA selection by the ribosome is essential for the synthesis of functional proteins. Previous structural studies indicated that the ribosome distinguishes between cognate and near-cognate tRNAs by monitoring the geometry of the codon-anticodon helix in the decoding center using the universally conserved 16S ribosomal RNA bases G530, A1492 and A1493. These bases form hydrogen bonds with the 2'-hydroxyl groups of the codon-anticodon helix, which are expected to be disrupted with a near-cognate codon-anticodon helix. However, a recent structural study showed that G530, A1492 and A1493 form hydrogen bonds in a manner identical with that of both cognate and near-cognate codon-anticodon helices. To understand how the ribosome discriminates between cognate and near-cognate tRNAs, we made 2'-deoxynucleotide and 2'-fluoro substituted mRNAs, which disrupt the hydrogen bonds between the A site codon and G530, A1492 and A1493. Our results show that multiple 2'-deoxynucleotide substitutions in the mRNA substantially inhibit tRNA selection, whereas multiple 2'-fluoro substitutions in the mRNA have only modest effects on tRNA selection. Furthermore, the miscoding antibiotics paromomycin and streptomycin rescue the defects in tRNA selection with the multiple 2'-deoxynucleotide substituted mRNA. These results suggest that steric complementarity in the decoding center is more important than the hydrogen bonds between the A site codon and G530, A1492 and A1493 for tRNA selection.

Structural basis unifying diverse GTP hydrolysis mechanisms

Central to biological processes is the regulation rendered by GTPases. Until recently, the GTP hydrolysis mechanism, exemplified by Ras-family (and G-α) GTPases, was thought to be universal. This mechanism utilizes a conserved catalytic Gln supplied "in cis" from the GTPase and an arginine finger "in trans" from a GAP (GTPase activating protein) to stabilize the transition state. However, intriguingly different mechanisms are operative in structurally similar GTPases. MnmE and dynamin like cation-dependent GTPases lack the catalytic Gln and instead employ a Glu/Asp/Ser situated elsewhere and in place of the arginine finger use a K(+) or Na(+) ion. In contrast, Rab33 possesses the Gln but does not utilize it for catalysis; instead, the GAP supplies both a catalytic Gln and an arginine finger in trans. Deciphering the underlying principles that unify seemingly unrelated mechanisms is central to understanding how diverse mechanisms evolve. Here, we recognize that steric hindrance between active site residues is a criterion governing the mechanism employed by a given GTPase. The Arf-ArfGAP structure is testimony to this concept of spatial (in)compatibility of active site residues. This understanding allows us to predict an as yet unreported hydrolysis mechanism and clarifies unexplained observations about catalysis by Rab11 and the need for HAS-GTPases to employ a different mechanism. This understanding would be valuable for experiments in which abolishing GTP hydrolysis or generating constitutively active forms of a GTPase is important.

Mutational analysis of the ribosome assembly GTPase RbgA provides insight into ribosome interaction and ribosome-stimulated GTPase activation

Ribosome biogenesis GTPase A protein (RbgA) is an essential GTPase required for the biogenesis of the 50S subunit in Bacillus subtilis. Homologs of RbgA are widely distributed in bacteria and eukaryotes and are implicated in ribosome assembly in the mitochondria, chloroplast and cytoplasm. Cells depleted of RbgA accumulate an immature large subunit that is missing key ribosomal proteins. RbgA, unlike many members of the Ras superfamily of GTPases, lacks a defined catalytic residue for carrying out guanosine triphosphate (GTP) hydrolysis. To probe RbgA function in ribosome assembly, we used a combined bioinformatics, genetic and biochemical approach. We identified a RNA-binding domain within the C-terminus of RbgA that is structurally similar to AmiR–NasR Transcription Anti-termination Regulator (ANTAR) domains, which are known to bind structured RNA. Mutation of key residues in the ANTAR domain altered RbgA association with the ribosome. We identified a putative catalytic residue within a highly conserved region of RbgA, His9, which is contained within a similar PGH motif found in elongation factor Tu (EF-Tu) that is required for GTP hydrolysis on interaction with the ribosome. Finally, our results support a model in which the GTPase activity of RbgA directly participates in the maturation of the large subunit rather than solely promoting dissociation of RbgA from the 50S subunit.

Why nature really chose phosphate

Phosphoryl transfer plays key roles in signaling, energy transduction, protein synthesis, and maintaining the integrity of the genetic material. On the surface, it would appear to be a simple nucleophile displacement reaction. However, this simplicity is deceptive, as, even in aqueous solution, the low-lying d-orbitals on the phosphorus atom allow for eight distinct mechanistic possibilities, before even introducing the complexities of the enzyme catalyzed reactions. To further complicate matters, while powerful, traditional experimental techniques such as the use of linear free-energy relationships (LFER) or measuring isotope effects cannot make unique distinctions between different potential mechanisms. A quarter of a century has passed since Westheimer wrote his seminal review, 'Why Nature Chose Phosphate' (Science 235 (1987), 1173), and a lot has changed in the field since then. The present review revisits this biologically crucial issue, exploring both relevant enzymatic systems as well as the corresponding chemistry in aqueous solution, and demonstrating that the only way key questions in this field are likely to be resolved is through careful theoretical studies (which of course should be able to reproduce all relevant experimental data). Finally, we demonstrate that the reason that nature really chose phosphate is due to interplay between two counteracting effects: on the one hand, phosphates are negatively charged and the resulting charge-charge repulsion with the attacking nucleophile contributes to the very high barrier for hydrolysis, making phosphate esters among the most inert compounds known. However, biology is not only about reducing the barrier to unfavorable chemical reactions. That is, the same charge-charge repulsion that makes phosphate ester hydrolysis so unfavorable also makes it possible to regulate, by exploiting the electrostatics. This means that phosphate ester hydrolysis can not only be turned on, but also be turned off, by fine tuning the electrostatic environment and the present review demonstrates numerous examples where this is the case. Without this capacity for regulation, it would be impossible to have for instance a signaling or metabolic cascade, where the action of each participant is determined by the fine-tuned activity of the previous piece in the production line. This makes phosphate esters the ideal compounds to facilitate life as we know it.

Addressing open questions about phosphate hydrolysis pathways by careful free energy mapping

The nature and mechanism of phosphate hydrolysis reactions are of great interest in view of the crucial role of these reactions in key biological processes. Although it is becoming clearer that the ultimate way of resolving mechanistic controversies must involve reliable theoretical studies, it is not widely realized that such studies cannot be performed at present by using most existing automated ways and that only careful systematic studies can lead to meaningful conclusions. The present work clarifies the above point by considering the hydrolysis of phosphate monoesters. The clarification starts by defining the actual issues that should be addressed in careful studies and by highlighting the problems with studies that ignore the need for unique mechanistic definitions (e.g., works that confuse associative and dissociative pathways). We then focus on the analysis of the proton transfer (PT) pathways in phosphate hydrolysis and on recent suggestions that PT involves more than one water molecule. Here we point out that most of the studies that found a proton transfer through several water molecules have not involved a sufficient systematic search of the relevant reaction coordinates. This includes both energy minimization approaches as well as a recent metadynamics (MTD) simulation study. To illustrate the crucial need of exploring the potential surfaces reliably, rather than relying on automated approaches, we present here a very careful study of the free energy landscape along a 3D reaction coordinate (RC) exploring both the standard 2D RC, comprised of the attacking and leaving group reaction coordinates, as well as of the proton transfer (PT) coordinate. Our study points out that QM/MM minimization or MTD studies that concluded that the hydrolysis of phosphate monoesters involves a PT through several water molecules, have not explored carefully the single water (1W) path (that involves a direct PT form the attacking water molecule to the phosphate oxygen). Furthermore, we identified the most likely reason for the difficulty in finding the 1W path by QM/MM minimization methods, as well as by the current MTD simulations. We also discuss the problems with current studies that challenge the phosphate as a base mechanism and emphasize that all recent studies found associative/concerted paths (although many have not realized the meaning of their results). Finally, although we clearly do not have the last word about the 1W versus 2W paths we believe that we illustrated that the crucial mechanistic problems with alternative pathways should not be resolved by just running black box search approaches.

Structural basis for translation termination by archaeal RF1 and GTP-bound EF1α complex

When a stop codon appears at the ribosomal A site, the class I and II release factors (RFs) terminate translation. In eukaryotes and archaea, the class I and II RFs form a heterodimeric complex, and complete the overall translation termination process in a GTP-dependent manner. However, the structural mechanism of the translation termination by the class I and II RF complex remains unresolved. In archaea, archaeal elongation factor 1 alpha (aEF1α), a carrier GTPase for tRNA, acts as a class II RF by forming a heterodimeric complex with archaeal RF1 (aRF1). We report the crystal structure of the aRF1·aEF1α complex, the first active class I and II RF complex. This structure remarkably resembles the tRNA·EF–Tu complex, suggesting that aRF1 is efficiently delivered to the ribosomal A site, by mimicking tRNA. It provides insights into the mechanism that couples GTP hydrolysis by the class II RF to stop codon recognition and peptidyl-tRNA hydrolysis by the class I RF. We discuss the different mechanisms by which aEF1α recognizes aRF1 and aPelota, another aRF1-related protein and molecular evolution of the three functions of aEF1α.

Converting structural information into an allosteric-energy-based picture for elongation factor Tu activation by the ribosome

The crucial process of aminoacyl-tRNA delivery to the ribosome is energized by the GTPase reaction of the elongation factor Tu (EF-Tu). Advances in the elucidation of the structure of the EF-Tu/ribosome complex provide the rare opportunity of gaining a detailed understanding of the activation process of this system. Here, we use quantitative simulation approaches and reproduce the energetics of the GTPase reaction of EF-Tu with and without the ribosome and with several key mutants. Our study provides a novel insight into the activation process. It is found that the critical H84 residue is not likely to behave as a general base but rather contributes to an allosteric effect, which includes a major transition state stabilization by the electrostatic effect of the P loop and other regions of the protein. Our findings have general relevance to GTPase activation, including the processes that control signal transduction.

Polyamines accelerate codon recognition by transfer RNAs on the ribosome

The selection of aminoacyl-tRNAs by the ribosome is a fundamental step in the elongation cycle of protein synthesis. tRNA selection is a multistep process that ensures only correct aminoacyl-tRNAs are accepted while incorrect aminoacyl-tRNAs are rejected. A key step in tRNA selection is the formation of base pairs between the anticodon of the aminoacyl-tRNA and the mRNA codon in the A site, called "codon recognition". Here, we report the development of a new, fluorescence-based, kinetic assay for monitoring codon recognition by the ribosome. Using this assay, we show that codon recognition is a second-order binding step under optimal conditions. Additionally, we show that at low Mg(2+) concentrations, the polyamines spermine and spermidine stimulate codon recognition by the ribosome without a loss of fidelity. Polyamines may accelerate codon recognition by altering the structure and dynamics of the anticodon arm of the aminoacyl-tRNA.

Elongation in translation as a dynamic interaction among the ribosome, tRNA, and elongation factors EF-G and EF-Tu

The ribosome is a complex macromolecular machine that translates the message encoded in the messenger RNA and synthesizes polypeptides by linking the individual amino acids carried by the cognate transfer RNAs (tRNAs). The protein elongation cycle, during which the tRNAs traverse the ribosome in a coordinated manner along a path of more than 100 A, is facilitated by large-scale rearrangements of the ribosome. These rearrangements go hand in hand with conformational changes of tRNA as well as elongation factors EF-Tu and EF-G - GTPases that catalyze tRNA delivery and translocation, respectively. This review focuses on the structural data related to the dynamics of the ribosomal machinery, which are the basis, in conjunction with existing biochemical, kinetic, and fluorescence resonance energy transfer data, of our knowledge of the decoding and translocation steps of protein elongation.

GTPase activation of elongation factor EF-Tu by the ribosome during decoding

We have used single-particle reconstruction in cryo-electron microscopy to determine a structure of the Thermus thermophilus ribosome in which the ternary complex of elongation factor Tu (EF-Tu), tRNA and guanine nucleotide has been trapped on the ribosome using the antibiotic kirromycin. This represents the state in the decoding process just after codon recognition by tRNA and the resulting GTP hydrolysis by EF-Tu, but before the release of EF-Tu from the ribosome. Progress in sample purification and image processing made it possible to reach a resolution of 6.4 A. Secondary structure elements in tRNA, EF-Tu and the ribosome, and even GDP and kirromycin, could all be visualized directly. The structure reveals a complex conformational rearrangement of the tRNA in the A/T state and the interactions with the functionally important switch regions of EF-Tu crucial to GTP hydrolysis. Thus, the structure provides insights into the molecular mechanism of signalling codon recognition from the decoding centre of the 30S subunit to the GTPase centre of EF-Tu.

Mechanism of the chemical step for the guanosine triphosphate (GTP) hydrolysis catalyzed by elongation factor Tu

Elongation factor Tu (EF-Tu), the protein responsible for delivering aminoacyl-tRNAs (aa-tRNAs) to ribosomal A site during translation, belongs to the group of guanosine-nucleotide (GTP/GDP) binding proteins. Its active 'on'-state corresponds to the GTP-bound form, while the inactive 'off'-state corresponds to the GDP-bound form. In this work we focus on the chemical step, GTP+H(2)O-->GDP+Pi, of the hydrolysis mechanism. We apply molecular modeling tools including molecular dynamics simulations and the combined quantum mechanical-molecular mechanical calculations for estimates of reaction energy profiles for two possible arrangements of switch II regions of EF-Tu. In the first case we presumably mimic binding of the ternary complex EF-Tu.GTP.aa-tRNA to the ribosome and allow the histidine (His85) side chain of the protein to approach the reaction active site. In the second case, corresponding to the GTP hydrolysis by EF-Tu alone, the side chain of His85 stays away from the active site, and the chemical reaction GTP+H(2)O-->GDP+Pi proceeds without participation of the histidine but through water molecules. In agreement with the experimental observations which distinguish rate constants for the fast chemical reaction in EF-Tu.GTP.aa-tRNA.ribosome and the slow spontaneous GTP hydrolysis in EF-Tu, we show that the activation energy barrier for the first scenario is considerably lower compared to that of the second case.

Different aa-tRNAs are selected uniformly on the ribosome

Ten E. coli aminoacyl-tRNAs (aa-tRNAs) were assessed for their ability to decode cognate codons on E. coli ribosomes by using three assays that evaluate the key steps in the decoding pathway. Despite a wide variety of structural features, each aa-tRNA exhibited similar kinetic and thermodynamic properties in each assay. This surprising kinetic and thermodynamic uniformity is likely to reflect the importance of ribosome conformational changes in defining the rates and affinities of the decoding process as well as the evolutionary "tuning" of each aa-tRNA sequence to modify their individual interactions with the ribosome at each step.

Bacterial elongation factors EF-Tu, their mutants, chimeric forms, and domains: isolation and purification

Prokaryotic elongation factors EF-Tu form a family of homologous, three-domain molecular switches catalyzing the binding of aminoacyl-tRNAs to ribosomes during the process of mRNA translation. They are GTP-binding proteins, or GTPases. Binding of GTP or GDP regulates their conformation and thus their activity. Because of their particular structure and regulation, various activities (also outside of the translation system) and a relative abundance they represent attractive tools for studies of many basic but still not fully understood mechanisms both of the translation process, the structure-function relationships in EF-Tu molecules themselves and proteins and energy transduction mechanisms in general. The review critically summarizes procedures for the isolation and purification of native and engineered eubacterial elongation factors EF-Tu and their mutants on a large as well as small scale. Current protocols for the purification of both native and polyHis-tagged or glutathione-S-transferase (GST)-tagged EF-Tu proteins and their variants using conventional procedures and the Ni-NTA-Agarose or Glutathione Sepharose are presented.

Elongation factor Tu-targeted antibiotics: four different structures, two mechanisms of action

Elongation factor Tu (EF-Tu), the carrier of aa-tRNA to the mRNA-programmed ribosome, is the target of four families of antibiotics of unrelated structure, of which the action is supported by two basic mechanisms. Kirromycin and enacyloxin block EF-Tu.GDP on the ribosome; pulvomycin and GE2270 A inhibit the interaction of EF-Tu.GTP with aa-tRNA. The crystallographic analysis has unveiled the structural background of their actions, explaining how antibiotics of unrelated structures and binding modes and sites can employ similar mechanism of action. The selective similarities and differences of their binding sites and the induced EF-Tu conformations make understand how nature can affect the activities of a complex regulatory enzyme by means of low-molecular compounds, and have proposed a suitable approach for drug design.

Structural Basis of the Action of Pulvomycin and GE2270 A on Elongation Factor Tu,

Pulvomycin inhibits protein synthesis by preventing the formation of the ternary complex between elongation factor Tu (EF-Tu) x GTP and aa-tRNA. In this work, the crystal structure of Thermus thermophilus EF-Tu x pulvomycin in complex with the GTP analogue guanylyl imino diphosphate (GDPNP) at 1.4 A resolution reveals an antibiotic binding site extending from the domain 1-3 interface to domain 2, overlapping the domain 1-2-3 junction. Pulvomycin binding interferes with the binding of the 3'-aminoacyl group, the acceptor stem, and 5' end of tRNA. Only part of pulvomycin overlaps the binding site of GE2270 A, a domain 2-bound antibiotic of a structure unrelated to pulvomycin, which also hinders aa-tRNA binding. The structure of the T. thermophilus EF-Tu x GDPNP x GE2270 A complex at 1.6 A resolution shows that GE2270 A interferes with the binding of the 3'-aminoacyl group and part of the acceptor stem of aa-tRNA but not with the 5' end. Both compounds, pulvomycin more markedly, hinder the correct positioning of domain 1 over domains 2 and 3 that characterizes the active form of EF-Tu, while they affect the domain 1 switch regions that control the EF-Tu x GDP/GTP transitions in different ways. This work reveals how two antibiotics with different structures and binding modes can employ a similar mechanism of action.

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.

Essential role of histidine 84 in elongation factor Tu for the chemical step of GTP hydrolysis on the ribosome

Elongation factor Tu (EF-Tu) is a GTP-binding protein that delivers aminoacyl-tRNA to the A site of the ribosome during protein synthesis. The mechanism of GTP hydrolysis in EF-Tu on the ribosome is poorly understood. It is known that mutations of a conserved histidine residue in the switch II region of the factor, His84 in Escherichia coli EF-Tu, impair GTP hydrolysis. However, the partial reaction which is directly affected by mutations of His84 was not identified and the effect on GTP hydrolysis was not quantified. Here, we show that the replacement of His84 with Ala reduces the rate constant of GTP hydrolysis more than 10(6)-fold, whereas the preceding steps of ternary complex binding to the ribosome, codon recognition and, most importantly, the GTPase activation step are affected only slightly. These results show that His84 plays a key role in the chemical step of GTP hydrolysis. Rate constants of GTP hydrolysis by wild-type EF-Tu, measured using the slowly hydrolyzable GTP analog, GTPgammaS, showed no dependence on pH, indicating that His84 does not act as a general base. We propose that the catalytic role of His84 is to stabilize the transition state of GTP hydrolysis by hydrogen bonding to the attacking water molecule or, possibly, the gamma-phosphate group of GTP.

Mechanisms of EF-Tu, a pioneer GTPase

This review considers several aspects of the function of EF-Tu, a protein that has greatly contributed to the advancement of our knowledge of both protein biosynthesis and GTP-binding proteins in general. A number of topics are described with emphasis on the function-structure relationships, in particular of EF-Tu's domains, the nucleotide-binding site, and the magnesium-binding network. Aspects related to the interaction with macromolecular ligands and antibiotics and to folding and GTPase activity are also presented and discussed. Comments and criticism are offered to draw attention to remaining discrepancies and problems.

Mutation of Thr445 and Ile500 of initiation factor 2 G-domain affects Escherichia coli growth rate at low temperature

The Escherichia coli protein synthesis initiation factor IF2 is a member of the large family of G-proteins. Along with translational elongation factors EF-Tu and EF-G and translational release factor RF-3, IF2 belongs to the subgroup of G-proteins that are part of the prokaryotic translational apparatus. The roles of IF2 and EF-Tu are similar: both promote binding of an aminoacyl-tRNA to the ribosome and hydrolyze GTP. In order to investigate the differences and similarities between EF-Tu and IF2 we have created point mutations in the G-domain of IF2, Thr445 to Cys, Ile500 to Cys, and the double mutation. Threonine 445 (X1), which corresponds to cysteine 81 in EF-Tu, is well conserved in the DX1X2GH consensus sequence that has been proposed to interact with GTP. The NKXD motif, in which X is isoleucine 500 in IF2, corresponds to cysteine 137 in EF-Tu, and is responsible for the binding of the guanine ring. The recombinant mutant proteins were expressed and tested in vivo for their ability to sustain growth of an Escherichia coli strain lacking the chromosomal copy of the infB gene coding for IF2. All mutated proteins resulted in cell viability when grown at 42 degrees C or 37 degrees C. However, Thr445 to Cys mutant showed a significant decrease in the growth rate at 25 degrees C. The mutant proteins were overexpressed and purified. As observed in vivo, a reduced activity at low temperature was measured when carrying out in vitro ribosome dependent GTPase and stimulation of ribosomal fMet-tRNAfMet binding.

Mutagenesis of three residues, isoleucine-60, threonine-61, and aspartic acid-80, implicated in the GTPase activity of Escherichia coli elongation factor Tu

The properties of variants of elongation factor (EF) Tu mutated at three positions implicated in its GTPase activity are presented. Mutation I60A, which reduces one wing of a "hydrophobic barrier" screening off the nucleophilic water molecule found at the GTP gamma-phosphate, causes a reduction of the intrinsic GTPase activity contrary to prediction and has practically no influence on other properties. Mutation D80N, which in the isolated G-domain of EF-Tu caused a strong stimulation of the intrinsic GTPase, reduces this activity in the intact molecule. However, whereas for wild-type EF-Tu complex formation with aa-tRNA reduces the GTPase, EF-Tu[D80N] shows a strongly increased activity when bound to Phe-tRNA. Moreover, ribosomes or kirromycin can stimulate its GTPase up to the same level as for wild-type. This indicates that a local destabilization of the magnesium binding network does not per se cause an increased GTPase but does affect its tight regulation. Interestingly, mutant D80N sequestrates EF-Ts by formation of a more stable complex. Substitutions T61A and T61N induce low intrinsic GTPase, and the stimulation by ribosome is less for T61A than for T61N but still detectable, while kirromycin stimulates the GTPase of both mutants equally. This provides more evidence that stimulation by kirromycin and ribosomes follows a different mechanism. The functional implications of these mutations are discussed in the context of a transition state mechanism for catalysis. An alternative structural explanation for the strong conservation of Ile-60 is proposed.

In vitro study of two dominant inhibitory GTPase mutants of Escherichia coli translation initiation factor IF2. Direct evidence that GTP hydrolysis is necessary for factor recycling

We have recently shown that the Escherichia coli initiation factor 2 (IF2) G-domain mutants V400G and H448E do not support cell survival and have a strong negative effect on growth even in the presence of wild-type IF2. We have isolated both mutant proteins and performed an in vitro study of their main functions. The affinity of both mutant proteins for GTP is almost unchanged compared with wild-type IF2. However, the uncoupled GTPase activity of the V400G and H448E mutants is severely impaired, the Vmax values being 11- and 40-fold lower, respectively. Both mutant forms promoted fMet-tRNAfMet binding to 70 S ribosomes with similar efficiencies and were as sensitive to competitive inhibition by GDP as wild-type IF2. Formation of the first peptide bond, as measured by the puromycin reaction, was completely inhibited in the presence of the H448E mutant but still significant in the case of the V400G mutant. Sucrose density gradient centrifugation revealed that, in contrast to wild-type IF2, both mutant proteins stay blocked on the ribosome after formation of the 70 S initiation complex. This probably explains their dominant negative effect in vivo. Our results underline the importance of GTP hydrolysis for the recycling of IF2.

The elongation factor 1 A-2 isoform from rabbit: cloning of the cDNA and characterization of the protein

Eukaryotic elongation factor 1 A (eEF1A, formerly elongation factor-1 alpha) is an important component of the protein synthesis apparatus. Here we report the isolation and characterization of the cDNA sequence encoding rabbit eEF1A-2, an isoform of eEF1A, as well as a structural and functional comparison of the two rabbit isoforms. Northern analysis of the expression pattern of eEF1A-2 showed that this isoform is expressed in skeletal muscle, heart, brain and aorta, while transcripts are not detected in liver, kidney, spleen and lung. In contrast, the previously characterized eEF1A-1 isoform is expressed in all tissues examined except skeletal muscle. We have recently purified eEF1A-2 from rabbit skeletal muscle. By partial amino acid sequencing and determination of the post-translational modifications of eEF1A-2 we found that both of the glycerylphosphorylethanolamine modifications observed in eEF1A-1 appear to be present in eEF1A-2. However, two of the residues found dimethylated in eEF1A-1 appeared to be trimethylated in eEF1A-2. A comparison of the enzymatic activity showed that eEF1A-1 and eEF1A-2 have indistinguishable activity in an in vitro translation system. In contrast, the GDP dissociation rate constant is approximately 7 times higher for eEF1A-1 than for eEF1A-2. The nucleotide preference ratio (GDP/GTP) for eEF1A-1 was 0.82, while the preference ratio for eEF1A-2 was 1.50.

Functional role of the noncatalytic domains of elongation factor Tu in the interactions with ligands

Elongation factor (EF) Tu from Escherichia coli contains three domains, of which domain 1 (N-terminal domain) harbors the site for nucleotide binding and GTP hydrolysis. To analyze the function of domains 2 [middle (M) domain] and 3 [C-terminal (C) domain], EF-Tu(DeltaM) and EF-Tu(DeltaC) were engineered as GST-fused products and purified. Circular dichroism and thermostability showed that both constructs have conserved organized structures. Though inactive in poly(Phe) synthesis the two constructs could bind GDP and GTP with comparable micromolar affinities. Therefore, like the isolated N-terminal domain, they had lost a typical feature of EF-Tu, the >100 times stronger affinity for GDP than for GTP. EF-Tu(DeltaM) and EF-Tu(DeltaC) had an intrinsic GTPase activity comparable to that of wild-type EF-Tu. Ribosomes did not stimulate the GTPase activity of either factor, while kirromycin increased the GTPase activity of both constructs, particularly of EF-Tu(DeltaC), to a level, however, much lower than that of the intact molecule. The interaction with aa-tRNA of both mutants was >90% reduced. As a major result, their GDP-bound form could efficiently respond to EF-Ts. All four EF-Tu-specific antibiotics [kirromycin, pulvomycin, GE2270 A (=MDL 62 879), and enacyloxin IIa] retarded significantly the dissociation of EF-Tu(DeltaC).GTP, showing the same kind of effect as on EF-Tu.GTP, but they were little active on EF-Tu(DeltaM). GTP. Like EF-Tu(DeltaC).GTP, EF-Tu(DeltaM).GTP was, however, able to bind efficiently kirromycin and enacyloxin IIa, as determined via competition with EF-Ts. Together, these results enlight selective functions of domains 2 and 3, particularly toward the interaction with EF-Ts and antibiotics, and emphasize their functional cooperativity for an efficient interaction of EF-Tu with ribosomes and aa-tRNA and for maintaining the differential affinity for GTP and GDP.

Elongation in bacterial protein biosynthesis

The past year has brought some notable advances in our understanding of the structure and function of elongation factors (EFs) involved in protein biosynthesis. The structures of the ternary complex of aminoacylated tRNA with EF-Tu.GTP and of the complex EF-Tu.EF-Ts have been determined. Within the same period, new cryo-electron microscopy reconstructions of ribosome particles have been obtained.

Limited proteolysis and amino acid replacements in the effector region of Thermus thermophilus elongation factor Tu

The effector region of the elongation factor Tu (EF-Tu) from Thermus thermophilus was modified by limited proteolysis or via site-directed mutagenesis. The biochemical properties of the obtained EF-Tu variants were investigated with respect to partial reactions of the functional cycle of EF-Tu. EF-Tu that was cleaved at the Arg59-Gly60 peptide bond [EF-Tu-(1-59)/EF-Tu-(60-405)] bound GDP, EF-Ts and aminoacyl-tRNA, had normal intrinsic GTPase activity and was active in poly(U)-dependent poly(Phe) synthesis. However, the GTPase activity of EF-Tu-(1-59)/EF-Tu-(60-405) was not stimulated by T. thermophilus 70S ribosomes, and its GTP-dissociation rate was increased compared with that of intact EF-Tu. EF-Tu cleaved at the Lys52-Ala53 peptide bond has properties similar to EF-Tu-(1-59)/EF-Tu-(60-405). By means of site-directed mutagenesis, Glu55 was replaced by Leu, Glu56 by Ala and Arg59 by Thr in T. thermophilus EF-Tu. These amino acid substitutions did not substantially affect either the affinity of EF-Tu. GTP for aminoacyl-tRNA or the interactions with GDP, GTP or EF-Ts. Similarly the intrinsic GTPase activity is not influenced. Replacement of Glu56 by Ala led to strong reduction in the ribosome-induced GTPase activity. This effect is specific since replacement of the neighbouring Glu55 by Leu did not affect the ribosome-induced GTPase activity. The results demonstrate that the structure of the effector region of EF-Tu in the vicinity of Arg59 is important for the control of the GTPase activity by ribosomes.

Messenger RNA translation in prokaryotes: GTPase centers associated with translational factors

During the decoding of messenger RNA, each step of the translational cycle requires the intervention of protein factors and the hydrolysis of one or more GTP molecule(s). Of the prokaryotic translational factors, IF2, EF-Tu, SELB, EF-G and RF3 are GTP-binding proteins. In this review we summarize the latest findings on the structures and the roles of these GTPases in the translational process.

Site-directed mutagenesis of Thermus thermophilus EF-Tu: the substitution of threonine-62 by serine or alanine

The invariant threonine-62, which occurs in the effector region of all GTP/GDP-binding regulatory proteins, was substituted via site-directed mutagenesis by alanine and serine in the elongation factor Tu from Thermus thermophilus. The altered proteins were overproduced in Escherichia coli, purified and characterized. The EF-Tu T62S variant had similar properties with respect to thermostability, aminoacyl-tRNA binding, GTPase activity and in vitro translation as the wild-type EF-Tu. In contrast, EF-Tu T62A is severely impaired in its ability to sustain polypeptide synthesis and has only very low intrinsic and ribosome-induced GTPase activity. The affinity of aminoacyl-tRNA to the EF-Tu T62A.GTP complex is almost 40 times lower as compared to the native EF-Tu.GTP. These observations are in agreement with the tertiary structure of EF-Tu.GTP, in which threonine-62 is interacting with the Mg2+ ion, gamma-phosphate of GTP and a water molecule, which is presumably involved in the GTP hydrolysis.

Regulatory GTPases

The past year has witnessed a tremendous increase in our understanding of the structures and interactions of the GTPases. The highlights include crystal structures of G alpha subunits, as well as the first complex between a GTPase (Rap1A) and an effector molecule (c-Raf1 Ras-binding domain). In the field of elongation factors (EFs), three very important structures have been determined: EF-G, the ternary complex of EF-Tu.GTP with aminoacyl-tRNA, and the EF-Tu.EF-Ts complex.