Toward a model for the interaction between elongation factor Tu and the ribosome

A new factor from Escherichia coli affects translocation of mRNA

Reconstitution of protein synthesis from purified translation factors on ribosomes from Escherichia coli has revealed the requirement for a protein, W, that affects chain elongation and is essential to reconstitute the process (Ganoza, M. C., Cunningham, C., and Green, R. M. (1985) Proc. Natl. Acad. Sci. U.S.A. 82, 1648-1652). We report that W has no effect on initiation complex formation by 30 or 70 S ribosomes or on the association of ribosomal subunits, peptide bond synthesis, or binding Ala-tRNA, which is the second amino acid of the coat protein of the MS2 RNA virion. W has a pronounced effect on tripeptide synthesis, and is obligatory for the synthesis of the coat protein or of the hexapeptide encoded by f2am3 RNA. Extracts from a temperature-sensitive mutant of the translocase, EF-G, were purified free of the W protein and were used to score for translocation defects. W is required for binding Ser-tRNA, the third N-terminal amino acid of the MS2 or f2 RNA coat protein to ribosomes bearing fMet-Ala-tRNA, as well as for the ejection of deacyl-tRNA from ribosomes, which occurred concomitant with the binding of the Ser-tRNA. We propose that W functions by ejecting tRNAs from ribosomes in a step that precedes the movement of mRNA during translocation.

GTPases: a family of molecular switches and clocks

Members of the GTPase superfamily share a core domain with a conserved three-dimensional structure and a common GTPase cycle, but perform a wide variety of regulatory tasks in eukaryotic cells. Evolution has created functional diversity from the conserved GTPase structure in two principal ways: (i) by combining in the product of a single gene the core GTPase domain attached to one or more additional folded domains; (ii) by building around a core GTPase an assembly of proteins encoded by different genes. Analysis of the patterns of conserved amino acid side chains on surfaces of G alpha proteins reveals interfaces with other proteins in the G-protein signal linking device.

Reciprocal stimulation of GTP hydrolysis by two directly interacting GTPases

The Escherichia coli guanosine triphosphate (GTP)-binding proteins Ffh and FtsY have been proposed to catalyze the cotranslational targeting of proteins to the bacterial plasma membrane. A mutation was introduced into the GTP-binding domain of FtsY that altered its nucleotide specificity from GTP to xanthosine triphosphate (XTP). The mutant FtsY protein stimulated GTP hydrolysis by a ribonucleoprotein consisting of Ffh and 4.5S RNA in a reaction that required XTP, and it hydrolyzed XTP in a reaction that required both the Ffh-4.5S ribonucleoprotein and GTP. Thus, nucleotide triphosphate hydrolysis by Ffh and FtsY is likely to occur in reciprocally coupled reactions in which the two interacting guanosine triphosphatases act as regulatory proteins for each other.

The elongation factor 3 unique in higher fungi and essential for protein biosynthesis is an E site factor

Two elongation factors drive the ribosomal elongation cycle; elongation factor 1 alpha (EF-1 alpha) mediates the binding of an aminoacyl-tRNA to the ribosomal A site, whereas elongation factor 2 (EF-2) catalyzes the translocation reaction. Ribosomes from yeast and other higher fungi require a third elongation factor (EF-3) which is essential for the elongation process, but the step affected by EF-3 has not yet been identified. Here we demonstrate that the first and the third tRNA binding site (A and E sites, respectively) of yeast ribosomes are reciprocally linked; if the A site is occupied the E site has lost its binding capability, and vice versa, if the E site is occupied the A site has a low affinity for tRNAs. EF-3 is essential for EF-1 alpha-dependent A site binding of amino-acyl-tRNA only when the E site is occupied with a deacylated tRNA. The ATP-dependent activity of EF-3 is required for the release of deacylated tRNA from the E site during A site occupation.

Requirement of nucleotide exchange factor for Ypt1 GTPase mediated protein transport

Small GTPases of the rab family are involved in the regulation of vesicular transport. It is believed that cycling between the GTP- and GDP-bound forms, and accessory factors regulating this cycling are crucial for rab function. However, an essential role for rab nucleotide exchange factors has not yet been demonstrated. In this report we show the requirement of nucleotide exchange factor activity for Ypt1 GTPase mediated protein transport. The Ypt1 protein, a member of the rab family, plays a role in targeting vesicles to the acceptor compartment and is essential for the first two steps of the yeast secretory pathway. We use two YPT1 dominant mutations that contain alterations in a highly conserved GTP-binding domain, N121I and D124N. YPT1-D124N is a novel mutation that encodes a protein with nucleotide specificity modified from guanine to xanthine. This provides a tool for the study of an individual rab GTPase in crude extracts: a xanthosine triphosphate (XTP)-dependent conditional dominant mutation. Both mutations confer growth inhibition and a block in protein secretion when expressed in vivo. The purified mutant proteins do not bind either GDP or GTP. Moreover, they completely inhibit the ability of the exchange factor to stimulate nucleotide exchange for wild type Ypt1 protein, and are potent inhibitors of ER to Golgi transport in vitro at the vesicle targeting step. The inhibitory effects of the Ypt1-D124N mutant protein on both nucleotide exchange activity and protein transport in vitro can be relieved by XTP, indicating that it is the nucleotide-free form of the mutant protein that is inhibitory. These results suggest that the dominant mutant proteins inhibit protein transport by sequestering the exchange factor from the wild type Ypt1 protein, and that this factor has an essential role in vesicular transport.

Ribosomal decoding processes at codons in the A or P sites depend differently on 2'-OH groups

The importance of 2'-OH groups of codons for binding of cognate tRNAs to ribosomal P and A sites was analyzed applying the following strategy. An mRNA of 41 nucleotides was synthesized with the structure C16-GAA-UUC-GUC-C16 coding for glutamic acid (E), phenylalanine (F) and valine (V), respectively, in the middle (EFV-mRNA). A second template, the E(dF)V-mRNA, was identical except that it carried a deoxyribo-codon-dUdUdC- for phenylalanine. tRNA binding to the P site is totally insensitive to the presence or absence of the 2'-OH group of the P-site codon, and tRNA binding to the P site is also not affected if the A-site codon lacks the 2'-OH groups. However, binding is impaired if the deoxy-codon is present at the E site. In sharp contrast, the A-site binding of Ac-aminoacyl-tRNA was severely reduced in the presence of the deoxy-codon at the A site as well as at the P site. The results demonstrate that the correctness of base pairing is also "sensed" via a correct sugar structure of the codon, e.g. positioning of the sugar pucker (2'-OH), during the decoding process at the A site (elongation) but not during the decoding at the P site (initiation).

Phosphorylation of elongation factor Tu prevents ternary complex formation

The elongation factor Tu (EF-Tu) is a member of the GTP/GDP-binding proteins and interacts with various partners during the elongation cycle of protein biosynthesis thereby mediating the correct binding of amino-acylated transfer RNA (aa-tRNA) to the acceptor site (A-site) of the ribosome. After GTP hydrolysis EF-Tu is released in its GDP-bound state. In vivo, EF-Tu is post-translationally modified by phosphorylation. Here we report that the phosphorylation of EF-Tu by a ribosome associated kinase activity is drastically enhanced by EF-Ts. The antibiotic kirromycin, known to block EF-Tu function, inhibits the modification. This effect is specific, since kirromycin-resistant mutants do become phosphorylated in the presence of the antibiotic. On the other hand, phosphorylated wild-type EF-Tu does not bind kirromycin. Most interestingly, the phosphorylation of EF-Tu abolishes its ability to bind aa-tRNA. In the GTP conformation the site of modification is located at the interface between domains 1 and 3 and is involved in a strong interdomain hydrogen bond. Introduction of a charged phosphate group at this position will change the interaction between the domains, leading to an opening of the molecule reminiscent of the GDP conformation. A model for the function of EF-Tu phosphorylation in protein biosynthesis is presented.

Switching nucleotide specificity of Ha-Ras p21 by a single amino acid substitution at aspartate 119

We examined c-Ha-Ras harboring an aspartate to asparagine substitution at position 119 (mutation D119N). The Asp-119 is part of the conserved NKXD motif shared by members of the regulatory GTPase family. This asparagine residue has been proposed to participate in direct bonding to the guanine ring and to determine the guanine-nucleotide binding specificity. The D119N mutation was found to alter nucleotide specificity of Ha-Ras from guanine to xanthine, an observation that directly supports the essential role of hydrogen bonding between the side chain of the aspartic acid residue and the guanine ring in nucleotide binding specificity. Besides nucleotide binding specificity, the D119N mutation has little or no effect on the interaction of Ha-Ras with SDC25C, SOS1, GAP, or Raf. Neither does it affect the hydrolysis of nucleotide triphosphate. Like xanthine-nucleotide-specific EF-Tu, xanthine-nucleotide-specific Ras and related proteins will be useful tools for elucidating cellular systems containing multiple regulatory GTPases.

GTP consumption of elongation factor Tu during translation of heteropolymeric mRNAs

The stoichiometry of elongation factor Tu (EF-Tu) and GTP in the complex with aminoacyl-tRNA and the consumption of GTP during peptide bond formation on the ribosome were studied in the Escherichia coli system. The ribosomes were programmed either with two different heteropolymeric mRNAs coding for Met-Phe-Thr-Ile ... (mMFTI) or Met-Phe-Phe-Gly ... (mMFFG) or with poly(U). The composition of the complex of EF-Tu, GTP, and Phe-tRNA(Phe) was studied by gel chromatography. With equimolar amounts of factor and Phe-tRNA(Phe), a pentameric complex, (EF-Tu.GTP)2.Phe-tRNA(Phe), was observed, whereas the classical ternary complex, EF-Tu.GTP.Phe-tRNA(Phe), was found only when Phe-tRNA(Phe) was in excess. Upon binding of the purified pentameric complex to ribosomes carrying fMet-tRNA(fMet) in the peptidyl site and exposing a Phe codon in the aminoacyl site, only one out of two GTPs of the pentameric complex was hydrolyzed per Phe-tRNA bound and peptide bond formed, regardless of the mRNA used. In the presence of EF-G, the stoichiometry of one GTP hydrolyzed per peptide bond formed was found on mMFTI when one or two elongation cycles were completed. In contrast, on mMFFG, which contains two contiguous Phe codons, UUU-UUC, two GTP molecules of the pentameric complex were hydrolyzed per Phe incorporated into dipeptide, whereas the incorporation of the second Phe to form tripeptide consumed only one GTP. Thus, generally one GTP is hydrolyzed by EF-Tu per aminoacyl-tRNA bound and peptide bond formed, and more than one GTP is hydrolyzed only when a particular mRNA sequence, such as a homopolymeric stretch, is translated. The role of the additional GTP hydrolysis is not known; it may be related to frameshifting of peptidyl-tRNA during translocation.

Stoichiometry of the EF-Tu.GTP complex with aminoacyl-tRNA: ternary of quinternary?

The stoichiometry of the complex formed between the Escherichia coli polypeptide elongation factor EF-Tu, GTP and valyl-tRNA(val) has been determined by non-enzymatic deacylation studies on mixtures of the components at well-defined concentrations. A titration end-point was found corresponding to a 1:1 complex of EF-Tu.GTP with the aminoacylated-tRNA i.e. formation of a ternary complex. The result conforms to the classical model of the elongation step and not to the revolutionary proposition of the formation of a 2:2:1 complex; quinternary complex (EF-Tu.GTP)2.aa-RNA.

Two GTPs are consumed on EF-Tu per peptide bond in poly(Phe) synthesis, in spite of switching stoichiometry of the EF-Tu.aminoacyl-tRNA complex with temperature

Recent observations indicate that the stoichiometry for the complex between EF-Tu.GTP and aminoacyl-tRNA (aa-tRNA) changes with temperature. At 37 degrees C two EF-Tu.GTPs bind one aa-tRNA in an extended ternary complex, but at 0 degrees C the complex has 1:1 stoichiometry. However, the present experiments show that there are two GTPs hydrolyzed on EF-Tu per peptide bond in poly(Phe) synthesis at 37 degrees C as well as at 0 degrees C. This indicates two different pathways for the enzymatic binding of aa-tRNA to the A-site on the ribosome.

Special peptidyl-tRNA molecules can promote translational frameshifting without slippage

Recently we described an unusual programmed +1 frameshift event in yeast retrotransposon Ty3. Frameshifting depends on the presence of peptidyl-tRNA(AlaCGC) on the GCG codon in the ribosomal P site and on a translational pause stimulated by the slowly decoded AGU codon. Frameshifting occurs on the sequence GCG-AGU-U by out-of-frame binding of a valyl-tRNA to GUU without slippage of peptidyl-tRNA(AlaCGC). This mechanism challenges the conventional understanding that frameshift efficiency must correlate with the ability of mRNA-bound tRNA to slip between cognate or near-cognate codons. Though frameshifting does not require slippery tRNAs, it does require special peptidyl-tRNAs. We show that overproducing a second isoacceptor whose anticodon had been changed to CGC eliminated frameshifting; peptidyl-tRNA(AlaCGC) must have a special capacity to induce +1 frameshifting in the adjacent ribosomal A site. In order to identify other special peptidyl-tRNAs, we tested the ability of each of the other 63 codons to replace GCG in the P site. We found no correlation between the ability to stimulate +1 frameshifting and the ability of the cognate tRNA to slip on the mRNA--several codons predicted to slip efficiently do not stimulate frameshifting, while several predicted not to slip do stimulate frameshifting. By inducing a severe translational pause, we identified eight tRNAs capable of inducing measurable +1 frameshifting, only four of which are predicted to slip on the mRNA. We conclude that in Saccharomyces cerevisiae, special peptidyl-tRNAs can induce frameshifting dependent on some characteristic(s) other than the ability to slip on the mRNA.

Purification and crystallization of the ternary complex of elongation factor Tu:GTP and Phe-tRNA(Phe)

Elongation factor Tu (EF-Tu) is the most abundant protein in prokaryotic cells. Its general function in protein biosynthesis is well established. It is a member of the large family of G-proteins, all of which bind guanosine phosphates (GDP or GTP) as cofactors. In its active GTP bound state EF-Tu binds aminoacylated tRNA (aa-tRNA) forming the ternary complex EF-Tu:GTP:aa-tRNA. The ternary complex interacts with the ribosome where the anticodon on tRNA recognises a codon on mRNA, GTPase activity is induced and inactive EF-Tu:GDP is released. Here we report the successful crystallization of a ternary complex of Thermus aquaticus EF-Tu:GDPNP and yeast Phe-tRNA(Phe) after its purification by HPLC.

Special peptidyl-tRNA molecules can promote translational frameshifting without slippage

Recently we described an unusual programmed +1 frameshift event in yeast retrotransposon Ty3. Frameshifting depends on the presence of peptidyl-tRNA(AlaCGC) on the GCG codon in the ribosomal P site and on a translational pause stimulated by the slowly decoded AGU codon. Frameshifting occurs on the sequence GCG-AGU-U by out-of-frame binding of a valyl-tRNA to GUU without slippage of peptidyl-tRNA(AlaCGC). This mechanism challenges the conventional understanding that frameshift efficiency must correlate with the ability of mRNA-bound tRNA to slip between cognate or near-cognate codons. Though frameshifting does not require slippery tRNAs, it does require special peptidyl-tRNAs. We show that overproducing a second isoacceptor whose anticodon had been changed to CGC eliminated frameshifting; peptidyl-tRNA(AlaCGC) must have a special capacity to induce +1 frameshifting in the adjacent ribosomal A site. In order to identify other special peptidyl-tRNAs, we tested the ability of each of the other 63 codons to replace GCG in the P site. We found no correlation between the ability to stimulate +1 frameshifting and the ability of the cognate tRNA to slip on the mRNA--several codons predicted to slip efficiently do not stimulate frameshifting, while several predicted not to slip do stimulate frameshifting. By inducing a severe translational pause, we identified eight tRNAs capable of inducing measurable +1 frameshifting, only four of which are predicted to slip on the mRNA. We conclude that in Saccharomyces cerevisiae, special peptidyl-tRNAs can induce frameshifting dependent on some characteristic(s) other than the ability to slip on the mRNA.

Energy cost of translational proofreading in vivo. The aminoacylation of transfer RNA in Escherichia coli

In many cases, the intrinsic binding energies of amino acids to aminoacyl-tRNA synthetases are inadequate to give the required accuracy of translation. This has necessitated the evolution of a second determinant of specificity, proofreading, or editing mechanisms that involve the expenditure of energy to remove errors. Studies of an error-editing function of bacterial methionyl-tRNA synthetase have led to the discovery of a distinct chemical mechanism of editing and to molecular dissection of the dual synthetic-editing function of the active site of the synthetase. Studies have also established the importance of proofreading in living cells and allowed direct measurements of energy costs associated with editing in vivo. An unexpected outcome of these studies was a discovery of functional and structural similarities between methionyl-tRNA synthetase and S-adenosylmethionine synthetase, suggesting an evolutionary relationship between the two proteins. The mechanism of editing involves a nucleophilic attack of a sulfur atom on the side chain of homocysteine in homocysteinyl adenylate on its carbonyl carbon, yielding homocysteine thiolactone. The model of the active site of methionyl-tRNA synthetase derived from structure-function studies explains how the active site partitions amino acids between synthetic and editing pathways. Hydrophobic and hydrogen bonding interactions of active site residues Trp305 and Tyr15 with the side chain of methionine prevent the cognate amino acid from entering the editing pathway. These interactions are missing in the case of the smaller side chain of the noncognate homocysteine, which therefore enters the editing pathway. Homocysteine thiolactone is formed as a result of editing of homocysteine by methionyl-tRNA synthetase in bacteria, yeast, and some cultured mammalian cells. In mammalian cells, enhanced synthesis of homocysteine thiolactone, is, thus far, associated with oncogenic transformation. In E. coli, most of the energy cost of proofreading by methionyl-tRNA synthetase is due to editing of the incorrect product, homocysteinyl adenylate.

Comparative analysis of ribosome-associated adenosinetriphosphatase (ATPase) from pig liver and the ATPase of elongation factor 3 from Saccharomyces cerevisiae

Elongation factor 3 (EF-3) is a unique and essential requirement of the fungal translational machinery. Non-fungal organisms do not have and do not require a soluble form of the third elongation factor for translation. To test whether non-fungal organisms have a direct analog of EF-3 incorporated in the structure of the ribosomes, a comparison of EF-3 adenosinetriphosphatase (ATPase) with ATPases associated with pig liver ribosomes was carried out. EF-3 function depends on ATP (GTP) hydrolysis. The hydrolytic activity of EF-3 is enhanced by two orders of magnitude by yeast ribosomes due to an increase in the turnover rate of EF-3. The nucleotide hydrolytic activity of EF-3 is significantly constrained by the binding of aminoacylated tRNA(Phe) to poly(U)-programmed ribosomes. The translational inhibitors--neomycin and alpha-sarcin suppress the ATPase activity of EF-3. These results reflect a direct correlation between EF-3 ATPase and the functional state of the ribosome. Four lines of evidence indicate that yeast EF-3 ATPase is functionally distinct from pig liver ribosome associated ATPases. The kinetic parameters of ATPases from these two sources are different. Poly(U) and tRNA have no effect on the ATPase activity associated with the pig liver ribosomes. The latter activity is unaffected by the translational inhibitors neomycin and alpha-sarcin. The translational activity of pig liver ribosomes is not influenced by ATP, ADP or adenosine 5'-[beta, gamma-imido]triphosphate. In an in vitro system, one can demonstrate a small but consistent stimulatory effect of yeast EF-3 on polyphenylalanine synthesis by pig liver ribosomes only when EF-1 alpha is present at a limited concentration. The EF-3 effect disappears when EF-1 alpha is added in a stoichiometric amount to the pig liver ribosomes. This result is in contrast to the yeast system where the ribosomes are completely dependent on EF-3 at all concentrations of EF-1 alpha.

Why does Escherichia coli have two primary pathways for synthesis of glutamate?

Escherichia coli has two primary pathways for glutamate synthetase-glutamate synthase pathway is known to be essential for synthesis at low ammonium concentrations and for regulation of the glutamine pool, but the necessity for glutamate dehydrogenase (GDH) has been uncertain. The results of competition experiments between the wild type and a GDH-deficient mutant during nutrient-limited growth and of direct enzyme measurements suggest that GDH is used in glutamate synthesis when the cell is limited for energy (and carbon) but ammonium and phosphate are present in excess, while the glutamine synthetase-glutamate synthase pathway is used when the cell is not under energy limitation. The use of alternative routes for glutamate synthesis implies that the energy cost of biosynthesis may be less when energy is limited than when energy is unlimited.

Elongation factor Tu: a regulatory GTPase with an integrated effector

Several elongation factors involved in protein synthesis are GTPases that share structural and mechanistic homology with the large family of proteins including Ras and heterotrimeric receptor-coupled G proteins. The structure of elongation factor Tu (EF-Tu) from thermophilic bacteria, in its 'active' GTP-bound form, has recently been solved by X-ray crystallography. Comparison of this structure with the structure of Escherichia coli EF-Tu bound to GDP reveals a dramatic conformational change that is dependent on GTPase activity. The mechanism of this conformational change and of GTPase activation are discussed, and a model for the EF-Tu-GTP complex with aminoacyl-tRNA is presented.

Effector region of the translation elongation factor EF-Tu.GTP complex stabilizes an orthoester acid intermediate structure of aminoacyl-tRNA in a ternary complex

tRNA(Val) from Escherichia coli was aminoacylated with [1-13C]valine and its complex with Thermus thermophilus elongation factor EF-Tu.GTP was analyzed by 13C NMR spectroscopy. The results suggest that the aminoacyl residue of the valyl-tRNA in ternary complex with bacterial EF-Tu and GTP is not attached to tRNA by a regular ester bond to either a 2'- or 3'-hydroxyl group; instead, an intermediate orthoester acid structure with covalent linkage to both vicinal hydroxyls of the terminal adenosine-76 is formed. Mutation of arginine-59 located in the effector region of EF-Tu, a conserved residue in protein elongation factors and the alpha subunits of heterotrimeric guanine nucleotide-binding regulatory proteins (G proteins), abolishes the stabilization of the orthoester acid structure of aminoacyl-tRNA.

Peptide-chain elongation in eukaryotes

The elongation phase of translation leads to the decoding of the mRNA and the synthesis of the corresponding polypeptide chain. In most eukaryotes, two distinct protein elongation factors (eEF-1 and eEF-2) are required for elongation. Each is active as a complex with GTP. eEF-1 is a multimer and mediates the binding of the cognate aminoacyl-tRNA to the ribosome, while eEF-2, a monomer, catalyses the movement of the ribosome relative to the mRNA. Recent work showing that bacterial ribosomes possess three sites for tRNA binding and that during elongation tRNAs may occupy 'hybrid' sites is incorporated into a model of eukaryotic elongation. In fungi, elongation also requires a third factor, eEF-3. A number of mechanisms exist to promote the accuracy or 'fidelity' of elongation: eEF-3 may play a role here. cDNAs for this and the other elongation factors have been cloned and sequenced, and the structural and functional properties of the elongation factors are discussed. eEF-1 and eEF-2 can be regulated by phosphorylation, and this may serve to control rates of elongation in vivo.

Why do two EF-Tu molecules act in the elongation cycle of protein biosynthesis?

In the elongation cycle of bacterial protein biosynthesis, the binding of aminoacyl-tRNA (aa-tRNA) to the A-site of mRNA-programmed ribosomes is mediated by elongation factor Tu (EF-Tu) and associated with the hydrolysis of GTP. Recently, in the case of cognate aa-tRNA, the participation of two GTP molecules has been implicated in this reaction. These are likely to be involved in preventing the indiscriminate binding of aa-tRNA to the ribosomal A-site. This article integrates this unexpected finding with our current knowledge of the structure-function relationships of the macro-molecules involved in the elongation cycle.

Selective perturbation of G530 of 16 S rRNA by translational miscoding agents and a streptomycin-dependence mutation in protein S12

Previous studies have shown that a concise set of universally conserved bases in 16 S rRNA are strongly protected from attack by chemical probes when tRNA is bound specifically to the ribosomal A site. Two of these bases, A1492 and A1493, are located in the cleft of the 30 S subunit, the site of codon-anticodon interaction. A third residue, G530, is located within the highly conserved 530 stem-loop, a region that is involved in interactions with proteins S4 and S12, mutations in which perturb the translational error frequency. The 530 loop is also thought to be located at or near the site of interaction of elongation factor Tu on the 30 S subunit, a location that is distinct from the decoding site. This study monitors the response of these two A-site-related regions of 16 S rRNA to a variety of translational miscoding agents. Several of these agents, including streptomycin, neomycin and ethanol, selectively potentiate tRNA-dependent protection of residue G530 from kethoxal modification; in contrast, little change in reactivity of residues A1492 and A1493 is observed. These results are consistent with the previously demonstrated importance of G530 for A-site function and, moreover, suggest a common mechanism of action for these miscoding agents, even though they appear to have distinctly different modes of interaction with 16 S rRNA. In contrast to the miscoding agents, we find that a streptomycin-dependence (SmD) mutation in protein S12, which causes ribosomes to be hyperaccurate, antagonizes tRNA-dependent protection of G530. The possibility that 5' or 3' flanking regions of mRNA could be involved in tRNA-dependent protection of G530 was tested by using different lengths of oligo(U) to promote binding of tRNA(Phe) to the A site. The relative levels of protection of G530, A1492 and A1493 were unchanged as the size of the mRNA fragment was decreased from 16 to 6 bases in length. We conclude, therefore, that for protection of G530 to be the result of direct contact with message, it must necessarily be located directly at the decoding site; otherwise, its protection is best explained by allosteric interactions, either with mRNA, or with the codon-anticodon complex. These results are discussed in terms of a model wherein the conformation of the 530 loop is correlated with the affinity of the ribosome for elongation factor Tu.

Two GTPs are hydrolysed on two molecules of EF-Tu for each elongation cycle during code translation

A new experimental design has been used to determine the number of GTPs hydrolysed per peptide bond in EF-Tu function in a poly(U)-translation system. We find that two GTPs are consumed for every amino acid incorporated into the nascent poly(Phe)-chains, in accordance with previous findings with other techniques. These results necessitate a revision of current views concerning E coli translation; also new schemes for ribosome function are discussed.

Asparagine-135 of elongation factor Tu is a crucial residue for the folding of the guanine nucleotide binding pocket

This work studies the structure-function relationships of Asn135, a residue situated in the GTP binding pocket of elongation factor Tu (EF-Tu). For this purpose we constructed EF-TuN135D/D138N and assayed its reactivity towards various purine nucleotides. We found that EF-TuN135D/D138N had no functional effect with GTP, ATP, XTP and isoGTP. The lack of a productive interaction with isoGTP shows that the Asn135 side-chain does not recognize the exocyclic keto group of the guanine base. However, EF-TuN135D/D138N, whose native conformation is stabilized by either elongation factor Ts or kirromycin, was able to support the enzymatic binding of aa-tRNA to the ribosome in the absence of any nucleotide, when in complex with the antibiotic. Taken together, these results show that Asn135 is important for the correct folding of the nucleotide binding site and that EF-Tu.kirromycin can mediate the binding of aa-tRNA to the mRNA-programmed ribosomes independently of the native conformation of this site.

The crystal structure of elongation factor EF-Tu from Thermus aquaticus in the GTP conformation

BACKGROUND

Elongation factor Tu (EF-Tu) is a GTP-binding protein that is crucial for protein biosynthesis. In the GTP form of the molecule, EF-Tu binds tightly to aminoacyl-tRNA, forming a ternary complex that interacts with the ribosomal acceptor site. During this interaction, GTP is hydrolyzed, and EF-Tu.GDP is ejected.

RESULTS

The crystal structure of EF-Tu from Thermus aquaticus, complexed to the GTP analogue GDPNP, has been determined at 2.5 A resolution and compared to the structure of Escherichia coli EF-Tu.GDP. During the transition from the GDP (inactive) to the GTP (active) form, domain 1, containing the GTP-binding site, undergoes internal conformational changes similar to those observed in ras-p21. In addition, a dramatic rearrangement of domains is observed, corresponding to a rotation of 90.8 degrees of domain 1 relative to domains 2 and 3. Residues that are affected in the binding of aminoacyl-tRNA are found in or near the cleft formed by the domain interface.

CONCLUSION

GTP binding by EF-Tu leads to dramatic conformational changes which expose the tRNA binding site. It appears that tRNA binding to EF-Tu induces a further conformational change, which may affect the GTPase activity.

Solution of the ribosome riddle: how the ribosome selects the correct aminoacyl-tRNA out of 41 similar contestants

Three tRNA binding sites, the A, P and E sites, have been demonstrated on ribosomes of bacterial, archaebacterial and eukaryotic origin. In all these cases the first and the third site, the A and the E site, are allosterically coupled in the sense of a negative co-operativity. Therefore, the allosteric three-site model seems to be a generally valid description of the ribosomal elongation phase, where in a cycle of reactions the nascent peptide chain is prolonged by one amino acid. The molecular concept of the allosteric three-site model explains the astonishing ability of the ribosome to select the correct substrate out of a large number of very similar substrates, and it provides a framework within which the mechanisms of the elongation factors could be understood.

Elongation factors in protein synthesis

Recent discoveries of elongation factor-related proteins have considerably complicated the simple textbook scheme of the peptide chain elongation cycle. During growth and differentiation the cycle may be regulated not only by factor modification but also factor replacement. In addition, rare tRNAs may have their own rare factor proteins. A special case is the acquisition of resistance by bacteria to elongation factor-directed antibiotics. Pertinent data from the literature and our own work with Escherichia coli and Streptomyces are discussed. The GTP-binding domain of EF-Tu has been studied extensively, but little molecular detail is available on the interactions with its other ligands or effectors, or on the way they are affected by the GTPase switch signal. A growing number of EF-Tu mutants obtained by ourselves and others are helping us in testing current ideas. We have found a synergistic effect between EF-Tu and EF-G in their uncoupled GTPase reactions on empty ribosomes. Only the EF-G reaction is perturbed by fluoroaluminates.

Ternary complex between elongation factor Tu.GTP and Phe-tRNA(Phe)

The effect of aminoacylation and ternary complex formation with elongation factor Tu.GTP on the tertiary structure of yeast tRNA(Phe) was examined by 1H-NMR spectroscopy. Esterification of phenylalanine to tRNA(Phe) does not lead to changes with respect to the secondary and tertiary base pair interactions of tRNA. Complex formation of Phe-tRNA(Phe) with elongation factor Tu.GTP results in a broadening of all imino proton resonances of the tRNA. The chemical shifts of several NH proton resonances are slightly changed as compared to free tRNA, indicating a minor conformational rearrangement of Phe-tRNA(Phe) upon binding to elongation factor Tu.GTP. All NH proton resonances corresponding to the secondary and tertiary base pairs of tRNA, except those arising from the first three base pairs in the aminoacyl stem, are detectable in the Phe-tRNA(Phe)-elongation factor Tu-GTP ternary complex. Thus, although the interactions between elongation factor Tu and tRNA accelerate the rate of NH proton exchange in the aminoacyl stem-region, the Phe-tRNA(Phe) preserves its typical L-shaped tertiary structure in the complex. At high (> 10(-4) M) ligand concentrations a complex between tRNA(Phe) and elongation factor Tu-GDP can be detected on the NMR time-scale. Formation of this complex is inhibited by the presence of any RNA not related to the tRNA structure. Using the known tertiary structures of yeast tRNA(Phe) and Thermus thermophilus elongation factor Tu in its active, GTP form, a model of the ternary complex was constructed.