Mechanisms of elongation on the ribosome: dynamics of a macromolecular machine

Protein synthesis in the cell is performed on ribosomes, large ribonucleoprotein particles, which in bacteria consist of three RNA molecules and over 50 proteins. This review summarizes recent progress in understanding the mechanisms of the elongation phase of protein synthesis. Results from rapid kinetic analysis of elongation reactions are discussed in the light of recent structural data.

Translational elongation factor G: a GTP-driven motor of the ribosome

EF-G is a large, five-domain GTPase that promotes the directional movement of mRNA and tRNAs on the ribosome in a GTP-dependent manner. Unlike other GTPases, but by analogy to the myosin motor, EF-G performs its function of powering translocation in the GDP-bound form; that is, in a kinetically stable ribosome-EF-G(GDP) complex formed by GTP hydrolysis on the ribosome. The complex undergoes an extensive structural rearrangement, in particular affecting the small ribosomal subunit, which leads to mRNA-tRNA movement. Domain 4, which extends from the 'body' of the EF-G molecule much like a lever arm, appears to be essential for the structural transition to take place. In a hypothetical model, GTP hydrolysis induces a conformational change in the G domain of EF-G which affects the interactions with neighbouring domains within EF-G. The resulting rearrangement of the domains relative to each other generates conformational strain in the ribosome to which EF-G is fixed. Because of structural features of the tRNA-ribosome complex, this conformational strain results in directional tRNA-mRNA movement. The functional parallels between EF-G and motor proteins suggest that EF-G differs from classical G-proteins in that it functions as a force-generating mechanochemical device rather than a conformational switch. There are other multi-domain GTPases that may function in a similar way.

Fidelity of aminoacyl-tRNA selection on the ribosome: kinetic and structural mechanisms

The ribosome discriminates between correct and incorrect aminoacyl-tRNAs (aa-tRNAs), or their complexes with elongation factor Tu (EF-Tu) and GTP, according to the match between anticodon and mRNA codon in the A site. Selection takes place at two stages, prior to GTP hydrolysis (initial selection) and after GTP hydrolysis but before peptide bond formation (proofreading). In part, discrimination results from different rejection rates that are due to different stabilities of the respective codon-anticodon complexes. An important additional contribution is provided by induced fit, in that only correct codon recognition leads to acceleration of rate-limiting rearrangements that precede chemical steps. Recent elucidation of ribosome structures and mutational analyses suggest which residues of the decoding center may be involved in signaling formation of the correct codon-anticodon duplex to the functional centers of the ribosome. In utilizing induced fit for substrate discrimination, the ribosome resembles other nucleic acid-programmed polymerases.

Elongation factor G-induced structural change in helix 34 of 16S rRNA related to translocation on the ribosome

During the translocation step of the elongation cycle, two tRNAs together with the mRNA move synchronously and rapidly on the ribosome. The movement is catalyzed by the binding of elongation factor G (EF-G) and driven by GTP hydrolysis. Here we study structural changes of the ribosome related to EF-G binding and translocation by monitoring the accessibility of ribosomal RNA (rRNA) for chemical modification by dimethyl sulfate or cleavage by hydroxyl radicals generated by Fe(II)-EDTA. In the state of the ribosome that is formed upon binding of EF-G but before the movement of the tRNAs takes place, residues 1054,1196, and 1201 in helix 34 in 16S rRNA are strongly protected. The protections depend on EF-G binding, but do not require GTP hydrolysis, and are lost upon translocation. Mutants of EF-G, which are active in ribosome binding and GTP hydrolysis but impaired in translocation, do not bring about the protections. According to cryo-electron microscopy (Stark et al., Cell, 2000, 100:301-309), there is no contact of EF-G with the protected residues of helix 34 in the pretranslocation state, suggesting that the observed protections are due to an induced conformational change. Thus, the present results indicate that EF-G binding to the pretranslocation ribosome induces a structural change of the head of the 30S subunit that is essential for subsequent tRNA-mRNA movement in translocation.

[Mechanism of tRNA translocation on the ribosome]

During the translocation step of the elongation cycle of peptide synthesis two tRNAs together with the mRNA move synchronously and rapidly on the ribosome. Translocation is catalyzed by the elongation factor G (EF-G) and requires GTP hydrolysis. The fundamental biochemical features of the process were worked out in the 1970-80s, to a large part by A.S. Spirin and his colleagues. Recent results from pre-steady-state kinetic analysis and cryoelectron microscopy suggest that translocation is a multistep dynamic process that entails large-scale structural rearrangements of both ribosome and EF-G. Kinetic and thermodynamic data, together with the structural information on the conformational changes of the ribosome and of EF-G, provide a detailed mechanistic model of translocation and suggest a mechanism of translocation catalysis by EF-G.

A common structural motif in elongation factor Ts and ribosomal protein L7/12 may be involved in the interaction with elongation factor Tu

Elongation factor (EF) Tu alternates between two interaction partners, EF-Ts and the ribosome, during its functional cycle. On the ribosome, the interaction involves, among others, ribosomal protein L7/12. Here we compare EF-Ts and L7/12 with respect to the conservation of sequence and structure. There is significant conservation of functionally important residues in the N-terminal domain of EF-Ts and in the C-terminal domain of L7/12. The structure alignment based on the crystal structures of the two domains suggests a high degree of similarity between the alpha A--beta D--alpha B motif in L7/12 and the h1--turn--h2 motif in EF-Ts which defines a common structural motif. The motif is remarkably similar with respect to fold, bulkiness, and charge distribution of the solution surface, suggesting that it has a common function in binding EF-Tu.

Important role of the tetraloop region of 4.5S RNA in SRP binding to its receptor FtsY

Binding of Escherichia coli signal recognition particle (SRP) to its receptor, FtsY, requires the presence of 4.5S RNA, although FtsY alone does not interact with 4.5S RNA. In this study, we report that the exchange of the GGAA tetraloop sequence in domain IV of 4.5S RNA for UUCG abolishes SRP-FtsY interaction, as determined by gel retardation and membrane targeting experiments, whereas replacements with other GNRA-type tetraloops have no effect. A number of other base exchanges in the tetraloop sequence have minor or intermediate inhibitory effects. Base pair disruptions in the stem adjacent to the tetraloop or replacement of the closing C-G base pair with G-C partially restored function of the otherwise inactive UUCG mutant. Chemical probing by hydroxyl radical cleavage of 4.5S RNA variants show that replacing GGAA with UUCG in the tetraloop sequence leads to structural changes both within the tetraloop and in the adjacent stem; the latter change is reversed upon reverting the C-G closing base pair to G-C. These results show that the SRP-FtsY interaction is strongly influenced by the structure of the tetraloop region of SRP RNA, in particular the tetraloop stem, and suggest that both SRP RNA and Ffh undergo mutual structural adaptation to form SRP that is functional in the interaction with the receptor, FtsY.

Ribosome fidelity: tRNA discrimination, proofreading and induced fit

The ribosome selects aminoacyl-tRNAs with high fidelity. Kinetic studies reveal that codon-anticodon recognition both stabilizes aminoacyl-tRNA binding on the ribosome and accelerates reactions of the productive pathway, indicating an important contribution of induced fit to substrate selection. Similar mechanisms are used by other template-programmed enzymes, such as DNA and RNA polymerases.

Energetic contribution of tRNA hybrid state formation to translocation catalysis on the ribosome

Upon transpeptidylation, the 3' end of aminoacyl-tRNA (aa-tRNA) in the ribosomal A site enters the A/P hybrid state. We report that transpeptidylation of Phe-tRNA to fMetPhe-tRNA on Escherichia coli ribosomes substantially lowers the kinetic stability of the ribosome-tRNA complex and decreases the affinity by 18.9 kJ mol(-1). At the same time, the free energy of activation of elongation factor G dependent translocation decreases by 12.5 kJ mol(-1), indicating that part of the free energy of transpeptidylation is used to drive translocation kinetically. Thus, the formation of the A/P hybrid state constitutes an important element of the translocation mechanism.

Conformationally restricted elongation factor G retains GTPase activity but is inactive in translocation on the ribosome

Elongation factor G (EF-G) from Escherichia coli is a large, five-domain GTPase that promotes tRNA translocation on the ribosome. Full activity requires GTP hydrolysis, suggesting that a conformational change of the factor is important for function. To restrict the intramolecular mobility, two cysteine residues were engineered into domains 1 and 5 of EF-G that spontaneously formed a disulfide cross-link. Cross-linked EF-G retained GTPase activity on the ribosome, whereas it was inactive in translocation as well as in turnover. Both activities were restored when the cross-link was reversed by reduction. These results strongly argue against a GTPase switch-type model of EF-G function and demonstrate that conformational mobility is an absolute requirement for EF-G function on the ribosome.

Role of domains 4 and 5 in elongation factor G functions on the ribosome

Elongation factor G (EF-G) is a large, five domain GTPase that catalyses the translocation of the tRNAs on the bacterial ribosome at the expense of GTP. In the crystal structure of GDP-bound EF-G, domain 1 (G domain) makes direct contacts with domains 2 and 5, whereas domain 4 protrudes from the body of the molecule. Here, we show that the presence of both domains 4 and 5 is essential for tRNA translocation and for the turnover of the factor on the ribosome, but not for rapid single-round GTP hydrolysis by EF-G. Replacement of a highly conserved histidine residue at the tip of domain 4, His583, with lysine or arginine decreases the rate of tRNA translocation at least 100-fold, whereas the binding of the factor to the ribosome, GTP hydrolysis and P(i) release are not affected by the mutations. Various small deletions in the tip region of domain 4 decrease the translocation activity of EF-G even further, but do not block the turnover of the factor. Unlike native EF-G, the mutants of EF-G lacking domains 4/5 do not interact with the alpha-sarcin stem-loop of 23 S rRNA. These mutants are not released from the ribosome after GTP hydrolysis or translocation, indicating that the contact with, or a conformational change of, the alpha-sarcin stem-loop is required for EF-G release from the ribosome.

Arginines 29 and 59 of elongation factor G are important for GTP hydrolysis or translocation on the ribosome

GTP hydrolysis by elongation factor G (EF-G) is essential for the translocation step in protein elongation. The low intrinsic GTPase activity of EF-G is strongly stimulated by the ribosome. Here we show that a conserved arginine, R29, of Escherichia coli EF-G is crucial for GTP hydrolysis on the ribosome, but not for GTP binding or ribosome interaction, suggesting that it may be directly involved in catalysis. Another conserved arginine, R59, which is homologous to the catalytic arginine of G(alpha) proteins, is not essential for GTP hydrolysis, but influences ribosome binding and translocation. These results indicate that EF-G is similar to other GTPases in that an arginine residue is required for GTP hydrolysis, although the structural changes leading to GTPase activation are different.

Late events of translation initiation in bacteria: a kinetic analysis

Binding of the 50S ribosomal subunit to the 30S initiation complex and the subsequent transition from the initiation to the elongation phase up to the synthesis of the first peptide bond represent crucial steps in the translation pathway. The reactions that characterize these transitions were analyzed by quench-flow and fluorescence stopped-flow kinetic techniques. IF2-dependent GTP hydrolysis was fast (30/s) followed by slow P(i) release from the complex (1.5/s). The latter step was rate limiting for subsequent A-site binding of EF-Tu small middle dotGTP small middle dotPhe-tRNA(Phe) ternary complex. Most of the elemental rate constants of A-site binding were similar to those measured on poly(U), with the notable exception of the formation of the first peptide bond which occurred at a rate of 0.2/s. Omission of GTP or its replacement with GDP had no effect, indicating that neither the adjustment of fMet-tRNA(fMet) in the P site nor the release of IF2 from the ribosome required GTP hydrolysis.

GTPases mechanisms and functions of translation factors on the ribosome

The elongation factors (EF) Tu and G and initiation factor 2 (IF2) from bacteria are multidomain GTPases with essential functions in the elongation and initiation phases of translation. They bind to the same site on the ribosome where their low intrinsic GTPase activities are strongly stimulated. The factors differ fundamentally from each other, and from the majority of GTPases, in the mechanisms of GTPase control, the timing of Pi release, and the functional role of GTP hydrolysis. EF-Tu x GTP forms a ternary complex with aminoacyl-tRNA, which binds to the ribosome. Only when a matching codon is recognized, the GTPase of EF-Tu is stimulated, rapid GTP hydrolysis and Pi release take place, EF-Tu rearranges to the GDP form, and aminoacyl-tRNA is released into the peptidyltransferase center. In contrast, EF-G hydrolyzes GTP immediately upon binding to the ribosome, stimulated by ribosomal protein L7/12. Subsequent translocation is driven by the slow dissociation of Pi, suggesting a mechano-chemical function of EF-G. Accordingly, different conformations of EF-G on the ribosome are revealed by cryo-electron microscopy. GTP hydrolysis by IF2 is triggered upon formation of the 70S initiation complex, and the dissociation of Pi and/or IF2 follows a rearrangement of the ribosome into the elongation-competent state.

Intact aminoacyl-tRNA is required to trigger GTP hydrolysis by elongation factor Tu on the ribosome

GTP hydrolysis by elongation factor Tu (EF-Tu) on the ribosome is induced by codon recognition. The mechanism by which a signal is transmitted from the site of codon-anticodon interaction in the decoding center of the 30S ribosomal subunit to the site of EF-Tu binding on the 50S subunit is not known. Here we examine the role of the tRNA in this process. We have used two RNA fragments, one which contains the anticodon and D hairpin domains (ACD oligomer) derived from tRNA(Phe) and the second which comprises the acceptor stem and T hairpin domains derived from tRNA(Ala) (AST oligomer) that aminoacylates with alanine and forms a ternary complex with EF-Tu. GTP. While the ACD oligomer and the ternary complex containing the Ala-AST oligomer interact with the 30S and 50S A site, respectively, no rapid GTP hydrolysis was observed when both were bound simultaneously. The presence of paromomycin, an aminoglycoside antibiotic that binds to the decoding site and stabilizes codon-anticodon interaction in unfavorable coding situations, did not increase the rate of GTP hydrolysis. These results suggest that codon recognition as such is not sufficient for GTPase activation and that an intact tRNA molecule is required for transmitting the signal created by codon recognition to EF-Tu.

Large-scale movement of elongation factor G and extensive conformational change of the ribosome during translocation

Elongation factor (EF) G promotes tRNA translocation on the ribosome. We present three-dimensional reconstructions, obtained by cryo-electron microscopy, of EF-G-ribosome complexes before and after translocation. In the pretranslocation state, domain 1 of EF-G interacts with the L7/12 stalk on the 50S subunit, while domain 4 contacts the shoulder of the 30S subunit in the region where protein S4 is located. During translocation, EF-G experiences an extensive reorientation, such that, after translocation, domain 4 reaches into the decoding center. The factor assumes different conformations before and after translocation. The structure of the ribosome is changed substantially in the pretranslocation state, in particular at the head-to-body junction in the 30S subunit, suggesting a possible mechanism of translocation.

Conformational switch in the decoding region of 16S rRNA during aminoacyl-tRNA selection on the ribosome

Binding of aminoglycoside antibiotics to 16S ribosomal RNA induces a particular structure of the decoding center and increases the misincorporation of near-cognate amino acids. By kinetic analysis we show that this is due to stabilization of the near-cognate codon recognition complex and the acceleration of two rearrangements that limit the rate of amino acid incorporation. The same rearrangement steps are accelerated in the cognate coding situation. We suggest that cognate codon recognition, or near-cognate codon recognition augmented by aminoglycoside binding, promote the transition of 16S rRNA from a 'binding' to a 'productive' conformation that determines the fidelity of decoding.

Conformational changes in the bacterial SRP receptor FtsY upon binding of guanine nucleotides and SRP

In cotranslational preprotein targeting in Escherichia coli, the signal recognition particle (SRP) binds to the signal peptide emerging from the ribosome and, subsequently, interacts with the signal recognition particle receptor, FtsY, at the plasma membrane. Both FtsY and the protein moiety of the signal recognition particle, Ffh, are GTPases, and GTP is required for the formation of the SRP-FtsY complex. We have studied the binding of GTP/GDP to FtsY as well as the SRP-FtsY complex formation by monitoring the fluorescence of tryptophan 343 in the I box of mutant FtsY. Thermodynamic and kinetic parameters of the FtsY complexes with GDP, GTP, and signal recognition particle are reported. Upon SRP-FtsY complex formation in the presence of GTP, the fluorescence of tryptophan 343 increased by 50 % and was blue-shifted by 10 nm. We conclude that GTP-dependent SRP-FtsY complex formation leads to an extensive conformational change in the I box insertion in the effector region of FtsY.

Stimulation of the GTPase activity of translation elongation factor G by ribosomal protein L7/12

Elongation factors (EFs) Tu and G are GTPases that have important functions in protein synthesis. The low intrinsic GTPase activity of both factors is strongly stimulated on the ribosome by unknown mechanisms. Here we report that isolated ribosomal protein L7/12 strongly stimulates GTP hydrolysis by EF-G, but not by EF-Tu, indicating a major contribution of L7/12 to GTPase activation of EF-G on the ribosome. The effect is due to the acceleration of the catalytic step because the rate of GDP-GTP exchange on EF-G, as measured by rapid kinetics, is much faster than the steady-state GTPase rate. The unique, highly conserved arginine residue in the C-terminal domain of L7/12 is not essential for the activation, excluding an "arginine finger"-type mechanism. L7/12 appears to function by stabilizing the GTPase transition state of EF-G.

Thiostrepton inhibits the turnover but not the GTPase of elongation factor G on the ribosome

The region around position 1067 in domain II of 23S rRNA frequently is referred to as the GTPase center of the ribosome. The notion is based on the observation that the binding of the antibiotic thiostrepton to this region inhibited GTP hydrolysis by elongation factor G (EF-G) on the ribosome at the conditions of multiple turnover. In the present work, we have reanalyzed the mechanism of action of thiostrepton. Results obtained by biochemical and fast kinetic techniques show that thiostrepton binding to the ribosome does not interfere with factor binding or with single-round GTP hydrolysis. Rather, the antibiotic inhibits the function of EF-G in subsequent steps, including release of inorganic phosphate from EF-G after GTP hydrolysis, tRNA translocation, and the dissociation of the factor from the ribosome, thereby inhibiting the turnover reaction. Structurally, thiostrepton interferes with EF-G footprints in the alpha-sarcin stem loop (A2660, A2662) located in domain VI of 23S rRNA. The results indicate that thiostrepton inhibits a structural transition of the 1067 region of 23S rRNA that is important for functions of EF-G after GTP hydrolysis.

Induced fit in initial selection and proofreading of aminoacyl-tRNA on the ribosome

The fidelity of aminoacyl-tRNA (aa-tRNA) selection by the bacterial ribosome is determined by initial selection before and proofreading after GTP hydrolysis by elongation factor Tu. Here we report the rate constants of A-site binding of a near-cognate aa-tRNA. The comparison with the data for cognate aa-tRNA reveals an additional, important contribution to aa-tRNA discrimination of conformational coupling by induced fit. It is found that two rearrangement steps that limit the chemical reactions of A-site binding, i.e. GTPase activation (preceding GTP hydrolysis) and A-site accommodation (preceding peptide bond formation), are substantially faster for cognate than for near-cognate aa-tRNA. This suggests an induced-fit mechanism of aa-tRNA discrimination on the ribosome that operates in both initial selection and proofreading. It is proposed that the cognate codon-anticodon interaction, more efficiently than the near-cognate one, induces a particular conformation of the decoding center of 16S rRNA, which in turn promotes GTPase activation and A-site accommodation of aa-tRNA, thereby accelerating the chemical steps. As kinetically favored incorporation of the correct substrate has also been suggested for DNA and RNA polymerases, the present findings indicate that induced fit may contribute to the fidelity of template-programed systems in general.

Ribosomal RNA is the target for oxazolidinones, a novel class of translational inhibitors

Oxazolidinones are antibacterial agents that act primarily against gram-positive bacteria by inhibiting protein synthesis. The binding of oxazolidinones to 70S ribosomes from Escherichia coli was studied by both UV-induced cross-linking using an azido derivative of oxazolidinone and chemical footprinting using dimethyl sulphate. Oxazolidinone binding sites were found on both 30S and 50S subunits, rRNA being the only target. On 16S rRNA, an oxazolidinone footprint was found at A864 in the central domain. 23S rRNA residues involved in oxazolidinone binding were U2113, A2114, U2118, A2119, and C2153, all in domain V. This region is close to the binding site of protein L1 and of the 3' end of tRNA in the E site. The mechanism of action of oxazolidinones in vitro was examined in a purified translation system from E. coli using natural mRNA. The rate of elongation reaction of translation was decreased, most probably because of an inhibition of tRNA translocation, and the length of nascent peptide chains was strongly reduced. Both binding sites and mode of action of oxazolidinones are unique among the antibiotics known to act on the ribosome.

Dynamics of translation on the ribosome: molecular mechanics of translocation

The translocation step of protein elongation entails a large-scale rearrangement of the tRNA-mRNA-ribosome complex. Recent years have seen major advances in unraveling the mechanism of the process on the molecular level. A number of intermediate states have been defined and, in part, characterized structurally. The article reviews the recent evidence that suggests a dynamic role of the ribosome and its ligands during translocation. The focus is on dynamic aspects of tRNA movement and on the role of elongation factor G and GTP hydrolysis in translocation catalysis. The significance of structural changes of the ribosome induced by elongation factor G as well the role of ribosomal RNA are addressed. A functional model of elongation factor G as a motor protein driven by GTP hydrolysis is discussed.

Complete kinetic mechanism of elongation factor Tu-dependent binding of aminoacyl-tRNA to the A site of the E. coli ribosome

The kinetic mechanism of elongation factor Tu (EF-Tu)-dependent binding of Phe-tRNAPhe to the A site of poly(U)-programmed Escherichia coli ribosomes has been established by pre-steady-state kinetic experiments. Six steps were distinguished kinetically, and their elemental rate constants were determined either by global fitting, or directly by dissociation experiments. Initial binding to the ribosome of the ternary complex EF-Tu.GTP.Phe-tRNAPhe is rapid (k1 = 110 and 60/micromM/s at 10 and 5 mM Mg2+, 20 degreesC) and readily reversible (k-1 = 25 and 30/s). Subsequent codon recognition (k2 = 100 and 80/s) stabilizes the complex in an Mg2+-dependent manner (k-2 = 0.2 and 2/s). It induces the GTPase conformation of EF-Tu (k3 = 500 and 55/s), instantaneously followed by GTP hydrolysis. Subsequent steps are independent of Mg2+. The EF-Tu conformation switches from the GTP- to the GDP-bound form (k4 = 60/s), and Phe-tRNAPhe is released from EF-Tu.GDP. The accommodation of Phe-tRNAPhe in the A site (k5 = 8/s) takes place independently of EF-Tu and is followed instantaneously by peptide bond formation. The slowest step is dissociation of EF-Tu.GDP from the ribosome (k6 = 4/s). A characteristic feature of the mechanism is the existence of two conformational rearrangements which limit the rates of the subsequent chemical steps of A-site binding.

Interaction of guanine nucleotides with the signal recognition particle from Escherichia coli

The bacterial signal recognition particle (SRP) is an RNA-protein complex. In Escherichia coli, the particle consists of a 114 nt RNA, a 4.5S RNA, and a 48 kDa GTP-binding protein, Ffh. GDP-GTP exchange on, and GTP hydrolysis by, Ffh are thought to regulate SRP function in membrane targeting of translating ribosomes. In the present paper, we report the equilibrium and kinetic constants of guanine nucleotide binding to Ffh in different functional complexes. The association and dissociation rate constants of GTP/GDP binding to Ffh were measured using a fluorescent analogue of GTP/GDP, mant-GTP/GDP. For both nucleotides, association and dissociation rate constants were about 10(6) M-1 s-1 and 10 s-1, respectively. The equilibrium constants of nonmodified GTP and GDP binding to Ffh alone and in SRP, and in the complex with the ribosomes were measured by competition with mant-GDP. In all cases, the same 1-2 microM affinity for GTP and GDP was observed. Binding of both GTP and GDP to Ffh was independent of Mg2+ ions. The data suggest that, at conditions in vivo, (i) there will be rapid spontaneous GDP-GTP exchange, and (ii) the GTP-bound form of Ffh, or of SRP, will be predominant.

The Escherichia coli SRP and SecB targeting pathways converge at the translocon

Two distinct protein targeting pathways can direct proteins to the Escherichia coli inner membrane. The Sec pathway involves the cytosolic chaperone SecB that binds to the mature region of pre-proteins. SecB targets the pre-protein to SecA that mediates pre-protein translocation through the SecYEG translocon. The SRP pathway is probably used primarily for the targeting and assembly of inner membrane proteins. It involves the signal recognition particle (SRP) that interacts with the hydrophobic targeting signal of nascent proteins. By using a protein cross-linking approach, we demonstrate here that the SRP pathway delivers nascent inner membrane proteins at the membrane. The SRP receptor FtsY, GTP and inner membranes are required for release of the nascent proteins from the SRP. Upon release of the SRP at the membrane, the targeted nascent proteins insert into a translocon that contains at least SecA, SecY and SecG. Hence, as appears to be the case for several other translocation systems, multiple targeting mechanisms deliver a variety of precursor proteins to a common membrane translocation complex of the E.coli inner membrane.

Visualization of elongation factor Tu on the Escherichia coli ribosome

The delivery of a specific amino acid to the translating ribosome is fundamental to protein synthesis. The binding of aminoacyl-transfer RNA to the ribosome is catalysed by the elongation factor Tu (EF-Tu). The elongation factor, the aminoacyl-tRNA and GTP form a stable 'ternary' complex that binds to the ribosome. We have used electron cryomicroscopy and angular reconstitution to visualize directly the kirromycin-stalled ternary complex in the A site of the 70S ribosome of Escherichia coli. Electron cryomicroscopy had previously given detailed ribosomal structures at 25 and 23 A resolution, and was used to determine the position of tRNAs on the ribosome. In particular, the structures of pre-translocational (tRNAs in A and P sites) and post-translocational ribosomes (P and E sites occupied) were both visualized at a resolution of approximately 20 A. Our three-dimensional reconstruction at 18 A resolution shows the ternary complex spanning the inter-subunit space with the acceptor domain of the tRNA reaching into the decoding centre. Domain 1 (the G domain) of the EF-Tu is bound both to the L7/L12 stalk and to the 50S body underneath the stalk, whereas domain 2 is oriented towards the S12 region on the 30S subunit.

Arrangement of tRNAs in pre- and posttranslocational ribosomes revealed by electron cryomicroscopy

The three-dimensional structure of the translating 70S E. coli ribosome is presented in its two main conformations: the pretranslocational and the posttranslocational states. Using electron cryomicroscopy and angular reconstitution, structures at 20 A resolution were obtained, which, when compared with our earlier reconstruction of "empty" ribosomes, showed densities corresponding to tRNA molecules--at the P and E sites for posttranslocational ribosomes and at the A and P sites for pretranslocational ribosomes. The P-site tRNA lies directly above the bridge connecting the two ribosomal subunits, with the A-site tRNA fitted snugly against it at an angle of approximately 50 degrees, toward the L7/L12 side of the ribosome. The E-site tRNA appears to lie between the side lobe of the 30S subunit and the L1 protuberance.

Hydrolysis of GTP by elongation factor G drives tRNA movement on the ribosome

Elongation factor G (EF-G) is a GTPase that is involved in the translocation of bacterial ribosomes along messenger RNA during protein biosynthesis. In contrast to current models, EF-G-dependent GTP hydrolysis is shown to precede, and greatly accelerate, the rearrangement of the ribosome that leads to translocation. Domain IV of the EF-G structure is crucial for both rapid translocation and subsequent release of the factor from the ribosome. By coupling the free energy of GTP hydrolysis to translocation, EF-G serves as a motor protein to drive the directional movement of transfer and messenger RNAs on the ribosome.

The G222D mutation in elongation factor Tu inhibits the codon-induced conformational changes leading to GTPase activation on the ribosome

Elongation factor Tu (EF-Tu) from Escherichia coli carrying the mutation G222D is unable to hydrolyze GTP on the ribosome and to sustain polypeptide synthesis at near physiological Mg2+ concentration, although the interactions with guanine nucleotides and aminoacyl-tRNA are not changed significantly. GTPase and polypeptide synthesis activities are restored by increasing the Mg2+ concentration. Here we report a pre-steady-state kinetic study of the binding of the ternary complexes of wild-type and mutant EF-Tu with Phe-tRNA(Phe) and GTP to the A site of poly(U)-programed ribosomes. The kinetic parameters of initial binding to the ribosome and subsequent codon-anticodon interaction are similar for mutant and wild-type EF-Tu, independent of the Mg2+ concentration, suggesting that the initial interaction with the ribosome is not affected by the mutation. Codon recognition following initial binding is also not affected by the mutation. The main effect of the G222D mutation is the inhibition, at low Mg2+ concentration, of codon-induced structural transitions of the tRNA and, in particular, their transmission to EF-Tu that precedes GTP hydrolysis and the subsequent steps of A-site binding. Increasing the Mg2+ concentration to 10 mM restores the complete reaction sequence of A-site binding at close to wild-type rates. The inhibition of the structural transitions is probably due to the interference of the negative charge introduced by the mutation with negative charges either of the 3' terminus of the tRNA, bound in the vicinity of the mutated amino acid in domain 2 of EF-Tu, or of the ribosome. Increasing the Mg2+ concentration appears to overcome the inhibition by screening the negative charges.

The "allosteric three-site model" of elongation cannot be confirmed in a well-defined ribosome system from Escherichia coli

For the functional role of the ribosomal tRNA exit (E) site, two different models have been proposed. It has been suggested that transient E-site binding of the tRNA leaving the peptidyl (P) site promotes elongation factor G (EF-G)-dependent translocation by lowering the energetic barrier of tRNA release [Lill, R., Robertson, J. M. & Wintermeyer, W. (1989) EMBO J. 8, 3933-3938]. The alternative "allosteric three-site model" [Nierhaus, K.H. (1990) Biochemistry 29, 4997-5008] features stable, codon-dependent tRNA binding to the E site and postulates a coupling between E and aminoacyl (A) sites that regulates the tRNA binding affinity of the two sites in an anticooperative manner. Extending our testing of the two conflicting models, we have performed translocation experiments with fully active ribosomes programmed with heteropolymeric mRNA. The results confirm that the deacylated tRNA released from the P site is bound to the E site in a kinetically labile fashion, and that the affinity of binding, i.e., the occupancy of the E site, is increased by Mg2+ or polyamines. At conditions of high E-site occupancy in the posttranslocation complex, filling the A site with aminoacyl-tRNA had no influence on the E site, i.e., there was no detectable anticooperative coupling between the two sites, provided that second-round translocation was avoided by removing EF-G. On the basis of these results, which are entirely consistent with our previous results, we consider the allosteric three-site model of elongation untenable. Rather, as proposed earlier, the E site-bound state of the leaving tRNA is a transient intermediate and, as such, is a mechanistic feature of the classic two-state model of the elongating ribosome.

Truncated elongation factor G lacking the G domain promotes translocation of the 3' end but not of the anticodon domain of peptidyl-tRNA

The mechanism by which elongation factor G (EF-G) catalyzes the translocation of tRNAs and mRNA on the ribosome is not known. The reaction requires GTP, which is hydrolyzed to GDP. Here we show that EF-G from Escherichia coli lacking the G domain still catalyzed partial translocation in that it promoted the transfer of the 3' end of peptidyl-tRNA to the P site on the 50S ribosomal subunit into a puromycin-reactive state in a slow-turnover reaction. In contrast, it did not bring about translocation on the 30S subunit, since (i) deacylated tRNA was not released from the P site and (ii) the A site remained blocked for aminoacyl-tRNA binding during and after partial translocation. The reaction probably represents the first EF-G-dependent step of translocation that follows the spontaneous formation of the A/P state that is not puromycin-reactive [Moazed, D. & Noller, H. F. (1989) Nature (London) 342, 142-148]. In the complete system--i.e., with intact EF-G and GTP--the 50S phase of translocation is rapidly followed by the 30S phase during which the tRNAs together with the mRNA are shifted on the small ribosomal subunit, and GTP is hydrolyzed. As to the mechanism of EF-G function, the results show that the G domain has an important role, presumably exerted through interactions with other domains of EF-G, in the promotion of translocation on the small ribosomal subunit. The G domain's intramolecular interactions are likely to be modulated by GTP binding and hydrolysis.

Structure of 4.5S RNA in the signal recognition particle of Escherichia coli as studied by enzymatic and chemical probing

The structure of 4.5S RNA, the Escherichia coli homologue of the signal recognition particle (SRP) RNA, alone and in the SRP complex with protein P48 (Ffh) was probed both enzymatically and chemically. The molecule is largely resistant against single strand-specific nucleases, indicating a highly base paired structure. Reactivity appears mainly in the apical tetraloop and in one of the conserved internal loops. Although some residues are found reactive toward dimethylsulphate and kethoxal in regions predicted to be unpaired by the phylogenetic secondary structure model of 4.5S RNA, generally the reactivity is low, and some residues in internal loops are not reactive at all. RNase V1 cleaves the RNA at multiple sites that coincide with predicted helices, although the cleavages show a pronounced asymmetry. The binding of protein P48 to 4.5S RNA results in a protection of residues in the apical part of the molecule homologous to eukaryotic SRP RNA (domain IV), whereas the cleavages in the conserved apical tetraloop are not protected. Hydroxyl radical treatment reveals an asymmetric pattern of backbone reactivity; in particular, the region encompassing nucleotides 60-82, i.e., the 3' part of the conserved domain IV, is protected. The data suggest that a bend in the domain IV region, most likely at the central asymmetric internal loop, is an important element of the tertiary structure of 4.5S RNA. Hyperchromicity and lead cleavage data are consistent with the model as they reveal the unfolding of a higher-order structure between 30 and 40 degrees C. Protection by protein P48 occurs in this region of the RNA and, more strongly, in the 5' part of domain IV (nt 26-50, most strongly from 35 to 49). It is likely that P48 binds to the outside of the bent form of 4.5S RNA.

Initial binding of the elongation factor Tu.GTP.aminoacyl-tRNA complex preceding codon recognition on the ribosome

The first step in the sequence of interactions between the ribosome and the complex of elongation factor Tu (EF-Tu), GTP, and aminoacyl-tRNA, which eventually leads to A site-bound aminoacyl-tRNA, is the codon-independent formation of an initial complex. We have characterized the initial binding and the resulting complex by time-resolved (stopped-flow) and steady-state fluorescence measurements using several fluorescent tRNA derivatives. The complex is labile, with rate constants of 6 x 10(7) M-1 s-1 and 24 s-1 (20 degrees C, 10 mM Mg2+) for binding and dissociation, respectively. Both thermodynamic and activation parameters of initial binding were determined, and five Mg2+ ions were estimated to participate in the interaction. While a cognate ternary complex proceeds form initial binding through codon recognition to rapid GTP hydrolysis, the rate constant of GTP hydrolysis in the non-cognate complex is 4 orders of magnitude lower, despite the rapid formation of the initial complex in both cases. Hence, the ribosome-induced GTP hydrolysis by EF-Tu is strongly affected by the presence of the tRNA. This suggests that codon-anticodon recognition, which takes place after the formation of the initial binding complex, provides a specific signal that triggers fast GTP hydrolysis by EF-Tu on the ribosome.

Elongation factor Tu, a GTPase triggered by codon recognition on the ribosome: mechanism and GTP consumption

The mechanism of elongation factor Tu (EF-Tu) catalyzed aminoacyl-tRNA (aa-tRNA) binding to the A site of the ribosome was studied. Two types of complexes of EF-Tu with GTP and aa-tRNA, EF-Tu.GTP-aa-tRNA (ternary) and (EF-Tu.GTP)2.aa-tRNA (quinternary), can be formed in vitro depending on the conditions. On interaction with the ribosomal A site, generally only one molecule of GTP is hydrolysed per aa-tRNA bound and peptide bond formed. The second GTP molecule from the quinternary complex is hydrolyzed only during translation of an oligo(U) tract in the presence of EF-G. The first step in the interaction between the ribosome and the ternary complex is the codon-independent formation of an initial complex. In the absence of codon recognition, the aa-tRNA-EF-Tu complex does not enter further steps of A site binding and remains in the initial binding state. Despite the rapid formation of the initial complex, the rate constant of GTP hydrolysis in the noncognate complex is four orders of magnitude lower compared with the cognate complex. This, together with the results of time-resolved fluorescence measurements, suggests that codon recognition by the ternary complex on the ribosome initiates a series of structural rearrangements that result in a conformational change of EF-Tu, presumably involving the effector region, which, in turn, triggers GTP hydrolysis and the subsequent steps of A site binding.

The functioning of the SRP receptor FtsY in protein-targeting in E. coli is correlated with its ability to bind and hydrolyse GTP

In this study, we have established that FtsY, the E. coli homolog of the mammalian signal recognition particle (SRP) receptor, is a GTP-binding protein which displays intrinsic GTPase activity. GTP was found to influence the protease sensitivity of FtsY indicative of a conformational change. FtsY mutated in the 4th GTP-binding consensus element displayed reduced GTP-binding and -hydrolysis which correlated with a reduced ability to interact with SRP. Overexpression of the mutant proteins had a stronger inhibitory effect on protein translocation than overexpression of wild-type FtsY. These observations suggest that in E. coli GTP is important for proper functioning of FtsY in protein-targeting.

Codon-dependent conformational change of elongation factor Tu preceding GTP hydrolysis on the ribosome

The mechanisms by which elongation factor Tu (EF-Tu) promotes the binding of aminoacyl-tRNA to the A site of the ribosome and, in particular, how GTP hydrolysis by EF-Tu is triggered on the ribosome, are not understood. We report steady-state and time-resolved fluorescence measurements, performed in the Escherichia coli system, in which the interaction of the complex EF-Tu.GTP.Phe-tRNAPhe with the ribosomal A site is monitored by the fluorescence changes of either mant-dGTP [3'-O-(N-methylanthraniloyl)-2-deoxyguanosine triphosphate], replacing GTP in the complex, or of wybutine in the anticodon loop of the tRNA. Additionally, GTP hydrolysis is measured by the quench-flow technique. We find that codon-anticodon interaction induces a rapid rearrangement within the G domain of EF-Tu around the bound nucleotide, which is followed by GTP hydrolysis at an approximately 1.5-fold lower rate. In the presence of kirromycin, the activated conformation of EF-Tu appears to be frozen. The steps following GTP hydrolysis--the switch of EF-Tu to the GDP-bound conformation, the release of aminoacyl-tRNA from EF-Tu to the A site, and the dissociation of EF-Tu-GDP from the ribosome--which are altogether suppressed by kirromycin, are not distinguished kinetically. The results suggest that codon recognition by the ternary complex on the ribosome initiates a series of structural rearrangements resulting in a conformational change of EF-Tu, possibly involving the effector region, which, in turn, triggers GTP hydrolysis.

Site-directed mutagenesis of Thermus thermophilus elongation factor Tu. Replacement of His85, Asp81 and Arg300

His85 in Thermus thermophilus elongation factor Tu (EF-Tu) was replaced by glutamine, leucine and glycine residues, leading to [H85Q]EF-Tu, [H85L] EF-Tu and [H85G]EF-Tu, respectively. Asp81 was replaced by alanine leading to [D81A]EF-Tu, and replacement of Arg300 provided [R300I]EF-Tu. Glycine in position 85 of domain I induces a protease-sensitive site in domain II and causes complete protein degradation in vivo. A similar effect was observed when Asp81 was replaced by alanine or Arg300 by isoleucine. Degradation is probably due to disturbed interactions between the domains of EF-Tu.GTP, inducing a protease-sensitive cleavage site in domain II. [H85Q]EF-Tu, which can be effectively overproduced in Escherichia coli, is slower in poly(U)-dependent poly(Phe) synthesis, has lower affinity to aminoacyl-tRNA but shows only a slightly reduced rate of intrinsic GTP hydrolysis compared to the native protein. The GTPase of this protein variant is not efficiently stimulated by aminoacyl-tRNA and ribosomes. The slow GTPase of [H85Q]EF-Tu increases the fidelity of translation as measured by leucine incorporation into poly(Phe) in in vitro poly(U)-dependent ribosomal translation. Replacement of His85 in T. thermophilus EF-Tu by leucine completely deactivates the GTPase activity but does not substantially influence the aminoacyl-tRNA binding. [H85L]EF-Tu is inactive in poly(U)-dependent poly(Phe)-synthesis. The rate of nucleotide dissociation is highest for [H85L]EF-Tu, followed by [H85Q]EF-Tu and native T. thermophilus EF-Tu. Mutation of His85, a residue which is not directly involved in the nucleotide binding, thus influences the interaction of EF-Tu domains, nucleotide binding and the efficiency and rate of GTPase activity.

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.

Transient conformational states of aminoacyl-tRNA during ribosome binding catalyzed by elongation factor Tu

Conformational transitions of Phe-tRNA(Phe) that take place during elongation factor Tu (EF-Tu)-dependent binding to the A site of Escherichia coli ribosomes were followed by transient fluorescence measurements. The fluorescence signal of proflavin replacing dihydrouracil at position 16 or 17 in yeast tRNA(Phe) was utilized to monitor changes of the conformation of the D loop. The ternary complex EF-Tu.GTP.Phe-TRNA(Phe)(Pf16/17) was purified by gel filtration. Upon binding of the complex to the A site of poly(U)-programmed, P-site-blocked ribosomes, the fluorescence changes in several steps. First, the rapid formation of an initial complex gives rise to a small fluorescence increase. Subsequent codon-anticodon recognition leads to a conformational rearrangement of the D loop of the tRNA that is reflected in a major fluorescence increase. Fluorescence-quenching data indicate an unfolding of the D loop in this state. The latter conformational state is short-lived, and the aminoacyl-tRNA refolds during the following rearrangement that occurs after GTP hydrolysis and accompanies the release of the aminoacyl-tRNA from EF-Tu.GDP and/or its accommodation in the A site. Further experiments show that the status of the P site influences the binding to the A site in that the two rearrangement steps are slowed down when the P site is unoccupied and even more so when it is occupied with the near-cognate tRNA(Leu2). In contrast, the occupancy of the E site has no influence on A-site binding, and vice versa, thus excluding any coupling between the two sites.

Formation of SRP-like particle induces a conformational change in E. coli 4.5S RNA

E. coli P48 protein is homologous to the SRP54 component of the eukaryotic signal recognition particle. In vivo, P48 is associated with 4.5S RNA which shares a homology with eukaryotic SRP RNA. To study the interaction between P48 and 4.5S RNA in vitro, we used 4.5S RNA with fluorescein coupled to the 3'-terminal ribose. Upon binding of P48, the fluorescent 4.5S RNA shows a substantial decrease in fluorescence. Fluorescence quenching as well as anisotropy measurements reveal that the effect is not due to a direct interaction of P48 with the dye. This suggests that the binding of P48 induces a conformational change in 4.5S RNA which affects the structure at the 3' end of the RNA. From equilibrium titrations with fluorescent 4.5S RNA, a dissociation constant of 0.15 microns is obtained for the RNA.protein complex. The formation of the complex is not affected by GTP binding to or hydrolysis by P48.

Topography of the E site on the Escherichia coli ribosome

Three photoreactive tRNA probes have been utilized in order to identify ribosomal components that are in contact with the aminoacyl acceptor end and the anticodon loop of tRNA bound to the E site of Escherichia coli ribosomes. Two of the probes were derivatives of E. coli tRNA(Phe) in which adenosines at positions 73 and 76 were replaced by 2-azidoadenosine. The third probe was derived from yeast tRNA(Phe) by substituting wyosine at position 37 with 2-azidoadenosine. Despite the modifications, all of the photoreactive tRNA species were able to bind to the E site of E. coli ribosomes programmed with poly(A) and, upon irradiation, formed covalent adducts with the ribosomal subunits. The tRNA(Phe) probes modified at or near the 3' terminus exclusively labeled protein L33 in the 50S subunit. The tRNA(Phe) derivative containing 2-azidoadenosine within the anticodon loop became cross-linked to protein S11 as well as to a segment of the 16S rRNA encompassing the 3'-terminal 30 nucleotides. We have located the two extremities of the E site-bound tRNA on the ribosomal subunits according to the positions of L33, S11 and the 3' end of 16S rRNA defined by immune electron microscopy. Our results demonstrate conclusively that the E site is topographically distinct from either the P site or the A site, and that it is located alongside the P site as expected for the tRNA exit site.

Two tRNA-binding sites in addition to A and P sites on eukaryotic ribosomes

The interaction of tRNA with 80 S ribosomes from rabbit liver was studied using biochemical as well as fluorescence techniques. Besides the canonical A and P sites, two additional sites were found which specifically bind deacylated tRNA. One of the sites is analogous to the E site of prokaryotic ribosomes, in that binding of tRNA is labile, does not depend on codon-anticodon interaction, does not protect the anticodon loop from solvent access, and requires the presence of the 3'-terminal adenosine of the tRNA. In contrast, the stability of the tRNA complex with the second site (S site) is high. tRNA binding to the S site is also codon-independent; nevertheless, the anticodon loop is shielded from solvent access. Removal of the 3'-terminal adenosine decreases the affinity of tRNA(Phe) for the S site approximately 50-fold. tRNA(Phe) is retained at the S site during translocation and through poly(Phe) synthesis. Thus, the S site does not seem to be an intermediate site for the tRNA during the elongation cycle. Rather, the tRNA bound to the S site may allosterically modulate the function of the ribosome.

Binding of the 3′ terminus of tRNA to 23S rRNA in the ribosomal exit site actively promotes translocation

A key event in ribosomal protein synthesis is the translocation of deacylated tRNA, peptidyl tRNA and mRNA, which is catalyzed by elongation factor G (EF-G) and requires GTP. To address the molecular mechanism of the reaction we have studied the functional role of a tRNA exit site (E site) for tRNA release during translocation. We show that modifications of the 3' end of tRNAPhe, which considerably decrease the affinity of E-site binding, lower the translocation rate up to 40-fold. Furthermore, 3'-end modifications lower or abolish the stimulation by P site-bound tRNA of the GTPase activity of EF-G on the ribosome. The results suggest that a hydrogen-bonding interaction of the 3'-terminal adenine of the leaving tRNA in the E site, most likely base-pairing with 23S rRNA, is essential for the translocation reaction. Furthermore, this interaction stimulates the GTP hydrolyzing activity of EF-G on the ribosome. We propose the following molecular model of translocation: after the binding of EF-G.GTP, the P site-bound tRNA, by a movement of the 3'-terminal single-stranded ACCA tail, establishes an interaction with 23S rRNA in the adjacent E site, thereby initiating the tRNA transfer from the P site to the E site and promoting GTP hydrolysis. The co-operative interaction between the E site and the EF-G binding site, which are distantly located on the 50S ribosomal subunit, is probably mediated by a conformational change of 23S rRNA.

Specific recognition of the 3'-terminal adenosine of tRNAPhe in the exit site of Escherichia coli ribosomes

Ribosomes from Escherichia coli possess, in addition to A and P sites, a third tRNA binding site, which according to its presumed function in tRNA release during translocation has been termed the exit site. The exit site exhibits a remarkable specificity for deacylated tRNA; charged tRNA, e.g. N-AcPhe-tRNAPhe, is not bound significantly. To determine the molecular basis of this discrimination, we have measured the exit site binding affinities of a number of derivatives of tRNAPhe from E. coli, modified at the 3' end. Binding to the exit site of the tRNAPhe derivatives was measured fluorimetrically by competition with a fluorescent tRNAPhe derivative. We show here that removal of the 2' and 3' hydroxyl groups of the 3'-terminal adenosine decreases the affinity of tRNAPhe for the exit site 15 and 40-fold, respectively. Substitutions at the 3' hydroxyl group (aminoacylation, phosphorylation, cytidylation) as well as removal of the 3'-terminal adenosine (or adenylate) of tRNAPhe lower the affinity below the detection limit of 2 x 10(5) M-1, i.e. more than 100-fold. Modification of the adenine moiety (1,N6-etheno adenine) or replacement of it with other bases (cytosine, guanine) has the same dramatic effect. In contrast, the binding to both P and A sites is virtually unaffected by all of the modifications tested. These results suggest that a major fraction (at least -12 kJ/mol, probably about -17 kJ/mol) of the free energy of exit site binding of tRNAPhe (-42 kJ/mol at 20 mM-Mg2+) is contributed by the binding of the 3'-terminal adenine to the ribosome. The binding most likely entails the formation of hydrogen bonds.