Determination of tRNA nucleotide residues directly interacting with proteins in the post- and pretranslocated ribosomal complexes

Nucleotide residues of E. coli tRNA interacting directly with proteins in pre- and posttranslocated ribosomal complexes have been identified by analysis of photo-induced tRNA-protein cross-links. A9, G18, A26 and U59 residues of NAcPhePhe-tRNA, located in the Ab-site (pretranslocated complex) have been cross-linked with proteins S10, L27, S7 and L2 respectively. In deacylated tRNA, located in the Pb-site, residues C17, G44, C56 and U60 have been cross-linked with proteins L2, L5, L27 and S9 respectively. The G44-L5 cross-link disappeared after translocation (NAc-PhePhe-tRNA located in the Pt-site).     

Neighbourhood of the central fold of the tRNA molecule bound to the E. coli ribosome--affinity labeling studies with modified tRNAs carrying photoreactive probes attached to the dihydrouridine loop.

The neighbourhood of the dihydrouridine loop of tRNA molecule bound to E. coli ribosome has been studied by affinity labeling, using modified tRNAs carrying photoreactive azidonitrophenyl probes attached to the 3-(3-amino-3-carboxypropyl)-uridine located at position 20:1 of Lupin methionine elongator tRNA. The maximum distance between the pyrimidine ring and the azido group estimated for the two probes employed in this study is 10-11 A and 18-19 A, respectively. Cross-linking of the uncharged, modified tRNAs has been studied with poly(A, U, G) as a message, under conditions directing uncharged tRNAs preferentially to the ribosomal P-site. Modified tRNAs bind covalently to both ribosomal subunits with high yields upon irradiation of the respective non-covalent complexes. Proteins S7, L33 and L1 have been consistently found cross-linked to tRNAs modified with both probes, and S5 and L5 to tRNA modified with the longer probe. Surprisingly, an S5-tRNA cross-linking product is reproducibly found in a protein fraction prepared from the purified 50S subunit. Cross-linking to rRNAs is significant only for the longer probe and is stimulated 2-4 fold in the presence of poly(A,U,G). The cross-linking sites are located between nucleotides 1302 and 1398 in 16S rRNA and between nucleotides 2281 and 2358 in 23S rRNA.     

Ribosomal proteins S7 and L1 are located close to the decoding site of E. coli ribosome--affinity labeling studies with modified tRNAs carrying photoreactive probes attached adjacent to the 3''-end of the anticodon.

Two photoreactive azidonitrophenyl probes have been attached to Yeast methionine elongator tRNA by chemical modification of the N6-(threoninocarbonyl)adenosine located next to the 3'-end of the anticodon. The maximum distance between the purine ring and the azido group estimated for the two probes is 16-17 and 23-24A, respectively. Binding and cross-linking of the uncharged, modified tRNAs to E. coli ribosomes have been studied with and without poly(A,U,G) as a message, under conditions directing uncharged tRNAs preferentially to the P-site. The modified tRNAs retain their binding activity and upon irradiation bind covalently to the ribosome with very high yields. Protein S7 is the major cross-linking target for both modified tRNAs, in the presence or absence of poly(A,U,G). Protein L1 and to a lesser extent proteins L33 and L27 have been found to be cross-linked with the short probe. Cross-linking to 168 rRNA reaches significant levels only in the absence of the message.     

Photochemical cross-linking of yeast tRNA(Phe) containing 8-azidoadenosine at positions 73 and 76 to the Escherichia coli ribosome

The 3'-terminal -A-C-C-A sequence of yeast tRNA(Phe) has been modified by replacing either adenosine-73 or adenosine-76 with the photoreactive analogue 8-azidoadenosine (8N3A). The incorporation of 8N3A into tRNA(Phe) was accomplished by ligation of 8-azidoadenosine 3',5'-bisphosphate to the 3' end of tRNA molecules which were shortened by either one or four nucleotides. Replacement of the 3'-terminal A76 with 8N3A completely blocked aminoacylation of the tRNA. In contrast, the replacement of A73 with 8N3A has virtually no effect on the aminoacylation of tRNA(Phe). Neither substitution hindered binding of the modified tRNAs to Escherichia coli ribosomes in the presence of poly(U). Photoreactive tRNA derivatives bound noncovalently to the ribosomal P site were cross-linked to the 50S subunit upon irradiation at 300 nm. Nonaminoacylated tRNA(Phe) containing 8N3A at either position 73 or position 76 cross-linked exclusively to protein L27. When N-acetylphenylalanyl-tRNA(Phe) containing 8N3A at position 73 was bound to the P site and irradiated, 23S rRNA was the main ribosomal component labeled, while smaller amounts of the tRNA were cross-linked to proteins L27 and L2. Differences in the labeling pattern of nonaminoacylated and aminoacylated tRNA(Phe) containing 8N3A in position 73 suggest that the aminoacyl moiety may play an important role in the proper positioning of the 3' end of tRNA in the ribosomal P site. More generally, the results demonstrate the utility of 8N3A-substituted tRNA probes for the specific labeling of ribosomal components at the peptidyltransferase center.     

Study of the photoaffinity modification of Escherichia coli ribosomes near the donor tRNA-binding center

Affinity labelling of E. coli ribosomes near the donor tRNA-binding (P) site was studied with the use of photoreactive derivatives of tRNAPhe bearing arylazidogroups on N7 atoms of guanine residues (azido-tRNA). UV-irradiation of complexes 70S ribosome.poly(U).azido- tRNA(P-site) and 70S ribosome.poly(U).azido-tRNA(P-site).Phe- tRNAPhe(A-site) resulted in covalent attachment of azido-tRNA to ribosomes, both subunits being labelled. In both cases modification extent of 30S subunit was two-fold than that of the 50S one. It was shown that when the A-site was free the azido-tRNA located in P-site labelled proteins S9, S11, S12, S13, S21 and L14, L27, L31. Azido-tRNA located in P-site when the A-site was occupied with Phe-tRNAPhe labelled proteins S11, S12, S13, S14, S19, L32/L33 and possibly L23, L25. From the comparison of the sets of proteins labelled when A-site was free or occupied a conclusion was drawn that aminoacyl-tRNA located in ribosomal A-site affects the arrangement of deacylated tRNA in P-site. Data obtained allow to propose that proteins S5, S19, S20 and L24, L33 interact with guanine residues important for the tRNA tertiary structure formation.     

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.     

The role of translocation in ribosomal accuracy. Translocation rates for cognate and noncognate aminoacyl- and peptidyl-tRNAs on Escherichia coli ribosomes

The ribosomal translocation, as measured in vitro by peptide formation on poly(U)-programmed Escherichia coli ribosomes in the presence of ternary complex, deacylated tRNA or N-acetyl-Phe-tRNA, and elongation factor G, is the rate-limiting step of protein synthesis. Elongation factor G stimulates the spontaneous translocation by a factor of about 500. N-Acetyl-Phe-Phe-tRNA(Phe E. coli) is translocated with a rate constant of 1-2 s-1 at 25 degrees C. Translocation of N-acetyl-Phe-Phe-tRNA(Phe yeast) and N-acetyl-Phe-Leu-tRNA(Leu E. coli) under identical conditions proceeds with a rate by about a factor of 2 and 10, respectively, more slowly. The translocation rate, therefore, is influenced by the nature of the tRNAs in the A-site. We can show, furthermore, that also the tRNA in the P-site, and presumably in the E-site as well, influences the rate of translocation. Reduced rates of translocation of noncognate peptidyl-tRNAs are accompanied by preferential dissociation of these tRNAs at the beginning of the translation of a mRNA.     

Photoaffinity modification of Escherichia coli ribosomes near the tRNA-binding centers by tRNAPhe derivatives carrying arylazido groups on guanosine residues

Photoreactive derivatives of tRNAPhe (E. coli) bearing arylazido groups scattered statistically over guanosine residues (azido-tRNA) were applied for affinity labelling of E. coli ribosomes in elongation factor-dependent or factor-free model systems mimicking different steps of elongation. It is shown that UV-irradiation of the corresponding complexes of ribosomes with tRNA derivatives results in labelling of both subunits, the 30S one is labelled preferentially. In all experiments only ribosomal proteins were labelled. Comparison of the sets of proteins labelled by tRNA derivatives in different states at P-site allowed us to draw important conclusions concerning the influence of peptidyl moiety and of the occupancy of the A-site with aminoacyl- or peptidyl-tRNA on the arrangement of tRNA located at the P-site. Three of the 30S proteins--S11, S13 S19--are labelled with tRNA derivatives located at P-site in all states.     

Orientation of the tRNA anticodon in the ribosomal P-site: quantitative footprinting with U33-modified, anticodon stem and loop domains.

Binding of transfer RNA (tRNA) to the ribosome involves crucial tRNA-ribosomal RNA (rRNA) interactions. To better understand these interactions, U33-substituted yeast tRNA(Phe) anticodon stem and loop domains (ASLs) were used as probes of anticodon orientation on the ribosome. Orientation of the anticodon in the ribosomal P-site was assessed with a quantitative chemical footprinting method in which protection constants (Kp) quantify protection afforded to individual 16S rRNA P-site nucleosides by tRNA or synthetic ASLs. Chemical footprints of native yeast tRNA(Phe), ASL-U33, as well as ASLs containing 3-methyluridine, cytidine, or deoxyuridine at position 33 (ASL-m3U33, ASL-C33, and ASL-dU33, respectively) were compared. Yeast tRNAPhe and the ASL-U33 protected individual 16S rRNA P-site nucleosides differentially. Ribosomal binding of yeast tRNA(Phe) enhanced protection of C1400, but the ASL-U33 and U33-substituted ASLs did not. Two residues, G926 and G1338 with KpS approximately 50-60 nM, were afforded significantly greater protection by both yeast tRNA(Phe) and the ASL-U33 than other residues, such as A532, A794, C795, and A1339 (KpS approximately 100-200 nM). In contrast, protections of G926 and G1338 were greatly and differentially reduced in quantitative footprints of U33-substituted ASLs as compared with that of the ASL-U33. ASL-m3U33 and ASL-C33 protected G530, A532, A794, C795, and A1339 as well as the ASL-U33. However, protection of G926 and G1338 (KpS between 70 and 340 nM) was significantly reduced in comparison to that of the ASL-U33 (43 and 61 nM, respectively). Though protections of all P-site nucleosides by ASL-dU33 were reduced as compared to that of the ASL-U33, a proportionally greater reduction of G926 and G1338 protections was observed (KpS = 242 and 347 nM, respectively). Thus, G926 and G1338 are important to efficient P-site binding of tRNA. More importantly, when tRNA is bound in the ribosomal P-site, G926 and G1338 of 16S rRNA and the invariant U33 of tRNA are positioned close to each other.     

Changes in subunit conformation and their reciprocal configuration in the transition from the pretranslocated to the posttranslocated state

RNA-protein contacts in pretranslocated and posttranslocated states of E. coli ribosomes have been determined by means of UV-induced cross-linking. In the two functional states as well as in free 70C ribosome, the same proteins are involved in RNA-protein intersubunit contacts, located in the region of L1 protuberance (left side of 70S ribosome). The transition from pre- to posttranslocated state is accompanied by disappearance of RNA-protein contacts in the region of L7/L12 stalk. This favours the locking-unlocking model of the translating ribosome.     

Role of 16S ribosomal RNA methylations in translation initiation in Escherichia coli

Translation initiation from the ribosomal P-site is the specialty of the initiator tRNAs (tRNA(fMet)). Presence of the three consecutive G-C base pairs (G29-C41, G30-C40 and G31-C39) in their anticodon stems, a highly conserved feature of the initiator tRNAs across the three kingdoms of life, has been implicated in their preferential binding to the P-site. How this feature is exploited by ribosomes has remained unclear. Using a genetic screen, we have isolated an Escherichia coli strain, carrying a G122D mutation in folD, which allows initiation with the tRNA(fMet) containing mutations in one, two or all the three G-C base pairs. The strain shows a severe deficiency of methionine and S-adenosylmethionine, and lacks nucleoside methylations in rRNA. Targeted mutations in the methyltransferase genes have revealed a connection between the rRNA modifications and the fundamental process of the initiator tRNA selection by the ribosome.     

Polynucleotide-protein interactions in the translation system. Identification of proteins interacting with tRNA in the A- and P-sites of E. coli ribosomes.

Ultraviolet irradiation (lambda = 254 nm) of ternary complexes of E. coli 70 S ribosomes with poly(U) and either Phe-tRNAPhe (in the A-site) or NAcPhe-tRNAPhe (in the P-site) effectively induces covalent linking of tRNA with a limited number of ribosomal proteins. The data obtained indicate that in both sites tRNA is in contact with proteins of both 30 S and 50 S subunits (S5, S7, S9, S10, L2, L6 and L16 proteins in the A-site and S7, S9, S11, L2, L4, L7/L12 and L27 proteins in the P-site). Similar sets of proteins are in contact with total aminoacyl-tRNA and N-acetylaminoacyl-tRNA. However, here no contacts of tRNA in the P-site with the S7 and L25/S17 proteins were revealed, whereas in the A-site total aminoacyl-tRNA contacts L7/L12. Proteins S9, L2 and, probably, S7 and L7/L12 are common to both sites.     

Locking and unlocking of ribosomal motions

During the ribosomal translocation, the binding of elongation factor G (EF-G) to the pretranslocational ribosome leads to a ratchet-like rotation of the 30S subunit relative to the 50S subunit in the direction of the mRNA movement. By means of cryo-electron microscopy we observe that this rotation is accompanied by a 20 A movement of the L1 stalk of the 50S subunit, implying that this region is involved in the translocation of deacylated tRNAs from the P to the E site. These ribosomal motions can occur only when the P-site tRNA is deacylated. Prior to peptidyl-transfer to the A-site tRNA or peptide removal, the presence of the charged P-site tRNA locks the ribosome and prohibits both of these motions.     

Tertiary structure of Escherichia coli tRNA(3Thr) in solution and interaction of this tRNA with the cognate threonyl-tRNA synthetase

The solution structure of Escherichia coli tRNA(3Thr) (anticodon GGU) and the residues of this tRNA in contact with the alpha 2 dimeric threonyl-tRNA synthetase were studied by chemical and enzymatic footprinting experiments. Alkylation of phosphodiester bonds by ethylnitrosourea and of N-7 positions in guanosines and N-3 positions in cytidines by dimethyl sulphate as well as carbethoxylation of N-7 positions in adenosines by diethyl pyrocarbonate were conducted on different conformers of tRNA(3Thr). The enzymatic structural probes were nuclease S1 and the cobra venom ribonuclease. Results will be compared to those of three other tRNAs, tRNA(Asp), tRNA(Phe) and tRNA(Trp), already mapped with these probes. The reactivity of phosphates towards ethylnitrosourea of the unfolded tRNA was compared to that of the native molecule. The alkylation pattern of tRNA(3Thr) shows some similarities to that of yeast tRNA(Phe) and mammalian tRNA(Trp), especially in the D-arm (positions 19 and 24) and with tRNA(Trp), at position 50, the junction between the variable region and the T-stem. In the T-loop, tRNA(3Thr), similarly to the three other tRNAs, shows protections against alkylation at phosphates 59 and 60. However, tRNA(3Thr) is unique as far as very strong protections are also found for phosphates 55 to 58 in the T-loop. Compared with yeast tRNA(Asp), the main differences in reactivity concern phosphates 19, 24 and 50. Mapping of bases with dimethyl sulphate and diethyl pyrocarbonate reveal conformational similarities with yeast tRNA(Phe). A striking conformational feature of tRNA(3Thr) is found in the 3'-side of its anticodon stem, where G40, surrounded by two G residues, is alkylated under native conditions, in contrast to other G residues in stem regions of tRNAs which are unreactive when sandwiched between two purines. This data is indicative of a perturbed helical conformation in the anticodon stem at the level of the 30-40 base pairs. Footprinting experiments, with chemical and enzymatic probes, on the tRNA complexed with its cognate threonyl-tRNA synthetase indicate significant protections in the anticodon stem and loop region, in the extra-loop, and in the amino acid accepting region. The involvement of the anticodon of tRNA(3Thr) in the recognition process with threonyl-tRNA synthetase was demonstrated by nuclease S1 mapping and by the protection of G34 and G35 against alkylation by dimethyl sulphate. These data are discussed in the light of the tRNA/synthetase recognition problem and of the structural and functional properties of the tRNA-like structure present in the operator region of the thrS mRNA.     

Interaction of tRNAs with the ribosome at the A and P sites.

In vitro transcribed tRNA(Phe) analogues from Escherichia coli containing up to four randomly distributed A, G, U or C phosphorothioated nucleotides were used to investigate contact patterns with the ribosome in the A and P sites. The tRNAs were biologically active. Molecular iodine (I2) can trigger a break in the sugar-phosphate backbone at phosphorothioated positions of the ribosomal bound tRNAs if contacts with ribosomal components do not prevent access of the iodine. Highly differentiated protection patterns were found which were strikingly different in the A and P sites, respectively. Strong protections accumulated in the T psi C loop and no protection was seen in the extra-arm region in both sites, whereas the phosphates in the anticodon loop are more strongly protected in the A site. Strong common protections in both the A and P sites were found neighbouring universally or semi-universally conserved bases in prominent regions of the tertiary structure of tRNAs: Y11, Y32, U33, psi55, C56, A58 and Y60. These bases are therefore candidates for 'identity elements' in ribosomal tRNA recognition. The data further indicate that tRNAs change their conformations upon binding to either ribosomal site.     

A study of the conformation of tRNA(IAGLeu) from the cow mammary gland using chemical modification methods

The nucleosides of tRNA(IAGLeu) (with a long variable loop) from the cow mammary gland included in formation of the three-dimensional structure have been analysed by the chemical modification methods. Exposed guanosine and cytidine residues were detected by means of dimethylsulfate, whereas diethylpyrocarbonate was used to detect exposed adenosine residues. The low level of the modification was characteristic of guanosine residues in positions 10 (m2G), 13, 15, 23, 24, 29, 30, 47 H, 51, 52, 53, 57; of cytidine residues in positions 48 (m5C), 56 and those involved in Watson--Crick pairing; of adenosine residues in positions 14, 22, 31, 42, 59, 64. Most bases of tRNA(IAGLeu) thus detected are similarly located in the yeast tRNA(Phe) molecule, which suggests a common role of these bases in the formation of the spacial structure of both tRNAs.     

Comparison of the tertiary structure of yeast tRNA(Asp) and tRNA(Phe) in solution. Chemical modification study of the bases

A comparative study of the solution structures of yeast tRNA(Asp) and tRNA(Phe) was undertaken with chemical reagents as structural probes. The reactivity of N-7 positions in guanine and adenine residues was assayed with dimethylsulphate and diethyl-pyrocarbonate, respectively, and that of the N-3 position in cytosine residues with dimethylsulphate. Experiments involved statistical modifications of end-labelled tRNAs, followed by splitting at modified positions. The resulting end-labelled oligonucleotides were resolved on polyacrylamide sequencing gels and analysed by autoradiography. Three different experimental conditions were used to follow the progressive denaturation of the two tRNAs. Experiments were done in parallel on tRNA(Asp) and tRNA(Phe) to enable comparison between the two solution structures and to correlate the results with the crystalline conformations of both molecules. Structural differences were detected for G4, G45, G71 and A21: G4 and A21 are reactive in tRNA(Asp) and protected in tRNA(Phe), while G45 and G71 are protected in tRNA(Asp) and reactive in tRNA(Phe). For the N-7 atom of A21, the different reactivity is correlated with the variable variable loop structures in the two tRNAs; in the case of G45 the results are explained by a different stacking of A9 between G45 and residue 46. For G4 and G71, the differential reactivities are linked to a different stacking in both tRNAs. This observation is of general significance for helical stems. If the previous results could be fully explained by the crystal structures, unexpected similarities in solution were found for N-3 alkylation of C56 in the T-loop, which according to crystallography should be reactive in tRNA(Asp). The apparent discrepancy is due to conformational differences between crystalline and solution tRNA(Asp) at the level of the D and T-loop contacts, linked to long-distance effects induced by the quasi-self-complementary anticodon GUC, which favour duplex formation within the crystal, contrarily to solution conditions where the tRNA is essentially in its free state.     

Sense codon-dependent introduction of unnatural amino acids into multiple sites of a protein

Cell-free protein synthesis, driven by a crude S30 extract from Escherichia coli, has been applied to the preparation of proteins containing unnatural amino acids at specific positions. We have developed methods for inactivating tRNA(Asp) and tRNA(Phe) within a crude E. coli tRNA by an antisense treatment and for digesting most of the tRNA within the S30 extract without essential damage to the ribosomal activity. In the present study, we applied these methods to the substitution of Asp and Phe residues of the HIV-1 protease with unnatural amino acids. With 10 mM Mg(2+), the translation efficiency was higher than that with the other tested concentration, and the misreading efficiency was low. The protease mRNA was translated in the presence of an antisense DNA-treated tRNA mixture and 2-naphthylalanyl- and/or p-phenylazophenylalanyl-tRNA. The results suggest that a good portion of the translation products are substituted at all of the seven positions originally occupied by Asp or Phe.     

The ribosomal neighbourhood of the central fold of tRNA: cross-links from position 47 of tRNA located at the A, P or E site.

The naturally occurring nucleotide 3-(3-amino-3-carboxy-propyl)uridine (acp3U) at position 47 of tRNA(Phe) from Escherichia coli was modified with a diazirine derivative and bound to ribosomes in the presence of suitable mRNA analogues under conditions specific for the ribosomal A, P or E sites. After photo-activation at 350 nm the cross-links to ribosomal proteins and RNA were identified by our standard procedures. In the 30S subunit protein S19 (and weakly S9 and S13) was the target of cross-linking from tRNA at the A site, S7, S9 and S13 from the P site and S7 from the E site. Similarly, in the 50S subunit L16 and L27 were cross-linked from the A site, L1, L5, L16, L27 and L33 from the P site and L1 and L33 from the E site. Corresponding cross-links to rRNA were localized by RNase H digestion to the following areas: in 16S rRNA between positions 687 and 727 from the P and E sites, positions 1318 and 1350 (P site) and 1350 and 1387 (E site); in the 23S rRNA between positions 865 and 910 from the A site, 1845 and 1892 (P site), 1892 and 1945 (A site), 2282 and 2358 (P site), 2242 and 2461 (P and E sites), 2461 and 2488 (A site), 2488 and 2539 (all three sites) and 2572 and 2603 (A and P sites). In most (but not all) cases, more precise localizations of the cross-link sites could be made by primer extension analysis.     

tRNA and the guanosinetriphosphatase activity of elongation factor Tu

Different sites of the tRNA molecule influence the activity of the elongation factor Tu (EF-Tu) center for GTP hydrolysis [Parlato, G., Pizzano, R., Picone, D., Guesnet, J., Fasano, O., & Parmeggiani, A. (1983) J. Biol. Chem. 258, 995-1000]. Continuing these studies, we have investigated some aspects of (a) the effect of different tRNA(Phe) species, including Ac-Phe-tRNA(Phe) and 3'-truncated tRNA-CCA in the presence and absence of codon-anticodon interaction, and (b) the effect of occupation of the ribosomal P-site by different tRNA(Phe) species. Surprisingly, we have found that 3'-truncated tRNA can enhance the GTPase activity in the presence of poly(U), in contrast to its inhibitory effect in the absence of codon-anticodon interaction. Moreover, Ac-Phe-tRNA(Phe) was found to have some stimulatory effect on the ribosome EF-Tu GTPase in the presence of poly(U). These results indicate that under specific conditions the 3'-terminal end and a free terminal alpha-NH2 group are not essential for the stimulation of the catalytic center of EF-Tu; therefore, the same structure of the tRNA molecule can act as a stimulator or an inhibitor of EF-Tu functions, depending on the presence of codon-anticodon interaction and on the concentration of monovalent and divalent cations. EF-Tu-GTP does not recognize a free ribosomal P-site from a P-site occupied by the different tRNA(Phe) species. When EF-Tu acts as a component of the ternary complex formed with GTP and aa-tRNA, the presence of tRNA in the P-site strongly increases the GTPase activity.(ABSTRACT TRUNCATED AT 250 WORDS)