Role of the 5'-terminal phosphate of tRNA for its function during protein biosynthesis elongation cycle.

The 5'-terminal phosphate of tRNAPhe from yeast was removed using tRNAPhe lacking its 3'-terminal adenosine. After regeneration of the C-C-A terminus this tRNA was investigated in following reactions: aminoacylation, spontaneous hydrolysis of the amino acid from aminoacyl-tRNA, aminoacyl-tRNA.EF-Tu.GTP ternary complex formation and poly(U)-dependent synthesis of poly(Phe). The absence of the 5'-terminal phosphate of Phe-tRNAPhe does not influence the rate of hydrolysis of the amino acid or the ability of this rRNA to participate in complex formation with EF-Tu.GTP. The translation of the polyuridylic acid is slightly inhibited whereas the rate and extent of the enzymatic aminoacylation is not affected.     

The site of interaction of aminoacyl-tRNA with elongation factor Tu

We have used RNases T1, T2 and A to digest two aminoacyl-tRNAs, Escherichia coli Phe-tRNAPhe and E. coli Met- tRNAMetm both in the naked forms and in ternary complexes with E. coli elongation factor Tu (EF-Tu) and GTP. An analysis of the 'footprinting' results has led to an interpretation that has localized the part of the three-dimensional structure of aminoacyl-tRNA covered by the protein in the ternary complex. In terms of the three-dimensional structure of tRNA established for yeast tRNAPhe, EF-Tu covers the aa-end, aa-stem, T-stem, and extra loop on the side of the L-shaped tRNA that exposes the extra loop.     

The complex formation between Escherichia coli aminoacyl-tRNA, elongation factor Tu and GTP. The effect of the side-chain of the amino acid linked to tRNA

The interaction between Escherichia coli aminoacyl-tRNAs and elongation factor Tu (EF-Tu) x GTP was examined. Ternary complex formation with Phe-tRNAPhe and Lys-tRNALys was compared to that with the respective misaminoacylated Tyr-tRNAPhe and Phe-tRNALys. There was no pronounced difference in the efficiency of aminoacyl-tRNA x EF-Tu x GTP complex formation between Phe-tRNAPhe and Tyr-tRNAPhe. However, Phe-tRNALys was bound preferentially to EF-Tu x GTP as compared to Lys-tRNALys. This was shown by the ability of EF-Tu x GTP to prevent the hydrolysis of the aminoacyl ester linkage of the aminoacyl-tRNA species. Furthermore, gel filtration of ternary complexes revealed that the complex formed with the misaminoacylated tRNALys was also more stable than the one formed with the correctly aminoacylated tRNALys. Both misaminoacylated aminoacyl-tRNA species could participate in the ribosomal peptide elongation reaction. Poly(U)-directed synthesis of poly(Tyr) using Tyr-tRNAPhe occurred to a comparable extent as the synthesis of poly(Phe) with Phe-tRNAPhe. In the translation of poly(A) using native Lys-tRNALys, poly(Lys) reached a lower level than poly(Phe) when Phe-tRNALys was used. It was concluded that the side-chain of the amino acid linked to a tRNA affects the efficiency of the aminoacyl-tRNA x EF-Tu x GTP ternary complex formation.     

Kinetics and thermodynamics of the interaction of elongation factor Tu with elongation factor Ts, guanine nucleotides, and aminoacyl-tRNA

The exchange of elongation factor Tu (EF-Tu)-bound GTP in the presence and absence of elongation factor Ts (EF-Ts) was monitored by equilibrium exchange kinetic procedures. The kinetics of the exchange reaction were found to be consistent with the formation of a ternary complex EF-Tu X GTP X EF-Ts. The equilibrium association constants of EF-Ts to the EF-Tu X GTP complex and of GTP to EF-Tu X EF-Ts were calculated to be 7 X 10(7) and 2 X 10(6) M-1, respectively. The dissociation rate constant of GTP from the ternary complex was found to be 13 s-1. This is 500 times larger than the GTP dissociation rate constant from the EF-Tu X GTP complex (2.5 X 10(-2) s-1). A procedure based on the observation that EF-Tu X GTP protects the aminoacyl-tRNA molecule from phosphodiesterase I-catalyzed hydrolysis was used to study the interactions of EF-Tu X GTP with Val-tRNAVal and Phe-tRNAPhe. Binding constants of Phe-tRNAPhe and Val-tRNAVal to EF-Tu X GTP of 4.8 X 10(7) and 1.2 X 10(7)M-1, respectively, were obtained. The exchange of bound GDP with GTP in solution in the presence of EF-Ts was also examined. The kinetics of the reaction were found to be consistent with a rapid equilibrium mechanism. It was observed that the exchange of bound GDP with free GTP in the presence of a large excess of the latter was accelerated by the addition of aminoacyl-tRNA. On the basis of these observations, a complete mechanism to explain the interactions among EF-Tu, EF-Ts, guanine nucleotides, and aminoacyl-tRNA has been developed.     

Ribosomal proteins interacting with Phe-tRNAPhe during enzymatic binding with translating ribosome before and after the release of the elongation factor EF-Tu

Proteins, directly interacting with tRNA in R- and A-sites of E. coli ribosome were determined by means of ultraviolet-induced RNA-protein cross-links. It is shown, that tRNAPhe in the R-site (upon enzymatic binding of the ternary complex Phe-tRNAPhe. X Tu X GMPPCP to ribosome) directly interact with factor Tu and ribosomal proteins S4, S5, S8 and L6, while in the A-site (upon binding of Phe-tRNAPhe X Tu X GTP, GTP hydrolysis, Tu release and transpeptidation)--with proteins S5, S10, L6, L16 and S13/S14/L27.     

Fluorescence characterization of the interaction of various transfer RNA species with elongation factor Tu.GTP: evidence for a new functional role for elongation factor Tu in protein biosynthesis

The ubiquity of elongation factor Tu (EF-Tu)-dependent conformational changes in amino-acyl-tRNA (aa-tRNA) and the origin of the binding energy associated with aa-tRNA.EF-Tu.GTP ternary complex formation have been examined spectroscopically. Fluorescein was attached covalently to the 4-thiouridine base at position 8 (s4U-8) in each of four elongator tRNAs (Ala, Met-m, Phe, and Val). Although the probes were chemically identical, their emission intensities in the free aa-tRNAs differed by nearly 3-fold, indicating that the dyes were in different environments and hence that the aa-tRNAs had different tertiary structures near s4U-8. Upon association with EF-Tu.GTP, the emission intensities increased by 244%, 57%, or 15% for three aa-tRNAs due to a change in tRNA conformation; the fourth aa-tRNA exhibited no fluorescence change upon binding to EF-Tu.GTP. Despite the great differences in the emission intensities of the free aa-tRNAs and in the magnitudes of their EF-Tu-dependent intensity increases, the emission intensity per aa-tRNA molecule was nearly the same (within 9% of the average) for the four aa-tRNAs when bound to EF-Tu-GTP. Thus, the binding of EF-Tu.GTP induced or selected a tRNA conformation near s4U-8 that was very similar, and possibly the same, for each aa-tRNA species. It therefore appears that EF-Tu functions, at least in part, by minimizing the conformational diversity in aa-tRNAs prior to their beginning the recognition and binding process at the single decoding site on the ribosome. Since an EF-Tu-dependent fluorescence change was also observed with fluorescein-labeled tRNA(Phe), the protein-dependent structural change is effected by direct interactions between EF-Tu and the tRNA and does not require the aminoacyl group. The Kd of the tRNA(Phe).EF-Tu.GTP ternary complex was determined, at equilibrium, to be 2.6 microM by the ability of the unacylated tRNA to compete with fluorescent Phe-tRNA for binding to the protein. Comparison of this Kd with that of the Phe-tRNA ternary complex showed that in this case the aminoacyl moiety contributed 4.3 kcal/mol toward ternary complex formation at 6 degrees C but that the bulk of the binding energy in the ternary complex was derived from direct protein-tRNA interactions.(ABSTRACT TRUNCATED AT 400 WORDS)     

Direct determination of the association constant between elongation factor Tu X GTP and aminoacyl-tRNA using fluorescence

We have investigated the formation of the aa-tRNA X EF-Tu X GTP ternary complex spectroscopically by monitoring a fluorescence change that accompanies the association of EF-Tu X GTP with Phe-tRNAPhe-F8, a functionally active analogue of Phe-tRNAPhe with a fluorescein moiety covalently attached to the s4U-8 base. With this approach, the protein-nucleic acid interaction could be examined by direct means and at equilibrium. The fluorescence emission intensity of each Phe-tRNAPhe-F8 increased by 36-55% upon association with EF-Tu X GTP, depending on the solvent conditions. Thus, when Phe-tRNAPhe-F8 was titrated with EF-Tu X GTP, the extent of ternary complex formation was determined from the increase in emission intensity. A nonlinear least-squares analysis of the titration data yielded a dissociation constant of 0.85 nM for the ternary complex in 50 mM N-(2-hydroxyethyl)piperazine-N'-2-ethanesulfonic acid (pH 7.6), 10 mM MgCl2, and 50 mM NH4Cl, at 6 degrees C. The delta H degrees of this interaction, determined by the temperature dependence of Kd, was -16 kcal/mol; the delta S degrees was therefore -16 cal mol-1 deg-1 at 6 degrees C in this buffer. In a more physiological polycation-containing solvent ("polymix"), the Kd was 4.7 nM. The ionic strength dependence of ternary complex formation showed that a minimum of two salt bridges and a substantial nonelectrostatic contribution are involved in the binding of aa-tRNA to EF-Tu. The affinities of unmodified aa-tRNAs for EF-Tu X GTP were determined by their abilities to compete with the fluorescent aa-tRNA for binding to the protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

Properies of tRNAPhe from yeast carrying a spin label on the 3''-terminal. Interaction with yeast phenylalanyl-tRNA Synthetase and elongation factor Tu from Escherichia coli.

The 2-thioketo function of tRNAPhe-C-s2C-A in which the penultimate cytidine residue is replaced by 20thiocytidine can serve as a site of specific attachment of spin label. By alkylation of tRNAPhe-C-s2C-A with iodoacetamide or its spin label derivatives tRNAPhe-C-(acm)s2C-A or tRNAPheC-(SL)s2C-A are formed. The enzymatic phenylalanylation of these tRNAsPhe revealed that the 2-position of the penultimate cytidine can be modified without impairing this enzymatic reaction but there exists a sterical limitation for the subsituent on this position beyond which the tRNAPhe:phenylalanyl-tRNA synthetase recognition is not possible. Both Phe-tRNAPhe-C-(acm)s2C-A as well as Phe-tRNAPhe-C(SL)s2C-A form ternary complexes with EF-Tu.GTP. The part of the 3'-terminus of tRNAPhe where the additional substituents are attached is therefore not involved in the interaction with this elongation factor. This could be also demonstrated by ESR measurements of spin labelled tRNAsPhe. The correlation times, tauc, for tRNAPhe-C-(SL)s2C-A, Phe-tRNAPhe-C-(SL)s2C-A and Phe-tRNAPhe-C-(SL)s2C-A.EF-Tu:GTP are essentially identical indicating that the structure of the 3'-end of tRNAPhe is not influenced significantly by aminoacylation or ternary complex formation.     

Chemical modification study of aminoacyl-tRNA conformation.

Chemical reactivity of cytosines in 32P-labeled E. coli tRNA1Leu, E. coli tRNAPhe and yeast tRNAPhe before and after aminoacylation was examined by use of a cytosine-specific reagent, semicarbazide-bisulfite mixture. In all the three tRNA species examined, the cytosine residues that were susceptible to the modification were the same in the aminoacylated tRNA and the unacylated tRNA. Only a limited number of the cytosine residues were modifiable: those that occur in the anticodon, the 3'-CCA terminus, the D-loop, and the extra loop. The sites accessible by the reagent are in good agreement with the general three-dimensional structure of tRNA proposed in literature. These results indicate that the gross conformation of these tRNAs does not change on aminoacylation, and consequently favor the view that the T psi C(G) sequence could become exposed in later steps of protein synthesis in order to achieve the binding of aminoacyl tRNA to ribosomes.     

Decoding at the ribosomal A site: antibiotics, misreading and energy of aminoacyl-tRNA binding

The binding of Phe-tRNAPhe at the programmed ribosomal A site has been investigated using antibiotics that influence this binding in different ways. The adhesion of Phe-tRNAPhe, the consumption of GTP and the extent of the peptidyl transfer reaction were monitored. All of the five known misreading-inducing antibiotics that were tested stabilised the binding of Phe-tRNAPhe after its affixture to the A site by EF-Tu with GTP hydrolysis. The stabilisation was sufficient to overcome a single mismatch in the codon-anticodon interaction. Combinations of stabilising and destabilising influences were found to be additive, thus supporting the concepts: (1) that there is a 'correct' binding energy for aminoacyl tRNA in the A site, whose reduction hampers polypeptide synthesis and whose increase makes it inaccurate by by-passing proofreading; and (2) that the different antibiotics affect the bound aminoacyl tRNA at different points.     

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.     

Affinity modification of Escherichia coli ribosomes with the non-hydrolyzed GTP analog, gamma-[4-N-(2-chloroethyl)-N-methylaminobenzyl]amide of GTP

Substituted gamma-amides of GTP viz. GTP gamma-[4-N-(2-chloro- and gamma-[4-N-(2-hydroxyethyl)-N-methylaminobenzyl]amide (CIRCH2NHpppG and OHRCH2NHpppG, resp.) were shown to be unhydrolisable GTP analogues in the EF-Tu-dependent GTP-ase reaction of ribosomes. The reactive analogue, CIRCH2NHpppG, was used for affinity labelling within the 70S ribosome.poly(U).tRNAPhe(P-site).Phe-tRNAPhe.EF-Tu.CIR[14C]CH2.NHpppG complex. Both 50S and 30S subunits were thus labelled but 50S subunit was modified considerably more than 30C subunit. Labelled were proteins L17, L21, S16, S21, and rRNA of both subunits, 23C rRNA within 50C subunit being labelled preferentially as compared with 50C proteins. No labelling of EF-Tu within the complex was detected.     

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.     

Interference of ligands on the phenylalanyl-tRNA synthetase from yeast

The present paper reports a study of the mutual interactions between the substrates, the intermediate, and the products of the aminoacylation reaction, when bound to the phenylalanyl-tRNA synthetase from yeast. The following conclusions can be drawn. a) tRNAPhe displaces Phe-tRNAPhe from the synthetase by lowering the affinity of the enzyme for the aminoacylated tRNA. b) Phe-tRNAPhe and Phe-AMP compete for the catalytically active site of the enzyme. c) Chemically synthesized Phe-AMP, when added to the synthetase, primarily forms a low-affinity complex with the enzyme. The transformation of this complex into the high-affinity catalytic complex is a very slow process. These findings confirm a previous study, based on steady-state kinetics. A schematic representation of the aminoacylation process is given. It summarizes the present and previous results and illustrates a rather complex 'flip-flop' mechanism.     

Effects of nucleotide- and aurodox-induced changes in elongation factor Tu conformation upon its interactions with aminoacyl transfer RNA. A fluorescence study

The effects of GDP and of aurodox (N-methylkirromycin) on the affinity of elongation factor Tu (EF-Tu) for aminoacyl-tRNA (aa-tRNA) have been quantified spectroscopically by using Phe-tRNA(Phe)-Fl8, a functionally active analogue of Phe-tRNA(Phe) with a fluorescein dye convalently attached to the s4U-8 base. The association of EF-Tu.GDP with Phe-tRNA(Phe)-Fl8 resulted in an average increase of 33% in fluorescein emission intensity. This spectral change was used to monitor the extent of ternary complex formation as a function of EF-Tu.GDP concentration, and hence to obtain a dissociation constant, directly and at equilibrium, for the EF-Tu.GDP-containing ternary complex. The Kd for the Phe-tRNA(Phe)-Fl8.EF-Tu.GDP complex was found to average 28.5 microM, more than 33,000-fold greater than the Kd of the Phe-tRNA(Phe)-Fl8.EF-Tu.GTP complex under the same conditions. In terms of free energy, the delta G degree for ternary complex formation at 6 degrees C was -11.5 kcal/mol with GTP and -5.8 kcal/mol with GDP. Thus, the hydrolysis of the ternary complex GTP results in a dramatic decrease in the affinity of EF-Tu for aa-tRNA, thereby facilitating the release of EF-Tu.GDP from the aa-tRNA on the ribosome. Aurodox (200 microM) decreased the Kd of the GDP complex by nearly 20-fold, to 1.46 microM, and increased the Kd of the GTP complex by at least 6-fold. The binding of aurodox to EF-Tu therefore both considerably strengthens EF-Tu.GDP affinity for aa-tRNA and also weakens EF-Tu.GTP affinity for aa-tRNA.(ABSTRACT TRUNCATED AT 250 WORDS)     

Isolation and stability of ternary complexes of elongation factor Tu, GTP and aminoacyl-tRNA.

Intact, native EF-Tu, isolated using previously described methods and fully active in binding GTP, was never found to be fully active in binding aminoacyl-tRNA as judged by high performance liquid chromatography (HPLC) gel filtration and zone-interference gel-electrophoresis. In the presence of kirromycin, however, all these EF-Tu.GTP molecules bind aminoacyl-tRNA, although with a drastically reduced affinity. For the first time, the purification of milligram quantities of ternary complexes of EF-Tu.GTP and aminoacyl-tRNA, free of deacylated tRNA and inactive EF-Tu, has become possible using HPLC gel filtration. We also describe an alternative new method for the isolation of the ternary complexes by means of fractional extraction in the presence of polyethylene glycol. In the latter procedure, the solubility characteristics of the ternary complexes are highly reminiscent to those of free tRNA. Concentrated samples of EF-Tu.GMPPNP.aminoacyl-tRNA complexes show a high stability.     

Interaction of mitochondrial elongation factor Tu with aminoacyl-tRNA and elongation factor Ts

Elongation factor (EF) Tu promotes the binding of aminoacyl-tRNA (aa-tRNA) to the acceptor site of the ribosome. This process requires the formation of a ternary complex (EF-Tu.GTP.aa-tRNA). EF-Tu is released from the ribosome as an EF-Tu.GDP complex. Exchange of GDP for GTP is carried out through the formation of a complex with EF-Ts (EF-Tu.Ts). Mammalian mitochondrial EF-Tu (EF-Tu(mt)) differs from the corresponding prokaryotic factors in having a much lower affinity for guanine nucleotides. To further understand the EF-Tu(mt) subcycle, the dissociation constants for the release of aa-tRNA from the ternary complex (K(tRNA)) and for the dissociation of the EF-Tu.Ts(mt) complex (K(Ts)) were investigated. The equilibrium dissociation constant for the ternary complex was 18 +/- 4 nm, which is close to that observed in the prokaryotic system. The kinetic dissociation rate constant for the ternary complex was 7.3 x 10(-)(4) s(-)(1), which is essentially equivalent to that observed for the ternary complex in Escherichia coli. The binding of EF-Tu(mt) to EF-Ts(mt) is mutually exclusive with the formation of the ternary complex. K(Ts) was determined by quantifying the effects of increasing concentrations of EF-Ts(mt) on the amount of ternary complex formed with EF-Tu(mt). The value obtained for K(Ts) (5.5 +/- 1.3 nm) is comparable to the value of K(tRNA).     

Affinities of tRNA binding sites of ribosomes from Escherichia coli

The binding affinities of tRNAPhe, Phe-tRNAPhe, and N-AcPhe-tRNAPhe from either Escherichia coli or yeast to the P, A, and E sites of E. coli 70S ribosomes were determined at various ionic conditions. For the titrations, both equilibrium (fluorescence) and nonequilibrium (filtration) techniques were used. Site-specific rather than stoichiometric binding constants were determined by taking advantage of the varying affinities, stabilities, and specificities of the three binding sites. The P site of poly(U)-programmed ribosomes binds tRNAPhe and N-AcPhe-tRNAPhe with binding constants in the range of 10(8) M-1 and 5 X 10(9) M-1, respectively. Binding to the A site is 10-200 times weaker, depending on the Mg2+ concentration. Phe-tRNAPhe binds to the A site with a similar affinity. Coupling A site binding of Phe-tRNAPhe to GTP hydrolysis, by the addition of elongation factor Tu and GTP, leads to an apparent increase of the equilibrium constant by at least a factor of 10(4). Upon omission of poly(U), the affinity of the P site is lowered by 2-4 orders of magnitude, depending on the ionic conditions, while A site binding is not detectable anymore. The affinity of the E site, which specifically binds deacylated tRNAPhe, is comparable to that of the A site. In contrast to P and A sites, binding to the E site is labile and insensitive to changes of the ionic strength. Omission of the mRNA lowers the affinity at most by a factor of 4, suggesting that there is no efficient codon-anticodon interaction in the E site. On the basis of the equilibrium constants, the displacement step of translocation, to be exergonic, requires that the tRNA leaving the P site is bound to the E site. Under in vivo conditions, the functional role of transient binding of the leaving tRNA to the E site, or a related site, most likely is to enhance the rate of translocation.     

Specificity of elongation factor Tu from Escherichia coli with respect to attachment to the amino acid to the 2' or 3'-hydroxyl group of the terminal adenosine of tRNA.

Modified Tyr-tRNATyr and Phe-tRNAPhe species from yeast having the aminoacyl residue bound specifically to the 2' and 3' position of the terminal adenosine, respectively, were investigated for their ability to form ternary complexes with Escherichia coli elongation factor Tu and GTP. Both Tyr-tRNATyr-CpCpA (2'd) and Tyr-tRNATyr-CpCpA(3' d) derivatives which are esterified with the amino acid on the 3' and 2' position respectively and which lack the vicinal hydroxyl were able to form ternary complexes. The stability of these ternary complexes was lower than in the case of native Tyr-tRNATyr-CpCpA. Tyr-tRNATyr-CpCpA(3' d) having the amino acid attached to the 2' position interacted considerably more strongly with EF-Tu - GTP than Tyr-tRNATyr-CpCpA(2' d). Ternary complex formation was observed with neither Phe-tRNAPhe-CpCpA(2'NH2) nor Phe-tRNAPhe-CpCpA(3'NH2). It is concluded that 2' as well as 3' isomers of native aminoacyl-tRNA can be utilized for ternary complex formation but in a following step a uniform 2'-aminoacyl-tRNA - EF-Tu - GTP complex is formed. Although the free vicinal hydroxyl group of the terminal adenosine is not absolutely required, replacement of the ester linkage through with the amino acid is attached to tRNA by an amide linkage leads to loss of ability to interact with elongation factor Tu.     

Interaction between initiator Met-tRNAfMet and elongation factor EF-Tu from E. coli

It has recently been shown that the non-formylated initiator Met-tRNAfMet from E. coli can form a stable ternary complex with the elongation factor EF-Tu and GTP. Using the protection of EF-Tu:GTP against spontaneous hydrolysis of the aminoacylester bond of Met-tRNAfMet, we confirm these results, and show that the protection is specific for the non-formylated form of the initiator tRNA. The ternary complex Met-tRNAfMet:EF-Tu:GTP can be isolated by column chromatography in a way similar to that demonstrated previously with EF-Tu complexed to the elongator Met-tRNAmMet. 32P-labeled Met-tRNAfMet within the ternary complex was analyzed by the footprinting technique. The pattern of initiator tRNA protection by EF-Tu against ribonuclease digestion is not significantly different from the one found previously for elongator tRNAs. These results lead us to suggest that the initiator tRNAfMet, under growth conditions which do not permit formylation, may to some extent function as an elongator tRNA.