Kinetic studies of Escherichia coli elongation factor Tu-guanosine 5'-triphosphate-aminoacyl-tRNA complexes

A new method for measuring the dissociation rate of the Escherichia coli elongation factor Tu-GTP--aminoacyl-tRNA complex has been developed and applied to the determination of the dissociation rates of ternary complexes formed between E. coli EF-Tu-GTP and a set of E. coli aminoacyl-tRNAs. The set of aminoacyl-tRNAs includes at least one tRNA coding for each of the 20 amino acids as well as purified isoacceptor tRNA species for arginine, glycine, leucine, lysine, and tyrosine. The results reveal that the dissociation rates vary for each ternary complex. Tu-GTP-Gln-tRNA dissociates the slowest and Tu-GTP-Val-tRNA the fastest of all noninitiator ternary complexes at 4 degrees C, pH 7.4. The equilibrium dissociation constant for Tu-GTP-Thr-tRNA has been determined to be 1.3 (0.4) X 10(-9) M under identical reaction conditions, and the absolute value of the equilibrium dissociation constant has been calculated for 28 ternary complexes from the relative equilibrium dissociation constant ratios previously measured [Louie, A., Ribeiro, N. S., Reid, B. R., & Jurnak, F. (1984) J. Biol. Chem. 259, 5010-5016]. The association rate of each ternary complex has been estimated from the ratio of the dissociation rate relative to the equilibrium dissociation constant. Tu-GTP-His-tRNA associates the fastest and Tu-GTP-Leu-tRNA1Leu the slowest. By inclusion of Tu-GTP-Met-tRNAfMet in the studies, evidence has been obtained that suggests that the initiator ternary complex does not function in the elongation cycle because the dissociation rate of the complex is very fast.     

Study of the transfer RNAs coded by T2, T4, and T6 bacteriophages.

T2, T4, and T6 bacteriophage tRNAs coding for arginine, leucine, proline, isoleucine, and glycine were isolated under conditions of short term and long term infection of Escherichia coli B cells. The corresponding phage tRNA species were examined for sequence homology by RNA-DNA hybridization analysis and by their relative behavior on reversed phase chromatography. The results indicate that all three T-even phages code for similar tRNA species; however, some tRNA species are homologous, others are not, and not all of the same tRNA species are coded by each bacteriophage. Reversed phase chromatography showed the presence of isoacceptor tRNAs for each phage aminoacyl-tRNA species. Pulse-chase experiments for [32P]tRNAGly suggest that the multiple isoacceptor species observed derive from the intracellular modification of a single tRNAGly gene product.     

Negative correlation between the abundance of Escherichia coli aminoacyl-tRNA families and their affinities for elongation factor Tu-GTP

The number of aminoacyl-tRNA molecules in Escherichia coli cells varies by about one order of magnitude from 730 (glutaminyl-tRNA) to 7900 (valyl-tRNA). Relative affinities of E. coli aminoacyl-tRNA for elongation factor Tu-GTP vary also by about one order of magnitude from 2.08 (glutaminyl-tRNA) to 0.15 (valyl-tRNA). The relationship between the abundance of all 20 aminoacyl-tRNA families in 5 E. coli strains and their affinities for elongation factor Tu-GTP was examined by statistical methods. Negative correlation between the two parameters was found. The correlation coefficient was -0.62 to -0.52 with significance level 0.01. Regression analysis give the following formula for the relation between relative abundance of aminoacyl-tRNA families (x) and their relative affinities for elongation factor Tu-GTP (y): y = 1.25 - 0.25x. The analyses indicate that those aminoacyl-tRNA families that are present in cells in low copy number exhibit higher affinity than the more abundant aminoacyl-tRNA families for elongation factor Tu-GTP. The bacterial protein biosynthetic apparatus evolved in such a way as to compensate for a low copy number of some aminoacyl-tRNAs by tight binding of the aminoacyl-tRNA to elongation factor Tu-GTP. This may assure adequate supply of low copy number aminoacyl-tRNAs under conditions of limitation in elongation factor Tu-GTP, e.g. during stringent response, and is consistent with the idea of elongation factor Tu-GTP modulating translational efficiencies of aminoacyl-tRNAs.     

Kirromycin drastically reduces the affinity of Escherichia coli elongation factor Tu for aminoacyl-tRNA

We have studied the interaction between EF-Tu-GDP or EF-Tu-GTP in complex with kirromycin or aurodox (N1-methylkirromycin) and aminoacyl-tRNA, N-acetylaminoacyl-tRNA, or deacylated tRNA. Three independent methods were used: zone-interference gel electrophoresis, GTPase stimulation, and fluorescence. All three methods revealed that kirromycin induces a severe drop in the stability of the complex of EF-Tu-GTP and aminoacyl-tRNA of about 3 orders of magnitude. The affinities of EF-Tu-kirromycin-GTP and EF-Tu-kirromycin-GDP for aa-tRNA were found to be of about the same order of magnitude. We conclude that kirromycin and related compounds do not induce a so-called GTP-like conformation of EF-Tu with respect to tRNA binding. The findings shed new light on the mechanism of action of the antibiotic during the elongation cycle. In contrast to indirect evidence previously obtained in our laboratory [Van Noort et al. (1982) EMBO J. 1, 1199-1205; Van Noort et al. (1986) Proc. Natl. Acad. Sci. U.S.A. 71, 4910-4914], we were unable to demonstrate complexes of EF-Tu-aurodox-GTP/GDP with N-acetylaminoacyl-tRNA or deacylated tRNA by direct detection using zone-interference gel electrophoresis. Modification with N-tosyl-L-phenylalanine chloromethyl ketone (TPCK) decreases the affinity of EF-Tu-kirromycin-GTP for aminoacyl-tRNA, just like it does in the absence of the antibiotic.     

Effect of trypsin modification of the Escherichia coli elongation factor Tu on the ternary complex with aminoacyl-tRNA

The ribonuclease resistance assay has been used to probe the effect of trypsin modification of the Escherichia coli elongation factor Tu X GTP on the interaction with E. coli aminoacyl-tRNAs. First, the equilibrium dissociation constant of the trypsin-modified Tu X GTP X Thr-tRNA complex was determined to be 2.3 (0.1) X 10(-5)M at 4 degrees C, pH 7.4. Second, binding of 17 of 20 noninitiator aminoacyl-tRNAs and four sets of purified isoacceptor tRNAs to the modified protein was measured. At 4 degrees C, the complex stabilities vary 500-fold over the range of aminoacyl-tRNAs, with Gln-tRNA forming the strongest ternary complex and Val-tRNA, the weakest. The results are compared to a similar study of ternary complex formation using intact elongation factor Tu X GTP, and the major differences are discussed. An analysis of both data sets, particularly that for the leucine isoacceptor tRNAs, suggests that the trypsin modification of elongation factor Tu X GTP disrupts a region of protein that is involved with the aminoacyl side chain rather than that of the acceptor stem helix region of the aminoacyl-tRNA.     

The bacterial YbaK protein is a Cys-tRNAPro and Cys-tRNA Cys deacylase

Bacterial prolyl-tRNA synthetases and some smaller paralogs, YbaK and ProX, can hydrolyze misacylated Cys-tRNA Pro or Ala-tRNA Pro. To assess the significance of this quality control editing reaction in vivo, we tested Escherichia coli ybaK for its ability to suppress the E. coli thymidylate synthase thyA:146CCA missense mutant strain, which requires Cys-tRNA(Pro) for growth in the absence of thymine. Missense suppression was observed in a ybaK deletion background, suggesting that YbaK functions as a Cys-tRNA Pro deacylase in vivo. In vitro studies with the full set of 20 E. coli aminoacyl-tRNAs revealed that the Haemophilus influenzae and E. coli YbaK proteins are moderately general aminoacyl-tRNA deacylases that preferentially hydrolyze Cys-tRNA Pro and Cys-tRNA Cys and are also weak deacylases that cleave Gly-tRNA, Ala-tRNA, Ser-tRNA, Pro-tRNA, and Met-tRNA. The ProX protein acted as an aminoacyl-tRNA deacylase that cleaves preferentially Ala-tRNA and Gly-tRNA. The potential of H. influenzae YbaK to hydrolyze in vivo correctly charged Cys-tRNA Cys was tested in E. coli strain X2913 (ybaK+). Overexpression of H. influenzae ybaK decreased the in vivo ratio of Cys-tRNA Cys to tRNA Cys from 65 to 35% and reduced the growth rate of strain X2913 by 30% in LB medium. These data suggest that YbaK-mediated hydrolysis of aminoacyl-tRNA can influence cell growth.     

The effect of mutations in EF-Tu on its affinity for tRNA as measured by two novel and independent methods of general applicability

Elongation factor Tu is essential for binding and a correct delivery of aminoacyl-tRNA during protein biosynthesis. For a good characterization of its interaction with tRNA in terms of structure-function relationship, determinations of kinetic equilibrium parameters are of great value. We describe two novel methods for that purpose. One method is based on EF-Tu protection of the tRNA 3' acceptor end against RNase A cleavage and yields the Kd value together with the corresponding dissociation and association rate constants from one single set of experiments. The other is a rapid method for screening relative affinities of mutant EF-Tus for tRNA. It is based on competition between EF-Tu species with and without a (His)6 extension for the same aminoacyl-tRNA and yields a relative Kd value. The method can be of general importance for the measuring of ligand affinities of all sorts of His-tagged proteins. Both methods are illustrated by their application in the analysis of mutant EF-Tus with changed interactions with tRNA and antibiotics. Raising the assay temperature from 4 to 37 degrees C causes a 30-fold increase of Kd for EF-Tu x GTP x Phe-tRNA complexes. The mutation K237E leads to rapid inactivation at the latter temperature. A parallel is found between the order of increasing Kd values for EF-Tus with mutation G316D, A375T and Q124K, respectively, and their order of increasing resistance to kirromycin.     

Rates of aminoacyl-tRNA selection at 29 sense codons in vivo

We have placed aminoacyl-tRNA selection at individual codons in competition with a frameshift that is assumed to have a uniform rate. By assaying a reporter in the shifted frame, relative rates for association of the 29 YNN codons and their cognate aminoacyl-tRNAs were obtained during logarithmic growth in Escherichia coli. For five codons, three beginning with C and two with U, these relative rates agree with relative in vitro rates for elongation factor Tu-mediated aminoacyl-tRNA binding to ribosomes and subsequent GTP hydrolysis. Therefore, the frameshift assay probably measures this process in vivo. Observed rates for aminoacyl-tRNA selection span a 25-fold range. Therefore, the time required to transit different codons in vivo probably differs substantially. Codons very frequently used in highly expressed genes generally select aminoacyl-tRNAs more quickly than do rarely used codons. This suggests that speed of aminoacyl-tRNA selection is a significant factor determining biased use of synonymous codons. However, the preferential use of codons appears to be marked only for codons with the highest rates of aminoacyl-tRNA selection. Rapid selection in vivo is usually effected by elevation of the tRNA concentration for codons with moderate intrinsic speed (rate constant), not by choosing intrinsically fast codons. Despite a preference for high rate, there are quickly translated codons that are not commonly used, and common codons that are translated relatively slowly. Other factors are therefore more important than speed for some codons. Strong preference for rapid aminoacyl-tRNA selection is not observed in weakly expressed genes. Instead, there is a slight preference for slower aminoacyl-tRNA selection. The rate of aminoacyl-tRNA selection by a YNC codon is always greater than the rate of the corresponding YNU codon even though in many YNC/U pairs both codons react with the same elongation factor Tu/GTP/aminoacyl-tRNA complex. Thus, for these tRNAs, the differences between in vivo rate constants of tRNAs are dependent on the nature of anticodon base-pairing. However, no more general relationship is evident between codon/anticodon composition and rate of aminoacyl-tRNA selection. The frameshift method can be extended to all codons.     

Separation of aminoacyl-transfer RNAs by polyacrylamide gel electrophoresis

A polyacrylamide gel electrophoresis system for separating $\text{E.}$$\text{coli}$ tRNAs and aminoacyl-tRNAs is described. The tRNA was separated into 6 discrete bands which contained varyin aamounts of tRNA and therefore varying numbers of tRNA species. In order to locate specific tRNAs, tRNA was charged with a ¹⁴C amino acid and the aminoacyl-tRNA was located by autoradiography. With several amino acids, 2 isoaccepting species were found. In total, 30 aminoacyl-tRNAs were located.     

STRUCTURAL ALTERATIONS OF AMINO ACIDS AT THE LEVEL OF AMINOACYL-tRNAS: IDENTIFICATION OF THE TRANSFORMATION PRODUCTS OF DICARBOXYLIC AMINO ACIDS

Abstract— Glutamyl-, glutaminyl-, aspartyl- and asparaginyl-tRNAs were separated into different isoacceptor species by reverse phase column chromatography. RNase hydrolysates of any of the isoacceptor [¹⁴C]aminoacyl-tRNAs for a given amino acid gave radioactivity profiles, on paper electrophoresis, very similar to unfractionated tRNA. This suggested a lack of tRNA specificity for the transformation reaction involving the aminoacyl moieties of asparaginyl and glutaminyl-tRNAs. GnP₂ and AnP₂ detected in the products of deaminoacylation of glutaminyl and asparaginyl-tRNA showed a number of properties in common with GnE₃ and AnE₃ present in the RNase hydrolysates of the same tRNAs. Thus, GnP₂ and GnE₃ chromatographed in the same position in the phenol: water solvent and both yielded glutamate on acid hydrolysis and a mixture of glutamine and isoglutamine on alkaline hydrolysis. Similarly, AnP₂ and AnE₃ had the same R_F value in phenol :water chromatography and gave aspartate or a mixture of asparagine and isoasparagine when hydrolyzed with acid or alkali. On the basis of these results and other evidence, GnP₂ and GnE₃ were assigned the structure, α-aminoglutarimide; AnP₂ and AnE₃ were identified as α-aminosuccinimide. These cyclic compounds are presumed to be formed by nucleophilic attack of the amide nitrogen of asparagine or glutamine on the carbon of the aminoacyl ester carbonyl group. The cyclization-deesterification appeared to be facilitated by RNase hydrolysis of aminoacyl-tRNA indicating that the aminoacyl-tRNA is probably more resistant to this reaction than aminoacyladenosine. Neither the imides nor the amino acid isoamides were detected in the reaction mixture in which aminoacylation of tRNA was performed, suggesting that a mechanism may exist for inhibition of the cyclization reaction under conditions of active aminoacylation.     

Antibody nucleic acid complexes. Immunospecific retention of N6-methyladenosine-containing transfer ribonucleic acid.

Antibodies specific for N6-methyladenosine (m6A) were immobilized on Sepharose and the resulting immunoadsorbent was tested for its ability to retain those Escherichia coli tRNAs containing the antigenic hapten, i.e., m6A. Results obtained with [32P]PO4- and [methyl-3H]-methionine-labeled tRNAs indicated that approximately 3 to 5% of the radioactive RNA was retained by the immunoadsorbent. Under identical conditions, but in the presence of m6A (1 mg/mL), less than 0.2% of the radioactivity was retained. Subsequent characterization of the retained tRNA via (a) analysis of methyl-3H-labeled, methylated nucleosides, (b) two-dimensional gel electrophoresis, and (c) analysis of the retention of [3H]aminoacyl-tRNA species led to the conclusion that the anti-m6A/Sepharose adsorbent quantitatively and exclusively retained a single tRNA species containing m6A, namely, tRNAVal.     

Competition of aminoacyl-tRNA synthetases for tRNA ensures the accuracy of aminoacylation.

The accuracy of protein biosynthesis rests on the high fidelity with which aminoacyl-tRNA synthetases discriminate between tRNAs. Correct aminoacylation depends not only on identity elements (nucleotides in certain positions) in tRNA (1), but also on competition between different synthetases for a given tRNA (2). Here we describe in vivo and in vitro experiments which demonstrate how variations in the levels of synthetases and tRNA affect the accuracy of aminoacylation. We show in vivo that concurrent overexpression of Escherichia coli tyrosyl-tRNA synthetase abolishes misacylation of supF tRNA(Tyr) with glutamine in vivo by overproduced glutaminyl-tRNA synthetase. In an in vitro competition assay, we have confirmed that the overproduction mischarging phenomenon observed in vivo is due to competition between the synthetases at the level of aminoacylation. Likewise, we have been able to examine the role competition plays in the identity of a non-suppressor tRNA of ambiguous identity, tRNA(Glu). Finally, with this assay, we show that the identity of a tRNA and the accuracy with which it is recognized depend on the relative affinities of the synthetases for the tRNA. The in vitro competition assay represents a general method of obtaining qualitative information on tRNA identity in a competitive environment (usually only found in vivo) during a defined step in protein biosynthesis, aminoacylation. In addition, we show that the discriminator base (position 73) and the first base of the anticodon are important for recognition by E. coli tyrosyl-tRNA synthetase.     

The specificity of aminoacylation: a tRNA-tRNA interaction model.

Most of the isoacceptor species for a particular tRNA can be classified according to the middle base in the anticodon together with the fourth base in the amino acid stem. These specifying nucleotides would operate if a tRNA-tRNA interaction occurs on the aminoacyl-tRNA synthetase so that the anticodon of one tRNA molecule faces the fourth base of the other tRNA molecule. This model explains most of the misacylation reactions or changes in aminoacylation after mutation or chemical modifications of tRNAs. It also provides an explanation for biochemical properties of the aminoacyl-tRNA synthetases such as the presence of two active sites, and for the high fidelity of the aminoacylation. It may give insight into the origin and stability of the genetic code.     

A single amidotransferase forms asparaginyl-tRNA and glutaminyl-tRNA in Chlamydia trachomatis

Aminoacyl-tRNA is generally formed by aminoacyl-tRNA synthetases, a family of 20 enzymes essential for accurate protein synthesis. However, most bacteria generate one of the two amide aminoacyl-tRNAs, Asn-tRNA or Gln-tRNA, by transamidation of mischarged Asp-tRNA(Asn) or Glu-tRNA(Gln) catalyzed by a heterotrimeric amidotransferase (encoded by the gatA, gatB, and gatC genes). The Chlamydia trachomatis genome sequence reveals genes for 18 synthetases, whereas those for asparaginyl-tRNA synthetase and glutaminyl-tRNA synthetase are absent. Yet the genome harbors three gat genes in an operon-like arrangement (gatCAB). We reasoned that Chlamydia uses the gatCAB-encoded amidotransferase to generate both Asn-tRNA and Gln-tRNA. C. trachomatis aspartyl-tRNA synthetase and glutamyl-tRNA synthetase were shown to be non-discriminating synthetases that form the misacylated tRNA(Asn) and tRNA(Gln) species. A preparation of pure heterotrimeric recombinant C. trachomatis amidotransferase converted Asp-tRNA(Asn) and Glu-tRNA(Gln) into Asn-tRNA and Gln-tRNA, respectively. The enzyme used glutamine, asparagine, or ammonia as amide donors in the presence of either ATP or GTP. These results suggest that C. trachomatis employs the dual specificity gatCAB-encoded amidotransferase and 18 aminoacyl-tRNA synthetases to create the complete set of 20 aminoacyl-tRNAs.     

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.     

Stability and separation of aminoacyl-transfer RNAs on chromatography columns

In order to demonstrate that the apparent amount of a tRNA isoacceptor depends on the column matrix employed, chromatographic separations of lysyl tRNAs on several polystyrene anion exchangers and on a reversed-phase matrix (RPC-5) have been studied. Experiments were carried out to distinguish between the actual yield of isoacceptors (aminoacylated and free species) and the apparent yield of isoacceptors (aminoacylated species only). The results indicate that several polystyrene anion exchangers with similar physical properties resolve lysyl tRNAs differently. The differences are noted in the apparent yields and in the degree of chromatographic resolution. When fire column matrices are incubated separately with [³H]lysyl tRNAs and the deacylations measured, the results indicate chemical deacylation by two polystyrene anion exchange matrices but not by two other polystyrene matrices or by RPC-5. Further study of two major isoacceptors of lysyl-tRNA on these column matrices confirm that different matrices cause chemical deacylation of the aminoacyl tRNA bond at different rates. Therefore, the apparent yield of an isoacceptor depends upon the column matrix. The dissociation of the ester bond of the aminoacyl tRNA appears to be catalysed by the quaternary ammonium groups of the matrix. Enhanced deesterification of the aminoacyl tRNA bond is noted in slightly alkaline eluants, suggesting a nucleophilic attack by the hydroxyl anion of the medium. The major conclusion to be drawn is that both the yield and relative amounts of isoacceptors are dependent not only upon the resolving power of the column matrix, but also upon the physical and chemical nature of the matrix and upon the experimental conditions employed. This catalytic effect is in addition to the base-catalysed de-esterification promoted by the residual primary, secondary or tertiary amine groups present in the polystyrene anion exchangers.     

Acceptor activity, isoacceptor profiles and function in protein synthesis of transfer RNAs from regenerating skeletal muscle

Transfer RNAs have been prepared from control and regenerating rat skeletal muscle. The yield of tRNA is highest during the early stages of the regeneration process (5 and 8 days following the induction of regeneration) and decreases to near control values thereafter. The amino acid acceptor activity (extent of aminoacylation) of tRNA from regenerating muscle was also found to be higher for some amino acids than the activity of control tRNA, and the maximum increase in activity was observed between 5 and 8 days following the initiation of regeneration with a decrease to control levels through 15 and 30 days. The isoacceptor pattern, determined by RPC-5 chromatography, for methionyl-tRNAs from control muscle and 5-day regenerating muscle were essentially indistinguishable, while a minor peak of prolyl-tRNA was observed in the population from 5-, 8- and 15-day regenerates which was apparently absent from the control tRNA. Lysyl-tRNAs from control muscle contain two major isoacceptors while a third isoacceptor is observed in the tRNA preparations from 5-, 8- and 15-day regenerating muscle. The relative amount of this third isoacceptor is highest in the 8-day population and decreases in amount in tRNAs from 15- and 30-day regenerates. Control muscle also contains two major glutamyl-tRNA species while a third isoacceptor can be detected in regenerates. The relative amount of this species increases during the early course of the regeneration process but is present at near control levels by 30 days following Marcaine injection. Cell-free protein synthesis using muscle polyribosomes showed that tRNAs from regenerating muscle were more effective in stimulating [³⁵S]methionine incorporation than tRNAs from control muscle.     

The complex between ribosomal proteins and aminoacyl-tRNA: the interactions and hydrolytic activities are not confined to the proteins L2 and L16 of Escherichia coli ribosomes

The capacity of some Escherichia coli (E. coli) ribosomal proteins to bind to tRNA and to hydrolyse their aminoacylated derivatives has been analysed. The following results were obtained: (1) The basic proteins L2, L16 and L33 and S20 bound f[3H]Met-tRNA to a similar extent as the total proteins from 30 S (TP30) or 50 S (TP50) when tested by nitrocellulose filtration, in contrast to the more acidic proteins L7/L12 and S8. (2) The proteins of the peptidyltransferase centre, L2 and L16, showed no distinct specificity, binding various charged tRNAs from E. coli and Saccharomyces cerevisiae (S. cerevisiae). (3) A number of isolated ribosomal proteins hydrolysed aminoacyl-tRNA as assessed by trichloroacetic acid precipitation, in contrast to the TP30 and TP50. (4) The loss of radiolabel from Ac[14C]Phe-tRNA and from [14C]tRNA in the presence of these proteins could not be prevented by RNasin, a ribonuclease inhibitor, whereas that mediated by a sample of non-RNase-free bovine serum albumin was inhibited. (5) When double-labelled, Ac[3H]Phe-[14C]tRNA was incubated with L2 both radiolabels were lost, indicating that this potential candidate for a peptidyltransferase enzyme does not specifically cleave the ester bond between the aminoacyl residue and the tRNA.     

Interaction of elongation factor Tu from Escherichia coli with aminoacyl-tRNA carrying a fluorescent reporter group on the 3' terminus

Transfer ribonucleic acids containing 2-thiocytidine in position 75 ([s2C]tRNAs) were prepared by incorporation of the corresponding cytidine analogue into 3'-shortened tRNA using ATP(CTP):tRNA nucleotidyltransferase. [s2C]tRNA was selectively alkylated with fluorescent N-iodoacetyl-N'-(5-sulfo-1-naphthyl)ethylenediamine (1,5-I-AEDANS) on the 2-thiocytidine residue. The product [AEDANS-s2C]aminoacyl-tRNA, forms a ternary complex with Escherichia coli elongation factor Tu and GTP, leading to up to 130% fluorescence enhancement of the AEDANS chromophore. From fluorescence titration experiments, equilibrium dissociation constants of 0.24 nM, 0.22 nM and 0.60 nM were determined for yeast [AEDANS-s2C]Tyr-tRNATyr, yeast Tyr-tRNATyr, and the homologous E. coli Phe-tRNAPhe, respectively, interacting with E. coli elongation factor Tu.GTP. The measurement of the association and dissociation rates of the interaction of [AEDANS-s2C]Tyr-tRNATyr with EF-Tu.GTP and the temperature dependence of the resulting dissociation constants gave values of 55 J mol-1 K-1 for delta S degrees' and -34.7 kJ mol-1 for delta H degrees' of this reaction.