The influence of elongation-factor-Tu . GTP and anticodon-anticodon interactions on the anticodon loop conformation of yeast tRNATyr

Effect of elongation factor Tu on the conformation of phenylalanyl-tRNAPhe

Structural features of the tRNAPhe molecule upon ternary complex formation with the bacterial elongation factor Tu were investigated. Phosphodiester bonds at positions 18 and 34 were found to be labilized in bound tRNA. Conversely, a higher stability of the phosphodiester links at positions 20, 21 and 36 was detected. Using ethylnitrosourea as a chemical probe a conformational change occurring at phosphate position 53 was observed in complexed tRNA. These results are interpreted by a structural rearrangement of the nucleic acid induced by complex formation.

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.

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.

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

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

The conformation of the initiator tRNA and of the 16S rRNA from Escherichia coli during the formation of the 30S initiation complex

The conformation of the E. coli initiator tRNA and of the 16S rRNA at different steps leading to the 30S.IF2.fMet-ARN(fMet).AUG.GTP complex has been investigated using several structure-specific probes. As compared to elongator tRNA, the initiator tRNA exhibits specific structural features in the anticodon arm, the T and D loops and the acceptor arm. Initiation factor 2 (IF2) interacts with the T-loop and the minor groove of the T stem of the RNA, and induces an increased flexibility in the anticodon arm. In the 30S initiation complex, additional protection is observed in the acceptor stem and in the anticodon arm of the tRNA. Within the 30S subunit, IF2 does not significantly shield defined portions of 16S rRNA, but induces both reduction and enhancement of reactivity scattered in the entire molecule. Most are constrained in a region corresponding to the cleft, the lateral protrusion and the part of the head facing the protrusion. All the reactivity changes induced by the binding of IF2 are still observed in the presence of the initiator tRNA and AUG message. The additional changes induced by the tRNA are mostly centered around the cleft-head-lateral protrusion region, near positions affected by IF2 binding.

Internal dynamics of tRNA(Phe) studied by depolarized dynamic light scattering

The collective internal dynamics of transfer RNA(Phe) from brewer's yeast in solution was studied by depolarized dynamic light scattering (DDLS). Within the melting region of tRNA the depolarized spectra consist of two Lorentzian, where the narrow (slow) component describes the overall rotation of the macromolecule. The broad component is attributed to the collective reorientation of the bases within the biopolymer. At high temperature only this relaxation process is observed in the spectrum. The viscosity dependence of the collective internal relaxation process is described by the Stokes-Einstein-Debye equation for rotational diffusion. Estimates of the internal orientational pair correlation factor from the integral depolarized intensities of tRNA(Phe) solutions indicates that the observed dynamics correspond to the collective reorientation of approximately 5 bases. A comparison of the results presented with DDLS studies on the aggregation of the mononucleotide guanosine-5'-monophosphate confirms this result. For a further characterization of the relaxation process we studied the effect of hydrostatic pressure (1-1000 bar) on the depolarized spectra of tRNA. While other spectroscopic methods like nmr, fluorescence polarization anisotropy decay, or ESR give information about the very local motion of a single base within the DNA or RNA, this study shows that by DDLS one can characterize collective internal motions of macromolecules.

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.

Crosslinking of elongation factor Tu to tRNA(Phe) by trans-diamminedichloroplatinum (II). Characterization of two crosslinking sites in the tRNA

Trans-diamminedichloroplatinum (II) was used to induce reversible crosslinks between EF-Tu and Phe-tRNA(Phe) within the ternary EF-Tu/GTP/Phe-tRNA(Phe) complex. Up to 40% of the complex was specifically converted into crosslinked species. Two crosslinking sites have been unambiguously identified. The major one encompassing nucleotides 58 to 65 is located in the 3'-part of the T-stem, and the minor one encompassing nucleotides 31 to 42 includes the anticodon loop and part of the 3'-strand of the anticodon stem.

Structural features in aminoacyl-tRNAs required for recognition by elongation factor Tu

In bacterial polypeptide synthesis aminoacyl-tRNA (aa-tRNA) bound to elongation factor Tu (EF-Tu) and GTP is part of a crucial intermediate ribonucleoprotein complex involved in the decoding of messenger RNA. The conformation and topology as well as the affinity of the macromolecules in this ternary aa-tRNA X EF-Tu X GTP complex are of fundamental importance for the nature of the interaction of the complex with the ribosome. The structural elements of aa-tRNA required for interaction with EF-Tu and GTP and the resulting functional implications are presented here.

Study of the interaction between uncharged yeast tRNAPhe and elongation factor Tu from Bacillus stearothermophilis

Proton NMR studies are presented on the interaction of nonaminoacylated yeast tRNAPhe and elongation factor Tu X GTP from Bacillus stearothermophilis. From experiments in which transfer of magnetization is observed between proton spins of tRNA and the protein, it is concluded that complex formation takes place. Amino acid residues of the protein come into close contact with the base pair A5U68 and/or U52A62 of the acceptor T psi C limb of the tRNA molecule. From the line broadening of tRNA resonances, associated with complex formation, an association constant of 10(3)-10(4) M-1 is estimated. The NMR experiments do not monitor a significant conformational change of the tRNA molecule upon interaction with the protein. However, at times long after the onset of complex formation, spectral changes indicate that the upper part of the acceptor helix becomes distorted.

Involvement of the 3' side of the anticodon loop of yeast tRNATyr in messenger-free binding to ribosomes. An electron-spin resonance study

Electron-spin resonance (ESR) spectra of a nitroxide spin-label attached to residue i6A-37 of yeast tRNATyr were measured in complexes of deacylated tRNATyr with Escherichia coli ribosomes. A Scatchard plot, obtained in the absence of mRNA, indicated strong binding with an association constant of 1 X 10(7) l X mol-1, suggesting the P-site binding. The ESR spectrum of free tRNATyr, characteristic for a rapidly tumbling nitroxide, changes to a spectrum with extensively broadened lines in the ribosome-tRNA complex. The original spectrum can be restored upon long incubations of the complex with an excess of extraneous tRNA. ESR spectra suggest that the spin-label motion is drastically perturbed though not completely blocked in the ribosome-tRNATyr complex. Since ESR spectra of a spin-label attached to the opposite, i.e. 5', side of the anticodon loop are only slightly perturbed by the messenger-free binding to ribosomes [Rodriguez et al. (1980) J. Biol. Chem. 255, 8116-8120], it is concluded that the two sides of the anticodon loop face entirely different environments when bound to the P site, the 3' side being oriented towards the surface of the ribosome, and the other side towards its environment or a large cavity.

Formation and properties of a covalent complex between elongation factor Tu and Phe-tRNA bearing a photoaffinity probe on its 3-(3-amino-3-carboxypropyl)uridine residue

Escherichia coli Phe-tRNA, modified with the photoaffinity reagent 6-(2-nitro-4-azidophenylamino)caproate on the 3-(3-amino-3-carboxypropyl)uridine residue, was crosslinked to E. coli EFTu Section upon irradiation at 0 degree C with visible light at wavelengths greater than 400 nm. Crosslinking was dependent on irradiation, the photoaffinity probe, and was blocked by pre-photolysis. 1 mM-dithiothreitol completely quenched crosslinking. Binding of the tRNA to EFTu was a prerequisite for crosslinking, because neither EFTu . GDP nor AcPhe-tRNA could substitute; EFTu . GDPCP, however, was almost as active as EFTu . GTP. Crosslinking was complete in less than five minutes and was stable to at least 20 minutes of irradiation with a single 650 W tungsten lamp 4 cm away. The crosslinking yield ranged from 15% to 25%. The crosslinked complex possessed several remarkable properties. At 0.5 mM-Mg2+, the complex protected the AA-tRNA link to chemical hydrolysis, stabilized the bound GTP to dissociation or exchange, and was not adsorbed to cellulose nitrate filters. The purified crosslinked complex could be bound to ribosomes with concomitant hydrolysis of GTP. Extensive peptide bond formation with AcPhe-tRNA in the P site occurred despite the presence of the crosslinked EFTu. We conclude that hydrolysis of GTP is sufficient to release the 3' end of the Phe-tRNA from complexation with EFTu. Translocation of the A site bound complex did not occur. The crosslink site on EFTu is probably near the periphery of the molecule, because shortening the probe from 20 A to 14 A completely blocked crosslinking. A similar but shorter 8 A probe, p-azidophenacyl-4-thiouridine located on the opposite face of the tRNA, did not crosslink.