Codon-anticodon interaction in tRNAPhe. II. A nuclear magnetic resonance study of the binding of the codon UUC

Nuclear magnetic resonance study of the codon-anticodon interaction in Bombyx mori tRNA(GCCGly)

NMR spectra of Bombyx mori tRNA(GCCGly) were recorded in the GCC absence and presence of the oligonucleotide, GGCUp, which contains the codon sequence, GGC. The difference between the spectra with and without the codon oligonucleotide indicates the appearance of five new imino proton peaks. For the assignment of these peaks, G*GCUp, in which the 5'-terminal G was enriched with 95% 15N, was prepared (G*, 15N-labeled guanosine). In the imino proton spectrum of B. mori tRNA(GCCGly) on the addition of G*GCUp, the peak at 12 ppm became a doublet due to coupling with 15N nuclei. In the two-dimensional 1H-15N heteronuclear multiple-quantum correlation (HMQC) spectrum, only the peak at 12 ppm was observed, and thus it was assigned to the imino proton of the 5'-terminal G of GGCUp interacting with tRNA(GCCGly). Judging from the temperature effect and chemical shifts, the five new imino proton peaks are presumed to be due to three G.C base pairs, induced by the codon-anticodon interaction, and one U.U base pair, induced by an interaction between the 3' terminal U of GGCUp and U33 neighboring the anticodon. The binding of three trinucleotides (GGCp, GGUp and GCUp) to B. mori tRNA(GCCGly) was also investigated. Ultracentrifugation analysis showed that tRNA(GCCGly) underwent dimerization through the anticodon-anticodon interaction, but the dimerization was broken on addition of GGCUp. On 1H-NMR and ultracentrifugation analysis, it was found that GCUp not complementary to the anticodon also binds to the anticodon loop.

19F nuclear magnetic resonance as a probe of anticodon structure in 5-fluorouracil-substituted Escherichia coli transfer RNA

The use of 19F nuclear magnetic resonance (n.m.r.) spectroscopy as a probe of anticodon structure has been extended by investigating the effects of tetranucleotide binding to 5-fluorouracil-substituted Escherichia coli tRNA(Val)1 (anticodon FAC). 19F n.m.r. spectra were obtained in the absence and presence of different concentrations of oligonucleotides having the sequence GpUpApX (X = A,G,C,U), which contain the valine codon GpUpA. Structural changes in the tRNA were monitored via the 5-fluorouracil residues located at positions 33 and 34 in the anticodon loop, as well as in all other loops and stems of the molecule. Binding of GpUpApA, which is complementary to the anticodon and the 5'-adjacent FUra 33, shifts two resonances in the 19F spectrum. One, peak H (3.90 p.p.m.), is also shifted by GpUpA and was previously assigned to FUra 34 at the wobble position of the anticodon. The effects of GpUpApA differ from those of GpUpA in that the tetranucleotide induces the downfield shift of a second resonance, peak F (4.5 p.p.m.), in the 19F spectrum of 19F-labeled tRNA(Val)1. Evidence that the codon-containing oligonucleotides bind to the anticodon was obtained from shifts in the methyl proton spectrum of the 6-methyladenosine residue adjacent to the anticodon and from cleavage of the tRNA at the anticodon by RNase H after binding dGpTpApA, a deoxy analog of the ribonucleotide codon. The association constant for the binding of GpUpApA to fluorinated tRNA(Val)1, obtained by Scatchard analysis of the n.m.r. results, is in good agreement with values obtained by other methods. On the basis of these results, we assign peak F in the 19F n.m.r. spectrum of 19F-labeled tRNA(Val)1 to FUra 33. This assignment and the previous assignment of peak H to FUra 34 are supported by the observation that the intensities of peaks F and H in the 19F spectrum of fluorinated tRNA(Val)1 are specifically decreased after partial hydrolysis with nucleass S1 under conditions leading to cleavage in the anticodon loop. The downfield shift of peak F occurs only with adenosine in the 3'-position of the tetranucleotide; binding of GpUpApG, GpUpApC, or GpUpApU results only in the upfield shift of peak H. The possibility is discussed that this base-specific interaction between the 3'-terminal adenosine and the 5-fluorouracil residue at position 33 involves a 5'-stacked conformation of the anticodon loop. Evidence also is presented for a temperature-dependent conformational change in the anticodon loop below the melting temperature of the tRNA.

A stereochemical model of the transpeptidation complex

Molecular models are proposed to describe the relative arrangement of aminoacyl and peptidyl tRNAs when bound to their respective A and P sites on the ribosome. The crystallographically determined structures of tRNAasp and tRNAphe have served as the models for these bound structures, while the imposed steric constraints for the model complexes were based on the results of published experimental data. The constructed models satisfy the stereochemical requirements needed for codon-anticodon interaction and for peptide bond formation. In this paper, the results of the complex containing tRNAphe as the A and P site bound transfer RNAs, is compared to a similarly constructed model which uses tRNAasp as the ribosome-bound transfer RNAs. The models have the following three major features: 1) the aminoacyl and peptidyl transfer RNAs assume an angle of approximately 45 degrees relative to each other; 2) in providing the proper stereochemistry for peptide bond condensation, a significant kink must be present in the messenger RNA between the A site and P site codons; and 3) a comparison of the two model complexes indicates that structural variations between the tRNAs or any allosteric transitions of the transfer RNAs associated with codon-anticodon recognition may be accommodated in the model by way of freedom of rotation about the phosphate backbone bonds in the mRNA between consecutive codons.

Codon-induced association of the isolated anticodon loop of tRNAPhe

The binding of the codon UUC to the isolated anticodon loop of tRNAPhe (yeast) has been studied as a model of codon recognition by a simple adaptor. Fluorescence titrations demonstrate that UUC binds to the isolated anticodon loop with an equilibrium constant of 1.4 X 10(3) M-1 (at 7.2 degrees C). Equilibrium sedimentation curves reveal that UUC binding induces association of anticodon loops beyond the dimer stage. A set of complete sedimentation curves obtained for various reactant concentrations was analyzed according to a model with an infinite number of subsequent association steps for UUC-anticodon loop complexes and with equal affinity for each step. The coupling of association and sedimentation was considered quantitatively, and the information resulting from conservation of mass was used by integration. According to this procedure, the experimental data can be described by an isodesmic association constant of 8 X 10(3) M-1 with satisfactory accuracy. Temperature-jump relaxation detected by fluorescence measurements provides independent evidence for codon-induced association of the anticodon loop. The data are consistent with the following mechanism: UUC preferentially binds to one of two loop conformations with a rate constant of 4.5 X 10(6) M-1 s-1; the UUC-anticodon loop complex undergoes association with a rate constant of 6.5 X 10(6) M-1 s-1. The reactions observed for the isolated anticodon loop are surprisingly similar to those observed previously for the complete tRNA, suggesting that simple hairpin loops are appropriate adaptors for a translation process at an early stage of evolution; the codon-induced association of the hairpin loop should be very useful to facilitate the transfer of cognate amino acids during translation.

Conformational dynamics of the anticodon loop in yeast tRNAPhe as sensed by the fluorescence of wybutine

Conformational and dynamic properties of the anticodon loop of yeast tRNAPhe were investigated by analyzing the time resolved fluorescence of wybutine serving as a local structural probe adjacent to the anticodon GmAA on its 3' side. The influence of Mg2+, important for stabilizing the tertiary structure of tRNA, and of the complementary anticodon s2UUC of E. coli tRNA2Glu were investigated. Fluorescence lifetimes and anisotropies were measured with ps time resolution using time correlated single photon counting and a mode locked synchronously pumped and frequency doubled dye laser as excitation source. From the analysis of lifetimes (tau) and rotational relaxation times (tau R) we conclude that wybutine occurs in various structural states: one stacked conformation where the base has no free mobility and the only rotational motion reflects the mobility of the whole tRNA molecule (tau = 6 ns, tau R = 19 ns), an unstacked conformation where the base can freely rotate (tau = 100 ps, tau R = 370 ps) and an intermediary state (tau = 2 ns, tau R = 1.6 ns). Under biological conditions, i.e. in the presence of Mg2+ and neutral salts, wybutine is found in a stacked and immobile state which is consistent with the crystallographic picture. In the presence of the complementary codon however, as exemplified by the E. coli-tRNA2Glu anticodon, our analysis indicates that the codon-anticodon complex exists in an equilibrium of structural states with different rotational mobility of wybutine. The conformation with wybutine freely mobile is the predominant one and suggests that this conformation of the codon-anticodon structure differs from the canonical 3'-5' stack.

Fluorine-19 nuclear magnetic resonance study of codon-anticodon interaction in 5-fluorouracil-substituted E. coli transfer RNAs

Codon-anticodon interaction was investigated in fully active 5-fluorouracil-substituted E. coli tRNAVal1 (anticodon FAC) by 19F NMR spectroscopy. Binding of the codon GpUpA results in the upfield shift of a 19F resonance at 3.9 ppm in the central region of the 19F NMR spectrum, whereas trinucleotides not complementary to the anticodon have no effect. The same 19F resonance shifts upfield upon formation of an anticodon-anticodon dimer between the 19F-labeled tRNA and E. coli tRNATyr2 (anticodon QUA). These results permit assignment of the peak at 3.9 ppm to the 5-fluorouracil at position 34 in the anticodon of fluorouracil-substituted tRNAVal1. The methionine codon ApUpG also causes a sequence-specific upfield shift of a peak in the central part of the 19F NMR spectrum of fluorinated E. coli tRNAMetm. However, ApUpG has no effect on the 19F spectrum of 19F-labeled E. coli tRNAMetf, indicating possible conformational differences between the anticodon loop of initiator and chain-elongating methionine tRNAs. 19F NMR experiments detect no binding of CpGpApA to the complementary FpFpCpG (replaces Tp psi pCpG) in the T-loop of 5-fluorouracil-substituted tRNAVal1, in the presence or absence of codon, suggesting that the tertiary interactions between the T- and D-loops are not disrupted by codon-anticodon interactions.

Anticodon-anticodon interactions in solution. Studies of the self-association of yeast or Escherichia coli tRNAAsp and of their interactions with Escherichia coli tRNAVal

The temperature-jump method was used to measure the thermodynamic and kinetic parameters of the yeast tRNAAsp (anticodon GUC) duplex, which involves a U/U mismatch in the middle position of the quasi self-complementary anticodon, and of the yeast tRNAAsp (GUC)-Escherichia coli tRNAVal (GAC) complex, in which the tRNAs have complementary anticodons. The existence of the tRNAAsp duplex involving GUC-GUC interactions as evidenced in the crystal structure has now been demonstrated in solution. However, the value of its association constant (Kass = 10(4)M-1 at 0 degrees C) is characteristic of a rather weak complex, when compared with that between tRNAAsp and tRNAVal (Kass = 4 X 10(6) M-1 at 0 degrees C), the effect being essentially linked to differences in the rate constant for dissociation. tRNAAsp split in the anticodon by T1 ribonuclease gives no relaxation signal, indicating that the effects observed with intact tRNA were entirely due to anticodon interactions. No duplex formation was observed with other tRNAs having quasi self-complementary GNC anticodons (where N is C, A or G), such as E. coli tRNAGly (GCC), E. coli tRNAVal (GAC) or E. coli tRNAAla (GGC). This is compatible with the idea that, probably as in the crystal structure, a short double helix is formed in solution between the two GUC anticodons. Because of steric effects, such a complex formation would be hindered if a cytosine, adenine or guanine residue were located in the middle position of the anticodon. Escherichia coli tRNAAsp possessing a modified G residue, the Q base, at the first position of the anticodon, showed a weaker self-association than yeast tRNAAsp but its complex with E. coli tRNAVal was found to be only 1.5 times less stable than that between yeast tRNAAsp and E. coli tRNAVal. Temperature-jump experiments conducted under conditions mimicking those used for the crystallization of yeast tRNAAsp (in the presence of 1.6 M-ammonium sulphate and 3mM-spermine) revealed an important stabilization of the yeast and E. coli tRNAAsp duplexes or of their complexes with E. coli tRNAVal. The effect is due exclusively to ammonium sulphate; it is entropy driven and its influence is reflected on the association rate constant; no influence on the dissociation rate constant was observed. For all tRNA-tRNA complexes, the melting temperature upon addition of ammonium sulphate was considerably increased. This study permits the definition of solution conditions in which tRNAs with appropriate anticodons exist mainly as anticodon-anticodon dimers.

Mechanism of codon recognition by transfer RNA studied with oligonucleotides larger than triplets

The binding of yeast tRNAPhe to UUCA, UUCC, UUCCC, UUCUUCU, U4, U5, U6 and U7 was analysed by fluorescence temperature jump and equilibrium sedimentation measurements. In all cases the two observed relaxation processes can be assigned to alpha) an intramolecular conformation change of the anticodon loop and beta) preferential binding of the oligonucleotides to one of the anticodon conformations. The anticodon loop transition is associated with inner sphere complexation of Mg2+ and proceeds with rate constants of about 10(3) s-1. The rate constants of oligonucleotide binding are between 4 and 10 X 10(6) M-1s-1 and reflect an increase of the association rate with the number of binding sites compensated to some degree by electrostatic repulsion in the preequilibrium complex. Neither temperature jump nor equilibrium sedimentation experiments provided evidence for UUCA or UUCC induced tRNA dimerisation, although UUC binding leads to strong tRNA dimerisation under equivalent conditions. The results obtained for the longer oligonucleotides are similar. In the case of UUCUUCU with its two potential binding sites for tRNAPhe there was no evidence for the formation of 'ternary' complexes. Apparently tRNAPhe binds preferentially to the second UUC of this 'messenger' and forms additional contacts with residues on either side of the codon. Some evidence for the formation of ternary complexes is obtained for U6 and U7, although the extent of this reaction remains very small. Our results demonstrate that the mode of tRNA binding to a codon is strongly influenced by residues next to the codon. The formation of cooperative contacts between tRNA molecules at adjacent codons apparently requires support by a catalyst adjusting an appropriate conformation of messenger and tRNA molecules.

Mechanism of codon recognition by transfer RNA and codon-induced tRNA association

The steps of UUC recognition by tRNAPhe were analysed by temperature-jump measurements. At ion concentrations close to physiological conditions we found three relaxation processes, which we assigned to (1) formation of codon-anticodon complexes, (2) a conformational change of the anticodon loop coupled with Mg2+ binding, and (3) codon-induced association of tRNA. The relaxation data were evaluated both by the usual procedure (fitting the exponentials evaluated from the individual experiments of a set to a reaction model) and by "global fitting", i.e. fitting a set of relaxation curves obtained at various concentrations directly to a reaction model, thus leaving out the intermediate exponential fitting step. The data can be represented quantitatively by a three-step model: the codon binds to the anticodon at a rate of 4 X 10(6) to 6 X 10(6) M-1S-1 as is usual for the formation of oligomer helices; the conformation change of the anticodon loop is associated with inner sphere complexation of Mg2+ at a rate of 10(3) S-1; the codon-tRNA complexes form dimers at a rate of 5 X 10(6) to 15 X 10(6) M-1S-1. A similar mechanism is found for the binding of the wobble codon UUU to tRNAPhe at increased concentrations of Mg2+. Measurements at different Mg2+ concentrations demonstrate the distinct role of this ion in the codon recognition and the codon-induced tRNA dimerization. We propose a simple mechanism, based upon the special properties of magnesium ions, for long-distance transfer of reaction signals along nucleic acid chains.

Structure of the ribotrinucleoside diphosphate codon UpUpC bound to tRNAPhe from yeast. A time-dependent transferred nuclear Overhauser enhancement study

The structure of the ribotrinucleoside diphosphate UpUpC, the codon for phenylalanine, bound to yeast tRNAPhe in solution is elucidated using time-dependent proton-proton transferred nuclear Overhauser enhancement measurements to determine distances between bound ligand protons. The glycosidic bond and ribose conformations are low anti and 3'-endo, respectively, typical of an A-RNA type structure. The main chain torsion angles are all within the range of those expected for A-RNA but small differences from those in conventional A-RNA 11 result in a special structure with a larger rotation per residue (40 to 45 degrees compared to 32.7 degrees in R-RNA 11) and almost perfect stacking of the bases. These two structural features, which are similar to those found in the anticodon triplet of the monoclinic crystal form of tRNAPhe, can account for the known greater stability of the codon-anticodon complex relative to an equivalent double helical RNA trimer with a conventional A-RNA structure.