Mechanism of discrimination between cognate and non-cognate tRNAs by phenylalanyl-tRNA synthetase from yeast.

The interaction between phenylalanyl-tRNA synthetase from yeast and Escherichia coli and tRNAPhe (yeast), tRNASer (yeast), tRNA1Val (E. coli) has been investigated by ultracentrifugation analysis, fluorescence titrations and fast kinetic techniques. The fluorescence of the Y-base of tRNAPhe and the intrinsic fluorescence of the synthetases have been used as optical indicators. 1. Specific complexes between phenylalanyl-tRNA synthetase and tRNAPhe from yeast are formed in a two-step mechanism: a nearly diffusion-controlled recombination is followed by a fast conformational transition. Binding constants, rate constants and changes in the quantum yield of the Y-base fluorescence upon binding are given under a variety of conditions with respect to pH, added salt, concentration of Mg2+ ions and temperature. 2. Heterologous complexes between phenylalanyl-tRNA synthetase (E. coli) and tRNAPhe (yeast) are formed in a similar two-step mechanism as the specific complexes; the conformational transition, however, is slower by a factor 4-5. 3. Formation of non-specific complexes between phenylalanyl-tRNA synthetase (yeast) and tRNATyr (E. coli) proceeds in a one-step mechanism. Phenylalanyl-tRNA synthetase (yeast) binds either two molecules of tRNAPhe (yeast) or only one molecule of tRNATyr (E. coli); tRNA1Val (E. coli) or tRNASer (yeast) are also bound in a 1:1 stoichiometry. Binding constants for complexes of phenylalanyl-tRNA synthetase (yeast) and tRNATyr (E. coli) are determined under a variety of conditions. In contrast to specific complex formation, non-specific binding is disfavoured by the presence of Mg2+ ions, and is not affected by pH and the presence of pyrophosphate. The difference in the stabilities of specific and non-specific complexes can be varied by a factor of 2--100 depending on the ionic conditions. Discrimination of cognate and non-cognate tRNA by phenylalanyl-tRNA synthetase (yeast) is discussed in terms of the binding mechanism, the topology of the binding sites, the nature of interacting forces and the relation between specificity and ionic conditions.     

Replacement of wybutine by hydrazines and its effect on the active conformation of yeast tRNAPhe.

The highly modified base wybutine (YWye) next to the anticodon of yeast tRNAPhe has been replaced by different hydrazine derivatives. The effect of the replacement on the activity of the tRNA has been studied in the heterologous aminoacylation with synthetase from E. coli and in the poly(U) directed binding to ribosomes from both yeast and E. coli. It was found that starting from tRNA-PheYWye the activity increased with increasing size, aromaticity, and stacking tendency of the substituent replacing YWye. It is concluded that YWye by the size of its aromatic system and by its stacking properties is particularly well suited for stabilizing the native conformation of tRNAPhe.     

A novel conformational change of the anticodon region of tRNAPhe (yeast).

The temperature dependence of the fluorescence of the Y-base of tRNAPhe (yeast) was investigated kinetically by the temperature jump method. In the range between -15 degrees C and +30 degrees C A NOVEL CONFORMATIONAL TRANSITION OF THE TRNA could be characterized. This conformational change was found in the absence of any artificial label; it is a characteristic property of tRNAPhe in its native structure. This transition accounts for 30% of the total fluorescence change. Its activation enthalpy is 16 kcal/mole (67 kJ/mole), and the transition enthalpy is between -2 kcal/mole and +2 kcal/mole (+/-8 kJ/mole). A model is represented in which this transition can be explained by a a change in the stacking pattern of the anticodon loop. The experimental findings are discussed with respect to several hypotheses about the molecular mechanism of protein biosynthesis which postulate conformational rearrangements of the anticodon loop.     

Conformation transitions of a tRNA--aminoacyl-tRNA synthetase complex induced by tRNAs bearing different modifications in the 3' terminus.

The influence of modifications of the 3'-terminal adenosine of tRNAPhe (yeast) on the complex formation between this tRNA and phenylalanyl-tRNA synthetase (yeast) has been investigated by using fluorescence titrations and fast kinetic techniques. Subtle changes in the 3' terminus are reflected by distinct alterations in the two-step recognition process which had been demonstrated earlier for the native substrate tRNAPheCCA [Krauss, G., Riesner, D., & Maass, G. (1977) Nucleic Acids Res. 4, 2253--2262]. Binding experiments with tRNAPheCC, tRNAPheCCA-ox-red, tRNAPheCC2'dA, tRNAPheCC3'dA, tRNAPheCC-formycin, and tRNAPheCC-formycin-ox-red confirm that the 3'-terminal adenosine participates in a conformational change of the tRNA--synthetase complex. This is valid in both the absence and presence of phenylalaninyl-5'-AMP, the alkyl analogue of the aminoacyladenylate. As compared to tRNAPheCCA, a slower conformational change is observed with the competitive inhibitor tRNAPheCC-formycin-ox-red. The reaction enthalpy and/or the quench of the Y-base fluorescence that accompany the conformational change are altered upon binding of tRNAPheC2'dA, tRNAPheCC3'dA, and tRNAPheCC-formycin. It is evident that the final adaptation between tRNA and its synthetase in the complex is determined by the chemical nature of the 3'-terminal nucleotide. This is of vital importance for the specificity of the aminoacylation process.     

Specificity and mechanism of the cleavages induced in yeast tRNAPhe by magnesium ions

The specificity of magnesium ion-induced hydrolysis of yeast tRNAPhe in solution was studied as a function of the excess of Mg(II) ions and pH. The major cuts at phosphates 16 and 20 as well as minor cleavages at phosphates 17, 18, 21, 34 and 36 occur at all pH values in the range of 8.0-9.5, and at a molar excess of magnesium ions over the tRNA ranging from 125 to 5000. In yeast tRNA(Phe)-Y the efficiency of the anticodon and D-loop cleavages is considerably decreased while the differently modified Y-base of yellow lupin tRNA(Phe) lowers the specificity of the weak anticodon loop cleavages. The mechanism of the Mg(II)-induced cleavages is discussed on the basis of yeast tRNA(Phe) crystal structure data, and the two major D-loop cleavages are thought to be effected from two distinct magnesium binding sites. The possibility of probing the environments of magnesium binding sites in tRNAs by the induced cleavages is demonstrated, and the relevance of magnesium-induced tRNA cleavages to RNA catalysis is discussed.     

Specific interaction of anticodon loop residues with yeast phenylalanyl-tRNA synthetase

Thirteen different yeast tRNAPhe variants with single nucleotide changes in positions 34-37 in the anticodon region were prepared by an enzymatic procedure described previously. Aminoacylation kinetics using purified yeast phenylalanyl-tRNA synthetase revealed that the level of aminoacylation was very different for different sequences inserted. The low level of aminoacylation was the result of a steady state between a slow forward reaction rate and spontaneous deacylation of the product. Aminoacylation kinetics performed at higher synthetase concentrations revealed that substitution at position 34 in tRNAPhe decreased the Km nearly 10-fold but only had a small effect on Vmax. Similar substitutions at positions 35, 36, and 37 had a lesser effect. These data suggest a sequence-specific contact between the anticodon of yeast tRNAPhe and the cognate synthetase.     

Long-range conformational transition in yeast tRNAPhe, induced by the Y-base removal and detected by chloroacetaldehyde modification.

Chemical modification was used to study the conformational changes occurring in yeast tRNAPhe after the Y-base excision. The chemical probe was the adenine- and cytosine-specific reagent chloroacetaldehyde. Comparison of the modification patterns in tRNAPhe and tRNAPhe-Y shows that seven bases, adenines 35, 36 and 38 in the anticodon loop and adenines 73, 76 and cytosines 74, 75 in the 3'-terminus were modified in both tRNAs with a quantitative difference in the modification level of the anticodon loop bases. The most interesting, however, is the qualitative difference consisting in modification of cytosine-60 in the T psi C loop of tRNAPhe-Y. Some aspects of the mechanism of this long-distance conformational transition are briefly discussed.     

Characterization of the lead(II)-induced cleavages in tRNAs in solution and effect of the Y-base removal in yeast tRNAPhe

The specificity of lead(II)-induced hydrolysis of yeast tRNA(Phe) was studied as a function of concentration of Pb2+ ions. The major cut was localized in the D-loop and minor cleavages were detected in the anticodon and T-loops at high metal ion concentration. The effects of pH, temperature, and urea were also analyzed, revealing a basically unchanged specificity of hydrolysis. In the isolated 5'-half-molecule of yeast tRNAPhe not cut was found in the D-loop, indicating its stringent dependence on T-D-loop interaction. Comparison of hydrolysis patterns and efficiencies observed in yeast tRNA(Phe) with those found in other tRNAs suggests that the presence of a U59-C60 sequence in the T-loop is responsible for the highly efficient and specific hydrolysis in the spatially close region of the D-loop. The efficiencies of D-loop cleavage in intact yeast tRNA(Phe) and in tRNA(Phe) deprived of the Y base next to the anticodon were also compared at various Pb2+ ion concentrations. Kinetics of the D-loop hydrolysis analyzed at 0, 25, and 37 degrees C showed a 6 times higher susceptibility of tRNA(Phe) minus Y base (tRNA(Phe)-Y) to lead(II)-induced hydrolysis than in tRNA(Phe). The observed effect is discussed in terms of a long-distance conformational transition in the region of the interacting D- and T-loops triggered by the Y-base excision.     

Yeast tRNAAsp tertiary structure in solution and areas of interaction of the tRNA with aspartyl-tRNA synthetase. A comparative study of the yeast phenylalanine system by phosphate alkylation experiments with ethylnitrosourea

Ethylnitrosourea is an alkylating reagent preferentially modifying phosphate groups in nucleic acids. It was used to monitor the tertiary structure, in solution, of yeast tRNAAsp and to determine those phosphate groups in contact with the cognate aspartyl-tRNA synthetase. Experiments involve 3' or 5'-end-labelled tRNA molecules, low yield modification of the free or complexed nucleic acid and specific splitting at the modified phosphate groups. The resulting end-labelled oligonucleotides are resolved on polyacrylamide sequencing gels and data analysed by autoradiography and densitometry. Experiments were conducted in parallel on yeast tRNAAsp and on tRNAPhe. In that way it was possible to compare the solution structure of two elongator tRNAs and to interpret the modification data using the known crystal structures of both tRNAs. Mapping of the phosphates in free tRNAAsp and tRNAPhe allowed the detection of differential reactivities for phosphates 8, 18, 19, 20, 22, 23, 24 and 49: phosphates 18, 19, 23, 24 and 49 are more reactive in tRNAAsp, while phosphates 8, 20 and 22 are more reactive in tRNAPhe. All other phosphates display similar reactivities in both tRNAs, in particular phosphate 60 in the T-loop, which is strongly protected. Most of these data are explained by the crystal structures of the tRNAs. Thermal transitions in tRNAAsp could be followed by chemical modifications of phosphates. Results indicate that the D-arm is more flexible than the T-loop. The phosphates in yeast tRNAAsp in contact with aspartyl-tRNA synthetase are essentially contained in three continuous stretches, including those at the corner of the amino acid accepting and D-arm, at the 5' side of the acceptor stem and in the variable loop. When represented in the three-dimensional structure of the tRNAAsp, it clearly appears that one side of the L-shaped tRNA molecule, that comprising the variable loop, is in contact with aspartyl-tRNA synthetase. In yeast tRNAPhe interacting with phenylalanyl-tRNA synthetase, the distribution of protected phosphates is different, although phosphates in the anticodon stem and variable loop are involved in both systems. With tRNAPhe, the data cannot be accommodated by the interaction model found for tRNAAsp, but they are consistent with the diagonal side model proposed by Rich & Schimmel (1977). The existence of different interaction schemes between tRNAs and aminoacyl-tRNA synthetases, correlated with the oligomeric structure of the enzyme, is proposed.     

Fluorescent derivatives of yeast tRNAPhe.

The preparation of four fluorescent derivatives of tRNAPhe (yeast) and their characterization by chemical, spectroscopic, and biochemical methods is described. The derivatives are prepared by replacing wybutine (position 37 in the anticodon loop) or NaBH4-reduced dihydrouracil (positions 16/17 in the hU loop) with ethidium or proflavine; they are isolated by reversed-phase chromatography (RPC-5). All tRNAPhe-dye derivatives are aminoacylated by yeast phenylalanyl-tRNA synthetase to at least 80% of the charging capacity of the unmodified tRNAPhe with an unchanged Km (0.2 mucroM) and a V lowered by 30--50%. They exhibit good to excellent activity in the aminoacylation assay from synthetase from Escherichia coli. It is concluded that the insertion of the dyes does not seriously disturb essential elements of the native tRNAPhe structure. The dyes are bound via N-ribosylic linkages. The appearance of isomeric tRNAPhe-ethidium derivatives is attributed to the involvement of the different amino groups of ethidium in the condensation. In addition, there are indications for the existence of alpha and beta anomers of the tRNA-dye compounds. The dyes are rigidly fixed to their position in the tRNA molecule by stacking interactions with the neighboring bases. The ethidium probes show Mg2+-induced changes of the tRNA conformation which are paralleled by changes of the rate of aminoacylation. On the basis of this observation it is hypothesized that conformational flexibility of the tRNA molecule is a functionally important feature of the tRNA structure.     

Analysis of the steady-state mechanism of the aminoacylation of tRNAPhe by phenylalanyl-tRNA synthetase from yeast.

The steady-state mechanism of the aminoacylation of tRNAPhe by the corresponding synthetase from yeast has been investigated in detail by kinetic experiments. It was found that there are two alternative mechanisms: one favoured at low tRNA concentrations and the other at high tRNA concentrations. ATP and Phe are bound randomly to the enzyme. AMP is released immediately after the binding of ATP and Phe. Between the release of AMP and pyrophosphate (PPi) there is at least one additional step. Based on the experimental results a model of the steady-state mechanism is proposed. This model includes the sequence of addition of substrates to the enzyme and the release of products from the enzyme as well as the composition of the intermediate complexes with the enzyme. This model is in accordance with previous results based on different techniques. The results are explained by a "flip-flop" mechanism for all the substrates and products involved in the reaction.     

Mitochondrial phenylalanyl t-RNA synthetase from yeast: formation of enzyme-substrate complexes shown by heat or SH reagent inactivation

The binding of substrates to purified mitochondrial phenylalanyl-tRNA synthetase from yeast was examined using the kinetics of heat or p-hydroxymercurybenzoate inactivation. Individually magnesium chloride and each of the substrates protect the enzyme against thermal denaturation and p-hydroxymercurybenzoate inhibition. No enzyme protection is observed with ATP alone against p-hydroxymercurybenzoate inhibition. The combinations of the various substrates induce a synergistic protection effect. Protection constants of 31 microM and 0.3 microM were found for L-Phe and mt tRNAPhe respectively, from heat inactivation studies. The inhibition of the enzyme activity by p-hydroxymercurybenzoate can be reverted by 2-mercaptoethanol or dithiothreitol.     

Incorporation of 1,N6-ethenoadenosine into the 3' terminus of tRNA using T4 RNA ligase. 1. Preparation of yeast tRNAPhe derivatives

The 3'-terminal A-C-C-A sequence of yeast tRNAPhe has been modified by replacing either adenosine 76 or 73 with the fluorescent analogues 1,N6-ethenoadenosine (epsilon A) or 2-aza-1,N6-ethenoadenosine (aza-epsilon A). T4 RNA ligase was used to join the nucleoside 3',5'-bisphosphates to the 3' end of the tRNA which was shortened by one [tRNAPhe(-A)] or four [tRNAPhe(-ACCA)] nucleotides. It was found that the base-paired 3'-terminal cytidine 72 in tRNAPhe(-ACCA) is a more efficient acceptor in the ligation reaction than the unpaired cytidine 75 at the A-C-C terminus of tRNAPhe(-A). This finding indicates that the mobility of the accepting nucleoside substantially influences the ligation reaction, the efficiency being higher the lower the mobility. This conclusion is corroborated by the observation that the ligation reaction with the double-stranded substrate exhibits a positive temperature dependence rather than a negative one as found for single-stranded acceptors. The replacement of the 3'-terminal adenosine 76 with epsilon A and aza-epsilon A leads to moderately fluorescent tRNAPhe derivatives, which are inactive in the aminoacylation reaction. A number of other tRNAs (Met, Ser, Glu, Lys and Leu-specific tRNAs both from yeast and Escherichia coli) are also inactivated by epsilon A incorporation. Replacement of adenosine 73 followed by repair of the C-C-A end using nucleotidyl transferase leads to tRNAPhe derivatives which are fully active in the aminoacylation reaction and in polyphenylalanine synthesis. The fluorescence of epsilon A and aza-epsilon A at position 73 is virtually completely quenched, suggesting a stacked arrangement of bases around this position. There is no fluorescence increase when the epsilon A-labeled tRNAPhe is complexed with phenylalanyl-tRNA synthetase, elongation factor Tu, or ribosomes. These observations indicate that the stacked conformation of the 3' terminus is not changed appreciably in these complexes.     

Manganese(II) as a paramagnetic probe of the tertiary structure of transfer RNA.

The effect of manganese on both the low field (10--15 ppm) and the high field (o--3 ppm) NMR spectra of unfractionated tRNA and yeast tRNAPhe has been investigated. Trace amounts of Mn2+ cause selective broadening of resonances which are assigned to specific tertiary interactions. The order in which resonances broaden is the same as the order in which they are stabilized by the addition of magnesium, namely s4U8 - A14, U33 and A58 - T54. From this we conclude that three of the strong binding sites probably are the same for both Mn2+ and Mg2+, and that these sites are located close to the tertiary interactions which are stabilized by the strongly bound metals. The broadening data, taken in conjunction with published X-ray data on yeast tRNAPhe, permit us to suggest some plausible locations for the strong binding sites.     

Nucleotide sequence of phenylalanine transfer RNA from Schizosaccharomyces pombe: implications for transfer RNA recognition by yeast phenylalanyl-tRNA synthetase.

The nucleotide sequence of Schizosaccharomyces pombe tRNAPhe was determined to be pG-U-C-G-C-A-A-U-G**-G*-U-G-psi-A-G-D-D-G-G-G-A-G-C-A-psi-G*-A-C-A-G-A-Cm-U-Gm-A-A-Y-A-psi-m5C-U-G-U-U-G-m7G-U*-C-A-U-C-G-G-T-psi-C-G-A-U-C-C-C-G-G-U-U-U-G-U-G-A-C-A-C-C-AOH. This sequence differs from that of S. cerevisiae tRNAPhe in 27 nucleotides. Saccharomyces cerevisiae phenylalanyl-tRNA synthetase aminoacylates both the homologous tRNAPhe and S. pombe t-NAPhe; the reactions have similar Km and Vmax values. However, the nucleotide sequence in the D stem is different in the two tRNAs. This region was proposed by Roe, B., et al. [(1973) Biochemistry 12, 4146--4154] to be the major recognition site for yeast phenylalanyl-tRNA synthetase, but the present results cast doubt on the validity of this hypothesis.     

Enzymatic conversion of guanosine 3'' adjacent to the anticodon of yeast tRNAPhe to N1-methylguanosine and the wye nucleoside: dependence on the anticodon sequence.

N1-Methylguanosine (m1G) or wye nucleoside (Y) are found 3' adjacent to the anticodon (position 37) of eukaryotic tRNAPhe. The biosynthesis of these two modified nucleosides has been investigated. The importance of the type of nucleosides in the anticodon of yeast tRNAPhe on the potentiality of this tRNA to be a substrate for the corresponding maturation enzyme has also been studied. This involved microinjection into Xenopus laevis oocytes and incubation in a yeast extract of restructured yeast tRNAPhe in which the anticodon GmAA and the 3' adjacent Y nucleoside were substituted by various tetranucleotides ending with a guanosine. The results obtained by oocyte microinjection indicate: that all the restructured yeast tRNAsPhe are efficient substrates for the tRNA (guanosine-37 N1)methyltransferase. This means that the anticodon sequence is not critical for the tRNA recognition by this enzyme; in contrast, for Y nucleoside biosynthesis, the anticodon sequence GAA is an absolute requirement; the conversion of G-37 into Y-37 nucleoside is a multienzymatic process in which m1G-37 is the first obligatory intermediate; all the corresponding enzymes are cytoplasmic. In a crude yeast extract, restructured yeast tRNAPhe with G-37 is efficiently modified only into m1G-37; the corresponding enzyme is a S-adenosyl-L-methionine-dependent tRNA methyltransferase. The pure Escherichia coli tRNA (guanosine-37 N1) methyltransferase is unable to modify the guanosine-37 of yeast tRNAPhe.     

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.     

Identification of the magnesium, europium and lead binding sites in E. coli and lupine tRNAPhe by specific metal ion-induced cleavages

The Pb, Eu and Mg-induced cleavages in E. coli and lupine tRNAPhe have been characterized and compared with those found in yeast tRNAPhe. The pattern of lupine tRNAPhe hydrolysis closely resembles that of yeast tRNAPhe, while several major differences occur in the specificity and efficiency of the E. coli tRNAPhe hydrolysis. The latter tRNA is cleaved with much lower yield in the D-loop, and interestingly, cleavage is also detected in the variable region, that is highly resistant to hydrolysis in eukaryotic tRNAs. The possible location of tight Pb, Eu and Mg binding sites in E. coli tRNAPhe is discussed on the basis of the specific hydrolysis data.     

Evidence for the existence of an expressed minor variant tRNAPhe in yeast

Two expressed brewer's yeast tRNAsPhe, a major and a minor one, have been purified and sequenced. The major tRNAPhe corresponds to the already known tRNAPhe, whereas the minor one differs from the former in the substitution of T6-A67 by C6-G67 base pair in the "acceptor stem". The minor tRNAPhe contaminates all preparations of yeast tRNAPhe except those prepared by polyacrylamide gel electrophoresis.