Misacylation and editing by Escherichia coli valyl-tRNA synthetase: evidence for two tRNA binding sites.

Valyl-tRNA synthetase (ValRS) has difficulty discriminating between its cognate amino acid, valine, and structurally similar amino acids. To minimize translational errors, the enzyme catalyzes a tRNA-dependent editing reaction that prevents accumulation of misacylated tRNA(Val). Editing occurs with threonine, alanine, serine, and cysteine, as well as with several nonprotein amino acids. The 3'-end of tRNA plays a vital role in promoting the tRNA-dependent editing reaction. Valine tRNA having the universally conserved 3'-terminal adenosine replaced by any other nucleoside does not stimulate the editing activity of ValRS. As a result 3'-end tRNA(Val) mutants, particularly those with 3'-terminal pyrimidines, are stably misacylated with threonine, alanine, serine, and cysteine. Valyl-tRNA synthetase is unable to hydrolytically deacylate misacylated tRNA(Val) terminating in 3'-pyrimidines but does deacylate mischarged tRNA(Val) terminating in adenosine or guanosine. Evidently, a purine at position 76 of tRNA(Val) is essential for translational editing by ValRS. We also observe misacylation of wild-type and 3'-end mutants of tRNA(Val) with isoleucine. Valyl-tRNA synthetase does not edit wild-type tRNA(Val)(A76) mischarged with isoleucine, presumably because isoleucine is only poorly accommodated at the editing site of the enzyme. Misacylated mutant tRNAs as well as 3'-end-truncated tRNA(Val) are mixed noncompetitive inhibitors of the aminoacylation reaction, suggesting that ValRS, a monomeric enzyme, may bind more than one tRNA(Val) molecule. Gel-mobility-shift experiments to characterize the interaction of tRNA(Val) with the enzyme provide evidence for two tRNA binding sites on ValRS.     

Order of binding of substrate to valyl-tRNA synthetase from Bacillus stearothermophilus in amino acid activation reaction

Amino acid activation reaction with valyl-tRNA synthetase (EC 6.1.1.9) from Bacillus stearothermophilus was studied kinetically by measuring ATP-PPi exchange to find the order of the binding of substrate to the enzyme. The effects of the concentration of the substrates (L-valine and ATP) and two dead-end inhibitors (L-valinol and adenosine) on the reaction rate were analyzed. The results indicate that L-valine and ATP are bound to the enzyme in a random sequence. This conclusion is consistent with the one previously suggested by static binding experiments.     

Influence of various factors on the recognition specificity of tRNAs by yeast valyl-tRNA synthetase.

Using filtration through nitrocellulose membranes we found that complexes between yeast valyl-tRNA synthetase can easily be detected at low pH and ionic strength with the cognate tRNAVal, but also with several non-cognate tRNAs (tRNAPhe, tRNATyr, tRNAMet and tRNAAsp). We show here that the amino acid linked to the tRNA has no detectable effect on these interactions. The influence of various factors on the discrimination by the enzyme between the cognate and the non-cognate tRNAs has been studied. An increase in pH or ionic strength leads to a decrease in the same ratio of the affinity constants between the enzyme and the cognate as well as the noncognate tRNA. The addition of organic solvents has little effect on these constant either in the cognate or in the non-cognate systems; the addition of substrates of the aminoacylation reaction has not effect on the ratio between the constants. This similar behaviour suggests that at least part of the specific of non-specific interactions must be identical. On the contrary, magnesium between 1 mM and 50 mM increases the specificity of recognition, showing the importance of slight conformational changes in the tRNA molecule to the specificity of interaction.     

Mechanism of molecular interactions for tRNA(Val) recognition by valyl-tRNA synthetase

The molecular interactions between valyl-tRNA synthetase (ValRS) and tRNA(Val), with the C34-A35-C36 anticodon, from Thermus thermophilus were studied by crystallographic analysis and structure-based mutagenesis. In the ValRS-bound structure of tRNA(Val), the successive A35-C36 residues (the major identity elements) of tRNA(Val) are base-stacked upon each other, and fit into a pocket on the alpha-helix bundle domain of ValRS. Hydrogen bonds are formed between ValRS and A35-C36 of tRNA(Val) in a base-specific manner. The C-terminal coiled-coil domain of ValRS interacts electrostatically with A20 and hydrophobically with the G19*C56 tertiary base pair. The loss of these interactions by the deletion of the coiled-coil domain of ValRS increased the K(M) value for tRNA(Val) 28-fold and decreased the k(cat) value 19-fold in the aminoacylation. The tRNA(Val) K(M) and k(cat) values were increased 21-fold and decreased 32-fold, respectively, by the disruption of the G18*U55 and G19*C56 tertiary base pairs, which associate the D- and T-loops for the formation of the L-shaped tRNA structure. Therefore, the coiled-coil domain of ValRS is likely to stabilize the L-shaped tRNA structure during the aminoacylation reaction.     

Ultracentrifugation studies of yeast valyl-tRNA synthetase and of its interaction with tRNAVal.

Yeast valyl-tRNA synthetase and its complexes with yeast tRNAVal were investigated by means of analytical ultracentrifugation. A molecular weight of 125 700 +/- 1500 and a sedimentation coefficient (SO 20, w) of 6.3 +/- 0.3 were found for the native enzyme. When the enzyme (3--60 muM) was mixed with its cognate tRNA, several types of complex were observed, depending on the relative amounts of the two macromolecules. In the presence of equimolecular amounts of tRNA and enzyme, a complex formed by the association of one of each molecule was observed with a sedimentation coefficient of about 7.3 S. However, for tRNA/enzyme stoichiometries lower than one, beside the 1 : 1 complex, a complex of higher molecular weight was observed, with a sedimentation coefficient of about 10.0 S which fits with the association of two valyl-tRNA synthetase molecules with one tRNA molecule. This 2 : 1 complex was predominant from tRNA/enzyme stoichiometries lower than 0.3. It dissociated into the 1 : 1 complex upon addition of monovalent salts or MgCl2, suggesting the electrostatic nature of the interaction in this association. All these association and dissociation phenomena were detected over a large range of pH (6.0--7.5) and in various buffers.     

Interactions of yeast valyl-tRNA synthetase with RNAs and conformational changes of the enzyme.

Different conformations have been identified for the enzyme valyl-tRNA synthetase from yeast inside its complex with one tRNA molecule by neutron scattering. One form is identical to that of the free enzyme in solution; the other form is more contracted, having a radius of gyration which is smaller by 10% and a specific volume which is smaller by 1%. The contracted conformation has been found for the complexes with tRNA^Val and tRNA^Asp in phosphate buffer (pH 6.3) provided the ionic strength is lower than about 150 mm. In higher ionic strength (up to about 500 mm) the enzyme still forms a complex with tRNA^Val but its conformation remains that of the free protein in solution. In the complex with tRNA₃^Leu, the enzyme conformation is that of the free state even at the lowest ionic strength examined (that of the phosphate buffer, 60 mm). The free enzyme is an elongated molecule of radius of gyration 40 Å (a compact protein of the same molecular weight would have a radius of gyration of 30 Å).The positioning within the complex of tRNA^Val, on the one hand, and tRNA₃^Leu, on the other, is very different. The first tRNA is intimately associated with the enzyme, lying predominantly closer to the centre of mass of the complex than the protein. In the complex with tRNA₃^Leu, the tRNA lies further away from the centre of mass of the complex than the protein.Small concentrations of tRNA^Val, tRNA^Asp, tRNA₃^Leu or Escherichia coli 5 S ribosomal RNA cause the enzyme to aggregate into dimers, trimers and higher aggregates provided the ionic strength of the buffer is below 150 mm. In higher ionic strength or for [RNA]: [enzyme] > 1 the aggregates are dissociated to yield the one-to-one RNA-enzyme complex.     

The use of affinity elution from Blue Dextran Sepharose by yeast tRNA2Val in the complete purification of the cytoplasmic valyl-tRNA synthetase from Euglena gracilis

Two distinct monomers, α and β participate in the structures of diffe$\text{r}$ ent oligomers of $\text{Neurospora crassa}$ glutamine synthetase (EC 6. 3. 1. 2). In ammonium-limited cultures a tetrameric form composed mainly of α monomers was found. In excess of nitrogen an octameric form composed mainly from β monomers is the predominant oligomeric state. The presence of both monomers was observed in intermediate oligomeric forms.     

tRNA discrimination by T. thermophilus phenylalanyl-tRNA synthetase at the binding step

The extent of tRNA recognition at the level of binding by Thermus thermophilus phenylalanyl-tRNA synthetase (PheRS), one of the most complex class II synthetases, has been studied by independent measurements of the enzyme association with wild-type and mutant tRNA(Phe)s as well as with non-cognate tRNAs. The data obtained, combined with kinetic data on aminoacylation, clearly show that PheRS exhibits more tRNA selectivity at the level of binding than at the level of catalysis. The anticodon nucleotides involved in base-specific interactions with the enzyme prevail both in the initial binding recognition and in favouring aminoacylation catalysis. Tertiary nucleotides of base pair G19-C56 and base triple U45-G10-C25 contribute primarily to stabilization of the correctly folded tRNA(Phe) structure, which is important for binding. Other nucleotides of the central core (U20, U16 and of the A26-G44 tertiary base pair) are involved in conformational adjustment of the tRNA upon its interaction with the enzyme. The specificity of nucleotide A73, mutation of which slightly reduces the catalytic rate of aminoacylation, is not displayed at the binding step. A few backbone-mediated contacts of PheRS with the acceptor and anticodon stems revealed in the crystal structure do not contribute to tRNA(Phe) discrimination, their role being limited to stabilization of the complex. The highest affinity of T. thermophilus PheRS for cognate tRNA, observed for synthetase-tRNA complexes, results in 100-3000-fold binding discrimination against non-cognate tRNAs.     

Crucial role of conserved lysine 277 in the fidelity of tRNA aminoacylation by Escherichia coli valyl-tRNA synthetase

Valyl-tRNA synthetase (ValRS) from Escherichia coli undergoes covalent valylation by a donor valyl adenylate synthesized by the enzyme itself. ValRS could also be modified, although to a lesser extent, by the noncognate isosteric substrate L-threonine from a donor threonyl adenylate synthesized by the synthetase itself, or by the nonsubstrate methionine from methionyl adenylate produced by catalytic amounts of methionyl-tRNA synthetase. MALDI mass spectrometry analysis designated lysines 154, 162, 170, 533, 554, 593, 894, 930, and 940 of ValRS as the target residues for the attachment of valine. Following autothreonylation, lysines 162, 170, 178, 277, 291, 554, 580, 593, 861, 894, and 930 were found to be modified. Finally, L-Met-labeled residues were lysines 118, 162, 170, 178, 277, and 938. Alignment of the available ValRS amino acid sequences showed that lysines 277 and 554 are strictly conserved (with the exception concerning replacement of Lys-277 with a methionine or a tyrosine in archaebacteria), suggesting that these residues might be functionally significant. Indeed, lysine 554 of ValRS is the first lysine of the Lys-Met-Ser-Lys-Ser signature of the catalytic site of class I aminoacyl-tRNA synthetases. Lys-277 which is labeled by L-threonine or L-methionine, and not by L-valine, is located at or near the editing site, in the three-dimensional structure of ValRS. The role of lysine 277 was evaluated by site-directed mutagenesis. The Lys277Ala mutant (K277A) exhibited a posttransfer Thr-tRNA(Val) editing rate that was significantly lower than that observed for the wild-type enzyme. In addition, the K277A substitution altered amino acid discrimination in the editing site, resulting in hydrolysis of the correctly charged cognate Val-tRNA(Val). Finally, significant amounts of mischarged Thr-tRNA(Val) were produced by the K277A mutant, and not by wild-type ValRS. Altogether, our results designate Lys-277 as a likely candidate for nucleophilic attack of misacylated tRNA in the editing site of ValRS.