Interaction of eukaryotic threonyl-tRNA synthetase with high-Mr RNAs and tRNA(Thr)

Threonyl-tRNA synthetase of rabbit reticulocytes was purified to homogeneity. We have found that this enzyme can interact not only with cognate tRNA(Thr), but also with high-Mr RNAs. tRNA(Thr) removes rRNA from the complexes with threonyl-tRNA synthetase. On the other hand, rRNA is unable to dissociate tRNA(Thr) from the complexes with the enzyme. Despite its dimeric organization, threonyl-tRNA synthetase is unable to form stable ternary complexes with tRNA(Thr) and rRNA. In the extract of rabbit reticulocytes about one-third of the threonyl-tRNA synthetase molecules are in association with cognate tRNA(Thr) and thus are unable to interact with high-Mr RNAs.     

Escherichia coli threonyl-tRNA synthetase and tRNA(Thr) modulate the binding of the ribosome to the translational initiation site of the thrS mRNA

Escherichia coli threonyl-tRNA synthetase binds to the leader region of its own mRNA at two major sites: the first shares some analogy with the anticodon arm of several tRNA(Thr) isoacceptors and the second corresponds to a stable stem-loop structure upstream from the first one. The binding of the enzyme to its mRNA target site represses its translation by preventing the ribosome from binding to its attachment site. The enzyme is still able to bind to derepressed mRNA mutants resulting from single substitutions in the anticodon-like arm. This binding is restricted to the stem-loop structure of the second site. However, the interaction of the enzyme with this site fails to occlude ribosome binding. tRNA(Thr) is able to displace the wild-type mRNA from the enzyme at both sites and suppresses the inhibitory effect of the synthetase on the formation of the translational initiation complex. Our results show that tRNA(Thr) acts as an antirepressor on the synthesis of its cognate aminoacyl-tRNA synthetase. This repression/derepression double control allows precise adjustment of the rate of synthesis of threonyl-tRNA synthetase to the tRNA level in the cell.     

Domains of the Escherichia coli threonyl-tRNA synthetase translational operator and their relation to threonine tRNA isoacceptors.

The expression of the gene for threonyl-tRNA synthetase (thrS) is negatively autoregulated at the translational level in Escherichia coli. The synthetase binds to a region of the thrS leader mRNA upstream from the ribosomal binding site inhibiting subsequent translation. The leader mRNA consists of four structural domains. The present work shows that mutations in these four domains affect expression and/or regulation in different ways. Domain 1, the 3' end of the leader, contains the ribosomal binding site, which appears not to be essential for synthetase binding. Mutations in this domain probably affect regulation by changing the competition between the ribosome and the synthetase for binding to the leader. Domain 2, 3' from the ribosomal binding site, is a stem and loop with structural similarities to the tRNA(Thr) anticodon arm. In tRNAs the anticodon loop is seven nucleotides long, mutations that increase or decrease the length of the anticodon-like loop of domain 2 from seven nucleotides abolish control. The nucleotides in the second and third positions of the anticodon-like sequence are essential for recognition and the nucleotide in the wobble position is not, again like tRNA(Thr). The effect of mutations in domain 3 indicate that it acts as an articulation between domains 2 and 4. Domain 4 is a stable arm that has similarities to the acceptor arm of tRNA(Thr) and is shown to be necessary for regulation. Based on this mutational analysis and previous footprinting experiments, it appears that domains 2 and 4, those analogous to tRNA(Thr), are involved in binding the synthetase which inhibits translation probably by interfering with ribosome loading at the nearby translation initiation site.     

Recognition of acceptor-stem structure of tRNA(Asp) by Escherichia coli aspartyl-tRNA synthetase

Protein-RNA recognition between aminoacyl-tRNA synthetases and tRNA is highly specific and essential for cell viability. We investigated the structure-function relationships involved in the interaction of the Escherichia coli tRNA(Asp) acceptor stem with aspartyl-tRNA synthetase. The goal was to isolate functionally active mutants and interpret them in terms of the crystal structure of the synthetase-tRNA(Asp) complex. Mutants were derived from Saccharomyces cerevisiae tRNA(Asp), which is inactive with E. coli aspartyl-tRNA synthetase, allowing a genetic selection of active tRNAs in a tRNA(Asp) knockout strain of E. coli. The mutants were obtained by directed mutagenesis or library selections that targeted the acceptor stem of the yeast tRNA(Asp) gene. The mutants provide a rich source of tRNA(Asp) sequences, which show that the sequence of the acceptor stem can be extensively altered while allowing the tRNA to retain substantial aminoacylation and cell-growth functions. The predominance of tRNA backbone-mediated interactions observed between the synthetase and the acceptor stem of the tRNA in the crystal and the mutability of the acceptor stem suggest that many of the corresponding wild-type bases are replaceable by alternative sequences, so long as they preserve the initial backbone structure of the tRNA. Backbone interactions emerge as an important functional component of the tRNA-synthetase interaction.     

Autogenous repression of Escherichia coli threonyl-tRNA synthetase expression in vitro

Escherichia coli threonyl-tRNA synthetase (EC 6.1.1.3) expression has been examined in an acellular protein-synthesizing system programmed with a plasmid DNA carrying thrS, infC, pheS, and pheT, the gene for threonyl-tRNA synthetase, initiation factor 3, and the two protomers of phenylalanyl-tRNA synthetase (EC 6.1.1.20), respectively. The initial rate of synthesis of L-[35S]methionine-labeled threonyl-tRNA synthetase is markedly reduced by the addition of homogeneous RNase-free threonyl-tRNA synthetase to the assay, not by that of phenylanyl- or tyrosyl-tRNA synthetase (EC 6.1.1.1). The inhibition is 50% in the presence of 0.25 microM threonyl-tRNA synthetase and reaches 90% with 2 microM enzyme. Synthesis of mRNA in the acellular DNA-dependent protein-synthesizing system has been measured by molecular hybridization to gene-specific lambda DNA probes corresponding to thrS, pheS, and pheT. The addition to the assay of 2 microM threonyl-tRNA synthetase does not affect the extent of mRNA hybridizing to the thrS-specific DNA probe. This result is interpreted as reflecting an effect of the synthetase on its expression at the translational level. Analysis of the DNA sequence of the thrS gene predicts several potential secondary structures capable of forming in the thrS mRNA. One of these potential structures is a cloverleaf. The possible role of such structures in controlling expression of thrS is discussed.     

Autogenous control of Escherichia coli threonyl-tRNA synthetase expression in vivo

The regulation of the expression of thrS, the structural gene for threonyl-tRNA synthetase, was studied using several thrS-lac fusions cloned in lambda and integrated as single copies at att lambda. It is first shown that the level of beta-galactosidase synthesized from a thrS-lac protein fusion is increased when the chromosomal copy of thrS is mutated. It is also shown that the level of beta-galactosidase synthesized from the same protein fusion is decreased if wild-type threonyl-tRNA synthetase is overproduced from a thrS-carrying plasmid. These results strongly indicate that threonyl-tRNA synthetase controls the expression of its own gene. Consistent with this hypothesis it is shown that some thrS mutants overproduce a modified form of threonyl-tRNA synthetase. When the thrS-lac protein fusion is replaced by several types of thrS-lac operon fusions no effect of the chromosomal thrS allele on beta-galactosidase synthesis is observed. It is also shown that beta-galactosidase synthesis from a promoter-proximal thrS-lac operon fusion is not repressed by threonyl-tRNA synthetase overproduction. The fact that regulation is seen with a thrS-lac protein fusion and not with operon fusions indicates that thrS expression is autoregulated at the translational level. This is confirmed by hybridization experiments which show that under conditions where beta-galactosidase synthesis from a thrS-lac protein fusion is derepressed three- to fivefold, lac messenger RNA is only slightly increased.     

Tertiary structure of animal tRNATrp in solution and interaction of tRNATrp with tryptophanyl-tRNA synthetase

Alkylation in beef tRNATrp of phosphodiester bonds by ethylnitrosourea and of N-7 in guanosines and N-3 in cytidines by dimethyl sulfate and carbethoxylation of N-7 in adenosines by diethyl pyrocarbonate were investigated under various conditions. This enabled us to probe the accessibility of tRNA functional groups and to investigate the structure of tRNATrp in solution as well as its interactions with tryptophanyl-tRNA synthetase. The phosphate reactivity towards ethylnitrosourea of unfolded tRNA was compared to that of native tRNA. The pattern of phosphate alkylation of tRNATrp is very similar to that found with other tRNAs studied before using the same approach with protected phosphates mainly located in the D and T psi arms. Base modification experiments showed a striking similarity in the reactivity of conserved bases known to be involved in secondary and tertiary interactions. Differences are found with yeast tRNAPhe since beef tRNATrp showed a more stable D stem and a less stable T psi stem. When alkylation by ethylnitrosourea was studied with the tRNATrp X tryptophanyl-tRNA synthetase complex we found that phosphates located at the 5' side of the anticodon stem and in the anticodon loop were strongly protected against the reagent. The alkylation at the N-3 position of the two cytidines in the CCA anticodon was clearly diminished in the synthetase X tRNA complex as compared with the modification in free tRNATrp; in contrast the two cytidines of the terminal CCA in the acceptor stem are not protected by the synthetase. The involvement of the anticodon region of tRNATrp in the recognition process with tryptophanyl-tRNA synthetase was confirmed in nuclease S1 mapping experiments.     

Cocrystallization of Lysyl–tRNA synthetase from Thermus thermophilus with its cognate tRNAlys and with Escherichia coli tRNAlys

Lysyl-tRNA synthetase from Thermus thermophilus has been cocrystallized with either its cognate tRNA^lYS or Escherichia coli tRNA^lys using ammonium sulfate as precipitant. The crystals grow from solutions containing a 1:2.5 stoichiometry of synthetase dimer to tRNA in 18–22% ammonium sulfate in 50 mM Tris-maleate buffer at pH 7.5. Both complexes form square prismatic, tetragonal crystals with very similar unit cell parameters (a = b = 233 Å, c = 119 Å) and diffract to at least 2.7 Å resolution. However the homocomplex is of space group P42₁2 and the heterocomplex of space group I422. © 1995 Wiley-Liss, Inc.     

The translational regulation of threonyl-tRNA synthetase. Functional relationship between the enzyme, the cognate tRNA and the ribosome

The E. coli threonyl-tRNA synthetase gene is negatively autoregulated at the translational level by a direct binding of the enzyme to the leader region of the thrS mRNA. This region folds in four well-defined domains. The enzyme binds to the leader at two major sites: the first is a stem-loop structure located in domain II upstream of the translational initiation site (domain I) which shares structural analogies with the anticodon arm of several tRNA(Thr) isoacceptors. The second site corresponds to a stable stem-loop structure located in domain IV. Both sites are separated by a large unpaired region (domain III). In vivo and in vitro experiments show that the structural integrity of both sites is required for the regulatory process. The binding of the enzyme to its mRNA target site represses its translation by preventing the ribosome from binding to its attachment site. tRNA(Thr) suppresses this inhibitory effect by displacing the mRNA from the enzyme at both the upstream stem-loop structure and the tRNA-like anticodon arm.     

Allosteric interaction of nucleotides and tRNA(ala) with E. coli alanyl-tRNA synthetase

Alanyl-tRNA synthetase, a dimeric class 2 aminoacyl-tRNA synthetase, activates glycine and serine at significant rates. An editing activity hydrolyzes Gly-tRNA(ala) and Ser-tRNA(ala) to ensure fidelity of aminoacylation. Analytical ultracentrifugation demonstrates that the enzyme is predominately a dimer in solution. ATP binding to full length enzyme (ARS875) and to an N-terminal construct (ARS461) is endothermic (ΔH = 3-4 kcal mol(-1)) with stoichiometries of 1:1 for ARS461 and 2:1 for full-length dimer. Binding of aminoacyl-adenylate analogues, 5'-O-[N-(L-alanyl)sulfamoyl]adenosine (ASAd) and 5'-O-[N-(L-glycinyl)sulfamoyl]adenosine (GSAd), are exothermic; ASAd exhibits a large negative heat capacity change (ΔC(p) = 0.48 kcal mol(-1) K(-1)). Modification of alanyl-tRNA synthetase with periodate-oxidized tRNA(ala) (otRNA(ala)) generates multiple, covalent, enzyme-tRNA(ala) products. The distribution of these products is altered by ATP, ATP and alanine, and aminoacyl-adenylate analogues (ASAd and GSAd). Alanyl-tRNA synthetase was modified with otRNA(ala), and tRNA-peptides from tryptic digests were purified by ion exchange chromatography. Six peptides linked through a cyclic dehydromoropholino structure at the 3'-end of tRNA(ala) were sequenced by mass spectrometry. One site lies in the N-terminal adenylate synthesis domain (residue 74), two lie in the opening to the editing site (residues 526 and 585), and three (residues 637, 639, and 648) lie on the back side of the editing domain. At least one additional modification site was inferred from analysis of modification of ARS461. The location of the sites modified by otRNA(ala) suggests that there are multiple modes of interaction of tRNA(ala) with the enzyme, whose distribution is influenced by occupation of the ATP binding site.     

Induced fit and kinetic mechanism of adenylation catalyzed by Escherichia coli threonyl-tRNA synthetase

Threonyl-tRNA synthetase (ThrRS) must discriminate among closely related amino acids to maintain the fidelity of protein synthesis. Here, a pre-steady state kinetic analysis of the ThRS-catalyzed adenylation reaction was carried out by monitoring changes in intrinsic tryptophan fluorescence. Stopped flow fluorimetry for the forward reaction gave a saturable fluorescence quench whose apparent rate increased hyperbolically with ATP concentration, consistent with a two-step mechanism in which rapid substrate binding precedes an isomerization step. From similar experiments, the equilibrium dissociation constants for dissociation of ATP from the E.Thr complex (K(3) = 450 +/- 180 microM) and threonine from the E.ATP complex (K'(4) = 135 microM) and the forward rate constant for adenylation (k(+5) = 29 +/- 4 s(-1)) were determined. A saturable fluorescence increase accompanied the pyrophosphorolysis of the E.Thr - AMP complex, affording the dissociation constant for PP(i) (K(6) = 170 +/- 50 microM) and the reverse rate constant (k(-5) = 47 +/- 4 s(-1)). The longer side chain of beta-hydroxynorvaline increased the apparent dissociation constant (K(4[HNV]) = 6.8 +/- 2.8 mM) with only a small reduction in the forward rate (k'(+5[HNV]) = 20 +/- 3.1 s(-1)). In contrast, two nonproductive substrates, threoninol and the adenylate analogue 5'-O-[N-(L-threonyl)sulfamoyl]adenosine (Thr-AMS), exhibited linear increases in k(app) with ligand concentration, suggesting that their binding is slow relative to isomerization. The proposed mechanism is consistent with steady state kinetic parameters. The role of threonine binding loop residue Trp434 in fluorescence changes was established by mutagenesis. The combined kinetic and molecular genetic analyses presented here support the principle of induced fit in the ThrRS-catalyzed adenylation reaction, in which substrate binding drives conformational changes that orient substrates and active site groups for catalysis.     

Binding of the anticodon domain of tRNA(fMet) to Escherichia coli methionyl-tRNA synthetase

A stem and loop RNA domain carrying the methionine anticodon (CAU) was designed from the tRNA(fMet) sequence and produced in vitro. This domain makes a complex with methionyl-tRNA synthetase (Kd = 38(+/- 5) microM; 25 degrees C, pH 7.6, 7 mM-MgCl2). The formation of this complex is dependent on the presence of the cognate CAU anticodon sequence. Recognition of this RNA domain is abolished by a methionyl-tRNA synthetase mutation known to alter the binding of tRNA(Met).     

Solution structure of the Escherichia coli YojN histidine-phosphotransferase domain and its interaction with cognate phosphoryl receiver domains

The Rcs signaling system in Escherichia coli controls a variety of physiological functions, including capsule synthesis, cell division and motility. The activity of the central regulator RcsB is modulated by phosphorylation through the sensor kinases YojN and RcsC, with the YojN histidine phosphotransferase (HPt) domain representing the catalytic unit that coordinates the potentially reversible phosphotransfer reaction between the receiver domains of the RcsB and RcsC proteins. Heteronuclear high-resolution NMR spectroscopy was employed to determine the solution structure of the YojN-HPt domain and to map the interaction with its two cognate receiver domains. The solution structure of YojN-HPt exhibits a well-ordered and rigid protein core consisting of the five helices alphaI to alphaV. The helices alphaII to alphaV form a four-helix bundle signature motif common to proteins of similar function, and helix alphaI forms a cap on top of the bundle. The helix alphaII is separated by a proline induced kink into two parts with different orientations and dynamic behavior that is potentially important for complex formation with other proteins. The N-terminal part of YojN-HPt spanning the first 26 amino acid residues seems to contain neither a regular secondary structure nor a stable tertiary structure and is disordered in solution. The identified YojN-HPt recognition sites for the regulator RcsB and for the isolated receiver domain of the RcsC kinase largely overlap in defined regions of the helices alphaII and alphaIII, but show significant differences. Using the residues with the largest chemical shift changes obtained from titration experiments, we observed a dissociation constant of approximately 200microM for YojN-HPt/RcsC-PR and of 40microM for YojN-HPt/RcsB complexes. Our data indicate the presence of a recognition area in close vicinity to the active-site histidine residue of HPt domains as a determinant of specificity in signal-transduction pathways.