Tertiary structure of Escherichia coli tRNA(3Thr) in solution and interaction of this tRNA with the cognate threonyl-tRNA synthetase

pH-driven conformational switch between non-canonical DNA structures in a C-rich domain of EGFR promoter

EGFR is an oncogene that encodes for a trans-membrane tyrosine kinase receptor. Its mis-regulation is associated to several human cancers that, consistently, can be treated by selective tyrosine kinase inhibitors. The proximal promoter of EGFR contains a G-rich domain located at 272 bases upstream the transcription start site. We previously proved it folds into two main interchanging G-quadruplex structures, one of parallel and one of hybrid topology. Here we present the first evidences supporting the ability of the complementary C-rich strand (EGFR-272_C) to assume an intramolecular i-Motif (iM) structure that, according to the experimental conditions (pH, presence of co-solvent and salts), can coexist with a different arrangement we referred to as a hairpin. The herein identified iM efficiently competes with the canonical pairing of the two complementary strands, indicating it as a potential novel target for anticancer therapies. A preliminary screening for potential binders identified some phenanthroline derivatives as able to target EGFR-272_C at multiple binding sites when it is folded into an iM.

NAD captureSeq indicates NAD as a bacterial cap for a subset of regulatory RNAs

A distinctive feature of prokaryotic gene expression is the absence of 5'-capped RNA. In eukaryotes, 5',5'-triphosphate-linked 7-methylguanosine protects messenger RNA from degradation and modulates maturation, localization and translation. Recently, the cofactor nicotinamide adenine dinucleotide (NAD) was reported as a covalent modification of bacterial RNA. Given the central role of NAD in redox biochemistry, posttranslational protein modification and signalling, its attachment to RNA indicates that there are unknown functions of RNA in these processes and undiscovered pathways in RNA metabolism and regulation. The unknown identity of NAD-modified RNAs has so far precluded functional analyses. Here we identify NAD-linked RNAs from bacteria by chemo-enzymatic capture and next-generation sequencing (NAD captureSeq). Among those identified, specific regulatory small RNAs (sRNAs) and sRNA-like 5'-terminal fragments of certain mRNAs are particularly abundant. Analogous to a eukaryotic cap, 5'-NAD modification is shown in vitro to stabilize RNA against 5'-processing by the RNA-pyrophosphohydrolase RppH and against endonucleolytic cleavage by ribonuclease (RNase) E. The nudix phosphohydrolase NudC decaps NAD-RNA and thereby triggers RNase-E-mediated RNA decay, while being inactive against triphosphate-RNA. In vivo, ∼13% of the abundant sRNA RNAI is NAD-capped in the presence, and ∼26% in the absence, of functional NudC. To our knowledge, this is the first description of a cap-like structure and a decapping machinery in bacteria.

Atypical archaeal tRNA pyrrolysine transcript behaves towards EF-Tu as a typical elongator tRNA

The newly discovered tRNA(Pyl) is involved in specific incorporation of pyrrolysine in the active site of methylamine methyltransferases in the archaeon Methanosarcina barkeri. In solution probing experiments, a transcript derived from tRNA(Pyl) displays a secondary fold slightly different from the canonical cloverleaf and interestingly similar to that of bovine mitochondrial tRNA(Ser)(uga). Aminoacylation of tRNA(Pyl) transcript by a typical class II synthetase, LysRS from yeast, was possible when its amber anticodon CUA was mutated into a lysine UUU anticodon. Hydrolysis protection assays show that lysylated tRNA(Pyl) can be recognized by bacterial elongation factor. This indicates that no antideterminant sequence is present in the body of the tRNA(Pyl) transcript to prevent it from interacting with EF-Tu, in contrast with the otherwise functionally similar tRNA(Sec) that mediates selenocysteine incorporation.

The modular structure of Escherichia coli threonyl-tRNA synthetase as both an enzyme and a regulator of gene expression

In addition to its role in tRNA aminoacylation, Escherichia coli threonyl-tRNA synthetase is a regulatory protein which binds a site, called the operator, located in the leader of its own mRNA and inhibits translational initiation by competing with ribosome binding. This work shows that the two essential steps of regulation, operator recognition and inhibition of ribosome binding, are performed by different domains of the protein. The catalytic and the C-terminal domain of the protein are involved in binding the two anticodon arm-like structures in the operator whereas the N-terminal domain of the enzyme is responsible for the competition with the ribosome. This is the first demonstration of a modular structure for a translational repressor and is reminiscent of that of transcriptional regulators. The mimicry between the operator and tRNA, suspected on the basis of previous experiments, is further supported by the fact that identical regions of the synthetase recognize both the operator and the tRNA anticodon arm. Based on these results, and recent structural data, we have constructed a computer-derived molecular model for the operator-threonyl-tRNA synthetase complex, which sheds light on several essential aspects of the regulatory mechanism.

Recognition of tRNA backbone for aminoacylation with cysteine: evolution from Escherichia coli to human

The underlying basis of the genetic code is specific aminoacylation of tRNAs by aminoacyl-tRNA synthetases. Although the code is conserved, bases in tRNA that establish aminoacylation are not necessarily conserved. Even when the bases are conserved, positions of backbone groups that contribute to aminoacylation may vary. We show here that, although the Escherichia coli and human cysteinyl-tRNA synthetases both recognize the same bases (U73 and the GCA anticodon) of tRNA for aminoacylation, they have different emphasis on the tRNA backbone. The E. coli enzyme recognizes two clusters of phosphate groups. One is at A36 in the anticodon and the other is in the core of the tRNA structure and includes phosphate groups at positions 9, 12, 14, and 60. Metal-ion rescue experiments show that those at positions 9, 12, and 60 are involved with binding divalent metal ions that are important for aminoacylation. The E. coli enzyme also recognizes 2'-hydroxyl groups within the same two clusters: at positions 33, 35, and 36 in the anticodon loop, and at positions 49, 55, and 61 in the core. The human enzyme, by contrast, recognizes few phosphate or 2'-hydroxy groups for aminoacylation. The evolution from the backbone-dependent recognition by the E. coli enzyme to the backbone-independent recognition by the human enzyme demonstrates a previously unrecognized shift that nonetheless has preserved the specificity for aminoacylation with cysteine.

Alternative design of a tRNA core for aminoacylation

The core of Escherichia coli tRNA(Cys) is important for aminoacylation of the tRNA by cysteine-tRNA synthetase. This core differs from the common tRNA core by having a G15:G48, rather than a G15:C48 base-pair. Substitution of G15:G48 with G15:C48 decreases the catalytic efficiency of aminoacylation by two orders of magnitude. This indicates that the design of the core is not compatible with G15:C48. However, the core of E. coli tRNA(Gln), which contains G15:C48, is functional for cysteine-tRNA synthetase. Here, guided by the core of E. coli tRNA(Gln), we sought to test and identify alternative functional design of the tRNA(Cys) core that contains G15:C48. Although analysis of the crystal structure of tRNA(Cys) and tRNA(Gln) implicated long-range tertiary base-pairs above and below G15:G48 as important for a functional core, we showed that this was not the case. The replacement of tertiary interactions involving 9, 21, and 59 in tRNA(Cys) with those in tRNA(Gln) did not construct a functional core that contained G15:C48. In contrast, substitution of nucleotides in the variable loop adjacent to 48 of the 15:48 base-pair created functional cores. Modeling studies of a functional core suggests that the re-constructed core arose from enhanced stacking interactions that compensated for the disruption caused by the G15:C48 base-pair. The repacked tRNA core displayed features that were distinct from those of the wild-type and provided evidence that stacking interactions are alternative means than long-range tertiary base-pairs to a functional core for aminoacylation.

The structure of threonyl-tRNA synthetase-tRNA(Thr) complex enlightens its repressor activity and reveals an essential zinc ion in the active site

E. coli threonyl-tRNA synthetase (ThrRS) is a class II enzyme that represses the translation of its own mRNA. We report the crystal structure at 2.9 A resolution of the complex between tRNA(Thr) and ThrRS, whose structural features reveal novel strategies for providing specificity in tRNA selection. These include an amino-terminal domain containing a novel protein fold that makes minor groove contacts with the tRNA acceptor stem. The enzyme induces a large deformation of the anticodon loop, resulting in an interaction between two adjacent anticodon bases, which accounts for their prominent role in tRNA identity and translational regulation. A zinc ion found in the active site is implicated in amino acid recognition/discrimination.

Universal rules and idiosyncratic features in tRNA identity

Correct expression of the genetic code at translation is directly correlated with tRNA identity. This survey describes the molecular signals in tRNAs that trigger specific aminoacylations. For most tRNAs, determinants are located at the two distal extremities: the anticodon loop and the amino acid accepting stem. In a few tRNAs, however, major identity signals are found in the core of the molecule. Identity elements have different strengths, often depend more on k cat effects than on K m effects and exhibit additive, cooperative or anti-cooperative interplay. Most determinants are in direct contact with cognate synthetases, and chemical groups on bases or ribose moieties that make functional interactions have been identified in several systems. Major determinants are conserved in evolution; however, the mechanisms by which they are expressed are species dependent. Recent studies show that alternate identity sets can be recognized by a single synthetase, and emphasize the importance of tRNA architecture and anti-determinants preventing false recognition. Identity rules apply to tRNA-like molecules and to minimalist tRNAs. Knowledge of these rules allows the manipulation of identity elements and engineering of tRNAs with switched, altered or multiple specificities.

The Escherichia coli threonyl-tRNA synthetase gene contains a split ribosomal binding site interrupted by a hairpin structure that is essential for autoregulation

The expression of the gene encoding Escherichia coli threonyl-tRNA synthetase (ThrRS) is negatively autoregulated at the translational level. ThrRS binds to its own mRNA leader, which consists of four structural and functional domains: the Shine-Dalgarno (SD) sequence and the initiation codon region (domain 1); two upstream hairpins (domains 2 and 4) connected by a single-stranded region (domain 3). Using a combination of in vivo and in vitro approaches, we show here that the ribosome binds to thrS mRNA at two non-contiguous sites: region -12 to +16 comprising the SD sequence and the AUG codon and, unexpectedly, an upstream single-stranded sequence in domain 3. These two regions are brought into close proximity by a 38-nucleotide-long hairpin structure (domain 2). This domain, although adjacent to the 5' edge of the SD sequence, does not inhibit ribosome binding as long as the single-stranded region of domain 3 is present. A stretch of unpaired nucleotides in domain 3, but not a specific sequence, is required for efficient translation. As the repressor and the ribosome bind to interspersed domains, the competition between ThrRS and ribosome for thrS mRNA binding can be explained by steric hindrance.

A strategy of tRNA recognition that includes determinants of RNA structure

Recognition of tRNAs by aminoacyl tRNA synthetases establishes the connection between amino acids and anticodon triplets of the genetic code. Although anticodons and nucleotides adjacent to the amino acid attachment site are generally important, the tertiary structural framework of tRNAs has recently been implicated to have a role in tRNA recognition. A G15:G48 tertiary hydrogen base pair of E. coli tRNA(Cys) is important for recognition of the tRNA by cysteine tRNA synthetase. This base pair is proposed to consist of N2:N3, rather than N1:O6, hydrogen bonds. The reproduction of the hydrogen pairing scheme of tRNA(Gly). This reproduction required an A13:A22 mismatch in the dihyrouridine stem. To determine if A13:A22 is a determinant of the structural features of G15:G48, we investigated the A15:U48 and A15:A48 variants of tRNA(Gly) which harbored specific substitutions of A13:A22. We show here that introduction of A13:A22 to both tRNA frameworks confers structural features similar to those of G15:G48 in E. coli tRNA(Cys). These structural features are accompanied by efficient recognition of both tRNAs by cysteine tRNA synthetase. Substitution of A13:A22 with U13:A22 alters the structural features at 15:48 and impairs tRNA recognition. The dependence on A13:22 for tRNA recognition has a distinct similarity to that of E. coli tRNA(Cys) and to that of the G15:G48 variant of tRNA(Gly). The results have implications for the design and manipulation of RNA structural elements as the basis for tRNA recognition.

Structural elements that contribute to an unusual tertiary interaction in a transfer RNA

Transfer RNAs (tRNAs) contain a set of defined tertiary hydrogen-bonding interactions that are established between conserved and semiconserved nucleotides. Although the crystal structures of tRNAs describe each of the tertiary interactions in detailed molecular terms, little is known about the underlying structural parameters that stabilize the tertiary interactions. Escherichia coli (E. coli) tRNA(Cys) has an unusual tertiary interaction between G15 in the dihydrouridine (D) loop and G48 in the variable loop that is critical for cysteine aminoacylation. All other tRNAs have a purine 15 and a complementary pyrimidine 48 that establish a tertiary interaction known as the Levitt base pair [Levitt, M. (1969) Nature 224, 759-763; Klug et al. (1974) J. Mol. Biol. 89, 511-516]. In this study, the G15.G48 tertiary interaction in E. coli tRNA(Cys) was used to investigate the structural elements that contribute to its variation from the Levitt base pair. Analysis with chemical probes showed that substitution of U21 with A21 in the D loop and formation of a Watson-Crick base pair between nucleotides 13 and 22 in the D stem switch the hydrogen-pairing of G15.G48 to a Levitt-like G15.G48 base pair. This switch was accompanied by a decrease of the catalytic efficiency of aminoacylation by 2 orders of magnitude. In contrast, insertion of additional nucleotides in the D or variable loops had little effect.(ABSTRACT TRUNCATED AT 250 WORDS)

Threonyl-tRNA synthetase from Thermus thermophilus: purification and some structural and kinetic properties

Threonyl-tRNA synthetase (ThrRS) has been isolated from an extreme thermophile Thermus thermophilus strain HB8. The enzyme was purified to electrophoretic homogeneity by combinations of column chromatographies on DEAE-Sepharose, S-Sepharose, ACA-44 Ultrogel and HA-Ultrogel. Seventeen mg of purified enzyme were obtained from 1 kg of biomass. In parallel, purified aspartyl- and phenylalanyl-tRNA synthetases were obtained. The purified ThrRS is composed of two identical subunits with a molecular mass of about 77,000 (virtually the same as E coli ThrRS). The N-terminal sequence has been determined. The homology between the first 45 amino acid residues of ThrRS from T thermophilus and E coli is about 29%. A comparative study of tRNA(Thr) charging by ThrRS from E coli and T thermophilus reveals a similar efficiency of the reaction in both homologous systems. This efficiency remains unchanged for aminoacylation of tRNA(Thr) from T thermophilus by the heterologous ThrRS from E coli, but decreases 700 times for aminoacylation of E coli tRNA(Thr) by ThrRS from T thermophilus.

An unusual RNA tertiary interaction has a role for the specific aminoacylation of a transfer RNA

The nucleotides in a tRNA that specifically interact with the cognate aminoacyl-tRNA synthetase have been found largely located in the helical stems, the anticodon, or the discriminator base, where they vary from one tRNA to another. The conserved and semiconserved nucleotides that are responsible for the tRNA tertiary structure have been shown to have little role in synthetase recognition. Here we report that aminoacylation of Escherichia coli tRNA(Cys) depends on the anticodon, the discriminator base, and a tertiary interaction between the semiconserved nucleotides at positions 15 and 48. While all other tRNAs contain a purine at position 15 and a complementary pyrimidine at position 48 that establish the tertiary interaction known as the Levitt pair, E. coli tRNA(Cys) has guanosine -15 and -48. Replacement of guanosine -15 or -48 with cytidine virtually eliminates aminoacylation. Structural analyses with chemical probes suggest that guanosine -15 and -48 interact through hydrogen bonds between the exocyclic N-2 and ring N-3 to stabilize the joining of the two long helical stems of the tRNA. This tertiary interaction is different from the traditional base pairing scheme in the Levitt pair, where hydrogen bonds would form between N-1 and O-6. Our results provide evidence for a role of RNA tertiary structure in synthetase recognition.

Translational regulation of the Escherichia coli threonyl-tRNA synthetase gene: structural and functional importance of the thrS operator domains

Previous work showed that E coli threonyl-tRNA synthetase (ThrRS) binds to the leader region of its own mRNA and represses its translation by blocking ribosome binding. The operator consists of four distinct domains, one of them (domain 2) sharing structural analogies with the anticodon arm of the E coli tRNA(Thr). The regulation specificity can be switched by using tRNA identity rules, suggesting that the operator could be recognized by ThrRS as a tRNA-like structure. In the present paper, we investigated the relative contribution of the four domains to the regulation process by using deletions and point mutations. This was achieved by testing the effects of the mutations on RNA conformation (by probing experiments), on ThrRS recognition (by footprinting experiments and measure of the competition with tRNA(Thr) for aminoacylation), on ribosome binding and ribosome/ThrRS competition (by toeprinting experiments). It turns out that: i) the four domains are structurally and functionally independent; ii) domain 2 is essential for regulation and contains the major structural determinants for ThrRS binding; iii) domain 4 is involved in control and ThrRS recognition, but to a lesser degree than domain 2. However, the previously described analogies with the acceptor-like stem are not functionally significant. How it is recognized by ThrRS remains to be resolved; iv) domain 1, which contains the ribosome loading site, is not involved in ThrRS recognition. The binding of ThrRS probably masks the ribosome binding site by steric hindrance and not by direct contacts. This is only achieved when ThrRS interacts with both domains 2 and 4; and v) the unpaired domain 3, which connects domains 2 and 4, is not directly involved in ThrRS recognition. It should serve as an articulation to provide an appropriate spacing between domains 2 and 4. Furthermore, it is possibly involved in ribosome binding.

Molecular mimicry in translational control of E. coli threonyl-tRNA synthetase gene. Competitive inhibition in tRNA aminoacylation and operator-repressor recognition switch using tRNA identity rules

We previously showed that: (i) E.coli threonyl-tRNA synthetase (ThrRS) binds to the leader of its mRNA and represses translation by preventing ribosome binding to its loading site; (ii) the translational operator shares sequence and structure similarities with tRNA(Thr); (iii) it is possible to switch the specificity of the translational control from ThrRS to methionyl-tRNA synthetase (MetRS) by changing the CGU anticodon-like sequence to CAU, the tRNA(Met) anticodon. Here, we show that the wild type (CGU) and the mutated (CAU) operators act as competitive inhibitors of tRNA(Thr) and tRNA(fMet) for aminoacylation catalyzed by E.coli ThrRS and MetRS, respectively. The apparent Kd of the MetRS/CAU operator complex is one order magnitude higher than that of the ThrRS/CGU operator complex. Although ThrRS and MetRS shield the anticodon- and acceptor-like domains of their respective operators, the relative contribution of these two domains differs significantly. As in the threonine system, the interaction of MetRS with the CAU operator occludes ribosome binding to its loading site. The present data demonstrate that the anticodon-like sequence is one major determinant for the identity of the operator and the regulation specificity. It further shows that the tRNA-like operator obeys to tRNA identity rules.

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.

Footprinting evidence for close contacts of the yeast tRNA(Asp) anticodon region with aspartyl-tRNA synthetase

Chemical footprinting experiments on brewer's yeast tRNA(Asp) complexed to its cognate aspartyl-tRNA synthetase are reported: they demonstrate that bases of the anticodon loop, including the anticodon itself, are in close proximity with the synthetase. Contacts were determined using dimethylsulfate as the probe for testing reactivity of guanine and cytosine residues in free and complexed tRNA. Results correlate with the decrease in aspartylation activity of yeast tRNA(Asp) molecules mutated at these contact positions and will be compared with other structural data arising from solution and crystallographic studies on the aspartic acid complex.

Identity determinants of E. coli threonine tRNA

To investigate the identity determinants of E. coli threonine tRNA, various transcripts were prepared by in vitro transcription system with T7 RNA polymerase. Substitutions of the anticodon second letter G35 and the third letter U36 to other nucleotides led to a remarkable decrease of threonine charging activity. Charging experiments with a series of anticodon-deletion transcripts also suggest the importance of the G35U36 sequence. A mutation at either the G1-C72 or C2-G71 base pair in the acceptor stem seriously affected the threonine charging activity. These results indicate that the second and third positions of the anticodon and the first and second base pairs in the acceptor stem are the recognition sites of E. coli tRNA(THR) for threonyl-tRNA synthetase. Discriminator base, A73, is not involved in threonine charging activity.

Interaction of Escherichia coli tRNA(Ser) with its cognate aminoacyl-tRNA synthetase as determined by footprinting with phosphorothioate-containing tRNA transcripts

A footprinting technique using phosphorothioate-containing RNA transcripts has been developed and applied to identify contacts between Escherichia coli tRNA(Ser) and its cognate aminoacyl-tRNA synthetase. The cloned gene for the tRNA was transcribed in four reactions in which a different NTP was complemented by 5% of the corresponding nucleoside 5'-O-(1-thiotriphosphate). The phosphorothioate groups of such transcripts are cleaved by reaction with iodine to permit sequencing of the transcripts. Footprinting was achieved by performing the same reaction with the phosphorothioate-tRNA-enzyme complex. At 1 mM iodine, selective protection of the tRNA transcripts in the cognate system was observed, with strong protection at positions 52 and 68 and weak protection at positions 46, 53, 67, 69, and 70. It is suggested that these regions of the tRNA interact with the helical arm of the synthetase.

Nucleotides that determine Escherichia coli tRNA(Arg) and tRNA(Lys) acceptor identities revealed by analyses of mutant opal and amber suppressor tRNAs

We have constructed an opal suppressor system in Escherichia coli to complement an existing amber suppressor system to study the structural basis of tRNA acceptor identity, particularly the role of middle anticodon nucleotide at position 35. The opal suppressor tRNA contains a UCA anticodon and the mRNA of the suppressed protein (which is easily purified and sequenced) contains a UGA nonsense triplet. Opal suppressor tRNAs of two tRNA(Arg) isoacceptor sequences each gave arginine in the suppressed protein, while the corresponding amber suppressors with U35 in their CUA anticodons each gave arginine plus a second amino acid in the suppressed protein. Since C35 but not U35 is present in the anticodon of wild-type tRNA(Arg) molecules, while the first anticodon position contains either C34 or U34, these results establish that C35 contributes to tRNA(Arg) acceptor identity. Initial characterizations of opal suppressor tRNA(Arg) mutants by suppression efficiency measurements suggest that the fourth nucleotide from the 3' end of tRNA(Arg) (A73 or G73 in different isoacceptors) also contributes to tRNA(Arg) acceptor identity. Wild-type and mutant versions of opal and amber tRNA(Lys) suppressors were examined, revealing that U35 and A73 are important determinants of tRNA(Lys) acceptor identity. Several possibilities are discussed for the general significance of having tRNA acceptor identity in the same positions in different tRNA acceptor types, as exemplified by positions 35 and 73 in tRNA(Arg) and tRNA(Lys).

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.

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.

The relation between catalytic activity and gene regulation in the case of E coli threonyl-tRNA synthetase

The expression of the gene for threonyl-tRNA synthetase (thrS) has previously been shown as being negatively autoregulated at the translational level. The region of the thrS leader mRNA responsible for that control is located immediately upstream of the ribosomal binding site, and was proposed to fold in a tRNA(Thr) anticodon arm-like structure. The present paper reviews experiments using enzymatic and chemical probes that prove the existence of a tRNA(Thr) anticodon-like structure in the thrS mRNA. These structural studies have also shown the presence of another arm upstream in the leader mRNA that has striking similarities with the acceptor arm of the tRNA(Thr) isoacceptors. This second arm was shown, by mutational analysis, to also be involved in thrS regulation. Footprinting experiments have shown that both the anticodon-like and the acceptor-like arms interact with the synthetase. Finally, the similarity of the interaction of the synthetase with its 2 RNA ligands (mRNA and tRNA) has been investigated by selecting and studying mutants of the synthetase itself. The observed correlation between regulatory and aminoacylation defects in these mutants strongly suggests that the synthetase recognizes similar regions of its 2 RNA ligands in an analogous manner.

Solution conformation of several free tRNALeu species from bean, yeast and Escherichia coli and interaction of these tRNAs with bean cytoplasmic Leucyl-tRNA synthetase. A phosphate alkylation study with ethylnitrosourea

The solution conformation of eight leucine tRNAs from Phaseolus vulgaris, baker's yeast and Escherichia coli, characterized by long variable regions, and the interaction of four of them with bean cytoplasmic leucyl-tRNA synthetase were studied by phosphate mapping with ethylnitrosourea. Phosphate reactivities in the variable regions agree with the existence of RNA helices closed by miniloops. At the junction of these regions with the T-stem, phosphate 48 is strongly protected, in contrast to small variable region tRNAs where P49 is protected. The constant protection of P22 is another characteristics of leucine tRNAs. Conformational differences between leucine isoacceptors concern the anticodon region, the D-arm and the variable region. In several parts of free tRNALeu species, e.g. in the T-loop, phosphate reactivities are similar to those found in tRNAs of other specificities, indicating conformational similarities among tRNAs. Phosphate alkylation of four leucine tRNAs complexed to leucyl-tRNA synthetase indicates that the 3'-side of the anticodon stem, the D-stem and the hinge region between the anticodon and D-stems are in contact with the plant enzyme.

The contacts of yeast tRNA(Ser) with seryl-tRNA synthetase studied by footprinting experiments

Yeast tRNA(Ser) is a member of the class II tRNAs, whose characteristic is the presence of an extended variable loop. This additional structural feature raises questions about the recognition of these class II tRNAs by their cognate synthetase and the possibility of the involvement of the extra arm in the recognition process. A footprinting study of yeast tRNA(Ser) complexed with its cognate synthetase, yeast seryl-tRNA synthetase (an alpha 2 dimer), was undertaken. Chemical (ethylnitrosourea) and enzymatic (nucleases S1 and V1) probes were used in the experiments. A map of the contact points between the tRNA and the synthetase was established and results were analyzed with respect to a three-dimensional model of yeast tRNA(Ser). Regions in close vicinity with the synthetase are clustered on one face of tRNA. The extra arm, which is strongly protected from chemical modifications, appears as an essential part of the contact area. The anticodon triplet and a large part of the anticodon arm are, in contrast, still accessible to the probes when the complex is formed. These results are discussed in the context of the recognition of tRNAs in the aminoacylation reaction.

New photoactivatable structural and affinity probes of RNAs: specific features and applications for mapping of spermine binding sites in yeast tRNA(Asp) and interaction of this tRNA with yeast aspartyl-tRNA synthetase

Aryldiazonium salts are shown to be useful as phototriggered structural probes for RNA mapping as well as for footprinting of RNA/protein interaction. In particular the yeast tRNA(Asp)/aspartyl-tRNA synthetase complex is shown to involve the variable loop face and the concave side of the L-shaped nucleic acid bound to a lipophilic area of the enzyme. When chemically linked to spermine, the photoactive group cleaves RNA at polyamine binding sites; 3-4 spermines have been located in the tRNA(Asp), stabilizing the central part of the molecule in regions where two ribose-phosphate strands are close to each other.

Structural analogies between the 3' tRNA-like structure of brome mosaic virus RNA and yeast tRNATyr revealed by protection studies with yeast tyrosyl-tRNA synthetase

Contacts between the tRNA-like domain in brome mosaic virus RNA and yeast tyrosyl-tRNA synthetase have been determined by footprinting with enzymatic probes. Regions in which the synthetase caused protections indicative of direct interaction coincide with loci identified by mutational studies as being important for efficient tyrosylation [Dreher, T. W. & Hall, T. C. (1988) J. Mol. Biol. 201, 41-55]. Additional extensive contacts were found upstream of the core of the tRNA-like structure. In parallel, the contacts of yeast tRNATyr with its cognate synthetase were determined by the same methodology and comparison of protected nucleotides in the two RNAs has permitted the assignment of structural analogies between domains in the viral tRNA-like structure and tRNATyr. Amino acid acceptor stems are similarly recognized by yeast tyrosyl-tRNA synthetase in the two RNAs, indicating that the pseudoknotted fold in the viral RNA does not perturb the interaction with the synthetase. A further important analogy appears between the anticodon/D arm of the L-conformation of tRNAs and a complex branched arm of the viral tRNA-like structure. However, no apparent anticodon triplet exists in the viral RNA. These results suggest that the major determinants for tyrosylation of yeast tRNATyr lie outside the anticodon stem and loop, possibly in the amino acid acceptor stem.

Solution structure of a tRNA with a large variable region: yeast tRNASer

Different chemical reagents were used to study the tertiary structure of yeast tRNASer, a tRNA with a large variable region: ethylnitrosourea, which alkylates the phosphate groups; dimethylsulphate, which methylates N-7 of guanosine and N-3 of cytosine; and diethylpyrocarbonate, which modifies N-7 of adenine. The non-reactivity of N-3 of cytidine 47:1, 47:6, 47:7 and 47:8 and the reactivity of cytidine 47:3 confirms the existence of a variable stem of four base-pairs and a short variable loop of three residues. For the N-7 positions in purines, accessible residues are G1, G10, Gm18, G19, G30, I34, G35, A36, i6A37, G45, G47, G47:5, G47:9 and G73. The protection of N-7 atoms of residues G9, G15, A21, A22 and G47:9 reflects the tertiary folding. Strong phosphate protection was observed for P8 to P11, P20:1 to P22, P48 to P50 and for P59 and P60. A model was built on a PS300 graphic system on the basis of these data and its stereochemistry refined. While trying to keep most tertiary interactions, we adapted the tertiary folding of the known structures of tRNAAsp and tRNAPhe to the present sequence and solution data. The resulting model has the variable arm not far from the plane of the common L-shaped structure. A generalization of this model to other tRNAs with large variable regions is discussed.