Developing the intervention material to increase physical activity levels of European preschool children: the ToyBox-study.

Early childhood is an important period for adopting positive health-related behaviours. More than 95% of European preschool children attend kindergartens, making these settings ideal for the implementation of health promotion interventions. The ToyBox-intervention addressed preschool children, their parents/caregivers and teachers. The aim of the intervention was to improve four energy balance-related behaviours (i.e. healthy snacking, water consumption, physical activity and sedentary behaviour) by implementing a kindergarten-based, family-involved intervention in six European countries (Belgium, Bulgaria, Germany, Greece, Poland and Spain). The intervention material was developed following the intervention mapping protocol, taking into account local and cultural differences among the intervention countries. The present paper focuses on the development of the physical activity component of the intervention. Parental involvement was addressed by providing parents/caregivers with two newsletters, two tip cards and a poster. Teachers received a handbook with guidance on environmental changes in the classroom, 26 physical education sessions and suggestions for fun, interactive classroom activities aiming at total class participation to increase preschoolers' physical activity levels. The ToyBox-intervention material was distributed according to a standard time frame. Teachers received their material prior to the start of the intervention and parents/caregivers received their material during the intervention when each energy balance-related behaviour was implemented.

The relationship between translational control and mRNA degradation for the Escherichia coli threonyl-tRNA synthetase gene.

Expression of thrS, the gene encoding Escherichia coli threonyl-tRNA synthetase, is negatively autoregulated at the translational level. Regulation is due to the binding of threonyl-tRNA synthetase to its own mRNA at a site called the operator, located immediately upstream of the initiation codon. The present work investigates the relationship between regulation and mRNA degradation. We show that two regulatory mutations, which increase thrS expression, cause an increase in the steady-state mRNA concentration. Unexpectedly, however, the half-life of thrS mRNA in the derepressed mutants is equal to that of the wild-type, indicating that mRNA stability is independent of the repression level. All our results can be explained if one assumes that thrS mRNA is either fully translated or immediately degraded. The immediately degraded RNAs are never detected due to their extremely short half-lives, while the fully translated messengers share the same half-lives, irrespective of the mutations. The increase in the steady-state level of thrS mRNA in the derepressed mutants is simply explained by an increase in the population of translated molecules, i.e. those never bound by the repressor, ThrRS. Despite this peculiarity, thrS mRNA degradation seems to follow the classical degradation pathway. Its stability is increased in a strain defective for RNase E, indicating that an endonucleolytic cleavage by this enzyme is the rate-limiting process in degradation. We also observe an accumulation of small fragments corresponding to the 5' end of the message in a strain defective for polynucleotide phosphorylase, indicating that, following the endonucleolytic cleavages, fragments are normally degraded by 3' to 5' exonucleolytic trimming. Although mRNA degradation was suspected to increase the efficiency of translational control based on several considerations, our results indicate that inhibition of mRNA degradation has no effect on the level of repression by ThrRS.

Discrimination by Escherichia coli initiation factor IF3 against initiation on non-canonical codons relies on complementarity rules.

Translation initiation factor IF3, one of three factors specifically required for translation initiation in Escherichia coli, inhibits initiation on any codon other than the three canonical initiation codons, AUG, GUG, or UUG. This discrimination against initiation on non-canonical codons could be due to either direct recognition of the two last bases of the codon and their cognate bases on the anticodon or to some ability to "feel" codon-anticodon complementarity. To investigate the importance of codon-anticodon complementarity in the discriminatory role of IF3, we constructed a derivative of tRNALeuthat has all the known characteristics of an initiator tRNA except the CAU anticodon. This tRNA is efficiently formylated by methionyl-tRNAfMettransformylase and charged by leucyl-tRNA synthetase irrespective of the sequence of its anticodon. These initiator tRNALeuderivatives (called tRNALI) allow initiation at all the non-canonical codons tested, provided that the complementarity between the codon and the anticodon of the initiator tRNALeuis respected. More remarkably, the discrimination by IF3, normally observed with non-canonical codons, is neutralised if a tRNALIcarrying a complementary anticodon is used for initiation. This suggests that IF3 somehow recognises codon-anticodon complementarity, at least at the second and third position of the codon, rather than some specific bases in either the codon or the anticodon.

Mutations that alter initiation codon discrimination by Escherichia coli initiation factor IF3.

This work describes the isolation of mutations in infC, the structural gene for IF3, using different genetic screens. Among 21 mutants characterised, seven were shown to produce stable variant IF3 proteins unable to fully complement a strain carrying a chromosomal deletion of the infC gene. The mutants were also shown to be unable to normally discriminate against several non-canonical initiation codons such as AUU and ACG. The two mutants with the strongest complementation or discrimination defects carry changes in the C-terminal domain of IF3, which is responsible for the binding of the factor to the 30 S ribosomal subunit. We show that the first mutant has an expected decreased but the second an unexpected increased capacity to bind the 30 S subunit. The in vivo defects of the second mutant are explained by its capacity to bind unspecifically to other targets, as shown by its increased affinity for the 50 S subunit, which is normally not recognised by the factor. Interestingly, this mutant corresponds to a change of an acidic residue that might play a negative discriminatory role in preventing interactions with non-cognate RNAs, as has been reported for acidic residues of aminoacyl-tRNA synthetases shown to be involved in tRNA recognition.

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.

The expression of E.coli threonyl-tRNA synthetase is regulated at the translational level by symmetrical operator-repressor interactions.

Threonyl-tRNA synthetase from Escherichia coli represses the translation of its own mRNA by binding to the operator region located upstream from the ribosome binding site. The operator contains two stemloop structures which interact specifically with the homodimeric enzyme. Here, we provide in vitro and in vivo evidence that these two stem-loop structures are recognized by the enzyme in an analogous way and mimic the anticodon arm of E.coli tRNA(Thr). Determination of the stoichiometry of the different RNA-threonyl-tRNA synthetase complexes reveals that two tRNA(Thr) molecules bind to the enzyme whereas only one thrS operator interacts with the homodimeric enzyme. A model is presented in which the two anticodon-like domains of the operator bind symmetrically to the two tRNA(Thr) anticodon recognition sites (one per subunit) of the dimeric threonyl-tRNA synthetase. Although symmetrical operator-repressor interactions in transcriptional control are widespread, this report stresses the importance of such interactions in translational regulation of gene expression.

Growth rate-dependent control, feedback regulation and steady-state mRNA levels of the threonyl-tRNA synthetase gene of Escherichia coli.

The expression of the gene thrS encoding threonyl-tRNA synthetase is under the control of two apparently different regulatory loops: translational feedback regulation and growth rate-dependent control. The translational feedback regulation is due to the binding of threonyl-tRNA synthetase to a site located in the leader RNA of thrS, upstream of the initiation codon, which mimics the anticodon stem and loop of tRNA(Thr). This binding competes with that of the ribosome and thus inhibits translation initiation. Here, we investigate the mechanism of growth rate-dependent control, i.e. the mechanism by which the synthetase accumulates at high growth rates. We show that growth rate-dependent control acts at the level of translation and requires feedback regulation since mutations that abolish feedback regulation also abolish growth rate-dependent control. We also show that tRNA(Thr), which accumulates at high growth rates, is one of the effectors of growth rate-dependent control since its accumulation can cause derepression independently of growth rate. We show that this tRNA(Thr)-dependent derepression is also dependent on feedback regulation since mutations which abolish feedback also prevent derepression. Based on these results and previous data concerning the mechanism of translational feedback regulation, we propose that threonyl-tRNA synthetase growth rate-dependent control is the consequence of the accumulation at high growth rates of two effectors, the ribosome and tRNA(Thr). We also study the growth rate-dependence of the steady state level of thrS mRNA and show that the steady state level of thrS mRNA increases at high growth rates. This increase is dependent on the translational feedback regulation and can also be detected, independently of growth rate, when thrS mRNA translation is derepressed. Consistently with the model of growth rate-dependent control above, we propose that at high growth rates, the mRNA is well translated and thus stabilised and that, at low growth rates, because of its low translation, thrS mRNA is rapidly degraded.

The role of the AUU initiation codon in the negative feedback regulation of the gene for translation initiation factor IF3 in Escherichia coli.

The expression of the infC gene encoding translation initiation factor IF3 is negatively autoregulated at the level of translation, i.e. the expression of the gene is derepressed in a mutant infC background where the IF3 activity is lower than that of the wild type. The special initiation codon of infC, AUU, has previously been shown to be essential for derepression in vivo. In the present work, we provide evidence that the AUU initiation codon causes derepression by itself, because if the initiation codon of the thrS gene, encoding threonyl-tRNA synthetase, is changed from AUG to AUU, its expression is also derepressed in an infC mutant background. The same result was obtained with the rpsO gene encoding ribosomal protein S15. We also show that derepression of infC, thrS, and rpsO is obtained with other 'abnormal' initiation codons such as AUA, AUC, and CUG which initiate with the same low efficiency as AUU, and also with ACG which initiates with an even lower efficiency. Under conditions of IF3 excess, the expression of infC is repressed in the presence of the AUU or other 'abnormal' initiation codons. Under the same conditions and with the same set of 'abnormal' initiation codons, the repression of thrS and rpsO expression is weaker. This result suggests that the infC message has specific features that render its expression particularly sensitive to excess of IF3. We also studied another peculiarity of the infC message, namely the role of a GC-rich sequence located immediately downstream of the initiation codon and conserved through evolution. This sequence was proposed to interact with a conserved region in 16S RNA and enhance translation initiation. Unexpectedly, mutating this GC-rich sequence increases infC expression, indicating that this sequence has no enhancing role. Chemical and enzymatic probing of infC RNA synthesized in vitro indicates that this GC-rich sequence might pair with another region of the mRNA. On the basis of our in vivo results we propose, as suspected from earlier in vitro results, that IF3 regulates the expression of its own gene by using its ability to differentiate between 'normal' and 'abnormal' initiation codons.

Physiological effects of translation initiation factor IF3 and ribosomal protein L20 limitation in Escherichia coli.

To investigate the physiological roles of translation initiation factor IF3 and ribosomal protein L20 in Escherichia coli, the infC, rpmI and rpIT genes encoding IF3, L35 and L20, respectively, were placed under the control of lac promotor/operator sequences. Thus, their expression is dependent upon the amount of inducer isopropyl thiogalactoside (IPTG) in the medium. Lysogenic strains were constructed with recombinant lambda phages that express either rpmI and rplT or infC and prmI in trans, thereby allowing depletion of only IF3 or L20 at low IPTG concentrations. At low cellular concentration of IF3, but not L20, decreases and the growth rate slows. Furthermore, ribosomes run off polysomes, indicating that IF3 functions during the initiation phase of protein synthesis in vivo. During slow growth, the ratio of RNA to protein increases rather than decreases as occurs with control strains, indicating that IF3 limitation disrupts feedback inhibition of rRNA synthesis. As IF3 levels drop, expression from an AUU-infC-lacZ fusion increases, whereas expression decreases from an AUG-infC-lacZ fusion, thereby confirming the model of autogenous regulation of infC. The effects of L20 limitation are similar; cells grown in low concentrations of IPTG exhibited a decrease in the rate of growth, a decrease in cellular L20 concentration, no change in IF3 concentration, and a small increase in the ratio of RNA to protein. In addition, a decrease in 50S subunits and the appearance of an aberrant ribosome peak at approximately 41-43S is seen. Previous studies have shown that the L20 protein negatively controls its own gene expression. Reduction of the cellular concentration of L20 derepresses the expression of an rplT-lacZ gene fusion, thus confirming autogenous regulation by L20.

Stabilised secondary structure at a ribosomal binding site enhances translational repression in E. coli.

The expression of the gene encoding Escherichia coli threonyl-tRNA synthetase is negatively autoregulated at the translational level. The negative feedback is due to the binding of the synthetase to an operator site on its own mRNA located upstream of the initiation codon. The present work describes the characterisation of operator mutants that have the rare property of enhancing repression. These mutations cause (1) a low basal level of expression, (2) a temperature-dependent expression, and (3) an increased capacity of the synthetase to repress its own expression at low temperature. Surprisingly, this enhancement of repression is not explained by an increase of affinity of the mutant operators for the enzyme but by the formation, at low temperature, of a few supplementary base-pairs between the ribosomal binding site and a normally single-stranded domain of the operator. Although this additional base-pairing only slightly inhibits ribosome binding in the absence of repressor, simple thermodynamic considerations indicate that this is sufficient to increase repression. This increase is explained by the competition between the ribosome and repressor for overlapping regions of the mRNA. When the ribosomal binding site is base-paired, the ribosome cannot bind while the repressor can, giving the repressor the advantage in the competition. Thus, the existence of an open versus base-paired equilibrium in a ribosomal binding site of a translational operator amplifies the magnitude of control. This molecular amplification device might be an essential component of translational control considering the low free repressor/ribosome ratio of the low affinity of translational repressors for their target operators.

Messenger RNA secondary structure and translational coupling in the Escherichia coli operon encoding translation initiation factor IF3 and the ribosomal proteins, L35 and L20.

The Escherichia coli infC-rpmI-rplT operon encodes translation initiation factor IF3 and the ribosomal proteins, L35 and L20, respectively. The expression of the last cistron (rplT) has been shown to be negatively regulated at a post-transcriptional level by its own product, L20, which acts at an internal operator located within infC. The present work shows that L20 directly represses the expression of rpmI, and indirectly that of rplT, via translational coupling with rpmI. Deletions and an inversion of the coding region of rpmI, suggest an mRNA secondary structure forming between sequences within rpmI and the translation initiation site of rplT. To verify the existence of this structure, detailed analyses were performed using chemical and enzymatic probes. Also, mutants that uncoupled rplT expression from that of rpmI, were isolated. The mutations fall at positions that would base-pair in the secondary structure. Our model is that L20 binds to its operator within infC and represses the translation of rpmI. When the rpmI mRNA is not translated, it can base-pair with the ribosomal binding site of rplT, sequestering it, and abolishing rplT expression. If the rpmI mRNA is translated, i.e. covered by ribosomes, the inhibitory structure cannot form leaving the translation initiation site of rplT free for ribosomal binding and for full expression. Although translational coupling in ribosomal protein operons has been suspected to be due to the formation of secondary structures that sequester internal ribosomal binding sites, this is the first time that such a structure has been shown to exist.

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.

The specificity of translational control switched with transfer RNA identity rules.

The interaction of Escherichia coli threonyl-transfer RNA (tRNA) synthetase with the leader sequence of its own messenger RNA inhibits ribosome binding, resulting in negative translational feedback regulation. The leader sequence resembles the substrate (tRNA(Thr)) of the enzyme, and the nucleotides that mediate the correct recognition of the leader and the tRNA may be the same. A mutation suggested by tRNA identity rules that switches the resemblance of the leader sequence from tRNA(Thr) to tRNA(Met) causes the translation of the threonyl-tRNA synthetase messenger RNA to become regulated by methionyl-tRNA synthetase. This identity swap in the leader messenger RNA indicates that tRNA identity rules may be extended to interactions of synthetases with other RNAs.

Translated translational operator in Escherichia coli. Auto-regulation in the infC-rpmI-rplT operon.

The genes coding for translation initiation factor IF3 (infC) and for the ribosomal proteins L35 (rpmI) and L20 (rplT) are transcribed in that order from a promoter in front of infC. The last two cistrons of the operon (rpmI and rplT) can be transcribed from a weak secondary promoter situated within the first cistron (infC). Previous experiments have shown that the expression of infC, the first cistron of the operon, is negatively autoregulated at the translational level and that the abnormal AUU initiation codon of infC is responsible for the control. We show that the expression of the last cistron (rplT) is also autoregulated at the posttranscriptional level. The L20 concentration regulates the level of rplT expression by acting in trans at a site located within the first cistron (infC) and thus different from that at which IF3 is known to act. This regulatory site, several hundred nucleotides upstream from the target gene (rplT), was identified through deletions, insertions and a point mutation. Thus, the expression of the operon is controlled in trans by the products of two different cistrons acting at two different sites. The localization within an open reading frame (infC) of a regulatory site acting in cis on the translation of a downstream gene (rplT) is new and was unforeseen since ribosomes translating through the regulatory site might be expected to impair either the binding of L20 or the mRNA secondary structure change caused by the binding. The possible competition between translation of the regions acting in cis and the regulation of the expression of the target gene is discussed.

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.

tRNA-like structures and gene regulation at the translational level: a case of molecular mimicry in Escherichia coli.

Escherichia coli threonyl-tRNA synthetase regulates the translation of its own mRNA by binding to it in a region, called the operator, located in front of the ribosomal binding site. The primary and secondary structures of the operator resemble those of the anticodon arm of several tRNA(Thr) isoacceptor species. We reasoned that if the interaction between the synthetase and its two partially analogous ligands, the tRNA and the mRNA, had some common features, single mutations in the enzyme should affect both interactions in a very similar way. We thus isolated synthetase mutants (called super-repressors) that repress the translation of their mRNA in trans to an extreme level, and other mutants that are completely unable to perform any repression. The super-repressors, which are suspected to bind their mRNA with high affinity, are shown to bind the tRNA with an increased affinity. The non-repressing mutants, which are suspected to have lost their capacity to bind the mRNA, are shown to bind their tRNA with less affinity. The binding properties of the mutant enzymes for the other substrates, ATP and threonine, are unchanged. The observed correlation between regulatory and aminoacylation defects strongly suggests that the synthetase recognizes the similar parts of its two RNA ligands--the anticodon-like arm of the mRNA and the true anticodon arm of the tRNA--in an analogous way.

Translational control in E. coli: the case of threonyl-tRNA synthetase.

Genetic studies have shown that expression of the E. coli threonyl-tRNA synthetase (thrS) gene is negatively auto-regulated at the translational level. A region called the operator, located 110 nucleotides downstream of the 5' end of the mRNA and between 10 and 50 bp upstream of the translational initiation codon in the thrS gene, is directly involved in that control. The conformation of an in vitro RNA fragment extending over the thrS regulatory region has been investigated with chemical and enzymatic probes. The operator locus displays structural similarities to the anti-codon arm of threonyl tRNA. The conformation of 3 constituent mutants containing single base changes in the operator region shows that replacement of a base in the anti-codon-like loop does not induce any conformational change, suggesting that the residue concerned is directly involved in regulation. However mutation in or close to the anti-codon-like stem results in a partial or complete rearrangement of the structure of the operator region. Further experiments indicate that there is a clear correlation between the way the synthetase recognises each operator, causing translational repression, and threonyl-tRNA.

Open reading frames in the control regions of the phenylalanyl-tRNA synthetase operon of E. coli.

The pheST operon codes for the two subunits of phenylalanyl-tRNA synthetase and it expression is controlled by attenuation in a way similar to many amino acid biosynthetic operons. The nucleotide sequence of the control regions of the operon indicates the presence of several open reading frames besides that of the leader peptide. One of these open reading frames, called the alternative leader peptide, starts at about the same place as the leader peptide and ends after the terminator of the attenuator. Another open reading frame, called the terminator peptide, starts after the terminator and covers about half the distance to pheS, the first structural gene of the operon. The present report shows that, in fact, the only open reading frame to be translated efficiently is the leader peptide itself. The alternative leader peptide and the terminator peptide are both translated at a negligible rate.

Escherichia coli protein synthesis initiation factor IF3 controls its own gene expression at the translational level in vivo.

Measurements of the relative synthesis rates of mRNAs transcribed from the gene (thrS) for threonyl-tRNA synthetase and the adjacent gene (infC) for initiation factor IF3 show four- to fivefold more infC mRNA than thrS mRNA in vivo, suggesting that infC expression can be controlled independently of thrS expression. S1 mapping experiments reveal the existence of two transcription initiation sites for infC mRNAs internal to the thrS structural gene. Both the mRNA measurements and the S1 mapping experiments indicate that the majority of infC transcription initiates at the infC proximal promoter. In agreement with these results, the deletion of the infC distal promoter from infC-lacZ gene fusions does not affect the expression of these gene fusions in vivo. Measurements of the relative synthesis rate of infC mRNA in vivo in infC- strains overproducing IF3 shows that infC mRNA levels are normal in these strains, thus suggesting that IF3 regulates the translation of infC mRNAs in vivo. Extension of these experiments using infC-lacZ gene fusions carried on lambda bacteriophage and integrated at the lambda att site on the Escherichia coli chromosome shows that the expression of infC-lacZ protein fusions, but not infC-lacZ operon fusions, is derepressed in two infC- strains. A cellular excess of IF3 represses the expression of an infC-lacZ protein fusion but not an infC-lacZ operon fusion. Measurements of the relative mRNA synthesis rates of hybrid infC-lacZ mRNA synthesized from an infC-lacZ protein fusion under conditions of a fourfold derepression or a threefold repression of hybrid IF3-beta-galactosidase expression shows that the hybrid infC-lacZ mRNA levels remain unchanged. These results indicate that the cellular levels of IF3 negatively regulate the expression of its own gene, infC, at the translational level in vivo.

Genetic definition of the translational operator of the threonine-tRNA ligase gene in Escherichia coli.

The Escherichia coli gene thrS that codes for threonine-tRNA ligase (tRNAThr ligase, formerly threonine-tRNA synthetase, EC 6.1.1.3) has previously been shown to be negatively autoregulated at the level of translation. Here we describe the use of several thrS-lac gene fusions to isolate cis-acting regulatory mutations that increase the translation but not the transcription of the thrS gene. These mutations lead to a total loss of control of repression and derepression of thrS. DNA sequence analysis locates the mutations between 10 and 40 base pairs upstream of the translation initiation codon of thrS and more than 100 base pairs downstream of the transcription initiation site. The mRNA region where these mutations are located shares primary and secondary structure homologies with specific parts of several isoacceptor tRNAThr species. These findings suggest that the ligase regulates its translation by binding to its mRNA at a place that shares some homology with its natural substrate.