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.

Structural elements of rps0 mRNA involved in the modulation of translational initiation and regulation of E. coli ribosomal protein S15.

Previous experiments showed that S15 inhibits its own translation by binding to its mRNA in a region overlapping the ribosome loading site. This binding was postulated to stabilize a pseudoknot structure that exists in equilibrium with two stem-loops and to trap the ribosome on its mRNA loading site in a transitory state. In this study, we investigated the effect of mutations in the translational operator on: the binding of protein S15, the formation of the 30S/mRNA/tRNA(fMet) ternary initiation complex, the ability of S15 to inhibit the formation of this ternary complex. The results were compared to in vivo expression and repression rates. The results show that (1) the pseudoknot is required for S15 recognition and translational control; (2) mRNA and 16S rRNA efficiently compete for S15 binding and 16S rRNA suppresses the ability of S15 to inhibit the formation of the active ternary complex; (3) the ribosome binds more efficiently to the pseudoknot than to the stem-loop; (4) sequences located between nucleotides 12 to 47 of the S15 coding phase enhances the efficiency of ribosome binding in vitro; this is correlated with enhanced in vivo expression and regulation rates.

Minimal 16S rRNA binding site and role of conserved nucleotides in Escherichia coli ribosomal protein S8 recognition.

Escherichia coli ribosomal protein S8 was previously shown to bind a 16S rRNA fragment (nucleotides 584-756) with the same affinity as the complete 16S rRNA, and to shield an irregular helical region (region C) [Mougel, M., Eyermann, F., Westhof, E., Romby, P., Expert-Bezançon, Ebel, J. P., Ehresmann, B. & Ehresmann, C. (1987). J. Mol. Biol. 198, 91-107]. Region C was postulated to display characteristic features: three bulged adenines (A595, A640 and A642), a non-canonical U598-U641 pair surrounded by two G.C pairs. In order to delineate the minimal RNA binding site, deletions were introduced by site-directed mutagenesis and short RNA fragments were synthesized. Their ability to bind S8 was assayed by filter binding. Our results show that the RNA binding site can be restricted to a short helical stem (588-605/633-651) containing region C. The second part of the work focused on region C and on the role of conserved nucleotides as potential determinants of S8 recognition. Single and double mutations were introduced by site-directed mutagenesis in fragment 584-756, and their effect on S8 binding was measured. It was found that the three bulged positions are essential and that adenines are required at positions 640 and 642. U598 is also crucial and the highly conserved G597.C643 pair cannot be inverted. These conserved nucleotides are either directly involved in the recognition process as direct contacts or required to maintain a specific conformation. The strong evolutionary pressure and the small number of positive mutants stress the high stringency of the recognition process.

Ribosomal protein S15 from Escherichia coli modulates its own translation by trapping the ribosome on the mRNA initiation loading site.

From genetic and biochemical evidence, we previously proposed that S15 inhibits its own translation by binding to its mRNA in a region overlapping the ribosome loading site. This binding was postulated to stabilize a pseudoknot structure that exists in equilibrium with two stem-loops. Here, we use "toeprint" experiments with Moloney murine leukemia virus reverse transcriptase to analyze the effect of S15 on the formation of the ternary mRNA-30S-tRNA(fMet) complex. We show that the binding of the 30S subunit on the mRNA stops reverse transcriptase near position +10, corresponding to the 3' terminus of the pseudoknot, most likely by stabilizing the pseudoknot conformation. Furthermore, S15 is found to stabilize the binary 30S-mRNA complex. When the ternary 30S-mRNA-tRNA(fMet) complex is formed, a toeprint is observed at position +17. This toeprint progressively disappears when the ternary complex is formed in the presence of increasing concentrations of S15, while a shift from position +17 to position +10 is observed. Beside, RNase T1 footprinting experiments reveal the simultaneous binding of S15 and 30S subunit on the mRNA. Otherwise, we show by filter binding assays that initiator tRNA remains bound to the 30S subunit even in the presence of S15. Our results indicate that S15 prevents the formation of a functional ternary 30S-mRNA-tRNA(fMet) complex, the ribosome being trapped in a preternary 30S-mRNA-tRNA(fMet) complex.

Probing the phosphates of the Escherichia coli ribosomal 16S RNA in its naked form, in the 30S subunit, and in the 70S ribosome.

Ethylnitrosourea is an alkylating reagent which preferentially modifies phosphates in nucleic acids. It was used to map phosphates in naked Escherichia coli 16S rRNA engaged in tertiary interactions through hydrogen bonds or ion coordination. Of the phosphates, 7% are found involved in such interactions, and 57% of them are located in loops or interhelical regions, where they are involved in maintaining local intrinsic structures or long-distance tertiary interactions. The other phosphates (43%) are found in helical regions. These phosphates often occur at the proximity of bulged nucleotides or in irregular helices containing noncanonical base pairs (and bulges) and are assumed to bind cations in order to neutralize negative charges and to stabilize unusual phosphate backbone folding. In the 30S subunit, ENU allowed mapping of phosphates in contact with proteins. The RNA is not uniformly engaged in RNA/protein interactions. Regions 1-51, 250-310, 567-612, 650-670, and 1307-1382 are particularly buried whereas the 3'-terminal domain and the 5'-proximal region (nucleotides 53-218) are exposed. The conformation of 16S rRNA is not drastically affected by protein binding, but conformational adjustments are detected in several defined regions. They are found in the 5' domain (region 147-172), in the central domain (region 827-872), in the 3' major domain (nucleotides 955-956, 994, 1054, 1181, 1257, and 1262-1263), and in the 3'-terminal domain (around 1400). The 50S subunit shields clusters of phosphates located at the subunit interface. The most extensive protections are observed in the 3'-terminal domain (1490-1542), in the central region of the molecule (770-930), and in the upper 3' major domain.(ABSTRACT TRUNCATED AT 250 WORDS)

Binding of Escherichia coli ribosomal protein S8 to 16 S rRNA. A model for the interaction and the tertiary structure of the RNA binding site.

We have investigated in detail the secondary and tertiary structures of the 16 S rRNA binding site of protein S8 using a variety of chemical and enzymatic probes. Bases were probed with dimethylsulfate (at A(N-1), C(N-3) and G(N-7)), with N-cyclohexyl-N'-(2-(N-methylmorpholino)-ethyl)-carbodiimide-p- toluenesulfonate (at G(N-1) and U(N-3)) and with diethylpyrocarbonate (at A(N-7)). The involvement of phosphates in hydrogen bonds or ion co-ordination was monitored with ethylnitrosourea. RNases T1, U2 and nuclease S1 were used to probe unpaired nucleotides and RNase V1 to monitor base-paired or stacked nucleotides. The RNA region, encompassing nucleotides 582 to 656 was probed within: (1) the complete 16 S rRNA molecule; (2) a 16 S rRNA fragment corresponding to nucleotides 578 to 756 obtained by transcription in vitro; (3) the S8-16 S rRNA complex; (4) the S8-RNA fragment complex; (5) the 30 S subunit. Cleavage or modification sites were detected by primer extension with reverse transcriptase. We present a three-dimensional model derived from mapping experiments and graphic modeling. Nucleotides in area 594-599/639-645 display unusual features: a non-canonical base-pair is formed between U598 and U641; and A595, A640 and A642 are bulging out of the major groove. The resulting helix is slightly unwound. Comparative analysis of probing experiments leads to several conclusions. (1) The synthesized fragment adopts the same conformation as the corresponding region in the complete RNA molecule, thus confirming the existence of independent folding domains in RNAs. (2) A long-range interaction involving cytosine 618 and its 5' phosphate occurs in 16 S rRNA but not in the fragment. (3) The fragment contains the complete information required for S8 binding. (4) The RNA binding site of S8 is centered in the major groove of the slightly unwound helix (594-599/639-645), with the three bulged adenines appearing as specific recognition sites. (5) This same region of the 16 S RNA is not exposed at the surface of the 30 S subunit.