A Mg2+-dependent RNA tertiary structure forms in the Bacillus subtilis trp operon leader transcript and appears to interfere with trpE translation control by inhibiting TRAP binding.

Expression of the trpEDCFBA operon of Bacillus subtilis is regulated by transcription attenuation and translation control mechanisms. In each case, binding of the trp RNA-binding attenuation protein (TRAP) to the untranslated trp leader transcript mediates conformational changes in the RNA secondary structure. We examined the structure of the trp leader readthrough RNA in the absence of TRAP. Using chemical and enzymatic probes, the secondary structure of the trp leader RNA was found to be similar to predicted models. In addition, this RNA was found to adopt a Mg(2+)-dependent, long-range tertiary interaction under physiological monovalent salt conditions. Formation of this tertiary structure does not require significant changes in the preformed secondary structure. Enzymatic probing of the RNA in the presence of competitor DNA oligonucleotides that were designed to disrupt the predicted tertiary structure allowed identification of the interacting partners as the single-stranded portion of the purine-rich TRAP binding target and a large downstream pyrimidine-rich internal loop. UV cross-linking experiments utilizing 5'-p-azidophenacyl-containing transcripts revealed a Mg(2+)-dependent cross-link. Mapping of this cross-link provided evidence that the single-stranded segment of the TRAP binding site is in close proximity to the internal loop. Results from UV melting experiments with wild-type and mutant trp leader transcripts suggested a likely base-pairing register for the tertiary structure. Filter-binding studies demonstrated that the addition of Mg(2+) inhibits TRAP binding, which may be partially due to the effect of Mg(2+) on RNA tertiary structure formation. Results from expression studies using trpE'-'lacZ translational fusions and RNA-directed cell-free translation experiments suggest that the Mg(2+)-dependent tertiary structure inhibits TRAP's ability to regulate translation of trpE.

Characterization of a native hammerhead ribozyme derived from schistosomes.

A recent re-examination of the role of the helices surrounding the conserved core of the hammerhead ribozyme has identified putative loop-loop interactions between stems I and II in native hammerhead sequences. These extended hammerhead sequences are more active at low concentrations of divalent cations than are minimal hammerheads. The loop-loop interactions are proposed to stabilize a more active conformation of the conserved core. Here, a kinetic and thermodynamic characterization of an extended hammerhead sequence derived from Schistosoma mansoni is performed. Biphasic kinetics are observed, suggesting the presence of at least two conformers, one cleaving with a fast rate and the other with a slow rate. Replacing loop II with a poly(U) sequence designed to eliminate the interaction between the two loops results in greatly diminished activity, suggesting that the loop-loop interactions do aid in forming a more active conformation. Previous studies with minimal hammerheads have shown deleterious effects of Rp-phosphorothioate substitutions at the cleavage site and 5' to A9, both of which could be rescued with Cd2+. Here, phosphorothioate modifications at the cleavage site and 5' to A9 were made in the schistosome-derived sequence. In Mg2+, both phosphorothioate substitutions decreased the overall fraction cleaved without significantly affecting the observed rate of cleavage. The addition of Cd2+ rescued cleavage in both cases, suggesting that these are still putative metal binding sites in this native sequence.

Phylogenetic conservation of RNA secondary and tertiary structure in the trpEDCFBA operon leader transcript in Bacillus.

Expression of the trpEDCFBA operon of Bacillus subtilis is regulated by transcription attenuation and translation control mechanisms. We recently determined that the B. subtilis trp leader readthrough transcript can adopt a Mg(2+)-dependent tertiary structure that appears to interfere with TRAP-mediated translation control of trpE. In the present study, sequence comparisons to trp leaders from three other Bacillus sp. were made, suggesting that RNA secondary and tertiary structures are phylogenetically conserved. To test this hypothesis, experiments were carried out with the trp leader transcript from Bacillus stearothermophilus. Structure mapping experiments confirmed the predicted secondary structure. Native gel experiments identified a faster mobility species in the presence of Mg(2+), suggesting that a Mg(2+)-dependent tertiary structure forms. Mg(2+)-dependent protection of residues within the first five triplet repeats of the TRAP binding target and a pyrimidine-rich internal loop were observed, consistent with tertiary structure formation between these regions. Structure mapping in the presence of a competitor DNA oligonucleotide allowed the interacting partners to be identified as a single-stranded portion of the purine-rich TRAP binding target and the large downstream pyrimidine-rich internal loop. Thermal denaturation experiments revealed a Mg(2+)- and pH-dependent unfolding transition that was absent for a transcript missing the first five triplet repeats. The stability of several mutant transcripts allowed a large portion of the base-pairing register for the tertiary interaction to be determined. These data indicate that RNA secondary and tertiary structures involved in TRAP-mediated translation control are conserved in at least four Bacillus species.

Isolation and characterization of a family of stable RNA tetraloops with the motif YNMG that participate in tertiary interactions.

RNA is known to fold into a variety of structural elements, many of which have sufficient sequence complexity to make the thermodynamic study of each possible variant impractical. We previously reported a method for isolating stable and unstable RNA sequences from combinatorial libraries using temperature gradient gel electrophoresis (TGGE). This method was used herein to analyze a six-nucleotide RNA hairpin loop library. Three rounds of in vitro selection were performed using TGGE, and unusually stable RNAs were identified by cloning and sequencing. Known stable tetraloops were found, including sequences belonging to the UNCG motif closed by a CG base pair, and the CUUG motif closed by a GC base pair. In addition, unknown tetraloops were found that were nearly as stable as cUNCGg, including sequences related through substitution of the U with a C (Y), the C with an A (M), or both. These substitutions allow hydrogen bonding and stacking interactions in the UNCG loop to be maintained. Thermodynamic analysis of YNMG and variant loops confirmed optimal stability with Y at position 1 and M at position 3. Similarity in structure and stability among YNMG loops was further supported by deoxyribose substitution, CD, and NMR experiments. A conserved tertiary interaction in 16S rRNA exists between a YAMG loop at position 343 and two adenines in the loop at position 159 (Escherichia coli numbering). NMR and functional group substitution experiments suggest that YNAG loops in particular have enhanced flexibility, which allows the tertiary interaction to be maintained with diverse loop sequences at position 159. Taken together, these results support the existence of an extended family of UNCG-like tetraloops with the motif cYNMGg that are thermodynamically stable and structurally similar and can engage in tertiary interactions in large RNA molecules.