Lanthanide metals such as terbium have previously been shown to be useful for mapping metal-binding sites in RNA. Terbium binds to the same sites on RNA as magnesium, however, with a much higher affinity. Thus, low concentrations of terbium ions can easily displace magnesium and promote phosphodiester backbone scission. At higher concentrations, terbium cleaves RNA in a sequence-independent manner, with a preference for single-stranded, non-Watson–Crick base-paired regions. Here, we show that terbium is a sensitive probe of human tRNALys,3 tertiary structure and folding. When 1 μM tRNA is used, the optimal terbium ion concentration for detecting Mg2+-induced tertiary structural changes is 50–60 μM. Using these concentrations of RNA and terbium, a magnesium-dependent folding transition with a midpoint (KMg) of 2.6 mM is observed for unmodified human tRNALys,3. At lower Tb3+ concentrations, cleavage is restricted to nucleotides that constitute specific metal-binding pockets. This small chemical probe should also be useful for detecting protein induced structural changes in RNA.

An RNA aptamer containing a 15-nt binding site shows high affinity and specificity for the bronchodilator theophylline. A variety of base modifications or 2′ deoxyribose substitutions in binding-site residues were tested for theophylline-binding affinity and the results were compared with the previously determined three-dimensional structure of the RNA–theophylline complex. The RNA–theophylline complex contains a U6-A28-U23 base triple, and disruption of this A28-U23 Hoogsteen-pair by a 7-deaza, 2′-deoxy A28 mutant reduces theophylline binding >45-fold at 25 °C. U24 is part of a U-turn in the core of the RNA, and disruption of this U-turn motif by a 2′-deoxy substitution of U24 also reduces theophylline binding by >90-fold. Several mutations outside the “conserved core” of the RNA aptamer showed reduced binding affinity, and these effects could be rationalized by comparison with the three-dimensional structure of the complex. Divalent ions are absolutely required for high-affinity theophylline binding. High-affinity binding was observed with 5 mM Mg2+, Mn2+, or Co2+ ions, whereas little or no significant binding was observed for other divalent or lanthanide ions. A metal-binding site in the core of the complex was revealed by paramagnetic Mn2+-induced broadening of specific RNA resonances in the NMR spectra. When caffeine is added to the aptamer in tenfold excess, the NMR spectra show no evidence for binding in the conserved core and instead the drug stacks on the terminal helix. The lack of interaction between caffeine and the theophylline-binding site emphasizes the extreme molecular discrimination of this RNA aptamer.

Divalent metal ions are essential for the folding and catalytic activities of many RNAs. A commonly employed biochemical technique to identify metal-binding sites in RNA is the rescue of RP α-phosphorothioate (PS) interference by the addition of soft divalent metal ions. To access the ability of such experiments to accurately identify metal-ion coordinations within a complex RNA fold, we report metal-rescue results from the Tetrahymena group I intron P4–P6 domain, where the location and coordination of five divalent metal ions have been determined by X-ray crystallography [J.H. Cate et al., Nat Struct Biol, 1997, 4:553]. We used a native gel mobility-shift to assay for P4–P6 folding in the presence of various divalent metal ions, and found that even moderate concentrations of Mn2+ (≥0.5 mM) can rescue PS interference at sites that do not coordinate metal ions within the P4–P6 crystal structure. To control for such effects, 2′-deoxynucleotide interference was used to titrate the Mn2+ concentration to a level that produces metal-ion-specific rescue (0.3 mM). This concentration of Mn2+ specifically rescued four of the six metal-dependent phosphorothioate effects within the RNA domain, including PS interference resulting from outer-sphere coordination to the metals. Both sites that were not specifically rescued make inner-sphere metal-ion coordinations. Cd2+ and Zn2+ afforded rescue at a smaller subset of the six metal-specific PS sites, though again phosphates making outer-sphere coordinations to metal ions were rescued preferentially. These data on P4–P6 domain folding reinforce the need for caution when interpreting metal-rescue experiments.

A novel metal-binding site has been identified in the hammerhead ribozyme by 31P NMR. The metal-binding site is associated with the A13 phosphate in the catalytic core of the hammerhead ribozyme and is distinct from any previously identified metal-binding sites. 31P NMR spectroscopy was used to measure the metal-binding affinity for this site and leads to an apparent dissociation constant of 250–570 μM at 25 °C for binding of a single Mg2+ ion. The NMR data also show evidence of a structural change at this site upon metal binding and these results are compared with previous data on metal-induced structural changes in the core of the hammerhead ribozyme. These NMR data were combined with the X-ray structure of the hammerhead ribozyme (Pley HW, Flaherty KM, McKay DB. 1994. Nature 372:68–74) to model RNA ligands involved in binding the metal at this A13 site. In this model, the A13 metal-binding site is structurally similar to the previously identified A9 metal-binding site and illustrates the symmetrical nature of the tandem G[bull ]A base pairs in domain 2 of the hammerhead ribozyme. These results demonstrate that 31P NMR represents an important method for both identification and characterization of metal-binding sites in nucleic acids.