A single-molecule study of RNA catalysis and folding.

Using fluorescence microscopy, we studied the catalysis by and folding of individual Tetrahymena thermophila ribozyme molecules. The dye-labeled and surface-immobilized ribozymes used were shown to be functionally indistinguishable from the unmodified free ribozyme in solution. A reversible local folding step in which a duplex docks and undocks from the ribozyme core was observed directly in single-molecule time trajectories, allowing the determination of the rate constants and characterization of the transition state. A rarely populated docked state, not measurable by ensemble methods, was observed. In the overall folding process, intermediate folding states and multiple folding pathways were observed. In addition to observing previously established folding pathways, a pathway with an observed folding rate constant of 1 per second was discovered. These results establish single-molecule fluorescence as a powerful tool for examining RNA folding.

Use of duplex rigidity for stability and specificity in RNA tertiary structure.

The Tetrahymena group I ribozyme's oligonucleotide substrate, CCCUCUA(5), forms six base pairs with the ribozyme's internal guide sequence (IGS, 5'GGAGGG) to give the P1 duplex, and this duplex then docks into the active site via tertiary interactions. Shortening the substrate by three residues to give UCUA(5) reduces the equilibrium constant for P1 docking by approximately 200-fold even though UCUA(5) retains all the functional groups known to be involved in tertiary interactions [Narlikar, G. J., Bartley, L. E., Khosla, M., and Herschlag, D. (1999) Biochemistry 38, 14192-14204]. Here we show that the P1 duplex formed with UCUA(5) engages in all of the major tertiary interactions made by the standard P1 duplex. This suggests that the destabilization is not due to disruption of specific tertiary interactions. It therefore appears that the weaker docking of UCUA(5) arises from the increased conformational freedom of the undocked P1 duplex, which has three unpaired IGS residues and thus a larger entropic cost for docking. Further, a 2'-methoxy substitution at an IGS residue that is base-paired in the standard P1 duplex with CCCUCUA(5) but unpaired in the P1 duplex with UCUA(5) destabilizes docking of the standard P1 duplex approximately 300-fold more than it destabilizes docking of the P1 duplex formed with UCUA(5). These results suggest that fixation of groups in the context of a rigid duplex may be a general strategy used by RNA to substantially increase interaction specificity, both by aiding binding of the desired functional groups and by increasing the energetic cost of forming alternative interactions.

Characterization of a local folding event of the Tetrahymena group I ribozyme: effects of oligonucleotide substrate length, pH, and temperature on the two substrate binding steps.

Binding of the Tetrahymena group I ribozyme's oligonucleotide substrate occurs in two steps: P1 duplex formation with the ribozyme's internal guide sequence which forms an "open complex" is followed by docking of the P1 duplex into tertiary interactions within the catalytic core which forms a "closed complex". By systematically varying substrate length, pH, and temperature, we have identified conditions under which P1 duplex formation, P1 docking, or the chemical cleavage step limits the rate of the ribozyme reaction. This has enabled characterization of the individual steps as a function of substrate length, pH, and temperature, leading to several conclusions. (1) The rate constant for formation of the open complex is largely independent of substrate length, pH, and temperature, analogous to that of duplex formation in solution. This extends previous results suggesting that open complex formation entails mainly secondary structure formation and strengthens the view that the second binding step, P1 docking, represents a simple transition from secondary to tertiary structure in the context of an otherwise folded RNA. (2) The temperature dependence of the rate constant for P1 docking yields a negative activation entropy, in contrast to the positive entropy change previously observed for the docking equilibrium. This suggests a model in which tertiary interactions are not substantially formed in the transition state for P1 docking. (3) Shortening the substrate by three residues decreases the equilibrium constant for P1 docking by 200-fold, suggesting that the rigidity imposed by full-length duplex formation facilitates formation of tertiary interactions. (4) Once docked, shortened substrates are cleaved at rates within 3-fold of that for the full-length substrate. Thus, all the active site interactions required to accelerate the chemical cleavage event are maintained with shorter substrates. (5) The rate constant of approximately 10(3) min(-1) obtained for P1 docking is significantly faster than the other steps previously identified in the tertiary folding of this RNA. Nevertheless, P1 docking presumably follows other tertiary folding steps because the P1 duplex docks into a core that is formed only upon folding of the rest of the ribozyme.