Folding of the hammerhead ribozyme: pyrrolo-cytosine fluorescence separates core folding from global folding and reveals a pH-dependent conformational change

The catalytic activity of the hammerhead ribozyme is limited by its ability to fold into the native tertiary structure. Analysis of folding has been hampered by a lack of assays that can independently monitor the environment of nucleobases throughout the ribozyme-substrate complex in real time. Here, we report the development and application of a new folding assay in which we use pyrrolo-cytosine (pyC) fluorescence to (1) probe active-site formation, (2) examine the ability of peripheral ribozyme domains to support native folding, (3) identify a pH-dependent conformational change within the ribozyme, and (4) explore its influence on the equilibrium between the folded and unfolded core of the hammerhead ribozyme. We conclude that the natural ribozyme folds in two distinct noncooperative steps and the pH-dependent correlation between core folding and activity is linked to formation of the G8-C3 base pair.     

Metal ion specificities for folding and cleavage activity in the Schistosoma hammerhead ribozyme

The effects of various metal ions on cleavage activity and global folding have been studied in the extended Schistosoma hammerhead ribozyme. Fluorescence resonance energy transfer was used to probe global folding as a function of various monovalent and divalent metal ions in this ribozyme. The divalent metals ions Ca²⁺, Mg²⁺, Mn²⁺, and Sr²⁺ have a relatively small variation (less than sixfold) in their ability to globally fold the hammerhead ribozyme, which contrasts with the very large difference (>10,000-fold) in apparent rate constants for cleavage for these divalent metal ions in single-turnover kinetic experiments. There is still a very large range (>4600-fold) in the apparent rate constants for cleavage for these divalent metal ions measured in high salt (2 M NaCl) conditions where the ribozyme is globally folded. These results demonstrate that the identity of the divalent metal ion has little effect on global folding of the Schistosoma hammerhead ribozyme, whereas it has a very large effect on the cleavage kinetics. Mechanisms by which the identity of the divalent metal ion can have such a large effect on cleavage activity in the Schistosoma hammerhead ribozyme are discussed.     

A helical twist-induced conformational switch activates cleavage in the hammerhead ribozyme

We have captured the structure of a pre-catalytic conformational intermediate of the hammerhead ribozyme using a phosphodiester tether formed between I and Stem II. This phosphodiester tether appears to mimic interactions in the wild-type hammerhead RNA that enable switching between nuclease and ligase activities, both of which are required in the replicative cycles of the satellite RNA viruses from which the hammerhead ribozyme is derived. The structure of this conformational intermediate reveals how the attacking nucleophile is positioned prior to cleavage, and demonstrates how restricting the ability of Stem I to rotate about its helical axis, via interactions with Stem II, can inhibit cleavage. Analogous covalent crosslinking experiments have demonstrated that imposing such restrictions on interhelical movement can change the hammerhead ribozyme from a nuclease to a ligase. Taken together, these results permit us to suggest that switching between ligase and nuclease activity is determined by the helical orientation of Stem I relative to Stem II.     

A pH-dependent conformational change, rather than the chemical step, appears to be rate-limiting in the hammerhead ribozyme cleavage reaction.

We have investigated the chemical basis for a previously observed 7.8 A conformational change in the hammerhead ribozyme that positions the substrate for in-line attack. We have found that the conformational change can only be observed at or above pH 8.5 (in the presence of Co(2+)) and requires the presence of an ionizable 2'-OH at the cleavage site, and note that this observed apparent pK(a) of 8.5 for the conformational change is within experimental error (+/-0.5) of the previously reported apparent kinetic pK(a) of 8.5 for the hammerhead ribozyme in the presence of Co(2+). We have solved two crystal structures of hammerhead ribozymes having 2'-OCH(3) or 2'-F substitutions at the cleavage site and have found that these will not undergo a conformational change equivalent to that observed for the hammerhead ribozyme having an unmodified attacking nucleophile under otherwise identical conditions. We have also characterized the kinetics of cleavage in the crystal. In addition to verifying that the particular sequence of RNA that we crystallized cleaves faster in the crystal than in solution, we also find that the extent of cleavage in the crystal is complete, unlike in solution where this and most other hammerhead ribozyme substrates are cleaved only to about 70 % completion. The initial cleavage rate in the crystal obeys the expected log-linear relation between cleavage-rate and pH with a slope of 0.7, as has been observed for other hammerhead ribozyme sequences in solution, indicating that in both the crystal and in solution the pH-dependent step is rate-limiting. However, the cleavage rate in the crystal is biphasic, with the most dramatic distinction between initial (slower) and final (faster) phases appearing at pH 6.0. The initial phase corresponds to the pH-dependent cleavage rate observed in solution, but the second, faster phase is roughly pH-independent and closely parallels the cleavage rate observed at pH 8 (0.4/minute). This result is particularly remarkable because it entails that the rapidly cleaving phase at pH 6 is comparable to the cleavage rate for the fastest cleaving hammerhead ribozymes at pH 6. Based upon these observations, we conclude that the pH-dependent conformational change is the rate-determining step under standard conditions for the hammerhead ribozyme self-cleavage reaction, and that an ionizable 2'-proton at cleavage site is required for this conformational change. We further hypothesize that deprotonation of the cleavage-site 2'-oxygen drives this conformational change.     

Restriction in the cleavage activity of hammerhead ribozymes ensures ongoing evolution in prebiotic RNA world

Self-cleaving infectious RNAs found in many plant viruses and viroids can also cleave intrans and form hammerhead type secondary structure. It has been observed that the cleavage site must contain the triplet GUC. Also, in other cases, the sequence XUY holds good where X = A, C, G, U and Y = A, C, U but not G. The high electronegative nature of guanosine holds the key to its resistance to cleavage which does not allow hybrid formation between the ribozyme and substrate strands. Guanosine resistance to cleavage might have been the starting thrust for the evolution of a translational initiation codon from XUG. A hypothesis is proposed in this regard and its evolutionary consequences are discussed briefly. Presented at the National Symposium on Evolution of Life.     

Productive folding to the native state by a group II intron ribozyme.

Group II introns are large catalytic RNA molecules that fold into compact structures essential for the catalysis of splicing and intron mobility reactions. Despite a growing body of information on the folded state of group II introns at equilibrium, there is currently no information on the folding pathway and little information on the ionic requirements for folding. Folding isotherms were determined by hydroxyl radical footprinting for the 32 individual protections that are distributed throughout a group II intron ribozyme derived from intron ai5gamma. The isotherms span a similar range of Mg(2+) concentrations and share a similar index of cooperativity. Time-resolved hydroxyl radical footprinting studies show that all regions of the ribozyme fold slowly and with remarkable synchrony into a single catalytically active structure at a rate comparable to those of other ribozymes studied thus far. The rate constants for the formation of tertiary contacts and recovery of catalytic activity are identical within experimental error. Catalytic activity analyses in the presence of urea provide no evidence that the slow folding of the ai5gamma intron is attributable to the presence of unproductive kinetic traps along the folding pathway. Taken together, the data suggest that the rate-limiting step for folding of group II intron ai5gamma occurs early along the reaction pathway. We propose that this behavior resembles protein folding that is limited in rate by high contact order, or the need to form key tertiary interactions from partners that are located far apart in the primary or secondary structure.     

Local kinetic measures of macromolecular structure reveal partitioning among multiple parallel pathways from the earliest steps in the folding of a large RNA molecule

At the heart of the RNA folding problem is the number, structures, and relationships among the intermediates that populate the folding pathways of most large RNA molecules. Unique insight into the structural dynamics of these intermediates can be gleaned from the time-dependent changes in local probes of macromolecular conformation (e.g. reports on individual nucleotide solvent accessibility offered by hydroxyl radical (()OH) footprinting). Local measures distributed around a macromolecule individually illuminate the ensemble of separate changes that constitute a folding reaction. Folding pathway reconstruction from a multitude of these individual measures is daunting due to the combinatorial explosion of possible kinetic models as the number of independent local measures increases. Fortunately, clustering of time progress curves sufficiently reduces the dimensionality of the data so as to make reconstruction computationally tractable. The most likely folding topology and intermediates can then be identified by exhaustively enumerating all possible kinetic models on a super-computer grid. The folding pathways and measures of the relative flux through them were determined for Mg(2+) and Na(+)-mediated folding of the Tetrahymena thermophila group I intron using this combined experimental and computational approach. The flux during Mg(2+)-mediated folding is divided among numerous parallel pathways. In contrast, the flux during the Na(+)-mediated reaction is predominantly restricted through three pathways, one of which is without detectable passage through intermediates. Under both conditions, the folding reaction is highly parallel with no single pathway accounting for more than 50% of the molecular flux. This suggests that RNA folding is non-sequential under a variety of different experimental conditions even at the earliest stages of folding. This study provides a template for the systematic analysis of the time-evolution of RNA structure from ensembles of local measures that will illuminate the chemical and physical characteristics of each step in the process. The applicability of this analysis approach to other macromolecules is discussed.     

Hidden Structural Modules in a Cooperative RNA Folding Transition

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Single-molecule mechanical unfolding and folding of a pseudoknot in human telomerase RNA

RNA unfolding and folding reactions in physiological conditions can be facilitated by mechanical force one molecule at a time. By using force-measuring optical tweezers, we studied the mechanical unfolding and folding of a hairpin-type pseudoknot in human telomerase RNA in a near-physiological solution, and at room temperature. Discrete two-state folding transitions of the pseudoknot are seen at approximately 10 and approximately 5 piconewtons (pN), with ensemble rate constants of approximately 0.1 sec(-1), by stepwise force-drop experiments. Folding studies of the isolated 5'-hairpin construct suggested that the 5'-hairpin within the pseudoknot forms first, followed by formation of the 3'-stem. Stepwise formation of the pseudoknot structure at low forces are in contrast with the one-step unfolding at high forces of approximately 46 pN, at an average rate of approximately 0.05 sec(-1). In the constant-force folding trajectories at approximately 10 pN and approximately 5 pN, transient formation of nonnative structures were observed, which is direct experimental evidence that folding of both the hairpin and pseudoknot takes complex pathways. Possible nonnative structures and folding pathways are discussed.