Efficient ligation of the Schistosoma hammerhead ribozyme

The hammerhead ribozyme from Schistosoma mansoni is the best characterized of the natural hammerhead ribozymes. Biophysical, biochemical, and structural studies have shown that the formation of the loop-loop tertiary interaction between stems I and II alters the global folding, cleavage kinetics, and conformation of the catalytic core of this hammerhead, leading to a ribozyme that is readily cleaved under physiological conditions. This study investigates the ligation kinetics and the internal equilibrium between cleavage and ligation for the Schistosoma hammerhead. Single turnover kinetic studies on a construct where the ribozyme cleaves and ligates substrate(s) in trans showed up to 23% ligation when starting from fully cleaved products. This was achieved by an approximately 2000-fold increase in the rate of ligation compared to a minimal hammerhead without the loop-loop tertiary interaction, yielding an internal equilibrium that ranges from 2 to 3 at physiological Mg2+ ion concentrations (0.1-1 mM). Thus, the natural Schistosoma hammerhead ribozyme is almost as efficient at ligation as it is at cleavage. The results here are consistent with a model where formation of the loop-loop tertiary interaction leads to a higher population of catalytically active molecules and where formation of this tertiary interaction has a much larger effect on the ligation than the cleavage activity of the Schistosoma hammerhead ribozyme.     

Rearrangement of substrate secondary structure facilitates binding to the Neurospora VS ribozyme

The Neurospora VS ribozyme differs from other small, naturally occurring ribozymes in that it recognizes for trans cleavage or ligation a substrate that consists largely of a stem-loop structure. We have previously found that cleavage or ligation by the VS ribozyme requires substantial rearrangement of the secondary structure of stem-loop I, which contains the cleavage/ligation site. This rearrangement includes breaking the top base-pair of stem-loop I, allowing formation of a kissing interaction with loop V, and changing the partners of at least three other base-pairs within stem-loop I to adopt a conformation termed shifted. In the work presented, we have designed a binding assay and used mutational analysis to investigate the contribution of each of these structural changes to binding and ligation. We find that the loop I-V kissing interaction is necessary but not sufficient for binding and ligation. Constitutive opening of the top base-pair of stem-loop I has little, if any, effect on either activity. In contrast, the ability to adopt the shifted conformation of stem-loop I is a major determinant of binding: mutants that cannot adopt this conformation bind much more weakly than wild-type and mutants with a constitutively shifted stem-loop I bind much more strongly. These results implicate the adoption of the shifted structure of stem-loop I as an important process at the binding step in the VS ribozyme reaction pathway. Further investigation of features near the cleavage/ligation site revealed that sulphur substitution of the non-bridging phosphate oxygen atoms immediately downstream of the cleavage/ligation site, implicated in a putative metal ion binding site, significantly altered the cleavage/ligation equilibrium but did not perturb substrate binding significantly. This indicates that the substituted oxygen atoms, or an associated metal ion, affect a step that occurs after binding and that they influence the rates of cleavage and ligation differently.     

Identification of separate structural features that affect rate and cation concentration dependence of self-cleavage by the Neurospora VS ribozyme

The cleavage site of the Neurospora VS ribozyme is located in an internal loop in a hairpin called stem-loop I. Stem-loop I undergoes a cation-dependent structural change to adopt a conformation, termed shifted, that is required for activity. Using site-directed mutagenesis and kinetic analyses, we show here that the insertion of a single-stranded linker between stem-loop I and the rest of the ribozyme increases the observed self-cleavage rate constant by 2 orders of magnitude without affecting the Mg(2+) requirement of the reaction. A distinct set of mutations that favors the formation of the shifted conformation of stem-loop I decreases the Mg(2+) requirement by an order of magnitude with little or no effect on the observed cleavage rate under standard reaction conditions. Similar trends were seen in reactions that contained Li(+) instead of Mg(2+). Mutants with lower ionic requirements also exhibited increased thermostability, providing evidence that the shifted conformation of stem-loop I favors the formation of the active conformation of the RNA. In natural, multimeric VS RNA, where a given ribozyme core is flanked by one copy of stem-loop I immediately upstream and another copy 0.7 kb downstream, cleavage at the downstream site is strongly preferred, providing evidence that separation of stem-loop I from the ribozyme core reflects the naturally evolved organization of the RNA.     

Rapid formation of a solvent-inaccessible core in the Neurospora Varkud satellite ribozyme

We have used hydroxyl radicals generated by decomposition of peroxynitrous acid to study Mg(2+)-dependent structure and folding of the Varkud satellite (VS) ribozyme. Protection from radical cleavage shows the existence of a solvent-inaccessible core, which includes nucleotides near two three-helix junctions, the kissing interaction between stem-loops I and V and other nucleotides, most of which have also been implicated as important for folding or activity. Kinetic folding experiments showed that the ribozyme folds very quickly, with the observed protections completely formed within 2 s of addition of MgCl(2). In mutants that disrupt the kissing interaction or entirely remove stem-loop I, which contains the cleavage site, nucleotides in the three-helix junctions and a subset of those elsewhere remain protected. Unlike smaller ribozymes, the VS ribozyme retains a significant amount of structure in the absence of its substrate. Protections that depend on proper interaction between the substrate and the rest ribozyme map to a region previously proposed as the active site of the ribozyme and along both sides of helix II, identifying candidate sites of docking for the substrate helix.     

The P5abc peripheral element facilitates preorganization of the tetrahymena group I ribozyme for catalysis

Phylogenetic comparisons and site-directed mutagenesis indicate that group I introns are composed of a catalytic core that is universally conserved and peripheral elements that are conserved only within intron subclasses. Despite this low overall conservation, peripheral elements are essential for efficient splicing of their parent introns. We have undertaken an in-depth structure-function analysis to investigate the role of one of these elements, P5abc, using the well-characterized ribozyme derived from the Tetrahymena group I intron. Structural comparisons using solution-based free radical cleavage revealed that a ribozyme lacking P5abc (E(DeltaP5abc)) and E(DeltaP5abc) with P5abc added in trans (E(DeltaP5abc).P5abc) adopt a similar global tertiary structure at Mg(2+) concentrations greater than 20 mM [Doherty, E. A., et al. (1999) Biochemistry 38, 2982-90]. However, free E(DeltaP5abc) is greatly compromised in overall oligonucleotide cleavage activity, even at Mg(2+) concentrations as high as 100 mM. Further characterization of E(DeltaP5abc) via DMS modification revealed local structural differences at several positions in the conserved core that cluster around the substrate binding sites. Kinetic and thermodynamic dissection of individual reaction steps identified defects in binding of both substrates to E(DeltaP5abc), with > or =25-fold weaker binding of a guanosine nucleophile and > or =350-fold weaker docking of the oligonucleotide substrate into its tertiary interactions with the ribozyme core. These defects in binding of the substrates account for essentially all of the 10(4)-fold decrease in overall activity of the deletion mutant. Together, the structural and functional observations suggest that the P5abc peripheral element not only provides stability but also positions active site residues through indirect interactions, thereby preferentially stabilizing the active ribozyme structure relative to alternative less active states. This is consistent with the view that peripheral elements engage in a network of mutually reinforcing interactions that together ensure cooperative folding of the ribozyme to its active structure.     

Catalytic diversity of extended hammerhead ribozymes

Chimeras of the well-characterized minimal hammerhead 16 and nine extended hammerheads derived from natural viroids and satellite RNAs were constructed with the goal of assessing whether their very different peripheral tertiary interactions modulate their catalytic properties. For each chimera, three different assays were used to determine the rate of cleavage and the fraction of full-length hammerhead at equilibrium and thereby deduce the elemental cleavage ( k 2) and ligation ( k -2) rate constants. The nine chimeras were all more active than minimal hammerheads and exhibited a very broad range of catalytic properties, with values of k 2 varying by 750-fold and k -2 by 100-fold. At least two of the hammerheads exhibited an altered dependence of k obs on magnesium concentration. Since much less catalytic diversity is observed among minimal hammerheads that lack the tertiary interactions, a possible role for the different tertiary interaction is to modulate the hammerhead cleavage properties in viroids. For example, differing hammerhead cleavage and ligation rates could affect the steady state concentrations of linear, circular, and polymeric genomes in infected cells.     

Effects of cobalt hexammine on folding and self-cleavage of the Neurospora VS ribozyme

We have investigated the effects of Co(NH3)6(3+), an analog of hexahydrated Mg2+, on folding and catalysis of the Neurospora VS ribozyme. Most of the metal ion-induced changes detected by chemical modification structure probing in either metal ion are similar, but occur at approximately 33-fold lower concentrations of Co(NH3)6(3+) than Mg2+. However, Co(NH3)6(3+) is not as effective at inducing two functionally important structural changes: stabilizing the pseudoknot interaction between loops I and V, and rearranging the secondary structure of helix Ib. Comparison of the folding of the precursor and the downstream cleavage product, which lacks helix Ia, shows that helix Ia inhibits stable pseudoknot formation and rearrangement of helix Ib. The VS ribozyme does not self-cleave with Co(NH3)6(3+) as the sole polyvalent cation; however, mixed-metal kinetic experiments show that Co(NH3)6(3+) does not inhibit Mg2+-induced self-cleavage. In contrast, at sub-saturating concentrations of Mg2+, Co(NH3)6(3+) increases the rate of Mg2+-induced self-cleavage, indicating that Co(NH3)6(3+) contributes to the functionally relevant folding of the VS ribozyme.     

Distinct reaction pathway promoted by non-divalent-metal cations in a tertiary stabilized hammerhead ribozyme

Divalent ion sensitivity of hammerhead ribozymes is significantly reduced when the RNA structure includes appropriate tertiary stabilization. Therefore, we investigated the activity of the tertiary stabilized "RzB" hammerhead ribozyme in several nondivalent ions. Ribozyme RzB is active in spermidine and Na(+) alone, although the cleavage rates are reduced by more than 1,000-fold relative to the rates observed in Mg(2+) and in transition metal ions. The trivalent cobalt hexammine (CoHex) ion is often used as an exchange-inert analog of hydrated magnesium ion. Trans-cleavage rates exceeded 8 min(-1) in 20 mM CoHex, which promoted cleavage through outersphere interactions. The stimulation of catalysis afforded by the tertiary structural interactions within RzB does not require Mg(2+), unlike other extended hammerhead ribozymes. Site-specific interaction with at least one Mg(2+) ion is suggested by CoHex competition experiments. In the presence of a constant, low concentration of Mg(2+), low concentrations of CoHex decreased the rate by two to three orders of magnitude relative to the rate in Mg(2+) alone. Cleavage rates increased as CoHex concentrations were raised further, but the final fraction cleaved was lower than what was observed in CoHex or Mg(2+) alone. These observations suggest that Mg(2+) and CoHex compete for binding and that they cause misfolded structures when they are together. The results of this study support the existence of an alternate catalytic mechanism used by nondivalent ions (especially CoHex) that is distinct from the one promoted by divalent metal ions, and they imply that divalent metals influence catalysis through a specific nonstructural role.     

The internal equilibrium of the hairpin ribozyme: temperature, ion and pH effects

The hairpin ribozyme reversibly cleaves phosphodiesters of RNA substrates to generate products with 5' hydroxyl and 2',3'-cyclic phosphate termini. We previously found that the rate constant for ligation is tenfold faster than the rate constant for cleavage under standard conditions. The hammerhead ribozyme catalyzes the same reactions but is reported to favor cleavage relative to ligation by more than 100-fold under the same conditions. To explore the basis for this difference, we examined the influence of temperature, ions and pH on the hairpin ribozyme internal equilibrium. Under the same conditions, the loss of entropy associated with ligation is less for the hairpin than for the hammerhead ribozyme, consistent with the notion that a more rigid hairpin structure undergoes a smaller decrease in dynamics upon ligation than the more flexible hammerhead structure. Increased salt and reduced temperature shift the equilibrium toward ligation while pH has little effect, suggesting that conditions that stabilize RNA structure tend to promote ligation. The hairpin ribozyme appears to take up at least one tri- or divalent cation or two monovalent cations upon ligation. The efficiency with which different cations promote ligation depends strongly on valence and, less strongly, on ionic radius or electronegativity. This pattern of cation selectivity suggests that cations promote ligation through delocalized electrostatic shielding, perhaps interacting with a region of especially high charge density in the ligated ribozyme. Changes in ionic conditions produce large but compensating changes in enthalpy and entropy for cleavage and ligation. Thus, in addition to any increase in ribozyme dynamics associated with cleavage, re-organization of associated cations contributes significantly to hairpin ribozyme thermodynamics.     

Solvent protection of the hammerhead ribozyme in the ground state: evidence for a cation-assisted conformational change leading to catalysis

Tertiary folding of the hammerhead ribozyme has been analyzed by hydroxyl radical footprinting. Three hammerhead constructs with distinct noncore sequences, connectivities, and catalytic properties show identical protection patterns, in which conserved core residues (G5, A6, U7, G8, and A9) and the cleavage site (C17, G1.1, and U1.2) become reproducibly protected from nucleolytic attack by radicals. Metal ion titrations show that all protections appear together, suggesting a single folding event to a common tertiary structure, rather than an ensemble of different folds. The apparent binding constants for folding and catalysis by Mg(2+) are lower than those for Li(+) by 3 orders of magnitude, but in each case the protected sites are identical. For both Mg(2+) and Li(+), the ribozyme folds into the protected tertiary structure at significantly lower cation concentrations than those required for cleavage. The sites of protection include all of the sites of reduced solvent accessibility calculated from two different crystal structures, including both core and noncore nucleotides. In addition, experimentally observed protected sites include additional sequences adjacent to those predicted by the crystal structures, suggesting that the solution structure may be folded into a more compact shape. A 2'-deoxy substitution at G5 abolishes all protection, indicating that the 2'-OH is essential for folding. Together, these results support a model in which low concentrations of metal ions fold the ribozyme into a stable ground state tertiary structure that is similar to the crystallographic structures, and higher concentrations of metal ions support a transient conformational change into the transition state for catalysis. These data do not themselves address the issue as to whether a large- or small-scale conformational change is required for catalysis.     

Long-range tertiary interactions in single hammerhead ribozymes bias motional sampling toward catalytically active conformations

Enzymes generally are thought to derive their functional activity from conformational motions. The limited chemical variation in RNA suggests that such structural dynamics may play a particularly important role in RNA function. Minimal hammerhead ribozymes are known to cleave efficiently only in ～ 10-fold higher than physiologic concentrations of Mg(2+) ions. Extended versions containing native loop-loop interactions, however, show greatly enhanced catalytic activity at physiologically relevant Mg(2+) concentrations, for reasons that are still ill-understood. Here, we use Mg(2+) titrations, activity assays, ensemble, and single molecule fluorescence resonance energy transfer (FRET) approaches, combined with molecular dynamics (MD) simulations, to ask what influence the spatially distant tertiary loop-loop interactions of an extended hammerhead ribozyme have on its structural dynamics. By comparing hammerhead variants with wild-type, partially disrupted, and fully disrupted loop-loop interaction sequences we find that the tertiary interactions lead to a dynamic motional sampling that increasingly populates catalytically active conformations. At the global level the wild-type tertiary interactions lead to more frequent, if transient, encounters of the loop-carrying stems, whereas at the local level they lead to an enrichment in favorable in-line attack angles at the cleavage site. These results invoke a linkage between RNA structural dynamics and function and suggest that loop-loop interactions in extended hammerhead ribozymes-and Mg(2+) ions that bind to minimal ribozymes-may generally allow more frequent access to a catalytically relevant conformation(s), rather than simply locking the ribozyme into a single active state.     

The three-dimensional architecture of the class I ligase ribozyme

The class I ligase ribozyme catalyzes a Mg(++)-dependent RNA-ligation reaction that is chemically analogous to a single step of RNA polymerization. Indeed, this ribozyme constitutes the catalytic domain of an accurate and general RNA polymerase ribozyme. The ligation reaction is also very rapid in both single- and multiple-turnover contexts and thus is informative for the study of RNA catalysis as well as RNA self-replication. Here we report the initial characterization of the three-dimensional architecture of the ligase. When the ligase folds, several segments become protected from hydroxyl-radical cleavage, indicating that the RNA adopts a compact tertiary structure. Ribozyme folding was largely, though not completely, Mg(++) dependent, with a K(1/2[Mg]) < 1 mM, and was observed over a broad temperature range (20 degrees C -50 degrees C). The hydroxyl-radical mapping, together with comparative sequence analyses and analogy to a region within 23S ribosomal RNA, were used to generate a three-dimensional model of the ribozyme. The predictive value of the model was tested and supported by a photo-cross-linking experiment.     

A pH-sensitive RNA tertiary interaction affects self-cleavage activity of the HDV ribozymes in the absence of added divalent metal ion

Self-cleavage of the genomic and antigenomic ribozymes from hepatitis delta virus (HDV) requires divalent cation for optimal activity. Recently, the HDV genomic ribozyme has been shown to be active in NaCl in the absence of added divalent metal ion at low pH (apparent pKa 5.7). However, we find that the antigenomic ribozyme is 100 to 1000-fold less active under similar conditions. With deletion of a three-nucleotide sequence (C41-A42-A43) unique to the genomic ribozyme, the rate constant for cleavage decreased substantially, while activity of the antigenomic ribozyme was enhanced by introducing a CAA sequence. From the crystal structure, it has been proposed that C41 in this sequence is protonated. To investigate a possible connection between activity at low pH and protonation of C41, mutations were made that were predicted to either eliminate protonation or alter the nature of the tertiary interaction upon protonation. In the absence of added Mg2+, these mutations reduced activity and eliminated the observed pH-rate dependence. Thermal denaturation studies revealed a pH-sensitive structural feature in the genomic ribozyme, while unfolding of the mutant ribozymes was pH-independent. We propose that, in the absence of added Mg2+, protonation of C41 contributes to enhanced activity of the HDV genomic ribozyme at low pH.     

Ligation of the hairpin ribozyme in cis induced by freezing and dehydration

Although reducing the temperature slows most chemical reactions, freezing can stimulate some reactions by mechanisms that are only partially understood. Here we show that freezing stimulates the self-ligation (circularization) of linear forms of the hairpin ribozyme (HPR) containing 2',3'-cyclic phosphate and 5'-OH termini. Divalent metal ions (M2+) are not required, but monovalent cations and anions at millimolar concentrations can have various effects on this reaction depending on the specific ion. Under optimal conditions, the observed rate of M2+-independent self-ligation reaches a peak (0.04 min(-1)) at -10 degrees C with a yield of -60% after 1 h. In contrast, no ligation occurs either at above 0 degrees C or in solutions that remain unfrozen when supercooled to subzero temperatures. Under freezing conditions, the cleavage-ligation equilibrium strongly favors ligation. Besides freezing, evaporation of the aqueous solvent as well as the presence of ethanol at levels of 40% or above can also induce M2+-independent HPR ligation at 25 degrees C. We argue that partial RNA dehydration, which is a common feature of freezing, evaporation, and the presence of ethanol, is a key factor supporting HPR ligation activity at both above- and below-freezing temperatures. In the context of the RNA world hypothesis, freezing-induced ligation is an attractive mechanism by which complex RNAs could have evolved under conditions in which RNA was relatively protected against degradation.     

Hammerheads derived from sTRSV show enhanced cleavage and ligation rate constants

The catalytic properties of the hammerhead ribozyme embedded in the (+) strand of the satellite tobacco ringspot viral genome are analyzed with the goal of obtaining the elemental rate constants of the cleavage (k(2)) and ligation (k(-)(2)) steps. Two different chimeras combining the sTRSV (+) hammerhead and the well-characterized hammerhead 16 were used to measure the cleavage rate constant (k(2)), the rate of approach to equilibrium (k(obs) = k(2) + k(-)(2)), and the fraction of full-length hammerhead at equilibrium (k(-)(2)/k(2) + k(-)(2)). When compared to minimal hammerheads that lack the recently discovered loop I-loop II interaction, an extended format hammerhead derived from sTRSV studied here shows at least a 20-fold faster k(2) and a 1300-fold faster k(-)(2) at 10 mM MgCl(2). However, the magnesium dependence of the cleavage rate is not significantly changed. Thus, the enhanced cleavage of this hammerhead observed in vivo is due to its higher intrinsic rate and not due to its tighter binding of magnesium ions. The faster k(-)(2) of this hammerhead suggests that ligation may be used to form circular RNA genomes. This in vitro system will be valuable for experiments directed at understanding the hammerhead mechanism and the role of the loop I-loop II interaction.     

Diffusely bound Mg2+ ions slightly reorient stems I and II of the hammerhead ribozyme to increase the probability of formation of the catalytic core

The hammerhead ribozyme is one of the best-studied small RNA enzymes, yet is mechanistically still poorly understood. We measured the Mg(2+) dependencies of folding and catalysis for two distinct hammerhead ribozymes, HHL and HH alpha. HHL has three long helical stems and was previously used to characterize Mg(2+)-induced folding. HH alpha has shorter stems and an A.U tandem next to the cleavage site that increases activity approximately 10-fold at 10 mM Mg(2+). We find that both ribozymes cleave with fast rates (5-10 min(-1), at pH 8 and 25 degrees C) at nonphysiologically high Mg(2+) concentrations, but with distinct Mg(2+) dissociation constants for catalysis: 90 mM for HHL and 10 mM for HH alpha. Using time-resolved fluorescence resonance energy transfer, we measured the stem I-stem II distance distribution as a function of Mg(2+) concentration, in the presence and absence of 100 mM Na(+), at 4 and 25 degrees C. Our data show two structural transitions. The larger transition (with Mg(2+) dissociation constants in the physiological range of approximately 1 mM, below the catalytic dissociation constants) brings stems I and II close together and is hindered by Na(+). The second, globally minor, rearrangement coincides with catalytic activation and is not hindered by Na(+). Additionally, the more active HH alpha exhibits a higher flexibility than HHL under all conditions. Finally, both ribozyme-product complexes have a bimodal stem I-stem II distance distribution, suggesting a fast equilibrium between distinct conformers. We propose that the role of diffusely bound Mg(2+) is to increase the probability of formation of a properly aligned catalytic core, thus compensating for the absence of naturally occurring kissing-loop interactions.     

Substitution of the 2'-hydroxyl group at position 2.1 by an amino group interferes with Mg(2+) binding and efficient cleavage by hammerhead ribozyme.

Recently we have demonstrated that hammerhead ribozymes can be fully substituted with 2'-amino pyrimidines without detriment to the catalytic activity, provided that positions 2.2 and/or 2.1 are not modified. We now report on the potential molecular mechanisms by which 2'-amino groups at these positions inhibit the ribozyme cleavage activity. In the presence of Mg(2+), the 2'-amino modification at positions 2.2 and/or 2.1 had no significant effect on substrate binding. Detailed analysis of the ribozyme initial cleavage rates in the presence of various Mg(2+) concentrations indicated that Mg(2+) binding is inhibited by the 2'-amino group at position 2.1. Furthermore, preannealed substrate molecules to the modified ribozyme are not effectively cleaved upon Mg(2+) addition, indicating an alteration of the ribozyme cleavage step. Surprisingly, the cleavage activity of the modified ribozymes was substantially increased when Mg(2+) ions were replaced by the thiophilic Mn(2+) ions, whereas only a moderate cleavage enhancement occurred with its unmodified version. Taken together, our findings indicate that changes in the sugar at position 2.1 alter Mg(2+)-promoting ribozyme cleavage.     

Sequence elements outside the hammerhead ribozyme catalytic core enable intracellular activity

The hammerhead ribozyme (HHRz) is a small, naturally occurring ribozyme that site-specifically cleaves RNA and has long been considered a potentially useful tool for gene silencing. The minimal conserved HHRz motif derived from natural sequences consists of three helices that intersect at a highly conserved catalytic core of 11 nucleotides. The presence of this motif is sufficient to support cleavage at high Mg2+ concentrations, but not at the low Mg2+ concentrations characteristic of intracellular environments. Here we demonstrate that natural HHRzs require the presence of additional nonconserved sequence elements outside of the conserved catalytic core to enable intracellular activity. These elements may stabilize the HHRz in a catalytically active conformation via tertiary interactions. HHRzs stabilized by these interactions cleave efficiently at physiological Mg2+ concentrations and are functional in vivo. The proposed role of these tertiary interacting motifs is supported by mutational, functional, structural and molecular modeling analysis of natural HHRzs.     

Principles of RNA compaction: insights from the equilibrium folding pathway of the P4-P6 RNA domain in monovalent cations

Counterions are required for RNA folding, and divalent metal ions such as Mg(2+) are often critical. To dissect the role of counterions, we have compared global and local folding of wild-type and mutant variants of P4-P6 RNA derived from the Tetrahymena group I ribozyme in monovalent and in divalent metal ions. A remarkably simple picture of the folding thermodynamics emerges. The equilibrium folding pathway in monovalent ions displays two phases. In the first phase, RNA molecules that are initially in an extended conformation enforced by charge-charge repulsion are relaxed by electrostatic screening to a state with increased flexibility but without formation of long-range tertiary contacts. At higher concentrations of monovalent ions, a state that is nearly identical to the native folded state in the presence of Mg(2+) is formed, with tertiary contacts that involve base and backbone interactions but without the subset of interactions that involve specific divalent metal ion-binding sites. The folding model derived from these and previous results provides a robust framework for understanding the equilibrium and kinetic folding of RNA.     

Structure and function of the hairpin ribozyme

The hairpin ribozyme belongs to the family of small catalytic RNAs that cleave RNA substrates in a reversible reaction that generates 2',3'-cyclic phosphate and 5'-hydroxyl termini. The hairpin catalytic motif was discovered in the negative strand of the tobacco ringspot virus satellite RNA, where hairpin ribozyme-mediated self-cleavage and ligation reactions participate in processing RNA replication intermediates. The self-cleaving hairpin, hammerhead, hepatitis delta and Neurospora VS RNAs each adopt unique structures and exploit distinct kinetic and catalytic mechanisms despite catalyzing the same chemical reactions. Mechanistic studies of hairpin ribozyme reactions provided early evidence that, like protein enzymes, RNA enzymes are able to exploit a variety of catalytic strategies. In contrast to the hammerhead and Tetrahymena ribozyme reactions, hairpin-mediated cleavage and ligation proceed through a catalytic mechanism that does not require direct coordination of metal cations to phosphate or water oxygens. The hairpin ribozyme is a better ligase than it is a nuclease while the hammerhead reaction favors cleavage over ligation of bound products by nearly 200-fold. Recent structure-function studies have begun to yield insights into the molecular bases of these unique features of the hairpin ribozyme.