NMR structure of the A730 loop of the Neurospora VS ribozyme: insights into the formation of the active site

The Neurospora VS ribozyme is a small nucleolytic ribozyme with unique primary, secondary and global tertiary structures, which displays mechanistic similarities to the hairpin ribozyme. Here, we determined the high-resolution NMR structure of a stem-loop VI fragment containing the A730 internal loop, which forms part of the active site. In the presence of magnesium ions, the A730 loop adopts a structure that is consistent with existing biochemical data and most likely reflects its conformation in the VS ribozyme prior to docking with the cleavage site internal loop. Interestingly, the A730 loop adopts an S-turn motif that is also present in loop B within the hairpin ribozyme active site. The S-turn appears necessary to expose the Watson-Crick edge of a catalytically important residue (A756) so that it can fulfill its role in catalysis. The A730 loop and the cleavage site loop of the VS ribozyme display structural similarities to internal loops found in the active site of the hairpin ribozyme. These similarities provided a rationale to build a model of the VS ribozyme active site based on the crystal structure of the hairpin ribozyme.     

A pH controlled conformational switch in the cleavage site of the VS ribozyme substrate RNA

The VS ribozyme is a 154 nucleotide sequence found in certain natural strains of Neurospora. The RNA can be divided into a substrate and a catalytic domain. Here we present the solution structure of the substrate RNA that is cleaved in a trans reaction by the catalytic domain in the presence of Mg2+. The 30 nucleotide substrate RNA forms a compact helix capped by a flexible loop. The cleavage site bulge contains three non-canonical base-pairs, including an A+.C pair with a protonated adenine. This adenine (A622) is a pH controlled conformational switch that opens up the internal loop at higher pH. The possible significance of this switch for substrate recognition and cleavage is discussed.     

Formation of an active site in trans by interaction of two complete Varkud Satellite ribozymes

The complete VS ribozyme comprises seven helical segments, connected by three three-way RNA junctions. In the presence of Mg²⁺ ions, cleavage occurs within the internal loop of helix I. This requires the participation of a guanine (G638) within the helix I loop, and a remote adenine (A756) within an internal loop of helix VI. Previous structural studies have suggested that helix I docks into the fold of the remaining part of the ribozyme, bringing A756 and G638 close to the scissile phosphate to allow the cleavage reaction to proceed. We show here that while either A756C or G638A individually exhibit very low cleavage activity, a mixture of the two variants leads to cleavage of the A756C RNA, but not the G638A RNA. The rate of cleavage depends on the concentration of the VS G638A RNA, as expected for a bimolecular interaction. This regaining of cleavage activity by complementation indicates that helix I of one VS RNA can interact with another VS RNA molecule to generate a functional active site in trans.     

Do the hairpin and VS ribozymes share a common catalytic mechanism based on general acid–base catalysis? A critical assessment of available experimental data

The active centers of the hairpin and VS ribozymes are both generated by the interaction of two internal loops, and both ribozymes use guanine and adenine nucleobases to accelerate cleavage and ligation reactions. The centers are topologically equivalent and the relative positioning of key elements the same. There is good evidence that the cleavage reaction of the VS ribozyme is catalyzed by the guanine (G638) acting as general base and the adenine (A756) as general acid. We now critically evaluate the experimental mechanistic evidence for the hairpin ribozyme. We conclude that all the available data are fully consistent with a major contribution to catalysis by general acid-base catalysis involving the adenine (A38) and guanine (G8). It appears that the two ribozymes are mechanistically equivalent.     

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.     

Adenine protonation in domain B of the hairpin ribozyme

Protein enzymes often use ionizable side chains, such as histidine, for general acid-base catalysis because the imidazole pK(a) is near neutral pH. RNA enzymes, on the other hand, are comprised of nucleotides which do not have apparent pK(a) values near neutral pH. Nevertheless, it has been recently shown that cytidine and adenine protonation can play an important role in both nucleic acid structure and catalysis. We have employed heteronuclear NMR methods to determine the pK(a) values and time scales of chemical exchanges associated with adenine protonation within the catalytically essential B domain of the hairpin ribozyme. The large, adenine-rich internal loop of the B domain allows us to determine adenine pK(a) values for a variety of non-Watson-Crick base pairs. We find that adenines within the internal loop have pK(a) values ranging from 4.8 to 5.8, significantly higher than the free mononucleotide pK(a) of 3. 5. Adenine protonation results in potential charge stabilization, hydrogen bond formation, and stacking interactions that are expected to stabilize the internal loop structure at low pH. Fast proton exchange times of 10-50 micros were determined for the well-resolved adenines. These results suggest that shifted pK(a) values may be a common feature of adenines in non-Watson-Crick base pairs, and identify two adenines which may participate in hairpin ribozyme active site chemistry.     

The structure of the L3 loop from the hepatitis delta virus ribozyme: a syn cytidine.

The structure of the L3 central hairpin loop isolated from the antigenomic sequence of the hepatitis delta virus ribozyme with the P2 and P3 stems from the ribozyme stacked on top of the loop has been determined by NMR spectroscopy. The 26 nt stem-loop structure contains nine base pairs and a 7 nt loop (5'-UCCUCGC-3'). This hairpin loop is critical for efficient catalysis in the intact ribozyme. The structure was determined using homonuclear and heteronuclear NMR techniques on non-labeled and15N-labeled RNA oligonucleotides. The overall root mean square deviation for the structure was 1.15 A (+/- 0.28 A) for the loop and the closing C.G base pair and 0.90 A (+/- 0.18 A) for the loop and the closing C.G base pair but without the lone purine in the loop, which is not well defined in the structure. The structure indicates a U.C base pair between the nucleotides on the 5'- and 3'-ends of the loop. This base pair is formed with a single hydrogen bond involving the cytosine exocyclic amino proton and the carbonyl O4 of the uracil. The most unexpected finding in the loop is a syn cytidine. While not unprecedented, syn pyrimidines are highly unusual. This one can be confidently established by intranucleotide distances between the ribose and the base determined by NMR spectroscopy. A similar study of the structure of this loop showed a somewhat different three-dimensional structure. A discussion of differences in the two structures, as well as possible sites of interaction with the cleavage site, will be presented.     

Base and sugar requirements for RNA cleavage of essential nucleoside residues in internal loop B of the hairpin ribozyme: implications for secondary structure.

The hairpin ribozyme is a small self-cleaving RNA that can be engineered for RNA cleavage in trans and has potential as a therapeutic agent. We have used a chemical synthesis approach to study the requirements of hairpin RNA cleavage for sugar and base moieties in residues of internal loop B, an essential region in one of the two ribozyme domains. Individual nucleosides were substituted by either a 2'-deoxy-nucleoside, an abasic residue, or a C3-spacer (propyl linker) and the abilities of the modified ribozymes to cleave an RNA substrate were studied in comparison with the wild-type ribozyme. From these results, together with previous studies, we propose a new model for the potential secondary structure of internal loop B of the hairpin ribozyme.     

A guanine nucleobase important for catalysis by the VS ribozyme

A guanine (G638) within the substrate loop of the VS ribozyme plays a critical role in the cleavage reaction. Replacement by any other nucleotide results in severe impairment of cleavage, yet folding of the substrate is not perturbed, and the variant substrates bind the ribozyme with similar affinity, acting as competitive inhibitors. Functional group substitution shows that the imino proton on the N1 is critical, suggesting a possible role in general acid-base catalysis, and this in accord with the pH dependence of the reaction rate for the natural and modified substrates. We propose a chemical mechanism for the ribozyme that involves general acid-base catalysis by the combination of the nucleobases of guanine 638 and adenine 756. This is closely similar to the probable mechanism of the hairpin ribozyme, and the active site arrangements for the two ribozymes appear topologically equivalent. This has probably arisen by convergent evolution.     

Comparative analysis of hairpin ribozyme structures and interference data

Great strides in understanding the molecular underpinnings of RNA catalysis have been achieved with advances in RNA structure determination by NMR spectroscopy and X-ray crystallography. Despite these successes the functional relevance of a given structure can only be assessed upon comparison with biochemical studies performed on functioning RNA molecules. The hairpin ribozyme presents an excellent case study for such a comparison. The active site is comprised of two stems each with an internal loop that forms a series of non-canonical base pairs. These loops dock into each other to create an active site for catalysis. Recently, three independent structures have been determined for this catalytic RNA, including two NMR structures of the isolated loop A and loop B stems and a high-resolution crystal structure of both loops in a docked conformation. These structures differ significantly both in their tertiary fold and the nature of the non-canonical base pairs formed within each loop. Several of the chemical groups required to achieve a functioning hairpin ribozyme have been determined by nucleotide analog interference mapping (NAIM). Here we compare the three hairpin structures with previously published NAIM data to assess the convergence between the structural and functional data. While there is significant disparity between the interference data and the individual NMR loop structures, there is almost complete congruity with the X-ray structure. The only significant differences cluster around an occluded pocket adjacent to the scissile phosphate. These local differences may suggest a role for these atoms in the transition state, either directly in chemistry or via a local structural rearrangement.     

Analysis of the functional role of a G.A sheared base pair by in vitro genetics

A classical genetic strategy has been combined with an in vitro selection method to search for functional interactions between the two domains of the hairpin ribozyme. G(21) is located within internal loop B; it is proposed to form a sheared base pair with A(43) across loop B and to bind a Mg(2+) ion. Both nucleotides are important for ribozyme function, and G.A sheared base pairs are a very widespread motif in structured RNA. We took advantage of its presence in the hairpin ribozyme to study its functional role. Pseudorevertants, in which the loss of G(21) was compensated by mutations at other positions, were isolated by in vitro selection. The vast majority of G(21) revertants contained substitutions within domain A, pointing to functional communication between specific sites within the two domains of the hairpin ribozyme. The possibility of a direct or redundant contacts is supported by electrophoretic mobility shift studies showing that a complex formed between domain B of the ribozyme and the substrate was disrupted and restored by base substitutions that have analogous effects on catalytic activity. The functional significance of this complex, the role of the nucleotides involved, and the basis for magnesium ion requirement is discussed.     

The hairpin ribozyme

The hairpin ribozyme is a member of a family of small RNA endonucleases, which includes hammer-head, human hepatitis delta virus, Neurospora VS, and the lead-dependent catalytic RNAs. All these catalytic RNAs reversibly cleave the phosphodiester bond of substrate RNA to generate 5'-hydroxyl and 2',3'-cyclic phosphate termini. Whereas the reaction products from family members are similar, large structural and mechanistic differences exist. Structurally the hairpin ribozyme has two principal domains that interact to facilitate catalysis. The hairpin ribozyme uses a catalytic mechanism that does not require metals for cleavage or ligation of substrate RNA. In this regard it is presently unique among RNA catalysts. Targeting rules for cleavage of substrate have been determined and required bases for catalysis have been identified. The hairpin ribozyme has been developed and used for gene therapy and was the first ribozyme to be approved for human clinical trials.     

Rearrangement of a stable RNA secondary structure during VS ribozyme catalysis

The Neurospora VS ribozyme recognizes and cleaves a substrate RNA that contains a GC-rich stem loop. In contrast to most RNA secondary structures that are stable during tertiary or quaternary folding, this substrate undergoes extensive ribozyme-induced rearrangement in the presence of magnesium in which the base pairings of at least seven of the ten nucleotides in the stem are changed. This conformational switch is essential for catalytic activity with the wild-type substrate and creates a metal-binding secondary structure motif near the cleavage site. Base pair rearrangement is accompanied by bulging a cytosine from the middle of the stem, indicating that ribozymes may perform base flipping, an activity previously observed only with protein enzymes that modify DNA.     

The role of magnesium ions and 2'-hydroxyl groups in the VS ribozyme-substrate interaction

The minimal substrate of the trans-cleaving Neurospora VS ribozyme has a stem-loop structure and interacts with the ribozyme by RNA tertiary interactions that remain only partially defined. The magnesium ion dependence of the catalytic parameters of a trans-cleaving VS-derived ribozyme were studied. The turnover number of the catalytic RNA was found to depend on the binding of at least three magnesium ions, with an apparent magnesium ion dissociation constant of 16mM, but K(M) was observed to be metal ion independent in the millimolar range. To address the role of 2'-hydroxyl groups of the VS substrate RNA in interactions with the ribozyme, 23 altered substrates, each with a single 2'-deoxyribonucleoside substitution, were synthesised and their kinetic properties in the VS ribozyme reaction were analysed. The removal of five 2'-hydroxyl groups, at positions G620, A621, U628, C629 and G630 inhibited the reaction, whereas at two sites, G623 and A639, reaction was stimulated by the modification. Substitution of G620 with a 2'-deoxynucleoside was expected to inhibit the reaction, in line with the critical role of this 2'-hydroxyl group in the transesterification reaction. Altered substrates in which a 2'-O-methyl nucleoside replaced A621, U628, C629 and G630 were prepared and characterised. Although removal of the hydroxyl group of A621 inhibited the turnover number of the ribozyme significantly, this activity was recovered upon 2'-O-methyl adenosine substitution, suggesting that the 2'-oxygen atom of this nucleoside forms an important contact within the ribozyme active site. A cluster of residues within the loop region of the substrate, were more modestly affected by 2'-deoxynucleoside substitution. In two cases, magnesium binding was impaired, suggesting that stem-loop I is a possible magnesium ion binding site.     

Functional group requirements in the probable active site of the VS ribozyme

The VS ribozyme catalyses the site-specific cleavage of a phosphodiester linkage by a transesterification reaction that entails the attack of the neighbouring 2'-oxygen with departure of the 5'-oxygen. We have previously suggested that the A730 loop is an important component of the active site of the ribozyme, and that A756 is especially important in the cleavage reaction. Functional group modification experiments reported here indicate that the base of A756 is more important than its ribose for catalysis. A number of changes to the base, including complete ablation, lead to cleavage rates that are reduced 1000-fold, while removal of the 2'-hydroxyl group from the ribose results in tenfold slower cleavage. 2-Aminopurine fluorescence experiments indicate that this 2'-hydroxyl group is important for the structure of the A730 loop. Catalytic activity is especially sensitive to changes involving the exocyclic amine of A756; by contrast, the cleavage activity is only weakly sensitive to modification at the 7-position of the purine nucleus. These results suggest that the Watson-Crick edge of the adenine base is important in ribozyme function. We sought to test the possibility of a direct role of the nucleobase in the chemistry of the cleavage reaction. Addition of imidazole base in the medium failed to restore the activity of a ribozyme from which the nucleobase of A756 was removed. However, no restoration was obtained with exogenous adenine base either, indicating that the cavity that might result from ablation of the base was closed.     

A conformational change in the "loop E-like" motif of the hairpin ribozyme is coincidental with domain docking and is essential for catalysis

The catalysis of site-specific RNA cleavage and ligation by the hairpin ribozyme requires the formation of a tertiary interaction between two independently folded internal loop domains, A and B. Within the B domain, a tertiary structure has been identified, known as the loop E motif, that has been observed in many naturally occurring RNAs. One characteristic of this motif is a partial cross-strand stack of a G residue on a U residue. In a few cases, including loop B of the hairpin ribozyme, this unusual arrangement gives rise to photoreactivity. In the hairpin, G21 and U42 can be UV cross-linked. Here we show that docking of the two domains correlates very strongly with a loss of UV reactivity of these bases. The rate of the loss of photoreactivity during folding is in close agreement with the kinetics of interdomain docking as determined by hydroxyl-radical footprinting and fluorescence resonance energy transfer (FRET). Fixing the structure of the complex in the cross-linked form results in an inability of the two domains to dock and catalyze the cleavage reaction, suggesting that the conformational change is essential for catalysis.     

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.     

Helix-length compensation studies reveal the adaptability of the VS ribozyme architecture

Compensatory mutations in RNA are generally regarded as those that maintain base pairing, and their identification forms the basis of phylogenetic predictions of RNA secondary structure. However, other types of compensatory mutations can provide higher-order structural and evolutionary information. Here, we present a helix-length compensation study for investigating structure-function relationships in RNA. The approach is demonstrated for stem-loop I and stem-loop V of the Neurospora VS ribozyme, which form a kissing-loop interaction important for substrate recognition. To rapidly characterize the substrate specificity (k(cat)/K(M)) of several substrate/ribozyme pairs, a procedure was established for simultaneous kinetic characterization of multiple substrates. Several active substrate/ribozyme pairs were identified, indicating the presence of limited substrate promiscuity for stem Ib variants and helix-length compensation between stems Ib and V. 3D models of the I/V interaction were generated that are compatible with the kinetic data. These models further illustrate the adaptability of the VS ribozyme architecture for substrate cleavage and provide global structural information on the I/V kissing-loop interaction. By exploring higher-order compensatory mutations in RNA our approach brings a deeper understanding of the adaptability of RNA structure, while opening new avenues for RNA research.     

Identification of the catalytic subdomain of the VS ribozyme and evidence for remarkable sequence tolerance in the active site loop

We show here that the ribozyme domain of the Neurospora VS ribozyme consists of separable upper and lower subdomains. Deletion analysis demonstrates that the entire upper subdomain (helices III/IV/V) is dispensable for site-specific cleavage activity, providing experimental evidence that the active site is contained within the lower subdomain and within the substrate itself. We demonstrate an important role in cleavage activity for a region of helix VI called the 730 loop. Surprisingly, several loop sequences, sizes, and structures at this position can support site-specific cleavage, suggesting that a variety of non-Watson-Crick structures, rather than a specific loop structure, in this region of the ribozyme can contribute to formation of the active site.     

Conformational heterogeneity at position U37 of an all-RNA hairpin ribozyme with implications for metal binding and the catalytic structure of the S-turn

The hairpin ribozyme is an RNA enzyme that performs site-specific phosphodiester bond cleavage between nucleotides A-1 and G+1 within its cognate substrate. Previous functional studies revealed that the minimal hairpin ribozyme exhibited "gain-of-function" cleavage properties resulting from U39C or U39 to propyl linker (C3) modifications. Furthermore, each "mutant" displayed different magnesium-dependence in its activity. To investigate the molecular basis for these gain-of-function variants, crystal structures of minimal, junctionless hairpin ribozymes were solved in native (U39), and mutant U39C and U39(C3) forms. The results revealed an overall molecular architecture comprising two docked internal loop domains folded into a wishbone shape, whose tertiary interface forms a sequestered active site. All three minimal hairpin ribozymes bound Co(NH(3))(6)(3+) at G21/A40, the E-loop/S-turn boundary. The native structure also showed that U37 of the S-turn adopts both sequestered and exposed conformations that differ by a maximum displacement of 13 A. In the sequestered form, the U37 base packs against G36, and its 2'-hydroxyl group forms a water mediated hydrogen bond to O4' of G+1. These interactions were not observed in previous four-way-junction hairpin ribozyme structures due to crystal contacts with the U1A splicing protein. Interestingly, the U39C and U39(C3) mutations shifted the equilibrium conformation of U37 into the sequestered form through formation of new hydrogen bonds in the S-turn, proximal to the essential nucleotide A38. A comparison of all three new structures has implications for the catalytically relevant conformation of the S-turn and suggests a rationale for the distinctive metal dependence of each mutant.