Nucleotide sequence requirements for self-cleavage of Neurospora VS RNA

The Varkud Satellite Ribozyme: A Thirty-Year Journey through Biochemistry, Crystallography, and Computation

The discovery of catalytic RNAs or ribozymes introduced a new class of enzymes to biology. In addition to their increasingly important roles in modern life, ribozymes are key players in the RNA World hypothesis, which posits that life started or flourished with RNA supporting both genetic and enzymatic functions. Therefore, investigations into the mechanisms of ribozyme function provide an exciting opportunity to examine the foundational principles of biological catalysis. Ribozymes are also attractive model systems to investigate the relationship between structure and function in RNA. Endonucleolytic ribozymes represent the largest class of catalytic RNA, of which the Varkud satellite (VS) ribozyme is structurally the most complex. The last ribozyme to be discovered by accident, the VS ribozyme had eluded structural determination for over two decades. When we solved the first crystal structures of the VS ribozyme, an extensive body of biochemical and biophysical data had accumulated over the years with which we could evaluate the functional relevance of the structure. Conversely, the structures provided a new perspective from which to reexamine the functional data and test new hypotheses. The VS ribozyme is organized in a modular fashion where independently folding domains assemble into the active conformation of the ribozyme via three-way junctions. Structures of the VS ribozyme in complex with its substrate at different stages of activation enabled us to map the structural reorganization of the substrate that must precede catalysis. In addition to defining the global architecture of the RNA, the essential interactions between the substrate and catalytic domains, and the rearrangements in the substrate prior to catalysis, these structures provided detailed snapshots of the ribozyme active site, revealing potential catalytic interactions. High resolution structures of the active site bolstered the view that the catalytic mechanism involved nucleobase-mediated general acid-base catalysis and uncovered additional catalytic interactions between the cleavage site and catalytic residues. Informed by the crystal structures of the VS ribozyme, an integrated experimental and computational approach identified the key players and essential interactions that define the active site of the ribozyme. This confluence of biochemical, structural, and computational studies revealed the catalytic mechanism of the ribozyme at unprecedented detail. Additionally, comparative analyses of the active site structures of the VS ribozyme and other nucleic acid-based endoribonucleases revealed common architectural motifs and strikingly similar catalytic strategies. In this Account, we document the progress of VS ribozyme research starting from its discovery and extending to the elucidation of its detailed catalytic mechanism 30 years later.

The L-platform/L-scaffold framework: a blueprint for RNA-cleaving nucleic acid enzyme design

We develop an L-platform/L-scaffold framework we hypothesize may serve as a blueprint to facilitate site-specific RNA-cleaving nucleic acid enzyme design. Building on the L-platform motif originally described by Suslov and coworkers, we identify new critical scaffolding elements required to anchor a conserved general base guanine ("L-anchor") and bind functionally important metal ions at the active site ("L-pocket"). Molecular simulations, together with a broad range of experimental structural and functional data, connect the L-platform/L-scaffold elements to necessary and sufficient conditions for catalytic activity. We demonstrate that the L-platform/L-scaffold framework is common to five of the nine currently known naturally occurring ribozyme classes (Twr, HPr, VSr, HHr, Psr), and intriguingly from a design perspective, the framework also appears in an artificially engineered DNAzyme (8-17dz). The flexibility of the L-platform/L-scaffold framework is illustrated on these systems, highlighting modularity and trends in the variety of known general acid moieties that are supported. These trends give rise to two distinct catalytic paradigms, building on the classifications proposed by Wilson and coworkers and named for the implicated general base and acid. The "G + A" paradigm (Twr, HPr, VSr) exclusively utilizes nucleobase residues for chemistry, and the "G + M + " paradigm (HHr, 8-17dz, Psr) involves structuring of the "L-pocket" metal ion binding site for recruitment of a divalent metal ion that plays an active role in the chemical steps of the reaction. Finally, the modularity of the L-platform/L-scaffold framework is illustrated in the VS ribozyme where the "L-pocket" assumes the functional role of the "L-anchor" element, highlighting a distinct mechanism, but one that is functionally linked with the hammerhead ribozyme.

Insights into RNA structure and dynamics from recent NMR and X-ray studies of the Neurospora Varkud satellite ribozyme

Despite the large number of noncoding RNAs and their importance in several biological processes, our understanding of RNA structure and dynamics at atomic resolution is still very limited. Like many other RNAs, the Neurospora Varkud satellite (VS) ribozyme performs its functions through dynamic exchange of multiple conformational states. More specifically, the VS ribozyme recognizes and cleaves its stem-loop substrate via a mechanism that involves several structural transitions within its stem-loop substrate. The recent publications of high-resolution structures of the VS ribozyme, obtained by NMR spectroscopy and X-ray crystallography, offer an opportunity to integrate the data and closely examine the structural and dynamic properties of this model RNA system. Notably, these investigations provide a valuable example of the divide-and-conquer strategy for structural and dynamic characterization of a large RNA, based on NMR structures of several individual subdomains. The success of this divide-and-conquer approach reflects the modularity of RNA architecture and the great care taken in identifying the independently-folding modules. Together with previous biochemical and biophysical characterizations, the recent NMR and X-ray studies provide a coherent picture into how the VS ribozyme recognizes its stem-loop substrate. Such in-depth characterization of this RNA enzyme will serve as a model for future structural and engineering studies of dynamic RNAs and may be particularly useful in planning divide-and-conquer investigations. WIREs RNA 2017, 8:e1421. doi: 10.1002/wrna.1421 For further resources related to this article, please visit the WIREs website.

Rational engineering of the Neurospora VS ribozyme to allow substrate recognition via different kissing-loop interactions

The Neurospora VS ribozyme is a catalytic RNA that has the unique ability to specifically recognize and cleave a stem-loop substrate through formation of a highly stable kissing-loop interaction (KLI). In order to explore the engineering potential of the VS ribozyme to cleave alternate substrates, we substituted the wild-type KLI by other known KLIs using an innovative engineering method that combines rational and combinatorial approaches. A bioinformatic search of the protein data bank was initially performed to identify KLIs that are structurally similar to the one found in the VS ribozyme. Next, substrate/ribozyme (S/R) pairs that incorporate these alternative KLIs were kinetically and structurally characterized. Interestingly, several of the resulting S/R pairs allowed substrate cleavage with substantial catalytic efficiency, although with reduced activity compared to the reference S/R pair. Overall, this study describes an innovative approach for RNA engineering and establishes that the KLI of the trans VS ribozyme can be adapted to cleave other folded RNA substrates.

RNASTAR: an RNA STructural Alignment Repository that provides insight into the evolution of natural and artificial RNAs

Automated RNA alignment algorithms often fail to recapture the essential conserved sites that are critical for function. To assist in the refinement of these algorithms, we manually curated a set of 148 alignments with a total of 9600 unique sequences, in which each alignment was backed by at least one crystal or NMR structure. These alignments included both naturally and artificially selected molecules. We used principles of isostericity to improve the alignments from an average of 83%-94% isosteric base pairs. We expect that this alignment collection will assist in a wide range of benchmarking efforts and provide new insight into evolutionary principles governing change in RNA structural motifs. The improved alignments have been contributed to the Rfam database.

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.

Nondenaturing purification of co-transcriptionally folded RNA avoids common folding heterogeneity

Due to the energetic frustration of RNA folding, tertiary structured RNA is typically characterized by a rugged folding free energy landscape where deep kinetic barriers separate numerous misfolded states from one or more native states. While most in vitro studies of RNA rely on (re)folding chemically and/or enzymatically synthesized RNA in its entirety, which frequently leads into kinetic traps, nature reduces the complexity of the RNA folding problem by segmental, co-transcriptional folding starting from the 5' end. We here have developed a simplified, general, nondenaturing purification protocol for RNA to ask whether avoiding denaturation of a co-transcriptionally folded RNA can reduce commonly observed in vitro folding heterogeneity. Our protocol bypasses the need for large-scale auxiliary protein purification and expensive chromatographic equipment and involves rapid affinity capture with magnetic beads and removal of chemical heterogeneity by cleavage of the target RNA from the beads using the ligand-induced glmS ribozyme. For two disparate model systems, the Varkud satellite (VS) and hepatitis delta virus (HDV) ribozymes, we achieve >95% conformational purity within one hour of enzymatic transcription, without the need for any folding chaperones. We further demonstrate that in vitro refolding introduces severe conformational heterogeneity into the natively-purified VS ribozyme but not into the compact, double-nested pseudoknot fold of the HDV ribozyme. We conclude that conformational heterogeneity in complex RNAs can be avoided by co-transcriptional folding followed by nondenaturing purification, providing rapid access to chemically and conformationally pure RNA for biologically relevant biochemical and biophysical studies.

Single VS ribozyme molecules reveal dynamic and hierarchical folding toward catalysis

Non-coding RNAs of complex tertiary structure are involved in numerous aspects of the replication and processing of genetic information in many organisms; however, an understanding of the complex relationship between their structural dynamics and function is only slowly emerging. The Neurospora Varkud Satellite (VS) ribozyme provides a model system to address this relationship. First, it adopts a tertiary structure assembled from common elements, a kissing loop and two three-way junctions. Second, catalytic activity of the ribozyme is essential for replication of VS RNA in vivo and can be readily assayed in vitro. Here we exploit single molecule FRET to show that the VS ribozyme exhibits previously unobserved dynamic and heterogeneous hierarchical folding into an active structure. Readily reversible kissing loop formation combined with slow cleavage of the upstream substrate helix suggests a model whereby the structural dynamics of the VS ribozyme favor cleavage of the substrate downstream of the ribozyme core instead. This preference is expected to facilitate processing of the multimeric RNA replication intermediate into circular VS RNA, which is the predominant form observed in vivo.

The role of phosphate groups in the VS ribozyme-substrate interaction

The VS ribozyme trans-cleavage substrate interacts with the catalytic RNA via tertiary interactions. To study the role of phosphate groups in the ribozyme-substrate interaction, 18 modified substrates were synthesized, where an epimeric phosphorothioate replaces one of the phosphate diester linkages. Sites in the stem-loop substrate where phosphorothioate substitution impaired reaction cluster in two regions. The first site is the scissile phosphate diester linkage and nucleotides downstream of this and the second site is within the loop region. The addition of manganese ions caused recovery of the rate of reaction for phosphorothioate substitutions between A621 and A622 and U631 and C632, suggesting that these two phosphate groups may serve as ligands for two metal ions. In contrast, significant manganese rescue was not observed for the scissile phosphate diester linkage implying that electrophilic catalysis by metal ions is unlikely to contribute to VS ribozyme catalysis. In addition, an increase in the reaction rate of the unmodified VS ribozyme was observed when a mixture of magnesium and manganese ions acted as the cofactor. One possible explanation for this effect is that the cleavage reaction of the VS ribozyme is rate limited by a metal dependent docking of the substrate on the ribozyme.

The solution structure of the VS ribozyme active site loop reveals a dynamic "hot-spot"

The VS ribozyme is the largest ribozyme in its class and is also the least structurally characterized thus far. The current working model of the VS ribozyme locates the active site in stem-loop VI. The solution structure of this active site loop was determined using high resolution NMR spectroscopy. The structure reveals that the ground-state conformation of the active site differs significantly from that determined previously from chemical structure probing and mutational analysis of the ribozyme in its active conformation, which contains several looped out bases. In contrast, the base-pairing scheme found for the isolated loop contains three mismatched base-pairs: an A+-C, a G-U wobble, and a sheared G-A base-pair and no looped out bases. Dynamics observed within the active site loop provide insight into the mechanism by which the RNA can rearrange its secondary structure into an "activated" conformation prior to cleavage. These findings lend support to the idea that RNA secondary structure is more fluid than once believed and that a better understanding of structure and dynamic features of ribozymes is required to unravel the intricacies of their catalytic abilities.

Exceptionally fast self-cleavage by a Neurospora Varkud satellite ribozyme

Most of the small ribozymes, including those that have been investigated as potential therapeutic agents, appear to be rather poor catalysts. These RNAs use an internal phosphoester transfer mechanism to catalyze site-specific RNA cleavage with apparent cleavage rate constants typically <2 min(-1). We have identified variants of one of these, the Neurospora Varkud satellite ribozyme, that self-cleaves with experimentally measured apparent rate constants of up to 10 s(-1) (600 min(-1)), approximately 2 orders of magnitude faster than any previously characterized self-cleaving RNA. We describe structural features of the cleavage site loop and an adjacent helix that affect the apparent rate constants for cleavage and ligation and the equilibrium between them. These data show that the phosphoester transfer ribozymes can catalyze reactions with rate constants much larger than previously appreciated and in the range of those of protein enzymes that perform similar reactions.

NMR structure of the active conformation of the Varkud satellite ribozyme cleavage site

Substrate cleavage by the Neurospora Varkud satellite (VS) ribozyme involves a structural change in the stem-loop I substrate from an inactive to an active conformation. We have determined the NMR solution structure of a mutant stem-loop I that mimics the active conformation of the cleavage site internal loop. This structure shares many similarities, but also significant differences, with the previously determined structures of the inactive internal loop. The active internal loop displays different base-pairing interactions and forms a novel RNA fold composed exclusively of sheared G-A base pairs. From chemical-shift mapping we identified two Mg2+ binding sites in the active internal loop. One of the Mg2+ binding sites forms in the active but not the inactive conformation of the internal loop and is likely important for catalysis. Using the structure comparison program mc-search, we identified the active internal loop fold in other RNA structures. In Thermus thermophilus 16S rRNA, this RNA fold is directly involved in a long-range tertiary interaction. An analogous tertiary interaction may form between the active internal loop of the substrate and the catalytic domain of the VS ribozyme. The combination of NMR and bioinformatic approaches presented here has identified a novel RNA fold and provides insights into the structural basis of catalytic function in the Neurospora VS ribozyme.

Ribozymes: recent advances in the development of RNA tools

The discovery 20 years ago that some RNA molecules, called ribozymes, are able to catalyze chemical reactions was a breakthrough in biology. Over the last two decades numerous natural RNA motifs endowed with catalytic activity have been described. They all fit within a few well-defined types that respond to a specific RNA structure. The prototype catalytic domain of each one has been engineered to generate trans-acting ribozymes that catalyze the site-specific cleavage of other RNA molecules. On the 20th anniversary of ribozyme discovery we briefly summarize the main features of the different natural catalytic RNAs. We also describe progress towards developing strategies to ensure an efficient ribozyme-based technology, dedicating special attention to the ones aimed to achieve a new generation of therapeutic agents.

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.

Folding and catalysis by the VS ribozyme

The VS ribozyme is a 154 nt self-cleaving RNA molecule that can be divided into a trans-acting five-helix ribozyme and stem-loop substrate. The structure of the ribozyme is organised by two three-way helical junctions, the structure of which has been determined by a combination of comparative gel electrophoresis and fluorescence resonance energy transfer experiments. From this, the overall global architecture of the ribozyme has been deduced. The substrate is then thought to dock into the cleft formed between helices II and VI, where it makes a close interaction with the loop containing A730. The A730 loop is the probable active site of the ribozyme, and A756 within it is a strong candidate to play a direct role in the transesterification chemistry, possibly by general acid-base catalysis.

The contribution of 2'-hydroxyls to the cleavage activity of the Neurospora VS ribozyme

We have used nucleotide analog interference mapping and site-specific substitution to determine the effect of 2'-deoxynucleotide substitution of each nucleotide in the VS ribozyme on the self-cleavage reaction. A large number of 2'-hydroxyls (2'-OHs) that contribute to cleavage activity of the VS ribozyme were found distributed throughout the core of the ribozyme. The locations of these 2'-OHs in the context of a recently developed helical orientation model of the VS ribozyme suggest roles in multi-stem junction structure, helix packing, internal loop structure and catalysis. The functional importance of three separate 2'-OHs supports the proposal that three uridine turns contribute to local and long-range tertiary structure formation. A cluster of important 2'-OHs near the loop that is the candidate region for the active site and one very important 2'-OH in the loop that contains the cleavage site confirm the functional importance of these two loops. A cluster of important 2'-OHs lining the minor groove of stem-loop I and helix II suggests that these regions of the backbone may play an important role in positioning helices in the active structure of the ribozyme.

An efficient ligation reaction promoted by a Varkud Satellite ribozyme with extended 5'- and 3'-termini

The Neurospora Varkud Satellite (VS) RNA is capable of promoting a reversible self-cleavage reaction important for its replication pathway. In vivo the VS RNA performs a cis-cleavage reaction to generate monomeric length transcripts that are subsequently ligated to produce circular VS RNA. The predominant form of VS RNA observed in vivo is the closed circular form, though minimal VS ribozyme self-cleavage constructs lack detectable ligation activity. MFOLD analysis of the entire VS RNA sequence revealed an extended region 5' and 3' of the minimal self-cleaving region that could anneal to form a complementary helix, which we have termed helix 7. In full-length VS RNA, this helix appears to span over 40 bp of sequence and brings the 5'- and 3'-ends of the RNA into proximity for the ligation reaction. Here we report a variant of the VS ribozyme with an extended 5'- and 3'-terminus capable of forming a truncated helix 7 that promotes the ligation reaction in vitro. Through mutation and selection of this RNA we have identified a ribozyme containing two point mutations in the truncated helix 7 that ligates with >70% efficiency. These results show that an additional helical element absent in current VS ribozyme constructs is likely to be important for the ligation activity of VS RNA.

Functional equivalence of the uridine turn and the hairpin as building blocks of tertiary structure in the Neurospora VS ribozyme

Mutational, kinetic, and chemical modification experiments show that one of the three-way helical junctions in the Neurospora VS ribozyme contains a uridine turn that is important for organizing the functional three-dimensional structure of this junction. Disruption of the uridine turn disrupts the structure of the junction and decreases the self-cleavage activity of the ribozyme; however, substitution of the uridine turn with a variety of different hairpins, thereby transforming the three-way junction into a four-way junction, maintains catalytic activity. Chemical modification structure probing reveals that both the native junction and the hairpin-containing junction support the same tertiary interactions required elsewhere in the ribozyme for catalysis. These observations show that functionally equivalent three-dimensional RNA structures can be built from different secondary structure elements.

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 A730 loop is an important component of the active site of the VS ribozyme

The core of the VS ribozyme comprises five helices, that act either in cis or in trans on a stem-loop substrate to catalyse site-specific cleavage. The structure of the 2-3-6 helical junction indicates that a cleft is formed between helices II and VI that is likely to serve as a receptor for the substrate. Detailed analysis of sequence variants suggests that the base bulges of helices II and VI play an architectural role. By contrast, the identity of the nucleotides in the A730 loop is very important for ribozyme activity. The base of A756 is particularly vital, and substitution by any other nucleotide or ablation of the base leads to a major reduction in cleavage rate. However, variants of A756 bind substrate efficiently, and are not defective in global folding. These results suggest that the A730 loop is an important component of the active site of the ribozyme, and that A756 could play a key role in catalysis.

Intramolecular secondary structure rearrangement by the kissing interaction of the Neurospora VS ribozyme

Kissing interactions in RNA are formed when bases between two hairpin loops pair. Intra- and intermolecular kissing interactions are important in forming the tertiary or quaternary structure of many RNAs. Self-cleavage of the wild-type Varkud satellite (VS) ribozyme requires a kissing interaction between the hairpin loops of stem-loops I and V. In addition, self-cleavage requires a rearrangement of several base pairs at the base of stem I. We show that the kissing interaction is necessary for the secondary structure rearrangement of wild-type stem-loop I. Surprisingly, isolated stem-loop V in the absence of the rest of the ribozyme is sufficient to rearrange the secondary structure of isolated stem-loop I. In contrast to kissing interactions in other RNAs that are either confined to the loops or culminate in an extended intermolecular duplex, the VS kissing interaction causes changes in intramolecular base pairs within the target stem-loop.

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.

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.

Structure, folding and activity of the VS ribozyme: importance of the 2-3-6 helical junction

The VS nucleolytic ribozyme has a core comprising five helices organized by two three-way junctions. The ribozyme can act in trans on a hairpin-loop substrate, with which it interacts via tertiary contacts. We have determined that one of the junctions (2-3-6) undergoes two-stage ion-dependent folding into a stable conformation, and have determined the global structure of the folded junction using long-range distance restraints derived from fluorescence resonance energy transfer. A number of sequence variants in the junction are severely impaired in ribozyme cleavage, and there is good correlation between changes in activity and alteration in the folding of junction 2-3-6. These studies point to a special importance of G and A nucleotides immediately adjacent to helix II, and comparison with a similar junction of known structure indicates that this could adopt a guanine-wedge structure. We propose that the 2-3-6 junction organizes important aspects of the structure of the ribozyme to facilitate productive association with the substrate, and suggest that this results in an interaction between the substrate and the A730 loop to create the active complex.

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.

Enhancement of RNA self-cleavage by micellar catalysis

It has been reported recently that naturally occurring catalytic RNAs like hammerhead and hairpin ribozyme do not require metal ions for efficient catalysis. It seems that the folded tertiary structure of the RNA contributes more to the catalytic function than was initially recognized. We found that a highly specific self-cleavage reaction can occur within a small bulge loop of four nucleotides in a mini-substrate derived from Arabidopsis thaliana intron-containing pre-tRNA(Tyr) in the absence of metal ions. NH(4)(+) cations and non-ionic or zwitter-ionic detergents at or above their critical micelle concentration are sufficient to catalyze this reaction. The dependence on micelles for the reaction leads to the assumption that physical properties, i.e. the hydrophobic interior of a micelle, are essential for this self-cleavage reaction. We suggest that NH(4)(+)-ions play a crucial role for the entry of the negatively charged RNA into the hydrophobic interior of a detergent micelle. A change of the pattern of hydration or hydrogen bonds caused by the hydrophobic surrounding enhances the reaction by a factor of 100. These findings suggest that highly structured RNAs may shift pK(a) values towards neutrality via the local environment and thereby enhance their ability to perform general acid-base catalysis without the participation of metal ions.

Identification of phosphate groups involved in metal binding and tertiary interactions in the core of the Neurospora VS ribozyme

We have used ethylation protection experiments and modification interference using phosphorothioate nucleosides to identify phosphate groups involved in the magnesium-dependent tertiary structure and function of the VS ribozyme, a small, self-cleaving RNA. Phosphorothioate interference-rescue experiments in the presence of the thiophilic manganese ion implicate four phosphate groups in direct metal ion binding. Phosphorothioate substitution also creates a new manganese binding site that increases the cis cleavage rate of the ribozyme, possibly by disrupting an inhibitory structure. Interpreting these data in the context of a recently developed structural model shows that almost all of the important phosphate groups are located in the central core of the ribozyme. The model suggests roles for certain phosphate groups in particular steps of RNA folding and identifies a candidate region for the active site of the ribozyme.

The hammerhead, hairpin and VS ribozymes are catalytically proficient in monovalent cations alone

BACKGROUND

The catalytic activity of RNA enzymes is thought to require divalent metal ions, which are believed to facilitate RNA folding and to play a direct chemical role in the reaction.

RESULTS

We have found that the hammerhead, hairpin and VS ribozymes do not require divalent metal ions, their mimics such as [Co(NH3)6]3+, or even monovalent metal ions for efficient self-cleavage. The HDV ribozyme, however, does appear to require divalent metal ions for self-cleavage. For the hammerhead, hairpin and VS ribozymes, very high concentrations of monovalent cations support RNA-cleavage rates similar to or exceeding those observed in standard concentrations of Mg2+. Analysis of all reaction components by inductively coupled plasma-optical emission spectrophotometry (ICPOES) and the use of a variety of chelating agents effectively eliminate the possibility of contaminating divalent and trivalent metal ions in the reactions. For the hairpin ribozyme, fluorescence resonance energy transfer experiments demonstrate that high concentrations of monovalent cations support folding into the catalytically proficient tertiary structure.

CONCLUSIONS

These results directly demonstrate that metal ions are not obligatory chemical participants in the reactions catalysed by the hammerhead, hairpin, and VS ribozymes. They permit us to suggest that the folded structure of the RNA itself contributes more to the catalytic function than was previously recognised, and that the presence of a relatively dense positive charge, rather than divalent metal ions, is the general fundamental requirement. Whether this charge is required for catalysis per se or simply for RNA folding remains to be determined.

Smaller, faster ribozymes reveal the catalytic core of Neurospora VS RNA

We have investigated the structural requirements for cis-cleavage of the VS ribozyme by designing deletions, substitutions, and circular permutations based on the secondary structure model. Four of the six helices predicted in the model have been shortened, resulting in self-cleaving RNAs of only 121 to 126 nucleotides. Remarkably, the shorter ribozymes exhibit a 30 to 40-fold faster cis-cleavage rate. The increase in activity results from disrupting an inhibitory helix whose 5' side contains bases upstream of the cleavage site, and from constructing a circular permutation that tethers the helix containing the cleavage site to a shortened version of the rest of the ribozyme. The non-essential regions identified by the deletions map to the periphery of a recently proposed structure model, revealing a central ribozyme core that contains the essential structural elements required for activity of the VS ribozyme.

Identification of functional domains in the self-cleaving Neurospora VS ribozyme using damage selection

Varkud Satellite (VS) RNA contains a small self-cleaving RNA motif that is distinct in its sequence and secondary structure from the hammerhead, hairpin, and hepatitis delta virus ribozymes, which are found in other natural RNAs. We have used a base specific chemical damage selection (modification interference) assay to identify functionally important nucleotides and structural elements in VS RNA. Many modified bases interfered with self-cleavage and most of these clustered at helix junctions, certain internal loops, and in a long-range pseudoknot; these correspond to previously determined sites of magnesium-dependent protection from chemical modification. The clustering suggests that these bases are important not only for a large number of individual interactions, but because they form a smaller number of structural elements that are important for activity. Modification of bases in other single-stranded regions, which did not exhibit magnesium-dependent protection, generally did not interfere with activity, suggesting that some of these regions might be dispensable for function. Surprisingly, we found a separate cluster of bases whose modification significantly enhanced cleavage. These bases appear to form a structural element that naturally attenuates the self-cleavage reaction. In natural VS RNA this attenuator structure may affect the cleavage/ligation equilibrium by inhibiting circle re-opening, thereby helping to maintain the RNA in a circular form, which is the predominant form of VS RNA in vivo. Taken together, the results of the damage selection experiments localize the catalytic core of VS RNA to a small subset of the previously determined minimal contiguous sequence.

Recombinant mitochondrial plasmids in Neurospora composed of Varkud and a new multimeric mitochondrial plasmid

A mitochondrial plasmid, V5124, in Neurospora intermedia isolate 5124 has a deletion in its sequence relative to the highly similar Mauriceville and Varkud plasmids. These insertions in the latter plasmids are 28 bp in length and are positioned at sites that correspond to their major transcript 5' termini. The 28-bp sequence is nearly identical to a putative processing site upstream of the ND4L gene on the mitochondrial genome. The absence of this 28-bp sequence in V5124 apparently results in transcripts whose 5' termini correspond to an upstream consensus promoter sequence. Two variant forms of V5124 coexist with V5124 and have either of two similar 0.3-kb inserts positioned exactly as is the 28-bp insert in Varkud. These long inserts are chimeric, partly deriving from a newly discovered multimeric plasmid, MP. MP has significant similarity to a short region of the mitochondrial satellite plasmid VS. Another part of the 0.3-kb inserts in V5124 variants derives from the mitochondrial genome, within restriction fragment EcoRI-8. Neurospora mitochondria in many isolates can have several types of mitochondrial plasmids belonging to different homology groups. We propose that a common ancestral plasmid acquired insertions from either the mitochondrial genome or from other plasmids. The V5124 variants are the first instance of a chimeric mitochondrial plasmid in which distinct plasmids have recombined. This recombination proves that different plasmids coexist currently, or else did so at some point in their evolution, within a single mitochondrion.

A secondary-structure model for the self-cleaving region of Neurospora VS RNA

Neurospora VS RNA performs an RNA-mediated self-cleavage reaction whose products contain 2',3'-cyclic phosphate and 5'-hydroxyl termini. This reaction is similar to those of hammerhead, hairpin, and hepatitis delta virus ribozymes; however, VS RNA is not similar in sequence to these other self-cleaving motifs. Here we propose a model for the secondary structure of the self-cleaving region of VS RNA, supported by site-directed mutagenesis and chemical modification structure probing data. The secondary structure of VS RNA is distinct from those of the other naturally occurring RNA self-cleaving domains. In addition to a unique secondary structure, several Mg-dependent interactions occur during the folding of VS RNA into its active tertiary conformation.

The VS catalytic RNA replicates by reverse transcription as a satellite of a retroplasmid

The mitochondria of certain natural isolates of Neurospora contain both the Varkud plasmid, which encodes a reverse transcriptase, and a small unrelated RNA (VS RNA) that performs RNA-mediated self-cleavage and ligation reactions. Here, we show that VS RNA is transcribed from a VS plasmid DNA template by the Neurospora mitochondrial RNA polymerase using a promoter located immediately upstream of the RNA self-cleavage site that generates monomeric transcripts. VS RNA is then reverse transcribed by the Varkud plasmid reverse transcriptase to yield a full-length (-) strand cDNA, a predicted replication intermediate. Combined with previous genetic evidence, our results indicate that the VS plasmid replicates by reverse transcription as a satellite of the Varkud plasmid. This mode of replication, unprecedented for a satellite RNA, likely reflects the promiscuity of the Varkud plasmid reverse transcriptase, which does not require a specific primer to initiate cDNA synthesis. Our findings indicate how primitive reverse transcriptases with similar relaxed specificity could have facilitated the evolution of new retroelements.

Molecular evolution. Unlocking the secrets of retroviral evolution

Studies of a small circular plasmid found in the mitochondria of the fungus Neurospora crassa shed unexpected light on the evolution of RNA viruses into retroviruses.

Cis- and trans-acting ribozymes from a human pathogen, hepatitis delta virus

Hepatitis delta virus (HDV) contains two self-cleaving RNA sequences (ribozymes) that may naturally function as such in human cells. A pseudo-knot-containing structural motif, which is distinct from the well-characterized secondary structures of self-cleaving RNAs common to the plant pathogenic RNAs, is shared by the cis-acting HDV ribozymes. Definition of the sequences and secondary structures of the HDV ribozymes has facilitated the design of novel catalytic molecules, such as small RNA circles, capable of site-specific cleavage of RNA in trans.