Efficient trans-cleavage of a stem-loop RNA substrate by a ribozyme derived from neurospora VS RNA

X-Ray Crystallography to Study Conformational Changes in a TPP Riboswitch

Conformational rearrangements are key to the function of riboswitches. These regulatory mRNA regions specifically bind to cellular metabolites using evolutionarily conserved sensing domains and modulate gene expression via adjacent downstream expression platforms, which carry gene expression signals. The regulation is achieved through the ligand-dependent formation of two alternative and mutually exclusive conformations involving the same RNA region. While X-ray crystallography cannot visualize dynamics of such dramatic conformational rearrangements, this method is pivotal to understand RNA-ligand interaction that stabilize the sensing domain and drive folding of the expression platform. X-ray crystallography can reveal local changes in RNA necessary for discriminating cognate and noncognate ligands. This chapter describes preparation of thiamine pyrophosphate riboswitch RNAs and its crystallization with different ligands, resulting in structures with local conformational changes in RNA. These structures can help to derive information on the dynamics of the RNA essential for specific binding to small molecules, with potential for using this information for developing designer riboswitch-ligand systems.

Overview of Methods for Large-Scale RNA Synthesis

In recent years, it has become clear that RNA molecules are involved in almost all vital cellular processes and pathogenesis of human disorders. The functional diversity of RNA comes from its structural richness. Although composed of only four nucleotides, RNA molecules present a plethora of secondary and tertiary structures critical for intra and intermolecular contacts with other RNAs and ligands (proteins, small metabolites, etc.). In order to fully understand RNA function it is necessary to define its spatial structure. Crystallography, nuclear magnetic resonance and cryogenic electron microscopy have demonstrated considerable success in determining the structures of biologically important RNA molecules. However, these powerful methods require large amounts of sample. Despite their limitations, chemical synthesis and in vitro transcription are usually employed to obtain milligram quantities of RNA for structural studies, delivering simple and effective methods for large-scale production of homogenous samples. The aim of this paper is to provide an overview of methods for large-scale RNA synthesis with emphasis on chemical synthesis and in vitro transcription. We also present our own results of testing the efficiency of these approaches in order to adapt the material acquisition strategy depending on the desired RNA construct.

Self-cleaving ribozymes: substrate specificity and synthetic biology applications

Various self-cleaving ribozymes appearing in nature catalyze the sequence-specific intramolecular cleavage of RNA and can be engineered to catalyze cleavage of appropriate substrates in an intermolecular fashion, thus acting as true catalysts. The mechanisms of the small, self-cleaving ribozymes have been extensively studied and reviewed previously. Self-cleaving ribozymes can possess high catalytic activity and high substrate specificity; however, substrate specificity is also engineerable within the constraints of the ribozyme structure. While these ribozymes share a common fundamental catalytic mechanism, each ribozyme family has a unique overall architecture and active site organization, indicating that several distinct structures yield this chemical activity. The multitude of catalytic structures, combined with some flexibility in substrate specificity within each family, suggests that such catalytic RNAs, taken together, could access a wide variety of substrates. Here, we give an overview of 10 classes of self-cleaving ribozymes and capture what is understood about their substrate specificity and synthetic applications. Evolution of these ribozymes in an RNA world might be characterized by the emergence of a new ribozyme family followed by rapid adaptation or diversification for specific substrates.

Self-cleaving ribozymes have become important tools of synthetic biology. Here we summarize the substrate specificity and applications of the main classes of these ribozymes.

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.

A multi-axial RNA joint with a large range of motion promotes sampling of an active ribozyme conformation

Investigating the dynamics of structural elements in functional RNAs is important to better understand their mechanism and for engineering RNAs with novel functions. Previously, we performed rational engineering studies with the Varkud satellite (VS) ribozyme and switched its specificity toward non-natural hairpin substrates through modification of a critical kissing-loop interaction (KLI). We identified functional VS ribozyme variants with surrogate KLIs (ribosomal RNA L88/L22 and human immunodeficiency virus-1 TAR/TAR*), but they displayed ∼100-fold lower cleavage activity. Here, we characterized the dynamics of KLIs to correlate dynamic properties with function and improve the activity of designer ribozymes. Using temperature replica exchange molecular dynamics, we determined that the natural KLI in the VS ribozyme supports conformational sampling of its closed and active state, whereas the surrogate KLIs display more restricted motions. Based on in vitro selection, the cleavage activity of a VS ribozyme variant with the TAR/TAR* KLI could be markedly improved by partly destabilizing the KLI but increasing conformation sampling. We formulated a mechanistic model for substrate binding in which the KLI dynamics contribute to formation of the active site. Our model supports the modular nature of RNA in which subdomain structure and dynamics contribute to define the thermodynamics and kinetics relevant to RNA function.

Isotope labeling for studying RNA by solid-state NMR spectroscopy

Nucleic acids play key roles in most biological processes, either in isolation or in complex with proteins. Often they are difficult targets for structural studies, due to their dynamic behavior and high molecular weight. Solid-state nuclear magnetic resonance spectroscopy (ssNMR) provides a unique opportunity to study large biomolecules in a non-crystalline state at atomic resolution. Application of ssNMR to RNA, however, is still at an early stage of development and presents considerable challenges due to broad resonances and poor dispersion. Isotope labeling, either as nucleotide-specific, atom-specific or segmental labeling, can resolve resonance overlaps and reduce the line width, thus allowing ssNMR studies of RNA domains as part of large biomolecules or complexes. In this review we discuss the methods for RNA production and purification as well as numerous approaches for isotope labeling of RNA. Furthermore, we give a few examples that emphasize the instrumental role of isotope labeling and ssNMR for studying RNA as part of large ribonucleoprotein complexes.

Transient compartmentalization of RNA replicators prevents extinction due to parasites

The appearance of molecular replicators (molecules that can be copied) was probably a critical step in the origin of life. However, parasitic replicators would take over and would have prevented life from taking off unless the replicators were compartmentalized in reproducing protocells. Paradoxically, control of protocell reproduction would seem to require evolved replicators. We show here that a simpler population structure, based on cycles of transient compartmentalization (TC) and mixing of RNA replicators, is sufficient to prevent takeover by parasitic mutants. TC tends to select for ensembles of replicators that replicate at a similar rate, including a diversity of parasites that could serve as a source of opportunistic functionality. Thus, TC in natural, abiological compartments could have allowed life to take hold.

Structural Basis for Substrate Helix Remodeling and Cleavage Loop Activation in the Varkud Satellite Ribozyme

The Varkud satellite (VS) ribozyme catalyzes site-specific RNA cleavage and ligation reactions. Recognition of the substrate involves a kissing loop interaction between the substrate and the catalytic domain of the ribozyme, resulting in a rearrangement of the substrate helix register into a so-called "shifted" conformation that is critical for substrate binding and activation. We report a 3.3 Å crystal structure of the complete ribozyme that reveals the active, shifted conformation of the substrate, docked into the catalytic domain of the ribozyme. Comparison to previous NMR structures of isolated, inactive substrates provides a physical description of substrate remodeling, and implicates roles for tertiary interactions in catalytic activation of the cleavage loop. Similarities to the hairpin ribozyme cleavage loop activation suggest general strategies to enhance fidelity in RNA folding and ribozyme cleavage.

Applications of NMR to structure determination of RNAs large and small

Nuclear magnetic resonance (NMR) spectroscopy is a powerful tool to investigate the structure and dynamics of RNA, because many biologically important RNAs have conformationally flexible structures, which makes them difficult to crystallize. Functional, independently folded RNA domains, range in size between simple stem-loops of as few as 10-20 nucleotides, to 50-70 nucleotides, the size of tRNA and many small ribozymes, to a few hundred nucleotides, the size of more complex RNA enzymes and of the functional domains of non-coding transcripts. In this review, we discuss new methods for sample preparation, assignment strategies and structure determination for independently folded RNA domains of up to 100 kDa in molecular weight.

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.

Crystal structure of the Varkud satellite ribozyme

Varkud Satellite (VS) ribozyme mediates rolling circle replication of a plasmid found in the Neurospora mitochondria. We report crystal structures of this ribozyme at 3.1Å resolution, revealing an intertwined dimer formed by an exchange of substrate helices. Within each protomer, an arrangement of three-way helical junctions organizes seven helices into a global fold that creates a docking site for the substrate helix of the other protomer, resulting in the formation of two active sites in trans. This mode of RNA-RNA association resembles the process of domain swapping in proteins and has implications for RNA regulation and evolution. Within each active site, adenine and guanine nucleobases abut the scissile phosphate, poised to serve direct roles in catalysis. Similarities to the active sites of the hairpin and hammerhead ribozymes highlight the functional significance of active site features, underscore the ability of RNA to access functional architectures from distant regions of sequence space, and suggest convergent evolution.

The NMR structure of the II-III-VI three-way junction from the Neurospora VS ribozyme reveals a critical tertiary interaction and provides new insights into the global ribozyme structure

As part of an effort to structurally characterize the complete Neurospora VS ribozyme, NMR solution structures of several subdomains have been previously determined, including the internal loops of domains I and VI, the I/V kissing-loop interaction and the III-IV-V junction. Here, we expand this work by determining the NMR structure of a 62-nucleotide RNA (J236) that encompasses the VS ribozyme II-III-VI three-way junction and its adjoining stems. In addition, we localize Mg(2+)-binding sites within this structure using Mn(2+)-induced paramagnetic relaxation enhancement. The NMR structure of the J236 RNA displays a family C topology with a compact core stabilized by continuous stacking of stems II and III, a cis WC/WC G•A base pair, two base triples and two Mg(2+) ions. Moreover, it reveals a remote tertiary interaction between the adenine bulges of stems II and VI. Additional NMR studies demonstrate that both this bulge-bulge interaction and Mg(2+) ions are critical for the stable folding of the II-III-VI junction. The NMR structure of the J236 RNA is consistent with biochemical studies on the complete VS ribozyme, but not with biophysical studies performed with a minimal II-III-VI junction that does not contain the II-VI bulge-bulge interaction. Together with previous NMR studies, our findings provide important new insights into the three-dimensional architecture of this unique ribozyme.

Cut and paste RNA for nuclear magnetic resonance, paramagnetic resonance enhancement, and electron paramagnetic resonance structural studies

RNA is a crucial regulator involved in most molecular processes of life. Understanding its function at the molecular level requires high-resolution structural information. However, the dynamic nature of RNA complicates structure determination because crystallization is often not possible or can result in crystal-packing artifacts resulting in nonnative structures. To study RNA and its complexes in solution, we described an approach in which large multi-domain RNA or protein-RNA complex structures can be determined at high resolution from isolated domains determined by nuclear magnetic resonance (NMR) spectroscopy, and then constructing the entire macromolecular structure using electron paramagnetic resonance (EPR) long-range distance constraints. Every step in this structure determination approach requires different types of isotope or spin-labeled RNAs. Here, we present a simple modular RNA cut and paste approach including protocols to generate (1) small isotopically labeled RNAs (<10 nucleotides) for NMR structural studies, which cannot be obtained by standard protocols, (2) large segmentally isotope and/or spin-labeled RNAs for diamagnetic NMR and paramagnetic relaxation enhancement NMR, and (3) large spin-labeled RNAs for pulse EPR spectroscopy.

RNA synthesis and purification for structural studies

RNAs play pivotal roles in the cell, ranging from catalysis (e.g., RNase P), acting as adaptor molecule (tRNA) to regulation (e.g., riboswitches). Precise understanding of its three-dimensional structures has given unprecedented insight into the molecular basis for all of these processes. Nevertheless, structural studies on RNA are still limited by the very special nature of this polymer. The most common methods for the determination of 3D RNA structures are NMR and X-ray crystallography. Both methods have their own set of requirements and give different amounts of information about the target RNA. For structural studies, the major bottleneck is usually obtaining large amounts of highly pure and homogeneously folded RNA. Especially for X-ray crystallography it can be necessary to screen a large number of variants to obtain well-ordered single crystals. In this mini-review we give an overview about strategies for the design, in vitro production, and purification of RNA for structural studies.

Structural insights into substrate recognition by the Neurospora Varkud satellite ribozyme: importance of U-turns at the kissing-loop junction

Substrate recognition by the Neurospora Varkud satellite ribozyme depends on the formation of a magnesium-dependent kissing-loop interaction between the stem-loop I (SLI) substrate and stem-loop V (SLV) of the catalytic domain. From mutagenesis studies, it has been established that this I/V kissing-loop interaction involves three Watson–Crick base pairs and is associated with a structural rearrangement of the SLI substrate that facilitates catalysis. Here, we report the NMR structural characterization of this I/V kissing-loop using isolated stem-loops. NMR studies were performed on different SLI/SLV complexes containing a common SLV and shiftable, preshifted, or double-stranded SLI variants. These studies confirm the presence of three Watson–Crick base pairs at the kissing-loop junction and provide evidence for the structural rearrangement of shiftable SLI variants upon SLV binding. NMR structure determination of an SLI/SLV complex demonstrates that both the SLI and SLV loops adopt U-turn structures, which facilitates intermolecular Watson–Crick base pairing. Several other interactions at the I/V interface, including base triples and base stacking, help create a continuously stacked structure. These NMR studies provide a structural basis to understand the stability of the I/V kissing-loop interaction and lead us to propose a kinetic model for substrate activation in the VS ribozyme.

Isotope labeling and segmental labeling of larger RNAs for NMR structural studies

NMR spectroscopy has become substantial in the elucidation of RNA structures and their complexes with other nucleic acids, proteins or small molecules. Almost half of the RNA structures deposited in the Protein Data Bank were determined by NMR spectroscopy, whereas NMR accounts for only 11% for proteins. Recent improvements in isotope labeling of RNA have strongly contributed to the high impact of NMR in RNA structure determination. In this book chapter, we review the advances in isotope labeling of RNA focusing on larger RNAs. We start by discussing several ways for the production and purification of large quantities of pure isotope labeled RNA. We continue by reviewing different strategies for selective deuteration of nucleotides. Finally, we present a comparison of several approaches for segmental isotope labeling of RNA. Selective deuteration of nucleotides in combination with segmental isotope labeling is paving the path for studying RNAs of ever increasing size.

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.

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 fast, efficient and sequence-independent method for flexible multiple segmental isotope labeling of RNA using ribozyme and RNase H cleavage

Structural information on RNA, emerging more and more as a major regulator in gene expression, dramatically lags behind compared with information on proteins. Although NMR spectroscopy has proven to be an excellent tool to solve RNA structures, it is hampered by the severe spectral resonances overlap found in RNA, limiting its use for large RNA molecules. Segmental isotope labeling of RNA or ligation of a chemically synthesized RNA containing modified nucleotides with an unmodified RNA fragment have proven to have high potential in overcoming current limitations in obtaining structural information on RNA. However, low yields, cumbersome preparations and sequence requirements have limited its broader application in structural biology. Here we present a fast and efficient approach to generate multiple segmentally labeled RNAs with virtually no sequence requirements with very high yields (up to 10-fold higher than previously reported). We expect this approach to open new avenues in structural biology of RNA.

Riboswitch structure: an internal residue mimicking the purine ligand

The adenine and guanine riboswitches regulate gene expression in response to their purine ligand. X-ray structures of the aptamer moiety of these riboswitches are characterized by a compact fold in which the ligand forms a Watson–Crick base pair with residue 65. Phylogenetic analyses revealed a strict restriction at position 39 of the aptamer that prevents the G39–C65 and A39–U65 combinations, and mutational studies indicate that aptamers with these sequence combinations are impaired for ligand binding. In order to investigate the rationale for sequence conservation at residue 39, structural characterization of the U65C mutant from Bacillus subtilis pbuE adenine riboswitch aptamer was undertaken. NMR spectroscopy and X-ray crystallography studies demonstrate that the U65C mutant adopts a compact ligand-free structure, in which G39 occupies the ligand-binding site of purine riboswitch aptamers. These studies present a remarkable example of a mutant RNA aptamer that adopts a native-like fold by means of ligand mimicking and explain why this mutant is impaired for ligand binding. Furthermore, this work provides a specific insight into how the natural sequence has evolved through selection of nucleotide identities that contribute to formation of the ligand-bound state, but ensures that the ligand-free state remains in an active conformation.

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 Mg(2+) 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.

Modulating RNA structure and catalysis: lessons from small cleaving ribozymes

RNA is a key molecule in life, and comprehending its structure/function relationships is a crucial step towards a more complete understanding of molecular biology. Even though most of the information required for their correct folding is contained in their primary sequences, we are as yet unable to accurately predict both the folding pathways and active tertiary structures of RNA species. Ribozymes are interesting molecules to study when addressing these questions because any modifications in their structures are often reflected in their catalytic properties. The recent progress in the study of the structures, the folding pathways and the modulation of the small ribozymes derived from natural, self-cleaving, RNA motifs have significantly contributed to today’s knowledge in the field.

Fluorine substituted adenosines as probes of nucleobase protonation in functional RNAs

Ionized nucleobases are required for folding, conformational switching, or catalysis in a number of functional RNAs. A common strategy to study these sites employs nucleoside analogues with perturbed pKa, but the interpretation of these studies is often complicated by the chemical modification introduced, in particular modifications that add, remove, or translocate hydrogen bonding groups in addition to perturbing pKa values. In the present study we present a series of fluorine substituted adenosine analogues that produce large changes in N1 pKa values with minimal structural perturbation. These analogues include fluorine for hydrogen substitutions in the adenine ring of adenosine and 7-deaza-adenosine with resulting N1 pKa values spanning more than 4 pKa units. To demonstrate the utility of these analogues we have conducted a nucleotide analogue interference mapping (NAIM) study on a self-ligating construct of the Varkud Satellite (VS) ribozyme. We find that each of the analogues is readily incorporated by T7 RNA polymerase and produces fully active transcripts when substituted at the majority of sites. Strong interferences are observed for three sites known to be critical for VS ribozyme function, most notably A756. Substitutions at A756 lead to slight enhancements in activity for elevated pKa analogues and dramatic interferences in activity for reduced pKa analogues, supporting the proposed catalytic role for this base. The structural similarity of these analogues, combined with their even incorporation and selective interference, provides an improved method for identifying sites of adenosine protonation in a variety of systems.

The complete VS ribozyme in solution studied by small-angle X-ray scattering

We have used small-angle X-ray solution scattering to obtain ab initio shape reconstructions of the complete VS ribozyme. The ribozyme occupies an electron density envelope with an irregular shape, into which helical sections have been fitted. The ribozyme is built around a core comprising a near-coaxial stack of three helices, organized by two three-way helical junctions. An additional three-way junction formed by an auxiliary helix directs the substrate stem-loop, juxtaposing the cleavage site with an internal loop to create the active complex. This is consistent with the current view of the probable mechanism of trans-esterification in which adenine and guanine nucleobases contributed by the interacting loops combine in general acid-base catalysis.

Role of SLV in SLI substrate recognition by the Neurospora VS ribozyme

Substrate recognition by the VS ribozyme involves a magnesium-dependent loop/loop interaction between the SLI substrate and the SLV hairpin from the catalytic domain. Recent NMR studies of SLV demonstrated that magnesium ions stabilize a U-turn loop structure and trigger a conformational change for the extruded loop residue U700, suggesting a role for U700 in SLI recognition. Here, we kinetically characterized VS ribozyme mutants to evaluate the contribution of U700 and other SLV loop residues to SLI recognition. To help interpret the kinetic data, we structurally characterized the SLV mutants by NMR spectroscopy and generated a three-dimensional model of the SLI/SLV complex by homology modeling with MC-Sym. We demonstrated that the mutation of U700 by A, C, or G does not significantly affect ribozyme activity, whereas deletion of U700 dramatically impairs this activity. The U700 backbone is likely important for SLI recognition, but does not appear to be required for either the structural integrity of the SLV loop or for direct interactions with SLI. Thus, deletion of U700 may affect other aspects of SLI recognition, such as magnesium ion binding and SLV loop dynamics. As part of our NMR studies, we developed a convenient assay based on detection of unusual (31)P and (15)N N7 chemical shifts to probe the formation of U-turn structures in RNAs. Our model of the SLI/SLV complex, which is compatible with biochemical data, leads us to propose novel interactions at the loop I/loop V interface.

Preparation of large RNA oligonucleotides with complementary isotope-labeled segments for NMR structural studies

RNA structure determination by solution NMR spectroscopy is often restricted to small RNAs (<15 kDa) owing to the problem of chemical shift degeneracy. A fruitful coupling of novel NMR techniques with segmental RNA labeling methodologies could be a powerful tool to overcome the molecular mass limitation of RNA NMR spectroscopy. Herein, we describe a time- and cost-effective procedure to prepare and purify segmentally labeled large RNAs. Two sets of RNA fragments with complementary labeling schemes, such as one fragment (13)C- and the other (15)N-labeled, are prepared by in vitro transcription from a single plasmid DNA. The desired RNA fragments are excised from the primary transcript by two cis-acting hammerhead ribozymes, yielding the required engineered ends for subsequent, complementary ligation. The resulting RNA oligonucleotides display NMR spectra with greatly reduced resonance overlap and thus enable NMR studies of smaller labeled RNA segments within the native context of a large RNA. The procedure is expected to take 3-4 weeks to implement.

Synthesis of oligo-RNAs with photocaged adenosine 2′-hydroxyls

This protocol describes a general method for the preparation of RNAs in which the reactivity or hydrogen-bonding properties of the molecule are modified in a photoreversible fashion by use of a caging strategy. A single caged adenosine, modified at the 2' position as a nitro-benzyl ether, can be incorporated into short RNAs by chemical synthesis or into long RNAs by a combination of chemical and enzymatic synthesis. The modified RNAs can be uncaged by photolysis under a variety of conditions including the use of a laser or xenon lamp, and the course of this uncaging reaction may be readily followed by HPLC or thin-layer chromatography.

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.

Extraordinary rates of transition metal ion-mediated ribozyme catalysis

In pre-steady-state, fast-quench kinetic analysis, the tertiary-stabilized hammerhead ribozyme "RzB" cleaves its substrate RNA with maximal measured k (obs) values of approximately 3000 min(-1) in 1 mM Mn(2+) and approximately 780 min(-1) in 1 mM Mg(2+) at 37 degrees C (pH 7.4). Apparent pKa for the catalytic general base is approximately 7.8-8.5, independent of the corresponding metal hydrate pKa, suggesting potential involvement of a nucleobase as general base as suggested previously from nucleobase substitution studies. The pH-rate profile is bell-shaped for Cd(2+), for which the general catalytic acid has a pKa of 7.3 +/- 0.1. Simulations of the pH-rate relation suggest a pKa for the general catalytic acid to be approximately 9.5 in Mn(2+) and >9.5 in Mg(2+). The acid pKa's follow the trend in the pKa of the hydrated metal ions but are displaced by approximately 1-2 pH units in the presence of Cd(2+) and Mn(2+). One possible explanation for this trend is direct metal ion coordination with a nucleobase, which then acts as general acid.

Influence of Helix Length on Cleavage Efficiency of Hammerhead Ribozymes

The cleavage rates of RNA substrates by trans-acting, hammerhead ribozymes are controlled by interactions between helices I and II. The interactions are affected by the relative lengths of these two double helices and by unpaired nucleotides protruding beyond helix I, either in the substrate or the ribozyme strand. Maximum cleavage rates are observed for ribozyme–substrate complexes with three or more base pairs in helix II and six or less base pairs in helix I. However, for these helix combinations, rates fall sharply with unpaired nucleotides at the end of helix I. Cleavage rates by ribozymes with one or two base pairs in helix II increase as helix I is lengthened, and are unaffected by unpaired nucleotides on the end. Since miniribozymes, with one base pair in helix II, efficiently cleave long RNA transcripts under physiological conditions, they represent the optimal design for the simple hammerheads for application in vivo.

Catalytic nucleic acid enzymes for the study and development of therapies in the central nervous system: Review Article

Nucleic acid enzymes have been used with great success for studying natural processes in the central nervous system (CNS). We first provide information on the structural and enzymatic differences of various ribozymes and DNAzymes. We then discuss how they have been used to explore new therapeutic approaches for treating diseases of the CNS. They have been tested in various systems modeling retinitis pigmentosum, proliferative vitreoretinopathy, Alzheimer's disease, and malignant brain tumors. For these models, effective targets for nucleic acid enzymes have been readily identified and the rules for selecting cleavage sites have been well established. The bulk of studies, including those from our laboratory, have emphasized their use for gliomas. With the availability of multiple excellent animal models to test glioma treatments, good progress has been made in the initial testing of nucleic acid enzymes for brain tumor therapy. However, opportunities still exist to significantly improve the delivery and efficacy of ribozymes to achieve effective treatment. The future holds significant potential for the molecular targeting and therapy of eye diseases, neurodegenerative disorders, and brain tumors with these unique treatment agents.

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.

The Varkud satellite ribozyme

The VS ribozyme is the largest nucleolytic ribozyme, for which there is no crystal structure to date. The ribozyme consists of five helical sections, organized by two three-way junctions. The global structure has been determined by solution methods, particularly FRET. The substrate stem-loop binds into a cleft formed between two helices, while making a loop-loop contact with another section of the ribozyme. The scissile phosphate makes a close contact with an internal loop (the A730 loop), the probable active site of the ribozyme. This loop contains a particularly critical nucleotide A756. Most changes to this nucleotide lead to three-orders of magnitude slower cleavage, and the Watson-Crick edge is especially important. NAIM experiments indicate that a protonated base is required at this position for the ligation reaction. A756 is thus a strong candidate for nucleobase participation in the catalytic chemistry.

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.

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.

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.

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.

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.

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.

ATP-dependent interaction of yeast U5 snRNA loop 1 with the 5' splice site

Pre-messenger RNA splicing is a two-step process by which introns are removed and exons joined together. In yeast, the U5 snRNA loop 1 interacts with the 5' exon before the first step of splicing and with the 5' and 3' exons before the second step. In vitro studies revealed that yeast U5 loop 1 is not required for the first step of splicing but is essential for holding the 5' and 3' exons for ligation during the second step. It is critical, therefore, that loop 1 contacts the 5' exon before the first step of splicing to hold this exon following cleavage from the pre-mRNA. At present it is not known how U5 loop 1 is positioned on the 5' exon prior to the first step of splicing. To address this question, we have used site-specific photoactivated crosslinking in yeast spliceosomes to investigate the interaction of U5 loop 1 with the pre-mRNA prior to the first step of splicing. We have found that the highly conserved uridines in loop 1 make ATP-dependent contacts with an approximately 8-nt region at the 5' splice site that includes the invariant GU. These interactions are dependent on functional U2 and U6 snRNAs. Our results support a model where U5 snRNA loop 1 interacts with the 5' exon in two steps during its targeting to the 5' splice site.

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.

Structure of the ribozyme substrate hairpin of Neurospora VS RNA: a close look at the cleavage site

The cleavage site of the Neurospora VS RNA ribozyme is located in a separate hairpin domain containing a hexanucleotide internal loop with an A-C mismatch and two adjacent G-A mismatches. The solution structure of the internal loop and helix la of the ribozyme substrate hairpin has been determined by nuclear magnetic resonance (NMR) spectroscopy. The 2 nt in the internal loop, flanking the cleavage site, a guanine and adenine, are involved in two sheared G.A base pairs similar to the magnesium ion-binding site of the hammerhead ribozyme. Adjacent to the tandem G.A base pairs, the adenine and cytidine, which are important for cleavage, form a noncanonical wobble A+-C base pair. The dynamic properties of the internal loop and details of the high-resolution structure support the view that the hairpin structure represents a ground state, which has to undergo a conformational change prior to cleavage. Results of chemical modification and mutagenesis data of the Neurospora VS RNA ribozyme can be explained in context with the present three-dimensional structure.