Cleavage of oligoribonucleotides by a ribozyme derived from the hepatitis delta virus RNA sequence.

A self-cleaving RNA sequence from hepatitis delta virus was modified to produce a ribozyme capable of catalyzing the cleavage of RNA in an intermolecular (trans) reaction. The delta-derived ribozyme cleaved substrate RNA at a specific site, and the sequence specificity could be altered with mutations in the region of the ribozyme proposed to base pair with the substrate. A substrate target size of approximately 8 nucleotides in length was identified. Octanucleotides containing a single ribonucleotide immediately 5' to the cleavage site were substrates for cleavage, and cleavage activity was significantly reduced only with a guanine base at that position. A deoxyribose 5' to the cleavage site blocked the reaction. These data are consistent with a proposed secondary structure for the self-cleaving form of the hepatitis delta virus ribozyme in which a duplex forms with sequences 3' to the cleavage site, and they support a proposed mechanism in which cleavage involves attack on the phosphorus at the cleavage site by the adjacent 2'-hydroxyl group.     

Essential nucleotide sequences and secondary structure elements of the hairpin ribozyme.

In vitro selection experiments have been used to isolate active variants of the 50 nt hairpin catalytic RNA motif following randomization of individual ribozyme domains and intensive mutagenesis of the ribozyme-substrate complex. Active and inactive variants were characterized by sequencing, analysis of RNA cleavage activity in cis and in trans, and by substrate binding studies. Results precisely define base-pairing requirements for ribozyme helices 3 and 4, and identify eight essential nucleotides (G8, A9, A10, G21, A22, A23, A24 and C25) within the catalytic core of the ribozyme. Activity and substrate binding assays show that point mutations at these eight sites eliminate cleavage activity but do not significantly decrease substrate binding, demonstrating that these bases contribute to catalytic function. The mutation U39C has been isolated from different selection experiments as a second-site suppressor of the down mutants G21U and A43G. Assays of the U39C mutation in the wild-type ribozyme and in a variety of mutant backgrounds show that this variant is a general up mutation. Results from selection experiments involving populations totaling more than 10(10) variants are summarized, and consensus sequences including 16 essential nucleotides and a secondary structure model of four short helices, encompassing 18 bp for the ribozyme-substrate complex are derived.     

Self-Replication Reactions Dependent on Tertiary Interaction Motifs in an RNA Ligase Ribozyme

RNA can function both as an informational molecule and as a catalyst in living organisms. This duality is the premise of the RNA world hypothesis. However, one flaw in the hypothesis that RNA was the most essential molecule in primitive life is that no RNA self-replicating system has been found in nature. To verify whether RNA has the potential for self-replication, we constructed a new RNA self-assembling ribozyme that could have conducted an evolvable RNA self-replication reaction. The artificially designed, in vitro selected ligase ribozyme was employed as a prototype for a self-assembling ribozyme. The ribozyme is composed of two RNA fragments (form R1·Z1) that recognize another R1·Z1 molecule as their substrate and perform the high turnover ligation reaction via two RNA tertiary interaction motifs. Furthermore, the substrate recognition of R1·Z1 is tolerant of mutations, generating diversity in the corresponding RNA self-replicating network. Thus, we propose that our system implies the significance of RNA tertiary motifs in the early RNA molecular evolution of the RNA world.     

Nuclease footprint analyses of the interactions between RNase P ribozyme and a model mRNA substrate.

RNase P ribozyme cleaves an RNA helix substrate which resembles the acceptor stem and T-stem structures of its natural tRNA substrate. By linking the ribozyme covalently to a sequence (guide sequence) complementary to a target RNA, the catalytic RNA can be converted into a sequence-specific ribozyme, M1GS RNA. We have previously shown that M1GS RNA can efficiently cleave the mRNA sequence encoding thymidine kinase (TK) of herpes simplex virus 1. In this study, a footprint procedure using different nucleases was carried out to map the regions of a M1GS ribozyme that potentially interact with the TK mRNA substrate. The ribozyme regions that are protected from nuclease degradation in the presence of the TK mRNA substrate include those that interact with the acceptor stem and T-stem, the 3' terminal CCA sequence and the cleavage site of a tRNA substrate. However, some of the protected regions (e.g. P13 and P14) are unique and not among those protected in the presence of a tRNA substrate. Identification of the regions that interact with a mRNA substrate will allow us to study how M1GS RNA recognizes a mRNA substrate and facilitate the development of mRNA-cleaving ribozymes for gene-targeting applications.     

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

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

Concurrent molecular recognition of the amino acid and tRNA by a ribozyme.

We have recently reported an in vitro-evolved precursor tRNA (pre-tRNA) that is able to catalyze aminoacylation on its own 3'-hydroxyl group. This catalytic pre-tRNA is susceptible to RNase P RNA, generating the 5'-leader ribozyme and mature tRNA. The 5'-leader ribozyme is also capable of aminoacylating the tRNA in trans, thus acting as an aminoacyl-tRNA synthetase-like ribozyme (ARS-like ribozyme). Here we report its structural characterization that reveals the essential catalytic core. The ribozyme consists of three stem-loops connected by two junction regions. The chemical probing analyses show that a U-rich region (U59-U62 in J2a/3 and U67-U68 in L3) of the ribozyme is responsible for the recognition of the phenylalanine substrate. Moreover, a GGU-motif (G70-U72) of the ribozyme, adjacent to the U-rich region, forms base pairs with the tRNA 3' terminus. Our demonstration shows that simple RNA motifs can recognize both the amino acid and tRNA simultaneously, thus aminoacylating the 3' terminus of tRNA in trans.     

An RNA chaperone activity of non-specific RNA binding proteins in hammerhead ribozyme catalysis.

We have previously shown that a protein derived from the p7 nucleocapsid (NC) protein of HIV type-1 increases kcat/Km and kcat for cleavage of a cognate substrate by a hammerhead ribozyme. Here we show directly that the increase in kcat/Km arises from catalysis of the annealing of the RNA substrate to the ribozyme and the increase in kcat arises from catalysis of dissociation of the RNA products from the ribozyme. A peptide polymer derived from the consensus sequence of the C-terminal domain of the hnRNP A1 protein (A1 CTD) provides similar enhancements. Although these effects apparently arise from non-specific interactions, not all non-specific binding interactions led to these enhancements. NC and A1 CTD exert their effects by accelerating attainment of the thermodynamically most stable species throughout the ribozyme catalytic cycle. In addition, NC protein is shown to resolve a misfolded ribozyme-RNA complex that is otherwise long lived. These in vitro results suggest that non-specific RNA binding proteins such as NC and hnRNP proteins may have a biological role as RNA chaperones that prevent misfolding of RNAs and resolve RNAs that have misfolded, thereby ensuring that RNA is accessible for its biological functions.     

Analysis of the cleavage reaction of a trans-acting human hepatitis delta virus ribozyme.

The cleavage reaction catalyzed by the trans -acting genomic ribozyme of human hepatitis delta virus (HDV) was analyzed with a 13mer substrate (R13) and thio-substituted [SR13(Rp) and SR13(Sp)] substrates under single-turnover conditions. The cleavage of RNA by the trans -acting HDV ribozyme proceeded as a first order reaction. The logarithm of the rate of cleavage (kclv) increased linearly (with a slope of approximately 1) between pH 4.0 and 6.0, an indication that a single deprotonation reaction occurred. This result suggests that kclv reflects the rate of the chemical cleavage step, at least around pH 5. The amount of active complex with the SR13(Sp) substrate was almost as large as with R13 (60-80%), whereas the amount of the corresponding active complex formed with the SR13(Rp) substrate was, at most, 20% of this value (with 0.5-100 mM Mg2+ions) at pH 5.0. Nonetheless, the value of kclv for all substrates was almost the same (0.4-0.5 min-1). Neither a 'thio effect' nor a 'Mn2+rescue effect' were observed. These results suggest that Mg2+ions do not interact with pro-R oxygen directly but are essential to the formation of the active complex of the ribozyme and its substrate.     

Catalytically active geometry in the reversible circularization of 'mini-monomer' RNAs derived from the complementary strand of tobacco ringspot virus satellite RNA.

The less abundant polarity of the satellite RNA of tobacco ringspot virus, designated sTobRV(-)RNA, contains a ribozyme and its substrate. We demonstrate that the ribozyme can catalyze the ligation of substrate cleavage products and that oligoribonucleotides, termed 'mini-monomers' and containing little more than covalently attached ribozyme and substrate cleavage products, circularized spontaneously, efficiently and reversibly. The kinetics of ligation and cleavage of one such mini-monomer was consistent with a simple unimolecular reaction at some temperatures. Evidence suggests that the circular ligation product includes a 5 bp stem that is connected to a 4 bp stem by a bulge loop. Reduction of the bulge loop to one nt is expected to place the 4 and 5 bp helices in a nearly coaxial, rather than an angled or parallel, orientation. Such molecules did not circularize in a unimolecular reaction but did when incubated with second, trans-acting oligoribonucleotides that had either the original or a substituted 4 bp helix. These results suggest that a bulge loop that is too small prevents formation of geometry essential for unimolecular ligation. We suggest the term 'paperclip' to represent the arrangement of RNA strands in the region of sTobRV(-)RNA that participates in the cleavage and ligation reactions.     

Differential effects of the protein cofactor on the interactions between an RNase P ribozyme and its target mRNA substrate

RNase P from Escherichia coli is a tRNA-processing enzyme and consists of a catalytic RNA subunit (M1 RNA) and a protein component (C5 protein). M1GS, a gene-targeting ribozyme derived from M1, can cleave a herpes simplex virus 1 mRNA efficiently in vitro and inhibit its expression effectively in viral-infected cells. In this study, the effects of C5 on the interactions between a M1GS ribozyme and a model mRNA substrate were investigated by site-specific UV crosslink mapping. In the presence of the protein cofactor, the ribozyme regions crosslinked to the substrate sequence 3′ immediately to the cleavage site were similar to those found in the absence of C5. Meanwhile, some of the ribozyme regions (e.g. P12 and J11/12) that were crosslinked to the leader sequence 5′ immediately to the cleavage site in the presence of C5 were different from those regions (e.g. P3 and P4) found in the absence of the protein cofactor and were not among those that are believed to interact with a tRNA. Understanding how C5 affects the specific interactions between the ribozyme and its target mRNA may facilitate the development of gene-targeting ribozymes that function effectively in vivo, in the presence of cellular proteins.     

Relationship between 2'-hydroxyls and magnesium binding in the hammerhead RNA domain: a model for ribozyme catalysis.

The use of deoxyribonucleotide substitution in RNA (mixed RNA/DNA polymers) permits an evaluation of the role of 2'-hydroxyl groups in ribozyme catalysis. Specific deoxyribonucleotide substitution at G9 and A13 of the ribozyme decreases the catalytic activity (kcat) of the ribozyme by factors of 14 and 20, respectively. The reduction of the reaction rate concomitant with the absence of these 2'-OHs or the 2'-OH of the substrate U7 position can be partially compensated by increasing the Mg2+ concentration above 10 mM. The KMg of the all-RNA ribozyme is 5.3 mM, and the lack of either of the three influential 2'-OHs increases this value by a factor of approximately 3. These and other reaction constants for the ribozyme and the deoxy-substituted analogues have been determined by assuming a three-step mechanism. The data presented here provide the basis for the formulation of a molecular model of ribozyme activity.     

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.     

Rapid kinetic characterization of hammerhead ribozymes by real-time monitoring of fluorescence resonance energy transfer (FRET)

In established methods for analyzing ribozyme kinetics, radiolabeled RNA substrates are primarily used. Each data point requires the cumbersome sampling, gel electrophoretic separation, and quantitation of reaction products, apart from the continuous loss of substrate by radioactive decay. We have used stable, double fluorescent end-labeled RNA substrates. Fluorescence of one fluorophore is quenched by intramolecular energy transfer (FRET). Upon substrate cleavage, both dyes become separated in two RNA products and fluorescence is restored. This can be followed in real time and ribozyme reactions can be analyzed under multiple (substrate excess) and under single (ribozyme excess) turnover conditions. A detailed comparison of unlabeled, single, and double fluorescent-labeled RNAs revealed moderate kinetic differences. Results with two systems, hammerhead ribozymes in I/II (small ribozyme, large substrate) and in I/III format (large ribozyme, small substrate), are reported.     

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.     

Catalysis of RNA cleavage by the Tetrahymena thermophila ribozyme. 1. Kinetic description of the reaction of an RNA substrate complementary to the active site

A ribozyme derived from the intervening sequence (IVS) of the Tetrahymena preribosomal RNA catalyzes a site-specific endonuclease reaction: G2CCCUCUA5 + G in equilibrium with G2CCCUCU + GA5 (G = guanosine). This reaction is analogous to the first step in self-splicing of the pre-rRNA, with the product G2CCCUCU analogous to the 5'-exon. The following mechanistic conclusions have been derived from pre-steady-state and steady-state kinetic measurements at 50 degrees C and neutral pH in the presence of 10 mM Mg2+. The value of kcat/Km = 9 x 10(7) M-1 min-1 for the oligonucleotide substrate with saturating G represents rate-limiting binding. This rate constant for binding is of the order expected for formation of a RNA.RNA duplex between oligonucleotides. (Phylogenetic and mutational analyses have shown that this substrate is recognized by base pairing to a complementary sequence within the IVS). The value of kcat = 0.1 min-1 represents rate-limiting dissociation of the 5'-exon analogue, G2CCCUCU. The product GA5 dissociates first from the ribozyme because of this slow off-rate for G2CCCUCU. The similar binding of the product, G2CCCUCU, and the substrate, G2CCCUCUA5, to the 5'-exon binding site of the ribozyme, with Kd = 1-2 nM, shows that the pA5 portion of the substrate makes no net contribution to binding. Both the substrate and product bind approximately 10(4)-fold (6 kcal/mol) stronger than expected from base pairing with the 5'-exon binding site. Thus, tertiary interactions are involved in binding. Binding of G2CCCUCU and binding of G are independent. These and other data suggest that binding of the oligonucleotide substrate, G2CCCUCUA5, and binding of G are essentially random and independent. The rate constant for reaction of the ternary complex is calculated to be kc approximately equal to 350 min-1, a rate constant that is not reflected in the steady-state rate parameters with saturating G. The simplest interpretation is adopted, in which kc represents the rate of the chemical step. A site-specific endonuclease reaction catalyzed by the Tetrahymena ribozyme in the absence of G was observed; the rate of the chemical step with solvent replacing guanosine, kc(-G) = 0.7 min-1, is approximately 500-fold slower than that with saturating guanosine. The value of kcat/Km = 6 x 10(7) M-1 min-1 for this hydrolysis reaction is only slightly smaller than that with saturating guanosine, because the binding of the oligonucleotide substrate is predominantly rate-limiting in both cases.(ABSTRACT TRUNCATED AT 400 WORDS)     

Characterization in vitro and in vivo of hammerhead ribozymes directed against murine tumor necrosis factoralpha.

A hammerhead ribozyme directed against murine TNFalpha (mTNFalpha) mRNA has been constructed. In vitro studies showed that this ribozyme was released from the parent molecule by flanking cis-acting hammerhead and hairpin ribozymes. This same anti-mTNFalpha ribozyme specifically cleaved both synthetically derived substrate RNA and mTNFalpha mRNA within a pool of total cellular RNA. Endogenous delivery of this anti-mTNFalpha ribozyme via the self-cleaving cassette reduced mTNFalpha mRNA and protein levels in lipopolysaccharide (LPS)-stimulated, stably transfected murine macrophage RAW 264.7 cells. When complexed to liposomes and exogenously delivered to mouse peritoneal macrophages, the same ribozyme, with and without the cis-acting ribozymes, reduced mTNFalpha protein levels. However, an irrelevant ribozyme delivered in an identical fashion was also effective at reducing mTNFalpha protein levels. These data suggest that anti-mTNFalpha ribozymes can be constructed which efficiently cleave mTNFalpha mRNA, but irrelevant RNA/liposome complexes also effectively limit TNFalpha mRNA expression and can mimic functional ribozyme activity under in vitro conditions.     

A ribozyme with DNA in the hybridising arms displays enhanced cleavage ability.

Hammerhead ribozymes cleave RNA substrates containing the UX sequence, where X = U, C or A, embedded within sequences which are complementary to the hybridising 'arms' of the ribozyme. In this study we have replaced the RNA in the hybridising arms of the ribozyme with DNA, and the resulting ribozyme is many times more active than its precursor. In turnover-kinetics experiments with a 13-mer RNA substrate, the kcat/Km ratios are 10 and 150 microM-1min-1 for the RNA- and DNA-armed ribozymes, respectively. The effect is due mainly to differences in kcat. In independent experiments where the cleavage step is rate-limiting, the DNA-armed ribozyme cleaves the substrate with a rate constant more than 3 times greater than the all-RNA ribozyme. DNA substrates containing a ribocytidine at the cleavage site have been shown to be cleaved less efficiently than their all-RNA analogues; again however, the DNA-armed ribozyme is more effective than the all-RNA ribozyme against such DNA substrates. These results demonstrate that there are no 2'-hydroxyl groups in the arms of the ribozyme that are required for cleavage; and that the structure of the complex formed by the DNA-armed ribozyme with its substrate is more favourable for cleavage than that formed by the all-RNA ribozyme and its substrate.     

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.     

Ribozymes correctly cleave a model substrate and endogenous RNA in vivo

The alpha-sarcin domain of 28 S RNA in Xenopus oocytes is attacked by several catalytic toxins (e.g. alpha-sarcin and ricin) that abolish protein synthesis. We synthesized 6 ribozymes targeted to the alpha-sarcin domain and to an oligoribonucleotide (34-mer) that mimics this domain. Sarcin ribozyme 5 (SR5) efficiently cleaved after the CUC site in the synthetic 34-mer in vitro at 50 degrees C. SR5 also cut the same site when both substrate and ribozyme were coinjected or injected separately into oocytes at 18 degrees C. Correct cleavage in vivo was shown by isolating and sequencing the large cleavage fragment. The cleavage reaction appeared to function equally well in the oocyte nucleus and cytoplasm. SR5 also correctly cleaved endogenous 28 S RNA in oocytes, although cutting was much less efficient than with alpha-sarcin. We therefore demonstrated that a ribozyme specifically cuts both a model substrate and a cellular RNA in vivo. Earlier work showed that certain injected deoxyoligonucleotides complementary to the alpha-sarcin region abolish protein synthesis. Oocyte protein synthesis was also abolished by an SR5 containing a single G----U substitution that inactivates RNA catalysis, indicating that SR5's translational suppression was perhaps due to antisense function rather than ribozyme cleavage.     

Recognition of the 5' leader of pre-tRNA substrates by the active site of ribonuclease P

The bacterial tRNA processing enzyme ribonuclease P (RNase P) is a ribonucleoprotein composed of a approximately 400 nucleotide RNA and a smaller protein subunit. It has been established that RNase P RNA contacts the mature tRNA portion of pre-tRNA substrates, whereas RNase P protein interacts with the 5' leader sequence. However, specific interactions with substrate nucleotides flanking the cleavage site have not previously been defined. Here we provide evidence for an interaction between a conserved adenosine, A248 in the Escherichia coli ribozyme, and N(-1), the substrate nucleotide immediately 5' of the cleavage site. Specifically, mutations at A248 result in miscleavage of substrates containing a 2' deoxy modification at N(-1). Compensatory mutations at N(-1) restore correct cleavage in both the RNA-alone and holoenzyme reactions, and also rescue defects in binding thermodynamics caused by A248 mutation. Analysis of pre-tRNA leader sequences in Bacteria and Archaea reveals a conserved preference for U at N(-1), suggesting that an interaction between A248 and N(-1) is common among RNase P enzymes. These results provide the first direct evidence for RNase P RNA interactions with the substrate cleavage site, and show that RNA and protein cooperate in leader sequence recognition.