Structure and function of the hairpin ribozyme

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

The hairpin ribozyme

The hairpin ribozyme is a naturally occurring RNA that catalyzes sequence-specific cleavage and ligation of RNA. It has been the subject of extensive biochemical and structural studies, perhaps the most detailed for any catalytic RNA to date. Comparison of the structures of its constituent domains free and fully assembled demonstrates that the RNA undergoes extensive structural rearrangement. This rearrangement results in a distortion of the substrate RNA that primes it for cleavage. This ribozyme is known to achieve catalysis employing exclusively RNA functional groups. Metal ions or other catalytic cofactors are not used. Current experimental evidence points to a combination of at least four mechanistic strategies by this RNA: (1) precise substrate orientation, (2) preferential transition state binding, (3) electrostatic catalysis, and (4) general acid base catalysis.     

The antisense sequence of the HIV-1 TAR stem-loop structure covalently linked to the hairpin ribozyme enhances its catalytic activity against two artificial substrates

This work is an in vitro study of the efficiency of catalytic antisense RNAs whose catalytic domain is the wild-type sequence of the hairpin ribozyme, derived from the minus strand of the tobacco ringspot virus satellite RNA. The sequence in the target RNA recognized by the antisense molecule was the stem-loop structure of the human immunodeficiency virus-1 (HIV-1) TAR region. This region was able to form a complex with its antisense RNA with a binding rate of 2 x 10(4) M(-1)s(-1). Any deletion of the antisense RNA comprising nucleotides of the stem-loop resulted in a decrease in binding rate. Sequences 3' of the stem in the sense RNA also contributed to binding. This stem-loop TAR-antisense segment, covalently linked to a hairpin ribozyme, enhanced its catalytic activity. The highest cleavage rate was obtained when the stem-loop structure was present in both ribozyme and substrate RNAs and they were complementary. Similarly, an extension at the 5'-end of the hairpin ribozyme increased the cleavage rate when its complementary sequence was present in the substrate. Inclusion of the stem-loop at the 3'-end and the extension at the 5'-end of the hairpin ribozyme abolished the positive effect of both antisense units independently. These results may help in the design of hairpin ribozymes for gene silencing.     

Mg2+-independent hairpin ribozyme catalysis in hydrated RNA films

The hairpin ribozyme catalyzes RNA cleavage in partially hydrated RNA films in the absence of added divalent cations. This reaction exhibits the characteristics associated with the RNA cleavage reaction observed under standard conditions in solution. Catalysis is a site-specific intramolecular transesterification reaction, requires the 2'-hydroxyl group of substrate nucleotide A(-1), and generates 2',3'-cyclic phosphate and 5'-hydroxyl termini. Mutations in both ribozyme and substrate abolish catalysis in hydrated films. The reaction is accelerated by cations that may enhance binding, conformational stability, and catalytic activity, and is inhibited by Tb3+. The reaction has an apparent temperature optimum of 4 degrees C. At this temperature, cleavage is slow (k(obs): 2 d(-1)) and progressive, with accumulation of cleavage products to an extent of 40%. The use of synthetic RNAs, chelators, and analysis of all reaction components by inductively coupled plasma-optical spectrophotometry (ICPOES) effectively rules out the possibility of contaminating divalent metals in the reactions. Catalysis is minimal under conditions of extreme dehydration, indicating that the reaction requires hydration of RNA by atmospheric water. Our results provide a further caution for those studying the biochemical activity of ribozymes in vitro and in cells, as unanticipated catalysis could occur during RNA manipulation and lead to misinterpretation of data.     

Intracellular ribozyme-catalyzed trans-cleavage of RNA monitored by fluorescence resonance energy transfer

Small catalytic RNAs like the hairpin ribozyme are proving to be useful intracellular tools; however, most attempts to demonstrate trans-cleavage of RNA by ribozymes in cells have been frustrated by rapid cellular degradation of the cleavage products. Here, we describe a fluorescence resonance energy transfer (FRET) assay that directly monitors cleavage of target RNA in tissue-culture cells. An oligoribonucleotide substrate was modified to inhibit cellular ribonuclease degradation without interfering with ribozyme cleavage, and donor (fluorescein) and acceptor (tetramethylrhodamine) fluorophores were introduced at positions flanking the cleavage site. In simple buffers, the intact substrate produces a strong FRET signal that is lost upon cleavage, resulting in a red-to-green shift in dominant fluorescence emission. Hairpin ribozyme and fluorescent substrate were microinjected into murine fibroblasts under conditions in which substrate cleavage can occur only inside the cell. A strong FRET signal was observed by fluorescence microscopy when substrate was injected, but rapid decay of the FRET signal occurred when an active, cognate ribozyme was introduced with the substrate. No acceleration in cleavage rates was observed in control experiments utilizing a noncleavable substrate, inactive ribozyme, or an active ribozyme with altered substrate specificity. Subsequently, the fluorescent substrates were injected into clonal cell lines that expressed cognate or noncognate ribozymes. A decrease in FRET signal was observed only when substrate was microinjected into cells expressing its cognate ribozyme. These results demonstrate trans-cleavage of RNA within mammalian cells, and provide an experimental basis for quantitative analysis of ribozyme activity and specificity within the cell.     

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.     

Efficient RNA ligation by reverse-joined hairpin ribozymes and engineering of twin ribozymes consisting of conventional and reverse-joined hairpin ribozyme units

In recent years major progress has been made in elucidating the mechanism and structure of catalytic RNA molecules, and we are now beginning to understand ribozymes well enough to turn them into useful tools. Work in our laboratory has focused on the development of twin ribozymes for site-specific RNA sequence alteration. To this end, we followed a strategy that relies on the combination of two ribozyme units into one molecule (hence dubbed twin ribozyme). Here, we present reverse-joined hairpin ribozymes that are structurally optimized and which, in addition to cleavage, catalyse efficient RNA ligation. The most efficient variant ligated its appropriate RNA substrate with a single turnover rate constant of 1.1 min(-1) and a final yield of 70%. We combined a reverse-joined hairpin ribozyme with a conventional hairpin ribozyme to create a twin ribozyme that mediates the insertion of four additional nucleotides into a predetermined position of a substrate RNA, and thus mimics, at the RNA level, the repair of a short deletion mutation; 17% of the initial substrate was converted to the insertion product.     

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

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

The protein component of bacterial ribonuclease P flickers the metal ion response to the substrate shape preference of the ribozyme

The substrate shape specificity of the Escherichia coli ribonuclease P (RNase P) ribozyme depends on the concentration of magnesium ion. At 10 mM or more, it can cleave a hairpin substrate as well as a cloverleaf pre-transfer RNA (tRNA). The results showed, however, that the holo enzyme cleaved the hairpin substrate at low concentrations of magnesium ion. Considering that the homologous E. coli tRNAs are resistant to internal cleavage by the RNase P, the phenomena suggest that this catalytic activity might take part in the removing the mis-folded RNAs in the cell.     

A cis and trans adenine-dependent hairpin ribozyme against Tpl-2 target

Ribozymes are catalytic RNAs that possess the property of cutting an RNA target via site-specific cleavage after sequence-specific recognition. Ribozymes can moreover cleave multiple substrate molecules. An increasing number of studies show that ribozymes are particularly well adapted tools against cancer, silencing or down-regulating gene expression at the RNA level. We have constructed an adenine-dependent hairpin ribozyme that cleaves the sequence at nucleotides A(225)(downward arrow)G(226) relative to the start codon of translation of the Tpl-2 kinase mRNA; this serine/threonine kinase activates the mitogen-activated protein kinase pathway implicated in cell proliferation in breast cancer. An adenine-dependent hairpin ribozyme 1 (ADHR1) was previously isolated using the Systematic Evolution of Ligands by EXponential enrichment procedure. Switch on/switch off ribozymes are particularly useful since high amounts of stable ribozyme can be produced in the absence of adenine and the ribozyme specifically cleaves its target in the presence of adenine. The ADHR1 target sequence was replaced by a sequence derived from the Tpl-2 kinase mRNA. The resulting Tpl-2 ribozyme is active in cis cleavage: kinetic studies have been performed as a function of Mg2+ concentration, adenine concentration, as well as at different pH and with various cofactors. Finally, the Tpl-2 ribozyme was shown to cleave its target in trans successfully. These findings demonstrate that a potential therapeutic ribozyme can be produced by simple sequence modification.     

Imaging of single hairpin ribozymes in solution by atomic force microscopy.

The hairpin ribozyme is a short endonucleolytic RNA motif isolated from a family of related plant virus satellite RNAs. It consists of two independently folding domains, each comprising two Watson-Crick helices flanking a conserved internal loop. The domains need to physically interact (dock) for catalysis of site-specific cleavage and ligation reactions. Using tapping-mode atomic force microscopy in aqueous buffer solution, we were able to produce high quality images of individual hairpin ribozyme molecules with extended terminal helices. Three RNA constructs with either the essential cleavage site guanosine or a detrimental adenosine substitution and with or without a 6-nt insertion to confer flexibility to the interdomain hinge show structural differences that correlate with their ability to form the active docked conformation. The observed contour lengths and shapes are consistent with previous bulk-solution measurements of the transient electric dichroism decays for the same RNA constructs. The active docked construct appears as an asymmetrically docked conformation that might be an indication of a more complicated docking event than a simple collapse around the interdomain hinge.     

Comparative analyses of hairpin substrate recognition by Escherichia coli and Bacillus subtilis ribonuclease P ribozymes

Previously, we reported that the substrate shape recognition of the Escherichia coli ribonuclease (RNase) P ribozyme depends on the concentration of magnesium ion in vitro. We additionally examined the Bacillus subtilis RNase P ribozyme and found that the B. subtilis enzyme also required high magnesium ion, above 10 mM, for cleavage of a hairpin substrate. The results of kinetic studies showed that the metal ion concentration affected both the catalysis and the affinity of the ribozymes toward a hairpin RNA substrate.     

Nucleobase catalysis in the hairpin ribozyme

RNA catalysis is important in the processing and translation of RNA molecules, yet the mechanisms of catalysis are still unclear in most cases. We have studied the role of nucleobase catalysis in the hairpin ribozyme, where the scissile phosphate is juxtaposed between guanine and adenine bases. We show that a modified ribozyme in which guanine 8 has been substituted by an imidazole base is active in both cleavage and ligation, with ligation rates 10-fold faster than cleavage. The rates of both reactions exhibit bell-shaped dependence on pH, with pK(a) values of 5.7 +/- 0.1 and 7.7 +/- 0.1 for cleavage and 6.1 +/- 0.3 and 6.9 +/- 0.3 for ligation. The data provide good evidence for general acid-base catalysis by the nucleobases.     

Structure of the Tetrahymena ribozyme: base triple sandwich and metal ion at the active site

The Tetrahymena intron is an RNA catalyst, or ribozyme. As part of its self-splicing reaction, this ribozyme catalyzes phosphoryl transfer between guanosine and a substrate RNA strand. Here we report the refined crystal structure of an active Tetrahymena ribozyme in the absence of its RNA substrate at 3.8 A resolution. The 3'-terminal guanosine (omegaG), which serves as the attacking group for RNA cleavage, forms a coplanar base triple with the G264-C311 base pair, and this base triple is sandwiched by three other base triples. In addition, a metal ion is present in the active site, contacting or positioned close to the ribose of the omegaG and five phosphates. All of these phosphates have been shown to be important for catalysis. Therefore, we provide a picture of how the ribozyme active site positions both a catalytic metal ion and the nucleophilic guanosine for catalysis prior to binding its RNA substrate.     

RNA double cleavage by a hairpin-derived twin ribozyme

The hairpin ribozyme is a small catalytic RNA that catalyses reversible sequence-specific RNA hydrolysis in trans. It consists of two domains, which interact with each other by docking in an antiparallel fashion. There is a region between the two domains acting as a flexible hinge for interdomain interactions to occur. Hairpin ribozymes with reverse-joined domains have been constructed by dissecting the domains at the hinge and rejoining them in reverse order. We have used both the conventional and reverse-joined hairpin ribozymes for the design of a hairpin-derived twin ribozyme. We show that this twin ribozyme cleaves a suitable RNA substrate at two specific sites while maintaining the target specificity of the individual monoribozymes. For characterisation of the studied ribozymes we have evaluated a quantitative assay of sequence-specific ribozyme activity using fluorescently labelled RNA substrates in conjunction with an automated DNA sequencer. This assay was found to be applicable with hairpin and hairpin-derived ribozymes. The results demonstrate the potential of hairpin ribozymes for multi-target strategies of RNA cleavage and suggest the possibility for employing hairpin-derived twin ribozymes as powerful tools for RNA manipulation in vitro and in vivo.     

Chimeric DNA-RNA hammerhead ribozymes have enhanced in vitro catalytic efficiency and increased stability in vivo.

Subsequent to the discovery that RNA can have site specific cleavage activity, there has been a great deal of interest in the design and testing of trans-acting catalytic RNAs as both surrogate genetic tools and as therapeutic agents. We have been developing catalytic RNAs or ribozymes with target specificity for HIV-1 RNA and have been exploring chemical synthesis as one method for their production. To this end, we have chemically synthesized and experimentally analyzed chimeric catalysts consisting of DNA in the non-enzymatic portions, and RNA in the enzymatic core of hammerhead type ribozymes. Substitutions of DNA for RNA in the various stems of a hammerhead ribozyme have been analyzed in vitro for kinetic efficiency. One of the chimeric ribozymes used in this study, which harbors 24 bases of DNA capable of base-pairing interactions with an HIV-1 gag target, but maintains RNA in the catalytic center and in stem-loop II, has a sixfold greater kcat value than the all RNA counterpart. This increased activity appears to be the direct result of enhanced product dissociation. Interestingly, a chimeric ribozyme in which stem-loop II (which divides the catalytic core) is comprised of DNA, exhibited a marked reduction in cleavage activity, suggesting that DNA in this region of the ribozyme can impart a negative effect on the catalytic function of the ribozyme. DNA-RNA chimeric ribozymes transfected by cationic liposomes into human T-lymphocytes are more stable than their all-RNA counterparts. Enhanced catalytic turnover and stability in the absence of a significant effect on Km make chimeric ribozymes favorable candidates for therapeutic agents.     

Competitive regulation of modular allosteric aptazymes by a small molecule and oligonucleotide effector

The hairpin ribozyme can catalyze the cleavage of RNA substrates by employing its conformational flexibility. To form a catalytic complex, the two domains A and B of the hairpin-ribozyme complex must interact with one another in a folding step called docking. We have constructed hairpin ribozyme variants harboring an aptamer sequence that can be allosterically induced by flavin mononucleotide (FMN). Domains A and B are separated by distinct bridge sequences that communicate the formation of the FMN-aptamer complex to domains A and B, facilitating their docking. In the presence of a short oligonucleotide that is complementary to the aptamer, catalytic activity of the ribozyme is completely abolished, due to the formation of an extended conformer that cannot perform catalysis. However, in the presence of the small molecule effector FMN, the inhibitory effect of the oligonucleotide is competitively neutralized and the ribozyme is activated 150-fold. We thus have established a new principle for the regulation of ribozyme catalysis in which two regulatory factors (an oligonucleotide and a small molecule) that switch the ribozyme's activity in opposite directions compete for the same binding site in the aptamer domain.     

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.     

The role of essential pyrimidines in the hairpin ribozyme-catalysed reaction.

The hairpin ribozyme is an example of a small catalytic RNA that catalyses the endonucleolytic transesterification of RNA in a highly sequence-specific manner. We have utilised chemical synthesis of RNA to create mutants of the hairpin ribozyme in which a nucleoside analogue replaces one of the essential pyrimidines in the ribozyme. Individual pyrimidine nucleosides were substituted by 4-thiouridine, O4-methyluridine, O2-methyluridine or 2-pyrimidinone-1-beta-d-riboside. To facilitate the synthesis of oligoribonucleotides containing 4-thiouridine, we have devised a new synthetic route to the key intermediate 5'-O-(4, 4'-dimethoxytrityl)-2'-O-tert-butyldimethylsilyl-S-cyanoethyl-4-thiou ridine. The ability of the modified ribozymes to support catalysis was studied and the steady-state kinetic parameters were determined for each mutant. The range of analogues used in this study allows the important functional groups of the essential pyrimidines to be identified. The results demonstrate that each pyrimidine (U41, U42 and C25) plays an important role in hairpin ribozyme catalysis. The findings are discussed in terms of the various models that have been proposed for loop B of the hairpin ribozyme.