Tertiary structure stabilization promotes hairpin ribozyme ligation.

The hairpin ribozyme catalyzes a reversible RNA cleavage reaction that participates in processing intermediates of viral satellite RNA replication in plants. A minimal hairpin ribozyme consists of two helix-loop-helix segments. These segments associate noncoaxially in the active folded structure in a way that brings catalytically important loop nucleotides into close proximity. The hairpin ribozyme in the satellite RNA of Tobacco Ringspot Virus assembles in the context of a four-way helical junction. Recent physical characterization of hairpin ribozyme structures using fluorescence resonance energy transfer demonstrated enhanced stability of the folded structure in the context of a four-way helical junction compared to minimal hairpin ribozyme variants. Analysis of the functional consequences of this modification of the helical junction has revealed two changes in the hairpin ribozyme kinetic mechanism. First, ribozymes with a four-way helical junction bind 3' cleavage products with much higher affinity than minimal hairpin ribozymes, evidence that tertiary interactions within the folded structure contribute to product binding energy. Second, the balance between ligation and cleavage shifts in favor of ligation. The enhanced ligation activity of hairpin ribozymes that contain a four-way helical junction supports the notion that tertiary structure stability is a major determinant of the hairpin ribozyme proficiency as a ligase and illustrates the link between RNA structure and biological function.     

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.     

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.     

Selection of targets and the most efficient hairpin ribozymes for inactivation of mRNAs using a self-cleaving RNA library

The identification of proficient target sites within long RNA molecules, as well as the most efficient ribozymes for each, is a major concern for the use of ribozymes as gene suppressers. In vitro selection methods using combinatorial libraries are powerful tools for the rapid elucidation of interactions between macromolecules, and have been successfully used for different types of ribozyme study. This paper describes a new method for selecting effective target sites within long RNAs using a combinatorial library of self-cleaving hairpin ribozymes that includes all possible specificities. The method also allows the identification of the most appropriate ribozyme for each identified site. Searching for targets within the lacZ gene with this strategy yielded a clearly accessible site. Sequence analysis of ribozymes identified two variants as the most appropriate for this site. Both selected ribozymes showed significant inhibitory activity in the cell milieu.     

Design of hairpin ribozyme variants with improved activity for poorly processed substrates

Application of ribozymes for knockdown of RNA targets requires the identification of suitable target sites according to the consensus sequence. For the hairpin ribozyme, this was originally defined as Y?2 N?1 *G+1 U+2 Y+3 B+?, with Y = U or C, and B = U, C or G, and C being the preferred nucleobase at positions -2 and +4. In the context of development of ribozymes for destruction of an oncogenic mRNA, we have designed ribozyme variants that efficiently process RNA substrates at U?2 G?1 *G+1 U+2 A+3 A+? sites. Substrates with G?1 *G+1 U+2 A+3 sites were previously shown to be processed by the wild-type hairpin ribozyme. However, our study demonstrates that, in the specific sequence context of the substrate studied herein, compensatory base changes in the ribozyme improve activity for cleavage (eight-fold) and ligation (100-fold). In particular, we show that A+3 and A+? are well tolerated if compensatory mutations are made at positions 6 and 7 of the ribozyme strand. Adenine at position +4 is neutralized by G? →U, owing to restoration of a Watson-Crick base pair in helix 1. In this ribozyme-substrate complex, adenine at position +3 is also tolerated, with a slightly decreased cleavage rate. Additional substitution of A? with uracil doubled the cleavage rate and restored ligation, which was lost in variants with A?, C? and G?. The ability to cleave, in conjunction with the inability to ligate RNA, makes these ribozyme variants particularly suitable candidates for RNA destruction.     

Combinatorial Screening and Intracellular Antiviral Activity of Hairpin Ribozymes Directed against Hepatitis B Virus

A combinatorial screening method has been used to identify hairpin ribozymes that inhibit hepatitis B virus (HBV) replication in transfected human hepatocellular carcinoma (HCC) cells. A hairpin ribozyme library (5 x 10(5) variants) containing a randomized substrate-binding domain was used to identify accessible target sites within 3.3 kb of full-length in vitro-transcribed HBV pregenomic RNA. Forty potential target sites were found within the HBV pregenomic RNA, and 17 sites conserved in all four subtypes of HBV were chosen for intracellular inhibition experiments. Polymerase II and III promoter expression constructs for corresponding hairpin ribozymes were generated and cotransfected into HCC cells together with a replication-competent dimer of HBV DNA. Four ribozymes inhibited HBV replication by 80, 69, 66, and 49%, respectively, while catalytically inactive mutant forms of these ribozymes affected HBV replication by 36, 28, 0, and 0%. These findings indicate that the inhibitory effects on HBV replication were largely mediated by the catalytic activity of the ribozymes. In conclusion, we have identified catalytically active RNAs by combinatorial screening that mediate intracellular antiviral effects on HBV.     

Suppression of BCR-ABL mRNA by various ribozymes in HeLa cells.

Ribozymes are RNA molecules with enzymatic activity that can cleave target RNA molecules in a sequence specific manner. To date, various types of ribozyme have been constructed to cleave other RNAs and such trans-acting ribozymes include hammerhead, hairpin and HDV ribozymes. External guide sequence (EGS) can also induce the suppression of a gene-expression by taking advantage of cellular RNase P. Here we compared the activities of various functional RNA cleavers both in vitro and in vivo. The first purpose of this comparison was intended to determine the best ribozyme motif with the highest activity in cells. The second purpose is to know the correlation between the activities of ribozymes in vitro and in vivo. Our results indicated that the intrinsic cleavage activity of ribozymes is not the sole determinant that is responsible for the activity of a ribozyme in cultured cells.     

In vitro selection of adenine-dependent hairpin ribozymes

Adenine-dependent hairpin ribozymes were isolated by in vitro selection from a degenerated hairpin ribozyme population. Two new adenine-dependent ribozymes catalyze their own reversible cleavage in the presence of free adenine. Both aptamers have Mg(2+) requirements for adenine-assisted cleavage similar to the wild-type hairpin ribozyme. Cleavage kinetics studies in the presence of various other small molecules were compared. The data suggest that adenine does not induce RNA self-cleavage in the same manner for both aptamers. In addition, investigations of pH effects on catalytic rates show that both adenine-dependent aptamers are more active in basic conditions, suggesting that they use new acid/base catalytic strategies in which adenine could be involved directly. The discovery of hairpin ribozymes dependent on adenine for their reversible self-cleavage presents considerable biochemical and evolutionary interests because we show that RNA is able to use exogenous reactive molecules to enhance its own catalytic activity. Such a mechanism may have been a means by which the ribozymes of the RNA world enlarged their chemical repertoire.     

Ribozymes in the age of molecular therapeutics

Ribozymes are RNA molecules capable of sequence-specific cleavage of other RNA molecules. Since the discovery of the first group I intron ribozyme in 1982, new classes of ribozymes, each with their own unique reaction, target site specifications, and potential applications, have been identified. These include hammerhead, hairpin, hepatitis delta, varkud satellite, groups I and II intron, and RNase P ribozymes, as well as the ribosome and spliceosome. Meanwhile, ribozyme engineering has enabled the in vitro selection of synthetic ribozymes with unique properties. This, along with advances in ribozyme delivery methods and expression systems, has led to an explosion in the potential therapeutic applications of ribozymes, whether for anti-cancer or anti-viral therapy, or for gene repair.     

A chemo-genetic approach for the study of nucleobase participation in nucleolytic ribozymes

A novel chemo-genetic approach for the analysis of general acid-base catalysis by nucleobases in ribozymes is reviewed. This involves substitution of a C-nucleoside with imidazole in place of a natural nucleobase. The Varkud satellite ribozyme in which the nucleobase at the critical 756 position has been replaced by imidazole is active in both cleavage and ligation reactions. Similarly, a modified hairpin ribozyme with the nucleobase at position 8 substituted by imidazole is active in cleavage and ligation reactions. Although the rates are lower than those of the natural ribozymes, they are significantly greater than other variants at these positions. The dependence of the hairpin ribozyme reaction rates on pH has been studied. Both cleavage and ligation reactions display a bell-shaped pH dependence, consistent with general acid-base catalysis involving the nucleotide at position 8.     

Mechanistic considerations for general acid-base catalysis by RNA: revisiting the mechanism of the hairpin ribozyme

Several small ribozymes carry out self-cleavage at a specific phosphodiester bond to yield 2',3'-cyclic phosphate and 5'-hydroxyl termini. Prior mechanistic and structural studies on the HDV ribozymes led to the proposal that the pK(a) of C75 is shifted toward neutrality, making it an effective general acid. Recent mechanistic studies on the hairpin ribozyme have led to models in which protonation of G8 is required for phosphodiester cleavage, either for general acid catalysis or for electrostatic stabilization. Inspection of recent crystal structures of the hairpin ribozyme, including a complex with a vanadate transition state mimic, suggests an alternative model involving general acid-base catalysis with G8 serving as the general base and A38 as the general acid. This model is consistent with the literature on the hairpin ribozyme, including pH-rate profiles of wild-type and mutant ribozymes and solvent isotope effects. General mechanistic considerations for RNA catalysis suggest that the penalty for having general acids and bases with pK(a)s removed from neutrality is not as severe as expected. These considerations suggest that general acid-base catalysis may be a common mechanistic strategy of RNA enzymes.     

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.     

Sequence elements outside the catalytic core of natural hairpin ribozymes modulate the reactions differentially

Abstract Hairpin ribozymes occur naturally only in the satellite RNAs of tobacco ringspot virus (TRsV), chicory yellow mottle virus (CYMoV) and arabis mosaic virus (ArMV). The catalytic centre of the predominantly studied sTRsV hairpin ribozyme, and of sArMV is organised around a four-way helical junction. We show here that sCYMoV features a five-way helical junction instead. Mutational analysis indicates that the fifth stem does not influence kinetic parameters of the sCYMoV hairpin ribozyme in vitro reactions, and therefore seems an appendix to that junction in the other ribozymes. We report further that all three ribozymes feature a three-way helical junction outside the catalytic core in stem A, with Watson-Crick complementarity to loop nucleotides in stem B. Kinetic analyses of cleavage and ligation reactions of several variants of the sTRsV and sCYMoV hairpin ribozymes in vitro show that the presence of this junction interferes with their reactions, particularly the ligation. We provide evidence that this is not due to a presumed interaction of the afore-mentioned elements in stems A and B. The evolutionary survival of this cis-inhibiting element seems rather to be caused by the coincidence of its position with that of the hammerhead ribozyme in the other RNA polarity.     

Sensing complex regulatory networks by conformationally controlled hairpin ribozymes

The hairpin ribozyme catalyses RNA cleavage by a mechanism utilizing its conformational flexibility during the docking of two independently folded internal loop domains A and B. Based on this mechanism, we designed hairpin ribozyme variants that can be induced or repressed by external effector oligonucleotides influencing the docking process. We incorporated a third domain C to assimilate alternate stable RNA motifs such as a pseudo-half-knot or an internal stem-loop structure. Small sequence changes in domain C allowed targeted switching of ribozyme activity: the same effector oligonucleotide can either serve as an inducer or repressor. The ribozymes were applied to trp leader mRNA, the RNA sequence tightly bound by l-tryptophan-activated trp-RNA-binding attenuation protein (TRAP). When domain C is complementary to this mRNA, ribozyme activity can be altered by annealing trp leader mRNA, then specifically reverted by its TRAP/tryptophan-mediated sequestration. This approach allows to precisely sense the activity status of a protein controlled by its metabolite molecule.     

Structure and function of regulatory RNA elements: Ribozymes that regulate gene expression

Since their discovery in the 1980s, it has gradually become apparent that there are several functional classes of naturally occurring ribozymes. These include ribozymes that mediate RNA splicing (the Group I and Group II introns, and possibly the RNA components of the spliceosome), RNA processing ribozymes (RNase P, which cleaves precursor tRNAs and other structural RNA precursors), the peptidyl transferase center of the ribosome, and small, self-cleaving genomic ribozymes (including the hammerhead, hairpin, HDV and VS ribozymes). The most recently discovered functional class of ribozymes include those that are embedded in the untranslated regions of mature mRNAs that regulate the gene's translational expression. These include the prokaryotic glmS ribozyme, a bacterial riboswitch, and a variant of the hammerhead ribozyme, which has been found embedded in mammalian mRNAs. With the discovery of a mammalian riboswitch ribozyme, the question of how an embedded hammerhead ribozyme's switching mechanism works becomes a compelling question. Recent structural results suggest several possibilities.     

The origin of the genetic code: amino acids as cofactors in an RNA world.

The genetic code, understood as the specific assignment of amino acids to nucleotide triplets, might have preceded the existence of translation. Amino acids became utilized as cofactors by ribozymes in a metabolically complex RNA world. Specific charging ribozymes linked amino acids to corresponding RNA handles, which could basepair with different ribozymes, via an anticodon hairpin, and so deliver the cofactor to the ribozyme. Growing of the 'handle' into a presumptive tRNA was possible while function was retained and modified throughout. A stereochemical relation between some amino acids and cognate anticodons/codons is likely to have been important in the earliest assignments. Recent experimental findings, including selection for ribozymes catalyzing peptide-bond formation and those utilizing an amino acid cofactor, hold promise that scenarios of this major transition can be tested.     

Comparative kinetic analysis of structural variants of the hairpin ribozyme reveals further potential to optimize its catalytic performance.

The hairpin ribozyme derived from the minus strand of the satellite RNA associated with the tobacco ringspot virus is one of the small catalytic RNAs that has been shown to catalyze trans-cleavage reactions. There is much interest in designing hairpin ribozymes with improved catalytic activity for the development of new therapeutic agents. Extensive mutagenesis studies as well as in vitro selection experiments have been performed to define the structure and optimize its catalytic activity. This communication describes a comparative kinetic analysis of four structural variants, introduced, either alone, or in combination, into the hairpin ribozyme. We have shown that extension of the helix 2 from 4 to 6 bp resulted in a significant decrease in K(M). Furthermore, the combination of this extension with the simultaneous stabilization of helix 4, led to a more than two-fold increase in the catalytic efficiency. This variant showed a 15-fold reduction in the K(M) value in respect to the wild-type ribozyme. This could be of great interest for the in vivo application of this catalytic motif. The 9-bp enlargement of helix 4 implied about a three-fold improvement in the catalytic activity. Similarly, the U39C substitution brought up the efficiency of the ribozyme slightly. However, introduction of nucleotides at the hinge region between A and B domains reduced the catalytic activity. This reduction was gradually increased with the number of nucleotides. Results obtained with variants carrying more than one modification always agreed with the ones obtained from each single variant.     

Ribozymes of the hepatitis delta virus: recent findings on their structure, mechanism of catalysis and possible applications.

Although the delta ribozymes have been studied for more than ten years the most important information concerning their structure and mechanism of catalysis were only obtained very recently. The crystal structure of the genomic delta ribozyme turns out to be an excellent example of the extraordinary properties of RNA molecules to fold into uniquely compact structures. Details of the X-ray structure have greatly stimulated further studies on the folding of the ribozymes into functionally active molecules as well as on the mechanism of RNA catalysis. The ability of the delta ribozymes to carry out general acid-base catalysis by nucleotide side chains has been assumed in two proposed mechanisms of self-cleavage. Recently, considerable progress has been also made in characterizing the catalytic properties of trans-acting ribozyme variants that are potentially attractive tools in the strategy of directed RNA degradation.