Allosteric regulation of a ribozyme activity through ligand-induced conformational change

An allosteric ribozyme has been designed using the hammerhead ribozyme as the active site and aflavin-specific RNA aptamer as a regulatory site. We constructed six variants with a series of base pairs in the linker region (stem II). Under single turnover conditions, kinetic studies were carried out in the absence and presence of flavin mononucleotide (FMN). Interestingly, FMN addition did not influence the cleavage rate of constructs with a 5-6 bp linker but stimulated the catalytic activity of those bearing a shorter linker. In particular, the apparent k cat of Rz3 increases by approximately 10-fold upon addition of saturating amounts of FMN. To determine the rate constants( K m4and k cat), the ribozyme regulated most effectively by FMN was further investigated. FMN mainly affected the k cat value, reflecting the rate limiting conformational change step of the overall cleavage reaction, depending on helix formation in stem II. Probably, FMN influences the orientation of structures necessary for the cleavage reaction through stem II formation. The result of chemical modification revealed that binding of FMN to the aptamer domain induced the helix formation in stem II required for catalytic activity. Therefore, a specific FMN-mediated allosteric interaction seems to promote a conformational alteration from an open to a closed structure in stem II. The concept of conformational modification in the allosteric effect is consistent with other allosteric enzymes, suggesting that such a conformational change is a fundamental feature of allosteric enzymes in biological systems.     

An unusual pH-independent and metal-ion-independent mechanism for hairpin ribozyme catalysis

BACKGROUND: Hairpin ribozymes (RNA enzymes) catalyze the same chemical reaction as ribonuclease A and yet RNAs do not usually have functional groups analogous to the catalytically essential histidine and lysine sidechains of protein ribonucleases. Some RNA enzymes appear to recruit metal ions to act as Lewis acids in charge stabilization and metal-bound hydroxide for general base catalysis, but it has been reported that the hairpin ribozyme functions in the presence of metal ion chelators. This led us to investigate whether the hairpin ribozyme exploits a metal-ion-independent catalytic strategy. RESULTS: Substitution of sulfur for nonbridging oxygens of the reactive phosphate of the hairpin ribozyme has small, stereospecific and metal-ion-independent effects on cleavage and ligation mediated by this ribozyme. Cobalt hexammine, an exchange-inert metal complex, supports full hairpin ribozyme activity, and the ribozyme's catalytic rate constants display only a shallow dependence on pH. CONCLUSIONS: Direct metal ion coordination to phosphate oxygens is not essential for hairpin ribozyme catalysis and metal-bound hydroxide does not serve as the general base in this catalysis. Several models might account for the unusual pH and metal ion independence: hairpin cleavage and ligation might be limited by a slow conformational change; a pH-independent or metal-cation-independent chemical step, such as breaking the 5' oxygen-phosphorus bond, might be rate determining; or finally, functional groups within the ribozyme might participate directly in catalytic chemistry. Whichever the case, the hairpin ribozyme appears to employ a unique strategy for RNA catalysis.     

Structure-activity correlation for an HDV ribozyme composed of three RNA strands

Hepatitis delta virus (HDV) RNA ribozyme system which consists of three RNA oligomer strands (substrate 8-mer; enzyme 16-mer plus 35-mer, Fig. 1) was designed. Effects of Mg2+ concentration on the pseudo first-order rate constant (kobs) of RNA cleavage reaction and on conformation of ribozyme complex were examined. The secondary structure of the complex was also analyzed by limited digestion with ribonucleases. The kobs and CD data were analyzed by curve-fitting analysis using equations derived for two-Mg2+ and three-Mg2+ ion binding models. The result revealed that a three-Mg2+ binding model can explain the Mg(2+)-concentration-dependent changes of both conformation and activity of the HDV ribozyme.     

Hammerhead ribozymes targeted to the FBN1 mRNA can discriminate a single base mismatch between ribozyme and target

Hammerhead ribozymes are catalytic RNA molecules that can act in trans, with ribozyme and substrate being two different oligoribonucleotides with regions of complementarity. Mutations in the gene for fibrillin-1 (FBN1) cause Marfan syndrome. The majority of mutations are single-base changes, many of which exert their effect via a dominant-negative mechanism. Previously we have shown that an antisense hammerhead ribozyme, targeted to the FBN1 mRNA can reduce deposition of fibrillin to the extracellular matrix of cultured fibroblasts, suggesting it may be possible to utilize ribozymes to down regulate the production of mutant protein and thus restore normal fibrillin function. This might be achieved by the mutation creating a ribozyme cleavage site that is not present in the normal allele, however this is likely to limit the number of mutations that could be targeted. Alternatively, it might be possible to target the mutant allele via the ribozyme binding arms. To determine the potential of ribozymes to preferentially target mutant FBN1 alleles via the latter approach, the effect of mismatches in helix I of a hammerhead ribozyme, on the cleavage of fibrillin (FBN1) mRNA was investigated. A single base mismatch significantly reduced ribozyme cleavage efficiency both in vitro and in vivo. The discrimination between fully-matched and mismatched ribozyme varied with the length of helix I, with the discrimination being more pronounced in ribozymes with a shorter helix. These data suggest that it should be possible to design hammerhead ribozymes that can discriminate between closely related (mutant and normal) target RNAs varying in as little as a single nucleotide, even if the mutation does not create a ribozyme cleavage site.     

Substrate specificity of delta ribozyme cleavage

The specificity of delta ribozyme cleavage was investigated using a trans-acting antigenomic delta ribozyme. Under single turnover conditions, the wild type ribozyme cleaved the 11-mer ribonucleotide substrate with a rate constant of 0.34 min-1, an apparent Km of 17.9 nM and an apparent second-order rate constant of 1.89 x 10(7) min-1 M-1. The substrate specificity of the delta ribozyme was thoroughly investigated using a collection of substrates that varied in either the length or the nucleotide sequence of their P1 stems. We observed that not only is the base pairing of the substrate and the ribozyme important to cleavage activity, but also both the identity and the combination of the nucleotide sequence in the substrates are essential for cleavage activity. We show that the nucleotides in the middle of the P1 stem are essential for substrate binding and subsequent steps in the cleavage pathway. The introduction of any mismatches at these positions resulted in a complete lack of cleavage by the wild type ribozyme. Our findings suggest that factors more complex than simple base pairing interactions, such as tertiary structure interactions, could play an important role in the substrate specificity of delta ribozyme cleavage.     

Amino acids and ammonium regulate mouse embryo development in culture

The conformation of the bulge formed between the hairpin ribozyme R derived from (-)sTRSV and noncleavable all-deoxy-substrate analogues dS was studied by photoaffinity labelling. The photolabel deoxy-6-thioinosine was inserted in place of residue G+1 or A-1, located immediately 3' and 5' to the cleavage site, respectively. Upon 335 nm irradiation both substrate analogues were linked to ribozyme at multiple sites. Formation of the R-dS complex is absolutely required for the generation of the crosslinks, since they were detected neither in the absence of Mg2+ nor upon using a ds6I containing 14-mer, unable to interact with the ribozyme. The fraction of ribozyme crosslinked at completion of the reaction increased with increasing analogue concentrations, yielding apparent KD values for the R-dS complex in the range of 5 +/- 2 microM. Multiple crosslinks between ribozyme and each one of the substrate analogues provide clear evidence for a large flexibility of the bulge region.     

Percutaneous mechanical revascularization of chronic iliac artery occlusion with "first intention" stent placement

The selective inactivation of genes, in a tissue-specific or temporally controlled manner, is now an important requirement for the analysis of nervous system development and function. Hammerhead ribozymes--catalytic RNA enzymes that specifically bind to and then cleave target RNAs--may provide a way to meet this requirement, particularly for organisms in which gene inactivation by homologous recombination is not feasible. However, ribozyme application has to some extent been hampered by limited knowledge as to the base-pairing accessibility of RNA target sites in vivo. In an attempt to circumvent this limitation, we have used a computer program based on free energy minimization to predict secondary structures for 128 RNA sequences for which corresponding ribozymes or antisense oligonucleotides have been synthesized, tested, and reported in the literature. A comparative analysis of the predicted structures of these targets with the reported efficacy of their corresponding antisense reagents has allowed us to formulate a set of rules for the rational choice of hammerhead ribozyme flanking arms and cleavage sites.     

Structure and activity of the hairpin ribozyme in its natural junction conformation: effect of metal ions

The natural form of the hairpin ribozyme consists of a four-way RNA junction of which the single-stranded loop-carrying helices are adjacent arms. The junction can be regarded as providing a framework for constructing the active ribozyme, and the rate of cleavage can be modulated by changing the conformation of the junction. We find that the junction-based form of the hairpin ribozyme is active in magnesium, calcium, or strontium ions, but not in manganese, cadmium, or sodium ions. Using fluorescence resonance energy transfer experiments, we have investigated the global structure of the ribozyme. The basic folding of the construct is based on pairwise helical stacking, so that the two loop-carrying arms are located on opposite stacked helical pairs. In the presence of magnesium, calcium, or strontium ions, the junction of the ribozyme undergoes a rotation into a distorted antiparallel geometry, creating close physical contact between the two loops. Manganese ions induce the same global folding, but no catalytic activity; this change in global conformation is therefore necessary but not sufficient for catalytic activity. Fitting the dependence of the conformation on ionic concentration to a two-state model suggests that cooperative binding of two ions is required to bring about the folding. However, further ion binding is required for cleavage activity. Cobalt hexammine ions also bring about global folding, while spermidine generates a more symmetrical form of the antiparallel structure. Cadmium ions generate a different folded form, interpreted in terms of close loop-loop association while the junction is unfolded. Sodium ions were unable to induce any folding of the ribozyme, which remained slightly parallel. These results are consistent with a folding process induced by the binding of two group IIA metal ions, distributed between the junction and the loop interface.     

Structural basis for heterogeneous kinetics: reengineering the hairpin ribozyme

The RNA cleavage reaction catalyzed by the hairpin ribozyme shows biphasic kinetics, and chase experiments show that the slow phase of the reaction results from reversible substrate binding to an inactive conformational isomer. To investigate the structural basis for the heterogeneous kinetics, we have developed an enzymatic RNA modification method that selectively traps substrate bound to the inactive conformer and allows the two forms of the ribozyme-substrate complex to be separated and analyzed by using both physical and kinetic strategies. The inactive form of the complex was trapped by the addition of T4 RNA ligase to a cleavage reaction, resulting in covalent linkage of the 5' end of the substrate to the 3' end of the ribozyme and in selective and quantitative ablation of the slow kinetic phase of the reaction. This result indicates that the inactive form of the ribozyme-substrate complex can adopt a conformation in which helices 2 and 3 are coaxially stacked, whereas the active form does not have access to this conformation, because of a sharp bend at the helical junction that presumably is stabilized by inter-domain tertiary contacts required for catalytic activity. These results were used to improve the activity of the hairpin ribozyme by designing new interfaces between the two domains, one containing a non-nucleotidic orthobenzene linkage and the other replacing the two-way junction with a three-way junction. Each of these modified ribozymes preferentially adopts the active conformation and displays improved catalytic efficiency.     

Delta ribozyme has the ability to cleave in transan mRNA

We report here the first demonstration of the cleavage of an mRNA in trans by delta ribozyme derived from the antigenomic version of the human hepatitis delta virus (HDV). We characterized potential delta ribozyme cleavage sites within HDV mRNA sequence (i.e. C/UGN6), using oligonucleotide binding shift assays and ribonuclease H hydrolysis. Ribozymes were synthesized based on the structural data and then tested for their ability to cleave the mRNA. Of the nine ribozymes examined, three specifically cleaved a derivative HDV mRNA. All three active ribozymes gave consistent indications that they cleaved single-stranded regions. Kinetic characterization of the ability of ribozymes to cleave both the full-length mRNA and either wild-type or mutant small model substrate suggests: (i) delta ribozyme has turnovers, that is to say, several mRNA molecules can be successively cleaved by one ribozyme molecule; and (ii) the substrate specificity of delta ribozyme cleavage is not restricted to C/UGN6. Specifically, substrates with a higher guanosine residue content upstream of the cleavage site (i.e. positions -4 to -2) were always cleaved more efficiently than wild-type substrate. This work shows that delta ribozyme constitutes a potential catalytic RNA for further gene-inactivation therapy.     

Hairpin ribozyme cleavage catalyzed by aminoglycoside antibiotics and the polyamine spermine in the absence of metal ions

The hairpin ribozyme is a small catalytic RNA that achieves an active configuration by docking of its two helical domains in an antiparallel fashion. Both docking and subsequent cleavage are dependent on the presence of divalent metal ions, such as magnesium, but there is no evidence to date for direct participation of such ions in the chemical cleavage step. We show that aminoglycoside antibiotics inhibit cleavage of the hairpin ribozyme in the presence of metal ions with the most effective being 5-epi-sisomicin and neomycin B. In contrast, in the absence of metal ions, a number of aminoglycoside antibiotics at 10 mM concentration promote hairpin cleavage with rates only 13-20-fold lower than the magnesium-dependent reaction. We show that neomycin B competes with metal ions by ion replacement with the postively charged amino groups of the antibiotic. In addition, we show that the polyamine spermine at 10 mM promotes efficient hairpin cleavage with rates similar to the magnesium-dependent reaction. Low concentrations of either spermine or the shorter polyamine spermidine synergize with 5 mM magnesium ions to boost cleavage rates considerably. In contrast, at 500 microM magnesium ions, 4 mM spermine, but not spermidine, boosts the cleavage rate. The results have significance both in understanding the role of ions in hairpin ribozyme cleavage and in potential therapeutic applications in mammalian cells.     

Pre-steady-state kinetics of nucleotide insertion following 8-oxo-7,8-dihydroguanine base pair mismatches by bacteriophage T7 DNA polymerase exo-

8-Oxo-7,8-dihydroguanine (8-oxoGua) can base pair with either cytosine (C) or adenine (A) when replicated by DNA polymerases. The 8-oxoGua.A mismatch is extended in preference to the 8-oxoGua.C pair. Using a model 25-mer/36-mer DNA duplex containing either guanine (Gua).C, 8-oxoGua.C, or 8-oxoGua.A base pairs at the primer terminus and A at the standing start position, we found that the pre-steady-state addition of dTTP opposite A following all three base pairs by bacteriophage T7 DNA polymerase exo- showed burst kinetics, suggesting that extension of all three base pairs is controlled by the rate of a step at or before phosphodiester bond formation. Substitution of dTTP alpha S for dTTP yielded modest thio effects of 1-6, suggesting that extension of all three pairs is limited by the rate of the conformational change prior to phosphodiester bond formation. Pre-steady-state values for kpol (maximum polymerization rate) were 120, 12, and 28 s-1, and Kd values were 2, 75, and 22 microM for insertion of dTTP following Gua.C, 8-oxoGua.C, and 8-oxoGua.A base pairs, respectively. Additional analysis of extension was provided by substitution of A in the standing start position by 2-aminopurine (2-AP), a fluorescent base analogue. Comparison of rapid-quench gel-based assays with stopped-flow fluorescence quenching assays suggested that during addition of dTTP opposite 2-AP phosphodiester bond formation was rate-limiting when 8-oxoGua.C or 8-oxoGua.A were the preceding base pairs, while conformational change was rate-limiting when Gua.C was the preceding base pair. Furthermore, the difference in apparent conformational change rates for addition of dTTP opposite 2-AP following the 8-oxoGua base pairs was greater than the differences in their phosphodiester bond formation rates, suggesting that discrimination in extension may be influenced more by conformational change rates than the rates of phosphodiester bond formation in this mispaired system.     

Ionic requirements for RNA binding, cleavage, and ligation by the hairpin ribozyme

Metal ion requirements for RNA binding, cleavage, and ligation by the hairpin ribozyme have been analyzed. RNA cleavage is observed when Mg2+, Sr2+, or Ca2+ are added to a 40 mM Tris-HCl buffer, indicating that these divalent cations were capable of supporting the reaction. No reaction was observed when other ions (Mn2+, Co2+, Cd2+, Ni2+, Ba2+, Na+, K+, Li+, NH4+, Rb+, and Cs+) were tested. In the absence of added metal ions, spermidine can induce a very slow ribozyme-catalyzed cleavage reaction that is not quenched by chelating agents (EDTA and EGTA) that are capable of quenching the metal-dependent reaction. Addition of Mn2+ to a reaction containing 2 mM spermidine increases the rate of the catalytic step by at least 100-fold. Spermidine also reduces the magnesium requirement for the reaction and strongly stimulates activity at limiting Mg2+ concentrations. There are no special ionic requirements for formation of the initial ribozyme-substrate complex--analysis of complex formation using native gels and kinetic assays shows that the ribozyme can bind substrate in 40 mM Tris-HCl buffer. Complex formation is inhibited by both Mn2+ and Co2+. Ionic requirements for the ribozyme-catalyzed ligation reaction are very similar to those for the cleavage reaction. We propose a model for catalysis by the hairpin ribozyme that is consistent with these findings. Formation of an initial ribozyme-substrate complex occurs without the obligatory involvement of divalent cations. Ions (e.g., Mg2+) can then bind to form a catalytically proficient complex, which reacts and dissociates.(ABSTRACT TRUNCATED AT 250 WORDS)     

Sequence specificity of a group II intron ribozyme: multiple mechanisms for promoting unusually high discrimination against mismatched targets

Group II intron ai5 gamma was reconstructed into a multiple-turnover ribozyme that efficiently cleaves small oligonucleotide substrates in-trans. This construct makes it possible to investigate sequence specificity, since second-order rate constants (kcat/K(m), or the specificity constant) can be obtained and compared with values for mutant substrates and with other ribozymes. The ribozyme used in this study consists of intron domains 1 and 3 connected in-cis, together with domain 5 as a separate catalytic cofactor. This ribozyme has mechanistic features similar to the first step of reverse-splicing, in which a lariat intron attacks exogenous RNA and DNA substrates, and it therefore serves as a model for the sequence specificity of group II intron mobility. To quantitatively evaluate the sequence specificity of this ribozyme, the WT kcat/Km value was compared to individual kcat/Km values for a series of mutant substrates and ribozymes containing single base changes, which were designed to create mismatches at varying positions along the two ribozyme-substrate recognition helices. These mismatches had remarkably large effects on the discrimination index (1/relative kcat/K(m)), resulting in values > 10,000 in several cases. The delta delta G++ for mismatches ranged from 2 to 6 kcal/mol depending on the mismatch and its position. The high specificity of the ribozyme is attributable to effects on duplex stabilization (1-3 kcal/mol) and unexpectedly large effects on the chemical step of reaction (0.5-2.5 kcal/mol). In addition, substrate association is accompanied by an energetic penalty that lowers the overall binding energy between ribozyme and substrate, thereby causing the off-rate to be faster than the rate of catalysis and resulting in high specificity for the cleavage of long target sequences (> or = 13 nucleotides).     

Pharmacokinetics of a synthetic, chemically modified hammerhead ribozyme against the rat cytochrome P-450 3A2 mRNA after single intravenous injections

Modulation of gene expression via nucleic acid sequence-specific intervention represents a new paradigm for drug discovery and development. Ribozymes are small RNA structures capable of cleaving RNA target molecules in a catalytic fashion. A 2'-O-allyl-modified hammerhead ribozyme designed to cleave the messenger RNA of cytochrome P-450 3A2 was administered to rats via 0.25 mg intravenous injections to investigate the disposition of this compound. The chemically modified ribozyme binds to serum albumin and can be displaced by phosphorothioate oligonucleotides. A biphasic plasma clearance with a distribution half-life of 12 min and an elimination half-life of 6.5 h was observed. A volume of distribution of 2.1 l/kg indicates perfusion into tissues well beyond the vascular system. The chemically modified ribozyme can be detected intact in the plasma up to 48 h after injection. Metabolic degradation of the chemically modified ribozyme occurs at unmodified ribonucleotides, leaving the 2'-O-allyl-modified sites intact. Recovery of intact chemically modified ribozyme was 1.9% of the administered dose at 12 h along with significant metabolites. The renal clearance of the intact ribozyme is an average 34.3 ml/h. The tissue distribution of the chemically modified ribozyme at 48 h is primarily to kidney and liver but the only detected material is a single 27-mer metabolite that has been cut in the unmodified GAAA region. The brain concentration of the prominent 27-mer metabolite is greater than that observed in the lung or spleen. Examination of tissues reveals no morphological evidence of toxicity. These data strongly support the potential utility of synthetic, 2'-O-allyl-modified hammerhead ribozymes as therapeutic agents in vivo.     

Inhibition of the hammerhead ribozyme cleavage reaction by site-specific binding of Tb

Terbium(III) [Tb(III)] was shown to inhibit the hammerhead ribozyme by competing with a single magnesium(II) ion. X-ray crystallography revealed that the Tb(III) ion binds to a site adjacent to an essential guanosine in the catalytic core of the ribozyme, approximately 10 angstroms from the cleavage site. Synthetic modifications near this binding site yielded an RNA substrate that was resistant to Tb(III) binding and capable of being cleaved, even in the presence of up to 20 micromolar Tb(III). It is suggested that the magnesium(II) ion thought to bind at this site may act as a switch, affecting the conformational changes required to achieve the transition state.     

Identification of individual nucleotides in the bacterial ribonuclease P ribozyme adjacent to the pre-tRNA cleavage site by short-range photo-cross-linking

The bacterial RNase P ribozyme is a site-specific endonuclease that catalyzes the removal of pre-tRNA leader sequences to form the 5' end of mature tRNA. While several specific interactions between enzyme and substrate that direct this process have been determined, nucleotides on the ribozyme that interact directly with functional groups at the cleavage site are not well-defined. To identify individual nucleotides in the ribozyme that are in close proximity to the pre-tRNA cleavage site, we introduced the short-range photoaffinity cross-linking reagent 6-thioguanosine (s6G) at position +1 of tRNA and position -1 in a tRNA bearing a one-nucleotide leader sequence [tRNA(G-1)] and examined cross-linking in representatives of the two structural classes of bacterial RNase P RNA (from Escherichia coli and Bacillus subtilis). These photoagent-modified tRNAs bind with similar high affinity to both ribozymes, and the substrate bearing a single s6G upstream of the cleavage (-1) site is cleaved accurately. Interestingly, s6G at position +1 of tRNA cross-links with high efficiency to homologous positions in J5/15 in both E. coli and B. subtilis RNase P RNAs, while s6G at position -1 of tRNA(G-1) cross-links to homologous nucleotides in J18/2. Both cross-links are detected over a range of ribozyme and substrate concentrations, and importantly, ribozymes cross-linked to position -1 of tRNA(G-1) accurately cleave the covalently attached substrate. These data indicate that the conserved guanosine at the 5' end of tRNA is adjacent to A248 (E. coli) of J5/15, while the base upstream of the substrate phosphate is adjacent to G332 (E. coli) of J18/2 and, along with available biochemical data, suggest that these nucleotides play a direct role in binding the substrate at the cleavage site.     

Cryoenzymology of the hammerhead ribozyme

The technique of cryoenzymology has been applied to the hammerhead ribozyme in an attempt to uncover a structural rearrangement step prior to cleavage. Several cryosolvents were tested and 40% (v/v) methanol in water was found to perturb the system only minimally. This solvent allowed the measurement of ribozyme activity between 30 and -33 degrees C. Eyring plots are linear down to -27 degrees C, but a drastic reduction in activity occurs below this temperature. However, even at extremely low temperatures, the rate is still quite pH dependent, suggesting that the chemical step rather than a structural rearrangement is still rate-limiting. The nonlinearity of the Eyring plot may be the result of a transition to a cold-denatured state or a glassed state.