Interactions of the antibiotics neomycin B and chlortetracycline with the hammerhead ribozyme as studied by Zn2+-dependent RNA cleavage

We have investigated the interactions of two antibiotics, neomycin B and chlortetracycline (CTC), with the hammerhead ribozyme using two Zn(2+) cleavage sites at U4 and A9 in its catalytic core. CTC-dependent inhibition of Zn(2+) cleavage was observed in all cases. In contrast, we unexpectedly observed acceleration of A9 cleavage by neomycin under low ionic strength conditions similar to those used to study inhibition of hammerhead substrate cleavage by this antibiotic. This result provides evidence that the inhibitory mechanism of neomycin does not include competition with the metal ion bound to the A9/G10.1 metal-ion binding site, as previously proposed. Under high ionic strength conditions, optimized for Zn(2+)-dependent cleavage, we observed neomycin-dependent inhibition of cleavage at both A9 and U4. The ability of neomycin to both inhibit and accelerate Zn(2+) cleavage suggests that there is either more than one neomycin binding site or multiple binding modes at a single site in the hammerhead ribozyme. Furthermore, the accessibilities and/or affinities of disparate neomycin binding sites or binding modes are dependent on the ionic strength and the pH of the medium.     

Kinetics of intermolecular cleavage by hammerhead ribozymes.

The hammerhead catalytic RNA effects cleavage of the phosphodiester backbone of RNA through a transesterification mechanism that generates products with 2'-3'-cyclic phosphate and 5'-hydroxyl termini. A minimal kinetic mechanism for the intermolecular hammerhead cleavage reaction includes substrate binding, cleavage, and product release. Elemental rate constants for these steps were measured with six hammerhead sequences. Changes in substrate length and sequence had little effect on the rate of the cleavage step, but dramatic differences were observed in the substrate dissociation and product release steps that require helix-coil transitions. Rates of substrate binding and product dissociation correlated well with predictions based on the behavior of simple RNA duplexes, but substrate dissociation rates were significantly faster than expected. Ribozyme and substrate alterations that eliminated catalytic activity increased the stability of the hammerhead complex. These results suggest that substrate destabilization may play a role in hammerhead catalysis.     

Critical nature of a specific uridine O2-carbonyl for cleavage by the hammerhead ribozyme.

Three modified hammerhead ribozyme/substrate complexes have been prepared in which individual uridine O2-carbonyls have been eliminated. The modified complexes were chemically synthesized with the substitution of a single 2-pyridone (2P) base analogue for residues U4, U7, and U16.1. Steady-state kinetic analyses indicate that the cleavage efficiencies for the U7 and U16.1 complexes were not significantly reduced relative to the native complex as measured by kcat/KM. The cleavage efficiency for the 2P4 complex, with the analogue present within the uridine loop, was reduced by greater than 2 orders of magnitude. This significant reduction in catalytic efficiency was due primarily to a decrease in kcat. The pH vs cleavage rate profile suggests that the O2-carbonyl of the U4 residue of the hammerhead complex is critical for transition state stabilization and efficient cleavage activity. The results of a Mg2+ rescue assay do not implicate the O2-carbonyl of U4 in an interaction with a divalent metal ion. In addition, the results of a ribozyme folding assay suggest that the presence of the 2P4 within the uridine loop does not alter the folding pathway (relative to the native sequence) both in the absence and in the presence of Mg2+. The O2-carbonyl of U4 appears oriented toward the interior of the catalytic pocket where it may be involved in a critical hydrogen bonding interaction necessary for transition state stabilization.     

Effects of phosphorothioate and 2-amino groups in hammerhead ribozymes on cleavage rates and Mg2+ binding

Mg2+ is important for the RNase activity of the hammerhead ribozyme. To investigate the binding properties of Mg2+ to the hammerhead ribozyme, cleavage rates and CD spectra for substrates containing inosine or guanosine at the cleavage site were measured. The 2-amino group of this guanosine interfered with the rate of the cleavage reaction and did not affect the amount of Mg2+ bound to the hammerhead RNA. The kinetics and CD spectra for chemically synthesized oligoribonucleotides with a Sp or Rp phosphorothioate diester bond at the cleavage site indicated that 1 mol of Mg2+ binds to the pro-R oxygen of phosphate. The binding constant for Mg2+ was about 10(4) M-1, which represents outer-sphere complexation. The hammerhead ribozyme catalyzes the cleavage reaction via an in-line pathway. This mechanism has been proved for RNA cleavage by RNase A by using a modified oligonucleotide that has an Sp phosphorothionate bond at the cleavage site. From these results, we present the reaction pathway and a model for Mg2+ binding to the hammerhead ribozyme.     

Configurationally defined phosphorothioate-containing oligoribonucleotides in the study of the mechanism of cleavage of hammerhead ribozymes.

The chemical synthesis is described of oligoribonucleotides containing a single phosphorothioate linkage of defined Rp and Sp configuration. The oligoribonucleotides were used as substrates in the study of the mechanism of cleavage of an RNA hammerhead domain having the phosphorothioate group at the cleavage site. Whereas the Rp isomer was cleaved only very slowly in the presence of magnesium ion, the rate of cleavage of the Sp isomer was only slightly reduced from that of the unmodified phosphodiester. This finding gives further evidence for the hypothesis that the magnesium ion is bound to the pro-R oxygen in the transition state of the hammerhead cleavage reaction. Also, inversion of configuration at phosphorus is confirmed for a two-stranded hammerhead.     

The different role of high-affinity and low-affinity metal ions in cleavage by a tertiary stabilized cis hammerhead ribozyme from tobacco ringspot virus.

The aim of this study was to investigate the dependence of the observed cleavage rates (k(obs)) of a tertiary stabilized hammerhead ribozyme (tsHHRz) and of a minimal hammerhead ribozyme (mHHRz), both derived from tobacco ringspot virus, on the type and concentration of divalent metal ions in order to interpret the functional role of high-affinity ions detected by electron paramagnetic resonance (EPR). To measure the fast cleavage of the cis tsHHRz, a new method using chemically synthesized fluorescent-labeled RNAs has been developed. The tsHHRz cleavage rate is up to 20-fold faster than that of the mHHRz under similar conditions. The presence of Mn(2+) ions leads to a 60-fold faster cleavage than in the presence of Mg(2+) ions. The functional role of the high-affinity ion was evaluated using neomycin B inhibition studies. Neomycin B reduces the cleavage activity of both ribozymes but the inhibitory effect on tsHHRz is much weaker than that on the mHHRz. EPR data had shown that neomycin B displaces both low-affinity and high-affinity Mn(2+) ions from the mHHRz, but only low-affinity ions from tsHHRz. Inhibition of the tsHHRz activity may be due to the displacement of weakly bound Me(2+) ions required for the local folding leading to cleavage, whereas both the high-affinity ion required for folding and the weakly bound ions are replaced in the mHHRz. The high-affinity metal ion is required for the stabilization of the global HHRz structure, but is not involved in catalysis or stabilization of the transient state.     

Catalytic diversity of extended hammerhead ribozymes

Chimeras of the well-characterized minimal hammerhead 16 and nine extended hammerheads derived from natural viroids and satellite RNAs were constructed with the goal of assessing whether their very different peripheral tertiary interactions modulate their catalytic properties. For each chimera, three different assays were used to determine the rate of cleavage and the fraction of full-length hammerhead at equilibrium and thereby deduce the elemental cleavage ( k 2) and ligation ( k -2) rate constants. The nine chimeras were all more active than minimal hammerheads and exhibited a very broad range of catalytic properties, with values of k 2 varying by 750-fold and k -2 by 100-fold. At least two of the hammerheads exhibited an altered dependence of k obs on magnesium concentration. Since much less catalytic diversity is observed among minimal hammerheads that lack the tertiary interactions, a possible role for the different tertiary interaction is to modulate the hammerhead cleavage properties in viroids. For example, differing hammerhead cleavage and ligation rates could affect the steady state concentrations of linear, circular, and polymeric genomes in infected cells.     

Role of divalent metal ions in the hammerhead RNA cleavage reaction.

A hammerhead self-cleaving domain composed of two oligoribonucleotides was used to study the role of divalent metal ions in the cleavage reaction. Cleavage rates were measured as a function of MgCl2, MnCl2, and CaCl2 concentration in the absence or presence of spermine. In the presence of spermine, the rate vs metal ion concentration curves are broader, and lower concentrations of divalent ions are necessary for catalytic activity. This suggests that spermine can promote proper folding of the hammerhead and one or more divalent ions are required for the reaction. Six additional divalent ions were tested for their ability to support hammerhead cleavage. In the absence of spermine, rapid cleavage was observed with Co2+ while very slow cleavage occurred with Sr2+ and Ba2+. No detectable specific cleavage was observed with Cd2+, Zn2+, or Pb2+. However, in the presence of 0.5 mM spermine, rapid cleavage was observed with Zn2+ and Cd2+, and the rate with Sr2+ was increased, indicating that while these three ions could not promote proper folding of the hammerhead they were able to stimulate cleavage. These results suggest certain divalent ions either participate directly in the cleavage mechanism or are specifically involved in stabilizing the tertiary structure of the hammerhead. Additionally, an altered divalent metal ion specificity was observed when a unique phosphorothioate linkage was inserted at the cleavage site. The substitution of a sulfur for a nonbridging oxygen atom substantially reduced the affinity of an important Mg2+ ion necessary for efficient cleavage. In contrast, the reaction proceeds normally with Mn2+, presumably due to its ability to coordinate with both oxygen and sulfur.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification of the hammerhead ribozyme metal ion binding site responsible for rescue of the deleterious effect of a cleavage site phosphorothioate

The hammerhead ribozyme crystal structure identified a specific metal ion binding site referred to as the P9/G10.1 site. Although this metal ion binding site is approximately 20 A away from the cleavage site, its disruption is highly deleterious for catalysis. Additional published results have suggested that the pro-R(P) oxygen at the cleavage site is coordinated by a metal ion in the reaction's transition state. Herein, we report a study on Cd(2+) rescue of the deleterious phosphorothioate substitution at the cleavage site. Under all conditions, the Cd(2+) concentration dependence can be accounted for by binding of a single rescuing metal ion. The affinity of the rescuing Cd(2+) is sensitive to perturbations at the P9/G10.1 site but not at the cleavage site or other sites in the conserved core. These observations led to a model in which a metal ion bound at the P9/G10.1 site in the ground state acquires an additional interaction with the cleavage site prior to and in the transition state. A titration experiment ruled out the possibility that a second tight-binding metal ion (< 10 microM) is involved in the rescue, further supporting the single metal ion model. Additionally, weakening Cd(2+) binding at the P9/G10.1 site did not result in the biphasic binding curve predicted from other models involving two metal ions. The large stereospecific thio-effects at the P9/G10.1 and the cleavage site suggest that there are interactions with these oxygen atoms in the normal reaction that are compromised by replacement of oxygen with sulfur. The simplest interpretation of the substantial rescue by Cd(2+) is that these atoms interact with a common metal ion in the normal reaction. Furthermore, base deletions and functional group modifications have similar energetic effects on the transition state in the Cd(2+)-rescued phosphorothioate reaction and the wild-type reaction, further supporting the model that a metal ion bridges the P9/G10.1 and the cleavage site in the normal reaction (i.e., with phosphate linkages rather than phosphorothioate linkages). These results suggest that the hammerhead undergoes a substantial conformational rearrangement to attain its catalytic conformation. Such rearrangements appear to be general features of small functional RNAs, presumably reflecting their structural limitations.     

Expression of a chimeric ribozyme gene results in endonucleolytic cleavage of target mRNA and a concomitant reduction of gene expression in vivo.

The subclass of catalytic RNAs termed ribozymes cleave specific target RNA sequences in vitro. Only circumstantial evidence supports the idea that ribozymes may also act in vivo. In this study, ribozymes with a hammerhead motif directed against a target sequence within the mRNA of the neomycin phosphotransferase gene (npt) were embedded into a functional chimeric gene. Two genes, one containing the ribozyme and the other producing the target, were cotransfected into plant protoplasts. Following in vivo expression, a predefined cleavage product of the target mRNA was detected by ribonuclease protection. Expression of both the ribozyme gene and the target gene was driven by the CaMV 35S promoter. Concomitant with the endonucleolytic cleavage of the target mRNA, a complete reduction of NPT activity was observed. An A to G substitution within the ribozyme domain completely inactivates ribozyme-mediated hydrolysis but still shows a reduction in NPT activity, albeit less pronounced. Therefore, the reduction of NPT activity produced by the active ribozyme is best explained by both hydrolytic cleavage and an antisense effect. However, the mutant ribozyme--target complex was more stable than the wildtype ribozyme--target complex. This may result in an overestimation of the antisense effect contributing to the overall reduction of gene expression.     

Studies on the hammerhead RNA self-cleaving domain

Nine different hammerhead RNA self-cleaving domains consistent with the consensus secondary structure proposed by Keese and Symons (1987) were prepared and tested for cleavage. Each hammerhead was constructed from two oligoribonucleotides in two different configurations. Although cleavage was observed in all nine cases, the rates of cleavage varied by more than a thousand fold. The presence of RNA secondary structure incompatible with hammerhead formation in the individual oligos may be responsible for the large rate differences. We have also examined the degree of participation of a proposed dimer hammerhead intermediate in one case and conclude that, while such a four-stranded structure can form, it is not the preferred reaction intermediate.     

High-pressure analysis of a hammerhead ribozyme from Chrysanthemum chlorotic mottle viroid reveals two different populations of self-cleaving molecule

The activity of the full-length hammerhead ribozyme requires a tertiary interaction between its distal loops leading to the closure of the molecule and its stabilization in the active conformation. In this study, the conformational changes accompanying the cis-cleavage reaction of Chrysanthemum chlorotic mottle viroid hammerhead ribozyme were investigated by high-pressure experiments on the complete cleavage reaction. Two activation volumes (ΔV(≠)) were measured, pointing to the presence of two different populations of molecules corresponding to fast-cleaving and slow-cleaving ribozymes in the reaction mixture. The fast population, with a small ΔV(≠) of 2.6 mL·mol(-1), most likely represents molecules in the near-active conformation, whereas the slow population, with a larger ΔV(≠) of 11.6 mL·mol(-1 , represents molecules that need a larger conformational change to induce activity. In addition, pH-dependence experiments suggest that the group whose deprotonation is required for activity intervenes in the formation of the transition state or in the chemistry of the reaction, but not in the conformational change that precedes it.     

Efficient ligation of the Schistosoma hammerhead ribozyme

The hammerhead ribozyme from Schistosoma mansoni is the best characterized of the natural hammerhead ribozymes. Biophysical, biochemical, and structural studies have shown that the formation of the loop-loop tertiary interaction between stems I and II alters the global folding, cleavage kinetics, and conformation of the catalytic core of this hammerhead, leading to a ribozyme that is readily cleaved under physiological conditions. This study investigates the ligation kinetics and the internal equilibrium between cleavage and ligation for the Schistosoma hammerhead. Single turnover kinetic studies on a construct where the ribozyme cleaves and ligates substrate(s) in trans showed up to 23% ligation when starting from fully cleaved products. This was achieved by an approximately 2000-fold increase in the rate of ligation compared to a minimal hammerhead without the loop-loop tertiary interaction, yielding an internal equilibrium that ranges from 2 to 3 at physiological Mg2+ ion concentrations (0.1-1 mM). Thus, the natural Schistosoma hammerhead ribozyme is almost as efficient at ligation as it is at cleavage. The results here are consistent with a model where formation of the loop-loop tertiary interaction leads to a higher population of catalytically active molecules and where formation of this tertiary interaction has a much larger effect on the ligation than the cleavage activity of the Schistosoma hammerhead ribozyme.     

The hammerhead cleavage reaction in monovalent cations

Recently, Murray et al. (Chem Biol, 1998, 5:587-595) found that the hammerhead ribozyme does not require divalent metal ions for activity if incubated in high (> or =1 M) concentrations of monovalent ions. We further characterized the hammerhead cleavage reaction in the absence of divalent metal. The hammerhead is active in a wide range of monovalent ions, and the rate enhancement in 4 M Li+ is only 20-fold less than that in 10 mM Mg2+. Among the Group I monovalent metals, rate correlates in a log-linear manner with ionic radius. The pH dependence of the reaction is similar in 10 mM Mg2+, 4 M Li+, and 4 M Na+. The exchange-inert metal complex Co(NH3)3+ also supports substantial hammerhead activity. These results suggest that a metal ion does not act as a base in the reaction, and that the effects of different metal ions on hammerhead cleavage rates primarily reflect structural contributions to catalysis.     

Hammerhead redux: Does the new structure fit the old biochemical data?

The cleavage rates of 78 hammerhead ribozymes containing structurally conservative chemical modifications were collected from the literature and compared to the recently determined crystal structure of the Schistosoma mansoni hammerhead. With only a few exceptions, the biochemical data were consistent with the structure, indicating that the new structure closely resembles the transition state of the reaction. Since all the biochemical data were collected on minimal hammerheads that have a very different structure, the minimal hammerhead must be dynamic and occasionally adopt the quite different extended structure in order to cleave.     

Capturing hammerhead ribozyme structures in action by modulating general base catalysis

We have obtained precatalytic (enzyme–substrate complex) and postcatalytic (enzyme–product complex) crystal structures of an active full-length hammerhead RNA that cleaves in the crystal. Using the natural satellite tobacco ringspot virus hammerhead RNA sequence, the self-cleavage reaction was modulated by substituting the general base of the ribozyme, G12, with A12, a purine variant with a much lower pK_a that does not significantly perturb the ribozyme's atomic structure. The active, but slowly cleaving, ribozyme thus permitted isolation of enzyme–substrate and enzyme–product complexes without modifying the nucleophile or leaving group of the cleavage reaction, nor any other aspect of the substrate. The predissociation enzyme-product complex structure reveals RNA and metal ion interactions potentially relevant to transition-state stabilization that are absent in precatalytic structures.     

Comparison of the hammerhead cleavage reactions stimulated by monovalent and divalent cations

Although the hammerhead reaction proceeds most efficiently in divalent cations, cleavage in 4 M LiCl is only approximately 10-fold slower than under standard conditions of 10 mM MgCl2 (Murray et al., Chem Biol, 1998, 5:587-595; Curtis & Bartel, RNA, 2001, this issue, pp. 546-552). To determine if the catalytic mechanism with high concentrations of monovalent cations is similar to that with divalent cations, we compared the activities of a series of modified hammerhead ribozymes in the two ionic conditions. Nearly all of the modifications have similar deleterious effects under both reaction conditions, suggesting that the hammerhead adopts the same general catalytic structure with both monovalent and divalent cations. However, modification of three ligands previously implicated in the binding of a functional divalent metal ion have substantially smaller effects on the cleavage rate in Li+ than in Mg2+. This result suggests that an interaction analogous to the interaction made by this divalent metal ion is absent in the monovalent reaction. Although the contribution of this divalent metal ion to the overall reaction rate is relatively modest, its presence is needed to achieve the full catalytic rate. The role of this ion appears to be in facilitating formation of the active structure, and any direct chemical role of metal ions in hammerhead catalysis is small.     

Oligonucleotide facilitators may inhibit or activate a hammerhead ribozyme.

Facilitators are oligonucleotides capable of affecting hammerhead ribozyme activity by interacting with the substrate at the termini of the ribozyme. Facilitator effects were determined in vitro using a system consisting of a ribozyme with 7 nucleotides in every stem sequence and two substrates with inverted facilitator binding sequences. The effects of 9mer and 12mer RNA as well as DNA facilitators which bind either adjacent to the 3'- or 5'-end of the ribozyme were investigated. A kinetic model was developed which allows determination of the apparent dissociation constant of the ribozyme-substrate complex from single turnover reactions. We observed a decreased dissociation constant of the ribozyme-substrate complex due to facilitator addition corresponding to an additional stabilization energy of delta delta G=-1.7 kcal/mol with 3'-end facilitators. The cleavage rate constant was increased by 3'-end facilitators and decreased by 5'-end facilitators. Values for Km were slightly lowered by all facilitators and kcat was increased by 3'-end facilitators and decreased by 5'-end facilitators in our system. Generally the facilitator effects increased with the length of the facilitators and RNA provided greater effects than DNA of the same sequence. Results suggest facilitator influences on several steps of the hammerhead reaction, substrate association, cleavage and dissociation of products. Moreover, these effects are dependent in different manners on ribozyme and substrate concentration. This leads to the conclusion that there is a concentration dependence whether activation or inhibition is caused by facilitators. Conclusions are drawn with regard to the design of hammerhead ribozyme facilitator systems.     

Photocrosslinking detects a compact, active structure of the hammerhead ribozyme

The hammerhead ribozyme has been intensively studied for approximately 15 years, but its cleavage mechanism is not yet understood. Crystal structures reveal a Y-shaped molecule in which the cleavage site is not ideally aligned for an S(N)2 reaction and no RNA functional groups are positioned appropriately to perform the roles of acid and base or other functions in the catalysis. If the ribozyme folds to a more compact structure in the transition state, it probably does so only transiently. We have used photocrosslinking as a tool to trap hammerhead ribozyme-substrate complexes in various stages of folding. Results suggest that the two substrate residues flanking the cleavage site approach and stack upon two guanosines (G8 and G12) in domain 2, moving 10-15 A closer to domain 2 than they appear in the crystal structure. Most crosslinks obtained with the nucleotide analogues positioned in the ribozyme core are catalytically inactive; however, one cobalt(III) hexaammine-dependent crosslink of an unmodified ribozyme retains catalytic activity and confirms the close stacking of cleavage site residue C17 with nucleotide G8 in domain 2. These findings suggest that residues involved in the chemistry of hammerhead catalysis are likely located in that region containing G8 and G12.     

Selection of tetracycline inducible self-cleaving ribozymes as synthetic devices for gene regulation in yeast

Synthetic regulatory devices are key components for the development of complex biological systems and the reprogramming of cellular functions and networks. Here we describe the selection of tetracycline inducible hammerhead ribozymes. A tetracycline aptamer was fused to the full-length hammerhead ribozyme via a variable linker region. 11 rounds of in vitro selection were applied to isolate linker sequences that mediate tetracycline dependent hammerhead cleavage. We identified allosteric ribozymes that cleave in the presence of 1 μM tetracycline as fast as the full-length ribozyme whereas cleavage is inhibited up to 333-fold in the absence of tetracycline. Reporter gene assays indicate that the allosteric ribozymes can be employed to control gene expression in yeast.