Sequence elements outside the hammerhead ribozyme catalytic core enable intracellular activity

The hammerhead ribozyme (HHRz) is a small, naturally occurring ribozyme that site-specifically cleaves RNA and has long been considered a potentially useful tool for gene silencing. The minimal conserved HHRz motif derived from natural sequences consists of three helices that intersect at a highly conserved catalytic core of 11 nucleotides. The presence of this motif is sufficient to support cleavage at high Mg2+ concentrations, but not at the low Mg2+ concentrations characteristic of intracellular environments. Here we demonstrate that natural HHRzs require the presence of additional nonconserved sequence elements outside of the conserved catalytic core to enable intracellular activity. These elements may stabilize the HHRz in a catalytically active conformation via tertiary interactions. HHRzs stabilized by these interactions cleave efficiently at physiological Mg2+ concentrations and are functional in vivo. The proposed role of these tertiary interacting motifs is supported by mutational, functional, structural and molecular modeling analysis of natural HHRzs.     

The tolerance to exchanges of the Watson Crick base pair in the hammerhead ribozyme core is determined by surrounding elements

Tertiary interacting elements are important features of functional RNA molecules, for example, in all small nucleolytic ribozymes. The recent crystal structure of a tertiary stabilized type I hammerhead ribozyme revealed a conventional Watson-Crick base pair in the catalytic core, formed between nucleotides C3 and G8. We show that any Watson-Crick base pair between these positions retains cleavage competence in two type III ribozymes. In the Arabidopsis thaliana sequence, only moderate differences in cleavage rates are observed for the different base pairs, while the peach latent mosaic viroid (PLMVd) ribozyme exhibits a preference for a pyrimidine at position 3 and a purine at position 8. To understand these differences, we created a series of chimeric ribozymes in which we swapped sequence elements that surround the catalytic core. The kinetic characterization of the resulting ribozymes revealed that the tertiary interacting loop sequences of the PLMVd ribozyme are sufficient to induce the preference for Y3-R8 base pairs in the A. thaliana hammerhead ribozyme. In contrast to this, only when the entire stem-loops I and II of the A. thaliana sequences are grafted on the PLMVd ribozyme is any Watson-Crick base pair similarly tolerated. The data provide evidence for a complex interplay of secondary and tertiary structure elements that lead, mediated by long-range effects, to an individual modulation of the local structure in the catalytic core of different hammerhead ribozymes.     

Inhibition of the hammerhead ribozyme by neomycin.

A series of antibiotics was tested for stimulation or inhibition of the hammerhead ribozyme cleavage reaction. Neomycin was found to be a potent inhibitor of the reaction with a Kl of 13.5 microM. Two hammerheads with well-characterized kinetics were used to determine which steps in the reaction mechanism were inhibited by neomycin. The data suggest that neomycin interacts preferentially with the enzyme-substrate complex and that this interaction leads to a reduction in the cleavage rate by stabilizing the ground state of the complex and destabilizing the transition state of the cleavage step. A comparison of neomycin with other aminoglycosides and inhibitors of hammerhead cleavage implies that the ammonium ions of neomycin are important for the antibiotic-hammerhead interaction.     

Folding and catalysis by the VS ribozyme

The VS ribozyme is a 154 nt self-cleaving RNA molecule that can be divided into a trans-acting five-helix ribozyme and stem-loop substrate. The structure of the ribozyme is organised by two three-way helical junctions, the structure of which has been determined by a combination of comparative gel electrophoresis and fluorescence resonance energy transfer experiments. From this, the overall global architecture of the ribozyme has been deduced. The substrate is then thought to dock into the cleft formed between helices II and VI, where it makes a close interaction with the loop containing A730. The A730 loop is the probable active site of the ribozyme, and A756 within it is a strong candidate to play a direct role in the transesterification chemistry, possibly by general acid-base catalysis.     

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.     

Internal equilibrium of the hammerhead ribozyme is altered by the length of certain covalent cross-links

A method was developed that permits covalent cross-links of different linker lengths to be introduced into RNA at defined positions. The previous observation that a cross-link between stems I and II of the hammerhead ribozyme was confirmed and further explored. By examining the catalytic consequences of varying the position and length of this cross-link, we conclude that the previously proposed conformational dampening model cannot sufficiently explain the increase in ligation rate induced by the cross-link. Rather, the cross-link constrains the cleaved hammerhead into a structure that more closely resembles the transition state, thereby increasing the reverse ligation rate relative to a non-cross-linked control.     

Cobalt hexammine inhibition of the hammerhead ribozyme

The effects of Co(NH(3))(6)(3+) on the hammerhead ribozyme are analyzed using several techniques, including activity measurements, electron paramagnetic resonance (EPR), and circular dichroism (CD) spectroscopies and thermal denaturation studies. Co(NH(3))(6)(3+) efficiently displaces Mn(2+) bound to the ribozyme with an apparent dissociation constant of K(d app) = 22 +/- 4.2 microM in 500 microM Mn(2+) (0.1 M NaCl). Displacement of Mn(2+) coincides with Co(NH(3))(6)(3+) inhibition of hammerhead activity in 500 microM Mn(2+), reducing the activity of the WT hammerhead by approximately 15-fold with an inhibition constant of K(i) = 30.9 +/- 2.3 microM. A residual 'slow' activity is observed in the presence of Co(NH(3))(6)(3+) and low concentrations of Mn(2+). Under these conditions, a single Mn(2+) ion remains bound and has a low-temperature EPR spectrum identical to that observed previously for the highest affinity Mn(2+) site in the hammerhead ribozyme in 1 M NaCl, tentatively attributed to the A9/G10.1 site [Morrissey, S. R. , Horton, T. E., and DeRose, V. J. (2000) J. Am. Chem. Soc. 122, 3473-3481]. Circular dichroism and thermal denaturation experiments also reveal structural effects that accompany the observed inhibition of cleavage and Mn(2+) displacement induced by addition of Co(NH(3))(6)(3+). Taken together, the data indicate that a high-affinity Co(NH(3))(6)(3+) site is responsible for significant inhibition accompanied by structural changes in the hammerhead ribozyme. In addition, the results support a model in which at least two types of metal sites, one of which requires inner-sphere coordination, support hammerhead activity.     

Folding and catalysis by the hairpin ribozyme.

The hairpin ribozyme undergoes a site-specific transesterification cleavage of the phosphodiester backbone. The natural form of the ribozyme is a four-way helical junction, where two arms contain unpaired loops. This folds by pairwise coaxial stacking of helical arms, and a rotation into an antiparallel conformation in which there is close association between the loops. This probably generates the local conformation required to facilitate the trajectory into an in-line SN2 transition state. Folding is induced by the cooperative binding of at least two divalent metal ions, which are probably distributed between the junction and the loop-loop interface. The junction forms the structural scaffold on which the geometry of the ribozyme is built, and structural perturbation of the junction leads to impaired catalytic activity.     

RNA folding and misfolding of the hammerhead ribozyme

The hammerhead ribozyme undergoes a well-defined two-stage folding process induced by the sequential binding of two magnesium ions. These probably correspond to the formation of domain 2 (0-500 microM magnesium ions) and domain 1 (1-20 mM magnesium ions), respectively. In this study we have used fluorescence resonance energy transfer (FRET) to analyze the ion-induced folding of a number of variants of the hammerhead ribozyme. We find that both A14G and G8U mutations are highly destabilizing, such that these species are essentially unfolded under all conditions. Thus they appear to be blocked in the first stage of the folding process, and using uranyl-induced photocleavage we show that the core is completely accessible to this probe under these conditions. Changes at G5 do not affect the first transition but appear to provide a blockage at the second stage of folding; this is true of changes in the sugar (removal of the 2'-hydroxyl group) and base (G5C mutation, previously studied by comparative gel electrophoresis). Arrest of folding at this intermediate stage leads to a pattern of uranyl-induced photocleavage that is changed from the wild-type, but suggests a structure less open than the A14G mutant. Specific photocleavage at G5 is found only in the wild-type sequence, suggesting that this ion-binding site is formed late in the folding process. In addition to folding that is blocked at selected stages, we have also observed misfolding. Thus the A13G mutation appears to result in the ion-induced formation of a novel tertiary structure.     

Structure—function studies of the hammerhead ribozyme

Elucidation of the catalytic mechanism and structure—function relationship studies of the hammerhead ribozyme continue to be an area of intensive research. A combination of diverse approaches, such as X ray crystallography, spectral studies, chemical modifications, sequence variations and kinetic analyses, have provided valuable insight into the cleavage mechanism of this ribozyme. The hammerhead ribozyme crystal structures have provided valuable insight into conformational deformations needed to attain the catalytically active structure. Similarly, determination of ribozyme solution structure by spectroscopic analyses and the effect of divalent metal ions on RNA folding has further aided in the construction of a model for hammerhmead catalysis.     

Recent developments in the hammerhead ribozyme field.

Developments in the hammerhead ribozyme field during the last two years are reviewed here. New results on the specificity of this ribozyme, the mechanism of its action and on the question of metal ion involvement in the cleavage reaction are discussed. To demonstrate the potential of ribozyme technology examples of the application of this ribozyme for the inhibition of gene expression in cell culture, in animals, as well as in plant models are presented. Particular emphasis is given to critical steps in the approach, including RNA site selection, delivery, vector development and cassette construction.     

Folding of the hammerhead ribozyme: pyrrolo-cytosine fluorescence separates core folding from global folding and reveals a pH-dependent conformational change

The catalytic activity of the hammerhead ribozyme is limited by its ability to fold into the native tertiary structure. Analysis of folding has been hampered by a lack of assays that can independently monitor the environment of nucleobases throughout the ribozyme-substrate complex in real time. Here, we report the development and application of a new folding assay in which we use pyrrolo-cytosine (pyC) fluorescence to (1) probe active-site formation, (2) examine the ability of peripheral ribozyme domains to support native folding, (3) identify a pH-dependent conformational change within the ribozyme, and (4) explore its influence on the equilibrium between the folded and unfolded core of the hammerhead ribozyme. We conclude that the natural ribozyme folds in two distinct noncooperative steps and the pH-dependent correlation between core folding and activity is linked to formation of the G8-C3 base pair.     

Origins of the temperature dependence of hammerhead ribozyme catalysis.

The difficulties in interpreting the temperature dependence of protein enzyme reactions are well recognized. Here, the hammerhead ribozyme cleavage was investigated under single-turnover conditions between 0 and 60 degrees C as a model for RNA-catalyzed reactions. Under the adopted conditions, the chemical step appears to be rate-limiting. However, the observed rate of cleavage is affected by pre-catalytic equilibria involving deprotonation of an essential group and binding of at least one low-affinity Mg2+ion. Thus, the apparent entropy and enthalpy of activation include contributions from the temperature dependence of these equilibria, precluding a simple physical interpretation of the observed activation parameters. Similar pre-catalytic equilibria likely contribute to the observed activation parameters for ribozyme reactions in general. The Arrhenius plot for the hammerhead reaction is substantially curved over the temperature range considered, which suggests the occurrence of a conformational change of the ribozyme ground state around physiological temperatures.     

2-C-Methyluridine modified hammerhead ribozyme against the estrogen receptor

A new synthesis of 2′-C-methyluridine phosphoramidite is presented. Special emphasis is dedicated to the improvement of the protection of the tertiary 2′-hydroxyl group. Comparison to previous protecting strategies and analysis of stability under 5′-DMTr removing conditions are discussed. The synthetic incorporation of this modified nucleoside into the catalytic core of a hammerhead ribozyme against the estrogen receptor α protein (ER-α), and transfection experiments in MCF-7 cell line are also presented.     

Inhibition by polyamines of the hammerhead ribozyme from a Chrysanthemum chlorotic mottle viroid

Background

Viroids are the smallest pathogens known to date. They infect plants and cause considerable economic losses. The members of the Avsunviroidae family are known for their capability to form hammerhead ribozymes (HHR) that catalyze self-cleavage during their rolling circle replication.

Methods

In vitro inhibition assays, based on the self-cleavage kinetics of the hammerhead ribozyme from a Chrysanthemum chlorotic mottle viroid (CChMVd-HHR) were performed in the presence of various putative inhibitors.

Results

Aminated compounds appear to be inhibitors of the self-cleavage activity of the CChMVd HHR. Surprisingly the spermine, a known activator of the autocatalytic activity of another hammerhead ribozyme in the presence or absence of divalent cations, is a potent inhibitor of the CChMVd-HHR with K_i of 17 ± 5 μM. Ruthenium hexamine and TMPyP4 are also efficient inhibitors with K_i of 32 ± 5 μM and IC₅₀ of 177 ± 5 nM, respectively.

Conclusions

This study shows that polyamines are inhibitors of the CChMVd-HHR self-cleavage activity, with an efficiency that increases with the number of their amino groups.

General significance

This fundamental investigation is of interest in understanding the catalytic activity of HHR as it is now known that HHR are present in the three domains of life including in the human genome. In addition these results emphasize again the remarkable plasticity and adaptability of ribozymes, a property which might have played a role in the early developments of life and must be also of significance nowadays for the multiple functions played by non-coding RNAs.     

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.     

Characterization of a native hammerhead ribozyme derived from schistosomes

A recent re-examination of the role of the helices surrounding the conserved core of the hammerhead ribozyme has identified putative loop-loop interactions between stems I and II in native hammerhead sequences. These extended hammerhead sequences are more active at low concentrations of divalent cations than are minimal hammerheads. The loop-loop interactions are proposed to stabilize a more active conformation of the conserved core. Here, a kinetic and thermodynamic characterization of an extended hammerhead sequence derived from Schistosoma mansoni is performed. Biphasic kinetics are observed, suggesting the presence of at least two conformers, one cleaving with a fast rate and the other with a slow rate. Replacing loop II with a poly(U) sequence designed to eliminate the interaction between the two loops results in greatly diminished activity, suggesting that the loop-loop interactions do aid in forming a more active conformation. Previous studies with minimal hammerheads have shown deleterious effects of Rp-phosphorothioate substitutions at the cleavage site and 5' to A9, both of which could be rescued with Cd2+. Here, phosphorothioate modifications at the cleavage site and 5' to A9 were made in the schistosome-derived sequence. In Mg2+, both phosphorothioate substitutions decreased the overall fraction cleaved without significantly affecting the observed rate of cleavage. The addition of Cd2+ rescued cleavage in both cases, suggesting that these are still putative metal binding sites in this native sequence.     

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.