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)     

Essential nucleotide sequences and secondary structure elements of the hairpin ribozyme

In vitro selection experiments have been used to isolate active variants of the 50 nt hairpin catalytic RNA motif following randomization of individual ribozyme domains and intensive mutagenesis of the ribozyme-substrate complex. Active and inactive variants were characterized by sequencing, analysis of RNA cleavage activity in cis and in trans, and by substrate binding studies. Results precisely define base-pairing requirements for ribozyme helices 3 and 4, and identify eight essential nucleotides (G8, A9, A10, G21, A22, A23, A24 and C25) within the catalytic core of the ribozyme. Activity and substrate binding assays show that point mutations at these eight sites eliminate cleavage activity but do not significantly decrease substrate binding, demonstrating that these bases contribute to catalytic function. The mutation U39C has been isolated from different selection experiments as a second-site suppressor of the down mutants G21U and A43G. Assays of the U39C mutation in the wild-type ribozyme and in a variety of mutant backgrounds show that this variant is a general up mutation. Results from selection experiments involving populations totaling more than 10(10) variants are summarized, and consensus sequences including 16 essential nucleotides and a secondary structure model of four short helices, encompassing 18 bp for the ribozyme-substrate complex are derived.     

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.     

Antibody responses of cows during an outbreak of neosporosis evaluated by indirect fluorescent antibody test and different enzyme-linked immunosorbent assays

Hairpin ribozymes with high cleavage activities were designed. An extra sequence was introduced at the 3'-end of the hairpin ribozyme to increase the binding to the substrate RNA, as compared to the wild-type hairpin ribozyme. A three-way junction (TWJ) was formed between the newly designed ribozyme and the substrate RNA. The complex with a solid TWJ showed less RNA cleavage activity than the wild-type hairpin ribozyme. However, the ribozyme with a TWJ with five unpaired bases or propandiol phosphate linkers had higher cleavage activity than the parent ribozyme without the TWJ. When a cis-cleavage system, in which the 5'-end of the substrate RNA was conjugated to the 3'-end of the ribozyme, was employed, the complex with the TWJ containing unpaired bases was also cleaved faster than the complex with the solid TWJ. This suggested that these differences in the cleavage activities were derived from the confirmation, and this was proven by nondenaturing gel electrophoresis. The TWJ hairpin ribozyme containing unpaired bases is able to bind strongly with substrate RNAs and to cleave them efficiently. Since the three-way ribozyme presented here is more active than the wild-type ribozyme, this type of ribozyme can serve as a more efficient tool to control RNA activities in vitro and in vivo.     

Modification of primary structures of hairpin ribozymes for probing active conformations

Hairpin ribozymes consist of two stem-loop domains, and these domains are assumed to interact with each other to produce the self-cleavage activity. We have studied the relationship of the tertiary structure of the hairpin ribozyme and the cleavage activity by dividing and re-joining the domains. A hairpin ribozyme (E50) was divided at the hinge region, and the main part was joined to a substrate (S1) using tri- or penta-cytidylates. These ribozymes retained the cleavage activity in the presence of the rest of the molecule, indicating that the active conformation could be maintained if the two domains interacted with each other. Based on the these results, we designed a new type of hairpin ribozyme by replacing one of the domains. To maintain the interaction of the domains, oligocytidylates were inserted at a junction. These reversely jointed ribozyme complexes showed cleavage activity that was dependent on the linker lengths. These modifications in the primary structure of the hairpin ribozyme confirm the structural requirement for the catalytic reaction and provide information for the correlation of the tertiary structure with the cleavage of the hairpin ribozyme.     

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.     

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.     

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.     

Structural variation induced by different nucleotides at the cleavage site of the hammerhead ribozyme

The hammerhead ribozyme is capable of cleaving RNA substrates at 5' UX 3' sequences (where the cleavage site, X, can be A, C, or U). Hammerhead complexes containing dC, dA, dI, or rG nucleotides at the cleavage site have been studied by NMR. The rG at the cleavage site forms a Watson-Crick base pair with C3 in the conserved core of the hammerhead, indicating that rG substrates inhibit the cleavage reaction by stabilizing an inactive conformation of the molecule. Isotope-edited NMR experiments on the hammerhead complexes show that there are different short proton-proton distances between neighboring residues depending upon whether there is a dC or dA at the cleavage site. These NMR data demonstrate that there are significant differences in the structure and/or dynamics of the active-site residues in these hammerhead complexes. Molecular dynamics calculations were used to model the conformations of the cleavage-site variants consistent with the NMR data. The solution conformations of the hammerhead ribozyme-substrate complexes are compared with the X-ray structure of the hammerhead ribozyme and are used to help understand the thermodynamic and kinetic differences among the cleavage-site variants.     

Structural and sequence elements required for the self-cleaving activity of the hepatitis delta virus ribozyme

The hepatitis delta virus (HDV) is a subviral RNA that contains a self-cleaving activity that is similar to the ribozyme activity found in certain plant pathogens. However, the sequences surrounding the cleavage site are unrelated to the hammerhead or hairpin ribozyme motifs, and it is considered to be a distinct ribozyme type. We made site-specific changes within two regions of the smallest contiguous HDV sequence that has optimal activity and kinetically analyzed the data at different temperatures to determine the potential roles of the residues. We distinguish between those changes that affect the rate of catalysis and those that promote the formation of inactive structures. We find that nucleotides +45 to +72 downstream from the cleavage site, which can form a hairpin structure, are dispensable for catalytic activity but that they enhance the cleavage efficiency. Nucleotides +17 to +19 and +28 to +30 form Watson and Crick base pairs that are important for activity, but the actual sequence is not critical. In contrast, the nucleotides between +21 and +26 are important for activity, and they may be involved in significant tertiary interactions.     

Thermodynamic dissection of the substrate-ribozyme interaction in the hammerhead ribozyme

The free energy of substrate binding to the hammerhead ribozyme was compared for 10 different hammerheads that differed in the length and sequence of their substrate recognition helices. These hammerheads were selected because neither ribozyme nor substrate oligonucleotide formed detectable alternate secondary structures. The observed free energies of binding varied from -8 to -24 kcal/mol and agreed very well with binding energies calculated from the nearest-neighbor free energies if a constant energetic penalty of DeltaG degreescore = +3.3 +/- 1 kcal/mol is used for the catalytic core. A set of substrates that contained a competing hairpin secondary structure showed weaker binding to the ribozyme by an amount consistent with the predicted free energy for hairpin formation. These thermodynamic conclusions permit the prediction of substrate binding affinities for ribozyme-substrate pairs of any helix length and sequence, and thus, should be very valuable for the rational design of ribozymes directed toward gene inactivation.     

Interaction of structural modules in substrate binding by the ribozyme from Bacillus subtilis RNase P

The ribozyme from bacterial ribonuclease P recognizes two structural modules in a tRNA substrate: the T stem-loop and the acceptor stem. These two modules are connected through a helical linker. The T stem-loop binds at a surface confined in a folding domain away from the active site. Substrates for the Bacillus subtilis RNase P RNA were previously selected in vitro that are shown to bind comparably well or better than a tRNA substrate. Chemical modification of P RNA-substrate complexes with dimethylsulfate and kethoxal was performed to determine how the P RNA recognizes three in vitro selected substrates. All three substrates bind at the surface known to interact with the T stem-loop of tRNA. Similar to a tRNA, the secondary structure of these substrates contains a helix around the cleavage site and a hairpin loop at the corresponding position of the T stem-loop. Unlike a tRNA, these two structural modules are connected through a non-helical linker. The two structural modules in the tRNA and in the selected substrates bind to two different domains in P RNA. The properties of substrate recognition exhibited by this ribozyme may be exploited to isolate new ribozyme-substrate pairs with interactive structural modules.     

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.     

Inter-domain cross-linking and molecular modelling of the hairpin ribozyme

The hairpin ribozyme is a small catalytic RNA composed of two helical domains containing a small and a large internal loop and, thus, constitutes a valuable paradigm for the study of RNA structure and catalysis. We have carried out molecular modelling of the hairpin ribozyme to learn how the two domains (A and B) might fold and approach each other. To help distinguish alternative inter-domain orientations, we have chemically synthesized hairpin ribozymes containing 2'-2' disulphide linkages of known spacing (12 or 16 A) between defined ribose residues in the internal loop regions of each domain. The abilities of cross-linked ribozymes to carry out RNA cleavage under single turnover conditions were compared to the corresponding disulphide-reduced, untethered ribozymes. Ribozymes were classed in three categories according to whether their cleavage rates were marginally, moderately, or strongly affected by cross-linking. This rank order of activity guided the docking of the two domains in the molecular modelling process. The proposed three-dimensional model of the hairpin ribozyme incorporates three different crystallographically determined structural motifs: in domain A, the 5'-GAR-3'-motif of the hammerhead ribozyme, in domain B, the J4/5 motif of group I ribozymes, and connecting the two domains, a "ribose zipper", another group I ribozyme feature, formed between the hydroxyl groups of residues A10, G11 of domain A and C25, A24 of domain B. This latter feature might be key to the selection and precise orientation of the inter-domain docking necessary for the specific phosphodiester cleavage. The model provides an important basis for further studies of hairpin ribozyme structure and function.     

The mechanism of the hammerhead ribozyme

The rate of cleavage of a 13-mer substrate by an all-RNA ribozyme with 2 10-mer hybridising arms (TAT RA), appears to be limited by a conformational change involving the longer than necessary arms. The same limitation does not apply to a similar ribozyme with DNA arms (TAT RB) or to an all-RNA ribozyme with only 6 hybridising bases on each arm (TAT RA 6x2). The limitation does not arise in the hybridisation step nor in the dissociation of products. An extra step involving a conformational change of the pre-formed ribozyme-substrate prior to cleavage is introduced to explain the observed kinetics.     

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.     

Folding of the four-way RNA junction of the hairpin ribozyme

The hairpin ribozyme consists of two loop-carrying duplexes (called A and B) that are adjacent arms of a four-way junction in its natural context in the viral RNA. We have shown previously that the activity of the ribozyme is strongly influenced by the structure adopted by the junction. In this study, we have used fluorescence resonance energy transfer to analyze the conformation and folding of the isolated four-way junction. Like other four-way RNA junctions, in the absence of added metal ions this junction adopts a square configuration of coaxially stacked arms, based on A on D and B on C stacking. Upon addition of magnesium ions, the junction undergoes an ion-induced transition to an antiparallel conformation. The data are consistent with folding induced by the binding of a single ion, with an apparent association constant in the range of 2000 M-1. Other divalent metal ions (calcium or manganese) can also induce this change in structure; however, sodium ions are unable to substitute for these ions, and are slightly inhibitory with respect to the transition. The loop-free hairpin junction adopts the same stacking conformer as the full ribozyme, but forms a more symmetrical X-shaped structure. In addition, the apparent stoichiometry of structural ion binding is lower for the isolated junction, and the affinity is considerably lower.