Ribozyme cleavage of a 2,5-phosphodiester linkage: mechanism and a restricted divalent metal-ion requirement.

The natural substrate cleaved by the hepatitis delta virus (HDV) ribozyme contains a 3',5'-phosphodiester linkage at the cleavage site; however, a 2',5'-linked ribose-phosphate backbone can also be cleaved by both trans-acting and self-cleaving forms of the HDV ribozyme. With substrates containing either linkage, the HDV ribozyme generated 2',3'-cyclic phosphate and 5'-hydroxyl groups suggesting that the mechanisms of cleavage in both cases were by a nucleophilic attack on the phosphorus center by the adjacent hydroxyl group. Divalent metal ion was required for cleavage of either linkage. However, although the 3',5'-linkage was cleaved slightly faster in Ca2+ than in Mg2+, the 2',5'-linkage was cleaved in Mg2+ (or Mn2+) but not Ca2+. This dramatic difference in metal-ion specificity is strongly suggestive of a crucial metal-ion interaction at the active site. In contrast to the HDV ribozymes, cleavage at a 2',5'-phosphodiester bond was not efficiently catalyzed by the hammerhead ribozyme. The relaxed linkage specificity of the HDV ribozymes may be due in part to lack of a rigid binding site for sequences 5' to the cleavage site.     

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.     

Distinct reaction pathway promoted by non-divalent-metal cations in a tertiary stabilized hammerhead ribozyme

Divalent ion sensitivity of hammerhead ribozymes is significantly reduced when the RNA structure includes appropriate tertiary stabilization. Therefore, we investigated the activity of the tertiary stabilized "RzB" hammerhead ribozyme in several nondivalent ions. Ribozyme RzB is active in spermidine and Na(+) alone, although the cleavage rates are reduced by more than 1,000-fold relative to the rates observed in Mg(2+) and in transition metal ions. The trivalent cobalt hexammine (CoHex) ion is often used as an exchange-inert analog of hydrated magnesium ion. Trans-cleavage rates exceeded 8 min(-1) in 20 mM CoHex, which promoted cleavage through outersphere interactions. The stimulation of catalysis afforded by the tertiary structural interactions within RzB does not require Mg(2+), unlike other extended hammerhead ribozymes. Site-specific interaction with at least one Mg(2+) ion is suggested by CoHex competition experiments. In the presence of a constant, low concentration of Mg(2+), low concentrations of CoHex decreased the rate by two to three orders of magnitude relative to the rate in Mg(2+) alone. Cleavage rates increased as CoHex concentrations were raised further, but the final fraction cleaved was lower than what was observed in CoHex or Mg(2+) alone. These observations suggest that Mg(2+) and CoHex compete for binding and that they cause misfolded structures when they are together. The results of this study support the existence of an alternate catalytic mechanism used by nondivalent ions (especially CoHex) that is distinct from the one promoted by divalent metal ions, and they imply that divalent metals influence catalysis through a specific nonstructural role.     

A re-investigation of the thio effect at the hammerhead cleavage site.

The effect of introducing a phosphorothioate at the hammerhead cleavage site was investigated using a kinetically well-characterized hammerhead. In buffers containing Mg ion, the RP-phosphorothioate isomer cleaved 2000- to 80 000-fold slower than the SPisomer or the unmodified RNA substrate. Addition of low concentrations of several thiophilic metal ions, especially Cd2+, to these reactions is sufficient to fully restore the cleavage rate of the RPsubstrate without affecting cleavage rate of the all-oxygen or SPsubstrate. Thus, a model proposing coordination of a divalent metal ion to the pro-R oxygen at the hammerhead cleavage site appears justified.     

Significant change in the structure of a ribozyme upon introduction of a phosphorothioate linkage at P9: NMR reveals a conformational fluctuation in the core region of a hammerhead ribozyme

A modified hammerhead ribozyme (R32S) with a phosphorothioate linkage between G(8) and A(9), a site that is considered to play a crucial role in catalysis, was examined by high-resolution 1H and (31)P nuclear magnetic resonance (NMR) spectroscopy. Signals due to imino protons that corresponded to stems were observed, but the anticipated signals due to imino protons adjacent to the phosphorothioate linkage were not detected and the (31)P signal due to the phosphorothioate linkage was also absent irrespective of the presence or absence of the substrate. (31)P NMR is known to reflect backbone mobility, and thus the absence of signals indicated that the introduction of sulfur at P9 had increased the mobility of the backbone near the phosphorothioate linkage. The addition of metal ions did not regenerate the signals that had disappeared, a result that implied that the structure of the core region of the hammerhead ribozyme had fluctuated even in the presence of metal ions. Furthermore, kinetic analysis suggested that most of the R32S-substrate complexes generated in the absence of Mg(2+) ions were still in an inactive form and that Mg(2+) ions induced a further conformational change that converted such complexes to an activated state. Finally, according to available NMR studies, signals due to the imino protons of the central core region that includes the P9 metal binding site were broadened or not observed, suggesting that this catalytically important region might be intrinsically flexible. Our present analysis revealed a significant change in the structure of the ribozyme upon the introduction of the single phosphorothioate linkage at P9 that is in general considered to be a conservative modification.     

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.     

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.     

Comparison of metal-ion-dependent cleavages of RNA by a DNA enzyme and a hammerhead ribozyme

Joyce's DNA enzyme catalyzes cleavage of RNAs with almost the same efficiency as the hammerhead ribozyme. The cleavage activity of the DNA enzyme was pH dependent, and the logarithm of the cleavage rate increased linearly with pH from pH 6 to pH 9 with a slope of approximately unity. The existence of an apparent solvent isotope effect, with cleavage of RNA by the DNA enzyme in H(2)O being 4.3 times faster than cleavage in D(2)O, was in accord with the interpretation that, at a given pH, the concentration of the active species (deprotonated species) is 4.3 times higher in H(2)O than the concentration in D(2)O. This leads to the intrinsic isotope effect of unity, demonstrating that no proton transfer occurs in the transition state in reactions catalyzed by the DNA enzyme. Addition of La(3+) ions to the Mg(2+)-background reaction mixture inhibited the DNA enzyme-catalyzed reactions, suggesting the replacement of catalytically and/or structurally important Mg(2+) ions by La(3+) ions. Similar kinetic features of DNA enzyme mediated cleavage of RNA and of hammerhead ribozyme-mediated cleavage suggest that a very similar catalytic mechanism is used by the two types of enzyme, despite their different compositions.     

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)     

Long-range tertiary interactions in single hammerhead ribozymes bias motional sampling toward catalytically active conformations

Enzymes generally are thought to derive their functional activity from conformational motions. The limited chemical variation in RNA suggests that such structural dynamics may play a particularly important role in RNA function. Minimal hammerhead ribozymes are known to cleave efficiently only in ～ 10-fold higher than physiologic concentrations of Mg(2+) ions. Extended versions containing native loop-loop interactions, however, show greatly enhanced catalytic activity at physiologically relevant Mg(2+) concentrations, for reasons that are still ill-understood. Here, we use Mg(2+) titrations, activity assays, ensemble, and single molecule fluorescence resonance energy transfer (FRET) approaches, combined with molecular dynamics (MD) simulations, to ask what influence the spatially distant tertiary loop-loop interactions of an extended hammerhead ribozyme have on its structural dynamics. By comparing hammerhead variants with wild-type, partially disrupted, and fully disrupted loop-loop interaction sequences we find that the tertiary interactions lead to a dynamic motional sampling that increasingly populates catalytically active conformations. At the global level the wild-type tertiary interactions lead to more frequent, if transient, encounters of the loop-carrying stems, whereas at the local level they lead to an enrichment in favorable in-line attack angles at the cleavage site. These results invoke a linkage between RNA structural dynamics and function and suggest that loop-loop interactions in extended hammerhead ribozymes-and Mg(2+) ions that bind to minimal ribozymes-may generally allow more frequent access to a catalytically relevant conformation(s), rather than simply locking the ribozyme into a single active state.     

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.     

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.     

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.     

A 2'-methyl or 2'-methylene group at G+1 in precursor tRNA interferes with Mg2+ binding at the enzyme-substrate interface in E-S complexes of E. coli RNase P

We analyzed processing of precursor tRNAs carrying a single 2'-deoxy, 2'-OCH(3), or locked nucleic acid (LNA) modification at G+1 by Escherichia coli RNase P RNA in the absence and presence of its protein cofactor. The extra methyl or methylene group caused a substrate binding defect, which was rescued at higher divalent metal ion (M(2+)) concentrations (more efficiently with Mn(2+) than Mg(2+)), and had a minor effect on cleavage chemistry at saturating M(2+) concentrations. The 2'-OCH(3) and LNA modification at G+1 resulted in higher metal ion cooperativity for substrate binding to RNase P RNA without affecting cleavage site selection. This indicates disruption of an M(2+) binding site in enzyme-substrate complexes, which is compensated for by occupation of alternative M(2+) binding sites of lower affinity. The 2'-deoxy modification at G+1 caused at most a two-fold decrease in the cleavage rate; this mild defect relative to 2'-OCH(3) and LNA at G+1 indicates that the defect caused by the latter two is steric in nature. We propose that the 2'-hydroxyl at G+1 in the substrate is in the immediate vicinity of the M(2+) cluster at the phosphates of A67 to U69 in helix P4 of E. coli RNase P RNA.     

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.     

Selection of novel Mg(2+)-dependent self-cleaving ribozymes.

Four RNA motifs are known that catalyse site-specific cleavage in the presence of Mg2+ ions, all discovered in natural RNAs. In a single in vitro selection experiment we have isolated representatives of five novel classes of Mg(2+)-dependent ribozymes. Small versions of three of these showed that a very simple internal loop type of secondary structure is responsible for the activity. One of these was synthesized in a bimolecular form, and compared directly with the hammerhead ribozyme; for the new ribozyme, the cleavage step of the reaction is much faster than the spontaneous rate of phosphodiester bond cleavage, yet substantially slower than that for the hammerhead. The results suggest that many more Mg(2+)-dependent self-cleaving RNA sequences can be found.     

Substitution of the 2'-hydroxyl group at position 2.1 by an amino group interferes with Mg(2+) binding and efficient cleavage by hammerhead ribozyme.

Recently we have demonstrated that hammerhead ribozymes can be fully substituted with 2'-amino pyrimidines without detriment to the catalytic activity, provided that positions 2.2 and/or 2.1 are not modified. We now report on the potential molecular mechanisms by which 2'-amino groups at these positions inhibit the ribozyme cleavage activity. In the presence of Mg(2+), the 2'-amino modification at positions 2.2 and/or 2.1 had no significant effect on substrate binding. Detailed analysis of the ribozyme initial cleavage rates in the presence of various Mg(2+) concentrations indicated that Mg(2+) binding is inhibited by the 2'-amino group at position 2.1. Furthermore, preannealed substrate molecules to the modified ribozyme are not effectively cleaved upon Mg(2+) addition, indicating an alteration of the ribozyme cleavage step. Surprisingly, the cleavage activity of the modified ribozymes was substantially increased when Mg(2+) ions were replaced by the thiophilic Mn(2+) ions, whereas only a moderate cleavage enhancement occurred with its unmodified version. Taken together, our findings indicate that changes in the sugar at position 2.1 alter Mg(2+)-promoting ribozyme cleavage.     

Diffusely bound Mg2+ ions slightly reorient stems I and II of the hammerhead ribozyme to increase the probability of formation of the catalytic core

The hammerhead ribozyme is one of the best-studied small RNA enzymes, yet is mechanistically still poorly understood. We measured the Mg(2+) dependencies of folding and catalysis for two distinct hammerhead ribozymes, HHL and HH alpha. HHL has three long helical stems and was previously used to characterize Mg(2+)-induced folding. HH alpha has shorter stems and an A.U tandem next to the cleavage site that increases activity approximately 10-fold at 10 mM Mg(2+). We find that both ribozymes cleave with fast rates (5-10 min(-1), at pH 8 and 25 degrees C) at nonphysiologically high Mg(2+) concentrations, but with distinct Mg(2+) dissociation constants for catalysis: 90 mM for HHL and 10 mM for HH alpha. Using time-resolved fluorescence resonance energy transfer, we measured the stem I-stem II distance distribution as a function of Mg(2+) concentration, in the presence and absence of 100 mM Na(+), at 4 and 25 degrees C. Our data show two structural transitions. The larger transition (with Mg(2+) dissociation constants in the physiological range of approximately 1 mM, below the catalytic dissociation constants) brings stems I and II close together and is hindered by Na(+). The second, globally minor, rearrangement coincides with catalytic activation and is not hindered by Na(+). Additionally, the more active HH alpha exhibits a higher flexibility than HHL under all conditions. Finally, both ribozyme-product complexes have a bimodal stem I-stem II distance distribution, suggesting a fast equilibrium between distinct conformers. We propose that the role of diffusely bound Mg(2+) is to increase the probability of formation of a properly aligned catalytic core, thus compensating for the absence of naturally occurring kissing-loop interactions.     

Importance of the +73/294 interaction in Escherichia coli RNase P RNA substrate complexes for cleavage and metal ion coordination

We have studied an interaction, the "73/294-interaction", between residues 294 in M1 RNA (the catalytic subunit of Escherichia coli RNase P) and +73 in the tRNA precursor substrate. The 73/294-interaction is part of the "RCCA-RNase P RNA interaction", which anchors the 3' R(+73)CCA-motif of the substrate to M1 RNA (interacting residues underlined). Considering that in a large fraction of tRNA precursors residue +73 is base-paired to nucleotide -1 immediately 5' of the cleavage site, formation of the 73/294-interaction results in exposure of the cleavage site. We show that the nature/orientation of the 73/294-interaction is important for cleavage site recognition and cleavage efficiency. Our data further suggest that this interaction is part of a metal ion-binding site and that specific chemical groups are likely to act as ligands in binding of Mg(2+) or other divalent cations important for function. We argue that this Mg(2+) is involved in metal ion cooperativity in M1 RNA-mediated cleavage. Moreover, we suggest that the 73/294-interaction operates in concert with displacement of residue -1 in the substrate to ensure efficient and correct cleavage. The possibility that the residue at -1 binds to a specific binding surface/pocket in M1 RNA is discussed. Our data finally rationalize why the preferred residue at position 294 in M1 RNA is U.     

Crystal structure of the leadzyme at 1.8 A resolution: metal ion binding and the implications for catalytic mechanism and allo site ion regulation

The leadzyme is a small ribozyme, derived from in vitro selection, which catalyzes site specific, Pb(2+)-dependent RNA cleavage. Pb(2+) is required for activity; Mg(2+) inhibits activity, while many divalent and trivalent ions enhance it. The leadzyme structure consists of an RNA duplex interrupted by a trinucleotide bulge. Here, crystal structures determined to 1.8 A resolution, both with Mg(2+) as the sole divalent counterion and with Mg(2+) and Sr(2+) (which mimics Pb(2+) with respect to binding but not catalysis), reveal the metal ion interactions with both the ground state and precatalytic conformations of the leadzyme. Mg(H(2)O)(6)(2+) ions bridge complementary strands of the duplex at multiple locations by binding tandem purines of one RNA strand in the major groove. At one site, Mg(H(2)O)(6)(2+) ligates the phosphodiester backbone of the trinucleotide bulge in the ground state conformation, but not in the precatalytic conformation, suggesting (a) Mg(2+) may inhibit leadzyme activity by stabilizing the ground state and (b) metal ions which displace Mg(2+) from this site may activate the leadzyme. Binding of Sr(2+) to the presumed catalytic Pb(2+) site in the precatalytic leadzyme induces local structural changes in a manner that would facilitate alignment of the catalytic ribose 2'-hydroxyl with the scissile bond for cleavage. These data support a model wherein binding of a catalytic ion to a precatalytic conformation of the leadzyme, in conjunction with the flexibility of the trinucleotide bulge, may facilitate structural rearrangements around the scissle phosphodiester bond favoring configurations that allow bond cleavage.