Enhancement of the cleavage rates of DNA-armed hammerhead ribozymes by various divalent metal ions

Ribozyme Assays to Quantify the Capping Efficiency of In Vitro-Transcribed mRNA

The presence of the cap structure on the 5′-end of in vitro-transcribed (IVT) mRNA determines its translation and stability, underpinning its use in therapeutics. Both enzymatic and co-transcriptional capping may lead to incomplete positioning of the cap on newly synthesized RNA molecules. IVT mRNAs are rapidly emerging as novel biologics, including recent vaccines against COVID-19 and vaccine candidates against other infectious diseases, as well as for cancer immunotherapies and protein replacement therapies. Quality control methods necessary for the preclinical and clinical stages of development of these therapeutics are under ongoing development. Here, we described a method to assess the presence of the cap structure of IVT mRNAs. We designed a set of ribozyme assays to specifically cleave IVT mRNAs at a unique position and release 5′-end capped or uncapped cleavage products up to 30 nt long. We purified these products using silica-based columns and visualized/quantified them using denaturing polyacrylamide gel electrophoresis (PAGE) or liquid chromatography and mass spectrometry (LC–MS). Using this technology, we determined the capping efficiencies of IVT mRNAs with different features, which include: Different cap structures, diverse 5′ untranslated regions, different nucleoside modifications, and diverse lengths. Taken together, the ribozyme cleavage assays we developed are fast and reliable for the analysis of capping efficiency for research and development purposes, as well as a general quality control for mRNA-based therapeutics.

Influence of monovalent metal ions on metal binding and catalytic activity of the 10-23 DNAzyme

Deoxyribozymes (DNAzymes) are single-stranded DNA molecules that catalyze a broad range of chemical reactions. The 10-23 DNAzyme catalyzes the cleavage of RNA strands and can be designed to cleave essentially any target RNA, which makes it particularly interesting for therapeutic and biosensing applications. The activity of this DNAzyme in vitro is considerably higher than in cells, which was suggested to be a result of the low intracellular concentration of bioavailable divalent cations. While the interaction of the 10-23 DNAzyme with divalent metal ions was studied extensively, the influence of monovalent metal ions on its activity remains poorly understood. Here, we characterize the influence of monovalent and divalent cations on the 10-23 DNAzyme utilizing functional and biophysical techniques. Our results show that Na⁺ and K⁺ affect the binding of divalent metal ions to the DNAzyme:RNA complex and considerably modulate the reaction rates of RNA cleavage. We observe an opposite effect of high levels of Na⁺ and K⁺ concentrations on Mg²⁺- and Mn²⁺-induced reactions, revealing a different interplay of these metals in catalysis. Based on these findings, we propose a model for the interaction of metal ions with the DNAzyme:RNA complex.

Existence of efficient divalent metal ion-catalyzed and inefficient divalent metal ion-independent channels in reactions catalyzed by a hammerhead ribozyme

The hammerhead ribozyme is generally accepted as a well characterized metalloenzyme. However, the precise nature of the interactions of the RNA with metal ions remains to be fully defined. Examination of metal ion-catalyzed hammerhead reactions at limited concentrations of metal ions is useful for evaluation of the role of metal ions, as demonstrated in this study. At concentrations of Mn2+ ions from 0.3 to 3 mM, addition of the ribozyme to the reaction mixture under single-turnover conditions enhances the reaction with the product reaching a fixed maximum level. Further addition of the ribozyme inhibits the reaction, demonstrating that a certain number of divalent metal ions is required for proper folding and also for catalysis. At extremely high concentrations, monovalent ions, such as Na+ ions, can also serve as cofactors in hammerhead ribozyme-catalyzed reactions. However, the catalytic efficiency of monovalent ions is extremely low and, thus, high concentrations are required. Furthermore, addition of monovalent ions to divalent metal ion-catalyzed hammerhead reactions inhibits the divalent metal ion-catalyzed reactions, suggesting that the more desirable divalent metal ion-ribozyme complexes are converted to less desirable monovalent metal ion-ribozyme complexes via removal of divalent metal ions, which serve as a structural support in the ribozyme complex. Even though two channels appear to exist, namely an efficient divalent metal ion-catalyzed channel and an inefficient monovalent metal ion-catalyzed channel, it is clear that, under physiological conditions, hammerhead ribozymes are metalloenzymes that act via the significantly more efficient divalent metal ion-dependent channel. Moreover, the observed kinetic data are consistent with Lilley's and DeRose's two-phase folding model that was based on ground state structure analyses.

Measurements of weak interactions between truncated substrates and a hammerhead ribozyme by competitive kinetic analyses: implications for the design of new and efficient ribozymes with high sequence specificity

Exploitation of ribozymes in a practical setting requires high catalytic activity and strong specificity. The hammerhead ribozyme R32 has considerable potential in this regard since it has very high catalytic activity. In this study, we have examined how R32 recognizes and cleaves a specific substrate, focusing on the mechanism behind the specificity. Comparing rates of cleavage of a substrate in a mixture that included the correct substrate and various substrates with point mutations, we found that R32 cleaved the correct substrate specifically and at a high rate. To clarify the source of this strong specificity, we quantified the weak interactions between R32 and various truncated substrates, using truncated substrates as competitive inhibitors since they were not readily cleaved during kinetic measurements of cleavage of the correct substrate, S11. We found that the strong specificity of the cleavage reaction was due to a closed form of R32 with a hairpin structure. The self-complementary structure within R32 enabled the ribozyme to discriminate between the correct substrate and a mismatched substrate. Since this hairpin motif did not increase the Km (it did not inhibit the binding interaction) or decrease the kcat (it did not decrease the cleavage rate), this kind of hairpin structure might be useful for the design of new ribozymes with strong specificity and high activity.

A circular RNA-DNA enzyme obtained by in vitro selection

A circular RNA-DNA enzyme with higher activity to target RNA cleavage and higher stability than that of the hammerhead ribozyme in the presence of RNase A was obtained by in vitro selection. The molecule is composed of a catalytic domain of 22-mer ribonucleotides derived from the hammerhead ribozyme and a fragment of 55-mer deoxyribonucleotides. The DNA fragment contains two substrate-binding domains (9-mer and 6-mer, respectively) and a "regulation domain" (assistant 40-mer DNA with 20-mer random deoxyribonucleotides sequence), which probably play the role in the regulation of flexibility and rigidity of the circular RNA-DNA enzyme. The above results suggest that the circular RNA-DNA enzyme will have a great prospect in gene-targeting therapies.

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.

A new and efficient DNA enzyme for the sequence-specific cleavage of RNA

A new DNA enzyme, the "Bipartite DNAzyme", suitable for the sequence-specific cleavage of RNA, was obtained from a random DNA library by in vitro selection. Only a single family of catalytic molecules emerged from the selection, and a 22 nucleotide consensus sequence common to all clones defined a putative catalytic core. The most abundant clone self-cleaved at a single internal ribonucleotide phosphodiester with a relatively fast k(obs) value of 1.7 min(-1), in 10 mM MgCl(2) at 23 degrees C. This DNAzyme ("Bipartite I") required divalent cations, with magnesium and manganese most optimally supporting cleavage. A reselection from a mutagenized DNAzyme pool for the ability to cleave at extended RNA substrates yielded an unchanged catalytic core sequence. From this re-selection a DNAzyme ("Bipartite II") capable of sequence-specifically cleaving extended stretches of RNA was derived. A rate versus pH analysis of the Bipartite II DNAzyme revealed a two-phase profile, similar to that reported for the hepatitis delta virus (HDV) ribozyme, suggesting that the Bipartite II DNAzyme and the HDV ribozyme may share similar catalytic strategies. Multiple-turnover kinetics, measured in 30 mM MgCl(2), at 37 degrees C, with an HIV-1-derived RNA substrate, yielded a k(cat) value of approximately 1.4 min(-1) and a K(M) value of approximately 230 nM, which were of the same order as k(cat) and K(M )values measured for other ribozymes and DNAzymes in general use for RNA cleavage. The Bipartite DNAzyme therefore represents a new and potentially useful reagent, both for the processing of RNA transcripts in vitro and for mRNA ablation procedures in vivo.

Allosterically controllable maxizymes cleave mRNA with high efficiency and specificity

Ribozymes are small and versatile nucleic acids that can cleave RNA molecules at specific sites. However, because of the limited number of cleavable sequences on the target mRNA, in some cases conventional ribozymes do not have precise cleavage specificity. To overcome this problem, an allosteric version (a maxizyme) was developed that displayed activity and specificity in vivo. More than five custom-designed maxizymes have demonstrated sensor functions, which indicates that the technology might be broadly applicable in molecular biology and possibly in the clinic.

In vitro selection and characterization of a highly efficient Zn(II)-dependent RNA-cleaving deoxyribozyme

A group of highly efficient Zn(II)-dependent RNA-cleaving deoxyribozymes has been obtained through in vitro selection. They share a common motif with the '8-17' deoxyribozyme isolated under different conditions, including different design of the random pool and metal ion cofactor. We found that this commonly selected motif can efficiently cleave both RNA and DNA/RNA chimeric substrates. It can cleave any substrate containing rNG (where rN is any ribo-nucleotide base and G can be either ribo- or deoxy-ribo-G). The pH profile and reaction products of this deoxyribozyme are similar to those reported for hammerhead ribozyme. This deoxyribozyme has higher activity in the presence of transition metal ions compared to alkaline earth metal ions. At saturating concentrations of Zn(2+), the cleavage rate is 1.35 min(-1)at pH 6.0; based on pH profile this rate is estimated to be at least approximately 30 times faster at pH 7.5, where most assays of Mg(2+)-dependent DNA and RNA enzymes are carried out. This work represents a comprehensive characterization of a nucleic acid-based endonuclease that prefers transition metal ions to alkaline earth metal ions. The results demonstrate that nucleic acid enzymes are capable of binding transition metal ions such as Zn(2+)with high affinity, and the resulting enzymes are more efficient at RNA cleavage than most Mg(2+)-dependent nucleic acid enzymes under similar conditions.

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.

Enzymatic and antisense effects of a specific anti-Ki-ras ribozyme in vitro and in cell culture

Due to their mode of action, ribozymes show antisense effects in addition to their specific cleavage activity. In the present study we investigated whether a hammerhead ribozyme is capable of cleaving mutated Ki-ras mRNA in a pancreatic carcinoma cell line and whether antisense effects contribute to the activity of the ribozyme. A 2[prime]-O-allyl modified hammerhead ribozyme was designed to cleave specifically the mutated form of the Ki- ras mRNA (GUU motif in codon 12). The activity was monitored by RT-PCR on Ki- ras RNA expression by determination of the relative amount of wild type to mutant Ki-ras mRNA, by 5-bromo-2[prime]-deoxy-uridine incorporation on cell proliferation and by colony formation in soft agar on malignancy in the human pancreatic adenocarcinoma cell line CFPAC-1, which is heterozygous for the Ki-ras mutation. A catalytically inactive ribozyme was used as control to differentiate between antisense and cleavage activity and a ribozyme with random guide sequences as negative control. The catalytically active anti-Ki-ras ribozyme was at least 2-fold more potent in decreasing cellular Ki-ras mRNA levels, inhibiting cell proliferation and colony formation in soft agar than the catalytically inactive ribozyme. The catalytically active anti-Ki-ras ribozyme, but not the catalytically inactive or random ribozyme, increased the ratio of wild type to mutated Ki-ras mRNA in CFPAC-1 cells. In conclusion, both cleavage activity and antisense effects contribute to the activity of the catalytically active anti-Ki-ras hammerhead ribozyme. Specific ribozymes might be useful in the treatment of pancreatic carcinomas containing an oncogenic GTT mutation in codon 12 of the Ki-ras gene.

Capillary electrophoresis of RNA oligonucleotides: catalytic activity of a hammerhead ribozyme

Ribozymes are sequences of catalytic RNA that are being evaluated as possible antisense therapeutics. This paper describes how capillary electrophoresis (CE) could be used to measure the catalytic rate of a synthetic hammerhead ribozyme in cleaving its substrate. This substrate was a synthetic full-RNA 17-mer, whereas the ribozyme was made up of a mixture of 37 2'-OH and 2'-OCH3 RNA nucleotides. After experimental conditions to exclude ribonuclease contamination were successfully met, different CE modes were tried out to separate the ribozyme from its substrate. Only the combination of chemical and thermal denaturation was adequate to disrupt strong secondary structures and to inhibit comigration of the two molecules. Cleavage kinetics were measured by continuous injection from the reaction vial into a polymer-filled capillary, and by determination of the area of the shrinking substrate peak. Compared to the well-established slab gel electrophoresis, CE is at least one order of magnitude faster, may be completely automated, allows easier and more precise quantitation of results, and, due to the small scale and self-contained nature of the apparatus, reduces health risks from dangerous chemicals. Unfortunately, UV detection in a 100-microm internal diameter capillary lacked the sensitivity to perform assays in the nanomolar range, which was necessary for a full Michaelis-Menten analysis.

Effects of helical structures formed by the binding arms of DNAzymes and their substrates on catalytic activity

As a part of our efforts to clarify structure-function relationships in reactions catalyzed by deoxyribozymes (DNAzymes), which were recently selected in vitro , we synthesized various chimeras and analyzed the kinetics of the corresponding cleavage reactions. We focused on the binding arms and generated helices composed of binding arms and substrates that consisted of RNA and RNA, of RNA and DNA or of DNA and DNA. As expected for the rate limiting chemical cleavage step in reactions catalyzed by DNAzymes, a linear relationship between log( k cat) and pH was observed. In all cases examined, introduction of DNA into the binding helix enhanced the rate of chemical cleavage. Comparison of CD spectra of DNAzyme. substrate complexes suggested that higher levels of B-form-like helix were associated with higher rates of cleavage of the substrate within the complex. To our surprise, the enhancement of catalytic activity that followed introduction of DNA into the binding helix (enhancement by the presence of more B-form-like helix) was very similar to that observed in the case of the hammerhead ribozymes that we had investigated previously. These data, together with other observations, strongly suggest that the reaction mechanism of metal-ion-dependent DNAzymes is almost identical to that of hammerhead ribozymes.

A spermidine-induced conformational change of long-armed hammerhead ribozymes: ionic requirements for fast cleavage kinetics

The catalytic activity of the trans cleaving hammerhead ribozyme 2as-Rz12, with long antisense flanks of 128 and 278 nt, was tested under a wide range of different reaction conditions for in vitro cleavage of a 422 nt RNA transcript derived from human immunodeficiency virus type 1 (HIV-1). Depending on the reaction conditions, in vitro cleavage rates varied by a factor of approximately 100. Increasing concentrations of magnesium up to 1 M were found to enhance the reaction. Sodium when added simultaneously with magnesium showed an inhibitory effect on the cleavage reaction. Addition of sodium during pre-annealing, however, produced a stimulating effect. It was found that the additional inclusion of spermidine during pre-annealing further increased the reaction rate markedly. In accordance with accelerated cleavage, it was possible to identify a distinct, spermidine-induced conformer of the ribozyme-substrate complex. Under the most favourable conditions cleavage rates of 1/min were obtained, which are in the range of rates obtained for conventional hammerhead ribozymes with short antisense flanks. A comparison of thermodynamic data for short- and long-armed hammerhead ribozymes suggested that the activation entropy became unfavourable when helices I and III formed a long chain ribozyme-substrate complex. We conclude that in the absence of spermidine folding into the active conformation is impaired by increased friction of long helices, resulting in relatively low cleavage rates in vitro.

Cleavage effect of oligoribonucleotides substituted at the cleavage sites with modified pyrimidine- and purine-nucleosides

The precursor of an RNA molecule from T4-infected E. coli cells (p2Spl RNA) has the capacity to cleave itself at specific positions [UpA (139-140) and CpA (170-171)], within a putative loop and stem structure. This sequence-specific cleavage requires at least a monovalent cation and non-ionic detergents. In order to determine the influence of the pyrimidine and purine bases on these sequence-specific cleavage reactions, we studied the cleavage reactions of hairpin loop RNAs substituted at the cleavage sites with modified pyrimidine- and purine-nucleosides. The cleavage was affected by the 2'-hydroxyl groups and the bases of the pyrimidines, and the 6-amino group of the purine.

An ultraviolet crosslink in the hammerhead ribozyme dependent on 2-thiocytidine or 4-thiouridine substitution

The hammerhead domain is one of the smallest known ribozymes. Like other ribozymes it catalyzes site-specific cleavage of a phosphodiester bond. The hammerhead ribozyme has been the subject of a vast number of biochemical and structural studies aimed at determining the structure and mechanism of cleavage. Recently crystallographic analysis has produced a structure for the hammerhead. As the hammerhead is capable of undergoing cleavage within the crystal, it would appear that the crystal structure is representative of the catalytically active solution structure. However, the crystal structure conflicts with much of the biochemical data and reveals a catalytic metal ion binding site expected to be of very low affinity. Clearly, additional studies are needed to reconcile the discrepancies and provide a clear understanding of the structure and mechanism of the hammerhead ribozyme. Here we demonstrate that a unique crosslink can be induced in the hammerhead with 2-thiocytidine or 4-thiouridine substitution at different locations within the conserved core. Generation of the same crosslink with different modifications at different positions suggests that the structure trapped by the crosslink may be relevant to the catalytically active solution structure of the hammerhead ribozyme. As this crosslink appears to be incompatible with the crystal structure, this provides yet another indication that the active solution and crystal structures may differ significantly.

Use of intrinsic binding energy for catalysis by an RNA enzyme

The contribution of several individual ribozyme.substrate base pairs to binding and catalysis has been investigated using hammerhead ribozyme substrates that were truncated at their 3' or 5' ends. The base pairs at positions 1.1-2.1 and 15.2-16.2, which flank the conserved core, each contribute 10(4)-fold in the chemical step, without affecting substrate binding. In contrast, base pairs distal to the core contribute to substrate binding but have no effect on the chemical step. These results suggest a "fraying model" in which each ribozyme.substrate helix can exist in either an unpaired ("open") state or a helical ("closed") state, with the closed state required for catalysis. The base pairs directly adjacent to the conserved core contribute to catalysis by allowing the closed state to form. Once the number of base pairs is sufficient to ensure that the closed helical state predominates, additional residues provide stabilization of the helix, and therefore increase binding, but have no further effect on the chemical step. Remarkably, the >5 kcal/mol free energy contribution to catalysis from each of the internal base pairs is considerably greater than the free energy expected for formation of a base pair. It is suggested that this unusually large energetic contribution arises because free energy that is typically lost in constraining residues within a base pair is expressed in the transition state, where it is used for positioning. This extends the concept of "intrinsic binding energy" from protein to RNA enzymes, suggesting that intrinsic binding energy is a fundamental feature of biological catalysis.

Catalytic activities of hammerhead ribozymes with a triterpenoid linker instead of stem/loop II

A minizyme is a hammerhead ribozyme with short oligonucleotide linkers instead of stem/loop II. In a previous study we demonstrated that a minizyme with high-level activity forms a dimeric structure with a common stem II (Amontov and Taira, J. Am. Chem. Soc., 118 (1996) 1624-1628). As a continuation of this study, we recently examined whether a short oligonucleotide linker at stem/loop II could be replaced by a triterpenoid linker and whether the resulting minizymes with bulky hydrophobic groups would form dimeric structures. In contrast to the minizyme with high-level activity that we characterized in the previous study, minizymes that contained a triterpenoid group had low cleavage activities. The nature of the dependence of the activity on the concentration of ribozyme revealed that these minizymes with a triterpenoid group do not form dimeric structures. Thus, the low activities of these structures can be attributed to their failure to form dimers.

Selection of the best target site for ribozyme-mediated cleavage within a fusion gene for adenovirus E1A-associated 300 kDa protein (p300) and luciferase

The cellular 300 kDa protein known as p300 is a target for the adenoviral E1A oncoprotein and it is thought to participate in prevention of the G0/G1 transition during the cell cycle, in activation of certain enhancers and in the stimulation of differentiation pathways. In order to determine the exact function of p300, as a first step we constructed a simple assay system for the selection of a potential target site of a hammerhead ribozyme in vivo. For the detection of ribozyme-mediated cleavage, we used a fusion gene (p300-luc) that consisted of the sequence encoding the N-terminal region of p300 and the gene for luciferase, as the reporter gene. We were also interested in the correlation of the GUX rule, for the triplet adjacent to the cleavage site, with ribozyme activity in vivo. Therefore, we selected five target sites that all included GUX The rank order of activities in vitro indeed followed the GUX rule; with respect to the kcat, a C residue as the third base (X) was the best, next came an A residue and a U residue was the worst (GUC > GUA > GUU). However, in vivo the tRNA(Val) promoter-driven ribozyme, targeted to a GUA located upstream of the initiation codon, had the highest inhibitory effect (96%) in HeLa S3 cells when the molar ratio of the DNA template for the target p300 RNA to that for the ribozyme was 1:4. Since the rank order of activities in vivo did not conform to the GUX rule, it is unlikely that the rate limiting step for cleavage of the p300-luc mRNA was the chemical step. This kind of ribozyme expression system should be extremely useful for elucidation of the function of p300 in vivo.

Characterization of several kinds of dimer minizyme: simultaneous cleavage at two sites in HIV-1 tat mRNA by dimer minizymes

A minizyme is a hammerhead ribozyme with short oligonucleotide linkers instead of stem-loop II. In a previous study we demonstrated that a minizyme with high activity forms a dimeric structure with a common stem II. Because of their dimeric structure, minizymes are potentially capable of cleaving a substrate at two different sites simultaneously. In order to examine the properties of different kinds of minizyme, we constructed a number of minizymes with short oligonucleotide linkers (2-5 bases) instead of stem-loop II and examined their cleavage activities against HIV-1 tat mRNA. Analyses of melting curves, as well as Arrhenius plots, revealed that, in general, the longer the oligonucleotide linkers, the more stable and more active were the dimer minizymes. All minizymes examined cleaved the target substrate at two sites simultaneously. The activity of the dimer minizyme with a 5 nt linker was higher than that of the parental hammerhead ribozyme because the latter full-sized ribozyme was able to cleave at one site only.

Dependence on Mg2+ ions of the activities of dimeric hammerhead minizymes

A minizyme is a hammerhead ribozyme with short oligonucleotide linkers instead of stem/loop II. In a previous study we demonstrated that a minizyme with high-level activity forms a dimeric structure with a common stem II [Amontov and Taira (1996) J. Am. Chem. Soc. 118, 1624-1628]. We now demonstrate that the stability of the dimeric structure is influenced by Mg2+ ions. We found that the dependence on Mg2+ ions of the activity of homodimeric minizyme (a dimer with two identical binding sites) has composite biphasic characteristics. When the concentration of Mg2+ ions reached a specific critical level, the dependence on the concentration of Mg2+ ions lost its tendency to reach a plateau. In the case of the heterodimeric minizyme (a dimer with two different binding sites), we investigated the kinetic behavior of two different forms of the dimer, namely, free dimer and the complex of the dimer with an uncleavable substrate. The kinetic behavior of the free heterodimer was very similar to that of the homodimeric minizyme. In contrast, in the presence of the uncleavable substrate at a concentration as high as that of the minizyme, the curve for the dependence on Mg2+ ions showed normal saturation kinetics. While, at low concentrations of Mg2+ ions, the activity of the heterodimers was much higher when the dimeric structure was stabilized by the presence of the uncleavable substrate, at high concentrations of Mg2+ ions, this difference in activity became less and less significant. Thus, high concentrations of Mg2+ ions were able to stabilize the dimeric minizymes in the absence of the uncleavable substrate.

Magnesium-mediated conversion of an inactive form of a hammerhead ribozyme to an active complex with its substrate. An investigation by NMR spectroscopy

The effects of magnesium ions on a 32-mer ribozyme (R32) were examined by high resolution NMR spectroscopy. In solution, R32 (without its substrate) consisted of a GAAA loop, stem II, a non-Watson-Crick 3-base pair duplex and a 4-base pair duplex that included a wobble G:U base pair. When an uncleavable substrate RNA (RdC11) was added to R32 without Mg2+ ions, a complex did not form between R32 and RdC11 because the substrate recognition regions of R32 formed intramolecular base pairs (the recognition arms were closed). By contrast, in the presence of Mg2+ ions, the R32-RdC11 complex was formed. Moreover, titration of mixtures of R32 and RdC11 with Mg2+ ions also induced the ribozyme-substrate interaction. Elevated concentrations (1.0 M) of monovalent Na+ ions could not induce the formation of the R32-RdC11 complex. These data suggest that Mg2+ ions are not only important as the true catalysts in the function of ribozyme-type metalloenzymes, but they also induce the structural change in the R32 hammerhead ribozyme that is necessary for establishment of the active form of the ribozyme-substrate complex.

In vitro activity of minimised hammerhead ribozymes

A number of minimised hammerhead ribozymes (minizymes) which lack stem II have been kinetically characterised. These minizymes display optimal cleavage activity at temperatures around 37 degrees C. The cleavage reactions of the minizymes are first order in hydroxide ion concentration up to around pH 9.3 above which the cleavage rate constants decline rapidly. The reactions show a biphasic dependence on magnesium-ion concentration; one of the interactions has an apparent dissociation constant of around 20 mM while the other appears to be very weak, showing no sign of saturation at 200 mM MgCl2. The minizymes are significantly less active than comparable, full-size ribozymes when cleaving short substrates. However, at a particular site in a transcribed TAT gene from HIV-1, minizymes are more effective than ribozymes.

A comparison of the in vitro activity of DNA-armed and all-RNA hammerhead ribozymes

Hammerhead ribozymes targeted against two unrelated RNA substrates have been prepared. For each substrate, four ribozymes, differing in their hybridising arm length and composition (DNA or RNA), have been synthesised and kinetically characterised. The presence of DNA in the hybridising arms had little effect on the overall cleavage rate when the cleavage step was rate determining. Shortening each of the hybridising arms of ribozymes from 10 to 6 nucleotides generally resulted in modest changes in rate constants for cleavage of the same 13mer substrate. In one case the presence of long RNA hybridising arms significantly impeded the cleavage reaction. Cleavage rates displayed first order dependence on hydroxide ion concentration at low pHs. At higher pH, some ribozymes deviated from this first order dependence because of a change in the rate-determining step, possibly due to a requirement for a conformation change in the ribozyme-substrate complex prior to cleavage. Ribozyme cleavage was strongly dependent on temperature in the range 5-45 degrees C, with an activation energy for the reaction of approximately 60 kJ mol-1. The ribozymes displayed biphasic dependence on magnesium ion concentration; evidence of strong apparent binding (Kd approximately 10 mM) as well as a looser interaction was observed for all ribozymes.

Modified nucleoside-dependent transition metal binding to DNA analogs of the tRNA anticodon stem/loop domain

Biologically active DNA analogs of tRNAPhe (tDNAPhe) were used to investigate metal ion interaction with tRNA-like structures lacking the 2'OH. Binding of Mg2+ to the 76 oligonucleotide tDNAPhe, monitored by circular dichroism spectroscopy, increased base stacking and thus the conformational stability of the molecule. Mg2+ binding was dependent on a d(m5C) in the anticodon region. In contrast to Mg2+, Cd2+ decreased base stacking interactions, thereby destabilizing the molecule. Since alterations in the anticodon region contributed to most of the spectral changes observed, detailed studies were conducted with anticodon hairpin heptadecamers (tDNAPheAC). The conformation of tDNAPheAC-d(m5C) in the presence of 1 mM Cd2+, Co2+, Cr2+, Cu2+, Ni2+, Pb2+, VO2+ or Zn2+ differed significantly from that of the biologically active structure resulting from interaction with Mg2+, Mn2+ or Ca2+. Nanomolar concentrations of the transition metals were sufficient to denature the tDNAPheAC-d(m5C) structure without catalyzing cleavage of the oligonucleotide. In the absence of Mg2+ and at [Cd2+] to [tDNAPheAC-d(m5C)] ratios of approximately 0.2-1.0, tDNAPheAC-d(m5C40) formed a stable conformation with one Cd2+ bound with a Kd = 3.7 x 10(-7) M. In contrast to Mg2+, Cd2+ altered the DNA analogs without discriminating between modified and unmodified tDNAPheAC. This ability of transition metals to disrupt higher order DNA structures, and possibly RNA, at microM concentrations, in vitro, demonstrates that these structures are potential targets in chronic metal exposure, in vivo.

Extraordinary enhancement of the cleavage activity of a DNA-armed hammerhead ribozyme at elevated concentrations of Mg2+ ions

As part of an ongoing effort to characterize structure-function relationships, activities of all-RNA and DNA-armed hammerhead ribozymes were examined. An analysis of the dependence on the concentration of Mg2+ ions of cleavage rates revealed that, whereas the kcat of the reaction catalyzed by the all-RNA ribozyme reached a maximum value of about 18 min-1 at a concentration of about 200 mM Mg2+ ions, that of the DNA-armed ribozyme increased linearly as the concentration of Mg2+ ions was increased above 300 mM, finally reaching a value of more than 100 min-1 at 700 mM Mg2+ ions. These results suggest that the potential activity of a hammerhead ribozyme might be greater than is usually recognized.

Temperature-dependent change in the rate-determining step in a reaction catalyzed by a hammerhead ribozyme

To characterize the reaction catalyzed by a hammerhead ribozyme, the dependence on temperature of the reaction was examined. An Arrhenius plot revealed a transition that indicated a temperature-dependent change in the activation energy at around 25 degrees C. Thermodynamic parameters of the reaction were estimated at 10 and 35 degrees C. The analyses led to the following conclusions. At 25-50 degrees C, the chemical cleavage step (kcleav) was the rate-determining step, and the cleaved fragments dissociated from the ribozyme at a higher rate than the rate of the chemical reaction. When the temperature was below 25 degrees C, the cleaved fragments adhered to the ribozyme more tightly and the product dissociation step became the rate-determining step. Above 50 degrees C, the rate of the reaction decreased because, at such high temperatures, the formation of the Michaelis-Menten complex (duplex formation) was hampered by thermal melting. A conformational change in the ribozyme-substrate complex was not the rate-determining step at any of the temperatures examined.

Effects of deoxyribonucleotide substitutions in the substrate strand on hammerhead ribozyme-catalyzed reactions

In order to examine the effects of deoxyribonucleotide substitutions in the substrate strand, several chimeric DNA/RNA substrates for a hammerhead ribozyme were chemically synthesized. Measurements of kinetic parameters revealed that a chimeric DNA/RNA substrate, that contained GUC at the cleavage site as ribonucleotides, was cleaved by an all-RNA ribozyme with a threefold higher kcat than that of the wild-type (wt) reaction. Moreover, this chimeric substrate was also cleaved by a DNA-armed ribozyme that has a higher kcat than the all-RNA ribozyme [Shimayama et al., Nucleic Acids Res. 21 (1993) 2605-2611], with a fourfold higher kcat than that of the wt reaction. Km was increased stepwise by 60-fold per substitutions of the strand of stems I and III by deoxyribonucleotides. These observations demonstrate that although substitutions by deoxyribonucleotides in stems I and III decrease the affinity of substrate and ribozyme, rates of chemical cleavage are actually increased, instead of being decreased, with substitutions by deoxyribonucleotides either on the substrate side or on the ribozyme side or even on both in our system.