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

Chemoenzymatic Installation of Site-Specific Chemical Groups on DNA Enhances the Catalytic Activity

Functional DNAs are valuable molecular tools in chemical biology and analytical chemistry but suffer from low activities due to their limited chemical functionalities. Here, we present a chemoenzymatic method for site-specific installation of diverse functional groups on DNA, and showcase the application of this method to enhance the catalytic activity of a DNA catalyst. Through chemoenzymatic introduction of distinct chemical groups, such as hydroxyl, carboxyl, and benzyl, at specific positions, we achieve significant enhancements in the catalytic activity of the RNA-cleaving deoxyribozyme 10-23. A single carboxyl modification results in a 100-fold increase, while dual modifications (carboxyl and benzyl) yield an approximately 700-fold increase in activity when an RNA cleavage reaction is catalyzed on a DNA-RNA chimeric substrate. The resulting dually modified DNA catalyst, CaBn, exhibits a kobs of 3.76 min-1 in the presence of 1 mM Mg2+ and can be employed for fluorescent imaging of intracellular magnesium ions. Molecular dynamics simulations reveal the superior capability of CaBn to recruit magnesium ions to metal-ion-binding site 2 and adopt a catalytically competent conformation. Our work provides a broadly accessible strategy for DNA functionalization with diverse chemical modifications, and CaBn offers a highly active DNA catalyst with immense potential in chemistry and biotechnology.

Unraveling the Kinetics of the 10-23 RNA-Cleaving DNAzyme

DNA-based enzymes, or DNAzymes, are single-stranded DNA sequences with the ability to catalyze various chemical reactions, including the cleavage of the bond between two RNA nucleotides. Lately, an increasing interest has been observed in these RNA-cleaving DNAzymes in the biosensing and therapeutic fields for signal generation and the modulation of gene expression, respectively. Additionally, multiple efforts have been made to study the effects of the reaction environment and the sequence of the catalytic core on the conversion of the substrate into product. However, most of these studies have only reported alterations of the general reaction course, but only a few have focused on how each individual reaction step is affected. In this work, we present for the first time a mathematical model that describes and predicts the reaction of the 10-23 RNA-cleaving DNAzyme. Furthermore, the model has been employed to study the effect of temperature, magnesium cations and shorter substrate-binding arms of the DNAzyme on the different kinetic rate constants, broadening the range of conditions in which the model can be exploited. In conclusion, this work depicts the prospects of such mathematical models to study and anticipate the course of a reaction given a particular environment.

A new Pb2+-specific DNAzyme by revisiting the catalytic core of 10-23 DNAzyme

10-23 DNAzyme is a catalytic DNA molecule from in vitro selection, the 15-mer catalytic core was investigated for more DNAzyme variants by block deletions. DNAzyme DZM01 was selected with metal ion dependence of Pb²⁺ ≫ Mn²⁺, with no activity in the presence of Mg²⁺ (20 mM), Ca²⁺ (20 mM), Zn²⁺ (20 mM, pH 6). The unique binding properties of Pb²⁺ with nucleic acids might be responsible for the formation of the catalytic core, which is different from that of other divalent metal ions. More DNAzyme variants are expected to be derived for specific metal ion dependence by various nucleobase sequences and modifications.

Core modified 8-17 DNAzymes with 2'-deoxy-2'-C-methylpyrimidine nucleosides

The catalytic core of an 8-17 DNAzyme directed against STAT 3 was modified using (2'R) and (2'S) 2'-deoxy-2'-C-methyluridine and cytidine. While 2'-deoxy-2'-C-methyluridine significantly diminished the catalytic activity, 2'-deoxy-2'-C-methylcytidine replacement was better accepted, being the k_act of modified DNAzymes at 8- and 11-positions comparable to the non-modified one. When 2'-O-methyl and phosphorothioate nucleotides were tested in the binding arms together with core modified DNAzymes the k_cat was affected in a non predictable way, emphasizing the fact that both chemical substitutions should be considered globally. Finally, 2'-deoxy-2'-C-methyl modified DNAzymes stability was assayed finding that the double 2'-C-methyl modification in the catalytic core enhanced 70% the stability against a T47D cell lysate compared to a non-modified control.

Cationic copolymer enhances 8–17 DNAzyme and MNAzyme activities

Cationic copolymer acts as a chaperone to facilitate multiple strand assembly and enhance nucleic acid enzyme activities.

Biochemical and Biophysical Understanding of Metal Ion Selectivity of DNAzymes

This review summarizes research into the metal-binding properties of catalytic DNAzymes, towards the goal of understanding the structural properties leading to metal ion specificity. Progress made and insight gained from a range of biochemical and biophysical techniques are covered, and promising directions for future investigations are discussed.

Probing the effect of minor groove interactions on the catalytic efficiency of DNAzymes 8-17 and 10-23

DNAzymes (Dz) 8-17 and 10-23 are two widely studied and well-characterized RNA-cleaving DNA catalysts. In an effort to further improve the understanding of the fragile interactions and dynamics of the enzymatic mechanism, this study examines the catalytic efficiency of minimally modified DNAzymes. Five single mutants of Dz8-17 and Dz10-23 were prepared by replacing the adenine residues in the corresponding catalytic cores with 3-deazaadenine units. Kinetic assays were used to assess the effect on the catalytic activity and thereby identify the importance of hydrogen bonding that arises from the N3 atoms. The results suggest that modifications at A15 and A15.0 of Dz8-17 have a significant influence and show a reduction in catalytic activity. Modification at each location in Dz10-23 results in a decrease of the observed rate constants, with A12 appearing to be the most affected with a reduction of ∼80% of kobs and ∼25% of the maximal cleavage rate compared to the wild-type DNAzyme. On the other hand, modification of A12 in Dz8-17 showed an ∼130% increase in kobs, thus unraveling a new potential site for the introduction of chemical modifications. A pH-profile analysis showed that the chemical cleavage step is rate-determining, regardless of the presence and/or location of the mutation. These findings point towards the importance of the N3-nitrogens of certain adenine nucleotides located within the catalytic cores of the DNAzymes for efficient catalytic activity and further suggest that they might directly partake in maintaining the appropriate tertiary structure. Therefore, it appears that minor groove interactions constitute an important feature of DNAzymes as well as ribozymes.

Highly selective detection of bacterial alarmone ppGpp with an off-on fluorescent probe of copper-mediated silver nanoclusters

In this study, a facile strategy for highly selective and sensitive detection of bacterial alarmone, ppGpp, which is generated when bacteria face stress circumstances such as nutritional deprivation, has been established by developing an off-on fluorescent probe of Cu(2+)-mediated silver nanoclusters (Ag NCs). This work not only achieves highly selective detection of ppGpp in a broad range concentration of 2-200 μM, but also improves our understanding of the specific recognitions among DNA-Ag NCs, Cu(2+), and ppGpp. The present strategy, together with other reports on the Ag NCs-related analytical methods, has also identified that Ag NCs functionalized with different molecules on their surfaces can be engineered fluorescent probes for a wide range of applications such as biosensing and bioimaging.

Inhibition of HIV-1 Integrase gene expression by 10-23 DNAzyme

HIV Integrase (IN) is an enzyme that is responsible for the integration of the proviral genome into the human genome, and this integration step is the first step of the virus hijacking the human cell machinery for its propagation and replication. 10-23 DNAzyme has the potential to suppress gene expressions through sequence-specific mRNA cleavage. We have designed three novel DNAzymes, DIN54, DIN116, and DIN152, against HIV-1 Integrase gene using Mfold software and evaluated them for target site cleavage activity on the in vitro transcribed mRNA. All DNAzymes were tested for its inhibition of expression of HIV Integrase protein in the transiently transfected cell lines. DIN116 and DIN152 inhibited IN-EGFP expression by 80 percent and 70 percent respectively.

A novel strategy of chemical modification for rate enhancement of 10-23 DNAzyme: a combination of A9 position and 8-aza-7-deaza-2'-deoxyadenosine analogs

With the help of a divalent-metal ion, 10-23 DNAzyme cleaves RNA. Chemical modification of its catalytic loop to make a more efficient enzyme has been a challenge. Our strategy started from its five 2'-deoxyadenosine residues (A5, A9, A11, A12, and A15) in the loop based on the capability of the N7 atom to form hydrogen bonds in tertiary structures. 8-Aza-7-deaza-2'-deoxyadenosine and its analogs with 7-substituents (3-aminopropyl, 3-hydroxylpropyl, or phenethyl) were each used to replace five dA residues, respectively, and their effect on cleavage rate were evaluated under single-turnover conditions. The results indicated that the N7 atom of five dA residues were necessary for catalytic activity, and the N8 atom and 7-substituents were detrimental to the catalytic behavior of 10-23 DNAzyme, except that all these modifications at A9 were favourable for the activity. Especially, DZ-3-9 with 7-(3-aminopropyl)-8-aza-7-deaza-2'-deoxyadenosine (3) at A9 position gave a 12- fold increase of k(obs), compared to the corresponding parent 10-23 DNAzyme. DZ-3-9 was supposed to catalyze the cleavage reaction with the same mechanism as 10-23 DNAzyme based on their very similar pH-dependent and divalent metal ions-dependent cleavage patterns. Introduction of functional groups at A9 position was demonstrated to be a successful and feasible approach for more efficient 10-23 DNAzyme analogs.

Efficient silencing of gene expression by an ASON-bulge-DNAzyme complex

BACKGROUND

DNAzymes are DNA molecules that can directly cleave cognate mRNA, and have been developed to silence gene expression for research and clinical purposes. The advantage of DNAzymes over ribozymes is that they are inexpensive to produce and exhibit good stability. The "10-23 DNA enzyme" is composed of a catalytic domain of 15 deoxynucleotides, flanked by two substrate-recognition domains of approximately eight nucleotides in each direction, which provides the complementary sequence required for specific binding to RNA substrates. However, these eight nucleotides might not afford sufficient binding energy to hold the RNA substrate along with the DNAzyme, which would interfere with the efficiency of the DNAzyme or cause side effects, such as the cleavage of non-cognate mRNAs.

METHODOLOGY

In this study, we inserted a nonpairing bulge at the 5' end of the "10-23 DNA enzyme" to enhance its efficiency and specificity. Different sizes of bulges were inserted at different positions in the 5' end of the DNAzyme. The non-matching bulge will avoid strong binding between the DNAzyme and target mRNA, which may interfere with the efficiency of the DNAzyme.

CONCLUSIONS

Our novel DNAzyme constructs could efficiently silence the expression of target genes, proving a powerful tool for gene silencing. The results showed that the six oligo bulge was the most effective when the six oligo bulge was 12-15 bp away from the core catalytic domain.

Activity, folding and Z-DNA formation of the 8-17 DNAzyme in the presence of monovalent ions

The effect of monovalent ions on both the reactivity and global folding of the 8-17 DNAzyme is investigated, and the results are compared with those of the hammerhead ribozyme, which has similar size and secondary structure. In contrast to the hammerhead ribozyme, the 8-17 DNAzyme activity is not detectable in the presence of 4 M K(+), Rb(+), or Cs(+) or in the presence of 80 mM, [Co(NH(3))(6)](3+). Only 4 M Li(+), NH(4)(+) and, to a lesser extent, Na(+) conferred detectable activity. The observed rate constants (k(obs) approximately 10(-3) min(-1) for Li(+) and NH(4)(+)) are approximately 1000-fold lower than that in the presence of 10 mM Mg(2+), and approximately 200,000-fold slower than that in the presence of 100 microM Pb(2+). Since the hammerhead ribozyme displays monovalent ion-dependent activity that is often within approximately 10-fold of divalent metal ion-dependent activity, these results suggest that the 8-17 DNAzyme, obtained by in vitro selections, has evolved to have a more stringent divalent metal ion requirement for high activity as compared to the naturally occurring ribozymes, making the 8-17 DNAzyme an excellent choice as a Pb(2+) sensor with high selectivity. In contrast to the activity data, folding was observed in the presence of all the monovalent ions investigated, although those monovalent ions that do not support DNAzyme activity have weaker binding affinity (K(d) approximately 0.35 M for Rb(+) and Cs(+)), while those that confer DNAzyme activity possess stronger affinity (K(d) approximately 0.22 M for Li(+), Na(+) and NH(4)(+)). In addition, a correlation between metal ion charge density, binding affinity and enzyme activity was found among mono- and divalent metal ions except Pb(2+); higher charge density resulted in stronger affinity and higher activity, suggesting that the observed folding and activity is at least partially due to electrostatic interactions between ions and the DNAzyme. Finally, circular dichroism (CD) study has revealed Z-DNA formation with the monovalent metal ions, Zn(2+) and Mg(2+); the K(d) values obtained using CD were in the same range as those obtained from folding studies using FRET. However, Z-DNA formation was not observed with Pb(2+). These results indicate that Pb(2+)-dependent function follows a different mechanism from the monovalent metal ions and other divalent metal ions; in the presence of latter metal ions, metal-ion dependent folding and structural changes, including formation of Z-DNA, play an important role in the catalytic function of the 8-17 DNAzyme.

MNAzymes, a versatile new class of nucleic acid enzymes that can function as biosensors and molecular switches

To increase the versatility and utility of nucleic acid enzymes, we developed multicomponent complexes, known as MNAzymes, which produce amplified “output” signals in response to specific “input” signals. Multiple oligonucleotide partzymes assemble into active MNAzymes only in the presence of an input assembly facilitator such as a target nucleic acid. Once formed, MNAzymes catalytically modify a generic substrate, generating an amplified output signal that heralds the presence of the target while leaving the target intact. We demonstrated several applications including sensitive, isothermal target detection; discrimination of polymorphisms; and highly specific monitoring of real-time polymerase chain reaction (PCR). Furthermore, we showed their capacity to function as molecular switches and to work in series to create a molecular cascade. The modular nature of MNAzymes, together with the separation of input and output functionalities, provides potential for their integration into diverse devices such as diagnostic biosensors, molecular computers, and/or nanoscale machines.

DNAzyme-mediated catalysis with only guanosine and cytidine nucleotides

Single-stranded DNA molecules have the capacity to adopt catalytically active structures known as DNAzymes, although the fundamental limits of this ability have not been determined. Starting with a parent DNAzyme composed of all four types of standard nucleotides, we conducted a search of the surrounding sequence space to identify functional derivatives with catalytic cores composed of only three, and subsequently only two types of nucleotides. We provide the first report of a DNAzyme that contains only guanosine and cytidine deoxyribonucleotides in its catalytic domain, which consists of just 13 nucleotides. This DNAzyme catalyzes the Mn(2+)-dependent cleavage of an RNA phosphodiester bond approximately 5300-fold faster than the corresponding uncatalyzed reaction, but approximately 10,000-fold slower than the parent. The demonstration of a catalytic DNA molecule made from a binary nucleotide alphabet broadens our understanding of the fundamental limits of nucleic-acid-mediated catalysis.

Catalytic DNAzymes: derivations and functions

BACKGROUND

Although catalytic RNA enzymes (CRzs) are naturally occurring in many organisms, their DNA counterparts (CDzs) were developed by in vitro selection/evolution from random sequence libraries.

OBJECTIVE

To provide a brief overview of how CDzs have been selected in vitro, and of their properties and functions, as well as their possible future utility.

METHODS

We concentrated on examples of 'direct' selection of CDzs. Many CDzs have been used in biological settings, for example downregulation of target mRNAs, while many more recent applications use CDzs in biosensor and nanotechnology settings.

CONCLUSIONS

Although much work has concentrated on using CDzs for regulating gene expression, their potential as nucleic acid medicines has diminished substantially, supplanted by simple antisense oligonucleotides and, more recently, by small interfering RNAs (siRNAs). It seems unlikely that CDzs will have clinical utility. In contrast, they are likely to have significant potential in the sensor/nanotechnology arena.

1,3,2-Oxathiaphospholane approach to the synthesis of P-chiral stereodefined analogs of oligonucleotides and biologically relevant nucleoside polyphosphates

Among the various classes of modified nucleotides and oligonucleotides, phosphorothioate analogs, in which the sugar-phosphate backbone is modified by the substitution of a sulfur atom for one of the nonbridging oxygen atoms, have been most extensively studied in both in vitro and in vivo experiments. However, this substitution induces P-chirality of the dinucleoside phosphorothioate moiety. Consequently, even short phosphorothioate oligonucleotides synthesized using standard chemical methods exist as mixtures of many diastereoisomers. In our laboratory, the oxathiaphospholane (OTP) method has been developed for a stereocontrolled synthesis of oligo(deoxyribonucleoside phosphorothioate)s. Recently, this approach has been extended to ribonucleoside derivatives, and stereodefined phosphorothioate diribonucleotides were incorporated into oligomers suitable for mechanistic studies on deoxyribozymes. Next, it was found that the OTP ring can be opened with nucleophiles as weak as the phosphate or pyrophosphate anion, giving rise to nucleoside α-thiopolyphosphates. Surprisingly, the reaction between nucleoside OTP and O,O-dialkyl H-phosphonate or O,O-dialkyl H-phosphonothioate led to nucleoside 5'-O-(α-thio-β-O,O-dialkyl-hypophosphate) or 5'-O-(α,β-dithio-β-O,O-dialkyl-hypophosphate), respectively, i.e., derivatives containing a direct P-P bond.

Design and switch of catalytic activity with the DNAzyme-RNAzyme combination

Design and switch of catalytic activity in enzymology remains a subject of intense investigation. Here, we employ a DNAzyme-RNAzyme combination strategy for construction of a 10-23 deoxyribozyme-hammerhead ribozyme combination that targets different sites of the beta-lactamase mRNA. The 10-23 deoxyribozyme-hammerhead ribozyme combination gene was cloned into phagemid vector pBlue-scriptIIKS (+). In vitro the single-strand recombinant phagemid vector containing the combination sequence exhibited 10-23 deoxyribozyme activity, and the linear transcript displayed hammerhead ribozyme activity. In bacteria, the 10-23 deoxyribozyme-hammerhead ribozyme combination inhibited the beta-lactamase expression and repressed the growth of drug-resistant bacteria. Thus, we created a DNAzyme-RNAzyme combination strategy that provides a useful approach to design and switch of catalytic activities for nucleic acid enzymes.

Mapping of the functional phosphate groups in the catalytic core of deoxyribozyme 10-23

The RNA phosphodiester bond cleavage activity of a series of 16 thio-deoxyribozymes 10-23, containing a P-stereorandom single phosphorothioate linkage in predetermined positions of the catalytic core from P1 to P16, was evaluated under single-turnover conditions in the presence of either 3 mM Mg(2+) or 3 mM Mn(2+). A metal-specificity switch approach permitted the identification of nonbridging phosphate oxygens (proR(P) or proS(P)) located at seven positions of the core (P2, P4 and P9-13) involved in direct coordination with a divalent metal ion(s). By contrast, phosphorothioates at positions P3, P6, P7 and P14-16 displayed no functional relevance in the deoxyribozyme-mediated catalysis. Interestingly, phosphorothioate modifications at positions P1 or P8 enhanced the catalytic efficiency of the enzyme. Among the tested deoxyribozymes, thio-substitution at position P5 had the largest deleterious effect on the catalytic rate in the presence of Mg(2+), and this was reversed in the presence of Mn(2+). Further experiments with thio-deoxyribozymes of stereodefined P-chirality suggested direct involvement of both oxygens of the P5 phosphate and the proR(P) oxygen at P9 in the metal ion coordination. In addition, it was found that the oxygen atom at C6 of G(6) contributes to metal ion binding and that this interaction is essential for 10-23 deoxyribozyme catalytic activity.

Systematic analysis of the role of target site accessibility in the activity of DNA enzymes

We employed an approach using oligonucleotide scanning arrays and computational analysis to conduct a systematic analysis of the interaction between catalytic nucleic acids (DNA enzymes or DNAzymes) and long RNA targets. A radio-labelled transcript representing mRNA of Xenopus cyclin B5 was hybridised to an array of oligonucleotides scanning the first 120 nucleotides of the coding region to assess the ability of the immobilised oligonucleotides to form heteroduplexes with the target. The hybridisation revealed oligonucleotides showing varying levels of signal intensities along the length of the array, reflecting on the variable accessibility of the corresponding complementary regions in the target RNA. Deoxyribozymes targeting a number of these regions were selected and tested for their ability to cleave the target RNA. The mRNA cleavage observed indicates that indeed target accessibility was an important component in the activity of deoxyribozymes and that it was important that at least one of the two binding arms was complementary to an accessible site. Computational analysis suggested that intra-molecular folding of deoxyribozymes into stable structures may also negatively contribute to their activity. 10-23 type deoxyribozymes generally appeared more active than 8-17 type and it was possible to predict deoxyribozymes with high cleavage efficiency using scanning array hybridization and computational analysis as guides. The data presented here therefore have implications on designing effective DNA enzymes.

Locked nucleoside analogues expand the potential of DNAzymes to cleave structured RNA targets

BACKGROUND

DNAzymes cleave at predetermined sequences within RNA. A prerequisite for cleavage is that the DNAzyme can gain access to its target, and thus the DNAzyme must be capable of unfolding higher-order structures that are present in the RNA substrate. However, in many cases the RNA target sequence is hidden in a region that is too tightly structured to be accessed under physiological conditions by DNAzymes.

RESULTS

We investigated how incorporation of LNA (locked nucleic acid) monomers into DNAzymes improves their ability to gain access and cleave at highly-structured RNA targets. The binding arms of DNAzymes were varied in length and were substituted with up to three LNA and alpha-L-LNA monomers (forming LNAzymes). For one DNAzyme, the overall cleavage reaction proceeded fifty times faster after incorporation of two alpha-L-LNA monomers per binding arm (kobs increased from 0.014 min-1 to 0.78 min-1).

CONCLUSION

The data demonstrate how hydrolytic performance can be enhanced by design of LNAzymes, and indicate that there are optimal lengths for the binding arms and for the number of modified LNA monomers.

In vitro selection, characterization, and application of deoxyribozymes that cleave RNA

Over the last decade, many catalytically active DNA molecules (deoxyribozymes; DNA enzymes) have been identified by in vitro selection from random-sequence DNA pools. This article focuses on deoxyribozymes that cleave RNA substrates. The first DNA enzyme was reported in 1994 and cleaves an RNA linkage. Since that time, many other RNA-cleaving deoxyribozymes have been identified. Most but not all of these deoxyribozymes require a divalent metal ion cofactor such as Mg²⁺ to catalyze attack by a specific RNA 2′-hydroxyl group on the adjacent phosphodiester linkage, forming a 2′,3′-cyclic phosphate and a 5′-hydroxyl group. Several deoxyribozymes that cleave RNA have utility for in vitro RNA biochemistry. Some DNA enzymes have been applied in vivo to degrade mRNAs, and others have been engineered into sensors. The practical impact of RNA-cleaving deoxyribozymes should continue to increase as additional applications are developed.

Design of efficient DNAzymes against muscle AChR alpha-subunit cRNA in vitro and in HEK 293 cells

DNAzymes are catalytic DNA which bind to target RNA by complementary sequence arms on a Watson-Crick basis and cleave RNA at specific sites. Potential therapeutic applications require DNAzymes that can efficiently cleave their target. Here we investigate factors affecting DNAzyme cleavage efficacy against the muscle acetylcholine receptor (AChR) alpha-subunit. The 10-23 DNAzymes cleave at Y-R nucleotide motifs, where R is A or G, and Y is U or C. Targeting a series of sites within different regions of the full-coding length cRNA under simulated physiological conditions found that the most efficient motifs for cleavage were in the hierarchy: GU >/= AU > GC >>> AC. This order is consistent with the kinetic analysis of short synthetic RNA substrates that have the same binding arms but different cleavage sites. DNAzymes with longer symmetric binding arms were more efficient than those with shorter arms, while asymmetric DNAzymes with a longer arm I were also more efficient, suggesting a dominant role for arm I in determining cleavage activity. Modification of one DNAzyme by inverted thymidine (iT) or locked nucleic acids (LNA) showed the LNA-modified DNAzyme gave efficient silencing of AChR expression in HEK 293 cells. Our data demonstrate the usefulness of screening in vitro for an efficient DNAzyme prior to cellular applications.

Rapid preparation of RNA samples for NMR spectroscopy and X-ray crystallography

Knowledge of the three-dimensional structures of RNA and its complexes is important for understanding the molecular mechanism of RNA recognition by proteins or ligands. Enzymatic synthesis using T7 bacteriophage RNA polymerase is used to prepare samples for NMR spectroscopy and X-ray crystallography. However, this run-off transcription method results in heterogeneity at the RNA 3-terminus. For structural studies, RNA purification requires a single nucleotide resolution. Usually PAGE purification is used, but it is tedious, time-consuming and cost ineffective. To overcome these problems in high-throughput RNA synthesis, we devised a method of RNA preparation that uses trans-acting DNAzyme and sequence-specific affinity column chromatography. A tag sequence is added at the 3' end of RNA, and the tagged RNA is picked out using an affinity column that contains the complementary DNA sequence. The 3' end tag is then removed by sequence-specific cleavage using trans-acting DNAzyme, the arm lengths of which are optimized for turnover number. This purification method is simpler and faster than the conventional method.

A novel replicating circular DNAzyme

10-23 DNAzyme has the potential to suppress gene expressions through sequence-specific mRNA cleavage. However, the dependence on exogenous delivery limits its applications. The objective of this work is to establish a replicating DNAzyme in bacteria using a single-stranded DNA vector. By cloning the 10-23 DNAzyme into the M13mp18 vector, we constructed two circular DNAzymes, C-Dz7 and C-Dz482, targeting the beta-lactamase mRNA. These circular DNAzymes showed in vitro catalytic efficiencies (kcat/K(M)) of 7.82 x 10(6) and 1.36 x 10(7) M(-1) x min(-1), respectively. Their dependence on divalent metal ions is similar to that found with linear 10-23 DNAzyme. Importantly, the circular DNAzymes were not only capable of replicating in bacteria but also exhibited high activities in inhibiting beta-lactamase and bacterial growth. This study thus provides a novel strategy to produce replicating DNAzymes which may find widespread applications.

Inhibition of Ampicillin-Resistant Bacteria by Novel Mono-DNAzymes and Di-DNAzyme Targeted to β-Lactamase mRNA

In view of the weakness of antibiotics and the properties of antisense drugs, we applied DNAzymes to the field of drug resistance in bacteria. Two 10-23 mono-DNAzymes (Dz1, Dz2) and a di-DNAzyme (Dz1-2) targeted to beta-lactamase mRNA were designed to determine to what degree the growth of ampicillin-resistant bacteria (TEM-1, TEM-3) was inhibited. All three DNAzymes can play a role both in vitro and in vivo. In vitro, they exhibited high catalytic efficiency (kcat/KM) of 63.5, 91.1, and 30.8 pM(-1) min(-1), respectively, under multiple-turnover conditions. In vivo, after 9 hours' incubation, the degree of inhibition of Dz1, Dz2, and Dz1-2 for TEM-1 bacteria was 27.2%, 39.6%, and 57.7%, respectively, and that for TEM-3 bacteria was 39.1%, 44%, and 62.6%, respectively. Dz1-2 showed the greatest inhibiting effect, demonstrating in vivo activity may be increased by constructing multiple-target DNAzymes. The results indicated a potential possibility for DNAzymes to act as a new type of antibacterial or a tool of gene functional analysis for prokaryocytes.

Kinetic and thermodynamic characterization of the RNA-cleaving 8-17 deoxyribozyme

The 8-17 deoxyribozyme is a small DNA catalyst of significant applicative interest. We have analyzed the kinetic features of a well behaved 8-17 construct and determined the influence of several reaction conditions on such features, providing a basis for further exploration of the deoxyribozyme mechanism. The 8-17 bound its substrate with a rate constant approximately 10-fold lower than those typical for the annealing of short complementary oligonucleotides. The observed free energy of substrate binding indicates that an energetic penalty near to +7 kcal/mol is attributable to the deoxyribozyme core. Substrate cleavage required divalent metal ion cofactors, and the dependence of activity on the concentration of Mg2+, Ca2+ or Mn2+ suggests the occurrence of a single, low-specificity binding site for activating ions. The efficiency of activation correlated with the Lewis acidity of the ion cofactor, compatible with a metal-assisted deprotonation of the reactive 2'-hydroxyl group. However, alternative roles of the metal ions cannot be excluded, because those ions that are stronger Lewis acids are also capable of forming stronger interactions with ligands such as the phosphate oxygens. The apparent enthalpy of activation for the 8-17 reaction was close to the values observed for hydroxide-catalyzed and hammerhead ribozyme-catalyzed RNA cleavage.

RNA cleaving '10-23' DNAzymes with enhanced stability and activity

'10-23' DNAzymes can be used to cleave any target RNA in a sequence-specific manner. For applications in vivo, they have to be stabilised against nucleolytic attack by the introduction of modified nucleotides without obstructing cleavage activity. In this study, we optimise the design of a DNAzyme targeting the 5'-non-translated region of the human rhinovirus 14, a common cold virus, with regard to its kinetic properties and its stability against nucleases. We compare a large number of DNAzymes against the same target site that are stabilised by the use of a 3'-3'-inverted thymidine, phosphorothioate linkages, 2'-O-methyl RNA and locked nucleic acids, respectively. Both cleavage activity and nuclease stability were significantly enhanced by optimisation of arm length and content of modified nucleotides. Furthermore, we introduced modified nucleotides into the catalytic core to enhance stability against endonucleolytic degradation without abolishing catalytic activity. Our findings enabled us to establish a design for DNAzymes containing nucleotide modifications both in the binding arms and in the catalytic core, yielding a species with up to 10-fold enhanced activity and significantly elevated stability against nucleolytic cleavage. When transferring the design to a DNAzyme against a different target, only a slight modification was necessary to retain activity.

Structural rearrangements of the 10-23 DNAzyme to beta 3 integrin subunit mRNA induced by cations and their relations to the catalytic activity

The intracellular ability of the "10-23" DNAzyme to efficiently inhibit expression of targeted proteins has been evidenced by in vitro and in vivo studies. However, standard conditions for kinetic measurements of the DNAzyme catalytic activity in vitro include 25 mM Mg2+, a concentration that is very unlikely to be achieved intracellularly. To study this discrepancy, we analyzed the folding transitions of the 10-23 DNAzyme induced by Mg2+. For this purpose, spectroscopic analyzes such as fluorescence resonance energy transfer, fluorescence anisotropy, circular dichroism, and surface plasmon resonance measurements were performed. The global geometry of the DNAzyme in the absence of added Mg2+ seems to be essentially extended, has no catalytic activity, and shows a very low binding affinity to its RNA substrate. The folding of the DNAzyme induced by binding of Mg2+ may occur in several distinct stages. The first stage, observed at 0.5 mM Mg2+, corresponds to the formation of a compact structure with limited binding properties and without catalytic activity. Then, at 5 mM Mg2+, flanking arms are projected at right position and angles to bind RNA. In such a state, DNAzyme shows substantial binding to its substrate and significant catalytic activity. Finally, the transition occurring at 15 mM Mg2+ leads to the formation of the catalytic domain, and DNAzyme shows high binding affinity toward substrate and efficient catalytic activity. Under conditions simulating intracellular conditions, the DNAzyme was only partially folded, did not bind to its substrate, and showed only residual catalytic activity, suggesting that it may be inactive in the transfected cells and behave like antisense oligodeoxynucleotide.

Exponential growth by cross-catalytic cleavage of deoxyribozymogens

We have designed an autocatalytic cycle based on the highly efficient 10-23 RNA-cleaving deoxyribozyme that is capable of exponential amplification of catalysis. In this system, complementary 10-23 variants were inactivated by circularization, creating deoxyribozymogens. Upon linearization, the enzymes can act on their complements, creating a cascade in which linearized species accumulate exponentially. Seeding the system with a pool of linear catalysts resulted not only in amplification of function but in sequence selection and represents an in vitro selection experiment conducted in the absence of any protein enzymes.

LNAzymes: incorporation of LNA-type monomers into DNAzymes markedly increases RNA cleavage

Incorporation of two alpha-L-LNA/LNA nucleotides into each of the two binding arms of a "10-23" DNAzyme has been accomplished and the RNA cleavage with these novel LNAzymes studied. In comparison with the unmodified DNAzyme, the LNAzymes show significantly improved cleavage of the phosphodiester backbone at the target nucleotide in a small RNA substrate (58n RNA) under single-turnover conditions. The LNAzymes show efficient multiple turnover. With the LNAzymes, efficient cleavage was accomplished also of a naturally occurring ribosomal RNA at a target site within a highly structured region. The reference DNAzyme was ineffective at cleaving the ribosomal RNA target.

Molecular tryst peeping: detection of interactions between nonlabeled nucleic acids by fluorescence resonance energy transfer

We have developed a new method for monitoring the interactions between nonlabeled RNAs that involves detection of fluorescence resonance energy transfer (FRET) between two DNA probes with different fluorescent label. The sequences of the probes are complementary to those of the RNAs. In this study, we examined the interaction between a portion of the LTR RNA of HIV-1 and the corresponding antisense RNA. The antisense RNA was designed not to bind to the fluorescent DNA without prior hybridization to the target RNA. A mixture of RNAs and DNA probes with fluorescent labels was fractionated by electrophoresis on a nondenaturing polyacrylamide gel and then the gel was analyzed with a fluorescence imaging analyzer. FRET was observed only in the presence of target RNA, antisense RNA, and both of the fluorescent DNA probes. This strategy should be useful for the detection of interactions between nucleic acids that cannot be subjected to chemical modification, such as RNA transcripts inside cells.

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.

Nucleic acid mutation analysis using catalytic DNA

The sequence specificity of the '10-23' RNA-cleaving DNA enzyme (deoxyribozyme) was utilised to discriminate between subtle differences in nucleic acid sequence in a relatively conserved segment of the L1 gene from a number of different human papilloma virus (HPV) genotypes. DNA enzymes specific for the different HPV types were found to cleave their respective target oligoribonucleotide substrates with high efficiency compared with their unmatched counterparts, which were usually not cleaved or cleaved with very low efficiency. This specificity was achieved despite the existence of only very small differences in the sequence of one binding arm. As an example of how this methodology may be applied to mutation analysis of tissue samples, type-specific deoxyribozyme cleavable substrates were generated by genomic PCR using a chimeric primer containing three bases of RNA. The RNA component enabled each amplicon to be cleavable in the presence of its matching deoxyribozyme. In this format, the specificity of deoxyribozyme cleavage is defined by Watson-Crick interactions between one substrate-binding domain (arm I) and the polymorphic sequence which is amplified during PCR. Deoxy-ribozyme-mediated cleavage of amplicons generated by this method was used to examine the HPV status of genomic DNA derived from Caski cells, which are known to be positive for HPV16. This method is applicable to many types of nucleic acid sequence variation, including single nucleotide polymorphisms.

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.

Deoxyribozymes: new players in the ancient game of biocatalysis

The repetitive and extraordinarily stable polynucleotide chains of DNA serve as an ideal storage system for genetic information. Although it is best known for its helical structure and relatively inert character, in vitro selection can be used to compel DNA to perform a surprising variety of chemical reactions. These artificial DNA enzymes or 'deoxyribozymes' generate large chemical rate enhancements and demonstrate precise substrate recognition, much like their protein and RNA counterparts. Recent studies with these prototypic deoxyribozymes indicate that DNA has a substantial untapped potential for intricate structure formation that could be exploited in novel chemical and biological catalysis.

Extremely high and specific activity of DNA enzymes in cells with a Philadelphia chromosome

BACKGROUND

Chronic myelogenous leukemia (CML) results from chromosome 22 translocations (the Philadelphia chromosome) that creates BCR-ABL fusion genes, which encode two abnormal mRNAs (b3a2 and b2a2). Various attempts to design antisense oligonucleotides that specifically cleave abnormal L6 BCR-ABL fusion mRNA have not been successful. Because b2a2 mRNA cannot be effectively cleaved by hammerhead ribozymes near the BCR-ABL junction, it has proved very difficult to engineer specific cleavage of this chimeric mRNA. Nonspecific effects associated with using antisense molecules make the use of such antisense molecules questionable.

RESULTS

The usefulness of DNA enzymes in specifically suppressing expression of L6 BCR-ABL mRNA in mammalian cells is demonstrated. Although the efficacy of DNA enzymes with natural linkages decreased 12 hours after transfection, partially modified DNA enzymes, with either phosphorothioate or 2'-O-methyl groups at both their 5' and 3' ends, remained active for much longer times in mammalian cells. Moreover, the DNA enzyme with only 2'-O-methyl modifications was also highly specific for abnormal mRNA.

CONCLUSIONS

DNA enzymes with 2'-O-methyl modifications are potentially useful as gene-inactivating agents in the treatment of diseases such as CML. In contrast to conventional antisense DNAs, some of the DNA enzymes used in this study were highly specific and cleaved only abnormal BCR-ABL mRNA.