Investigation of the catalytic mechanism of a synthetic DNAzyme with protein-like functionality: an RNaseA mimic?

Selection of M2+-independent RNA-cleaving DNAzymes with Sidechains Mimicking Arginine and Lysine

Sequence-specific cleavage of RNA by nucleic acid catalysts in the absence of a divalent metal cation (M 2+ ) has remained an important goal in biomimicry with potential therapeutic applications. Given the lack of functional group diversity in canonical nucleotides, modified nucleotides with amino acid-like side chains were used to enhance self-cleavage rates at a single embedded ribonucleoside site. Previous works relied on three functional groups: an amine, a guanidine and an imidazole ensconced on three different nucleosides. However, to date, few studies have systematically addressed the necessity of all three modifications, as the value of any single modified nucleoside is contextualized at the outset of selection. Herein, we report on the use of only two modified dNTPs, excluding an imidazole, i.e. 5-(3-guanidinoallyl)-2'-dUTP (dU ga TP) and 5-aminoallyl-2'-dCTP (dC aa TP), to select in-vitro self-cleaving DNAzymes that cleave in the absence of M 2+ in a pH-independent fashion. Cleavage shows biphasic kinetics with rate constants that are significantly higher than in unmodified DNAzymes and compare favorably to certain DNAzymes involving an imidazole. This work is the first report of a M2+-independent DNAzyme with two cationic modifications; as such it shows appreciable self-cleaving activity in the absence of an imidazole modification.

Activation of 8-17 DNAzyme with extra functional group at conserved residues is related to catalytic metal ion

In 8-17 DNAzyme, the end loop A⁶G⁷C⁸ is a highly conserved motif. Here we reported an activation approach by specific chemical modifications on A6 and C8 for more efficient Ca²⁺-mediated reaction. The importance of the end loop was further highlighted and its critical conservation broken for more powerful catalysts.

In vitro Selection of Chemically Modified DNAzymes

DNAzymes are in vitro selected DNA oligonucleotides with catalytic activities. RNA cleavage is one of the most extensively studied DNAzyme reactions. To expand the chemical functionality of DNA, various chemical modifications have been made during and after selection. In this review, we summarize examples of RNA-cleaving DNAzymes and focus on those modifications introduced during in vitro selection. By incorporating various modified nucleotides via polymerase chain reaction (PCR) or primer extension, a few DNAzymes were obtained that can be specifically activated by metal ions such as Zn2+ and Hg2+. In addition, some modifications were introduced to mimic RNase A that can cleave RNA substrates in the absence of divalent metal ions. In addition, single modifications at the fixed regions of DNA libraries, especially at the cleavage junctions, have been tested, and examples of DNAzymes with phosphorothioate and histidine-glycine modified tertiary amine were successfully obtained specific for Cu2+, Cd2+, Zn2+, and Ni2+. Labeling fluorophore/quencher pair right next to the cleavage junction was also used to obtain signaling DNAzymes for detecting various metal ions and cells. Furthermore, we reviewed work on the cleavage of 2'-5' linked RNA and L-RNA substrates. Finally, applications of these modified DNAzymes as biosensors, RNases, and biochemical probes are briefly described with a few future research opportunities outlined at the end.

Deciphering the Self-Cleavage Reaction Mechanism of Hairpin Ribozyme

Hairpin ribozyme catalyzes the reversible self-cleavage of phosphodiester bonds which plays prominent roles in key biological processes involving RNAs. Despite impressive advances on ribozymatic self-cleavage, critical aspects of its molecular reaction mechanism remain controversially debated. Here, we generate and analyze the multidimensional free energy landscape that underlies the reaction using extensive QM/MM metadynamics simulations to investigate in detail the full self-cleavage mechanism. This allows us to answer several pertinent yet controversial questions concerning activation of the 2'-OH group, the mechanistic role of water molecules present in the active site, and the full reaction pathway including the structures of transition states and intermediates. Importantly, we find that a sufficiently unrestricted reaction subspace must be mapped using accelerated sampling methods in order to compute the underlying free energy landscape. It is shown that lower-dimensional sampling where the bond formation and cleavage steps are coupled does not allow the system to sufficiently explore the landscape. On the basis of a three-dimensional free energy surface spanned by flexible generalized coordinates, we find that 2'-OH is indirectly activated by adjacent G8 nucleobase in conjunction with stabilizing H-bonding involving water. This allows the proton of the 2'-OH group to directly migrate toward the 5'-leaving group via a nonbridging oxygen of the phosphodiester link. At variance with similar enzymatic processes where water wires connected to protonable side chains of the protein matrix act as transient proton shuttles, no such de/reprotonation events of water molecules are found to be involved in this ribozymatic transesterification. Overall, our results support an acid-catalyzed reaction mechanism where A38 nucleobase directly acts as an acid whereas G8, in stark contrast, participates only indirectly via stabilizing the nascent nucleophile for subsequent attack. Moreover, we conclude that self-cleavage of hairpin ribozyme follows an A_N + D_N two-step associative pathway where the rate-determining step is the cleavage of the phosphodiester bond. These results provide a major advancement in our understanding of the unique catalytic mechanism of hairpin ribozyme which will fruitfully impact on the design of synthetic ribozymes.

Modified nucleotides may have enhanced early RNA catalysis

The modern version of the RNA World Hypothesis begins with activated ribonucleotides condensing (nonenzymatically) to make RNA molecules, some of which possess (perhaps slight) catalytic activity. We propose that noncanonical ribonucleotides, which would have been inevitable under prebiotic conditions, might decrease the RNA length required to have useful catalytic function by allowing short RNAs to possess a more versatile collection of folded motifs. We argue that modified versions of the standard bases, some with features that resemble cofactors, could have facilitated that first moment in which early RNA molecules with catalytic capability began their evolutionary path toward self-replication.

Side chain determinants of biopolymer function during selection and replication

The chemical functionalities within biopolymers determine their physical properties and biological activities. The relationship between the side-chains available to a biopolymer population and the potential functions of the resulting polymers, however, has proven difficult to study experimentally. Using seven sets of chemically diverse charged, polar, and nonpolar side-chains, we performed cycles of artificial translation, in vitro selections for binding to either PCSK9 or IL-6 protein, and replication on libraries of random side-chain-functionalized nucleic acid polymers. Polymer sequence convergence, bulk population target binding, affinity of individual polymers, and head-to-head competition among post-selection libraries collectively indicate that polymer libraries with nonpolar side-chains outperformed libraries lacking these side-chains. The presence of nonpolar groups, resembling functionality present in proteins but missing from natural nucleic acids, thus may be strong determinants of binding activity. This factor may contribute to the apparent evolutionary advantage of proteins over their nucleic acid precursors for some molecular recognition tasks.

Systematic study of constraints imposed by modified nucleoside triphosphates with protein-like side chains for use in in vitro selection

Successful selection of modified DNAzymes depends on the potential for modified nucleoside triphosphates (dNTPs) to replace their unmodified counterparts in enzyme catalyzed primer extension reactions and, once incorporated, to serve as template bases for information transfer prior to PCR amplification. To date, the most densely modified DNAzymes have been selected from three modified dNTPs: 8-histaminyl-deoxyadenosine (dA^imTP), 5-guanidinoallyl-deoxyuridine (dU^gaTP), and 5-aminoallyl-deoxycytidine (dC^aaTP) to provide several RNA-cleaving DNAzymes with greatly enhanced rate constants compared to unmodified counterparts. Here we report biophysical and enzymatic properties of these three modified nucleosides in the context of specific oligonucleotide sequences to understand how these three modified nucleobases function in combinatorial selection. The base-pairing abilities of oligonucleotides bearing one or three modified nucleosides were investigated by thermal denaturation studies and as templates for enzymatic polymerization with both modified and unmodified dNTPs. While we address certain shortcomings in the use of modified dNTPs, we also provide key evidence of faithful incorporation and enzymatic read-out, which strongly supports their continued use in in vitro selection.

A densely modified M2+-independent DNAzyme that cleaves RNA efficiently with multiple catalytic turnover

Sequence-specific cleavage of RNA targets in the absence of a divalent metal cation (M²⁺) has been a long-standing goal in bioorganic chemistry. Herein, we report the in vitro selection of novel RNA cleaving DNAzymes that are selected using 8-histaminyl-deoxyadenosine (dA^imTP), 5-guanidinoallyl-deoxyuridine (dU^gaTP), and 5-aminoallyl-deoxycytidine (dC^aaTP) along with dGTP. These modified dNTPs provide key functionalities reminiscent of the active sites of ribonucleases, notably RNase A. Of several such M²⁺-free DNAymes, DNAzyme 7-38-32 cleaves a 19 nt all-RNA substrate with multiple-turnover, under simulated physiological conditions wherein only 0.5 mM Mg²⁺ was present, attaining values of k_cat of 1.06 min^-1 and a K_M of 1.37 μM corresponding to a catalytic efficiency of ∼10⁶ M^-1 min^-1. Therefore, Dz7-38-32 represents a promising candidate towards the development of therapeutically efficient DNAzymes.

In Vitro Selection of Diversely Functionalized Aptamers

We describe the application of T4 DNA ligase-catalyzed DNA templated oligonucleotide polymerization toward the evolution of a diversely functionalized nucleic acid aptamer for human α-thrombin. Using a 256-membered ANNNN comonomer library comprising 16 sublibraries modified with different functional groups, a highly functionalized aptamer for thrombin was raised with a dissociation constant of 1.6 nM. The aptamer was found to be selective for thrombin and required the modifications for binding affinity. This study demonstrates the most differentially functionalized nucleic acid aptamer discovered by in vitro selection and should enable the future exploration of functional group dependence during the evolution of nucleic acid polymer activity.

Synthesis of chemically modified DNA

Naturally occurring DNA is encoded by the four nucleobases adenine, cytosine, guanine and thymine. Yet minor chemical modifications to these bases, such as methylation, can significantly alter DNA function, and more drastic changes, such as replacement with unnatural base pairs, could expand its function. In order to realize the full potential of DNA in therapeutic and synthetic biology applications, our ability to 'write' long modified DNA in a controlled manner must be improved. This review highlights methods currently used for the synthesis of moderately long chemically modified nucleic acids (up to 1000 bp), their limitations and areas for future expansion.

Selection of DNA aptamers with two modified bases

Aptamers are now used ubiquitously as binding agents for a broad range of applications. Natural (unmodified) DNA and RNA aptamers have considerably less chemical diversity than protein-based ligands such as antibodies, limiting their utility. Aptamers possessing a single chemical modification have helped bridge this diversity gap. We report the selection and identification of aptamers with two diversity-enhancing chemical modifications that bind and inhibit proprotein convertase subtilisin/kexin type 9 (PCSK9), a representative human therapeutic protein target. The addition of a second modification, especially in certain pairwise combinations, resulted in significant improvements in affinity, ligand efficiency, epitope coverage, metabolic stability, and inhibitory activity. Extensively chemically functionalized aptamers have the potential to become the next generation of nucleic-acid–based ligands.

The nucleobases comprising DNA and RNA aptamers provide considerably less chemical diversity than protein-based ligands, limiting their versatility. The introduction of novel functional groups at just one of the four bases in modified aptamers has recently led to dramatic improvement in the success rate of identifying nucleic acid ligands to protein targets. Here we explore the benefits of additional enhancement in physicochemical diversity by selecting modified DNA aptamers that contain amino-acid–like modifications on both pyrimidine bases. Using proprotein convertase subtilisin/kexin type 9 as a representative protein target, we identify specific pairwise combinations of modifications that result in higher affinity, metabolic stability, and inhibitory potency compared with aptamers with single modifications. Such doubly modified aptamers are also more likely to be encoded in shorter sequences and occupy nonoverlapping epitopes more frequently than aptamers with single modifications. These highly modified DNA aptamers have broad utility in research, diagnostic, and therapeutic applications.

Enzymatic Synthesis of Sequence-Defined Synthetic Nucleic Acid Polymers with Diverse Functional Groups

The development and in-depth analysis of T4 DNA ligase-catalyzed DNA templated oligonucleotide polymerization toward the generation of diversely functionalized nucleic acid polymers is described. The NNNNT codon set enables low codon bias, high fidelity, and high efficiency for the polymerization of ANNNN libraries comprising various functional groups. The robustness of the method was highlighted in the copolymerization of a 256-membered ANNNN library comprising 16 sub-libraries modified with different functional groups. This enabled the generation of diversely functionalized synthetic nucleic acid polymer libraries with 93.8 % fidelity. This process should find ready application in DNA nanotechnology, DNA computing, and in vitro evolution of functional nucleic acid polymers.

Generation of Synthetic Copolymer Libraries by Combinatorial Assembly on Nucleic Acid Templates

Recent advances in nucleic acid-templated copolymerization have expanded the scope of sequence-controlled synthetic copolymers beyond the molecular architectures witnessed in nature. This has enabled the power of molecular evolution to be applied to synthetic copolymer libraries to evolve molecular function ranging from molecular recognition to catalysis. This Review seeks to summarize different approaches available to generate sequence-defined monodispersed synthetic copolymer libraries using nucleic acid-templated polymerization. Key concepts and principles governing nucleic acid-templated polymerization, as well as the fidelity of various copolymerization technologies, will be described. The Review will focus on methods that enable the combinatorial generation of copolymer libraries and their molecular evolution for desired function.

Polymerase Synthesis and Restriction Enzyme Cleavage of DNA Containing 7-Substituted 7-Deazaguanine Nucleobases

Previous studies of polymerase synthesis of base-modified DNAs and their cleavage by restriction enzymes have mostly related only to 5-substituted pyrimidine and 7-substituted 7-deazaadenine nucleotides. Here we report the synthesis of a series of 7-substituted 7-deazaguanine 2'-deoxyribonucleoside 5'-O-triphosphates (dG(R) TPs), their use as substrates for polymerase synthesis of modified DNA and the influence of the modification on their cleavage by type II restriction endonucleases (REs). The dG(R) TPs were generally good substrates for polymerases but the PCR products could not be visualised on agarose gels by intercalator staining, due to fluorescence quenching. The presence of 7-substituted 7-deazaguanine residues in recognition sequences of REs in most cases completely blocked the cleavage.

Identification of a pKa-regulating motif stabilizing imidazole-modified double-stranded DNA

The predictable 3D structure of double-stranded DNA renders it ideally suited as a template for the bottom-up design of functionalized nucleic acid-based active sites. We here explore the use of a 14mer DNA duplex as a scaffold for the precise and predictable positioning of catalytic functionalities. Given the ubiquitous participation of the histidine-based imidazole group in protein recognition and catalysis events, single histidine-like modified duplexes were investigated. Tethering histamine to the C5 of the thymine base via an amide bond, allows the flexible positioning of the imidazole function in the major groove. The mutual interactions between the imidazole and the duplex and its influence on the imidazolium pKa_H are investigated by placing a single modified thymine at four different positions in the center of the 14mer double helix. Using NMR and unrestrained molecular dynamics, a structural motif involving the formation of a hydrogen bond between the imidazole and the Hoogsteen side of the guanine bases of two neighboring GC base pairs is established. The motif contributes to a stabilization against thermal melting of 6°C and is key in modulating the pKa_H of the imidazolium group. The general features, prerequisites and generic character of the new pKa_H-regulating motif are described.

Synthesis of base-modified 2'-deoxyribonucleoside triphosphates and their use in enzymatic synthesis of modified DNA for applications in bioanalysis and chemical biology

The synthesis of 2'-deoxyribonucleoside triphosphates (dNTPs) either by classical triphosphorylation of nucleosides or by aqueous cross-coupling reactions of halogenated dNTPs is discussed. Different enzymatic methods for synthesis of modified oligonucleotides and DNA by polymerase incorporation of modified nucleotides are summarized, and the applications in redox or fluorescent labeling, as well as in bioconjugations and modulation of interactions of DNA with proteins, are outlined.

Nucleic Acid Ligands With Protein-like Side Chains: Modified Aptamers and Their Use as Diagnostic and Therapeutic Agents

Limited chemical diversity of nucleic acid libraries has long been suspected to be a major constraining factor in the overall success of SELEX (Systematic Evolution of Ligands by EXponential enrichment). Despite this constraint, SELEX has enjoyed considerable success over the past quarter of a century as a result of the enormous size of starting libraries and conformational richness of nucleic acids. With judicious introduction of functional groups absent in natural nucleic acids, the “diversity gap” between nucleic acid–based ligands and protein-based ligands can be substantially bridged, to generate a new class of ligands that represent the best of both worlds. We have explored the effect of various functional groups at the 5-position of uracil and found that hydrophobic aromatic side chains have the most profound influence on the success rate of SELEX and allow the identification of ligands with very low dissociation rate constants (named Slow Off-rate Modified Aptamers or SOMAmers). Such modified nucleotides create unique intramolecular motifs and make direct contacts with proteins. Importantly, SOMAmers engage their protein targets with surfaces that have significantly more hydrophobic character compared with conventional aptamers, thereby increasing the range of epitopes that are available for binding. These improvements have enabled us to build a collection of SOMAmers to over 3,000 human proteins encompassing major families such as growth factors, cytokines, enzymes, hormones, and receptors, with additional SOMAmers aimed at pathogen and rodent proteins. Such a large and growing collection of exquisite affinity reagents expands the scope of possible applications in diagnostics and therapeutics.

Position-specific modification with imidazolyl group on10-23 DNAzyme realized catalytic activity enhancement

Nucleoside analogues with imidazolyl and histidinyl groups were synthesized for site-specific modification on the catalytic core of 10-23 DNAzyme. The distinct position-dependent effect of imidazolyl group was observed. Positive effect at A9 position was always observed. The pH- and Mg(2+)-dependence of the imidazolyl-modified DNAzymes suggested that imidazolyl group in 10-23 DNAzyme probably plays a dual role, its hydrogen bonding ability and spacial occupation play the favorable influence on the catalytic conformation of the modified DNAzymes. This research demonstrated that the catalytic performance of DNAzymes could be enhanced by incorporation of additional functional groups. Chemical modification is a feasible approach toward more efficient DNAzymes for therapeutic and biotechnological applications.

QM/MM simulation (B3LYP) of the RNase A cleavage-transesterification reaction supports a triester A(N) + D(N) associative mechanism with an O2' H internal proton transfer

The mechanism of the backbone cleavage-transesterification step of the RNase A enzyme remains controversial even after 60 years of study. We report quantum mechanics/molecule mechanics (QM/MM) free energy calculations for two optimized reaction paths based on an analysis of all structural data and identified by a search for reaction coordinates using a reliable quantum chemistry method (B3LYP), equilibrated structural optimizations, and free energy estimations. Both paths are initiated by nucleophilic attack of the ribose O2' oxygen on the neighboring diester phosphate bond, and both reach the same product state (PS) (a O3'-O2' cyclic phosphate and a O5' hydroxyl terminated fragment). Path 1, resembles the widely accepted dianionic transition-state (TS) general acid (His119)/base (His12) classical mechanism. However, this path has a barrier (25 kcal/mol) higher than that of the rate-limiting hydrolysis step and a very loose TS. In Path 2, the proton initially coordinating the O2' migrates to the nonbridging O1P in the initial reaction path rather than directly to the general base resulting in a triester (substrate as base) AN + DN mechanism with a monoanionic weakly stable intermediate. The structures in the transition region are associative with low barriers (TS1 10, TS2 7.5 kcal/mol). The Path 2 mechanism is consistent with the many results from enzyme and buffer catalyzed and uncatalyzed analog reactions and leads to a PS consistent with the reactive state for the following hydrolysis step. The differences between the consistently estimated barriers in Path 1 and 2 lead to a 10(11) difference in rate strongly supporting the less accepted triester mechanism.

Diguanidinocalix[4]arenes as effective and selective catalysts of the cleavage of diribonucleoside monophosphates

Upper rim diguanidino-cone-calix[4]arenes catalyze the hydrolytic cleavage of diribonucleoside monophosphates in aqueous DMSO with good substrate selectivity and rate accelerations approaching 10⁵-fold in the most favourable substrate-catalyst combinations.

Guanidine-guanidinium cooperation in bifunctional artificial phosphodiesterases based on diphenylmethane spacers; gem-dialkyl effect on catalytic efficiency

Diphenylmethane derivatives 1-3, decorated with two guanidine units, are effective catalysts of HPNP transesterification. Substitution of the methylene group of the parent diphenylmethane spacer with cyclohexylidene and adamantylidene moieties enhances catalytic efficency, with gem-dialkyl effect accelerations of 4.5 and 9.1, respectively. Activation parameters and DFT calculations of the rotational barriers around the C-Ar bonds indicate that a major contribution to the driving force for enhanced catalysis is entropic in nature.

Toward the combinatorial selection of chemically modified DNAzyme RNase A mimics active against all-RNA substrates

The convenient use of SELEX and related combinatorial methods of in vitro selection provides a formidable gateway for the generation of DNA enzymes, especially in the context of improving their potential as gene therapeutic agents. Here, we report on the selection of DNAzyme 12-91, a modified nucleic acid catalyst adorned with imidazole, ammonium, and guanidinium groups that provide for efficient M(2+)-independent cleavage of an all-RNA target sequence (kobs = 0.06 min(-1)). While Dz12-91 was selected for intramolecular cleavage of an all-RNA target, it surprisingly cleaves a target containing a lone ribocytosine unit with even greater efficiency (kobs = 0.27 min(-1)) than Dz9-86 (kobs = 0.13 min(-1)). The sequence composition of Dz12-91 bears a marked resemblance to that of Dz9-86 (kobs = 0.0014 min(-1) with an all-RNA substrate) that was selected from the same library to cleave a target containing a single ribonucleotide. However, small alterations in the sequence composition have a profound impact on the substrate preference and catalytic properties. Indeed, Dz12-91 displays the highest known rate enhancement for the M(2+)-independent cleavage of all-RNA targets. Hence, Dz12-91 represents a step toward the generation of potentially therapeutically active DNAzymes and further underscores the usefulness of modified triphosphates in selection experiments.

A structure-activity relationship study for 2'-deoxyadenosine analogs at A9 position in the catalytic core of 10-23 DNAzyme for rate enhancement

Modification on the catalytic core of 10-23 DNAzyme with protein-like functional groups is a potential approach to obtain its more efficient analogs. In our efforts for this purpose, a lead structure (DZ-2-9) with 8-aza-7-deaza-2'-deoxyadenosine at the A9 position in its catalytic core was obtained. Here we report our structure-activity relationship studies on this lead structure. Various functional groups of different chemical properties were introduced through the 7-substituents of 8-aza-7-deaza-2'-deoxyadenosine to DZ-2-9. The functional groups capable of forming hydrogen bonds, like amino and hydroxyl groups, are more favorable for catalytic rate enhancement than the large groups with spacial occupation, like phenyl and tert-butylphenyl groups, and the flexible alkyl linkage was the more preferred choice for optimizing their positive effect. Furthermore, they exerted positive effect cooperatively with the N8 atom. These results give us a clear hint in the design of compounds for A9 substitution of 10-23 DNAzyme for more efficient DNAzymes.

Upper rim guanidinocalix[4]arenes as artificial phosphodiesterases

Calix[4]arene derivatives, blocked in the cone conformation and functionalized with two to four guanidinium units at the upper rim were synthesized and investigated as catalysts in the cleavage of the RNA model compound 2-hydroxypropyl p-nitrophenyl phosphate. When compared with the behavior of a monofunctional model compound, the catalytic superiority of the calix[4]arene derivatives points to a high level of cooperation between catalytic groups. Combination of acidity measurements with the pH dependence of catalytic rates unequivocally shows that a necessary requisite for effective catalysis is the simultaneous presence, on the same molecular framework, of a neutral guanidine acting as a general base and a protonated guanidine acting as an electrophilic activator. The additional guanidinium (guanidine) group in the diprotonated (monoprotonated) trifunctional calix[4]arene acts as a more or less innocent spectator. This is not the case with the tetrasubstituted calix[4]arene, whose mono-, di-, and triprotonated forms are slightly less effective than the corresponding di- and triguanidinocalix[4]arene derivatives, most likely on account of a steric interference with HPNP caused by overcrowding.

Charged nucleobases and their potential for RNA catalysis

Catalysis in living cells is carried out by both proteins and RNA. Protein enzymes have been known for over 200 years, but RNA enzymes, or "ribozymes", were discovered only 30 years ago. Developing insight into RNA enzyme mechanisms is invaluable for better understanding both extant biological catalysis as well as the primitive catalysis envisioned in an early RNA-catalyzed life. Natural ribozymes include large RNAs such as the group I and II introns; small RNAs such as the hepatitis delta virus and the hairpin, hammerhead, VS, and glmS ribozymes; and the RNA portion of the ribosome and spliceosome. RNA enzymes use many of the same catalytic strategies as protein enzymes, but do so with much simpler side chains. Among these strategies are metal ion, general acid-base, and electrostatic catalysis. In this Account, we examine evidence for participation of charged nucleobases in RNA catalysis. Our overall approach is to integrate direct measurements on catalytic RNAs with thermodynamic studies on oligonucleotide model systems. The charged amino acids make critical contributions to the mechanisms of nearly all protein enzymes. Ionized nucleobases should be critical for RNA catalysis as well. Indeed, charged nucleobases have been implicated in RNA catalysis as general acid-bases and oxyanion holes. We provide an overview of ribozyme studies involving nucleobase catalysis and the complications involved in developing these mechanisms. We also consider driving forces for perturbation of the pK(a) values of the bases. Mechanisms for pK(a) values shifting toward neutrality involve electrostatic stabilization and the addition of hydrogen bonding. Both mechanisms couple protonation with RNA folding, which we treat with a thermodynamic formalism and conceptual models. Furthermore, ribozyme reaction mechanisms can be multichannel, which demonstrates the versatility of ribozymes but makes analysis of experimental data challenging. We examine advances in measuring and analyzing perturbed pK(a) values in RNA. Raman crystallography and fluorescence spectroscopy have been especially important for pK(a) measurement. These methods reveal pK(a) values for the nucleobases A or C equal to or greater than neutrality, conferring potential histidine- and lysine/arginine-like behavior on them. Structural support for ionization of the nucleobases also exists: an analysis of RNA structures in the databases conducted herein suggests that charging of the bases is neither especially uncommon nor difficult to achieve under cellular conditions. Our major conclusions are that cationic and anionic charge states of the nucleobases occur in RNA enzymes and that these states make important catalytic contributions to ribozyme activity. We conclude by considering outstanding questions and possible experimental and theoretical approaches for further advances.

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.

A divalent metal-dependent self-cleaving DNAzyme with a tyrosine side chain

The enzymatic incorporation of a phenol-modified 2'-deoxyuridine triphosphate gave rise to a modified DNA library that was subsequently used in an in vitro selection for ribophosphodiester-cleaving DNAzymes in the presence of divalent zinc and magnesium cations. After 11 rounds of selection, cloning and sequencing resulted in 14 distinct sequences, the most active of which was Dz11-17PheO. Dz11-17PheO self-cleaved an embedded ribocytidine with an observed rate constant of 0.20 ± 0.02 min(-1) in the presence of 10 mM Mg(2+) and 1 mM Zn(2+) at room temperature. The activity was inhibited at low concentrations of Hg(2+) cations and somewhat higher concentrations of Eu(3+) cations.

Protein-inspired modified DNAzymes: dramatic effects of shortening side-chain length of 8-imidazolyl modified deoxyadenosines in selecting RNaseA mimicking DNAzymes

The discovery of imidazole/amine-functionalized DNAzymes that efficiently cleave RNA independently of divalent metal cations (M(2+)) and cofactors underscores the importance of expanding the catalytic repertoire with modified nucleosides. Considerable effort has gone into defining polymerase tolerances of various modified dNTPs for synthesizing and amplifying modified DNA. While long linkers are generally found to enhance incorporation and therefore increase sequence space, shorter linkers may reduce the entropic penalty paid for orienting catalytic functionality. Catalytic enhancement ultimately depends on both the functional group and appropriate linkage to the nucleobase. Whether a shorter linker provides enough catalytic enhancement to outweigh the cost of reduced polymerizability can only be determined by the outcome of the selection. Herein, we report the selection of DNAzyme 20-49 (Dz20-49), which depends on amine, guanidine, and imidazole-modified dNTPs. In contrast to previous selections where we used dA(ime)TP (8-(4-imidazolyl)ethylamino-2'-dATP), here we used dA(imm)TP (8-(4-imidazolyl)methylamino-2'-dATP), in which the linker arm is shortened by one methylene group. Although the most active clone, Dz20-49, was absolutely dependent on the incorporation of either dA(imm)p or dA(ime)p, it catalyzed cofactor independent self-cleavage with a rate constant of 3.1 ± 0.3 × 10(-3) min(-1), a value not dissimilar from unmodified catalysts and strikingly inferior to modified catalysts selected with dA(ime)TP. These results demonstrate that very subtle differences in modified nucleotide composition may dramatically effect DNAzyme selection.

Hydroxyl-functionalized DNAs with different linkers and their complementary duplex stability

Tert-butyldiphenylsilyl (TBDPS) was testified to be an appropriate orthogonal protecting group for novel 7-hydroxyl-functionalized 8-aza-7-deaza-2'-deoxyadenosine analogues. It was stable in partial and complete hydrogenation reactions used for the different linker preparation. The corresponding phosphoramidites and hydroxyl-functionalized oligodeoxynucleotides were synthesized and identified. The thermal effect of the hydroxyl group with different linkers on DNA duplexes was evaluated. It provided a feasible strategy for the preparation of hydroxyl-functionalized DNAs for the nucleic acid research.