Sequence-specific cleavage of yeast tRNA(Phe) with oligonucleotides conjugated to a diimidazole construct

Elucidating the influence of RNA modifications and Magnesium ions on tRNA Phe conformational dynamics in S. cerevisiae : Insights from Replica Exchange Molecular Dynamics simulations

Post-transcriptional modifications in RNA can significantly impact their structure and function. In particular, transfer RNAs (tRNAs) are heavily modified, with around 100 different naturally occurring nucleotide modifications contributing to codon bias and decoding efficiency. Here, we describe our efforts to investigate the impact of RNA modifications on the structure and stability of tRNA Phenylalanine (tRNA Phe ) from S. cerevisiae using molecular dynamics (MD) simulations. Through temperature replica exchange MD (T-REMD) studies, we explored the unfolding pathway to understand how RNA modifications influence the conformational dynamics of tRNA Phe , both in the presence and absence of magnesium ions (Mg 2+ ). We observe that modified nucleotides in key regions of the tRNA establish a complex network of hydrogen bonds and stacking interactions which is essential for tertiary structure stability of the tRNA. Furthermore, our simulations show that modifications facilitate the formation of ion binding sites on the tRNA. However, high concentrations of Mg 2+ ions can stabilize the tRNA tertiary structure in the absence of modifications. Our findings illuminate the intricate interactions between modifications, magnesium ions, and RNA structural stability.

Site-Selective Artificial Ribonucleases: Renaissance of Oligonucleotide Conjugates for Irreversible Cleavage of RNA Sequences

RNA-targeting therapeutics require highly efficient sequence-specific devices capable of RNA irreversible degradation in vivo. The most developed methods of sequence-specific RNA cleavage, such as siRNA or antisense oligonucleotides (ASO), are currently based on recruitment of either intracellular multi-protein complexes or enzymes, leaving alternative approaches (e.g., ribozymes and DNAzymes) far behind. Recently, site-selective artificial ribonucleases combining the oligonucleotide recognition motifs (or their structural analogues) and catalytically active groups in a single molecular scaffold have been proven to be a great competitor to siRNA and ASO. Using the most efficient catalytic groups, utilising both metal ion-dependent (Cu(II)-2,9-dimethylphenanthroline) and metal ion-free (Tris(2-aminobenzimidazole)) on the one hand and PNA as an RNA recognising oligonucleotide on the other, allowed site-selective artificial RNases to be created with half-lives of 0.5-1 h. Artificial RNases based on the catalytic peptide [(ArgLeu)₂Gly]₂ were able to take progress a step further by demonstrating an ability to cleave miRNA-21 in tumour cells and provide a significant reduction of tumour growth in mice.

Restriction endonucleases: natural and directed evolution

Type II restriction endonucleases (REs) are highly sequence-specific compared with other classes of nucleases. PD-(D/E)XK nucleases, initially represented by only type II REs, now comprise a large and extremely diverse superfamily of proteins and, although sharing a structurally conserved core, typically display little or no detectable sequence similarity except for the active site motifs. Sequence similarity can only be observed in methylases and few isoschizomers. As a consequence, REs are classified according to combinations of functional properties rather than on the basis of genetic relatedness. New alignment matrices and classification systems based on structural core connectivity and cleavage mechanisms have been developed to characterize new REs and related proteins. REs recognizing more than 300 distinct specificities have been identified in RE database (REBASE: http://rebase.neb.com/cgi-bin/statlist ) but still the need for newer specificities is increasing due to the advancement in molecular biology and applications. The enzymes have undergone constant evolution through structural changes in protein scaffolds which include random mutations, homologous recombinations, insertions, and deletions of coding DNA sequences but rational mutagenesis or directed evolution delivers protein variants with new functions in accordance with defined biochemical or environmental pressures. Redesigning through random mutation, addition or deletion of amino acids, methylation-based selection, synthetic molecules, combining recognition and cleavage domains from different enzymes, or combination with domains of additional functions change the cleavage specificity or substrate preference and stability. There is a growing number of patents awarded for the creation of engineered REs with new and enhanced properties.

Site-selective artificial ribonucleases: oligonucleotide conjugates containing multiple imidazole residues in the catalytic domain

Design of site-selective artificial ribonucleases (aRNases) is one of the most challenging tasks in RNA targeting. Here, we designed and studied oligonucleotide-based aRNases containing multiple imidazole residues in the catalytic part and systematically varied structure of cleaving constructs. We demonstrated that the ribonuclease activity of the conjugates is strongly affected by the number of imidazole residues in the catalytic part, the length of a linker between the catalytic imidazole groups of the construct and the oligonucleotide, and the type of anchor group, connecting linker structure and the oligonucleotide. Molecular modeling of the most active aRNases showed that preferable orientation(s) of cleaving constructs strongly depend on the structure of the anchor group and length of the linker. The inclusion of deoxyribothymidine anchor group significantly reduced the probability of cleaving groups to locate near the cleavage site, presumably due to a stacking interaction with the neighbouring nucleotide residue. Altogether the obtained results show that dynamics factors play an important role in site-specific RNA cleavage. Remarkably high cleavage activity was displayed by the conjugates with the most flexible and extended cleaving construct, which presumably provides a better opportunity for imidazole residues to be correctly positioned in the vicinity of scissile phosphodiester bond.

Hydrolysis of bulged nucleotides in hybrids formed by RNA and imidazole-derivatized oligo-2'-O-methylribonucleotides

In order to enhance the efficacy of small antisense molecules, we examined a series of antisense oligonucleotides derivatized with functional groups designed to enable them to hydrolyze their RNA target. Solid phase synthetic methods were used to prepare imidazole-derivatized antisense oligo-2'-O-methylribonucleotides. Upon binding, these oligonucleotides create internal bulged bases in the target RNA that serve as sites for hydrolysis. We observed that an oligonucleotide derivatized with a side chain containing two imidazole groups was capable of hydrolyzing 58% of its RNA target when incubated with the target for 48 hours at 37°C and physiological pH.

Enhanced complexity and catalytic efficiency in the hydrolysis of phosphate diesters by rationally designed helix-loop-helix motifs

HJ1, a 42-residue peptide that folds into a helix-loop-helix motif and dimerizes to form a four-helix bundle, successfully catalyzes the cleavage of "early stage" DNA model substrates in an aqueous solution at pH 7.0, with a rate enhancement in the hydrolysis of heptyl 4-nitrophenyl phosphate of over three orders of magnitude over that of the imidazole-catalyzed reaction, k(2)(HJ1)/k(2)(Im) = 3135. The second-order rate constant, k(2)(HJ1) was determined to be 1.58x10(-4) M(-1) s(-1). The catalyst successfully assembles residues that in a single elementary reaction step are capable of general-acid and general-base catalysis as well as transition state stabilization and proximity effects. The reactivity achieved with the HJ1 polypeptide, rationally designed to catalyze the hydrolysis of phosphodiesters, is based on two histidine residues flanked by four arginines and two adjacent tyrosine residues, all located on the surface of a helix-loop-helix motif. The introduction of Tyr residues close to the catalytic site improves efficiency, in the cleavage of activated aryl alkyl phosphates as well as less activated dialkyl phosphates. HJ1 is also effective in the cleavage of an RNA-mimic substrate, uridine-3'-2,2,2-trichloroethyl phosphate (leaving group pK(a) = 12.3) with a second-order rate constant of 8.23x10(-4) M(-1) s(-1) in aqueous solution at pH 7.0, some 500 times faster than the reaction catalyzed by imidazole, k(2)(HJ1)/k(2)(Im) = 496.

Methionine Sustituted Polyamides are RNAse Mimics that Inhibit Translation

RNAse mimics are small molecules that can cleave RNA in a fashion similar to ribonucleases. These compounds would be very useful as gene specific reagents if their activities could be regulated and targeted. We demonstrate here that polyamides with methionine substituents show enhanced RNA cleavage activity relative to other polyamides. Conjugation of these compounds to aminoglycosides produced RNAse mimics that are capable of inhibiting eukaryotic protein synthesis. As a new class of compounds capable of interacting with nucleic acids, these novel aminoglycoside-polyamides constitute promising scaffolds for the construction of nuclease mimics with biological activity.

Catalysis of the cleavage of uridine 3'-2,2,2-trichloroethylphosphate by a designed helix-loop-helix motif peptide

A 42-residue peptide that folds into a helix-loop-helix motif and dimerizes to form a four-helix bundle has been designed to catalyze the hydrolysis of phosphodiesters. The active site on the surface of the folded catalyst is composed of two histidine and four arginine residues, with the capacity to provide general acid, general base, and/or nucleophilic catalysis as well as transition state stabilization. Uridine 3'-2,2,2 trichloroethylphosphate (2) is a mimic of RNA with a leaving group pKa of 12.3. Its hydrolysis is energetically less favorable than that of commonly used model substrates with p-nitrophenyl leaving groups and therefore a more realistic model for the design of catalysts capable of cleaving RNA. The second-order rate constant for the hydrolysis of 2 at pH 7.0 by the polypeptide catalyst was 418 x 10(-6) M-1 s-1, and that of the imidazole catalyzed reaction was 1.66 x 10(-6) M-1 s-1. The pH dependence suggested that catalysis is due to the unprotonated form of a residue with a pKa of around 5.3, and the observed kinetic solvent isotope effect of 1.9 showed that there is significant hydrogen bonding in the transition state, consistent with general acid-base catalysis. The rate constant ratio k2(Pep)/k2(Im) of 252 is probably due to a combination of nucleophilic and general acid-base catalysis, as well as transition state stabilization. Substrate binding was weak since no sign of saturation kinetics was observed for substrate concentrations in the range from 5 to 40 mM. The results provide a platform for the further development of catalysts for RNA cleavage with a potential role in the development of drugs.

Effective modulation of DNA duplex stability by reversible transition metal complex formation in the minor groove

Herein we describe the reversible changing of DNA duplex thermal stability by exploiting transition metal complexation phenomena. A terpyridine ligand was conjugated to the N2'-atoms of 2'-amino-2'-deoxyuridine and its locked counterpart 2'-amino-LNA, and these metal-complexing monomers were incorporated into oligodeoxyribonucleotides. Upon addition of varying amounts of transition metal ions, the thermal stability of DNA duplexes containing these terpyridine-functionalized units in different constitutions was affected to different degrees (DeltaTm values = -15.5 to +49.0 degrees C, relative to the unmodified duplex). The most pronounced effects were observed when two complexing monomers were positioned in opposite strands. Addition of 1 equiv of Ni2+ to such a system induced extraordinary duplex stabilization. Molecular modeling studies suggest, as an explanation for this phenomenon, formation of nickel-mediated interstrand linkages in the minor groove. Addition of an excess of metal ions resulted in largely decreased Tm values. Alternating addition of metal ions and EDTA demonstrated reversibility of metal ion-induced changes in hybridization strength, proving that the described approach provides an efficient method for duplex stability modulation.

Artificial ribonucleases

Mimicking the action of enzymes by simpler and more robust man-made catalysts has long inspired bioorganic chemists. During the past decade, mimics for RNA-cleaving enzymes, ribonucleases, or, more precisely, mimics of ribozymes that cleave RNA in sequence-selective rather than base-selective manner, have received special attention. These artificial ribonucleases are typically oligonucleotides (or their structural analogs) that bear a catalytically active conjugate group and catalyze sequence-selective hydrolysis of RNA phosphodiester bonds.

DNA Mismatch Detection by Resonance Energy Transfer between Ruthenium(II) and Osmium(II) Tris(2,2‘-bipyridyl) Chromophores

Octahedral tris-chelate complexes [M(II)(bpy)(3)](2+) (M = Ru or Os, bpy = 2,2'-bipyridyl), covalently attached to the 3'- and 5'-phosphates of two oligonucleotides, are juxtaposed when hybridized contiguously to a fully complementary DNA target. Visible metal-to-ligand charge-transfer (MLCT) excitation of the [Ru(II)(bpy)(3)](2+) unit leads to resonance energy transfer to the MLCT state of the [Os(II)(bpy)(3)](2+) moiety, with the energy transfer efficiency depending on the degree of hybridization. The extent of attenuation of the intense red luminescence from the Ru(II) chromophore hence allows highly sensitive structural probing of the assembly and constitutes a novel approach to DNA sensing which is capable of detecting mutations.

Sequence-specific artificial ribonucleases. I. Bis-imidazole-containing oligonucleotide conjugates prepared using precursor-based strategy

Antisense oligonucleotide conjugates, bearing constructs with two imidazole residues, were synthesized using a precursor-based technique employing post-synthetic histamine functionalization of oligonucleotides bearing methoxyoxalamido precursors at the 5'-termini. The conjugates were assessed in terms of their cleavage activities using both biochemical assays and conformational analysis by molecular modelling. The oligonucleotide part of the conjugates was complementary to the T-arm of yeast tRNA(Phe) (44-60 nt) and was expected to deliver imidazole groups near the fragile sequence C61-ACA-G65 of the tRNA. The conjugates showed ribonuclease activity at neutral pH and physiological temperature resulting in complete cleavage of the target RNA, mainly at the C63-A64 phosphodiester bond. For some constructs, cleavage was completed within 1-2 h under optimal conditions. Molecular modelling was used to determine the preferred orientation(s) of the cleaving group(s) in the complexes of the conjugates with RNA target. Cleaving constructs bearing two imidazole residues were found to be conformationally highly flexible, adopting no preferred specific conformation. No interactions other than complementary base pairing between the conjugates and the target were found to be the factors stabilizing the 'active' cleaving conformation(s).

Preparation of azacrown-functionalized 2'-O-methyl oligoribonucleotides, potential artificial RNases

An improved synthesis for 3-(3-aminopropyl)- and 3-(3-mercaptopropyl)-1,5,9-triazacyclododecane has been developed and alternative methods for their conjugation to oligonucleotides have been described. Accordingly, the 3-aminopropyl azacrown and its N-(3-aminopropanoyl)-3-aminopropyl analogue have been tethered to the 3'-terminus of a 2'-O-methyloligoribonucleotide by aminolytic cleavage of the thioester linker utilized for the chain assembly. Studies on a monomeric model compound verify that the reaction proceeds solely by the attack of the primary amino group. 5'-Conjugation has been achieved by introducing a 2-benzylthio-2-oxoethyl group to the 5'-terminus as a phosphoramidite reagent and cleaving the thioester bond with the 3-aminopropyl azacrown. For intrachain conjugation, a phosphoramidite reagent derived from 1-deoxy-1-(2-benzylthio-2-oxoethyl)-beta-d-erythro-pentofuranose has been inserted in a desired position within the chain and subjected to on-support aminolysis with the 3-aminopropyl azacrown or its N-(3-aminopropanoyl)-3-aminopropyl and N-(6-aminohexanoyl)-3-aminopropyl analogues. The 3-mercaptopropyl-derivatized azacrown has been tetherd by a disulfide bond to a 3'-(3-mercaptoalkyl)phosphate-tailed oligonucleotide. The 3'- and intrachain-tethered conjugates have been shown to cleave as their Zn(II) chelate complementary oligoribonucleotide sequences.

Highly efficient catalytic RNA cleavage by the cooperative action of two Cu(II) complexes embodied within an antisense oligonucleotide

Based on our recent studies of RNA cleavage by oligonucleotide-terpyridine.Cu(II) complex 5'- and/or 3'-conjugates, we designed 2'-O-methyloligonucleotides with two terpyridine-attached nucleosides at contiguous internal sites. To connect the 2'-terpyridine-modified uridine residue at the 5'-side to the 5'-O-terpyridyl nucleoside residue at the 3'-side, a dimethoxytrityl derivative of 5-hydroxypropyl-5'-O-terpyridyl-2'-deoxyuridine-3'-phosphoramidite was newly synthesized. Using this unit, we constructed two terpyridine conjugates, with either an unusual phophodiester bond or the bond extended by a propanediol(s)-containing linker. Cleavage reactions of the target RNA oligomer, under the conditions of conjugate excess in the presence of Cu(II), indicated that the conjugates precisely cleaved the RNA at the predetermined site and that one propanediol-containing linker was the most appropriate for inducing high cleavage activity. Furthermore, a comparison of the activity of the propanediol agent with those of the control conjugates with one complex confirmed that the two complexes are required for efficient RNA cleavage. The reaction of the novel cleaver revealed a bell-shaped pH-rate profile with a maximum at pH approximately 7.5, which is a result of the cooperative action of the complexes. In addition, we demonstrated that the agent catalytically cleaves an excess of the RNA, with the kinetic parameter kcat/K(m) = 0.118 nM(-1) x h(-1).

Site-specific cleavage of human telomerase RNA using PNA-neocuproine.Zn(II) derivatives

Here we report the synthesis of a novel PNA based neocuproine.Zn RNA cleaving agent; we demonstrate that such agents sequence specifically cleave a synthetic RNA target and in particular the RNA component of human telomerase.

Incorporation of 8-histaminyl-deoxyadenosine [8-(2-(4-imidazolyl)ethylamino)-2'-deoxyriboadenosine] into oligodeoxyribonucleotides by solid phase phosphoramidite coupling

The 3'phosphoramidite of 8-histaminyl deoxyadenosine has been prepared and successfully incorporated into a short oligodeoxyribonucleotide. The synthetic methodology leading to this preparation is given and the implications for developing new DNAzymes as well as probing unusual nucleic acid structures are discussed.

Enhancing sequence-specific cleavage of RNA within a duplex region: incorporation of 1,3-propanediol linkers into oligonucleotide conjugates of serinol-terpyridine

The syntheses and RNA cleavage efficiencies of a new series of oligonucleotide conjugates of Cu(II)-serinol-terpyridine and 1,3-propanediol are reported. These reagents, termed ribozyme mimics, were designed such that they would yield multiple unpaired RNA residues directly opposite the site of the RNA cleavage catalyst upon ribozyme mimic-RNA duplex formation. This design effect was implemented using the 1,3-propanediol linker 3, which mimics the three-carbon spacing between the 5'- and 3'-hydroxyls of a natural nucleotide. Incorporation of one or more of these 1,3-propanediol linkers at positions directly adjacent to the serinol-terpyridine modification in the ribozyme mimic DNA strand resulted in cleavage at multiple phosphates in a complementary 31-mer RNA target sequence. The linkers effectively created artificial mismatches in the RNA-DNA duplexes, rendering the opposing RNA residues much more susceptible to cleavage via the transesterification/hydrolysis pathway. The RNA cleavage products produced by the various mimics correlated directly with the number and locations of the linkers in their DNA strands, and the most active ribozyme mimic in the series exhibited multiple turnover in the presence of excess 31-mer RNA target.

Anti-HIV-1 activity of an antisense phosphorothioate oligonucleotide bearing imidazole and primary amine groups

We have previously shown that RNA cleaving reagents with imidazole and primary amine groups on the 5'-end of antisense oligodeoxyribonucleotides could site-specifically cleave CpA as the target sequence of the substrate tRNA in vitro. In this study, a RNA cleaving reagent, composed of imidazole and primary amine groups on an antisense phosphorothioate oligonucleotide (Im-anti-s-ODN), was synthesized and evaluated for anti-HIV-1 activity in MT-4 cells. The sequence of the Im-anti-s-ODN was designed to be complementary to the HIV-1 gag-mRNA and to bind adjacent to the CpA cleavage site position. Im-anti-s-ODN encapsulated with the transfection reagent, DMRIE-C, had higher anti-HIV-1 activity than the unmodified antisense phosphorothioate oligonucleotide (anti-s-ODN) at a 2 microM concentration. Furthermore, the Im-anti-ODN encapsulated with DMRIE-C conferred sequence-specific inhibition.

RNase activity of a DNA minor groove binder with a minimalist catalytic motif from RNase A

Imidazole and compounds containing imidazole residues have been shown to cleave RNA in an RNase A-mimicking manner. Di-imidazole lexitropsin is a compound which is derived from the polyamide drugs distamycin and netropsin essentially by the replacement of two pyrrole heterocycles with N-methyl-imidazole residues. This enables it to bind to the minor groove of B-DNA in a sequence-specific manner. We demonstrate here that this lexitropsin derivative has RNA cleavage activity, as tested on model RNAs. Optimal cleavage conditions and cleavage specificity resemble those known from other imidazole conjugates and are thus consistent with an RNase A type cleavage mechanism. The optimum concentration of the compound for cleavage is similar to previously investigated imidazole-based RNase mimics. As a whole new class of chemical compounds capable of interacting with nucleic acids through extensive hydrogen bonding, these imidazole containing compounds constitute promising scaffolds and ligands, for the construction of novel RNase mimics with high affinity.

A bridge between the RNA and protein worlds? Accelerating delivery of chemical reactivity to RNA and DNA by a specific short peptide (AAKK)(4)

BACKGROUND

RNA can catalyze diverse chemical reactions, leading to the hypothesis that an RNA world existed early in evolution. Today, however, catalysis by naturally occurring RNAs is rare and most chemical transformations within cells require proteins. This has led to interest in the design of small peptides capable of catalyzing chemical transformations.

RESULTS

We demonstrate that a short lysine-rich peptide (AAKK)(4) can deliver a nucleophile to DNA or RNA and amplify the rate of chemical modification by up to 3400-fold. We also tested similar peptides that contain ornithine or arginine in place of lysine, peptides with altered stereochemistry or orientation, and peptides containing eight lysines but with different spacing. Surprisingly, these similar peptides function much less well, suggesting that specific combinations of amino acids, charge distribution, and stereochemistry are necessary for the rate enhancement by (AAKK)(4).

CONCLUSIONS

By appending other reactive groups to (AAKK)(4) it should be possible to greatly expand the potential for small peptides to directly catalyze modification of DNA or RNA or to act as cofactors to promote ribozyme catalysis.

Cleavage of the phosphodiester bond of uridylyl-(3',5')-8-carboxymethylaminoadenosine by hydronium, hydroxide and zinc(II) ions: a model study aimed at elucidating the potential of a carboxylate function as an intramolecular catalyst

Uridylyl-(3',5')-8-carboxymethylaminoadenosine has been synthesised, and its transesterification to uridine 2',3'-cyclic phosphate in the presence and absence of Zn2+ ion has been studied. The results show that a carboxylate function in the vicinity of the phosphodiester bond accelerates the metal ion promoted cleavage but not the metal ion independent reaction. Under acidic conditions, the predominant reaction is the cleavage of the side chain, giving the 8-amino derivative.

Cleavage of yeast tRNAPhe with complementary oligonucleotide conjugated to a small ribonuclease mimic

An oligonucleotide conjugate bearing a chemical construct mimicking the catalytic center of ribonuclease A has been designed and studied. The conjugate efficiently cleaves yeast tRNAPhe at a single site adjacent to the target complementary sequence.

Refined high-field NMR solution structure of a binary-addressed pyrene/perfluoro-azide complementary DNA oligonucleotide system shows extensive distortion in the central nick region

The structural analysis of the photoactivated binary system of complementary-addressing nucleic acid sequences (1:2:3) by high-resolution NMR spectroscopy and restrained molecular dynamics is reported. The binary system comprised a 12 base-pair target DNA sequence, pdGTATCAGTTTCT (1), and two hexanucleotides, (dAGAAACp-L-Az (2) and Pyr-pdTGATAC (3)), complementary to neighbouring sites in the target DNA. Oligonucleotide (2) is conjugated with a p-azidotetrafludrobenzyl group (Az) via a linker group (L), and the other oligonucleotide (3) is equipped with the photosensitizing pyrenyl-1-methylamino group (Pyr). We now extend the structural analysis of 1:2:3, which was previously based on qualitative 2D 1H-NMR data and thermodynamic analysis of complex formation from UV-visible thermal denaturation experiments. In the current work structural refinement was performed by separate molecular dynamics runs for six different starting structures based on 318 proton-proton distance-range constraints, evaluated from the 1H-NOESY spectrum (tau(mix) = 200 ms, 600 MHz) using complete relaxation matrix analysis (NMR/TRIAD/MARDIGRAS). Additional Watson-Crick hydrogen bond restraints were included in the calculations based on the detected signals from the exchangeable protons, using REFOPT(NY) methods. The final averaged structure obtained from the six refined co-ordinate sets showed a considerable degree of axis bend (62.5 degrees) with the bending point in the middle of the duplex in the region of the backbone nick between the two short oligonucleotides. The complex behaves dynamically as the equivalent of two short B-DNA-like duplexes displaying a hinge-like flexing at their junction. In all final structures the Pyr function location was very restricted, the aromatic group lying in the duplex minor groove near residues 4T, 5C and 2T. In contrast, the location of the perfluoroazido group was different in all the final structures, indicating the high flexibility of this group in the duplex. The only feature common to all six final azido group orientations was the outside location on the side of the major groove. The distance between the Pyr and Az groups varied from 11 A to 24 A for the six final structures (17 A, final average structure). The dynamics of duplex denaturation for 1:2:3 was probed by monitoring the temperature-induced NMR line broadening of the imino protons in a 1D variable temperature NMR experiment. The melting of 1:2:3 starts both from the ends and from the middle part of the duplex at the backbone break between the two short oligonucleotides reflecting the destabilisation of the pyrene-arylazido nick region in the duplex.

The sequence-specific cleavage of RNA by artificial chemical ribonucleases

Based on work spanning 50 years, several groups have recently achieved the specific cleavage of RNA by attaching RNA-cleaving chemical moieties to antisense oligonucleotides. Such artificial chemical ribonucleases have potential as a possible next generation of antisense compounds and also as probes for structural and functional investigations of RNA. Different chemical moieties, such as polyamines, imidazoles, and metal complexes, have been used as the catalytic part of the artificial nucleases. To be of practical use as therapeutics, however, the conjugates must fulfil a number of strict requirements, such as ease of preparation, chemical stability, selectivity, nontoxicity, and, for metal complexes, inertness to loss of cation from the ligand. In addition, high cleavage efficiency is essential to overcome short lifetimes of cellular mRNA targets, and the reaction should not depend on additional cofactors. Based on these criteria, we believe that metal complexes, in particular macrocyclic lanthanide complexes, have the best chance of success for said purpose.