Creating RNA bulges: cleavage of RNA in RNA/DNA duplexes by metal ion catalysis

Metal ion-induced site-selective RNA hydrolysis by use of acridine-bearing oligonucleotide as cofactor

New types of noncovalent ribozyme-mimics for site-selective RNA scission are prepared by combining metal ions with oligonucleotides bearing an acridine. Lanthanide(III) ions and various divalent metal ions (Zn(II), Mn(II), Cu(II), Ni(II), Co(II), Mg(II), and Ca(II)) are employed without being bound to any sequence-recognizing moiety. The modified oligonucleotide forms a heteroduplex with the substrate RNA, and selectively activates the phosphodiester linkages in front of the acridine. As a result, these linkages are preferentially hydrolyzed over the others, even though the metal ions are not fixed anywhere. The scission is efficient under physiological conditions, irrespective of the sequence at the target site. Site-selective RNA scission is also successful with the combination of an oligonucleotide bearing an acridine at its terminus, another unmodified oligonucleotide, and the metal ion. In a proposed mechanism, the acridine pushes the unpaired ribonucleotide out of the heteroduplex and changes the conformation of RNA at the target site for the sequence-selective activation.

Oligonucleotide conjugates as potential antisense drugs with improved uptake, biodistribution, targeted delivery, and mechanism of action

This review summarizes the effect of conjugating small molecules and large biomacromolecules to antisense oligonucleotides to improve their therapeutic potential. In many cases, favorable changes in pharmacokinetic and pharmacodynamic properties were observed. Opportunities exist to change the terminating mechanism of antisense action or to enhance the RNase H mode of action via conjugate formation.

Crystal structure of an adenine bulge in the RNA chain of a DNA.RNA hybrid, d(CTCCTCTTC).r(gaagagagag)

Crystal structure of a DNA.RNA hybrid, d(CTCCTCTTC).r(gaagagagag), with an adenine bulge in the polypurine RNA strand was determined at 2.3 A resolution. The structure was solved by the molecular replacement method and refined to a final R-factor of 19.9% (Rfree 22.2%). The hybrid duplex crystallized in the space group I222 with unit cell dimensions, a = 46.66 A, b = 47.61 A and c = 54.05 A, and adopts the A-form conformation. All RNA and DNA sugars are in the C3'-endo conformation, the glycosyl angles in anti conformation and the majority of the C4'-C5' torsion angles in g+ except two trans angles, in conformity with the C3'-endo rigid nucleotide hypothesis. The adenine bulge is looped out and it is also in the anti C3'-endo conformation. The bulge is involved in a base-triple (C.g)*a interaction with the end base-pair (C9.g10) in the minor groove of a symmetry-related molecule. The 2' hydroxyl group of g15 is hydrogen bonded to O2P and O5' of g17, skipping the bulged adenine a16 and stabilizing the sugar-phosphate backbone of the hybrid. The hydrogen bonding and the backbone conformation at the bulged adenine site is very similar to that found in the crystal structure of a protein-RNA complex.

Enhancement of RNA self-cleavage by micellar catalysis

It has been reported recently that naturally occurring catalytic RNAs like hammerhead and hairpin ribozyme do not require metal ions for efficient catalysis. It seems that the folded tertiary structure of the RNA contributes more to the catalytic function than was initially recognized. We found that a highly specific self-cleavage reaction can occur within a small bulge loop of four nucleotides in a mini-substrate derived from Arabidopsis thaliana intron-containing pre-tRNA(Tyr) in the absence of metal ions. NH(4)(+) cations and non-ionic or zwitter-ionic detergents at or above their critical micelle concentration are sufficient to catalyze this reaction. The dependence on micelles for the reaction leads to the assumption that physical properties, i.e. the hydrophobic interior of a micelle, are essential for this self-cleavage reaction. We suggest that NH(4)(+)-ions play a crucial role for the entry of the negatively charged RNA into the hydrophobic interior of a detergent micelle. A change of the pattern of hydration or hydrogen bonds caused by the hydrophobic surrounding enhances the reaction by a factor of 100. These findings suggest that highly structured RNAs may shift pK(a) values towards neutrality via the local environment and thereby enhance their ability to perform general acid-base catalysis without the participation of metal ions.

Metal ion-dependent hydrolysis of RNA phosphodiester bonds within hairpin loops. A comparative kinetic study on chimeric ribo/2'-O-methylribo oligonucleotides

Several chimeric ribo/2'- O -methylribo oligonucleotides were synthesized and their hydrolytic cleavage studied in the presence of Mg2+, Zn2+, Pb2+and the 1,4,9-triaza-cyclododecane chelate of Zn2+(Zn2+[12]aneN3) to evaluate the importance of RNA secondary structure as a factor determining the reactivity of phosphodiester bonds. In all the cases studied, a phosphodiester bond within a 4-7 nt loop was hydrolytically more stable than a similar bond within a linear single strand, but markedly less stable than that in a double helix. With Zn2+and Zn2+[12]aneN3, the hydrolytic stability of a phosphodiester bond within a hairpin loop gradually decreased on increasing the distance from the stem. A similar but less systematic trend was observed with Pb2+. Zn2+- and Pb2+-promoted cleavage was observed to be considerably more sensitive to the secondary structure of the chain than that induced by Zn2+[12]aneN3. This difference in behaviour may be attributed to bidentate binding of uncomplexed aquo ions to two different phosphodiester bonds. Mg2+was observed to be catalytically virtually inactive compared with the other cleaving agents studied.

Natural antisense RNA/target RNA interactions: possible models for antisense oligonucleotide drug design

Current antisense oligonucleotides designed for drug therapy rely on Watson-Crick base pairing for the specificity of interactions between antisense and target molecules. However, thermodynamically stable duplexes containing non-Watson-Crick pairs have been formed with synthetic oligonucleotides. There are also numerous examples of non-canonical base pairs that participate in stable intra- and inter-molecular RNA/RNA pairing in prokaryotic and eukaryotic cells. Several natural antisense RNA/target RNA duplexes contain looped-out and bulged positions as well as non-canonical pairs as exemplified by formation of the Escherichia coli antisense micF RNA/ompF mRNA duplex. Secondary structures and the phylogenetic conservation of nucleotide sequences are well characterized in this system. Natural antisense/ target interactions may serve as models for determining possible and optimal antisense/target interactions in oligonucleotide drug design.

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.