Physicochemical and biochemical properties of 2',5'-linked RNA and 2',5'-RNA:3',5'-RNA "hybrid" duplexes

Advances in structural-guided modifications of siRNA

To date, the US Food and Drug Administration (FDA) has approved six small interfering RNA (siRNA) drugs: patisiran, givosiran, lumasiran, inclisiran, vutrisiran, and nedosiran, serving as compelling evidence of the promising potential of RNA interference (RNAi) therapeutics. The successful implementation of siRNA therapeutics is improved through a combination of various chemical modifications and diverse delivery approaches. The utilization of chemically modified siRNA at specific sites on either the sense strand (SS) or antisense strand (AS) has the potential to enhance resistance to ribozyme degradation, improve stability and specificity, and prolong the efficacy of drugs. Herein, we provide comprehensive analyses concerning the correlation between chemical modifications and structure-guided siRNA design. Various modifications, such as 2'-modifications, 2',4'-dual modifications, non-canonical sugar modifications, and phosphonate mimics, are crucial for the activity of siRNA. We also emphasize the essential strategies for enhancing overhang stability, improving RISC loading efficacy and strand selection, reducing off-target effects, and discussing the future of targeted delivery.

High-Fidelity RNA Copying via 2',3'-Cyclic Phosphate Ligation

Templated ligation offers an efficient approach to replicate long strands in an RNA world. The 2',3'-cyclic phosphate (>P) is a prebiotically available activation that also forms during RNA hydrolysis. Using gel electrophoresis and high-performance liquid chromatography, we found that the templated ligation of RNA with >P proceeds in simple low-salt aqueous solutions with 1 mM MgCl2 under alkaline pH ranging from 9 to 11 and temperatures from -20 to 25 °C. No additional catalysts were required. In contrast to previous reports, we found an increase in the number of canonical linkages to 50%. The reaction proceeds in a sequence-specific manner, with an experimentally determined ligation fidelity of 82% at the 3' end and 91% at the 5' end of the ligation site. With splinted oligomers, five ligations created a 96-mer strand, demonstrating a pathway for the ribozyme assembly. Due to the low salt requirements, the ligation conditions will be compatible with strand separation. Templated ligation mediated by 2',3'-cyclic phosphate in alkaline conditions therefore offers a performant replication and elongation reaction for RNA on early Earth.

From bench to bedside: Improving the clinical safety of GalNAc-siRNA conjugates using seed-pairing destabilization

Preclinical mechanistic studies have pointed towards RNA interference-mediated off-target effects as a major driver of hepatotoxicity for GalNAc-siRNA conjugates. Here, we demonstrate that a single glycol nucleic acid or 2'-5'-RNA modification can substantially reduce small interfering RNA (siRNA) seed-mediated binding to off-target transcripts while maintaining on-target activity. In siRNAs with established hepatotoxicity driven by off-target effects, these novel designs with seed-pairing destabilization, termed enhanced stabilization chemistry plus (ESC+), demonstrated a substantially improved therapeutic window in rats. In contrast, siRNAs thermally destabilized to a similar extent by the incorporation of multiple DNA nucleotides in the seed region showed little to no improvement in rat safety suggesting that factors in addition to global thermodynamics play a role in off-target mitigation. We utilized the ESC+ strategy to improve the safety of ALN-HBV, which exhibited dose-dependent, transient and asymptomatic alanine aminotransferase elevations in healthy volunteers. The redesigned ALN-HBV02 (VIR-2218) showed improved specificity with comparable on-target activity and the program was reintroduced into clinical development.

Site-specific Incorporation of 2',5'-Linked Nucleic Acids Enhances Therapeutic Profile of Antisense Oligonucleotides

Site-specific incorporation of 2'-modifications and neutral linkages in the deoxynucleotide gap region of toxic phosphorothioate (PS) gapmer ASOs can enhance therapeutic index and safety. In this manuscript, we determined the effect of introducing 2',5'-linked RNA in the deoxynucleotide gap region on toxicity and potency of PS ASOs. Our results demonstrate that incorporation of 2',5'-linked RNA in the gap region dramatically improved hepatotoxicity profile of PS-ASOs without compromising potency and provide a novel alternate chemical approach for improving therapeutic index of ASO drugs.

Hybrid DNA/RNA nanostructures with 2'-5' linkages

Nucleic acid nanostructures with different chemical compositions have shown utility in biological applications as they provide additional assembly parameters and enhanced stability. The naturally occurring 2'-5' linkage in RNA is thought to be a prebiotic analogue and has potential use in antisense therapeutics. Here, we report the first instance of DNA/RNA motifs containing 2'-5' linkages. We synthesized and incorporated RNA strands with 2'-5' linkages into different DNA motifs with varying number of branch points (a duplex, four arm junction, double crossover motif and tensegrity triangle motif). Using experimental characterization and molecular dynamics simulations, we show that hybrid DNA/RNA nanostructures can accommodate interspersed 2'-5' linkages with relatively minor effect on the formation of these structures. Further, the modified nanostructures showed improved resistance to ribonuclease cleavage, indicating their potential use in the construction of robust drug delivery vehicles with prolonged stability in physiological conditions.

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.

Effect of 2'-5'/3'-5' phosphodiester linkage heterogeneity on RNA interference

We report on the synthesis of siRNAs containing both 2′-5′- and 3′-5′-internucleotide linkages and their effects on siRNA structure, function, and interaction with RNAi proteins. Screening of these siRNAs against their corresponding mRNA targets showed that 2′-5′ linkages were well tolerated in the sense strand, but only at a few positions in the antisense strand. Extensive modification of the antisense strand minimally affected 5′-phosphorylation of the siRNA by kinases, however, it negatively affected siRNA loading into human AGO2. Modelling and molecular dynamics simulations were fully consistent with these findings. Furthermore, our studies indicated that the presence of a single 5′p-rN₁-(2′-5′)-N₂ unit in the antisense strand does not alter the ‘clover leaf’ bend and sugar puckers that are critical for anchoring the 5′-phosphate to Ago 2 MID domain. Importantly, 2′-5′-linkages had the added benefit of abrogating immune-stimulatory activity of siRNAs. Together, these results demonstrate that 2′-5′/3′-5′-modified siRNAs, when properly designed, can offer an efficient new class of siRNAs with diminished immune-stimulatory responses.

2'/3' Regioselectivity of Enzyme-Free Copying of RNA Detected by NMR

The RNA-templated extension of oligoribonucleotides by nucleotides produces either a 3',5' or a 2',5'-phosphodiester. Nature controls the regioselectivity during RNA chain growth with polymerases, but enzyme-free versions of genetic copying have modest specificity. Thus far, enzymatic degradation of products, combined with chromatography or electrophoresis, has been the preferred mode of detecting 2',5'-diesters produced in enzyme-free reactions. This approach hinges on the substrate specificity of nucleases, and is not suitable for in situ monitoring. Here we report how ¹ H NMR spectroscopy can be used to detect the extension of self-templating RNA hairpins and that this reveals the regioisomeric nature of the newly formed phosphodiesters. We studied several modes of activating nucleotides, including imidazolides, a pyridinium phosphate, an active ester, and in situ activation with carbodiimide and organocatalyst. Conversion into the desired extension product ranged from 20 to 90 %, depending on the leaving group. Integration of the resonances of H1' protons of riboses and H5 protons of pyrimidines gave regioselectivities ranging from 40:60 to 85:15 (3',5' to 2',5' diester), but no simple correlation between 3',5' selectivity and yield. Our results show how monitoring with a high-resolution technique sheds a new light on a process that may have played an important role during the emergence of life.

The furanosidic scaffold of d-ribose: a milestone for cell life

The recruitment of the furanosidic scaffold of ribose as the crucial step for nucleotides and then for nucleic acids synthesis is presented. Based on the view that the selection of molecules to be used for relevant metabolic purposes must favor structurally well-defined molecules, the inadequacy of ribose as a preferential precursor for nucleotides synthesis is discussed. The low reliability of ribose in its furanosidic hemiacetal form must have played ab initio against the choice of d-ribose for the generation of d-ribose-5-phosphate, the fundamental precursor of the ribose moiety of nucleotides. The latter, which is instead generated through the 'pentose phosphate pathway' is strictly linked to the affordable and reliable pyranosidic structure of d-glucose.

Regioselective formation of RNA strands in the absence of magnesium ions

The oligomerization of ribonucleotides can produce short RNA strands in the absence of enzymes. This reaction gives one of two regioisomeric phosphodiester linkages, a 2',5'- or a 3',5'-diester. The former, non-natural linkage is detrimental for duplex stability, and is known to form preferentially in oligomerizations occurring in homogeneous solution with preactivated nucleotides in the presence of magnesium cations. We have studied ribonucleotide oligomerization with in situ activation, using NMR as monitoring technique. Unexpectedly, the known preference for 2',5'-linkages in the oligomerization of AMP was reversed in the absence of magnesium ions at slightly basic pH. Further, oligomerization was surprisingly efficient in the absence of Mg2+ salts, producing oligomers long enough for duplex formation. A quantitative systems chemistry analysis then revealed that the absence of magnesium ions favors the activation of nucleotides, and that the high concentration of active species can compensate for slower coupling. Further, organocatalytic intermediates can help to overcome the unfavorable regioselectivity of the magnesium-catalyzed reactions. Our findings allay concerns that RNA may have been difficult to form in the absence of enzymes. They also show that there is an efficient path to genetic material that does not require mineral surfaces or cations known to catalyze RNA hydrolysis.

Extensive CRISPR RNA modification reveals chemical compatibility and structure-activity relationships for Cas9 biochemical activity

CRISPR (clustered regularly interspaced short palindromic repeat) endonucleases are at the forefront of biotechnology, synthetic biology and gene editing. Methods for controlling enzyme properties promise to improve existing applications and enable new technologies. CRISPR enzymes rely on RNA cofactors to guide catalysis. Therefore, chemical modification of the guide RNA can be used to characterize structure-activity relationships within CRISPR ribonucleoprotein (RNP) enzymes and identify compatible chemistries for controlling activity. Here, we introduce chemical modifications to the sugar–phosphate backbone of Streptococcus pyogenes Cas9 CRISPR RNA (crRNA) to probe chemical and structural requirements. Ribose sugars that promoted or accommodated A-form helical architecture in and around the crRNA ‘seed’ region were tolerated best. A wider range of modifications were acceptable outside of the seed, especially D-2′-deoxyribose, and we exploited this property to facilitate exploration of greater chemical diversity within the seed. 2′-fluoro was the most compatible modification whereas bulkier O-methyl sugar modifications were less tolerated. Activity trends could be rationalized for selected crRNAs using RNP stability and DNA target binding experiments. Cas9 activity in vitro tolerated most chemical modifications at predicted 2′-hydroxyl contact positions, whereas editing activity in cells was much less tolerant. The biochemical principles of chemical modification identified here will guide CRISPR-Cas9 engineering and enable new or improved applications.

Nucleic acids: function and potential for abiogenesis

The emergence of functional cooperation between the three main classes of biomolecules - nucleic acids, peptides and lipids - defines life at the molecular level. However, how such mutually interdependent molecular systems emerged from prebiotic chemistry remains a mystery. A key hypothesis, formulated by Crick, Orgel and Woese over 40 year ago, posits that early life must have been simpler. Specifically, it proposed that an early primordial biology lacked proteins and DNA but instead relied on RNA as the key biopolymer responsible not just for genetic information storage and propagation, but also for catalysis, i.e. metabolism. Indeed, there is compelling evidence for such an 'RNA world', notably in the structure of the ribosome as a likely molecular fossil from that time. Nevertheless, one might justifiably ask whether RNA alone would be up to the task. From a purely chemical perspective, RNA is a molecule of rather uniform composition with all four bases comprising organic heterocycles of similar size and comparable polarity and pK a values. Thus, RNA molecules cover a much narrower range of steric, electronic and physicochemical properties than, e.g. the 20 amino acid side-chains of proteins. Herein we will examine the functional potential of RNA (and other nucleic acids) with respect to self-replication, catalysis and assembly into simple protocellular entities.

Evolution of specific 3'-5'-linkages in RNA in pre-biotic soup: a new hypothesis

This article reviews the different possibilities towards progression of the formation of DNA/RNA in the chemical world, before life, in enzyme-free conditions. The advent of deoxyribo- and ribopentose-sugars, nucleosides, nucleotides and oligonucleotides in the prebiotic soup is briefly discussed. Further, the formation of early single stranded oligomers, base-pairing possibilities and information transfer based on the stability parameters of the derived duplexes is reviewed. Each theory has its own merits and demerits which we have elaborated upon. Lastly, using clues from this literature, a possible explanation for the specific 3'-5'-linkages in RNA is proposed.

Structural insights into RNA duplexes with multiple 2΄-5΄-linkages

2΄-5΄-linked RNAs play important roles in many biological systems. In addition, the mixture of 2΄-5΄ and 3΄-5΄ phosphodiester bonds have emerged as a plausible structural element in prebiotic RNAs. Toward our mechanistic studies of RNA folding and structures with heterogeneous backbones, we recently reported two crystal structures of a decamer RNA duplex containing two and six 2΄-5΄-linkages, showing how RNA duplexes adjust the structures to accommodate these non-canonical linkages (Proc. Natl. Acad. Sci. USA, 2014, 111, 3050-3055). Herein, we present two additional high-resolution crystal structures of the same RNA duplex containing four and eight 2΄-5΄-linkages at different positions, providing new insights into the effects of these modifications and a dynamic view of RNA structure changes with increased numbers of 2΄-5΄-linkages in the same duplex. Our results show that the local structural perturbations caused by 2΄-5΄ linkages can be distributed to nearly all the nucleotides with big ranges of changes in different geometry parameters. In addition, hydration pattern and solvation energy analysis indicate less favorable solvent interactions of 2΄-5΄-linkages comparing to the native 3΄-5΄-linkages. This study not only promotes our understanding of RNA backbone flexibility, but also provides a knowledge base for studying the biochemical and prebiotic significance of RNA 2΄-5΄-linkages.

Probing the Backbone Topology of DNA: Synthesis and Properties of 7',5'-Bicyclo-DNA

We describe the synthesis and pairing properties of the novel DNA analogue 7',5'-bicyclo(bc)-DNA. In this analogue, the point of attachment of the connecting phosphodiester group is switched from the 3' to the 7' position of the underlying bicyclic sugar unit and is thus in a topological position that is inaccessible in natural DNA. The corresponding phosphoramidite building blocks carrying all natural nucleobases were synthesized and incorporated into oligonucleotides. From T_m experiments of duplexes with complementary DNA and RNA we find that single modifications are generally well tolerated with some variability as to the nature of the nucleobase. Fully modified oligonucleotides show low affinity for RNA and DNA complements. However, they form antiparallel homo-duplexes with similar thermal stability as DNA. CD spectra of the homo-duplexes show distinct changes in the helix conformation compared to natural DNA. A conformational analysis at the ab initio level of the mononucleosides revealed two minimal energy structures which primarily deviate in the conformation of the cyclopentane ring. Molecular dynamics simulation of a 7',5'-bc-DNA homo-duplex revealed a right-handed structure with a smaller helical rise and a significantly wider minor groove compared to DNA. Interestingly, this duplex is characterized by an atypical, alternating 6'-endo/6'-exo conformational pattern of consecutive nucleotides which seems to be responsible for the poor binding to natural nucleic acids.

An Efficient Lanthanide-Dependent DNAzyme Cleaving 2'-5'-Linked RNA

RNA can form two types of linkage. In addition to the predominant 3'-5' linkage, 2'-5'-linked RNA is also important in biology, medicine, and prebiotic studies. Here, in vitro selection was used to isolate a DNAzyme that specifically cleaves 2'-5' RNA by using Ce(3+) as the metal cofactor, but leaves the 3'-5' counterpart intact. This Ce5 DNAzyme requires trivalent light lanthanide ions and shows a rate of 0.16 min(-1) in the presence of 10 μm Ce(3+) ; the activity decreases with heavier lanthanide ions. This is the fastest DNAzyme reported for this reaction, and it might enable applications in chemical biology. As a proof-of-concept, using this DNAzyme, the reactions between phosphorothioate-modified RNA and strongly thiophilic metals (Hg(2+) and Tl(3+) ) were studied as a function of pH.

Enzymatic Synthesis of Nucleic Acids with Defined Regioisomeric 2'-5' Linkages

Information‐bearing nucleic acids display universal 3′‐5′ linkages, but regioisomeric 2′‐5′ linkages occur sporadically in non‐enzymatic RNA synthesis and may have aided prebiotic RNA replication. Herein we report on the enzymatic synthesis of both DNA and RNA with site‐specific 2′‐5′ linkages by an engineered polymerase using 3′‐deoxy‐ or 3′‐O‐methyl‐NTPs as substrates. We also report the reverse transcription of the resulting modified nucleic acids back to 3′‐5′ linked DNA with good fidelity. This enables a fast and simple method for “structural mutagenesis” by the position‐selective incorporation of 2′‐5′ linkages, whereby nucleic acid structure and function may be probed through local distortion by regioisomeric linkages while maintaining the wild‐type base sequence as we demonstrate for the 10–23 RNA endonuclease DNAzyme.

Progress toward synthetic cells

The complexity of even the simplest known life forms makes efforts to synthesize living cells from inanimate components seem like a daunting task. However, recent progress toward the creation of synthetic cells, ranging from simple protocells to artificial cells approaching the complexity of bacteria, suggests that the synthesis of life is now a realistic goal. Protocell research, fueled by advances in the biophysics of primitive membranes and the chemistry of nucleic acid replication, is providing new insights into the origin of cellular life. Parallel efforts to construct more complex artificial cells, incorporating translational machinery and protein enzymes, are providing information about the requirements for protein-based life. We discuss recent advances and remaining challenges in the synthesis of artificial cells, the possibility of creating new forms of life distinct from existing biology, and the promise of this research for gaining a deeper understanding of the nature of living systems.

Structural insights into the effects of 2'-5' linkages on the RNA duplex

The mixture of 2'-5' and 3'-5' linkages generated during the nonenzymatic replication of RNA has long been regarded as a central problem for the origin of the RNA world. However, we recently observed that both a ribozyme and an RNA aptamer retain considerable functionality in the presence of prebiotically plausible levels of linkage heterogeneity. To better understand the RNA structure and function in the presence of backbone linkage heterogeneity, we obtained high-resolution X-ray crystal structures of a native 10-mer RNA duplex (1.32 Å) and two variants: one containing one 2'-5' linkage per strand (1.55 Å) and one containing three such linkages per strand (1.20 Å). We found that RNA duplexes adjust their local structures to accommodate the perturbation caused by 2'-5' linkages, with the flanking nucleotides buffering the disruptive effects of the isomeric linkage and resulting in a minimally altered global structure. Although most 2'-linked sugars were in the expected 2'-endo conformation, some were partially or fully in the 3'-endo conformation, suggesting that the energy difference between these conformations was relatively small. Our structural and molecular dynamic studies also provide insight into the diminished thermal and chemical stability of the duplex state associated with the presence of 2'-5' linkages. Our results contribute to the view that a low level of 2'-5' substitution would not have been fatal in an early RNA world and may in contrast have been helpful for both the emergence of nonenzymatic RNA replication and the early evolution of functional RNAs.

Functional RNAs exhibit tolerance for non-heritable 2'-5' versus 3'-5' backbone heterogeneity

A plausible process for non-enzymatic RNA replication would greatly simplify models of the transition from prebiotic chemistry to simple biology. However, all known conditions for the chemical copying of an RNA template result in the synthesis of a complementary strand that contains a mixture of 2'-5' and 3'-5' linkages, rather than the selective synthesis of only 3'-5' linkages as found in contemporary RNA. Here we show that such backbone heterogeneity is compatible with RNA folding into defined three-dimensional structures that retain molecular recognition and catalytic properties and, therefore, would not prevent the evolution of functional RNAs such as ribozymes. Moreover, the same backbone heterogeneity lowers the melting temperature of RNA duplexes that would otherwise be too stable for thermal strand separation. By allowing copied strands to dissociate, this heterogeneity may have been one of the essential features that allowed RNA to emerge as the first biopolymer.

Synthesis and structural studies of S-type/N-type-locked/frozen nucleoside analogues and their incorporation in RNA-selective, nuclease resistant 2'-5' linked oligonucleotides

2'-endo locked or frozen (S-type)/3'-endo locked or frozen (N-type) nucleoside analogues were synthesized. Conformational analysis based on (3)J(HH) and NOE measurements is presented which is further confirmed by X-ray crystal structural studies. 2'-5'isoDNA oligonucleotides (ON) were synthesized using these modified nucleoside analogues and UV-T(m) studies of the resultant 2'-5'isoDNA : RNA duplexes reflect the site- and sequence-dependent effects and confirm that the S-type sugar conformations were preferred over the N-type sugar geometry in such duplexes.

Characterization of side reactions during the annealing of small interfering RNAs

Small interfering RNAs (siRNAs) are emerging as a novel therapeutic modality for the specific inhibition of target gene expression. The development of siRNA-based therapeutics requires in-depth knowledge of the manufacturing process as well as adequate analytical methods to characterize this class of molecules. Here the impurity formation during the annealing of siRNA was investigated. Two siRNAs containing common chemical RNA modifications (2'-O-methyl, 2'-deoxy-2'-fluoro, 2'-deoxy-ribose, and phosphorothioate linkages) were used to determine major side reactions-such as 2',3'-isomerization, strand scission, and HF elimination-depending on annealing parameters such as RNA concentration, presence of cations, temperature, and time. Individual impurities were characterized using analytical size exclusion chromatography, denaturing and nondenaturing ion-pair reversed-phase high-performance liquid chromatography, differential scanning calorimetry, and ultraviolet spectrometry. The degradation pathways described in this work can lead to significantly reduced product quality and compromised drug activity. The data reported here provide background to successfully address challenges associated with the manufacture of siRNAs and other nucleic acid therapeutics such as aptamers, spiegelmers, and decoy and antisense oligonucleotides.

Synthesis and RNA binding selectivity of oligonucleotides modified with five-atom thioacetamido nucleic acid backbone structures

Convenient chemical synthesis and incorporation of dithymidine and thymidine-cytidine dimer blocks connected with a five-atom amide linker N3'-CO-CH2-S-CH2 into oligonucleotides (ONs) are reported. The UV-Tm experiments for binding affinities of these mixed backbone ONs with complementary DNA and RNA sequences revealed important results such as significantly higher RNA-binding selectivity as compared with complementary DNA. NMR studies of the dimer blocks suggested a marginal increase in the N-type sugar conformations over that of the native DNA.

RNA: prebiotic product, or biotic invention?

Spectacular advances in structural and molecular biology have added support to the 'RNA world' hypothesis, and provide a mandate for chemistry to explain how RNA might have been generated prebiotically on the early earth. Difficulties in achieving a prebiotically plausible synthesis of RNA, however, have led many to ponder the question posed in the title of this paper. Herein, we review recent experimental work on the assembly of potential RNA precursors, focusing on methods for stereoselective C-C bond construction by aldolisation and related processes. This chemistry is presented in the context of a broader picture of the potential constitutional self-assembly of RNA. Finally, the relative accessibility of RNA and alternative nucleic acids is considered.

A new RNA branching activity: the GIR1 ribozyme

The formation of lariat intermediates during the first step of splicing of group II introns and spliceosomal introns is a well-studied fundamental reaction in molecular biology. Apart from this prominent example, there are surprisingly few occurrences of branched nucleotides or even 2',5'-phosphodiester bonds in biology. We recently described a new ribozyme, the GIR1 branching ribozyme, which catalyzes the formation of a tiny lariat that caps an mRNA. This new example together with work on artificial branching ribozymes and deoxyribozymes shows that branching is facile and points to the possibility that branching reactions could be more prevalent than previously recognized.

Reaction of cytidine nucleotides with cyanoacetylene: support for the intermediacy of nucleoside-2',3'-cyclic phosphates in the prebiotic synthesis of RNA

A robust and prebiotically plausible synthesis of RNA is a key requirement of the "RNA World" hypothesis, but, to date, no such synthesis has been demonstrated. Monomer synthesis strategies involving attachment of preformed nucleobases to sugars have failed, and, even if activated 5'-nucleotides could be made, the hydrolysis of these intermediates in water makes their efficient oligomerisation appear unlikely. We recently reported a synthesis of cytidine-2',3'-cyclic phosphate 1 (C>p) in which the nucleobase was assembled in stages on a sugar-phosphate template. However, 2',3'-cyclic nucleotides (N>p's) also undergo hydrolysis, in this case giving a mixture of the 2'- and 3'-monophosphates. This hydrolysis has previously been seen as making the, otherwise promising, oligomerisation of N>p's seem as unlikely as that of the 5'-activated nucleotides. We now find that cyanoacetylene, the reagent used for the second stage of nucleobase assembly in the synthesis of C>p, also reverses the effect of the hydrolysis by driving efficient cyclisation of C2'p and C3'p back to C>p. Excess cyanoacetylene also derivatises the nucleobase, but this modification is reversible at neutral pH. These findings significantly strengthen the case for N>p's in a prebiotic synthesis of RNA.

Nonenzymatic ligation of short-chained 2'-5'- or 3'-5'-linked oligoribonucleotides on 2'-5'- or 3'-5'-linked complementary templates

5'-pACUG tetraribonucleotides containing 2'-5' or 3'-5' linkages self-condensed on 2'-5'- or 3'-5'-linked complementary decaribonucleotide (5'-CAGUCAGUCA) templates. CD and UV melting studies showed that helix formation took place in all four possible combinations of linkage isomers of the substrate tetramer and the template decamer under the ligation conditions. The hybridization ability followed the order: [3'-5' tetramer with 3'-5' decamer] > [2'-5' tetramer with 3'-5' decamer] > [2'-5' tetramer with 2'-5' decamer] > or = [3'-5' tetramer with 2'-5' decamer]. Each tetramer condensed on the complementary decaribonucletide template to form the corresponding octamer, but the ligation efficiency varied considerably, depending on the types of linkage in the tetramer substrate and the template decamer. The yields of the octamers obtained by the template-directed ligation followed the order: [2'-5' substrate: 2'-5' template] > [3'-5':3'-5'] > [2'-5':3'-5'] > [3'-5':2'-5']. The results demonstrate that a homo-linkage system is preferable for the template-directed synthesis of RNA. The resulting linkage of the octamer formed from the 2'-5'-linked substrate and the 2'-5'-linked template is mainly 2'-5'.

Synthesis, characterization, and biological properties of small branched RNA fragments containing chiral (Rp and Sp) 2',5'-phosphorothioate linkages

Synthetic branched RNA fragments were prepared to examine the stereochemical requirements for hydrolysis of RNA lariats by the yeast debranching enzyme (yDBR). Specifically, two branched trinucleoside diphosphates and a tetranucleoside triphosphate containing a 2',5'-linked phosphorothioate linkage of defined stereochemistry, namely Rp-A(2'ps5'G)pC, Sp-A(2'ps5'G)pC and Sp-ApA(2'ps5'G)pC, were prepared via solution-phase methods. Unlike the all-phosphodiester control, A(2'p5'G)pC, the Rp-thioated trimer was not cleaved by yDBR, demonstrating that changing the pro-Rp oxygen at the 2',5' phosphodiester bond averts hydrolysis by the enzyme. In contrast, the Sp branched compounds (trimer and tetramer) were cleaved yDBR, albeit with reduced efficiency relative to the corresponding all-phosphodiester branched compounds. Furthermore, the small branched RNAs (5 nt) were not cleaved as efficiently as a 18-nt bRNA, suggesting that the enzyme appears to have a stronger preference for larger bRNA substrates. The non-hydrolyzable branched RNA fragments prepared during these studies may be promising candidates for the future co-crystallization and X-ray analyses of DBR:bRNA complexes.

RNA interference by 2′,5′-linked nucleic acid duplexes in mammalian cells

Synthetic small interfering RNA (siRNA) mediated silencing of a specific gene is emerging as a powerful tool for gene regulation. However, their utility is limited for therapeutic applications primarily due to poor stability. The 2',5'-linked oligonucleotides are known to be more stable to nucleolytic degradation than 3',5'-linked oligonucleotides. The 2',5'-linkage is tolerated in the sense strand of the siRNA duplex. However, the 2',5'-linkage is not tolerated in the antisense strand of the siRNA duplex.

Synthesis, nucleic acid hybridization properties and molecular modelling studies of conformationally restricted 3'-O,4'-C-methylene-linked alpha-L-ribonucleotides

Nucleotides with conformationally restricted carbohydrate rings such as locked nucleic acid (LNA), alpha-L-LNA or 2',5'-linked 3'-O,4'-C-methyleribonucleotides exhibit significant potential as building blocks for antigene and antisense strategies. 2',5'-Linked alpha-L-ribo configured monomer X (termed alpha-L-ONA) was designed as a potential structural mimic of alpha-L-LNA. The corresponding phosphoramidite building block of monomer X was obtained in five steps (10% overall yield) from the easily obtainable thymine derivative 1. Incorporation of monomer X into oligodeoxyribonucleotides (ONs) results in dramatically decreased thermal stabilities with DNA/RNA complements (DeltaTm/mod=-11.5 to -17.0 degrees C) compared to unmodified reference ONs. Less pronounced decreases (DeltaTm/mod=-4.5 to -8.5 degrees C) are observed when monomer X is incorporated into triplex forming ONs and targeted against double-stranded DNA (parallel orientation, pyrimidine motif). This biophysical data, together with modelling studies, suggest that 2',5'-linked alpha-L-ONA is a poor structural mimic of alpha-L-LNA.

Preference for ribose over deoxyribose in loop-closing base pairs of extra stable nucleic acid hairpins

We have investigated the effect of switching ribose to deoxyribose at the closing base-pair of an extra-stable RNA hairpin. Specifically, we studied the sequence 5'-GGAC(UUCG)GUCC, a dodecanucleotide that folds into a well-characterized, "extra stable" RNA hairpin structure. Recently, we showed that hairpins containing a 2',5'-linked (UUCG) loop instead of the native 3',5'-linked loop also exhibit extra-stability (Hannoush and Damha, J. Am. Chem. Soc., 2001, 123, 12368-12374). In this article, we show that the ribose units located at the loop-closing positions (i.e., rC4 and rG9) contribute significantly to the stabilization of RNA hairpins, particularly those containing the 3',5'-UUCG loop. Interestingly, the requirement of rC4 and rG9 is more relaxed for DNA hairpins containing the 2',5'-UUCC loop and, in fact, they may be replaced altogether (ribose--> deoxyribose) without affecting stability. The results broaden our understanding of the behavior of highly stable (UUCG) hairpin loops and how they respond to structural perturbation of the loop-closing base pairs.

Synthesis and hybridization studies of oligonucleotides containing 1-(2-deoxy-2-alpha-C-hydroxymethyl-beta-D-ribofuranosyl)thymine (2'-alpha-hm-dT)

We report the first investigation of oligoribonucleotides containing a few 1-(2-deoxy-2-α-C-hydroxymethyl-β-d-ribofuranosyl)thymine units (or 2′-hm-dT, abbreviated in this work as ‘H’). Both the 2′-CH₂O-phosphoramidite and 3′-O-phosphoramidite derivatives of H were synthesized and incorporated into both 2′,5′-RNA and RNA chains. The hybridization properties of the modified oligonucleotides have been studied via thermal denaturation and circular dichroism studies. While 3′,5′-linked H was shown previously to significantly destabilize DNA:RNA hybrids and DNA:DNA duplexes (modification in the DNA strand; ΔT_m ∼ −3°C/insert), we find that 2′,5′-linked H have a smaller effect on 2′,5′-RNA:RNA and RNA:RNA duplexes (ΔT_m = −0.3°C and −1.2°C, respectively). The incorporation of 3′,5′-linked H into 2′,5′-RNA:RNA and RNA:RNA duplexes was found to be more destabilizing (−0.7°C and −3.6°C, respectively). Significantly, however, the 2′,5′-linked H units confer marked stability to RNA hairpins when they are incorporated into a 2′,5′-linked tetraloop structure (ΔT_m = +1.5°C/insert). These results are rationalized in terms of the compact and extended conformations of nucleotides.

Diversity-oriented solid-phase synthesis and biological evaluation of oligonucleotide hairpins as HIV-1 RT RNase H inhibitors

The inhibitory potencies of several hairpins comprising DNA, RNA and 2',5'-linked RNA segments were assessed against the RNase H activity of the human immunodeficiency virus reverse transcriptase (HIV-1 RT), an indispensable enzyme for HIV genomic replication. The hairpin library was constructed via diversity-oriented nucleic-acid synthesis (DONAS), an approach inspired from traditional split-pool synthesis. DONAS provided access to an array of oligonucleotide hairpins possessing distinct conformational, structural and biological properties. The inhibitory potency of these compounds was highly specific towards HIV-1 RT RNase H and strongly depended on the structure of both the stem and tetraloop. Hairpins that have an overall A-type geometry are better inhibitors of RNase H activity than hairpins with 'intermediate' or B-type conformations, although interestingly, the inhibitory activity is quite sensitive to the nucleotide sequence in both the stem and loop regions of the hairpin. The most potent hairpins bear a 3',5'-linked rather than 2',5'-linked RNA loop, but the latter is necessary for activity of hairpins consisting of DNA stems. Inhibitory activity was essentially independent of hairpin thermal stability. The potent hairpins also demonstrated high nuclease resistance in biological media, particularly those bearing a 2',5'-linked tetraloop. These studies collectively bring into light a new class of nucleic acid aptamers that act exclusively upon the retroviral RNase H domain in vitro, and thus represent novel lead compounds for the development of specific and potent HIV-1 RT inhibitors.

Solution structure of 2',5' d(G4C4). Relevance to topological restrictions and nature's choice of phosphodiester links

The NMR structure of 2',5' d(GGGGCCCC) was determined to gain insights into the structural differences between 2',5'- and 3',5'-linked DNA duplexes that may be relevant in elucidating nature's choice of sugar-phosphate links to encode genetic information. The oligomer assumes a duplex with extended nucleotide repeats formed out of mostly N-type sugar puckers. With the exception of the 5'-terminal guanine that assumes the syn glycosyl conformation, all other bases prefer the anti glycosyl conformation. Base pairs in the duplex exhibit slide (-1.96 A) and intermediate values for X-displacement (-3.23 A), as in ADNA, while their inclination to the helical axis is not prominent. Major and minor grooves display features intermediate to A and BDNA. The duplex structure of iso d(GGGGCCCC) may therefore be best characterized as a hybrid of A and BDNA. Importantly, the results confirm that even 3' deoxy 2',5' DNA supports duplex formation only in the presence of distinct slide (>or=-1.6 A) and X-displacement (>or=-2.5 A) for base pairs, and hence does not favor an ideal BDNA topology characterized by their near-zero values. Such restrictions on base pair movements in 2',5' DNA, which are clearly absent in 3',5' DNA, are expected to impose constraints on its ability for deformability of the kind observed in DNA during its compaction and interaction with proteins. It is therefore conceivable that selection pressure relating to the optimization of topological features might have been a factor in the rejection of 2',5' links in preference to 3',5' links.

An unusual "senseless" 2',5'-oligoribonucleotide with potent anti-HIV activity

A new 32-mer 2',5'-oligoribonucleotide of 1-methyl-6-thioinosinic acid (10) has been synthesized. The design of this unique oligoribonucleotide is based on the reported HIV inhibitory activities of both 2',5'-oligonucleotides and the 3',5'-oligoribonucleotides containing the 1-methyl-6-mercaptopurine base. Tm and CD studies of 10 revealed that it has no organized secondary structure, presumably due to the rigidity of the molecule. The synthesized oligomer, 10, showed a potent inhibitory effect on HIV-1RF and significantly inhibited HIV-1 reverse transcriptase.

Selective inhibition of HIV-1 reverse transcriptase (HIV-1 RT) RNase H by small RNA hairpins and dumbbells

We present here the design of a novel class of RNA inhibitors of the RNase H domain of HIV-1 RT, a ribonuclease activity that is essential for viral replication in vivo. Specifically, we show that small RNA hairpins and dumbbells can selectively inhibit the RNase H activity of HIV-1 RT without affecting other cellular RNases H (e.g., E. coli and human RNase H). These results suggest that the inhibitors do not interact with the nucleic acid binding site of RT RNase H, as this region should be well conserved among the various enzymes. The most potent inhibitors displayed IC50 values in the 3-8 microM range. Remarkably, the DNA polymerase activity, an intrinsic property of HIV RT, was not inhibited by the hairpin and dumbbell aptamers, a property not previously observed for any nucleic acid aptamer directed against RT RNase H. The results described here suggest a noncompetitive binding mechanism, as outlined in the differential inhibitory characteristics of each of the nucleic acid aptamers against the bacterial, human, and viral RNase H homologues.

2',5'-linked DNA is a template for polymerase-directed DNA synthesis

Genomes are composed of nucleic acids bearing 3',5'-phosphodiester-linked sugars. The 2',5'-phosphodiester linkage is a fundamental alternative to the natural linkage and is the predominant product of most nontemplate, nonenzymatic oligomerizations of nucleotide monomers. This fact suggests a chemical bias for the formation of 2',5'-phosphodiester bonds, an important consideration in the context of molecular evolution on Earth or elsewhere. Although 2',5'-linked RNA occurs naturally, it is evidently not used to encode genetic information. Nevertheless, the capacity of the 2',5'-phosphodiester linkage to serve as a genetic material has been probed in laboratory experiments. Initial studies examined both self-pairing and pairing with natural nucleic acids. These studies showed that, while 2',5'-linked DNA and RNA form double and triple helices with themselves, their interactions with natural nucleic acids are asymmetric-pairing is seen with 3',5'-linked RNA but not DNA. Although the ability to form a stable structure (such as a helix) is likely a necessary condition for nonenzymatic information transfer, in the case of enzymatic reactions this precondition may be expected to be lifted in cases where the enzyme can serve as a "template for the template" and make up for structural deficiencies that would be fatal to its abiotic counterpart. In support of this suggestion, we demonstrate that 2',5'-linked DNA is a template for enzymatic synthesis of natural DNA with a variety of DNA polymerases and reverse transcriptases directing the incorporation of all four natural nucleotides with fidelity.

A novel RNA motif based on the structure of unusually stable 2',5'-linked r(UUCG) loops

We have recently shown that hairpins containing 2',5'-linked RNA loops exhibit superior thermodynamic stability compared to native hairpins comprised of 3',5'-RNA loops [Hannoush, R. N.; Damha, M. J. J. Am. Chem. Soc. 2001, 123, 12368-12374]. A remarkable feature of the 2',5'-r(UUCG) tetraloop is that, unlike the corresponding 3',5'-linked tetraloop, its stability is virtually independent of the hairpin stem composition. Here, we determine the solution structure of unusually stable hairpins of the sequence 5'-G(1)G(2)A(3)C(4)-(U(5)U(6)C(7)G(8))-G(9)(U/T(10))C(11)C(12)-3' containing a 2',5'-linked RNA (UUCG) loop and either an RNA or a DNA stem. The 2',5'-linked RNA loop adopts a new fold that is completely different from that previously observed for the native 3',5'-linked RNA loop. The 2',5'-RNA loop is stabilized by (a). U5.G8 wobble base pairing, with both nucleotide residues in the anti-conformation, (b). extensive base stacking, and (c). sugar-base and sugar-sugar contacts, all of which contribute to the extra stability of this hairpin structure. The U5:G8 base pair stacks on top of the C4:G9 loop-closing base pair and thus appears as a continuation of the stem. The loop uracil U6 base stacks above U5 base, while the cytosine C7 base protrudes out into the solvent and does not participate in any of the stabilizing interactions. The different sugar pucker and intrinsic bonding interactions within the 2',5'-linked ribonucleotides help explain the unusual stability and conformational properties displayed by 2',5'-RNA tetraloops. These findings are relevant for the design of more effective RNA-based aptamers, ribozymes, and antisense agents and identify the 2',5'-RNA loop as a novel structural motif.

Synthesis of lariat-DNA via the chemical ligation of a dumbbell complex

[reaction: see text] An efficient synthesis of a medium-sized DNA lariat through the chemical ligation of a Y-shaped dumbbell precursor is described. The methodology requires only commercially available phosphoramidites and reagents and affords regioisomerically pure lariat molecules. Characterization of the lariat by T(m) analysis reveals that the molecule displays markedly enhanced thermal stability and unimolecular association-dissociation kinetics, consistent with DNA dumbbell behavior.

RNA-cleaving DNA enzymes with altered regio- or enantioselectivity

In vitro evolution methods were used to obtain DNA enzymes that cleave either a 2',5'-phosphodiester following a D-ribonucleotide or a 3',5'-phosphodiester following an L-ribonucleotide. Both enzymes can operate in an intermolecular reaction format with multiple turnover. The DNA enzyme that cleaves a 2',5'-phosphodiester exhibits a k(cat) of approximately 0.01 min(-1) and catalytic efficiency, k(cat)/K(m), of approximately 10(8) M(-1) min(-1). The enzyme that cleaves an L-ribonucleotide is about 10-fold slower and has a catalytic efficiency of approximately 4 x 10(5) M(-1) min(-1). Both enzymes require a divalent metal cation for their activity and have optimal catalytic rate at pH 7-8 and 35-50 degrees C. In a comparison of each enzyme's activity with either its corresponding substrate that contains an unnatural ribonucleotide or a substrate that instead contains a standard ribonucleotide, the 2',5'-phosphodiester-cleaving DNA enzyme exhibited a regioselectivity of 6000-fold, while the L-ribonucleotide-cleaving DNA enzyme exhibited an enantioselectivity of 40-fold. These molecules demonstrate how in vitro evolution can be used to obtain regio- and enantioselective catalysts that exhibit specificities for nonnatural analogues of biological compounds.

Direct measurement of the association constant of HER2/neu antisense oligonucleotide to its target RNA sequence using a molecular beacon

A molecular beacon approach was developed to directly determine the association constant of RNA-DNA hybrid formation. The molecular beacon was composed of a 15-nt loop structure containing the antisense sequence that can hybridize with the AUG translational start site of the HER2/neu gene, which is overexpressed in a significant proportion of breast, ovarian, and lung tumors. The equilibrium association constant (Ka) of DNA binding to the RNA oligonucleotide was 6.4 +/- 0.14 x 10(7) M(-1) in the presence of 150 mM NaCl at 22 degrees C. The free energy change (AG) associated with RNA-DNA hybrid formation was -10.7 kcal/mole. The melting temperature (Tm) of RNA-DNA hybrid was 64.4 degrees C +/- 1 degree C in the presence of 150 mM NaCl. The RNA-DNA hybrid was more stable than the corresponding DNA-DNA duplex in 150 mM NaCl, as judged by both Ka and Tm data. We also determined the Ka, deltaG, and Tm values of RNA-DNA and DNA-DNA duplex formation in the presence of three monovalent cations, Li+, K+, and Cs+. The feasibility of this method was also investigated using a phosphorothioate molecular beacon. The information generated through this new approach for thermodynamic measurements might be useful for the design of oligonucleotides for antisense therapeutics.

Structural basis for the unusual properties of 2',5' nucleic acids and their complexes with RNA and DNA

To provide insights into the unusual properties of 2',5' nucleic acids (iso nucleic acids), that includes their rejection by Nature as information molecules, modeling studies have been carried out to examine if they indeed possess the stereochemical ability to form helical duplexes and triplexes, just as their 3',5' linked constitutional isomers. The results show that the formation of helical duplexes with 2',5' linkages demands a mandatory displacement of the Watson and Crick base pairs from the helical axis, as a direct consequence of the lateral shift of the sugar-phosphate backbone from the periphery towards the interior of the helix. Thus, both duplexes and triplexes formed with a 2',5'-sugar-phosphate backbone possess this intrinsic trait, manifested normally only in A type duplexes of DNA and RNA. It was found that only a 10-fold symmetric parallel triplex with isomorphous T.AT triplets is stereochemically favorable for isoDNA with 'extended' nucleotide repeats, unlike the 12-fold symmetric triplex favored by DNA. The wider nature of a 12-fold triplex, concomitant with mandatory slide requirement for helix formation in isoDNA, demands even larger displacement, especially with 'extended' nucleotide structural repeats, thereby violating symmetry. However, a symmetric triplex possessing higher twist, can be naturally formed for isoDNA with a 'compact' nucleotide repeat. Two nanosecond molecular dynamics simulation of a 2',5'-B DNA duplex, formed with an intrinsic base pair displacement of -3.3 A, does not seem to favor a total transition to a typical A type duplex, although enhanced slide, X-displacement, decrease in helical rise and narrowing of the major groove during simulation seem to indicate a trend. Modeling of the interaction between the chimeric isoDNA.RNA duplex and E. coli RNase H has provided a structural basis for the inhibitory action of the enzyme. Interaction of residues Gln 80, Trp 81, Asn 16 and Lys 99, of E. coli RNase H with DNA of the DNA.RNA hybrid, are lost when the DNA backbone is replaced by isoDNA. Based on modeling and experimental observations, it is argued that 2',5' nucleic acids possess restricted conformational flexibility for helical polymorphism. The inability of isoDNA to favor the biologically relevant B form duplex and the associated topological inadequacies related to nucleic acid compaction and interactions with regulatory proteins may be some of the factors that might have led to the rejection of 2',5' links.

Remarkable stability of hairpins containing 2',5'-linked RNA loops

We report here the results of a comparative study of hairpin loops that differ in the connectivity of phosphodiester linkages (3',5'- versus 2',5'-linkages). In addition, we have studied the effect of changing the stem composition on the thermodynamic stability of hairpin loops. Specifically, we constructed hairpins containing one of six stem duplex combinations, i.e., DNA:DNA ("DD"), RNA:RNA ("RR"), DNA:RNA ("DR"), 2',5'-RNA:RNA ("RR"), 2',5'-RNA:DNA ("RD"), and 2',5'-RNA:2',5'-RNA ("RR"), and one of three tetraloop compositions, i.e., 2',5'-RNA ("R"), RNA ("R"), and DNA ("D"). All hairpins contained the conserved and well-studied loop sequence 5'-...C(UUCG)G...-3' [Cheong et al. Nature 1990, 346, 680-682]. We show that the 2',5'-linked loop C(UUCG)G, i.e.,...C(3'p5')U(2'p5')U(2'p5')C(2'p5')G(2'p5')G(3'p5')..., like its "normal" RNA counterpart, forms an unusually stable tetraloop structure. We also show that the stability imparted by 2',5'-RNA loops is dependent on base sequence, a property that is shared with the regioisomeric 3',5'-RNA loops. Remarkably, we find that the stability of the UUCG tetraloop is virtually independent of the hairpin stem composition (DD, RR, RR, etc.), whereas the native RNA tetraloop exerts extra stability only when the stem is duplex RNA (R:R). As a result, the relative stabilities of hairpins with a 2',5'-linked tetraloop, e.g. ggac(UUCG)gtcc (T(m) = 61.4 degrees C), are often superior to those with RNA tetraloops, e.g. ggac(UUCG)gtcc (T(m) = 54.6 degrees C). In fact, it has been possible to observe the formation of a 2',5'-RNA:DNA hybrid duplex by linking the hybrid's strands to a (UUCG) loop. These duplexes (RD), which are not stable enough to form in an intermolecular complex [Wasner et al. Biochemistry 1998, 37, 7478-7486], were stable at room temperature (T(m) approximately 50 degrees C). Thus, 2',5'-loops have potentially important implications in the study of nucleic acid complexes where structural data are not yet available. Furthermore, they may be particularly useful as structural motifs for synthetic ribozymes and nucleic acid "aptamers".

Conformational rigidity introduced by 2',5'-phosphodiester links in DNA

Conformational properties of 2',5'-linked 3'-deoxyribonucleotides have been compared with their natural isomer using CD spectroscopy. It is inferred from the salt induced titration curves that the 2',5'-linked-3'deoxyribonucleotides have rigid phosphodiester backbone.

NMR structure of a 2',5' RNA favors A type duplex with compact C2'endo nucleotide repeat

In order to provide a structural basis for the unusual properties of 2',5' nucleic acids, especially their unsuitability as information molecules, we report here a high resolution NMR structure of a 2',5' RNA fragment r(GCCGCGGC). It forms an A type duplex with C2'endo compact nucleotide repeat, instead of the familiar C3'endo compact nucleotide (seen in RNA) supporting the deductions made earlier from stereochemical considerations. This data together with the observation that 2',5' nucleic acids require mandatory slide and displacement for duplex and triplex structure formation suggest their reluctance to form the biologically relevant B type duplex. It is argued that this lack of flexibility for helical polymorphism and other inadequacies as a consequence of this may be a contributing factor for the rejection of 2',5' links by nature. The structure exhibits interesting features such as the syn glycosyl conformation for the terminal guanine and a hydrogen bond between O3' hydroxyl and anionic oxygen of the phosphate.