Synthesis and Pairing Properties of Oligonucleotides Containing 3-Hydroxy-4-hydroxymethyl-1-cyclohexanyl Nucleosides

A Visual Compendium of Principal Modifications within the Nucleic Acid Sugar Phosphate Backbone

Nucleic acid chemistry is a huge research area that has received new impetus due to the recent explosive success of oligonucleotide therapy. In order for an oligonucleotide to become clinically effective, its monomeric parts are subjected to modifications. Although a large number of redesigned natural nucleic acids have been proposed in recent years, the vast majority of them are combinations of simple modifications proposed over the past 50 years. This review is devoted to the main modifications of the sugar phosphate backbone of natural nucleic acids known to date. Here, we propose a systematization of existing knowledge about modifications of nucleic acid monomers and an acceptable classification from the point of view of chemical logic. The visual representation is intended to inspire researchers to create a new type of modification or an original combination of known modifications that will produce unique oligonucleotides with valuable characteristics.

The Medicinal Chemistry of Artificial Nucleic Acids and Therapeutic Oligonucleotides

Nucleic acids play a central role in human biology, making them suitable and attractive tools for therapeutic applications. While conventional drugs generally target proteins and induce transient therapeutic effects, nucleic acid medicines can achieve long-lasting or curative effects by targeting the genetic bases of diseases. However, native oligonucleotides are characterized by low in vivo stability due to nuclease sensitivity and unfavourable physicochemical properties due to their polyanionic nature, which are obstacles to their therapeutic use. A myriad of synthetic oligonucleotides have been prepared in the last few decades and it has been shown that proper chemical modifications to either the nucleobase, the ribofuranose unit or the phosphate backbone can protect the nucleic acids from degradation, enable efficient cellular uptake and target localization ensuring the efficiency of the oligonucleotide-based therapy. In this review, we present a summary of structure and properties of artificial nucleic acids containing nucleobase, sugar or backbone modifications, and provide an overview of the structure and mechanism of action of approved oligonucleotide drugs including gene silencing agents, aptamers and mRNA vaccines.

Xeno nucleic acids (XNAs) having non-ribose scaffolds with unique supramolecular properties

DNA and RNA have significance as a genetic materials, therapeutic potential, and supramolecular properties. Advances in nucleic acid chemistry have enabled large-scale synthesis of DNA and RNA oligonucleotides and oligomers...

Synthesis of Piperidine Nucleosides as Conformationally Restricted Immucillin Mimics

The de novo synthesis of piperidine nucleosides from our homologating agent 5,6-dihydro-1,4-dithiin is herein reported. The structure and conformation of nucleosides were conceived to faithfully resemble the well-known nucleoside drugs Immucillins H and A in their bioactive conformation. NMR analysis of the synthesized compounds confirmed that they adopt an iminosugar conformation bearing the nucleobases and the hydroxyl groups in the appropriate orientation.

Therapeutic antisense oligonucleotides for movement disorders

Movement disorders are a group of neurological conditions characterized by abnormalities of movement and posture. They are broadly divided into akinetic and hyperkinetic syndromes. Until now, no effective symptomatic or disease-modifying therapies have been available. However, since many of these disorders are monogenic or have some well-defined genetic component, they represent strong candidates for antisense oligonucleotide (ASO) therapies. ASO therapies are based on the use of short synthetic single-stranded ASOs that bind to disease-related target RNAs via Watson-Crick base-pairing and pleiotropically modulate their function. With information arising from the RNA sequence alone, it is possible to design ASOs that not only alter the expression levels but also the splicing defects of any protein, far exceeding the intervention repertoire of traditional small molecule approaches. Following the regulatory approval of ASO therapies for spinal muscular atrophy and Duchenne muscular dystrophy in 2016, there has been tremendous momentum in testing such therapies for other neurological disorders. This review article initially focuses on the chemical modifications aimed at improving ASO effectiveness, the mechanisms by which ASOs can interfere with RNA function, delivery systems and pharmacokinetics, and the common set of toxicities associated with their application. It, then, describes the pathophysiology and the latest information on preclinical and clinical trials utilizing ASOs for the treatment of Parkinson's disease, Huntington's disease, and ataxias 1, 2, 3, and 7. It concludes with issues that require special attention to realize the full potential of ASO-based therapies.

A Quencher-Free Linear Probe from Serinol Nucleic Acid with a Fluorescent Uracil Analogue

With the goal of developing a quencher-free probe composed of an artificial nucleic acid, the fluorescent nucleobase analogue 5-(perylenylethynyl)uracil (^Pe U), which was incorporated into totally artificial serinol nucleic acid (SNA) as a substitute for thymine, has been synthesized. In the context of a 12-mer duplex with RNA, these fluorophores reduce duplex stability slightly compared with that of an SNA without ^Pe U modification; thus suggesting that structural distortion is not induced by the modification. If two ^Pe Us were incorporated at separate positions in an SNA, the fluorescent emission at λ≈490 nm was clearly enhanced upon hybridization with complementary RNA. A quencher-free SNA linear probe containing three ^Pe Us, each separated by six nucleobases, has been designed. Detection of target RNA with high sensitivity and discrimination of a single-base mismatch has also been demonstrated.

Evaluation of anhydrohexitol nucleic acid, cyclohexenyl nucleic acid and d-altritol nucleic acid-modified 2'-O-methyl RNA mixmer antisense oligonucleotides for exon skipping in vitro

Antisense oligonucleotide (AO) mediated exon skipping has been widely explored as a therapeutic strategy for several diseases, in particular, for rare genetic disorders such as Duchenne muscular dystrophy (DMD). To date, the potential of anhydrohexitol nucleic acid (HNA), cyclohexenyl nucleic acid (CeNA) and altritol nucleic acid (ANA) has not been explored in exon skipping. For the first time, in this study we designed and synthesised HNA, CeNA and ANA-modified 2'-O-methyl (2'-OMe) mixmer AOs on a phosphorothioate (PS) backbone, and evaluated their potential to induce exon 23 skipping in mdx mouse myotubes, as a model system. Our results clearly showed that all three AO candidates modified with HNA, CeNA and ANA could efficiently induce Dmd exon 23 skipping in vitro in parallel to the fully modified 2'-OMePS AO with reduced dual exon 22/23 skipping. In addition, they showed high nuclease resistance and no cytotoxicity compared to the 2'-OMePS AO, demonstrating the applicability of HNA, CeNA and ANA nucleotide-modified AOs in exon skipping.

Oligonucleotides containing a ribo-configured cyclohexanyl nucleoside: probing the role of sugar conformation in base pairing selectivity

The synthesis and a preliminary evaluation of the pairing properties of ribo-cyclohexanyl nucleic acids (r-CNA) is herein reported. Incorporation of a single r-CNA nucleotide into natural duplexes did not enhance their stability, while a very high pairing selectivity for RNA was found. As deduced by comparative analysis of Tm and NMR data, a relationship between pairing selectivity and conformational preferences of the "sugar" moiety of r-CNA (and more generally of six-membered nucleic acids) was suggested.

Molecular simulation of cyclohexanyl nucleic acid (CNA) duplexes with CNA, DNA and RNA and CNA triloop and tetraloop hairpin structures

As part of a selection strategy for artificial nucleic acids (XNA) (to be considered as potential new information systems in vivo), we have carried out a modelling study on cyclohexanyl nucleic acids (CNA) duplexes and hairpins. CNA may form a duplex as well as hairpin structures, having the carbocyclic nucleosides in the (4)C1 conformation (with equatorial basis). The geometry of ds CNA is close to that of a HNA:RNA duplex. We demonstrated that CNA triphosphates function as a substrate for polymerases. Modelling experiments indicate that the monomers are probably presented to the polymerase in the (1)C4 conformation.

Direct observation of two cyclohexenyl (CeNA) ring conformations in duplex DNA

Cyclohexene Nucleic Acids (CeNA), in which the 2'-deoxyribofuranose ring of the DNA building blocks is substituted by a cyclohexenyl ring, were designed as potential mimics of natural nucleic acids for antisense and, later, for siRNA applications. CeNA units, in contrast to HNA (hexitol nucleic acid) building blocks, show more flexibility at the level of the C2'-C3' bond due to the possibility of the cyclohexenyl moiety to adopt different conformations. In order to analyze the influence of CeNA residues onto the helix conformation and hydration of natural nucleic acid structures and to verify the cyclohexenyl ring conformation, a cyclohexenyl-thymine building block was incorporated into the non-self-complementary sequence d(GCG(xT)GCG)/d(CGCACGC) with (xT) a cyclohexene residue. The crystal structure of this sequence has been determined to a resolution of 1.17 Å and contains two duplexes in the asymmetric unit. The global helices belong to the B-type family and the conformations of the cyclohexenyl rings in both duplexes are different. The cyclohexene ring adopts as well the (2)H(3)-conformation (similar to C2'-endo) as the (3)H(2)-conformation (similar to C3'-endo). The crystal packing is stabilized by cobalt hexamine residues and triplet formation.

Oligonucleotides with 1,4-dioxane-based nucleotide monomers

An epimeric mixture of H-phosphonates 5R and 5S has been synthesized in three steps from known secouridine 1. Separation of the epimers has been accomplished by RP-HPLC, allowing full characterization and incorporation of monomers X and Y into 9-mer oligonucleotides using H-phosphonates building blocks 5R and 5S, respectively. A single incorporation of either monomer X or monomer Y in the central position of a DNA 9-mer results in decreased thermal affinity toward both DNA and RNA complements (ΔT(m) = -3.5 °C/-3.5 °C for monomer X and ΔT(m) = -11.0 °C/-6.5 °C for monomer Y). CD measurements do not reveal major rearrangements of the duplexes formed, but molecular modeling suggests that local rearrangement of the sugar phosphate backbone and decreased base interactions with neighboring bases might be the origin of the decreased stability of duplexes.

Exploring the role of chirality in nucleic acid recognition

The study of the base-pairing properties of nucleic acids with sugar moieties in the backbone belonging to the L-series (β-L-DNA, β-L-RNA, and their analogs) are reviewed. The major structural factors underlying the formation of stable heterochiral complexes obtained by incorporation of modified nucleotides into natural duplexes, or by hybridization between homochiral strands of opposite sense of chirality are highlighted. In addition, the perspective use of L-nucleic acids as candidates for various therapeutic applications, or as tools for both synthetic biology and etiology-oriented investigations on the structure and stereochemistry of natural nucleic acids is discussed.

Antisense drug discovery and development

Numerous chemically modified oligonucleotides have been developed so far and show their own unique chemical properties and pharmacodynamic/pharmacokinetic characteristics. Among all non-natural nucleotides, to the best of our knowledge, only five chemistries are currently being tested in clinical trials: phosphorothioate, 2´-O-methyl RNA, 2´-O-methoxyethyl RNA, 2´,4´-bridged nucleic acid/locked nucleic acid and the phosphorodiamidate morpholino oligomer. Since phosphorothioate modification can improve the pharmacokinetics of oligonucleotides, this modification is currently used in combination with all other modifications except phosphorodiamidate morpholino oligomer. For the treatment of metabolic, cardiovascular, cancer and other systemic diseases, the phosphorothioate class of drugs is obviously helpful, while superior efficacies can be observed in phosphorodiamidate morpholino oligomer compared to other classes of oligonucleotides for the treatment of Duchenne muscular dystrophy. Which properties of antisense molecules are actually essential for clinical applications? In this article, we provide an overview of the medicinal chemistry of existing non-natural antisense molecules, as well as their clinical applications, to discuss which properties of antisense oligonuculeotides affect therapeutic potency.

Nucleic acids with a six-membered 'carbohydrate' mimic in the backbone

Starting from pyranose nucleic acids, several series of modified nucleic acids with a six-membered carbohydrate moiety (mimic) have been synthesized and analyzed over a period of 20 years, and this work is summarized here. The process starts with structural and conformational considerations, followed by synthetic efforts and a structural analysis, and ends up with a biological confirmation of the concept, demonstrating that these modified nucleic acids represent very valuable tools in chemistry and biology.

Synthesis and base pairing properties of 1',5'-anhydro-L-hexitol nucleic acids (L-HNA)

Oligonucleotides composed of 1',5'-anhydro-arabino-hexitol nucleosides belonging to the L series (L-HNA) were prepared and preliminarily studied as a novel potential base-pairing system. Synthesis of enantiopure L-hexitol nucleotide monomers equipped with a 2'-(N(6)-benzoyladenin-9-yl) or a 2'-(thymin-1-yl) moiety was carried out by a de novo approach based on a domino reaction as key step. The L oligonucleotide analogues were evaluated in duplex formation with natural complements as well as with unnatural sugar-modified oligonucleotides. In many cases stable homo- and heterochiral associations were found. Besides T(m) measurements, detection of heterochiral complexes was unambiguously confirmed by LC-MS studies. Interestingly, circular dichroism measurements of the most stable duplexes suggested that L-HNA form left-handed helices with both D and L oligonucleotides.

Polymerase-catalysed incorporation of glucose nucleotides into a DNA duplex

The enzymatic recognition of six-membered ring nucleoside triphosphates--in particular the 6'-triphosphates of (beta-D-glucopyranosyl)thymine, (2',3'-dideoxy-beta-D-glucopyranosyl)thymine, (3',4'-dideoxy-beta-D-glucopyranosyl)thymine and (2',3'-dideoxy-beta-D-glucopyranosyl)adenine--was investigated. Despite the facts that the pyranose nucleic acids obtained by polymerisation of these monomers do not hybridise in solution with DNA and that the geometry of a DNA strand in a natural duplex differs from that of a pyranose nucleic acid, elongation of the DNA duplex with all four nucleotide analogues by Vent (exo(-)) polymerase was observed. Modelling experiments showed that hydrogen bonds are formed when 2',3'-dideoxy-beta-homo-T building blocks or beta-D-gluco-T building blocks are incorporated opposite adenosine residues in the template but not when they are incorporated opposite thymine residues in the template. The model shows a near perfect alignment of a secondary hydroxy group at the end of the primer and the alpha-phosphate group of the incoming triphosphate. The results of these experiments provide new information on the role of the active site of the enzyme in the polymerisation reaction.

Screening the structural and functional properties of bicyclo-DNA: bc(ox)-DNA

The synthesis of two novel pyrimidine bicyclonucleosides (bc(ox)-nucleosides) has been accomplished. These bicyclonucleosides each carry a lipophilic benzyloxime substituent on the carbocyclic ring and show improved conformational similarity to 2'-deoxyribonucleosides as shown by their X-ray structures. The thymine-containing bc(ox)-nucleoside was converted into the corresponding phosphoramidite building block and incorporated into oligodeoxyribonucleotides by standard phosphoramidite chemistry. T(m) data with complementary RNA and DNA were measured and compared to corresponding cases of natural and unfunctionalized bc-DNA. It was found that single incorporations of bc(ox) residues destabilize duplexes by roughly 5 degrees C per modification. The destabilization was found to be due to the oxime substituent and not to the bicyclic scaffold itself. No significant alteration of the base-pairing selectivity as a function of the modification was observed. With RNA (but not with DNA) as a complement the relative thermal destabilization of bc(ox)-oligothymidylates was gradually reduced and converted into a stabilizing interaction with increasing numbers of consecutive modifications. While no cellular uptake of bc(ox)-oligonucleotides into HeLa cells occurred without transfecting agents, a significant increase in the transfection rate relative to unmodified DNA was observed in complexation with lipofectamine.

Synthesis of 2'-cyclohexenylnucleosides and corresponding CeNA building blocks

A cyclohexene ring has similar structural properties and conformational behavior to a saturated five-membered furanose ring. In particular, it has good hydrolytic stability. Cyclohexenylnucleosides have been utilized in antiviral drug design, and some nucleosides and oligonucleotides based on the cyclohexene system have been developed. For further investigation of these modified nucleosides and oligonucleotides, synthesis of the chiral cyclohexenylnucleosides in high enantiomeric excess and in bulk quantities is necessary. This unit describes the complete synthesis of four enantiomerically pure 5'-hydroxy-4'-hydroxymethyl-2'-cyclohexenylnucleosides (thymine, cytosine, guanine, and adenine) and the four corresponding N-protected 4'-(monomethoxytrityl)oxymethyl cyclohexenyl nucleic acids (CeNA) building blocks. The chirality of these compounds is 1'S, 4'R, and 5'S.

Oxepane nucleic acids: synthesis, characterization, and properties of oligonucleotides bearing a seven-membered carbohydrate ring

The synthesis and properties of oxepane nucleic acids (ONAs) are described. ONAs are sugar-phosphate oligomers in which the pentofuranose ring of DNA and RNA is replaced with a seven-membered (oxepane) sugar ring. The oxepane nucleoside monomers were prepared from the ring expansion reaction of a cyclopropanated glycal, 1, and their conversion into phosphoramidite derivatives allowed efficient assembly of ONAs on a solid support. ONAs (oT15 and oA15) were found to be much more resistant toward nuclease degradation than natural DNA (dT15 and dA15) in fetal bovine serum (FBS) after 24 h of incubation at 37 degrees C. ONAs also display several attributes in common with the naturally occurring DNA. For example, oT15 exhibited cross-pairing with complementary RNA to give a duplex (oT15/rA15) whose conformation evaluated by CD spectroscopy very closely matched that of the natural DNA/RNA hybrid (dT15/rA15). Furthermore, oT15 was found to elicit Escherichia coli RNase H-mediated degradation of the rA15 strand. When we compared the rates of RNase H-mediated degradation induced by 5- (furanose, dT15), 6- (2'-enopyranose, pT18), and 7-membered (oxepane, oT15) ring oligonucleotides at a temperature that ensures maximum duplex population (10 degrees C), the following trend was observed: dT15 >> oT15 > pT18. The wider implications of these results are discussed in the context of our current understanding of the catalytic mechanism of the enzyme. The homopolymer oT15 also paired with its oxepane complement, oA15, to form a duplex structure that was different [as assessed by circular dichroic (CD) spectroscopy] and of lower thermal stability relative to the native dT15/dA15 hybrid. Hence, ONAs are useful tools for biological studies and provide new insights into the structure and function of natural and alternative genetic systems.

Conformational and chiral selection of oligonucleotides

In view of a better understanding of chiral selection of oligonucleotides, we have studied the hybridization of D- and L-CNA (cyclohexane nucleic acids) and D- and L-DNA, with chiral D-beta-homo-DNA and achiral PNA (peptide nucleic acids). PNA hybridizes as well with D-DNA, L-DNA as with D-beta-homo-DNA. The structure of the PNA x D-beta-homo-DNA complex is different from the PNA x DNA duplexes. D-CNA prefers D-DNA as hybridization partner, while L-CNA prefers D-beta-homo-DNA as hybridization partner. The conformation of the enantiomeric oligonucleotides D-CNA and L-CNA in the supramolecular complex with D-DNA and D-beta-homo-DNA, respectively, is different. These data may contribute to the confirmation of a hypothesis of the existence of achiral informative polymers as RNA predecessor, and to the understanding of homochirality of nucleic acids.

Structural insights into the effect of isonucleosides on B-DNA duplexes using molecular-dynamics simulations

Some structural insights into the conformations of the isonucleosides containing duplexes have been provided. Unrestrained molecular-dynamics simulations on 18-mer duplexes with isonucleosides incorporated at the 3'-end or in the center of one strand have been carried out with explicit solvent under periodic boundary conditions using the AMBER force field and the particle mesh Ewald method. The Watson–Crick hydrogen-bonding patterns of the duplexes studied remained intact throughout the simulation. For the modified duplexes, the changes observed in the inter-base pair parameters and backbone torsional angles were primarily localized at the isonucleoside-inserted area. All five structures studied remained in the B-form family. The decreased stacking abilities indicated by the large changes in inter-base pair parameters and the large changes in backbones made the modified duplexes show a minor thermal destabilization in comparison with native DNA. The MM_PBSA method for estimating binding free energies on two complementary strands was used. The results showed that the binding free energies of isonucleoside-incorporated DNA duplexes were lower than the native DNA duplex, which is in good agreement with experimental observations.

NMR structure determination of a modified DNA oligonucleotide containing a new intercalating nucleic acid

The intercalating nucleic acid (INA) presented in this paper is a novel 1-O-(1-pyrenylmethyl)glycerol DNA intercalator that induces high thermal affinity for complementary DNA. The duplex examined contained two INA intercalators, denoted X, inserted directly opposite each other: d(C(1)T(2)C(3)A(4)A(5)C(6)X(7)C(8)A(9)A(10)G(11)C(12)T(13)):d(A(14)G(15)C(16)T(17)-T(18)G(19)X(20)G(21)T(22)T(23)G(24)A(25)G(26)). Unlike most other nucleotide analogues, DNA with INA inserted has a lower affinity for hybridizing to complementary DNA with an INA inserted directly opposite than to complementary unmodified DNA. In this study we used two-dimensional (1)H NMR spectroscopy to determine a high-resolution solution structure of the weak INA-INA duplex. A modified ISPA approach was used to obtain interproton distance bounds from NOESY cross-peak intensities. These distance bounds were used as restraints in molecular dynamics (rMD) calculations. Twenty final structures were generated for the duplex from a B-type DNA starting structure. The root-mean-square deviation (RMSD) of the coordinates for the 20 structures of the complex was 1.95 A. This rather large value, together with broad lines in the area of insertion, reflect the high degree of internal motion in the complex. The determination of the structure revealed that both intercalators were situated in the center of the helix, stacking with each other and the neighboring nucleobases. The intercalation of the INAs caused an unwinding of the helix in the insertion area, creating a ladderlike structure. The structural changes observed upon intercalation were mainly of local character; however, a broadening of the minor groove was found throughout the helix.

Synthesis and Conformational Analysis of 1-[2,4-Dideoxy-4-C-hydroxymethyl-α-l-lyxopyranosyl]thymine

Previously different types of nucleosides with a six-membered carbohydrate moiety have been evaluated for their potential antiviral and antibiotic properties and as building blocks in nucleic acid synthesis. However, a pyranose nucleoside with a 1,4-substitution pattern like 1-[2,4-dideoxy-4-C-hydroxymethyl-alpha-l-lyxopyranosyl]thymine (4) has not been studied yet. Modeling suggested that this nucleoside would show the (4)C(1) conformation in contrast to anhydrohexitol nucleosides (1) whose most stable conformation is (1)C(4). The key to the synthesis of 4 involves the stereoselective introduction of the hydroxymethyl group onto the C-4 carbon of the pyranose sugar. Attempts to achieve this via hydroboration/oxidation of a C-4'-exocyclic vinylic intermediate selectively yielded the undesired alpha-directed hydroxymethyl group. Therefore, we envisaged another approach in which the C-4 substituent was introduced upon treatment of 2,3-O-isopropylidene-1-O-methyl-4-O-phenoxythiocarbonyl-alpha-l-lyxopyranose with beta-tributylstannyl styrene. This allowed stereoselective beta-directed introduction of a 2-phenylethenyl group at C-4, which was converted via oxidation/reduction (OsO(4), NaIO(4)/NaBH(4)) into the desired 4-hydroxymethyl group (20). The resulting 1-O-methyl-2,3,6-tri-O-acetyl-protected sugar was coupled with silylated thymine, using SnCl(2) as Lewis acid (22). After suitable protection, Barton deoxygenation of the 2'-hydroxyl function of the obtained ribo-nucleoside yielded the desired 2'-deoxynucleoside 4, indeed showing the expected equatorial orientation of the thymine ring ((4)C(1)).

DNA analogues: from supramolecular principles to biological properties

Mainly driven by the needs of antisense research, a large number of oligonucleotide analogues have been prepared and evaluated over the last 15 years. Besides minor structural modifications of the building blocks of DNA and RNA itself, a considerable effort has been devoted to the de novo design of nucleoside analogues with improved binding properties. A particularly successful concept turned out to be that of conformational restriction. This review focuses on recent advances in this area and tries to summarize scope and limitations of this design principle.

Hybridization between "six-membered" nucleic acids: RNA as a universal information system

Within the polyA:polyT recognition system, cross-pairing between several nucleic acids with a phosphorylated six-membered carbohydrate (mimic) as repeating unit in the backbone structure has been observed. All investigated nucleic acids (except for beta-homo-DNA) hybridize with RNA, leaving RNA as a versatile biopolymer for informational transfer. [reaction: see text]

Alpha-homo-DNA and RNA form a parallel oriented non-A, non-B-type double helical structure

Cross-talking between nucleic acids is a prerequisite for information transfer. The absence of observed base pairing interactions between pyranose and furanose nucleic acids has excluded considering the former type as a (potential) direct precursor of contemporary RNA and DNA. We observed that alpha-pyranose oligonucleotides (alpha-homo-DNA) are able to hybridize with RNA and that both nucleic acid strands are parallel oriented. Hybrids between alpha-homo-DNA and DNA are less stable. During the synthesis of alpha-homo-DNA we observed extensive conversion of N6-benzoyl-5-methylcytosine into thymine under the usual deprotection conditions of oligonucleotide synthesis. Alpha-homo-DNA:RNA represents the first hybridization system between pyranose and furanose nucleic acids. The duplex formed between alpha-homo-DNA and RNA was investigated using CD, NMR spectroscopy, and molecular modeling. The general rule that orthogonal orientation of base pairs prevents hybridization is infringed. NMR experiments demonstrate that the base moieties of alpha-homo-DNA in its complex with RNA, are equatorially oriented and that the base moieties of the parallel RNA strand are pseudoaxially oriented. Modeling experiments demonstrate that the duplex formed is different from the classical A- or B-type double stranded DNA. We observed 15 base pairs in a full helical turn. The average interphosphate distance in the RNA strand is 6.2 A and in the alpha-homo-DNA strand is 6.9 A. The interstrand P-P distance is much larger than found in the typical A- and B-DNA. Most helical parameters are different from those of natural duplexes.

Cyclohexene nucleic acids (CeNA) form stable duplexes with RNA and induce RNase H activity

Cyclohexene nucleic acids (CeNA) were synthesized using classical phosporamidite chemistry. Incorporation of a cyclohexene nucleo-side in a DNA chain leads to an increase in stability of the DNA/RNA duplex. CeNA is stable against degradation in serum. A CeNA/RNA hybrid is able to activate E. Coli RNase H. resulting in cleavage of the RNA strand.

The cyclohexene ring system as a furanose mimic: synthesis and antiviral activity of both enantiomers of cyclohexenylguanine

Both enantiomers of cyclohexenylguanine were synthesized in a stereospecific way starting from the same starting material: R-(-)-carvone. Both compounds showed potent and selective anti-herpesvirus activity (HSV-1, HSV-2, VZV, CMV). The binding of both cyclohexene nucleosides in the active site of HSV-1 thymidine kinase was investigated, and a model for the binding of both enantiomers is proposed. The amino acids involved in binding of the optical antipodes are the same, but the interaction energy of both enantiomers is slightly different. This may be attributed to the interaction of the secondary hydroxyl function of the nucleoside analogues with Glu-225. Structural analysis has demonstrated the flexibility of the cyclohexenyl system, and this may be considered as an important conformational characteristic explaining the potent antiviral activity.

Conformationally restricted carbohydrate-modified nucleic acids and antisense technology

The study of conformationally restricted carbohydrate modified nucleic acids has given new insights into the concept of the antisense technology. We learned to understand the structural requirements of a modified nucleic acid to function as steric blocker for RNA. Several of the physicochemical and conformational factors influencing duplex stabilization are analyzed with respect to their relative importance for the antisense field.