Configuration of the 5'-methyl group modulates the biophysical and biological properties of locked nucleic acid (LNA) oligonucleotides

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.

Development of nucleic acid medicines based on chemical technology

Oligonucleotide-based therapeutics have attracted attention as an emerging modality that includes the modulation of genes and their binding proteins related to diseases, allowing us to take action on previously undruggable targets. Since the late 2010s, the number of oligonucleotide medicines approved for clinical uses has dramatically increased. Various chemistry-based technologies have been developed to improve the therapeutic properties of oligonucleotides, such as chemical modification, conjugation, and nanoparticle formation, which can increase nuclease resistance, enhance affinity and selectivity to target sites, suppress off-target effects, and improve pharmacokinetic properties. Similar strategies employing modified nucleobases and lipid nanoparticles have been used for developing coronavirus disease 2019 mRNA vaccines. In this review, we provide an overview of the development of chemistry-based technologies aimed at using nucleic acids for developing therapeutics over the past several decades, with a specific emphasis on the structural design and functionality of chemical modification strategies.

Synthesis and applications of bicyclic sugar modified locked nucleic acids: A review

A large number of Locked Nucleic Acids (LNAs) with variety of modifications and restricted conformations have been developed in the last few decades. These modifications have significantly improved the biological properties of oligonucleotides, when LNAs moieties were incorporated into them. Herein, the synthesis and applications of these modified locked nucleic acids as antisense oligonucleotides are discussed.Supplemental data for this article is available online at https://doi.org/10.1080/15257770.2022.2052316 .

Site-specific incorporation of 5'-methyl DNA enhances the therapeutic profile of gapmer ASOs

We recently showed that site-specific incorporation of 2′-modifications or neutral linkages in the oligo-deoxynucleotide gap region of toxic phosphorothioate (PS) gapmer ASOs can enhance therapeutic index and safety. In this manuscript, we determined if introducing substitution at the 5′-position of deoxynucleotide monomers in the gap can also enhance therapeutic index. Introducing R- or S-configured 5′-Me DNA at positions 3 and 4 in the oligodeoxynucleotide gap enhanced the therapeutic profile of the modified ASOs suggesting a different positional preference as compared to the 2′-OMe gap modification strategy. The generality of these observations was demonstrated by evaluating R-5′-Me and R-5′-Ethyl DNA modifications in multiple ASOs targeting HDAC2, FXI and Dynamin2 mRNA in the liver. The current work adds to a growing body of evidence that small structural changes can modulate the therapeutic properties of PS ASOs and ushers a new era of chemical optimization with a focus on enhancing the therapeutic profile as opposed to nuclease stability, RNA-affinity and pharmacokinetic properties. The 5′-methyl DNA modified ASOs exhibited excellent safety and antisense activity in mice highlighting the therapeutic potential of this class of nucleic acid analogs for next generation ASO designs.

Chemical strategies for strand selection in short-interfering RNAs

Therapeutic small interfering RNAs (siRNAs) are double stranded RNAs capable of potent and specific gene silencing through activation of the RNA interference (RNAi) pathway. The potential of siRNA drugs has recently been highlighted by the approval of multiple siRNA therapeutics. These successes relied heavily on chemically modified nucleic acids and their impact on stability, delivery, potency, and off-target effects. Despite remarkable progress, clinical trials still face failure due to off-target effects such as off-target gene dysregulation. Each siRNA strand can downregulate numerous gene targets while also contributing towards saturation of the RNAi machinery, leading to the upregulation of miRNA-repressed genes. Eliminating sense strand uptake effectively reduces off-target gene silencing and helps limit the disruption to endogenous regulatory mechanisms. Therefore, our understanding of strand selection has a direct impact on the success of future siRNA therapeutics. In this review, the approaches used to improve strand uptake are discussed and effective methods are summarized.

Synthesis, chirality-dependent conformational and biological properties of siRNAs containing 5'-(R)- and 5'-(S)-C-methyl-guanosine

Various chemical modifications have been identified that enhance potency of small interfering RNAs (siRNAs) and that reduce off-target effects, immune stimulation, and toxicities of metabolites of these therapeutic agents. We previously described 5′-C-methyl pyrimidine nucleotides also modified at the 2′ position of the sugar. Here, we describe the synthesis of 2′-position unmodified 5′-(R)- and 5′-(S)-C-methyl guanosine and evaluation of these nucleotides in the context of siRNA. The (R) isomer provided protection from 5′ exonuclease and the (S) isomer provided protection from 3′ exonuclease in the context of a terminally modified oligonucleotide. siRNA potency was maintained when these modifications were incorporated at the tested positions of sense and antisense strands. Moreover, the corresponding 5′ triphosphates were not substrates for mitochondrial DNA polymerase. Models generated based on crystal structures of 5′ and 3′ exonuclease oligonucleotide complexes with 5′-(R)- and 5′-(S)-C-methyl substituents attached to the 5′- and 3′-terminal nucleotides, respectively, provided insight into the origins of the observed protections. Structural properties of 5′-(R)-C-methyl guanosine incorporated into an RNA octamer were analysed by X-ray crystallography, and the structure explains the loss in duplex thermal stability for the (R) isomer compared with the (S) isomer. Finally, the effect of 5′-C-methylation on endoribonuclease activity has been explained.

Synthesis and biological evaluation of 5'-C-methyl nucleotide prodrugs for treating HCV infections

Nucleotide prodrugs are of great clinical interest for treating a variety of viral infections due to their ability to target tissues selectively and to deliver relatively high concentrations of the active nucleotide metabolite intracellularly. However, their clinical successes have been limited, oftentimes due to unwanted in vivo metabolic processes that reduce the quantities of nucleoside triphosphate that reach the site of action. In an attempt to circumvent this, we designed novel nucleosides that incorporate a sterically bulky group at the 5'-carbon of the phosphoester prodrug, which we reasoned would reduce the amounts of non-productive PO bond cleavage back to the corresponding nucleoside by nucleotidases. Molecular docking studies with the NS5B HCV polymerase suggested that a nucleotide containing a 5'-methyl group could be accommodated. Therefore, we synthesized mono- and diphosphate prodrugs of 2',5'-C-dimethyluridine stereoselectively and evaluated their cytotoxicity and anti-HCV activity in the HCV replicon assay. All four prodrugs exhibited anti-HCV activity with IC₅₀ values in the single digit micromolar concentrations, with the 5'(R)-C-methyl prodrug displaying superior potency relative to its 5'(S)-C-methyl counterpart. However, when compared to the unmethylated prodrug, the potency is poorer. The poorer potency of these prodrugs may be due to unfavorable steric interactions of the 5'-C-methyl group in the active sites of the kinases that catalyze the formation of active triphosphate metabolite.

Biological applications of xeno nucleic acids

Xeno nucleic acids (XNAs) are a group of chemically modified nucleic acid analogues that have been applied to various biological technologies such as antisense oligonucleotides, siRNAs and aptamers.

Design, synthesis, and duplex-stabilizing properties of conformationally constrained tricyclic analogues of LNA

The design, synthesis and biophysical evaluation of two highly-constrained tricyclic analogues of locked nucleic acid (LNA), which restrict rotation around the C4'-C5'-exocyclic bond (torsion angle γ) and enhance hydrophobicity in the minor groove and along the major groove, are reported. A structural model that provides insights into the sugar-phosphate backbone conformations required for efficient hybridization to complementary nucleic acids is also presented.

Pharmacology of Antisense Drugs

Recent studies have led to a greater appreciation of the diverse roles RNAs play in maintaining normal cellular function and how they contribute to disease pathology, broadening the number of potential therapeutic targets. Antisense oligonucleotides are the most direct means to target RNA in a selective manner and have become an established platform technology for drug discovery. There are multiple molecular mechanisms by which antisense oligonucleotides can be used to modulate RNAs in cells, including promoting the degradation of the targeted RNA or modulating RNA function without degradation. Antisense drugs utilizing various antisense mechanisms are demonstrating therapeutic potential for the treatment of a broad variety of diseases. This review focuses on some of the advances that have taken place in translating antisense technology from the bench to the clinic.

The Medicinal Chemistry of Therapeutic Oligonucleotides

Oligonucleotide-based therapeutics have made rapid progress in the clinic for treatment of a variety of disease indications. Unmodified oligonucleotides are polyanionic macromolecules with poor drug-like properties. Over the past two decades, medicinal chemists have identified a number of chemical modification and conjugation strategies which can improve the nuclease stability, RNA-binding affinity, and pharmacokinetic properties of oligonucleotides for therapeutic applications. In this perspective, we present a summary of the most commonly used nucleobase, sugar and backbone modification, and conjugation strategies used in oligonucleotide medicinal chemistry.

Development of Antisense Drugs for Dyslipidemia

Abnormal elevation of low-density lipoprotein (LDL) and triglyceride-rich lipoproteins in plasma as well as dysfunction of anti-atherogenic high-density lipoprotein (HDL) have both been recognized as essential components of the pathogenesis of atherosclerosis and are classified as dyslipidemia. This review describes the arc of development of antisense oligonucleotides for the treatment of dyslipidemia. Chemically-armed antisense candidates can act on various kinds of transcripts, including mRNA and miRNA, via several different endogenous antisense mechanisms, and have exhibited potent systemic anti-dyslipidemic effects. Here, we present specific cutting-edge technologies have recently been brought into antisense strategies, and describe how they have improved the potency of antisense drugs in regard to pharmacokinetics and pharmacodynamics. In addition, we discuss perspectives for the use of armed antisense oligonucleotides as new clinical options for dyslipidemia, in the light of outcomes of recent clinical trials and safety concerns indicated by several clinical and preclinical studies.

Structural Basis of Duplex Thermodynamic Stability and Enhanced Nuclease Resistance of 5'-C-Methyl Pyrimidine-Modified Oligonucleotides

Although judicious use of chemical modifications has contributed to the success of nucleic acid therapeutics, poor systemic stability remains a major hurdle. The introduction of functional groups around the phosphate backbone can enhance the nuclease resistance of oligonucleotides (ONs). Here, we report the synthesis of enantiomerically pure (R)- and (S)-5'-C-methyl (C5'-Me) substituted nucleosides and their incorporation into ONs. These modifications generally resulted in a decrease in thermal stability of oligonucleotide (ON) duplexes in a manner dependent on the stereoconfiguration at C5' with greater destabilization characteristic of (R)-epimers. Enhanced stability against snake venom phosphodiesterase resulted from modification of the 3'-end of an ON with either (R)- or (S)-C5'-Me nucleotides. The (S)-isomers with different 2'-substituents provided greater resistance against 3'-exonucleases than the corresponding (R)-isomers. Crystal structure analyses of RNA octamers with (R)- or (S)-5'-C-methyl-2'-deoxy-2'-fluorouridine [(R)- or (S)-C5'-Me-2'-FU, respectively] revealed that the stereochemical orientation of the C5'-Me and the steric effects that emanate from the alkyl substitution are the dominant determinants of thermal stability and are likely molecular origins of resistance against nucleases. X-ray and NMR structural analyses showed that the (S)-C5'-Me epimers are spatially and structurally more similar to their natural 5' nonmethylated counterparts than the corresponding (R)-epimers.

Identification of metabolically stable 5'-phosphate analogs that support single-stranded siRNA activity

The ss-siRNA activity in vivo requires a metabolically stable 5'-phosphate analog. In this report we used crystal structure of the 5'-phosphate binding pocket of Ago-2 bound with guide strand to design and synthesize ss-siRNAs containing various 5'-phosphate analogs. Our results indicate that the electronic and spatial orientation of the 5'-phosphate analog was critical for ss-siRNA activity. Chemically modified ss-siRNA targeting human apoC III mRNA demonstrated good potency for inhibiting ApoC III mRNA and protein in transgenic mice. Moreover, ApoC III ss-siRNAs were able to reduce the triglyceride and LDL cholesterol in transgenic mice demonstrating pharmacological effect of ss-siRNA. Our study provides guidance to develop surrogate phosphate analog for ss-siRNA and demonstrates that ss-siRNA provides an alternative strategy for therapeutic gene silencing.

Alternative syntheses of (S)-cEt-BNA: a key constrained nucleoside component of bioactive antisense gapmer sequences

Approaches to the synthesis of the constrained 5-methyluracil nucleoside (S)-cEt-BNA, a key "gapmer" unit in a number of biologically relevant antisense oligonucleotides, are described using 5-methyluridine as starting material. In the shorter synthesis, a nine-step linear sequence afforded a O-protected (S)-cEt-BNA consisting of a [2.2.1]dioxabicycloheptane core in 7% overall yield. A competing reaction in an intramolecular cyclization of a tosylate led to a bicyclic oxetane.

Differential effects on allele selective silencing of mutant huntingtin by two stereoisomers of α,β-constrained nucleic acid

We describe the effects of introducing two epimers of neutral backbone α,β-constrained nucleic acid (CNA) on the activity and allele selectivity profile of RNase H active antisense oligonucleotides (ASOs) targeting a single nucleotide polymorphism (SNP) for the treatment of Huntington's disease (HD). ASOs modified with both isomers of α,β-CNA in the gap region showed good activity versus the mutant allele, but one isomer showed improved selectivity versus the wild-type allele. Analysis of the human RNase H cleavage patterns of α,β-CNA modified ASOs versus matched and mismatched RNA revealed that both isomers support RNase H cleavage on the RNA strand across from the site of incorporation in the ASO--an unusual observation for a neutral linkage oligonucleotide modification. Interestingly, ASOs modified with (R)- and (S)-5'-hydroxyethyl DNA (RHE and SHE respectively) formed by partial hydrolysis of the dioxaphosphorinane ring system in α,β-CNA also showed good activity versus the mutant allele but an improved selectivity profile was observed for the RHE modified ASO. Our observations further support the profiling of neutral and 5'-modified nucleic acid analogs as tools for gene silencing applications.

Rigid 2',4'-difluororibonucleosides: synthesis, conformational analysis, and incorporation into nascent RNA by HCV polymerase

We report on the synthesis and conformational properties of 2'-deoxy-2',4'-difluorouridine (2',4'-diF-rU) and cytidine (2',4'-diF-rC) nucleosides. NMR analysis and quantum mechanical calculations show that the strong stereoelectronic effects induced by the two fluorines essentially "lock" the conformation of the sugar in the North region of the pseudorotational cycle. Our studies also demonstrate that NS5B HCV RNA polymerase was able to accommodate 2',4'-diF-rU 5'-triphosphate (2',4'-diF-rUTP) and to link the monophosphate to the RNA primer strand. 2',4'-diF-rUTP inhibited RNA synthesis in dinucleotide-primed reactions, although with relatively high half-maximal inhibitory concentrations (IC50 > 50 μM). 2',4'-diF-rU/C represents rare examples of "locked" ribonucleoside mimics that lack a bicyclic ring structure.

Hepatitis C virus gene-specific locked nucleic acid enzyme significantly inhibits C gene expression in vitro

AIM: To investigate the inhibitory effects of locked nucleic acid enzyme targeting the hepatitis C virus (HCV) C gene on HCV RNA replication and expression in HepG2.9706 cells.

METHODS: The sequences encoding DNAzyme, thiolmodificated DNAzyme and LNAzyme targeting the HCV C gene were designed and synthesized. The following experimental groups were set up: lipo-DNAzyme, lipo-S-DNAzyme, lipo-LNAzyme, blank control, empty liposomes, and lipo-random-LNAzyme. Transfection was performed using cationic liposomes. The level of HCV RNA and luciferase gene expression in supernatants were tested by real-time fluorescent quantitative PCR and chemiluminescence technique 24, 48 and 96 h after treatment, respectively. Cytotoxicity of LNAzyme was evaluated by MTT assay.

RESULTS: Significant down-regulation of HCV RNA replication and luciferase gene expression was noted in the lipo-LNAzyme group, lipo-DNAzyme group and lipo-S-DNAzyme group compared with the control group (P < 0.05 for all). Relative to the lipo-DNAzyme group and lipo-S-DNAzyme group, the average inhibition rates in the lipo-LNAzyme group were 47.55% and 52.44%, respectively. With the prolongation of the treatment time, the inhibition rate increased. At 96 h, HCR RNA replication and fluorescent protein expression were significantly lower than those before treatment in the lipo-LNAzyme group (P < 0.01 for both), and the average inhibition rates were 79.40% and 84.05%, respectively. No obvious toxicity was observed.

CONCLUSION: LNAzyme has a significant inhibitory effect on HCV C gene replication and expression in vitro, which is stronger than that of the thiolmodificated DNAzyme.

Structure Activity Relationships of α-L-LNA Modified Phosphorothioate Gapmer Antisense Oligonucleotides in Animals

We report the structure activity relationships of short 14-mer phosphorothioate gapmer antisense oligonucleotides (ASOs) modified with α-L-locked nucleic acid (LNA) and related modifications targeting phosphatase and tensin homologue (PTEN) messenger RNA in mice. α-L-LNA represents the α-anomer of enantio-LNA and modified oligonucleotides show LNA like binding affinity for complementary RNA. In contrast to sequence matched LNA gapmer ASOs which showed elevations in plasma alanine aminotransferase (ALT) levels indicative of hepatotoxicity, gapmer ASOs modified with α-L-LNA and related analogs in the flanks showed potent downregulation of PTEN messenger RNA in liver tissue without producing elevations in plasma ALT levels. However, the α-L-LNA ASO showed a moderate dose-dependent increase in liver and spleen weights suggesting a higher propensity for immune stimulation. Interestingly, replacing α-L-LNA nucleotides in the 3′- and 5′-flanks with R-5′-Me-α-L-LNA but not R-6′-Me- or 3′-Me-α-L-LNA nucleotides, reversed the drug induced increase in organ weights. Examination of structural models of dinucleotide units suggested that the 5′-Me group increases steric bulk in close proximity to the phosphorothioate backbone or produces subtle changes in the backbone conformation which could interfere with recognition of the ASO by putative immune receptors. Our data suggests that introducing steric bulk at the 5′-position of the sugar-phosphate backbone could be a general strategy to mitigate the immunostimulatory profile of oligonucleotide drugs. In a clinical setting, proinflammatory effects manifest themselves as injection site reactions and flu-like symptoms. Thus, a mitigation of these effects could increase patient comfort and compliance when treated with ASOs.

Antiviral effects of locked nucleic acid antisense oligonucleotides targeting the HBV preS1 gene in HepG2 2.2.15 cells

AIM: To investigate the inhibitory effects of locked nucleic acid (LNA) antisense oligonucleotides targeting the purine region of the hepatitis B virus (HBV) preS1 gene in HepG2 2.2.15 cells, and to screen effective LNA anti-gene oligonucleotides.

METHODS: LNA anti-gene oligonucleotides of different lengths that were complementary to the purine-abundant regions (2 941-2 962 nt, 3 015-3 036 nt and 3 089-3 110 nt) of the HBV preS1 gene were designed, synthesized, and introduced into HepG2 2.2.15 cells by cationic liposome-mediated transfection. Hepatitis B surface antigen (HBsAg) and HBV DNA levels in cell supernatants were tested by time-resolved fluorescence immune assay (TRFIA) and fluorescent quantitative polymerase chain reaction (FQ-PCR) 1, 3, 5 and 7 d after transfection. The cell toxicity of LNA anti-gene oligonucleotides was detected by methyl thiazolyl tetrazolium (MTT) assay.

RESULTS: LNA anti-gene oligonucleotides targeting the HBV preS1 gene showed strong inhibitory effects on HBV DNA replication and HBsAg expression in vitro, and the effects were time-dependent. Seven days after transfection, the reduced rates of HBV DNA and HBsAg levels were 64.32% and 67.51%, respectively. The inhibitory effects were significantly different between each experimental group and control group (all P < 0.05). The inhibitory effect of the LNA anti-gene oligonucleotide targeting the region 2 941-2 962 nt was most strong. The optimal length of LNA anti-gene oligonucleotides ranges from 20 to 30 bases. No obvious cell toxicity was observed with LNA anti-gene oligonucleotides.

CONCLUSION: LNA anti-gene oligonucleotides targeting the HBV preS1 gene showed strong inhibitory effects on HBV replication in vitro. The inhibitory effect of the LNA anti-gene oligonucleotide targeting the region 2 941-2 962 nt was most strong, and the optimal length of LNA anti-gene oligonucleotides ranges from 20 to 30 bases.

Synthesis and antisense properties of fluoro cyclohexenyl nucleic acid (F-CeNA), a nuclease stable mimic of 2'-fluoro RNA

We report the design and synthesis of 2'-fluoro cyclohexenyl nucleic acid (F-CeNA) pyrimidine phosphoramidites and the synthesis and biophysical, structural, and biological evaluation of modified oligonucleotides. The synthesis of the nucleoside phosphoramidites was accomplished in multigram quantities starting from commercially available methyl-D-mannose pyranoside. Installation of the fluorine atom was accomplished using nonafluorobutanesulfonyl fluoride, and the cyclohexenyl ring system was assembled by means of a palladium-catalyzed Ferrier rearrangement. Installation of the nucleobase was carried out under Mitsunobu conditions followed by standard protecting group manipulations to provide the desired pyrimidine phosphoramidites. Biophysical evaluation indicated that F-CeNA shows behavior similar to that of a 2'-modified nucleotide, and duplexes with RNA showed slightly lower duplex thermostability as compared to that of the more rigid 3'-fluoro hexitol nucleic acid (FHNA). However, F-CeNA modified oligonucleotides were significantly more stable against digestion by snake venom phosphodiesterases (SVPD) as compared to unmodified DNA, 2'-fluoro RNA (FRNA), 2'-methoxyethyl RNA (MOE), and FHNA modified oligonucleotides. Examination of crystal structures of a modified DNA heptamer duplex d(GCG)-T*-d(GCG):d(CGCACGC) by X-ray crystallography indicated that the cyclohexenyl ring system exhibits both the (3)H(2) and (2)H(3) conformations, similar to the C3'-endo/C2'-endo conformation equilibrium seen in natural furanose nucleosides. In the (2)H(3) conformation, the equatorial fluorine engages in a relatively close contact with C8 (2.94 Å) of the 3'-adjacent dG nucleotide that may represent a pseudo hydrogen bond. In contrast, the cyclohexenyl ring of F-CeNA was found to exist exclusively in the (3)H(2) (C3'-endo like) conformation in the crystal structure of the modified A-form DNA decamer duplex [d(GCGTA)-T*-d(ACGC)](2.) In an animal experiment, a 16-mer F-CeNA gapmer ASO showed similar RNA affinity but significantly improved activity compared to that of a sequence matched MOE ASO, thus establishing F-CeNA as a useful modification for antisense applications.

TricycloDNA-modified oligo-2'-deoxyribonucleotides reduce scavenger receptor B1 mRNA in hepatic and extra-hepatic tissues--a comparative study of oligonucleotide length, design and chemistry

We report the evaluation of 20-, 18-, 16- and 14-mer phosphorothioate (PS)-modified tricycloDNA (tcDNA) gapmer antisense oligonucleotides (ASOs) in T_m, cell culture and animal experiments and compare them to their gap-matched 20-mer 2′-O-methoxyethyl (MOE) and 14-mer 2′,4′-constrained ethyl (cEt) counterparts. The sequence-matched 20-mer tcDNA and MOE ASOs showed similar T_m and activity in cell culture under free-uptake and cationic lipid-mediated transfection conditions, while the 18-, 16- and 14-mer tcDNA ASOs were moderate to significantly less active. These observations were recapitulated in the animal experiments where the 20-mer tcDNA ASO formulated in saline showed excellent activity (ED₅₀ 3.9 mg/kg) for reducing SR-B1 mRNA in liver. The tcDNA 20-mer ASO also showed better activity than the MOE 20-mer in several extra-hepatic tissues such as kidney, heart, diaphragm, lung, fat, gastrocnemius and quadriceps. Interestingly, the 14-mer cEt ASO showed the best activity in the animal experiments despite significantly lower T_m and 5-fold reduced activity in cell culture relative to the 20-mer tcDNA and MOE-modified ASOs. Our experiments establish tcDNA as a useful modification for antisense therapeutics and highlight the role of chemical modifications in influencing ASO pharmacology and pharmacokinetic properties in animals.

Insights from crystal structures into the opposite effects on RNA affinity caused by the S- and R-6'-methyl backbone modifications of 3'-fluoro hexitol nucleic acid

Locked nucleic acid (LNA) analogues with 2',4'-bridged sugars show promise in antisense applications. S-5'-Me-LNA has high RNA affinity, and modified oligonucleotides show weakened immune stimulation in vivo. Conversely, an R-5'-methyl group dramatically lowers RNA affinity. To test the effects of S- and R-6'-methyl groups on 3'-fluoro hexitol nucleic acid (FHNA) stability, we synthesized S- and R-6'-Me-FHNA thymidine and incorporated them into oligo-2'-deoxynucleotides. As with LNA, S-6'-Me is stabilizing whereas R-6'-Me is destabilizing. Crystal structures of 6'-Me-FHNA-modified DNAs explain the divergent consequences for stability and suggest convergent origins of these effects by S- and R-6'-Me (FHNA) [-5'-Me (LNA and RNA)] substituents.

Structural requirements for hybridization at the 5'-position are different in α-l-LNA as compared to β-D-LNA

The synthesis and biophysical evaluation of R and S-5'-Me-α-l-LNA nucleoside phosphoramidites and modified oligo-2'-deoxyribonucleotides is reported. Synthesis of the nucleoside phosphoramidites was accomplished in multi-gram quantities starting from diacetone glucose. The 5'-methyl group in the S configuration was introduced by reacting the sugar 5'-aldehyde with MeMgBr. Synthesis of the R-5'-Me isomer was accomplished from the S-5'-Me nucleoside by a late stage inversion using Mitsunobu conditions. Evaluation of the modified oligonucleotides in thermal denaturation experiments revealed that R-5'-Me-α-l-LNA showed similar RNA affinity as α-l-LNA while the S-5'-Me analog was less stabilizing. This result is in contrast to the β-d-series where the S-5'-Me isomer showed LNA-like affinity for RNA while the R-5'-Me group completely reversed the stabilization effect on duplex thermostability.

Synthesis, improved antisense activity and structural rationale for the divergent RNA affinities of 3'-fluoro hexitol nucleic acid (FHNA and Ara-FHNA) modified oligonucleotides

The synthesis, biophysical, structural, and biological properties of both isomers of 3'-fluoro hexitol nucleic acid (FHNA and Ara-FHNA) modified oligonucleotides are reported. Synthesis of the FHNA and Ara-FHNA thymine phosphoramidites was efficiently accomplished starting from known sugar precursors. Optimal RNA affinities were observed with a 3'-fluorine atom and nucleobase in a trans-diaxial orientation. The Ara-FHNA analog with an equatorial fluorine was found to be destabilizing. However, the magnitude of destabilization was sequence-dependent. Thus, the loss of stability is sharply reduced when Ara-FHNA residues were inserted at pyrimidine-purine (Py-Pu) steps compared to placement within a stretch of pyrimidines (Py-Py). Crystal structures of A-type DNA duplexes modified with either monomer provide a rationalization for the opposing stability effects and point to a steric origin of the destabilization caused by the Ara-FHNA analog. The sequence dependent effect can be explained by the formation of an internucleotide C-F···H-C pseudo hydrogen bond between F3' of Ara-FHNA and C8-H of the nucleobase from the 3'-adjacent adenosine that is absent at Py-Py steps. In animal experiments, FHNA-modified antisense oligonucleotides formulated in saline showed a potent downregulation of gene expression in liver tissue without producing hepatotoxicity. Our data establish FHNA as a useful modification for antisense therapeutics and also confirm the stabilizing influence of F(Py)···H-C(Pu) pseudo hydrogen bonds in nucleic acid structures.

Synthesis and biophysical evaluation of 3'-Me-α-L-LNA - Substitution in the minor groove of α-L-LNA duplexes

The synthesis and biophysical evaluation of 3'-Me-α-L-LNA is reported. The synthesis of the nucleoside building block phosphoramidite was accomplished starting from diacetone glucose. The 3'-Me group was introduced in the desired configuration by hydride mediated opening of an exocyclic epoxide. Inversion of the 2'-hydroxyl group was achieved by means of an oxidation/reduction sequence followed by cyclization onto a 5'-leaving group to assemble the [2.2.1] ring system. Biophysical evaluation of 3'-Me-α-L-LNA modified oligonucleotides showed good duplex thermal stabilizing properties which were similar to α-L-LNA. Mismatch discrimination experiments revealed that 3'-Me-α-L-LNA possess slightly enhanced discrimination properties for the GU wobble base-pair as compared to related nucleic acid analogs.

Synthesis and biophysical characterization of R-6'-Me-α-L-LNA modified oligonucleotides

The synthesis and biophysical properties of R-6'-Me-α-L-LNA, which has a methyl group in the (R) configuration on the 2',4'-bridging substituent of α-L-LNA, is reported. The synthesis of the uracil nucleobase phosphoramidite was efficiently accomplished in 14 steps and 8 chromatographic purifications starting from a known sugar intermediate. Biophysical evaluation revealed that substitution along the edge of the major groove does not impair the high affinity duplex forming ability of α-L-LNA modified oligonucleotides.