Molecular Construction of Sulfonamide Antisense Oligonucleotides

Synthesis of LNA gapmers that replace a phosphorothioate linkage with a sulfonamide in the gap region, and their ability to form duplexes with complementary RNA targets

Antisense oligodeoxynucleotides can bind to target RNAs and cleave them using RNase H. Despite the high activity of antisense oligodeoxynucleotides modified with locked nucleic acids (LNA) at several bases at both the 5' and 3' ends (LNA gapmer), toxicity has been reported, necessitating additional backbone modifications to reduce toxicity. In this study, we introduced a sulfonamide linkage into the LNA gapmer to elucidate its fundamental properties such as hybridization, base recognition, and induction of RNase H activity. A new chemically stable sulfonyltriazole was used as a synthetic intermediate to introduce a sulfonamide linkage between the two nucleosides. We studied the properties of the duplex of the sulfonamide-linked gapmer and target RNAs, such as melting temperature, circular dichroism, and cleavage of RNA strands by RNase H. We found that the gapmers had a lower but tolerable duplex stability with base-pair specificity and the ability to induce RNase H activity.

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.

Synthesis and Conformational Analyses of Cyclonucleoside Having 13-Membered Ring Bridging Nucleobase and 5'-Position via a Linker Containing Sulfonamide

A cyclic nucleoside has been designed and synthesized to serve as a conformationally fixed building block for the development of functional oligonucleotides. The bridge was introduced between the nucleobase and the 5'-position to fix the rotation around the C4'-C5' bond, the base orientation, and the sugar puckering all at once. The 13-membered cyclic structure was introduced using a sulfonamide linkage, which retains an N-H group that can be used to attach an additional nucleoside moiety. The sulfonamide linkage was formed through the end-to-end cyclization of an intermediate that contained both a sulfonyltriazole and amino groups. Both 1H NMR and computational studies revealed that the sugar conformation, base orientation, and γ torsion angle were S-type, anti, and trans, respectively. As such, cyclic nucleosides show promise for introducing these specific distorted conformations into functional nucleic acids.

Synthesis, gene silencing activity, thermal stability, and serum stability of siRNA containing four (S)-5'-C-aminopropyl-2'-O-methylnucleosides (A, adenosine; U, uridine; G, guanosine; and C, cytidine)

Herein, we report the synthesis of (S)-5'-C-aminopropyl-2'-O-methyladenosine and (S)-5'-C-aminopropyl-2'-O-methylguanosine phosphoramidites and the properties of small interfering RNAs (siRNAs) containing four (S)-5'-C-aminopropyl-2'-O-methylnucleosides (A, adenosine; U, uridine; G, guanosine; and C, cytidine). The siRNAs containing (S)-5'-C-aminopropyl-nucleosides at the 3'- and 5'-regions of the passenger strand were well tolerated for RNA interference (RNAi) activity. Conversely, the (S)-5'-C-aminopropyl modification in the central region of the passenger strand decreased the RNAi activity. Furthermore, the siRNAs containing three or four consecutive (S)-5'-C-aminopropyl-2'-O-methylnucleosides at the 3'- and 5'-regions of the passenger strand exhibited RNAi activity similar to that of the corresponding 2'-O-methyl-modified siRNAs. Finally, it was observed that (S)-5'-C-aminopropyl modifications effectively improved the serum stability of the siRNAs, compared with 2'-O-methyl modifications. Therefore, (S)-5'-C-aminopropyl-2'-O-methylnucleosides would be useful for improving the serum stability of therapeutic siRNA molecules without affecting their RNAi activities.

DNA with zwitterionic and negatively charged phosphate modifications: Formation of DNA triplexes, duplexes and cell uptake studies

Two phosphate modifications were introduced into the DNA backbone using the Staudinger reaction between the 3’,5’-dinucleoside β-cyanoethyl phosphite triester formed during DNA synthesis and sulfonyl azides, 4-(azidosulfonyl)-N,N,N-trimethylbutan-1-aminium iodide (N+ azide) or p-toluenesulfonyl (tosyl or Ts) azide, to provide either a zwitterionic phosphoramidate with N+ modification or a negatively charged phosphoramidate for Ts modification in the DNA sequence. The incorporation of these N+ and Ts modifications led to the formation of thermally stable parallel DNA triplexes, regardless of the number of modifications incorporated into the oligodeoxynucleotides (ONs). For both N+ and Ts-modified ONs, the antiparallel duplexes formed with complementary RNA were more stable than those formed with complementary DNA (except for ONs with modification in the middle of the sequence). Additionally, the incorporation of N+ modifications led to the formation of duplexes with a thermal stability that was less dependent on the ionic strength than native DNA duplexes. The thermodynamic analysis of the melting curves revealed that it is the reduction in unfavourable entropy, despite the decrease in favourable enthalpy, which is responsible for the stabilisation of duplexes with N+ modification. N+ONs also demonstrated greater resistance to nuclease digestion by snake venom phosphodiesterase I than the corresponding Ts-ONs. Cell uptake studies showed that Ts-ONs can enter the nucleus of mouse fibroblast NIH3T3 cells without any transfection reagent, whereas, N+ONs remain concentrated in vesicles within the cytoplasm. These results indicate that both N+ and Ts-modified ONs are promising for various in vivo applications.