2′- O -Carbamate-containing oligonucleotides: synthesis and properties

Cationic oligonucleotide derivatives and conjugates: A favorable approach for enhanced DNA and RNA targeting oligonucleotides

Antisense oligonucleotides (ASOs) have the ability of binding to endogenous nucleic acid targets, thereby inhibiting the gene expression. Although ASOs have great potential in the treatment of many diseases, the search for favorable toxicity profiles and distribution has been challenging and consequently impeded the widespread use of ASOs as conventional medicine. One strategy that has been employed to optimize the delivery profile of ASOs, is the functionalization of ASOs with cationic amine groups, either by direct conjugation onto the sugar, nucleobase or internucleotide linkage. The introduction of these positively charged groups has improved properties like nuclease resistance, increased binding to the nucleic acid target and improved cell uptake for oligonucleotides (ONs) and ASOs. The modifications highlighted in this review are some of the most prevalent cationic amine groups which have been attached as single modifications onto ONs/ASOs. The review has been separated into three sections, nucleobase, sugar and backbone modifications, highlighting what impact the cationic amine groups have on the ONs/ASOs physiochemical and biological properties. Finally, a concluding section has been added, summarizing the important knowledge from the three chapters, and examining the future design for ASOs.

Postsynthetic On-Column 2' Functionalization of RNA by Convenient Versatile Method

We report a universal straightforward strategy for the chemical synthesis of modified oligoribonucleotides containing functional groups of different structures at the 2' position of ribose. The on-column synthetic concept is based on the incorporation of two types of commercial nucleotide phosphoramidites containing orthogonal 2'-O-protecting groups, namely 2'-O-thiomorpholine-carbothioate (TC, as "permanent") and 2'-O-tert-butyl(dimethyl)silyl (tBDMS, as "temporary"), to RNA during solid-phase synthesis. Subsequently, the support-bound RNA undergoes selective deprotection and follows postsynthetic 2' functionalization of the naked hydroxyl group. This convenient method to tailor RNA, utilizing the advantages of solid phase approaches, gives an opportunity to introduce site-specifically a wide range of linkers and functional groups. By this strategy, a series of RNAs containing diverse 2' functionalities were synthesized and studied with respect to their physicochemical properties.

Synthesis and properties of cationic 2'-O-[N-(4-aminobutyl)carbamoyl] modified oligonucleotides

2'-O-[N-(4-Aminobutylcarbamoyl)]uridine (U(abcm)) was synthesized and incorporated into oligonucleotides. The oligonucleotides incorporating U(abcm) formed more stable duplexes with their complementary and mismatched RNAs than those containing 2'-O-carbamoyluridine (U(cm)). The stability of duplex with a U(abcm)-rG base pair showed higher thermostability than the duplex having unmodified U-rG base pair. The U(abcm) residue showed enhanced resistance to snake venome phosphodiesterase.

Synthesis and hybridization of 2'-O-methyl-RNAs incorporating 2'-O-carbamoyluridine and unique participation of the carbamoyl group in U-G base pair

2'-O-Carbamoyluridine (U(cm)) was synthesized and incorporated into DNAs and 2'-O-Me-RNAs. The oligonucleotides incorporating U(cm) formed less stable duplexes with their complementary and U(cm)-U, U(cm)-C single-base mismatched DNAs and RNAs in comparison with those without the carbamoyl group. On the contrary, the T(m) analyses revealed that the duplexes with a mismatched U(cm)-G base pair showed almost the same thermostability as the corresponding unmodified duplexes. Molecular dynamics (MD) simulations of the U(cm)-modified 2'-O-Me-RNA/RNA duplexes with U(cm)-G mismatched base pair suggested that the carbamoyl group could participate in the U(cm)-G base pair by an additional intermolecular hydrogen bond between the carbamoyl oxygen and the H2 of the guanine base.

Uridine 2'-carbamates: facile tools for oligonucleotide 2'-functionalization

A facile method for preparation of uridine 2'-carbamate derivatives based on reaction of 3',5'-disilyl-protected uridine with 1,1'-carbonyldiimidazole followed by treatment with an aliphatic amine is presented. A phosphoramidite monomer suitable for automated oligonucleotide synthesis is obtained in a few steps. The compounds are useful for the introduction of various labels and modifications into an oligonucleotide chain. Although 2'-carbamate modification is somewhat destabilizing for DNA-DNA and DNA-RNA duplexes, it is suitable for the direction of ligands into the minor groove of duplexes or at non-base-paired sites (e.g., loops and bulges) of oligonucleotides. Pyrene-modified oligonucleotide 2'-carbamates show a considerable increase in fluorescence intensity upon hybridization to a complementary RNA (but not DNA).

A general method for the synthesis of 2'-O-cyanoethylated oligoribonucleotides having promising hybridization affinity for DNA and RNA and enhanced nuclease resistance

[reaction: see text] An effective method for the synthesis of 2'-O-cyanoethylated oligoribonucleotides as a new class of 2'-O-modified RNAs was developed. The reaction of appropriately protected ribonucleoside derivatives with acrylonitrile in t-BuOH in the presence of Cs2CO3 gave 2'-O-cyanoethylated ribonucleoside derivatives in excellent yields, which were converted by a successive selective deprotection/protection strategy to 2'-O-cyanoethylated 5'-O-dimethoxytritylribonucleoside 3'-phosphoramidite derivatives in high yields. Fully 2'-O-cyanoethylated oligoribonucleotides, (Uce)12 and (GceAceCceUce)3, were successfully synthesized in the phosphoramidite approach by use of the phosphoramidite building blocks. It was also found that oligoribonucleotides having a 2'-O-cyanoethylated ribonucleoside (Uce, Cce, Ace, or Gce) could be obtained by the selective removal of the TBDMS group from fully protected oligoribonucleotide intermediates without loss of the cyanoethyl group by use of NEt3 x 3HF as a desilylating reagent. The detailed T(m) experiments revealed that oligoribonucleotides containing 2'-O-cyanoethylated ribonucleosides have higher hybridization affinity for both DNA and RNA than the corresponding unmodified and 2'-O-methylated oligoribonucleotides. In addition, introduction of a cyanoethyl group into the 2'-position of RNA resulted in significant increase of nuclease resistance toward snake venom and bovine spleen phosphodiesterases compared with that of the methyl group.

Structural rationalization of a large difference in RNA affinity despite a small difference in chemistry between two 2'-O-modified nucleic acid analogues

Chemical modification of nucleic acids at the 2'-position of ribose has generated antisense oligonucleotides (AONs) with a range of desirable properties. Electron-withdrawing substituents such as 2'-O-[2-(methoxy)ethyl] (MOE) confer enhanced RNA affinity relative to that of DNA by conformationally preorganizing an AON for pairing with the RNA target and by improving backbone hydration. 2'-Substitution of the ribose has also been shown to increase nuclease resistance and cellular uptake via changes in lipophilicity. Interestingly, incorporation of either 2'-O-[2-(methylamino)-2-oxoethyl]- (NMA) or 2'-O-(N-methylcarbamate)-modified (NMC) residues into AONs has divergent effects on RNA affinity. Incorporation of 2'-O-NMA-T considerably improves RNA affinity while incorporation of 2'-O-NMC-T drastically reduces RNA affinity. Crystal structures at high resolution of A-form DNA duplexes containing either 2'-O-NMA-T or 2'-O-NMC-T shed light on the structural origins of the surprisingly large difference in stability given the relatively minor difference in chemistry between NMA and NMC. NMA substituents adopt an extended conformation and use either their carbonyl oxygen or amino nitrogen to trap water molecules between phosphate group and sugar. The conformational properties of NMA and the observed hydration patterns are reminiscent of those found in the structures of 2'-O-MOE-modified RNA. Conversely, the carbonyl oxygen of NMC and O2 of T are in close contact, providing evidence that an unfavorable electrostatic interaction and the absence of a stable water structure are the main reasons for the loss in thermodynamic stability as a result of incorporation of 2'-O-NMC-modified residues.

Synthesis and fluorescence studies of multiple labeled oligonucleotides containing dansyl fluorophore covalently attached at 2'-terminus of cytidine via carbamate linkage

Synthesis of modified oligonucleotides in which the specific cytidine nucleoside analogues linked at 2'-OH position via a carbamate bond with an amino ethyl derivative of dansyl fluorophore is reported. For the multiple labeling of oligonucleotides, a strategy involving prelabeling at the monomeric level followed by solid phase assembly of oligonucleotides to obtain regiospecifically labeled probes has been described. The labeled monomer was phosphitylated using 2-cyanoethyl-N,N,N',N'-tetraisopropyl-phosphoramidite (Bis-reagent) and pyridiniumtrifluoro acetate (Py.TFA) as an activator. To ascertain the minimal number of labeled monomers required for a specific length of oligonucleotide for detection and also to assess the effect of carbamate linkage on hybridization, hexamer and 20-mer sequences were selected. Both were labeled with 1, 2, and 3 monomers at the 5'-end and hybridized with normal (unmodified) complementary sequences. As compared to midsequence or 3'-terminal labeling reported earlier, the 5'-terminal labeling has been found to have minimal contact-mediated quenching on duplex formation. This may be due to complementary deoxyguanosine (dG) rich oligonucleotide sequences or CG base pairs at a terminus that is known to yield stronger binding. This is one reason for selecting cytidine for labeling. The results may aid rational design of multiple fluorescent DNA probes for nonradioactive detection of nucleic acids.