Reagents for the preparation of two oligonucleotides per synthesis (TOPS)

A Facile and General Tandem Oligonucleotide Synthesis Methodology for DNA and RNA

Tandem oligonucleotide synthesis (TOS) is an attractive strategy to increase automated oligonucleotide synthesis efficiency. TOS is accomplished via the introduction of an immolative linker within a single sequence composed of multiple oligonucleotide fragments. Here, we report the use of a commercially available building block, typically utilized for the chemical phosphorylation of DNA/RNA oligomers, to perform TOS. We show that the 2,2'-sulfonyldiethylene linker is efficiently self-immolated during the standard deprotection of DNA and RNA and presents itself as a generalizable methodology for nucleic acid TOS. Furthermore, we show the utility of this methodology by assembling a model siRNA construct, and showcase a template-directed ligation pathway to incorporate phosphoramidate or pyrophosphate linkages within DNA oligomers.

MicroRNA Pools Synthesized Using Tandem Solid-Phase Oligonucleotide Synthesis

Herein, we describe a new approach to make pools of microRNA targeting breast cancer cells. The microRNA pools were synthesized at once on the same solid support using the "Tandem Oligonucleotide Synthesis" strategy. We make up to four consecutive microRNAs (miR129-1-5p, miR31, miR206, and miR27b-3p) using 2'/3'OAc nucleotide phosphoramidites, with the total length of the pool reaching 88 nucleotides. The developed phosphoramidites, when combined, give a cleavable moiety that separates the microRNAs and is cleaved using standard post-RNA synthesis cleavage conditions. Furthermore, we investigate making branched pools (microRNA dendrimers) versus linear pools as a strategy to further improve the product yields. Our approach provides with microRNA pools in high yields, which is of relevance to the growing demand on synthetic RNA oligomers for nucleic acid research and technology.

New Cleavable Spacers for Tandem Synthesis of Multiple Oligo­nucleotides

In solid-phase oligonucleotide synthesis, a single oligonucleotide is generally acquired from a column loaded with a specific solid support. Herein, we have developed new cleavable spacer (CS) derivatives for tandem synthesis of multiple oligonucleotides on a single column­. Four CS analogues were designed, synthesized, and inserted between two oligonucleotide sequences using an automated oligonucleotide synthesizer. The CS derivatives bearing a cyclic cis-1,2-diol exhibited efficient release of the two oligonucleotides under commonly employed basic conditions of aqueous ammonia. Among the CS analogues, it was found that CS with a robust structure can potentially be applied as a spacer molecule in the tandem synthesis of multiple oligonucleotides in a single sequence.

Solid-phase supports for oligonucleotide synthesis

This unit attempts to provide a reasonably complete inventory of over 280 solid supports available to oligonucleotide chemists for preparation of natural and 3'-modified oligonucleotides. Emphasis is placed on non-nucleosidic solid supports. The relationship between the structural features of linkers and their behavior in oligonucleotide synthesis and deprotection is discussed wherever the relevant observations are available.

A universal and recyclable solid support for oligonucleotide synthesis

This unit provides a modified phosphoramidite method to synthesize oligodeoxyribonucleotides onto a universal and reusable hydroxyl solid support thanks to the use of deoxyribonucleoside tert-butyl and cyanoethyl phosphoramidites. The nucleoside tert-butyl phosphoramidite allows the introduction of an H-phosphonate diester linkage using the phosphoramidite method. After elongation, the H-phosphonate diester linker is cleaved by transesterification under mild basic conditions to yield an oligonucleotide with free 3'- and 5'-hydroxyls and the starting solid support. Thus, the solid support is easily recycled and used for a subsequent synthesis. In addition, a nucleoside tert-butyl phosphoramidite could be introduced inside the oligonucleotide chain during the elongation to yield a second H-phosphonate diester linkage. After elongation, the two H-phosphonate diester linkages are cleaved, producing two oligonucleotides with free 3'- and 5'-hydroxyls.

Fast deprotection of synthetic oligodeoxyribonucleotides using standard reagents under microwave irradiation

Fast methods for the removal of permanent amide exo-cyclic protective groups widely used in phosphoramidite-method DNA synthesis are desirable for many genomics and proteomics applications. In this communication, we present a method for the deprotection of a range of N-acyl deoxyribonucleosides (T, dA Bz, dC Bz, dC Ac, dG ibu, dG PAC) and synthetic oligodeoxyribonucleotides, ranging in length from 5-mer to 50-mer. Oligodeoxyribonucleotides were synthesized using standard amide protecting groups (dA Bz, dC Bz, dG ibu) and phosphoramidite chemistry on cis-diol solid phase support. This deprotection method utilizes 29% aqueous ammonia solution at 170 degrees C for 5 minutes under monomode microwave irradiation at a 20-nmole reaction scale. Reaction products were analyzed by TLC, RP-HPLC, CE, ESI-MS, real-time PCR, agarose gel electrophoresis, and by DNA uracil glycosylase (UDG) and phosphodiesterase I (PDE) enzymatic digestions.

Solid-phase supports for oligonucleotide synthesis

This unit begins with a discussion of the advantages and disadvantages of oligonucleotide synthesis using solid supports. The physical and chemical properties of solid-phase supports are discussed in terms of their suitability for oligonucleotide synthesis. In addition, the unit outlines the properties of linkers used for transient or permanent attachment of properly protected nucleosides to the derivatized support, as well as strategies for coupling nucleosides to linkers and conditions for the release of synthetic oligonucleotides from specific supports.

Nucleoside phosphoramidites containing cleavable linkers

Phosphoramidite reagents (linker phosphoramidites) containing a cleavable 3'-ester linkage between the nucleoside and the phosphoramidite group can be used to attach the first nucleoside to a solid-phase support. Inexpensive underivatized supports such as LCAA-CPG can then be used as universal supports for oligonucleotide synthesis. No modifications to synthesis coupling conditions and no 3'-dephosphorylation are required. Only oligonucleotides with terminal 3'-OH ends are produced. Phosphoramidites containing both a succinate and a sulfonyldiethanol linkage are particularly useful and create oligonucleotides with both a 3'-OH and 5'-phosphate. In addition, by using these reagents, one oligonucleotide sequence can be added onto the 5'-end of another (tandem synthesis) to produce a string of multiple oligonucleotides linked end-to-end. Deprotection releases the oligonucleotides from each other to yield a mixture of oligonucleotides. This approach is particularly useful for making pairs of PCR primers or both strands of a double-stranded sequence in a single operation.

Universal solid supports for the synthesis of oligonucleotides via a transesterification of H-phosphonate diester linkage

[Structure: see text]. Three universal solid supports exhibiting an hydroxyl function were prepared. The introduction of a first H-phosphonate diester linkage which was kept throughout the elongation allowed the release of 3'-hydroxyl oligonucleotides by a transesterification mechanism. The transesterification was performed in a few minutes with either amino alcohols or K2CO3/methanol. Starting from a hydroxyl solid support, tandem oligonucleotides were synthesized and the solid support was easily recyclable. This strategy was extended to the release of an oligonucleotide from the solid support by a nonbasic treatment opening the way to the synthesis of base-sensitive oligonucleotides thanks to the selective deprotection of a hydroxyl in beta of the H-phosphonate diester linkage.

Universal reusable polymer support for oligonucleotide synthesis

A new efficient reusable universal polymer support for oligonucleotide synthesis, based on a non-ammoniacal cleavable linker, is described. Twenty six cycles of oligonucleotide synthesis have been carried out without compromising the quality of the fully deprotected oligonucleotides.

Tandem oligonucleotide synthesis using linker phosphoramidites

Multiple oligonucleotides of the same or different sequence, linked end-to-end in tandem can be synthesized in a single automated synthesis. A linker phosphoramidite [R. T. Pon and S. Yu (2004) Nucleic Acids Res., 32, 623–631] is added to the 5′-terminal OH end of a support-bound oligonucleotide to introduce a cleavable linkage (succinic acid plus sulfonyldiethanol) and the 3′-terminal base of the new sequence. Conventional phosphoramidites are then used for the rest of the sequence. After synthesis, treatment with ammonium hydroxide releases the oligonucleotides from the support and cleaves the linkages between each sequence. Mixtures of one oligonucleotide with both 5′- and 3′-terminal OH ends and other oligonucleotides with 5′-phosphorylated and 3′-OH ends are produced, which are deprotected and worked up as a single product. Tandem synthesis can be used to make pairs of PCR primers, sets of cooperative oligonucleotides or multiple copies of the same sequence. When tandem synthesis is used to make two self-complementary sequences, double-stranded structures spontaneously form after deprotection. Tandem synthesis of oligonucleotide chains containing up to six consecutive 20mer (120 bases total), various trinucleotide codons and primer pairs for PCR, or self-complementary strands for in situ formation of double-stranded DNA fragments has been demonstrated.

Tandem oligonucleotide synthesis on solid-phase supports for the production of multiple oligonucleotides

More than one oligonucleotide can be synthesized at a time by linking multiple oligonucleotides end-to-end in a tandem manner on the surface of a solid-phase support. The 5'-terminal hydroxyl position of one oligonucleotide serves as the starting point for the next oligonucleotide synthesis. The two oligonucleotides are linked via a cleavable 3'-O-hydroquinone-O,O'-diacetic acid linker arm (Q-linker). The Q-linker is rapidly and efficiently coupled to the 5'-OH position of immobilized oligonucleotides using HATU, HBTU, or HCTU in the presence of 1 equiv of DMAP. This protocol avoids introduction of phosphate linkages on either the 3'- or 5'-end of oligonucleotides. A single NH(4)OH cleavage step can simultaneously release the products from the surface of the support and each other to produce free 5'- and 3'-hydroxyl termini. Selective cleavage of one oligonucleotide out of two sequences has also been accomplished via a combination of succinyl and Q-linker linker arms. Tandem synthesis of multiple oligonucleotides is useful for producing sets of primers for PCR, DNA sequencing, and other diagnostic applications as well as double-stranded oligonucleotides. Tandem synthesis of the same sequence multiple times increases the yield of material from any single synthesis column for maximum economy in large-scale synthesis. This method can also be combined with reusable solid-phase supports to further reduce the cost of oligonucleotide production.

Multiple oligonucleotide synthesis in tandem on solid-phase supports for small and large scale synthesis

Multiple oligonucleotides linked end-to-end in tandem can be synthesized by adding a nucleoside to the 5'-OH end of a prior sequence. Nucleosides with 3'-succinyl or Q-Linker arms are coupled with HBTU/DMAP. Alternatively, new phosphoramidite reagents with 3'-ester linkages can be used. Hydroxyl or amino supports can also be used as universal starting materials. Treatment with NH4OH cleaves the 3'-ester to yield only 3'-OH groups and no unwanted 3'-phosphorylated products occur.

Synthesis and properties of alpha- and beta-oligodeoxynucleotides containing alpha- and beta-1-(2-O-methyl-D-arabino-furanosyl)thymine

Synthesis of the alpha- and beta-anomer of 2'-OMe-araT (alpha- and beta-1-(2-O-methyl-D-arabinofuranosyl)thymine) and their incorporation into oligodeoxynucleotide (ODN) analogues is described. Condensation of the key arabinofuranose derivative with silylated thymine afforded the alpha-anomer and the beta-anomer which were converted into the respective phosphoramidite building blocks. Automated synthesis of beta-ODNs containing beta-2'-OMe-araT (by use of standard beta-amidites and phosphoramidite building block 9b) and alpha-ODNs containing alpha-2'-OMe-araT (by use of alpha-T-amidite and phosphoramidite building block 9a) allowed evaluation of their properties. With regard to 3'-exonucleolytic degradation, 3'-end incorporation of either beta- or alpha-2'-OMe-araT resulted in considerable stabilization compared to unmodified beta-ODNs. Thermal stabilities of duplexes formed between modified ODNs and both unmodified DNA and RNA were evaluated and compared to unmodified controls. In all experiments stable duplexes were formed, but whereas beta-ODNs containing beta-2'-OMe-araT showed moderately lowered thermal stabilities towards both DNA and RNA, alpha-ODNs containing alpha-2'-OMe-araT exhibited significantly increased melting points (compared to beta-ODN controls) when complexed with RNA. These results illustrate the potential of using arabino-configurated nucleosides as modified monomers in biologically active ODN-analogues, either as, e.g., 2'-O-alkylated or 2'-O-functionalized derivatives.

Oligonucleotide analogues containing 4'-C-(hydroxymethyl)uridine: synthesis, evaluation and mass spectrometric analysis

2',3'-Di-O-tert-butyldimethylsilyl-4'-C-(hydroxymethyl)uridine was synthesized and converted into the phosphoramidite building blocks 9 and 13. Novel oligodeoxynucleotide analogues containing 4'-C-hydroxymethyl linked phosphodiester internucleoside linkages and 3'-hydroxyl linked phosphodiester internucleotide linkages were synthesized on an automated DNA-synthesizer. The latter modification introduced an additional 4'-C-hydroxymethyl functionality. Oligodeoxynucleotides with one or two modifications in the middle or in the ends of 17-mers, 15-mers and 14-mers have been evaluated with respect to hybridization properties and enzymatic stability. Compared to unmodified oligomers, 3'-end-modified oligodeoxynucleotides were stabilized towards 3'-exonucleolytic degradation, but showed moderately to strongly lowered hybridization properties towards complementary DNA. However, more promising results were obtained in melting experiments with complementary RNA where only small decreases in melting temperature were detected. Matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS) was used to identify products from syntheses of the modified oligodeoxynucleotide analogues.