Microwave-assisted preparation of nucleoside-phosphoramidites

Meher, Geeta; Efthymiou, Tim C.; Stoop, Matthias; Krishnamurthy, Ramanarayanan

doi:10.1039/c4cc03092c

Cited by 12 publications

(13 citation statements)

References 13 publications

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“…Monomer synthesis : Ribulofuranoside ( r t and r a ) phosphoramidite monomers were synthesized as outlined in the literature, and the synthesis of both r c and r g phosphoramidite intermediates are outlined in the Supporting Information (Sections 2.1–2.2). Microwave‐assisted phosphitylation of all four ( r t , r a , r c and r g ) phosphoramidites was carried out as described in literature …”

Section: Methodsmentioning

confidence: 99%

“…Microwave-assisted phosphitylation of all four ( r t, r a, r c and r g)p hosphoramidites was carried out as described in literature. [39] Oligonucleotide synthesis:A ll modified oligonucleotides were synthesized in-house through automated solid-support DMT-phosphoramidite chemistry as described in the literature [40] using slightly modified reagents, coupling protocols and deprotection/purification strategies (see Supporting Section 4.0). Biophysical analysis:Oligonucleotide samples (single-and doublestranded) were analyzed by UV-monitored thermal denaturation experiments, monitored at l 254, 260 and 272 nm.…”

Section: Methodsmentioning

confidence: 99%

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Chimeric XNA: An Unconventional Design for Orthogonal Informational Systems

Efthymiou

Gavette

Stoop

et al. 2018

Chemistry A European J

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The paradigm of homogenous-sugar-backbone of RNA and DNA has reliably guided the construction of many functional and useful xeno nucleic acid (XNA) systems to date. Deviations from this monotonous and canonical design, in many cases, results in oligonucleotide systems that lack base pairing with themselves, or with RNA or DNA. Here we show that nucleotides of two such compromised XNA systems can be combined with RNA and DNA in specific patterns to produce chimeric-backbone oligonucleotides, which in certain cases demonstrate base pairing properties comparable to-or stronger than-canonical systems, while also altering the conventional Watson-Crick pairing behavior. The unorthodox pairing properties generated from these chimeric sugar-backbone oligonucleotides suggest a counterintuitive approach of creating modules consisting of non-base pairing XNAs with RNA/DNA in a set pattern. This strategy has the potential to increase the diversity of unconventional nucleic acids leading to orthogonal backbone-sequence-controlled informational systems.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Chimeric XNA: An Unconventional Design for Orthogonal Informational Systems

Efthymiou

Gavette

Stoop

et al. 2018

Chemistry A European J

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“…2.19.3). The demonstration of reduced reaction times and adequate-to-high yields (Meher et al, 2014) illustrates the potential of microwave-assisted phosphitylation as an extremely facile and efficient method with which industry can produce large quantities of phosphoramidites with considerable time and potential cost savings. In addition to demystifying the common perception about the sensitivity of phosphoramidite chemistry to elevated temperatures, this protocol demonstrates that one can phosphitylate both DNA and RNA nucleoside monomers with the help of microwave irradiation using the most common phosphitylating reagent.…”

Section: Microwave-assisted Phosphitylation Of Canonical Dna and Rna mentioning

confidence: 99%

“…For synthesis of phosphoramidite building blocks in the sterically hindered ribulofuranosyl series of nucleoside analogs (Stoop et al, 2013), the development of an efficient and high-yielding phosphitylation procedure was crucial. The phosphitylation strategy had to be unique in nature, because extended reaction times under standard phosphitylating conditions, coupled with different protecting groups produced inadequate results (Meher et al, 2014). Since alternative phosphitylating reagents such as 2-cyanoethyl-N, N-diethylamino chlorophosphoramidite or 2cyanoethyl-N,N,N ,N -tetraethylamino phosphane were difficult to acquire and inherently more unstable, it was postulated that better results could be obtained through another strategy.…”

Section: Commentary Background Informationmentioning

confidence: 99%

“…While attempting to chemically phosphitylate a series of novel nucleoside analogs based on a ribulofuranosyl sugar scaffold (1a-d; Meher and Krishnamurthy, 2011), it became clear that typical phosphitylating techniques would not efficiently produce the desired phosphoramidite products in decent yields or in a timely manner. To help expedite the phosphitylation process, microwave irradiation was employed (Meher et al, 2014). This approach was attempted to address the reported sensitivity of phosphitylating reagents and ribulosebased phosphoramidite products to elevated temperatures (Caruthers et al, 1987).…”

Section: Introductionmentioning

confidence: 99%

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Microwave‐Assisted Phosphitylation of DNA and RNA Nucleosides and Their Analogs

Efthymiou

Krishnamurthy

2015

CP Nucleic Acid Chemistry

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Microwave-assisted chemical phosphitylation of novel nucleoside analogs containing a ribulose sugar unit was successful with yields ranging from 50% to 79% using 2-cyanoethyl-N,N-diisopropyl chlorophosphoramidite as the phosphitylating reagent. The resultant phosphoramidite products remained intact, with no signs of degradation over extended reaction times (up to 60 min) at an elevated temperature (65°C). When the same microwave-mediated phosphitylating protocols were applied to canonical DNA and RNA nucleoside monomers as substrates, using either 2-cyanoethyl-N,N,-diisopropyl chlorophosphoramidite or 2-cyanoethyl-N,N,N',N'-tetraisopropyl phosphane with an activator, 40% to 90% yields of DNA and RNA phosphoramidites were obtained within 10 to 15 min. These results demonstrate that microwave-assisted phosphitylation is an efficient alternative to standard phosphitylating conditions that can be expanded and refined to include a variety of substrates.

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Microwave‐Assisted One‐Step Synthesis of 2′,3′‐Cyclic Phosphates of Nucleosides

2023

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Cyclic canonical nucleotides are an important class of compounds playing broad roles in regulating biological processes and are investigated in the context of prebiotic chemistry as activated nucleotides for oligonucleotide formation. Despite their growing importance, synthetic access of 2 ,3 -cyclic nucleotides is constrained, resulting in their cost-prohibitive commercial prices. Here, we describe a microwave-assisted one-pot synthesis starting from commercially available nucleosides employing an easily available cyclophosphorylating reagent, bis(dimethyldiamino)phosphorodiamidate (BDMDAP). The corresponding 2 ,3 -cyclic nucleotides are isolated in good yields (70-91%) by a simple ion-exchange column with no further workup. The nucleosides require no protecting group as the cyclophosphorylation reaction is selective for the 2 ,3 -dihydroxyl groups. The experimental protocol is robust and can be run in parallel to provide access to gram quantities of these 2 ,3 -cyclic nucleotides within a day.

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Microwave-assisted preparation of nucleoside-phosphoramidites

Abstract: Microwave-assisted phosphitylation of sterically hindered nucleosides is demonstrated to be an efficient method for the preparation of corresponding phosphoramidites (otherwise onerous under standard conditions) and is shown to be general in its applicability.

Cited by 12 publications

References 13 publications

Chimeric XNA: An Unconventional Design for Orthogonal Informational Systems

Chimeric XNA: An Unconventional Design for Orthogonal Informational Systems

Microwave‐Assisted Phosphitylation of DNA and RNA Nucleosides and Their Analogs

Microwave‐Assisted One‐Step Synthesis of 2′,3′‐Cyclic Phosphates of Nucleosides

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