One-Pot Synthesis of Nucleoside 5′-Triphosphates from Nucleoside 5′-<i>H</i>-Phosphonates

Sun, Qi; Edathil, Jocelyn P.; Wu, Runzhi; Smidansky, Eric D.; Cameron, Craig Ε.; Peterson, Blake R.

doi:10.1021/ol8003029

Cited by 42 publications

(36 citation statements)

References 27 publications

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“…Taking into account the high susceptibility of H-phosphonothioate monoester to oxidation by iodine, the method developed by Sun et al [12] represented an alternative to achieve the oxidative phosphorylation. The conditions used for the synthesis of NTPs via a pyridinium phosphoramidate intermediate were adapted to our synthesis route.…”

Section: Resultsmentioning

confidence: 99%

Solid‐Phase Synthesis of Oligonucleotide 5′‐(α‐P‐Thio)triphosphates and 5′‐(α‐P‐Thio)(β,γ‐methylene)triphosphates

et al. 2014

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A robust solid‐phase synthesis was developed to obtain original oligonucleotides (ONs) functionalized at their 5′ end with modified triphosphate (TP) moieties, in which a nonbridging oxygen atom of the α phosphorus atom was replaced by a sulfur atom and the labile P–O–P linkage was changed into a methylene bridge between the β and γ phosphorus atoms. The efficient method is based on solid‐supported ON assembly followed by 5′‐H‐phosphonylation, oxidation to the thiophosphate subsequently activated as a phosphoanhydride with diphenyl phosphoryl chloride, then nucleophilic substitution with the alkylammonium salt of pyrophosphate or its β,γ‐methylene analogue. After deprotection and release from the solid support under basic conditions, 5′‐(α‐P‐thio)TP and 5′‐(α‐P‐thio)(β,γ‐methylene)TP oligonucleotides were obtained in satisfactory yields, and they were isolated with high purity. These hydrolysis‐resistant 5′‐TP ONs will be useful in biological research to elucidate the mechanism of enzymes involved in mRNA processing and maturation.

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Section: Resultsmentioning

confidence: 99%

Solid‐Phase Synthesis of Oligonucleotide 5′‐(α‐P‐Thio)triphosphates and 5′‐(α‐P‐Thio)(β,γ‐methylene)triphosphates

et al. 2014

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“…After considering extensive reviews on nucleoside triphosphate synthesis (Burgess & Cook, ; Roy, Depaix, Perigaud, & Peyrottes, ), we decided to forego the use of the popular “one pot, three step” chemistry (Ludwig, ; Yoshikawa, Kato, & Takenishi, ) and instead utilized a more recent methodology that employs a phosphonate precursor before elaborating to the full triphosphate (Sun et al., ), which we found to be easier to purify and would also allow for simple adaption to synthesize mono‐ and diphosphate derivatives if desired.…”

Section: Commentarymentioning

confidence: 99%

Synthesis of 4‐Cyanoindole Nucleosides, 4‐Cyanoindole‐2ʹ‐Deoxyribonucleoside‐5ʹ‐Triphosphate (4CIN‐TP), and Enzymatic Incorporation of 4CIN‐TP into DNA

Passow

Antczak

Sturla

et al. 2020

CP Nucleic Acid Chemistry

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4‐Cyanoindole‐2ʹ‐deoxyribonucleoside (4CIN) is a fluorescent isomorphic nucleoside analogue with superior spectroscopic properties in terms of Stokes shift and quantum yield in comparison to the widely utilized isomorphic nucleoside analogue, 2‐aminopurine‐2ʹ‐deoxyribonucleoside (2APN). Notably, when inserted into single‐ or double‐stranded DNA, 4CIN experiences substantially less in‐strand fluorescence quenching compared to 2APN. Given the utility of these properties for a spectrum of research applications involving oligonucleotides and oligonucleotide‐protein interactions (e.g., enzymatic processes, DNA hybridization, DNA damage), we envision that additional reagents based on 4‐cyanoindole nucleosides may be widely utilized. This protocol expands on the previously published synthesis of 4CIN to include synthetic routes to both 4‐cyanoindole‐ribonucleoside (4CINr) and 4‐cyanoindole‐2ʹ‐deoxyribonucleoside‐5ʹ‐triphosphate (4CIN‐TP), as well as a method for the enzymatic incorporation of 4CIN‐TP into DNA by a polymerase. These methods are anticipated to further enable the utilization of 4CIN in diverse applications involving DNA and RNA oligonucleotides. © 2020 by John Wiley & Sons, Inc. Basic Protocol 1: Synthesis of 4‐cyanoindole‐2ʹ‐deoxyribonucleoside (4CIN) and 4CIN phosphoramidite 4 Basic Protocol 2: Synthesis of 4‐cyanoindole‐ribonucleoside (4CINr) Basic Protocol 3: Synthesis of 4‐cyanoindole‐2ʹ‐deoxyribonucleoside‐5ʹ‐triphosphate (4CIN‐TP) Basic Protocol 4: Steady state incorporation kinetics of 2AP‐TP and 4CIN‐TP by a DNA polymerase

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“…The intermediate salicylphosphite 6 (Scheme ) is very sensitive to traces of water in the reaction mixture, and the main product of the triphosphate synthesis according to Scheme might be nucleoside H ‐phosphonate. This disadvantage was overcome by Peterson and co‐workers, who specially prepared nucleoside 5′‐ H ‐phosphonates by the treatment of partially protected nucleosides with 4 or PCl 3 and subsequent hydrolysis . After deprotection, nucleoside 5′‐ H ‐phosphonates 14 were activated by forming silyl esters and oxidized by I 2 in the presence of pyridine (Scheme ).…”

Section: The Use Of P‐h Phosphonatesmentioning

confidence: 99%

How To Form a Phosphate Anhydride Linkage in Nucleotide Derivatives

Sherstyuk

Abramova

2015

ChemBioChem

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The fundamental roles of nucleoside triphosphates and nucleotide cofactors such as NAD(+) in biochemistry are well known. In recent decades, continuing research has revealed the key role of 5'-capped RNA and 5',5'-dinucleoside polyphosphates in the regulation of vitally important physiological processes. Last but not least, the commercial potential of nucleoside triphosphate synthesis can hardly be overestimated. Nevertheless, despite decades of investigation and the obvious topicality of the research on the chemical synthesis of the nucleotide compounds containing phosphate anhydride linkages, none of the existing procedures can be considered an up-to-date "gold standard". However, there are a number of fruitful synthetic approaches to forming phosphate anhydride linkages in satisfactory yield. These are summarized in this concise review, organized by the type of active phosphorous intermediate and reagents used.

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One-Pot Synthesis of Nucleoside 5′-Triphosphates from Nucleoside 5′-H-Phosphonates

Cited by 42 publications

References 27 publications

Solid‐Phase Synthesis of Oligonucleotide 5′‐(α‐P‐Thio)triphosphates and 5′‐(α‐P‐Thio)(β,γ‐methylene)triphosphates

Solid‐Phase Synthesis of Oligonucleotide 5′‐(α‐P‐Thio)triphosphates and 5′‐(α‐P‐Thio)(β,γ‐methylene)triphosphates

Synthesis of 4‐Cyanoindole Nucleosides, 4‐Cyanoindole‐2ʹ‐Deoxyribonucleoside‐5ʹ‐Triphosphate (4CIN‐TP), and Enzymatic Incorporation of 4CIN‐TP into DNA

How To Form a Phosphate Anhydride Linkage in Nucleotide Derivatives

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