Electrochemical Synthesis of Imino‐C‐Nucleosides by “Reactivity Switching” Methodology for in situ Generated Glycoside Donors

Redox‐induced regioselective C(sp3)‐H C‐glycosidation for unactivated prolinols was achieved by controlling the anomeric reactivity of electrochemically generated iminium cations. A mechanistic study revealed that the intermediate was pooled as covalent azaribose or iminium cation species in situ, a...

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Veröffentlicht in:	European journal of organic chemistry 2021-05, Vol.2021 (17), p.2479-2484
Hauptverfasser:	Okamoto, Kazuhiro, Tsutsui, Mizuki, Morizumi, Haruka, Kitano, Yoshikazu, Chiba, Kazuhiro
Format:	Artikel
Sprache:	eng
Schlagworte:	C-Glycoside Cations Chemical synthesis Electrosynthesis Iminium cation Iminosugar Methodology Nucleosides Reactivity Switching
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container_title	European journal of organic chemistry
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creator	Okamoto, Kazuhiro Tsutsui, Mizuki Morizumi, Haruka Kitano, Yoshikazu Chiba, Kazuhiro
description	Redox‐induced regioselective C(sp3)‐H C‐glycosidation for unactivated prolinols was achieved by controlling the anomeric reactivity of electrochemically generated iminium cations. A mechanistic study revealed that the intermediate was pooled as covalent azaribose or iminium cation species in situ, and the electrophilicity of intermediates can be adjusted by changing coexisting acids. We found that the armed/disarmed analogy concept of traditional glycochemistry can be adapted to our C‐glycosidation reaction. Finally, we invented a logical synthetic methodology, named “reactivity switching” concept, and synthesized a series of imino‐C‐nucleosides (C‐azanucleosides) based on this methodology. Electrochemical C‐glycoside formation was achieved by a “reactivity switching” methodology, which is an expansion of the traditional armed/disarmed concept. Logical reactivity design was enabled by considering electron density, pKa, and resulting anomeric leaving ability of acetate moiety of in situ generated glycoside donors. Finally, we synthesized various imino‐C‐nucleosides (C‐azanucleosides).
doi_str_mv	10.1002/ejoc.202100106
format	Article
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A mechanistic study revealed that the intermediate was pooled as covalent azaribose or iminium cation species in situ, and the electrophilicity of intermediates can be adjusted by changing coexisting acids. We found that the armed/disarmed analogy concept of traditional glycochemistry can be adapted to our C‐glycosidation reaction. Finally, we invented a logical synthetic methodology, named “reactivity switching” concept, and synthesized a series of imino‐C‐nucleosides (C‐azanucleosides) based on this methodology. Electrochemical C‐glycoside formation was achieved by a “reactivity switching” methodology, which is an expansion of the traditional armed/disarmed concept. Logical reactivity design was enabled by considering electron density, pKa, and resulting anomeric leaving ability of acetate moiety of in situ generated glycoside donors. 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subjects	C-Glycoside Cations Chemical synthesis Electrosynthesis Iminium cation Iminosugar Methodology Nucleosides Reactivity Switching
title	Electrochemical Synthesis of Imino‐C‐Nucleosides by “Reactivity Switching” Methodology for in situ Generated Glycoside Donors
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