Potassium Phosphate-Mediated Synthesis of C4-Phosphorylated Quinolines via Cascade Cycloisomerization of Ynones

Yi-Feng Qiu; Jin-Hao Li; Qiang Wang; Ming Li; Zheng-Jun Quan; Xi-Cun Wang; Yong-Min Liang

doi:10.1002/chem.202403585

Potassium Phosphate-Mediated Synthesis of C4-Phosphorylated Quinolines via Cascade Cycloisomerization of Ynones

Chemistry. 2024 Nov 5:e202403585. doi: 10.1002/chem.202403585. Online ahead of print.

Authors

Yi-Feng Qiu¹, Jin-Hao Li², Qiang Wang³, Ming Li⁴, Zheng-Jun Quan⁴, Xi-Cun Wang⁴, Yong-Min Liang⁵

Affiliations

¹ Northwest Normal University, Chemical and Chemistry Engineering, 730070, Lanzhou, CHINA.
² Northwest Normal University, Chemistry and Chemical Engineering, Lanzhou, CHINA.
³ Northwest Normal University, Chemistry and Chemical Engineering, 967#, East Anning Road, 730070, Lanzhou, CHINA.
⁴ Northwest Normal University, Chemistry and Chemical Engineering, CHINA.
⁵ Lanzhou University, Chemistry and Chemical Engineering, CHINA.

PMID: 39498765
DOI: 10.1002/chem.202403585

Abstract

A cascade phosphorylation cycloisomerization of readily accessible ynones and diphenylphosphine oxides facilitated by potassium phosphate is described, allowing for the straightforward synthesis of C4-phosphorylated quinoline scaffolds. The formation of a C-P bond and a C-N bond is achieved in a single procedure without the need for pre-assembled quinoline cores prior to phosphorylation. This transformation operates without the requirement for metals or oxidants and exhibits excellent compatibility with various functional groups. Furthermore, antimicrobial activity evaluation demonstrated that the synthesized C4 phosphorylated quinoline derivatives exhibited potent inhibitory activity against Staphylococcus aureus.

Keywords: C4-phosphorylated quinolines; antimicrobial activity; cascade cycloisomerization; potassium phosphate-mediated synthesis; ynones.