Synthesis of (5S)-Tricyclic Penems as Novel and Potent Inhibitors of Bacterial Signal Peptidases

 

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Abstract

(5S)-Tricyclic penems were synthesized for the first time via intramolecular cyclization of penem epoxy amides catalyzed by a weak Lewis acid [Mg(ClO₄)₂]. Due to the high degree of ring strain in these molecules, mild reaction conditions were developed to successfully construct penem intermediates and the tricyclic penem final products. These tricyclic penems and other newly synthesized (5S)-penem esters and amides exhibited good-to-high potency when tested as inhibitors of bacterial signal peptidases.

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The characterization of (5S)-Penems was based on MS and NMR analyses. In the ¹H NMR spectrum, both 5S- and 5R-isomers show similar peak patterns, but different chemical shifts. The most diagnostic peaks are CH-5, CH-6 and CH₃-8. In the 5S-isomer, a large coupling constant J = >4 Hz (vs J = <2 Hz for 5R-isomer) for CH-5 indicated a cis relationship with CH-6.

A thiozone by-product was isolated and characterized. Similar observation was descried by authors in Ref. [5]

Although the initially formed penem sodium salt was readily isolated and found relatively stable under ambiguous conditions, the acid was obtained in <5% yield after flash chromatography separation.

All compounds showed satisfactory analytical data.

The E. coli SPase was kindly provided by Dr. R. E. Dalbey (Ohio State University).