Design of Type II Topoisomerase Inhibitors As Potential Antimicrobial Agents Targeting a Novel Binding Region

Overview

Journal RSC Med Chem

Publisher Royal Society of Chemistry

Specialty Chemistry

Date 2022 Aug 3

PMID 35919336

Authors

Kyle M Orritt

Lipeng Feng

Juliette F Newell

Jack N Sutton

Scott Grossman

Thomas Germe

Lauren R Abbott

Holly L Jackson

Benjamin K L Bury

Anthony Maxwell

Martin J McPhillie

Colin W G Fishwick

Affiliations

Soon will be listed here.

Abstract

By 2050, it is predicted that antimicrobial resistance will be responsible for 10 million global deaths annually, more deaths than cancer, costing the world economy $100 trillion. Clearly, strategies to address this problem are essential as bacterial evolution is rendering our current antibiotics ineffective. The discovery of an allosteric binding site on the established antibacterial target DNA gyrase offers a new medicinal chemistry strategy. As this site is distinct from the fluoroquinolone binding site, resistance is not yet documented. Using molecular design methods, we have designed and synthesised a novel series of biphenyl-based inhibitors inspired by a published thiophene-based allosteric inhibitor. This series was evaluated against DNA gyrase and topoisomerase IV with the most potent compounds exhibiting IC values towards the low micromolar range for DNA gyrase and only ∼2-fold less active against topoisomerase IV. The structure-activity relationships reported herein suggest insights to further exploit this allosteric site, offering a pathway to overcome developing fluoroquinolone resistance.

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