Compagne, Nina, Jiménez-Castellanos, Juan-Carlos, Meurillon, Virginie, Pradel, Elizabeth, Vieira Da Cruz, Anais, Piveteau, Catherine, Biela, Alexandre, Eveque, Maxime, Leroux, Florence, Deprez, Benoit, Willand, Nicolas, Hartkoorn, Ruben C., and Flipo, Marion
Multidrug–resistant Escherichia coli is a continuously growing worldwide public health problem, in which the well-known AcrAB-TolC tripartite RND efflux pump is a critical driver. We have previously described pyridylpiperazines as a novel class of allosteric inhibitors of E. coli AcrB which bind to a unique site in the protein transmembrane domain, allowing for the potentiation of antibiotic activity. Here, we show a rational optimization of pyridylpiperazines by modifying three specific derivatization points of the pyridine core to improve the potency and the pharmacokinetic properties of this chemical series. In particular, this work found that the introduction of a primary amine to the pyridine through ester (29, BDM91270) or oxadiazole (44, BDM91514) based linkers allowed for analogues with improved antibiotic boosting potency through AcrB inhibition. In vitro studies, using genetically engineered mutants, showed that this improvement in potency is mediated through novel interactions with distal acidic residues of the AcrB binding pocket. Of the two leads, compound 44 was found to have favorable physico-chemical properties and suitable plasma and microsomal stability. Together, this work expands the current structure-activity relationship data on pyridylpiperazine efflux pump inhibitors, and provides a promising step towards future in vivo proof of concept of pyridylpiperazines as antibiotic potentiators. [Display omitted] • Structure-activity relationships around the pyridylpiperazine core. • Pyridylpiperazine inhibitors boost a panel of antibiotic substrates of AcrB. • Test on E. coli AcrB mutants validate interactions with AcrB acidic residues. • Plasma and microsomal stability of the most potent compounds. [ABSTRACT FROM AUTHOR]