Antimicrobial and Antibiofilm Activity of Disubstituted Bis-benzimidazolium Salts.

The increased prevalence of antibiotic-resistant bacteria is a critical issue for human health. Developing new antibiotic agents is vital for fighting persistent infections and lowering mortality rates. In this study, we designed lutidine-disubstituted bis-benzimidazolium salts (lutidine-bis-benzimidazolium core with octyl, adamantyl, and cholesteryl lipophilic side chains), and tested their antimicrobial activity, their capacity to inhibit planktonic bacterial and fungal growth, and their ability to inhibit the formation of or disrupt mature methicillin-resistant Staphylococcus aureus (MRSA) biofilms. The antibiofilm activity of these salts was analyzed in terms of their lipophilicity, capacity to induce transmembrane ion transport, perturbation of the cellular membrane, and mechanism of action in the phospholipid bilayer. The synthesized compounds were not active against MRSA biofilms, as the formation of transmembrane channels had no effect on the integrity of the extracellular polymeric substance matrix and only octyl and adamantyl derivatives possessed the capacity to inhibit biofilm formation. The synthesized derivatives could be used as lead candidates for the development of anti-MRSA agents.

Adaptation of a bacterial membrane permeabilization assay for quantitative evaluation of benzalkonium chloride as a membrane-disrupting agent.

We describe the use of the ortho-nitrophenyl-ß-galactoside (ONPG) assay developed by Lehrer et al. to which a new mathematical data treatment was applied. In this simplified assay, only one enzymatic assay is needed to provide direct evidence of the kinetics of Escherichia coli membrane permeabilization induced by different concentrations of benzalkonium chloride (BAC). Analysis of the data obtained from the revised ONPG assay with our adapted mathematical formula indicates that BAC induces permeabilization of the bacterial outer and inner membranes in a two-step process. The two effective concentration (EC50) values obtained in this study, combined with the results from an outer membrane permeabilization assay, suggest that the two steps observed in the permeabilization process are related to the two different bacterial membranes. We show that membrane permeabilization occurs very fast upon the addition of bacterial cells to the BAC solutions and demonstrate that sub-lethal concentrations of BAC disturb the integrity of the Gram-negative bacterial membranes. Overall, our work broadens our knowledge on the mode of action of BAC on bacterial cells and emphasizes that BAC, and quaternary ammonium compounds in general, should not be used at sub-lethal concentrations in order to lower the risk of bacterial tolerance and resistance to antibiotics.

Host-Guest Strategy to Reversibly Control a Chloride Carrier Process with Cyclodextrins.

Herein, we report a reversible modular chloride transport process based on host-guest competitive interactions between an imidazolium-based chloride carrier and beta-cyclodextrin. We report evidence for the formation of the supramolecular complex between 1,3-bis(2-(adamantan-1-yl)ethyl)imidazolium bis(trifluorometyl-sulfonyl)imide with two ß-cyclodextrins. Through fluorescence assays in liposomes and black lipid membrane experiments, we demonstrate that the formation of the supramolecular complex results in the inhibition of the chloride transport. We show that the chloride transport process can be entirely restored in the presence of competitive adamantyl-functionalized guests. This is the first example of an entirely reversible modular chloride transport process in phospholipid bilayers involving a mobile carrier transporter and cyclodextrin supramolecular complex.