Polyaspartate-derived synthetic antimicrobial polymer enhances the activity of rifampicin against multidrug-resistant Pseudomonas aeruginosa infections.

Infections caused by multidrug-resistant Pseudomonas aeruginosa (P. aeruginosa) pose major challenges for treatment due to the acquired, adaptive, and intrinsic resistance developed by the bacteria. Accumulation of mutations, the ability to form biofilms, and the presence of lipopolysaccharides in the outer bacterial membranes are the key mechanisms of drug resistance. Here, we show that a polyaspartate-derived synthetic antimicrobial polymer (SAMP) with a hexyl chain (TAC6) is an effective adjuvant for a hydrophobic antibiotic, rifampicin. Our in vitro studies demonstrated that the combination of TAC6 and rifampicin is effective against clinically isolated multidrug-resistant strains of P. aeruginosa. Membrane permeabilization studies showed that TAC6 allows the permeabilization of bacterial membranes, and the accumulation of rifampicin inside the cells, thereby enhancing its activity. The combination of TAC6 and rifampicin can also degrade the P. aeruginosa biofilms, and therefore can mitigate the adaptive resistance developed by bacteria. We further demonstrated that the combination of TAC6 and rifampicin can clear P. aeruginosa-mediated wound infections effectively. Therefore, our study showed polyaspartate-derived SAMP to be an effective antibiotic adjuvant against P. aeruginosa infections.

N-methyl Benzimidazole Tethered Cholic Acid Amphiphiles Can Eradicate S. aureus-Mediated Biofilms and Wound Infections.

Infections associated with Gram-positive bacteria like S. aureus pose a major threat as these bacteria can develop resistance and thereby limit the applications of antibiotics. Therefore, there is a need for new antibacterials to mitigate these infections. Bacterial membranes present an attractive therapeutic target as these membranes are anionic in nature and have a low chance of developing modifications in their physicochemical features. Antimicrobial peptides (AMPs) can disrupt the microbial membranes via electrostatic interactions, but the poor stability of AMPs halts their clinical translation. Here, we present the synthesis of eight N-methyl benzimidazole substituted cholic acid amphiphiles as antibacterial agents. We screened these novel heterocyclic cholic acid amphiphiles against different pathogens. Among the series, CABI-6 outperformed the other amphiphiles in terms of bactericidal activity against S. aureus. The membrane disruptive property of CABI-6 using a fluorescence-based assay has also been investigated, and it was inferred that CABI-6 can enhance the production of reactive oxygen species. We further demonstrated that CABI-6 can clear the pre-formed biofilms and can mitigate wound infection in murine models.