Carbene formation as a mechanism for efficient intracellular uptake of cationic antimicrobial carbon acid polymers.

Cationic polymers have emerged as promising next-generation antimicrobial agents, albeit with inherent limitations such as low potency and limited biocompatibility. Classical cationic polymers kill bacteria via physical membrane disruption. We propose a non-classical mechanism of crossing the bacterial plasma membrane barrier, a step required for subsequent inhibition of intracellular targets, by cationic polymers which are carbon acids. Oligoimidazolium (OIM) carbon acids, instead of lysing bacteria, transiently deprotonate in water to form hydrophobic N-heterocyclic carbenes (NHCs) and exhibit efficient plasma membrane translocation. Only OIMs that are carbon acids have potent antibacterial activities against even colistin- and multidrug-resistant bacteria. OIM amide derivatives exhibit excellent antibacterial efficacy in murine sepsis and thigh infection models, while a polymeric version acts as a prophylactic agent against bovine mastitis, which is a global agricultural problem. This study unveils a promising path for the development of an alternative class of potent antimicrobial agents.