Antimicrobial peptides alter lipid bilayer properties before disrupting membrane barrier property.

Abstract

Antimicrobial peptides (AMPs) have been the subject of inquiry since the initial search for antibiotics in the ­first half of 20th century; the first antibiotic used in humans was the linear pentadecapeptide gramicidin. Much of this interest comes from the modest frequency of bacterial resistance against AMPs. Though AMPs differ in sequence and structure, the majority share three core physicochemical properties; they are short, cationic and amphipathic. Moreover, enantiomers of AMPs tend to have similar potencies. These common features have led to a focus on the bacterial membrane as a target for AMPs. High concentrations of AMPs cause gross bilayer defects, through pore formation or micellar breakdown. At lower concentrations, AMPs have effects on bacterial physiology that appear unrelated to membrane permeabilization, suggesting that they may act through bilayer-mediated regulation (BMR) of membrane protein function. If correct, this offers a mechanism of action that integrates the known membrane-modifying effects of AMPs with their ability to broadly alter bacterial physiology at sub-pore forming concentrations. We tested this hypothesis using melittin, gramicidin S, and indolicidin, three AMPs with distinct structures, that indeed alter bilayer properties at concentrations below those required for pore formation. Contrary to expectation, AMP induced BMR is attenuated in anionic bilayers despite increased AMP binding, suggesting an organizing effect of membrane-bound counterions. We further found that amphiphilic bilayer modifiers promote membrane permeabilization, suggesting that BMR may be responsible for the cooperativity of AMP-induced permeabilization. Two membrane-impermeant detergents, CHAPS and zwittergent, promote pore formation despite inhibiting AMP binding, suggesting a role for leaflet-specific lateral pressure differences. These results suggest a new mechanism by which AMPs exert their bactericidal effect, which may guide antibiotic design and provide a path for circumventing bacterial resistance.