Decoding the Functional Roles of Cationic Side Chains of the Major Antimicrobial Region of Human Cathelicidin LL-37

Abstract

ABSTRACTHuman cathelicidin LL-37 is a critical cationic antimicrobial peptide for host defense against infection, immune modulation, and wound healing. This article elucidates the functional roles of the cationic side chains of the major antimicrobial region of LL-37, corresponding to residues 17 to 32 (designated GF-17). Antimicrobial assays, killing kinetics studies, and vesicle leakage experiments all indicate that a conversion of lysines to arginines affected the ability of the peptide to kill the Gram-positiveStaphylococcus aureusstrain USA300. Alanine scanning experiments show thatS. aureusis less sensitive thanEscherichia colito a single cationic residue mutation of GF-17. Among the five cationic residues, R23 appears to be somewhat important in killingS. aureus. However, R23 and K25 of GF-17 are of prime importance in killing the Gram-negative organismE. coli. In particular, R23 is essential for (i) rapid recognition, (ii) permeation of theE. coliouter membrane, (iii) clustering of anionic lipids in a membrane system mimicking theE. coliinner membrane, and (iv) membrane disruption. Bacterial aggregation (i.e., rapid recognition via charge neutralization) is the first step of the peptide action. Structurally, R23 is located in the interface (i.e., the first action layer), a situation ideal for the interactions listed above. In contrast, residues K18, R19, and R29 are on the hydrophilic surface of the amphipathic helix and play only a secondary role. Mapping of the functional spectrum of cationic residues of GF-17 provides a solid basis for engineering bacterium-specific antimicrobials using this highly potent template.