posted on 2024-10-11, 14:38authored byGiulia
F. Trevellin, JuYoung Kwag, Michelle L. Shui, Hannah Klim, Valentina Alvarez, Louise E. O. Darling, Donald E. Elmore
Antimicrobial peptides (AMPs) hold promise as useful
tools to combat
bacterial infection. Hybrid peptides, made by linking two independent
AMPs together through peptide bonds, have the potential for enhancing
antimicrobial activity. Here we explore hybrids created by combining
two histone-derived antimicrobial peptides (HDAPs), BF2 and DesHDAP1,
that each translocate across bacterial membranes. Our work represents
the first systematic approach considering the activity and mechanism
of hybrids made from two translocating AMPs. BF2/DesHDAP1 hybrids
showed increased antimicrobial activity against both Gram-positive
and Gram-negative bacteria compared with the parent peptides and no
cytotoxicity against eukaryotic cells. Introducing amino acid linkers
between the parent peptides did not further enhance the antibacterial
activity. The increased antimicrobial activity comes from a mechanistic
shift, as hybrid peptides show decreased translocation across bacterial
cell membranes but increased membrane permeabilization compared to
BF2 and DesHDAP1. These observations lay the groundwork for the further
design of hybrid AMPs made from translocating peptides.