Open Access
Experimental and Computational Characterization of Oxidized and Reduced Protegrin Pores in Lipid Bilayers
Author(s) -
Mykola V. Rodnin,
Victor VasquezMontes,
Binod Nepal,
Alexey S. Ladokhin,
Themis Lazaridis
Publication year - 2020
Publication title -
the journal of membrane biology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.591
H-Index - 98
eISSN - 1432-1424
pISSN - 0022-2631
DOI - 10.1007/s00232-020-00124-3
Subject(s) - human physiology , lipid bilayer , characterization (materials science) , biophysics , chemistry , nanotechnology , materials science , chemical engineering , membrane , biochemistry , biology , engineering , endocrinology
Protegrin-1 (PG-1), an 18-residue β-hairpin stabilized by two disulfide bonds, is a member of a family of powerful antimicrobial peptides which are believed to act through membrane permeabilization. Here we used a combination of experimental and computational approaches to characterize possible structural arrangements of PG-1 in lipid bilayers mimicking bacterial membranes. We have measured the dose-response function of the PG-1-induced leakage of markers of various sizes from vesicles and found it to be consistent with the formation of pores of two different sizes. The first one allows the release of small dyes and occurs at peptide:lipid ratios < 0.006. Above this ratio, larger pores are observed through which the smallest of dextrans FD4 can be released. In parallel with pore formation, we observe a general large-scale destabilization of vesicles which is probably related to complete rupture of some vesicles. The population of vesicles that are completely ruptured depends linearly on PG-1:lipid ratio. Neither pore size, nor vesicle rupture are influenced by the formation of disulfide bonds. Previous computational work on oxidized protegrin is complemented here by all-atom MD simulations of PG-1 with reduced disulfide bonds both in solution (monomer) and in a bilayer (dimer and octamer). The simulations provide molecular insights into the influence of disulfide bonds on peptide conformation, aggregation, and oligomeric structure.