Antimicrobial peptide cWFW kills by combining lipid phase separation with autolysis

The synthetic cyclic hexapeptide cWFW (cyclo(RRRWFW)) has a rapid bactericidal activity against both Gram-positive and Gram-negative bacteria. Its detailed mode of action has, however, remained elusive. In contrast to most antimicrobial peptides, cWFW neither permeabilizes the membrane nor transloca...

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Bibliographic Details
Published in:Scientific reports 2017-03, Vol.7 (1), p.44332-44332, Article 44332
Main Authors: Scheinpflug, Kathi, Wenzel, Michaela, Krylova, Oxana, Bandow, Julia E., Dathe, Margitta, Strahl, Henrik
Format: Article
Language:English
Subjects:
14/35
14/63
631/154/555
631/326/22/1290
631/326/41
631/45/287/1192
82/29
82/58
Antibiotics
Antimicrobial agents
Antimicrobial peptides
Autolysis
Bacteria
Bactericidal activity
Biosynthesis
Cell walls
Cytoplasm
Energy
Enzymes
Fluidity
Fluorescence microscopy
Gram-negative bacteria
Humanities and Social Sciences
Lipids
Membrane fluidity
Membrane proteins
Membranes
Metabolism
Mode of action
multidisciplinary
Peptides
Proteins
Proteomes
Rigidity
Science
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Summary:The synthetic cyclic hexapeptide cWFW (cyclo(RRRWFW)) has a rapid bactericidal activity against both Gram-positive and Gram-negative bacteria. Its detailed mode of action has, however, remained elusive. In contrast to most antimicrobial peptides, cWFW neither permeabilizes the membrane nor translocates to the cytoplasm. Using a combination of proteome analysis, fluorescence microscopy, and membrane analysis we show that cWFW instead triggers a rapid reduction of membrane fluidity both in live Bacillus subtilis cells and in model membranes. This immediate activity is accompanied by formation of distinct membrane domains which differ in local membrane fluidity, and which severely disrupts membrane protein organisation by segregating peripheral and integral proteins into domains of different rigidity. These major membrane disturbances cause specific inhibition of cell wall synthesis, and trigger autolysis. This novel antibacterial mode of action holds a low risk to induce bacterial resistance, and provides valuable information for the design of new synthetic antimicrobial peptides.
ISSN:2045-2322
2045-2322
DOI:10.1038/srep44332