Abstract
Antimicrobial peptides are important components of the host innate defense mechanism against invading pathogens, especially for drug-resistant bacteria. In addition to bactericidal activity, the 25 residue peptide TP4 isolated from Nile tilapia also stimulates cell proliferation and regulates the innate immune system in mice. In this report, TP4 hyperpolarized and depolarized the membrane potential of Pseudomonas aeruginosa at sub-lethal and lethal concentrations. It also inhibited and eradicated biofilm formation. The in vitro binding of TP4 to bacterial outer membrane target protein, OprI, was markedly enhanced by a membrane-like surfactant sarkosyl and lipopolysaccharide, which converted TP4 into an α-helix. The solution structure of TP4 in dodecylphosphocholine was solved by NMR analyses. It contained a typical α-helix at residues Phe10-Arg22 and a distorted helical segment at Ile6-Phe10, as well as a hydrophobic core at the N-terminus and a cationic patch at the C-terminus. Residues Ile16, Leu19 and Ile20 in the hydrophobic face of the main helix were critical for the integrity of amphipathic structure, other hydrophobic residues played important roles in hemolytic and bactericidal activities. A model for the assembly of helical TP4 embedded in sarkosyl vesicle is proposed. This study may provide valuable insight for engineering AMPs to have potent bactericidal activity but low hemolytic activity.
Highlights
Conventional antibiotics can inhibit the synthesis of bacterial nucleic acids, proteins, or cell wall components
The biofilm formation of methicillin-resistant Staphylococcus aureus (MRSA) was markedly inhibited by TP4 at the sub-inhibitory concentration, 8 μg/ml, which did not inhibit the growth of planktonic bacteria (Fig 1E)
Determination of the TP4 structure and identification of residues responsible for these activities are helpful for the understanding of multiple functional antimicrobial peptides/proteins (AMPs) and potential application in clinical therapy for microbial infection
Summary
Conventional antibiotics can inhibit the synthesis of bacterial nucleic acids, proteins, or cell wall components. The widespread use of antibiotics in both medicine and agriculture have caused the emergence of drug-resistant bacteria [1,2]. Occurring antimicrobial peptides/proteins (AMPs) can disrupt the bacterial membrane integrity and may fill this need It has been isolated from multiple sources including bacteria, fungi, insects, invertebrates and vertebrates with remarkably diverse structures and bioactivity profiles [2,3,4]. These bioactive peptides do not merely act as direct antimicrobial agents and
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