PEGylation enhances the antibacterial and therapeutic potential of amphibian host defence peptides.

Aurein 2.1, aurein 2.6 and aurein 3.

Linearized esculentin-2EM shows pH dependent antibacterial activity with an alkaline optimum.

Here the hypothesis that linearized esculentin 2EM (E2EM-lin) from Glandirana emeljanovi possesses pH dependent activity is investigated. The peptide showed weak activity against Gram-negative bacteria (MLCs ≥ 75.0 μM) but potent efficacy towards Gram-positive bacteria (MLCs ≤ 6.

Biophysical studies on the antimicrobial activity of linearized esculentin 2EM.

Linearized esculentin 2 EM (E2EM-lin) from the frog, Glandirana emeljanovi was highly active against Gram-positive bacteria (minimum lethal concentration ≤ 5.0 μM) and strongly α-helical in the presence of lipid mimics of their membranes (>55.0%).

The role of C-terminal amidation in the membrane interactions of the anionic antimicrobial peptide, maximin H5.

Maximin H5 is an anionic antimicrobial peptide from amphibians, which carries a C-terminal amide moiety, and was found to be moderately haemolytic (20%). The α-helicity of the peptide was 42% in the presence of lipid mimics of erythrocyte membranes and was found able to penetrate (10.8 mN m(-1)) and lyse these model membranes (64 %).

The interaction of aurein 2.5 with fungal membranes.

Aurein 2.5 (GLFDIVKKVVGAFGSL-NH2) is an antimicrobial peptide, which was seen to have activity against Stachybotris chartarum, Penicillium roseopurpureum and Aspergillus flavus with minimum fungicidal concentrations in the range 250-500 μM. S.

A novel form of bacterial resistance to the action of eukaryotic host defense peptides, the use of a lipid receptor.

Host defense peptides show great potential for development as new antimicrobial agents with novel mechanisms of action. However, a small number of resistance mechanisms to their action are known, and here, we report a novel bacterial resistance mechanism mediated by a lipid receptor. Maximin H5 from Bombina maxima bound anionic and zwitterionic membranes with low affinity (Kd > 225 μM) while showing a strong ability to lyse (>55%) and penetrate (π > 6.

Antimicrobial activity of aurein 2.5 against yeasts.

Fungal infections with multiple resistance to conventional antifungals are increasingly becoming a medical problem, and there is an urgent need for new antifungal compounds with novel mechanisms of action. Here, we show that aurein 2.5, a naturally occurring peptide antibiotic, displays activity against the fungal strains: Rhodotorula rubra and Schizosaccharomyces pombe (MICs < 130 μM).

Role of molecular architecture on the relative efficacy of aurein 2.5 and modelin 5.

In order to gain an insight into the mechanism of antimicrobial peptide action, aurein 2.5 and modelin-5 were studied. When tested against Staphylococcus aureus, aurein 2.

Effect of amidation on the antimicrobial peptide aurein 2.5 from Australian southern bell frogs.

Aurein 2.5 is a naturally C-terminally amidated amphibian antimicrobial peptide. C-terminal amidation can increase efficacy and hence a comparison was made between aurein 2.

A study on the interactions of Aurein 2.5 with bacterial membranes.

Aurein 2.5 (GLFDIVKKVVGAFGSL-NH(2)) is an uncharacterised antimicrobial peptide. At an air/water interface, it exhibited strong surface activity (maximal surface pressure 25mNm(-1)) and molecular areas consistent with the adoption of alpha-helical structure orientated either perpendicular (1.

The impact of membrane lipid composition on antimicrobial function of an alpha-helical peptide.

VP1, a putative alpha-helical antimicrobial peptide (alpha-AMP) inhibited growth of Bacillus subtilis and Escherichia coli at 500microM. The peptide induced stable surface pressure changes in monolayers formed from B. subtilis native lipid extract (circa 4.

Antimicrobial properties of a lipid interactive alpha-helical peptide VP1 against Staphylococcus aureus bacteria.

Theoretical analysis indicates that peptide VP1 forms a membrane interactive amphiphilic alpha-helix with antibacterial properties. Fourier transform infra-red based analyses showed VP1 to be alpha-helical (45%) in the presence of vesicle mimics of membranes from Staphylococcus aureus and to induce increases in the fluidity of these vesicles, as indicated by a rise in wavenumber of circa 0.5 to 1.

Investigations into the ability of an oblique alpha-helical template to provide the basis for design of an antimicrobial anionic amphiphilic peptide.

AP1 (GEQGALAQFGEWL) was shown by theoretical analysis to be an anionic oblique-orientated alpha-helix former. The peptide exhibited a monolayer surface area of 1.42 nm(2), implying possession of alpha-helical structure at an air/water interface, and Fourier transform infrared spectroscopy (FTIR) showed the peptide to be alpha-helical (100%) in the presence of vesicle mimics of Escherichia coli membranes.

Interactions of an anionic antimicrobial peptide with Staphylococcus aureus membranes.

The antimicrobial activity of the anionic peptide, AP1 (GEQGALAQFGEWL), was investigated. AP1 was found to kill Staphylococcus aureus with an MLC of 3mM and to induce maximal surface pressure changes of 3.8 mN m(-1) over 1200s in monolayers formed from lipid extract of S.