Ergosterol depletion by fish AMP analogs likely enhances fungal membrane permeability.

Abstract

The molecular interactions between a fungal membrane model and SJGAP, a 32-amino-acid antimicrobial peptide (AMP) derived from skipjack tuna GAPDH, as well as four analogs, were investigated using molecular dynamics simulations and Fourier transform infrared (FTIR) spectroscopy. In a previous study, Analog 7, modified by replacing three alanine residues with leucine residues, exhibited unique antifungal activity without any antibacterial effect. This contrasts with other analogs, which showed both antifungal and antibacterial effects. In this study, Analog 7 displayed the strongest interactions with the membrane's hydrophobic core, inserting more deeply and causing significantly greater membrane deformation and thinning compared with the other analogs. Its presence caused significant membrane deformation, evident from the displacement of both the phosphate groups and terminal methyls of the lipids. Notably, Analog 7 was the only analog to induce a marked depletion of ergosterol around the peptide insertion site. FTIR spectroscopy experiments further confirmed the distinctive impact of Analog 7 on a fungal membrane model. The combined results from molecular dynamics simulations and spectroscopy emphasize the critical role of leucine substitutions in Analog 7, particularly at residues 18 and 19 within the central α helix, in promoting membrane thinning and inducing ergosterol depletion, suggesting increased membrane permeabilization, which could explain its previously reported antifungal specificity. This study provides the first insights into the molecular interactions between a GAPDH-derived AMP and a fungal membrane model, offering valuable information about its antifungal mechanism of action.