Antifungális proteinek – Antifungális hatásmechanizmus és biológiai szerep vizsgálata
új terápiás...(FK 134343) Támogató: NKFIH
(NKFIH (K146131))
(NKFIH (K146131))
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Tudomány
Fungal infections with high mortality rates represent an increasing health risk. The
Neosartorya (Aspergillus) fischeri antifungal protein 2 (NFAP2) is a small, cysteine-rich,
cationic protein exhibiting potent anti-Candida activity. As the underlying mechanism,
pore formation has been demonstrated; however, molecular level details on its membrane
disruption action are lacking. Herein, we addressed the lipid binding of NFAP2 using
a combined computational and experimental approach to simple lipid compositions with
various surface charge properties. Simulation results revealed binding preferences
for negatively charged model membranes, where selectivity is mediated by anionic lipid
components enriched at the protein binding site but also assisted by zwitterionic
lipid species. Several potential binding routes initiated by various anchoring contacts
were observed, which resulted in one main binding mode and a few variants, with NFAP2
residing on the membrane surface. Region 10NCPNNCKHKKG20 of the flexible N-terminal
part of the protein showed potency to insert into the lipid bilayer, where the disulfide
bond-stabilized short motif 11CPNNC15 could play a key role. In addition, several
areas, including the beginning of the N-terminal (residues 1-8), played roles in facilitating
initial membrane contacts. Besides, individual roles of residues such as Lys24, Lys32,
Lys34, and Trp42 were also revealed by the simulations. Combined data demonstrated
that the solution conformation was not perturbed markedly upon membrane interaction,
and the folded part of the protein also contributed to stabilizing the bound state.
Data also highlighted that the binding of NFAP2 to lipid vesicles is sensitively affected
by environmental factors such as ionic strength. Electrostatic interactions driven
by anionic lipids were found pivotal, explaining the reduced membrane activity observed
under high salt conditions. Experimental data supported the lipid-selective binding
mechanisms and pointed to salt-dependent effects, particularly to protein-assisted
vesicle aggregation at low ionic strength. Our findings can contribute to the development
of NFAP2-based anti-Candida agents and studies aiming at future medical use of peptide-based
natural antifungal compounds.