Poly(N-vinylpyrrolidone) Antimalaria Conjugates of Membrane-Disruptive Peptides.

The concepts of polymer-peptide conjugation and self-assembly were applied to antimicrobial peptides (AMPs) in the development of a targeted antimalaria drug delivery construct. This study describes the synthesis of α-acetal, ω-xanthate heterotelechelic poly(N-vinylpyrrolidone) (PVP) via reversible addition-fragmentation chain transfer (RAFT)-mediated polymerization, followed by postpolymerization deprotection to yield α-aldehyde, ω-thiol heterotelechelic PVP. A specific targeting peptide, GSRSKGT, for Plasmodium falciparum-infected erythrocytes was used to sparsely decorate the α-chain ends via reductive amination while cyclic decapeptides from the tyrocidine group were conjugated to the ω-chain end via thiol-ene Michael addition. The resultant constructs were self-assembled into micellar nanoaggregates whose sizes and morphologies were determined by dynamic light scattering (DLS) and transmission electron microscopy (TEM). The in vitro activity and selectivity of the conjugates were evaluated against intraerythrocytic P. falciparum parasites.

Antifungal membranolytic activity of the tyrocidines against filamentous plant fungi.

The tyrocidines and analogues are cyclic decapeptides produced by Brevibacillus parabrevis with a conserved sequence of cyclo(D-Phe1-Pro2-X3-x4-Asn5-Gln6-X7-Val8-X9-Leu10) with Trp3,4/Phe3,4 in the aromatic dipeptide unit, Lys9/Orn9 as their cationic residue and Tyr (tyrocidines), Trp (tryptocidines) or Phe (phenicidines) in position 7. Previous studies indicated they have a broad antifungal spectrum with the peptides containing a Tyr residue in position 7 being more active than those with a Phe or Trp residue in this position. Detailed analysis of antifungal inhibition parameters revealed that Phe3-D-Phe4 in the aromatic dipeptide unit lead to more consistent activity against the three filamentous fungi in this study. These peptides exhibited high membrane activity and fast leakage kinetics against model membranes emulating fungal membranes, with selectivity towards ergosterol containing membranes. More fluid membranes and doping of liposomes with the sphingolipid, glucosylceramide, led to a decreased permeabilising activity. Peptide-induced uptake of membrane impermeable dyes was observed in hyphae of both Fusarium solani and Botrytis cinerea, with uptake more pronounced at the hyphal growth tips that are known to contain ergosterol-sphigolipid rich lipid rafts. Tyrocidine interaction with these rafts may lead to the previously observed fungal hyperbranching. However, the leakage of model membranes and Bot. cinerea did not correlate directly with the antifungal inhibition parameters, indicating another target or mode of action. Proteinase K treatment of target fungi had a minimal influence or even improved the tyrocidine activity, ruling out a mannoprotein target in the fungal cell wall. ß-glucanase treatment of Bot. cinerea did not significantly affect the tyrocidine activity, but there was a significant loss in activity towards the ß-glucanase treated F. solani. This study showed the tyrocidine antifungal membrane activity is selective towards ergosterol and possibly lipid rafts, but also point to additional targets such as the cell wall ß-glucans that could modulate their activity.

Inhibition of agronomically relevant fungal phytopathogens by tyrocidines, cyclic antimicrobial peptides isolated from Bacillus aneurinolyticus.

The tyrocidines, a complex of analogous cyclic decapeptides produced by Bacillus aneurinolyticus, exhibited noteworthy activity against a range of phytopathogenic fungi, including Fusarium verticillioides, Fusarium solani and Botrytis cinerea. The activity of the tyrocidine peptide complex (Trc mixture) and purified tyrocidines exhibited minimum inhibition concentrations below 13 µg ml(-1) (~10 µM) and was significantly more potent than that of the commercial imidazole fungicide, bifonazole. Although the tyrocidines' activity was negatively influenced by the presence of Ca(2+), it remained unaffected by the presence of Mg(2+), Na(+) and K(+). Microscopic analysis revealed significant impact on the morphology of F. solani and Bot. cinerea including retarded germination and hyperbranching of hyphae. Studies with membrane-impermeable dyes, SYTOX green and propidium iodide suggested that the main mode of action of tyrocidines involves the disruption of fungal membrane integrity. Because of the tyrocidines' broad spectrum and potent antifungal activity, possible multiple targets reducing the risk of overt resistance and general salt tolerance, they are promising candidates that warrant further investigation as bio-fungicides.