Jack Blazyk scite author profile

All known naturally occurring linear cationic peptides adopt an amphipathic ␣-helical conformation upon binding to lipids as an initial step in the induction of cell leakage. We designed an 18-residue peptide, (KIGAKI) 3 -NH 2 , that has no amphipathic character as an ␣-helix but can form a highly amphipathic ␤-sheet. When bound to lipids, (KIGAKI) 3 -NH 2 did indeed form a ␤-sheet structure as evidenced by Fourier transform infrared and circular dichroism spectroscopy. The antimicrobial activity of this peptide was compared with that of (KI-AGKIA) 3 -NH 2 , and it was better than that of GMASKA-GAIAGKIAKVALKAL-NH 2 (PGLa) and (KLAGLAK) 3 -NH 2 , all of which form amphipathic ␣-helices when bound to membranes. (KIGAKI) 3 -NH 2 was much less effective at inducing leakage in lipid vesicles composed of mixtures of the acidic lipid, phosphatidylglycerol, and the neutral lipid, phosphatidylcholine, as compared with the other peptides. However, when phosphatidylethanolamine replaced phosphatidylcholine, the lytic potency of PGLa and the ␣-helical model peptides was reduced, whereas that of (KIGAKI) 3 -NH 2 was improved. Fluorescence experiments using analogs containing a single tryptophan residue showed significant differences between (KIGAKI) 3 -NH 2 and the ␣-helical peptides in their interactions with lipid vesicles. Because the data suggest enhanced selectivity between bacterial and mammalian lipids, linear amphipathic ␤-sheet peptides such as (KIGAKI) 3 -NH 2 warrant further investigation as potential antimicrobial agents.

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Secondary Structure and Location of a Magainin Analogue in Synthetic Phospholipid Bilayers

Hirsh

et al. 1996

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Magainins are cationic, membrane-active peptides which show broad-spectrum antimicrobial activity. We have investigated the secondary structure and location of an analogue of magainin 2 in synthetic phospholipid bilayers using a combination of Fourier transform infrared (FTIR) spectroscopy and solid-state nuclear magnetic resonance (NMR) spectroscopy. Ala19-magainin 2 amide exhibits both alpha-helix and beta-sheet secondary structures in lipid bilayers containing either dipalmitoylphosphatidylglycerol (DPPG) or a 1:1 molar mixture of DPPG and dipalmitoylphosphatidylcholine (DPPC). The combination of FTIR and solid-state NMR results suggests that there are two populations of peptide. The secondary structure of one population is alpha-helix while that of the other population is beta-sheet. We demonstrate that the solid-state NMR technique, rotational-echo double resonance (REDOR), can be used to measure both intra- and intermolecular dipole-dipole interactions in membrane-bound peptides. Our REDOR experiments indicate that alpha-helical Ala19-magainin 2 amide is bound near the phospholipid head groups.

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Structure and Function in Antimicrobial Piscidins: Histidine Position, Directionality of Membrane Insertion, and pH-Dependent Permeabilization

et al. 2019

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Piscidins are histidine-enriched antimicrobial peptides that interact with lipid bilayers as amphipathic α-helices. Their activity at acidic and basic pH in vivo makes them promising templates for biomedical applications. This study focuses on p1 and p3, both 22-residue-long piscidins with 68% sequence identity. They share three histidines (H3, H4 and H11) but p1, which is significantly more permeabilizing, has a fourth histidine (H17). This study investigates how variations in amphipathic character associated with histidines affect the permeabilization properties of p1 and p3. First, we show that the permeabilization ability of p3, but not p1, is strongly inhibited at pH 6.0 when the conserved histidines are partially charged and H17 is

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Complementary Effects of Host Defense Peptides Piscidin 1 and Piscidin 3 on DNA and Lipid Membranes: Biophysical Insights into Contrasting Biological Activities

et al. 2015

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Piscidins were the first antimicrobial peptides discovered in the mast cells of vertebrates. While two family members, piscidin 1 (p1) and piscidin 3 (p3), have highly similar sequences and α-helical structures when bound to model membranes, p1 generally exhibits stronger antimicrobial and hemolytic activity than p3 for reasons that remain elusive. In this study, we combine activity assays and biophysical methods to investigate the mechanisms underlying the cellular function and differing biological potencies of these peptides, and report findings spanning three major facets. First, added to Gram-positive (Bacillus megaterium) and Gram-negative (Escherichia coli) bacteria at sublethal concentrations and imaged by confocal microscopy, both p1 and p3 translocate across cell membranes and colocalize with nucleoids. In E. coli, translocation is accompanied by nonlethal permeabilization that features more pronounced leakage for p1. Second, p1 is also more disruptive than p3 to bacterial model membranes, as quantified by a dye-leakage assay and (2)H solid-state NMR-monitored lipid acyl chain order parameters. Oriented CD studies in the same bilayers show that, beyond a critical peptide concentration, both peptides transition from a surface-bound state to a tilted orientation. Third, gel retardation experiments and CD-monitored titrations on isolated DNA demonstrate that both peptides bind DNA but p3 has stronger condensing effects. Notably, solid-state NMR reveals that the peptides are α-helical when bound to DNA. Overall, these studies identify two polyreactive piscidin isoforms that bind phosphate-containing targets in a poised amphipathic α-helical conformation, disrupt bacterial membranes, and access the intracellular constituents of target cells. Remarkably, the two isoforms have complementary effects; p1 is more membrane active, while p3 has stronger DNA-condensing effects. Subtle differences in their physicochemical properties are highlighted to help explain their contrasting activities.

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Jack Blazyk

A Novel Linear Amphipathic β-Sheet Cationic Antimicrobial Peptide with Enhanced Selectivity for Bacterial Lipids

Secondary Structure and Location of a Magainin Analogue in Synthetic Phospholipid Bilayers

Structure and Function in Antimicrobial Piscidins: Histidine Position, Directionality of Membrane Insertion, and pH-Dependent Permeabilization

Complementary Effects of Host Defense Peptides Piscidin 1 and Piscidin 3 on DNA and Lipid Membranes: Biophysical Insights into Contrasting Biological Activities

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