Quang Huynh scite author profile

Certain antibiotic peptides are thought to permeabilize membranes of pathogens by effects that are also observed for simple detergents, such as membrane thinning and disordering, asymmetric bilayer expansion, toroidal pore formation, and micellization. Here we test the hypothesis that such peptides act additively with detergents when applied in parallel. Additivity is defined analogously to a fractional inhibitory concentration index of unity, and the extent and mechanism of leakage is measured by the fluorescence lifetime-based vesicle leakage assay using calcein-loaded vesicles. Good additivity was found for the concerted action of magainin 2, the fungicidal lipopeptide class of surfactins from Bacillus subtilis QST713, and the detergent octyl glucoside, respectively, with the detergent C12EO8. Synergistic or superadditive action was observed for fengycins from B. subtilis, as well as the detergent CHAPS, when combined with C12EO8. The results illustrate two mechanisms of synergistic action: First, maximal leakage requires an optimum degree of heterogeneity in the system that may be achieved by mixing a graded with an all-or-none permeabilizer. (The optimal perturbation should be focused to certain defect structures, yet not to the extent that some vesicles are not affected at all.) Second, a cosurfactant may enhance the bioavailability of a poorly soluble peptide. The results are important for understanding the concerted action of membrane-permeabilizing compounds in biology as well as for optimizing formulations of such antimicrobials for medical applications or crop protection.

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The evolutionary background and functional consequences of the rs2071307 polymorphism in human tropoelastin

Reichheld¹,

Muiznieks

Huynh³

et al. 2020

Biopolymers

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Elastin is a major polymeric protein of the extracellular matrix, providing critical properties of extensibility and elastic recoil. The rs2071307 genomic polymorphism, resulting in the substitution of a serine for a glycine residue in a VPG motif in tropoelastin, has an unusually high minor allele frequency in humans. A consequence of such allelic heterozygosity would be the presence of a heterogeneous elastin polymer in up to 50% of the population, a situation which appears to be unique to Homo sapiens. VPG motifs are extremely common in hydrophobic domains of tropoelastins and are the sites of transient β‐turns that are essential for maintaining the conformational flexibility required for its function as an entropic elastomer. Earlier data demonstrated that single amino acid substitutions in tropoelastin can have functional consequences for polymeric elastin, particularly when present in mixed polymers. Here, using NMR and molecular dynamics approaches, we show the rs2071307 polymorphism reduces local propensity for β‐turn formation, with a consequent increase in polypeptide hydration and an expansion of the conformational ensemble manifested as an increased hydrodynamic radius, radius of gyration and asphericity. Furthermore, this substitution affects functional properties of polymeric elastin, particularly in heterogeneous polymers mimicking allelic heterozygosity. We discuss whether such effects, together with the unusually high minor allele frequency of the polymorphism, could imply some some evolutionary advantage for the heterozygous state.

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Lipid Selectivity of Fungicidal Lipopeptides

Fiedler

Huynh

Patel

et al. 2015

Biophysical Journal

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Gram-negative bacteria such as E.coli are protected by a surprisingly complex cell envelope. The cell envelope is composed of two membranes that form a protective barrier around the cells, and control the influx and efflux of solutes via various routes. Lysing the cell by disrupting the membranes, or permeating across them to gain access to the cell interior are key properties for antimicrobial agents. Polymyxins are a class of antibiotics that have been shown to be highly active against Gram-negative bacteria. It is thought they enter bacterial cells through a self-uptake mechanism, although the molecular details of the mechanism are still unclear. We present, to our knowledge, the first molecular dynamics simulation study of an antimicrobial peptide, with both membranes of E.coli. Our model of the outer membrane contains lipopolysaccharide molecules in the inner leaflet and a mixture of ohosphilipids in the inner leaflet. In contrast, the inner membrane is comprised only of phospholipids. Our simulations reveal the effects of Polymyxin B1 (PMB1) binding on the physical properties of each membrane. Thus they are able to identify potentially different mechanisms for membrane disruption by PMB1. Peptide aggregation and insertion of one peptide tail was observed in the outer membrane. In contrast, PMB1 peptides insert readily as monomers, accompanied by water penetration into the inner membrane. Our simulations demonstrate the importance of capturing relevant details of biological complexity, in molecular models of biological membrane systems.

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1+1=3? Concerted Action of Membrane Permeabilizers

Patel

Huynh

Bärlehner

et al. 2014

Biophysical Journal

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The ability of amphipathic polypeptides with substantial net positive charges to translocate across lipid membranes is a fundamental problem in physical biochemistry. These peptides should not passively cross the bilayer nonpolar region, but they do. Here we present a method to measure peptide translocation, and test it on three representative membrane-active peptides. In samples of giant unilamellar vesicles (GUVs) prepared by electroformation, some GUVs enclose inner vesicles. When these GUVs are added to a peptide solution containing a membrane-impermeant fluorescent dye (carboxyfluorescein), the peptide permeabilizes the outer membrane, and dye enters the outer GUV, which then exhibits green fluorescence. The inner vesicles remain dark if the peptide

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Synergistic Action of Fungicidal Lipopeptides as a Mechanism of Target Membrane Selectivity

Dietel

Huynh

Fiedler

et al. 2018

Biophysical Journal

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Quang Huynh

Additive and Synergistic Membrane Permeabilization by Antimicrobial (Lipo)Peptides and Detergents

The evolutionary background and functional consequences of the rs2071307 polymorphism in human tropoelastin

Lipid Selectivity of Fungicidal Lipopeptides

1+1=3? Concerted Action of Membrane Permeabilizers

Synergistic Action of Fungicidal Lipopeptides as a Mechanism of Target Membrane Selectivity

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