Mibel Aguilar scite author profile

Antimicrobial peptides (AMPs) are showing increasing promise as potential candidate antibacterial drugs in the face of the rapidly emerging bacterial resistance to conventional antibiotics in recent years. The target of these peptides is the microbial membrane and there are numerous models to explain their mechanism of action ranging from pore formation to general membrane disruption. The interaction between the AMP and the target membrane is critical to the specificity and activity of these peptides. However, a precise understanding of the relationship between antimicrobial peptide structure and their cytolytic function in a range of organisms is still lacking. This is a result of the complex nature of the interactions of AMPs with the cell membrane, the mechanism of which can vary considerably between different classes of antimicrobia peptides. A wide range of biophysical techniques have been used to study the influence of a number of peptide and membrane properties on the cytolytic activity of these peptides in model membrane systems. Central to characterisation of this interaction is a quantitative analysis of the binding of peptide to the membrane and the coherent dynamic changes in membrane structure. Recently, dual polarization interferometry has been used to perform an in depth analysis of antimicrobial peptide induced membrane perturbation and with new mass-structure co-fitting kinetic analysis have allowed a real-time label free analysis of binding affinity and kinetics. We review these studies which describe multi-step mechanisms which are adopted by various AMPs in nature and may advance our approach to the development of a new generation of effective antimicrobial therapeutics.

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Amino acid sequence controls the self-assembled superstructure morphology of N-acetylated tri-β³-peptides

Seoudi

Dowd

Borgo

et al. 2015

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Peptides based on unnatural β3-amino acids offer a versatile platform for the design of self-assembling nanostructures due to the folding stability of the 14-helix and the high symmetry of the side chains inherent in this geometry. We have previously described that N-terminal acetylation (Ac-) forms a supramolecular self-assembly motif that allows β3-peptides to assemble head-to-tail into a helical nanorod which then further bundles into hierarchical superstructures. Here we investigate the effect of the topography of the 14-helical nanorod on lateral self-assembly. Specifically, we report on the variations in the superstructure of three isomeric peptides comprising the same three β3-amino acid residues: β3-leucine (L), β3-isoleucine (I) β3-alanine (A) to give peptides Ac-β3[LIA], Ac-β3[IAL] and Ac-β3[ALI]. AFM imaging shows markedly different superstructures for the three peptides. Well defined synchrotron far-infrared spectra reveal uniform geometries with a high degree of similarity between the isomeric peptides in the amide modes of the 400–650 wavenumber range. Far-IR also confirms that the C-terminal carboxyl group is free in the assemblies, thus it is solvated in the dispersant. Hence, the differences in the superstructures formed by the fibers are defined primarily by van der Waals energy minimization between the varied cross sectional morphologies of the core nanorods.

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Molecular Simulation of Peptide Interactions with an RP-HPLC Sorbent

1997

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A simulation procedure based on molecular dynamics has been developed for modeling the interaction of peptides with n-alkylsilica reversed phase chromatographic sorbents. A four-step docking procedure was used which included the following stages: (1) interactive rigid-body docking of the peptide with an n-butylsilica sorbent using amino acid hydrophobicity coefficients to direct the orientation; (2) automated rigid-body docking by a Monte Carlo simulated annealing procedure in the space of six orientational parameters; (3) solvation of the peptide-sorbent complex with water, and (4) automated docking by molecular dynamics simulated annealing in the full Cartesian coordinate space. The procedure has been validated with the simulation of the binding of the peptide bombesin to an n-butylsilica C4 sorbent. The results were analyzed in terms of the change in conformation of both the n-butyl ligand chains and the peptide solute following peptide docking. These studies demonstrate that the partial helical character of bombesin was maintained throughout the hightemperature annealing. Overall, this investigation demonstrates the potential of molecular dynamics procedures to aid in the elucidation of peptide interactions with immobilized hydrophobic ligands. Moreover, this study provides a systematic approach to investigate the potential role of hydrophobic effects in peptide-surface interactions.

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Conformational analysis of neuropeptide Y-[18–36] analogs in hydrophobic environments

Lazoura

Maidonis

Bayer

et al. 1997

Biophysical Journal

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The interactive and conformational behavior of a series of neuropeptide Y-[18-36] (NPY-[18-36]) analogs in hydrophobic environments have been investigated using reversed-phase high-performance liquid chromatography (RP-HPLC) and circular dichroism (CD) spectroscopy. The peptides studied comprised a series of 16 analogs of NPY-[18-36], each containing a single D-amino acid substitution. The influence of these single L-->D substitutions on the alpha-helical conformation of the NPY-[18-36] analogs in different solvent environments was determined by CD spectroscopy. Retention parameters related to the hydrophobic contact area and the affinity of interaction were determined with an n-octadecyl (C18) adsorbent. Structural transitions for all peptides were manifested as significant changes in the hydrophobic binding domain and surface affinity between 4 degrees C and 37 degrees C. The results indicated that the central region of NPY-[18-36] (residues 23-33) is important for maintenance of the alpha-helical conformation. Moreover, L-->D amino acid residue substitutions within the N- and C-terminal regions, as well as Asn29 and Leu30, do not appear to affect the secondary structure of the peptide. These studies demonstrate that RP-HPLC provides a powerful adjunct for investigations into the induction of stabilized secondary structure in peptides upon their interaction with hydrophobic surfaces.

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High-performance liquid chromatography of amino acids, peptides and proteins

Hearn

Hodder

Aguilar

1985

Journal of Chromatography A

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Mibel Aguilar

Antimicrobial Peptide Structure and Mechanism of Action: A Focus on the Role of Membrane Structure

Amino acid sequence controls the self-assembled superstructure morphology of N-acetylated tri-β³-peptides

Molecular Simulation of Peptide Interactions with an RP-HPLC Sorbent

Conformational analysis of neuropeptide Y-[18–36] analogs in hydrophobic environments

High-performance liquid chromatography of amino acids, peptides and proteins

Contact Info

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Resources

About

Mibel Aguilar

Antimicrobial Peptide Structure and Mechanism of Action: A Focus on the Role of Membrane Structure

Amino acid sequence controls the self-assembled superstructure morphology of N-acetylated tri-β3-peptides

Molecular Simulation of Peptide Interactions with an RP-HPLC Sorbent

Conformational analysis of neuropeptide Y-[18–36] analogs in hydrophobic environments

High-performance liquid chromatography of amino acids, peptides and proteins

Contact Info

Product

Resources

About

Amino acid sequence controls the self-assembled superstructure morphology of N-acetylated tri-β³-peptides