Abstract
Lipids exhibit an extraordinary polymorphism in self-assembled mesophases, with lamellar phases as the most relevant biological representative. To mimic lipid lamellar phases with amphiphilic designer peptides, seven systematically varied short peptides were engineered. Indeed, four peptide candidates (V4D, V4WD, V4WD2, I4WD2) readily self-assembled into lamellae in aqueous solution. Small-angle X-ray scattering (SAXS) patterns revealed ordered lamellar structures with a repeat distance of ∼ 4–5 nm. Transmission electron microscopy (TEM) images confirmed the presence of stacked sheets. Two derivatives (V3D and V4D2) remained as loose aggregates dispersed in solution; one peptide (L4WD2) formed twisted tapes with internal lamellae and an antiparallel β-type monomer alignment. To understand the interaction of peptides with lipids, they were mixed with phosphatidylcholines. Low peptide concentrations (1.1 mM) induced the formation of a heterogeneous mixture of vesicular structures. Large multilamellar vesicles (MLV, d-spacing ∼ 6.3 nm) coexisted with oligo- or unilamellar vesicles (∼ 50 nm in diameter) and bicelle-like structures (∼ 45 nm length, ∼ 18 nm width). High peptide concentrations (11 mM) led to unilamellar vesicles (ULV, diameter ∼ 260–280 nm) with a homogeneous mixing of lipids and peptides. SAXS revealed the temperature-dependent fine structure of these ULVs. At 25 °C the bilayer is in a fully interdigitated state (headgroup-to-headgroup distance dHH ∼ 2.9 nm), whereas at 50 °C this interdigitation opens up (dHH ∼ 3.6 nm). Our results highlight the versatility of self-assembled peptide superstructures. Subtle changes in the amino acid composition are key design elements in creating peptide- or lipidpeptide nanostructures with richness in morphology similar to that of naturally occurring lipids.
Highlights
The remarkable ability of phospholipids to selfassemble into various lamellar structures is essential for life, as they create the fundamental structural component of biological membranes [1,2,3,4,5]
To study whether the designed amphiphilic designer peptides are capable of forming lamellar structures, their self-assembling behavior was investigated at extremely high peptide concentrations
We suggest that three hydrophobic valines are not able to balance the electrostatic repulsion of one aspartic acid residue (V3D), and likewise, four valines are not able to balance the electrostatic repulsion of two aspartic acid residues (V4D2)
Summary
The remarkable ability of phospholipids to selfassemble into various lamellar structures is essential for life, as they create the fundamental structural component of biological membranes [1,2,3,4,5]. A critical aggregation concentration (CAC), amphiphiles selfassemble into supramolecular structures similar to lipid mesophases. Do peptides structurally resemble lipid molecules, but they exhibit similar surfactant-like properties. Several earlier studies focused on their application as surfactants in membrane protein stabilization [18,19,20,21,22,23]. Their use as antimicrobial agents has been considered [24, 25]. All applications involve peptides either mimicking lipid molecules or coming in close contact with biological lipid membranes
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