The sponge phase of a mixed surfactant system.

We study the sponge phase of the mixed non-ionic/ionic surfactant system C14DMAO-TTAB-hexanol-brine. Our aim is to determine if this phase exists in this mixed system and if it preserves or changes its structure when the relative amount of the charged surfactant is increased in the mixture. SAXS, FFEM, and conductivity results show that for the same bilayer volume fraction the sponge phase preserves its global structure.

Effect of a neutral water-soluble polymer on the lamellar phase of a zwitterionic surfactant system.

We have studied the effect of adding a water-soluble polymers (PEG) to the lamellar phases of the ternary system tetradecyldimethylaminoxide (C14DMAO)-hexanol-water. The results of Freeze-Fracture Electron Microscopy (FFEM) and Small Angle X-ray Scattering (SAXS) experiments show that the addition of the polymer induces the spontaneous formation of highly monodisperse multilayered vesicles above a threshold polymer concentration.

Shear-induced permeation and fusion of lipid vesicles.

This paper introduces a novel approach to controlling membrane permeability in free unilamellar vesicles using shearing in the presence of a detergent with a large head-group to tune pore formation. Such shear-induced permeation could offer a simple means of postencapsulating bioactive molecules to prepare vesicle vectors for drug delivery. Using UV absorption, fluorescence emission, dynamic light scattering, and electron microscopy, we investigated the membrane permeability and the morphology of unilamellar lipid vesicles (diameter in the range 50-400 nm) subjected to a shear stress in the presence of a small amount of nonionic surfactant (Brij 76).

Fusogenic supramolecular vesicle systems induced by metal ion binding to amphiphilic ligands.

The incorporation of lipophilic ligands into the bilayer membrane of vesicles offers the possibility to induce, upon binding of suitable metal ions, a variety of processes, in particular vesicle aggregation and fusion and generation of vesicle arrays, under the control of specific metal-ligand recognition events. Synthetic bipyridine lipoligands Bn bearing a bipyridine unit as head group were prepared and incorporated into large unilamellar vesicles. The addition of Ni2+ or Co2+ metal ions led to the formation of complexes MBn and MBn2 followed by spontaneous fusion to generate giant multilamellar vesicles.

Shape control through molecular segregation in giant surfactant aggregates.

Mixtures of cationic and anionic surfactants crystallized at various ratios in the absence of added salt form micrometer-sized colloids. Here, we propose and test a general mechanism explaining how this ratio controls the shape of the resulting colloidal structure, which can vary from nanodiscs to punctured planes; during cocrystallization, excess (nonstoichiometric) surfactant accumulates on edges or pores rather than being incorporated into crystalline bilayers. Molecular segregation then produces a sequence of shapes controlled by the initial mole ratio only.

Selective complexation and transport of europium ions at the interface of vesicles.

The aim of the present work was to design functionalized lipidic membranes that can selectively interact with lanthanide ions at the interface and to exploit the interaction between membranes induced by this molecular-recognition process with a view to building up self-assembled vesicles or controlling the permeability of the membrane to lanthanide ions. Amphiphilic molecules bearing a beta-diketone unit as head group were synthesized and incorporated into phospholipidic vesicles. Binding of Eu(III) ions to the amphiphilic ligand can lead to formation of a complex involving ligands of the same vesicle membrane (intravesicular complex) or of two different vesicles (intervesicular complex).

Biomimetic organization: Octapeptide self-assembly into nanotubes of viral capsid-like dimension.

The controlled self-assembly of complex molecules into well defined hierarchical structures is a promising route for fabricating nanostructures. These nanoscale structures can be realized by naturally occurring proteins such as tobacco mosaic virus, capsid proteins, tubulin, actin, etc. Here, we report a simple alternative method based on self-assembling nanotubes formed by a synthetic therapeutic octapeptide, Lanreotide in water.

N-ethylmaleimide-sensitive factor is required to organize functional exocytotic microdomains in paramecium.

In exocytosis, secretory granules contact plasma membrane at sites where microdomains can be observed, which are sometimes marked by intramembranous particle arrays. Such arrays are particularly obvious when membrane fusion is frozen at a subterminal stage, e.g.

Slow Reorganization of Small Phosphatidylcholine Vesicles upon Adsorption of Amphiphilic Polymers.

Static or dynamic light scattering measurements were performed in parallel, on dilute mixtures of DPPC/DPPA vesicles (typical radius 60 nm) and hydrophobically modified polymers. This technique gave evidence of the slow kinetics involved in both the reorganization of an adsorbed polymer layer and the membrane breakage. Hours, or sometimes days, were required in order to follow the variation of both the hydrodynamic radius and the scattering intensity at intermediate stages.

Selective adhesion, lipid exchange and membrane-fusion processes between vesicles of various sizes bearing complementary molecular recognition groups.

Equimolar mixtures of large unilamellar vesicles (LUVs) obtained from mixtures of egg lecithin and lipids containing complementary hydrogen bonding head groups (barbituric acid (BAR) and 2,4,6-triaminopyrimidine (TAP)) were shown to aggregate and fuse. These events have been studied in detail using electron microscopy and dynamic light scattering, and by fluorimetry using membrane or water-soluble fluorescence probes. It was shown that aggregation was followed by two competitive processes: a) lipid mixing leading to redispersion of the vesicles; b) fusion events generating much larger vesicles.

Self-assembly of regular hollow icosahedra in salt-free catanionic solutions.

Self-assembled structures having a regular hollow icosahedral form (such as those observed for proteins of virus capsids) can occur as a result of biomineralization processes, but are extremely rare in mineral crystallites. Compact icosahedra made from a boron oxide have been reported, but equivalent structures made of synthetic organic components such as surfactants have not hitherto been observed. It is, however, well known that lipids, as well as mixtures of anionic and cationic single chain surfactants, can readily form bilayers that can adopt a variety of distinct geometric forms: they can fold into soft vesicles or random bilayers (the so-called sponge phase) or form ordered stacks of flat or undulating membranes.

VAMP (synaptobrevin) is present in the plasma membrane of nerve terminals.

Synaptic vesicle docking and exocytosis require the specific interaction of synaptic vesicle proteins (such as VAMP/synaptobrevin) with presynaptic plasma membrane proteins (such as syntaxin and SNAP 25). These proteins form a stable, SDS-resistant, multimolecular complex, the SNARE complex. The subcellular distribution of VAMP and syntaxin within Torpedo electric organ nerve endings was studied by immunogoldlabeling of SDS-digested freeze-fracture replicas (Fujimoto, 1995).

Macromolecular Colloids of Diblock Poly(amino acids) That Bind Insulin.

The diblock polymer poly(l-leucine-block-l-glutamate), bLE, was synthesized by acid hydrolysis of the ester poly(l-leucine-block-l-methyl glutamate). During the hydrolysis reaction the leucine block precipitates from the reaction mixture, forming nanosized particulate structures. These particles can be purified and further suspended in water or in 0.

Self-assembly of chlorophenols in water.

In saturated solutions of some di- and trichlorophenols, structures with complex morphologies, consisting of thin, transparent sheets often coiling into helices and ultimately twisting into filaments, were observed under the optical microscope. Freeze-fracture electron microscopy, x-ray diffraction, phase diagrams, and molecular modeling were performed to elucidate the observed phenomena. Here, we present evidence that the chlorophenols studied, when interacting with water, self-assemble into bilayers.

Self-assembly of flat nanodiscs in salt-free catanionic surfactant solutions.

Discs of finite size are a very rare form of stable surfactant self-assembly. It is shown that mixing of two oppositely charged single-chain surfactants can produce rigid nanodiscs as well as swollen lamellar liquid crystals with frozen bilayers. The crucial requirement for obtaining nanodisc self-assembly is the use of H+ and OH- as counterions.

Crystallographic analysis of freeze-fractured three-dimensionally ordered specimens.

We describe here an original approach for solving the structure of three-dimensionally ordered specimens at low and medium resolutions. It combines freeze-fracture electron microscopy and quantitative image processing and has been first successfully applied to the crystallographic study of different lipid-containing cubic phases. The structure preservation during cryofixation is controlled by recording X-ray diffraction before and after freezing.

Perfluoroalkylphosphocholines are poor protein-solubilizing surfactants, as tested with neutrophil plasma membranes.

We have tested the membrane-protein solubilizing properties of two perfluoroalkylphosphocholines. These compounds belong to a series of fluorinated amphiphiles which are being investigated as potential stabilizing agents for a variety of fluorocarbon-based systems. We are particularly interested in cytochrome b558 from phagocytes, the redox component of NADPH oxidase.

Molecular biology of S-layers.

In this chapter we report on the molecular biology of crystalline surface layers of different bacterial groups. The limited information indicates that there are many variations on a common theme. Sequence variety, antigenic diversity, gene expression, rearrangements, influence of environmental factors and applied aspects are addressed.

The S-layer protein of Corynebacterium glutamicum is anchored to the cell wall by its C-terminal hydrophobic domain.

PS2 is the S-layer protein of Corynebacterium glutamicum. The S-layer may be detached from the cell as organized sheets by detergents at room temperature. The solubilization of PS2 in the form of monomers requires detergent treatment at high temperature (70 degrees C), conditions under which the protein is denatured.

Freeze fracture electron microscopy of lyotropic lipid systems: quantitative analysis of the inverse micellar cubic phase of space group Fd3m (Q227).

An inverse micellar cubic phase of cubic aspect 15 formed by dioleoylglycerol/dioleoylphosphatidylcholine mixtures has been studied by freeze fracture electron microscopy. The structure was well preserved after freezing samples which had been hydrated either in pure water or in 30 vol% aqueous glycerol solutions. Electron microscopy images of high quality and resolution have been obtained.

Organization of the outer layers of the cell envelope of Corynebacterium glutamicum: a combined freeze-etch electron microscopy and biochemical study.

The cell surface of Corynebacterium glutamicum grown on solid medium was totally covered with a highly ordered, hexagonal surface layer. Also, freeze-fracture revealed two fracture surfaces which were totally covered with ordered arrays displaying an hexagonal arrangement and the same unit cell dimension as the surface layer. The ordered arrays on the concave fracture surface, closest to the cell surface, were due to the presence of particles while those on the convex fracture surface were their imprints.

Polymorphic phase behavior of perfluoroalkylated phosphatidylcholines.

The polymorphic phase behavior of the F-alkyl modified phosphatidylcholines FnCmPC with Fn = CnF2n + 1 and Cm = -(CH2)m- and the physicochemical properties of their aqueous dispersions have been investigated. We show that the supramolecular assemblies formed by F4C4PC, F6C4PC, F8C4PC and F4C10PC dispersed in water consist of liposomes. F6C10PC forms, as does F8C10PC, a ribbon-like phase (two-dimensional centered rectangular lattice) at 25 degrees C, but on heating, it forms a lamellar phase.