Cécile Loudet scite author profile

Specialized lipid domains (rafts) that are generally enriched in sterols and sphingolipids, are most likely present in cell membranes of animals, plants and fungi. While cholesterol and ergosterol are predominant in vertebrates and fungi, plants possess complex sterol profiles, dominated by sitosterol and stigmasterol in Arabidopsis thaliana. Fully hydrated model membranes of composition approaching those found in rafts of mammals, fungi and plants were investigated by means of solid-state 2H-NMR, using deuterated dipalmitoylphosphatidylcholine (2H(62)-DPPC). The dynamics of such membranes was determined through measuring of membrane ordering or disordering properties. The presence of the liquid-ordered, lo, phase, which may be an indicator of rigid sterol-sphingolipid domains, was detected in all binary or ternary mixtures of all sterols investigated. Of great interest, the dynamics of ternary mixtures mimicking rafts in plants (phytosterol/glucosylcerebroside/DPPC), showed a lesser temperature sensitivity to thermal shocks, on comparing to systems mimicking rafts in mammals and fungi. This effect was particularly marked with sitosterol. The presence of an ethyl group branched on the alkyl chain of sitosterol and stigmasterol is proposed as reinforcing the membrane cohesion by additional attractive van der Waals interactions with the alkyl chains of sphingolipids and phospholipids. As a side result, the elevated resolution of NMR spectra in the presence of sitosterol also suggests domains of smaller size than with other sterols. Finally, the role of phytosterols in maintaining plant membranes in a state of dynamics less sensitive to temperature shocks is discussed.

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Bicelles: A natural ‘molecular goniometer’ for structural, dynamical and topological studies of molecules in membranes

Diller

Loudet

Aussenac

et al. 2009

Biochimie

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Major biological processes occur at the biological membrane. One of the great challenges is to understand the function of chemical or biological molecules inside the membrane; as well of those involved in membrane trafficking. This requires obtaining a complete picture of the in situ structure and dynamics as well as the topology and orientation of these molecules in the membrane lipid bilayer. These led to the creation of several innovative models of biological membranes in order to investigate the structure and dynamics of amphiphilic molecules, as well as integral membrane proteins having single or multiple transmembrane segments. Because the determination of the structure, dynamics and topology of molecules in membranes requires a macroscopic alignment of the system, a new membrane model called 'bicelles' that represents a crossover between lipid vesicles and classical micelles has become very popular due to its property of spontaneous self-orientation in magnetic fields. In addition, crucial factors involved in mimicking natural membranes, such as sample hydration, pH and salinity limits, are easy to control in bicelle systems. Bicelles are composed of mixtures of long chain (14-18 carbons) and short chain phospholipids (6-8 carbons) hydrated up to 98% with buffers and may adopt various morphologies depending on lipid composition, temperature and hydration. We have been developing bicelle systems under the form of nano-discs made of lipids with saturated or biphenyl-containing fatty acyl chains. Depending on the lipid nature, these membranous nano-discs may be macroscopically oriented with their normal perpendicular or parallel to the magnetic field, providing a natural 'molecular goniometer' for structural and topological studies, especially in the field of NMR. Bicelles can also be spun at the magic angle and lead to the 3D structural determination of molecules in membranes.

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Cécile Loudet

Plant sterols in “rafts”: a better way to regulate membrane thermal shocks

Bicelles: A natural ‘molecular goniometer’ for structural, dynamical and topological studies of molecules in membranes

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