Insertion Of X-Ray Structures Of Proteins In Membranes

Few structures of membrane proteins are known and their relationships with the membrane are unclear. In a previous report, 20 X-ray structures of transmembrane proteins were analyzed in silico for their orientation in a 36A-thick membrane [J. Mol. Graph. Model. 20 (2001) 235]. In this paper, we use the same approach to analyze how the insertion of the X-ray structures varies with the bilayer thickness. The protein structures are kept constant and, at each membrane thickness, the protein is allowed to tilt and rotate in order to accommodate at their best. The conditions are said to be optimal when the energy of insertion is minimal. The results show that most helix bundles require thicker membranes than porin barrels. Moreover, in a few instances, the ideal membrane thickness is unrealistic with respect to natural membranes supporting that the X-ray structure requires adaptation to stabilize in membrane. For instance, the squalene cyclase could adapt by bending the side chains of its ring of lysine and arginine in order to increase the hydrophobic surface in contact with membranes. We analyzed the distribution of amino acids in the water, interface and acyl chain layers of the membrane and compared with the literature

Molecular organization of surfactin-phospholipid monolayers: Effect of phospholipid chain length and polar head

Mixed monolayers of the surface-active lipopeptide surfactin-C-15 and various lipids differing by their chain length (DMPC, DPPC, DSPC) and polar headgroup (DPPC, DPPE, DPPS) were investigated by atomic force microscopy (AFM) in combination with molecular modeling (Hypermatrix procedure) and surface pressure-area isotherms. In the presence of surfactin, AFM topographic images showed phase separation for each surfactin-phospholipid system except for surfactin-DMPC, which was in good agreement with compression isotherms. On the basis of domain shape and line tension theory, we conclude that the miscibility between surfactin and phospholipids is higher for shorter chain lengths (DMPC > DPPC > DSPC) and that the polar headgroup of phospholipids influences the miscibility of surfactin in the order DPPC > DPPE > DPPS. Molecular modeling data show that mixing surfactin and DPPC has a destabilizing effect on DPPC monolayer while it has a stabilizing effect towards DPPE and DPPS molecular interactions. Our results provide valuable information on the activity mechanism of surfactin and may be useful for the design of surfactin delivery systems. (c) 2007 Elsevier B.V. All rights reserved

Rotational behaviour of PEGylated gold nanorods in a lipid bilayer system

PEGylated gold nanorods are widely used as nanocarriers in targeted drug delivery and other nanotechnology applications due to the special optical and photo-thermal characteristics of gold nanorods. In this work, we employ coarse-grain molecular simulations to examine the pathway by which PEGylated gold nanorods enter and exit a dipalmitoylphosphatidylcholine lipid bilayer membrane and follow the behaviour of the system to investigate the consequences. We find that PEGylated gold nanorods rotate during permeation, lying down and straightening up as they make their way through the lipid membrane. We find that this rotational behaviour, irrespective of the initial orientation of the nanorod with respect to the membrane normal, is concomitant with the changing interactions of polyethylene glycol (PEG) beads with lipid head beads in both membrane leaflets. For a nanorod with hydrophilic ligands, such as PEG, lying down appears to be driven by favourable hydrophilic interactions with the phosphate and choline groups of the lipid. Mobility of the ligands offers mechanisms for these favourable interactions and for minimising unfavourable interactions with the hydrophobic lipid tails that constitute the inner section of the membrane; the PEG ligands can stretch out to reach the phosphate and choline groups of both leaflets and they can coil in and interact with each other and avoid the alkane lipid tails. Recently developed experimental techniques for imaging, orientation, and rotation of single gold nanorods may be able to observe this predicted rotational behaviour. We find that lipid flip-flop mechanisms do not differ significantly from a spherical gold nanoparticle to a gold nanorod, and PEGylated gold nanorods like their spherical counterparts do not remove lipid molecules from the bilayer membrane. Our results should be of interest to experimentalists who plan to use functionalised gold nanorods in biomedical applications

Profile of the Belgian dermatologist: results of an online survey

SCOPUS: le.jFLWINinfo:eu-repo/semantics/publishe