Antioxidant and Membrane Binding Properties of Serotonin Protect Lipids from Oxidation.

Serotonin (5-hydroxytryptamine, 5-HT) is a well-known neurotransmitter that is involved in a growing number of functions in peripheral tissues. Recent studies have shown nonpharmacological functions of 5-HT linked to its chemical properties. Indeed, it was reported that 5-HT may, on the one hand, bind lipid membranes and, on the other hand, protect red blood cells through a mechanism independent of its specific receptors. To better understand these underevaluated properties of 5-HT, we combined biochemical, biophysical, and molecular dynamics simulations approaches to characterize, at the molecular level, the antioxidant capacity of 5-HT and its interaction with lipid membranes. To do so, 5-HT was added to red blood cells and lipid membranes bearing different degrees of unsaturation. Our results demonstrate that 5-HT acts as a potent antioxidant and binds with a superior affinity to lipids with unsaturation on both alkyl chains. We show that 5-HT locates at the hydrophobic-hydrophilic interface, below the glycerol group. This interfacial location is stabilized by hydrogen bonds between the 5-HT hydroxyl group and lipid headgroups and allows 5-HT to intercept reactive oxygen species, preventing membrane oxidation. Experimental and molecular dynamics simulations using membrane enriched with oxidized lipids converge to further reveal that 5-HT contributes to the termination of lipid peroxidation by direct interaction with active groups of these lipids and could also contribute to limit the production of new radicals. Taken together, our results identify 5-HT as a potent inhibitor of lipid peroxidation and offer a different perspective on the role of this pleiotropic molecule.

Effects of surfactin on membrane models displaying lipid phase separation.

Surfactin, a bacterial amphiphilic lipopeptide is attracting more and more attention in view of its bioactive properties which are in relation with its ability to interact with lipids of biological membranes. In this work, we investigated the effect of surfactin on membrane structure using model of membranes, vesicles as well as supported bilayers, presenting coexistence of fluid-disordered (DOPC) and gel (DPPC) phases. A range of complementary methods was used including AFM, ellipsometry, dynamic light scattering, fluorescence measurements of Laurdan, DPH, calcein release, and octadecylrhodamine B dequenching. Our findings demonstrated that surfactin concentration is critical for its effect on the membrane. The results suggest that the presence of rigid domains can play an essential role in the first step of surfactin insertion and that surfactin interacts both with the membrane polar heads and the acyl chain region. A mechanism for the surfactin lipid membrane interaction, consisting of three sequential structural and morphological changes, is proposed. At concentrations below the CMC, surfactin inserted at the boundary between gel and fluid lipid domains, inhibited phase separation and stiffened the bilayer without global morphological change of liposomes. At concentrations close to CMC, surfactin solubilized the fluid phospholipid phase and increased order in the remainder of the lipid bilayer. At higher surfactin concentrations, both the fluid and the rigid bilayer structures were dissolved into mixed micelles and other structures presenting a wide size distribution.

The potent antimalarial peptide cyclosporin A induces the aggregation and permeabilization of sphingomyelin-rich membranes.

Cyclosporin A (CsA) is a hydrophobic peptide drug produced by the fungus Tolypocladium inflatum. CsA is commonly used as an immunosuppressive drug, but it also has antimalarial activity. The immunosuppressive activity of CsA is clearly due to its association with specific proteins of immune cells such as cyclophilins. By contrast, the antimalarial properties of this peptide are completely independent of the association with a parasite's cyclophilins. Because of its hydrophobicity, CsA may interact with biological membranes, which may participate in its therapeutic effect. Recently, we have shown a marked preference of CsA for insertion into sphingomyelin (SM) monolayers. In this article, we measure for the first time the ability of CsA to induce permeabilization and aggregation and to change the lipid order, especially in the presence of SM. Calcein-release experiments permitted us to show that CsA causes the leakage of the fluorescent probe from SM-rich liposomes by 40% and PC liposomes by 11%, suggesting a lipid-selective effect. Electron microscopy and dynamic light scattering experiments confirmed the different interaction of CsA with SM and PC vesicles: it formed much larger aggregates with SM than with PC. Our results taken together suggest that CsA could specifically weaken and aggregate SM-rich membranes, which could in turn explain why CsA is efficient in the treatment of malaria. Indeed, CsA could inhibit the development of Plasmodium by permeabilizing and aggregating the SM-rich membrane network formed by the parasite during its intraerythrocytic growth cycle.

Cholesterol modulation of membrane resistance to Triton X-100 explored by atomic force microscopy.

Biomembranes are not homogeneous, they present a lateral segregation of lipids and proteins which leads to the formation of detergent-resistant domains, also called "rafts". These rafts are particularly enriched in sphingolipids and cholesterol. Despite the huge body of literature on raft insolubility in non-ionic detergents, the mechanisms governing their resistance at the nanometer scale still remain poorly documented. Herein, we report a real-time atomic force microscopy (AFM) study of model lipid bilayers exposed to Triton X-100 (TX-100) at different concentrations. Different kinds of supported bilayers were prepared with dioleoylphosphatidylcholine (DOPC), sphingomyelin (SM) and cholesterol (Chol). The DOPC/SM 1:1 (mol/mol) membrane served as the non-resistant control, and DOPC/SM/Chol 2:1:1 (mol/mol/mol) corresponded to the raft-mimicking composition. For all the lipid compositions tested, AFM imaging revealed that TX-100 immediately solubilized the DOPC fluid phase leaving resistant patches of membrane. For the DOPC/SM bilayers, the remaining SM-enriched patches were slowly perforated leaving crumbled features reminiscent of the initial domains. For the raft model mixture, no holes appeared in the remaining SM/Chol patches and some erosion occurred. This work provides new, nanoscale information on the biomembranes' resistance to the TX-100-mediated solubilization, and especially about the influence of Chol.

Cytochrome c provokes the weakening of zwitterionic membranes as measured by force spectroscopy.

Cytochrome c (cyt c) is a small soluble protein from the intermembrane space of mitochondria. This protein is essential because it transfers electrons between two membrane complexes of the respiratory chain. In fact, during this transfer, the positively charged amino-acid residues surrounding the heme in the protein structure allow the cyt c to interact properly with the anionic part of other molecules: mainly the cardiolipin-rich membrane of mitochondria and respiratory complexes. We have previously shown that besides its interaction with anionic lipids, the cyt c is also able to cross neutral lipid membranes. In this work, with the help of AFM and punch-through experiments, we have measured the force required to penetrate the membrane in the fluid and in the gel phases with or without cyt c molecules. In the presence of cyt c molecules, the structures generated by the interaction with the protein were considerably weakened, which led to the desorption of the fluid bilayer and to a considerable loss of cohesion of the gel phase. These results show the usefulness of punch-through experiments in determining the changes of membrane properties in the presence of external agents.

Cytochrome c interaction with neutral lipid membranes: influence of lipid packing and protein charges.

The interaction of cytochrome c (cyt c) with fluid/gel neutral supported lipid membranes was investigated by time-lapse atomic force microscopy (AFM). AFM revealed the random formation of depressed areas in fluid membranes promoted by cyt c. These depressions corresponded to the desorption of fluid bilayer patches induced by cyt c. By contrast, the gel domains were never desorbed but they were progressively thickened in the presence of the protein. These results suggest that cyt c molecules might intercalate between the mica and the lipid bilayer. Although the interaction of cyt c with the mica surface is likely to be an artifact, this work is the first direct observation of cyt c ability to cross membranes. Furthermore, our data show that the net positive charge of cyt c molecules plays a pivotal role but it is not the sole factor responsible for cyt c insertion in the membrane.

Characterization of biomaterials polar interactions in physiological conditions using liquid-liquid contact angle measurements: relation to fibronectin adsorption.

Wettability of biomaterials surfaces and protein-coated substrates is generally characterized with the sessile drop technique using polar and apolar liquids. This procedure is often performed in air, which does not reflect the physiological conditions. In this study, liquid/liquid contact angle measurements were carried out to be closer to cell culture conditions. This technique allowed us to evaluate the polar contribution to the work of adhesion between an aqueous medium and four selected biomaterials widely used in tissue culture applications: bacteriological grade polystyrene (PS), tissue culture polystyrene (tPS), poly(2-hydroxyethyl methacrylate) film (PolyHEMA), and hydroxypropylmethylcellulose-carboxymethylcellulose bi-layered Petri dish (CEL). The contributions of polar interactions were also estimated on the same biomaterials after fibronectin (Fn) adsorption. The quantity of Fn adsorbed on PS, tPS, PolyHEMA and CEL surfaces was evaluated by using the fluorescein-labeled protein. PolyHEMA and CEL were found to be hydrophilic, tPS was moderately hydrophilic and PS was highly hydrophobic. After Fn adsorption on PS and tPS, a significant increase of the surface polar interaction was observed. On PolyHEMA and CEL, no significant adsorption of Fn was detected and the polar interactions remained unchanged. Finally, an inverse correlation between the polarity of the surfaces and the quantity of adsorbed Fn was established.

In situ micropatterning technique by cell crushing for co-cultures inside microfluidic biochips.

To perform dynamic cell co-culture on micropatterned areas, we have developed a new type of "on chip and in situ" micropatterning technique. The microchip is composed of a 200 microm thick PDMS (polydimethylsiloxane) chamber at the top of which are located 100 mum thick microstamps. The PDMS chamber is bonded to a glass slide. After sterilization and cell adhesion processes, a controlled force is applied on the top of the PDMS chamber. Mechanically, the microstamps come into contact of the cells. Due to the applied force, the cells located under the microstamps are crushed. Then, a microfluidic perfusion is applied to rinse the microchip and remove the detached cells. To demonstrate the potential of this technique, it was applied successfully to mouse fibroblasts (Swiss 3T3) and liver hepatocarcinoma (HepG2/C3a) cell lines. Micropatterned areas were arrays of octagons of 150, 300 and 500 microm mean diameter. The force was applied during 30 to 60s depending on the cell types. After cell crushing, when perfusion was applied, the cells could successfully grow over the patterned areas. Cultures were successfully performed during 72 h of perfusion. In addition, monolayers of HepG2/C3a were micropatterned and then co cultured with mouse fibroblasts. Numerical simulations have demonstrated that the presence of the microstamps at the top of the PDMS chamber create non uniform flow and shear stress applied on the cells. Once fabricated, the main advantage of this technique is the possibility to use the same microchip several times for cell micropatterning and microfluidic co-cultures. This protocol avoids complex and numerous microfabrication steps that are usually required for micropatterning and microfluidic cell culture in the same time.

Probing fibronectin-surface interactions: a multitechnique approach.

The development of adhesive as well as antiadhesive surfaces is essential in various biomaterial applications. In this study, we have used a multidisciplinary approach that combines biological and physicochemical methods to progress in our understanding of cell-surface interactions. Four model surfaces have been used to investigate fibronectin (Fn) adsorption and the subsequent morphology and adhesion of preosteoblasts. Such experimental conditions lead us to distinguish between anti- and proadhesive substrata. Our results indicate that Fn is not able to induce cell adhesion on antiadhesive materials. On adhesive substrata, Fn did not increase the number of adherent cells but favored their spreading. This work also examined Fn-surface interactions using ELISA immunoassays, fluorescent labeling of Fn, and force spectroscopy with Fn-modified tips. The results provided clear evidence of the advantages and limitations of each technique. All of the techniques confirmed the important adsorption of Fn on proadhesive surfaces for cells. By contrast, antiadhesive substrata for cells avoided Fn adsorption. Furthermore, ELISA experiments enabled us to verify the accessibility of cell binding sites to adsorbed Fn molecules.

Membrane resistance to Triton X-100 explored by real-time atomic force microscopy.

Lateral segregation of lipids and proteins in biological membranes leads to the formation of detergent-resistant domains, also called "rafts". Understanding the mechanisms governing the biomembrane's resistance to solubilization by detergents is crucial in biochemical research. Here, we used real-time atomic force microscopy (AFM) imaging to visualize the behavior of a model supported lipid bilayer in the presence of different Triton X-100 (TX-100) concentrations. Mixed dioleoylphosphatidylcholine/dipalmitoylphosphatidylcholine (DOPC/DPPC) supported bilayers were prepared by vesicle fusion. Real-time AFM imaging revealed that, at concentrations below the critical micelle concentration (CMC), TX-100 did not solubilize the bilayer, but the DPPC domains were eroded in a time-dependent manner. This effect was attributed to the DPPC molecular packing disorganization by the detergent starting from the DOPC/DPPC interface. Just above the CMC, the detergent led to a complete solubilization of the DOPC matrix, leaving the DPPC domains unaltered. At higher TX-100 concentrations, the DOPC was also immediately removed just after detergent addition, and the DPPC domains remaining on the mica surface appeared to be more swollen and were gradually solubilized. This progressive solubilization of the DPPC remaining phase did not start at the edge of the domains but from holes appearing and expanding at the center of DPPC patches. The swelling of the DPPC domains was directly correlated with TX-100 concentration above the CMC and with detergent intercalation between DPPC molecules. We are convinced that this approach will provide a key system to elucidate the physical mechanisms of membrane solubilization by nonionic detergents.

The SIV tilted peptide induces cylindrical reverse micelles in supported lipid bilayers.

Elucidation of the molecular mechanism leading to biomembrane fusion is a challenging issue in current biomedical research in view of its involvement in controlling cellular functions and in mediating various important diseases. According to the generally admitted stalk mechanism described for membrane fusion, negatively curved lipids may play a central role during the early steps of the process. In this study, we used atomic force microscopy (AFM) to address the crucial question of whether negatively curved lipids influence the interaction of the simian immunodeficiency virus (SIV) fusion peptide with model membranes. To this end, dioleoylphosphatidylcholine/dipalmitoylphosphatidylcholine (DOPC/DPPC) bilayers containing 0.5 mol % dioleoylphosphatidic acid (DOPA) were incubated with the SIV peptide and imaged in real time using AFM. After a short incubation time, we observed a 1.9 nm reduction in the thickness of the DPPC domains, reflecting either interdigitation or fluidization of lipids. After longer incubation times, these depressed DPPC domains evolved into elevated domains, composed of nanorod structures protruding several nanometers above the bilayer surface and attributed to cylindrical reverse micelles. Such DOPC/DPPC/DOPA bilayer modifications were never observed with nontilted peptides. Accordingly, this is the first time that AFM reveals the formation of cylindrical reverse micelles in lipid bilayers promoted by fusogenic peptides.

Transphosphatidylation activity of Streptomyces chromofuscus phospholipase D in biomimetic membranes.

The phospholipase D (PLD) from Streptomyces chromofuscus belongs to the superfamily of PLDs. All the enzymes included in this superfamily are able to catalyze both hydrolysis and transphosphatidylation activities. However, S. chromofuscus PLD is calcium dependent and is often described as an enzyme with weak transphosphatidylation activity. S. chromofuscus PLD-catalyzed hydrolysis of phospholipids in aqueous medium leads to the formation of phosphatidic acid. Previous studies have shown that phosphatidic acid-calcium complexes are activators for the hydrolysis activity of this bacterial PLD. In this work, we investigated the influence of diacylglycerols (naturally occurring alcohols) as candidates for the transphosphatidylation reaction. Our results indicate that the transphosphatidylation reaction may occur using diacylglycerols as a substrate and that the phosphatidylalcohol produced can be directly hydrolyzed by PLD. We also focused on the surface pressure dependency of PLD-catalyzed hydrolysis of phospholipids. These experiments provided new information about PLD activity at a water-lipid interface. Our findings showed that classical phospholipid hydrolysis is influenced by surface pressure. In contrast, phosphatidylalcohol hydrolysis was found to be independent of surface pressure. This latter result was thought to be related to headgroup hydrophobicity. This work also highlights the physiological significance of phosphatidylalcohol production for bacterial infection of eukaryotic cells.

Role of calcium and membrane organization on phospholipase D localization and activity. Competition between a soluble and insoluble substrate.

The phospholipase D (PLD) from Streptomyces chromofuscus is a soluble enzyme known to be activated by the phosphatidic acid-calcium complexes. PLD-catalyzed hydrolysis of phospholipids in aqueous medium leads to the formation of phosphatidic acid (PA). Previous studies concluded on an allosteric activation of PLD by the PA-calcium complexes. In this work, the role of PA and calcium was investigated in terms of membrane structure and dynamics. The role of calcium in PLD partitioning between the soluble phase and the water-lipid interface was tested. The monomolecular film technique was used to measure both membrane dynamics and PLD activity. These experiments provided information on PLD activity at a water-lipid interface. Moreover, the ability of PA to enhance PLD activity toward phosphatidylcholine was correlated to the physical properties of PA itself, affecting the rheology of the membrane. The effect of calcium was investigated on PLD binding to lipids and on the catalytic process by competition experiments between a soluble and a vesicular substrate. These experiments confirmed the absolute PLD requirement for calcium and pointed out the importance of calcium for PLD catalytic process and for the enzyme location at the water-lipid interface.