Phases of phosphatidyl ethanolamine monolayers studied by synchrotron x-ray scattering.

For the first time, phospholid monolayers at the air/water interface have been studied by x-ray diffraction and reflection all along the isotherm from the laterally isotropic fluid (the so-called LE phase) to the ordered phases. The model used to analyze the data, and the accuracy of the parameters deduced, were tested by comparing the results obtained with two lipids having the same head group but different chain lengths. Compression of the fluid phase leads predominantly to a change of thickness of the hydrophobic moiety, much less of its density, with the head group extension remaining constant. The main transition involves a considerable increase (approximately 10%) of the electron density in the hydrophobic region, a dehydration of the head group and a positional ordering of the aliphatic tails, albeit with low coherence lengths (approximately 10 spacings). On further compression of the film, the ordered phase undergoes a continuous transition. This is characterized by an increase in positional ordering, a discontinuous decrease in lateral compressibility, a decrease in chain tilt angle with respect to the surface normal towards zero and probably also a head group dehydration and ordering.     

Conformation of peptides in lipid membranes studied by x-ray grazing incidence scattering

Although the antimicrobial, fungal peptide alamethicin has been extensively studied, the conformation of the peptide and the interaction with lipid bilayers as well as the mechanism of channel gating are still not completely clear. As opposed to studies of the crystalline state, the polypeptide structures in the environment of fluid bilayers are difficult to probe. We have investigated the conformation of alamethicin in highly aligned stacks of model lipid membranes by synchrotron-based x-ray scattering. The (wide-angle) scattering distribution has been measured by reciprocal space mappings. A pronounced scattering signal is observed in samples of high molar peptide/lipid ratio which is distinctly different from the scattering distribution of an ideal helix in the transmembrane state. Beyond simple models of ideal helices, the data is analyzed in terms of models based on atomic coordinates from the Brookhaven Protein Data Bank, as well as from published molecular dynamics simulations. The results can be explained by assuming a wide distribution of helix tilt angles with respect to the membrane normal and a partial insertion of the N-terminus into the membrane.     

Structural studies of the HIV-1 accessory protein Vpu in langmuir monolayers: synchrotron X-ray reflectivity

Vpu is an 81 amino acid integral membrane protein encoded by the HIV-1 genome with a N-terminal hydrophobic domain and a C-terminal hydrophilic domain. It enhances the release of virus from the infected cell and triggers degradation of the virus receptor CD4. Langmuir monolayers of mixtures of Vpu and the phospholipid 1,2-dilignoceroyl-sn-glycero-3-phosphocholine (DLgPC) at the water-air interface were studied by synchrotron radiation-based x-ray reflectivity over a range of mole ratios at constant surface pressure and for several surface pressures at a maximal mole ratio of Vpu/DLgPC. Analysis of the x-ray reflectivity data by both slab model-refinement and model-independent box-refinement methods firmly establish the monolayer electron density profiles. The electron density profiles as a function of increasing Vpu/DLgPC mole ratio at a constant, relatively high surface pressure indicated that the amphipathic helices of the cytoplasmic domain lie on the surface of the phospholipid headgroups and the hydrophobic transmembrane helix is oriented approximately normal to the plane of monolayer within the phospholipid hydrocarbon chain layer. At maximal Vpu/DLgPC mole ratio, the tilt of the transmembrane helix with respect to the monolayer normal decreases with increasing surface pressure and the conformation of the cytoplasmic domain varies substantially with surface pressure.     

Comparative interaction of alpha-helical and beta-sheet amphiphilic isopeptides with phospholipid monolayers

The two sequential amphiphilic peptide isomers, (Leu-Lys-Lys-Leu)4 and (Leu-Lys)8, were chosen as models for alpha-helical and beta-sheet peptides, respectively. In order to evaluate the contribution of the secondary structure of a peptide to its penetration into cellular membranes, interactions of these isopeptides with L-alpha-dimyristoyl phosphatidylcholine (DMPC) monolayers were studied. Both isopeptides penetrate into DMPC monolayers up to an exclusion pressure of approximately 27 mN/m, but a discontinuity is observed in the penetration profile of the alpha-helical (LKKL)4. The main parameters extracted from the compression isotherms of the mixed peptide/DMPC monolayers-namely, transition pressure, mean area, elasticity modulus, and energy of mixing-were analyzed. These analyses indicate that the alpha-helical isomer interacts strongly with DMPC by forming a 1:32 (LKKL)4-DMPC complex. When engaged in this complex, (LKKL)(4) behaves as an hydrophobic helix and has a tendency to become vertically oriented in the course of the compression process. The beta-sheet (LK)8 interacts more weakly with DMPC and no complex can be detected.     

Synthetic phospholipid analogs: a structural investigation with scattering methods

The phase behavior of the newly synthesized phospholipid analogs is necessary to be known because of the importance of the structure of the phospholipid analogs for the activity against tumor cell lines. The type of aggregates formed under defined conditions, the size distribution and the internal structure of the particles as well as stability upon storage are examined by scattering methods. Octadecyl-methyl-glycero-phosphocholine (OMGPC) and Octadecyl-imidazoyl-deoxy-glycero-phosphocholine (OIDGPC) are cytostatic systems designed synthetically for the medical application and, therefore, prepared and measured usually at 37 degrees C. Both phospholipid analogs behave under the same conditions almost similarly. They show also the similar behavior in long term studies like the biological ganglioside GM1. Under physiological conditions, OMGPC and OIDGPC form spherical micelles with a maximum dimension of about 8 nm, which do not change with concentration.     

Interfacial behavior of phospholipid monolayers revealed by mesoscopic simulation

A mesoscopic model with molecular resolution is presented for dipalmitoyl phosphatidylcholine (DPPC) and palmitoyl oleoyl phosphatidylcholine (POPC) monolayer simulations at the air-water interface using many-body dissipative particle dynamics (MDPD). The parameterization scheme is rigorously based on reproducing the physical properties of water and alkane and the interfacial property of the phospholipid monolayer by comparison with experimental results. Using much less computing cost, these MDPD simulations yield a similar surface pressure-area isotherm as well as similar pressure-related morphologies as all-atom simulations and experiments. Moreover, the compressibility modulus, order parameter of lipid tails, and thickness of the phospholipid monolayer are quantitatively in line with the all-atom simulations and experiments. This model also captures the sensitive changes in the pressure-area isotherms of mixed DPPC/POPC monolayers with altered mixing ratios, indicating that the model is promising for applications with complex natural phospholipid monolayers. These results demonstrate a significant improvement of quantitative phospholipid monolayer simulations over previous coarse-grained models.     

Small-angle x-ray scattering by poly-L-alanine solutions

The radius of gyration and “persistence length” of poly-L -alanine, calculated from small-angle x-ray scattering data, have values of 56 Å and 44 Å, respectively, in dichloroacetic acid, and 78 Å and ～30 Å in a 1:1 v/v mixture of trifluoroacetic acid and trifluoroethanol. This can be interpreted to mean that poly-L -alanine exists in a relatively rigid, predominantly α-helical conformation in dichloroacetic acid and in an extended, more flexible form in the mixed solvent system.     

Interactions of phospholipid monolayers with carbohydrates

Surface pressure studies of phospholipid monomolecular films of dimyristoylphosphatidylcholine (DMPC) and dipalmitoylphosphatidylcholine (DPPC) formed at an air/water interface have been made and the effects on the films studied when various carbohydrates are present in the subphase. The results obtained show that at a given temperature, the area per molecule of DPPC increases with increasing concentration of the carbohydrate in the subphase. The carbohydrate which has the greatest expanding effect on the phospholipid monolayer is glycerol, followed in turn by trehalose, sucrose, glucose, raffinose, and inositol. The mechanism of monolayer expansion by glycerol is different from that observed in other carbohydrates, as the following experiments demonstrate. Below the phase transition temperature of DPPC, the area per molecule of DPPC at a pressure of 12.5 dyn/cm is the same with and without glycerol in the subphase. However, when the monolayer is heated to a temperature above the phase transition temperature for DPPC, the area/molecule on glycerol is considerably greater than the area/molecule on water at the same surface pressure. Cooling the monolayer back to the lower temperature produces an area/molecule of DPPC which is identical on both water and glycerol subphases. Glycerol therefore has no effect on the low-temperature (condensed) monolayers but causes expansion of the high-temperature (expanded) monolayers. By contrast with glycerol, both trehalose and sucrose interact with the DPPC monolayer producing an increased area/molecule over that observed on water, both with low-temperature (condensed) monolayers and with the high-temperature (expanded) monolayers. The efficiency of these carbohydrates at expanding the monolayer films (with the exception of glycerol) shows a strong correlation with their ability to stabilize membrane structure and function at low water contents.     

Penetration of furosemide into phospholipid monolayers

Furosemide is a surface-active anion and it tends to displace lipid monolayers from the surface at positive polarizations lowering their potential stability range. The efficiency of the penetration and the displacement increases with decreasing surface pressure of the monolayer. Lower capacitance at a wider potential range corresponds to higher surface pressure. Monolayers with higher capacitances are indeed more readily penetrated and displaced as demonstrated by further increase in their capacitance and increase in their proton conductance. Furosemide raises the capacitance of the monolayer in the stable region due to intercalation between the head groups thus reducing the thickness of the hydrocarbon layer. In pure PC monolayer about 10% increase in capacitance is observed in the presence of 6 X 10(-4)M furosemide. The effect of furosemide becomes more pronounced with increasing sphingomyelin content in the mixed monolayers. The monolayer of PE is more condensed and its capacitance is lower (approximately 1.45 microF/cm2) and is stable in a wider potential range than that of PC. It is less affected by furosemide and concentrations higher than 10(-3) M are required to narrow the stability range and to increase the capacitance.     

Penetration of furosemide into phospholipid monolayers

Summary Furosemide is a surface-active anion and it tends to displace lipid monolyaers from the surface at positive polarizations lowering their potential stability range. The efficiency of the penetration and the displacement increases with decreasing surface pressure of the monolayer. Lower capacitance at a wider potential range corresponds to higher surface pressure. Monolayers with higher capacitances are indeed more readily penetrated and displaced as demonstrated by further increase in their capacitance and increase in their proton conductance. Furosemide raises the capacitance of the monolayer in the stable region due to intercalation between the head groups thus reducing the thickness of the hydrocarbon layer. In pure PC monolayer about 10% increase in capacitance is observed in the presence of 6×10^–4 m furosemide. The effect of furosemide becomes more pronounced with increasing sphingomyelin content in the mixed monolayers. The monolayer of PE is more condensed and its capacitance is lower (1.45 F/cm²) and is stable in a wider potential range than that of PC. It is less affected by furosemide and concentrations higher than 10^–3 m are required to narrow the stability range and to increase the capacitance.     

Small angle x-ray scattering studies on adenovirus type 2 hexon

Adenovirus type 2 hexons have been studied in solution by small angle X-ray scattering, and the following molecular parameters determined: radius of gyration (Rg) = 4.9 nm, molecular weight (M) = 310.000, invariant volume (Vinv) = 630 mn3, maximal distance (Dmax) = 14.5--15.5 nm. A diffraction pattern was obtained up to an angular increment of h = 2.5 nm-1. Various models for the hexon have been explored by calculating the diffraction pattern from the Debye formula for 1200 spheres arranged to define the scattering volume of each model. Models were first built according to electron micrographic results. Later, preliminary results of a crystallographic study were used for model building. The experimental pattern and the pattern resulting from the model determined by crystallographic methods were compared and showed good agreement.     

Conducting gramicidin channel activity in phospholipid monolayers

Potential step amperometry (chronoamperometry) of the Tl(I)/Tl(Hg) electrochemical reduction process has been used to investigate the underlying mechanisms of gramicidin activity in phospholipid monolayers. The experiments were carried out at gramicidin-modified dioleoyl phosphatidylcholine (DOPC)-coated electrodes. Application of a potential step to the coated electrode system results in a current transient that can be divided into two regions. An initial exponential decay of current corresponds to the inactivation of monomer channel conductance and a longer time scale quasi-steady-state represents the diffusion of ions to a bimolecular surface reaction. Concentrations of monomer conducting channels are relatively low, and the results indicate that two or more forms of gramicidin are in equilibrium with each other in the layer. Aromatic/conjugated compounds incorporated into the monolayer increase the reduction current by decreasing the rate of channel inactivation and increasing the stability of the conducting channel. This effect is positively correlated with the degree of the compound's aromaticity. The anomalous influence of alkali metal ions on the reduction current is consistent with the model of gramicidin being speciated in the monolayer in more than one form. The results have implications on the lability of the peptide conformation in biological membranes and its dependence on lipid environment, solution composition, and applied potential.     

Thermal and structural behavior of dioctadecyldimethylammonium bromide dispersions studied by differential scanning calorimetry and x-ray scattering

Dioctadecyldimethylammonium bromide (DODAB) is a double chain cationic lipid, which assembles as bilayer structures in aqueous solution. The precise structures formed depend on, e.g., lipid concentration and temperature. We here combine differential scanning calorimetry (DSC) and X-ray scattering (SAXS and WAXS) to investigate the thermal and structural behavior of up to 120 mM DODAB in water within the temperature range 1–70°C. Below 1 mM, this system is dominated by unilamellar vesicles (ULVs). Between 1 and 65 mM, ULVs and multilamellar structures (MLSs) co-exist, while above 65 mM, the MLSs are the preferred structure. Depending on temperature, DSC and X-ray data show that the vesicles can be either in the subgel (SG), gel, or liquid crystalline (LC) state, while the MLSs (with lattice distance d  = 36.7 Å) consist of interdigitated lamellae in the SG state, and ULVs in the LC state (no Bragg peak). Critical temperatures related to the thermal transitions of these bilayer structures obtained in the heating and cooling modes are reported, together with the corresponding transition enthalpies.     

The adsorption of prothrombin to phospholipid monolayers quantitated by ellipsometry

We investigated by means of an automated ellipsometer the calcium-dependent binding of prothrombin from a buffer solution to monolayers of dioleoylphosphatidylserine (DOPS) and dioleoylphosphatidylcholine (DOPC) deposited on chromium slides. This technique allows direct measurements of bound and free protein concentrations and is not hampered by calcium-induced aggregation of vesicles. For pure DOPS a dominant class of binding sites exists with a dissociation constant, Kd = (6 +/- 2) X 10(-10) M (mean +/- S.D.) and maximal binding of prothrombin, gamma max = 0.26 +/- 0.03 micrograms/cm2. Incorporation of a small fraction of DOPC in the monolayer causes a large decrease in the binding affinity with a pronounced biphasic behavior of the binding curve. For monolayers consisting of 20% DOPS and 80% DOPC the binding curve becomes monophasic with Kd = (1.6 +/- 0.6) X 10(-7) M and gamma max = 0.22 +/- 0.03 micrograms/cm2. The procoagulant activity of the monolayers was tested by measuring the generation of thrombin after addition of prothrombin and activated coagulation factors X and V. The thrombin-generating capacity of monolayers and single-bilayer vesicles is comparable but is apparently diffusion limited in the monolayer system. The calcium-dependent formation of stacked multilayers according to the Blodgett technique appeared to be strongly influenced by the DOPS/DOPC ratio in the phospholipid monolayer. From these results it is concluded that for pure DOPS monolayers high-affinity prothrombin-phospholipid and phospholipid-phospholipid interactions exist which are radically disturbed when the monolayer contains more than 20-30% of DOPC.     

Small angle x-ray scattering studies of magnetically oriented lipid bilayers.

Magnetically oriented lipid/detergent bilayers are potentially useful for studies of membrane-associated molecules and complexes using x-ray scattering and nuclear magnetic resonance (NMR). To establish whether the system is a reasonable model of a phospholipid bilayer, we have studied the system using x-ray solution scattering to determine the bilayer thickness, interparticle spacing, and orientational parameters for magnetically oriented lipid bilayers. The magnetically orientable samples contain the phospholipid L-alpha-dilauroylphosphatidylcholine (DLPC) and the bile salt analog 3-[(3-cholamidopropyl)dimethylammonio]-2-hydroxy-1-propanesulfonate (CHAPSO) in a 3:1 molar ratio in 70% water (w/v) and are similar to magnetically orientable samples used as NMR media for structural studies of membrane-associated molecules. A bilayer thickness of 30 A was determined for the DLPC/CHAPSO particles, which is the same as the bilayer thickness of pure DLPC vesicles, suggesting that the CHAPSO is not greatly perturbing the lipid bilayer. These data, as well as NMR data on molecules incorporated in the oriented lipid particles, are consistent with the sample consisting of reasonably homogeneous and well dispersed lipid particles. Finally, the orientational energy of the sample suggests that the size of the cooperatively orienting unit in the samples is 2 x 10(7) phospholipid molecules.     

Order in phospholipid Langmuir-Blodgett monolayers determined by total internal reflection fluorescence

Orientational order parameters of two diphenylhexatriene (DPH)-based fluorescent probes, 2-(3-(diphenylhexatrienyl)propanoyl)-1-hexadecanoyl-sn-glycero-3-p hosphocholine (DPHpPC) and 1-(4-trimethylammoniumphenyl)-6-phenyl-1,3,5-hexatriene (TMA-DPH), in dipalmitoylphosphatidylcholine (DPPC) Langmuir-Blodgett monolayers on quartz have been determined by total internal reflection fluorescence (TIRF). From these order parameters orientation distributions were reconstructed by the maximum-entropy method. For monolayers transferred from the liquid-condensed phase, preferential tilt angles with respect to the substrate normal around 14 degrees in the tail region and 5 degrees near the glycerol-acyl chain linkage were found, as reflected by the DPHpPC and TMA-DPH probes, respectively. The degree of ordering near the headgroup region seems to be larger than that further away from the surface. A substantial fraction of the TMA-DPH probes have a flat orientation and are probably located between the phospholipid headgroups and the substrate surface. Monolayers transferred from the liquid-expanded phase show a more random ordering, and most of the probe molecules (DPHpPC) are more or less flat on the surface. The results are consistent with earlier atomic force microscopy measurements on identical monolayers and are in reasonable agreement with previously published data on other organized phospholipid systems.     

Aggregation of gramicidin A in phospholipid Langmuir-Blodgett monolayers

The aggregation of Gramicidin A (gA) in dipalmitoylphosphatidylcoline (DPPC) monolayers is investigated by both thermodynamic and structural methods. Compression isotherm analysis and atomic force microscopy (AFM) observations are performed. Our experimental results indicate that gA aggregation does occur in DPPC monolayers even at very low gA concentration (about 8 x 10(-4) mol%). At the low gA concentration limit, the aggregation process seems to be mainly horizontal (i.e., side-by-side, into the monolayer plane), following a fractal pattern growth producing the formation of typical, flat (0.5 nm height) "doughnut" structures, with a diameter of approximately 150 nm. These structures appear to be composed of smaller subunits (about 70 nm diameter) showing the same doughnut structure. At a molar fraction of approximately 3.8 mol%, the big doughnuts start to disaggregate and only small doughnuts appear. Above a gA concentration of approximately 4.4 mol%, all doughnuts (large and small) disappear, and the morphology assumes the appearance of a patchwork of two distinct phases: one that, being very flat, can be associated with a gA-free or gA-poor DPPC phase, and a second one, characterized by a more corrugated surface, associated with a gA-rich DPPC phase. At gA concentration of approximately 5 mol%, a percolation transition in the gA-rich DPPC phase occurs. Thermodynamic data indicate that the maximum of miscibility between gA and DPPC molecules occurs at approximately 28 mol%, suggesting that gA could aggregate in hexamers that are, on average, bound to 16 DPPC molecules. At the same concentration, AFM images show a network of small gA aggregation units of a size compatible with gA hexamers.     

Development of equilibrium domain shapes in phospholipid monolayers

Fluorescence micrographs of monolayers of L-alpha-dipalmitoylphosphatidylcholine (DPPC) at the air water interface are analyzed. Ordered phase domains in coexistence with the fluid lipid phase change their shapes with time and with lateral pressure. With domains fixed under an electrode and well separated from their neighbours a peculiar instability of the boundary lines is observed. It is ascribed to the onset of an electrostatically induced shape transition. Elaborating the boundary regions where domain fusion and fission, respectively, are observed leads to a model on in-plane dipole orientation.