Lateral diffusion in equimolar mixtures of natural sphingomyelins with dioleoylphosphatidylcholine

Cellular membranes of mammals are composed of a complex assembly of diverse phospholipids. Sphingomyelin (SM) and phosphatidylcholine (PC) are important lipids of eukaryotic cellular membranes and neuronal tissues, and presumably participate in the formation of membrane domains, known as "rafts," through intermolecular interaction and lateral microphase decomposition. In these two-dimensional membrane systems, lateral diffusion of lipids is an essential dynamic factor, which might even be indicative of lipid phase separation process. Here, we used pulsed field gradient nuclear magnetic resonance to study lateral diffusion of lipid components in macroscopically oriented bilayers composed of equimolar mixtures of natural SMs of egg yolk, bovine brain, bovine milk and dipalmitoylphosphatidylcholine (DPPC) with dioleoylphosphatidylcholine (DOPC). In addition, differential scanning calorimetry was used as a complementary technique to characterize the phase state of the lipid bilayers. In fully liquid bilayers, the lateral diffusion coefficients in both DOPC/DPPC and DOPC/SM systems exhibit mean values of the pure bilayers. For DOPC/SM bilayer system, this behavior can be explained by a model where most SM molecules form short-lived lateral domains with preferential SM-SM interactions occurring within them. However, for bilayers in the presence of their low-temperature gel phase, lateral diffusion becomes complicated and cannot simply be understood solely by a simple change in the liquid phase decomposition.     

Coarse-grained simulations on interactions between spectrins and phase-separated lipid bilayers

Spectrin, the principal protein of the cytoskeleton of erythrocyte, plays a crucial role in the stability and flexibility of the plasma membrane of erythrocyte. In this work, we investigate the interactions between spectrins and phase-separated lipid bilayers using coarse-grained molecular dynamics simulation. We focus on the preference of spectrins with different lipids, the effects of the anionic lipids and the residue mutation on the interactions between spectrins and the lipid bilayers. The results indicate that spectrins prefer to contact with phosphatidylethanolamine (PE) lipids rather than with phosphatidylcholine (PC) lipids, and tend to contact with the liquid-disordered (Ld) domains enriched in unsaturated PE. Additionally, the anionic lipids, which show specific interaction with the positively charged or polar amino acids on the surface of the spectrins, can enhance the attraction between the spectrins and lipid domains. The mutation leads to the decrease of the structural stability of spectrins and increases the curvature of the lipid bilayer. This work provides some theoretical insights into understanding the erythrocyte structure and the mechanism of some blood diseases.     

Interaction of dipalmitoyl phosphatidylcholine (DPPC) liposomes and insulin

Insulin, a peptide that has been used for decades in the treatment of diabetes, has well-defined properties and delivery requirements. Liposomes, which are lipid bilayer vesicles, have gained increasing attention as drug carriers which reduce the toxicity and increase the pharmacological activity of various drugs. The molecular interaction between (uncharged lipid) dipalmitoyl phosphatidylcholine (DPPC) liposomes and insulin has been characterized by using Fourier transform infrared spectroscopy (FTIR) and X-ray diffraction. The characteristic protein absorption band peaks, Amide I (at about 1660?cm^?1) and Amide II band (at about 1546?cm^?1) are potentially reduced in the liposome insulin complex. Wide-angle x-ray scattering measurements showed that the association of insulin with DPPC lipid of liposomes still maintains the characteristic DPPC diffraction peaks with almost no change in relative intensities or change in peak positions. The absence of any shift in protein peak positions after insulin being associated with DPPC liposomes indicates that insulin is successfully forming complex with DPPC liposomes with possibly no pronounced alterations in the structure of insulin molecule.     

拉曼光谱研究人参皂苷Rb1与DPPC双层膜的作用

为深入了解人参皂苷的分子药理学特性,阐明人参皂苷与细胞膜的作用机制,利用拉曼光谱从分子水平研究了不同浓度人参皂苷Rb1与DPPC(二棕榈酰磷脂酸胆碱)双层膜的作用.结果表明,人参皂苷Rb1没有改变DPPC的极性头部O-C-C-N+的稳定构象,极性头仍然平行于膜表面.并且,拉曼峰值比I1096/I1126/1096/I1062和I2848/I288/0随着药物浓度的增加而相应的变大,说明Rbl增加了烃链的无序度,增强了双层膜的流动性.由此推测该药物与DPPC的作用可能由于皂苷分子内及分子间的氢键与磷脂双层膜的极性头部相作用而停留在膜的表面.     

Permeation of nanocrystals across lipid membranes

Biological membranes are one of the major structural elements of cells, and play a key role as a selective barrier and substrate for many proteins that facilitate transport and signaling processes. Understanding the structural and mechanical properties of lipid membranes during permeation of nanomaterials is of prime importance in determining the toxicity of nanomaterials to living cells. It has been shown that the interaction between lipid membranes and nanomaterials and the disruption of lipid membranes are often determined by physicochemical properties of nanomaterials, such as size, shape and surface composition. In this work, molecular dynamic simulations were carried out using various sizes of nanocrystals as a probe to explore the transport of nanomaterials across dipalmitoylphosphatidylcholine (DPPC) bilayers and the changes in the structural and mechanical properties of DPPC bilayers during the permeation. A coarse-grained model was used to provide insight at large time and length scales. In this work, an external driving force helps the nanocrystals across the lipid bilayer. The minimum forces needed to penetrate the model membrane and the interaction of nanocrystals and lipid bilayers were investigated in simulations. The elastic and dynamic properties of lipid bilayers, including the local and bulk properties during the permeation of the nanocrystals, which are of considerable fundamental interest, were also studied. The findings described will lead to better understanding of nanomaterial–lipid membrane interactions and the mechanical and dynamic properties of lipid membranes under permeation.     

31P NMR and FTIR studies on the interaction of phosphorylacetohydrazides with dipalmitoyl phosphatidylcholine model membranes

The effect of original synthetic nootropic drugs (phosphorylacetohydrazides) on the physical properties of the dipalmitoyl phosphatidylcholine (DPPC) membranes was studied by³¹P nuclear magnetic resonance and Fourier transform infrared spectroscopies. It has been shown that the tested preparations reduce the phase transition temperature, widen the transition interval, suppress pretransition, render some condensing effect on the gel phase and essentially disorder the lipid bilayer in the liquid-crystalline state. The obtained results are in agreement with the suggested mechanism of the primary pharmacological effect of nootropic preparations. According to this mechanism, the drug molecules penetrate into the hydrophilic region of the bilayer, interacting closely with the polar groups of DPPC, disturbing the bilayer organization and leading to polymorphism. By taking into account that the main property of nootropic preparations is to improve processes of training and memory, we suppose that the new lipid-drug organization of phospholipidic membranes and lipid polymorphism are the necessary steps of the nootropic activity. The similarity of molecular mechanisms of various nootropic drug effects on the lipid bilayer allows us to suppose that the positive effect of nootropics on the synaptic transmission may be governed by their influence on the phase transition of the lipid component of the synaptic membranes at the stage of the neurotransmitter release.     

含缩醛正离子类脂分子与蛋白质的相互作用

合成系列含缩醛的双链正离子类脂分子 ,并用荧光光谱研究其与牛血清蛋白 (BSA)的相互作用 .通过荧光的变化 ,解释蛋白质构象的变化 .在低类脂浓度时 ,少量类脂分子束缚在牛血清蛋白周围 ,荧光有很大幅度的淬灭 ,蛋白质本身肽链被解开 ,与此同时最大发射波长从 (3 44± 1)nm蓝移到 (3 3 1± 1)nm .由于疏水相互作用 ,更多类脂分子不断地聚集在蛋白质周围 ,牛血清蛋白中的两个色氨酸残基被完全地包裹在类脂分子形成的双分子膜中 ,荧光强度不断增加直到恒定不变     

Influence of salicylic acid on the biophysical properties of dipalmitoyl phosphatidylcholine vesicles

The effect of the keratolytic drug salicylic acid (SA) on the thermotropic behaviour, and dynamics of dipalmitoyl phosphatidyl choline (DPPC)–water/buffer pH?7.4 vesicles was studied using DSC and ¹H NMR. In both systems, incorporation of SA in DPPC bilayer causes a significant depression in the transition temperature of both the pre-transition (PT) and the gel-to-liquid crystalline (CM) transition. The presence of the drug reduces the cooperativity of both the PT and CM transitions. These findings indicate that SA is bound strongly to the lipid bilayer leading to increased membrane fluidity. The DPPC vesicles incorporated with high drug concentration show phase segregation. One of the interesting findings in this study is the formation of a more ordered high temperature gel (L_β2) phase when the SA-doped DPPC dispersion is prepared at physiological pH. The effect of inclusion of cholesterol in the SA-free and SA-doped DPPC dispersion was also studied.     

FTIR法研究氨基酸稀土配合物与磷脂的相互作用

利用傅里叶变换红外光谱（ＦＴＩＲ）法研究了不同类型氨基酸及其配合物与二棕榈酰磷脂酰胆碱脂质体浇铸膜的相互作用。结果表明，在有氨基酸存在下，二棕榈酰磷脂酰胆碱的红外谱图没有明显的变化；氨基酸稀土配合物与磷脂极性头基团有静电相互作用，作用的程度随稀土离子、氨基酸及稀土同氨基酸配比的不同而有所不同。     

Salt effect on bilayer phase transitions of dipalmitoylphosphatidylglycerol in saline water under high pressure

ABSTRACT

The phase transitions of dipalmitoylphosphatidylglycerol (DPPG) bilayer membrane at high NaCl concentrations under high pressure were investigated to construct the temperature–pressure phase diagram and to determine phase-transition properties. The constructed phase diagrams exhibited qualitative resemblance to that of the dipalmitoylphosphatidylcholine (DPPC) bilayer membrane: they showed the gel-phase polymorphism including the pressure-induced bilayer interdigitation. The phase-transition properties of the DPPG bilayer membrane changed in a salt concentration-dependent manner. We discussed the salt effect on the DPPG bilayer membrane from the variation in interactions between the polar head groups of the PG molecules.     

Does Aliphatic Chain Length Influence Carbocyanines' Orientation in Supported Lipid Multilayers?

UV-Vis linear dichroism was used to study the orientation of 3,3'-dihexyloxacarbocyanine (DiOC6(3)) and 3,3'-dihexadecyloxacarbocyanine (DiOC16(3)) in supported multilayers of dipalmitoylphosphatidylcholine (DPPC) and dilauroylphosphatidylcholine (DLPC). Orientational probability density functions were similar for the two carbocyanines in both lipids. Multimodal distributions were found in all cases. The main peak is at 9 degrees-11 degrees relative to the bilayer normal axis, except for DiOC16(3) in DLPC multilayers (main peaks at 13 degrees and 90 degrees). Quenching studies revealed that the two carbocyanines are localized at the interface region of the membrane regardless of the lipid matrix they are inserted in. Combining these data with linear dichroism results lead to the conclusion that both the aliphatic chain length of carbocyanines and the lipid phase have little influence in the structural organization of these probes in lipidic bilayers. The partition constants of DiOC6 (3), K(p), were determined from fluorescence anisotropy measurements; the values obtained were K(p) (DPPC) = (2.39 +/- 0.05) x 10(3) and K(p) (DLPC) = (5.01 +/- 1.15) x 10(3).     

Influences of the Structure of Lipids on Thermal Stability of Lipid Membranes

The binding free energy (BFE) of lipid to lipid bilayer is a critical factor to determine the thermal or mechanical stability of the bilayer. Although the molecular structure of lipids has significant impacts on BFE of the lipid, there lacks a systematic study on this issue. In this paper we use coarse-grained molecular dynamics simulation to investigate this problem for several typical phospholipids. We find that both the tail length and tail unsaturation can significantly affect the BFE of lipids but in opposite way, namely, BFE decreases linearly with increasing length, but increases linearly with addition of unsaturated bonds. Inspired by the specific structure of cholesterol which is a crucial component of biomembrane, we also find that introduction of carbo-ring-like structures to the lipid tail or to the bilayer may greatly enhance the stability of the bilayer. Our simulation also shows that temperature can influence the bilayer stability and this effect can be significant when the bilayer undergoes phase transition. These results may be helpful to the design of liposome or other self-assembled lipid systems.     

Characterization of the Lipid Binding Pocket in GM2AP and SapB with EPR Spectroscopy

Electron paramagnetic resonance (EPR) spectroscopy of spin-labeled lipids in complex with the sphingolipid activator proteins, GM2AP and SapB, was utilized to characterize the hydrophobic binding pocket of these lipid transfer proteins. Specifically, the EPR line shapes reveal that the mobility of the labeled lipids within the binding pockets of the transfer proteins are more restricted than when in a lipid bilayer environment and that lipids in GM2AP are slightly more restricted than in SapB. EPR accessibility based relaxation measurements show that the relative ratios of oxygen and water accessibility to sites along the acyl chains in lipids in complex with GM2AP are similar to the profiles obtained for a lipid bilayer albeit with lowered values. The results for SapB are quite different, with the oxygen profile mimicking a lipid bilayer, but there is a higher degree of water accessibility to the acyl chains in the SapB complex, likely because of the location of the lipid at the dimer interface in SapB coupled to dynamics of the dimer.     

磷脂微滴囊泡化的介观模拟

发展了一种非显示溶剂的粗粒化三粒子磷脂模型,该模型明确反映磷脂分子的双尾结构．模型分别采用变形的MIE作用势和Harmonic作用势描述分子间非成键和分子内成键相互作用,粗粒化力场参数通过拟合DPPC双分子层的结构和力学性质获得．该粗粒化模型成功重现了磷脂分子从随机初始态到双分子层和从盘状结构到囊泡的形成过程．应用该模型系统研究了球形和柱形磷脂微滴囊泡化的过程,结果表明此模型能有效地模拟介观尺度下复杂磷脂囊泡的形成及演化．     

<Emphasis Type="Italic">In situ</Emphasis> X-ray and neutron diffraction study of lipid membrane swelling

Liposome suspensions comprising the synthetic cationic lipid DOTAP, the zwitterionic DPPC and the anti-cancer agent Paclitaxel were deposited on solid substrates and investigated by X-ray and neutron reflectivity measurements at ESRF and ILL. Well ordered multilamellar drug/lipid membranes were obtained, such as indicated by the several orders of Bragg reflections in the diffraction pattern. With an excess of Paclitaxel, additional Bragg peaks from the drug crystalline phase could be observed. Changes of the molecular organization in the drug-lipid system were investigated as a function of relative humidity using a custom-built controlled humidity chamber. For DOTAP multilayers the effects of bilayer swelling were much more pronounced than for DPPC under similar conditions, while the crystalline peaks of the drug were not affected. The pronounced swelling of DOTAP multilayers might be related to the electrostatic repulsion between the charged lipid headgroups.     

Investigation of the structure of multilayer lipid membranes by real-time neutron diffraction

This paper reports on the results of neutron diffraction experiments on the study of structural changes in multilayer lipid membranes as a function of the degree of hydration. The experiments have been performed on a time-of-flight diffractometer at the IBR-2 pulsed reactor (Joint Institute for Nuclear Research, Dubna, Russia) with a dipalmitoylphosphatidylcholine (DPPC) multilayer membrane oriented on a quartz plate. The structural parameters have been determined from the simultaneously measured several (up to five) diffraction orders of reflection, which has made it possible to calculate the profile of the DPPC bilayer structure. A high rate of the measurement of diffraction patterns has allowed one to trace the evolution the lamellar structure of the lipid bilayer in the course of its hydration and dehydration. The minimum time of accumulation of the necessary statistics is 3 min, which has made it possible to determine the characteristic times of transition processes in the membrane with a high accuracy.     

变温拉曼光谱和DSC探讨人参皂苷Rb1分子与DPPC双层膜的作用

研究人参皂苷分子与生物膜的作用对于深入了解中药人参的药理活性及其生物学功效至关重要。DPPC作为具有双分子层结构的脂质分子,常被许多国内外学者作为模拟膜的模型来研究药物分子与细胞膜的作用;Rb1作为中药人参中的重要皂苷成分,具有显著的药理学功效和生物性能。拉曼光谱是探讨分子间作用的有力工具,差示扫描量热技术（differential scanning calorimetry, DSC）是研究脂双层分子单体及其与药物分子作用的常用技术,而将两者结合研究药物分子对细胞膜作用的研究的报道较少。本文采用变温拉曼光谱和DSC探讨了在温度变化条件下人参皂苷Rb1单体分子与DPPC双层膜的作用。通过拉曼光谱测试,在Rb1作用前后,DPPC分子极性头部O—C—C—N+和C—C伸缩振动区域以及烷基链部分C—H键的伸缩振动区域的变化表明,随着温度的增加,含有一定浓度Rb1的DPPC磷脂极性头部旁氏构象没有发生变化,脂酰链的无序性构象增多,侧向排列的无序性增强,DPPC脂双层的流动性增加。由DSC实验得到的几个热力学常数[相变温度（T_m）、半峰宽（ΔT_1/2）及相转变焓值（ΔH）]的变化表明,DSC进一步验证了变温拉曼实验结果,随着Rb1浓度的增大,DPPC双层膜的相变温度显著下降,流动性增强,说明Rb1对DPPC双层膜的影响较大。     

2H NMR and polyelectrolyte-induced domains in lipid bilayers

2H NMR studies of polyelectrolyte-induced domain formation in lipid bilayer membranes are reviewed. The 2H NMR spectrum of choline-deuterated phosphatidylcholine (PC) reports on any and all sources of lipid bilayer surface charge, since these produce a conformation change in the choline head group of PC, manifest as a change in the 2H NMR quadrupolar splitting. In addition, homogeneous and inhomogeneous surface charge distributions are differentiated. Adding polyelectrolytes to lipid bilayers consisting of mixtures of oppositely charged and zwitterionic lipids produces 2H NMR spectra which are superpositions of two Pake sub-spectra: one corresponding to a polyelectrolyte-bound lipid population and the other to a polyelectrolyte-free lipid population. Quantitative analysis of the quadrupolar splittings and spectral intensities of the two sub-spectra indicate that the polyelectrolyte-bound populations is enriched with oppositely charged lipid, while the polyelectrolyte-free lipid population is correspondingly depleted. The same domain-segregation effect is produced whether cationic polyelectrolytes are added to anionic lipid bilayers or anionic polyelectrolytes are added to cationic lipid bilayers. The 2H NMR spectra permit a complete characterization of domain composition and size. The anion:cation ratio within the domains is always stoichiometric, as expected for a process driven by Coulombic interactions. The zwitterionic lipid content of the domains is always statistical, reflecting the systems tendency to minimize the entropic cost of demixing charged lipids into domains. Domain formation is observed even with rather short polyelectrolytes, suggesting that individual polyelectrolyte chains aggregate at the surface to form "superdomains". Overall, the polyelectrolyte bound at the lipid bilayer surface appears to lie flat along the surface and to be essentially immobilized through its multiple electrostatic contacts.     

Diffusion in supported lipid bilayers: Influence of substrate and preparation technique on the internal dynamics

The diffusion law of DMPC and DPPC in Supported Lipid Bilayers (SLB), on different substrates, has been investigated in details by Fluorescence Recovery After Patterned Photobleaching (FRAPP). Over micrometer length scales, we demonstrate the validity of a purely Brownian diffusive law both in the gel and the fluid phases of the lipids. Measuring the diffusion coefficient as a function of temperature, we characterize the gel-to-liquid phase transition of DMPC and DPPC. It is shown that, depending on the type of substrate and the method used for bilayer preparation, completely different behaviours can be observed. On glass substrates, using the Langmuir-Blodgett deposition technique, both leaflets of the bilayer have the same dynamics. On mica, the dynamics of the proximal leaflet is slower than the dynamics of the distal leaflet, although the transition temperature is the same for both layers. Preparing bilayers from vesicle fusion in same conditions leads to more random behaviours and shifted transition temperatures.     

Methods for studying transmembrane peptides in bicelles: consequences of hydrophobic mismatch and peptide sequence

We have shown that bicelles prepared from dilauryl phosphatidylcholine (DLPC) and dipalmitoyl phosphatidylcholine (DPPC) align in a magnetic field under conditions similar to the more common dimyristoyl phosphatidylcholine (DMPC) bicelles. In addition, a model transmembrane peptide, P16, with a hydrophobic stretch of 24 A, and specific alanine-d(3) labels, was incorporated into all of the different bicelles. The long-chain phospholipid (DLPC, DMPC, or DPPC) remained unperturbed upon incorporation of the peptide while the quadrupolar splitting of the short-chain phospholipid along the bicelle rim increased by varying degrees in the different bicelle systems. The change in quadrupolar splitting of the short-chain phospholipids was attributed to changes in either fluidity of the planar region of the bicelle or differences in overall lipid packing. When the hydrophobic stretch of the bilayer was 22.8 (DMPC) or 26.3 A (DPPC), the peptide tilt was found to be transmembrane (33-35 degrees with respect to the bicelle normal). When the hydrophobic stretch of the bilayer was 19.5 A (DLPC), the peptide quadrupolar splittings suggested a loss of transmembrane orientation. When tryptophan was incorporated in the middle of the transmembrane region, the transmembrane orientation was also lost.