磷脂跨膜交换机制的研究

膜间磷脂交换是一项重要的生理活动, 其对药物运输及膜功能研究有重要意义. 本文用石英晶体微天平及耗散系数测试仪研究囊泡与囊泡、囊泡与支撑膜间磷脂交换行为, 荧光光谱仪用来测量膜表面电性与膜组分对磷脂交换的影响. 实验结果表明: 磷脂跨膜交换速率与交换时间成反比, 膜表面异电性磷脂的增加会加速膜内相互作用和磷脂跨膜交换速率, 以及改变膜表面组分会对囊泡与支撑膜间的磷脂交换产生影响. 本文研究有助于加深理解磷脂跨膜交换机制, 并对药学研究提供参考.     

磷脂跨膜交换机制的研究

膜间磷脂交换是一项重要的生理活动,其对药物运输及膜功能研究有重要意义.本文用石英晶体微天平及耗散系数测试仪研究囊泡与囊泡、囊泡与支撑膜间磷脂交换行为,荧光光谱仪用来测量膜表面电性与膜组分对磷脂交换的影响.实验结果表明:磷脂跨膜交换速率与交换时间成反比,膜表面异电性磷脂的增加会加速膜内相互作用和磷脂跨膜交换速率,以及改变膜表面组分会对囊泡与支撑膜间的磷脂交换产生影响.本文研究有助于加深理解磷脂跨膜交换机制,并对药学研究提供参考.     

多聚赖氨酸诱导的负电性磷脂巨囊泡形变

利用荧光显微技术表征了多聚赖氨酸诱导的负电性磷脂巨囊泡的动力学响应行为.研究发现,多聚赖氨酸可吸附至二油酰磷脂酰胆碱和二油酰磷脂酸混合磷脂巨囊泡的表面,诱导其发生粘连、出"绳"及破裂现象.分析认为,在低盐环境中,膜形变由多聚赖氨酸吸附于二油酰磷脂酸富集区引起的膜两叶应力不对称,以及静电相互作用等因素产生.研究结果对基于聚合物-巨囊泡体系的药物输运控释、细胞形变、微控反应和基因治疗等方面的研究提供有价值的支持.     

磷脂囊泡在胺端基和羧端基修饰金表面的沉积

磷脂囊泡与阴,阳离子性表面作用的深入理解对磷脂的生物纳米科技应用具有重要意义.通过石英电子微天平及耗散系数测量仪,研究了不同离子性磷脂囊泡在胺端基和羧端基修饰Au衬底的沉积行为.实验观察到四条囊泡沉积路径:(ⅰ)吸附至临界值后破裂成膜;(ⅱ)吸附即破裂成膜;(ⅲ)吸附不破裂;(ⅳ)不吸附.沉积路径由囊泡与衬底的双电层相互作用决定,离子可发挥调节作用.     

磷脂囊泡在胺端基和羧端基修饰金表面的沉积

磷脂囊泡与阴, 阳离子性表面作用的深入理解对磷脂的生物纳米科技应用具有重要意义. 通过石英电子微天平及耗散系数测量仪, 研究了不同离子性磷脂囊泡在胺端基和羧端基修饰Au衬底的沉积行为. 实验观察到四条囊泡沉积路径: (ⅰ)吸附至临界值后破裂成膜; (ⅱ)吸附即破裂成膜; (ⅲ)吸附不破裂; (ⅳ)不吸附. 沉积路径由囊泡与衬底的双电层相互作用决定, 离子可发挥调节作用.     

蜂毒肽浓度和磷脂组分对巨囊泡泄露的影响

蜂毒肽作为一种广谱抗菌肽已经得到广泛认知,用蜂毒肽构建载药体系攻击癌细胞研究正在兴起.基于仿生物膜模型探索其破坏机理,可以避免潜在活性细胞过程的影响.在此,我们选用细胞尺寸的单层巨囊泡膜模型,可在光学显微镜下直接观察和操作,获得仿正常细胞膜和仿癌细胞膜在不同蜂毒肽浓度刺激下的响应.研究得出,低浓度蜂毒肽诱导囊泡泄露实验表明中性磷脂囊泡以孔模式为主泄露,负电性磷脂囊泡以爆裂模式为主泄露;高浓度蜂毒肽诱导囊泡泄露实验表明负电性磷脂相较于中性磷脂可延迟蜂毒肽作用效果;蜂毒肽色氨酸残基荧光光谱表明囊泡膜表面蜂毒肽吸附量以及泄露模式依赖于磷脂组分.此外,推断了蜂毒肽对不同组分磷脂膜的破坏作用模型.研究为蜂毒肽在肿瘤细胞的作用机制及其衍生物的优化设计提供参考.     

蜂毒肽浓度和磷脂组分对巨囊泡泄露的影响

蜂毒肽作为一种广谱抗菌肽已经得到广泛认知,用蜂毒肽构建载药体系攻击癌细胞研究正在兴起.基于仿生物膜模型探索其破坏机理,可以避免潜在活性细胞过程的影响.在此,我们选用细胞尺寸的单层巨囊泡膜模型,可在光学显微镜下直接观察和操作,获得仿正常细胞膜和仿癌细胞膜在不同蜂毒肽浓度刺激下的响应.研究得出,低浓度蜂毒肽诱导囊泡泄露实验表明中性磷脂囊泡以孔模式为主泄露,负电性磷脂囊泡以爆裂模式为主泄露;高浓度蜂毒肽诱导囊泡泄露实验表明负电性磷脂相较于中性磷脂可延迟蜂毒肽作用效果;蜂毒肽色氨酸残基荧光光谱表明囊泡膜表面蜂毒肽吸附量以及泄露模式依赖于磷脂组分.此外,推断了蜂毒肽对不同组分磷脂膜的破坏作用模型.研究为蜂毒肽在肿瘤细胞的作用机制及其衍生物的优化设计提供参考.     

荧光显微镜研究极端pH值诱导磷脂支撑膜的侧向再组织

利用荧光显微镜研究了极端pH值诱导支撑磷脂双层膜的侧向再组织.结果表明,在强酸/强碱性溶液中,流动性较好的二油酰磷脂酰胆碱支撑膜出现破裂、分离、出芽或生出微管等与细胞内吞和外排相似的现象.基于极性分子与H+/H3O+或OH-的相互作用,以电中性的磷脂首基为核吸附溶液中的H+/H3O+或OH-.当磷脂膜上下叶吸附的电荷量不同时,引起两叶有效面积差,即磷脂膜曲率不对称,从而诱发磷脂膜出现各种结构和动力学的响应.本研究有助于理解极端环境对生物膜的影响,为研究生物膜的形变过程提供了参考.     

跨膜浓度梯度对渗透压囊泡循环活性的调控

本文通过分析囊泡在膨胀状态与孔隙状态的动力学行为,揭示调控膨胀拉伸能与孔隙势能的内在物理参量.建立递推微分方程的分析模型,该模型提供了膨胀-破裂循环特征量膨胀系数在各个循环中初始跨膜浓度梯度依赖性的定量信息.研究得出,通过增加初始跨膜浓度梯度,可加快膨胀系数增长速率(循环数为1时,初始跨膜浓度梯度增加3倍,膨胀系数增长速率增加2.65倍);随着循环数的增多,膨胀系数的增长由线性转变为非线性.此外,初始跨膜浓度梯度与循环次数密切相关,我们的模型计算预测增加初始跨膜浓度梯度可实现循环次数的增多.研究结果为靶组织以可编程方式释放活性生物治疗剂的发展提供了具有实际意义的理论依据.     

蜂毒肽与多组分生物膜作用：电性与相态的影响

蜂毒肽非特异性地靶向杀伤细菌具有重要的生物医学应用前景. 利用荧光光谱与荧光显微考察了蜂毒肽与单组分、多组分磷脂膜的作用机制. 发现对于不同电性与相态的磷脂膜, 肽-膜作用呈现为稳定桶板型孔、非稳U型孔及变薄裂解等多种机制, 具有显著不同的内含物泄露效率. 多组分磷脂囊泡的泄露实验表明, 泄露由肽亲和性较强的磷脂组分决定. 相较于凝胶相磷脂, 蜂毒肽与液相磷脂的亲和性强, 凝胶-液相混合囊泡与纯液相磷脂囊泡的泄露性质相近; 相较于双电性磷脂, 蜂毒肽与负电性磷脂的亲和性强, 双电-负电混合囊泡与纯负电磷脂囊泡的泄露性质相近. 研究深化了多肽与多组分生物膜作用机制的理解.     

Pathway of membrane fusion with two tension-dependent energy barriers

Fusion of bilayer membranes is studied via dissipative particle dynamics (DPD) simulations. A new set of DPD parameters is introduced which leads to an energy barrier for flips of lipid molecules between adhering membranes. A large number of fusion events is monitored for a vesicle in contact with a planar membrane. Several time scales of the fusion process are found to depend exponentially on the membrane tension. This implies an energy barrier of about 10k(B)T for intermembrane flips and a second size-dependent barrier for the nucleation of a small hemifused membrane patch.     

Molecular dynamics simulation of interaction between nanorod and phospholipid molecules bilayer

Natural and artificially prepared nanorods' surfaces have proved to have good bactericidal effect and self-cleaning property. In order to investigate whether nanorods can kill the enveloped virus, like destroying bacterial cell, we study the interaction between nanorods and virus envelope by establishing the models of nanorods with different sizes as well as the planar membrane and vesicle under the Dry Martini force field of molecular dynamics simulation. The results show that owing to the van der Waals attraction between nanorods and the tail hydrocarbon chain groups of phospholipid molecules, the phospholipid molecules on virus envelope are adsorbed to nanorods on a large scale. This process will increase the surface tension of lipid membrane and reduce the order of lipid molecules, resulting in irreparable damage to planar lipid membrane. Nanorods with different diameters have different effects on vesicle envelope, the larger the diameter of nanorod, the weaker the van der Waals effect on the unit cross-sectional area is and the smaller the degree of vesicle deformation. There is synergy between the nanorods in the nanorod array, which can enhance the speed and scale of lipid adsorption. The vesicle adsorbed in the array are difficult to desorb, and even if desorbed, vesicle will be seriously damaged. The deformation rate of the vesicle adsorbed in the nanorod array exceeds 100%, implying that the nanorod array has a strong destructive effect on the vesicle. This preliminarily proves the feasibility of nanorod array on a surface against enveloped virus, and provides a reference for the design of corresponding nanorods surface.     

Adhesion of fluid vesicles at chemically structured substrates

The adhesion of fluid vesicles at chemically structured substrates is studied theoretically via Monte Carlo simulations. The substrate surface is planar and repels the vesicle membrane apart from a single surface domain γ , which strongly attracts this membrane. If the vesicle is larger than the attractive γ domain, the spreading of the vesicle onto the substrate is restricted by the size of this surface domain. Once the contact line of the adhering vesicle has reached the boundaries of the γ domain, further deflation of the vesicle leads to a regime of low membrane tension with pronounced shape fluctuations, which are now governed by the bending rigidity. For a circular γ domain and a small bending rigidity, the membrane oscillates strongly around an average spherical cap shape. If such a vesicle is deflated, the contact area increases or decreases with increasing osmotic pressure, depending on the relative size of the vesicle and the circular γ domain. The lateral localization of the vesicle's center of mass by such a domain is optimal for a certain domain radius, which is found to be rather independent of adhesion strength and bending rigidity. For vesicles adhering to stripe-shaped surface domains, the width of the contact area perpendicular to the stripe varies nonmonotonically with the adhesion strength.     

Removal of aliphatic amino acids by hybrid organic-inorganic layered compounds

Amino acids have been extensively used in several processes of the pharmaceutical and food industries. Treatments for the recovery and reuse of the wastewaters generated from these processes are few and little known. This work aims at studying the influence of variables like temperature, pH and ionic strength on the adsorption of the amino acids Asp and Glu, contained in aqueous solutions, on layered double hydroxides of the Mg-Al-CO₃-LDH system. The adsorption experiments were performed at two different temperatures (298 and 310 K), two different pH values (7.0 and 10.0), and two ionic strength conditions (with or without the addition of NaCl). The adsorption isotherms exhibited similar profiles under the various conditions studied: an increase in temperature as well as an increase in the pH value decreased the amount of adsorbed amino acid while an increase in the ionic strength increased Asp and Glu adsorption. The PXRD analysis showed that the diffractograms obtained before and after the adsorption of amino acids have a similar pattern. The FT-IR spectra of the adsorbed material presented specific bands, which are related to the amino acids. The concentration range varied up to the anion solubility product and the extraction rate lay between 2.7 and 23.4% at higher equilibrium concentrations, showing that Mg-Al-CO₃-LDH is efficient at removing the amino acids from the aqueous medium.     

Curvature-dependent elastic properties of liquid-ordered domains result in inverted domain sorting on uniaxially compressed vesicles

Using a coarse-grained molecular model we study the spatial distribution of lipid domains on a 20-nm-sized vesicle. The lipid mixture laterally phase separates into a raftlike, liquid-ordered (l(o)) phase and a liquid-disordered phase. As we uniaxially compress the mixed vesicle keeping the enclosed volume constant, we impart tension onto the membrane. The vesicle adopts a barrel shape, which is composed of two flat contact zones and a curved edge. The l(o) domain, which exhibits a higher bending rigidity, segregates to the highly curved edge. This inverted domain sorting switches to normal domain sorting, where the l(o) domain prefers the flat contact zone, when we release the contents of the vesicle. We rationalize this domain sorting by a pronounced reduction of the bending rigidity and area compressibility of the l(o) phase upon bending.     

纳米氧化铁对铀(Ⅵ)吸附性能的研究

用可见分光光度法研究了新型吸附剂纳米氧化铁对水中铀的静态吸附行为,考察了溶液pH值、吸附时间、离子强度和铀初始浓度等对吸附率的影响.结果表明,溶液pH对吸附率的影响较明显,在pH为6时,吸附率达最大,吸附5min后达到吸附平衡,且吸附率达95%以上;随铀酰离子浓度的增加,吸附率呈下降趋势,而吸附容量逐渐上升;铀在纳米氧...     

Gelatinization kinetic of waxy starches under pressure according to ionic strength

High pressure is a potential technology for the texturization of food products at ambient temperature. In this area, waxy starches are particularly interesting because they gelatinize quickly under sufficient pressure. However, gelatinization may be influenced by other components in the food matrix. Here, we investigate the influence of increasing ionic strength on gelatinization rate and kinetics at 500 MPa for waxy corn and waxy rice starches. We show that increasing ionic strength strongly retards and inhibits starch gelatinization under pressure and leads to heterogeneous gels with remnant granules.     

Interaction of polyelectrolyte coated beads with phospholipid vesicles

Colloidal particles coated by polyelectrolyte multilayers of alternatingly positive and negative charge are shown to interact strongly with lipid vesicles. We have studied two cases: (i) the interaction between beads and small unilamellar vesicles (vesicles diameter smaller than the particles one), where we found evidence for coating of the beads with lipid bi- or multilayers in the form of an increase in bead diameter and changes in the beads surface potential; (ii) the interaction of beads with giant vesicles (vesicles larger than the particles), where we observed by fluorescence microscopy the spreading of the vesicle on the bead manipulated with an optical tweezer. Giant fluctuations of the vesicles are suppressed due to the adhesion of the vesicle to the bead and direct observation of the coating process shows that lipid coverage is not limited to the direct vesicle-bead contact area, but is rather extended to the entire bead. To cite this article: A. Fery et al., C. R. Physique 4 (2003).     

Isotope exchange study of the dissociation of metal —humic substance complexes

Isotope exchange was employed to study dissociation of metal cations from their complexes with humic substances (HS). Dissociation of cation from HS controls the rate of isotope exchange between two identical metal-HS solutions (but for the presence of a radiotracer) divided by a dialysis membrane. The rate of isotope exchange of Eu/¹⁵²Eu and Co/⁶⁰Co in the systems with various HS was monitored as a function of pH, ionic strength, and the degree of HS loading with metal. The apparent rate of Eu-HS dissociation was found to be enhanced by decreasing pH, increasing ionic strength, and increasing metal loading. Co-HS dissociation was too fast to be followed by the method. For interpretation of the experimental kinetic data, the multiple first order law has been applied. Based on the results, a concept of HS as a mixture of two types of binding sites is discussed.