亲和素蛋白与含有生物素的支撑平面膜之间相互作用的研究

生物功能分子的二维有序化组装是分子工程学的重要内容,本文通过构建有生物素受体的人工模型膜,对亲和素与生物这一具有极强亲和力的系统之间的特异性相互作用的某些制约因素进行了探讨,应用ＬＢ膜技术结合激光椭圆偏振术和表面等离激元谱技术,较深入地研究了蛋白质与脂单层膜发发的非特异性吸附,特异性结合以及结合的侧向空间位阻效应,实验结果表明,膜表面电荷对非特异性吸附的速率有很大的影响,而对最终的蛋白质附量影响不     

脂质体相行为对亲和素与膜表面模型受体特异性结合的影响

脂质体相行为对亲和素与膜表面模型受体特异性结合的影响刘铮,文辰晖,隋森芳（清华大学生物科学与技术系,北京１０００８４）关键词脂质体;抗生物素蛋白;荧光滴定生物体内的细胞是由一层磷脂双分子层的细胞膜包被的,细胞膜上有许多不同种类的受体,在细胞膜所执行的...     

病毒受体的研究方法

1概况 病毒受体可以定义为位于宿主细胞表面能够被病毒吸附蛋白识别并与之结合,从而引起病毒感染的分子复合物,其化学本质是糖蛋白、蛋白聚糖、脂类或糖脂,大多数属于蛋白质.病毒受体可以是单体也可以是多分子复合物,具有特异性、高亲和性、饱和性、结合位点及靶细胞部位的有限性以及独特的生物学活性等[1].病毒受体是公认的引发病毒感染宿主细胞的主要决定因素,也是影响病毒宿主特异性和组织亲嗜性的决定因素之一.     

雌激素受体介导的快速信号通路的研究进展

除了经典的基因组效应以外,雌激素还可以通过细胞内信号转导途径在几分钟甚至是几秒钟内产生快速生物学效应,被称为雌激素的非基因组效应.这种雌激素的非基因组效应与基因组效应一样,也存在着组织、细胞的特异性.本文将对雌激素膜受体存在的依据、以膜ER为核心的多分子复合物的特性及其介导的信号通路以及雌激素快速生物学效应的组织/细胞特异性作一综述.     

人胃癌细胞在丁酸钠的诱导下膜分子运动与膜相关骨架的关系

体外培养的人胃癌细胞,用丁酸钠处理后,显示细胞表面FN及细胞胞质微丝的变化,同时用荧光漂白恢复方法对细胞膜ConA受体复合物侧向扩散运动进行测定。结果表明,经丁酸钠处理后的细胞,胞质微丝及细胞膜表面FN均较对照组增加,而细胞膜分子侧向扩散运动减慢,说明与细胞膜相连的细胞骨架的变化对膜分子侧位运动具有牵制作用。     

血红蛋白对人红细胞膜脂质分子侧向运动的影响

用荧光漂白恢复法测定了血红蛋白对红细胞膜脂质分子侧向扩散的限制作用.血红蛋白主要是通过和内侧膜脂质的结合而产生影响的,pH6及PH7.7时都显示出效应的存在.和膜结合较强的高铁血红蛋白,表现出对膜脂质侧向扩散亦有较大的限制作用.     

淋巴细胞膜脂质对膜蛋白结构与功能的影响

淋巴细胞膜质组成及膜生物物理特性的变化显影响质膜上某些蛋白的结构与功能,膜脂质与膜蛋白的相互作用涉及两所带电荷性质,蛋白质疏水氨基酸等,同时也与两种分子空间位阻,水化作用有关。     

小鼠天然可溶性VEGF受体基因sflt-1的克隆及鉴定

 可溶性血管内皮细胞生长因子受体 (sFlt 1 )与膜表面受体Flt 1竞争结合血管内皮细胞生长因子 (VEGF) ,并且与膜表面受体Flt 1及KDR形成异源二聚体 .完全阻断VEGF的生物学活性 ,除与sFlt 1的结合部位结构域有关外 ,还与整个蛋白质分子的高效分泌表达有关 .而蛋白质分子的高效分泌表达与蛋白质在细胞内高尔基体及内质网的加工密切相关 ,基因工程重组可溶性受体由于一些尚未明了的原因 ,往往不能高效表达 ,从而大大影响了其应用价值 .利用RT PCR技术从胚胎小鼠中扩增出天然可溶性VEGF受体基因sflt 1 ,克隆于pcDNA3载体中 ,在COS 7细胞中短暂表达 ;并克隆至pET42b载体中 ,经IPTG诱导后 ,可大量稳定表达与His Tag形成的融合蛋白 ,经HisNi柱纯化 ,可特异性结合VEGF .可溶性受体sFlt 1在肿瘤组织的高效表达可有效阻断新生血管的形成 ,从而为肿瘤的治疗探索一种方法 .     

病毒受体的研究方法

1概况病毒受体可以定义为位于宿主细胞表面能够被病毒吸附蛋白识别并与之结合,从而引起病毒感染的分子复合物,其化学本质是糖蛋白、蛋白聚糖、脂类或糖脂,大多数属于蛋白质。病毒受体可以是单体也可以是多分子复合物,具有特异性、高亲和性、饱和性、结合位点及靶细胞部位的有限性以及独特的生物学活性等[1]。病毒受体是公认的引发病毒感染宿主细胞的主要决定因素,也是影响病毒宿主特异性和组织亲嗜性的决定因素之一。研究病毒受体的特性及其功能对于从分子水平阐明病毒感染与免疫的机制,深刻理解病毒与宿主细胞的相互关系,研制更有效的病毒…     

分子识别诱导的蛋白质和核酸多层膜的有序组装

通过生物大分子之间的特异性结合,采用表面等离激元共振技术监测,报导了支撑于固体表面脂单层膜上进行的亲和素、生物素标记的质粒ＤＮＡ、以及从系统性红斑狼疮患者血清中获得的抗ＤＮＡ抗体多层膜的有序组装。这种生物大分子的组装技术可以用于生物传感器以检测特定的抗原抗体。     

Specific binding of avidin to biotin containing lipid lamella surfaces studied with monolayers and liposomes

The interaction of avidin (from egg white) with phospholipid (monolayer and bilayer) model membranes containing biotin-conjugated phospholipids has been studied. In the first part, using surface sensitive techniques (ellipsometry and surface plasmon resonance) we demonstrated that the nonspecific adsorption of avidin to phospholipid lamella could be abolished by adding an amount of Ca²⁺, Mg²⁺, or Ba²⁺ that led to an electrostatic interaction. The specific binding of avidin to lipid mixtures containing biotin-conjugated phospholipids was obviously composition dependent. The ratio 1:12 of a B-DPPE/DPPE mixture was found to be the optimum molar ratio. When we compared the results from the surface sensitive techniques with those from the electron micrographs of a two dimensional crystal of avidin (obtained in our laboratory), the optimum ratio was found to be determined by the effect of lateral steric hindrance. In the second part, we observed the pattern of the layers of fluorescently labeled phospholipid and adsorbed proteins with a home-made micro fluorescence film balance. The fluorescence images showed that avidin was preferentially bound to the receptors that were in the fluid domains. Further, with a sensitive fluoresence assay method, the effect of the phase behavior of liposomes on the specific binding of avidin was measured. This showed that avidin interacted with biotin-lipid more weakly in the gel state liposome than in the liquid state liposome. The major conclusion was that the binding of avidin to a membrane bound model receptor was significantly restricted by two factors: one was the lateral steric hindrance and the other was the fluidity of the model membrane.Abbreviations B-DPPE Biotinyl dipalmitoylphosphatidyl ethanolamine - B-DMPE Biotinyl dimyristoylphosphatidyl ethanolamine - BNHS d-biotin-N-hydroxysuccinimide ester - DMPA dimyristoylphosphatidyl acid - DMPC dimyristoylphosphatidyl choline - DMPS dimyristoylphosphatidyl serine - DOPC dioleoylphosphatidyl choline - DPPC dipalmitoylphosphatidyl choline - DPPE dipalmitoylphosphatidyl ethanolamine - FITC fluorescein isothiocyanate - RDB-DOPE N(Lissamine rhodamine B sulfonyl) dioleoyl phosphatidylethanolamine - SPR surface plasmon resonance Correspondence to: S. F. Sui     

Analysis of membrane binding equilibria of peripheral proteins: Allowance for excluded area of bound protein

When peripheral proteins bind to phospholipid membranes lacking discrete binding sites, steric repulsion between bound protein molecules may result in a reduction of the surface area available to additional bound protein by an amount significantly greater than the actual area occupied by bound protein. An approximate treatment of this effect demonstrates that neglect of area exclusion by bound protein may lead to significant errors in the evaluation of equilibrium association constants and the fractional coverage of membrane surface area.     

Interactions between lipid-anchored and transmembrane proteins. Spin-label ESR studies on avidin-biotinyl phosphatidylethanolamine in membrane recombinants with myelin proteolipid proteins

Interactions between lipid-anchored and transmembrane proteins are relevant to the intracellular membrane sorting of glycosyl phosphatidylinositol-linked proteins. We have studied the interaction of a spin-labeled biotinyl diacyl phospholipid, with and without specifically bound avidin, with the myelin proteolipid protein (or the DM-20 isoform) reconstituted in dimyristoylphosphatidylcholine. Tetrameric avidin bound to the N-biotinyl lipid headgroup is a surface-anchored protein, and the myelin proteolipid is an integral protein containing four transmembrane helices. The electron spin resonance (ESR) spectrum of N-biotinyl phosphatidylethanolamine spin-labeled at the C-14 position of the sn-2 chain consists of two components in fluid-phase membranes of dimyristoylphosphatidylcholine containing the proteolipid. In the absence of avidin, this is characteristic of lipid-protein interactions with integral transmembrane proteins. The more motionally restricted component represents the lipid population in direct contact with the intramembranous surface of the integral protein, and the more mobile component corresponds to the bulk fluid lipid environment of the bilayer. In the presence of avidin, the biotin-lipid chains have reduced mobility because of the binding to avidin, even in the absence of the proteolipid [Swamy, M. J., and Marsh, D. (1997) Biochemistry 36, 7403-7407]. In the presence of the proteolipid, the major fraction of the avidin-anchored chains is further restricted in its mobility by interaction with the transmembrane protein. At a biotin-lipid concentration of 1 mol %, approximately 80% of the avidin-linked chains are restricted in membranes with a phosphatidylcholine:proteolipid molar ratio of 37:1. This relatively high stoichiometry of interaction can be explained when allowance is made for the closest interaction distance between the lipid-anchored avidin tetramer and the transmembrane proteolipid hexamer, without any specific interaction between the two types of membrane-associated proteins. The interaction is essentially one of steric exclusion, but the lipid chains are rendered more sensitive to interaction with the integral protein by being linked to avidin, even though they are removed from the immediate intramembrane protein-lipid interface. This could have implications for the tendency of lipid-anchored chains to associate with membrane domains with reduced lipid mobility.     

Avidin-biotin interactions at vesicle surfaces: adsorption and binding, cross-bridge formation, and lateral interactions.

Densely packed domains of membrane proteins are important structures in cellular processes that involve ligand-receptor binding, receptor-mediated adhesion, and macromolecule aggregation. We have used the biotin-avidin interaction at lipid vesicle surfaces to mimic these processes, including the influence of a surface grafted polymer, polyethyleneglycol (PEG). Single vesicles were manipulated by micropipette in solutions of fluorescently labeled avidin to measure the rate and give an estimate of the amount of avidin binding to a biotinylated vesicle as a function of surface biotin concentration and surface-grafted PEG as PEG-lipid. The rate of avidin adsorption was found to be four times less with 2 mol% PEG750 than for the unmodified surface, and 10 mol% PEG completely inhibited binding of avidin to biotin for a 2-min incubation. Using two micropipettes, an avidin-coated vesicle was presented to a biotinylated vesicle. In this vesicle-vesicle adhesion test, the accumulation of avidin in the contact zone was observed, again by using fluorescent avidin. More importantly, by controlling the vesicle membrane tension, this adhesion test provided a direct measure of the spreading pressure of the biotin-avidin-biotin cross-bridges confined in the contact zone. Assuming ideality, this spreading pressure gives the concentration of avidin cross-bridges in the contact zone. The rate of cross-bridge accumulation was consistent with the diffusion of the lipid-linked "receptors" into the contact zone. Once adherent, the membranes failed in tension before they could be peeled apart. PEG750 did not influence the mechanical equilibrium because it was not compressed in the contact zone, but it did perform an important function by eliminating all nonspecific adhesion. This vesicle-vesicle adhesion experiment, with a lower tension limit of 0.01 dyn/cm, now provides a new and useful method with which to measure the spreading pressures and therefore colligative properties of a range of membrane-bound macromolecules.     

Association of protein kinase C with phospholipid vesicles

The Ca2+- and phospholipid-dependent protein kinase, protein kinase C (PKC), was purified from bovine brain by a modified procedure that provided sufficient quantities of stable protein for analysis of physical properties of protein-membrane binding. The binding of PKC to phospholipid vesicles of various compositions was investigated by light-scattering and fluorescence energy transfer measurements. The binding properties for membranes of low phosphatidylserine (PS) content were consistent with a peripheral membrane association; PKC showed Ca2+ -dependent binding to phospholipid vesicles containing phosphatidylserine, phosphatidylinositol, or phosphatidylglycerol. Membranes containing 0-20% PS (the remainder of the phospholipid was phosphatidylcholine) bound less protein than membranes containing greater than 20% PS; the factor limiting protein binding to membranes containing low PS appeared to be the availability of acidic phospholipids. Increasing the PS content above 20% did not increase the amount of membrane-bound protein at saturation, and the limiting factor was probably steric packing of protein on the membrane surface. The membranes bound about 1 g of protein/g of phospholipid at steric saturation. Binding was of relatively high affinity (Kd less than 5 nM), and the association rate was rapid on the time scale of the experiments. Addition of ethylene glycol bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid to phospholipid-bound PKC caused dissociation of the complex, and the properties of this dissociation indicated an equilibrium binding of protein to membrane. However, only partial dissociation of PKC was achieved when the PS content of the vesicles exceeded 20%. A number of comparisons revealed that binding of protein to the membrane, even in the presence of phorbol esters, was insufficient for development of enzyme activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Aggregation of ligand-modified liposomes by specific interactions with proteins. II: Biotinylated liposomes and antibiotin antibody

The aggregation of biotinylated phospholipid vesicles (liposomes) cross-linked by antibiotin IgG was studied experimentally and theoretically. The liposomes were either low density liposomes that contained 0.4 mol% biotinylated phospholipid ( approximately 100 exposed biotin molecules per liposome), or high density liposomes that contained 2.7 mol% biotinylated phospholipid ( approximately 1000 exposed biotin molecules per liposome). The solution turbidity and mean particle size measured by quasi-elastic light scattering (QLS) were monitored throughout the aggregation. Three different lots of antibiotin antibodies, each with different association constants and binding heterogeneities, were used. The antibody binding characteristics affected the aggregation rates. The aggregation kinetics were analyzed using a model based on the Smoluchowski theory of aggregation, fractal concepts of aggregate microstructure, and Rayleigh and Mie light scattering theory. The experimental conditions of liposome concentration, protein concentration, and ligand density under which aggregation occurred correlated well with calculated sticking probabilities based on isotherms describing the adsorption of antibiotin antibody to the liposomes. These results are compared with prior observations made when avidin was used as the cross-linking protein. (c) 1996 John Wiley & Sons, Inc.     

The use of the 2-iminobiotin-avidin interaction for the selective retrieval of labeled plasma membrane components

A general method for the selective retrieval of surface labeled plasma membrane components had been devised. The basis of the technique is the covalent attachment of compounds containing 2-iminobiotin, the cyclic guanidino analog of biotin, onto the cell surface proteins and the use of immobilized avidin to recover the labeled components uncontaminated by other cytosolic and membrane components. The pH-dependent interaction of 2-iminobiotin with avidin makes recovery possible. At high pH the free base form of 2-iminobiotin retains the high affinity specific binding to avidin characteristic of biotin, whereas at acidic pH values, the salt form of the analog interacts poorly with avidin. Model studies on the interaction of 2-iminobiotinylated proteins with avidin-Sepharose 4B show that for tight binding to the affinity matrix, the pH of the column must be 9.5 or higher, that a single 2-iminobiotin group is sufficient for binding, and that proteins with different extents of labeling behave similarly when the low pH buffer is applied. When intact human erythrocytes were sequentially labeled with periodate and 2-iminobiotin hydrazide and the Triton X-100-solubilized plasma membrane proteins were subjected to affinity isolation, the major sialoglycoproteins, periodic acid-Schiff (PAS) 1, PAS 2, and PAS 3, plus two proteins with apparent molecular weights higher than band 3 were retrieved. The recovery of these proteins is not due to a nonspecific adsorption to the affinity matrix.