Effect of ionic strength on the membrane fluidity of rabbit intestinal brush-border membranes. A fluorescence probe study

The effect of ionic strength on the fluidity of rabbit intestinal brush-border membranes has been studied using two fluorescence probes, pyrene and 1-anilino-8-naphthalene sulfonate (ANS). The imposition of a potential gradient on the pyrene-probed membrane vesicles (out greater than in) with increasing NaCl concentration in the medium resulted in a marked enhancement of the excimer formation efficiency, accompanied by a decrease in the ratio of fluorescence intensities of the probe at 392 and 375 nm. Fluorescence polarization of the pyrene-membrane complex is independent of temperature in the absence of salts, while it is dependent on temperature from 10 to 47 degrees C in the presence of salts, as shown by the thermal Perrin plots of polarization. It has been demonstrated that there is a linear relationship between the changes in the pyrene excimer formation efficiency in the membranes and of the values of the binding parameters of ANS for the membranes. From these results, it is suggested that the lipid phase of the membranes becomes more fluid by shielding negatively charged groups of the membrane surface and that there is a fairly close correlation between the membrane organization and the membrane surface charge density.     

Reactions of fluorescent probes with normal and chemically modified myelin.

The fluorescent probes 8-anilino-1-naphthalenesulfonate (ANS) and 2-p-toluidinylnaphthalene-6-sulfonate (TNS) bind to highly purified myelin membranes obtained from bovine brain white matter. Binding of the dyes was markedly increased by environmental conditions which reduce the negative surface potential of the membrane, i.e., cations (La-3+ is greater than Ca-2+ is greater than Na-+,K-+), H-+, local anesthetics, and the antibiotic polymyxin B. Chemical alteration of accessible membrane charged groups affected dye binding in a manner consistent with the hypothesis that such binding is primarily dependent upon the membrane surface potential. Thus, binding was increased by blocking of carboxyl groups via carbodiimide activation and subsequent coupling with neutral amino acid esters, and even more so with a basic amino acid ester (e.g., arginine methyl ester). Dye binding was reduced by succinylation of amino groups, and by hydrolysis of choline and ethanolamine head groups of phospho- and sphingolipids by phospholipase C. Phospholipase C treatment of myelin, or sphingomyelin vesicles, reduced or abolished the augmentation of ANS and TNS binding due to cations, local anesthetics, or polymyxin B. Energy transfer from myelin tryptophan residues to bound ANS occurs, but with low efficiency. Oxidation of membrane tryptophan residues with N-bromosuccinimide, or alkylation with 2-hydroxy (or methoxy)-5-nitrobenzyl bromide, markedly reduced intrinsic membrane fluorescence and energy transfer to bound ANS, but did not significantly affect dye binding or the quantum yield of ANS fluorescence when excitation was at 380nm. Proteolytic digestion removed 6-30% of myelin protein, depending upon the enzyme used, but had no effect on fluorescent dye binding. It is concluded that the binding of the anionic fluorescent probes ANS and TNS to myelin is primarily a function of the membrane surface charge density and net surface potential, as is the case with other biological membranes. Conclusions about the degree of dye binding to membrane lipids or membrane proteins cannot be drawn unless additional studies are carried out on isolated water soluble membrane proteins.     

Effect of ionic strength on the membrane fluidity of rabbit intestinal brush-border membranes: A fluorescence probe study

The effect of ionic strength on the fluidity of rabbit intestinal brush-border membranes has been studied using two fluorescence probes, pyrene and 1-anilino-8-naphthalene sulfonate (ANS). The imposition of a potential gradient on the pyrene-probed membrane vesicles ($\text{out > in}$) with increasing NaCl concentration in the medium resulted in a marked enhancement of the excimer formation efficiency, accompanied by a decrease in the ratio of fluorescence intensities of the probe at 392 and 375 nm. Fluorescence polarization of the pyrene-membrane complex is independent of temperature in the absence of salts, while it is dependent on temperature from 10 to 47°C in the presence of salts, as shown by the thermal Perrin plots of polarization. It has been demonstrated that there is a linear relationship between the changes in the pyrene excimer formation efficiency in the membranes and of the values of the binding parameters of ANS for the membranes. From these results, it is suggested that the lipid phase of the membranes becomes more fluid by shielding negatively charged groups of the membrane surface and that there is a fairly close correlation between the membrane organization and the membrane surface charge density.     

The influence of diffusion potentials across liposomal membranes on the fluorescence intensity of 1-anilinonaphthalene-8-sulphonate

The influence of diffusion potentials across different phospholipid membranes on the fluorescence intensity of 1-anilinonaphthalene-8-sulphonate (ANS) was studied. With liposomes or chloroform spheres covered with a monolayer of egg lecithin, no specific effects were found. With liposomes of soy-bean phospholipids, generation of a diffusion potential leads to an enhancement or decrease, depending on the direction of the potential, of the intensity of ANS fluorescence. This effect is mainly due to a change in quantum yield of the bound ANS. These data support a mechanism according to which ANS molecules are pushed into or pulled out of the membrane by a potential, but not an electrophoretic one in which the potential causes movement of ANS across the membrane.     

Changes in the membrane surface charge density and/or membrane potential of the porcine intestinal brush-border membrane vesicles induced by treatment with neuraminidase

The effects of neuraminidase treatment on the membrane surface charge density and/or membrane potential of the porcine intestinal brush-border membrane vesicles were studied by using three fluorescent dyes, 1,6-diphenyl-1,3,5-hexatriene (DPH), 1-anilino-8-naphthalene sulfonate (ANS), and 3,3'-dipropyl-2,2'-thiadicarbocyanine iodide (DiS-C3(5]. The results of quenching studies of DPH-labeled membranes using cationic (T1+) and anionic (I-) quenchers suggested an increase of negative charge on the membrane surface by desialylation upon neuraminidase treatment. This interpretation was further supported by a decrease of ANS-binding affinity of the membranes after treatment with the enzyme. In addition, the degree of valinomycin-induced fluorescence change of DiS-C3(5)-probed membranes in the presence of various concentrations of KCl was reduced by treatment of the membranes with neuraminidase. This suggests that penetration of the dye molecules into the vesicle interior is facilitated by the treatment. The membrane potentials estimated from the null point of valinomycin-induced changes in the DiS-C3(5) fluorescence of the control and neuraminidase-treated membranes were -25 to -29.7 and -40 to -48.8 mV, respectively. From these results, it is suggested that the membrane surface charge density and/or membrane potential of the intestinal brush-border membranes are susceptible to modification of carbohydrate moieties on the membrane surface by neuraminidase treatment.     

能量化时线粒体内膜表面电荷的变化

本文报告用荧光探剂1,8—ANS和电泳激光光散射技术,研究鼠肝线粒体内膜在加入ATP的能量化过程中其膜表面电荷的变化。实验结果表明在加入ATP后线粒体内膜的能量化使其膜表面的负电荷减少。作者论讨了用上述二种方法研究线粒体内膜在能量化时表面电荷变化的有关问题。     

The role of membrane bound glycoprotein on the permeability of liposomes

The liposome permeability to potassium and methanosulfonate ions was determined in the presence of bound glycoprotein and protein. The permeability changes were registered by light-scattering measurements of the osmotic volume changes of liposome suspension after mixing with solutions containing K+ and MS- ions respectively. The permeability changes varied considerably with the change of glycoprotein-protein molar ratio in the liposomes. It was suggested that topological distribution of both molecules (glycoprotein and protein) in the lipid bilayer would play a substantial role and influence the permeability. It was confirmed from fluorescence measurements with ANS as a fluorescence marker. There was an increase of the number of binding sites (n) for ANS, increasing glycoprotein-protein molar ratio in the liposomes. These results were interpreted in terms of electrostatical changes of the membrane lipid region and membrane surface, caused by the interaction of glycoprotein and protein with lipids, as well as the associated role of these components on the permeability.     

The effect of ATP on the cell membrane structure]

ATP influence on the structure of plasma membranes thymocytes of cattle was studied. Fluorescence anisotropy of tryptophan residues of membrane proteins, fluorescence anisotropy of 3-methoxybenzanetron and fluorescence intensity of 1-anilinonaphthalene-8-sulphonate were determined. Changes of tryptophan fluorescence anisotropy and of ANS fluorescence intensity were established. It is supposed that the observed changes are connected with the change of membrane proteins structure and plasma membrane charge.     

Role of bound water in biological membrane structure: Fluorescence and infrared studies

Bound water is a major component of biological membranes and is required for the structural stability of the lipid bilayer. It has also been postulated that it is involved in water transport, membrane fusion, and mobility of membrane proteins and lipids. We have measured the fluorescence emission of membrane-bound 1-anilino-8-naphthalenesulfonate (ANS) and the infrared spectra of membranes, both as a function of hydration. ANS fluorescence is sensitive to polarity and fluidity of the membrane-aqueous interface, while infrared absorption is sensitive to the hydrogen bonding and vibrational motion of water and membrane proteins and lipids. The fluorescence results provide evidence of increasing rigidity and/or decreasing polarity of the membrane-aqueous interface with removal of water. The membrane infrared spectra show prominent hydration-dependent changes in a number of bands with possible assignments to cholesterol (vinyl CH bend, OH stretch), protein (amide A, II, V), and bound water (OH stretch). Further characterization of the bound water should allow its incorporation into current models of membrane structure and give insight into the role of membrane hydration in cell surface function.     

A study of carbachol-atropine interaction on intestinal smooth muscle vesicles, using a fluorescent probe.

Plasma membrane vesicles were prepared from guinea pig ileum longitudinal muscle. The vesicles were characterized by electron microscopy and analysis of lipid and protein content. They were shown to be free of gross contamination from actomyosin, sarcoplasmic reticulum, and mitochondria. 8-Anilino-1-naphthalene sulphonic acid (ANS) binding characteristics were similar to those found in other membranes. Both carbachol and atropine increased the fluorescence of ANS bound to this membrane, the maximum increase for atropine being greater than that for carbachol. Since neither drug effected the apparent affinity constant for the ANS-membrane interaction. It may be assumed that the increased fluorescence was due to an increase in the number of ANS binding sites. The carbachol-dependent increase in ANS fluorescence was blocked noncompetitively by atropine but not by tubocurarine or diphenhydramine. These latter two antagonists also increased ANS fluorescence but at much higher concentrations than either carbachol or atropine. Neither atropine nor carbachol increased ANS fluorescence on either erythrocyte ghosts or liposomes (prepared from a lipid extract of the muscle membrane).     

Fluorescence studies on erythrocyte membrane isolated fromPlasmodium berghei infected mice

The erythrocyte host cell plays a key role in the well defined developmental stages of the malarial parasite growth and propogation in the erythrocyte cycle of malaria. The host cell serves the parasites by supplying metabolites and removing the catabolites produced by the obligatory parasites. It has been observed that the plasma membrane of the infected cells show a substantially higher fluidity probably due to the depletion of cholesterol content from the host cell. The protein component of the membrane is also modulated due to the insertion of new polypeptides of the parasitic origin, which confers upon it new antigenic properties. We have studied the membrane fraction isolated from mice erythrocytes infected withPlasmodium berghei using fluorescent probes like DPH, ANS and series of fluorenyl fatty acids, which permit depth dependent analysis of membrane. We have observed that there is a marked difference in the fluorescence emission wavelength maximum, the dissociation constant K_d of ANS when bound to normal and infected erythrocytes, though relatively small differences are observed in the fluorescence polarisation values of the two cell types. The fluorenyl fatty acids also show the differences when bound to normal and infected erythrocytes, indicating that either they are in a different environment or they have differing binding properties to the two cell types.Abbreviations DPH 1,6-Diphenyl-1,3,5-Hexatriene - ANS 8-Anilino-napthalene Sulfonic Acid - C2A-FL 2-Fluorenyl-acetic Acid - C4A-FL 2-Fluorenyl-butyric Acid - C6A-FL 2-Fluorenyl-hexanoic Acid - C8A-FL 2-Fluorenyl-octanoic Acid     

Change of synaptic membrane lipid composition and fluidity by chronic administration of lithium

The effect of chronic administration of lithium salts on the lipid composition and physical properties of the synaptosomal plasma membrane was examined in rat brain. The effect of lithium treatment has been studied on the fluorescence polarization of synaptosomal plasma membrane and artificial lipid vesicles and on the lipid composition of the membranes. Fluorescence polarization of lipophilic probes was used to study membrane lipid structure. Steady-state polarization of 1,6-diphenyl-1,3,5-hexatriene (DPH), a probe of the hydrophobic core, was significantly lower in plasma membranes from lithium-treated animals. Altered DPH polarization was due to a decrease in the order parameter of the probe. The lithium-treatment also changed the fluorescence of 1-anilino-8-naphthalene sulfonate (ANS), a probe that binds to the polar head group of the phospholipids and to proteins on the membrane surface. Synaptic plasma membranes from treated rats presented no significant changes on the cholesterol-to-phospholipid ratio, although the phospholipid class distribution was altered and the membrane phospholipid unsaturation increased. In summary, the neural plasma membranes became disorder after chronic lithium administration at therapeutic levels. This structural change may be due to changes in plasma membrane phospholipid distribution and to the degree of unsaturation of phospholipid fatty acids.     

Structural properties of the membrane of intact human spermotozoa: A study with fluorescent probes

The properties of the membrane of intact, metabolically active, human persmatozoa have been studied by the use of 1-anilino-8-napthalene sulfonate (ANS). By fluorescence microscopy it was found that at neutral pH ANS is bound exclusively to the membrane of the entire sperm with some preferential binding to the midpiece, while at low pH some preferential binding to the aerosome was observed. By spectrofluorimetry, fluorescence was found to be enhanced 48-fold on binding of ANS to the spermatozoal membrane, with a 50-nm shift in the emission spectrum of the bound dye. $\text{2.47 ± 0.02}$ nmoles of ANS were bound per 10⁶ spermatozoa ($\text{K=2.3–10}{}^{\mathrm{?5}}\text{M}$). Scatchard plots indicate that all the binding sites on the spermatozoal membrane have similar binding characteristics with aZ value of 84.8. Energy transfer with an efficiency of 7% was found for recently ejaculated spermatozoa. The fluorescence of bound ANS depends on the pH of the medium and possibly on the metabolic state of the cell, since addition of succinate or fructose produces an enhancement of fluorescence, while addition of glucose results in a decrease of this parameter. These changes are inhibited by the presence of cyanide.     

光动力过程中线粒体膜电位和细胞存活关系

以1-anilionaphthalene-8-sulfonate(ANS)作荧光探针,通过其荧光光谱研究了苯硫基酞菁锌PcS)、苯硫基铝酞菁(AIPcS)和烷氧基铝酞菁(AIPc)这三种金属酞菁配合物作为光敏剂的光动力作用对癌细胞线粒体膜表面电位的影响．研究表明,光动力作用后线粒体膜表面电位降低,表面电荷数面密度增加．ZnPcS的影响最大,这与酶联免疫检测光动力作用后对癌细胞的杀伤效果相一致,提示细胞线粒体膜可能是金属酞菁配合物在光动力过程中的作用位点。通过比较细胞线粒体膜表面电位以及表面电荷数面密度与细胞存活之间的关系,阐述了光动力作用的物理学机制．同时,由于线粒体膜电位与细胞凋亡的密切关系,金属酞菁配合物对线粒体膜表面电位的影响提供了一个衡量药物疗效的判据。     

Partial characterization of the 1-anilino-8-naphthalene sulfonate-adrenochrome semicarbazide interaction site in erythrocyte ghost membrane fragments.

The effect of adrenochrome semicarbazide on the conformation of erythrocyte ghost membranes has been studied by ANS fluorescence, lipid and sulfhydryl spin labels and circular dichroism. No large conformational alterations in the membrane were detected by these techniques. Noncompetitive quenching of ANS fluorescence by ADCS suggests ADCS to interact with the membrane at sites close to the ANS binding domain.     

Transmembrane electrophoresis of 8-anilino-1-naphthalenesulfonate through egg lecithin liposome membranes.

Valinomycin has been shown to increase the amount of 8-anilino-1-naphthalenesulfonate (ANS) bound to egg lecithin liposomes and also to increase the maximum fluorescence value, as derived from double reciprocal plots. The assay conditions were such that addition of valinomycin would not produce a transmembrane potential. The formation of a valinomycin potassium ANS complex in the micelle membrane is proposed. This could account for the increase in the maximum fluorescence value and, by acting as an ANS transporter, could also account for the increase in ANS bound. Tributylamine was also shown to increase the binding and maximum fluorescence of ANS. In assay conditions where the addition of valinomycin would produce a transmembrane potential negative inside, the tributylamine-induced fluorescence was reversed. The fluorescense decrease is interpreted as transmembrane electrophoresis of ANS in response to a transmembrane potential.     

Effect of air ions on L 1210 cells: changes in fluorescence of membrane-bound 1,8-aniline-naphthalene-sulfonate (ANS) after in vitro exposure of cells to air ions

The ability of air ions to produce changes in the electrical properties of L 1210 mouse leukemia cells was tested. The fluorescence of ANS incorporated into a membrane lipid bilayer (measured microphotometrically) was used as a probe. It was shown that the action of air ions of both signs could change (negative ions by increasing and the positive ones by decreasing) the fluorescence intensity of ANS in the cell surface structures or to an imbalance of ions inside and outside the cell. Both possibilities are discussed in the light of the results of experiments using ouabain or biguanide as factors diminishing the intensity of ANS fluorescence.     

Microenvironment changes of human blood platelet membranes associated with fibrinogen binding

Alterations in the membrane organization caused by fibrinogen binding to human blood platelets and their isolated membranes were analyzed by fluorescence and electron spin resonance measurements. The degree of fluorescent anisotropy of DPH, ANS and fluorescamine increased significantly when fibrinogen reacted with its membrane receptors. Both fluorescence and ESR analyses showed that fibrinogen binding to platelet membranes is accompanied by an increase of the membrane lipid rigidity. This effect seems to be indirect in nature and is mediated by altered membrane protein interactions. As it has been shown that an increased membrane lipid rigidity leads to a greater exposure of membrane proteins, including fibrinogen receptors, this might facilitate a formation of molecular linkages between neighboring platelets. On the other hand, changes of fluorescence anisotropy of membrane tryptophans and N-(3-pyrene) maleimide suggest the augmented mobility of the membrane proteins. Evidence is presented which indicated that the binding of fibrinogen to the membrane receptors is not accompanied by any changes in the fluorescence intensity of ANS attached to the membranes. It may suggest that the covering of platelets with fibrinogen does not influence the surface membrane charge. In contrast to fibrinogen, calcium ions caused an increase of the fluorescence intensity resulting from the more efficient binding of ANS to the platelet membranes.     

Ans fluorescence and electrokinetic potential of activated lymphocytes by con A or LPS in vivo

The $\text{in vivo}$ effect of Concanavalin A (Con A), or bacterial lipopolysaccharide (LPS) on mouse spleen cell populations was investigated. The membrane fluorescence changes of activated splenic lymphocytes were studied during two weeks after the injection of polyclonal immunogens. Experiments were performed with the hydrophobic fluorescent probe: 1-anilino-8-naphthalene sulphonate (ANS). The kinetic studies further indicated that the course of fluorescence changes may considerably vary depending on both immunogens. These fluorescence intensity changes would be in direct relation to the electrokinetic surface potential changes of activated lymphocytes, as assessed by the electrophoretic mobility analysis. By comparison with the inverse relationship observed in our previous study, it would be concluded that the relation (direct or inverse) between ANS fluorescence and electrokinetic potential depends on the net electrical charge of the antigens used.     

A PVC-based electrode sensitive to DDA+ as a device for monitoring the membrane potential in biological systems

A polyvinyl chloride (PVC)-based membrane electrode sensitive to dibenzyldimethyl ammonium cation (DDA⁺) was constructed, and operational parameters such as the selectivity coefficients, the detection limit, and the response time were obtained. In comparison with the selectivity coefficients obtained with the previous liquid-membrane electrode, significant improvement was not obtained, but the response time became pronouncedly shorter. Furthermore, the electrode lifetime was remarkably prolonged. With the electrode developed, the change in the membrane potential of liposomes containing dibutyl ferrocene which separated oxidizing and reducing agent solutions was measured. The DDA⁺ uptake, U, and the membrane potential estimated from U changed in accordance with the redox potential in the medium when the concentration of internal ferricyanide was kept constant. The membrane potential collapsed when the uncoupler of oxidative phosphorylation was added. The ANS fluorescence measurement indicated that negative charges appeared on energization with oxidizing-reducing agent. The change in membrane potential of mitochondria during energization was also measured. It was found that the liposome described above is a good model for the generation of membrane potentials in mitochondria.