The binding of a neutral aromatic molecule to a negatively-charged lipid membrane. I. Thermodynamics and mode of binding

This paper presents a detailed study of the binding of the fluorescent dye N-phenyl naphthylamine (NPN) to bilayers composed of the negatively-charged phospholipid methylphosphatidic acid. Binding to the liquid-crystalline membrane is enthalpy-driven. It is shown by determination of the binding constant and confirmed by n.m.r. that most of the dye ("guest") molecules reside between the lipid hydrocarbon chains at a fixed distance from the head-group, and are not distributed uniformly throughout the hydrocarbon phase. Each guest molecule is surrounded by about four lipid molecules. Transition of the membrane from the liquid-crystalline to the crystalline state results in almost total expulsion of the bound NPN into the water phase. Electrostatic theory is developed to find the effect of electrostatics upon the binding of a neutral molecule to charged membranes. Although the charge product is zero, electrostatic interactions play a part in determining the strength of binding, if each guest molecule incorporated increases the area of the membrane. For NPN this increase was found to be ca. 41 A(2).     

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.     

Molecular mechanism of general anesthesia: I. Fluorescence studies in mitochondrial membranes

We have tested the working hypothesis that anesthetics, by labilizing lipid-protein interactions, induce conformational changes in membrane proteins involved in the transmission of neural impulses. In the first communication of this series we report that general anesthetics induce changes in the fluorescence of the probes ANS and NPN in model membranes, lipid vesicles and mitochondria. The changes observed concern the quantumyield but not the position of the emission maximum. Such changes may be interpreted as due to fluidization of the membrane core (NPN), accompanied by variable effects in the membrane surface(ANS).     

The interaction of human glycophorin with 8-anilino-1-naphthalene sulfonate.

Both the sialoglycoprotein of human erythrocyte membranes, glycophorin, and the sialic acid free protein, obtained by treatment of glycophorin with neuraminidase (EC 3.2.1.18), increase the fluorescence of 8-anilino-1-naphthalene sulfonate (ANS). Binding of ANS to glycophorin is weak compared with the binding to bovine serum albumin (BSA). equilibrium dialysis gives an apparent binding constant of about 4 X 10(3) M(-1) at neutral pH, but Ka increases 1.75 times when NaCl or CaCl2 are added and 10-fold when the pH is lowered to 3.0. Sialic acid groups do not significantly affect ANS binding, although they have some effect at low ionic strength and neutral pH. Fluorescence studies indicate only one to two binding sites for ANS, with apparent pK = 3.8 +/- 0.2, and located close to aromatic residues in glycophorin. Polarization and quantum efficiency of the fluorescence of ANS associated with glycophorin fail to indicate changes in the vicinity of the binding site when the pH is lowered.     

Effect of phospholipase A on the structure and functions of membrane vesicles from Mycobacterium phlei.

The phospholipid composition of the electron transport particles and coupling factor-depleted electron transport particles of Mycobacterium phlei are the same, but they differ in contents. The accessibility of partially purified phospholipase A to these membrane phospholipids was found to be different. Treatment of membranes of Mycobacterium phlei with phospholipase A impairs the rate of oxidation as well as phosphorylation. The inhibition of phosphorylation can be reversed by washing the membranes with defatted bovine serum albumin. The reconstitution of membrane-bound coupling factor-latent ATPase activity to phospholipase A-treated depleted electron transport particles and their capacity to couple phosphorylation to oxidation of substrates remained unaffected after phospholipase A treatment. However, the pH gradient as measured by bromthymol blue was not restored after reconstitution of phospholipase A-treated depleted electron transport particles with membrane-bound coupling factor-latent ATPase. These findings show that the phosphorylation coupled to the oxidation of substrates can take place without a pronounced pH gradient in these membrane vesicles. The dye 1-anilino-8-naphthalene sulfonic acid (ANS) exhibited low levels of energized and nonenergized fluorescence in phospholipase A-treated membranes. This decrease in the level of ANS fluorescence in phospholipase A-treated membranes was found to be directly related to the amount of phospholipids cleaved. The decrease in the energy-dependent ANS response in phospholipase A-treated electron transport particles, as compared with untreated electron transport particles, was shown to be a result of a change in the apparent K-d of the dye-membrane complex, and of a decrease in the number of irreversible or slowly reversible binding sites, with no change in the relative quantum efficiency of the dye. The decrease in ANS fluorescence in phospholipase A-treated particles appears to be due to a decrease in the hydrophobicity of the membranes.     

Reactions of fluorescent probes with normal and chemically modified myelin basic protein and proteolipid. Comparisons with myelin.

Basic (encephalitogenic) protein and water-soluble proteolipid apoprotein isolated from bovine brain myelin bind 8-anilino-1-naphthalenesulfonate and 2-p-toluidinylnaphthalene-6-sulfonate with resulting enhancement of dye fluorescence and a blue-shift of the emission spectrum. The dyes had a higher affinity and quantum yield, when bound to the proteolipid (Kans=2.3x10--6,=0.67) than to the basic protein (Kans=3.3x10--5,=0.40). From the efficiency of radiationless energy transfer from trytophan to bound ANS the intramolecular distances were calculated to be 17 and 27 A for the proteolipid and basic protein, respectively. Unlike myelin, incubation with proteolytic enzymes (e.g., Pronase and trypsin) abolished fluorescence enhancement of ANS or TNS by the extracted proteins. In contrast to myelin, the fluorescence of solutions of fluorescent probes plus proteolipid was reduced by Ca-2+,not affected by La-3+, local anesthetics, or polymyxin B, and only slightly increased by low pH or blockade of free carboxyl groups. The reactions of the basic protein were similar under these conditions except for a two- to threefold increase in dye binding in the presence of La-3+, or after blockade of carboxyl groups. N-Bromosuccinimide oxidation of tryptophan groups nearly abolished native protein fluorescence, but did not affect dye binding. However, alkylation of tryptophan groups of both proteins by 2-hydroxy (or methoxy)-5-nitrobenzyl bromide reduced the of bound ANS (excited at 380 nm) to 0.15 normal. The same effect was observed with human serum albumin. The fluorescence emission of ANS bound to myelin was not affected by alkylation of membrane tryptophan groups with the Koshland reagents, except for abolition of energy transfer from tryptophan to bound dye molecules. This suggests that dye binding to protein is negligible in the intact membrane. Proteolipid incorporated into lipid vesicles containing phosphatidylserine did not bind ANS or TNS unless Ca-2+, La-3+, polymyxin B, or local anesthetics were added to reduce the net negative surface potential of the lipid membranes. However, binding to protein in the lipid-protein vesicles remained less than for soluble protein. Basic protein or bovine serum albumin dye binding sites remained accessible after equilibration of these proteins with the same lipid vesicles. It is proposed that in the intact myelin membrane the proteolipid is probably strongly associated with specific anionic membrane lipids (i.e., phosphatidylserine), and most likely deeply embedded within the lipid hydrocarbon matrix of the myelin membrane. Also, in the intact myelin membrane the fluorescent probes are associated primarily, if not solely with the membrane lipids as indicated by the binding data. This is particularly the case for TNS where the total number of myelin binding sites is three to four times the potential protein binding sites.     

Effects of a series of alcohols on the binding of a fluorescent dye to erythrocyte membranes.

1. The effects of a series of aliphatic alcohols (methanol to octanol) on membrane proteins of erythrocytes were studied by monitoring the flueorescence of a dye (1-anilino-8-naphthalenesulfonic acid (ANS)) that adsorbs to erythrocyte ghost membranes. Low concentrations of all the alcohols reduced the ANS fluorescence of the membrane-ANS suspensions; lent to those which protect against hypotonic hemolysis on intact erythrocytes; higher concentrations markedly increased the fluorescence. Ethanol and methanol decreased ANS fluorescence at all concentrations. 2. Lytic concentrations of saponin did not increase ANS fluorescence and did not modify the membrane action of the alcohols. 3. None of these effects were observed in liposomes prepared from lipid extracts of the erythrocyte membrane. 4. Since the apparent dissociation constant for the ANS-membrane interaction was unchanged in the presence of the alcohols, it was assumed that the fluorescence changes anesthetic concentration of the alcohols alter the conformation of membrane proteins, as indicated by the decreased number of ANS binding sites.     

Binding of naphthalene dyes to the N and A conformers of bovine α-lactalbumin

Contrary to earlier findings, monomeric native α-lactalbumin does bind naphthalene dyes such as ANS and TNS with marked enhancement of their fluorescence. Nanosecond decay measurements indicate there to be two dye binding sites per protein molecule with lifetimes of ca. 2 and 15 ns for ANS and 5 and 11 ns for TNS. The fluorescence titrations curves of α-lactalbumin with ANS and TNS reflect this site multiplicity, i.e., it was not possible to analyze such curves with a single K_diss. The apparent dissociation constants for binding of ANS and TNS to native bovine α-lactalbumin, as determined by an ultracentrifugal technique, ca. 950 and 900 μm, respectively, indicate that such binding is considerably weaker than previously supposed. The A conformer (metal ion-free form) of α-lactalbumin binds ANS and TNS more tightly than the N (native) form of the protein with marked fluorescence enhancement. The A conformer has two dye binding sites with lifetimes for ANS and TNS comparable with those seen with native protein.     

Reevaluation of ANS binding to human and bovine serum albumins: key role of equilibrium microdialysis in ligand - receptor binding characterization

In this work we return to the problem of the determination of ligand-receptor binding stoichiometry and binding constants. In many cases the ligand is a fluorescent dye which has low fluorescence quantum yield in free state but forms highly fluorescent complex with target receptor. That is why many researchers use dye fluorescence for determination of its binding parameters with receptor, but they leave out of account that fluorescence intensity is proportional to the part of the light absorbed by the solution rather than to the concentration of bound dye. We showed how ligand-receptor binding parameters can be determined by spectrophotometry of the solutions prepared by equilibrium microdialysis. We determined the binding parameters of ANS - human serum albumin (HSA) and ANS - bovine serum albumin (BSA) interaction, absorption spectra, concentration and molar extinction coefficient, as well as fluorescence quantum yield of the bound dye. It was found that HSA and BSA have two binding modes with significantly different affinity to ANS. Correct determination of the binding parameters of ligand-receptor interaction is important for fundamental investigations and practical aspects of molecule medicine and pharmaceutics. The data obtained for albumins are important in connection with their role as drugs transporters.     

The interaction of 1-anilino-8-naphthalenesulfonate with the membranes of the sarcoplasmic reticulum and various lipid compounds

Summary (1) The enzymatic removal of lipids from the vesicular membranes of the sarcoplasmic reticulum does not interfere with the fluorescence of the 1-anilino-8-naphthalenesulfonate (ANS) vesicular complex. (2) The fluorescence intensity of the ANS vesicular complex is considerably (50%) reduced by oleic acid (0.5mm) because it displaces ANS from its binding sites. (3) Stearic acid, which also combines with the membranes, interferes neither with ANS binding nor with ANS fluorescence. (4) Of all lipid compounds tested, oleylamine produces the most pronounced fluorescence enhancement of ANS. (5) The complexes formed between oleic acid and cetyltrimethyl ammonium salts or between oleic acid and polylysine produce a much higher fluorescence enhancement than the isolated components. (6) Low concentrations of ether added to ANS-containing vesicular suspensions reduce their fluorescence intensity. It returns to the initial intensity when the ether is removed. (7) A small cyclic change of the fluorescence of the vesicular ANS complex takes place during active calcium uptake.     

没食子酸丙酯和没食子酸异丁酯对人红细胞膜结构与功能的影响

本文应用荧光探剂ANS(1—苯胺—8萘磺酸)、NPN(N—苯基—1—萘胺)和DPH(1.6—二苯基—1.3.5—已三烯)观察没食子酸丙醋和没食子酸异丁酯对人红细胞膜流动性和相变温度以及Na~ -K~ ATP酶活性的影响.实验结果指出该两种化合物均能:(1)降低与膜结合的荧光探剂强度但不改变探剂在水相与膜相的分配比例:(2)降低膜脂的相变温度,增加膜的流动性;(3)抑制红细胞膜Na~ -K~ ATP酶活性;(4)标记红细胞膜的DPH偏振度随化合物浓度的增加而降低,膜的流动性增加.在给定的浓度范围内,两种化合物的效应表现为明显的量效关系与构效关系.从上述结果推测该两种化合物可能是通过改变膜脂结构、膜蛋白的脂类环境而调节膜的功能,成为其治疗疾病的机理之一.     

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.     

The oxygenation-linked binding of neutral red to spiny lobster hemocyanin. A structural study of the partially oxygenated protein

The structural change of lobster hemocyanin in cooperative O2 binding was studied by the dye-binding method. It was found that neutral red shows an O2-linked binding to hemocyanin with a higher affinity for the oxy form. The number of the dye-binding sites was estimated to be three in the hexameric molecule of oxyhemocyanin. The course of the structural change in the partially oxygenated hemocyanin was examined using the absorbance change of the bound dye as a measure. It was found that the fractional change in the dye binding was considerably greater than the degree of O2 saturation of hemocyanin. The three-state allosteric model, which was proposed for explanation of the O2 binding properties of lobster hemocyanin [N. Makino (1986) Eur. J. Biochem. 154, 49--55], was also consistent with the effects of the dye on the O2 binding to the native hemocyanin. On the basis of this model, the dye binding to partially oxygenated hemocyanin could be connected with the populations of the affinity states. It was inferred that the binding of neutral red reflects the quaternary structure of the protein. In contrast, O2 binding to the stripped (EDTA-treated) hemocyanin showed a considerable decrease in the cooperativity in the presence of the dye. The O2-binding isotherms could not be explained by the three-state model. It is suggested that the subunit interaction is partially blocked by the dye in the absence of divalent cations.     

Effect of a phase transition on the binding of 1-anilino-8-naphthalenesulfonate to phospholipid membranes.

The binding of 1-anilino-8-naphthalenesulfonate (ANS) to dipalmitoyl-phosphatidycholine (DPPC)-sonicated vesicles was measured by a fluorimetric method in the vicinity of the gel-to-liquid crystalline phase transition temperature (Tm). A similar measurement was performed on large multimellar DPPC vesicles through equilibrium dialysis. Both measurements demonstrated anomalous dye binding in the temperature region of the Tm and slightly above (prefreezing region). The amount of ANS bound at this temperature region was in excess of what would be expected based on extrapolation of the high temperature binding data; just below the Tm, the amount of bound dye decreased abruptly. The fluorimetric studies on vesicles also indicated that inner monolayer binding of ANS was markedly inhibited below the Tm. The possibility that the increase in bound dye in the prefreezing region was caused by enhanced lateral compressibility, density fluctuations, or additional binding sites at the boundary of transient gel-like clusters is discussed and the general topic of anomalous increases in various membrane processes in the vicinity of a phase transition is briefly reviewed.     

The essentiality of His-47 and the N-terminal region for the binding of 8-anilinonaphthalene-1-sulfonate with Taiwan cobra phospholipase A2

The Protein Journal - The binding of the apolar fluorescent dye 8-anilinonaphthalene-1-sulfonate (ANS) toNaja naja atra phospholipase A2 (PLA2) as well as the enhancement of ANS fluorescence of the...     

The essentiality of His-47 and the N-terminal region for the binding of 8-anilinonaphthalene-1-sulfonate with Taiwan cobra phospholipase A2

The binding of the apolar fluorescent dye 8-anilinonaphthalene-1-sulfonate (ANS) toNaja naja atra phospholipase A₂ (PLA₂) as well as the enhancement of ANS fluorescence of the PLA₂-ANS complex decreased with increasing pH in a pH range from 3 to 9. These pH-dependent curves can be well interpreted as the perturbation of an ionizable group with pK value of 5.8, which was assigned as His-47 in the active site of PLA₂. The ionizable group with pK 5.8 was no longer observed after methylation of His-47, supporting the idea that thepH dependence of ANS binding arose from an electrostatic interaction between His-47 and the bound ANS. Removal of the N-terminal octapeptide of PLA₂ caused a precipitous drop in the capability of PLA₂ for binding with ANS and enhancing ANS fluorescence, reflecting that the integrity of the N-terminal region was essential for maintaining the hydrophobic character of the ANS-binding site. However, the nonpolarity of the ANS-binding site in the N-terminus-removed derivative was still partially retained at lowpH, but was completely lost at highpH. Evidently, the N-terminal region plays a more crucial role in ANS binding at highpH than at lowpH. These results indicate that hydrophobic interaction as well as electrostatic interaction are involved in the binding of ANS to PLA₂, and that the relative contributions of both interactions in ANS fluorescence enhancement may be different under differentpH.     

A thermodynamic characterization of the interaction of 8‐anilino‐1‐naphthalenesulfonic acid with native globular proteins: the effect of the ligand dimerization in the analysis of the binding isotherms

8‐Anilino‐1‐naphthalenesulfonic acid (ANS) is a popular fluorescence probe, broadly used for the analysis of proteins, but the nature of its interaction with proteins and the high increase in the fluorescence intensity that takes place upon such process are still unclear. In the last few years, isothermal titration calorimetry has been used to characterize the nature of the interaction of this dye with proteins. The analysis of the binding isotherms of these studies has not considered the dimerization equilibrium of ANS, which is pH dependent, and it can result in serious errors in the data analysis. In the present work we have developed a suitable data analysis by which this process is taken into account. To study the binding of the dye to proteins at different pH values, we have used the Abl‐SH3 domain. Our results suggest that at pH 3 and 5, where the dimerization of the ANS is important, electrostatic interactions are significant for the binding of ANS to the Abl‐SH3 domain. However, at pH 7, ANS behaves mostly as monomer and the interaction with the protein is mainly hydrophobic. The pH dependent behavior of the ANS binding to proteins can be explained in terms of ionization states of both, the protein and the ANS. Copyright © 2010 John Wiley & Sons, Ltd.     

The interaction of 8-anilino-1-naphthalenesulfonate with polylysine and polyarginine

Comparative studies on the interaction of 8-anilino-1-naphthalenesulfonate (ANS) with polylysine and polyarginine have been made by equilibrium dialysis and fluorescence or circular dichroism measurements, to investigate the structural characteristics of the polypeptides. The results are summarized as follows: (i) ANS binds to either of the polypeptides primarily by electrostatic interaction while hydrophobic interaction partially facilitates the dye binding; both interactions are stronger in the polyarginine-dye binding than the polylysine-dye binding. (ii) The fluorescence of ANS is more intensified when the dye binds to polyarginine than to polylysine regardless of the value of r (number of bound dye per amino-acid residue) of polypeptide-dye complexes, although the intensification depends on the r value and becomes maximum at r = 0.25–0.35 for both cases. (iii) The binding of ANS to each polypeptide is cooperative at r < 0.4. (iv) The circular dichroism is more efficiently induced in the spectral region of ANS by binding to polyarginine than to polylysine. From these results, it was concluded that, compared to polylysine, polyarginine suffers some structural change by ANS binding into a more compact molecular configuration having some regularity with a lower dielectric environment.     

Anilinonaphthalene sulphonate as a probe for the native structure of bovine alpha lactalbumin: absence of binding to the native, monomeric protein

The fluorescence properties of 1,8 anilinonaphthalene sulfonate (ANS) in the presence of high concentrations of bovine alpha lactalbumin have been studied. While ANS was shown to bind to aggregated or partially denatured bovine alpha lactalbumin, at neutral pH, 0.1 M phosphate, no significant binding of ANS to alpha lactalbumin or any associated fluorescence enhancement was detected. Sedimentation velocity experiments suggest that near the isoelectric point of the protein the binding of ANS stabilizes aggregates of alpha lactalbumin and therefore promotes association.     

Fluorescence analysis study of the structural lability of biomembranes and their components. II. Higher fatty acids]

Binding constants, quantum yield and temperature relationship of the fluorescence of ionic (1-anilinonaphtalene-8-sulphonate-ANS) and neutral (N-phenyl-1-naphtalamine-PNA) probes have been studied on micellae and ufasomes of natural fat acids. The following regularities have been obtained: 1. The Anion dye (ANS) sharply decreases the intensity of fluorescence on fat acid structures while alkilating the medium, it is not practically bound with them at pH-7; 2. The neutral dye (PNA) shiws no fluorescence on micellae of the limited fat acids and is comparatively well bound with urasomes. The binding constant quantum yield of PNA fluorescence significantly decreases during the transition from the ufasomes of oleic acid to those of polyunsaturated fat acids. 3. The temperature relationship of PNA fluorescence intensity sorbed on oleic acid ufasomes shows twists in the region of 16--20degreesC and 46--52degreesC. The first transition is connected with the melting of potassium oleate.