The interaction of 1-anilino-8-naphthalenesulfonate with thyroid lipids and membranes: A nuclear magnetic resonance study

The proton magnetic resonance (PMR) spectra of thyroid cell membranes and their total lipid extracts, in the presence of 1-anilino-8-naphthalenesulfonate (ANS), have been studied. The addition of ANS causes a shifting of the head group PMR signal, a splitting of the signal into two components and an increase in total spectral intensity. The data suggest that ANS interacts with phospholipid in the membrane as it does in total lipid vesicles. Evidence is also presented for the removal of lipids from the membrane, by ANS, and the subsequent formation of micelles. The membrane results are compatred with our earlier work on the interaction of ANS with egg phosphatidycholine (P.C.) vesicles and the results are used in explaining the inhibition of iodide transport in isolated thyroid slices.     

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.     

Escherichia coli phosphofructokinase: inhibition by 8-anilino-1-naphthalenesulfonate.

Phosphofructokinase was purified 1200-fold from extracts of Escherichia coli B. Kinetic studies of the enzyme were carried out in the presence of the fluorescent dye 8-anilino-1-naphthalenesulfonate (1,8-ANS). 1,8-ANS was competitive with ATP and an uncompetitive inhibitor with respect to fructose-6-P. These parabolic inhibitions were accounted for by assuming that at least two molecules of the inhibitor were responsible for decreasing the affinity of the enzyme for ATP. ADP and GDP are both positive effectors for E. coli Phosphofructokinase. Evidence is presented to indicate that 1,8-ANS binding decreases the affinity of a regulatory site for ADP but not the binding site for regulation by GDP.     

Substrate binding to phosphoglycerate kinase monitored by 1-anilino-8-naphthalenesulfonate

The interaction between 1-anilino-8-naphthalenesulfonate (ANS) and yeast phosphoglycerate kinase (ATP:3-phospho-D-glycerate 1-phosphotransferase, EC 2.7.2.3) and the use of ANS as a probe for studying the structure and function of phosphoglycerate kinase has been investigated. The interaction has been studied by kinetic methods, equilibrium dialysis, and fluorometric titrations. ANS inhibits the activity of the enzyme. More than one inhibitor site exists. ANS is competitive with MgATP and noncompetitive with 3-phosphoglycerate at the first detected inhibitor binding site. The Ki value is 1-2 mM. Several ANS molecules bind to the enzyme. By fluorometric titrations the first detected site has a dissociation constant that is in the same range as Ki or bigger. When ANS interacts with phosphoglycerate kinase its fluorescence is increased and a blue shift occurs. ANS appears to bind to a strongly hydrophobic site. The fluorescence is sensitive to the addition of substrates. ADP, ATP, or combinations of Mg2+ and nucleotide decreases the fluorescence as does free Mg2+. 3-Phosphoglycerate, on the other hand, increases the fluorescence giving evidence for conformational changes upon 3-phosphoglycerate binding.     

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.     

Ion association reactions with biological membranes,studied with the fluorescent dye 1-anilino-8-naphthalenesulfonate

Summary (1) When salts are added to buffered suspensions of membrane fragments containing the fluorochrome 1-anilino-8-naphthalenesulfonate (ANS), there is an increased fluorescence. This is caused by increased binding of the fluorochrome; the intrinsic fluorescence characteristics of the bound dye remain unaltered. These properties make ANS a sensitive and versatile indicator of ion association equilibria with membranes. (2) Alkali metal and alkylammonium cations bind to membranes in a unique manner. Cs⁺ binds most strongly to rat brain microsomal material, with the other alkali metals in the order Cs⁺>Rb⁺>K⁺>Na⁺>Li⁺. The reaction is endothermic and entropy driven. Monovalent cations are displaced by other monovalent cations. Divalent cations and some drugs (e. g., cocaine) displace monovalent cations more strongly. (3) Divalent cations bind to membranes (and to lecithin micelles) at four distinct sites, having apparent association constants between 50 and 0.2mm ^–1. The characteristics of the titration suggest that only one species of binding site is present at any one time, and open the possibility that structural transitions of the unassociated coordination sites may be induced by divalent cation binding. Divalent cation binding at the weakest site (like monovalent cation binding) is endothermic and entropy driven. At the next stronger site, the reaction is exothermic. Monovalent cations affect divalent cation binding by reducing the activity coefficient: they do not appear to displace divalent cations from their binding sites.     

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.     

The interaction of pseudohalides with the phospholipid head-group: a nuclear magnetic resonance study.

Liposomes have been studied by means of high-field magnetic resonance techniques. The choline N+(CH3)3 group showed two proton resonances for phosphatidylcholine whereas the addition of a charged species to the phospholipid resulted in a single N+(CH3)3 resonance. Upon the addition of either of two linear pseudohalide anions, the two resonances for phosphatidylcholine were further split whereas for the mixture of lipids containing a charged species, the single head-group resonance was now split. The presence of a negative charge on the liposome does not prevent the anion-liposome interaction observed for neutral liposomes. Incorporation of cholesterol into the negatively charged liposomes results in a clear initial splitting of the head-group proton signal in a manner very similar to that for neutral liposomes; this head-group signal is then further split upon anion addition. The small splitting involved suggests a weak pseudohalide-liposome interaction whose magnitude depends on the position of the anion in the lyotropic series. The phosphorous NMR signal from the head-group is unaffected by the pseudohalide interaction whereas the carbon signals from the N+(CH3)3 groups are affected, indicating that the initial anion interaction is localized to the region of the choline groups of the liposome. After the initial exposure of the liposome to the anion, however, the splitting decreases with time, indicating that the anions have entered the liposome and interact with both inside and outside head-groups.     

The effect of surface and membrane potential on 1-anilino-8-naphthalenesulfonate binding with E. coli membrane

Dependence of ANS fluorescence on the surface potential of E. coli under lowered resistance of the bacterial membrane and after application of the positive diffusion potential inside the cell was investigated. It was shown that in the absence of the latter ANS binding in de-energised bacteria occurs mainly at the outside surface. It may be due to the high negative charge of the inner side of the cytoplasmic membrane. According to produced evaluation the potential of this surface is 120 +/- 25 mV. The data obtained suggest that low ANS fluorescence in intact cells is due to the membrane modification on energisation.     

A proton nuclear magnetic resonance study of the interaction of cadmium with human erythrocytes

The binding of Cd²⁺ by molecules in the intracellular region of human erythrocytes has been studied by ¹H-NMR spectroscopy. From changes in spin-echo Fourier transform NMR spectra for both intact and hemolyzed erythrocytes to which CdCl₂ was added, direct evidence was obtained for the binding of Cd²⁺ by intracellular glutathione and hemoglobin. Time-courses were measured by ¹H-NMR for the uptake of Cd²⁺ by intact erythrocytes in saline/glucose solution and in whole blood. In both cases, the uptake, as indicated by changes in the ¹H-NMR spectrum for intracellular glutathione, plateaus after about 30 min. The effectiveness of the disodium salt of EDTA and of various thiol-chelating agents for releasing glutathione from its Cd²⁺ complexes in hemolyzed erythrocytes was also studied. EDTA was found to be more effective than thiols, and dithiols more effective than monothiols.     

Alcohol interactions with lipids: a carbon-13 nuclear magnetic resonance study using butanol labeled at C-1

The interactions of carbon-13 enriched butanol with dipalmitoylphosphatidylcholine (DPPC) and dimyristoylphosphatidylcholine (DMPC) were studied using C-13 nuclear magnetic resonance. It was found that above the gel to liquid crystal phase transition the resonance from the butanol could be resolved into two signals with similar chemical shifts but different T1 values and line widths. In contrast, only one narrow resonance was observed for ethanol, which has considerably less solubility in the lipids than butanol. Thermodynamic analyses of the effects of butanol on the phase transition temperature predict much greater solubility or butanol when the lipid is above the phase transition temperature than when it is below. It was concluded that the two butanol resonances represent two slowly exchanging populations, the free butanol in the aqueous phase and butanol dissolved in the liquid crystalline region of the lipid. No bound butanol was detected below the gel to liquid crystal phase transition. Relaxation studies were performed on the resonance of the bound butanol in DPPC and DMPC, including measurements of T1, line width, and nuclear Overhauser enhancement. Theoretical analysis of the relaxation parameters indicates that the lipid-bound alcohol has very high mobility within the fluid lipid bilayer. The data are consistent with butanol being present at the aqueous boundary or head group region of the lipid.     

A proton nuclear magnetic resonance study of the interaction of mercury with intact human erythrocytes

The binding of mercuric ion (Hg(II)) by small molecules in the intracellular region of intact human erythrocytes has been studied by ¹H-NMR spectroscopy. HgCl₂ added to intact erythrocytes in saline-glucose suspension is found to cross the membrane and reach an equilibrium distribution among the molecules of the erythrocyte within 4 min. In the intracellular region Hg(II) reacts with GSH and hemoglobin to form the ternary mixed-ligand complex GSH-Hg(II)-hemoglobin. The analogous complex with ergothioneine is formed after all the GSH is complexed. ¹H-NMR spectra show that the GSH-Hg(II)-hemoglobin complex also forms in simpler solutions containing HgCl₂, GSH and hemoglobin, whereas the complex Hg(GSH)₂ predominates in solutions of GSH and HgCl₂. The lifetime of the GSH in the GSH-Hg(II)-hemoglobin complex is shown to be less than 30 s, which provides direct evidence for the first time that Hg(II) complexes in biological systems are quite labile, even though their thermodynamic stability is large. The effectiveness of eight sulfhydryl-containing ligands, some of which have been used as antidotes for Hg(II) poisoning, for releasing GSH from its Hg(II) complex in hemolyzed erythrocytes was also studied. Dithiol ligands were found to be more effective than monothiols, with dithioerythritol the most effective of the dithiols.     

Ciliary dynein conformational changes as evidenced by the extrinsic fluorescent probe 8-anilino-1-naphthalenesulfonate

The binding of 8-anilino-1-naphthalenesulfonate (ANS) to ciliary dynein ATPase leads to a marked increase in the dye's fluorescence intensity, accompanied by a blue shift in the observed fluorescence emission maximum. We found that dynein has 37 +/- 3 ANS binding sites and that experimentally applied ANS concentrations failed to alter enzyme activity. The fluorescence properties of the enzyme-dye complex were used to learn more about the binding characteristics of dynein substrates and effectors and to probe for possible conformational changes of the enzyme. The fluorescence of the dynein-ANS complex is increased by a number of substrates, including ATP, GTP, and UTP. The transfer of excitation energy from dynein chromophores to adsorbed ANS was also investigated. Our findings indicate that dynein appears to undergo a localized conformational change in its interaction with ATP. Native dynein was also found to be conformationally different from heat-activated or NEM-modified enzyme as evidenced by the emission and excitation spectra of the various enzyme-ANS complexes.     

A quantitative study of organic phosphate-amine interaction by 31P nuclear magnetic resonance

Interactions between the phosphate group of 4-deoxypyridoxine 5′-phosphate and different protonated amines were quantitatively measured by means of {³¹P}-¹H nuclear magnetic double resonance technique combined with pD titration. An interaction of the phosphate group with added amine resulted in a measurable difference in the ³¹P chemical shift of these phosphate-containing samples with and without amine [Δδ(³¹P)]. Basic amino acids and biogenic amines had significant measurable Δδ(³¹P) values. No interactions were observed for acidic or neutral α, β and γ-amino acids.