Effect of the hemolytic lectin CEL-III from Holothuroidea Cucumaria echinata on the ANS fluorescence responses in sensitive MDCK and resistant CHO cells

The addition of CEL-III to sensitive MDCK cells preincubated with 8-anilino-1-naphthalenesulfonate (ANS) caused an increase in the fluorescence intensity of the probe. The increase in the ANS fluorescence caused by CEL-III was Ca2+-dependent and strongly inhibited by 0.1 M lactose, indicating that Ca2+-dependent binding of CEL-III to specific carbohydrate receptors on the plasma membrane is responsible for this phenomenon. In contrast, no significant effect of CEL-III on the ANS fluorescence was observed in CHO cells, which are highly resistant to CEL-III cytotoxicity. In MDCK cells, energy transfer from tryptophan residues to bound ANS molecules was observed in the presence of CEL-III, but not in CHO cells. Furthermore, the amount of ANS bound to MDCK cells increased as the concentration of CEL-III increased. Therefore, a simple interpretation is that the CEL-III-induced increase in ANS fluorescence is attributable to an increase of the hydrophobic region in the plasma membrane where ANS could bind. Immunoblotting analysis of proteins from cells treated with CEL-III indicated that CEL-III oligomers were irreversibly bound to the cells, and the amount of oligomer bound to MDCK cells was much greater than that bound to CHO cells under any conditions tested. The oligomerization may be accompanied by an enhancement of the hydrophobicity of CEL-III molecules, which in turn provides new ANS-binding sites. The difference in susceptibility of MDCK and CHO cells to CEL-III cytotoxicity may be due to a difference in oligomerization of bound CEL-III.     

Use of 1-anilino-8-naphthalene-sulfonate as a probe of gastric vesicle transport.

The interaction of 1-anilino-8-naphthalene-sulfonate (ANS) with vesicles derived from hog fundic mucosa was studied in the presence of valinomycin and with the addition of ATP. Evidence was found for two classes of sites, those rapidly accessible to ANS with a KD of 7.5 micronM and those slowly accessible, but rapidly accessed in the presence of valinomycin with a KD of 2.5 micronM. ATP transiently increases the quantum yield of the latter ANS binding sites only in the presence of valinomycin, but does not alter the number of KD of those sites. The time course of this increase correlates with H+ uptake and Rb+ extrusion by those vesicles and H+ carries such as tetrachlorsalicylanilide or nigericin abolish the ATP response. With ATP addition in the presence of SC14N and valinomycin there is transient uptake of SCN-. It is concluded that ANS is acting as a probe of a structural change dependent on a potential and H+ gradient.     

Complex formation between the uncoupler carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP) and valinomycin in the presence of potassium

Spectroscopic evidence is presented which indicates that the uncoupler carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP) and the peptide antibiotic valinomycin form a complex in the presence of potassium. Complex formation has been observed both in aqueous and nonaqueous media. Several techniques have been used to indicate the existence of a complex in aqueous solution. In the presence of valinomycin and K+, the absorption spectrum of FCCP is significantly perturbed, and there is also a large induced circular dichroism signal. In addition, the previously characterized complex which forms between valinomycin, K+, and the fluorescent probe 8-anilino-1-naphthalene-sulfonate (ANS) in aqueous solution is apparently disrupted by the addition of FCCP. The result is an effective quenching of the fluorescence due to the bound probe as it is displaced from the valinomycin.K+ by the uncoupler. In a nonpolar solvent, the absorption spectrum of FCCP is also perturbed by valinomycin in the presence of K+, again indicating the formation of a complex. These data point to the importance of considering the role of valinomycin.K+.uncoupler complex in interpreting physiological or ion transport data in which these substances have been used together.     

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。     

Neurite formation and membrane changes of mouse neuroblastoma cells induced by valinomycin

A clonal cell line of mouse neuroblastoma cells was found to undergo morphological differentiation in the presence of a K⁺ ionophore, valinomycin, in the assay medium. This effect was blocked by increasing the concentration of KCl of the medium, suggesting that the changes in resting membrane potential and ion fluxes may be involved in the mechanism of the formation of neurites. No enhancement of the neurite formation was observed in salines containing high concentrations of KCl in the absence of valinomycin. Depolarizing agents including veratridine, gramicidin and ouabain did not stimulate the outgrowth of neurites. Neither electrophoretic mobility of the cells nor molecular anisotropy of fluorescence probes in the membranes was modified by the treatment of valinomycin. Instead, it modified the slow binding phase in kinetics of the interaction of 1-anilinonaphthalene-8-sulfonate (ANS) with the cells, which is related to the penetration process of the probe into membranes. Valinomycin also enhanced the fluorescence intensity of ANS by increasing the binding sites in neuroblastoma cells.     

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).     

1-Anilino-8-Naphthalene Sulfonate (ANS) Is Not a Desirable Probe for Determining the Molten Globule State of Chymopapain

The molten globule (MG) state of proteins is widely detected through binding with 1-anilino-8-naphthalene sulphonate (ANS), a fluorescent dye. This strategy is based upon the assumption that when in molten globule state, the exposed hydrophobic clusters of protein are readily bound by the nonpolar anilino-naphthalene moiety of ANS molecules which then produce brilliant fluorescence. In this work, we explored the acid-induced unfolding pathway of chymopapain, a cysteine proteases from Carica papaya, by monitoring the conformational changes over a pH range 1.0–7.4 by circular dichroism, intrinsic fluorescence, ANS binding, acrylamide quenching, isothermal titration calorimetry (ITC) and dynamic light scattering (DLS). The spectroscopic measurements showed that although maximum ANS fluorescence intensity was observed at pH 1.0, however protein exhibited ∼80% loss of secondary structure which does not comply with the characteristics of a typical MG-state. In contrast at pH 1.5, chymopapain retains substantial amount of secondary structure, disrupted side chain interactions, increased hydrodynamic radii and nearly 30-fold increase in ANS fluorescence with respect to the native state, indicating that MG-state exists at pH 1.5 and not at pH 1.0. ITC measurements revealed that ANS molecules bound to chymopapain via hydrophobic interaction were more at pH 1.5 than at pH 1.0. However, a large number of ANS molecules were also involved in electrostatic interaction with protein at pH 1.0 which, together with hydrophobically interacted molecules, may be responsible for maximum ANS fluorescence. We conclude that maximum ANS-fluorescence alone may not be the criteria for determining the MG of chymopapain. Hence a comprehensive structural analysis of the intermediate is essentially required.     

Thermodynamic resolution of cytochrome P450 and characterization of an iron-sulfur center in rat liver microsomal preparations.

Binding of 8-anilinonaphthalene sulfonate (ANS) to glutamate dehydrogenase results in enzyme inhibition and a marked increase in the fluorescence of ANS. Perphenazine and GTP increase the fluorescence of ANS-glutamate dehydrogenase secondary to their known ability to alter the conformation of this enzyme. Aspartate aminotransferases, which form enzyme-enzyme complexes with glutamate dehydrogenase, produce a slight decrease in the fluorescence of ANS-glutamate dehydrogenase.While ANS and perphenazine are allosteric inhibitors of reactions catalyzed by free glutamate dehydrogenase, they do not inhibit reactions catalyzed by aminotransferaseglutamate dehydrogenase complexes. This is in spite of the fact that the aminotransferase does not prevent either ANS or perphenazine from being bound to glutamate dehydrogenase. Therefore, reactions catalyzed by the enzyme-enzyme complex are apparently not inhibited by ANS or perphenazine because binding of the aminotransferase to glutamate dehydrogenase prevents these ligands from altering the conformation of glutamate dehydrogenase. This is consistent with the fact that the aminotransferase also prevents perphenazine from enhancing the fluorescence of ANS-glutamate dehydrogenase.Reactions catalyzed by the enzyme-enzyme complex are inhibited by GTP and the aminotransferase does not prevent GTP from enhancing the fluorescence of ANS-glutamate dehydrogenase. Therefore, binding of the aminotransferase to glutamate dehydrogenase does not prevent GTP from altering the conformation of glutamate dehydrogenase.The fact that the aminotransferase completely prevents perphenazine from increasing the fluorescence of ANS-glutamate dehydrogenase suggests that in the enzymeenzyme complex each glutamate dehydrogenase polypeptide chain can be bound to an aminotransferase polypeptide chain. This would mean that three aminotransferase molecules can be bound to each monomeric unit (M_r 3 × 10⁵) of glutamate dehydrogenase.     

Response of an Escherichia coli-Bound Fluorescent Probe to Colicin E1

The fluorescent probe, 8-anilino-1-napthalenesulfonate (ANS) binds to Escherichia coli, showing an enhanced fluorescence. The interaction of colicin E1 with sensitive cells causes an increase of about 100% in the fluorescence of the bound ANS, and this change at equilibrium has an apparent "all-or-none" nature as a function of E1 multiplicity. Approximately 6 to 8% of the ANS is bound to the cells at equilibrium. The colicin E1-induced fluorescence increase can be attributed partly to an increase in ANS binding and partly to an increase in the fluorescence yield of the bound ANS. The kinetics of the E1-induced fluorescence increase in sensitive cells are very similar to those of the adenosine triphosphate decrease. The phosphorylation uncoupler p-trifluoromethoxy-carbonylcyanidephenylhydrazone also causes a large change in the fluorescence of bound ANS. Colicin E2 or E3 does not cause any fluorescence change, nor does colicin E1 cause fluorescence change with a colicinogenic strain. ANS appears to be a probe of structural or conformational change in the cell envelope that is closely associated with the colicin E1-induced adenosine triphosphate decrease.     

Temperature effects on 1,8-anilinonaphthalene sulfonic acid fluorescence with sarcolemma vesicles.

Increased temperature produces a red shift and decreased fluorescence intensity of the emission peak of 1,8-anilinonaphthalene sulfonic acid (ANS) in suspensions of biomembrane vesicles. These changes have been attributed to a conjectured increase in polarity of the microenvironment of ANS. If the conjecture is correct, fluorescence lifetimes must be decreased with warming. We showed than ANS binds to both protein and lipid protein of sarcolemma, that there are two kinds of sarcolemma-lipid ANS-binding sites, and that there are three fluorescence lifetimes of excited sarcolemma-bound ANS. The three fluroescence lifetimes were unchanged on warming, or decreased too little to account for the observations. Fluorescence lifetime data were consistent with the notion that the effect of increasing temperature is to decrease the amount of ANS bound to sarcolemma. From studies of liposomes prepared from lipid extracts of sarcolemma, and of proteins from sarcolemma it was deduced that warming reducted the amount of ANS bound to both of these sarcolemma components, probably mainly by reducing binding capacity. There might also be a shift of affinities such that the ratio, KA sarcolemma lipid/KA sarcolemma protein, is larger at higher temperature. Except at very small concentration ratios of ANS/sarcolemma, more than twice as much ANS was bound to sarcolemma lipids as to proteins.     

Use of a fluorescent probe for the study of the active center of D-glyceraldehyde-3-phosphate dehydrogenase]

The effect of NAD on the binding of 1-anilino-8-naphthalene sulfonate (ANS) to yeast glyceraldehyde-3-phosphate dehydrogenase has been studied using difference spectrophotometric and fluorescence techniques. Coenzyme addition causes the displacement of ANS from its complex with the dehydrogenase, as suggested by the effect of NAD on the fluorescence of the enzyme--ANS complex, as well as on the magnitude of the difference spectrum of the complex. Adenine containing NAD fragments, adenosine, 5'-AMP, and ADP were shown to compete with ANS for the common site on the enzyme using fluorimetric technique; in the case of adenosine and 5'-AMP a direct method of analytical ultracentrifugation was also employed. The results obtained by both methods suggest the dye binding at the adenine subsite of the dehydrogenase. The interaction with ANS causes no detectable conformational changes of the protein. The fluorescence of the dye-enzyme complex increases and the emission maximum shifts to shorter wavelengths on addition of nicotinamide mononucleotide. This suggest some conformational changes to occur in the microenvironment of the bound dye in response to the interaction with the ligand in the nicotinamide subsite. The participation of the nicotinamide subsite of the active center in determining the character of conformational transitions associated with coenzyme binding to glyceraldehyde-3-phosphate dehydrogenase is discussed.     

Neurite formation and membrane changes of mouse neurobalstoma cells induced by valinomycin

A clonal cell line of mouse neuroblastoma cells was found to undergo morphological differentiation in the presence of a K+ ionophore, valinomycin, in the assay medium. This effect was blocked by increasing the concentration of KCl of the medium, suggesting that the changes in resting membrane potential and ion fluxes may be involved in the mechanism of the formation of neurites. No enhancement of the neurite formation was observed in salines containing high concentrations of KCl in the absence of valinomycin. Depolarizing agents including veratridine, gramicidin and ouabain did not stimulate the outgrowth of neurites. Neither electrophoretic mobility of the cells nor molecular anisotropy of fluorescence probes in the membranes was modified by the treatment of valinomycin. Instead, it modified the slow binding phase in kinetics of the interaction of 1-anilinonaphthalene-8-sulfonate (ANS) with the cells, which is related to the penetration process of the probe into membranes. Valinomycin also enhanced the fluorescence intensity of ANS by increasing the binding sites in neuroblastoma cells.     

Active K+ transport in Mycoplasms mycoides var. Capri. Relationships between K+ distribution, electrical potential and ATPase activity.

The addition of 5 . 10(-5) M or less of dicyclohexylcarbodiimide to Mycoplasma mycoides var. Capri preferentially influences K+ influx rather than efflux and reduces by 30--40% the activity of the membrane-bound Mg2+- ATPase. Adding valinomycin to metabolizing cells does not markedly affect K+ distribution but induces a rapid and complete loss of intracellular K+ in non-metabolizing cells. Uncoupling agents such as dinitrophenol, carbonylcyanide p-trifluoromethoxyphenylhydrazone, dissipate the K+ concentration gradient only when combined with valinomycin. Variations in the merocyanine fluorescence intensity indicate that a transmembrane electrical potential (delta psi) is generated on cell energization. This delta psi, not affected by valinomycin or uncouplers when used alone, is collapsed by a mixture of both. No change in fluorescence intensity can be detected when glucose is added to dicyclohexylcarbodiimide treated organisms. These experiments suggest that the membrane-bound Mg-ATPase activity control K+ distribution in these organisms through the generation of a transmembrane electrical potential difference.     

Chemotaxis of Spirochaeta aurantia: involvement of membrane potential in chemosensory signal transduction.

The effects of valinomycin and nigericin on sugar chemotaxis in Spirochaeta aurantia were investigated by using a quantitative capillary assay, and the fluorescent cation, 3,3'-dipropyl-2,2'-thiodicarbocyanine iodide was used as a probe to study effects of chemoattractants on membrane potential. Addition of a chemoattractant, D-xylose, to cells in either potassium or sodium phosphate buffer resulted in a transient membrane depolarization. In the presence of valinomycin, the membrane potential of cells in potassium phosphate buffer was reduced, and the transient membrane depolarization that resulted from the addition of D-xylose was eliminated. Although there was no detectable effect of valinomycin on motility, D-xylose taxis of cells in potassium phosphate buffer was completely inhibited by valinomycin. In sodium phosphate buffer, valinomycin had little effect on membrane potential or D-xylose taxis. Nigericin is known to dissipate the transmembrane pH gradient of S. aurantia in potassium phosphate buffer. This compound did not dissipate the membrane potential or the transient membrane depolarization observed upon addition of D-xylose to cells in either potassium or sodium phosphate buffer. Nigericin did not inhibit D-xylose taxis in either potassium or sodium phosphate buffer. This study indicates that the membrane potential but not the transmembrane pH gradient of S. aurantia is somehow involved in chemosensory signal transduction.     

ANS fluorescence: Potential to discriminate hydrophobic sites of proteins in solid states

In the current study, ANS fluorescence was established as a powerful tool to study proteins in solid-state. Silk fibroin from Bombyx mori cocoons was used as a paradigm protein. ANS incorporated into the films of silk fibroin exhibits fluorescence with two-lifetime components that can be assigned to the patches and/or cavities with distinct hydrophobicities. Decay associated spectra (DAS) of ANS fluorescence from both sites could be fit to the single log-normal component indicating their homogeneity. ANS binding sites in the protein film are specific and could be saturated by ANS titration. ANS located in the binding site that exhibits the long-lifetime fluorescence is not accessible to the water molecules and its DAS stays homogeneously broadened upon hydration of the protein film. In contrast, ANS from the sites demonstrating the short-lifetime fluorescence is accessible to water molecules. In the hydrated films, solvent-induced fluctuations produce an ensemble of binding sites with similar characters. Therefore, upon hydration, the short-lifetime DAS becomes significantly red-shifted and inhomogeneously broadened. The similar spectral features have previously been observed for ANS complexed with globular proteins in solution. The data reveal the origin of the short-lifetime fluorescence component of ANS bound to the globular proteins in aqueous solution. Findings from this study indicate that ANS is applicable to characterize dehydrated as well as hydrated protein aggregates, amyloids relevant to amyloid diseases, such as Alzheimer's, Parkinson, and prion diseases.     

Relationship between ANS fluorescence and electrokinetic potential of activated lymphocytes.

An immune response was induced in vivo on C3H/He ♂ mouse strain with Bovine Serum Albumin (BSA), or Sheep Red Blood Cells (SRBC). The membrane fluorescence changes of activated splenic lymphocytes were studied two weeks after the injection of antigens. 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 antigens. Their fluorescence intensities were lower than control values. A maximum decrease of fluorescence was recorded on days 1, 6 and 9 after immunization with BSA-stimulated lymphocytes. SRBC-stimulated lymphocytes exhibited a maximum ANS fluorescence decrease on days 4 and 9 after immunization. These fluorescence phenomena would be in an inverse relationship with the electrokinetic surface potential of activated lymphocytes, as assessed by the electrophoretic mobility analysis (EPM). Some parameters affecting the ANS fluorescence in T and B cells are discussed. Quantification of hydrophobic sites in splenic cells would indicate that forces other than the hydrophobic ones may also be involved in the dye-binding changes following immune activation.     

A partially folded intermediate conformation is induced in pectate lyase C by the addition of 8-anilino-1-naphthalenesulfonate (ANS)

Addition of 8-anilino-1-naphthalenesulfonate (ANS) to acid-denatured pectate lyase C (pelC) leads to a large increase in the fluorescence quantum yield near 480 nm. The conventional interpretation of such an observation is that the ANS is binding to a partially folded intermediate such as a molten globule. Far-ultraviolet circular dichroism demonstrates that the enhanced fluorescence results from the induction of a partially folded protein species that adopts a large fraction of native-like secondary structure on binding ANS. Thus, ANS does not act as a probe to detect a partially folded species, but induces such a species. Near-ultraviolet circular dichroism suggests that ANS is bound to the protein in a specific conformation. The mechanism of ANS binding and structure induction was probed. The interaction of acid-unfolded pelC with several ANS analogs was investigated. The results strongly indicate that the combined effects of hydrophobic and electrostatic interactions account for the relatively high binding affinity of ANS for acid-unfolded pelC. These results demonstrate the need for caution in interpreting enhancement of ANS fluorescence as evidence for the presence of molten globule or other partially folded protein intermediates.     

Detection of ligand-induced conformation changes in lactate dehydrogenase by using fluorescent probes

The binding of ANS to apolactate dehydrogenase (apo-LDH) is accompanied by a 300-fold increase in dye fluorescence with a shift of the emission maximum from 515 to 479 nm, as well as by quenching of intrinsic protein fluorescence. A tetrameric LDH molecule has 6.4 +/- 1.6 non-interacting dye-binding sites with an association constant equal to (4.3 +/- 1.6) X 10(3) M-1. NAD+ added at saturating concentrations does not alter the number of ANS binding sites or the association constant value. The formation of binary LDH.NAD+, LDH.NADH, LDH.AMP and LDH.pyruvate complexes causes the quenching of fluorescence of the enzyme-bound ANS. The extent of quenching observed at ligand saturating concentrations differs for each ligand. Pyruvate added to the binary LDH.AMP complex exerts no effect on the fluorescence of protein-bound ANS; this indicates that the binding of AMP causes some alterations in the microenvironment of the substrate-binding site. Nicotinamide mononucleotide (NMN) can act as a coenzyme in the LDH-catalyzed reaction. AMP added together with NMN displays an inhibitory effect. The cationic (auramine O) and anionic (ANS) fluorescent probes bound to LDH exhibit different responses to conformational changes accompanying the transition from the apoenzyme to the LDH X NAD-pyruvate complex.     

A hydrophobic region on myosin light chains modulated by divalent cations

A hydrophobic region was detected on several types of myosin light chain by enhancement of the quantum yield of 1-anilino-8-naphthalenesulfonate (ANS) fluorescence. The character of this non-polar region was altered by the binding of Ca2+ or Mg2+ to the light chain, the quantum yield of the ANS being increased, and its emission maximum undergoing a blue-shift. These changes enabled the binding of divalent cations to the myosin light chains to be monitored. When Ca2+ was bound to gizzard regulatory light chain, a biphasic enhancement of light-chain-bound ANS fluorescence occurred, the first phase taking place in the micromolar range and the second in the millimolar range of free Ca2+ concentration. Enhancement of protein-bound ANS fluorescence as divalent cations were bound was also observed with other types of myosin light chain.     

Increase in lipid microviscosity of unilamellar vesicles upon the creation of transmembrane potential

Summary Diffusion potential of potassium ions was formed in unilamellar vesicles of phosphatidyl choline. The vesicles, which included potassium sulfate buffered with potassium phosphate, were diluted into an analogous salt solution made of sodium sulfate and sodium phosphate. The diffusion potential was created by the addition of the potassium-ionophore, valinomycin. The change in lipid microviscosity, ensuing the formation of membrane potential, was measured by the conventional method of fluorescence depolarization with 1,6-diphenyl-1,3,5-hexatriene as a probe. Lipid microviscosity was found to increase with membrane potential in a nonlinear manner, irrespective of the potential direction. Two tentative interpretations are proposed for this observation. The first assumes that the membrane potential imposes an energy barrier on the lipid flow which can be treated in terms of Boltzmann-distribution. The other interpretation assumes a decrease in lipid-free volume due to the pressure induced by the electrical potential. Since increase in lipid viscosity can reduce lateral and rotational motions, as well as increase exposure of functional membrane proteins, physiological effects induced by transmembrane potential could be associated with such dynamic changes.