Alignment of anilinonaphthalene-sulfonate and related fluorescent probe molecules in squid axon membrane and in synthetic polymers

As a fluorescent probe for the squid axon membrane, the behavior of 1-anilinonaphthalene-8-sulfonate (1,8-ANS) was found to be very different from that of its positional isomer, 2,6-ANS, or of the methylated derivative, 2,6-TNS. The degree of polarization of the fluorescent light contributing to a transient intensity reduction during nerve excitation was larger than about 0.7 for both 2,6-ANS and 2,6-TNS, while the corresponding value for 1,8-ANS in a squid axon was about 0.35.The physicochemical basis of this difference was investigated by measuring the fluorescence polarization of these probe molecules incorporated into poly(vinyl alcohol) sheets. In a stretched sheet of this synthetic polymer, 1,8-ANS showed poor alignment, while the 2,6-derivatives were highly oriented with their transition moments aligned approximately in the direction of stretching. Based on these findings, the experimental results obtained from squid axons were interpreted as an indication of the existence, at or near the membrane, of a longitudinally oriented macromolecular structure, bringing about a high degree of alignment of 2,6-ANS or 2,6-TNS molecules.It is clear that, as a probe for fluorescence polarization studies of macromolecular structures, 2,6-TNS is far superior to 1,8-ANS.     

Application of ANS fluorescent probes to identify hydrophobic sites on the surface of DREAM

DREAM (calsenilin or KChIP-3) is a calcium sensor involved in regulation of diverse physiological processes by interactions with multiple intracellular partners including DNA, K_v4 channels, and presenilin, however the detailed mechanism of the recognition of the intracellular partners remains unclear. To identify the surface hydrophobic surfaces on apo and Ca^2 +DREAM as a possible interaction sites for target proteins and/or specific regulators of DREAM function the binding interactions of 1,8-ANS and 2,6-ANS with DREAM were characterized by fluorescence and docking studies. Emission intensity of ANS–DREAM complexes increases upon Ca^2 + association which is consistent with an overall decrease in surface polarity. The dissociation constants for ANS binding to apoDREAM and Ca^2 +DREAM were determined to be 195 ± 20 μM and 62 ± 4 μM, respectively. Fluorescence lifetime measurements indicate that two ANS molecules bind in two independent binding sites on DREAM monomer. One site is near the exiting helix of EF-4 and the second site is located in the hydrophobic crevice between EF-3 and EF-4. 1,8-ANS displacement studies using arachidonic acid demonstrate that the hydrophobic crevice between EF-3 and EF-4 serves as a binding site for fatty acids that modulate functional properties of K_v4 channel:KChIP complexes. Thus, the C-terminal hydrophobic crevice may be involved in DREAM interactions with small hydrophobic ligands as well as other intracellular proteins.     

Detection of energy transfer between tryptophan residues in the tubulin molecule and bound bis(8-anilinonaphthalene-1-sulfonate), an inhibitor of microtubule assembly, that binds to a flexible region on tubulin

The fluorescent apolar probe bis(8-anilinonaphthalene-1-sulfonate) (Bis-ANS) is a potent inhibitor of microtubule assembly that binds to tubulin at a hitherto uncharacterized site distinct from those of the antimitotic drugs. We have found that energy transfer between tryptophan residues and bound Bis-ANS leads to quenching of the intrinsic tubulin fluorescence. The quenching is biphasic, implying two types of Bis-ANS binding sites. The estimated Kd values are 2.7 and 22.2 microM, consistent with reported values for the primary and secondary Bis-ANS binding sites. Preincubation of tubulin at 37 degrees C results in increased quenching of tryptophan fluorescence without any effect on the Kd values, suggesting localized structural change in the protein around the Bis-ANS binding sites. Concentration-dependent depolarization of Bis-ANS fluorescence was observed, suggesting energy transfer among bound Bis-ANS molecules. Such a concentration-dependent decrease in fluorescence polarization was not observed with 8-anilinonaphthalene-1-sulfonate (1,8-ANS), the monomeric form of Bis-ANS. Perrin-Weber plots were obtained for bound Bis-ANS and 1,8-ANS by varying the viscosity with sucrose. The rotational relaxation times calculated for Bis-ANS and 1,8-ANS are 18 and 96 ns, respectively. Comparison with the theoretical value (125 ns) suggests that Bis-ANS binds to a flexible region of tubulin. This, coupled with the fact that Bis-ANS, but not 1,8-ANS, inhibits microtubule assembly, suggests that the region in the tubulin molecule responsible for microtubule assembly is relatively flexible.     

Bis(1,8-anilinonaphthalenesulfonate). A novel and potent inhibitor of microtubule assembly

Two related compounds, 1,8-anilinonaphthalenesulfonate (1,8-ANS) and bis(1,8-anilinonaphthalenesulfonate) (Bis-ANS), are useful fluorescent probes for hydrophobic areas on protein molecules. Using fluorescence, we examined the binding of these compounds to bovine brain tubulin and found that Bis-ANS and 1,8-ANS bound to tubulin with Ki values of 2 and 25 microM, respectively. Bis-ANS potently inhibited the polymerization of tubulin into microtubules in vitro. In the presence of microtubule-associated protein 2, half-maximal inhibition of assembly was obtained at 3 microM Bis-ANS. In the presence of tau protein, half-maximal inhibition was obtained at 15 microM Bis-ANS. Surprisingly, 1,8-ANS, even at 200 microM, did not inhibit assembly. Scatchard analysis indicated one binding site for Bis-ANS on tubulin. Previous reports of 1,8-ANS binding to tubulin may have been influenced by the presence of Bis-ANS which until recently was a common contaminant of commercial supplies. Because of its intense fluorescence in addition to its potent inhibitory effects, Bis-ANS appears to be a useful probe to study microtubule assembly and other interactions involving tubulin.     

A comparative analysis of extrinsic fluorescence in nerve membranes and lipid bilayers

Changes in extrinsic fluorescence intensity, associated with step changes in membrane potential, have been studied in intracellularly or extracellularly stained squid axons, and in lipid bilayers, using six different aminonaphthalene dyes: 1,8-TNS; 2,6-TNS; 1,8-MANS; 2,6-MANS; 2,6-ANS and NPN. In all preparations the optical signals were found to be roughly proportional to the voltage applied. All signals had a very fast initial component, which was followed in some case by a slower change in the same direction. The slow component was observed only in intracellularly stained axons, and not for all chromophores studied. 1,8-TNS, 1,8-MANS and 2,6-MANS yielded the largest fluorescence signals in all preparations. The sign of these signals was independent of the type of membrane studied. However, the fluorescence changes of 2,6-MANS were opposite to those of 1,8-TNS and 1,8 MANS. Staining of both sides of the axolemma with 1,8-MANS or 2,6-MANS showed that these dyes yield larger signals when applied to the extracellular face. The changes in fluorescence light intensity of 2,6-TNS, 2,6-ANS and NPN were smaller and their sign depended on the membrane preparation studied. The comparison of the extrinsic fluorescence signals from the nerve membrane and the phosphatidylcholine bilayer suggests strong similarities between the basic structures of the two systems. The variety of observed signals cannot be easily interpreted in terms of changes in membrane structure. A possible alternative interpretation in terms of electrically induced displacements, rotations and changes in partition coefficient of bound chromophores, is discussed.Abbreviations 1,8-TNS 1-toluidinonaphthalene-8-sulfonate, and similarly, 2,6-TNS - 1,8-MANS 1-N-methylanilinonaphthalene-8-sulfonate, and similarly, 2,6-MANS - 1,8-ANS 1-anilinonaphthalene-8-sulfonate, and similarly, 2,6-ANS - NPN N-phenyl-1-naphthylamine     

Quantitative aspects of the development of a hydrophobic binding site on calmodulin by calcium binding

The interactive binding by calmodulin of Ca²⁺ and 1-anilinonaphthalene-8-sulfonate (1,8-ANS) has been examined. In the presence of saturating levels of Ca²⁺, calmodulin develops one moderately strong binding site for 1,8-ANS, plus one or more weaker sites. The binding of 1,8-ANS by unliganded, or singly liganded, calmodulin is slight; the development of a strong binding site, as well as the characteristic fluorescence enhancement and CD spectrum, requires the binding of two Ca²⁺ ions. Little further change occurs on binding additional Ca²⁺ ions.     

Ligand-induced thermostability in proteins: thermodynamic analysis of ANS-albumin interaction

A comparative thermodynamic study of the interaction of anilinonaphthalene sulfonate (ANS) derivatives with bovine serum albumin (BSA) was performed by using differential scanning calorimetry (DSC) and isothermal titration calorimetry (ITC). The chemically related ligands, 1,8-ANS and 2,6-ANS, present a similar affinity for BSA with different binding energetics. The analysis of the binding driving forces suggests that not only hydrophobic effect but also electrostatic interactions are relevant, even though they have been extensively used as probes for non-polar domains in proteins. Ligand association leads to an increase in protein thermostability, indicating that both dyes interact mainly with native BSA. ITC data show that 1,8-ANS and 2,6-ANS have a moderate affinity for BSA, with an association constant of around 1-9x10(5) M(-1) for the high-affinity site. Ligand binding is disfavoured by conformational entropy. The theoretical model used to simulate DSC data satisfactorily reproduces experimental thermograms, validating this approach as one which provides new insights into the interaction between one or more ligands with a protein. By comparison with 1,8-ANS, 2,6-ANS appears as a more "inert" probe to assess processes which involve conformational changes in proteins.     

Dietary cholesterol caused modification in the structure and function of rat hepatic microsomes, studied by fluorescent probes

A 4% cholesterol diet fed to rats for four weeks was found to increase the phospholipid and cholesterol contents and the activities of drug metabolizing enzymes in rat liver microsomes.Microsomes from rats on a high cholesterol diet were able to enhance the fluorescence of membrane bound 1-anilinonaphthalene 8-sulphonate (1,8-ANS) and ethidium bromide more than microsomes from rats on a standard diet.In the case of 1,8-ANS, the enhanced fluorescence was found to be due to the increased affinity of the molecules for microsomes. In the case of ethidium bromide the fluorescence increased partly because of the larger amount of binding sites and partly because of the enhanced quantum yield of the molecules.P-nitrophenol was found to compete with 1,8-ANS for the same binding sites in microsomes. On the other hand, 1,8-ANS lowered the rate of drug metabolism when present in the incubation mixture.In vitro treatments of microsomes with trypsin, phospholipase A or digitonin altered the binding properties of 1,8-ANS and ethidium bromide to microsomes.It is concluded that the binding sites of 1,8-ANS in microsomes are important for the activity of drug-metabolizing enzymes. The mechanisms of dietary cholesterol in enhancing the drug metabolism and the role of microsomal phospholipids in regulating the activity of drug-metabolizing enzymes are discussed.     

Properties of the complexes formed by 1-anilinonaphthalene-8-sulfonate with phosphorylase kinase and calmodulin

Phosphorylase kinase contains four approximately equivalent binding sites for 1-anilinonaphthalene-8-sulfonate (1,8-ANS). Measurements of the time decay of fluorescence anisotropy have failed to give any indication of internal degrees of rotational freedom involving a significant portion of the tertiary structure. In the presence of 1 mM Ca²⁺, calmodulin binds one molecule of 1,8-ANS. No binding occurs in the absence of Ca²⁺. The binding is strongly temperature-dependent, a decrease in binding occurring with increasing temperature. Determinations of the time decay of fluorescence anisotropy indicate the presence of internal rotations, which become more important with increasing temperature. Complex formation between phosphorylase kinase and calmodulin reduces the binding of 1,8-ANS.     

Location of a binding site for 1-anilinonaphthalene-8-sulfonate on calmodulin

The quenching by radiationless energy transfer of the ultraviolet fluorescence of Tyr-99 and Tyr-138 by bound 1-anilinonaphthalene-8-sulfonate (1,8-ANS) has been employed to determine the separation of a hydrophobic binding site of 1,8-ANS from each of the tyrosines. The results suggest that the dominant binding site is located in the N-terminal region of domain III.     

Fluorescence Decay Time Distribution Analysis Reveals Two Types of Binding Sites for 1,8-Anilinonaphthalene Sulfonate in Native Human Oxyhemoglobin

Binding of 1,8-anilinonaphthalene sulfonate (1,8-ANS) with native human oxyhemoglobin (Hb) in 50 mM potassium phosphate buffer (pH 7.4) was studied by steady state fluorescence spectroscopy and by laser spectrofluorimetry with subnanosecond time resolution. The distribution of fluorescence decay times and parameters of two- and three-exponential deconvolution of the fluorescence kinetics of 1,8-ANS in Hb solution demonstrate that the emission at wavelengths _em of 455-600 nm is not single-exponential and has components with mean decay times <0.5, 3.1-5.5, and 12.4-15.1 nsec with the amplitudes depending on the emission wavelength. Analysis of time-resolved fluorescence spectra shows that the shortest-lived component should be assigned to 1,8-ANS molecules in the aqueous medium, whereas the two longer-lived components are assigned to two types of binding sites for 1,8-ANS in the Hb molecule characterized by different polarity and accessibility to water molecules.     

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.     

Photophysics of ANS. III: Circular dichroism of ANS and anilinonaphthalene in I-FABP

We investigate the circular dichroism of the I-FABP system with the ligands ANS (1,8-anilinonaphthalene sulfonate) and AnN (anilinonaphthalene) as previously reported in our earlier publications in the series (referred to as I and II here) on ANS photophysics. We employ our semi-empirical calculated spectral functions (from II) to compute the actual CD spectra, without any additional assumptions or data except what we have previously presented with respect to binding geometry (in I). The common mechanisms fail to produce the observed spectra. However, we identify a novel mechanism of induced CD activity, which does succeed. This new mechanism also suggests how it is that near UV CD can often show extreme sensitivity to local 'order' effects.     

1,8-Anilinonaphthalene sulfonate binds to central cavity of human hemoglobin

Binding of 1,8-anilinonaphthalene sulfonate (1,8-ANS) to main (HbA(1)) and glycosylated (HbA(1C)) forms of human oxyhemoglobin in the presence/absence of inositolhexaphosphate (IHP) in 50 mM potassium phosphate buffer, pH 7.4, was studied by time-correlated single photon counter with subnanosecond time resolution. The redistribution of contributions of the most long-lived and the most short-lived fluorescent decay components in the presence of IHP provides an evidence of the probe binding within oxyhemoglobin central cavity, namely DPG-binding site. Finally, it was shown that the fluorescent probe is extremely sensitive for hemoglobin central cavity modification, provided by the carbohydrate moiety in case of 1,8-ANS interactions with HbA(1C).     

Identification of a novel ligand binding motif in the transthyretin channel

The design of therapeutic compounds targeting transthyretin (TTR) is challenging due to the low specificity of interaction in the hormone binding site. Such feature is highlighted by the interactions of TTR with diclofenac, a compound with high affinity for TTR, in two dissimilar modes, as evidenced by crystal structure of the complex. We report here structural analysis of the interactions of TTR with two small molecules, 1-amino-5-naphthalene sulfonate (1,5-AmNS) and 1-anilino-8-naphthalene sulfonate (1,8-ANS). Crystal structure of TTR:1,8-ANS complex reveals a peculiar interaction, through the stacking of the naphthalene ring between the side-chain of Lys15 and Leu17. The sulfonate moiety provides additional interaction with Lys15′ and a water-mediated hydrogen bond with Thr119′. The uniqueness of this mode of ligand recognition is corroborated by the crystal structure of TTR in complex with the weak analogue 1,5-AmNS, the binding of which is driven mainly by hydrophobic partition and one electrostatic interaction between the sulfonate group and the Lys15. The ligand binding motif unraveled by 1,8-ANS may open new possibilities to treat TTR amyloid diseases by the elucidation of novel candidates for a more specific pharmacophoric pattern.     

Testing of the portal hypothesis: analysis of a V32G, F57G, K58G mutant of the fatty acid binding protein of the murine adipocyte

The portal region of fatty acid binding proteins is hypothesized to function as a dynamic aperture, controlling accessibility of external ligands to the internal fatty acid binding cavity. To test this hypothesis, a triple mutant of the murine FABP4 has been developed (V32G, F57G, K58G, referred to as the portal mutant) that is predicted to constitutively enlarge the opening due to a reduction in the molecular dimensions of the side chains of key portal amino acids. The portal mutant was purified from expressing Escherichia coli, its stability was evaluated, and the thermodynamics and kinetics of ligand binding were compared to that of wild-type protein. Introduction of the three amino acid substitutions caused no significant change in the stability of the protein with a free energy of unfolding of 13.7 kJ/mol as compared to 14.0 kJ/mol for the wild-type protein. The portal mutant exhibited a modest decrease (4-fold) in ligand binding affinity using the fluorescent probe 1-anilinonaphthalene-8-sulfonic acid (1,8-ANS) as a surrogate ligand. 1,8-ANS displacement assays revealed that the binding affinity for oleate increased from a K0.5 of 196 +/- 15 nM for the wild-type protein to 165 +/- 8 for the portal mutant, while that for arachidonate decreased from the wild type of 186 +/- 11 nM to 418 +/- 26 nM for the portal mutant. To evaluate cavity accessibility, rate of 1,8-ANS binding was assessed between the portal and wild-type protein. Using equimolar amounts of ligand and protein at 4 degrees, 1,8-ANS bound within the cavity to 95% saturation (t0.95) in 750 ms, while the mutant protein was fully modified in less than 1.4 ms. To independently evaluate cavity accessibility, modification of the sole protein cysteine residue, C117 residing within the cavity near C2-C4 of the bound ligand, was monitored using 5,5'-dithio-bis(2-nitrobenzoic acid) modification. The half time for modification (t0.5) for the wild-type protein was approximately 20 s, while that for V32G F57G K58G occurred in less than a second. As such, enlargement of the portal region of FABP4 markedly increased the accessibility of ligands to the cavity while having only modest effects on ligand affinity. Taken together, these data provide support for the portal region hypothesis and suggest dynamic fluctuations in this region regulate cavity access, but not ligand affinity or selectivity.     

Use of fluorescence decay times of 8-ANS-protein complexes to study the conformational transitions in proteins which unfold through the molten globule state

The conformational transitions starting with the native protein, passing the molten globule state and finally approaching the unfolded state of proteins was investigated for bovine carbonic anhydrase B (BCAB) and human -lactalbumin (-HLA) by means of fluorescence decay time measurements of the dye 8-anilinonaphthalene-1-sulphonic acid (8-ANS). Stepwise denaturation was realized by using the denaturant guanidinium chloride (GdmCl). It was shown that 8-ANS bound with protein yields a double-exponential fluorescence decay, where both decay times considerably exceed the decay time of free 8-ANS in water. This finding reflects the hydrophobic environment of the dye molecules attached to the proteins.

The fluorescence lifetime of the short-time component is affected by protein association and can be effectively quenched by acrylamide, indicating that 8-ANS molecules preferentially bind at the protein surface. The fluorescence lifetime of the long-time component is independent of the protein and acrylamide concentration and may be related to protein-embedded dye molecules.

Changes of the long lifetime component upon GdmCl-induced denaturation and unfolding of BCAB and -HLA correlate well with overall changes of the protein conformation. The transition from native protein to the molten globule state is accompanied by an increase of the number of protein-embedded 8-ANS molecules, while the number of dye molecules located at the protein surface decreases. For the transition from the molten globule to the unfolded state was the opposite behaviour observed.     

Orientation and rotational freedom of fluorescent probes in lecithin bilayers

Summary The fluorescence polarization properties of lecithin bilayers stained with 2,6-MANS and 1,8-ANS under applied potential steps have been studied. The fluorescence signal components of both dyes were found to have different sign and relative amplitude, suggesting that 1,8-ANS and 2,6-MANS behave differently when bound to black lipid membranes. In order to determine the location and the extent of rotational brownian motions of the bound chromophores, the experimental data were analyzed by using a simplified physico-mathematical model. According to it 2,6-MANS appears to have a ratio /gt higher than 1,8-ANS ( being the rotational relaxation of in plane rotations and the lifetime of the excited singlet state of the bound molecules), suggesting that the former chromophore is more tightly held inside the bilayers. Furthermore, 2,6-MANS is found to possess the absorption and emission oscillators more closely oriented to the normal of membrane surface, while 1,8-ANS has both oscillators almost near the plane of the bilayers. The results furnish also a fair estimate of the random molecular motion own by the phospholipid molecules at room temperature. The comparison of the present data with those obtained from squid axon membranes confirms the validity of the proposed physical model, yielding a rough estimate of the axon membrane-area covered by integral protein macromolecules. These preliminary results derived from lecithin model membranes suggest that fluorescence polarization techniques can provide valuable informations if applied to study the macromolecular organization of in vitro reconstituted membranes.Abbreviations 2,6-MANS 2-n-methylanilinonaphthalene-6-sulfonate - 1,8-ANS 1-anilinonaphthalene-8-sulfonate     

Fluorescence studies on the interaction of myoglobin with mitochondria

To determine the nature and characteristic parameters of the myoglobin-mitochondrion interaction during oxymyoglobin (MbO₂) deoxygenation in the cell, we studied the quenching of the intrinsic mitochondrial flavin and tryptophan fluorescence by different liganded myoglobins in the pH range of 6–8, as well as the quenching of the fluorescence of the membrane probes 1,8-ANS and merocyanine 540 (M 540) embedded into the mitochondrial membrane. Physiologically active MbO₂ and oxidized metmyoglobin (metMb), which are unable to bind oxygen, were used as the quenchers. The absence of quenching of flavin and tryptophan fluorescence implies that myoglobin does not form quenching complexes with either electron transport chain proteins of the inner mitochondrial membrane or with outer membrane proteins. We found, however, that MbO₂ and metMb effectively quench 1,8-ANS and M 540 fluorescence in the pH range of 6–8. Characteristic parameters of 1,8-ANS and M 540 fluorescence quenching by the myoglobins (extent of quenching and quencher binding constant, K _m) are very similar, indicating that both probes are localized in phospholipid sites of the mitochondrial membrane, and myoglobin is complexed with these sites. The dependence of K _m on ionic strength proves the important role of coulombic interactions in the formation of the quenching complex. Since the overall charge of myoglobin is shown not to influence the K _m values, the ionic strength dependence must be due to local electrostatic interactions in which polar groups of some part of the myoglobin molecule participate. The most likely candidates to interact with anionic groups of mitochondrial phospholipids are invariant lysine and arginine residues in the environment of the myoglobin heme cavity, which do not change their ionization state in the pH range investigated.