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     

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.     

Orientation and rotational freedom of fluorescent probes in lecithin bilayers.

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 rho/tau higher than 1.8-ANS (rho being the rotational relaxation of in plane rotations and tau 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.     

Fluorescence polarization studies of squid giant axons stained with N-methylanilinonaphthalenesulfonates.

The polarized components of the extrinsic fluorescence of squid giant axons stained with 2,6-MANS or 1,8-MANS were studied. The polarization properties of the fluorescence changes associated with voltage-clamp pulses were found to be very different from those of the static fluorescence, supporting the notion that the optical changes involve highly oriented membrane adsorbed fluorophores. The theoretical expectations according to this hypothesis are discussed in detail. The experimental results are in good agreement with the theory assuming that possible probes reorientations are soley due to the action of the applied electric field upon the probes electric dipole. The quantitative analysis of the data for 2,6-MANS provides a fairly accurate determination of the orientation of the membrane bound 2,6-MANS molecules responsible for the fluorescence changes. Such orientation appears to be independent of the membrane face exposed to staining. The data for 1,8-MANS indicate a very different orientation of this isomer. The results suggest a profitable use of extrinsic fluorophores for studies of the structural organization of nerve membranes.     

Fluorescence polarization studies of squid giant axons stained with N-methylanilinonaphthalenesulfonates

The polarized components of the extrinsic fluorescence of squid giant axons stained with 2,6-MANS or 1,8-MANS were studied. The polarization properties of the fluorescence changes associated with voltage-clamp pulses were found to be very different from those of the static fluorescence, supporting the notion that the optical changes involve highly oriented membrane adsorbed fluorophores. The theoretical expectations according to this hypothesis are discussed in detail. The experimental results are in good agreement with the theory assuming that possible probes reorientations are solely due to the action of the applied electric field upon the probes electric dipole. The quantitative analysis of the data for 2,6 MANS provides a fairly accurate determination of the orientation of the membrane bound 2,6-MANS molecules responsible for the fluorescence changes. Such orientation appears to be independent of the membrane face exposed to staining. The data for 1,8-MANS indicate a very different orientation of this isomer. The results suggest a profitable use of extrinsic fluorophores for studies of the structural organization of nerve membranes.     

Effect of pulse electromagnetic radiation on erythrocyte ghosts

The pulse microwave radiation has been shown to increase the fluorescence intensity of 2-toluidinonaphthanene-6-sulfonate (2,6-TNS) and 1-anilinonaphthalene-8-sulfonate (1,8-ANS) built-in membranes of erythrocyte ghosts. In experiments with 2,6-TNS a frequency dependence of the effect of microwave radiation with maximum within the frequency range of 55-65 Hz has been found. It is suggested that the changes registered with fluorescent probes are induced by mechanical oscillations generated by the pulse microwave radiation.     

Circular dichroism of N-phenylnaphthylamine derivatives complexed with the β-form of poly(L-lysine)

Complex formation of 1-anilinonaphthalene-8-sulfonate (ANS) and 2-p-toluidinonaphthalene-6-sulfonate (TNS) with the β-form of poly(L -lysine) [(β-Lys)_n] has been studied by circular dichroism (CD) and absorption spectra measurements. Not only hydrophobic interactions but also hydrogen-bonding and electrostatic interactions contribute to complex formation. The relative importance of these stabilizing factors depends on the relative position of the arylamino group and the sulfonate. For example, ionic interactions play a significant role in the binding of 1,8-ANS and 1,8-TNS, but not in the case of 2,6-TNS. The induced CD of the complexes of (β-Lys)_n with 1,8-ANS and 1,8-TNS is consistent with theoretical calculations for nonplanar conformations of these dyes, twisted in a left-handed sense. As expected for steric reasons, the dominant isomer is one in which the arylamino group is oriented away from the 8-sulfonate (α₁). The induced CD of complexes with 2,6-TNS can be accounted for by an equimolar mixture of left-handed isomers in which the arylamino group is oriented toward the 1-position (β₂) and toward the 3-position (β₁). Our results demonstrate that (β-Lys)_n is capable of chiral discrimination and suggest its general utility for CD studies of racemic anionic dyes.     

Spectral analyses of extrinsic fluorescence of the nerve membrane labeled with aminonaphthalene derivatives

A fluorescence spectrophotometer was constructed to determine the emission spectrum of a nerve labeled with various fluorochromes. Using this spectrophotometer, the spectra of 2-p-toluidinylnaphthalene 6-sulfonate (2,6-TNS) and other aminonaphthalene derivatives in squid giant axons were determined at the peak of nerve excitation, as well as in the resting state of the axons. During nerve excitation the fluorescent light deriving from the 2,6-TNS-stained nerve undergoes a transient change in intensity. The spectrum of the light contributing to this change in intensity was found to be much narrower and sharper than the fluorescent spectrum of the light arising from labeled axons at rest. This narrow and sharp spectrum is interpreted as being derived from a transient variation in the polarity of the 2,6-TNS binding sites in the axon. In the Appendix, the results of a physicochemical investigation into the factors affecting the fluorescence of 2,6-TNS in vitro are described.     

Monitoring of chemical and enzymatic hydrolysis of water-soluble proteins using flow-injection analysis with fluorescence detection and an aqueous eluant containing 2-p-toluidinylnaphthalene-6-sulfonate as the fluorescent probe

The exposed hydrophobicity of proteins, which is due to the hydrophobic regions located on their surfaces, enhances the fluorescence intensity of the probe 2-p-toluidinylnaphthalene-6-sulfonate (2,6-TNS) by the formation of a complex. During the hydrolysis of a protein, the average exposed hydrophobicity of the substrate continuously changes with incubation time, and these changes are immediately reflected by a corresponding change in the fluorescence intensity of the 2,6-TNS/substrate complex. Therefore, 2,6-TNS seems to be a good probe to monitor the course of the depolymerization processes of proteins. In this work, bovine serum albumin and alpha-casein have been hydrolyzed both chemically and enzymatically, and the course of the reactions is monitored by using flow-injection analysis (FIA) with fluorescence detection and a buffered aqueous eluant containing 2,6-TNS as the fluorescent probe. Results indicate that the time evolution of the fluorescence intensity of the 2,6-TNS/substrate complex can be correlated with the initial concentration of the parent protein, in mass per unit volume, the hydrolytic activity added, and the time evolution of the mean chain length of the substrate. In addition, because the time elapsed between injection of the sample into the FIA system and measurement of the corresponding fluorescence intensity is only a few seconds, this methodology could be a useful tool for on-line monitoring of processes for the production of protein hydrolysates.     

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.     

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.     

Photoacoustic analysis of proteins: volumetric signals and fluorescence quantum yields.

A series of proteins has been examined using time-resolved, pulsed-laser volumetric photoacoustic spectroscopy. Photoacoustic waveforms were collected to measure heat release for calculation of fluorescence quantum yields, and to explore the possibility of photoinduced nonthermal volume changes occurring in these protein samples. The proteins studied were the green fluorescent protein (GFP); intestinal fatty acid binding protein (IFABP), and adipocyte lipid-binding protein (ALBP), each labeled noncovalently with 1-anilinonaphthalene-8-sulfonate (1,8-ANS) and covalently with 6-acryloyl-2-(dimethylamino)naphthalene (acrylodan); and acrylodan-labeled IFABP and ALBP with added oleic acid. Of this group of proteins, only the ALBP labeled with 1,8-ANS showed significant nonthermal volume changes at the beta = 0 temperature (approximately 3.8 degrees C) for the buffer used (10 mM Tris-HCI, pH 7.5) (beta is the thermal cubic volumetric expansion coefficient). For all of the proteins except for acrylodan-labeled IFABP, the fluorescence quantum yields calculated assuming simple energy conservation were anomalously high, i.e., the apparent heat signals were lower than those predicted from independent fluorescence measurements. The consistent anomalies suggest that the low photoacoustic signals may be characteristic of fluorophores buried in proteins, and that photoacoustic signals derive in part from the microenvironment of the absorbing chromophore.     

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.     

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.     

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.     

A fluorescent probe study of salmine AI

A fluorescent probe, 1-p-toluidinylnapthalene-8-sulfonate (1,8-TNS), was used to study the nonpolar sites on salmine AI. Fluorescence enhancement resulting from binding between the probe and the protein occurs at a wavelength of maximum emission of 497-500 nm, indicating the existence of moderately nonpolar binding sites on salmine AI.Fluorescence enhancement decreases as the ionic strength of the solvent is increased from 0.002 M to 0.050 M. Fluorescence increases with increasing acidity although this effect is not correlated to the pKa of 1,8-TNS. Positive cooperative binding takes place between 1,8-TNS and salmine AI. Equilibrium dialysis indicates that binding occurs only under conditions resulting in significant fluorescent enhancement. The binding was also studied using thin film dialysis, which is much faster than equilibrium dialysis and avoids the observed changes in probe-protein interaction that occur over long time periods with the latter system.     

Structural changes in erythrocyte ghosts after irradiation and the initiation of lipid oxidation detectable using 2,6-TNS and fluorescamine

It was shown on erythrocyte ghosts that the parameters of fluorescence of 2,6-toluidine-naphthalene-sulfonate (2,6-TNS) and fluorescamine undergo similar changes after irradiation. After a dose of 100 Gy the equally effective concentrations of Fe2+ were 1-5 microM and 50-100 microM with regard to changes in the rate of fluorescence of fluorescamine and 2,6-TNS, respectively, and greater than 100 microM with regard to fluorescence anisotropy.     

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.     

Study of the structural changes in irradiated erythrocyte membranes using 2,6-toluidinonaphthalene sulfonate

It was shown that 2,6-tolyidinonaphthalene sulfonate (2,6-TNS) is localized mainly at the bilayer-water border of the erythrocytic membranes. Under the effect of gamma-radiation the rearrangements occur in the membrane which bring about changes in the distribution of the probe between the membrane and the medium. The lifetime of the excited state of 2,6-TNS after irradiation varies slightly.