Reactions of fluorescent probes with normal and chemically modified myelin.

The fluorescent probes 8-anilino-1-naphthalenesulfonate (ANS) and 2-p-toluidinylnaphthalene-6-sulfonate (TNS) bind to highly purified myelin membranes obtained from bovine brain white matter. Binding of the dyes was markedly increased by environmental conditions which reduce the negative surface potential of the membrane, i.e., cations (La-3+ is greater than Ca-2+ is greater than Na-+,K-+), H-+, local anesthetics, and the antibiotic polymyxin B. Chemical alteration of accessible membrane charged groups affected dye binding in a manner consistent with the hypothesis that such binding is primarily dependent upon the membrane surface potential. Thus, binding was increased by blocking of carboxyl groups via carbodiimide activation and subsequent coupling with neutral amino acid esters, and even more so with a basic amino acid ester (e.g., arginine methyl ester). Dye binding was reduced by succinylation of amino groups, and by hydrolysis of choline and ethanolamine head groups of phospho- and sphingolipids by phospholipase C. Phospholipase C treatment of myelin, or sphingomyelin vesicles, reduced or abolished the augmentation of ANS and TNS binding due to cations, local anesthetics, or polymyxin B. Energy transfer from myelin tryptophan residues to bound ANS occurs, but with low efficiency. Oxidation of membrane tryptophan residues with N-bromosuccinimide, or alkylation with 2-hydroxy (or methoxy)-5-nitrobenzyl bromide, markedly reduced intrinsic membrane fluorescence and energy transfer to bound ANS, but did not significantly affect dye binding or the quantum yield of ANS fluorescence when excitation was at 380nm. Proteolytic digestion removed 6-30% of myelin protein, depending upon the enzyme used, but had no effect on fluorescent dye binding. It is concluded that the binding of the anionic fluorescent probes ANS and TNS to myelin is primarily a function of the membrane surface charge density and net surface potential, as is the case with other biological membranes. Conclusions about the degree of dye binding to membrane lipids or membrane proteins cannot be drawn unless additional studies are carried out on isolated water soluble membrane proteins.     

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

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

Interaction of prostaglandins and fatty acids with native and acetaldehyde-alkylated proteins

Using intrinsic and probe fluorescence, microcalorimetry and isotopic methods, the interactions of prostaglandins (PG) E2 and F2 alpha and some fatty acids with native and alkylated proteins (human serum albumin (HSA) and rat liver plasma membrane PG receptors), were studied. The fatty acid and PG interactions with human serum albumin (HSA) resulted in effective quenching of fluorescence of the probe, 1.8-anilinonaphthalene sulfonate (ANS), bound to the protein. Fatty acids competed with ANS for the binding sites; the efficiency of this process increased with an increase in the number of double bonds in the fatty acid molecule. PG induced a weaker fluorescence quenching of HSA-bound ANS and stabilized the protein molecule in a lesser degree compared to fatty acids. The sites of PG E2 and F2 alpha binding did not overlap with the sites of fatty acid binding on the HSA molecule. Nonenzymatic alkylation of HSA by acetaldehyde resulted in the abnormalities of binding sites for fatty acids and PG. Modification of the plasma membrane proteins with acetaldehyde sharply diminished the density of PG E2 binding sites without changing the association constants. Alkylation did not interfere with the parameters of PG F2 alpha binding to liver membrane proteins.     

Further studies of nerve membranes labeled with fluorescent probes

Summary By using the technique of intracellular perfusion combined with fluorescence measurements, the mode of binding of 6-p-toluidinylnaphthalene-2-sulfonate (2–6 TNS) in a squid giant axon was examined. The apparent dissociation constant for the binding sites in axons was found to be roughly 0.22mm. Out of approximately 5×10¹⁴ molecules/cm² of 2–6 TNS bound to the sites in and near the axonal membrane, roughly 2×10¹⁰ molecules/cm² are shown to contribute to a transient decrease in fluorescence during nerve excitation. By recording fluorescence signals with a polarizer and analyzer inserted in four different combinations of orientations, studies were made of the directions of the transition moments of various probe molecules relative to the longitudinal axis of the axon. Among hydrophobic probes examined, the polarization characteristics of the fluorescence signals obtained with 1–8 derivatives of aminonaphthalenesulfonate (1-8 ANS, 1-8 TNS and 1-8 AmNS) were found to be very different from those obtained with 2–6 derivatives (2-6 ANS, 2-6 TNS and 2-6 MANS). A tentative interpretation is proposed to account for this difference in physiological behavior between 1–8 and 2–6 derivatives. It is emphasized that measurements of fluorescence polarization yield significant information concerning the structure of the axonal membrane.     

Membrane effects of aminoglycoside antibiotics measured in liposomes containing the fluorescent probe, 1-anilino-8-naphthalene sulfonate

The mechanism of membrane disturbance by aminoglycoside antibiotics was investigated in liposomes containing the fluorescent probe, 1-anilino-8-naphthalene sulfonate (ANS). Liposomes of PC and different anionic phospholipids (1:1 to 15:1 molar ratios) were challenged with aminoglycosides in the presence of low (1 microM) and high (3 mM) concentrations of calcium. Liposomes containing PIP2 showed the greatest drug-induced changes in ANS fluorescence in the presence of high and low concentrations of calcium and at all PC:PIP2 molar ratios tested. Liposomes containing other anionic phospholipids (PS, PI and PIP) were not reactive toward aminoglycosides in the presence of 3 mM calcium or when the ratio of PC to anionic lipid was increased to 10:1. The aminoglycoside-induced changes of ANS fluorescence were not due to any changes in the emission spectrum of ANS, nor to changes in quantum yield, nor to a change in the binding affinity of ANS. It is concluded that a specific aminoglycoside-PIP2 interaction results in phase separation of PC and PIP2 and thus increases the number of available ANS binding sites in PC:PIP2 liposomes.     

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

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

Binding of hydrophobic ligands to plant lectins: Titration with arylaminonaphthalenesulfonates

Binding of the Hydrophobic ligands 1,8-anilinonaphthalenesulfonic acid (ANS) and 2,6-toluidinylnaphthalenesulfonic acid (TNS) to a variety of plant lectins was studied by lectin-induced alteration of the fluorescence spectra of the two ligands. With one exception, all legume lectins examined bound ANS, with affinity constants ranging from 10³ to 10⁴ M^?1. Similar ANS binding was noted for some nonlegume lectins. Titration of the five isolectins from Phaseolus vulgaris with ANS indicated positive cooperative binding of ANS to the two isolectins E₄ and E₃L₁. Titrations with TNS revealed high-affinity sites for this ligand in a number of lectins. Addition of haptenic sugars did not inhibit binding of ANS, suggesting that the hydrophobic binding sites of lectins are independent of the carbohydrate binding sites.     

Interaction of the fluorescent probe, 1-anilino-8-napthalene sulfonate, with the sulfate transport system of Ehrlich ascites tumor cells.

The addition of the fluorescent dye, ANS, to intact ascites tumor cells results in an enhancement of fluorescence intensity. The increase in fluorescence intensity as a function of time is biphasic which suggests that at least two processes occur. The first associated with the rapid initial rise in fluorescence represents binding to the cell surface while the second or slower phase reflects entrance of ANS into the intracellular phase. The relationship between bound and free ANS in 0.50 mM sulfate medium was used to calculate the apparent dissociation constant of ANS-membrane complex (Kd = 6.53 times 10(-5) M) and the total number of ANS binding sites (4.49 nmoles/mg dry weight). Kinetic analysis of steady state sulfate transport in the presence and absence of ANS suggests that (1) sulfate exchange can be described by Michaelis Menten type kinetics (Km = 2.05 times 10(-3) M), (2) a small fraction of surface associated ANS competitively inhibits sulfate exchange (Ki = 4.28 times 10(-6) M) and (3) the transport system has a higher affinity for ANS than for sulfate. These data are consistent with the hypothesis that inhibition of sulfate exchange is related to the direct, reversible interaction of the negatively charged sulfonate group of ANS with superficial positively charged membrane sites.     

Structural properties of the membrane of intact human spermotozoa: A study with fluorescent probes

The properties of the membrane of intact, metabolically active, human persmatozoa have been studied by the use of 1-anilino-8-napthalene sulfonate (ANS). By fluorescence microscopy it was found that at neutral pH ANS is bound exclusively to the membrane of the entire sperm with some preferential binding to the midpiece, while at low pH some preferential binding to the aerosome was observed. By spectrofluorimetry, fluorescence was found to be enhanced 48-fold on binding of ANS to the spermatozoal membrane, with a 50-nm shift in the emission spectrum of the bound dye. $\text{2.47 ± 0.02}$ nmoles of ANS were bound per 10⁶ spermatozoa ($\text{K=2.3–10}{}^{\mathrm{?5}}\text{M}$). Scatchard plots indicate that all the binding sites on the spermatozoal membrane have similar binding characteristics with aZ value of 84.8. Energy transfer with an efficiency of 7% was found for recently ejaculated spermatozoa. The fluorescence of bound ANS depends on the pH of the medium and possibly on the metabolic state of the cell, since addition of succinate or fructose produces an enhancement of fluorescence, while addition of glucose results in a decrease of this parameter. These changes are inhibited by the presence of cyanide.     

Thymocytes of irradiated rats studied using naphthalenesulfonic probes

The fluorescence intensity of 1.8-aniline naphthalene sulfonate (ANS) and 2.6-toluidine naphthalene sulfonate (TNS) introduced into irradiated rat thymocytes reached maximum 15 min and 4 h following irradiation (1-20 Gy). The parameters of 1.8-ANS binding to membranes did not contribute markedly to the effect observed.     

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.     

Membrane permeability transition promoted by phosphate enhances 1-anilino-8-naphthalene sulfonate fluoresence in calcium-loaded liver mitochondria

Phosphate and a number of other compounds induce membrane permeability transition (MBT) in Ca²⁺-loaded mitochondria. 1-Anilino-8-naphthalene sulfonate (ANS) was used as a fluorescent probe to investigate perturbations on the inner membrane during MBT. Induction of MBT caused ANS fluoresence enhancement with a biphasic rate that reached a plateau. The enhancement is analogous to that reported for de-energization of mitochondria. The fluoresence level was independent of whether ANS was added before or at different times after phosphate. In the absence of ANS, fluorescence was low and remained unchanged. The initial time course of MBT, as followed by large-amplitude swelling, was similar to that of fluorescence enhancement. Ruthenium red, EGTA, ADP, and cyclosporin A inhibited the enhancement. Only EGTA + ADP (or ATP) reversed the enhancement when added after phosphate. Efflux of matrix Ca²⁺ by sodium acetate or A23187 did not alter ANS fluoresence. The binding parameters (K _d and number of binding sites) were not significantly different, but the fluorescence maximum was more than doubled after MBT. Although the flourescence of bound ANS showed a nonlinear relationship, it was always higher (73.0 +/- 19.0%) after reaching the plateau. Since ANS binding to membranes is nonspecific, the exact mechanism of the enhanced fluorescence is not apparent. The dependence of the initial rate of fluorescence enhancement on Ca²⁺ concentration was nonlinear, with 45 µM at half-maximal rate. The dependence on phosphate was hyperbolic with 0.7 mM at half-maximal rate, which is close to theK _m value of phosphate carrier. The kinetics is compatible with Ca²⁺ binding to some membrane component(s) during MBT and cause ANS fluorescence enhancement. It is suggested that the bilayer-nonbilayer (hexagonal₁₁) transition consequent to Ca²⁺ binding to proteinphospholipid domains containing cardiolipin may play a role in fluorescence enhancement and MBT.     

Human aglycosyl-IgG exhibits increased hydrophobicity. Binding/fluorescence studies with 8-anilinonaphthalene-1-sulfonic acid (ANS)

Human monoclonal, aglycosyl-IgG produced in vitro in the presence of tunicamycin, was compared with its native and acid pH-altered counterparts for their respective abilities to bind the fluorescent hydrophobicity probe, 8-anilinonaphthalene sulfonate. A novel technique based on continuous-flow dynamic dialysis (Sparrow et al., 1982, Anal. Biochem. 123:255-264) allowed binding studies under non-equilibrium conditions. While the native IgG conformation exhibits two, weak ANS binding sites (ca. 10(3) l/mol), aglycosyl-IgG has one weak and one moderate affinity (least squares average Ka = 2 X 10(4) l/mol) site, and the acid conformer binds yet another two ANS molecules with moderate affinity (4 X 10(4) l/mol). Increases in affinity and in the number of sites correlate roughly with increased relative percent fluorescence by conventional fluorimetry. The fluorescence lifetime of ANS bound to altered IgGs is about 10% longer (T2 = 15 nsec by time-resolved fluorimetry) than that for native IgG. All populations also exhibit a rapid decay component (T1 = 3 nsec) analogous to that seen for ANS in 50% aqueous dioxane. Results are discussed in relation to structural role(s) for IgG-linked heterosaccharides.     

Detection of conformational changes in chloroplast coupling factor 1 by 8-anilino-1-naphthalene-sulphonate fluorescence changes

Chloroplast coupling factor 1 (CF1) contains a high-affinity binding site for 8-anilino-1-napthalene sulphonate (ANS,Kd = 5-6 microM). The binding of ANS to the enzyme is associated with a fluorescence enhancement and a blue-shift in the emission spectrum. ANS only slightly inhibits ATP hydrolysis by CF1. Adenine nucleotides and inorganic phosphate induce a fast ANS fluorescence quenching of about 50% which is due to a decrease in the affinity of the enzyme for ANS (Kd increases from 6 microM to 22 microM) and in the fluorescence quantum yield of the bound probe (by 33%) but not in the number of ANS sites (n = 1). Conversely, Mg and Ca ions induce a fluorescence enhancement of bound ANS. Inactivation of the enzyme enhances ANS fluorescence, eliminates the response to adenine nucleotides and inorganic phosphate but increases the response to divalent metals. The affinity of latent CF1 for ADP (Kd = 12 microM) is considerably higher than for ATP (Kd = 95 microM) in buffer containing EDTA. The Kd for inorganic phosphate is 140 microM. Mg increases the apparent affinity for ATP (Kd = 28 microM) but not for ADP or Pi. Binding of ATP to the tight-sites does not inhibit the ADP or Pi-induced fluorescence quenching but decreases the affinity for ADP (Kd = 34 microM) and for inorganic phosphate (Kd = 320 microM). These results suggest that the ADP and phosphate binding sites are different but not independent from the tight sites. Activation of a Mg-specific ATPase in CF1 by octyl glucoside decreases the affinity for ADP and inorganic phosphate by about threefold but increases the affinity for ATP. ATPase activation of CF1 also increases the Ki for ADP inhibition of ATP hydrolysis. ATPase activation also influences the ANS responses to Ca and Mg. Ca-ATPase activation increases the fluorescence enhancement and the apparent affinity for Ca whereas Mg-ATPase activation specifically increases the Mg-induced fluorescence enhancement. The fluorescence of CF1-bound ANS is enhanced by Dio-9 and quenched by phloridzin, quercetin, Nbf-Cl and FITC. Nbf-Cl and FITC completely inhibit the ADP-induced fluorescence quenching whereas Dio-9 inhibits the Mg-induced fluorescence enhancement. ANS does not relieve the quercetin or phloridzin inhibition of ATP hydrolysis indicating that these inhibitors do not compete with ANS for a common binding site. ANS may be used, therefore, as a sensitive probe to detect conformational changes in CF1 in response to activation or inactivation and to binding of substrates and of inhibitors.     

ANS fluorescence: potential to augment the identification of the external binding sites of proteins

8-anilino-1-naphthalenesulfonic acid (ANS) is believed to strongly bind cationic groups of proteins and polyamino acids through ion pair formation. A paucity of data exists on the fluorescent properties of ANS in these interactions. ANS binding to arginine and lysine derivatives was studied by fluorescence and circular dichroism spectroscopies to augment published information attained by isothermal titration calorimetry (ITC). Fluorescence enhancement with a hypsochromic shift results from the interaction of the charged group of lysine and arginine with the sulfonate group of ANS. Ion pairing between Arg (or Lys) and the sulfonate group of ANS reduce the intermolecular charge transfer (CT) rate constant that leads to enhancement of fluorescence. A positive charge near the -NH group of ANS changes the intramolecular CT process producing a blue shift of fluorescence. The Arg side chain compared to that of Lys more effectively interacts with both the -NH and sulfonate groups of ANS. ANS binding also induces a random coil-alpha helix transition in poly-Arg. Our data, in contrast to ITC results, indicate that electrostatic interactions between ANS derivatives and positively charged side chains do not account for binding affinity in the micromolar range. In addition to ion pairing complementary interactions, such as van der Waals, should be considered for high affinity (K(d)<1 mM) external binding sites of proteins.     

Mechanism of inhibition of Ca2+-transport activity of sarcoplasmic reticulum Ca2+-ATPase by anisodamine

The mechanism of inhibition of Ca2+-transport activity of rabbit sarcoplasmic reticulum Ca 2+-ATPase (SERCA) by anisodamine (a drug isolated from a medicinal herb Hyoscyamuns niger L) was investigated by using ANS (1-anilino-8-naphthalenesulfonate) fluorescence probe, intrinsic fluorescence quenching and Ca 2+-transport activity assays. The number of ANS binding sites for apo Ca2+-ATPase was determined as 8, using a multiple-identical binding site model. Both anisodamine and Ca2+ at millimolar level enhanced the ANS binding fluorescence intensities. Only anisodamine increased the number of ANS molecules bound by SERCA from 8 to 14. The dissociation constants of ANS to the enzyme without any ligand, with 30 mM anisodamine and with 15 mM Ca 2 were found to be 53.0 microM, 85.0 microM and 50.1 microM, respectively. Both anisodamine and Ca2+ enhanced the ANS binding fluorescenc with apparent dissociation constants of 7.6 mM and 2.3 mM, respectively, at a constant concentration of the enzyme. Binding of anisodamine significantly decreased the binding capacity of Ca2+ with the dissociation constant of 9.5 mM, but binding of Ca2+ had no obvious effect on binding of anisodamine. Intrinsic fluorescence quenching and Ca2+-transport activity assays gave the dissociation constants of anisodamine to SERCA as 9.7 and 5.4 mM, respectively, which were consistent with those obtained from ANS-binding fluorescence changes during titration of SERCA with anisodamine and anisodamine + 15 mM Ca2+, respectively. The results suggest that anisodamine regulates Ca2+-transport activity of the enzyme, by stabilizing the trans-membrane domain in an expanded, inactive conformation, at least at its annular ring region.     

Fluorescence study of lymphocyte plasma membranes]

ANS binding parameters--dissociation constant, number of binding sites, rotation freedom--are measured by fluorescence studies of a complex between ANS and lymph node cell plasma membranes. Divalent ions, Mg++ and Ca++, enhance the complex fluorescence intensity without shifting its maximum wavelength : this enhancement is induced by affinity and quantum yield increases, while the number of binding sites remains constant. The complex fluorescence quenching by ethacrynic acid shows the presence of free SH groups in the ANS binding site. An energy transfer takes place between membrane protein tryptophan residues and bound ANS ; the energy transfer yield is unaffected by Ca++ ions. A correlation of these results is postulated with the biological activity of the membrane.     

Interaction of native and modified Naja melanoleuca phospholipases A2 with the fluorescent probe 8-anilinonaphtalene-1-sulfonate

The fluorescent probe 8-anilinonaphtalene-1-sulfonate (ANS) binds at the active site of the Naja melanoleuca snake venom phospholipase A2, thus protecting the enzyme against active-site-directed chemical modification. Both hydrophobic and electrostatic interactions are involved in the binding. At pH 7.5, a binding constant of 100 microM was determined, which improved twofold upon addition of the enzymatic cofactor Ca2+. The pH dependence of the ANS binding in the absence and presence of Ca2+ ions showed a perturbation of a group with a pKa value of 5.2, which could be assigned to the carboxylate group of the Ca2+-binding ligand Asp49 at the active site of the protein. Monomeric concentrations of the substrate analog n-decylphosphocholine displace ANS from the protein, indicating again that both ligands bind at the active site. Binding studies with several modified N. melanoleuca enzymes showed that a loss of enzymatic activity on aggregated substrates was correlated with a loss of affinity for the active site bound ANS molecule. It is suggested therefore, that the fluorescent ANS probe can detect structural rearrangements at the active site, which are important for enzymatic activity.     

Investigation of the interaction of pig muscle lactate dehydrogenase with acidic phospholipids at low pH

Interaction of pig muscle lactate dehydrogenase (LDH) with acidic phospholipids is strongly dependent on pH and is most efficient at pH values<6.5. The interaction is ionic strength sensitive and is not observed when bilayer structures are disrupted by detergents. Bilayers made of phosphatidylcholine (PC) do not bind the enzyme. The LDH interaction with mixed composition bilayers phosphatidylserine/phosphatidylcholine (PS/PC) and cardiolipin/phosphatidylcholine (CL/PC) leads to dramatic changes in the specific activity of the enzyme above a threshold of acidic phospholipid concentration likely when a necessary surface charge density is achieved. The threshold is dependent on the kind of phospholipid. Cardiolipin (CL) is much more effective compared to phosphatidylserine, which is explained as an effect of availability of both phosphate groups in a CL molecule for interaction with the enzyme. A requirement of more than one binding point on the enzyme molecule for the modification of the specific activity is postulated and discussed. Changes in CD spectra induced by the presence of CL and PS vesicles evidence modification of the conformational state of the protein molecules. In vivo qualitative as well as quantitative phospholipid composition of membrane binding sites for LDH molecules would be crucial for the yield of the binding and its consequences for the enzyme activity in the conditions of lowered pH.     

Asymmetric membrane expansion and modification of active and passive cation permeability of human red cells by the fluorescent probe 1-anilino-8-napththalene sulfonate.

1. The membrane perturbations induced by the interaction of the fluorescent probe 1-anilino-8-naphthalene sulfonate (ANS) with human red blood cells were studied. 2. ANS below 0.5 mM inhibits partially (20% maximum) the ouabain-insensitive Na+ and K+ influx and efflux. Above 0.5 mM ANS increases both Na+ and K+ leak fluxes. The increased cation leaks are larger for Na+ than K+. 3. The (Na+ +K+)-ATPase and ouabain-sensitive Na+ and K+ fluxes are inhibited by ANS. Ouabain-insensitive, Mg2+-dependent ATPase activity of ghosts is stimulated by [ANS] less than 0.3 mM and inhibited by [ANS] greater than 0.3 mM. 4. ANS also inhibits the Na+-dependent, ouabain-insensitive K+ influx that is inhibited by ethacrynic acid and furosemide. 5. Red cells become crenated with [ANS] less than 1 mM and sphere at [ANS] greater than 1 mM. In the former conditions hypotonic hemolysis is decreased whereas the latter increase osmotic fragility. 6. It is suggested that ANS expands the membrane asymmetrically by binding preferentially to the external membrane surface. 7. It is concluded that ANS is a general inhibitor of ion transport, particularly of those processes thought to involve facilitated-diffusion mechanisms. The increased cation leaks observed at high ANS concentrations may be related to prehemolytic membrane disruption. 8. The membrane perturbations caused by ANS are compared to those caused by other reversible inhibitors of anion exchange in red blood cells. Their possible modes of action are discussed.