Na~(+)、Ca~(2+)、Cu~(2+)和Zn~(2+)与HSA相互作用的~(23)(Na)-NMR研究

 本文应用~23Na-NMR波谱技术,研究了Na~(+)、Ca~(2+)、Cu~(2+)和Zn~(2+)与人体血清白蛋白(HSA)的相互作用。在实验基础上,通过引入两位快交换模型,拟合计算获得了Na~(+)与HSA相互作用的结合常数和处于结合状态Na~(+)的相关时间;实验表明Ca~(2+)能与Na~(+)竞争同HSA结合,拟合计算获得了两者与HSA相互作用结合常数的比值,棕榈酸钠能增强Ca~(2+)同Na~(+)竞争与HSA结合的能力;从实验上未能观察到Cu~(2+)、Zn~(2+)能同Na~(+)竞争与HSA相互作用的证据。     

Interaction of alkaline metal ions with Ca(2+)-binding sites of Ca(2+)-ATPase of sarcoplasmic reticulum: 23Na-NMR studies.

The analysis of the 23Na-NMR signal shape variations in the presence of vesicles of light sarcoplasmic reticulum (SR) shows the existence of sodium sites on the membranes with Kd values of about 10 mM. Other monovalent cations displace Na+ from SR fragments in a competitive manner according to the row K+ greater than Rb+ greater than Cs+ greater than Li+. Calcium ions also reduce Na+ binding, the Na+ desorption curve being of a two-stage nature, which, as suggested, indicates the existence of two types of Ca(2+)-sensitive Na+ binding sites (I and II). Sites of type I and II are modified by Ca2+ in submicromolar and millimolar concentrations, respectively. Analysis of sodium (calcium) desorption produced by calcium (sodium) allowed us to postulate the competition of these two cations for sites I and identity of these sites to high-affinity Ca(2+)-binding ones on the Ca(2+)-ATPase. Sites I weakly interact with Mg2+ (KappMg approximately 30 mM). Reciprocal effects of sodium and calcium on binding of each other to sites II cannot be described by a simple competition model, which indicates nonhomogeneity of these sites. A portion of sites I (approximately 70%) interacts with Mg2+ (KappMg = 3-4 mM). The pKa value of sites II is nearly 6.0. The number of sites II is three times greater than that of sites I. In addition, sites with intermediate affinity for Ca2+ were found with Kd values of 2-5 microM. These sites were revealed due to the reducing of the sites II affinity for Na+ upon Ca2+ binding to SR membranes. It can thus be concluded that in nonenergized SR there are binding sites for monovalent cations of at least three types: (1) sites I (which also bind Ca2+ at low concentrations), (2) magnesium-sensitive sites II and (3) magnesium-insensitive sites II.     

Specificity of Na+ binding to phosphatidylserine vesicles from a 23Na NMR relaxation rate study.

23Na NMR relaxation rate measurements show that Na+ binds specifically to phosphatidylserine vesicles and is displaced partially from the binding site by K+ and Ca2+ but to a considerably less extent by tetraethylammonium ion. The data indicate that tetraethylammonium ion affects the binding of Na+ only slightly, by affecting the surface potential through its presence in the double layer, without competing for a phosphatidylserine binding site. Values for the intrinsic binding constant for the Na+-phosphatidylserine complex that would be consistent with the competition experiments (and the dependence of the relaxation rate on concentration of free Na+) fall in the range 0.4--1.2 M-1 with a better fit towards the higher values. We conclude that in the absence of competing cations in solution an appreciable fraction of the phosphatidylserine sites could be associated with bound Na+ at 0.1 M Na+ concentration.     

Relative affinities of divalent polyamines and of their N-methylated analogues for helical DNA determined by 23Na NMR

Interactions of divalent polyamines with double-helical DNA in aqueous solution are investigated by monitoring the decrease in 23Na NMR relaxation rates as NaDNA is titrated with H3N(+)-(CH2)m-+NH3, where m = 3, 4, 5, or 6. Analogous measurements are made for the same homologous series of methylated polyamines (methonium ions). The dependence of the 23Na relaxation rates on the amount of added divalent cation (M2+) is analyzed quantitatively in terms of a two-state model. The sodium ions are assumed to be in rapid exchange between a "bound" state, where they are close enough to DNA so that it affects their relaxation rate, and a "free" state in bulk solution, where their relaxation rate is the same as in solutions containing no DNA. The distribution of Na+ and M2+ between these states is described quantitatively in terms of an ion-exchange parameter: DM = (pMB)(1-pNaB)n/(pNaB)n(1-pMB), where pNaB and pMB are the fractions of Na+ and M2+ that are close enough to DNA to be considered bound (by the NMR criterion), and n is the number of sodium ions displaced from DNA by the binding of one M2+ ion. For each of the polyamines and methonium ions investigated here, equations derived from this two-state model yield acceptable fittings of the titration curves if roNa, the number of sodium ions bound per DNA phosphate when no competing cations are present, is assigned a value between 0.6 and 1.00. Within this range, changing the value assigned to roNa does change the best-fitted values of DM determined for these polyamines (DH) and for the methonium ions (DMe) but does not alter the following conclusions about the trends in these parameters. (1) For polyamines and methonium ions of the same m, DH exceeds DMe by factors that are significantly larger for m = 3 and 4 than for m = 5 and 6. (2) DH for m = 3 and 4 is larger than DH for m = 5 and 6. (3) DMe for m = 3 and 4 is smaller than DMe for m = 5 and 6.     

Ion binding to cytochrome c studied by nuclear magnetic quadrupole relaxation.

The enhancement of the 35Cl- transverse relaxation rate on binding of chloride ions to oxidized and reduced cytochrome c has been studied under conditions of variable sodium chloride concentration, temperature, pH, sodium phosphate, iron hexacyanide, and sodium cyanide concentration. The results revealed the presence of a strong binding site(s) for chloride in both oxidized and reduced cyt c, with a higher affinity in ferrocytochrome c. Competition experiments suggest that these sites also bind iron hexacyanide and phosphate. Cyanide binding to the iron in ferricytochrome c at alkaline and neutral pH was shown to decrease the binding of chloride. The pH dependence of the 35Cl- relaxation rate has been fitted by using literature pK values for ionizable groups. No indications of Na+ binding to oxidized and reduced cytochrome c have been observed by using 23Na+ NMR. Our results suggest that chloride is bound near the exposed heme edge and that the surface structure or dynamics in this region are different in the two oxidation states.     

Analysis of sodium-23 nuclear magnetic resonance spin-lattice relaxation for the study of the intracellular sodium state.

Sodium-23 Nuclear Magnetic Resonance relaxation spectroscopy has been used to investigate the state of intracellular Na+ in control and CCl4-treated rat livers. The analysis of spin-lattice relaxation rates at 1.88 and 7.07 Tesla based on a two-site exchange model led to estimates of pertinent modulation times. Also it has been found that a relatively high quantity of Na+ (PB = 1.59 x 10(-2)) is bound to charged sites of intracellular macromolecules or membranes. The degree of binding strongly decreases in CCl4 treated rat livers.     

Sodium-23 NMR spin-lattice relaxation rate studies of mono- and bis-intercalation in DNA

23Na spin-lattice relaxation rate (1/T1 = R1) measurements have been used to study the intercalation of a series of 9-aminoacridine derivatives in DNA. The 23Na relaxation rate is strongly dependent upon the amount of intercalator added to a sodium DNA solution. The results are analyzed by a combined use of the ion condensation theory and the quadrupolar relaxation theory of polyelectrolyte solutions. This interpretation shows that the major effect in lowering the relaxation rate by intercalation is not due to the release of sodium ions but is caused by a substantial decrease in the relaxation rate Rb for the remaining bound sodium ions. Likewise, titration of NaDNA solutions with MgCl2 shows that condensation of Mg2+ on the DNA double helix reduces Rb. A good agreement between experiment and theory is found if the average lengthening following intercalation of a 9-aminoacridine moiety is assumed to be approximately 2.7 A. The distinction between mono- and bis-intercalation is clearly indicated by the results. The two bis-intercalating drugs examined are found to bis-intercalate only up to r less than or equal to 0.02. For r greater than 0.02 the drugs apparently mono-intercalate.     

Interaction of alkali metal ions with Ca2+-binding center of Ca2+- ATPase of the sarcoplasmic reticulum in skeletal muscles

Sodium ion interaction with sarcoplasmic reticulum (SR) membranes leads to considerable alterations of the [23Na]NMR lineshape. Na+ binding to SR in the presence of Ca2+ and H+ is well described by a model which postulates a competitive ion binding to high and low affinity sites of Ca2+-ATPase. The dissociation constant, Kd, for high and low affinity sites is 5 and 10 mM, respectively, for Na+ and (3-5).10(-8) and 1.5.10(-3) M, respectively, for Ca2+. The pK value for high and low affinity sites is 7.3 and 6.1, respectively. Other alkaline metal ions compete with Na+ for the low affinity sites of Ca2+-ATPase; their affinities decrease in the following order: Na+ = K+ greater than Rb+ greater than Cs greater than Li+. Some of the Na+ binding sites (approximately 10%) do not interact with Ca2+.     

Association-dissociation equilibria of Octopus hemocyanin

The equilibria between the native (decameric) Octopus hemocyanin and its subunits were studied by analytical sedimentation. Equilibrium is obtained slowly, but the reaction is thermodynamically reversible. The mass action law for a monomer-decamer reaction is obeyed. The reassociated hemocyanin is virtually identical in its sedimentation behavior and oxygen binding with the native protein. The association-dissociation equilibria are mediated by cations; Mg2+, Ca2+, Na+, and H+ are all effective in stabilizing the decameric form at appropriate concentrations. About three to four cations per monomer must be bound for association to occur. Under some conditions, dimers of the subunits can be observed, but formation of this dimer does not depend on cation concentration, and it does not appear to be an obligate intermediate in the association to decamer.     

Interaction of lanthanide ions with Panulirus interruptus hemocyanin: Evidence for vicinity of some of the cation binding sites

The interaction of a number of lanthanide ions (namely terbium, praseodymium, erbium, lanthanum, gadolinium and europium) with Panulirus interruptus hemocyanin has been studied.Results from O₂-binding experiments indicate that all these ions may substitute for calcium as allosteric effectors of hemocyanin. Addition of the lanthanides to deoxygenated Panulirus hemocyanin saturated with Tb³⁺ results in a quenching of the terbium luminescence. The highly efficient quenching observed in the case of Eu³⁺ may indicate energy-transfer between Tb³⁺ and Eu³⁺. Since energy-transfer between lanthanides is only effective over very short distances, the data suggest that some of the cation binding sites of Panulirus hemocyanin are clustered.     

The divalent cation-binding sites of gramicidin A transmembrane ion-channel.

The conductance of the gramicidin A single channels in glycerolmonooleate membranes is strongly reduced in the presence of Mn2+ cations. The nmr experiments were performed for N-terminal to N-terminal gramicidin A dimer formed by two right-handed single-stranded helixes incorporated into the sodium dodecyl sulfate micelles in the presence of Mn2+ ions. Dependence of the nonselective spin-lattice relaxation rates of the gramicidin A protons on Mn2+ concentration was analyzed to determine coordinates of the divalent cation binding sites. It is inferred that Mn2+ ions are bound at the channel mouths at distances of 6.4, 8.6, and 8.8 A (+/- 2 A) from the oxygen atoms of exposed carbonyl groups of D-Leu 12, 14, and 10, respectively. The bounded Mn2+ retains its hydrate shell, the size of which (approximately 6 A) exceeds the inner pore diameter (approximately 4 A). That makes the gramicidin A channel impermeable for divalent cations.     

Stabilizing influence of calcium and magnesium ions on the decameric structure of chiton hemocyanins

The stabilizing effects of Ca2+ and Mg2+ ions on the decameric structure of hemocyanins from two representative chitons, Stenoplax conspicua and Mopalia muscosa were investigated by light-scattering molecular weight measurements, ultracentrifugation, absorbance, and circular dichroism methods. The dissociation profiles at any given pH resulting from the decrease in divalent ion concentration, investigated at a fixed protein concentration of 0.1 g.liter-1, could be fitted by a decamer-to-dimer-to monomer scheme of subunit dissociation. The initial decline in the light-scattering molecular weight curves required one or two apparent binding sites per hemocyanin dimer formed as intermediate dissociation product, with apparent dissociation constants (kD,2) for Ca2+ ions of 0.7 to 7 X 10(-4) M, not very different from the value of 2.5 X 10(-4) M obtained by Makino by equilibrium dialysis for the hemocyanin of the opistobranch, Dolabella auricularia. The binding of Mg2+ ion to S. conspicua and M. muscosa hemocyanins appears to be both weaker than the binding of Ca2+ and more pH dependent, with kD,2 values ranging from the 3 X 10(-4) to 4 X 10(-2) M at pH 8.5 to 9.5. The dissociation the decameric hemocyanin species (sedimentation coefficient ca. 60 S) is also observed in the ultracentrifugation with the initial appearance of 18-20 S dimers, followed by a shift in equilibrium to monomeric species of lower sedimentation rates of 11-12 S as the divalent ion concentration is reduced below 1 X 10(-4) M Ca2+ and Mg2+. The dissociation of dimers to monomers in the second step of the reaction is characterized by one or two binding sites per subunit and a somewhat stronger affinity for divalent ions, indicated by apparent dissociation constants (kD,1) of 0.7 X 10(-4) to 3 X 10(-3) M. Circular dichroism and absorbance measurements at 222 and 346 nm suggest no significant changes in the conformation of the hemocyanin subunits produced by the different stages of subunit dissociation.     

Calcium binding to bile salts

Calcium binding to bile salt monomers and micelles is an important issue with respect to the possible (but rare) precipitation of calcium bile salts in the gallbladder. In the present work the binding of Ca2+ to six bile salts was measured in solutions containing 2 to 100 mM bile salts by means of a calcium-sensitive dye, murexide, which determines the ionic calcium concentration. In solutions containing bile salt at concentration higher than 20 mM most, if not all, of the bound Ca2+ is associated with micellar surfaces. The results were analyzed by employing a model which combines specific binding with electrostatic equations and accounts for the system being a closed one. The analysis of Ca2+ binding data considered explicitly the presence of Na+ ions and yielded intrinsic binding coefficients for Ca2+ and Na+ which were utilized to explain and predict binding results for various concentrations of Ca2+, Na+ and bile salts. The calculations indicate that in saline solutions most of the surface sites were bound by Na+, whereas less than 10% were bound by Ca2+ even in the presence of 8 mM Ca2+. The binding of Ca2+ to bile salt micelles increases with pH. An increase in temperature results in reduced binding affinity of Ca2+ to the bile salt micelles.     

NMR studies of primary and secondary sites of parvalbumins using the two paramagnetic probes Gd (III) and Mn (II)

The binding of cations by parvalbumins was studied by the proton relaxation enhancement (PRE) method using the paramagnetic probes Gd(III) and Mn(II). Gd(III) appears as a specific probe of the primary sites CD and EF with the following binding parameters: n = 2, KdGd = 0.5 x 10(-11) M and epsilon b = 2.3. The low value of epsilon b is the result of a nearly complete dehydration of the protein bound ions. Competition experiments between Gd(III) and various diamagnetic cations show the following order of affinity for the EF and CD sites: Mg2+ less than Zn2+ less than Sr2+ less than Ca2+ less than Cd2+ less than La3+ less than or equal to Gd3+. Mn 2+ is a specific probe of a secondary site with the following binding parameters: n = 1, KdMn = 0.6 x 10(-3) M and epsilon b = 17. The high value of epsilon b suggests that the protein bound Mn(II) has retained most of its hydration shell. Competition experiments between (Mn(II) and different cations show similar affinities for this site: Ca2+ less than or equal to Mg2+ less than or equal to Cd2+ less than or equal to Mn2+. This secondary site is located near the EF primary site.     

Sodium-23 and potassium-39 nuclear magnetic resonance relaxation in eye lens. Examples of quadrupole ion magnetic relaxation in a crowded protein environment.

Single and multiple quantum nuclear magnetic resonance (NMR) spectroscopic techniques were used to investigate the motional dynamics of sodium and potassium ions in concentrated protein solution, represented in this study by cortical and nuclear bovine lens tissue homogenates. Both ions displayed homogeneous biexponential magnetic relaxation behavior. Furthermore, the NMR relaxation behavior of these ions in lens homogenates was consistent either with a model that assumed the occurrence of two predominant ionic populations, "free" and "bound," in fast exchange with each other or with a model that assumed an asymmetric Gaussian distribution of correlation times. Regardless of the model employed, both ions were found to occur in a predominantly "free" or "unbound" rapidly reorienting state. The fraction of "bound" 23Na+, assuming a discrete two-site model, was approximately 0.006 and 0.017 for cortical and nuclear homogenates, respectively. Corresponding values for 39K+ were 0.003 and 0.007, respectively. Estimated values for the fraction of "bound" 23Na+ or 39K+ obtained from the distribution model (tau C greater than omega L-1) were less than or equal to 0.05 for all cases examined. The correlation times of the "bound" ions, derived using either a two-site or distribution model, yielded values that were at least one order of magnitude smaller than the reorientational motion of the constituent lens proteins. This observation implies that the apparent correlation time for ion binding is dominated by processes other than protein reorientational motion, most likely fast exchange between "free" and "bound" environments. The results of NMR visibility studies were consistent with the above findings, in agreement with other studies performed by non-NMR methods. These studies, in combination with those presented in the literature, suggest that the most likely role for sodium and potassium ions in the lens appears to be the regulation of cell volume by affecting the intralenticular water chemical potential.     

A study of strontium binding to albumins, by a chromatographic method involving atomic emission spectrometric detection

A chromatographic method involving ICP-AES (inductively coupled plasma atomic emission spectrometry) detection has been successfully applied for the study of strontium-protein complexes. The chromatographic step involves the use of gel filtration-a large-zone Hummel and Dreyer method-which allows to dissociate the bound metallic ions and the free ones. This step is followed by an ICP-AES analysis of fractions collected throughout the chromatographic experiment: the concentration of ionic metallic species in solution can therefore be calculated. Two proteins have been tested: bovine serum albumin, which showed only weak interactions with Sr2+ ions, and bovine alpha-lactalbumin: this protein, well-known for its calcium binding capacity, proved to interact strongly with strontium. The influence of various parameters on the formation of strontium-lactalbumin complexes were determined, namely temperature, pH. Competition experiments between Sr2+ ions and, respectively Na+ and Ca2+ ions were also performed, by varying ionic strength of the medium, and by using both apo and native forms of bovine alpha-lactalbumin.     

The metal sites on sarcoplasmic reticulum membranes that bind lanthanide ions with the highest affinity are not the ATPase Ca2+ transport sites.

We attempted to establish whether lanthanide ions, when added to sarcoplasmic reticulum (SR) membranes in the absence of nucleotide, compete with Ca2+ for binding to the transport sites of the Ca(2+)-ATPase in these membranes, or whether they bind to different sites. Equilibrium measurements of the effect of lanthanide ions on the intrinsic fluorescence of SR ATPase and on 45Ca2+ binding to it were performed either at neutral pH (pH 6.8), i.e. when endogenous or contaminating Ca2+ was sufficient to nearly saturate the ATPase transport sites, or at acid pH (pH 5.5), which greatly reduced the affinity of calcium for its sites on the ATPase. These measurements did reveal apparent competition between Ca2+ and the lanthanide ions La3+, Gd3+, Pr3+, and Tb3+, which all behaved similarly, but this competition displayed unexpected features: lanthanide ions displaced Ca2+ with a moderate affinity and in a noncooperative way, and the pH dependence of this displacement was smaller than that of the Ca2+ binding to its own sites. Simultaneously, we directly measured the amount of Tb3+ bound to the ATPase relative to the amount of Ca2+ and found that Tb3+ ions only reduced significantly the amount of Ca2+ bound after a considerable number of Tb3+ ions had bound. Furthermore, when we tested the effect of Ca2+ on the amount of Tb3+ bound to the SR membranes, we found that the Tb3+ ions which bound at low Tb3+ concentrations were not displaced when Ca2+ was added at concentrations which saturated the Ca2+ transport sites. We conclude that the sites on SR ATPase to which lanthanide ions bind with the highest affinity are not the high affinity Ca2+ binding and transport sites. At higher concentrations, lanthanide ions did not appear to be able to replace Ca2+ ions and preserve the native structure of their binding pocket, as evaluated in rapid filtration measurements from the effect of moderate concentrations of lanthanide ions on the kinetics of Ca2+ dissociation. Thus, the presence of lanthanide ions slowed down the dissociation from its binding site of the first, superficially bound 45Ca2+ ion, instead of specifically preventing the dissociation of the deeply bound 45Ca2+ ion. These results highlight the need for caution when interpreting, in terms of calcium sites, experimental data collected using lanthanide ions as spectroscopic probes on SR membrane ATPase.     

Binding of monovalent cations to Na+,K+-dependent ATPase purified from porcine kidney. I. Simultaneous binding of three sodium and two potassium or rubidium ions to the enzyme

We previously measured the amounts of Na+ and K+ ions bound to the Na+,K+-dependent ATPase [EC 3.6.1.3] purified from porcine kidney by a modified membrane filtration method [(1979) J. Biochem. 86, 509--523]. In this study, we improved the method for measuring the amount of the active site and measured the amount of Rb+ ions (a K+ congener) bound to the ATPase as well as those of Na+ and K+ ions to get more accurate information on the K+- and Na+-binding sites. The following results were obtained. Two kinds of cation-binding sites were found to exist on the ATPase molecule. One was the Na+-binding sites (3 mol per mol of active site). Na+ ions were bound to the sites cooperatively (Hill coefficient, 2.5--3), and the apparent dissociation constant was 0.20--0.32 mM. Three moles of Na+ ions bound to the sites was displaced by 1 mol of K+ ions bound to the ATPase (phi K, 24 microM). The other was the K+-binding sites (2 mol per mol of active site). Two moles of K+, Rb+, or Na+ ions was bound to the sites cooperatively (Hill coefficient, 1.5--2), and their apparent dissociation constants were 0.044, 0.024, and 2.2 mM, respectively. We measured the amounts of Na+ and Rb+ ions bound to the ATPase in the presence of 0.8 mM NaCl and 0.13 mM RbCl, and obtained unequivocal evidence for the simultaneous binding of 3 mol of Na+ ions and 2 mol of Rb+ ions per mol of active site of the ATPase.     

A calcium-43 NMR study of calcium binding to an acidic proline-rich phosphoprotein from human saliva

The 43Ca NMR line width measured for Ca2+ bound to protein A, an acidic proline-rich salivary protein, is 1 order of magnitude narrower than has previously been observed for other proteins of similar molecular weight. The correlation times, quadrupole coupling constants, and chemical shifts estimated for Ca2+ ions bound to the intact protein (Mr approximately 10 000) and its 30 amino acid residue long acidic N-terminal TX peptide were indistinguishable within experimental error. These results--as well as the outcome of 1H NMR relaxation rate measurements--are indicative of extensive motions for the protein residues, which in turn give rise to a high degree of flexibility for the protein-bound Ca2+. Ca2+ titration and pH-dependent measurements on protein A, the TX peptide, and the dephosphorylated TX peptide established the importance of the two phosphoserine residues in the binding of Ca2+. Moreover, a comparison of the 43Ca NMR parameters with those obtained for other Ca2+-binding proteins suggests the presence of Ca2+-binding sites of similar symmetry in all these proteins. No evidence was found for a proposed interaction between the highly acidic N-terminal and the weakly basic C-terminal regions of protein A. In contrast, the high pH inflection that was observed in the pH titration curve for the intact protein was also found for the phospho and dephospho TX peptides, thus suggesting that basic moieties in the N-terminal region rather than those in the C-terminal region may be responsible for this observation.     

Comparison of the binding of Na+ and Ca2+ to bovine alpha-lactalbumin

alpha-Lactalbumin is a metal-binding protein which binds Ca2+- and Na+-ions competitively to one specific site, giving rise to a large conformational change of the protein. For this reason, the enthalpy change of binding Ca2+ to apo-alpha-lactalbumin (delta Ho) is strongly dependent on the concentration of Na+ ions in the medium. From that relationship a molar enthalpy of -145 +/- 3 kJ X mol-1 is calculated for the Ca2+-binding at pH 7.4 and 25 degrees C, while a delta Ho of -5 +/- 3 kJ X mol-1 is found to substitute a complexed Na+ by a Ca2+-ion. These measurements also allowed us to calculate a binding constant for Na+ of 195 +/- 18 M-1. The molar enthalpy of Na+-loading was found to be -142 +/- 3 kJ X mol-1, a value very close to delta Ho of the binding of Ca2+ to alpha-lactalbumin. Both enthalpy changes in binding Ca2+ and Na+ are independent of the protein concentration. These exothermic values are in agreement with the hypothesis that both Na+- and Ca2+-ions are able to induce the same conformational change in alpha-lactalbumin upon which hydrophobic regions are removed from the solvent, yielding a less hydrophobic protein. The latter is confirmed by means of affinity measurements of the hydrophobic fluorescent probe 4,4'-bis[1-(phenylamino)-8-naphthalene sulphonate](bis-ANS) to alpha-lactalbumin. The association constant (Ka) decreased from (6.6 +/- 0.5) X 10(4) M-1 in the absence of NaCl to (2.7 +/- 0.2) X 10(4) M-1 in 75 mM NaCl, while the maximum intensity (Imax) of the binary bis-ANS-alpha-lactalbumin complex remained constant at 0.44 +/- 0.02 (arbitrary units). The Ka value of bis-ANS for Ca2+-alpha-lactalbumin was determined at (1.7 +/- 0.2) X 10(4) M-1 and Imax was 0.43 +/- 0.02 (arbitrary units). The difference in hydrophobicity between the two conformational states of the protein was further demonstrated by adsorption experiments of both conformers to phenyl-Sepharose. Apo-alpha-lactalbumin, hydrophobically bound to phenyl-Sepharose, can be eluted by adding Ca2- or Na+-solutions.