Thyroglobulin structure-function: the effect of iodination on the structure of human thyroglobulin

Thyroglobulin of very low iodine content has been prepared from a single non-toxic human goitre. The initial iodine content of the protein (0.038%) has been increased to levels of 0.16% and 0.85% by in vitro treatment with thyroid peroxidase and the resulting proteins studied with respect to their intrinsic fluorescence, circular dichroism spectra and binding of the hydrophobic probe 1,8-anilinonaphthalene sulfonic acid (ANS). While significant differences were observed between levels of iodination in both the ANS binding and intrinsic fluorescence of the thyroglobulin, no significant differences in the near and far UV circular dichroism spectra of the protein as a function of iodine content were observed. These data suggest that, the iodination of thyroglobulin effects specific areas of the protein without significant disruption of its overall secondary structure.     

Elucidating the binding thermodynamics of 8-anilino-1-naphthalene sulfonic acid with the A-state of alpha-lactalbumin: an isothermal titration calorimetric investigation

Isothermal titration calorimetry has been used to demonstrate that the heat profile associated with the binding of 8-anilino-1-naphthalene sulfonic acid (ANS) with the acid induced molten globule state (A-state) of alpha-lactalbumin (alpha-LA) is different from that with the native and denatured states of the protein. The results corroborate the spectroscopic observations that ANS binds more strongly to the partially folded states of the protein compared to that with the native and denatured states. ANS binds to the A-state of alpha-LA at two independent binding sites that remain nearly the same in the temperature range of 10-35 degrees C. The number of moles of ANS binding at site 1 at 10 degrees C is 14.0+/-0.2 and remains nearly the same with rise in temperature. However, the number of moles of ANS molecules binding at site 2 show an increase from 1.6+/-0.2 at 10 degrees C to 4.1+/-0.1 at 35 degrees C. The deviation of the slope of enthalpy-entropy compensation plot from unity and nonadherence to van't Hoff dictates implies that the binding sites on the A-state of alpha-LA for ANS are not well defined and specific; rather, these binding sites are formed due to greater exposure of hydrophobic clusters in the A-state of the protein. The results for the first time demonstrate the use of isothermal titration calorimetry in characterizing the A-state of alpha-LA both qualitatively and quantitatively.     

Competitive binding of fatty acids and the fluorescent probe 1-8-anilinonaphthalene sulfonate to bovine beta-lactoglobulin

The use of spectroscopy in the study of fatty acids binding to bovine beta-lactoglobulin (BLG) appears to be a difficult task, as these acid compounds, assumed as the protein natural ligands, do not exhibit favorable optical response such as, for example, absorption or fluorescence. Therefore, the BLG fatty-acid equilibrium has been tackled by exploiting the competition between fatty acids and ANS, a widely used fluorescent hydrophobic probe, whose binding sites on the protein have been characterized recently. Two lifetime decays of the ANS-BLG complex have been found; the longer one has been attributed to the internal binding site and the shorter one to the external site. At increasing fatty acids concentration, the fractional weight associated with ANS bound to the internal site drops, in agreement with a model describing the competition of the dye with fatty acids, whereas the external site occupancy appears to be unaffected by the fatty acids binding to BLG. This model is supported by docking studies. An estimate of the acid-binding affinities for BLG has been obtained by implementing the fitting of the bound ANS intensities with a competitive binding model. A relevant dependence has been found upon the solution pH, in the range from 6 to 8, which correlates with the calyx accessibility modulated by the conformation of the EF loop. Fatty acids with longer aliphatic chains (palmitate and laurate) are found to display larger affinities for the protein and the interaction free energy nicely correlates with the number of contacts inside the protein calyx, in agreement with docking simulations.     

Insights into hydrophobicity and the chaperone-like function of alphaA- and alphaB-crystallins: an isothermal titration calorimetric study

Alpha-crystallin, composed of two subunits, alphaA and alphaB, has been shown to function as a molecular chaperone that prevents aggregation of other proteins under stress conditions. The exposed hydrophobic surfaces of alpha-crystallins have been implicated in this process, but their exact role has not been elucidated. In this study, we quantify the hydrophobic surfaces of alphaA- and alphaB-crystallins by isothermal titration calorimetry using 8-anilino-1-napthalenesulfonic acid (ANS) as a hydrophobic probe and analyze its correlation to the chaperone potential of alphaA- and alphaB-crystallins under various conditions. Two ANS binding sites, one with low and another with high affinity, were clearly detected, with alphaB showing a higher number of sites than alphaA at 30 degrees C. In agreement with the higher number of hydrophobic sites, alphaB-crystallin demonstrated higher chaperone activity than alphaA at this temperature. Thermodynamic analysis of ANS binding to alphaA- and alphaB-crystallins indicates that high affinity binding is driven by both enthalpy and entropy changes, with entropy dominating the low affinity binding. Interestingly, although the number of ANS binding sites was similar for alphaA and alphaB at 15 degrees C, alphaA was more potent than alphaB in preventing aggregation of the insulin B-chain. Although there was no change in the number of high affinity binding sites of alphaA and alphaB for ANS upon preheating, there was an increase in the number of low affinity sites of alphaA and alphaB. Preheated alphaA, in contrast to alphaB, exhibited remarkably enhanced chaperone activity. Our results indicate that although hydrophobicity appears to be a factor in determining the chaperone-like activity of alpha-crystallins, it does not quantitatively correlate with the chaperone function of alpha-crystallins.     

Thermally induced structural transitions of the variable and constant halves of Bence Jones proteins: fluorimetric studies

Fluorimetric method has been used to study the thermally induced structural transitions of the variable and constant halves of Bence Jones proteins. Like the intact protein, both the variable and constant halves exhibit significant increase in their fluorescence intensity at 50–56° due to conformational unfolding. The intact protein and its variable half, thus unfolded, exhibit considerable ANS dye (8-Anilinonapthalene-I-sulfonate) binding capacity, as measured by the increase in ANS fluorescence. However, this is not true for the unfolded constant half. The thermosolubility properties, which are shown by intact Bence Jones proteins and their variable halves but not by their constant halves, appear to correlate with the exposure of hydrophobic binding sites at elevated temperature.     

A thermodynamic characterization of the interaction of 8‐anilino‐1‐naphthalenesulfonic acid with native globular proteins: the effect of the ligand dimerization in the analysis of the binding isotherms

8‐Anilino‐1‐naphthalenesulfonic acid (ANS) is a popular fluorescence probe, broadly used for the analysis of proteins, but the nature of its interaction with proteins and the high increase in the fluorescence intensity that takes place upon such process are still unclear. In the last few years, isothermal titration calorimetry has been used to characterize the nature of the interaction of this dye with proteins. The analysis of the binding isotherms of these studies has not considered the dimerization equilibrium of ANS, which is pH dependent, and it can result in serious errors in the data analysis. In the present work we have developed a suitable data analysis by which this process is taken into account. To study the binding of the dye to proteins at different pH values, we have used the Abl‐SH3 domain. Our results suggest that at pH 3 and 5, where the dimerization of the ANS is important, electrostatic interactions are significant for the binding of ANS to the Abl‐SH3 domain. However, at pH 7, ANS behaves mostly as monomer and the interaction with the protein is mainly hydrophobic. The pH dependent behavior of the ANS binding to proteins can be explained in terms of ionization states of both, the protein and the ANS. Copyright © 2010 John Wiley & Sons, Ltd.     

Study of fluorescent tryptophyl residues and extrinsic probes for the characterization of molecular domains of Folch-Pi apoprotein.

The highly hydrophobic myelin Folch-Pi apoprotein can be solubilized in organic as well as in aqueous media. In order to understand the molecular organization changes consecutive to changes in the solvent medium, the environment of intrinsic probes and extrinsic labels has been studied by fluorescence and accessibility to some reagents. In acqueous solution, only two tryptophan residues per protein molecule of 23,500 molecular weight have been shown to fluoresce, and their fluorescence characterisitics indicate an hydrophobic and/or constrained environment. Two ANS binding sites have also been observed having a high quenching effect on the intrinsic chromophore fluorescence. A large accessibility has been evidenced for the protein sulfhydryl groups in chloroform-methanol 2:1 (v/v), both by kinetic study of the protein reaction with a specific reagent, N-(1-anilino-naphtyl-4) maleimide, and by the fluorescence characteristics of this probe once linked to the protein. The free sulfhydryl groups were still reactive in acqueous solution, but extrinsic fluorescence of the labelled apoprotein transferred from chloroform-methanol 2:1 (v/v) into water gave evidence of constraints on the probe or on its environment. Such constraints may contribute to the solubilization in acqueous solution of this highly hydrophobic protein.     

1-anilino-8-naphthalene sulfonate as a protein conformational tightening agent

1-Anilino-8-naphthalene sulfonate (ANS) anion is conventionally considered to bind to preexisting hydrophobic (nonpolar) surfaces of proteins, primarily through its nonpolar anilino-naphthalene group. Such binding is followed by an increase in ANS fluorescence intensity, similar to that occurring when ANS is dissolved in organic solvents. It is generally assumed that neither the negative sulfonate charge on the ANS, nor charges on the protein, participate significantly in ANS-protein interaction. However, titration calorimetry has demonstrated that most ANS binding to a number of proteins occurs through electrostatic forces, in which ion pairs are formed between ANS sulfonate groups and cationic groups on the proteins (D. Matulis and R. E. Lovrien, Biophys. J., 1998, Vol. 74, pp. 1-8). Here we show by viscometry and diffusion coefficient measurements that bovine serum albumin and gamma-globulin, starting from their acid-expanded, most hydrated conformations, undergo extensive molecular compaction upon ANS binding. As the cationic protein binds negatively charged ANS anion it also takes up positively charged protons from water to compensate the effect of the negative charge, and leaves the free hydroxide anions in solution thus shifting pH upward (the Scatchard-Black effect). These results indicate that ANS is not always a definitive reporter of protein molecular conformation that existed before ANS binding. Instead, ANS reports on a conformationally tightened state produced by the interplay of ionic and hydrophobic characters of both protein and ligand.     

Circular dichroic evidence for regulation of enzymatic activity by nonsubstrate hydrophobic ligand on glutathione S-transferase P.

1-Anilinonaphthalene-8-sulfonic acid (ANS) noncompetitively inhibited enzyme activity of glutathione S-transferase P for both glutathione and 1-chloro-2,4-dinitrobenzene (Ki = 30 microM). Dissociation constant for ANS.GST-P complex calculated from the binding study was 15 microM. From the similar values of the inhibition constant and the dissociation constant, it was concluded that specific ANS binding caused the loss of enzyme activity. In the protein structural analysis by circular dichroism, the secondary structures remarkably changed by ANS binding in accordance with the decrease of enzymatic activities. The conformational change of the protein and the decrease in enzymatic activity were reversed by dissociation of ANS. This fact strongly suggested that the enzymatic activity was regulated by a nonsubstrate hydrophobic ligand.     

Ligand binding induces a sharp decrease in hydrophobicity of folate binding protein assessed by 1-anilinonaphthalene-8-sulphonate which suppresses self-association of the hydrophobic apo-protein

High affinity folate binding protein (FBP) regulates as a soluble protein and as a cellular receptor intracellular trafficking of folic acid, a vitamin of great importance to cell growth and division. We addressed two issues of potential importance to the biological function of FBP, a possible decrease of the surface hydrophobicity associated with the ligand-induced conformation change of FBP, and protein-inter-protein interactions involved in self-association of hydrophobic apo-FBP. The extrinsic fluorescent apolar dye 1-anilinonaphthalene-8-sulphonate (ANS) exhibited enhanced fluorescence intensity and a blueshift of emission maximum from 510-520 to 460-470nm upon addition of apo-FBP indicating binding to a strongly hydrophobic environment. Neither enhancement of fluorescence nor blueshift of ANS emission maximum occurred when folate-ligated holo-FBP replaced apo-FBP. The drastic decrease in surface hydrophobicity of holo-FBP could have bearings on the biological function of FBP since changes in surface hydrophobicity have critical effects on the biological function of receptors and transport proteins. ANS interacts with exposed hydrophobic surfaces on proteins and may thereby block and prevent aggregation of proteins (chaperone-like effect). Hence, hydrophobic interactions seemed to participate in the concentration-dependent self-association of apo-FBP which was suppressed by high ANS concentrations in light scatter measurements.     

Binding of ions and hydrophobic probes to alpha-lactalbumin and kappa-casein as determined by analytical affinity chromatography

The technique of analytical affinity chromatography was extended to characterize binding of ions and hydrophobic probes to proteins. Using the immobilized protein mode of chromatography, alpha-lactalbumin and kappa-casein were covalently attached to 200-nm-pore-diameter controlled-pore glass beads and accommodated for high-performance liquid chromatography. The existence of a high affinity binding site (Kdiss = 0.16 microM) (site I) for calcium ion in alpha-lactalbumin was confirmed by chromatography of [45Ca2+]. In addition, chromatography of the hydrophobic probes, 1-(phenylamino)-8-naphthalene-sulfonate (ANS)2 and 4,4'-bis[1-(phenylamino)-8-naphthalenesulfonate (bis-ANS) indicated that Ca2+ bound to a second site (presumably the zinc site or site II) with weaker affinity. Dissociation constants obtained for apo-alpha-lactalbumin were about 80 microM for ANS and 4.7 microM for bis-ANS in the absence of sodium ion. Addition of Ca2+ initially caused a reduction in surface hydrophobicity (lowered affinity for the probe dyes) followed by an increase at higher Ca2+ concentrations (greater than 0.5 mM), suggesting that occupancy of site II restores an apo-like conformation to the protein. Moreover, the effect of Zn2+ was similar to that observed in the higher Ca2+ concentration range, whereas Na+ apparently bound to site I. A calcium binding site of moderate affinity also exists in kappa-casein (Kdiss = 15.6 microM). A cluster of negative charges, probably including the orthophosphate group, most likely comprise this binding site. By preventing self-association, analytical affinity chromatography permits microscale characterization of ligand equilibria in proteins that are unaffected by protein-protein interactions.     

High-risk (HPV16) human papillomavirus E7 oncoprotein is highly stable and extended,with conformational transitions that could explain its multiple cellular binding partners

High-risk papillomaviruses are known to exert their transforming activity mainly through E7, one of their two oncoproteins. Despite its relevance, no structural information has been obtained that could explain the apparent broad binding specificity of E7. Recombinant E7 from HPV-16 purified to near homogeneity showed two species in gel filtration chromatography, one of these corresponding to a dimer with a molecular weight of 22 kDa, determined by multiangle light scattering. The E7 dimer was isolated for characterization and was shown to undergo a substantial conformational transition when changing from pH 7.0 to 5.0, with an increase in helical structure and increased solvent accessibility to hydrophobic surfaces. The protein was resistant to thermal denaturation even in the presence of SDS, and we show that persistent residual structure in the monomer is responsible for its reported anomalous electrophoretic behavior. The dimer also displays a nonglobular hydrodynamic volume based on gel filtration experiments and becomes more globular in the presence of 0.3 M guanidinium chloride, with hydrophobic surfaces becoming accessible to the solvent, as indicated by the large increase in ANS binding. At low protein concentration, dissociation of the globular E7 dimer was observed, preceding the cooperative unfolding of the structured and extended monomer. Although E7 bears properties that resemble natively unfolded polypeptides, its far-UV circular dichroism spectrum, cooperative unfolding, and exposure of ANS binding sites support a folded and extended, as opposed to disordered and fluctuating, conformation. The large increase in solvent accessibility to hydrophobic surfaces upon small pH decrease within physiological range and in mild denaturant concentrations suggests conformational properties that could have evolved to enable protein-protein recognition of the large number of cellular binding partners reported.     

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

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

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

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

Characterization of two partially unfolded intermediates of the molecular chaperone DnaK at low pH

In this study, the effect of pH on the conformation and the reactivity of the Escherichia coli Hsp70 molecular chaperone DnaK was investigated using spectroscopic and chemical assays. DnaK exhibits negligible binding of the hydrophobic dye 1-anilino-naphthalene-8-sulfonate (ANS) between pH 7 to 5.0, whereas appreciable binding occurs between pH 4.5 to 4.0. The binding of ANS to a protein is diagnostic of the presence of accessible ordered hydrophobic surfaces. Such hydrophobic surfaces are often displayed by partially folded protein intermediates such as molten globules. Nucleotide inhibits 70% of the ANS binding at pH 4.5 but none of the ANS binding at pH 4.0. Proteolysis of nucleotide-free DnaK at pH 4.5 with cathepsin D yields detectable fragments (masses > 20 kDa) of the C-terminal peptide-binding domain but none of the N-terminal ATPase domain, thus the ATPase domain is preferentially targeted for proteolysis. In contrast, proteolysis of nucleotide-free DnaK at pH 4.0 with cathepsin D cuts near the linker region, yielding both functional domains. Our interpretation of these data is that incubation of DnaK at pH 4.5 produces a partially unfolded form of the ATPase domain, in which secondary structure is mainly intact, but tertiary structure is reduced. Incubation of the protein at pH 4.0 produces an intermediate in which both functional domains have collapsed and possibly separated. Nucleotide inhibits the conformational change that occurs at pH 4.5 but not at 4.0.     

Molecular cloning of rabbit hyaluronic acid synthases and their expression patterns in synovial membrane and articular cartilage

Interaction of camel lens zeta-crystallin with the hydrophobic probe 1-anilinonaphthalene-8-sulfonic acid (ANS) enhanced the ANS fluorescence and quenched the protein fluorescence. Both of these events were concentration-dependent and showed typical saturation curves suggesting specific ANS-zeta-crystallin binding. Quantitative analysis indicated that 1 mole zeta-crystallin bound at most 1 mole ANS. NADPH but not 9,10-phenanthrenequinone (PQ) was able to displace zeta-crystallin-bound ANS. These results suggested the presence of a hydrophobic domain in zeta-crystallin, possibly at the NADPH binding site. alpha-Crystallin as well as NADPH protected zeta-crystallin against thermal inactivation suggesting the importance of this site for enzyme stability. The NADPH:quinone oxidoreductase activity of zeta-crystallin was inhibited by ANS with NADPH as electron donor and PQ as electron acceptor. Lineweaver-Burk plots indicated mixed-type inhibition with respect to NADPH, with a K(i) of 2.3 microM. Secondary plots of inhibition with respect to NADPH indicated a dissociation constant (K'I) of 12 microM for the zeta-crystallin-NADPH-ANS complex. The K(i) being smaller than K'I suggested that competitive inhibition at the NADPH binding site was predominant over non-competitive inhibition. Like ANS-zeta-crystallin binding, inhibition was dependent on ANS concentration but independent of incubation time.     

Characterization of the binding of 8-anilinonaphthalene sulfonate to rat class Mu GST M1-1

Molecular docking and ANS-displacement experiments indicated that 8-anilinonaphthalene sulfonate (ANS) binds the hydrophobic site (H-site) in the active site of dimeric class Mu rGST M1-1. The naphthalene moiety provides most of the van der Waals contacts at the ANS-binding interface while the anilino group is able to sample different rotamers. The energetics of ANS binding were studied by isothermal titration calorimetry (ITC) over the temperature range of 5-30 degrees C. Binding is both enthalpically and entropically driven and displays a stoichiometry of one ANS molecule per subunit (or H-site). ANS binding is linked to the uptake of 0.5 protons at pH 6.5. Enthalpy of binding depends linearly upon temperature yielding a DeltaC(p) of -80+/-4 cal K(-1) mol(-1) indicating the burial of solvent-exposed nonpolar surface area upon ANS-protein complex formation. While ion-pair interactions between the sulfonate moiety of ANS and protein cationic groups may be significant for other ANS-binding proteins, the binding of ANS to rGST M1-1 is primarily hydrophobic in origin. The binding properties are compared with those of other GSTs and ANS-binding proteins.     

Substrate binding to phosphoglycerate kinase monitored by 1-anilino-8-naphthalenesulfonate

The interaction between 1-anilino-8-naphthalenesulfonate (ANS) and yeast phosphoglycerate kinase (ATP:3-phospho-D-glycerate 1-phosphotransferase, EC 2.7.2.3) and the use of ANS as a probe for studying the structure and function of phosphoglycerate kinase has been investigated. The interaction has been studied by kinetic methods, equilibrium dialysis, and fluorometric titrations. ANS inhibits the activity of the enzyme. More than one inhibitor site exists. ANS is competitive with MgATP and noncompetitive with 3-phosphoglycerate at the first detected inhibitor binding site. The Ki value is 1-2 mM. Several ANS molecules bind to the enzyme. By fluorometric titrations the first detected site has a dissociation constant that is in the same range as Ki or bigger. When ANS interacts with phosphoglycerate kinase its fluorescence is increased and a blue shift occurs. ANS appears to bind to a strongly hydrophobic site. The fluorescence is sensitive to the addition of substrates. ADP, ATP, or combinations of Mg2+ and nucleotide decreases the fluorescence as does free Mg2+. 3-Phosphoglycerate, on the other hand, increases the fluorescence giving evidence for conformational changes upon 3-phosphoglycerate binding.     

Uridine diphosphate galactose 4-epimerase: nucleotide and 8-anilino-1-naphthalenesulfonate binding properties of the substrate binding site.

Escherichia coli UDP-galactose 4-epimerase in its native form (epimerase.NAD) binds 8-anilino-1-naphthalenesulfonate (ANS) at one tight binding site per dimer with a dissociation constant of 25.9 +/- 2.1 micrometer at pH 8.5 and 27 degrees C. This appears to be the substrate binding site, as indicated by the fact that ANS is a kinetically competitive reversible inhibitor with a Ki of 27.5 micrometer and by the fact that ANS competes with UMP for binding to the enzyme. Upon binding at this site the fluorescence quantum yield of ANS is enhanced 185-fold, and its emission spectrum is blue shifted from a lambdamax of 515 to 470.nm, which suggests that the binding site is shielded from water and probably hydrophobic. Competitive binding experiments with nucleosides and nucleotides indicate that nucleotide binding at this site involves coupled hydrophobic and electrostatic interactions. The reduced form of the enzyme (epimerase.NADH) has no detectable binding affinity for ANS. The marked difference in the affinities of the native and reduced enzymes for ANS is interpreted to be a manifestation of a conformational difference between these enzyme forms.     

Design and synthesis of 3alpha-helix peptides forming a cavity for a fluorescent ligand

As a model of receptor protein, a series of 3alpha-helix bundle peptides constructed on a template peptide were designed so as to possess a hydrophobic cavity. The size of cavity was modulated by simple replacements of Leu residues to Ala residues in the hydrophobic core. Binding abilities to 8-anilino-1-naphthalenesulfonic acid (ANS) were estimated by the increase of fluorescence intensity. The peptide having three or four Ala residues in the hydrophobic core remarkably increased the binding ability for ANS, though the peptide having two Ala residues gave an inefficient cavity for ANS. The peptide having six Ala residues decreased the binding ability due to crucial destabilization of the helix bundle structure. This scaffold can be utilized to a receptor model, while further tuning of the sequence is necessary.