Coordination chemical studies on metalloenzymes. Measurement of binding constant between apo-tyrosinase and copper ion

The behavior of complexing agents for the copper removal reaction was studied by the equilibrium dialysis method. In the copper removal reaction, complexing agents are divided into two types: those that are reducing agents and those that are not. Sodium cyanide and sodium thiosulfate are of the first type, and 8-hydroxyquinoline-5-sulfonic acid, 2,2′-bipyridyl, and picolinic acid are of the second type. From equilibrium dialysis with the first type of complexing agent, the apparent binding constant (pH 6.0) between cuprous ions and apotyrosinase was calculated to be 10¹⁵m^?1. Similarly, the apparent binding constant (pH 6.0) between cupric ions and apo-tyrosinase was about 10¹³m^?1, which was calculated from equilibrium dialysis with the second type of complexing agent. The apparent binding constant between cuprous ions and apo-tyrosinase was larger than that between cupric ions and apo-tyrosinase.     

Further studies on the temperature dependence of the binding of testosterone to human pregnancy plasma proteins

The binding of testosterone by pregnancy plasma proteins has been studied by a new equilibrium dialysis system. The temperature dependence on the association constant has been investigated and the enthalpy change ΔH and entropy change ΔS have been calculated.By a computer optimization program, the binding constant of the high affinity testosterone binding protein has been estimated from Scatchard plots. The binding reactions were carried out at 5°, 25° and 37° C. The corresponding values were 3.1.10 1.2.10⁹ and 7.2.10⁸ liter/mole. The resulting enthalpy and entropy changes were ?2.0 kcal/mole and 35.0 cal/(mole.degree) respectively.It can be concluded that the binding of testosterone to the specific binding protein is an exothermic reaction and is stabilized by hydrophobic binding forces.     

Comparison of an iterative microcalorimetric method and dialysis equilibrium for calculating thermodynamic parameters of a binding protein which presents a weak affinity for its substrate

An original iterative microcalorimetric method is used to study the interaction of 5-fluorouracil, a cancer chemotherapeutic agent, with human serum albumin. Two equivalent binding sites are demonstrated with an association constant and an enthalpy variation equal to 370 ± 30 m^?1 and ?10 ± 0,5 kcal/mol, respectively. By means of a competitive microcalorimetric method, the partially competitive binding of dipotassium chlorazepate and 5-fluorouracil is shown. This iterative microcalorimetric method can be applied to all techniques involving the measurement of a phenomenon which is proportional to the concentration of the complex.     

Circular dichroism and fluorescence studies on the binding of ligands to the alpha subunit of tryptophan synthase.

Binding to the alpha subunit of tryptophan synthase induces extrinsic Cotton effects in the substrates indole (IND), indoleglycerol phosphate (IGP), and D-glyceraldehyde-3-P (D-GAP) and in the inhibitor indolepropanol phosphate (IPP). These effects disappear when the enzyme is denatured in guanidinium chloride. The induced circular dichroism (CD) was used to determine the dissociation constant and the number of binding sites for IPP. The dissociation constant so determined is equal to 48 muM and is in good agreement with the value of 48 muM obtained by equilibrium dialysis. From the temperature dependence of the dissociation constant, a value of -2.8 kcal/mol for the binding enthalpy was obtained. The determination of dissociation constants by means of extrinsic Cotton effects is shown to be quite feasible. CD competition experiments with glycerol phosphate (GP) suggest that IPP binds bifunctionally to the enzyme: via its indole part and its phosphate group. Indolepropanol, which lacks the phosphate group, does not show an extrinsic Cotton effect. Since the induced CD is strongly dependent on the binding geometry, the close similarity between the induced spectra in IPP and IGP is additional evidence that IPP is a good substrate analog. Binding to the enzyme results in a blue shift of the IPP fluorescence emission maximum. The dissociation constant determined by fluorescence titration equals 46 muM and agrees well with the values determined by the other two methods. Previous biochemical and fast kinetic studies suggested the existence of multiple conformational states for the enzyme and of ligand-induced conformational changes. No evidence was found in the far-uv CD spectra for conformational changes upon binding of IND and D-GAP. For IPP a very small effect was observed.     

Study of steroid-proteininteractions by electron spin resonance spectroscopy. Binding of a spin-labelled dihydrotestosterone to bovine serum albumin.

The interaction of bovine serum albumin with dihydrotestosterone bearing a spin label at C-3 was studied using electron spin resonance (ESR) spectroscopy. Quantitative binding parameters (Ka approximately 10(5) M-1; maximum binding capacity; two sites/mol albumin) obtained by ESR were in good agreement with those given by equilibrium dialysis. ESR study at various temperatures allowed the calculation of the thermodynamic parameters of the steroid-protein interaction: deltaG=-6.8 kcal/mol; deltaH=-7.9 kcal/mol; deltaS=-3.2 cal/mol per degree and confirmed a transition temperature of about 65 degrees C for albumin. Na, Liland Ca salts had a generally favorable effect on the interaction whereas other ions (e.g. Hg, Cu) impaired the binding process. Study of the width of the ESR spectra of the protein-bound spin-labelled steroid and extrapolation of a 2 T value to infinite viscosity (Azz coupling constant) indicated a non-polar binding site, which became increasingly hydrophobic as the temperature was raised. Since this methodology can give both pertinent quantitative and qualitative data, ESR spectroscopy should be of value in the study of steroid-protein interactions of biological significance.     

The Interaction of New Pyridylporphyrins with Bovine Serum Albumin

The interaction of meso-tetra(4-N-hydroxyethylpyridyl)porphyrin, meso-tetra(3-N-hydroxyethylpyridyl)porphyrin, and their zinc complexes with bovine serum albumin (BSA) was studied by electronic spectroscopy, CD, and equilibrium dialysis at pH 7.2. The titration of the porphyrins with BSA was accompanied by a decrease in light absorption and a bathochromic shift of the Soret band, as well as by the appearance of an isobestic point. The porphyrin interaction with BSA also led to the induction of positive CD spectra in the visible region, which is explained by the porphyrin sorption on the protein globule. The equilibrium dialysis helped in determining the stoichiometry of binding and the binding constants of the porphyrins under study with BSA using Scatchard plots. This interaction is nonspecific and reversible.     

Aluminum interaction with calmodulin. Evidence for altered structure and function from optical and enzymatic studies

The interaction of aluminum ions with bovine brain calmodulin has been examined by fluorescence spectroscopy, circular dichroic spectrophotometry and equilibrium dialysis, and by the calmodulin-dependent activation of 3',5'-cyclic nucleotide phosphodiesterase. These experiments show that aluminum binds stoichiometrically and cooperatively to calmodulin. Binding of aluminum at a molar ratio of 2:1 to calmodulin suffices to induce a major structural change. Estimates from spectroscopic data indicate that the binding affinity for the first mol of aluminum bound to the protein is about one order of magnitude stronger than that of calcium to its comparable site. These estimates agree with a dissociation constant of 0.4 microM derived from equilibrium dialysis experiments. Interaction of aluminum with calmodulin induces a helix-coil transition and enhances the hydrophobic surface area much more than calcium does. A molar ratio of 4:1 for [aluminum]/[calmodulin] is sufficient to block completely the activity of the calcium-calmodulin-dependent phosphodiesterase. Highly hydrated aluminum ions apparently promote solvent-rich, disordered polypeptide regions in calmodulin which, in turn, profoundly influence the protein's flexibility.     

A multitechnique approach to probe the interaction of a therapeutic tyrosine kinase inhibitor nintedanib and bovine serum albumin

Drug and protein interaction provides a structural guideline in the rational drug designing and in the synthesis of new and improved drugs with greater efficacy. We have examined here the interaction tendency and mechanism of nintedanib (NTB), an anticancer drug (tyrosine kinase inhibitor) with bovine serum albumin (BSA), by spectroscopic techniques. The decline in Stern–Volmer quenching constants and binding constant with the temperature rise suggests that BSA forms a complex with NTB. Binding constant obtained by modified Stern–Volmer equation at 3 temperatures was realized to be of the order of ~10⁴?M^?1. Negative ΔG (~?5.93?kcal?mol^?1), ΔH (?3.74?kcal?mol^?1), and ΔS (?1.50?kcal?mol^?1) values exhibited a spontaneous and exothermic reaction between BSA and NTB. NTB molecule interacts with BSA by forming hydrogen bonds, as elucidated by fluorescence results. Moreover, a minor increment in the helical conformation of BSA upon its binding to NTB was observed by circular dichroism spectroscopy. The modification in protein’s symmetry and a decline in hydrodynamic radii were observed in the presence of NTB (from ~3.6 to ~3?nm) as obtained by the dynamic light scattering measurement results.     

The interaction of collagen with the hydrophobic fluorescent probe-2-p-toluidinylnaphthalene-6-sulfonate.

Three kinds of fluorescence enhancement result from the interaction of 2-p-toluidinylnaphthalene-6-sulfonate and calf-skin collagen. They are negatively cooperative, independent, and highly cooperative fluorescence enhancement. In the independent region at pH 3.7, the binding number is about 36 moles of 2-p-toluidinylnaphthalene-6-sulfonate per mole of tropocollagen with a binding constant of 2.0 × 10⁴ M^?1; with ΔG = ?5.7 kcal/mole, ΔH = ?4.0 kcal/mole, and ΔS = 6 e.u. The pH dependence of fluorescence of native collagen shows that the deprotonated forms of the β and γ carboxyl groups of aspartic and glutamic acid decrease the intensity, possibly by charge repulsion of the negatively charged sulfonate group of 2-p-toluidinylnaphthalene-6-sulfonate. The positive charge of lysine is found to be unimportant in the interaction of 2-p-toluidinylnaphthalene-6-sulfonate with collagen. Fluorescence enhancement is caused mainly by the hydrophobic interactions of 2-p-toluidinylnaphthalene-6-sulfonate and collagen. Salt bridge formation between basic and acidic side chains in very low salt concentration may be detectable by 2-p-toluidinylnaphthalene-6-sulfonate fluorescence.     

Interaction of calcium ions with peptide hormones of the gastrin family

The interactions of Des-Trp¹-Nle¹²-minigastrin I (Nle¹¹-HG-13) and Nle¹⁵-little gastrin I (Nle¹⁵-HG-17) with calcium ions have been investigated in water and in trifluoroethanol solution using uv and CD absorption techniques. Both hormones strongly interact with Ca²⁺ in the organic medium. In the case of Nle¹¹-HG-13, the near-uv chiroptical properties (dominated by the transitions of the Trp residue in the C-terminal tetrapeptide sequence) indicate that three metal ions per mole of hormone are involved in the binding process. From the different response of near-uv and far-uv CD properties to the addition of calcium and from the change of the CD spectra in the aromatic absorption region, it is concluded that the biologically important C-terminal sequence is directly involved in the interaction with calcium. Elongation of the peptide chain from Nle¹¹-HG-13 to Nle¹⁵-HG-17 (Nle¹⁵-little gastrin I) does not provide any additional binding site for calcium ions. The change of the CD properties in the near- and far-uv indicates that three metal ions per mole of hormone are involved in the binding process. The dichroic absorption in the aromatic region indicates that only one of the two Trp residues of the little gastrin analog is sensitive to the presence of calcium. On the assumption that the variation of the CD properties is proportional to the extent of calcium binding, the binding constants K₁, K₂, and K₃ have been estimated roughly. Two similar sets of binding constants have been found, with K₁ ≥ 10⁶M^?1 and K₃ of the order of 10⁵M^?1, indicating similar binding sites in the two hormones with high affinity for calcium ions.     

A calorimetric investigation of the heats of binding of Mg ++ to poly A, to poly U, and to their complexes

The heats of binding of Mg⁺⁺ ions to poly A, poly U, and to their complexes, in the presence of Na⁺ ions, have been measurd calorimetrically. In all cases the heat, ΔH(θ), exhibitis a distinct dependence on the extent of binding, θ, and in the cases of poly A and poly U also on the Na⁺ concentration. The values of ΔH(θ) range from +2 to +3 kcal/mole of Mg⁺⁺ bound at θ = 0 to 1.3 kcal/mole at θ = 0.5 except in poly A where at θ = 0 ΔH(θ) = ?2 to ?3 kcal/mole. This is interpreted as being due to a facilitation of base stacking by the binding of Mg⁺⁺. The extent of facilitation is consistent with current estimates of base stacking. A similar effect but of much smaller magnitude is believed to obtain in poly A poly U. An interpretation of the dependence of ΔH(θ) on θ in terms of simple electrostatic interactions, but neglecting solvent effects, was attempted and found to be inadequate.     

Effects of calcium binding on the structure and stability of human growth hormone

Thermodynamic analysis of calcium ions binding to human growth hormone (hGH) was done at 27 °C in NaCl solution, 50 mM, using different techniques. The binding isotherm for hGH-Ca²⁺ was obtained by two techniques of ionmetry, using a Ca²⁺-selective membrane electrode, and isothermal titration calorimetry. Results obtained by two ionmetric and calorimetric methods are in good agreement. There is a set of three identical and non-interacting binding sites for calcium ions. The intrinsic dissociation equilibrium constant and the molar enthalpy of binding are 52 μM and −17.4 kJ/mol, respectively. Temperature scanning UV–vis spectroscopy was applied to elucidate the effect of Ca²⁺ binding on the protein stability, and circular dichroism (CD) spectroscopy was used to show the structural change of hGH due to the metal ion interaction. Calcium ions binding increase the protein thermal stability by increasing of the alpha helix content as well as decreasing of both beta and random coil structures.     

Interaction of the Escherichia coli trp aporepressor with its ligand, L-tryptophan

We have examined the interaction of the Escherichia coli trp aporepressor with its ligand, L-tryptophan, using both equilibrium dialysis and flow dialysis methods. Results obtained by the two procedures were equivalent and indicate that the trp aporepressor binds L-tryptophan with an equilibrium dissociation constant (Kd) of 40 microM at 25 degrees C under standard binding assay conditions (10 mM potassium phosphate, pH 7.4, 0.2 M potassium chloride, 0.1 mM EDTA, 5% glycerol). Molecular sizing of the purified trp aporepressor shows that in the absence of ligand the regulatory protein exists as a dimeric species with greater than 99% purity and an apparent molecular weight of 30,000. Under the storage and assay conditions used, the dimer appears quite stable, and essentially no monomer or higher multimeric species are detected. Analysis of binding data by Scatchard and direct linear plot methods shows two identical and independent ligand-binding sites/native trp aporepressor dimer. When examined as a function of temperature, L-tryptophan binding by trp aporepressor varied over 7-fold (Kd = 28 microM at 6.5 degrees C to Kd = 217 microM at 40 degrees C). At the optimal growth temperature for E. coli (37 degrees C), the dissociation constant was 160 microM for the ligand, L-tryptophan. From the relationship between temperature and L-tryptophan binding by trp aporepressor, the apparent enthalpy change delta H = -10.6 +/- 0.6 kcal mol-1 and the apparent entropy change delta S = -17 +/- 2 cal degree-1 mol-1 were determined.     

Destructive effect of anticancer oxali-palladium on heme degradation through the generation of endogenous hydrogen peroxide

The interaction between human hemoglobin (Hb) and oxali-palladium was studied using different spectroscopic methods of UV–vis, fluorescence, circular dichroism (CD), and chemiluminescence at two temperatures of 25 and 37°C. The experimental results showed that both dynamic and static quenching is occurred simultaneously when oxali-palladium quenches the fluorescence of Hb. According to the fluorescence quenching method, the binding site number, apparent binding constant, and corresponding thermodynamic parameters were measured at two temperatures. The values of ΔH°, ΔS°, and ΔG° indicate that process of the formation of oxali-palladium–Hb complex is a spontaneous interaction procedure in which electrostatic interaction plays a major role. In addition, UV–vis and CD results showed that the addition of oxali-palladium changes the conformation of Hb. To evaluate the functional changes of Hb via destruction of the heme structure, fluorescence studies were performed. The results demonstrated that two fluorescent heme degradation products are found during the interaction of oxali-palladium with Hb. Also, the amount of hydrogen peroxide produced in the solution of Hb due to the interaction of oxali-palladium with Hb using chemiluminescence method indicated heme degradation in the protein is occurred. Structural and functional changes induced in Hb via heme degradation are considered as side effects of this synthesized anticancer drug.     

Interaction of 3’-O-caffeoyl D-quinic acid with multisubunit protein helianthinin

Chlorogenic acid, 3’-O-caffeoyl D-quinic acid, is an inherent ligand present inHelianthus annuus L. The effect of pH on chlorogenic acid binding to helianthinin suggests that maximum binding occurs at pH 6.0. The protein-polyphenol complex precipitates as a function of time. The association constant of the binding of chlorogenic acid to helianthinin, determined by equilibrium dialysis, at 31°C has a value of 3.5 ± 0.1 × 10⁴M^−-1 resulting in a ΔG value of − 6.32 ± 0.12 kcal /mol. The association constantK _ais 1.0 ± 0.1 × 10⁴M⁻¹ as determined by ultraviolet difference spectral titration at 25°C with ΔG° of -5.46 ± 0.06 kcal/mol. From fluorescence spectral titration at 28°C, theK _avalue is 1.38 ± 0.1 × 1 0 4M⁻¹ resulting in a ΔG of − 5.70 ± 0.05 kcal/mol. The total number of binding sites on the protein are 420 ± 50 as calculated from equilibrium dialysis. Microcalorimetric data of the ligand-protein interaction at 23°C suggests mainly two classes of binding. The thermal denaturation temperature,T _mof the protein decreases from 76°C to 72°C at 1 × 10⁻³M chlorogenic acid concentration upon complexation. This suggests that the complexation destabilizes the protein. The effect of temperature onK _aof chlorogenic acid shows a nonlinear increase from 10.2°C to 45°C. Chemical modification of both lysyl and tryptophanyl residues of the protein decreases the strength of binding of chlorogenic acid. Lysine, tryptophan and tyrosine of protein are shown to be present at the binding site. Based on the above data, it is suggested that charge-transfer complexation and entropically driven hydrophobic interaction are the predominant forces that are responsible for binding of chlorogenic acid to the multisubunit protein, helianthinin. Publication No. 324.     

Thermodynamics of conformational transition and chain association of ι-carrageenan in aqueous solution: Calorimetric and chirooptical data

Isothermal microcalorimetry, differential scanning calorimetry (DSC), and chirooptical data obtained for ι-carrageenan in NaCl, LiCl, and NaI aqueous solutions are presented. The experiments have been performed as a function of concentration both for the polymer and for the simple salt as a cosolute. The experimental findings consistently show the occurrence of a salt-induced disorder-to-order transition. From microcalorimetric experiments the exothermic enthalpy of transition ΔH_tr is obtained as the difference between the theoretical, purely electrostatic ΔH_el enthalpy change and the actual mixing enthalpy ΔH_mix, measured when a ι-carrageenan salt-free solution at constant polymer concentration is mixed with a 1:1 electrolyte solution of variable concentration. In the case of added NaCl, the absolute values of enthalpy changes |ΔH_tr| are in good agreement with those obtained for the opposite process, at comparable polymer and salt concentrations, from DSC melting curves. The microcalorimetric results show that the negative maximum value of ΔH_tr corresponding to the interaction of Li⁺ counterion with ι-carrageenan polyion results to be significantly lower than the corresponding values obtained for Na⁺ counterion. At variance with the microcalorimetric data, chirooptical results show that the salt-induced disorder-to-order transition, occurring in the 0.02–0.2M salt concentration range, appears to be complete at a concentration of about 0.08–0.1M of the simple ion, irrespective of the polymer concentration and of the nature of added electrolyte. © 1998 John Wiley & Sons, Inc. Biopoly 45: 105–117, 1998     

The binding of deoxyguanosine to polycytidylic acid: an application of the thermodynamic model of monomer-polymer complex formation.

The thermodynamic model (equation 1) for formation of monomer-polymer complexes developed for better interpretation of the sigmoidal isotherms for the binding of adenosine to polyuridylic acid (2) and chemically modified polyuridylic acids (3) has been successfully applied to reproduce the isotherms for both the duplex binding of deoxyguanosine (d-G) to polycytidylic acid (at pH 6.8) and the triplex binding at pH 4.1. The value for the equilibrium constant, K, of the triplex complex (per unit of C-G-C) is ～2000 at the optimum value of n = 5 (n is the number of d-G units in the smallest complex that can form). The value of K for the duplex complex is 555 and the optimum value of n is 4.The value of ΔG for the triple helical complex is 4.15 kcal/mole, the value of w (the stacking free energy of the d-G units in the complex) is 2.05 kcal/mole. For the double helical complex at pH 6.8, ΔG° is 3.45 kcal/mole, w = 1.55 kcal/mole.It is also shown that equation (1) predicts that the shape and mid-point slope (i.e., w) of a binding isotherm depends only on the value of n; and thus the isotherms for rA-poly U (n = 5) and dG-poly C (n = 5) have the same mid-point slopes, and thus the same values of w. The difference between ΔG° and w is taken as a relative measure of the free energy of hydrogen bonding; values are calculated for the rA-poly U, the dG-poly C triple helix, and the dG-poly C double helical complexes.     

Binding of netropsin to DNA in complexes with polypeptides containing repetitive lysine sequences

The interaction of the antibiotic netropsin with calf thymus DNA, T4 DNA and poly(dA-dT) . poly(dA-dT) in complexes with sequential polypeptides containing repetitive lysine sequences and histone H1 was investigated using circular dichroism spectroscopy and equilibrium dialysis. Both soluble DNA-polypeptide complexes and insoluble complexes showed binding of netropsin. The possibility of displacement of polypeptides from DNA binding sites by competition with netropsin molecules was eliminated by experiments using 14C-labelled polypeptides. From the analysis of CD titration behavior as well as from the results of equilibrium dialysis studies it follows that netropsin does not compete with polypeptides for DNA binding sites, which suggests that these two ligands occupy different sites. Various explanations for minor differences in the CD behavior of the bound netropsin in the saturation region are also discussed.     

Parameters involved in binding of porcine pancreatic alpha-amylase with black bean inhibitor: role of sulfhydryl groups, chloride, calcium, solvent composition and temperature

The amylase inhibitor of black (kidney) beans (Phaseolus vulgaris; MW 53,000) forms a 1:1 stoichiometric complex with porcine pancreatic alpha-amylase (MW 52,000) at pH 5.40. The single sulfhydryl group of the inhibitor and the two sulfhydryl groups of alpha-amylase are not involved in recognition and binding. Chloride ions, required for activity of alpha-amylase at both pH 5.40 and 6.90, are important for inhibitor--enzyme binding at pH 6.90 but not at pH 5.40. Calcium-free alpha-amylase binds with the inhibitor. An increase in the ionic strength of the solvent increases the rate of binding of the inhibitor with alpha-amylase; a decrease in the dielectric constant decreases the rate of binding; and decreasing the temperature increases the dissociation constant, Kd, of the complex. These data support the hypothesis that hydrophobic interaction is of primary importance in complex formation. The activation energy, Ea, for complex formation was found to be 12.4 kcal/mol at pH 5.40 and 24.2 kcal/mol at pH 6.90. In the presence of the poor substrate, p-nitrophenyl-alpha-D-maltoside, the Ea for complex formation was 4.1 kcal/mol at pH 6.90.     

Binding of NAD+ to pertussis toxin.

The equilibrium dissociation constant of NAD+ and pertussis toxin was determined by equilibrium dialysis and by the quenching of the protein's intrinsic fluorescence on titration with NAD+. A binding constant, Kd, of 24 +/- 2 microM at 30 degrees C was obtained from equilibrium dialysis, consistent with the previously determined value for the Michaelis constant, Km, of 30 +/- 5 microM for NAD+ (when the toxin is catalysing the ADP-ribosylation of water and of dithiothreitol). The intrinsic fluorescence of pertussis toxin was quenched by up to 60% on titration with NAD+, and after correction for dilution and inner filter effects, a Kd value of 27 microM at 30 degrees C was obtained, agreeing well with that found by equilibrium dialysis. The binding constants were measured at a number of temperatures using both techniques, and from this the enthalpy of binding of NAD+ to toxin was determined to be 30 kJ.mol-1, a typical value for a protein-ligand interaction. There is one binding site for NAD+ per toxin molecule.