Use of fluorescence enhancement technique to study bilirubin–albumin interaction

Bilirubin–albumin solution gave an emission spectrum in the wavelength range 500–600 nm with emission maxima at 528 nm when excited at 487 nm. The magnitude of fluorescence intensity increased on increasing bilirubin/albumin molar ratio. At three different albumin concentrations, namely, 1.0, 2.5 and 10.0 μM, there was an initial linear increase in fluorescence up to a molar ratio 1.0 in all cases beyond which it sloped off or decreased. This fluorescence enhancement was used to calculate the binding parameters of bilirubin–albumin interaction and the value of binding constant was found to be 1.72×10⁷ l/mol similar to the published values obtained with other methods. Different serum albumins, namely, human (HSA), goat (GSA), pig (PSA) and dog serum albumins (DSA) bound bilirubin with almost the same affinity when studied by the technique of fluorescence enhancement. Bilirubin–albumin interaction was also studied at different pH and ionic strengths. There was a decrease in bilirubin–albumin complex formation on either decreasing the pH from 9.0 to 7.0 or increasing the ionic strength from 0.15 to 1.0. These results suggest that the technique of fluorescence enhancement can be used successfully to study the bilirubin–albumin interaction.     

Role of electrostatic forces in hydroxy and keto bile salt-albumin interactions: some experimental observations.

Proton binding to bovine serum albumin and effects on hydroxy and keto bile salts-albumin binding were studied within a pH range between 5 and 10. Electrostatic forces contribute to the binding of these ligands to albumin; prototropic groups of albumin such as imidazol are involved in the interaction. Bile salts binding produces a shift in pK of these groups. It is postulated that hydroxy bile salt-albumin binding is linked with the N in equilibrium with B transition of the protein, while for keto bile salts a microarrangement in the protein binding sites is driving the interaction.     

Interaction of prostaglandin E2 with human serum albumin

Using equilibrium dialysis, protein fluorescence and fluorescent probing as well as chemical modification, the interaction of prostaglandin E2 with human serum albumin was studied. The serum albumin molecule has a highly specific prostaglandin E2-binding site. The binding of prostaglandin causes conformational rearrangements in the protein molecule. The amino group of serum albumin is involved in the interaction with prostaglandin E2. Prolonged exposure of prostaglandin E2 to serum albumin causes partial irreversible binding of prostaglandin molecules to the protein.     

Studies on the mechanism of binding of serum albumins to immobilized cibacron blue F3G A.

The interaction of Cibacron Blue F3G A-Sepharose 4B with several serum albumins was studied. Although all albumins used were fond to bind to this adsorbent, human serum albumin was bound to a far greater extent than were the others. From the results of competition experiments and n.m.r. studies of Cibacron Blue and/or bilirubin binding to human serum albumin it is proposed that the mechanism of the interaction between human serum albumin and cibacron Blue is consistent wit Cibacron Blue binding to bilirubin-binding sites. In contrast with these findings with human serum albumin, there is little or no interaction of Cibacron Blue and the bilirubin-binding sites of albumins from rabbit, horse, bovine or sheep sera, although some interaction occurs between Cibacron Blue and the fatty acid-binding sites of these proteins. Structural analogues of Cibacron Blue have been used to investigate the binding of albumins to these ligands.     

The albumin receptor effect may be due to a surface-induced conformational change in albumin

To determine whether equilibrium binding between albumin and hepatocytes involves a cell surface receptor for albumin, we incubated freshly isolated rat hepatocytes with 125I-albumin and determined the amount of albumin associated with the cells as a function of the total albumin concentration. The resulting two-phase binding curve showed the rat albumin-hepatocyte interaction to consist of a saturable binding interaction with a dissociation constant of 1.1 microM and 2 X 10(6) sites/cell in addition to a weak, nonsaturable binding interaction. However, the saturable binding of albumin to hepatocytes did not appear to result from the presence of an albumin receptor on the cell surface; the interaction was the same for different species of albumin, for chemically modified albumins, and for fragments of albumin representing mutually exclusive domains of the molecule. The saturable binding was, instead, found to involve a subpopulation of albumin with an enhanced affinity for the cell surface. We show that this subpopulation of albumin is generated upon contact with either solid surfaces or cell surfaces and can be transferred from one surface to another. We propose that the two-phase Scatchard binding curve and the "albumin receptor effect" reflect two populations of albumin that bind to the cell surface with different affinities rather than one population of albumin that binds to two classes of binding sites.     

Interaction of anesthetic supplement thiopental with human serum albumin

Thiopental (TPL) is a commonly used barbiturate anesthetic. Its binding with human serum albumin (HSA) was studied to explore the anesthetic-induced protein dysfunction. The basic binding interaction was studied by UV-absorption and fluorescence spectroscopy. An increase in the binding affinity (K) and in the number of binding sites (n) with the increasing albumin concentration was observed. The interaction was conformation-dependent and the highest for the F isomer of HSA, which implicates its slow elimination. The mode of binding was characterized using various thermodynamic parameters. Domain II of HSA was found to possess a high affinity binding site for TPL. The effect of micro-metal ions on the binding affinity was also investigated. The molecular distance, r, between donor (HSA) and acceptor (TPL) was estimated by fluorescence resonance energy transfer (FRET). Correlation between the stability of the TPL-N and TPL-F complexes and drug distribution is discussed. The structural changes in the protein investigated by circular dichroism (CD) and Fourier transform infrared (FT-IR) spectroscopy reflect perturbation of the albumin molecule and provide an explanation for the heterogeneity of action of this anesthetic.     

Use of amphotericin B as optical probe to study conformational changes and thermodynamic stability in human serum albumin

The binding of polyene antibiotic amphotericin B to serum albumin was studied using absorption, fluorescence, and circular dichroism techniques. A hypochromic effect was observed in the absorption spectrum of amphotericin B in the presence of albumin with maxima at 366 nm, 385 nm, and 408 nm, which correspond to the absorption of the monomeric form of amphotericin B. A modification on the circular dichroism spectrum of amphotericin B in the presence of albumin was observed at bands 329 nm and 351 nm (excitronic interaction), which suggests that only amphotericin B monomer is bound to the protein. Amphotericin B perturbs the specific markers for sites I, II, and fatty acid binding site bound to these sites, suggesting that amphotericin B interacts with a great binding area in albumin. Lysines 199 and 525 in albumin participate in the molecular interaction between amphotericin B and the protein. The absorption spectrum of amphotericin B bound to albumin was sensitive to the chemical and thermal treatment of the protein, to neutral-basic transition of albumin and to conformational changes induced by the binding of other ligands to this protein.     

Different interactions of human and bovine serum albumin with Cibacron Blue and Blue Dextran

The interaction of human and bovine serum albumin with Cibacron Blue and Blue Dextran in aqueous solution was studied by means of difference spectroscopy. Both human and bovine albumin interact strongly with underivatized Cibacron Blue in three independent binding sites (K = 105). On the contrary, Blue Dextran interacts strongly only with human albumin, but does not bind appreciably to bovine albumin. These results suggest that the binding sites are exposed and easily accessible in human albumin, while in bovine albumin they are sterically hindered and therefore not accessible to the bulky Blue Dextran.     

Biomolecular interaction study of hydralazine with bovine serum albumin and effect of β‐cyclodextrin on binding by fluorescence, 3D,synchronous, CD,and Raman spectroscopic methods

Spectrofluoremetric technique was employed to study the binding behavior of hydralazine with bovine serum albumin (BSA) at different temperatures. Binding study of bovine serum albumin with hydralazine has been studied by ultraviolet–visible spectroscopy, fluorescence spectroscopy and confirmed by three‐dimensional, synchronous, circular dichroism, and Raman spectroscopic methods. Effect of β‐cyclodextrin on binding was studied. The experimental results showed a static quenching mechanism in the interaction of hydralazine with bovine serum albumin. The binding constant and the number of binding sites are calculated according to Stern–Volmer equation. The thermodynamic parameters ?H^o, ?G^o, ?S^o at different temperatures were calculated. These indicated that the hydrogen bonding and weak van der Waals forces played an important role in the interaction. Based on the Förster's theory of non‐radiation energy transfer, the binding average distance, r, between the donor (BSA) and acceptor (hydralazine) was evaluated and found to be 3.95 nm. Spectral results showed that the binding of hydralazine to BSA induced conformational changes in BSA. The effect of common ions on the binding of hydralazine to BSA was also examined. Copyright © 2016 John Wiley & Sons, Ltd.     

Biophysical insights into the binding characteristics of bovine serum albumin with dipyridamole and the influence of molecular interaction with β cyclodextrin

Abstract

The binding characteristic of anti-platelet drug dipyridamole has been investigated with a transport protein, serum albumin. A multi-spectroscopic approach has been employed, and the results were well supported by in silico molecular docking and simulation studies. The fluorescence quenching of serum albumin at three different temperatures revealed that the mechanism involved is static and the binding constant of the interaction was found to be of the order of 10⁴ M^?1. The reaction was found to be spontaneous and involved hydrophobic interactions. Synchronous, 3D fluorescence and CD spectroscopy indicated a change in conformation of bovine serum albumin (BSA) on interaction with DP. Using site-selective markers, the binding site of DP was found to be in subdomain IB. Molecular docking studies further corroborated these results. Molecular dynamic (MD) simulations showed lower RMSD values on interaction, suggesting the existence of a stable complex between DP and BSA. Furthermore, since β-Cyclodextrin (βCD) is used to improve the solubility of DP in ophthalmic solutions, therefore, the effect of (βCD) on the interaction of BSA and DP was also studied, and it was found that in the presence of βCD, the binding constant for BSA-DP interaction decreased. The present study is an attempt to characterize the transport of DP and to improve its bioavailability, consequently helping in dosage design to achieve optimum therapeutic levels.

Communicated by Ramaswamy H. Sarma     

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.     

Study of the interaction of human serum albumin with penicillins by means of spin labels]

Interaction of 8 penicillin preparations with human serum albumin was studied with the spin-labels method and a probe. Correlation between the binding level of penicillins with human serum albumin and their effect on the spectrum of EPR of the spin-label attached to albumin was observed only with the use of a hydrophobic probe (radical III). The covalent attached marks and the hydrophobic probe may be used for rapid orienting estimation of pencillin interaction with albumin.     

Effect of molecular parameters on the binding of phenoxyacetic acid derivatives to albumins

The interaction of 12 phenoxyacetic acid derivatives with human and serum albumin as well as with egg albumin was studied by charge-transfer reversed-phase (RP) thin-layer chromatography (TLC) and the relative strength of interaction was calculated. Each phenoxyacetic acid derivative interacted with human and bovine serum albumins whereas no interaction was observed with egg albumin. Stepwise regression analysis proved that the lipophilicity of the derivatives exert a significant impact on their capacity to bind to serum albumins. This result supports the hypothesis that the binding of phenoxyacetic acid derivatives to albumins may involve hydrophobic forces occurring between the corresponding apolar substructures of these derivatives and the amino acid side chains.     

A study on the allosteric interaction between the major binding sites of human serum albumin using microcalorimetry

The binding of warfarin and oxyphenbutazone to albumin has been studied at pH 6.8 and pH 9.2 by measuring the heat of binding of these ligands to their high-affinity binding sites on albumin (delta Ho'1). The -delta Ho'1 values for the binding of warfarin at pH 6.8 and 9.2 and oxyphenbutazone at pH 6.8 and 9.2 were found to be 16.9(+/- 0.6), 28.8(+/- 0.6), 10.5(+/- 0.4) and 17.4(+/- 0.6) kJmol-1, respectively. The Gibbs energies (delta Go'1) corresponding to these delta Ho'1 values cover a much smaller range. The pH dependences of delta Go'1 and delta Ho'1 are explained in terms of pK shifts in the albumin upon binding warfarin or oxyphenbutazone. Diazepam, which binds to a site on albumin which is different from the warfarin-oxyphenbutazone binding site, increases - delta Ho'1 for the binding of warfarin and oxyphenbutazone to albumin at pH 6.8, but it does not influence the -delta Ho'1 at pH 9.2. This phenomenon may be attributed to an allosteric interaction between the diazepam binding site and the warfarin binding site. This allosteric interaction must have its origin in a phenomenon other than the N-B transition.     

Paclitaxel binding to the fatty acid-induced conformation of human serum albumin--automated docking studies

Paclitaxel (Taxol^®) binding to the conformation of human serum albumin assumed in the presence of long-chain fatty acids was studied by automated docking. Reduced binding affinities at both the primary and secondary sites were predicted, compared to those characterizing the interaction with the fatty acid-free protein. The baccatin core of paclitaxel was found to play a more important role than its C13 side chain in determining the ligand binding mode as well as in contributing to the overall binding energy at the primary site.     

Stereoselective protein binding of ketoprofen: Effect of albumin concentration and of the biological system

Equilibrium dialysis was used to study in vitro the enantioselective binding of R, S, and racemic ketoprofen at physiological pH and temperature in human serum albumin (HSA) (1, 20, and 40 g/liter) and in plasma. The binding of enantiomers in a racemic mixture was studied to see the effect of each isomer on the other's interaction with the protein. The free fractions were determined by high-performance liquid chromatography. The binding of ketoprofen enantiomers to albumin was enantioselective, depending on both drug and protein concentrations. Enantioselectivity was observed in plasma too but was the opposite of that in HSA at 40 g/liter. The percentage of each isomer unbound was higher in the racemic mixture than with the isomer alone. The displacement of probes specific for HSA sites I and II, studied by spectrofluorimetry, suggests that all three preparations of ketoprofen are bound mainly to site I and secondarily to site II. © 1993 Wiley-Liss, Inc.     

Studies on the interaction between human serum protein fractions and 18O-labeled oxosteroids

The nature of the interaction between progesterone or testosterone and human albumin as well as the interaction between progesterone and partially purified human transcortin has been studied. Modification of lysine residues of albumin with maleic anhydride resulted in a decreased binding of the steroid as judged from equilibrium dialysis experiments. This suggested that lysine residues in albumin interact with the oxosteroids. In order to check this hypothesis, steroids labeled with 18O in their oxo function (testosterone and progesterone) were synthesized for use as probes of the interactions. However, no loss of label was noted when testosterone or progesterone specifically 18O-labeled in their oxo functions were incubated with albumin. This suggested that no covalent interaction between the steroidal oxo group and albumin took place. This was in contrast to the results obtained with 3,20-18O-labeled progesterone and partially purified transcortin, where a complete loss of 18O label in the protein-bound steroid was found. The nonbound steroid showed an almost complete retention of label. These results indicate a participation of steroid oxo groups in the binding of progesterone to transcortin. Of the possible mechanisms discussed, imine bonds between the steroid and transcortin seem most likely although other types of interactions cannot be ruled out.     

Binding of physostigmine to rat and human plasma and crystalline serum albumins

The binding of 3H-physostigmine (3H-Ph) to human and rat plasma proteins and crystalline serum albumin was studied by ultrafiltration technique. This study showed that the percentage of 3H-Ph bound to rat plasma slightly decreased from 49% to 41% whereas human plasma showed an increase in binding from 29% to 43% over a 50-fold increase in drug concentration. Human plasma samples which were collected in a bag coated with citrate phosphate dextrose adenine-1 solution bound 50% less 3H-Ph than samples collected with EDTA indicating a drug-drug interaction between 3H-Ph and anticoagulants. No significant change in binding was observed if the samples were frozen prior to use. Scatchard plots for binding of 3H-Ph resulted in a positive slope for human plasma and a negative slope for rat plasma; whereas curvilinear Scatchard plots with negative slopes were obtained for binding to human and rat crystalline serum albumin.     

Calorimetric Study of Nonspecific Interaction Between Lead Ions and Bovine Serum Albumin

The nonspecific interaction between lead ions and bovine serum albumin (BSA) was studied by the calorimetric technique. According to thermodynamic parameters calculated from titration curves, it can be seen that the increase of intermolecular bond energies and decrease of disorder in the system were accompanied by a binding process. This kind of binding is the reaction “driven by enthalpy.” Furthermore, the denatured BSA has more binding sites and more changes in enthalpy and entropy than the native BSA because the unfolded chain of denatured BSA could adapt itself to the binding reaction with lead ions more easily.