Modelisation of the Association Mechanism of a Series of Huperzine Derivatives Used for Alzheimer Disease with Human Serum Albumin: Effect of the Magnesium Cation

The role of the Mg²⁺ cation on huperzine molecule binding (drugs used for Alzheimer disease) on human serum albumin (HSA) was studied by affinity chromatography. The thermodynamic data corresponding to this binding were determined for a wide range of Mg²⁺ concentrations (x). For each solute, the huperzine binding on HSA was divided into two Mg²⁺ concentration regions. For a low x value, below x_c (1.2 mM), the binding decrease with x. For x above x_c the hydrophobic effect and van der Waals interactions between the huperzine molecule and the HSA implied a decrease in its binding. These results showed that for patients with Alzheimer disease, an Mg²⁺ supplementation during treatment with these huperzine molecules can increase the active pharmacological molecule concentration.     

Degree of Complexation of Anticoagulant Rodenticides with Human Serum Albumin: Effect of Saccharose and Sodium

A theoretical treatment has been developed to describe association between rodenticides and human serum albumin (HSA). The degree of complexation n_c (the amount (%) of complexed guest) and the association constant (K) for rodenticide–HSA binding were determined. Enthalpy–entropy compensation was also investigated in relation to this mathematical model to confirm rodenticide binding behavior with HSA. The role of the sodium cation and saccharose in this association were also analyzed. As expected for a salting-out agent, addition of Na⁺ cation to the mobile phase led to enhancement of n_c and K values by increasing the hydrophobic effect. When saccharose was increased above a critical x_c value equal to 4 mM, a decrease of the association constant and the degree of complexation was observed, owing to reduction of the radius of curvature of the HSA cavity.     

Study of the interactions between fluoroquinolones and human serum albumin by affinity capillary electrophoresis and fluorescence method

The interactions between fluoroquinolones and human serum albumin (HSA) were investigated by affinity capillary electrophoresis (ACE) and fluorescence quenching technique. Based on the efficient separation of several fluoroquinolones using a simple phosphate buffer, the binding constants of fluoroquinolones with HSA were determined simultaneously during one set of electrophoresis by ACE method. The thermodynamic parameters were obtained from data at different temperatures, and the negative ΔH and ΔS values showed that both hydrogen bonds and van der Waals interaction played major roles in the binding of fluoroquinolones to HSA. The interactions were also studied by fluorescence quenching technique. The results of fluorescence titration revealed that fluoroquinolones had the strong ability to quenching the intrinsic fluorescence of HSA through the static quenching procedure. The binding site number n, apparent binding constant K_b and the Stern-Volmer quenching constant K_sv were determined. The thermodynamic parameters were also studied by fluorescence method, and the results were consonant with that of ACE.     

Spectroscopic and Molecular Docking Approaches for Investigation of Interaction of Phellopterin with Human Serum Albumin

The mechanism of interaction between human serum albumin (HSA) and natural product phellopterin (PL) from Angelica dahurica was investigated by spectroscopic techniques with molecular docking under simulated physiological conditions. The experimental results showed that the fluorescence of HSA was regularly quenched by PL, and the quenching constants (K_SV) decreased with increasing temperature, which indicated that the quenching mechanism was a static quenching procedure. The binding constants (K_A) were larger than 10^?5 M^?1 and the number of binding sites (n) was approximate to 1 at different temperatures, which indicated that the binding affinity was hige and there was just one main binding site in HSA for PL. According to thermodynamic parameters from Van't Hoff equation, the binding process of PL with HSA was spontaneous and exothermic process due to ΔG < 0, and the electrostatic force played major role in the binding between PL and HSA according to ΔH < 0 and ΔS > 0. The binding distance (r) was calculated to be about 3.35 nm, which implied that the energy transfer from HSA to PL occurred with high possibility according to the theory of Förster's non-radiation energy transfer. The microenvironment and conformation of HSA changed with the addition of PL based on the results of synchronous and three-dimensional fluorescence methods. The molecular docking analysis revealed the binding locus of PL to HSA in subdomain IIIA (Sudlow's site II).     

Spectroscopic studies on interactions of the tetrakis(acetato)chloridodiruthenium(II,III) complex and the Ru2(II,III)-NSAID-derived metallodrugs of ibuprofen and ketoprofen with human serum albumin

Diruthenium paddlewheel-structured complexes bearing a Ru₂(II,III) multiply bonded core show promising potential in medicinal chemistry. This work reports studies on the interactions of the tetrakis(acetato)chloridodiruthenium(II,III) complex (RuAc), [Ru₂(μ-O₂CCH₃)₄Cl], and the corresponding Ru₂(II,III)-non-steroidal anti-inflammatory drug (NSAID) metallodrugs of the NSAIDs ibuprofen (RuIbp) and ketoprofen (RuKet) with the human serum albumin (HSA). Circular dichroism (CD) studies showed that the three Ru₂ complexes interact with the HSA and induce conformational changes on the secondary structure of the protein. The reaction of the RuAc complex with the protein was monitored and the RuAc/HSA binding constant was estimated on the basis of electronic absorption spectroscopy data. Fluorescence emission spectroscopy studies were performed for all the Ru₂ complex/HSA systems and the Stern–Volmer constants and the thermodynamic parameters were determined for the RuAc/HSA binding. Mass spectrometry data confirmed the presence of the Ru₂ complexes in the protein phase after ultrafiltration. The studies suggest that the nature of the RuAc binding to the HSA is distinct from that of the derived RuIbp and RuKet metallodrugs. Electrostatic forces, accompanied by coordination of the metal to the amino acid side chains of the protein, seem to be the main forces acting in the RuAc/HSA binding, while non-covalent/hydrophobic forces might be predominant in the Ru₂-NSAID metallodrug/protein interactions. The findings suggest that the HSA protein might be a potential carrier in the blood plasma for the Ru₂(II,III)-NSAID metallodrugs.     

Characterization of Interactions Between Fluoroquinolones and Human Serum Albumin by CE–Frontal Analysis

The binding of fluoroquinolones to the transport protein, human serum albumin (HSA), under simulated physiological conditions has been studied by capillary electrophoresis–frontal analysis (CE–FA). The binding of these drugs to human plasma was evaluated by using ultrafiltration and capillary electrophoresis. The free drug concentration [D]_f at each HSA concentration was determined by the plateau height in the electropherograms and the calibration lines. The binding constants of fluoroquinolones and HSA were estimated using nonlinear regression with origin 7.5 software. The fluoroquinolones were found to show low affinity toward HSA, with binding constants ranging from 1.73 × 10² to 5.40 × 10² M^?1. The percentages of protein binding (PB) for fluoroquinolones to HSA were between 8.6 and 22.2%, while the PB percentages for fluoroquinolones to human plasma were between 10.2 and 33.1%. It can be found that the PB percentages for fluoroquinolones to HSA are mostly lower than those for fluoroquinolones to human plasma. It suggests that HSA is the primary protein responsible for the binding of fluoroquinolones in human plasma. The thermodynamic parameters were obtained by CE–FA. The positive ?H and ?S values obtained by CE–FA showed that the binding reaction was an endothermic process, and the entropy drive the binding and hydrophobic interaction played major roles in the binding of fluoroquinolones to HSA.     

Zinc-human serum albumin association: testimony of two binding sites

The zinc cation (Zn²⁺) binding to human serum albumin (HSA) was studied using a non-equilibrium approach in order to prove two HSA binding sites. The effect of the bulk solvent pH and column temperature T on this binding and the corresponding thermodynamic data were also investigated. It appeared that the association process can be divided into two pH value ranges due to a predominant Zn²⁺ interaction with either HSA site I or site II. It was also demonstrated that the Zn²⁺ affinity for the site II was weakly affected by modifying the mobile phase pH whereas for the site I, the affinity constant increased strongly with increasing the pH of the bulk solvent.     

Characterization of the interaction between a platinum(II) complex and human serum albumin: spectroscopic analysis and molecular docking

In this study, the interaction between (2,2?-bipyridine)(pyrrolidinedithiocarbamato) platinum(II) nitrate, [Pt(bpy)(pyr-dtc]NO₃, and human serum albumin (HSA) was investigated by various spectroscopic methods (UV–vis, fluorescence, CD and FT-IR) and molecular docking technique at three temperatures. UV–vis absorption spectroscopy showed that Pt(II) complex can denature the protein at moderate concentrations. The results of emission quenching at two temperatures has revealed that the quenching mechanism of Pt(II) complex with HSA was static quenching mechanism. Binding constants (K), binding site number (n) and corresponding thermodynamic parameters ?G?, ?H? and ?S? were calculated and revealed that hydrophobic forces played a major role when Pt(II) complex interacted with HSA. The binding distance (r) between above complex and HSA based on Förster?s theory of non-radiation energy transfer was calculated as 3.22 nm. Alterations of HSA secondary structure induced by complex were confirmed by FT-IR and CD measurements. Also, a molecular docking study was performed for identification of key structural features of binding of the Pt complex into the receptor and predicting bioactive conformers. Our results may provide valuable information to understand the mechanistic pathway of drug delivery and to pharmacological behavior of drug.     

On Mn(Hg)/Mn(II) equilibria and reactions in aqueous solution

The title subject has been studied through galvanostatic single-pulse and chronopotentiometric measurements on the Mn(Hg)/Mn(II) electrode and equilibrium measurements on the same and the Ag/AgCl electrode, all in x MMnCl₂+(0.5?x)M MgCl₂ solutions of pH 4.3–4.9 at 25°C. The Mn(Hg)/Mn(II) reactions are found to occur in two consecutive steps, an unsymmetric (α_c near 0.8) ion-transfer step Mn(Hg)/Mn(I) and an essentially symmetric (α_c near 0.5) electron-transfer step Mn(I)/Mn(II). Besides charge transfer, no sluggishness other than diffusion is observed, but the dispersed precipitate Mn₂Hg₅ of saturated amalgam serves as an ageing-dependent source of anodic reactant Mn(Hg). Quantitative kinetic and thermodynamic data are presented and discussed. Comparisons are made to corresponding reactions for the succeeding elements iron, cobalt, nickel, copper, and zinc.     

Einfluß der Umkristallisation auf die Phasenumwandlungen von Dipalmitoyllecithin/Wasser-Mischungen

The influence of crystallization of phospholipids on the phase transition temperaturesT _u, enthalpiesΔ¯H _u and the molar heats¯c _p of 1,2-dipalmitoyllecithin-watermixtures was studied by differential scanning calorimetry. Three lecithin samples, crystallized under different conditions, were measured in the concentration range fromx _W=0,5 up tox _W=0,97x _W=mole fraction of water.

1. The different crystallization effects different structures. The temperatures and enthalpies of the main phase transition of the samples with the ordered crystalline structures are higher than those of the samples with lamellar structures.
2. The differences between the various samples in the thermodynamic parameters (T _u, Δ¯H_u, ¯c_p) of the main transition disappear in the concentration rangex _W>0.8. In this concentration range lamellar structures are existent.
3. The molar heat of the monohydrates is also a function of the crystallization conditions. In the concentration rangex _W>0.93 the¯c _p=f(T) curves of the three lecithin samples are identically.
4. The thermograms of the monohydrates show above the main phase transition two additional transition peaks which are also influenced by the conditions of crystallization.

     

Chromatographic Framework to Determine the Memantine Binding Mechanism on Human Serum Albumin Surface

In this work, the interaction of memantine with human serum albumin (HSA) immobilized on porous silica particles was studied using a biochromatographic approach. The determination of the enthalpy change at different pH values suggested that the protonated group in the memantine–HSA complex exhibits a heat protonation with a magnitude around 65 kJ mol^?1. This value agrees with the protonation of a guanidinium group, and confirmed that an arginine group may become protonated in the memantine–HSA complex formation. The thermodynamic data showed that memantine–HSA binding, for low temperature (<293 K), is dominated by a positive entropy change. This result suggests that dehydration at the binding interface and charge–charge interactions contribute to the memantine–HSA complex formation. Above 293 K, the thermodynamic data ΔH and ΔS became negative due to van der Waals interactions and hydrogen bonding which are engaged at the complex interface. The temperature dependence of the free energy of binding is weak because of the enthalpy–entropy compensation caused by a large heat capacity change, ΔC _p = ? 3.79 kJ mol^?1 K^?1 at pH = 7. These results were used to determine the potential binding site of this drug on HSA.     

Insight into the binding evaluation of two antitumor Pd(II) complexes with human serum albumin

The interaction between two novel water-soluble palladium(II) complexes (Pd(bpy)(pyr-dtc)]NO₃, complex I and ([Pd(phen)(pyr-dtc)]NO₃, complex II, where bpy = 2,2′-bipyridine, phen = 1,10-phenanthroline and pyr-dtc = pyrrolidinedithiocarbame) and human serum albumin (HSA) was investigated by fluorescence quenching spectroscopy, synchronous, fluorescence resonance energy transfer (FRET) and three-dimensional fluorescence combined with UV–Vis absorption spectroscopy and circular dichroism technique under simulative physiological conditions. Fluorescence analysis demonstrated that the quenching mechanism of HSA by Pd(II) complexes was static fluorescence quenching and hydrogen bonds and van der Waals interactions were the main intermolecular force based on thermodynamic data. The HSA–Pd(II) complex interaction had a high affinity of 10⁵ M^?1, and the number of binding sites n is almost 1. The results of synchronous fluorescence, three-dimensional fluorescence spectra, UV–Vis absorption and CD spectroscopy indicated that these two complexes may induce the microenvironment around the tryptophan residues and the conformation of human serum albumin. The binding distance (r) in the interaction between Pd(II) complex and HSA was estimated by the efficiency of fluorescence resonance energy transfer (FRET). Furthermore, results from multiple spectroscopic studies are consistent and indicate that the antitumor Pd(II) complexes can efficiently bind with human serum albumin molecules, providing a reasonable model that can help in understanding the design, transportation and toxic effects of anticancer agents.     

Characterization of interaction between doxycycline and human serum albumin by capillary electrophoresis‐frontal analysis

The binding of doxycycline to HSA under simulated physiological conditions (pH 7.4, 67 mM phosphate, I=0.17, drug concentration 100 μM, HSA concentration up to 475 μM, 36.5°C) was studied by CE‐frontal analysis. The number of primary binding sites, binding constant and physiological protein‐binding percentage were 1.9, 1.51×10³ M^?1 and 59.80%, respectively. In addition, the thermodynamic parameters including enthalpy change (ΔH), entropy change (ΔS) and free energy change (ΔG) of the reaction were obtained in order to characterize the acting forces between doxycycline and HSA. Furthermore, to better understand the nature of doxycycline–HSA binding and to get information about potential interaction with other drugs, displacement experiments were performed. The results showed that doxycycline binds at site II of HSA.     

A semi-empirical method for prediction of critical concentrations for polymer overlap in solution

The hydrodynamic volumes of solvated polymers shrink with increasing concentrations in solution until a concentration (c_x) is reached at which the effective dimensions are the same as those in a Flory theta solvent. Further increases beyond c_x result in progressively greater overlapping of separate macromolecules. Several theories are available for the prediction of c_x but none is entirely satisfactory. A semi-empirical method is described here for the estimation of c_x, using intrinsic viscosities as input parameters. The magnitude of c_x is shown to be solvent dependent; its lower limit is zero, in a theta solvent.     

Determination of the Interaction of Arsenic and Human Serum Albumin by Online Microdialysis Coupled to LC with Hydride Generation Atomic Fluorescence Spectroscopy

Study on the stoichiometry and affinity of the arsenicals bound to HSA is an important step toward a better understanding of arsenic toxic effects. After incubation of As^III or As^V with HSA at the physiological conditions (pH 7.43 and 37 °C), the free arsenicals and arsenic-HSA complexes were separated and detected by the combined techniques of microdialysis and liquid chromatography with hydride generation atomic fluorescence spectroscopy (MD–LC–HGAFS). The decrease of As^III peak response rather than As^V indicated that HSA reacted with As^III but not As^V. The binding plots indicated that the binding between HSA and As^III was in Scatchard pattern when the concentration ratios of As^III to HSA were ≤1:1. The strong binding sites (n ₁) were 1.6 and the stability constant (K ₁) was 1.54 × 10⁶ M^?1. When the concentration ratios of As^III to HSA were >1:1, the binding was in Plasvento pattern with the stability constant K ₂ ? 0 and no specific binding of As^III with HSA. On the contrary, As^V did not show binding with HSA. The results showed that As^III reacted with HSA more readily than As^V, which provides a chemical basis for arsenic toxicity.     

Computational and experimental study on the interaction of three novel rare earth complexes containing 2,9-dimethyl-1,10-phenanthroline with human serum albumin

In this paper, several rare earth [terbium(III), ytterbium(III) and yttrium(III)] complexes containing 2,9-dimethyl-1,10-phenanthroline (Me₂Phen) were successfully synthesized and characterized by means of elemental analysis (CHN), infrared spectroscopy (FT-IR), UV–vis absorption spectroscopy and ¹HNMR. To explore the potential medicinal value of these complexes (MMe₂Phen), their binding interactions with human serum albumin (HSA) were investigated through UV–vis and fluorescence spectroscopies and also molecular docking examinations. The thermodynamic parameters, binding forces and Förster resonance distance between these complexes and Trp-214 of HSA were estimated from the analysis of fluorescence measurements. The values of estimated binding constants (K_b) ranging for the formation of MMe₂Phen:HSA complex were in the order of 10⁵ M^?1. The thermodynamic parameters determined by van’t Hoff analysis of K_b (ΔH°?<?0 and ΔS°?<?0) clearly indicate the major rules of hydrogen bonds and van der Waals interactions in the formation process of MMe₂Phen:HSA. The values of Stern–Volmer constant and the evaluation of dynamic quenching constant at various temperatures provided good evidences for static quenching mechanism. Furthermore, the results of molecular docking calculation and competitive binding experiments represent the binding of these complexes to site 3 of HSA located in subdomain IB, containing both polar and apolar residues. The consistency of computational and experimental results, according to the binding sites and the order of binding affinities (TbMe₂Phen?>?YbMe₂Phen?>?YMe₂Phen), supports the accuracy of docking calculation.     

Study on the interaction of three structurally related cationic Pt(II) complexes with human serum albumin: importance of binding affinity and denaturing properties

Human serum albumin (HSA) primarily functions as a transport carrier for a vast variety of natural ligands and pharmaceutical drugs. In the present study, three structurally related cationic Pt(II) complexes ([Pt(ppy)(dppe)]CF₃CO₂: 1, Pt(bhq)(dppe)]CF₃CO₂: 2, and [Pt(bhq)(dppf)]CF₃CO₂: 3) were used to evaluate their interaction with HSA under different experimental setups, using UV–Vis absorption spectroscopy, fluorescence and circular dichroism techniques. The spectroscopic results suggest that upon binding to HSA, the Pt(II) complexes could effectively induce structural alteration of the protein. The complexes can bind to HSA with the binding affinities of the following order: 3 > 2 > 1. Also, thermodynamic parameters of binding between these complexes and HSA indicated the existence of entropy-driven spontaneous interaction which primarily dominated with the hydrophobic forces. Also, docking simulation study revealed the binding details of these complexes on HSA. Complex 3 with highest binding affinity for HSA indicates lowest denaturing effect on this protein. The low denaturation properties of 3 appear important in the terms of lower susceptibility of this platinum complex for possible development of deleterious side effects.     

Thermodynamic insights into the binding of ANS with the salt induced molten globule states of cytochrome c

The molten globule (MG) state or the A-state of cytochrome c (cyt c) has been induced by addition of salts sodium perchlorate (NaClO₄), sodium thiocyanate (NaSCN), and sodium sulphate (Na₂SO₄) at pH 2.0. Isothermal titration calorimetry (ITC) has been used for determining the energetics of binding of 8-anilino naphthalene sulphonate (ANS) to the salt induced A-state of cyt c, and the accompanying thermodynamic parameters have been analyzed to elucidate the nature of the interactions between ANS and the A-state of cyt c. Temperature dependent studies of the binding process reveal that the binding is not a two state process and there are more than a single type of interactions involved. Addition of a bulky salt tetraethylammonium bromide (TEAB) increases the stoichiometry of binding significantly, with a reduction in the binding affinity at a higher concentration. The results provide quantitative information on the binding of ANS to the salt induced molten globule states of cyt c. It is further inferred that the binding involves a combination of hydrophobic and electrostatic interactions.     

Study of caffeine binding to human serum albumin using optical spectroscopic methods

The binding of caffeine to human serum albumin (HSA) under physiological conditions has been studied by the methods of fluorescence, UV-vis absorbance and circular dichroism (CD) spectroscopy. The mechanism of quenching of HSA fluorescence by caffeine was shown to involve a dynamic quenching procedure. The number of binding sites n and apparent binding constant K _b were measured by the fluorescence quenching method and the thermodynamic parameters ΔH, ΔG, ΔS were calculated. The results indicate that the binding is mainly enthalpy-driven, with van der Waals interactions and hydrogen bonding playing major roles in the reaction. The distance r between donor (HSA) and acceptor (caffeine) was obtained according to the Förster theory of non-radiative energy transfer. Synchronous fluorescence, CD and three-dimensional fluorescence spectroscopy showed that the microenvironment and conformation of HSA were altered during the reaction.