Binding to human serum albumin of zidovudine (AZT) and novel AZT derivatives. Experimental and theoretical analyses

This work presents the binding of AZT and nine novel AZT derivatives to human serum albumin (HSA), both defatted (HSA(D)) and complexed with fatty acids (HSA(FA)). The bound fractions and binding site were determined by applying an ultrafiltration procedure, with an increased affinity for the majority of these derivatives to HSA(D) being found with respect to that of AZT, while only one derivative exhibited an increased affinity for HSA(FA). By means of computational methods, we observed that specific electrostatic interactions are responsible for the increased affinity for HSA(D), while the presence of fatty acids complexed to HSA caused an intense electrostatic repulsion with negatively charged ligands located in Sudlow site I, thus diminishing their bound fractions. A strong relationship between the calculated energetic components and the observed experimental affinity was identified.     

Deciphering the binding of carbendazim (fungicide) with human serum albumin: A multi-spectroscopic and molecular modelling studies

Carbendazim is a benzimidazole fungicide used to control the fungal invasion. However, its exposure might lead to potential health problems. The present study evaluates the interaction of carbendazim (CAR) with human serum albumin (HSA) which is an important drug carrier protein and plays a very crucial role in the transportation of small molecules. A number of biophysical techniques were employed to investigate the binding of CAR with HSA. The increased UV-absorption of HSA on titrating with CAR suggests the formation of HSA–CAR complex and it could be due to the exposure of aromatic residues. The fluorescence study confirmed that CAR quenches the fluorescence of HSA and showed the static mode of quenching. CAR (50 µM) quenches around 56.14% of the HSA fluorescence. The quenching constant, binding constant, number of binding site and free energy change was calculated by fluorescence quenching experiment. Competitive displacement assay showed Sudlow’s site I as the primary binding site of CAR on HSA. The synchronous fluorescence study revealed the perturbation in the microenvironment around tyrosine and tryptophan residues upon binding of CAR to HSA. The circular dichroism results suggested that the binding of CAR to HSA altered its secondary structure. Molecular docking experiment demonstrated the binding of CAR to Sudlow’s site I of HSA. Docking studies suggested that the hydrogen bonding, van der Waals and pi-alkyl are playing role in the interaction of CAR with HSA. The study confirmed the conformational changes within HSA upon binding of CAR.     

Molecular dynamics simulation as a tool for assessment of drug binding property of human serum albumin

Human serum albumin (HSA) is a major plasma protein and binding of drugs with this plasma protein has a great importance. It possess esterase activity which can cleave the drugs containing ester bond and thus, can regulate the effect of drugs. Till date no systematic study has been done to analyse binding of such drugs and to compare the results with the drugs which do not have ester bond. Therefore, in the present study two different categories—ester and non-ester drugs have been considered to analyse their interaction with HSA at two principle drug binding sites using molecular modelling tools. It is observed that the drugs irrespective of ester or non-ester nature prefer either Sudlow site I or II by hydrogen bond and hydrophobic interactions. The information obtained from the study can assist to study pharmacokinetics of the drugs and that in turn will help in noval drug discoveries.     

Probing the interaction of thionine with human serum albumin by multispectroscopic studies and its in vitro cytotoxic activity toward MCF-7 breast cancer cells

The studies on protein–dye interactions are important in biological process and it is regarded as vital step in rational drug design. The interaction of thionine (TH) with human serum albumin (HSA) was analyzed using isothermal titration calorimetry (ITC), spectroscopic, and molecular docking technique. The emission spectral titration of HSA with TH revealed the formation of HSA–TH complex via static quenching process. The results obtained from absorption, synchronous emission, circular dichroism, and three-dimensional (3D) emission spectral studies demonstrated that TH induces changes in the microenvironment and secondary structure of HSA. Results from ITC experiments suggested that the binding of TH dye was favored by negative enthalpy and a favorable entropy contribution. Site marker competitive binding experiments revealed that the binding site of TH was located in subdomain IIA (Sudlow site I) of HSA. Molecular docking study further substantiates that TH binds to the hydrophobic cavity of subdomain IIA (Sudlow site I) of HSA. Further, we have studied the cytotoxic activity of TH and TH–HSA complex on breast cancer cell lines (MCF-7) by MTT assay and LDH assay. These studies revealed that TH–HSA complex showed the higher level of cytotoxicity in cancer cells than TH dye-treated MCF-7 cells and the significant adverse effect did not found in the normal HBL-100 cells. Fluorescence microscopy analyses of nuclear fragmentation studies validate the significant reduction of viability of TH–HSA-treated human MCF-7 breast cancer cells through activation of apoptotic-mediated pathways.     

Applications of tailored ferrocenyl molecules as electrochemical probes of biochemical interactions

The development of electrochemical probes useful for investigating the occupancy by other molecules of sites on complex proteins such as human serum albumin (HSA) is described. Ferrocenyl-(oxoethylene)-fatty acid compounds of different fatty acid chain length probed different binding sites on HSA. The interaction could be changed from one primarily with a drug binding site, when the probe was ferrocene methanol, to one predominantly with medium-chain fatty acid binding sites, by adding an (oxoethylene)-fatty acid substituents. Finally, the interaction could be changed to one interacting primarily with high-affinity long-chain fatty acid binding sites, as the fatty acid chain length in ferrocene-(oxoethylene)-fatty acid molecules increased. These results strongly implied that the binding could be further tailored by relatively simple modifications to the probe, for example, by changing the balance of hydrophobicity and hydrophilicity. The possibility of a procedure using mass-produced electrochemical cells to determine the fractional occupancy of different sites on HSA is demonstrated.     

Interaction of meropenem with ‘N’ and ‘B’ isoforms of human serum albumin: a spectroscopic and molecular docking study

Carbapenems are used to control the outbreak of β-lactamases expressing bacteria. The effectiveness of drugs is influenced by its interaction with human serum albumin (HSA). Strong binding of carbapenems to HSA may lead to decreased bioavailability of the drug. The non-optimal drug dosage will provide a positive selection pressure on bacteria to develop resistance. Here, we investigated the interaction between meropenem and HSA at physiological pH 7.5 (N-isoform HSA) and non-physiological pH 9.2 (B-isoform HSA). Results showed that meropenem quenches the fluorescence of both ‘N’ and ‘B’ isoforms of HSA (ΔG < 0 and binding constant ~10⁴ M^?1). Electrostatic interactions and van der Waal interactions along with H-bonds stabilized the complex of meropenem with ‘N’ and ‘B’ isoforms of HSA, respectively. Molecular docking results revealed that meropenem binds to HSA near Sudlow’s site II (subdomain IIIA) close to Trp-214 with a contribution of a few residues of subdomain IIA. CD spectroscopy showed a change in the conformation of both the isoforms of HSA upon meropenem binding. The catalytic efficiency of HSA (only N-isoform) on p-nitrophenyl acetate was increased primarily due to a decrease in K_m and an increase in k_cat values. This study provides an insight into the molecular basis of interaction between meropenem and HSA.     

In vitro binding of leukotriene B4 (LTB4) to human serum albumin: evidence from spectroscopic, molecular modeling, and competitive displacement studies

Circular dichroism (CD) and UV absorption spectroscopy were utilized for the first time to investigate the interaction between leukotriene B4 (LTB4) and human serum albumin (HSA) in vitro. The weak intrinsic CD signal of LTB4 was enhanced fivefold in the presence of HSA. The red-shifted, hypochromic, and reduced vibrational fine structure of the ligand/protein UV absorption spectrum indicated complexation of the two molecules in solution. Results obtained from CD titration experiments were subjected to non-linear regression analysis to estimate the binding parameters (Ka = 6.7 x 10(4) M(-1), n = 1). Palmitic acid strongly decreased the induced CD signal of the LTB4/HSA complex, suggesting the role of a high-affinity fatty acid HSA binding site in the leukotriene complexation. Molecular modeling calculations based on the crystal structure of HSA predicted that the long-chain fatty acid site that overlaps with drug binding site II in subdomain IIIA was the most likely binding location for LTB4. Using the drug site II-specific marker ligand rac-ibuprofen, this prediction was confirmed with induced-CD displacement measurements. To the authors' knowledge, the current study represents the first demonstration of binding of LTB4 to HSA in vitro and has implications for the biological transport of this important pro-inflammatory mediator in vivo.     

Understanding the effects of two bound glucose in Sudlow site I on structure and function of human serum albumin: theoretical studies

Human serum albumin (HSA) is the most abundant protein found in blood serum. It carries essential metabolites and many drugs. The glycation of HSA causes abnormal biological effects. Importantly, glycated HSA (GHSA) is of interest as a biomarker for diabetes. Recently, the first HSA structure with bound pyranose (GLC) and open-chain (GLO) glucose at Sudlow site I has been crystallised. We therefore employed molecular dynamics (MD) simulations and ONIOM calculations to study the dynamic nature of two bound glucose in a pre-glycated HSA (pGHSA) and observe how those sugars alter a protein structure comparing to wild type (Apo) and fatty acid-bound HSA (FA). Our analyses show that the overall structural stability of pGHSA is similar to Apo and FA, except Sudlow site II. Having glucose induces large protein flexibility at Sudlow site II. Besides, the presence of glucose causes W214 to reorient resulting in a change in W214 microenvironment. Considering sugars, both sugars are exposed to water, but GLO is more solvent-accessible. ONIOM results show that glucose binding is favoured for HSA (?115.04 kcal/mol) and GLO (?85.10 kcal/mol) is more preferable for Sudlow site I over GLC (?29.94 kcal/mol). GLO can strongly react with K195 and K199, whereas K195 and K199 provide slightly repulsive forces for GLC. This can confirm that an open-chain GLO is more favourable inside a pocket.     

Structural basis of binding of fluorescent, site-specific dansylated amino acids to human serum albumin

Human serum albumin (HSA) has two primary binding sites for drug molecules. These sites selectively bind different dansylated amino acid compounds, which-due to their intrinsic fluorescence-have long been used as specific markers for the drug pockets on HSA. We present here the co-crystal structures of HSA in complex with six dansylated amino acids that are specific for either drug site 1 (dansyl-l-asparagine, dansyl-l-arginine, dansyl-l-glutamate) or drug site 2 (dansyl-l-norvaline, dansyl-l-phenylalanine, dansyl-l-sarcosine). Our results explain the structural basis of the site-specificity of different dansylated amino acids. They also show that fatty acid binding has only a modest effect on binding of dansylated amino acids to drug site 1 and identify the location of secondary binding sites.     

Human serum albumin binding of novel antiretroviral nucleoside derivatives of AZT.

The binding of novel nucleoside derivatives (2-7) to the Human Serum Albumin (HSA) was studied using zidovudine (AZT), as standard compound. The applicability of two different techniques to separate unbound drug from drug-protein complex was analyzed: the gel filtration and ultrafiltration methods. Ultrafiltration was found to be an adequate procedure for the separation of unbounded drug from the drug-protein complex. Incubation temperature ranging from 0 to 37 degrees C did not modify considerably the bound fractions. The same effects were observed as HSA concentration was modified. Binding assays of studied compounds to purified 1% (w/v) HSA at 0 degrees C, indicate that bound fraction of 2-7 ranges from 13 to 47%, exhibiting a higher affinity to HSA than AZT (12%), which would introduce some interesting improvements in their pharmacokinetic properties. In addition, by means of displacement studies using HSA site specific drugs such as diazepam and salicylate, it was determined that AZT binds to site I of the HSA molecule, by a mainly entropy driven process (DeltaS = 10.834 cal/mol degrees K), being these observations extensive to 2-7. Some structural basis to explain enhanced affinity of these novel derivatives was also established.     

Is the Sudlow site I of human serum albumin more generous to adopt prospective anti-cancer bioorganic compound than that of bovine: A combined spectroscopic and docking simulation approach

A comparative biophysical study on the individual conformational adaptation embraced by two homologous serum albumins (SA) (bovine and human) towards a potential anticancer bioorganic compound 2-(6-chlorobenzo[d] thiazol-2-yl)-1H-benzo[de] isoquinoline-1,3(2H)- dione (CBIQD) is apparent from the discrimination in binding behavior and the ensuing consequences accomplished by combined in vitro optical spectroscopy, in silico molecular docking and molecular dynamics (MD) simulation. The Sudlow site I of HSA although anion receptive, harbors neutral CBIQD in Sudlow site I (subdomain IIA, close to Trp) of HSA, while in BSA its prefers to snugly fit into Sudlow site II (subdomain IIIA, close to Tyr). Based on discernable diminution of HSA mean fluorescence lifetime as a function of biluminophore concentration, facile occurrence of fluorescence resonance energy transfer (FRET) is substantiated as the probable quenching mechanism accompanied by structural deformations in the protein ensemble. CBIQD establishes itself within HSA close to Trp214, and consequently reduces the micropolarity of the cybotactic environment that is predominantly constituted by hydrophobic amino acid residues. The stronger association of CBIQD with HSA encourages an allosteric modulation leading to slight deformation in its secondary structure whereas for BSA the association is comparatively weaker. Sudlow site I of HSA is capable to embrace a favorable conformation like malleable gold to provide room for incoming CBIQD, whereas for BSA it behaves more like rigid cast-iron which does not admit any change thus forcing CBIQD to occupy an altogether different binding location i.e. the Sudlow site II. The anticancer CBIQD is found to be stable within the HSA scaffold as vindicated by root mean square deviation (RMSD) and root mean square fluctuation (RMSF) obtained by MD simulation. A competitively inhibited esterase-like activity of HSA upon CBIQD binding to Lys199 and Arg257 residues, plausibly envisions that similar naphthalimide based prodrugs, bearing ester functionality, can be particularly activated by Sudlow site I of HSA. The consolidated spectroscopic research described herein may encourage design of naphthalimide based pro-drugs for effective in vivo biodistribution using HSA-based drug delivery systems.     

Chromatographic analysis of acetohexamide binding to glycated human serum albumin

Acetohexamide is a drug used to treat type II diabetes and is tightly bound to the protein human serum albumin (HSA) in the circulation. It has been proposed that the binding of some drugs with HSA can be affected by the non-enzymatic glycation of this protein. This study used high-performance affinity chromatography to examine the changes in acetohexamide–HSA binding that take place as the glycation of HSA is increased. It was found in frontal analysis experiments that the binding of acetohexamide to glycated HSA could be described by a two-site model involving both strong and weak affinity interactions. The average association equilibrium constant (K_a) for the high affinity interactions was in the range of 1.2–2.0 × 10⁵ M⁻¹ and increased in moving from normal HSA to HSA with glycation levels that might be found in advanced diabetes. It was found through competition studies that acetohexamide was binding at both Sudlow sites I and II on the glycated HSA. The K_a for acetohexamide at Sudlow site I increased by 40% in going from normal HSA to minimally glycated HSA but then decreased back to near-normal values in going to more highly glycated HSA. At Sudlow site II, the K_a for acetohexamide first decreased by about 40% and then increased in going from normal HSA to minimally glycated HSA and more highly glycated HSA. This information demonstrates the importance of conducting both frontal analysis and site-specific binding studies in examining the effects of glycation on the interactions of a drug with HSA.     

<Emphasis Type="Italic">In silico</Emphasis> analysis of paraoxon binding by human and bovine serum albumin

Albumin is known to be able to cleave ether bonds in organophosphates (OPs). Amino acids responsible for esterase and pseudo-esterase albumin activity towards OPs are not yet finally identified. Presumably, Sudlow’s site I with the Tyr150 residue shows a “true” esterase activity, while Sudlow’s II site with the Tyr411 residue—a pseudo-esterase one. Both human (HSA) and bovine (BSA) serum albumins were used in in vitro studies of albumin (pseudo)esterase activity towards OPs. There is a body of evidence that the efficiency of interaction of different xenobiotics differs for these two proteins. Using paraoxon as an example, the aim of this study was to conduct an in silico study of the OP interaction with the previously identified potential sites of HSA and BSA (pseudo)esterase activity, to estimate the possibility of enzymatic reactions at these sites, to comparatively analyze these proteins from the evolutionary viewpoint, and to assess the possibility of extrapolating the experimental data obtained on BSA to a human organism. Molecular docking of paraoxon into the sites of HSA and BSA potential (pseudo)esterase activity has been performed. Conformational changes occurring in the resultant complexes with time have been studied by molecular dynamics simulation. It has been shown that Sudlow’s site II is less liable to evolutionary changes. Binding of modulators at other sites is not required for productive sorption of OPs and the phosphorylation reaction at Sudlow’s site II. It has been concluded that simi lar results for HSA and BSA could be expected for the irreversible binding of OPs at Sudlow’s site II. Since Sudlow’s site I is less conservative, diff erent binding efficiency could be expected for rigid molecules or optically active compounds. Both for HSA and BSA, productive binding of OPs at Sudlow’s site I is possible only after changes in the albumin molecule structure induced by binding of modulators at other sites.     

Evaluation of blood-brain barrier penetration and examination of binding to human serum albumin of 7-O-arylpiperazinylcoumarins as potential antipsychotic agents

The delivery of drugs to the brain is complicated by the multiple factors including low blood–brain barrier (BBB) passive permeability, active BBB efflux systems, and plasma protein binding. Thus, a detailed understanding of the transport of the new potent substances through the membranes is vitally important and their physico-chemical characteristics should be analyzed at first. This work presents an evaluation of drug likeness of eight 7-O-arylpiperazinylcoumarin derivatives with high affinity towards serotoninergic receptors 5-HT_1A and 5-HT_2A with particular analysis of the requirements for the CNS chemotherapeutics. The binding constants to human serum albumin (HSA) were determined at physiological pH using fluorescence spectroscopy, and then their mode of action was explained by analysis of theoretical HSA complexes. Dynamic simulation of systems allowed for reliable evaluation of the interaction strength. The analyzed coumarins were able to pass BBB, and they present good drug likeness properties. They showed high affinities to HSA (log K_Q = 5.3–6.0 which corresponds to −8.12 to −7.15 kcalmol⁻¹ of Gibbs free energy). The changes of the emission intensity upon binding to HSA were scrutinized showing the different mode of action for 4-phenylpiperazinylcoumarins. The values of computed Gibbs free energy and determined on the basis of experimentally obtained binding constants log K_Q coincide suggesting a good quality of the theoretical model. Overall the 8-acetyl-7-O-arylpiperazinyl-4-methylcoumarin derivatives represent valuable lead compounds to be further tested in various preclinical assays as a possible chemotherapeutics against CNS diseases. Studied coumarins can be metabolized by cytochrome P450 to aldehydes and hydroxy derivatives. The existence of other binding sites inside HSA than Sudlow’s site 1 was postulated. The longer aliphatic linker between coumarin and piperazine moieties favored binding to HSA in other than Sudlow site 1 pocket.     

Crystal structure analysis of warfarin binding to human serum albumin: anatomy of drug site I

Human serum albumin (HSA) is an abundant transport protein found in plasma that binds a wide variety of drugs in two primary binding sites (I and II) and can have a significant impact on their pharmacokinetics. We have determined the crystal structures at 2.5 A-resolution of HSA-myristate complexed with the R-(+) and S-(-) enantiomers of warfarin, a widely used anticoagulant that binds to the protein with high affinity. The structures confirm that warfarin binds to drug site I (in subdomain IIA) in the presence of fatty acids and reveal the molecular details of the protein-drug interaction. The two enantiomers of warfarin adopt very similar conformations when bound to the protein and make many of the same specific contacts with amino acid side chains at the binding site, thus accounting for the relative lack of stereospecificity of the HSA-warfarin interaction. The conformation of the warfarin binding pocket is significantly altered upon binding of fatty acids, and this can explain the observed enhancement of warfarin binding to HSA at low levels of fatty acid.     

Reversible binding of ethacrynic acid to human serum albumin: Difference circular dichroism study

The reversible binding of ethacrynic acid was characterized by a difference circular dichroism method. A 2/1 stoichiometry was determined for the [drug]/[HSA] (human serum albumin) complex. The reversible binding of ethacrynic acid to HSA determines direct competition with ligands that selectivity bind to site II and to the fatty acid site. Furthermore, indirect competition was shown for ligands for site I (anticooperative) and to site III (cooperative). Chirality 11:33–38, 1999. © 1999 Wiley‐Liss, Inc.