Bilirubin binding properties of pigeon serum albumin and its comparison with human serum albumin

Binding of bilirubin (BR) to pigeon serum albumin (PgSA) was studied by absorption, fluorescence and CD spectroscopy and results were compared with those obtained with human serum albumin (HSA). PgSA was found to be structurally similar to HSA as judged by near- and far-UV CD spectra. However, PgSA lacks tryptophan. Binding of BR to PgSA showed relatively weaker interaction compared to HSA in terms of binding affinity, induced red shift in the absorption spectrum of BR and CD spectral characteristics of BR-albumin complexes. Photoirradiation results of BR-albumin complexes also showed PgSA-bound BR more labile compared to HSA-bound BR.     

Biological characteristics of two lysines on human serum albumin in the high-affinity binding of 4Z,15Z-bilirubin-IXα revealed by phage display

4Z,15Z-bilirubin-IXα (4Z,15Z-BR), an endogenous compound that is sparingly soluble in water, binds human serum albumin (HSA) with high affinity in a flexible manner. A phage library displaying recombinant HSA domain II was constructed, after three rounds of panning against immobilized 4Z,15Z-BR, and eight clones with high affinity for the pigment were found to contain conserved basic residues, such as lysine or arginine, at positions 195 and 199. The wild type and two mutants, K195A and K199A, of whole HSA as well as stand-alone domain II were expressed in Pichia pastoris for ligand-binding studies. The binding of 4Z,15Z-BR to the K195A and K199A mutants was decreased in both whole HSA and the domain II proteins. The P-helicity conformer (P-form) of 4Z,15Z-BR was found to preferentially bind to the wild types and the K195A mutants, whereas the M-form bound to the K199A mutants. Photoconversion experiments showed that the P-form of 4Z,15Z-BR was transformed into highly water-soluble isomers at a much faster rate than the M-form. In addition, the M-form of 4Z,15Z-BR showed higher affinity for domain I than for domain II. The present findings suggest that, whereas both Lys195 and Lys199 in subdomain IIA are important for the high-affinity binding of 4Z,15Z-BR, Lys199 plays a more prominent role in the elimination of 4Z,15Z-BR.     

Bilirubin,model membranes and serum albumin interaction: The influence of fatty acids

Electronic circular dichroism (ECD), absorption and fluorescence spectroscopy were used to study the enantioselective interactions which involved bilirubin (BR), liposomes, human serum albumin of two different purities, pure (HSA) and non-purified of fatty acids (FA-HSA), and individual fatty acids.The application of the ECD technique to such a complex problem provided a new perspective on the BR binding to liposomes. Our results demonstrated that in the presence of pure HSA, BR preferred to bind to the protein over the liposomes. However, in the presence of FA-HSA, BR significantly bound to the liposomes composed either of DMPC or of sphingomyelin and bound only moderately to the primary and secondary binding sites of FA-HSA even at high BR concentrations. For the DMPC liposomes, even a change of BR conformation upon binding to the primary binding site was observed. The individual saturated fatty acids influenced the BR binding to HSA and liposomes in a similar way as fatty acids from FA-HSA. The unsaturated fatty acids interacted with BR alone and prevented it from interacting with either 99-HSA or the liposomes. In the presence of arachidonic acid, BR interacted enantioselectively with the liposomes and only moderately with 99-HSA.Hence, our results show a substantial impact of the liposomes on the BR binding to HSA. As a consequence of the existence of fatty acids in the blood plasma and in the natural structure of HSA, BR may possibly bind to the cell membranes even though it is normally bound to HSA.     

Limited Role for the Bilirubin-Biliverdin Redox Amplification Cycle in the Cellular Antioxidant Protection by Biliverdin Reductase

In mammalian cells, heme is degraded by heme oxygenase to biliverdin, which is then reduced to bilirubin by biliverdin reductase (BVR). Both bile pigments have reducing properties, and bilirubin is now generally considered to be a potent antioxidant, yet it remains unclear how it protects cells against oxidative damage. A presently popular explanation for the antioxidant function of bilirubin is a redox cycle in which bilirubin is oxidized to biliverdin and then recycled by BVR. Here, we reexamined this putative BVR-mediated redox cycle. We observed that lipid peroxidation-mediated oxidation of bilirubin in chloroform, a model of cell membrane-bound bilirubin, did not yield biliverdin, a prerequisite for the putative redox cycle. Similarly, H₂O₂ did not oxidize albumin-bound bilirubin to biliverdin, and in vitro oxidation of albumin or ligandin-bound bilirubin by peroxyl radicals gave modest yields of biliverdin. In addition, decreasing cellular BVR protein and activity in HeLa cells using RNA interference did not alter H₂O₂-mediated cell death, just as BVR overexpression failed to enhance protection of these cells against H₂O₂-mediated damage, irrespective of whether bilirubin or biliverdin were added to the cells as substrate for the putative redox cycle. Similarly, transformation of human BVR into hmx1 (heme oxygenase) mutant yeast did not provide protection against H₂O₂ toxicity above that seen in hmx1 mutant yeast expressing human heme oxygenase-1. Together, these results argue against the BVR-mediated redox cycle playing a general or important role as cellular antioxidant defense mechanism.Biliverdin reductase (BVR)³ forms part of the major pathway for the disposition of cellular heme in mammalian cells. This pathway is initiated by heme oxygenase, which converts heme to carbon monoxide, iron, and biliverdin, which in turn is reduced to bilirubin by BVR at the expense of NADPH. Because of its intramolecular hydrogen bonding, the bilirubin produced is sparingly soluble in water at physiological pH and ionic strength (1). Hence, bilirubin is usually tightly bound to albumin in order to be transported within the blood circulation (2), from which it is removed mainly through uptake by hepatocytes. Once bilirubin is transferred across the cell membrane of hepatocytes, it binds glutathione S-transferases before being transformed to water-soluble derivatives by conjugation of one or both of its propionyl groups before its excretion into bile and then the intestine (3).Under physiological conditions, plasma bilirubin concentrations in humans range from ∼5 to 20 μm, practically all of which is unconjugated pigment bound to albumin (1). Abnormally high plasma concentrations are associated with the risk of developing neurologic dysfunction due to preferential deposition of bilirubin in brain and its toxic effects on cell functions. In fact for many years, biliverdin and bilirubin were generally regarded as waste products of heme metabolism in higher animals, although earlier work suggested that these bile pigments might play a role as natural antioxidants, since small quantities of the pigment stabilize vitamin A and β-carotene during intestinal uptake, and animals with low plasma bilirubin showed early signs of vitamin E deficiency (4, 5).In a series of in vitro studies, Stocker et al. (6–8) demonstrated that unconjugated bilirubin, at micromolar concentrations, efficiently scavenged peroxyl radicals in homogenous solution or multilamellar liposomes. At physiologically relevant oxygen tension, bilirubin surpassed α-tocopherol as an antioxidant in liposomes (8), and it is thought to protect plasma proteins and lipids from many but not all oxidants (9). However, it is less clear whether this antioxidant activity extends to in vivo situations or protection of cells from oxidative stress. Although produced in essentially all cells, the normal range of cellular bilirubin concentrations is unknown. However, it is probably in the low nanomolar range, well below that of established cellular antioxidants, such as glutathione and ascorbate, arguing against bilirubin being an important cellular antioxidant. Nonetheless, in vitro studies with rat neuronal cultures showed that the presence of 10 nm bilirubin in the culture medium protected cells against 10,000-fold higher concentrations of hydrogen peroxide (10). Later, Barañano et al. (11) confirmed such observations in HeLa cells and demonstrated that BVR depletion increased reactive oxygen species (ROS) and cell death. This led to the following proposal of the BVR-amplified redox cycle. While acting as an antioxidant, bilirubin is oxidized to biliverdin that is then reduced back to bilirubin by the ubiquitous and abundant BVR.An important underlying assumption of this amplification cycle is that ROS-mediated bilirubin oxidation in cells is specific and yields substantial if not stoichiometric amounts of biliverdin. Inconsistent with this assumption, however, earlier studies showed that high yields of biliverdin formation are limited to certain oxidants (i.e. peroxyl radicals) and albumin-bound bilirubin. In cells, bilirubin is probably present in membranes, bound to proteins other than albumin, or present in conjugated form. Therefore, we reexamined the putative redox amplification cycle. Our results show that reaction of these forms of bilirubin with 1e- or 2e-oxidants at best generates modest amounts of biliverdin. Furthermore, overexpression of BVR does not protect mammalian or yeast cells from hydrogen peroxide-mediated damage, thereby casting doubt on the importance of the putative BVR redox cycle for cellular antioxidant protection.     

Behavior of various mammalian albumins towards bilirubin binding and photochemical properties of different bilirubin-albumin complexes

Bilirubin (BR) binding properties of serum albumins from different mammalian species viz. human (HSA), equine (ESA), dog (DSA) and guinea pig (GPSA) were studied by absorption, fluorescence and CD spectroscopy. Whereas, a complex of BR with ESA produced maximum change, GPSA–BR complex showed weaker interaction as reflected from absorption and fluorescence spectroscopic data. Conformational analysis of these albumins by near- and far-UV CD spectra suggested similar structural characteristics (both secondary and tertiary structures) for ESA and HSA, whereas, DSA and GPSA had lower amounts of secondary and tertiary structures being minimum for GPSA. Photoirradiation results of BR–albumin complexes showed GPSA-bound BR more labile compared with other complexes, whereas, BR–ESA complex was found to be more stable against photoinduced chemical changes. Taken together, all these results suggest that chiroptical properties/stability of albumin bound BR varies with albumin species.     

Chiroptical Properties of Bilirubin-Serum Albumin Binding Sites

Although the interactions between bilirubin and serum albumin are among the most studied serum albumin-ligand interactions, the binding-site location and the participation of bilirubin-serum albumin complexes in pathological and physiological processes are under debate. In this article, we have benefited from the chiral structure of bilirubin and used CD spectroscopy to characterize the structure of bilirubin bound to human and bovine serum albumins. We determined that in a phosphate buffer at pH 7.8 there are three binding sites in both human and bovine serum albumins. While the primary binding sites in human and bovine serum albumins bind bilirubin with P- and M-helical conformations, respectively, the secondary binding sites in both albumins bind bilirubin in the P-helical conformation. We have shown that the bonding of bilirubin to the serum albumin matrix is a more favorable process than the self-association of bilirubin under the studied conditions, with a maximum of three bound bilirubins per serum albumin molecule. Although bilirubin bound to the primary binding site has attracted the most attention, the presented results have documented the impact of the secondary binding sites which are relevant in the displacement reactions between BR and drugs and in the phenomena where bilirubin plays antioxidant, antimutagenic, and anti-inflammatory roles. Chirality 00:000000, 2013. © 2013 Wiley Periodicals, Inc.     

On the modulation of photoinduced fluorescence enhancement and conformational stability of albumin-bound bilirubin: effect of epsilon-NH(2) groups blocking and chloroform binding

Photoinduced fluorescence enhancement of bilirubin bound to primary binding site on human serum albumin (HSA) was completely ceased when epsilon-NH(2) groups of its internal lysine residues were covalently blocked by acetylation or succinylation though the pigment bound to these derivatives in a folded conformation akin to that bound to HSA. These photoinduced fluorescence modulations cannot be ascribed to the binding of bilirubin to secondary low affinity sites as the CD spectrum of bilirubin bound to these derivatives showed complete inversion upon addition of chloroform which binds to subdomain IIA in HSA where high affinity bilirubin binding site is located. Presence of chloroform reconciled the photoinduced alterations in the CD spectrum observed in its absence, suggesting that chloroform stabilized the bound ligand against light but the fluorescence properties of bilirubin complexed with acetylated or succinylated derivatives remained unchanged. Guanidination of internal epsilon-NH(2) groups in HSA by O-methylisourea did not alter the spectral properties of the bound ligand. These results suggest that salt linkage(s) existing between epsilon-NH(2) groups of lysine residues in HSA and carboxyl groups of bilirubin, act(s) as a potential barrier during conformational rotation of the bound ligand assisted by photoactivation and their abolishment can alter its dynamics and stereoselectivity, a hitherto unnoticed implication of salt linkage(s) in BR-HSA complex.     

Role of salt bridge(s) in the binding and photoconversion of bilirubin bound to high affinity site on human serum albumin

The role of salt bridge(s) (between epsilon-NH(2) groups of lysine residues of human serum albumin (HSA) and carboxyl groups of bilirubin) in the binding and photoconversion of bilirubin bound to high affinity site on HSA was investigated by covalent modification of approximately 20% internal (buried) lysine residues of HSA with acetic anhydride, succinic anhydride and O-methylisourea and white light irradiation of their complexes with bilirubin. The different HSA derivatives, namely, acetylated HSA (aHSA), succinylated HSA (sHSA) and guanidinated HSA (gHSA), thus obtained, were found to be homogeneous with respect to charge and size and characterized in detail in terms of mean residue ellipticity, Stokes radius, tryptophan fluorescence, bilirubin binding and the photochemistry of their complexes with bilirubin. All the three derivatives retained helical contents and molecular size (Stokes radius) similar to HSA except for sHSA which showed a slight increase in the Stokes radius from 3.56 to 3.64 nm. Further, fluorescence properties of aHSA and sHSA were also found to be different from HSA and gHSA. Based on difference spectral change, fluorescence quenching and fluorescence enhancement results of bilirubin bound to HSA and its derivatives, nearly 46 and 48% reduction in bilirubin binding was observed in the case of aHSA and sHSA, respectively. Both aHSA and sHSA showed a decrease of 8- and 10-fold, respectively, in association constant compared to native HSA. Although the bisignate circular dichroism (CD) spectra of an equimolar (1:1) bilirubin-HSA complex was retained by all three HSA derivatives, the intensity of both positive and negative CD Cotton effects decreased significantly in both aHSA and sHSA. gHSA which retained net charge identical to native HSA, showed little decrease in bilirubin binding and the intensity of bisignate CD Cotton effects. The photochemical reaction of bilirubin bound to aHSA and sHSA produced opposite results to those observed with HSA and gHSA. A brief (2 min) irradiation of an equimolar complex of bilirubin with both aHSA and sHSA accompanied a rapid shift (14-15 nm) in the absorption spectrum of the bound pigment towards the blue region and almost complete elimination of negative CD Cotton effects while only moderately affecting the magnitude of positive CD Cotton effects. On the other hand, similar treatment of the complexes of bilirubin with HSA and gHSA did not show any change in the absorption spectrum, only a slight decrease in the intensity of both positive and negative CD Cotton effects was observed. The fluorescence intensity of bilirubin bound to HSA and gHSA was increased upon irradiation with white light and after 30 min it was nearly twice the value observed at 0 min irradiation. Interestingly, no change in the fluorescence intensity of bilirubin bound either to aHSA or sHSA was observed upon irradiation, even on increasing the duration of irradiation to 1 h. Taken together, the results on fluorescence quenching, fluorescence enhancement, CD spectral changes and visible absorption spectroscopy suggest that salt bridge(s) of the type (-COO(-).(+)H(3)N-) in which the epsilon-NH(2) group(s) contributed by lysine residues, are not only involved in the enantioselective binding of bilirubin but also in the stereospecific photoisomerization of bilirubin bound to a high affinity site on HSA.     

Species-dependent stereoselective drug binding to albumin: a circular dichroism study

Drug binding to albumins from different mammalian species was investigated to disclose evidence of species-dependent stereoselectivity in drug-binding processes and affinities. This aspect is important for evaluating the reliability of extrapolating distribution data among species. The circular dichroism (CD) signal induced by drug binding to the albumins [human serum albumin (HSA), bovine serum albumin (BSA), rat serum albumin (RSA), and dog serum albumin (DSA)] were measured and analyzed. The binding of selected drugs and metabolites to HSA significantly differed from the binding to the other albumins in terms of affinity and conformation of the bound ligands. In particular, phenylbutazone, a marker of site one on HSA, showed a higher affinity for binding to BSA with respect to RSA, HSA, and DSA, respectively. In the case of diazepam, a marker of site two on HSA, the affinity decreased in order from HSA to DSA, RSA, and BSA. The induced CD spectra were similar in terms of energy and band signs, suggesting almost the same conformation for the bound drug to the different albumins. Stereoselectivity was high for the binding of ketoprofen to HSA and RSA. A different sign was observed for the CD spectra induced by the drug to the two albumins because of the prevalence of a different conformation of the bound drug. Interestingly, the same induced CD spectra were obtained using either the racemic form or the (S)-enantiomer. Finally, significant differences were observed in the affinity of bilirubin, being highest for BSA, then decreasing for RSA, HSA, and DSA. A more complex conformational equilibrium was observed for bound bilirubin.     

Interaction of bilirubin with sealed and human serum albumin-entrapped sealed membranes

In order to study the mechanism of entry and localization of bilirubin (BR) into cell membrane, binding of BR to sealed and human serum albumin (HSA)-entrapped sealed membranes was studied by CD spectroscopy. An induced bisignate CD cotton effects (CDCEs) of BR-bound sealed membranes were observed with maxima at 515 nm and minima at 470 nm with a shoulder at 430 nm. BR-bound HSA-entrapped sealed membranes produced CD spectra with additional positive peaks at 450 and 475 nm and negative troughs at 390 and 415 nm. The induced CDCEs of BR-bound sealed membranes and BR-bound HSA-entrapped sealed membranes were perturbed by the addition of drugs (ceftriaxone and sodium salicylate) with the effect of ceftriaxone being more pronounced. Drugs’ being the displacer of BR from albumin, their incorporation in the incubation mixture was paralleled by reduction in CDCEs. Taken together, these results suggest that BR can traverse the membrane bilayer towards the inner surface instead of remaining intercalated in the exterior half of the bilayer.     

Human serum albumin: spectroscopic studies of the paclitaxel binding and proximity relationships with cisplatin and adriamycin

The interactions of anti-cancer drugs with blood constituents, particularly with serum albumin (HSA) may have a major influence on drug pharmacology and efficacy. In the present work the binding of paclitaxel (trade name Taxol) to human serum albumin and its effect on cisplatin and adriamycin interactions has been investigated through UV/visible, CD, fluorescence spectroscopy and the inductively couplet plasma atomic emission spectroscopy method. Displacement studies with use of bilirubin, as a competitive agent provided relevant information about the location of the binding site in HSA as well as the possible multidrug interactions.     

Chloroform-induced conformational changes in the bound pigmentin bilirubin-albumin complexes

Chloroform-induced conformational changes of bilirubin (BR) bound to different serum albumins were studied by circular dichroism (CD) and fluorescence spectroscopy. Addition of a small amount of chloroform ( approximately 20 mM) to a solution containing 20 microM albumin and 15 microM BR changed the sign order and magnitude of the characteristic CD spectra of all BR-albumin complexes except BR-PSA complex which showed abnormal behavior. Monosignate negative CD Cotton effects (CDCEs) of BR complexed with SSA, GSA and BuSA were transformed into bisignate CDCEs in presence of chloroform akin to those exhibited by chloroform free solution of BR-HSA complex, indicating that the pigment acquired right handed plus (P) chirality when chloroform was added to these complexes. Bisignate CD spectra of BR complexed with HSA and BSA showed complete inversion upon addition of chloroform corroborating earlier findings. On the other hand, changes observed with BR-RSA complex were slightly different showing an additional CD band of weak intensity centered around 390 nm though inversion of CDCEs was similar to that of BR-HSA complex. Monosignate CD spectra of BR-PSA complex also showed three CD bands occurring at 409, 470 and 514 nm after chloroform addition. These results indicated significant but different effects of chloroform on the conformation of bound BR in BR-albumin complexes which can be ascribed to the changes in the exciton chirality of bilirubin probably due to altered hydrophobic microenvironment induced by the binding of chloroform at or near the ligand binding site. Chloroform severely quenched the intrinsic tryptophan fluorescence of the protein and shifted the emission maxima towards blue region in all the albumins except PSA. However, quantitative differences in both quenching and blue shift were noted in different serum albumins. This suggests that chloroform probably binds in the close vicinity of tryptophan residue(s) located in subdomain(s) IIA or IB and II both. The fluorescence of BR-albumin complexes was also found to be sensitive to the presence of a small amount of chloroform. But the changes observed in the fluorescence of the bound pigment in presence of chloroform were less marked as compared to the changes in the intrinsic fluorescence of protein per se. Taken together, these results suggest that there is at least one conserved site for chloroform binding in all these albumins which is at or near the BR binding site.     

Understanding the role of internal lysine residues of serum albumins in conformational stability and bilirubin binding

The role of internal lysine residues of different serum albumins, viz. from human, rabbit, goat, sheep and buffalo (HSA, RbSA, GSA, SSA and BuSA), in conformational stability and bilirubin binding was investigated after blocking them using acetylation, succinylation and guanidination reactions. No significant change in the secondary structure was noticed whereas the tertiary structure of these proteins was slightly altered upon acetylation or succinylation as revealed by circular dichroism (CD), fluorescence and gel filtration results. Guanidination did not affect the native protein conformation to a measurable extent. Scatchard analysis, CD and absorption spectroscopic results showed marked reductions (5-21-fold decrease in K(a) and approximately 50% decrease in the CD Cotton effect intensity) in the affinity of albumins for bilirubin upon acetylation or succinylation whereas guanidination produced a small change. Interestingly, monosignate CD spectra of bilirubin complexed with GSA, SSA and BuSA were transformed to bisignate CD spectra upon acetylation or succinylation of internal lysine residues whereas spectra remained bisignate in the case of bilirubin bound to acetylated or succinylated derivatives of HSA and RbSA. When probed by CD spectroscopy, bilirubin bound to acetylated or succinylated derivatives of GSA and SSA rapidly switched over to native albumins and not vice versa. These results suggested that salt linkage(s) contributed by internal lysine residue(s) play an important role in the high-affinity binding of bilirubin to albumin and provide stability to the native three-dimensional conformation of the bound pigment. Chloroform severely decreased the intensity of both positive and negative CD Cotton effects of bilirubin complexed with acetylated or succinylated derivatives of all albumins which otherwise increased significantly in the case of bilirubin complexed with native and guanidinated albumin derivatives, except the bilirubin-RbSA complex which showed a small decrease in intensity. These results suggest that the presence of salt linkage(s) in bilirubin-albumin complexation is(are) crucial to bring about effective and efficient stereochemical changes in the bound pigment by co-binding of chloroform which seems to have at least one conserved binding site on these albumins that is shared with bilirubin.     

Effect of processing methods on colouration of human serum albumin preparations

Human serum albumin is a well tolerated therapeutic for the treatment of hypovolemia. Despite all commercial human albumin preparations being derived from plasma, these products can have a highly variable colour. Albumin samples derived from ethanol precipitation and chromatographic fractionation procedures were evaluated for bilirubin and biliverdin levels and by spectrophotometry. It was shown that albumin derived from a chromatographic process, which had a bilirubin:albumin ratio similar to that observed in plasma, had a vibrant yellow appearance. The albumin derived from ethanol precipitation had undetectable levels of bilirubin, and the amber colour of this product was attributed mainly to residual haem. The presence of bilirubin during pasteurisation led to oxidation to biliverdin, with a resultant colour change from yellow to yellow/green. Given that the antioxidant properties of bilirubin are well established, it is possible that bilirubin helps protect albumin from oxidation during the pasteurisation step.     

Prooxidant and antioxidant activities of bilirubin and its metabolic precursor biliverdin: a structure-activity study

Bilirubin, which is derived from its metabolic precursor biliverdin, is the end product of heme catabolism. It has been proposed as a physiological antioxidant present in human extracellular fluids. We have earlier shown that bilirubin in the presence of the transition metal ion Cu(II) causes strand cleavage in DNA through generation of reactive oxygen species, particularly the hydroxyl radical. Thus bilirubin possesses both antioxidant and prooxidant properties. In order to understand the chemical basis of various biological properties of bilirubin, we have studied the structure-activity relationship between bilirubin and its precursor biliverdin. The latter has also been reported to possess both antioxidant and toxic properties. In the present studies bilirubin was found to be more effective in the DNA cleavage reaction and a more efficient reducer of Cu(II). The rate of formation of hydrogen peroxide and hydroxyl radicals by the compounds also showed a similar pattern. The relative antioxidant activity was also examined by studying the effect of these compounds on DNA cleavage by a hydroxyl radical generating system and their quenching effect on hydroxyl radicals. The results indicate that bilirubin is more active both as an antioxidant as well as an oxidative DNA cleaving agent. A model for binding of copper to bilirubin has been proposed where two copper ions are bound to two molecules of bilirubin through their terminal pyrrole nitrogens. In order to account for the enhanced copper reducing capacity of bilirubin we have further proposed that an additional copper binding site is provided for in the case of bilirubin due to the absence of a double bond between pyrrole rings II and III. Further it would appear that the structural features of the bilirubin molecule which are important for its prooxidant action are also the ones that render it a more effective antioxidant.     

Probing the interaction of human serum albumin with bilirubin in the presence of aspirin by multi-spectroscopic, molecular modeling and zeta potential techniques: insight on binary and ternary systems

Here, we report on the effect of aspirin (ASA), on the binding parameters with regard to bilirubin (BR) to human serum albumin (HSA). Two different classes of binding sites were detected. Binding to the first and second classes of the binding sites was dominated by hydrophobic forces in the case of HSA-BR, whereas in the case of the ternary system, binding to the first and second classes of the binding sites was achieved by electrostatic interaction. The binding constant (K(a)) and number of binding site (n) obtained were 1.6 × 10(6)M(-1) and 0.98, respectively, for the primary binding site in the case of HSA-BR, and 3.7 × 10(6)M(-1) and 0.84, respectively, in the presence of ASA (ternary complex) at λ(ex)= 280 nm. The progressive quenching of the protein fluorescence as the BR concentration increased indicated an arrangement of the domain IIA in HSA. Changes in the environment of the aromatic residues were also observed by synchronous fluorescence spectroscopy (SFS). Changes of the secondary structure of HSA involving a decrease of α-helical and β-sheet contents and increased amounts of turns and unordered conformations were mainly found at high concentrations of BR. For the first time, the relationship between the structural parameters of HSA-BR by RLS for determining the critical induced aggregation concentration (C(CIAC)) of BR in the absence and presence of ASA was investigated, and there was a more significant enhancement in the case of the ternary mixture as opposed to the binary one. Changes in the zeta potential of HSA and the HSA-ASA complex in the presence of BR demonstrated a hydrophobic adsorption of this anionic ligand onto the surface of HSA in the binary system as well as both electrostatic and hydrophobic adsorption in the case of the ternary complex. By performing docking experiments, it was found that the acting forces between BR and HSA were mainly hydrophobic > hydrogen bonding > electrostatic interactions, and consequently BR had a long storage time in blood plasma, especially in the presence of ASA. This was due to the electrostatic interaction force between the BR and HSA being stronger in (HSA-ASA) BR than in the HSA-BR complex. In addition, it was demonstrated that, in the presence of ASA, the first binding site of BR on HSA was altered, but the parameters of binding did not become significantly modified, and thus the affinity of BR barely changed with and without ASA.     

Influence of aspirin and iron(III) tetrasulfonated phthalocyanine on bilirubin binding by human serum albumin

The interaction of bilirubin with aspirin-modified human serum albumin (HSA) and the influence of iron tetrasulfonated phthalocyanine on bilirubin binding by the native protein has been studied by difference spectroscopy and circular dichroism measurements. Spectroscopic studies of the systems containing bilirubin and aspirin-modified HSA compared to the analogous systems with the native protein have shown that selective acetylation of albumin at lysine 199 inhibits bilirubin binding by this protein. In both cases, interaction between bilirubin and albumin leads to complex formation at a molar ratio of ligand to protein of 2:1. The studies of the reaction of bilirubin with fragments of albumin produced by reaction with CNBr have demonstrated that one of the strong bilirubin binding sites is located in the M fragment and is close to the high-affinity binding site of aspirin. The other one was found in fragment C. Acetylation of albumin brings about marked conformational change in the protein, which probably accounts for the decrease in its ability to react with anti-HSA antibody. Bilirubin does not change the secondary structure of albumin but, like aspirin, lowers its antigenicity. It has been suggested that the decrease in antigenic properties in this case results from cooperation of the closely neighboring antigenic and bilirubin-binding sites. The studies of the influence of iron(III) tetrasulfonated phthalocyanine on bilirubin binding by HSA suggest that there is no competition between strong sites for iron(III) tetrasulfonated phthalocyanine and bilirubin, but these compounds compete for some of the weaker sites.     

Probing the Interaction of Human Serum Albumin With Bilirubin in the Presence of Aspirin by Multi-Spectroscopic,Molecular Modeling and Zeta Potential Techniques: Insight on Binary and Ternary Systems

Abstract

Here, we report on the effect of aspirin (ASA), on the binding parameters with regard to bilirubin (BR) to human serum albumin (HSA). Two different classes of binding sites were detected. Binding to the first and second classes of the binding sites was dominated by hydrophobic forces in the case of HSA-BR, whereas in the case of the ternary system, binding to the first and second classes of the binding sites was achieved by electrostatic interaction. The binding constant (K_a) and number of binding site (n) obtained were 1.6 × 10⁶ M^?1 and 0.98, respectively, for the primary binding site in the case of HSA-BR, and 3.7 × 10⁶ M^?1 and 0.84, respectively, in the presence of ASA (ternary complex) at δ_ex = 280 nm. The progressive quenching of the protein fluorescence as the BR concentration increased indicated an arrangement of the domain IIA in HSA. Changes in the environment of the aromatic residues were also observed by synchronous fluorescence spectroscopy (SFS). Changes of the secondary structure of HSA involving a decrease of α-helical and β-sheet contents and increased amounts of turns and unordered conformations were mainly found at high concentrations of BR. For the first time, the relationship between the structural parameters of HSA-BR by RLS for determining the critical induced aggregation concentration (C_CIAC) of BR in the absence and presence of ASA was investigated, and there was a more significant enhancement in the case of the ternary mixture as opposed to the binary one. Changes in the zeta potential of HSA and the HSA-ASA complex in the presence of BR demonstrated a hydrophobic adsorption of this anionic ligand onto the surface of HSA in the binary system as well as both electrostatic and hydrophobic adsorption in the case of the ternary complex. By performing docking experiments, it was found that the acting forces between BR and HSA were mainly hydrophobic > hydrogen bonding > electrostatic interactions, and consequently BR had a long storage time in blood plasma, especially in the presence of ASA. This was due to the electrostatic interaction force between the BR and HSA being stronger in (HSA-ASA) BR than in the HSA-BR complex. In addition, it was demonstrated that, in the presence of ASA, the first binding site of BR on HSA was altered, but the parameters of binding did not become significantly modified, and thus the affinity of BR barely changed with and without ASA.     

Paclitaxel-HSA interaction. Binding sites on HSA molecule

Paclitaxel (trade name Taxol) is one of the world's most effective anticancer drugs. It is used to treat several cancers including tumours of the breast, ovary and lung. In the present work the interaction of paclitaxel with human serum albumin (HSA) in aqueous solution at physiological pH has been investigated through CD, fluorescence spectroscopy and by the antibody precipitate test. Binding of paclitaxel to albumin impact on protein structure and it influences considerably albumin binding of other molecules like warfarin, heme or bilirubin. The paclitaxel-HSA interaction causes the conformational changes with the loss of helical stability of protein and local perturbation in the domain IIA binding pocket. The relative fluorescence intensity of the paclitaxel-bound HSA decreased, suggesting that perturbation around the Trp 214 residue took place. This was confirmed by the destabilization of the warfarin binding site, which includes Trp 214, and high affinity bilirubin binding site located in subdomain IIA.     

The radical ions and photoionization of bile pigments

The semireduced, semioxidized, and OH(.)-adduct radicals of bilirubin (BR) and biliverdin (BV) have been characterized using pulse radiolysis techniques. Laser flash photolysis (265-nm) of these pigments led to monophotonic photoionization with quantum yields of 0.08 for BR and 0.03 for BV. No evidence for triplet formation or for photoisomerization was found after 265-nm laser excitation. However, 347-nm excitation of BR in chloroform led to simultaneous photoisomerization and radical formation, but the radicals are thought to have originated from a pathway other than photoionization. The relevance of these observations to BR photoreactivity is discussed. BR radical ions in alkaline solution did not react with tryptophan (TrpH), but the semioxidized TrpH radical oxidized BR with k = 4.3 X 10(8) dm3 mole-1 sec-1. When human serum albumin (HSA) was oxidized using radiolytically generated azide radicals, a radical transformation involving TrpH and TyrOH residues occurred with k = 3.8 X 10(3) sec-1. When BR was complexed with the protein the transformation rate was reduced to 1.6 X 10(3) sec-1. This was interpreted in terms of a conformational change in the protein. Identification of the probable residues involved provided information about the primary BR binding site which was consistent with an earlier report.