Competitive interaction of biliverdin and bilirubin only at the primary bilirubin binding site on human albumin

The binding of biliverdin-IXα by human albumin and serum was quantitated, using three different binding techniques, to study the effects of biliverdin on bilirubin-albumin binding. The apparent equilibrium association constants (K ± SD) and binding capacities (n) of defatted albumin, pooled adult sera, and pooled umbilical cord sera for biliverdin are: K = 1.3 ± 2 × 10^{6 −1}, n = 1.00; K = 13.0 ± 3 × 10^{6 −1}, n = 0.90; and K = 6.8 ± 0.1 × 10^{6 −1}, n = 0.85, respectively. Although bilirubin binds at more than one albumin site, competitive studies showed that biliverdin binds only at the primary (highest affinity) bilirubin site. Sulfisoxazole, previously thought to compete with bilirubin for the primary binding site, was found to displace bilirubin from both primary and secondary bilirubin binding sites. Biliverdin, because of its specific binding and spectral characteristics, could be a useful probe for determining the capacity of the primary bilirubin-albumin binding site.     

Structural and functional differences between fetal and adult serum albumin

The binding of bilirubin with adult of fetal human serum albumin has been studied by steady-state fluorescence emission spectroscopy. The 1:1 complex between bilirubin and the two albumin samples shows very similar fluorescence properties, as well as essentially identical accessibility of the protein-bound bilirubin to fluorescence quenchers added to the aqueous medium. The intramolecular distance between bilirubin and the single tryptophyl residue can be estimated to be 2.4 +/- 0.2 nm for both proteins by singlet-singlet energy transfer. These findings suggest that fetal and adult human serum albumin have a very similar three-dimensional structure; the different binding capacity for bilirubin displayed by the two proteins is likely to be the consequence of small differences in the physico-chemical properties of some amino acid residues close to the bilirubin binding site, as indicated by pH-titration experiments of the intrinsic albumin fluorescence.     

Isolation and properties of a fatty acid-binding protein from the Pacific lamprey (Lampetra tridentata).

1. A survey of 12 vertebrate species showed that palmitate was bound by an albumin-like serum protein in all classes tested except the dogfish and the lamprey. 2. The major palmitate-binding protein of the Pacific lamprey was isolated and found to be of molecular mass 19,000. 3. The amino acid composition of this protein indicates that it is not a member of the albumin superfamily. 4. The 19-kDa lamprey protein binds bilirubin, cortisol and tryptophan only weakly, but binds palmitate with KA = 25 microM-1, comparable to the first long-chain fatty acid site of bovine albumin (KA = 34 microM-1).     

Albumin binding of photobilirubin II.

Photobilirubin II, a stereoisomer of bilirubin, binds to human serum albumin at a single binding site (K = 2.2 x 10(6)M-1), presumably the high-affinity bilirubin-binding site. Binding in the secondary (class II) binding sites is of minor importance. The results are discussed with respect to photometabolism of bilirubin and as a possible source of error in the determination of bilirubin unbound to albumin.     

Effects of aliphatic fatty acids on the binding of Phenol Red to human serum albumin.

Binding of Phenol Red to human serum albumin at pH 7.0 was studied by ultrafiltration (n1 = 1, K1 = 3.9 X 1-(4) M-1, n2 = 5, K2 = 9.6 X 10(2) M-1). The presence of 1 mol of octanoate or decanoate per mol of albumin caused a decrease in dye binding (dye/protein molar ratio 1:1), which, in contrast with additional fatty acid, was very pronounced: 1-8 mol of palmitate or stearate resulted in a small, and apparently linear, displacement of Phenol Red. The displacement effect of 1-5 mol of oleate, linoleate or linolenate per mol of albumin was comparable with that of the equimolar concentrations of palmitate or stearate. A higher molar ratios the unsaturated acids caused a drastic decrease in dye binding. The different Phenol Red-displacement effects of low molar ratios of medium-chain and long-chain fatty acids indicate that these acids have different high-affinity binding sites. In accordance with this proposal, low concentrations of stearate had only a small effect on the Phenol Red-displacement effect of octanoate. Phenol Red-binding curves in the presence of 1 mol of octanoate, 8 mol of stearate and 6 or 7 mol of linolenate per mol of albumin respectively indicated that the dye and the fatty acids do not complete for a common primary binding site. In contrast, a secondary Phenol Red-binding site could be identical with the primary octanoate-binding site. Furthermore, the primary Phenol Red-binding site could be the same as a secondary linolenate-binding site. Assignment of the different primary binding sites for Phenol Red and for medium-chain and long-chain fatty acids to a model of the secondary structure of albumin is attempted.     

Kinetics of bilirubin oxidase and modeling of an immobilized bilirubin oxidase reactor for bilirubin detoxification

The unbound bilirubin concentration and the enzymatic rate of bilirubin degradation by bilirubin oxidase in bilirubin-serum albumin solutions have been investigated experimentally and theoretically. A stoichiometric bilirubin-serum albumin binding analysis shows that the unbound bilirubin concentration depends only on the molar ratio of the total bilirubin concentration to the total serum albumin concentration. From the theoretical analysis and the measured unbound bilirubin concentrations, serum albumin may be modelled as a molecule having two binding sites, primary and secondary, with stoichiometric equilibrium constants of K(1) = 6 x 10(7)M(-1) and K(2) = 4.5 x 10(6)M(-1), respectively. The rate of total bilirubin degradation in bilirubin-serum albumin mixtures is zero order. An immobilized bilirubin oxidase reactor model, which shows good agreement with experimental bilirubin conversions, is presented. At a flow rate of 1 mL/min with a 8-mL reactor volume, a 50% bilirubin conversion per pass was observed with an inlet bilirubin concentration of 350muM and a serum albumin concentration of 500muM.     

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.     

Interaction of retinoids and bilirubin with the binding of arachidonic acid to human alpha-fetoprotein

Human alpha-fetoprotein (HAFP) has three binding sites for polyunsaturated fatty acids with association constant Ka = 1.8 X 10(7) M-1. One of these binding sites overlaps with a retinoid binding site with Ka = 2.6 X 10(6)M-1. Competition experiments with bilirubin showed that this compound does not compete neither with fatty acids nor with retinoids. Thus, the two bilirubin binding sites previously demonstrated appear as two additional binding sites on HAFP. Nevertheless, the close proximity of two fatty acid binding sites and two bilirubin binding sites resulted in a modification of the binding constants for fatty acids. It is hypothesised that the binding properties of HAFP reflect the three domain structures of the protein recently deduced from the study of the nucleotide sequence of HAFP mRNA and AFPcDNA segments.     

Flurorometric study of the partition of bilirubin among blood components: basis for rapid microassays of bilirubin and bilirubin binding capacity in whole blood

Bilirubin binds to many sites in blood, the strongest binding being to a single site on albumin. Secondary sites on albumin, most sites on other plasma proteins, and sites on erythrocyte membranes have affinities for bilirubin that are at most one-hundredth as great. Bilirubin binds to hemoglobin in red cells with an effective affinity that is less than one-thousandth that of the primary albumin site. Essentially the only bilirubin present in blood which fluoresces is that bound to the primary albumin site. Almost all the other bilirubin in blood fluoresces with a yield no more than one-fiftieth as large. Quantitative fluorometry of whole blood is possible using the “front-face” technique. The concentration of bilirubin bound to the primary albumin site can be determined in this way. The albumin binding capacity of a blood specimen can be similarly assayed upon titration of the specimen with bilirubin. The nonionic detergent dodecyldimethylamine oxide (DDAO) scavenges bilirubin from all sites in blood, and, since bilirubin is fluorescent in DDAO micelles, the total blood bilirubin can be assayed fluorometrically after addition of DDAO to the specimen. This detergent method also allows facile assay of red-cell-bound bilirubin. These fluorometric assays for total blood bilirubin, albumin-bound bilirubin, and albumin binding capacity are simple and rapid and use very small volumes of blood. They should be of great value in the research on neonatal jaundice and in its clinical management.     

Chemical modification of buried lysine residues of bovine serum albumin and its influence on protein conformation and bilirubin binding.

Using a double modification technique about 20% of the lysine residues of bovine serum albumin (BSA) which are not easily accessible in the native protein have been modified. The technique involved approximately 80% modification of lysine residues of BSA with citraconic anhydride followed by chemical modification of the remaining lysine residues with acetic anhydride, succinic anhydride, potassium cyanate, or O-methylisourea. Finally, these preparations were decitraconylated under mild acidic conditions to yield acetylated, succinylated, carbomylated or guanidinated BSA. All of these preparations were found to be homogeneous with respect to charge and size. The spectral, hydrodynamic and bilirubin binding properties of these preparations are described. In contrast to most of the highly modified proteins these preparations with the exception of succinylated BSA are very similar to native BSA in their spectral and hydrodynamic properties. However, the equilibrium association constant (Ka) with bilirubin measured by fluorescence quenching was decreased by about 100-fold in acetylated, carbamylated and succinylated BSA, but only 3-fold in guanidinated BSA. Since conformationally acetylated and carbamylated BSAs are identical to guanidinated BSA we conclude that the decrease in Ka in these preparations is solely due to loss of positive charge on 'critical' lysine residues. The results support a binding model for BSA in which bilirubin binding site is buried and the protein undergoes a series of relaxational changes in conformation upon interaction with bilirubin.     

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.     

The fatty acid analogue 11-(dansylamino)undecanoic acid is a fluorescent probe for the bilirubin-binding sites of albumin and not for the high-affinity fatty acid-binding sites.

1. The fluorescent fatty acid probe 11-(dansylamino)undecanoic acid (DAUDA) binds with high affinity to bovine and human serum albumin (BSA and HSA) at three sites. 2. The Kd of the primary binding site could not be determined; however, the two secondary sites appeared to be equivalent, with an apparent Kd of 8 x 10(-7) M for both BSA and HSA. 3. The spectral characteristics of DAUDA when bound to the primary site of the two albumins were different, with HSA producing a greater fluorescence enhancement and emission maximum at a shorter wavelength (480 nm) than for BSA (495 nm). 4. Displacement studies indicated that the DAUDA-binding sites were not equivalent to the primary long-chain fatty acid-binding sites on albumin, but corresponded to the bilirubin sites. Fatty acyl-CoAs also bind to the bilirubin sites, as do medium-chain fatty acids. 5. The solubility, stability and spectral properties of DAUDA make it an excellent probe for investigating the bilirubin-binding sites of albumin, particularly HSA.     

A novel binding site for bile acids on human serum albumin

Binding sites of bile acids on human serum albumin were studied using various probes: dansylsarcosine (site I probe), 7-anilinocoumarin-4-acetic acid (ACAA, site II probe), 5-dimethylaminonaphthelene-1-sulfonamide (DNSA, site III probe), cis-parinaric acid (probe for fatty acid binding site) and bilirubin. Bile acids competitively inhibited the binding of dansylsarcosine to human serum album whereas bile acids enhanced the binding of ACAA, DNSA, cis-parinaric acid and bilirubin. Considering the concentrations of bile acids required to inhibit the binding of dansylsarcosine to human serum albumin, the secondary binding site of bile acids may correspond to site I. Dissociation constants (K_d) of the primary binding sites of lithocholic and chenodeoxycholic acid to human serum albumin were approximately 0.2 and 4 μM, respectively, which was measured by equilibrium dialysis at 37° C. All the bile acids and their sulfates and glucuronides inhibited the binding of chenodeoxycholic acid to human serum albumin. Lithocholic and chenodeoxycholic acid and their sulfates and glucuronides exhibited more inhibition than cholic acid and its conjugates. In conclusion, bile acids may bind to a novel binding site on human serum albumin.     

The binding of bilirubin to albumin. A study using spin-labelled bilirubin

Binding between human serum albumin and a spin-labelled derivative of bilirubin was investigated by circular dichroism, fluorescence quenching, electron spin resonance and visible spectroscopy. The orders of magnitude of the binding constants obtained by flurorescence quenching and electron spin resonance spectroscopies were 10(7) and 10(3) 1 . mol-1, respectively. These data suggest that most spin-labelled bilirubin interacts with human serum albumin at the side not holding the spin-labelled side-arm. CD measurements showed the presence of at least two sites, associated with opposite Cotton effects. It is worthy of note that the Cotton sign of the first site is inverted with respect to the corresponding one of bilirubin. CD measurements on mixed systems (spin-labelled bilirubin/human serum albumin/bilirubin) were also performed. The decomposition of the ternary curves shows that the rotatory power of bilirubin bound to human serum albumin is higher in the ternary system than in the binary (bilirubin/human serum albumin). The corresponding CD measurements for the binding between spin-labelled bilirubin and bovine serum albumin are also reported and discussed.     

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.     

Interaction of bilirubin with reconstituted collagen fibrils.

1. Interaction of bilirubin with collagen fibrils was explored in a two-phase system where collagen was present as an opaque rigid gel composed of striated fibrils, and bilirubin as an aqueous solution. 2. The Ka value of the binding of bilirubin to collagen fibrils is 5.4 X 10(3)M-1. The interaction of bilirubin with collagen fibrils depends on temperature. Below 5 degrees C, the binding is greatly diminished and denaturation of collagen fibril aggregates at 52--53 degrees C into a dissolution state abolishes binding of bilirubin. 3. Salicylate and sulphanilamide do not affect the binding of bilirubin to reconstituted collagen fibrils. 4. Serum albumin (40--80mM), known to reverse the binding of bilirubin to lipids, dissociates only 50% of the bilirubin bound to collagen fibrils. This suggests that sites located on collagen participate in some tight binding of bilirubin and the corresponding binding sites on albumin do not compete with them. 5. Urea (4M) abolishes more than 70% of the binding of bilirubin to collagen. Urea and thermal denaturation studies indicate the importance of conformation and organization of collagen fibrillar aggregates for the binding of bilirubin.     

Mouse alpha 1-fetoprotein and albumin. A comparison of their binding properties with estrogen and fatty acid ligands

The binding of estradiol-17 beta (E2), diethylstilbestrol (DES), and polyene fatty acids, in particular arachidonate (C20:4), to alpha 1-fetoprotein (alpha-FP) and albumin purified from mouse embryo sera was studied using equilibrium dialysis and electrophoretic techniques. E2, arachidonate, and DES all bind to alpha-FP, but with decreasing strength. E2 is a high affinity, low capacity ligand (Ka approximately 0.8 X 10(8) M-1 and approximately 0.3 sites/mol of alpha-FP at 25 degrees C); arachidonate is a weaker ligand disposing of more sites (Ka approximately 0.3 X 10(7) M-1 and 4-5 sites/mol of alpha-FP); the binding of DES is of comparatively low affinity and capacity (Ka approximately 0.2 X 10(7) M-1 and n approximately 0.7/mol of alpha-FP). In spite of different structures and equilibrium parameters, E2, DES, and arachidonate are able to compete with each other for binding to the fetoprotein. The C22:4 and C22:6 fatty acids are also efficient concentration-dependent inhibitors of E2 or DES binding. Albumin binds the fatty acids and DES, but equilibrium parameters are different from those of alpha-FP. In particular, arachidonate is a better ligand for albumin, where it interacts with at least two classes of apparent sites (Ka1 approximately 0.3 X 10(8) M-1 and n1 approximately 1; Ka2 approximately 0.2 X 10(7) M-1 and n2 approximately 30). In contrast to alpha-FP, albumin virtually does not bind E2. Also, no competition could be demonstrated between DES and fatty acid ligands for binding to albumin. None of the studied interactions, with either albumin or alpha-FP, was modified even by high doses of bilirubin. The possible functions of the various binding activities present in fetal sera in the process of growth are discussed.     

Elucidating the interaction of ticlopidine with serum albumin and its role in bilirubin displacement in vitro

Ticlopidine is an anti-platelet drug that functions as a P2Y₁₂ receptor antagonist. The present study provides a detailed characterization of interaction of ticlopidine with a model transport protein, bovine serum albumin (BSA) as well as an assessment of its bilirubin displacing ability using a multi-spectroscopic approach in combination with isothermal titration calorimetry. The value of binding constant determined using ITC studies was found to be 3.03 × 10³ M^?1 with a binding stoichiometry of approximately 1:1. Competitive site marker experiments indicate that ticlopidine binds to Sudlow site I, located in subdomain IIA of BSA. In addition, Circular dichroism and 3D fluorescence spectroscopy indicated structural and conformational changes in BSA on interaction with ticlopidine. Thermodynamic parameters suggested that the reaction was spontaneous, exothermic, entropically driven, and involved hydrophobic interactions. These results were well supported by those obtained through molecular docking studies. Additionally, the effect of ticlopidine on bilirubin and albumin interaction was evaluated using the peroxidase method as well as through fluorescence spectroscopy. Ticlopidine was found to displace bilirubin from serum albumin. Moreover, the binding constant of bilirubin–serum albumin interaction also decreased in presence of ticlopidine. The results indicated that ticlopidine is a competitive displacer of bilirubin in vitro and may contribute to the incidences hyperbilirubinemia associated with the usage of this drug.     

Effect of bilirubin and serum albumin on the Na,K-ATPase activity in the synaptosomal membrane

The absorption spectrum of visible light, characteristic of the free bilirubin being in the aqueous medium, with a single maximum at 440 nm and with the shoulder in the region of 410-420 nm is transformed into the spectrum with two maxima in the region of 460 and 500 nm, respectively, when the pigment is bound in vitro by the synaptosomal membrane. There are two types of sites for bilirubin binding in the membrane particles, differing in the values of constants of association (Ka = 0.6 . 10(5) and approximately 2.02 . 10(5) M-1, respectively) and in the values of the maximum binding of bilidiene (5.0 and 7.0 nmoles/mg of membrane proteins, respectively). The binding of bilirubin by the synaptosomal membrane leads to a decrease in the specific activity of the membrane Na+,K+-ATPase. The enzyme activity is further decreasing when suspension of the membrane particles is exposed to the blue light (lambda max = 450-460 nm) in the presence of bilirubin. The addition of the serum albumin into the incubation medium potentiates the inhibition effect of bilirubin, when the suspension of membrane particles is lighted in the presence of bilirubin. The alkalization of the medium up to pH 7.8 (from pH 7.2) removes this potentiation effect of the addition of serum albumin.     

Analysis of binding interaction between the natural apocarotenoid bixin and human serum albumin by circular dichroism and fluorescence spectroscopy

Bixin is an important, pharmacologically active dietary cis-carotenoid, but its interaction with potential macromolecular targets is completely unexplored. This work was aimed to study the binding of bixin to human serum albumin (HSA), the most abundant protein in blood plasma. Circular dichroism (CD) spectroscopy in combination with UV/VIS absorption spectroscopy and fluorescence quenching techniques were applied. Appearance of induced CD bands in the UV- and VIS-absorption spectral regions indicated the formation of non-covalent carotenoid-albumin complexes. Shape and spectral position of the extrinsic Cotton effects suggested the binding of a single bixin molecule to HSA in chiral conformation. Scatchard and non-linear regression analyses of CD titration data resulted in similar values for the association constant (Ka = 6.6 and 4.6x10(5) M(-1), resp.) and for the number of binding sites (n = 1). The binding interaction was independently confirmed by fluorescence-quenching experiment from which the binding parameters were also calculated. CD Displacement measurements performed with marker ligands established that the main drug binding sites of HSA are not involved in binding of bixin. Palmitic acid decreased the amplitude of the induced CD bands suggesting a common albumin binding site for bixin and long-chain fatty acids. The above data indicate that HSA plays a significant role in the plasma transportation of bixin and related dietary carboxylic acid carotenoids.