Bilirubin and haeme binding to human serum albumin studied by spectroscopy methods

Cobinding of bilirubin and of haeme to human serum albumin was investigated by means of difference absorption spectroscopy and fluorescence spectroscopy. Two specific sites for bilirubin and two for haeme binding occur on the albumin molecule. The primary binding site for bilirubin (Ka = 2.5 microM-1) is different from the primary heame binding site (Ka = 50 microM-1; Beaven et al., Eur J. Biochem. 41, 539-546, 1974), the former, however, might be identical with the secondary center for haeme binding. Similarly, the primary haeme binding center might be identical with the secondary bilirubin binding site.     

Effect of obstructive jaundice on the fate of a nephrophilic organic anion in the rat

Renal transtubular transport of phenolsulfophthalein (PSP), a nephrophilic organic anion that circulates bound to albumin, was studied in normal and bile-duct-ligated rats. Intravenously injected PSP disappeared from the circulation more rapidly in bile-duct-ligated jaundiced rats than in intact animals. However, urinary excretion of PSP was significantly lower in the former than in the latter. Kinetic analysis revealed that binding of PSP to plasma protein(s) was significantly lower with jaundiced rats than with intact animals. Addition of albumin to plasma samples from bile-duct-ligated rats markedly increased PSP binding. The decreased PSP binding returned to normal levels after treating the jaundiced plasma with bilirubin oxidase, an enzyme that degrades amphiphilic bilirubin to water soluble metabolites. These results suggest that bilirubin might be the major metabolite that occupied the PSP binding site(s) on albumin in jaundiced rats. When PSP was injected bound to equimolar amount of albumin, the rate of PSP disappearance from the circulation decreased and urinary excretion of the ligand increased markedly; urinary excretion of PSP was significantly larger in bile-duct-ligated rats than in intact animals. These results suggest that the renal transport capacity for amphiphilic organic anions, such as PSP, might be increased compensatively in bile-duct-ligated animals, and that the apparent decrease in renal secretory transport for PSP might result from, at least in part, random distribution of the ligand to extrarenal tissues due to decrease in the binding activity of albumin.     

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.     

THE INFLUENCE OF BILIRUBIN ON OXIDATIVE PHOSPHORYLATION AND RELATED REACTIONS IN BRAIN AND LIVER MITOCHONDRIA: EFFECTS OF PROTEIN-BINDING

1. The uncoupling of oxidative phosphorylation of liver mitochondria by bilirubin does not occur in the presence of equimolar quantities of human serum albumin. With brain mitochondria, however, albumin was not protective. 2. A similar protective effect of albumin for liver, but not for brain, mitochondria was observed in studies of the effects of bilirubin on the ³²Pi-ATP exchange reaction. 3. The latent ATPase of fresh brain mitochondria is activated by Mg²⁺ but only slightly by DNP. Bilirubin increased the Mg²⁺ stimulated ATPase activity in liver mitochondria but depressed this activity in brain mitochondria. These effects were uninfluenced by protein binding. 4. Isotope studies with [¹⁴C]bilirubin demonstrated that the affinity of brain mitochondria for albumin-bound bilirubin is not greater than that of liver mitochondria. 5. The greater toxicity of protein-bound bilirubin for brain mitochondria than for liver mitochondria might be related to the greater lipid content of brain mitochondria.     

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.     

Affinity labeling of the primary bilirubin binding site of human serum albumin.

A label for the bilirubin binding sites of human serum albumin was synthesized by reacting 2 mol of Woodward's reagent K (N-ethyl-5-phenylisoxazolium-3'-sulfonate) with 1 mol of bilirubin. This yielded a water-soluble derivative in which both carboxyl groups of bilirubin were converted to reactive enol esters. Covalent labeling was achieved by reacting the label with human serum albumin under nitrogen at pH 9.4 and 20 degrees. Under the same conditions, no covalent binding to the monomers of several proteins could be demonstrated. The number of binding sites for bilirubin and the label were found to be the same, and competition experiments with bilirubin showed inhibition of covalent labeling. The absorption, fluorescence and CD spectra of the label in a complex with human serum albumin were similar to those of the bilirubin human serum albumin complex. However, following covalent attachment to the spectral properties were changed, indicating loss of conformational freedom of the chromophore. Labeling ratios were selected to result in the incorporation of less than 1 mol of label/mol of human serum albumin. Under these conditions, labeling is thought to occur primarily at the high affinity binding site.     

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.     

The Blood–Brain Barrier and Bilirubin Encephalopathy

1. The pathogenesis of bilirubin encephalopathy is multifactorial, involving the transport of bilirubin or albumin/bilirubin across the blood–brain barrier and delivering bilirubin to target neurons.2. The relative importance of the blood–brain barrier, unconjugated bilirubin levels, serum binding, and tissue susceptibility in this process is only partially understood. Even at dangerously high serum levels, bilirubin traverses the intact blood–brain barrier slowly, requiring time for encephalopathy to occur, although deposition of bilirubin can be rapid if a surge in plasma unbound bilirubin is produced by administering a drug which competes with bilirubin for binding to albumin.3. There may be maturational changes in permeability both in the fetus and postnatally which protect the brain from bilirubin.4. Disruption or partial disruption of the blood–brain barrier by disease or hypoxic ischemic injury will facilitate transport of bilirubin/albumin into brain, but the relative affinities of albumin and target neurons will determine whether the tissue bilirubin load is sufficient for toxicity to occur.     

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.     

A dynamic model for bilirubin binding to human serum albumin

Site-directed mutagenesis of human serum albumin was used to study the role of various amino acid residues in bilirubin binding. A comparison of thermodynamic, proteolytic, and x-ray crystallographic data from previous studies allowed a small number of amino acid residues in subdomain 2A to be selected as targets for substitution. The following recombinant human serum albumin species were synthesized in the yeast species Pichia pastoris: K195M, K199M, F211V, W214L, R218M, R222M, H242V, R257M, and wild type human serum albumin. The affinity of bilirubin was measured by two independent methods and found to be similar for all human serum albumin species. Examination of the absorption and circular dichroism spectra of bilirubin bound to its high affinity site revealed dramatic differences between the conformations of bilirubin bound to the above human serum albumin species. The absorption and circular dichroism spectra of bilirubin bound to the above human serum albumin species in aqueous solutions saturated with chloroform were also examined. The effect of certain amino acid substitutions on the conformation of bound bilirubin was altered by the addition of chloroform. In total, the present study suggests a dynamic, unusually flexible high affinity binding site for bilirubin on human serum albumin.     

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.     

Effect of the binding of bilirubin to either the first class or the second class of binding sites of the human serum albumin molecule on its photochemical reaction.

The kinetics of the photochemical changes of bilirubin were studied at a constant concentration of bilirubin bound either to the first class or to the second class of binding sites of the human serum albumin molecule. The more the bilirubin binds to the first class of binding sites in the human serum albumin molecule, the more readily geometric photoequilibrium to give (ZE)-bilirubin takes place. The more the bilirubin binds to the second class of binding sites or allosterically transformed binding sites induced by added SDS, the more readily structural photoisomerization, i.e. the formation of (EZ)-cyclobilirubin, takes place. When the serum bilirubin concentration is at low, safe, values bilirubin binds exclusively to the first class of binding sites and serves as an antioxidant [Onishi, Yamakawa & Ogawa (1971) Perinatology 1, 373-379]; at these concentrations human serum albumin protects bilirubin from irreversible photodegradation by only allowing readily reversible geometric photoisomerization. As the serum bilirubin concentration increases to high, and potentially dangerous, values, bilirubin binds to the second class of binding sites, and under these conditions human serum albumin seems to promote the photocyclization of bilirubin. During irradiation human serum albumin seems to act by retaining low, useful, concentrations of bilirubin while facilitating irreversible photoisomerization of excess bilirubin.     

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.     

Segregation distortion and differential fitness at the albumin locus in rhesus monkeys (Macaca mulatta)

The observed patterns of segregation of two co-dominant alleles at the macaque albumin locus in 400 rhesus monkey offspring were compared with those expected for five segregating mating phenotypes. Rates of reproductive loss and conception were also compared among females of each albumin phenotype. The common albumin allele in macaques, Al^A_mac, segregated more frequently than expected when the mother was heterozygous but less frequently than expected when she was homozygous for Al^B_mac. In both cases, the phenotype identical to that of the mother appeared to be favored. Mothers who were either homozygous for Al^A_mac or heterozygous were also found to experience higher conception rates than mothers homozygous for Al^B_mac. It is hypothesized that phenotypic differences in bilirubin binding, and in competitive binding by dietary constituents, by albumin influences both these results and the nonrandom distribution of Al^B_mac in Asian macaques.     

Intrinsically Disordered Regions in Serum Albumin: What Are They For?

Serum albumin is a major plasma protein in mammalian blood. The importance of this protein lies in its roles in both bioregulation and transport phenomena. Serum albumin binds various metal ions and participates in the transport and storage of fatty acids, bilirubin, steroids amino acids, and many other ligands, usually with regions of hydrophobic surface. Although the primary role of serum albumin is to transport various ligand, its versatile binding capacities and high concentration mean that it can assume a number of additional functions. The major goal of this article is to show how intrinsic disorder is encoded in the amino acid sequence of serum albumin, and how intrinsic disorder is related to functions of this important serum protein.     

Affinity of human serum albumin for bilirubin varies with albumin concentration and buffer composition: results of a novel ultrafiltration method

Albumin binding is a crucial determinant of bilirubin clearance in health and bilirubin toxicity in certain disease states. However, prior attempts to measure the affinity of albumin for bilirubin have yielded highly variable results, reflecting both differing conditions and the confounding influence of impurities. We therefore have devised a method based on serial ultrafiltration that successively removes impurities in [(14)C]bilirubin until a stable binding affinity is achieved, and then we used it to assess the effect of albumin concentration and buffer composition on binding. The apparent binding affinity of human serum albumin for [(14)C]bilirubin was strongly dependent on assay conditions, falling from (5.09 +/- 0.24) x 10(7) liters/mol at lower albumin concentrations (15 microm) to (0.54 +/- 0.05) x 10(7) liters/mol at higher albumin concentrations (300 microm). To determine whether radioactive impurities were responsible for this change, we estimated impurities in the stock bilirubin using a novel modeling approach and found them to be 0.11-0.13%. Formation of new impurities during the study and their affinity for albumin were also estimated. After correction for impurities, the binding affinity remained heavily dependent on the albumin concentration (range (5.37 +/- 0.26) x 10(7) liters/mol to (0.65 +/- 0.03) x 10(7) liters/mol). Affinities decreased by about half in the presence of chloride (50 mm). Thus, the affinity of human albumin for bilirubin is not constant, but varies with both albumin concentration and buffer composition. Binding may be considerably less avid at physiological albumin concentrations than previously believed.     

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.     

Multiple binding of bilirubin to human serum albumin and cobinding with laurate

Numerical analysis of multiple binding of two ligands to one carrier has been accomplished, using the principle of several sets of acceptable binding constants, with bilirubin-laurate-albumin as an example. Binding of bilirubin to defatted human serum albumin was investigated by a spectroscopic method, based upon a difference of light absorption spectrum for free and bound bilirubin. The observations were supplemented with previous data from an independent technique, measurement of oxidation rates of free bilirubin with hydrogen peroxide and peroxidase. A continuous isotherm was obtained, showing binding of at least 4 mol bilirubin per mole albumin with the following stoichiometric binding constants, 1.11 X 10(8), 1.7 X 10(7), 8 X 10(5), and 4 X 10(4) M-1 at pH 8.2, ionic strength 0.15 M, 25 degrees C. The binding is anticooperative at all steps. A saturation level was not reached. Cobinding of bilirubin and laurate was studied, with up to 2 mol of each ligand per mole albumin, using the peroxidase method for determination of free equilibrium concentrations of bilirubin, and a dialysis rate technique for free laurate. The findings could be described in terms of a stoichiometric model. Heterotropic cooperativity was present among the first bilirubin and the first and second laurate molecules. More than two molecules of either ligand can be bound at the same time.     

The albumin polymorphism and bilirubin binding in rhesus monkeys (Macaca mulatta)

Family studies confirmed a codominant mode of inheritance of albumin phenotypes identified in Macaca mulatta. Preliminary epidemiological and bilirubin binding studies suggest that selection favors the variant allele by reducing risks of hyperbilirubinemia and might be responsible for this otherwise rare polymorphism.     

Dansylation of human serum albumin in the study of the primary binding sites of bilirubin and L-tryptophan.

Binding of bilirubin and of L-tryptophan to dansylated albumins was investigated. Dansylation of less than one lysine residue per molecule of albumin did not affect the bilirubin binding, but decreased the L-tryptophan binding, indicating that dansylation had taken place in or near the l-tryptophan-binding site. Native albumin and albumin-bilirubin 1:1 complex showed the same affinity for L-tryptophan. The results indicate that, although L-tryptophan and bilirubin are bound in the same region, perhaps in a common cavity of the albumin molecule, such a cavity is sufficiently large to contain both ligands.