Stopped-flow studies of spectral changes in human serum albumin following an alkaline pH jump

A stopped-flow technique was used to study the spectral changes occurring in albumin following a pH jump from 11.3 to 11.8 at 25 degrees C. Ultraviolet difference spectra between various albumin species participating in the process are reported. These spectra are similar in shape to the difference spectrum between the phenolate and phenolic form of tyrosine. At pH 11.3 one-third of the 18 tyrosine residues in albumin are deprotonated. At pH 11.8 two-thirds are deprotonated. The total reaction was analyzed as a multistep unimolecular consecutive process completed in four or more steps. Estimates were made of the number of tyrosine residues involved in the individual transitions. The first transition occurs with a rate constant greater than 300 s-1, in which 4.3 tyrosine residues deprotonate. The second transition occurs with a rate constant of 56.6 +/- 5.9 s-1, deprotonating 1.5 tyrosine residues. During the third (3.4 +/- 2.8 s-1) and following transitions (less than 0.3 s-1), which could not be reproducibly separated, 0.7 tyrosine residues deprotonate. The rates of deprotonation are inconsistent with simple diffusional dissociation of protons from the tyrosine residues and reflect exposure of tyrosines through conformational changes of albumin or dissociations of stably hydrogen-bonded tyrosines.     

Conformational changes in the bilirubin-human serum albumin complex at extreme alkaline pH.

Light-absorption, c.d. and fluorescence of the bilirubin-albumin complex were investigated at extreme alkaline pH. Above pH 11.1 albumin binds the bilirubin molecule, twisted oppositely to the configuration at more neutral pH. On the basis of light-absorption it is shown that two alkaline transitions occur. The first alkaline transition takes place at pH between 11.3 and 11.8, co-operatively dissociating at least six protons. The second alkaline transition takes place at pH between 11.8 and 12.0. It probably implies a reversible unfolding of the albumin molecule, increasing the distance between tryptophan-214 and bilirubin, and partly exposing the liganded bilirubin to the solvent.     

Stopped-flow studies on the n equilibrium f transition in serum albumin

Stopped-flow studies of the refolding of iodoacetamide-blocked bovine serum albumin from the acid unfolded "F" state have been performed. If the protein is incubated with low concentrations of perchlorate anion then the refolding kinetics follow a simple first-order process. The dependence on pH of both the amplitude of the observed transients and the measured rate constants indicates that the N equilibrium F transition is highly cooperative. The results are consistent with the postulated multidomain structure of albumin which has been developed as a result of both sequence work and a variety of physical studies.     

Kinetics and mechanism of bilirubin binding to human serum albumin

The kinetics of bilirubin binding to human serum albumin at pH 7.40, 4 degrees C, was studied by monitoring changes in bilirubin absorbance. The time course of the absorbance change at 380 nm was complex: at least three kinetic events were detected including the bimolecular association (k1 = 3.8 +/- 2.0 X 10(7) M-1 S-1) and two relaxation steps (52 = 40.2 +/- 9.4 s-1 and k3 = 3.8 +/- 0.5 s-1). The presence of the two slow relaxations was confirmed under pseudo-first order conditions with excess albumin. Curve-fitting procedures allowed the assignment of absorption coefficients to the intermediate species. When the bilirubin-albumin binding kinetics was observed at 420 nm, only the two relaxations were seen; apparently the second order association step was isosbestic at this wavelength. The rate of albumin-bound bilirubin dissociation was measured by mixing the pre-equilibrated human albumin-bilirubin complex with bovine albumin. The rate constant for bilirubin dissociation measured at 485 nm was k-3 = 0.01 s-1 at 4 degrees C. A minimum value of the equilibrium constant for bilirubin binding to human albumin determined from the ratio k1/k-3 is therefore approximately 4 X 10(9) M-1.     

Human serum albumin. Spectroscopic studies of binding and proximity relationships for fatty acids and bilirubin.

Binding and proximity relationships of hydrophobic ligands on human serum albumin have been studied using absorption, fluorescence, circular dichroism, and electron paramagnetic resonance spectroscopy. The ligands studied were bilirubin, two conjugated linear polyene fatty acids, cis-parinaric acid and cis-eleostearic acid, and three nitroxide derivatives of stearic acid with doxyl groups at positions 5, 10, and 12, respectively. Binding of polyene fatty acids was monitored by absorption peak shifts, induced circular dichroism, enhancement of fluorescence, and energy transfer between albumin's single tryptophanyl residue and the polyene chromophore. Induced circular dichroism studies indicate excitonic ligand-ligand interaction between bound fatty acids. Fluorescence enhancement of cis-parinaric acid was analyzed using a stepwise multiple equilibrium model, and six binding constants in the range 10(8) to 10(6) M-1 were obtained, in agreement with previous measurements for other fatty acids. The temperature dependence of the equilibrium constants indicates that the binding enthalpy is nearly zero. Fluorescence energy transfer was similarly used to quantitate bilirubin binding to albumin. Energy transfer, nitroxide quenching of fluorescence, and electron paramagnetic resonance spectroscopy were used to elucidate binding geometries which support and extend proposed structural models for albumin. It is suggested that the first two fatty acids bind side-by-side in an antiparallel fashion in domain III of human serum albumin.     

Noninvolvement of surface lysine residues of bovine serum albumin in bilirubin binding

Interaction of bilirubin with bovine serum albumin and its five succinylated forms was studied using fluorescence spectroscopy at two different ionic strengths i.e., 0.15 and 1.0 respectively. Affinity constant was found to be 1.8 x 10(7) litres/mole at 0.15 ionic strength which decreased to 4.4 x 10(6) litres/mole after 87% succinylation. On increasing ionic strength to 1.0, there was a slight decrease in affinity constant for native albumin. However, affinity constant remained same in 55 and 87% modified albumins at high ionic strength. These results suggest noninvolvement of surface lysine residues in bilirubin albumin complex.     

Trinitrophenylation of the bilirubin binding site of human serum albumin.

Human serum albumin has been modified with 2,4,6-trinitrobenzenesulphonic acid and picryl chloride in low ratios of reagents/albumin. The derivatives have been investigated by spectrophotometry and by thin layer chromatography of the hydrolysates in order to assess the specificity of the reagents. The same reaction conditions were used to modify albumin previously complexed with bilirubin in the ratio of 1:1. The affinity of bilirubin to the modified albumins was estimated by an improved perozidase method. It is concluded that TNBS and picryl chloride react almost quantity with epsilon-amino groups of lysine on the albumin molecule. The results also suggest that at least on TNBS reactive amino group and at least one picryl chloride reactive amino group are located in or near the high-affinity bilirubin binding site.     

Influence of succinylation of bovine serum albumin on its conformation and bilirubin binding

In order to investigate the role of lysine residues in the interaction of bilirubin with bovine serum albumin, five succinylated preparations of albumin, namely: 23%, 39%, 49%, 55% and 87%, were prepared, and their conformational and bilirubin-binding properties were studied by the techniques of gel filtration, ultraviolet and visible spectroscopy, and fluorescence quenching. Gel filtration experiments performed at pH 7.0 and ionic strengths 0.15 and 1.0 suggested that the albumin molecule undergoes gradual disorganization with increase in succinylation. The Stokes radius and frictional ratio at ionic strength 0.15 increased from 3.7 nm and 1.36, respectively, for the native protein to 6.3 nm and 2.26 for maximally (87%) succinylated albumin. Interestingly, increase in ionic strength to 1.0 caused significant refolding in succinylated preparations as evidenced by a decrease in Stokes radius and frictional ratio (5.3 nm and 1.90 for 87% succinylated albumin). Progressive succinylation produced a steady decline in the intensity of bilirubin-induced fluorescence quenching, and in the visible spectral changes of the bilirubin-albumin complex at 480 nm. Both of these changes had a good correlation with increase in Stokes radius. Increase in ionic strength to 1.0 produced a significant reversal in these properties. From these results we conclude that probably none of the surface lysine residues is involved in bilirubin-albumin interaction, and that if lysine residues are involved in this interaction they must be buried in the protein interior.     

Understanding bilirubin conformation and binding. Circular dichroism of human serum albumin complexes with bilirubin and its esters

Human serum albumin binds tightly and noncovalently to a wide variety of hydrophobic bilirubins, including (4Z,15Z)-bilirubin-IX alpha, its dimethyl ester and mono methyl esters, its mono 2-butyl esters and amides, the dimethyl ester of (4Z,15Z)-mesobilirubin-IV alpha, and even (4Z,15Z)-etiobilirubin-IV gamma. The heteroassociation complexes formed from these highly water-insoluble pigments and the protein can be prepared in pH 7.4 aqueous by using a small quantity of dimethyl sulfoxide as amphiphilic carrier. In those solutions the protein acts as a water-soluble chiral complexation agent to induce an asymmetric transformation of the bound pigment. This is recognized by positive chirality, bisignate induced circular dichroism (CD) Cotton effects that fall in the region of the bichromophoric pigment's long wavelength UV-visible absorption band and are characteristic of intramolecular exciton coupling of the bilirubin component pyrromethenone chromophores. The same-signed CD spectra shared by all the pigments of this work indicate selection at the protein binding site for a positive chirality conformer and suggest a common binding site. The CD intensities, which are greatest ([delta epsilon[ congruent to 50) for pigments with one or two free carboxyl groups, are consistent with a binding model where one salt linkage plays a major role in the enantioselectivity of the right-handed folded conformation stabilized by inter- and intramolecular hydrogen bonds.     

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.     

Photochemical studies on the binding of an organic fluoride to bovine serum albumin

The interaction of fipronil (FPN), a pesticide containing fluorine, to bovine serum albumin (BSA) was studied by spectroscopy including fluorescence spectra, UV–Visible absorption, scattering spectra, circular dichroism (CD) spectra, synchronous and three-dimensional fluorescence spectra. The number of binding sites n and observed binding constant Kb was measured by fluorescence quenching method. The thermodynamic parameters ΔH, ΔG, ΔS at different temperatures were calculated and the results indicate that hydrophobic forces played major role in the reaction. The distance r between donor (BSA) and acceptor (FPN) was obtained according to the Förster theory of non-radiation energy transfer. The structural change of BSA molecules with addition of FPN was analyzed and the results may be helpful to biologists, chemists and therapeutists.     

Formation of a molten globule like state in bovine serum albumin at alkaline pH

Little work has been done to understand the folding profiles of multi-domain proteins at alkaline conditions. We have found the formation of a molten globule-like state in bovine serum albumin at pH 11.2 with the help of spectroscopic techniques; like far and near ultra-violet circular dichroism, intrinsic and extrinsic fluorescence spectroscopy. Interestingly, this state has features similar to the acid-denatured state of human serum albumin at pH 2.0 reported by Muzammil et al. (Eur J Biochem 266:26–32, 1999). This state has also shown significant increase in 8-anilino-1-naphthalene-sulfonate (ANS) binding in compare to the native state. At pH 13.0, the protein seems to acquire a state very close to 6 M guanidinium hydrochloride (GuHCl) denatured one. But, reversibility study shows it can regain nearly 40% of its native secondary structure. On the contrary, tertiary contacts have disrupted irreversibly. It seems, withdrawal of electrostatic repulsion leave room for local interactions, but disrupted tertiary contacts fail to regain their original states.     

Stopped-flow fluorescence kinetic studies of Glu-plasminogen. Conformational changes triggered by AH-site ligand binding

Binding of 6-aminohexanoic acid to the AH-site, a weak lysine binding site in Glu-plasminogen, alters the conformation of the molecule. The kinetics of the binding and the accompanying conformational change are investigated at pH 7.8, 25 degrees C. Changes of intrinsic protein fluorescence were measured as a function of time after rapid mixing in a stopped-flow apparatus. The results reflect a two-step reaction mechanism: Rapid association of Glu-plasminogen and 6-aminohexanoic acid (K1 = 44 mM) followed by the conformational change (k2 = 69 s-1 and k-2 = 3 s-1) with an overall dissociation constant Kd = 2.0 mM. Thus the conformational change is rather fast, t12 = 0.01 s. Its importance for the rates of Glu-plasminogen activation reactions is discussed.     

Conformational transitions of human alpha-1 fetoprotein and serum albumin at acid and alkaline pH

Conformational transitions of HAFP in the pH-range 2-12 were studied by fluorescence spectroscopy, fluorescence polarization measurements, circular dichroism and hydrophobic chromatography in order to compare molecular architecture of HAFP and that of human serum albumin. It was found that HAFP has a remarkably hydrophilic exposed molecular surface at neutral pH and possesses extensive hydrophobic binding sites located in crevices. Conformational changes occur in HAFP in the acid and alkaline pH regions; extensive hydrophobic areas in HAFP are exposed by both acid and alkaline transitions. The alpha-helix contents of HAFP were determined as 67% at pH 7.6, 47% at pH 2.11.     

Photoactivated covalent binding of [3H]bilirubin to human serum albumin.

A one-step procedure has been developed for the preparation of [3H]bilirubin IX-alpha in good yield from unlabelled bilirubin. Irradiation of an aqueous solution of [3H]bilirubin IX-alpha in the presence of human serum albumin results in the covalent attachment of the bilirubin to the protein. Preliminary degradation studies have been carried out to locate the site of attachment of the bilirubin to the albumin.