Resonance energy transfer between cysteine-34, tryptophan-214, and tyrosine-411 of human serum albumin

Reaction of p-nitrophenyl anthranilate with human serum albumin at pH 8.0 results in esterification of a single anthraniloyl moiety with the hydroxyl group of tyrosine-411. The absorption spectrum of the anthraniloyl group overlaps the fluorescence emission of the single tryptophan residue at position 214. This study complements that of the preceding paper [Suzukida, M., Le, H. P., Shahid, F., McPherson, R. A., Birnbaum, E.R., & Darnall, D. W. (1983) Biochemistry (preceding paper in this issue)] where an azomercurial group was introduced at cysteine-34. Anthraniloyl fluorescence was also quenched by the azomercurial absorption at Cys-34. Thus measurement of resonance energy transfer between these three sites allowed distances to be measured between Cys-34 in domain I, Trp-214 in domain II, and Tyr-411 in domain III of human serum albumin. At pH 7.4 in 0.1 M phosphate the Trp-214 leads to Tyr-411, Tyr-411 leads to Cys-34, and Trp-214 leads to Cys-34 distances were found to be 25.2 +/- 0.6, 25.2 +/- 2.1, and 31.8 +/- 0.8 A, respectively.     

Cross-talk between Cys34 and lysine residues in human serum albumin revealed by N-homocysteinylation

Protein N-homocysteinylation involves a post-translational modification by homocysteine (Hcy)-thiolactone. In humans, about 70% of circulating Hcy is N-linked to blood proteins, mostly to hemoglobin and albumin. It was unclear what protein site(s) were prone to Hcy attachment and how N-linked Hcy affected protein function. Here we show that Lys(525) is a predominant site of N-homocysteinylation in human serum albumin in vitro and in vivo. We also show that the reactivity of albumin lysine residues, including Lys(525), is affected by the status of Cys(34). The disulfide forms of circulating albumin, albumin-Cys(34)-S-S-Cys and albumin-Cys(34)-S-S-Hcy, are N-homocysteinylated faster than albumin-Cys(34)-SH. Although N-homocysteinylations of albumin-Cys(34)-SH and albumin-Cys(34)-S-S-Cys yield different primary products, subsequent thiol-disulfide exchange reactions result in the formation of a single product, N-(Hcy-S-S-Cys)-albumin-Cys(34)-SH. We also show that N-homocysteinylation affects the susceptibility of albumin to oxidation and proteolysis. The data suggest that a disulfide at Cys(34) of albumin promotes conversion of N-(Hcy-SH)-albumin-Cys(34)-SH to a proteolytically sensitive form N-(Hcy-S-S-Cys)-albumin-Cys(34)-SH, which would facilitate clearance of the N-homocysteinylated form of mercaptoalbumin.     

Spatial relationship between the nucleotide-binding site, Lys-61 and Cys-374 in actin and a conformational change induced by myosin subfragment-1 binding

The spatial relationship between Lys-61, the nucleotide binding site and Cys-374 was studied. Lys-61 was labelled with fluorescein-5-isothiocyanate as a resonance energy acceptor, the nucleotide-binding site was labelled with the fluorescent ATP analogues epsilon ATP or formycin-A 5'-triphosphate (FTP) and Cys-374 was labelled with 5-(2-[(iodoacetyl)amino]ethyl)aminonaphthalene-1-sulfonic acid (1,5-IAEDANS) as a resonance energy donor. The distances between the nucleotide binding site and Lys-61 or between Lys-61 and Cys-374 were calculated to be 3.5 +/- 0.3 nm and 4.60 +/- 0.03 nm, respectively. (The assumption has been made in calculating these distances that the energy donor and acceptor rotate rapidly relative to the fluorescence lifetime.) On the other hand, when doubly-labelled actin with 1,5-IAEDANS at Cys-374 and FITC at Lys-61 was polymerized in the presence of a twofold molar excess of phalloidin [Miki, M. (1987) Eur. J. Biochem. 164, 229-235], the fluorescence of 1,5-IAEDANS bound to actin was quenched significantly. This could be attributed to inter-monomer energy transfer. The inter-monomer distance between FITC attached to Lys-61 in a monomer and 1,5-IAEDANS attached to Cys-374 in its nearest-neighbour monomer in an F-actin filament was calculated to be 3.34 +/- 0.06 nm, assuming that the likely change in the intra-monomer distance does not change during polymerization by more than 0.4 nm. One possible spatial relationship between Lys-61, Cys-374 and the nucleotide binding site in an F-actin filament is proposed. The effect of myosin subfragment-1 (S1) binding on the energy transfer efficiency was studied. The fluorescence intensity of AEDANS-FITC-actin decreased by 30% upon interaction with S1. The fluorescence intensity of AEDANS-FITC-actin polymer in the presence of phalloidin increased by 21% upon interaction with S1. The addition of ATP led to the fluorescence intensity returning to the initial level. Assuming that the change of fluorescence intensity can be attributed to conformational change in the actin molecule induced by S1 binding, the intra-monomer distance was reduced by 0.4 nm and the inter-monomer distance was increased by 0.2 nm.     

The participation of human serum albumin domains in chemical and thermal unfolding

Fluorescence spectroscopy and differential scanning calorimetry were used to follow local and global changes in human serum albumin domains during chemical and thermal denaturation of this protein. Results suggests that thermal and chemical treatments involved an unfolding pathway of at least two steps and that domain IIA is not homogeneous. Unfolding at site I exposes a larger hydrophobic area to the solvent than at site II. The bilirubin-binding site showed atypical behavior: a significant increase in the hydrophobic area was exposed to the solvent when its binding site was denatured by guanidine hydrochloride. This result might be due to the high specificity of the bilirubin-binding site, whose binding makes an extensive conformational change in the environment of this site.     

The tryptophan residues of mitochondrial creatine kinase: roles of Trp-223, Trp-206, and Trp-264 in active-site and quaternary structure formation.

The 5 tryptophan residues of chicken sarcomeric mitochondrial creatine kinase (Mib-CK) were individually replaced by phenylalanine or cysteine using site-directed mutagenesis. The mutant proteins were analyzed by enzyme kinetics, fluorescence spectroscopy, circular dichroism, and conformational stability studies. In the present work, Trp-223 is identified as an active-site residue whose replacement even by phenylalanine resulted in > or = 96% inactivation of the enzyme. Trp-223 is responsible for a strong (18-21%) fluorescence quenching effect occurring upon formation of a transition state-analogue complex (TSAC;Mib-CK.creatine.MgADP.NO3-), and Trp-223 is probably required for the conformational change leading to the TSAC-induced octamer dissociation of Mib-CK. Replacement of Trp-206 by cysteine led to a destabilization of the active-site structure, solvent exposure of Trp-223, and to the dissociation of the Mib-CK dimers into monomers. However, this dimer dissociation was counteracted by TSAC formation or the presence of ADP alone. Trp-264 is shown to be located at the dimer-dimer interfaces within the Mib-CK octamer, being the origin of another strong (25%) fluorescence quenching effect, which was observed upon the TSAC-induced octamer dissociation. Substitution of Trp-264 by cysteine drastically accelerated the TSAC-induced dissociation and destabilized the octameric structure by one-fourth of the total free interaction energy, probably by weakening hydrophobic contacts. The roles of the other 2 tryptophan residues, Trp-213 and Trp-268, could be less well assigned.     

Probing the structure of the warfarin-binding site on human serum albumin using site-directed mutagenesis

The binding of warfarin to the following human serum albumin (HSA) mutants was examined: K195M, K199M, F211V, W214L, R218M, R222M, H242V, and R257M. Warfarin bound to human serum albumin (HSA) exhibits an intrinsic fluorescence that is approximately 10-fold greater than the corresponding signal for warfarin in aqueous solution. This property of the warfarin/HSA complex has been widely used to determine the dissociation constant for the interaction. In the present study, such a technique was used to show that specific substitutions in subdomain 2A altered the affinity of HSA for warfarin. The fluorescence of warfarin/mutant HSA complexes varied widely from the fluorescence of the warfarin/wild-type HSA complex at pH = 7.4, suggesting changes in the structure of the complex resulting from specific substitutions. The fluorescence of the warfarin/wild-type HSA complex increases about twofold as the pH is increased from 6.0 to 9.0 due to the neutral-to-base (N-B) transition, a conformational change that occurs in HSA as a function of pH. Changes in the fluorescence of warfarin/mutant HSA complexes as a function of pH suggests novel behavior for most HSA species examined. For the HSA mutants F211V and H242V, the midpoint of the N-B transition shifts from a wild-type pH of 7.8 to a pH value of 7.1-7.2.     

The effect of non-enzymatic glycation on the unfolding of human serum albumin

We monitored the unfolding of human serum albumin (HSA) and glycated human serum albumin (gHSA) subjected to guanidine hydrochloride (GndHCl) by using fluorescence and circular dichroism (CD) spectroscopy. A two-state model with sloping baselines best described the Trp-214 fluorescence unfolding measurements, while a three-state model best described the far-UV CD unfolding data. Glycation of HSA increased the [D](50%) point by approximately 0.20M. This corresponded to an increase in the free energy of unfolding of gHSA relative to HSA of 2.6kJ/mol. The intrinsic fluorescence of Trp-214 in gHSA is 0.72 of that of HSA and the far-UV CD spectrum of gHSA is nearly identical to that of HSA. These results showed that glycation altered the local structure around Trp-214 while not significantly impacting the secondary structure, and this alteration translated into an overall change in the stability of gHSA compared to HSA.     

Urea and acid induced unfolding of fatted and defatted human serum albumin

Urea induced equilibrium unfolding of fatted and defatted human serum albumin (HSA) showed that fatty acid stabilizes native and intermediate states. Similarly acid induced unfolding of fatted and defatted HSA also showed that fatty acid stabilizes Ntwo left arrowsF and Ftwo left arrowsE transitions. These results also showed that five electrostatic interactions along with one buried carboxyl group of acidic amino acid are involved in acid induced unfolding of HSA.     

Site-directed mutagenesis studies of human serum albumin define tryptophan at amino acid position 214 as the principal site for nitrosation

The patterns of nitric oxide (NO) release from nitrosated bovine serum albumin (BSA), human serum albumin (HSA) and a number of recombinant HSA mutants were compared. All albumin species were nitrosated by incubation with acidified NO(2)(-). The pattern of NO release from BSA nitrosated with acidified NO(2)(-) was in agreement with previous reports which indicated that Cys-34 is the primary target for nitrosation in BSA. In contrast, the pattern of NO release from HSA nitrosated with acidified NO(2)(-) indicated that the primary nitrosation target was an amino acid residue other than Cys-34. Based on our initial findings and a previous report that tryptophan is a potential target for nitrosation by acidified NO(2)(-), several recombinant HSA mutants were synthesized in the yeast species Pichia pastoris. The following recombinant HSA species were produced: wild-type, C34S, W214L, W214E and W214L/Y411W HSA. Nitrosation of these mutants using acidified NO(2)(-) showed that Trp-214 is the primary nitrosation target in HSA. Mutation of Trp-214 led to an increase in Cys-34 nitrosation, indicating possible competition between these two residues for reaction with N(2)O(3), the reactive nitrosating species formed in aqueous acidified NO(2)(-) solutions.     

The tryptophane residues of dimeric arginine kinase: roles of Trp-208 and Trp-218 in active site and conformation stability

Roles of the two tryptophane residues of dimeric arginine kinase (AK) were individually investigated by site-directed mutagenesis. Both residues were fully conserved in the phosphogen kinase family and the mutant proteins were analyzed by enzyme kinetics, fluorescence spectroscopy, fluorescence quenching experiments, thermal stability and conformational stability. Our studies revealed that Trp-218 was located at the active site of AK and was the major fluorescence contributor (96.9%). Single replacement of this residue by alanine led to almost complete inactivation of the enzyme. In addition, a decrease in the melting temperature in differential scanning calorimetry (DSC) profiles and the equilibrium studies in guanidine hydrochloride (GdnHCl) denaturation after mutagenesis also suggested that Trp-218 takes part in stabilizing the conformational structure of AK. Although another tryptophane, Trp-208 was not located at the active sites, it may take part in maintaining the correct dimer conformation for catalysis. Replacement of this tryptophane by alanine decreased the activity to 70.3% and made it susceptible to heat and denaturants, such as GdnHCl. In addition, Trp-208 also seemed to play an important role in correct protein folding.     

Mechanistic investigation of domain specific unfolding of human serum albumin and the effect of sucrose

This study is devoted to understand the unfolding mechanism of a multidomain protein, human serum albumin (HSA), in absence and presence of the sucrose by steady‐state and time‐resolved fluorescence spectroscopy with domain specific marker molecules and is further being substantiated by molecular dynamics (MD) simulation. In water, the domain III of HSA found to unfold first followed by domains I and II as the concentration of GnHCl is increased in the medium. The sequential unfolding behavior of different domains of HSA remains same in presence of sucrose; however, a higher GnHCl concentration is required for unfolding, suggesting stabilizing effect of sucrose on HSA. Domain I is found to be most stabilized by sucrose. The stabilization of domain II is somewhat similar to domain I, but the effect of sucrose on domain III is found to be very small. MD simulation also predicted a similar behavior of sucrose on HSA. The stabilizing effect of sucrose is explained in terms of the entrapment of water molecules in between HSA surface and sucrose layer as well as direct interaction between HSA and sucrose.     

Disruption of the tryptophan binding site in the human serum albumin dimer

Monomer and dimer fractions of human serum albumin (HSA) obtained from charcoal-treated Fraction V HSA have very similar fluorescence and circular dichroism spectra, but the dimer neither binds l-tryptophan nor reacts rapidly with p-nitrophenyl acetate. The latter reaction presumably occurs in a major binding site of the monomer as many strongly bound ligands including l-tryptophan, small fatty acid anions (e.g., S.-W. M. Koh and G. E. Means, 1979, Arch. Biochem. Biophys.192, 73–79), and several drugs (e.g, N. P. Sollenne and G. E. Means, 1979, Mol. Pharmacol.15, 754–757) all decrease rates of reaction in direct proportion to their concentration. Binding data for those ligands indicate the presence of less than one binding site per molecule of charcoal-treated Fraction V HSA, and thus appear to reflect only its content of albumin monomer. The absence of that binding site in the dimer may reflect its inclusion within the dimer interface.     

Modification of amino acid residues in human serum albumin by myeloperoxidase

Myeloperoxidase is released from stimulated polymorphonuclear leukocytes at inflammatory loci. Besides its bactericidal activity, it interacts with human serum albumin that is essential for the endothelial uptake of myeloperoxidase and its contribution in regulation of the blood vessel tonus. Here, we investigated which kinds of modification dominate in the albumin protein by the myeloperoxidase-hydrogen peroxide system at physiological pH. In the presence of chloride, bromide, and nitrite, the myeloperoxidase-hydrogen peroxide system caused an oxidation, bromination, and nitrosylation/nitration of eight amino acid residues of albumin as detected by fragment analysis of tryptic digests with matrix-assisted laser desorption/ionisation time-of-flight mass spectrometry. An oxygen was incorporated into the methionines Met147, Met353, and Met572 as well as into the tryptophan Trp238. In the case of methionine residues, this oxygen was derived from the water phase as shown using 18O-enriched water. Nitrosylation/nitration was observed at the tryptophan Trp238 and the tyrosines Tyr162, Tyr425, and Tyr476 according to the mass shift of 29 Da and 45 Da. The incorporation of one or two bromines was found into the tyrosines Tyr425 and Tyr476. We did not observe any chlorination of albumin fragments. Thus, myeloperoxidase modifies in multiple ways amino acid residues in human serum albumin.     

Analysis of the structure and dynamics of human serum albumin

A computational approach to designing a peptide-based ligand for the purification of human serum albumin (HSA) was undertaken using molecular docking and molecular dynamics (MD) simulation. A three-step procedure was performed to design a specific ligand for HSA. Based on the candidate pocket structure of HSA (warfarin binding site), a peptide library was built. These peptides were then docked into the pocket of HSA using the GOLD program. The GOLDscore values were used to determine the affinity of peptides for HSA. Consequently, the dipeptide Trp–Trp, which shows a high GOLDscore value, was selected and linked to a spacer arm of Lys[CO(CH₂)₅NH] on the surface of ECH-lysine sepharose 4 gel. For further evaluation, the Autodock Vina program was used to dock the linked compound into the pocket of HSA. The docking simulation was performed to obtain a first guess of the binding structure of the spacer–Trp–Trp–HSA complex and subsequently analyzed by MD simulations to assess the reliability of the docking results. These MD simulations indicated that the ligand–HSA complex remains stable, and water molecules can bridge between the ligand and the protein by hydrogen bonds. Finally, absorption spectroscopic studies were performed to illustrate the appropriateness of the binding affinity of the designed ligand toward HSA. These studies demonstrate that the designed dipeptide can bind preferentially to the warfarin binding site. Graphical Abstract

Three-step computational approach to the design of a dipeptide ligand for human serum albumin purification exploiting structure-based docking and molecular dynamics simulation     

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.     

Fipronil recognition by the FA1 site of human serum albumin

Fipronil is a broad‐spectrum pesticide widely used in agriculture, horticulture, and forestry. Because fipronil can cause a variety of toxic effects in animals and humans, its use is authorized as a pesticide in veterinary medicinal products for pets, but not for the treatment of livestock animals whose products are intended for consumption. Recently, however, the presence of fipronil residues has been detected in the eggs and meat of layer hens from farms located in different European countries. Given the relevance of fipronil toxicity for human health, it is important to gain information concerning its fate in the human body, including its binding mode to human serum albumin (HSA), the most abundant protein in plasma. Here, the inhibition of heme‐Fe(III) binding to the fatty acid site 1 (FA1) of HSA by fipronil is reported. Docking simulations support functional data, indicating that the FA1 site is the preferential cleft for fipronil recognition by HSA. The affinity of fipronil for HSA (K_f = 1.9 × 10^?6 M, at pH 7.3, and 20.0°C) may be relevant in vivo. Indeed, HSA could play a pivotal role in fipronil transport and scavenging, thus reducing the pesticide‐free plasmatic levels, with consequent reduced systemic toxicity. In turn, fipronil binding to the FA1 site of HSA could impair the recognition of endogenous and exogenous molecules.     

Fluorescence energy transfer between points in G-actin: the nucleotide-binding site, the metal-binding site and Cys-373 residue

Fluorescence energy transfers were studied in order to investigate the spatial relationships between the nucleotide-binding site, the metal-binding site and the Cys-373 residue in the G-actin molecule. When 1-N6-ethenoadenosine-5'-triphosphate (epsilon-ATP) in the nucleotide-binding site and Co2+ or Ni2+ in the metal-binding site were used as fluorescence donor and acceptor, respectively, the fluorescence intensity of epsilon-ATP was perfectly quenched by Ni2+ or Co2+. This indicated that the nucleotide-binding site is very close to the metal-binding site; the distance should be less than 10 A. When N-iodoacetyl-N'-(5-sulfo-1-naphthyl)ethylenediamine (IAEDANS) bound to Cys-373 residue and Co2+ in the metal-binding site were used as a fluorescence donor and an acceptor, respectively, the transfer efficiency was equal to 5 +/- 1%. The corresponding distance was calculated to be 23-32 A, assuming a random orientation factor K2 = 2/3.