Molecular characteristics of methylglyoxal-modified bovine and human serum albumins. Comparison with glucose-derived advanced glycation endproduct-modified serum albumins

The amino acid modification, gel filtration chromatographic, and electrophoretic characteristics of bovine and human serum albumins irreversibly modified by methylglyoxal (MG-SA) and by glucose-derived advanced glycation endproducts (AGE-SA) were investigated. Methylglyoxal selectively modified arginine residues at low concentration (1 mM); at high methylglyoxal concentration (100 mM), the extent of arginine modification increased and lysine residues were also modified. Both arginine and lysine residues were modified in AGE-SA. Analytical gel filtration HPLC of serum albumin derivatives suggested that the proportion of dimers and oligomers increased with modification in both low and highly modified MG-SA and AGE-SA derivatives relative to unmodified serum albumins. In SDS-PAGE analysis, dimers and oligomers of low-modified MG-SA were dissociated into monomers, but not in highly modified MG-SA. MG-SA had increased anodic electrophoretic mobility under nondenaturing conditions atpH 8.6, indicating an increased net negative charge, which increased with extent of modification; highly modified MG-SA and AGE-SA had similar high electrophoretic mobilities. MG-SA derivatives were fluorescent: the fluorescence was characteristic of the arginine-derived imidazoloneN -(5-methyl-4-imidazolon-2-yl)ornithine, but other fluorophores were also present. AGE-SA had similar fluorescence, attributed, in part, to glucose-derived imidazolones. AGE formed from glucose-modified proteins and AGE-like compounds formed from methylglyoxal-modified proteins may both be signals for recognition and degradation of senescent macromolecules.Abbreviations AGE advanced glycation endproduct - BSA bovine serum albumin - HSA human serum albumin - MG-SA methylglyoxal-modified serum albumin - MG-BSA methylglyoxal-modified bovine serum albumin - MG-HSA methylglyoxal-modified human serum albumin - AGE-SA AGE-modified serum albumin - AGE-BSA AGE-modified bovine serum albumin - AGE-HSA AGE-modified human serum albumin - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis - HPLC high-performance liquid chromatography - FFI 2-(2-furoyl)-4(5)-(2-furanyl)-1H-imidazole     

Functionalization of aminomodified probes for atomic force microscopy

Probes for atomic force microscopy functionalized by bovine serum albumin were obtained, which may be used for molecular recognition studies. The procedure of the modification and functionalization of probes includes three stages. First, amino probes are obtained by modification in vapors of amino silane derivative. Then a homobifunctional amino reactive cross-linker is covalently linked to surface amino groups of the amino probe. And finally, the probe with the covalently attached cross-linker is functionalized by bovine serum albumin molecules. The probes obtained were characterized at different stages of the modification by atomic force microscopy: the adhesion force and the work of adhesion force were determined from histograms. The modification of probe surface was confirmed by visualization of bovine serum albumin and supercoiled pGEMEX DNA molecules immobilized on the amino mica and amino mica modified by cross-linker.     

A highly reactive tyrosine residue as part of the indole and benzodiazepine binding site of human serum albumin.

The interaction of L-tryptophan and four benzodiazepine derivatives with tyrosine-modified human serum albumin was investigated by equilibrium dialysis and circular dichroism measurements. Out of the 18 tyrosine residues of the human serum albumin molecule, only 9 could be modified with tetranitromethane. At least up to a degree of modification of 5, the conformation of human serum albumin was not changed and no crosslinking and fractionation has been found, as revealed from circular dichroism measurements in the far ultraviolet range and from SDS polyacrylamide electrophoresis. The modification of only 2 out of the 9 accessible tyrosine residues of human serum albumin strongly affects the binding of L-tryptophan and diazepam to their common, stereospecific bindining site. This was evidently shown by a reduction of the association constants by more than 90% and by a large reduction of the extrinsic Cotton effects of four benzodiazepines bound to human serum albumin. The numbers of binding sites remained unchanged. Strong evidence was presented that only one tyrosine residue, which reacts faster with tetranitromethane than all others, is mainly involved in the specific indole and benzodiazepine binding site of human serum albumin. The location of this highly reactive tyrosine residue and that of the specific indole and benzodiazepine binding site within the human serum albumin primary structure is discussed.     

Modification of the amino acid residues in the serum albumin of oncological patients

A modified form of albumin isolated from the blood of oncological patients was studied. A modification of N-terminal amino acid, 50% tyrosine groups, free SH-group of cysteine and lysine group in the fourth position in the N-terminal sequence of amino acids was discovered. The possibility of a post-translation modification of serum albumin in disease in individual amino acid groups is discussed.     

Amino-modified probes with immobilized linkers and proteins for atomic force microscopy

Functionalized by bovine serum albumin (BSA) probes for atomic force microscopy (AFM) which can be used for molecular recognition studies has been obtained. Modification and functionalization procedure of AFM probe includes three stages. First, amino probes were obtained by modification in vapors of amino silane derivative. Then surface amino groups of the amino probe interacted with homobifunctional amino reactive crosslinker. And finally, the probe with covalently attached crosslinker was functionalized by BSA molecules. Obtained AFM probes were characterized on the different stages of the modification by force measurements and the adhesion forces were determined. Process of modification was confirmed by visualization of BSA and supercoiled pGEMEX DNA molecules immobilized on the standard amino mica and amino mica modified by crosslinker.     

Reactivity of histidine and lysine side-chains with diethylpyrocarbonate -- a method to identify surface exposed residues in proteins

The chemical modification of amino acid side-chains followed by mass spectrometric detection can reveal at least partial information about the 3-D structure of proteins. In this work we tested diethylpyrocarbonate, as a common histidyl modification agent, for this purpose. Appropriate conditions for the reaction and detection of modified amino acids were developed using angiotensin II as a model peptide. We studied the modification of several model proteins with a known spatial arrangement (insulin, cytochrome c, lysozyme and human serum albumin). Our results revealed that the surface accessibility of residues is a necessary, although in itself insufficient, condition for their reactivity; the microenvironment of side-chains and the dynamics of protein structure also affect the ability of residues to react. However the detection of modified residues can be taken as proof of their surface accessibility, and of direct contact with solvent molecules.     

Interaction of prostaglandin E2 with human serum albumin

Using equilibrium dialysis, protein fluorescence and fluorescent probing as well as chemical modification, the interaction of prostaglandin E2 with human serum albumin was studied. The serum albumin molecule has a highly specific prostaglandin E2-binding site. The binding of prostaglandin causes conformational rearrangements in the protein molecule. The amino group of serum albumin is involved in the interaction with prostaglandin E2. Prolonged exposure of prostaglandin E2 to serum albumin causes partial irreversible binding of prostaglandin molecules to the protein.     

The modification of the lone tryptophan residue in human serum albumin by 2-hydroxy-5-nitrobenzyl bromide. Characterization of the modified protein and the binding of L-tryptophan and benzodiazepines to the tryptophan-modified albumin.

The possible function of the lone tryptophan residue of human serum albumin in the stereospecific binding site for indole and benzodiazepine compounds was investigated by chemical modification. This residue can be selectively modified with 2-hydroxy-5-nitrobenzyl bromide. The modification alters the conformation of the albumin only slightly, as revealed by circular dichroism, fluorescence, and ultraviolet absorption measurements. A decrease in the association constants of L-tryptophan and diazepam of about 30 - 50% and a decrease in the extrinsic Cotton effects of four benzodiazepine derivatives of about 10 - 15% were found as specific effects of the tryptophan modification. The tryptophan modification itself did not change the number of binding sites of diazepam and L-tryptophan. It is suggested that the lone tryptophan residue of human serum albumin is not directly involved in the specific binding site for indole and benzodiazepine compounds. However, the modification alters the properties of the binding site either by an incomplete refolding of the albumin after urea treatment, or a more selective allosteric effect of the modified tryptophan residue.     

Some physicochemical properties of modified trypsin]

Physico-chemical properties of trypsin covalently bound with human serum albumin by glutaric aldehyde have been studied. The modification of the enzyme practically caused no changes in the pH optimum of trypsin. The inhibition of modified trypsin by inhibitors from soy beans and human blood serum has been also studied. The apparent inhibition constants have been calculated. The modification has been shown to result in a deceleration of autolytic degradation. The autolysis rate constants have been calculated at 50 degrees C.     

Functionalization of amino-modified probes for atomic force microscopy

The probes for atomic force microscopy (AFM) functionalized with bovine serum albumin (BSA) were obtained; they can be used for molecular recognition studies. The procedure of modification and functionalization of the AFM probe included three stages. First, amino probes were obtained by modification in vapors of an amino silane derivative. Then, a covalent bond was formed between the surface amino groups of the probe and a homobifunctional aminoreactive crosslinker. Finally, the probe with a covalently attached crosslinker was functionalized with BSA molecules. The AFM probes were characterized by force measurements at different stages of the modification; the adhesion force and the work of adhesion force were determined. The modification process was confirmed by visualization of BSA and supercoiled pGEMEX DNA molecules immobilized on the standard amino mica and on amino mica modified with a crosslinker.     

Peptide mapping identifies hotspot site of modification in human serum albumin by methylglyoxal involved in ligand binding and esterase activity

Methylglyoxal is a potent glycating agent under physiological conditions. Human serum albumin is modified by methylglyoxal in vivo. The glycation adducts formed and structural and functional changes induced by methylglyoxal modification have not been fully disclosed. Methylglyoxal reacted with human serum albumin under physiological conditions to form mainly the hydroimidazolone N(delta)-(5-hydro-5-methyl-4-imidazolon-2-yl)-ornithine (92% of total modification) with a minor formation of argpyrimidine, N(epsilon)-(1-carboxyethyl)lysine, and methylglyoxal lysine dimer. When human serum albumin was modified minimally with methylglyoxal, tryptic peptide mapping indicated a hotspot of modification at Arg-410 located in drug-binding site II and the active site of albumin-associated esterase activity. Modification of Arg-410 by methylglyoxal was found in albumin glycated in vivo. Other sites of minor modification were: Arg-114, Arg-186, Arg-218, and Arg-428. Hydroimidazolone formation at Arg-410 inhibited ketoprofen binding and esterase activity; correspondingly, glycation in the presence of ketoprofen inhibited Arg-410 modification and loss of esterase activity. The pH dependence of esterase activity indicated a catalytic group with pK(a) = 7.9 +/- 0.1, assigned to the catalytic base Tyr-411 with the conjugate base stabilized by interaction with the guanidinium group of Arg-410. Modification by methylglyoxal destabilized Tyr-411 and increased the pK(a) to 8.8 +/- 0.1. Molecular dynamics and modeling studies indicated that hydroimidazolone formation caused structural distortion leading to disruption of arginine-directed hydrogen bonding and loss of electrostatic interactions. Methylglyoxal modification of critical arginine residues, therefore, whether experimental or physiological, is expected to disrupt protein-ligand interactions and inactivate enzyme activity by hydroimidazolone formation.     

Glycation of human serum albumin alters its binding efficacy towards the dietary polyphenols: a comparative approach

Diabetes is a major problem in the world. The proteins became modified during glycation after reacting with the reducing sugars (e.g. D-glucose) via non-enzymatic pathways. The glycated analogue of human serum albumin (HSA) has been characterized with the help of multi-spectroscopic methods. It has been observed that six glucose molecules can bind covalently to HSA under experimental condition. The binding affinity of the modified HSA towards the dietary polyphenols has been estimated using UV–vis and fluorescence spectroscopic techniques. The binding constant values of the ligands were found to decrease after the modification of HSA.     

血清白蛋白与降血糖药物相互作用的关键位点分析

用生物信息学的方法分析不同物种的血清白蛋白的亲缘关系,分析降血糖药物米格列醇和伏格列波糖与人血清白蛋白相互作用位点在其他亲缘关系较近的物种中相应的氨基酸变化特点。结果表明米格列醇、伏格列波糖与人血清白蛋白的结合位点都位于人血清白蛋白亚区IB的疏水腔中,其间的主要作用力是氢键和疏水作用力。米格列醇和伏格列波糖与血清白蛋白结合位点处的氨基酸在其他物种中大部分都是保守的,只有少数的氨基酸不同,且极性也不相同。血清白蛋白疏水性分析发现米格列醇和伏格列波糖与血清白蛋白结合位点处的氨基酸中亲水性的较多,疏水性的少,在其他4个亲缘关系较近的物种也具有同样的现象。这些分析结果为进一步研究降血糖药物在其他物种中的表现及相互作用等提供了重要的科学依据。     

Antiserum specific for the carboxy terminus of the transforming protein of Rous sarcoma virus

An antiserum specific for the carboxy terminus of p60src, the transforming protein of Rous sarcoma virus, was produced by immunization of rabbits with a conjugate of bovine serum albumin and the synthetic peptide NH2-Tyr-Val-Leu-Glu-Val-Ala-Glu-COOH. The carboxy-terminal six amino acids of this peptide correspond in sequence to that deduced for the carboxy terminus of the p60src of the Schmidt-Ruppin strain of Rous sarcoma virus of subgroup A. The p60src proteins of the several strains of Rous sarcoma virus and the cellular homolog of the viral transforming protein, p60c-src, comprise a polymorphic family of polypeptides. The anticarboxy-terminal serum reacted readily with the p60src proteins of three different strains of Rous sarcoma virus. In contrast, no precipitation of cellular p60c-src could be detected with this serum. This suggests that the viral p60src proteins have identical carboxy termini and that the carboxy terminus of cellular p60c-src may be different from that of viral p60src. The anticarboxy-terminal serum reacted poorly with the subpopulation of viral p60src which is present in a complex with two cellular phosphoproteins. Apparently, the presence of the two cellular proteins interferes with the recognition of p60src by the anticarboxy-terminal serum. It seems likely, therefore, that these two cellular proteins bind to the carboxy-terminal domain of p60src.     

Activation of thiol-dependent antioxidant activity of human serum albumin by alkaline pH is due to the B-like conformational change

Antioxidant activity of human serum albumin (HSA) increased steeply as the reaction mixture was shifted from neutral to alkaline pH. The antioxidant activity was also remarkably increased by Ca(2+) or a cationic detergent (cetyltrimethylammonium chloride). Carboxyl group modification of HSA resulted in about 40-fold increase of the antioxidant activity. The chemical modification study indicated that in addition to functional cysteine(s), cationic amino acid residues such as histidine, arginine and lysine appeared to involve in the antioxidant reaction. HSA also exhibited alkaline-pH dependent peroxidase activity to remove fatty acid hydroperoxide. At neutral pH, only two thiols of Cys-289 and free Cys-34 of HSA were modified by a thiol-specific modification reagent, 5-((((2-iodoacetyl)amino)ethy)amino)naphthalene-1-sulfonic acid (I14), regardless of the presence or absence of dithiothreitol (DTT), and the resultant antioxidant activity was not decreased, suggesting that Cys-289 and Cys-34 did not participate in the antioxidant reaction. At alkaline pH, I14 modified several additional HSA thiols in the presence, but did not in the absence of DTT. The antioxidant activity of the modified HSA was remarkably decreased to as much as 30% of the antioxidant activity given by the unmodified HSA in the absence of DTT. The HPLC pattern for tryptic peptides containing modified cysteine(s) derived from the I14-treated c-HSA (carboxyl group-modified HSA) at pH 7.0 with DTT was very similar to that of the I14-modified HSA at pH 8.0 with DTT. Taken together, these results suggest that activation of thiol-dependent antioxidant activity of HSA at alkaline pH is due to the conformational change favorable for the functional cysteine(s)-mediated catalysis.     

Conservative chemical modification of proteins to study the effects of a single protein property on partitioning in aqueous two-phase systems

Relatively conservative modifications of three proteins were carried out to alter their surface properties. The protein properties modified were hydrophobicity and charge. This was done by acylation of amino groups with anhydrides. For the hydrophobic modification experiments, two proteins (beta-lactoglobulin and bovine serum albumin [BSA]) and four anhydrides (hexanoic, butyric, succinic, acetic) were used. For the modification of surface charge the protein thaumatin was selected and various proportions of the free amino groups were blocked with acetic anhydride to give a series of proteins with differing isoelectric points. Detailed characterization and purification of selected modified proteins was carried out including molecular weight measurements and conformational analysis. The criteria used for selecting the modified proteins for subsequent investigation of their partitioning in aqueous two-phase systems (ATPS) is described. With a judicious choice of starting material it was found that limited chemical modifications to proteins could effectively alter surface hydrophobicity or charge almost independently, with little effect on other molecular properties. It appears, however, that the method for chemical modification and the reaction conditions must also be carefully controlled. (c) 1996 John Wiley & Sons, Inc.     

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.     

Effect of ionizing radiation on the structure of human serum albumin. Effect of irradiation on the content of free amino groups and on the ability of HSA to be digested by proteinases

The effect of gamma-quanta on human serum albumin (HSA) solutions (1.6 mg/ml, borate buffer pH 7.45) in the air has been investigated. Using 2,4,6-trinitro-benzene-sulfonic acid it has been shown that 2-22 kGy radiation reduces the free amino groups content of HSA and increases its resistance to the hydrolytic effect of trypsin and pronase which is not influenced by the postirradiation exposure to heat. It is concluded that epsilon-NH2-groups of lysine residues are modified and firm cross-links are formed in HSA under the effect of radiation.     

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.     

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.