Characterization of oxidation end product of plasma albumin 'in vivo'

Anti-oxidants are paradoxically much lower in plasma than inside cells even blood is comparably exposed to the oxidative stress. 'In vitro' models suggest a critical role of albumin as substitutive anti-oxidant in plasma but no proof for this role is available 'in vivo.' Herein, we demonstrate by LC/MS/MS that plasma albumin undergoes massive oxidation in primary nephrotic syndrome, involving stable sulphonation SO3- of the free SH of Cys 34 with +48Da increase in exact mass of the protein (ESI-MS) and formation of a fast moving isoform in the pH range between 5 and 7. Physical-chemical experiments with DSC and fluorescence spectra indicate a thermal stabilization of the structure upon oxidation. This is the first demonstration of massive oxidation of albumin 'in vivo' that reflects a functional role of the protein. Free radicals should be implicated in the pathogenesis of proteinuria in human FSGS.     

The oxido-redox potential of albumin: Methodological approach and relevance to human diseases

In humans, an increased synthesis of reactive oxygen species (ROS) may be a relevant cause of amplification of physiologic processes resulting in inflammatory organ damage or neoplasia. Efficient anti-oxidative systems targeting oxidative stress are thus essential to prevent tissue damage. In plasma, proteins proved to be the first line of defence against ROS and albumin, the highest concentration plasma protein, has a key role in this antioxidant function. Recent studies have clearly documented that albumin oxido-redox potential changes upon oxidation by different oxidants thus becoming a deputy biomarker of this process.ROS react primarily with the free ³⁴Cysteine (³⁴Cys) residue of albumin to form two reversible intermediate derivatives, sulfenic-(SOH-alb) and sulfinic acid (SO₂H-alb), resulting in sulfonic acid (SO₃H-alb), the final stable product of the reaction.Upon stable oxidation (SO₃H-alb), albumin properties are altered: the protein becomes more susceptible to trypsin digestion and is degraded faster compared to the non-oxidized counterpart.The present review focuses on the characterization of albumin chemical changes induced by ROS, their relevance in human pathology and the most recent advances in the approach to oxidation adduct analysis.     

Analysis of the oxido-redox status of plasma proteins. Technology advances for clinical applications

Reactive oxygen species (ROS) are potentially implicated in renal pathology. Direct evidence is available for animal models of glomerulonephritis but the demonstration of ROS implication in human diseases is only circumstantial and requires further experimental support. One problem limiting any evolution is the brief life of ROS (in terms of milliseconds) that makes it difficult their direct detection 'in vivo'. An alternative is to look at the products of oxidation of proteins that remain in blood as a signature of ROS activity. Recent data have shown the presence of oxidation products of albumin (sulfonic (34)Cys albumin) in serum of patients with focal-glomerulosclerosis, that is a primary glomerular diseases causing nephrotic syndrome. Structural studies based on spectroscopy and calorimetry strengthened the relevance of oxidation of the unique free SH groups of (34)Cys for conformation of albumin, in analogy with what already reported for other proteins. In this review, we present new developments on technologies for the detection of the oxido-redox potential of proteins that are based on the concept that oxidation is inversely correlated with their free content of sulphydryl groups. We describe, in particular, two new iodoacetamide-substituted cyanines that have been developed for labelling sulphydryl groups and can be utilized as stable dyes prior mono- and bi-dimensional electrophoresis. Proteins with low binding with iodoacetamide-cyanines may be considered as surrogate biomarkers of ROS activity. Standardization of these techniques and their acquisition in more laboratories would enable clinicians to plan screening studies on ROS in human diseases.     

Formation of albumin dimers induced by exposure to peroxides in human plasma: a possible biomarker for oxidative stress

Human serum albumin (HSA) has one free thiol residue at Cys-34 that is likely oxidized by various reactive oxygen species (ROS). We attempted to identify the oxidation product of Cys-34 of HSA following exposure of plasma to ROS. Oxidation induced by tert-butyl hydroperoxide (t-BuOOH) of this free cysteine residue in HSA was observed in detail. Analysis of oxidized albumin in a partially purified fraction obtained by affinity column chromatography clearly revealed the formation of albumin disulfide dimers following t-BuOOH exposure. Albumin disulfide dimer formation was observed in normal plasma following treatment with various peroxides, as well as in untreated plasma from patients on hemodialysis using SDS-PAGE and Western blot analysis. The present results indicate that albumin dimers are oxidative products derived from peroxides, and that their presence in plasma might be a marker of oxidative stress as secondary metabolites of peroxidation.     

Cys34-Cysteinylated Human Serum Albumin Is a Sensitive Plasma Marker in Oxidative Stress-Related Chronic Diseases

The degree of oxidized cysteine (Cys) 34 in human serum albumin (HSA), as determined by high performance liquid chromatography (HPLC), is correlated with oxidative stress related pathological conditions. In order to further characterize the oxidation of Cys34-HSA at the molecular level and to develop a suitable analytical method for a rapid and sensitive clinical laboratory analysis, the use of electrospray ionization time-of-flight mass spectrometer (ESI-TOFMS) was evaluated. A marked increase in the cysteinylation of Cys34 occurs in chronic liver and kidney diseases and diabetes mellitus. A significant positive correlation was observed between the Cys-Cys34-HSA fraction of plasma samples obtained from 229 patients, as determined by ESI-TOFMS, and the degree of oxidized Cys34-HSA determined by HPLC. The Cys-Cys34-HSA fraction was significantly increased with the progression of liver cirrhosis, and was reduced by branched chain amino acids (BCAA) treatment. The changes in the Cys-Cys34-HSA fraction were significantly correlated with the alternations of the plasma levels of advanced oxidized protein products, an oxidative stress marker for proteins. The binding ability of endogenous substances (bilirubin and tryptophan) and drugs (warfarin and diazepam) to HSA purified from chronic liver disease patients were significantly suppressed but significantly improved by BCAA supplementation. Interestingly, the changes in this physiological function of HSA in chronic liver disease were correlated with the Cys-Cys34-HSA fraction. In conclusion, ESI-TOFMS is a suitable high throughput method for the rapid and sensitive quantification of Cys-Cys34-HSA in a large number of samples for evaluating oxidative stress related chronic disease progression or in response to a treatment.     

Regulation of redox forms of plasma thiols by albumin in multiple sclerosis after fasting and methionine loading test

Increases in plasma concentrations of total homocysteine (tHcy) have recently been reported in multiple sclerosis (MS) as the alteration of the methionine cycle for the onset of autoimmune diseases. Homocysteine (Hcy) and cysteine (Cys) are generated by the methionine cycle and transsulfuration reactions. Their plasma levels are subjected to complex redox changes by oxidation and thiol/disulfide (SH/SS) exchange reactions regulated by albumin. The methionine loading test (MLT) is a useful in vivo test to assay the functionality of the methionine cycle and transsulfuration reactions. Time courses of redox species of Cys, cysteinylglycine (CGly), Hcy, and glutathione have been investigated in plasma of MS patients versus healthy subjects after an overnight fasting, and 2, 4, and 6 h after an oral MLT (100 mg/kg body weight), to detect possible dysfunctions of the methionine cycle, transsulfuration reactions and alterations in plasma distribution of redox species. After fasting, the MS group showed a significant increase in cysteine-protein mixed disulfides (bCys) and total Cys (tCys). While plasma bCys and tCys in MS group remained elevated after methionine administration when compared to control, cystine (oxCys) increased significantly with respect to control. Although increased plasma concentrations of bCys and tCys at fasting might reflect an enhance of transsulfuration reactions in MS patients, this was not confirmed by the analysis of redox changes of thiols and total thiols after MLT. This study has also demonstrated that albumin-dependent SH/SS exchange reactions are a potent regulation system of thiol redox species in plasma.     

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.     

The structure and function of oxidized albumin in hemodialysis patients: Its role in elevated oxidative stress via neutrophil burst

Oxidized albumin is a reliable marker of oxidative stress in hemodialysis (HD) patients. However, oxidized albumin in vivo and its possible clinical significance has been rarely investigated. In the present study, the qualitative modification of albumin in HD patients (n = 20) was examined and their results were compared with healthy age-matched controls (n = 10). The increase in plasma protein carbonyl levels in HD patients was largely due to an increase in oxidized albumin. Human serum albumin (HSA) of HD patients, HSA of HD patients (HD-HSA) and normal subjects (Normal-HSA) were purified on a blue Sepharose CL-6B column. Spectroscopic analysis confirmed that the HD-HSA samples contained higher levels of carbonyls than Normal-HSA. An HPLC analysis also suggested that the state of the purified HSA used throughout the experiments accurately reflects the redox state of albumin in blood. HD-HSA was found to have a decreased the antioxidant activity, and was able to trigger the oxidative burst of human neutrophils, compared to Normal-HSA. HD-HSA was conformationally altered, with its hydrophobic regions more exposed and to have a negative charge. In binding experiments, HD-HSA showed impaired Site II-ligand binding capabilities. Collectively, the oxidation of plasma proteins, especially HSA, might enhance oxidative stress in HD patients.     

Mass spectrometry-based analyses for identifying and characterizing S-nitrosylation of protein tyrosine phosphatases

All members in the protein tyrosine phosphatase (PTP) family of enzymes contain an invariant Cys residue which is absolutely indispensable for catalysis. Due to the unique microenvironment surrounding the active center of PTPs, this Cys residue exhibits an unusually low pKa characteristic, thus being highly susceptible to oxidation or S-nitrosylation. While oxidation-dependent regulation of PTP activity has been extensively examined, the molecular details and biological consequences of PTP S-nitrosylation remain unexplored. We hypothesized that the catalytic Cys residue is targeted by proximal nitric oxide (NO) and its derivatives collectively termed reactive nitrogen species (RNS), leading to nitrosothiol formation concomitant with reversible inactivation of PTPs. To test this hypothesis, we have developed novel strategies to examine the redox status of Cys residues of purified PTP1B that was exposed to NO donor S-Nitroso-N-penicillamine (SNAP). A gel-based method in conjunction with mass spectrometry (MS) analysis revealed that the catalytic Cys215 of PTP1B was reversibly modified when PTP1B was briefly treated with SNAP. In order to further identify the exact mode of NO-induced modification, we employed an online LC-ESI-MS/MS analysis incorporating a mass difference-based, data-dependent acquisition function that effectively mapped the S-nitrosylated Cys residues. Our results demonstrated that treating PTP1B with SNAP led to S-nitrosothiol formation of the catalytic Cys215. Interestingly, SNAP-induced modifications were strictly reversible as highly oxidized Cys derivatives (Cys-SO(2)H or Cys-SO(3)H) were not identified by MS analyses. Thus, the methods introduced in this study provide direct evidence to prove the direct link between S-nitrosylation of the catalytic Cys residue and reversible inactivation of PTPs.     

Fatty acids increase the circulating levels of oxidative stress factors in mice with diet-induced obesity via redox changes of albumin

Plasma concentrations of free fatty acids are increased in metabolic syndrome, and the increased fatty acids may cause cellular damage via the induction of oxidative stress. The present study was designed to determine whether the increase in fatty acids can modify the free sulfhydryl group in position 34 of albumin (Cys34) and enhance the redox-cycling activity of the copper-albumin complex in high-fat diet-induced obese mice. The mice were fed with commercial normal diet or high-fat diet and water ad libitum for 3 months. The high-fat diet-fed mice developed obesity, hyperlipemia, and hyperglycemia. The plasma fatty acid/albumin ratio also significantly increased in high-fat diet-fed mice. The increased fatty acid/albumin ratio was associated with conformational changes in albumin and the oxidation of sulfhydryl groups. Moreover, an ascorbic acid radical, an index of redox-cycling activity of the copper-albumin complex, was detected only in the plasma from obese mice, whereas the plasma concentrations of ascorbic acid were not altered. Plasma thiobarbituric acid reactive substances were significantly increased in the high-fat diet group. These results indicate that the increased plasma fatty acids in the high-fat diet group resulted in the activated redox cycling of the copper-albumin complex and excessive lipid peroxidation.     

Effect of Cys34 Oxidation State of Albumin on Its Interaction with Paraoxon according to Molecular Modeling Data

Russian Journal of Bioorganic Chemistry - The effect of the Cys34 oxidation state in human serum albumin on its binding and catalytic activity towards paraoxon was investigated using molecular...     

Red blood cells protect albumin from cigarette smoke-induced oxidation

Different studies reported the presence of oxidized (carbonylated) albumin in the extravascular pool, but not in the intravascular one of cigarette smokers. In this study we attempted to explain this apparent discrepancy exposing human serum albumin (HSA) to aqueous cigarette smoke extract (CSE). CSE induces HSA carbonylation and oxidation of the HSA Cys34 sulfhydryl group. An antioxidant action of glutathione, cysteine, and its synthetic derivative N-acetylcysteine was observed only at supra-physiological concentrations, suggesting that physiological (plasma) concentrations of glutathione and cysteine in the low micromolar range are ineffective in preventing cigarette smoke-induced oxidation of HSA. Differently, human erythrocytes resulted to be protective towards CSE-induced oxidation (carbonylation and thiol oxidation) of both HSA and total human plasma proteins.     

Oxidative damage of albumin in advanced liver disease

Albumin has a number of biological functions and the serum albumin level is related to prognosis in advanced liver disease. Oxidative stress is believed to play an important role in the pathogenesis of liver failure. The aim of the present study was to characterize oxidative modification of albumin in patients with various degrees of liver failure and to investigate implications for its binding function. Patients with liver cirrhosis (n=10), acute-on-chronic liver failure (n=8) and healthy controls (n=15) were included in the study. Three fractions of albumin were separated by HPLC according to the redox state of cysteine-34 and detected by fluorescence as well as UV absorption. Carbonyl groups were measured as a marker of oxidative modification in plasma proteins and, by western blotting, on albumin. Progressive oxidative modification of albumin was found with increasing severity of liver failure indicated by an increased content of carbonyl groups and oxidation of cysteine-34. Fluorescence properties of albumin were altered by oxidation and, in patients with acute-on-chronic liver failure, by high plasma levels of bilirubin. This alteration of albumin fluorescence by bilirubin provides evidence for a preferred binding of bilirubin to the fully reduced form of albumin.     

Plasma nitroproteome of kidney disease patients

3′-nitrotyrosine (3NT) is a post-translational modification (PTM) of body fluids and tissues that is sustained by chronic inflammation and oxidative stress, two main clinical traits of chronic kidney disease (CKD). Despite this background, protein targets and their differential susceptibility to in vivo nitration remain almost completely unexplored in CKD. This study reports a first investigation of plasma nitroproteome in these patients, carried out by both immunorecognition and LC-MS/MS techniques. Plasma proteins of chronic and end-stage KD patients showed a higher burden of nitration than in healthy controls, but main nitration targets appeared to be the same in these populations. Immunoblotting data showed that uremic albumin is largely represented in the uremic nitroproteome together with fibrinogen chains (A, B and C), transferrin, α1-antitrypsin, complement factor D, haptoglobin, and IgG light and heavy chains. However, immunopurification and affinity chromatography experiments demonstrated that the relative content of 3NT on the albumin molecule was very low when compared with that of the remaining plasma proteins. The uremic nitroproteome was investigated using also plasma proteins obtained by in vivo ultrafiltration from patients treated with protein leaking or standard high-flux hemodialyzers. The study of these samples revealed the possibility to selectively remove protein nitration products during hemodialysis. Identification of intramolecular sites of nitration was preliminarily obtained in IgG chains isolated by 2D PAGE and assessed by bidimensional tandem mass spectrometry after chemoselective tagging. Further studies are needed to confirm at the molecular level the presence of nitrated Tyr residues in other proteins tentatively identified as nitration targets in this study and to explore the biological meaning of such a selective modification of plasma proteins by reactive nitrogen species in uremia and dialysis patients.     

γ-Glutamyl semialdehyde and 2-amino-adipic semialdehyde: biomarkers of oxidative damage to proteins

Reactive oxygen species are formed in the body by several natural processes and by induced oxidative stress. The reactive oxygen species may react with the various biomolecules of the body, including proteins. In order to assess the impact of oxidative damage to proteins, we have tried to identify oxidized amino acids in blood proteins which might serve as biomarkers of oxidative damage. When oxidative damage is induced into bovine serum albumin by metal-catalysed oxidation systems, the aldehyde groups formed can be derivatized by fluoresceinamine (FINH₂). Following acid hydrolysis of FINH₂-derivatized protein, two major oxidation products, γ-glutamyl semialdehyde (GGS) and 2-amino-adipic semialdehyde (AAS), were found and identified by HPLC and MS. Isolation and identification of oxidized amino acids from homopolymers (poly-Arg,-Pro,-Lys,-Trp or -Leu) confirmed that GGS can originate from Arg or Pro, while AAS is an oxidation product of Lys. When oxidative stress was induced in rats by treatments with t-butyl hydroperoxide or acrolein, rat plasma protein levels of GGS and AAS were found to be significantly higher compared with control rats. The AAS-content in serum albumin or in total plasma proteins collected from eight different mammalian species was found to be inversely proportional to their maximum lifespan potential. The content of AAS in plasma proteins of untreated adult rats showed a positive correlation with the age of the rat. In young rats a negative correlation with age was found for both GGS and AAS. We conclude that GGS or AAS may be useful novel biomarkers of oxidative damage to proteins in vivo.     

Biochemical and spectrophotometric significance of advanced oxidized protein products

We previously described the presence of advanced oxidation protein products (AOPP), a novel marker of oxidative stress in the plasma of hemodialyzed patients (HD). The present study was carried out to further investigate how myeloperoxidase (MPO)-catalyzed reactions could contribute to AOPP generation in the plasma. First, patterns of plasma protein oxidation obtained after in vitro incubation of control plasma with hypochlorous acid (HOCl) were compared to those from HD patients and control plasma. The use of various analytical techniques enabled localising and identifying the main oxidized proteins with albumin (HSA) after protein separation by size-exclusion chromatography and SDS-PAGE electrophoresis. The characterization of the oxidation level of the individual plasma proteins in terms of carbonyl groups and 3-nitrotyrosine formations was performed by immunoblotting. Secondly, to highlight the significance of AOPP index monitored by spectrophotometry, spectra were established for plasma fractions from HD patients and compared to data for control plasma and HOCl-treated plasma. The corresponding absorbance difference spectra were matched with external standards such as dityrosine, nitrotyrosine and pentosidine and elaborated chromophoric probe models. Indeed, HSA was chlorinated by HOCl reagent or HOCl generated via the MPO/H(2)O(2)/Cl(-) system and was nitrated by tetranitromethane. Increased absorbances at the range of 340 nm were observed both with chlorinated and nitrated HSA. Finally, our results indicate that HOCl, and not NO(2)(*), generated via MPO activity, could represent one of the pathways for AOPP production in plasma proteins exposed to activated phagocytes.     

Redox properties of serum albumin

Background

Oxidative damage results in protein modification, and is observed in numerous diseases. Human serum albumin (HSA), the most abundant circulating protein in the plasma, exerts important antioxidant activities against oxidative damage.

Scope of review

The present review focuses on the characterization of chemical changes in HSA that are induced by oxidative damage, their relevance to human pathology and the most recent advances in clinical applications.

Major conclusions

The antioxidant properties of HSA are largely dependent on Cys34 and its contribution to the maintenance of intravascular homeostasis, including protecting the vascular endothelium under disease conditions related to oxidative stress. Recent studies also evaluated the susceptibility of other important amino acid residues to free radicals. The findings suggest that a redox change in HSA is related to the oxidation of several amino acid residues by different oxidants. Further, Cys34 adducts, such as S-nitrosylated and S-guanylated forms also play an important role in clinical applications. On the other hand, the ratio of the oxidized form to the normal form of albumin (HMA/HNA), which is a function of the redox states of Cys34, could serve as a useful marker for evaluating systemic redox states, which would be useful for the evaluation of disease progression and therapeutic efficacy.

General significance

This review provides new insights into our current understanding of the mechanism of HSA oxidation, based on in vitro and in vivo studies.This article is part of a Special Issue entitled Serum Albumin.     

γ-Glutamyl semialdehyde and 2-amino-adipic semialdehyde: biomarkers of oxidative damage to proteins

Reactive oxygen species are formed in the body by several natural processes and by induced oxidative stress. The reactive oxygen species may react with the various biomolecules of the body, including proteins. In order to assess the impact of oxidative damage to proteins, we have tried to identify oxidized amino acids in blood proteins which might serve as biomarkers of oxidative damage. When oxidative damage is induced into bovine serum albumin by metal-catalysed oxidation systems, the aldehyde groups formed can be derivatized by fluoresceinamine (FINH₂). Following acid hydrolysis of FINH₂-derivatized protein, two major oxidation products, γ-glutamyl semialdehyde (GGS) and 2-amino-adipic semialdehyde (AAS), were found and identified by HPLC and MS. Isolation and identification of oxidized amino acids from homopolymers (poly-Arg,-Pro,-Lys,-Trp or -Leu) confirmed that GGS can originate from Arg or Pro, while AAS is an oxidation product of Lys. When oxidative stress was induced in rats by treatments with t-butyl hydroperoxide or acrolein, rat plasma protein levels of GGS and AAS were found to be significantly higher compared with control rats. The AAS-content in serum albumin or in total plasma proteins collected from eight different mammalian species was found to be inversely proportional to their maximum lifespan potential. The content of AAS in plasma proteins of untreated adult rats showed a positive correlation with the age of the rat. In young rats a negative correlation with age was found for both GGS and AAS. We conclude that GGS or AAS may be useful novel biomarkers of oxidative damage to proteins in vivo.     

Quantitative 2-D gel electrophoresis-based expression proteomics of albumin and IgG immunodepleted plasma

Proteomic analysis of plasma is challenging because of its large dynamic range, which prevents the detection of low abundance proteins. Immunodepletion of high abundance proteins, such as albumin and IgG, has emerged as a favored technology to overcome this problem; however its suitability in quantitative expression proteomics has not yet been adequately addressed. In this study, albumin and IgG immunodepletion was evaluated by ELISAs and the reproducibility of depletion was tested with 2-DGE. Depletion of plasma resulted in removal of 62+/-1.2% of the total protein, 93+/-1.4% of the albumin (0.43 microg/microL, residual), and 94+/-1.5% of the IgG (0.21 microg/microL, residual). These results were confirmed by immunoblotting. Computerized image analysis of 2-D gels using Progenesis SameSpots software revealed an enhancement in the number of visible spots (675-1325), with 10+/-6% inter-gel variability in spot density. LC-ESI-MS/MS identification of newly resolved protein spots further validated the procedure. An innovative application of the software employed led to identification of 11 proteins lost non-specifically during depletion. This study demonstrates the effectiveness of immunodepletion of albumin and IgG in quantitative 2-DGE-based differential analysis of plasma proteins.