Altered thiol pattern in plasma of subjects affected by rheumatoid arthritis.

OBJECTIVE: Rheumatoid arthritis (RA) is a chronic inflammatory disease which involves the synovial membrane of multiple diarthroidal joints causing damage to cartilage and bones. The damage process seems to be related to an overproduction of oxygen reactive species inducing an oxidative perturbation. Since sulfhydryl groups are primary antioxidant factors, we were interested in investigating the balance of plasma sulfhydryl/disulfides in patients with active RA compared to healthy control subjects. METHODS: Twenty-one patients with RA and 15 age-matched controls were studied. Plasmatic sulfhydryl groups and their disulfide form concentrations were measured by spectrophotometry or HPLC. RESULTS: RA patients showed significantly lower levels of plasma protein sulfhydryls and cysteinyl-glycine compared to healthy controls (p < 0.001). Conversely, cystine and homocystine, and protein-bound cysteine and homocysteine were significantly increased (p < 0.005 in disulfides forms and p < 0.05 in protein mixed disulfides forms). There was a significant correlation between some clinical data (ESR, number of tender/swollen joints) and some of the parameters studied. CONCLUSION: The results of this study indicate a biochemical disturbance of plasma sulfhydryl/disulfides balance in patients with RA compared to controls with an increase in some oxidised forms (disulfides and protein mixed disulfides) and a decrease in free thiols. The increase in total homocysteine, correlated to the higher risk of cardiovascular diseases in RA patients, is associated with higher levels of the oxidised forms, disulfides and protein-thiol mixed disulfides.

Thiolation and nitrosation of cysteines in biological fluids and cells.

Thiols (RSH) are potent nucleophilic agents, the rates of which depend on the pKa of the sulfhydryl. Unlike compounds having other nucleophile moieties (-OH or -NH(2)), RSH are involved in reactions, such as conjugations, redox and exchange reactions. Although protein SH groups (PSH) react like non-protein thiols (NPSH), the biochemistry of proteins is much more complex for reasons such as steric hindrance, charge distribution and accessibility of PSH to the solvent (protein conformation). The reaction rates and types of end-products of PSH vary a lot from protein to protein. The biological problem is even more complex because in all compartments and tissues, there may be specific competition between thiols (namely between GSH and PSH), regulated by the properties of antioxidant enzymes. Moreover, PSH are divided biologically into essential and non-essential and their respective influence in the various biological systems is unknown. It follows that during phenomena eliciting a prompt thiol response (oxidative stress), the antioxidant PSH response and reaction mechanisms vary considerably from case to case. For example, in spite of a relatively low pKa that should guarantee good antioxidant capacity, PSH of albumin has much less propensity to form adducts with conjugating agents than NPSH; moreover, the structural characteristics of the protein prevent albumin from forming protein disulfides when exposed to oxidants (whereas protein-thiol mixed disulfides are formed in relative abundance). On the other hand, proteins with a relatively high reactivity, such rat hemoglobin, have much greater antioxidant capacity than GSH, but although human hemoglobin has a pKa similar to GSH, for structural reasons it has less antioxidant capacity than GSH. When essential PSH are involved in S-thiolation and S-nitrosation reactions, a similar change in biological activity is observed. S-thiolated proteins are a recurrent phenomenon in oxidative stress elicited by reactive oxygen species (ROS). This event may be mediated by disulfides, that exchange with PSH, or by the protein intermediate sulfenic acid that reacts with thiols to form protein-mixed disulfides. During nitrosative stress elicited by reactive nitrogen species (RNS), depending on the oxygen concentration of the system, nitrosation reactions of thiols may also be accompanied by protein S-thiolation. In this review we discuss a number of cell processes and biochemical modifications of enzymes that indicate that S-thiolation and S-nitrosation may occur simultaneously in the same protein in the presence of appropriate interactions between ROS and RNS.

Methionine oxidation as a major cause of the functional impairment of oxidized actin.

A significant specific increase in the actin carbonyl content has been recently demonstrated in human brain regions severely affected by the Alzheimer's disease pathology, in postischemic isolated rat hearts, and in human intestinal cell monolayers following incubation with hypochlorous acid (HOCl). We have very recently shown that exposure of actin to HOCl results in the immediate loss of Cys-374 thiol, oxidation of some methionine residues, and, at higher molar ratios of oxidant to protein, increase in protein carbonyl groups, associated with filament disruption and inhibition of filament formation. In the present work, we have studied the effect of methionine oxidation induced by chloramine-T (CT), which at neutral or slightly alkaline pH oxidizes preferentially Met and Cys residues, on actin filament formation and stability utilizing actin blocked at Cys-374. Methionines at positions 44, 47, and 355, which are the most solvent-exposed methionyl residues in the actin molecule, were found to be the most susceptible to oxidation to the sulfoxide derivative. Met-176, Met-190, Met-227, and Met-269 are the other sites of the oxidative modification. The increase in fluorescence associated with the binding of 8-anilino-1-naphtalene sulfonic acid to hydrophobic regions of the protein reveals that actin surface hydrophobicity increases with oxidation, indicating changes in protein conformation. Structural alterations were confirmed by the decreased susceptibility to proteolysis and by urea denaturation curves. Oxidation of some critical methionines (those at positions 176, 190, and 269) causes a complete inhibition of actin polymerization and severely affects the stability of actin filaments, which rapidly depolymerize. The present results would indicate that the oxidation of some critical methionines disrupts specific noncovalent interactions that normally stabilize the structure of actin filaments. We suggest that the process involving formation of actin carbonyl derivatives would occur at an extent of oxidative insult higher than that causing the oxidation of some critical methionine residues. Therefore, methionine oxidation could be a damaging event preceding the appearance of carbonyl groups on actin and a major cause for the functional impairment of the carbonylated protein recently observed both in vivo and in vitro.

Protein thiols and glutathione influence the nitric oxide-dependent regulation of the red blood cell metabolism.

Nitric oxide (NO) can modulate red blood cell (RBC) glycolysis by translocation of the enzyme glyceraldehyde-3-phosphate dehydrogenase (GAPD) (EC 1.2.1.12) from the cytosolic domain of the membrane protein band 3 (cdb3) in the cytosol. In this study we have investigated which NO-reactive thiols might be influencing GAPD translocation and the specific role of glutathione. Two highly reactive Cys residues were identified by transnitrosylation with nitrosoglutathione (GSNO) of cdb3 and GAPD (K(2) = 73.7 and 101.5 M(-1) s(-1), respectively). The Cys 149 located in the catalytic site of GAPD is exclusively involved in the GSNO-induced nitrosylation. Reassociation experiments carried out at equilibrium with preparations of RBC membranes and GAPD revealed that different NO donors may form -SNO on, and decrease the affinity between, GAPD and cdb3. In intact RBC, the NO donors 3-morpholinosydnonimine (SIN-1) and peroxynitrite (ONOO(-)) significantly increased GAPD activity in the cytosol, glycolysis measured as lactate production, and energy charge levels. Our data suggest that ONOO(-) is the main NO derivative able to cross the RBC membrane, leading to GAPD translocation and -SNO formation. In cell-free experiments and intact RBC, diamide (a thiol oxidant able to inhibit GAPD activity) was observed to reverse the effect of SIN-1 on GAPD translocation. The results demonstrate that cdb3 and GAPD contain reactive thiols that can be transnitrosylated mainly by means of GSNO; these can ultimately influence GAPD translocation/activity and the glycolytic flux.

The actin cytoskeleton response to oxidants: from small heat shock protein phosphorylation to changes in the redox state of actin itself.

Actin is the major constituent of the cytoskeleton of almost all the eukaryotic cells. In vitro experiments have indicated that oxidant-stressed nonmuscle mammalian cells undergo remarkable changes in their morphology and in the structure of the actin cytoskeleton, often resulting in plasma membrane blebbing. Although the microfilament network is one of the earliest targets of oxidative stress, the mechanism by which oxidants change both the structure and the spatial organization of actin filaments is still a matter of debate and far from being fully elucidated. Starting from the 2-fold role of oxidants as injurious by-products of cellular metabolism and essential participants in cell signaling and regulation, this review attempts to gather the most relevant information related to (i) the activation of mitogen-activated protein (MAP) kinase stress-activated protein kinase-2/p38 (SAPK2/p38) which, via MAP kinase-activated protein (MAPKAP) kinase 2/3, leads to the phosphorylation of the actin polymerization (F-actin) modulator 25/27 kDa heat shock protein (HSP25/27), whose phosphorylation is causally related to the regulation of microfilament dynamics following oxidative stress; (ii) the alteration of the redox state of actin or some actin regulatory proteins. The actin cytoskeleton response to oxidants is discussed on the basis of the growing body of evidence indicating the actin system as the most sensitive constituent of the cytoskeleton to the oxidant attack.

Actin carbonylation: from a simple marker of protein oxidation to relevant signs of severe functional impairment.

The number of protein-bound carbonyl groups is an established marker of protein oxidation. Recent evidence indicates a significant increase in actin carbonyl content in both Alzheimer's disease brains and ischemic hearts. The enhancement of actin carbonylation, causing the disruption of the actin cytoskeleton and the loss of the barrier function, has also been found in human colonic cells after exposure to hypochlorous acid (HOCl). Here, the effects of oxidation induced by HOCl on purified actin are presented. Results show that HOCl causes a rapidly increasing yield of carbonyl groups. However, when carbonylation becomes evident, some Cys and Met residues have been already oxidized. Covalent intermolecular cross-linking as well as some noncovalent aggregation of carbonylated actin have been found. The covalent cross-linking, unaffected by reducing and denaturing agents, parallels an increase in dityrosine fluorescence. Moreover, HOCl-mediated oxidation induces the progressive disruption of actin filaments and the inhibition of F-actin formation. The molar ratios of HOCl to actin that lead to inhibition of actin polymerization seem to have effect only on cysteines and methionines. The process that involves oxidation of amino acid side chains with formation of a carbonyl group would occur at an extent of oxidative insult higher than that causing the oxidation of some critical amino acid residues. Therefore, the increase in actin content of carbonyl groups found in vivo would indicate drastic oxidative modification leading to drastic functional impairments.

Platelet antioxidant enzymes in insulin-dependent diabetes mellitus.

BACKGROUND: The measurement of the peroxidase scavenging system represented by the activities of superoxide dismutase (SOD), catalase and glutathione peroxidase (GSH-Px) in blood cells of diabetic patients has, in the past, given equivocal results. Likewise, the role of these intracellular enzymatic scavengers against the oxidative stress of diabetes-associated microangiopathic complications is unknown. METHODS: Choosing platelets as cell model (as commonly done in previous studies), the aim of this study was to relate the platelet content of SOD, catalase and GSH-Px to the presence of diabetes, as well as to the presence of nephropathy and retinopathy in 35 insulin-dependent diabetic patients, as compared to 10 age-matched control subjects. RESULTS: The enzymatic activities were not changed in diabetic patients in comparison with healthy controls. After stratifying patients according to presence of nephropathy (24-h urinary albumin excretion rate persistently > or =20 microg min(-1)) or retinopathy, the group of albuminuric patients was characterized by a significant decrease in SOD activity as compared to those in the normoalbuminuric range (4.36+/-1.06 vs. 6.81+/-2.26 mU 10(-9) platelets; p=0.01). Catalase and GSH-Px did not change. No modification in platelet enzyme activities has been found in diabetic subjects with retinopathy. CONCLUSIONS: These results suggest that diabetic nephropathy, at least in its early stage, may be related to an altered redox state of platelets, as tested by the reduction in SOD activity, thus, indicating that the renal damage in these patients may be associated to a selective increase in platelet susceptibility to variation in the redox state.

Responses of thiols to an oxidant challenge: differences between blood and tissues in the rat.

Treatment of rats with diamide (100 mg/kg i.p.) altered the thiol components of the blood to a very different extent than in tissues (liver, kidney, lung, spleen, heart and testis). A total consumption (10 min) and regeneration (120 min) of blood glutathione (GSH), matched by a parallel increase and decrease in glutathione-protein mixed disulfides (GS-SP) was observed. In contrast, no modification of non-protein SH groups (NPSH) and protein SH groups (PSH), GS-SP and malondialdehyde (MDA) was observed in liver, kidney, lung, testis spleen and heart within same time range. In particular, only glutathione disulfide (GSSG) levels and some activities of antioxidant enzymes were modified to a small extent and in an opposite direction in some organs. For example, GSSG, and glucose-6-phosphate dehydrogenase (G-6-PDH) and catalase (CAT) activities appeared up-regulated in one tissue and down-regulated in another. The least modified organ was the liver, whereas lung and spleen were the most affected (lung, GSSG, significantly increased whereas G-6-PDH, glutaredoxin (GRX), GPX, superoxide dimutase (SOD) levels were significantly lowered; spleen, GSSG and the activity of glutathione reductase (GR), G-6-PDH and glutathione transferase (GST) were significantly decreased). The different responses of erythrocytes and organs to diamide were explained by the high affinity of hemoglobin and by the relatively high potential of thiol regeneration in organs. The rapid reversibility of the process of protein S-thiolation in blood and the small effects in organs leads us to propose the existence of an inter-organ cooperation in the rat that regulates protein S-thiolation in blood. Plasma thiols may well play a role in this process.

Altered glutathione anti-oxidant metabolism during tumor progression in human renal-cell carcinoma.

It has been proposed that oxidative stress develops in tumors, with important consequences for growth and progression. To investigate this hypothesis, we measured low m.w. thiols, disulfides, protein-mixed disulfides and a pool of major anti-oxidant enzymes in renal-cortex as well as renal-cell carcinoma (RCC) specimens at stages I-II and III. Our data showed (i) a significant increase in the levels of total intracellular glutathione at both tumor stages (levels were 2.6-2.8 fold higher than those in the normal renal cortex), (ii) a marked lowering of the GSH/GSSG ratio in stage I-II accompanied by a significant decrease of many GSH-dependent enzymes (i.e., GPX, GST, GGT, GR) and (iii) unchanged GSH/GSSG ratio and GSH-dependent enzyme activity in stage III with respect to normal renal cortex. These results indicate that relevant variations exist in the glutathione antioxidant system in the different stages of RCC and support the hypothesis that oxidative stress plays an important role in RCC growth and progression.

Different metabolizing ability of thiol reactants in human and rat blood: biochemical and pharmacological implications.

The effect of oxidants, electrophiles, and NO donors in rat or human erythrocytes was analyzed to investigate the influence of protein sulfhydryl groups on the metabolism of these thiol reactants. Oxidant-evoked alterations in thiolic homeostasis were significantly different in the two models; large amounts of glutathione protein mixed disulfides were produced in rat but not in human erythrocytes by treatment with hydroperoxides or diamide. The disappearance of all forms of glutathione (reduced, disulfide, protein mixed disulfide) was induced by menadione only in human erythrocytes. The treatment of rat red blood cells with electrophiles produced glutathione S-conjugates to a much lower extent than in human red blood cells; GSH was only minimally depleted in rat red blood cells. The NO donor S-nitrosocysteine induced a rapid transnitrosation reaction with hemoglobin in rat erythrocytes producing high levels of S-nitrosohemoglobin; this reaction in human red blood cells was negligible. All drugs were cleared more rapidly in rat than in human erythrocytes. Unlike human Hb, rat hemoglobin contains three families of protein SH groups; one of these located at position beta125 is directly implicated in the metabolism of thiol reactants. This is thought to influence significantly the biochemical, pharmacological, and toxicological effects of some drugs.

The oxidation produced by hydrogen peroxide on Ca-ATP-G-actin.

We report here that in vitro exposure of monomeric actin to hydrogen peroxide leads to a conversion of 6 of the 16 methionine residues to methionine sulfoxide residues. Although the initial effect of H2O2 on actin is the oxidation of Cys374, we have found that Met44, Met47, Met176, Met190, Met269, and Met355 are the other sites of the oxidative modification. Met44 and Met47 are the methionyl sites first oxidized. The methionine residues that are oxidized are not simply related to their accessibility to the external medium and are found in all four subdomains of actin. The conformations of subdomain 1, a region critical for the functional binding of different actin-binding proteins, and subdomain 2, which plays important roles in the polymerization process and stabilization of the actin filament, are changed upon oxidation. The conformational changes are deduced from the increased exposure of hydrophobic residues, which correlates with methionine sulfoxide formation, from the perturbations in tryptophan fluorescence, and from the decreased susceptibility to limited proteolysis of oxidized actin.

S-NO-actin: S-nitrosylation kinetics and the effect on isolated vascular smooth muscle.

We describe the modification of reactive actin sulfhydryls by S-nitrosoglutathione. Kinetics of S-nitrosylation and denitrosylation suggest that only one cysteine of actin is involved in the reactions. By using the bifunctional sulfhydryl cross-linking reagent N,N'-1,4-phenylenebismaleimide and the monofunctional reagent N-iodoacetyl-N'-(5-sulpho-1-naphthyl)ethylenediamine, we identified this residue as Cys374. The time course of filament formation followed by high-shear viscosity changes revealed that S-nitrosylated G-actin polymerizes less efficiently than native monomers. The observed decrease in specific viscosity at steady state is due mainly to a marked inhibition of filament end-to-end annealing and, partially, to a reduction in F-actin concentration. Finally, S-nitrosylated actin acts as nitric oxide donor showing a fast, potent vasodilating activity at unusually low concentrations, being comparable with that of low molecular weight nitrosothiols.

Minor thiols cysteine and cysteinylglycine regulate the competition between glutathione and protein SH groups in human platelets subjected to oxidative stress.

Changes in the concentrations of protein-mixed disulfides (XS-SP) of glutathione (GSH), cysteine (CSH), and cysteinylglycine (CGSH) were studied in human platelets treated with diamide and t-BOOH in timecourse experiments (time range, 1-30 min) in order to understand the contribution of minor thiols CSH and CGSH to the regulation of glutathione-protein mixed disulfides (GS-SP). Diamide was much more potent than t-BOOH in altering the platelet thiol composition of XS-SP (threshold dose: diamide, 0.03 mM; t-BOOH, 0.5 mM) and caused reversible XS-SP peaks whose magnitude was related to the concentration of free thiols in untreated cells. Thus maximum levels of GS-SP (8 min after 0.4 mM diamide) were about 16-fold higher than those of controls (untreated platelets, GS-SP = 0.374 nmol/10(9) platelets), whereas those of CS-SP and CGS-SP were only 4-fold increased (untreated platelets, CS-SP = 0.112 nmol/10(9) platelets; CGS-SP = 0.024 nmol/10(9) platelets). The greater effects of diamide with respect to t-BOOH were explained on the basis of the activities of fast reactive protein SH groups for diamide and glutathione reductase (GR) and glucose-6-phosphate dehydrogenase (G-6-PDH) for t-BOOH. The addition of cysteine (0.3 mM, at 4 min) after treatment of platelets with 0.4 mM diamide increased the rate of reversal of GS-SP peaks to normal values, but also caused a relevant change in CGS-SP with respect to that of platelets treated with diamide alone. An increased gamma-glutamyltranspeptidase activity was found in platelets treated with diamide. Moreover, untreated platelets were found to release and hydrolyze GSH to CGSH and CSH. Ratios of thiols/disulfides (XSH/XSSX) and activities of GR and G-6PDH were also related to a high reducing potential exerted by GSH but not by minor thiols. The lower mass and charge of minor thiols is a likely requisite of the regulation of GS-SP levels in platelets.

Relationship between metabolic glycaemic control and platelet content of glutathione and its related enzymes, in insulin-dependent diabetes mellitus.

The relationship between glycaemic metabolic control and intracellular concentration of reduced glutathione (GSH) and related enzymes GSH-peroxidase (GSH-Px), GSH-reductase (GSH-Red), GSH-transferase (GSH-Tr), glucose-6-P-dehydrogenase (G6PDH), and thioltransferase (TT) in patients with insulin-dependent diabetes mellitus (IDDM) is controversial. Choosing platelets as cell model (as commonly done in previous studies), the aim of this study was to relate the platelet content of GSH and related enzymes to glycaemic metabolic control, expressed as glycated haemoglobin (HbA1c), as well as to presence of retinopathy and nephropathy in 114 IDDM patients. As compared to controls, both GSH and GSH-Red (geometric means (95% CI)) were significantly increased in platelets of diabetic patients: 3.3 (0.7-9.6) vs. 2.4 (0.8-7.6) mmol 10(-9) platelets; P=0.01 for GSH, and 30.6 (14.7-61.6) vs. 22.2 (8.7-52.2) mU 10(-9) platelets, P=0.0002 for GSH-Red, and TT activity was marginally decreased in the IDDM group (P=0.06). While no clear relationship was present between GSH-related enzymes and HbA1c, a trend was present toward a non-linear relation between HbA1c and GSH, being significantly related by a parabolic curve (P=0.002). As compared to patients with normoalbuminuria (n=88), diabetic patients with increased urinary albumin excretion rate (n=26) had a significant decrease in platelet TT concentration (3.2 (0.9-6.7) vs. 5.1 (1.9-18.7) mU 10(-9) platelets; P=0.0002), whereas retinopathy was not associated to modifications in GSH or in the enzymatic pattern. In summary: (a) platelet GSH and GSH-Red are increased in IDDM, while other enzymes are unmodified; (b) GSH seems to be related to metabolic control according to non-linear parabolic curve; (c) presence of increased albuminuria is associated to a selective decrease in platelet TT content.

Ozonation of blood during extracorporeal circulation. I. Rationale, methodology and preliminary studies.

We investigated whether exposure of blood ex-vivo to oxygen-ozone (O2-O3) through a gas exchanger is feasible and practical. We first evaluated the classical dialysis-type technique but we soon realized that semipermeable membranes are unsuitable because they are hydrophilic and vulnerable to O3. We therefore adopted a system with hydrophobic O3-resistant hollow fibers enclosed in a polycarbonate housing with a membrane area of about 0.5 m2. First we tested the system with normal saline, determining the production of hydrogen peroxide (H2O2) at O3 concentrations from 5 to 40 microg/ml. We then evaluated critical parameters by circulating swine blood in vitro; this revealed that heparin is not an ideal anticoagulant for this system. Finally, we performed several experiments in sheep and defined optimal anticoagulant dose (sodium citrate, ACD), priming solution, volume of blood flow per min, volume and concentration of O2-O3 mixture flowing countercurrent with respect to blood and the time necessary for perfusion in vivo. The biochemical parameters showed that an O3 concentration as low as 10 microg/ml is effective; this means that gas exchange and O3 reactivity are rapid and capable of inducing biological effects. The sheep showed no adverse effects even after 50 min of extracorporeal circulation at higher O3 concentrations (20 to 40 microg/ml) but the exchanger became less effective (low pO2 values) due to progressive clogging with cells.

Preferential transport of glutathione versus glutathione disulfide in rat liver microsomal vesicles.

A bi-directional, saturable transport of glutathione (GSH) was found in rat liver microsomal vesicles. GSH transport could be inhibited by the anion transport blockers flufenamic acid and 4, 4'-diisothiocyanostilbene-2,2'-disulfonic acid. A part of GSH taken up by the vesicles was metabolized to glutathione disulfide (GSSG) in the lumen. Microsomal membrane was virtually nonpermeable toward GSSG; accordingly, GSSG generated in the microsomal lumen could hardly exit. Therefore, GSH transport, contrary to previous assumptions, is preferred in the endoplasmic reticulum, and GSSG entrapped and accumulated in the lumen creates the oxidized state of its redox buffer.

Studies on the biological effects of ozone: 9. Effects of ozone on human platelets.

During the course of ozonated autohaemotherapy (O3-AHT) using heparin as an anticoagulant, it was occasionally observed that a few clots were retained in the filter during blood reinfusion. This observation prompted an investigation on the effect of ozone (O3) on human platelets. We have now shown, both by biochemical and morphological criteria, that heparin in the presence of O3 can promote platelet aggregation. In contrast, after Ca(2+) chelation with citrate, platelet aggregation is much reduced. The potential role of the transient formation of hydrogen peroxide (H2O2) in the presence of Ca2+ with the possible expression of adhesion molecules is briefly discussed.

Fast-reacting thiols in rat hemoglobins can intercept damaging species in erythrocytes more efficiently than glutathione.

The S-conjugation rates of the free-reacting thiols present on each component of rat hemoglobin with 5,5-dithio-bis(2,2-nitrobenzoic acid) (DTNB) have been studied under a variety of conditions. On the basis of their reactivity with DTNB (0.5 mM), three classes of thiols have been defined as follows: fast reacting (fHbSH), with t1/2 <100 ms; slow reacting (sHbSH), with t1/2 30-50 s; and very slow reacting (vsHbSH), with t1/2 180-270 s. Under paraphysiological conditions, fHbSH (identified with Cys-125beta(H3)) conjugates with DTNB 100 times faster than glutathione and approximately 4000 times more rapidly than (v)sHbSH (Cys-13alpha(A11) and Cys-93beta(F9)). Such characteristics of fHbSH reactivity that are independent of the quaternary state of hemoglobin are mainly due to the following: (i) its low pK (approximately 6.9, the cysteinyl anion being stabilized by a hydrogen bond with Ser-123beta(H1)) and (ii) the large exposure to the solvent (as measured by analysis of a model of the molecular surface) and make these thiols the kinetically preferred groups in rat erythrocytes for S-conjugation. In addition, because of the high cellular concentration (8 mM, i.e. four times that of glutathione), fHbSHs are expected to intercept damaging species in erythrocytes more efficiently than glutathione, thus adding a new physiopathological role (direct involvement in cellular strategies of antioxidant defense) to cysteinyl residues in proteins.

Role of protein -SH groups in redox homeostasis--the erythrocyte as a model system.

The reactivities of the sulfhydryl groups of rat, turkey, human, and calf hemoglobin were studied together with the enzyme activities of glutathione peroxidase, glutathione reductase, glucose-6-phosphate dehydrogenase, and glutaredoxin in lysed erythrocytes to evaluate their roles in regulating redox homeostasis. The results of -SH reactivity showed rate constants spanning four orders of magnitude (k2, calf, 6.67 M-1 s-1; rat -SH fast reacting, 2.8 x 10(4) M-1 s-1). Enzyme activities of glucose-6-phosphate dehydrogenase ranged from 0.402 U/ml (calf) to 0.900 U/ml (rat), glutathione reductase from 0. 162 U/ml (rat) to 0.381 U/ml (human), glutaredoxin from 0.778 U/ml (rat) to 2.28 U/ml (turkey), and glutathione peroxidase from 2.07 U/ml (human) to 27.3 U/ml (rat). Blood samples of the four species were also treated with 0.5-1.5 mM tert-butyl hydroperoxide (t-BOOH) or diamide, and levels of glutathione-derived species [GSH, GSSG, and glutathione-protein mixed disulfides (GS-SP)] were determined within 120 min and related to the corresponding protein -SH group (PSH) reactivities and enzyme repertoires. In all cases t-BOOH rapidly transformed GSH into GSSG by the action of glutathione peroxidase; GSSG was in turn transformed into GS-SP, according to the reaction GSSG + PSH --> GS-SP + GSH, or reduced back to GSH by glutathione reductase. The GSSG reduction was more efficient in rat and human blood, due to the contribution of the fast-reacting -SH of hemoglobin, in the rat, and to the efficiency of the enzyme repertoire of human blood. Calf blood showed a relatively low capacity to restore normal values after oxidative stress, due to its low PSH reactivity and the weak contribution of its enzymes. Diamide treatment, which is known to react nonenzymatically with thiols, gave increased GS-SP levels in rat and turkey, but not in human and calf blood, as expected from the different corresponding PSH reactivities. Species with relatively high PSH reactivity and glucose 6-phosphate dehydrogenase activity, such as the rat, therefore had a higher antioxidant capacity than species (calf) in which these parameters were relatively low.