Thiol regulation of pro-inflammatory cytokines reveals a novel immunopharmacological potential of glutathione in the alveolar epithelium

The therapeutic immunopharmacological potential of glutathione in the alveolar epithelium is not well characterized. We developed an in vitro model of fetal alveolar type II epithelial cells to investigate the effect of redox disequilibrium on chemioxyexcitation (DeltapO(2)/ROS) induced up-regulation of pro-inflammatory cytokines. Buthionine sulfoximine, an irreversible inhibitor of gamma-glutamylcysteine synthetase, the rate-limiting enzyme in glutathione (GSH) biosynthesis, induced intracellular reactive oxygen species (ROS) and the release of interleukin-1beta (IL-1beta), IL-6, and tumor necrosis factor-alpha. Chloroethyl nitrosourea, which blocks the NADPH-dependent recycling of oxidized glutathione (GSSG), reduced ROS-induced cytokine production, similar to pyrrolidine dithiocarbamate, an antioxidant/pro-oxidant thiuram, which elevates GSSG. The antioxidant and GSH precursor, acetylcysteine, abrogated cytokine release concomitant with suppression of ROS, an effect mimicked by gamma-glutamylcysteinyl-ethyl ester, a cell permeant GSH. Cysteine, the rate-limiting amino acid in the de novo synthesis of GSH, administered as oxothiazolidine carboxylate and adenosylmethionine, mitigated the chemioxyexcitation-dependent cytokine release. Ebselen, an anti-inflammatory antioxidant, which mimics the effect of glutathione peroxidase, neutralized ROS by the GSH-peroxidase-coupled reaction, thereby blocking the pathway to cytokine enhancement. Our results indicate that modulating redox equilibrium by pharmacological thiols exhibits differential regulation on pro-inflammatory cytokines, thus bearing clinical consequences for the therapeutic treatment of pediatric distresses in pathophysiology.     

15LO1 dictates glutathione redox changes in asthmatic airway epithelium to worsen type 2 inflammation

Altered redox biology challenges all cells, with compensatory responses often determining a cell’s fate. When 15 lipoxygenase 1 (15LO1), a lipid-peroxidizing enzyme abundant in asthmatic human airway epithelial cells (HAECs), binds phosphatidylethanolamine-binding protein 1 (PEBP1), hydroperoxy-phospholipids, which drive ferroptotic cell death, are generated. Peroxidases, including glutathione peroxidase 4 (GPX4), metabolize hydroperoxy-phospholipids to hydroxy derivatives to prevent ferroptotic death, but consume reduced glutathione (GSH). The cystine transporter SLC7A11 critically restores/maintains intracellular GSH. We hypothesized that high 15LO1, PEBP1, and GPX4 activity drives abnormal asthmatic redox biology, evidenced by lower bronchoalveolar lavage (BAL) fluid and intraepithelial cell GSH:oxidized GSH (GSSG) ratios, to enhance type 2 (T2) inflammatory responses. GSH, GSSG (enzymatic assays), 15LO1, GPX4, SLC7A11, and T2 biomarkers (Western blot and RNA-Seq) were measured in asthmatic and healthy control (HC) cells and fluids, with siRNA knockdown as appropriate. GSSG was higher and GSH:GSSG lower in asthmatic compared with HC BAL fluid, while intracellular GSH was lower in asthma. In vitro, a T2 cytokine (IL-13) induced 15LO1 generation of hydroperoxy-phospholipids, which lowered intracellular GSH and increased extracellular GSSG. Lowering GSH further by inhibiting SLC7A11 enhanced T2 inflammatory protein expression and ferroptosis. Ex vivo, redox imbalances corresponded to 15LO1 and SLC7A11 expression, T2 biomarkers, and worsened clinical outcomes. Thus, 15LO1 pathway–induced redox biology perturbations worsen T2 inflammation and asthma control, supporting 15LO1 as a therapeutic target.     

Mechanism for the hepatotoxicity of the antiandrogen, nilutamide. Evidence suggesting that redox cycling of this nitroaromatic drug leads to oxidative stress in isolated hepatocytes.

The nitroaromatic drug nilutamide has been shown previously to undergo redox cycling in aerobic rat liver microsomes, being reduced by NADPH-cytochrome P-450 reductase to a nitro anion-free radical which reacts with oxygen, to regenerate the parent drug, and form a superoxide anion dismuted to hydrogen peroxide. In the present study, the effects of nilutamide on isolated rat hepatocytes have been determined. After 6 and 8 hr of incubation with 0.5 mM nilutamide, lactate dehydrogenase was released in the incubation medium, and cell viability was decreased markedly. Consistent with a redox cycle producing reactive oxygen species, nilutamide increased nonmitochondrial (cyanide-resistant) oxygen consumption; the toxicity of nilutamide occurred sooner and was more extensive in the presence of sodium azide (an inhibitor of catalase). Consistent with an oxidative stress, the toxicity of nilutamide was associated with depletion of reduced glutathione, increased levels of glutathione disulfide, increased Ca(++)-dependent phosphorylase a activity, oxidation and accumulation of cytoskeleton-associated proteins and formation of blebs; toxicity was prevented by glutathione precursors, thiol reductants and/or antioxidants, such as L-cystine, L-cysteine, N-acetyl-L-cysteine, dithiothreitol, N,N'-diphenyl-p-phenylene-diamine and alpha-tocopherol. Feeding the animals with a diet supplemented with 2% L-cystine increased the initial glutathione stores of hepatocytes and prevented nilutamide toxicity. It is concluded that nilutamide is toxic to isolated rat hepatocytes, as a probable consequence of an oxidative stress due to the redox cycling of this nitroaromatic compound.     

Non-protein thiols flux to S-nitrosothiols in endothelial cells: an LPS redox signal

Lipopolysaccharide (LPS) injures blood vessels by activating pathways in the endothelium that lead either to cell survival and proliferation or apoptosis. It has been suggested that these outcomes are determined when reactive oxygen and nitrogen intermediates oxidize low molecular weight non-protein thiols (NPSHs) such as glutathione (GSH) and cysteine (Cys), which serve as major intracellular reducing agents. The oxidoreduction of NPSHs could be an important redox signal if it were shown to occur rapidly following injury. Towards that end, cultured bovine aortic endothelial cells were stained with the thiol fluorescent probe, monobromobimane (MBB). Most of the acid extractable MBB-reactive adducts are GSH (approximately 90%) and Cys (approximately 90%). Within 1 min of LPS exposure, 50-70% of the MBB-reactive NPSHs are consumed without evidence for concomitant net generation of superoxide, hydrogen peroxide, singlet oxygen, or glutathione disulfide (GSSG). Although LPS induces an increased rate of thiol-disulfide exchange, the slight increase does not explain the magnitude of NPSH consumption. Within the first 10 min of recovery from LPS exposure, the MBB-reactive NPSH fluorescence returns at or slightly above baseline values. When HgCl2 was added to the acid extract, one mole of S-nitrosothiol oxidizing equivalent was found for every mole of MBB-reactive NPSH consumed. It is suspected that the rapid flux of MBB-reactive NPSHs and Hg2+-inducible oxidants reflects transition of GSH to GSNO (S-nitrosoglutathione) and could be an important redox signal in endothelial cells exposed to LPS.     

一氧化氮供体诱导HL-60细胞凋亡过程中活性氧自由基和抗氧化能力的变化

为了研究外源性一氧化氮（NO）供体硝普钠（SNP）诱导HL-60细胞凋亡过程中活性氧自由基和抗氧化能力的变化，将HL-60细胞与SNP在体外培养，用MTT法观察NO对细胞的抑制作用；用透射电子显微镜和光学显微镜观察细胞结构的变化；用DNA凝胶电泳、细胞DNA含量、Annexin-V／PI法等分析细胞凋亡；用双氢罗丹明123（DHR）标记、流式细胞仪检测细胞内活性氧（ROS），并同时测定细胞内谷胱甘肽（GSH）和3种抗氧化酶的活性。结果表明：SNP能抑制HL-60细胞生长，典型的细胞形态改变、DNA片段化、亚二倍体峰比例增加、DNA末端标记和Annexin-V^＋／PI^-表达增加等证实NO能诱导白血病细胞凋亡，且两者之间有明显的量效和时效关系。在此过程中，细胞内ROS水平增加，细胞内谷胱甘肽和过氧化氢酶（CAT）、谷胱甘肽S转移酶（GST）、谷胱甘肽过氧化物酶（GPX）活性降低。ROS含量和CAT、GST、GPX活性与SNP之间也有明显的量效关系。结论：细胞内活性氧自由基增加和抗氧化能力下降在外源性一氧化氮供体诱导HL-60细胞凋亡中发挥了重要作用。     

亚硒酸钠和三氧化二砷诱导人急性早幼粒细胞白血病细胞系NB4细胞凋亡机制的比较

为比较亚硒酸钠（Na2SeO3）和三氧化二砷（As2O3）诱导NB4细胞凋亡的作用机制，本研究应用MTT实验、DNA琼脂糖电泳，细胞内DNA含量检测研究细胞生长抑制和细胞凋亡，用化学发光法，化学比色法检测细胞内活性氧和还原型谷胱甘肽，用流式细胞术检测细胞内线粒体膜电位，结果显示：5μmol/L亚硒酸钠和1μmol/L三氧化二砷作用24小时后均能诱导NB4细胞凋亡。在诱导细胞凋亡的过程中，亚硒酸钠和三氧化二砷组均伴有细胞内活性氧水平的提高和线粒体膜电位下降，但在亚硒酸钠组还伴有细胞内还原型谷胱甘肽下降，用N乙酰半胱氨酸提高细胞内还原型谷胱甘肽后，增强了硒诱导NB4细胞细胞和氧化应激的作用，但是抑制了砷诱导细胞凋亡和氧化应激的作用。结论：亚硒酸钠和三氧化二砷同样可以诱导NB4细胞的凋亡，但是二的作用机制可能存在差异。     

The importance of glutathione in human disease.

Reduced glutathione (GSH) is the most prevalent non-protein thiol in animal cells. Its de novo and salvage synthesis serves to maintain a reduced cellular environment and the tripeptide is a co-factor for many cytoplasmic enzymes and may also act as an important post-translational modification in a number of cellular proteins. The cysteine thiol acts as a nucleophile in reactions with both exogenous and endogenous electrophilic species. As a consequence, reactive oxygen species (ROS) are frequently targeted by GSH in both spontaneous and catalytic reactions. Since ROS have defined roles in cell signaling events as well as in human disease pathologies, an imbalance in expression of GSH and associated enzymes has been implicated in a variety of circumstances. Cause and effect links between GSH metabolism and diseases such as cancer, neurodegenerative diseases, cystic fibrosis (CF), HIV, and aging have been shown. Polymorphic expression of enzymes involved in GSH homeostasis influences susceptibility and progression of these conditions. This review provides an overview of the biological importance of GSH at the level of the cell and organism.     

Novel glutathione-dependent thiopurine prodrugs: evidence for enhanced cytotoxicity in tumor cells and for decreased bone marrow toxicity in mice

Elevated glutathione (GSH) levels have been detected in many tumors compared with the healthy, surrounding tissue. Often, this GSH up-regulation is associated with drug resistance. The prodrugs 6-(2-acetylvinylthio)guanine (AVTG) and 6-(2-acetylvinylthio)purine (AVTP) contain a novel butenone moiety that allows the prodrugs to react selectively with sulfhydryl nucleophiles to release the chemotherapeutic drug 6-thioguanine (6-TG) or 6-mercaptopurine (6-MP), respectively. The cellular uptake and metabolism of trans-AVTG in two human renal carcinoma cell lines that were used as models were rapid and associated with depletion of intracellular GSH. Formation of 6-TG from trans-AVTG correlated positively with intracellular GSH concentrations, and was significantly reduced by diethyl maleate pretreatment. Intracellular concentrations of 6-TG after incubations with trans-AVTG were significantly higher than the 6-TG concentrations obtained after incubations with equimolar concentrations of 6-TG; thus, the prodrug delivered more 6-TG to the cell than did 6-TG itself. Cytotoxicity studies demonstrated that AVTG and AVTP had similar IC(50) values that were comparable with those of 6-TG, but were significantly lower than those of 6-MP. Furthermore, after in vivo treatment of mice with the prodrugs, no reduction was observed in circulating white blood cell counts, whereas white blood cell counts of mice treated with equimolar or 60% lower doses of 6-TG were reduced by 50 to 60%. Collectively, the results show that AVTG and AVTP are novel potential chemotherapeutic agents that may target tumors with up-regulated levels of GSH, and may exhibit less systemic toxicity than the parent thiopurines.     

Glutathione metabolism in activated human neutrophils: stimulation of glutathione synthesis and consumption of glutathione by reactive oxygen species

Since glutathione (GSH) is involved in the modulation of the function of polymorphonuclear leucocytes (PMN) such as phagocytosis and production of reactive oxygen species, the metabolism of GSH was studied in human PMN. The concentration of GSH in resting PMN amounted to 13.3 nmol 10(-7) PMN and remained stable over 100 min of incubation. Upon activation of PMN with phorbol myristate acetate intracellular GSH decreased to 50% of the resting concentration within 80 min. In the presence of buthionine sulfoximine, which inhibits the synthesis of GSH, the depletion of intracellular GSH was dramatically accelerated, indicating that activation of PMN is associated with a marked stimulation of GSH synthesis. Since a similar depletion of GSH was seen in the presence of propargylglycine, an inhibitor of the cystathionine pathway, most of the cysteine required for the resynthesis of GSH must originate from methionine and not from cysteine generated by the catabolism of GSH. Further studies showed that GSH is sequentially oxidized by O2-. and HOCl, first to GSSG and then to an unidentified compound, most likely a chloramine. In the presence of an adequate supply of GSH and NADPH which is required for the reduction of GSSG by glutathione reductase this further oxidation of GSSG was prevented. Thus, the highly toxic HOCl generated by PMN can be detoxified by the glutathione reducatase system. The capacity of PMN to re-synthesize GSH may be an important determinant of PMN function.     

Preclinical pharmacokinetic analysis of NOV-002, a glutathione disulfide mimetic

NOV-002 is a glutathione disulfide (GSSG) mimetic that is the subject of clinical investigation in oncology indications. GSSG is reduced by glutathione reductase (GR) to form glutathione (GSH), thereby maintaining redox homeostasis. The purpose of the study was to report the pharmacokinetic properties of NOV-002 and evaluate the effect that NOV-002 elicits in redox homeostasis. The pharmacokinetic analysis and tissue distribution of NOV-002 and GSH was evaluated in mice following a dose of 250 mg/kg, i.p. The redox potential and total protein thiol status was calculated. Here we show that NOV-002 is a substrate for GR and that GSH is a primary metabolite. Non-linear pharmacokinetic modeling predicted that the estimated absorption and elimination rate constants correspond to a half-life of ∼13 min with an AUC of 1.18 μg h/mL, a C_max of 2.16 μg/ml and a volume of distribution of 42.61 L/kg. In addition, measurement of the redox potential and total protein thiol status indicated the generation of a transient oxidative signal in the plasma compartment after administration of NOV-002. These results indicate that NOV-002 exerts kinetic and dynamic effects in mice consistent with the GSSG component as the active pharmacological constituent of the drug. A longer-lasting decrease in total plasma free thiol content was also seen, suggesting that the oxidative effect of the GSSG from NOV-002 was impacting redox homeostasis.     

Inhibition of glutathione synthesis as a chemotherapeutic strategy for trypanosomiasis

With the expectation that trypanosomal glutathione (GSH) plays a major protective role against the endogenous oxidant stress that results form high intracellular levels of H2O2, we sought to deplete Trypanosoma brucei brucei of their GSH through inhibition of its biosynthesis. Administration of buthionine sulfoximine (BSO), a reversible inhibitor of gamma-glutamylcysteine synthetase, to parasitemic mice resulted in a progressive decrease in trypanosome GSH content, such that parasites isolated after 5 h or BSO treatment contained 50% of normal values. When BSO administration was continued for 18 h (intraperitoneal injection of 4 mmol/kg every 1.5 h), parasitemias temporarily cleared. When inhibitory plasma levels of BSO were maintained for about 27 h, two out of six infected mice were cured and the rest had significantly prolonged survival. These findings demonstrate the potential value of GSH depletion for the treatment of trypanosomiasis.     

Reactive oxygen species during ischemia-reflow injury in isolated perfused rat liver.

The hypothesis that intracellular generation of reactive oxygen species in hepatocytes or reticuloendothelial cells may cause ischemia-reperfusion injury was tested in isolated perfused livers of male Fischer rats. GSSG was measured in perfusate, bile, and tissue as a sensitive index of oxidative stress. After a preperfusion phase of 30 min, the perfusion was stopped (global ischemia) for various times (30, 120 min) and the liver was reperfused for another 60 min. The bile flow (1.48 +/- 0.17 microliters/min X gram liver weight), the biliary efflux of total glutathione (6.54 +/- 0.94 nmol GSH eq/min X g), and GSSG (1.59 +/- 0.23 nmol GSH eq/min X g) recovered to 69-86% after short-term ischemia and to 36-72% after 2 h of ischemia when compared with values obtained from control livers perfused for the same period of time. During reperfusion, the sinusoidal efflux of total glutathione (16.4 +/- 2.1 nmol GSH eq/min X g) and GSSG (0.13 +/- 0.05 nmol GSH eq/min X g) did not change except for an initial 10-30-s increase during reperfusion washout. No increased GSSG secretion into bile was detectable at any time during reperfusion. The liver content of total glutathione (32.5 +/- 3.5 nmol GSH eq/mg protein) and GSSG (0.27 +/- 0.09 nmol GSH eq/mg protein) did not change significantly during any period of ischemia or reperfusion. We conclude, therefore, that at most only a minor amount of reactive oxygen species were generated during reperfusion. Thus, reactive oxygen species are unlikely to cause ischemia/reperfusion injury in rat liver by lipid peroxidation or tissue thiol oxidation.     

The impact of redox and thiol status on the bone marrow: Pharmacological intervention strategies

Imbalances in cancer cell redox homeostasis provide a platform for new opportunities in the development of anticancer drugs. The control of severe dose-limiting toxicities associated with redox regulation, including myelosuppression and immunosuppression, remains a challenge. Recent evidence implicates a critical role for redox regulation and thiol balance in pathways that control myeloproliferation, hematopoietic progenitor cell mobilization, and immune response. Hematopoietic stem cell (HSC) self-renewal and differentiation are dependent upon levels of intracellular reactive oxygen species (ROS) and niche microenvironments. Redox status and the equilibrium of free thiol:disulfide couples are important in modulating immune response and lymphocyte activation, proliferation and differentiation. This subject matter is the focus of the present review. The potential of redox modulating chemotherapeutics as myeloproliferative and immunomodulatory agents is also covered.     

Role of selenium in reducing hypoxia-induced oxidative stress: an in vivo study.

At high altitudes, the reactive oxygen species are continuously generated as a consequence of low oxygen partial pressure (hypoxia), which causes tissue damage. The body's defence system to combat the oxidative stress (e.g., anti-oxidant enzymes, free radical scavengers such as vitamin C, vitamin E, beta-carotene, reduced glutathione and minerals such as selenium, etc.) may diminish. In the present study, the antioxidant effect of selenium (Se) in reducing the hypoxia-induced oxidative stress was evaluated by exposing male albino rats to hypoxic stress in a decompression chamber. Exposure to hypoxia resulted in an increase in malondialdehyde (MDA) levels in plasma and tissues and a concurrent decrease in blood glutathione (GSH), glutathione peroxidase (GPx), plasma protein and plasma selenium content when compared with controls. Haemoglobin concentration (Hb%), red blood corpuscles (RBC) and white blood corpuscles (WBC) count were also increased in the hypoxia-exposed group. Selenium supplementation to animals reversed the trend. There was a significant decrease (P < 0.001) in MDA and subsequent increase in plasma and tissue GSH levels. Similarly the blood and tissue GPx and plasma protein also increased significantly in the Se supplemented animals compared with control animals. The Hb%, RBC and WBC counts showed no significant difference between Se-fed and control rats. These results suggest that selenium may help in reducing the lipid peroxidation during hypoxia.     

The influence of depleted glutathione levels on the photodynamic action of zinc phthalocyanine in CHO K1 cells

OBJECTIVE: The current study focuses on any influence that depletion of endogenous glutathione in CHO K1 cells may have on the photodynamic action of zinc phthalocyanine (ZnPc). MATERIALS AND METHODS: Two lasers--a HeNe laser, 632.5 nm, maximum power output 3.5 mW, and a Toshiba semiconducting laser, 670 nm, maximum power of 7 mW--were used. Chinese Hamster Ovary cells (CHO K1) were exposed to light, 2-10 J. Cellular reduced glutathione levels [GSH] were depressed prior to exposure to ZnPc and laser light, using buthionine sulphoximine, a potent inhibitor of gamma-glutamylcysteine synthetase. The influence of hypoxic intracellular conditions was studied by reduction of oxygen content of cells by 80% following purging of cell cultures with nitrogen. RESULTS: In well-aerated cells, doubling times are reduced by the photodynamic action of ZnPc by 29 +/- 6%, fig 2 (p = 0.01). Cells with lowered [GSH] do not show this effect (p = 0.1). When hypoxic cells are studied at normal [GSH], no photodynamic effect is observed (p = 0.1). When cell viability is studied, using the 670-nm laser, a photodynamic effect is observed, (80% fall from controls, p < 0.001), irrespective of the cellular [GSH] level for a single dose of 6 J. This effect is observed in cells with normal [GSH], for varied doses of 2 J and higher (63% fall at 2 J, p < 0.001). CONCLUSIONS: Lowered [GSH] was observed to depress the photodynamic effect of ZnPc when cell-doubling times were the endpoint. The photostimulating effect of ZnPc was similarly suppressed by hypoxic conditions. When cell viability was the endpoint, then a photodynamic effect of ZnPc was observed irrespective of the endogenous [GSH] values.     

Resistance of human tumor cells in vitro to oxidative cytolysis.

Nine human cell types, six of them malignant, displayed a marked resistance to lysis by hydrogen peroxide (LD50, 2-20 mM). Of the reactive oxygen intermediates generated extracellularly, only H2O2 lysed all the cell types. OH was lytic to one of four, OI- to one of one, and O-2 to none of four cell types tested. Resistance to oxidative lysis did not correlate with specific activity of catalase, glutathione (GSH) peroxidase, other peroxidases, or glutathione disulfide reductase, or with specific content of GSH. Resistance to H2O2 seemed to occur via mechanisms distinct from those responsible for cellular consumption of H2O2. Consumption was inhibitable by azide and was probably due to catalase in each cell type. In contrast, resistance to oxidative lysis occurred via distinct routes in different cells. One cell type used the GSH redox cycle as the primary defense against H2O2, like murine tumors previously studied. Other cells seemed to utilize catalase as the major defense against H2O2. Nonetheless, with both catalase and the GSH redox cycle inhibited, all the human cells tested exhibited an inherent resistance to oxidative lysis, that is, resistance independent of detectable degradation of H2O2.     

Protective role of caffeic acid phenethyl ester in the liver of rats exposed to cold stress

Cold exposure can induce a form of environmental stress. Cold stress (CS) alters homeostasis, results in the creation of reactive oxygen species and leads to alterations in the antioxidant defense system. The caffeic acid phenethyl ester (CAPE), an active component of propolis, has an antioxidant capacity. We investigated the effect of CS on oxidative stress and antioxidant defense system and the possible protective effect of CAPE in rat liver tissue. Twenty-four female Wistar Albino rats were divided into four groups: Control, CAPE-treated, CS, and CAPE-treated CS (CS + CAPE) group. Catalase (CAT), glutathione peroxidase (GSH-Px), superoxide dismutase (SOD) activities and total glutathione (GSH) and malondialdehyde (MDA) levels were measured. In addition, histological changes in liver tissue were examined by light microscopy. SOD, CAT and GSH-Px activities and total GSH level were significantly declined in the CS group. In the CS + CAPE group, the activities of these three enzymes and GSH level significantly raised with regard to the CS group. MDA levels increased in the CS group and decreased in the CS + CAPE group. The tissues of the CS group showed some histopathological changes such as necrosis, hepatocyte degeneration, sinusoidal dilatation, hemorrhage and vascular congestion and dilatation. In the CS + CAPE group, the histopathological evidence of hepatic damage was markedly reduced. Histological parameters were consistent with biochemical parameters. In this study, CS increased oxidative stress in liver tissue. CAPE regulated antioxidant enzymes, inhibited lipid peroxidation and reduced hepatic damage.     

Organosulfur compounds from alliaceae in the prevention of human pathologies.

A strong association between elevated plasma low-density-lipoprotein (LDL) and the development of cardiovascular diseases (CVD) has been established. Oxidation of LDL (Ox-LDL) promotes vascular dysfunction, enhances the production and release of inflammatory mediators such as reactive oxygen species and contribute to the initiation and progression of atherosclerosis. In addition, Ox-LDL enhances the production and release of tumor necrosis factor (TNF-alpha), interleukin (IL)-6, arachidonic acid metabolites and nitric oxide (NO) that are responsible for various human pathologies including cancer. Organosulfur compounds (OSC) from alliaceae modulate the glutathione (GSH) redox cycle and inhibits NFkappa-B activation in human T cells. Furthermore, OSC bioactivities include antioxidant, antibacterial, anticarcinogenic, antiatherogenic, immunostimulatory, and liver protection potential.     

The effects of age and hyperhomocysteinemia on the redox forms of plasma thiols

We assayed the redox forms of cysteine (reduced [CSH], oxidized [CSSC], and bound to protein [CS-SP]), cysteinylglycine (CGSH; cysteinylgycine disulfide [CGSSGC] and cysteinylglycine-protein mixed disulfide [CGS-SP]), glutathione (GSH; glutathione disulfide [GSSG] and glutathione-protein mixed disulfide [GS-SP]), homocysteine (Hcy; homocystine [HcyS] and homocystine-protein mixed disulfides [bHcy]), and protein sulfhydryls in the plasma of healthy subjects (divided into 8 groups ranging in age from birth to 70 years) and patients with mild hyperhomocysteinemia associated with cardiovascular disease (heart-transplant patients) or vascular atherosclerosis, with or without renal failure. In healthy individuals, levels of disulfides and protein-mixed disulfides were more abundant than those of thiols, and those of protein-thiol mixed disulfides were higher than disulfides. Concentrations of CSH, GSH, and CGSH in the various groups had profiles characterized by a maximum over time. The concentration of Hcy was unchanged up to the age of 30 years, after which it increased. CSSC concentration increased gradually with age, whereas concentrations of the other disulfides were essentially unchanged. By contrast, the concentrations of all protein-thiol mixed disulfides, especially those with CSH, increased gradually with age. Ranks of distribution of the reduced forms changed with age (at birth, CSH > CGSH > GSH > Hcy; in 1- to 2-year-olds, CSH > GSH > CGSH > Hcy; and in 51- to 70-year-olds, CSH > CGSH = GSH > Hcy), whereas those of disulfides and protein-thiol mixed disulfides were substantially unchanged (in all age groups, CSSC > CGSSGC > GSSG = HcyS and CS-SP > CGS-SP > bHcy > GS-SP). In patients with pathologic conditions, plasma levels of disulfide forms CSSC, HcyS, CS-SP, and bHcy were significantly increased, whereas other redox forms of thiols were unchanged or showed variations opposite (increasing or decreasing) to control values. Maximal increases in disulfides and protein-thiol mixed disulfides were associated with renal failure. Our data suggest that increases in plasma bHcy concentrations in subjects with pathologic conditions were more likely the result of activation of thiol-disulfide exchange reactions between free reduced Hcy and CS-SP than of a direct action of reactive oxygen species.