Effect of nitrosative stress on Schizosaccharomyces pombe: inactivation of glutathione reductase by peroxynitrite

Oxidative stress has been shown to alter cellular redox status in various cell types. Changes in expressions of several antioxidative and antistress-responsive genes along with activation or inactivation of various proteins were also reported during oxidative insult as well as during nitrosative stress. In the present study, we show the effect of nitrosative stress on cellular redox status of fission yeast Schizosaccharomyces pombe. This is the first report of S-nitrosoglutathione (GSNO) reductase activity in S. pombe and its inactivation by GSNO. We also show the inactivation of glutathione reductase (GR) and glutathione peroxidase in the presence of various reactive nitrogen species in vivo. In addition, we first observe the inactivation of GR by peroxynitrite in vivo using S. pombe cells and also similar observations under in vitro conditions. An immunoreactive band against monoclonal anti-3-nitrotyrosine antibody confirms the modification of GR under in vitro conditions. We also show the effect of nitrosative stress on Deltapap1 cells of S. pombe, which are more sensitive to nitrosative stress, indicating the involvement of Pap1 in the protection against nitrosative stress. Finally, exposure of S. pombe cells to reactive nitrogen species reveals an important role of cellular thiol pool in protection against nitrosative stress.     

Enzymes that counteract nitrosative stress promote fungal virulence

Enzymes that protect cells from reactive oxygen species (superoxide dismutase, catalase, peroxidase) have well-established roles in mammalian biology and microbial pathogenesis. Two recently identified enzymes detoxify nitric oxide (NO)-related molecules; flavohemoglobin denitrosylase consumes NO, and S-nitrosoglutathione (GSNO) reductase metabolizes GSNO. Although both enzymes protect microorganisms from nitrosative challenge in vitro, their relevance has not been established in physiological contexts. Here we studied their biological functions in Cryptococcus neoformans, an established human fungal pathogen that replicates in macrophages and whose growth in vitro and in infected animals is controlled by NO bioactivity. We show that both flavohemoglobin denitrosylase and GSNO reductase contribute to C. neoformans pathogenesis. FHB1 and GNO1 mutations abolished NO- and GSNO-consuming activity, respectively. Growth of fhb1 mutant cells was inhibited by nitrosative challenge, whereas that of gno1 mutants was not. fhb1 mutants showed attenuated virulence in a murine model, and virulence was restored in iNOS(-/-) animals. Survival of the fhb1 mutant was also reduced in activated macrophages and restored to wild-type by inhibition of NOS activity. Combining mutations in flavohemoglobin and GSNO reductase, or flavohemoglobin and superoxide dismutase, further attenuated virulence. These studies illustrate that fungal pathogens elaborate enzymatic defenses against nitrosative stress mounted by the host.     

Nitrosative stress inhibits the aminophospholipid translocase resulting in phosphatidylserine externalization and macrophage engulfment: implications for the resolution of inflammation

Macrophage recognition of apoptotic cells depends on externalization of phosphatidylserine (PS), which is normally maintained within the cytosolic leaflet of the plasma membrane by aminophospholipid translocase (APLT). APLT is sensitive to redox modifications of its -SH groups. Because activated macrophages produce reactive oxygen and nitrogen species, we hypothesized that macrophages can directly participate in apoptotic cell clearance by S-nitrosylation/oxidation and inhibition of APLT causing PS externalization. Here we report that exposure of target HL-60 cells to nitrosative stress inhibited APLT, induced PS externalization, and enhanced recognition and elimination of "nitrosatively" modified cells by RAW 264.7 macrophages. Using S-nitroso-L-cysteine-ethyl ester (SNCEE) and S-nitrosoglutathione (GSNO) that cause intracellular and extracellular trans-nitrosylation of proteins, respectively, we found that SNCEE (but not GSNO) caused significant S-nitrosylation/oxidation of thiols in HL-60 cells. SNCEE also strongly inhibited APLT, activated scramblase, and caused PS externalization. However, SNCEE did not induce caspase activation or nuclear condensation/fragmentation suggesting that PS externalization was dissociated from the common apoptotic pathway. Dithiothreitol reversed SNCEE-induced S-nitrosylation, APLT inhibition, and PS externalization. SNCEE but not GSNO stimulated phagocytosis of HL-60 cells. Moreover, phagocytosis of target cells by lipopolysaccharide-stimulated macrophages was significantly suppressed by an NO. scavenger, DAF-2. Thus, macrophage-induced nitrosylation/oxidation plays an important role in cell clearance, and hence in the resolution of inflammation.     

Increased oxidative stress in the RAW 264.7 macrophage cell line is partially mediated via the S-nitrosothiol-induced inhibition of glutathione reductase

We investigated whether endogenously or exogenously produced nitric oxide (NO) can inhibit cellular glutathione reductase (GR) via the formation of S-nitrosothiols to decrease cellular glutathione (GSH) and increase oxidative stress in RAW 264.7 cells. The specificity of this inhibition was demonstrated by addition of a NO-synthase inhibitor, and met- or oxyhemoglobin. Using isolated GR we found that only certain NO donors inhibit this enzyme via S-nitrosothiol. Furthermore, we found that cellular GSH decrease is paralleled by an increase of superoxide anion production. Our results show that the GR enzyme is a potential target of S-nitrosothiols to decrease cellular GSH levels and to induce oxidative stress in macrophages.     

S-nitrosation of glutathione by nitric oxide,peroxynitrite, and (*)NO/O(2)(*-)

To elucidate potential mechanisms of S-nitrosothiol formation in vivo, we studied nitrosation of GSH and albumin by nitric oxide ((*)NO), peroxynitrite, and (*)NO/O(2)(*)(-). In the presence of O(2), (*)NO yielded 20% of S-nitrosoglutathione (GSNO) at pH 7.5. Ascorbate and the spin trap 4-hydroxy-[2,2,4,4-tetramethyl-piperidine-1-oxyl] (TEMPOL) inhibited GSNO formation by 67%. Electron paramagnetic resonance spectroscopy with 5-diethoxyphosphoryl-5-methyl-1-pyrroline-N-oxide (DEPMPO) demonstrated intermediate formation of glutathionyl radicals, suggesting that GSNO formation by (*)NO/O(2) is predominantly mediated by (*)NO(2). Peroxynitrite-triggered GSNO formation (0.06% yield) was stimulated 10- and 2-fold by ascorbate and TEMPOL, respectively. Co-generation of (*)NO and O(2)(*)(-) at equal fluxes yielded less GSNO than (*)NO alone, but was 100-fold more efficient (8% yield) than peroxynitrite. Moreover, in contrast to the reaction of peroxynitrite, GSNO formation by (*)NO/O(2)(*)(-) was inhibited by ascorbate. Similar results were obtained with albumin instead of GSH. We propose that sulfhydryl compounds react with O(2)(*)(-) to initiate a chain reaction that forms radical intermediates which combine with (*)NO to yield GSNO. In RAW 264.7 macrophages, S-nitrosothiol formation by (*)NO/O(2) and (*)NO/O(2)(*)(-) occurred with relative efficiencies comparable to those in solution. Our results indicate that concerted generation of (*)NO and O(2)(*)(-) may essentially contribute to nitrosative stress in inflammatory diseases.     

蜂蛹多肽对巨噬细胞RAW264.7免疫活性的影响

蜂蛹多肽因具有丰富的营养价值,以及增强免疫、抗肿瘤及抗氧化等生物学活性,而受到了广泛关注,但目前关于蜂蛹多肽纯化组分的体外免疫调节活性的研究尚未见报道。为了探究蜂蛹多肽对巨噬细胞RAW264.7免疫活性的影响,以蜂蛹多肽纯化组分BPP-21为研究对象,研究其在不同浓度（12.5、25、50、100和200 μg·mL-1）下对RAW264.7巨噬细胞的细胞活力、吞噬能力、细胞因子分泌能力、NO分泌能力和氧化应激指标的影响。结果显示,在浓度12.5~200 μg·mL-1范围内,BPP-21对RAW264.7巨噬细胞无明显的细胞毒性作用,可显著提高干扰素-γ（interferon-gamma,IFN-γ）与NO的分泌水平（P<0.05）;在浓度25~200 μg·mL-1范围内,显著增加细胞吞噬能力以及白细胞介素-2（interleukin-2,IL-2）、肿瘤坏死因子α（tumor necrosis factor-alpha,TNF-α）的分泌量（P<0.05）;在浓度50~200 μg·mL-1范围内,显著提高细胞内超氧化物歧化酶（superoxide dismutase,SOD）活力（P<0.05）。研究表明,蜂蛹多肽纯化组分BPP-21可增强RAW264.7巨噬细胞的免疫活性,为蜂蛹多肽免疫调节剂的研究与开发提供了理论依据。     

Overexpression of protein kinase C isoforms protects RAW 264.7 macrophages from nitric oxide-induced apoptosis: involvement of c-Jun N-terminal kinase/stress-activated protein kinase, p38 kinase, and CPP-32 protease pathways

Nitric oxide (NO) induces apoptotic cell death in murine RAW 264.7 macrophages. To elucidate the inhibitory effects of protein kinase C (PKC) on NO-induced apoptosis, we generated clones of RAW 264.7 cells that overexpress one of the PKC isoforms and explored the possible interactions between PKC and three structurally related mitogen-activated protein (MAP) kinases in NO actions. Treatment of RAW 264.7 cells with sodium nitroprusside (SNP), a NO-generating agent, activated both c-Jun N-terminal kinase/stress-activated protein kinase (JNK/SAPK) and p38 kinase, but did not activate extracellular signal-regulated kinase (ERK)-1 and ERK-2. In addition, SNP-induced apoptosis was slightly blocked by the selective p38 kinase inhibitor (SB203580) but not by the MAP/ERK1 kinase inhibitor (PD098059). PKC transfectants (PKC-beta II, -delta, and -eta) showed substantial protection from cell death induced by the exposure to NO donors such as SNP and S-nitrosoglutathione (GSNO). In contrast, in RAW 264.7 parent or in empty vector-transformed cells, these NO donors induced internucleosomal DNA cleavage. Moreover, overexpression of PKC isoforms significantly suppressed SNP-induced JNK/SAPK and p38 kinase activation, but did not affect ERK-1 and -2. We also explored the involvement of CPP32-like protease in the NO-induced apoptosis. Inhibition of CPP32-like protease prevented apoptosis in RAW 264.7 parent cells. In addition, SNP dramatically activated CPP32 in the parent or in empty vector-transformed cells, while slightly activated CPP32 in PKC transfectants. Therefore, we conclude that PKC protects NO-induced apoptotic cell death, presumably nullifying the NO-mediated activation of JNK/SAPK, p38 kinase, and CPP32-like protease in RAW 264.7 macrophages.     

Catalase modifies yeast Saccharomyces cerevisiae response towards S-nitrosoglutathione-induced stress

Abstract

Nitric oxide is known to be a messenger in animals and plants. Catalase may regulate the concentration of intracellular ^?NO. In this study, yeast Saccharomyces cerevisiae cells were treated with 1–20 mM S-nitrosoglutathione (GSNO), a nitric oxide donor, which decreased yeast survival in a concentration-dependent manner. In the wild-type strain (YPH250), 20 mM GSNO reduced survival by 32%. The strain defective in peroxisomal catalase behaved like the wild-type strain, while a mutant defective in cytosolic catalase showed 10% lower survival. Surprisingly, survival of the double catalase mutant was significantly higher than that of the other strains used. Incubation of yeast with GSNO increased the activities of both superoxide dismutase (SOD) and catalase. Pre-incubation with cycloheximide prevented the activation of catalase, but not SOD. The concentrations of oxidized glutathione increased in the wild-type strain, as well as in the mutants defective in peroxisomal catalase and an acatalasaemic strain; it failed to do this in the mutant defective in cytosolic catalase. The activity of aconitase was reduced after GSNO treatment in all strains studied, except for the mutant defective in peroxisomal catalase. The content of protein carbonyls and activities of glutathione reductase and S-nitrosoglutathione reductase were unchanged following GSNO treatment. The increase in catalase activity due to incubation with GSNO was not found in a strain defective in Yap1p, a master regulator of yeast adaptive response to oxidative stress. The obtained data demonstrate that exposure of yeast cells to the ^?NO-donor S-nitrosoglutathione induced mild oxidative/nitrosative stress and Yap1p may co-ordinate the up-regulation of antioxidant enzymes under these conditions.     

Redox and nitric oxide homeostasis are affected in tomato (Solanum lycopersicum) roots under salinity-induced oxidative stress

The nicotinamide adenine dinucleotide phosphate (NADPH) and reduced glutathione (GSH) molecules play important roles in the redox homeostasis of plant cells. Using tomato (Solanum lycopersicum) plants grown with 120 mM NaCl, we studied the redox state of NADPH and GSH as well as ascorbate, nitric oxide (NO) and S-nitrosoglutathione (GSNO) content and the activity of the principal enzymes involved in the metabolism of these molecules in roots. Salinity caused a significant reduction in growth parameters and an increase in oxidative parameters such as lipid peroxidation and protein oxidation. Salinity also led to an overall decrease in the content of these redox molecules and in the enzymatic activities of the main NADPH-generating dehydrogenases, S-nitrosoglutathione reductase and catalase. However, NO content as well as gluthahione reductase and glutathione peroxidase activity increased under salinity stress. These findings indicate that salinity drastically affects redox and NO homeostasis in tomato roots. In our view, these molecules, which show the interaction between ROS and RNS metabolisms, could be excellent parameters for evaluating the physiological conditions of plants under adverse stress conditions.     

Thioredoxin-mimetic peptides as catalysts of S-denitrosylation and anti-nitrosative stress agents

S-nitrosylation, the coupling of a nitric oxide moiety to a reactive cysteine residue to form an S-nitrosothiol (SNO), is an important posttranslational mechanism for regulating protein activity. Growing evidence indicates that hyper-S-nitrosylation may contribute to cellular dysfunction associated with various human diseases. It is also increasingly appreciated that thioredoxin and thioredoxin reductase play significant roles in the cellular catabolism of SNO and protection from nitrosative stress. Here, we investigated the SNO reductase activity and protective effects of thioredoxin-mimetic peptides (TXMs), Ac-Cys-Pro-Cys-amide (CB3) and Ac-Cys-Gly-Pro-Cys-amide (CB4), both under cell-free conditions and in nitrosatively stressed cultured cells. In vitro biochemical analyses revealed that the TXM peptides reduced small-molecule SNO compounds, such as S-nitrosoglutathione (GSNO), and acted as general and efficient protein-denitrosylating agents. In particular, CB3 was found to be a highly potent SNO-metabolizing agent. Notably, CB3 mimicked the activity of thioredoxin by coupling with thioredoxin reductase to enhance GSNO reduction. Moreover, in a cell-free lysate system, both CB3 and CB4 synergized with an NADPH-dependent activity to denitrosylate proteins. Further investigation revealed that the TXM peptides protect the peroxiredoxin–thioredoxin system from SNO-dependent inhibition. Indeed, SNO-inhibited Prx1 was efficiently denitrosylated and reactivated by CB3 or CB4. In addition, CB3 protected thioredoxin reductase from SNO-mediated inactivation both in vitro and in intact cells. Finally, CB3 and CB4 partially rescued human neuroblastoma SH-SY5Y cells and rat insulinoma INS-1 832/13 cells from GSNO-induced growth inhibition. Collectively, the present findings indicate the efficient denitrosylation activity and protective effects of TXM peptides and suggest their potential therapeutic value in treating pathological conditions related to nitrosative stress.     

Mechanical wounding induces a nitrosative stress by down-regulation of GSNO reductase and an increase in S-nitrosothiols in sunflower (Helianthus annuus) seedlings

Nitric oxide (NO) and related molecules such as peroxynitrite, S-nitrosoglutathione (GSNO), and nitrotyrosine, among others, are involved in physiological processes as well in the mechanisms of response to stress conditions. In sunflower seedlings exposed to five different adverse environmental conditions (low temperature, mechanical wounding, high light intensity, continuous light, and continuous darkness), key components of the metabolism of reactive nitrogen species (RNS) and reactive oxygen species (ROS), including the enzyme activities L-arginine-dependent nitric oxide synthase (NOS), S-nitrosogluthathione reductase (GSNOR), nitrate reductase (NR), catalase, and superoxide dismutase, the content of lipid hydroperoxide, hydrogen peroxide, S-nitrosothiols (SNOs), the cellular level of NO, GSNO, and GSNOR, and protein tyrosine nitration [nitrotyrosine (NO(2)-Tyr)] were analysed. Among the stress conditions studied, mechanical wounding was the only one that caused a down-regulation of NOS and GSNOR activities, which in turn provoked an accumulation of SNOs. The analyses of the cellular content of NO, GSNO, GSNOR, and NO(2)-Tyr by confocal laser scanning microscopy confirmed these biochemical data. Therefore, it is proposed that mechanical wounding triggers the accumulation of SNOs, specifically GSNO, due to a down-regulation of GSNOR activity, while NO(2)-Tyr increases. Consequently a process of nitrosative stress is induced in sunflower seedlings and SNOs constitute a new wound signal in plants.     

The response of Paracoccidioides spp. to nitrosative stress

Paracoccidioidomycosis (PCM) is an endemic disease in Latin America caused by species belonging to the genus Paracoccidioides. During infection, immune cells present a variety of defense mechanisms against pathogens. One of these defensive strategies is the production and release of nitric oxide (NO) and S-nitroso thiols (e.g., S-nitrosoglutathione, GSNO), which produce reactive nitrogen species (RNS). This results in damage to DNA and membranes, inhibition of respiration and inactivation of cellular enzymes. In response to nitrosative stress, human pathogenic fungi possess defense mechanisms to prevent the adverse effects of NO, which helps them survive during initial contact with the host immune system. To understand how Paracoccidioides spp. respond to nitrosative stress, we conducted this study to identify genes and proteins that might contribute to this response. The results of proteomic analysis demonstrated that nitrosative stress induced a reduction in the expression of proteins related to the mitochondrial electron transport chain. This hypothesis was supported by the reduced mitochondrial activity observed in the presence of GSNO. Additionally, lipids and branched chain amino acid metabolism enzymes were altered. The role played by enzymes acting in oxidative stress in the RNS response was remarkable. This interface among enzymes acting in both stress responses was confirmed by using a RNA approach to silence the ccp gene in Paracoccidioides. It was observed that mutants with low expression of the ccp gene were more sensitive to nitrosative stress.