KCa3.1 upregulation preserves endothelium‐dependent vasorelaxation during aging and oxidative stress

Endothelial oxidative stress develops with aging and reactive oxygen species impair endothelium‐dependent relaxation (EDR) by decreasing nitric oxide (NO) availability. Endothelial K_Ca3.1, which contributes to EDR, is upregulated by H₂O₂. We investigated whether K_Ca3.1 upregulation compensates for diminished EDR to NO during aging‐related oxidative stress. Previous studies identified that the levels of ceramide synthase 5 (CerS5), sphingosine, and sphingosine 1‐phosphate were increased in aged wild‐type and CerS2 mice. In primary mouse aortic endothelial cells (MAECs) from aged wild‐type and CerS2 null mice, superoxide dismutase (SOD) was upregulated, and catalase and glutathione peroxidase 1 (GPX1) were downregulated, when compared to MAECs from young and age‐matched wild‐type mice. Increased H₂O₂ levels induced Fyn and extracellular signal‐regulated kinases (ERKs) phosphorylation and K_Ca3.1 upregulation. Catalase/GPX1 double knockout (catalase^?/?/GPX1^?/?) upregulated K_Ca3.1 in MAECs. NO production was decreased in aged wild‐type, CerS2 null, and catalase^?/?/GPX1^?/? MAECs. However, K_Ca3.1 activation‐induced, N^G‐nitro‐l ‐arginine‐, and indomethacin‐resistant EDR was increased without a change in acetylcholine‐induced EDR in aortic rings from aged wild‐type, CerS2 null, and catalase^?/?/GPX1^?/? mice. CerS5 transfection or exogenous application of sphingosine or sphingosine 1‐phosphate induced similar changes in levels of the antioxidant enzymes and upregulated K_Ca3.1. Our findings suggest that, during aging‐related oxidative stress, SOD upregulation and downregulation of catalase and GPX1, which occur upon altering the sphingolipid composition or acyl chain length, generate H₂O₂ and thereby upregulate K_Ca3.1 expression and function via a H₂O₂/Fyn‐mediated pathway. Altogether, enhanced K_Ca3.1 activity may compensate for decreased NO signaling during vascular aging.     

Erythrocyte antioxidant enzymes in multiple sclerosis and the effect of hyperbaric oxygen

The activities of catalase, glutathione peroxidase, and glutathione reductase, were not significantly different from normal whereas that of superoxide dismutase was decreased (P<0.05) in erythrocytes from patients with multiple sclerosis. Assay of the lipid peroxidation product, malondialdehyde, after incubation of erythrocytes with 10 mM H₂O₂ under carefully controlled conditions (peroxide stress test) demonstrated that MS erythrocytes are significantly (P<0.001) less susceptible to H₂O₂-induced lipid peroxidation in vitro. This finding suggests that the level of an endogenous antioxidant, possibly vitamin E, may be elevated in MS red cells. After treatment with hyperbaric O₂, the activity of MS erythrocyte catalase is significantly (P<0.01) elevated by 2–6-fold.     

Differential expression and anti-oxidant function of glutathione peroxidase 3 in mouse uterus during decidualization

Glutathione peroxidase 3 (GPX3) is an important member of antioxidant enzymes for reducing reactive oxygen species and maintaining the oxygen balance. Gpx3 mRNA is strongly expressed in decidual cells from days 5 to 8 of pregnancy. After pregnant mice are treated with GPX inhibitor for 3 days, pregnancy rate is significantly reduced. Progesterone stimulates Gpx3 expression through PR/HIF1α in mouse endometrial stromal cells. In the decidua, the high level of GPX3 expression is closely associated with the reduction of hydrogen peroxide (H₂O₂). Based on our data, GPX3 may play a major role in reducing H₂O₂ during decidualization.     

An imbalance in antioxidant defense affects cellular function: the pathophysiological consequences of a reduction in antioxidant defense in the glutathione peroxidase-1 (Gpx1) knockout mouse

Abstract

Aerobic cells are subjected to damaging reactive oxygen species (ROS) as a consequence of oxidative metabolism and/or exposure to environmental toxins. Antioxidants limit this damage, yet peroxidative events occur when oxidant stress increases. This arises due to increased radical formation or decreased antioxidative defenses. The two-step enzymatic antioxidant pathway limits damage to important biomolecules by neutralising superoxides to water. However, an imbalance in this pathway (increased first-step antioxidants relative to second-step antioxidants) has been proposed as etiological in numerous pathologies. This review presents evidence that a shift in favor of hydrogen peroxide and/or lipid peroxides has pathophysiological consequences. The involvement of antioxidant genes in the regulation of redox status, and ultimately cellular homeostasis, is explored in murine transgenic and knockout models. The investigations of Sod1 transgenic cell-lines and mice, as well as Gpx1 knockout mice (both models favor H₂O₂ accumulation), are presented. Although in most instances accumulation of H₂O₂ affects cellular function and leads to exacerbated pathology, this is not always the case. This review highlights those instances where, for example, increased Sod1 levels are beneficial, and indicates a role for superoxide radicals in pathogenesis. Studies of Gpx1 knockout mice (an important second-step antioxidant) lead us to conclude that Gpx1 functions as the primary protection against acute oxidative stress, particularly in neuropathological situations such as stroke and cold-induced head trauma, where high levels of ROS occur during reperfusion or in response to injury. In summary, these studies clearly highlight the importance of limiting ROS-induced cellular damage by maintaining a balanced enzymatic antioxidant pathway.     

Peroxiredoxin 2 is upregulated in colorectal cancer and contributes to colorectal cancer cells’ survival by protecting cells from oxidative stress

Peroxiredoxin 2 (Prdx2) is a member of the peroxiredoxin family, which is responsible for neutralizing reactive oxygen species. Prdx2 has been found to be elevated in several human cancer cells and tissues, including colorectal cancer (CRC), and it influences diverse cellular processes involving cells’ survival, proliferation, and apoptosis, which suggests a possible role for Prdx2 in the maintenance of cancer cell. However, the mechanism by which Prdx2 modulates CRC cells’ survival is unknown. The current study aimed to determine the effect of elevated Prdx2 on CRC cells and to further understand the underlying mechanisms. The results of this study showed that Prdx2 was upregulated in CRC tissues compared with the matched noncancer colorectal mucosa tissues and that Prdx2 expression was positively associated with tumor metastasis and the TNM stage. In the LoVo CRC cell line, Prdx2 was upregulated at both the RNA and protein levels compared with the normal FHC colorectal mucosa cell line. In addition, the LoVo CRC cell line was significantly more resistant to hydrogen peroxide (H₂O₂)-induced apoptosis because of a failure to activate pro-apoptotic pathways in contrast to Prdx2 knockdown cells. Suppression of Prdx2 using a lentiviral vector-mediated Prdx2-specific shRNA in the LoVo cell line restored H₂O₂ sensitivity. Our results suggested that Prdx2 has an essential role in regulating oxidation-induced apoptosis in CRC cells. Prdx2 may have potential as a therapeutic target in CRC.     

Decreased catalase activity is the underlying mechanism of oxidant susceptibility in glucose-6-phosphate dehydrogenase-deficient erythrocytes

Historically, it has been theorized that the oxidant sensitivity of glucose-6-phosphate dehydrogenase (G6PD)-deficient erythrocytes arises as a direct consequence of an inability to maintain cellular gluthione (GSH) levels. This study alternatively hypothesizes that decreased NADPH concentration leads to impaired to catalase activity which, in turn, underlies the observed oxidant susceptibility. To investigate this hypothesis, normal and G6PD-deficient erythrocytes and hemolysates were challenged with a H₂O₂-generating agent. The results of this study demonstrated that catalase activity was severely impaired upon H₂O₂ challenge in the G6PD-deficient cell whiel only decrease was observed in normal cells. Supplmentation of either normal or G6PD-deficient hemolysates with purified NADPH was found to significantly (P < 0.001) inhibit catalase inactivation upon oxidant challenge while addition of NADP⁺ had no effect. Analysis of these results demonstrated direct correlation between NADPH concentration and catalase activity (r = 0.881) and an inverse correlation between catalase activity and erythrocyte oxidant sensitivity (r = 0.906). In contrast, no correlation was found to exist between glutathione concentration (r = 0.170) and oxidant sensitivity. Analysis of NADPH/NADPt ration in acatalasemic mouse erythrocytes demonstrated that NADPH maintenance alone was not sufficient to explain oxidant resistance, and that catalase activity was required. This study supports the hypothesis that impaired catalase activity underlies the enhanced oxidant sensitivity of G6PD-deficient erythrocytes and elucidates the importance of NADPH in the maintenance of normal catalase activity.     

Peroxynitrite and hydrogen peroxide elicit similar cellular stress responses mediated by the Ccp1 sensor protein

Peroxynitrite [ONOO(H)] is an oxidant associated with deleterious effects in cells. Because it is an inorganic peroxide that reacts rapidly with peroxidases, we speculated that cells may respond to ONOO(H) and H₂O₂ challenge in a similar manner. We exposed yeast cells to SIN-1, a well-characterized ONOO(H) generator, and observed stimulation of catalase and peroxiredoxin (Prx) activities. Previously, we reported that H₂O₂ challenge increases these activities in wild-type cells and in cells producing the hyperactive mutant H₂O₂ sensor Ccp1^W191F but not in Ccp1-knockout cells (ccp1Δ). We find here that the response of ccp1Δ and ccp1^W191F cells to SIN-1 mirrors that to H₂O₂, identifying Ccp1 as a sensor of both peroxides. SIN-1 simultaneously releases ^•NO and O₂^•−, which react to form ONOO(H), but exposure of the three strains separately to an ^•NO donor (spermine-NONOate) or an O₂^•− generator (paraquat) mainly depresses catalase or Prx activity, whereas co-challenge with the NONOate and paraquat stimulates these activities. Because Ccp1 appears to sense ONOO(H) in cells, we examined its reaction with ONOO(H) in vitro and found that peroxynitrous acid (ONOOH) rapidly (k₂>10⁶ M⁻¹ s⁻¹) oxidizes purified Ccp1 to an intermediate with spectral and ferrocytochrome-oxidizing properties indistinguishable from those of its well-characterized compound I formed with H₂O₂. Importantly, the nitrite released from ONOOH is not oxidized to ^•NO₂ by Ccp1^׳s compound I, unlike peroxidases involved in immune defense. Overall, our results reveal that yeast cells mount a common antioxidant response to ONOO(H) and H₂O₂, with Ccp1 playing a pivotal role as an inorganic peroxide sensor.     

The role of intracellular zinc in H2O2-induced oxidative stress in human erythrocytes

In vitro exposure of human erythrocytes to H₂O₂ at concentrations of 30–1000 μM resulted in a dose-dependent increase of the intracellular levels of Zn²⁺ and inhibition of the cytosolic esterase activity, which is a major marker of erythrocyte viability. The observed effect depended on the concentration of H₂O₂ and the duration of exposure of the cells to this compound. An inverse relationship between the changes in the intracellular level of labile zinc ions and esterase activity in the cells exposed to hydrogen peroxide was detected; this was indicative of the role of Zn²⁺ in the programmed death of red blood cells. The combined action of hydrogen peroxide and N',N'-tetrakis-(2-pyridyl-methyl)-ethylenediamine, an intracellular zinc ion chelator, has been found to eliminate the cytotoxic effect of H₂O₂, whereas the addition of Zn²⁺ to the erythrocyte incubation medium enhanced the effects of hydrogen peroxide. The reduction of the concentration of non-protein thiol groups due to a decrease of the level of reduced glutathione was shown to contribute to the release of Zn²⁺ from the intracellular binding sites during oxidative stress induced by H₂O₂ in human erythrocytes.

     

Peroxiredoxin 2, glutathione peroxidase,and catalase in the cytosol and membrane of erythrocytes under H2O2-induced oxidative stress

Abstract

Erythrocytes are continuously exposed to risk of oxidative injury due to oxidant oxygen species. To prevent damage, they have antioxidant agents namely, catalase (Cat), glutathione peroxidase (GPx), and peroxiredoxin 2 (Prx2). Our aim was to contribute to a better understanding of the interplay between Prx2, Cat, and GPx under H₂O₂-induced oxidative stress, by studying their changes in the red blood cell cytosol and membrane, in different conditions. These three enzymes were quantified by immunoblotting. Malondialdehyde, that is, lipoperoxidation (LPO) in the erythrocyte membrane, and membrane-bound hemoglobin (MBH) were evaluated, as markers of oxidative stress. We also studied the erythrocyte membrane protein profile, to estimate how oxidative stress affects the membrane protein structure. We showed that under increasing H₂O₂ concentrations, inhibition of the three enzymes with or without metHb formation lead to the binding of Prx2 and GPx (but not Cat) to the erythrocyte membrane. Prx2 was detected mainly in its oxidized form and the linkage of metHb to the membrane seems to compete with the binding of Prx2. Catalase played a major role in protecting erythrocytes from high exogenous flux of H₂O₂, since whenever Cat was active there were no significant changes in any of the studied parameters. When only Cat was inhibited, Prx2 and GPx were unable to prevent H₂O₂-induced oxidative stress resulting in increasing MBH and membrane LPO. Additionally, the inhibition of one or more of these enzymes induced changes in the anchor/linker proteins of the junctional complexes of the membrane cytoskeleton–lipid bilayer, which might lead to membrane destabilization.     

The relationship of hydrogen peroxide to the inhibition of the glyoxalase activity of intact erythrocytes by x-radiation

The x-irradiation of a dilute suspension of erythrocytes results in a decrease in the glyoxalase activity of the cells as a result of a fall in the reduced glutathione level. The present paper deals with the possible role of H₂O₂ in this reaction. The addition of intact erythrocytes to physiological saline previously irradiated with 150,000 r or 225,000 r results in a fall in the glyoxalase activity of the cells. The inhibition is prevented by the preincubation of the irradiated saline with catalase and is reversed by the addition of plasma, glucose, adenosine, and inosine to the cell suspension. An inhibition of the glyoxalase activity is also produced by the addition of H₂O₂ to the suspension of erythrocytes. The inhibitory effect of H₂O₂ can be prevented and largely reversed by plasma, glucose, adenosine, and inosine. Methylglyoxal is also protective under these conditions. Hydrogen peroxide formed continuously and in low concentrations by enzyme systems appears to be more effective than added H₂O₂ in inhibiting the glyoxalase system. The inhibition by H₂O₂-producing enzyme systems is minimized by the addition of catalase, plasma, glucose, methylglyoxal, and to a lesser extent, by adenosine and inosine, and is accentuated by the addition of sodium azide. The results are discussed in relation to the role of H₂O₂ and catalase in the toxicity of ionizing radiations.     

NO和H2O2诱导大豆根尖和边缘细胞耐铝反应的作用

 NO和H₂O₂是参与植物抗非生物胁迫反应的重要信号分子, 为了确定NO和H₂O₂在大豆(Glycine max)根尖和根边缘细胞(root border cells, RBCs)耐铝反应中的作用及其相互关系, 以‘浙春3号’大豆为材料, 研究了铝毒胁迫下大豆根尖内源NO和H₂O₂的变化, 以及外源NO和H₂O₂诱导大豆根尖和RBCs的耐铝反应。结果表明, 50 μmol·L^–1 Al处理48 h显著抑制大豆根的伸长, 提高Al在根尖的积累, 同时显著增加根尖内源NO和H₂O₂含量。施加0.25 mmol·L^–1外源NO供体亚硝基铁氰化钠(Na₂[Fe(CN)₅NO]·2H₂O, sodium nitroprusside, SNP)和0.1 mmol·L^–1H₂O₂, 能有效地缓解Al对大豆根伸长的抑制、根尖Al积累和RBCs 的死亡, 该缓解作用可以被0.05 mmol·L^–1 NO清除剂2-(4- 羧基苯)-4,4,5,5- 四甲基咪唑-1- 氧-3- 氧化物, 钾盐(C₁₄H₁₆N₂O₄·K, carboxy-PTIO, cPTIO)和150 U·mL^–1 H₂O₂清除酶(catalase, CAT)逆转。并且外源NO能够显著促进根尖H₂O₂的积累, 而外源H₂O₂对根尖NO的含量无显著影响。这表明NO和H₂O₂是诱导大豆根尖及RBCs耐铝反应的两种信号分子, NO可能通过调控H₂O₂的形成, 进而诱导大豆根尖及RBCs的耐铝反应。     

Hydrogen peroxide metabolism and sensing in human erythrocytes: A validated kinetic model and reappraisal of the role of peroxiredoxin II

Hydrogen peroxide (H₂O₂) metabolism in human erythrocytes has been thoroughly investigated, but unclear points persist. By integrating the available data into a mathematical model that accurately represents the current understanding and comparing computational predictions to observations we sought to (a) identify inconsistencies in present knowledge, (b) propose resolutions, and (c) examine their functional implications. The systematic confrontation of computational predictions with experimental observations of the responses of intact erythrocytes highlighted the following important discrepancy. The high rate constant (10⁷–10⁸ M⁻¹ s⁻¹) for H₂O₂ reduction determined for purified peroxiredoxin II (Prx2) and the high abundance of this protein indicate that under physiological conditions it consumes practically all the H₂O₂. However, this is inconsistent with extensive evidence that Prx2’s contribution to H₂O₂ elimination is comparable to that of catalase. Models modified such that Prx2’s effective peroxidase activity is just 10⁵ M⁻¹ s⁻¹ agree near quantitatively with extensive experimental observations. This low effective activity is probably due to a strong but readily reversible inhibition of Prx2’s peroxidatic activity in intact cells, implying that the main role of Prx2 in human erythrocytes is not to eliminate peroxide substrates. Simulations of the responses to physiological H₂O₂ stimuli highlight that a design combining abundant Prx2 with a low effective peroxidase activity spares NADPH while improving potential signaling properties of the Prx2/thioredoxin/thioredoxin reductase system.     

Reactive Oxygen Species-mediated TRPC6 Protein Activation in Vascular Myocytes,a Mechanism for Vasoconstrictor-regulated Vascular Tone

Both TRPC6 and reactive oxygen species (ROS) play an important role in regulating vascular function. However, their interplay has not been explored. The present study examined whether activation of TRPC6 in vascular smooth muscle cells (VSMCs) by ROS was a physiological mechanism for regulating vascular tone by vasoconstrictors. In A7r5 cells, arginine vasopressin (AVP) evoked a striking Ca²⁺ entry response that was significantly attenuated by either knocking down TRPC6 using siRNA or inhibition of NADPH oxidases with apocynin or diphenyleneiodonium. Inhibition of TRPC6 or ROS production also decreased AVP-stimulated membrane currents. In primary cultured aortic VSMCs, catalase and diphenyleneiodonium significantly suppressed AVP- and angiotensin II-induced whole cell currents and Ca²⁺ entry, respectively. In freshly isolated and endothelium-denuded thoracic aortas, hyperforin (an activator of TRPC6), but not its vehicle, induced dose- and time-dependent constriction in TRPC6 wide type (WT) mice. This response was not observed in TRPC6 knock-out (KO) mice. Consistent with the ex vivo study, hyperforin stimulated a robust Ca²⁺ entry in the aortic VSMCs from WT mice but not from KO mice. Phenylephrine induced a dose-dependent contraction of WT aortic segments, and this response was inhibited by catalase. Moreover, H₂O₂ itself evoked Ca²⁺ influx and inward currents in A7r5 cells, and these responses were significantly attenuated by either inhibition of TRPC6 or blocking vesicle trafficking. H₂O₂ also induced inward currents in primary VSMCs from WT but not from TRPC6 KO mice. Additionally, H₂O₂ stimulated a dose-dependent constriction of the aortas from WT mice but not from the vessels of KO mice. Furthermore, TIRFM showed that H₂O₂ triggered membrane trafficking of TRPC6 in A7r5 cells. These results suggest a new signaling pathway of ROS-TRPC6 in controlling vessel contraction by vasoconstrictors.     

Overexpression of SOD in retina: need for increase in H2O2-detoxifying enzyme in same cellular compartment

In retinitis pigmentosa (RP), various mutations cause rod photoreceptor cell death leading to increased oxygen levels in the outer retina, progressive oxidative damage to cones, and gradual loss of cone cell function. We have been exploring the potential of overexpressing components of the endogenous antioxidant defense system to preserve cone cell function in rd10^+/+ mice, a model of RP. rd10^+/+ mice deficient in superoxide dismutase 1 (SOD1) showed increased levels of superoxide radicals and carbonyl adducts (a marker of oxidative damage) in the retina and more rapid loss of cone function than rd10^+/+ mice with normal levels of SOD1. This suggests that SOD1 is an important component of the antioxidant defense system of cones, but increased expression of SOD1 in rd10^+/+ mice increased oxidative damage and accelerated the loss of cone function. Coexpression of SOD1 with glutathione peroxidase 4 (Gpx4), which like SOD1 is localized in the cytoplasm, but not with catalase targeted to the mitochondria, reduced oxidative damage in the retina and significantly slowed the loss of cone cell function in rd10^+/+ mice. Gene transfer resulting in increased expression of SOD2, but not coexpression of SOD2 and mitochondrial Gpx4, resulted in high levels of H₂O₂ in the retina. These data suggest that to provide benefit in RP, overexpression of an SOD must be combined with expression of a peroxide-detoxifying enzyme in the same cellular compartment.     

Deficiency of mouse mast cell protease 4 mitigates cardiac dysfunctions in mice after myocardium infarction

Mouse mast cell protease-4 (mMCP4) is a chymase that has been implicated in cardiovascular diseases, including myocardial infarction (MI). This study tested a direct role of mMCP4 in mouse post-MI cardiac dysfunction and myocardial remodeling. Immunoblot and immunofluorescent double staining demonstrated mMCP4 expression in cardiomyocytes from the infarct zone from mouse heart at 28 day post-MI. At this time point, mMCP4-deficient Mcpt4^?/? mice showed no difference in survival from wild-type (WT) control mice, yet demonstrated smaller infarct size, improved cardiac functions, reduced macrophage content but increased T-cell accumulation in the infarct region compared with those of WT littermates. mMCP4-deficiency also reduced cardiomyocyte apoptosis and expression of TGF-β1, p-Smad2, and p-Smad3 in the infarct region, but did not affect collagen deposition or α-smooth muscle actin expression in the same area. Gelatin gel zymography and immunoblot analysis revealed reduced activities of matrix metalloproteinases and expression of cysteinyl cathepsins in the myocardium, macrophages, and T cells from Mcpt4^?/? mice. Immunoblot analysis also found reduced p-Smad2 and p-Smad3 in the myocardium from Mcpt4^?/? mice, yet fibroblasts from Mcpt4^?/? mice showed comparable levels of p-Smad2 and p-Smad3 to those of WT fibroblasts. Flow cytometry, immunoblot analysis, and immunofluorescent staining demonstrated that mMCP4-deficiency reduced the expression of proapoptotic cathepsins in cardiomyocytes and protected cardiomyocytes from H₂O₂-induced apoptosis. This study established a role of mMCP4 in mouse post-MI dysfunction by regulating myocardial protease expression and cardiomyocyte death without significant impact on myocardial fibrosis or survival post-MI in mice.     

Oxidation of ethanol by hepatic microsomes of acatalasemic mice

Hepatic microsomes of acatalasemic Cs^b mice subjected to heat inactivation displayed decreased catalatic activity but NADPH dependent microsomal ethanol oxidation (MEOS) remained active and unaffected. Even without heat inactivation, in the Cs^b strain, the NADPH dependent metabolism of ethanol was much more active than the H₂O₂ mediated one whereas microsomes of Cs^a control mice displayed equal rates of H₂O₂ and NADPH dependent ethanol oxidation. Addition of catalase to liver microsomes in vitro abolished this difference whereas the catalase inhibitor azide established in the Cs^a mice a pattern similar to that of the Cs^b, namely a much more active NADPH dependent than a H₂O₂ mediated ethanol oxidation. The selective persistence in the Cs^b mice of NADPH dependent ethanol oxidation contrasting with the reduction in the H₂O₂ mediated metabolism of ethanol supports the existence of a microsomal ethanol oxidizing system independent of catalase.     

Macrophage-mediated cytolysis of erythrocytes in the guinea pig. II. Role of oxidative burst products in macrophage cytotoxicity activated by lectins and phorbol ester derivatives

Guinea pig peritoneal macrophages (GPPM) exhibited enhanced production of O₂^? and H₂O₂, and cytolytic activity toward erythrocytes, in response to reagents such as 12-O-tetradecanoyl-phorbol-13-acetate (TPA), its methylated derivative 4-O-MeTPA, Con A, wheat germ agglutinin (WGA), and opsonized zymosan. In order to examine the possible role of oxidative burst products such as O₂^? and H₂O₂ in the cytolytic process, we used reagents and enzymes which influence the balance of O₂^? and H₂O₂ outside and inside the GPPM cells. Macrophage-mediated cytolysis (MMC) of erythrocytes in the presence of the activators and modulators was assessed by ⁵¹Cr release assay. MMC activated by TPA and 4-O-MeTPA was inhibited by scavengers of H₂O₂ such as catalase and α-tocopherol, and was augmented by the catalase inhibitor 3-amino-1,2,4-triazole, and by horseradish peroxidase. TPA- and 4-O-MeTPA-activated MMC was only partially inhibited by the O₂^? scavenger cytochrome c and the enzyme superoxide dismutase and unaffected by cytochalasin D (an inhibitor of phagocytosis). MMC activated by the lectins Con A and WGA was unaffected by the scavengers and enzymes used, but markedly inhibited by cytochalasin D. Activation of MMC by TPA, WGA, and phagocytosis of opsonized zymosan, as well as O₂^? and H₂O₂ generation triggered by these reagents, were markedly inhibited by chlorpromazine. The results indicate that GPPM-mediated cytolysis activated by lectins, phorbol ester derivatives, and phagocytosis of opsonized zymosan, is dependent on the generation of oxidative burst products, mainly H₂O₂. TPA- or 4-O-MeTPA-activated MMC is mainly an extracellular event, while lectin-activated MMC may take place within the macrophages.     

Exogenous hydrogen peroxide can enhance tolerance of wheat seedlings to salt stress

Hydrogen peroxide (H₂O₂), an active oxygen species, is widely generated in many biological systems and mediates various physiological and biochemical processes in plants. In this study, we demonstrated that exogenous H₂O₂ was able to improve the tolerance of wheat seedlings to salt stress. Treatments with exogenous H₂O₂ for 2 days significantly enhanced salt stress tolerance in wheat seedlings by decreasing the concentration of malondialdehyde (MDA), the production rate of superoxide radical (O₂ ⁻), and increasing the activities of superoxide dismutase (SOD), peroxidase (POD), catalase (CAT) and ascorbate peroxidase (APX), and the concentration of glutathione (GSH) and carotenoids (CAR). To further clarify the role of H₂O₂ in preventing salt stress damage, CAT and ascorbate (AsA), the specific H₂O₂ scavengers, were used. The promoting effect of exogenous H₂O₂ on salt stress could be reversed by the addition of CAT and AsA. It was suggested that exogenous H₂O₂ induced changes in MDA, O₂ ⁻, antioxidant enzymes and antioxidant compounds were responsible for the increase in salt stress tolerance observed in the experiments. Therefore, H₂O₂ may participate in antioxidant enzymes and antioxidant compounds induced tolerance of wheat seedlings to salt stress. The results also showed that exogenous H₂O₂ had a positive physiological effect on the growth and development of salt-stressed seedlings.