H2 O2 -induced microvessel barrier dysfunction: the interplay between reactive oxygen species, nitric oxide, and peroxynitrite

Elevated H2 O2 is implicated in many cardiovascular diseases. We previously demonstrated that H2 O2 -induced endothelial nitric oxide synthase (eNOS) activation and excessive NO production contribute to vascular cell injury and increases in microvessel permeability. However, the mechanisms of excessive NO-mediated vascular injury and hyperpermeability remain unknown. This study aims to examine the functional role of NO-derived peroxynitrite (ONOO- ) in H2 O2 -induced vascular barrier dysfunction by elucidating the interrelationships between H2 O2 -induced NO, superoxide, ONOO- , and changes in endothelial [Ca2+ ]i and microvessel permeability. Experiments were conducted on intact rat mesenteric venules. Microvessel permeability was determined by measuring hydraulic conductivity (Lp). Endothelial [Ca2+ ]i , NO, and O2- were assessed with fluorescence imaging. Perfusion of vessels with H2 O2 (10 µmol/L) induced marked productions of NO and O2- , resulting in extensive protein tyrosine nitration, a biomarker of ONOO- . The formation of ONOO- was abolished by inhibition of NOS with NG -Methyl-L-arginine. Blocking NO production or scavenging ONOO- by uric acid prevented H2 O2 -induced increases in endothelial [Ca2+ ]i and Lp. Additionally, the application of exogenous ONOO- to microvessels induced delayed and progressive increases in endothelial [Ca2+ ]i and microvessel Lp, a pattern similar to that observed in H2 O2 -perfused vessels. Importantly, ONOO- caused further activation of eNOS with amplified NO production. We conclude that the augmentation of NO-derived ONOO- is essential for H2 O2 -induced endothelial Ca2+ overload and progressively increased microvessel permeability, which is achieved by self-promoted amplifications of NO-dependent signaling cascades. This novel mechanism provides new insight into the reactive oxygen and/or reactive nitrogen species-mediated vascular dysfunction in cardiovascular diseases.

Phenelzine reduces the oxidative damage induced by peroxynitrite in plasma lipids and proteins

Peroxynitrite is a reactive nitrogen species produced in the intravascular compartment from superoxide anion and nitric oxide. Peroxynitrite destroys blood plasma proteins and membranes of red blood cells and of platelets. This explains why excessive production of peroxynitrite contributes to diseases and to ageing. Therapeutics that antagonize peroxynitrite may delay ageing and the progression of disease. We developed an in vitro assay that allows the investigation of the oxidative damage caused by peroxynitrite in the intravascular compartment. This assay correlates the damage with the rate of formation of protein carbonyl groups, 3-nitrotyrosine (3-NT) and thiobarbituric acid reactive substances. Using this assay, we evaluated the ability of phenelzine, a scavenger of reactive aldehydes, to antagonize the effects of peroxynitrite. Herein, we showed that phenelzine significantly decreased the lipid peroxidative damage caused by peroxynitirite in blood plasma and platelets. Moreover, it inhibited carbonyl group and 3-NT formation in blood plasma and platelet proteins.

Arctic ground squirrel resist peroxynitrite-mediated cell death in response to oxygen glucose deprivation

Cerebral ischemia-reperfusion (I/R) injury initiates a cascade of events, generating nitric oxide (NO) and superoxide(O₂^•-) to form peroxynitrite (ONOO^-), a potent oxidant. Arctic ground squirrels (AGS; Urocitellus parryii) show high tolerance to I/R injury. However, the underlying mechanism remains elusive. We hypothesize that tolerance to I/R modeled in an acute hippocampal slice preparation in AGS is modulated by reduced oxidative and nitrative stress. Hippocampal slices (400µm) from rat and AGS were subjected to oxygen glucose deprivation (OGD) using a novel microperfusion technique. Slices were exposed to NO, O₂^.- donors with and without OGD; pretreatment with inhibitors of NO, O₂^.- and ONOO^- followed by OGD. Perfusates collected every 15min were analyzed for LDH release, a marker of cell death. 3-nitrotyrosine (3NT) and 4-hydroxynonenal (4HNE) were measured to assess oxidative and nitrative stress. Results show that NO/O₂^.- alone is not sufficient to cause ischemic-like cell death, but with OGD enhances cell death more in rat than in AGS. A NOS inhibitor, SOD mimetic and ONOO^- inhibitor attenuates OGD injury in rat but has no effect in AGS. Rats also show a higher level of 3NT and 4HNE with OGD than AGS suggesting the greater level of injury in rat is via formation of ONOO^-.

Yunnaneic Acid B, a Component of Pulmonaria officinalis Extract, Prevents Peroxynitrite-Induced Oxidative Stress in Vitro

Our work reveals that the aerial parts of Pulmonaria officinalis L. are a new source of yunnaneic acid B. We studied antioxidant activity and cytotoxicity of this compound (1-50 μg/mL) and its contents in various plant extracts. This is the first study confirming the presence of yunnaneic acid B in P. officinalis L. and Pulmonaria obscura Dumort and hence in the Boraginaceae family. Determination of 1,1-diphenyl-2-picrylhydrazyl radical reduction and peroxynitrite-scavenging efficacy in inorganic experimental systems provided EC₅₀ values of 7.14 and 50.45 μg/mL, respectively. Then we examined the antioxidant action of yunnaneic acid B in blood plasma under peroxynitrite-induced oxidative stress in vitro. Yunnaneic acid B effectively diminished oxidative damage to blood plasma proteins and lipids. Furthermore, it was able to prevent the peroxynitrite-induced decrease in nonenzymatic antioxidant capacity of blood plasma. Additionally, cytotoxicity of yunnaneic acid B (at concentrations ≤50 μg/mL) toward peripheral blood mononuclear cells was excluded.

Caveolin-1 protects against hepatic ischemia/reperfusion injury through ameliorating peroxynitrite-mediated cell death

Nitrative stress is considered as an important pathological process of hepatic ischemia and reperfusion injury but its regulating mechanisms are largely unknown. In this study, we tested the hypothesis that caveolin-1 (Cav-1), a plasma membrane scaffolding protein, could be an important cellular signaling against hepatic I/R injury through inhibiting peroxynitrite (ONOO(-))-induced cellular damage. Male wild-type mice and Cav-1 knockout (Cav-1(-/-)) were subjected to 1h hepatic ischemia following 1, 6 and 12h of reperfusion by clipping and releasing portal vessels respectively. Immortalized human hepatocyte cell line (L02) was subjected to 1h hypoxia and 6h reoxygenation and treated with Cav-1 scaffolding domain peptide. The major discoveries included: (1) the expression of Cav-1 in serum and liver tissues of wild-type mice was time-dependently elevated during hepatic ischemia-reperfusion injury. (2) Cav-1 scaffolding domain peptide treatment inhibited cleaved caspase-3 expression in the hypoxia-reoxygenated L02 cells; (3) Cav-1 knockout (Cav-1(-/-)) mice had significantly higher levels of serum transaminases (ALT&AST) and TNF-α, and higher rates of apoptotic cell death in liver tissues than wild-type mice after subjected to 1h hepatic ischemia and 6hour reperfusion; (4) Cav-1(-/-) mice revealed higher expression levels of iNOS, ONOO(-) and 3-nitrotyrosine (3-NT) in the liver than wild-type mice, and Fe-TMPyP, a representative peroxynitrite decomposition catalyst (PDC), remarkably reduced level of ONOO(-) and 3-NT and ameliorated the serum ALT, AST and TNF-α levels in both wild-type and Cav-1(-/-) mice. Taken together, we conclude that Cav-1 could play a critical role in preventing nitrative stress-induced liver damage during hepatic ischemia-reperfusion injury.

Modification of HSP proteins and Ca2+ are responsible for the NO-derived peroxynitrite mediated neurological damage in PC12 cell

Peroxynitrite as one crucial metabolite of NO-derived agents has been well multi-investigated to inspect its potential role and sought to define its concrete mechanism underlying the memory loss and impaired cognition involved in pathological processes. In this investigation, the cell viability was assessed by the MTT assay. The neurotoxicity of peroxynitrite was analyzed by using immunohistochemical measurements in cultured PC12 cells to explore the underlying mechanisms. The generation of ROS was evaluated by a fluorometry assay by a fluorometry assay. Apoptosis was assayed by annexin V-FITC and PI staining with flow cytometry. [Ca2+]i was examined by using the microspectrofluorometer. Hsp70 was detected by western blot assay. The results revealed that PC12 cells were inhibited by peroxynitrite both in a dose-dependent and time-dependent manner. The level of ROS in PC12 cells exposed to SIN-1 was increased in a dose-dependent manner. The result indicated that the SIN-1 induced apoptosis of PC12 cells in a dose-dependent manner. Quercetin inhibited the viability of PC12 cells in a concentration-dependent manner. [Ca2+]i was increased gradually when cells treated with quercetin alone and also increased with treatment of dantrolene-containing. Hsp70 was significantly decreased in SIN-1-treated group compared with that of control group (P<0.01). In conclusion, Ca2+ homeostasis and chaperone Hsp70 were critically involved in peroxynitrite induced nitrosative stress as protective. Peroxynitrite acts as the pathological agent in learning and memory defects in CNS disorders associated with challenge.

Myoglobin functions in the heart

The physiological role of myoglobin (Mb) within the heart depends on its oxygenation state. The myocardium exhibits a broad oxygen partial pressure (pO2) spectrum with a transmural gradient from the epicardial to the subendocardial layer, ranging from arterial values to an average of 19.3 mm Hg down to 0 mm Hg. The function of Mb as an O2 storage depot is well appreciated, especially during systolic compression. In addition, Mb controls myocardial nitric oxide (NO) homeostasis and thus modulates mitochondrial respiration under physiological and pathological conditions. We recently discovered the role of Mb as a myocardial O2 sensor; in its oxygenated state Mb scavenges NO, protecting the heart from the deleterious effects of excessive NO. Under hypoxia, however, deoxygenated Mb changes its role from an NO scavenger to an NO producer. The NO produced protects the cell from short phases of hypoxia and from myocardial ischemia/reperfusion injury. In this review we summarize the traditional and novel aspects of Mb and its (patho)physiological role in the heart.

Inhibition of UDP/P2Y6 purinergic signaling prevents phagocytosis of viable neurons by activated microglia in vitro and in vivo

Microglia activated through Toll-like receptor (TLR)-2 or -4 can cause neuronal death by phagocytosing otherwise-viable neurons—a form of cell death called “phagoptosis.” UDP release from neurons has been shown to provoke microglial phagocytosis of neurons via microglial P2Y₆ receptors, but whether inhibition of this process affects neuronal survival is unknown. We tested here whether inhibition of P2Y₆ signaling could prevent neuronal death in inflammatory conditions, and whether UDP signaling can induce phagoptosis of stressed but viable neurons. We find that delayed neuronal loss and death in mixed neuronal/glial cultures induced by the TLR ligands lipopolysaccharide (LPS) or lipoteichoic acid was prevented by: apyrase (to degrade nucleotides), Reactive Blue 2 (to inhibit purinergic signaling), or MRS2578 (to specifically block P2Y₆ receptors). In each case, inflammatory activation of microglia was not affected, and the rescued neurons remained viable for at least 7 days. Blocking P2Y₆ receptors with MRS2578 also prevented phagoptosis of neurons induced by 250 nM amyloid beta 1–42, 5 μM peroxynitrite, or 50 μM 3-morpholinosydnonimine (which releases reactive oxygen and nitrogen species). Furthermore, the P2Y₆ receptor agonist UDP by itself was sufficient to stimulate microglial phagocytosis and to induce rapid neuronal loss that was prevented by eliminating microglia or inhibiting phagocytosis. In vivo, injection of LPS into rat striatum induced microglial activation and delayed neuronal loss and blocking P2Y₆ receptors with MRS2578 prevented this neuronal loss. Thus, blocking UDP/P2Y₆ signaling is sufficient to prevent neuronal loss and death induced by a wide range of stimuli that activate microglial phagocytosis of neurons.

Aged garlic extract inhibits peroxynitrite-induced hemolysis

Nitric oxide (NO), which is synthesized by constitutive NO synthase (cNOS), plays important roles in physiological functions of the cardiovascular system. However, NO, which is synthesized by inducible NOS, is detrimental when it reacts with superoxide to form peroxynitrite. Peroxynitrite is recognized as a powerful oxidant, and results in vascular or tissue damage. We have previously reported that aged garlic extract (AGE) enhances NO production through cNOS stimulation. In the present study, we determined the effect of AGE, its fractions or constituents on peroxynitrite-induced hemolysis using rat erythrocytes. Incubation of rat erythrocytes with peroxynitrite (300 microM) for 30 min at 37 degrees C caused 4-fold hemolysis. AGE (0.14-0.57 %w/v) added to an erythrocyte suspension was found to reduce peroxynitrite-induced hemolysis in a concentration-dependent manner. Of the AGE fractions, a polar fraction and a low-molecular-weight fraction both suppressed the hemolysis to the same degree as that seen with AGE. S-allylcysteine, one of the major compounds in AGE, also reduced hemolysis at 1-10 mM dose-dependently. These data indicate that AGE and its compounds protect erythrocytes from membrane damage induced by peroxynitrite, suggesting that AGE could be useful for prevention of cardiovascular diseases associated with oxidative stress or dysfunction of NO production.

Myricitrin protects against peroxynitrite-mediated DNA damage and cytotoxicity in astrocytes

Peroxynitrite, a potent oxidising and nitrating species, has been implicated in the pathogenesis of neurodegenerative diseases. This study was undertaken to investigate the protective effect of myricitrin on peroxynitrite-mediated toxicity and the underlying mechanism. Our results showed that the presence of myricitrin was found to significantly inhibit peroxynitrite-mediated DNA damage. EPR spectroscopy demonstrated that myricitrin potently diminished the DMPO-hydroxyl radical adduct signal from peroxynitrite. Further study showed that glutathione (GSH) depletion caused by peroxynitrite can be effectively prevented by pre-incubation of astrocytes with myricitrin. Moreover, co-incubation of astrocytes with myricitrin and buthionine sulfoximine (BSO) eliminated the myricitrin-induced GSH increase. In contrast, co-incubation of myricitrin with BSO slightly protected astrocytes against cytotoxicity and DNA damage mediated by peroxynitrite. These results revealed that myricitrin can protect against peroxynitrite-induced DNA damage and cytotoxicity, which might have implications for myricitrin-mediated neuroprotection.

Role of peroxynitrite in the cardiovascular dysfunction of septic shock

The intense systemic inflammatory response characterizing septic shock is associated with an increased generation of free radicals by multiple cell types in cardiovascular and non cardiovascular tissues. The oxygen-centered radical superoxide anion (O2 .-) rapidly reacts with the nitrogen-centered radical nitric oxide (NO.) to form the potent oxidant species peroxynitrite. Peroxynitrite oxidizes multiple targets molecules, either directly or via the secondary generation of highly reactive radicals, resulting in significant alterations in lipids, proteins and nucleic acids, with significant cytotoxic consequences. The formation of peroxynitrite is a key pathophysiological mechanism contributing to the cardiovascular collapse of septic shock, promoting vascular contractile failure, endothelial and myocardial dysfunction, and is also implicated in the occurrence of multiple organ dysfunction in this setting. The recent development of various porphyrin-based pharmacological compounds accelerating the degradation of peroxynitrite has allowed to specifically address these pathophysiological roles of peroxynitrite in experimental septic shock. Such agents, including 5,10,15,20-tetrakis(4- sulfonatophenyl)porphyrinato iron III chloride (FeTTPs), manganese tetrakis(4-N-methylpyridyl)porphyrin (MnTMPyP), Fe(III) tetrakis-2-(N-triethylene glycol monomethyl ether)pyridyl porphyrin) (FP-15) and WW-85, have been shown to improve the cardiovascular and multiple organ failure in small and large animal models of septic shock. Therefore, these findings support the development of peroxynitrite decomposition catalysts as potentially useful novel therapeutic agents to restore cardiovascular function in sepsis.

Role of oxidative/nitrative stress in hepatic encephalopathy induced by thioacetamide

The study was designed to reveal the pathogenic mechanism of peroxynitrite in hepatic encephalopathy (HE), assess oxidative/nitrative stress in relation to HE induced by thiacetamide (TAA) and provide new ideas and scientific basis for the etiology and treatment of HE. Male Wistar rats were divided into four groups randomly: A (control), B (model), C (ebselen) and D (solvent). All the groups were treated with TAA by intraperitoneal (i.p.) except group A (treated with saline i.p.) to manufacture the model of HE. When rats treated with TAA came to the second stage of HE the four groups were administered intragastrically (i.g.) with saline (A, B), ebselen (C) and dimethyl sulfoxide (DMSO) (D), respectively. Plasma was collected to detect the levels of 3-nitrotyrosine (3-NT), NO, T-SOD and MDA. The results showed that the levels of 3-NT, NO, MDA significantly increased and T-SOD decreased obviously in rats suffering from HE. With the development and progression of HE the extent of oxidative/nitrative stress increased. When treated with ebselen the symptoms of HE mitigated and the levels of biochemical indicators ameliorated significantly. This indicates that oxidative/nitrative stress is involved in the mechanisms of hepatic encephalopathy.

Production of polycyclic aromatic hydrocarbon metabolites from a peroxynitrite/iron(III) porphyrin biomimetic model and their mutagenicities

Some polycyclic aromatic hydrocarbons (PAHs) are typical promutagens that require metabolic activation to exhibit their mutagenicities and carcinogenicities. The metabolites of three PAHs, pyrene (PY), fluoranthene (FLU), and benzo[a]pyrene (BaP), produced from the peroxynitrite/T(p-Cl)PPFeCl(peroxynitrite/(chloride)iron(III)tetrakis(p-chlorophenyl)porphyrin) system, have been identified with high-performance liquid chromatography coupled with electron spray ionization tandem mass spectrometry. The results demonstrated that three major metabolites were the quinone group, OH group, and nitro group. In the Ames test, all three PAH metabolites became mutagenic without using the enzymatic activating system, whereas their parents did not show positive results. Cell transformation assay indicated that 1,3-nitro-BaP and BaP metabolites produced from this biomimetic system have more serious effects in inducing cancer than the BaP parent.

[Surface architectonics and cytoskeleton state of different age rats' thymocytes exposed to peroxynitrite]

To reveal the role of aging in the changes of immune system cells response to proinflammatory (oxidizing) agent we have studied peroxynitrite (30 microM) influence on the cell surface layer structure of different age rats' thymocytes. In the absence of proinflammatory agent, there were no significant changes in morphological and topological parameters of thymocytes from the rats at 3 and 8 months of age. According to atomic force microscopy data, peroxynitrite stimulates actin cytoskeleton structures assembly in thymocytes from 3-month rats but inhibits it in cells from 8-month rats. Obtained results make clear the difference between the immune system responses in inflammatory processes of young and old organisms.

The protective effects of selenoorganic compounds against peroxynitrite-induced changes in plasma proteins and lipids

Many selenoorganic compounds play an important role in biochemical processes and act as antioxidants, enzyme inhibitors or drugs. The effects of a new selenocompound — bis(2-aminophenyl)-diselenide on oxidative/nitrative changes in human plasma proteins induced by peroxynitrite (ONOO⁻) were studied in vitro and compared with the those of ebselen, a well-known antioxidant. We also studied the role of the tested selenocompounds in peroxynitrite-induced plasma lipid peroxidation. Exposure of the plasma to peroxynitrite (0.1 mM) resulted in an increase in the level of carbonyl groups and nitrotyrosine residues in plasma proteins (estimated using the ELISA method and Western blot analysis). In the presence of different concentrations (0.025–0.1 mM) of the tested selenocompounds, 0.1 mM peroxynitrite caused a distinct decrease in the level of carbonyl group formation and tyrosine nitration in plasma proteins. Moreover, these selenocompounds also inhibited plasma lipid peroxidation induced by ONOO⁻¹ (0.1 mM). The obtained results indicate that in vitro bis(2-aminophenyl)-diselenide and ebselen have very similar protective effects against peroxynitrite-induced oxidative/nitrative damage to human plasma proteins and lipids.

Inducible nitric oxide synthase gene deficiency counteracts multiple manifestations of peripheral neuropathy in a streptozotocin-induced mouse model of diabetes

AIMS/HYPOTHESIS

Evidence for the importance of peroxynitrite, a product of superoxide anion radical reaction with nitric oxide, in peripheral diabetic neuropathy is emerging. The role of specific nitric oxide synthase isoforms in diabetes-associated nitrosative stress and nerve fibre dysfunction and degeneration remains unknown. This study evaluated the contribution of inducible nitric oxide synthase (iNOS) to peroxynitrite injury to peripheral nerve and dorsal root ganglia and development of peripheral diabetic neuropathy.

METHODS

Control mice and mice with iNos (also known as Nos2) gene deficiency (iNos ( -/- )) were made diabetic with streptozotocin, and maintained for 6 weeks. Peroxynitrite injury was assessed by nitrotyrosine and poly(ADP-ribose) accumulation (immunohistochemistry). Thermal algesia was evaluated by paw withdrawal, tail-flick and hot plate tests, mechanical algesia by the Randall-Selitto test, and tactile allodynia by a von Frey filament test.

RESULTS

Diabetic wild-type mice displayed peroxynitrite injury in peripheral nerve and dorsal root ganglion neurons. They also developed motor and sensory nerve conduction velocity deficits, thermal and mechanical hypoalgesia, tactile allodynia and approximately 36% loss of intraepidermal nerve fibres. Diabetic iNos ( -/- ) mice did not display nitrotyrosine and poly(ADP-ribose) accumulation in peripheral nerve, but were not protected from nitrosative stress in dorsal root ganglia. Despite this latter circumstance, diabetic iNos ( -/- ) mice preserved normal nerve conduction velocities. Small-fibre sensory neuropathy was also less severe in diabetic iNos ( -/- ) than in wild-type mice.

CONCLUSIONS/INTERPRETATION

iNOS plays a key role in peroxynitrite injury to peripheral nerve, and functional and structural changes of diabetic neuropathy. Nitrosative stress in axons and Schwann cells, rather than dorsal root ganglion neurons, underlies peripheral nerve dysfunction and degeneration.

Peroxynitrite-induced protein nitration contributes to liver mitochondrial damage in diabetic rats

Oxidative stress, especially peroxynitrite (ONOO(-))-mediated oxidative stress, plays a key role in diabetes. Mitochondria, as the generating source of ONOO(-), may also be the major damaging target of ONOO(-), which can cause a series of mitochondrial proteins nitration. Therefore, this study aimed to clarify the relationship between the nitration of entire mitochondrial proteins induced by ONOO(-) and liver mitochondrial structural damage in diabetes. Sprague-Dawley male rats were injected with streptozotocin to induce diabetes. After 10 weeks, transmission electron microscopy was used to observe the ultrastructure of liver mitochondria, and reverse transcription-polymerase chain reaction was used to detect liver inducible nitric oxide synthase (iNOS) mRNA expression. Nitrotyrosine (NT) content and distribution were detected with Western blot analysis and immunohistochemistry. In addition, some biochemical indicators were detected to represent oxidative stress and metabolic disorders. In diabetic rats, increasing levels of iNOS mRNA and NT content (P<.05) were observed, in accord with pathological alterations of the ultrastructure of liver mitochondria. Meanwhile, some alterations in biochemical indicators were observed in diabetes. Treatment with aminoguanidine could significantly attenuate these alterations (P<.01 or P<.05). In conclusion, the nitration of mitochondrial proteins induced by ONOO(-) may be responsible for structural damage to liver mitochondria, and aminoguanidine can reduce ONOO(-) generation and attenuate mitochondrial damage.

Early release of arachidonic acid prevents an otherwise immediate formation of toxic levels of peroxynitrite in astrocytes stimulated with lipopolysaccharide/interferon-γ

Addition of bacterial lipopolysaccharides (LPS) and interferon-gamma (IFN-gamma) to rat astrocytes in primary culture promotes an early release of arachidonic acid (ARA) associated with an immediate inhibition of neuronal nitric oxide synthase (nNOS). Preventing the release of constitutive nitric oxide (NO) is indeed critical for activation of the nuclear factor kappa B, and for the expression of inducible nitric oxide synthase responsible for the formation of large amounts of NO. LPS/IFN-gamma also promotes an early release of superoxide, via activation of NADPH oxidase, but the generation of peroxynitrite (ONOO-) is prevented by the different timing of superoxide (minutes) and NO (hours) formation. Upstream inhibition of the ARA-dependent nNOS inhibitory signaling, however, caused the parallel release of superoxide and constitutive NO, thereby leading to formation of ONOO- levels triggering loss of ATP and mitochondrial membrane potential followed by the mitochondrial release of cytochrome c, activation of caspase 3 and morphological evidence of apoptosis. Nanomolar levels of exogenous ARA prevented all these events via inhibition of early ONOO- formation. Thus, the ARA-dependent nNOS inhibition observed in astrocytes exposed to pro-inflammatory stimuli, as LPS/IFN-gamma, is critical for both the expression of nuclear factor kappa B-dependent genes and for survival.

Contrasting potential of nitric oxide and peroxynitrite to mediate oligodendrocyte injury in multiple sclerosis

Nitric oxide (NO) and peroxynitrite (ONOO(-)) are potential mediators of the injury and cytotoxicity occurring over time to oligodendrocytes in multiple sclerosis (MS) lesions. Our in vitro results indicate that human adult CNS-derived oligodendrocytes are relatively resistant to NO-mediated damage. In contrast, human oligodendrocytes are highly susceptible to peroxynitrite-mediated injury. In situ, we found that inducible nitric oxide synthase (iNOS) was expressed in astrocytes and macrophages in all active demyelinating and remyelinating MS lesions examined, yet no correlation was found between numbers of glial cells expressing iNOS and the extent of oligodendrocyte cell death. Nitrotyrosine groups, indicative of the presence of peroxynitrite in vivo, could be detected on astrocytes, macrophages, and oligodendrocytes in MS lesions. High numbers of nitrotyrosine-positive oligodendrocytes were found in one MS case that featured extensive oligodendrocyte cell death. Our results indicate that NO alone is unlikely to induce oligodendrocyte injury, whereas its more potent byproduct peroxynitrite is a potential mediator of injury to oligodendrocytes in MS.

Champagne wine polyphenols protect primary cortical neurons against peroxynitrite-induced injury

White wines are generally low in polyphenol content as compared to red wines. However, Champagne wines have been shown to contain relatively high amounts of phenolic acids that may exert protective cellular actions in vivo. In this study, we have investigated the potential neuroprotective effects of Champagne wine extracts, and individual phenolics present in these extracts, against peroxynitrite-induced injury. Organic and aqueous Champagne wine extracts exhibited potent neuroprotective activity against peroxynitrite-induced injury at low concentrations (0.1 microg/mL). This protection appeared to be in part due to the cellular actions of individual components found in the organic extracts, notably tyrosol, caffeic acid, and gallic acid. These phenolics were observed to exert potent neuroprotection at concentrations between 0.1 and 10 microM. Together, these data suggest that polyphenols present in Champagne wine may induce a neuroprotective effect against oxidative neuronal injury.

Peroxynitrite is a major trigger of cardiomyocyte apoptosis in vitro and in vivo

Recent evidence indicates that peroxynitrite represents a major cytotoxic effector in heart diseases, but its mechanisms of action are still not known exactly. Notably, the ability of peroxynitrite to trigger cardiomyocyte apoptosis, a crucial mode of cell death in many cardiac conditions, remains poorly defined. We evaluated apoptotic and necrotic cell death in cultured H9C2 cardiomyocytes, following a brief (20 min) exposure to peroxynitrite (50-500 microM). Peroxynitrite-dependent myocardial toxicity was then investigated in a rat model of myocardial ischemia-reperfusion (MIR), where the effects of peroxynitrite were blocked by the superoxide dismutase mimetics and peroxynitrite scavenger Mn(III)-tetrakis(4-benzoic acid) porphyrin (MnTBAP). In vitro, peroxynitrite killed cardiomyocytes mostly through apoptosis (DNA fragmentation, apoptotic nuclear alterations, caspase-3 activation, and PARP cleavage), but not necrosis (propidium iodide staining and LDH release). In vivo, MIR triggered myocardial oxidative stress (malondialdehyde generation), nitrotyrosine formation, neutrophil accumulation, and the cleavage of caspase-3 and PARP, indicating ongoing myocardial apoptosis. MnTBAP suppressed these alterations, allowing a considerable reduction of myocardial injury. Thus, peroxynitrite triggers apoptosis in cardiomyocytes in vitro and in the myocardium in vivo, through a pathway involving caspase-3 activation and the cleavage of PARP. These results provide important novel information on the mechanisms of myocardial toxicity of peroxynitrite.

Effect of lycopene and β-carotene on peroxynitrite-mediated cellular modifications

Peroxynitrite formed by the reaction of superoxide and nitric oxide is a highly reactive species with a role in various pathological processes such as cancer, chronic inflammation, and cardiovascular and neurological diseases. In the present study, the effect of the carotenoids, lycopene and beta-carotene, on peroxynitrite-mediated modifications in plasmid DNA as well as cellular DNA and proteins were investigated. In pUC18 plasmid DNA, these carotenoids strongly inhibited DNA strand breaks caused by peroxynitrite generated from 3-morpholinosydnonimine (SIN-1). SIN-1 was also used to determine effects on DNA damage and protein tyrosine nitration in Chinese hamster lung fibroblasts. SIN-1 dose-dependently increased nitration of proteins in cells above basal levels as determined by Western blotting. This nitration was inhibited in the presence of the uric acid as well as lycopene. Physiological concentrations (0.31-10 microM) of lycopene and beta-carotene also had protective effects on DNA damage, as measured by the comet assay. Lycopene significantly reduced DNA damage particularly, in the median range of concentrations (2.5 microM). The protective effects of lycopene and beta-carotene could be due to their scavenging of reactive oxygen (ROS) and/or nitrogen species (RNS) as they reduce the amount of intracellular ROS/RNS produced following treatment with SIN-1 by as much as 47.5% and 42.4%, respectively. The results obtained in this study suggest that carotenoids may alleviate some of the deleterious effects of peroxynitrite and possibly other reactive nitrogen species as well in vivo.

Glutathione reverses peroxynitrite-mediated deleterious effects of nitroglycerin on ischemic rat hearts

This study examined the potential deleterious effect of high-dose nitroglycerin (NTG) on cardiac function and cellular injury after ischemia (30 min) and reperfusion (120 min) in isolated perfused rat hearts. Low-dose (0.75 microg/h), medium-dose (3.75 microg/h), high-dose (15 microg/h) NTG or high-dose NTG plus glutathione (GSH, 1 mmol/L) was administrated at the time of reperfusion. Administration of high-dose NTG significantly exacerbated cardiac reperfusion injury as evidenced by increased creatine kinase and lactate dehydrogenase activity in coronary effluent, increased cardiomyocyte apoptosis and necrosis, and decreased cardiac function recovery after reperfusion. Compared with the vehicle group, formation of nitrotyrosine, a footprint for peroxynitrite (ONOO) production, was markedly increased in the hearts treated with medium-dose or high-dose NTG. Most interestingly, cotreatment with GSH blocked high-dose NTG-induced ONOO formation and attenuated myocardial ischemia/reperfusion injury. Taken together, our present results demonstrated that administration of high-dose NTG aggravated, rather than attenuated myocardial ischemia/reperfusion injury likely via increasing ONOO formation. Coadministration of GSH may reverse the advert action of high-dose NTG.

Post-treatment with the Ca2+–Mg2+-endonuclease inhibitor aurintricarboxylic acid prevents peroxynitrite-induced DNA damage and death of murine astrocytes

Oxidative stress plays critical roles in aging, cell death, and many diseases. Peroxynitrite is one of the major reactive oxygen species which mediates cell injury in a number of illnesses. It is of importance to identify the downstream events in peroxynitrite-initiated cell death cascade for preventing peroxynitrite toxicity. Ca(2+)-Mg(2+)-endonucleases have been suggested as the endonucleases that execute DNA fragmentation in several apoptotic cascades. In this study, we determined if astrocytes and neurons express the genes of Ca(2+)-Mg(2+)-endonucleases. We also tested our hypothesis that post-treatment with the Ca(2+)-Mg(2+)-endonuclease inhibitor aurintricarboxylic acid can decrease peroxynitrite-induced DNA damage and death of astrocytes. We found that both astrocytes and neurons express DNase I-like endonuclease-a major isoform of Ca(2+)-Mg(2+)-endonucleases. Treatment of astrocytes with aurintricarboxylic acid either before or after peroxynitrite exposures can profoundly decrease peroxynitrite-induced DNA damage and cell death. These results suggest that Ca(2+)-Mg(2+)-endonucleases may be a key downstream component in peroxynitrite-initiated cell death cascade in astrocytes and some other cell types, and aurintricarboxylic acid could be used to decrease peroxynitrite-induced DNA damage at delayed phases.

A mosquito 2-Cys peroxiredoxin protects against nitrosative and oxidative stresses associated with malaria parasite infection

Malaria parasite infection in anopheline mosquitoes induces nitrosative and oxidative stresses that limit parasite development, but also damage mosquito tissues in proximity to the response. Based on these observations, we proposed that cellular defenses in the mosquito may be induced to minimize self-damage. Specifically, we hypothesized that peroxiredoxins (Prxs), enzymes known to detoxify reactive oxygen species (ROS) and reactive nitrogen oxide species (RNOS), protect mosquito cells. We identified an Anopheles stephensi 2-Cys Prx ortholog of Drosophila melanogaster Prx-4783, which protects fly cells against oxidative stresses. To assess function, AsPrx-4783 was overexpressed in D. melanogaster S2 and in A. stephensi (MSQ43) cells and silenced in MSQ43 cells with RNA interference before treatment with various ROS and RNOS. Our data revealed that AsPrx-4783 and DmPrx-4783 differ in host cell protection and that AsPrx-4783 protects A. stephensi cells against stresses that are relevant to malaria parasite infection in vivo, namely nitric oxide (NO), hydrogen peroxide, nitroxyl, and peroxynitrite. Further, AsPrx-4783 expression is induced in the mosquito midgut by parasite infection at times associated with peak nitrosative and oxidative stresses. Hence, whereas the NO-mediated defense response is toxic to both host and parasite, AsPrx-4783 may shift the balance in favor of the mosquito.

Therapeutic action of cannabinoid on axonal injury induced by peroxynitrite

This study examined whether the potent cannabinoid HU210 ameliorates axonal injury through its indirect action to stimulate the secretion of corticosterone. We observed that HU210 dramatically reduced peroxynitrite-induced axonal injury in rats receiving adrenalectomy and corticosterone replacement treatment. These results suggest that the ameliorating effects of cannabinoids on axonal injury associated with multiple sclerosis are achieved by its direct action, but not by its indirect action to elevate the serum corticosterone levels.

Protection of peroxynitrite-induced DNA damage by dietary antioxidants

The present study was undertaken to test the hypothesis that dietary antioxidants protect DNA damage induced by peroxynitrite, a potent physiological inorganic toxin. The present study showed that dietary antioxidants such as (-)-epigallocatechin gallate, quercerin, rutin, resveratrol, and ursolic acid inhibit single strand breaks in supercoiled plasmid DNA induced by 3-morpholinosydnomine N-ethylcarbamide (SIN-1), a generator of peroxynitrite through the reaction between nitric oxide and superoxide anion. The formation of 8-hydroxy-2'-deoxyguanosine (8-OH-dG) in calf thymus DNA by SIN-1 was also inhibited by dietary antioxidants. When U937 cells were incubated with 1 mM SIN-1 bolus, a significant increase of 8-OH-dG level was observed. However, oxidative DNA damage was significantly lower in the cells pre-treated with dietary antioxidants when cells were exposed to SIN-1.

Intracellular zinc release and ERK phosphorylation are required upstream of 12-lipoxygenase activation in peroxynitrite toxicity to mature rat oligodendrocytes

Peroxynitrite toxicity has been implicated in the pathogenesis of white matter injury. The mechanisms of peroxynitrite toxicity to oligodendrocytes (OLs), the major cell type of the white matter, are unknown. Using primary cultures of mature OLs that express myelin basic protein, we found that 3-morpholinosydnonimine, a peroxynitrite generator, caused toxicity to OLs. N,N,N',N'-tetrakis (2-pyridylmethyl)ethylenediamine, a zinc chelator, completely blocked peroxynitrite-induced toxicity. Use of FluoZin-3, a specific fluorescence zinc indicator, demonstrated the liberation of zinc from intracellular stores by peroxynitrite. Peroxynitrite caused the sequential activation of extracellular signal-regulated kinase 42/44 (ERK42/44), 12-lipoxygenase, and generation of reactive oxygen species, which were all dependent upon the intracellular release of zinc. The same cell death pathway was also activated when exogenous zinc was used. These results suggest that in addition to preventing the formation of peroxynitrite, useful strategies in preventing disease progression in pathologies in which peroxynitrite toxicity plays a critical role might include maintaining intracellular zinc homeostasis, blocking phosphorylation of ERK42/44, inhibiting activation of 12-lipoxygenase, and eliminating the accumulation of reactive oxygen species.

Reduced mitochondrial formation of H2O2 is responsible for resistance of dimethyl sulfoxide differentiated U937 cells to peroxynitrite

Previous studies performed in our laboratory indicated that non-toxic concentrations of peroxynitrite nevertheless commit U937 cells to a rapid necrosis that is however prevented by a survival signaling driven by cytosolic phospholipase A(2)-released arachidonic acid. Toxicity was mediated by concentrations of peroxynitrite resulting in H(2)O(2)-dependent inhibition of arachidonic acid release. The present study shows that U937 cells differentiated to monocytes by prolonged exposure to dimethyl sulfoxide are resistant to peroxynitrite because able to respond with enhanced release of arachidonic acid. An additional important observation was that these cells require more arachidonate than the undifferentiated cells to support the survival signaling. The enhanced arachidonic acid release was not associated with changes in cytosolic phospholipase A(2) expression but was rather dependent on the increased responsiveness of the enzyme to calcium-dependent stimulation as well as on reduced mitochondrial formation of H(2)O(2). The latter event was found to be critical, since differentiated and undifferentiated cells were equally sensitive to peroxynitrite when the accumulation of H(2)O(2) was enhanced via depletion of catalase, or addition of a complex III inhibitor. Thus, the strategy selected by the differentiation process to allow monocytes to cope with peroxynitrite appears to involve some specific mechanism preventing the mitochondrial formation of H(2)O(2).

Role of Bcl-2 in the arachidonate-mediated survival signaling preventing mitochondrial permeability transition-dependent U937 cell necrosis induced by peroxynitrite

Antisense technology was successfully employed to selectively reduce the expression of Bcl-2 in U937 cells, while leaving their redox status intact. These cells displayed enhanced sensitivity to mitochondrial permeability transition (MPT)-dependent apoptosis induced by arsenite and underwent a rapid, MPT-dependent necrotic response after exposure to otherwise nontoxic concentrations of peroxynitrite. Several lines of evidence consistently indicate that these low concentrations of peroxynitrite nevertheless commit cells to MPT, which is, however, prevented by a survival signaling in which arachidonic acid, protein kinase Calpha (PKCalpha), and Bcl-2 are sequentially involved. Bcl-2, however, was not the direct target of PKCalpha but most likely Bad, a protein involved in the regulation of Bcl-2 activity via heterodimerization. Further studies revealed that Bcl-2 does not afford protection in cells challenged with intrinsically toxic concentrations of peroxynitrite. This was due to depletion of GSH, an event leading to loss of the anti-MPT function of Bcl-2. Collectively, these results demonstrate a role of Bcl-2 in monocyte survival signaling preventing MPT-dependent necrosis induced by peroxynitrite, and provide an explanation for the reported observation that Bcl-2 fails to prevent necrosis mediated by intrinsically toxic levels of peroxynitrite.

Role of Peroxynitrite Anion in Renal Hypothermic Preservation Injury

BACKGROUND

Peroxynitrite anions may play a role in normothermic renal ischemia and reperfusion. The purpose of this study was to determine if endogenous peroxynitrite anion is involved in renal preservation injury.

METHODS

Experiments were conducted in isolated canine renal tubules and in a canine autotransplant model of hypothermic preservation injury.

RESULTS

Isolated renal tubules demonstrated progressive loss of membrane transport function after reperfusion with increasing cold storage times in UW solution as assessed by tetraethylammonium cation transport (TEA). This transport defect was not altered by reperfusion in the presence of WW85, a peroxynitrite decomposition catalyst. Likewise, tubule LDH release was not altered by WW85. Renal tubules did not demonstrate any evidence of peroxynitrite formation after cold storage (0-120 h) or after subsequent reperfusion in vitro as measured by nitrotyrosine adduct formation. Addition of exogenous peroxynitrite (1 mM) directly to freshly isolated renal tubules produced strong nitrotyrosine signals but failed to alter membrane function (TEA uptake). Conversely, SIN-1, a peroxynitrite generator molecule, failed to produce a nitrotyrosine signal in extracted renal tubule proteins but significantly impaired transport function. Finally, function of cold stored canine autografts was not affected by the scavenging of peroxynitrite anions (WW85) before kidney harvest and immediately at reperfusion. Tissue biopsies from cold stored kidney autografts also failed to show evidence of peroxynitrite synthesis either after cold storage (72 h) or after kidney transplantation (60 min reperfusion).

CONCLUSIONS

This study concludes that peroxynitrite anions are not formed and are not involved in renal preservation injury.

Selectively increasing inducible heat shock protein 70 via TAT-protein transduction protects neurons from nitrosative stress and excitotoxicity

Induction of heat shock protein 70 (Hsp70) via sublethal stress protects neurons from subsequent lethal injuries. Here we show that specific and efficient intracellular transduction of Hsp70 can be achieved utilizing an 11 amino acid leading sequence from human immunodeficiency virus (TAT-Hsp70) in primary neuronal cultures. Western blot and immunohistochemistry demonstrated intracellular accumulation of Hsp70 in insoluble protein fractions and mitochondrial compartments. We then examined the effects of Hsp70 overexpression using TAT-Hsp70 in models of nitrosative and excitotoxic neuronal death in vitro. Neurons were pre-incubated with 300 nM TAT-Hsp 70 overnight, then exposed to either peroxynitrite (ONOO-) or glutamate. TAT-Hsp70 maintained cellular respiration, inhibited extracellular lactate dehydrogenase release, and/or reduced cell death assessed by flow cytometry vs. vehicle, wild-type Hsp70, and TAT-beta-galactosidase controls. Hsp70 transduction using a TAT fusion protein is an effective method to selectively increase Hsp70 in neurons and is sufficient to provide neuroprotection from nitrosative stress and excitotoxicity. Further study is needed to confirm whether TAT-Hsp70 is protective in in vivo models of brain injury.

Peroxynitrite activates ERK via Raf-1 and MEK, independently from EGF receptor and p21Ras in H9C2 cardiomyocytes

Peroxynitrite is a potent oxidant and nitrating species proposed as a direct effector of myocardial damage in a wide range of cardiac diseases. Whether peroxynitrite also acts indirectly, by modulating cell signal transduction pathways in the myocardium, has not been investigated. Here, we examined the ability of peroxynitrite to activate extracellular signal-related kinase (ERK), a MAP kinase which has been linked with hypertrophic and anti-apoptotic responses in the heart, in cultured H9C2 cardiomyocytes. Peroxynitrite elicited a concentration- and time-dependent activation of ERK, secondary to the upstream activation of MEK 1 (ERK kinase). Activation of MEK-ERK by peroxynitrite was related to the upstream activation of Raf-1 kinase, as ERK and MEK phosphorylation were prevented by the Raf-1 inhibitor BAY43-9006. These effects of peroxynitrite were not associated with the activation of p21(Ras), known as a common signaling target of cellular oxidative stress. In contrast to ERK activation mediated by the epidermal growth factor (EGF), ERK activation by peroxynitrite was not prevented by AG1478 (EGF receptor inhibitor). Peroxynitrite acted through oxidative, but not nitrative chemistry, as ERK remained activated while nitration was prevented by the flavanol epicatechin. In addition to ERK, peroxynitrite also potently activated two additional members of the MAP kinase family of signaling proteins, JNK and p38. Thus, peroxynitrite activates ERK in cardiomyocytes through an unusual signaling cascade involving Raf-1 and MEK 1, independently from EGFR and P21(Ras), and also acts as a potent activator of JNK and p38. These results provide the novel concept that peroxynitrite may represent a previously unrecognized signaling molecule in various cardiac pathologies.

Peroxynitrite-induced mitochondrial and endonuclease-mediated nuclear DNA damage in acetaminophen hepatotoxicity

Intracellular sources of peroxynitrite formation and potential targets for this powerful oxidant and nitrating agent have not been identified after acetaminophen (AAP) overdose. Therefore, we tested the hypothesis that peroxynitrite generated in mitochondria may be responsible for mitochondrial DNA (mtDNA) and nuclear DNA (nDNA) damage. C3Heb/FeJ mice were treated with 300 mg/kg AAP and monitored for up to 12 h. Loss of mtDNA (assayed by slot blot hybridization) and substantial nDNA fragmentation (evaluated by anti-histone enzyme-linked immunosorbent assay, terminal deoxynucleotidyl transferase dUTP nick-end labeling assay, and agarose gel electrophoresis) were observed as early as 3 h after AAP overdose. Analysis of nitrotyrosine protein adducts in subcellular fractions established that peroxynitrite was generated predominantly in mitochondria beginning at 1 h after AAP injection. Delayed treatment with a bolus dose of glutathione (GSH) accelerated the recovery of mitochondrial glutathione, which then effectively scavenged peroxynitrite. However, mtDNA loss was only partially prevented. Despite the absence of nitrotyrosine adducts in the nucleus after AAP overdose, nDNA damage was almost completely eliminated with GSH administration. A direct comparison of nDNA damage after AAP overdose with nDNA fragmentation during tumor necrosis factor receptor-mediated apoptosis showed similar DNA ladders on agarose gels but quantitatively different results in three other assays. We conclude that peroxynitrite may be partially responsible for mtDNA loss but is not directly involved in nDNA damage. In contrast, nDNA fragmentation after AAP overdose is not caused by caspase-activated DNase but most likely by other intracellular DNase(s), whose activation is dependent on the mitochondrial oxidant stress and peroxynitrite formation.

Nitrosative stress and pharmacological modulation of heart failure

Dysregulation of nitric oxide (NO) and increased oxidative and nitrosative stress are implicated in the pathogenesis of heart failure. Peroxynitrite is a reactive oxidant that is produced from the reaction of nitric oxide with superoxide anion and impairs cardiovascular function through multiple mechanisms, including activation of matrix metalloproteinases (MMPs) and nuclear enzyme poly(ADP-ribose) polymerase (PARP). Recent studies suggest that the neutralization of peroxynitrite or pharmacological inhibition of MMPs and PARP are promising new approaches in the experimental therapy of various forms of myocardial injury. In this article, the role of nitrosative stress and downstream mechanisms, including activation of MMPs and PARP, in various forms of heart failure are discussed and novel emerging therapeutic strategies offered by neutralization of peroxynitrite and inhibition of MMPs and PARP in these pathophysiological conditions are reviewed.

Peroxynitrite-initiated oxidation of acetoacetate and 2-methylacetoacetate esters by oxygen: potential sources of reactive intermediates in keto acidoses

Oxidative stress is believed to play a role in the pathogenesis of several diseases, including diabetes and inborn errors of metabolism. The types of oxidative damage observed in these pathologies have been attributed to the excessive production of reactive intermediates relating to the accumulation of toxic metabolites. The production of extremely oxidizing peroxynitrite can also be high in these pathologies. We study here the oxidation initiated by peroxynitrite of the ethyl esters of acetoacetate (EAA) and 2-methylacetoacetate (EMAA), metabolites that accumulate in diabetes and isoleucinemia, respectively. Oxygen consumption studies have confirmed that peroxynitrite promotes the aerobic oxidation of EAA and EMAA in phosphate buffer. These reactions were accompanied by ultraweak light emission, which probably arises from triplet carbonyl products formed by thermolysis of dioxetane intermediates. The kinetics of oxygen uptake and chemiluminescence by EAA and EMAA was strongly affected by the phosphate ion, known to catalyze carbonyl enolization and nucleophilic additions to carbonyls. The reaction pH profiles obtained by oxygen consumption and chemiluminescence measurements indicated that the peroxynitrite anion was the initiator of EAA and EMAA aerobic oxidation. EPR spin-trapping studies with the spin traps 3,5-dibromo-4-nitrosobenzenesulfonic acid and 2-methyl-2-nitrosopropane showed the intermediacy of methyl and a carbon-centered radical (*CH2COR) in the oxidation of EAA by peroxynitrite. In the case of EMAA, a tertiary carbon-centered radical (*EMAA) and an acyl radical were detected, the latter probably resulting from the cleavage of a triplet carbonyl product. Superstoichiometric formation of acetate from both substrates confirmed the occurrence of oxygen-dependent chain reactions, here proposed to be initiated by one-electron abstraction from the enolic form of the substrates. The free radicals and electronically excited species generated in the oxidation of EAA and EMAA may help shed further light on the molecular basis of these diseases.

U937 cell necrosis mediated by peroxynitrite is not caused by depletion of ATP and is prevented by arachidonate via an ATP-dependent mechanism

Exposure of U937 cells to an otherwise nontoxic concentration of peroxynitrite promotes a rapid necrotic response in the presence of pharmacological inhibitors of phospholipase A2. A 12-fold higher concentration of the oxidant, in the absence of additional treatments, caused remarkably greater DNA single-strand breakage, delayed formation of H2O2, and depletion of reduced glutathione but an identical level of toxicity. Cell death was prevented in both circumstances by nanomolar levels of arachidonic acid or by cyclosporin A via mechanisms unrelated to elimination of the above effects and was causally linked to prevention of mitochondrial permeability transition. Treatment with a high dose of peroxynitrite for 30 min caused an approximately 40% decline in ATP, both in the absence and presence of arachidonate, whereas only a small, arachidonic acid-sensitive reduction of the ATP pool was detected in cells treated with the low dose of peroxynitrite and the phospholipase A2 inhibitor. ATP-predepleted cells, however, were hypersensitive to peroxynitrite, and under these conditions, toxicity was not prevented by arachidonate. The above findings were reproduced in another promonocytic cell line, THP-1 cells. We concluded that the rapid necrotic response triggered by peroxynitrite in monocytes is mediated by a regulated process, not by ATP depletion, associated with reduced arachidonate availability. Supplementation of exogenous arachidonic acid always rescued cells via an ATP-dependent survival pathway.

The radical scavenger edaravone prevents oxidative neurotoxicity induced by peroxynitrite and activated microglia

The free radical scavenger edaravone has been used as an anti-oxidative agent in acute ischemic brain disorders. We examined the effect of edaravone on the production of nitric oxide (NO), reactive oxygen species (ROS) and proinflammatory cytokines by activated microglia, and we also examined its neuroprotective role in cortical neuronal cultures oxidatively stressed by the peroxynitrite donor N-morpholinosydnonimine (SIN-1) or activated microglia. Edaravone significantly suppressed the production of NO and ROS by activated microglia, though it did not suppress production of inflammatory cytokines. In addition, edaravone significantly suppressed neuronal cell death and dendrotoxicity induced by either SIN-1 or activated microglia in a dose-dependent manner. These results suggest that edaravone may function as a neuroprotective agent counteracting oxidative neurotoxicity arising from activated microglia, as occurs in either inflammatory or neurodegenerative disorders of the central nervous system.

Effects of Peroxynitrite Dose and Dose Rate on DNA Damage and Mutation in thesupFShuttle Vector

Peroxynitrite (ONOO-) induces oxidative and nitrosative DNA damage, and previous studies by our group have shown that it is strongly mutagenic in the supF shuttle vector pSP189 replicated in Escherichia coli MBL50 cells. In those experiments, however, the pSP189 plasmid was exposed under unphysiological conditions to large single bolus doses of ONOO-, which limits extrapolation of the data to in vivo pathological states in which ONOO- may play a role. We have thus sought to define the effects of ONOO- dose and dose rate on the DNA damage and mutations induced in the supF gene by three different dosage mechanisms: (i) by infusion of ONOO- solution into suspensions of pSP189 at rates approximating those estimated to occur in inflamed tissues; (ii) by exposure to 3-morpholinosydnonimine (SIN-1), which generates ONOO- spontaneously during decomposition; and (iii) by bolus doses of ONOO- solution. In all cases, plasmid DNA was exposed in the presence of 25 mM bicarbonate, since the reaction of CO2 with ONOO- (to form nitrosoperoxycarbonate) has a major impact on mutagenic potency of ONOO- in this system. Nucleobase and deoxyribose damage were evaluated by a plasmid nicking assay immediately after ONOO- and SIN-1 exposures. Mutation frequency (MF) and mutational spectra in the supF gene were determined after plasmid pSP189 replicated in host E. coli cells. Bolus ONOO- addition caused the highest amount of DNA damage, including base and deoxyribose lesions, while infusion caused the least. SIN-1 was found to induce almost exclusively deoxyribose oxidation, while bolus addition generated a high percentage of base damage. MF increased in a dose-dependent manner following all treatments, but infused ONOO- and SIN-1 exposures were less mutagenic than bolus ONOO- exposure. MFs induced by infusion and by SIN-1 incubated for 100 min at the highest level (4 mM) were 63 and 43% less, respectively, than that induced by bolus. All mutational hot spots were located at G:C sites except for A121 and A177 induced by SIN-1 exposure. Hot spots at C108 and C168 were common to all exposures; G113, G115, and G116 were common to bolus and infused ONOO- exposures; and G129 was common to infused ONOO- and SIN-1 exposures. Almost all mutations were single base pair substitutions under all exposure conditions. Whereas those induced by infused or bolus ONOO- and SIN-1 consisted predominantly of G:C to T:A transversions (66, 65, and 51%, respectively), G:C to C:G mutations were much less frequent following infusion and SIN-1 (8 and 19%, respectively) than those induced by bolus exposure (29%). A:T to T:A mutations induced were detected only after ONOO- infusion and SIN-1 exposure (9 and 11%, respectively). In conclusion, both dose and dose rate at which a genetic target is exposed to ONOO- substantially influence the damage and mutational response, indicating that these parameters will need to be taken into account in assessing the potential effects of ONOO- in vivo. Furthermore, the results indicate that the chemistry of SIN-1-induced DNA damage differs substantially from native ONOO-, which suggests the need for caution in interpreting the biological relevance of SIN-1 as a surrogate for ONOO-.

Caspase-1 and poly (ADP-ribose) polymerase inhibitors may protect against peroxynitrite-induced neurotoxicity independent of their enzyme inhibitor activity

We investigated the mechanism of 3-morpholinosyndnomine (SIN-1) neurotoxicity in nearly pure neuronal cultures. In a simple saline solution, SIN-1 neurotoxicity was found to be mediated by peroxynitrite and independent of glutamate receptor activation [Y. Zhang & P.A. Rosenberg (2002) Eur. J. Neurosci, 16, 1015-1024]. To further study the mechanism of peroxynitrite toxicity to neurons we investigated the role of caspases and poly (ADP-ribose) polymerase (PARP) in this model system. Ac-Tyr-Val-Ala-Asp-chloromethyl ketone (Ac-YVAD-cmk), a specific caspase-1 inhibitor, completely blocked neurotoxicity as well as ATP depletion induced by SIN-1. However, a caspase-3 inhibitor and a pan-caspase inhibitor were both without effect. These results suggested that the protection of Ac-YVAD-cmk might not be due to its inhibition of caspase-1. Indeed, Western blot analysis and assay of caspase activity indicated that caspase activation was not involved in SIN-1 toxicity. Ac-YVAD-cmk also completely blocked in vitro protein nitration induced by SIN-1 or peroxynitrite, suggesting that Ac-YVAD-cmk may interact with peroxynitrite directly. Similarly, although activation of PARP is thought to be a major cause of peroxynitrite-induced ATP depletion, and two PARP inhibitors, 1,5-dihydroxyisoquinoline (DHQ) and 3-aminobenzamide (3-AB), completely prevented ATP depletion and neurotoxicity induced by SIN-1, SIN-1 did not increase poly (ADP-ribosyl)ation and PARP activity. Furthermore, DHQ and 3-AB completely prevented in vitro protein nitration induced by peroxynitrite, indicating that DHQ and 3-AB directly interact with peroxynitrite. Taken together, these results suggest that in the model system used here peroxynitrite neurotoxicity is independent of caspase and PARP activation, and therefore implicate a novel mechanism.

The effect of desferrioxamine on peroxynitrite-induced oxidative damage in erythrocytes

The aim of this study was to investigate the effect of desferrioxamine on peroxynitrite-mediated damage in erythrocytes by measuring the 3-nitrotyrosine level and glutathione peroxidase and Na(+)-K(+) ATPase activities in vitro. 3-Nitrotyrosine levels were determined by HPLC; glutathione peroxidase and Na(+)-K(+) ATPase activities were measured by spectrophotometry. Peroxynitrite increased the 3-nitrotyrosine level but decreased both enzyme activities. In the presence of desferrioxamine, glutathione peroxidase activity was increased with a decrease in the 3-nitrotyrosine level. Desferrioxamine was found to possess an important antioxidant activity as assessed in an in vitro system, reducing protein nitration, restoring enzyme activities and maintaining erythrocyte membrane integrity.

Peroxynitrite delivery methods for toxicity studies

The endogenous synthesis of peroxynitrite (ONOO(-)) has been implicated in a number of diseases, but assessments of its cytotoxicity and genotoxicity have been hampered by its extremely short half-life under physiological conditions (<20 ms) and the consequent difficulty in exposing cells to known concentrations of it over at least several hours. Two methods for peroxynitrite delivery to cell cultures were investigated, one involving steady infusion of preformed ONOO(-) and the other based on the continuous in situ synthesis of ONOO(-) from NO and O(2)(-). In the latter, NO was supplied by diffusion through gas permeable tubing and O(2)(-) was generated using the hypoxanthine-xanthine oxidase reaction. The performance of both methods was assessed by measuring the rates of formation of tyrosine derivatives (dityrosine and nitrotyrosine) that are commonly employed as biomarkers for peroxynitrite. Experimental results in the absence of cells were compared in each case with predictions from kinetic models. In the infusion system, the measured dityrosine and nitrotyrosine yields were in excellent agreement with those predicted from the model. To characterize the other system, experiments were performed first to determine the kinetics of hypoxanthine oxidation by xanthine oxidase and uric acid oxidation by uricase. Simulations of the complex reaction network in the complete synthesis system suggested that dityrosine should be the major product there, that the yields of both tyrosine derivatives should be very sensitive to the relative rates of NO and O(2)(-) delivery, and that equal rates for NO and O(2)(-) should maximize those yields. Experiments performed under the predicted optimal conditions showed much lower levels of dityrosine than expected and no detectable nitrotyrosine. The unexpectedly low yields of tyrosine products could be explained largely by the partial inactivation of both xanthine oxidase and uricase by peroxynitrite-derived NO(2) and CO(3)(-) radicals. We conclude that continuous infusion of peroxynitrite is the more promising approach.

Potent inhibition of peroxynitrite-induced DNA strand breakage by ethanol: possible implications for ethanol-mediated cardiovascular protection

Epidemiological studies have conclusively demonstrated that moderate consumption of ethanol is causally associated with a significant reduction in cardiovascular events. However, the exact mechanisms underlying the ethanol-mediated cardiovascular protection remain to be elucidated. Because peroxynitrite has been extensively implicated in the pathogenesis of various forms of cardiovascular disorders via its cytotoxic effects, this study was undertaken to investigate if ethanol could inhibit peroxynitrite-induced DNA strand breaks, a critical event leading to peroxynitrite-elicited cytotoxicity. Toward this goal, phiX-174 RF I plasmid DNA was used as an in vitro model to determine the protective effects of ethanol on peroxynitrite-induced DNA strand breaks. Incubation of phiX-174 plasmid DNA with the peroxynitrite generator, 3-morpholinosydnonimine (SIN-1) led to the formation of both single- and double-stranded DNA breaks in a concentration- and time-dependent fashion. The presence of ethanol at concentrations ranging from 0.01 to 1% (w/v) resulted in a significant inhibition of SIN-1-induced DNA strand breaks. Ethanol also showed inhibitory effects on SIN-1-induced DNA strand breakage in the presence of bicarbonate. The inhibition of SIN-1-induced DNA strand breaks by ethanol exhibited a concentration-dependent manner. Notably, a marked inhibition of SIN-1-elicited DNA strand breaks was observed with 0.01% ethanol. Ethanol at 0.01-1% was unable to affect SIN-1-mediated oxygen consumption, indicating that ethanol did not affect the auto-oxidation of SIN-1 to form peroxynitrite. Furthermore, incubation of the plasmid DNA with authentic peroxynitrite resulted in a significant formation of DNA strand breaks, which could be dramatically inhibited by the presence of 0.02-0.1% ethanol. Taken together, this study demonstrates for the first time that ethanol at physiologically relevant concentrations can potently inhibit peroxynitrite-induced DNA strand breakage. In view of the critical involvement of peroxynitrite in cardiovascular disorders, the results of this study might have implications for the cardiovascular protection associated with moderate consumption of ethanol in humans.

Enhancing effects of intracellular ascorbic acid on peroxynitrite-induced U937 cell death are mediated by mitochondrial events resulting in enhanced sensitivity to peroxynitrite-dependent inhibition of complex III and formation of hydrogen peroxide

A short-term pre-exposure to dehydroascorbic acid (DHA) promotes U937 cell death upon exposure to otherwise non-toxic levels of peroxynitrite (ONOO-). Toxicity is mediated by a saturable mechanism and cell death takes place as a consequence of mitochondrial permeability transition. The following lines of evidence are consistent with the notion that the enhancing effects of DHA were related to mitochondrial events resulting in inhibition of complex III upon exposure to otherwise inactive concentrations of ONOO-. First, DHA, as well as bona fide complex III inhibitors, similarly enhanced toxicity and subsequent formation of H2O2 induced by ONOO- via a rotenone- or catalase-sensitive mechanism. Secondly, bona fide complex III inhibitors were ineffective in DHA-pre-loaded cells. In addition, respiration-deficient cells were resistant to toxicity elicited by ONOO- and their supplementation with increasing concentrations of DHA, although resulting in the accumulation of vitamin C levels identical with those observed in respiration-proficient cells, failed to affect ONOO- toxicity. Finally, oxygen-consumption experiments demonstrated that pre-exposure to DHA promotes the ONOO--dependent inhibition of complex III. In conclusion, the above results collectively demonstrate that increasing the intracellular accumulation of vitamin C promotes mitochondrial events leading to ONOO--dependent formation of H2O2 and resulting in a rapid necrotic response.

The arachidonate-dependent cytoprotective signaling evoked by peroxynitrite is a general response of the monocyte/macrophage lineage

U937, THP-1, and J774 cells or human monocytes and macrophages display similar levels of sensitivity to peroxynitrite and exposure to an otherwise non-toxic concentration of the oxidant in the presence of a phospholipase A(2) inhibitor was invariably associated with the onset of mitochondrial permeability transition (MPT)-dependent toxicity. These events were prevented by exogenous arachidonic acid (AA). In general, the protective concentrations of AA were greater in those cell types releasing more AA. Thus, non-toxic concentrations of peroxynitrite commit cells belonging to the monocyte/macrophage lineage to MPT-dependent toxicity that is however prevented by endogenous AA.

[Damage effects of peroxynitrite on different hepatocyte lines]

OBJECTIVE

To investigate the damages of peroxynitrite (ONOO-) to L-02 and HepG2 cell lines.

METHODS

Use MTT singe cell gel electrophoresis and flow cytometry was applied to detect the effects of peroxynitrite on cell viability, DNA impairment and cell apoptosis level in two cell lines.

RESULTS

Peroxynitrite had cell toxicity on both cell lines. It caused DNA damages, cell apoptosis and cell cycle change. Furthermore, the damage level was proportional to the concentration of peroxynitrite. The damages were more serious in L-02 in every concentration level than that in HepG2, but no statistic difference between two cell lines.

CONCLUSION

Peroxynitrite could cause DNA damage, apoptosis and changed cell cycles in both normal and carcinoma cell lines through no statistical significant difference among them was found.

Nitrotyrosine as a marker for peroxynitrite-induced neurotoxicity: the beginning or the end of the end of dopamine neurons?

This review examines the involvement of nitrotyrosine as a marker for peroxynitrite-mediated damage in the dopamine neuronal system. We propose that the dopamine neuronal phenotype can influence the cytotoxic signature of peroxynitrite. Dopamine and tetrahydrobiopterin are concentrated in dopamine neurons, and both are essential for their proper neurochemical function. It is not well appreciated that dopamine and tetrahydrobiopterin are also powerful blockers of peroxynitrite-induced tyrosine nitration. What is more, the reaction of peroxynitrite with either dopamine or tetrahydrobiopterin forms chemical species (i.e. o-quinones and pterin radicals, respectively) whose cytotoxic effects may be manifested far earlier than nitrotyrosine formation in the course of dopamine neuronal damage. A better understanding of how the dopamine neuronal phenotype modulates the effects of reactive nitrogen species could reveal early steps in drug- and disease-induced damage to the dopamine neuron and form the basis for rational, protective therapies.

Selenium Redox Cycling in the Protective Effects of Organoselenides against Oxidant-Induced DNA Damage

The biological role of selenium is a subject of intense current interest, and the antioxidant activity of selenoenzymes is now known to be dependent upon redox cycling of selenium within their active sites. Exogenously supplied or metabolically generated organoselenium compounds, capable of propagating a selenium redox cycle, might therefore supplement natural cellular defenses against the oxidizing agents generated during metabolism. We now report evidence that selenium redox cycling can enhance the protective effects of organoselenium compounds against oxidant-induced DNA damage. Phenylaminoethyl selenides were found to protect plasmid DNA from peroxynitrite-mediated damage by scavenging this powerful cellular oxidant and forming phenylaminoethyl selenoxides as the sole selenium-containing products. The redox properties of these organoselenoxide compounds were investigated, and the first redox potentials of selenoxides in the literature are reported here. Rate constants were determined for the reactions of the selenoxides with cellular reductants such as glutathione (GSH). These kinetic data were then used in a MatLab simulation, which showed the feasibility of selenium redox cycling by GSH in the presence of the cellular oxidant, peroxynitrite. Experiments were then carried out in which peroxynitrite-mediated plasmid DNA nick formation in the presence or absence of organoselenium compounds and GSH was monitored. The results demonstrate that GSH-mediated redox cycling of selenium enhances the protective effects of phenylaminoethyl selenides against peroxynitrite-induced DNA damage.

Protecting Against Peroxynitrite-Mediated Cytotoxicity in Vascular Smooth Muscle Cells Via Upregulating Endogenous Glutathione Biosynthesis by 3H-1,2-dithiole-3-thione

Peroxynitrite (ONOO(-)) is critically involved in the pathogenesis of cardiovascular diseases. Reaction with glutathione (GSH) was proposed to be a major detoxification pathway of ONOO(-) in the biological system. This study was undertaken to determine if chemically elevated intracellular GSH affords protection against ONOO(-)-mediated toxicity in vascular cells. Incubation of aortic smooth muscle A10 cells with 3H-1,2-dithiole-3-thione (D3T) led to a concentration- and time-dependent elevation of cellular GSH. Treatment of the cells with D3T also augmented protein and gene expression of gamma-glutamylcysteine ligase. To examine the effects of D3T-induced GSH on ONOO(-)-mediated toxicity, we pretreated A10 cells with D3T and then exposed them to either authentic ONOO(-) or the ONOO(-) generator, 3-morpholinosydnonimine. We observed that D3T pretreatment of A10 cells resulted in a significant protection against ONOO(-) cytotoxicity. Conversely, depletion of cellular GSH by buthionine sulfoximine (BSO) caused a marked potentiation of ONOO(-) cytotoxicity. To further demonstrate the causal involvement of GSH induction in D3T cytoprotection, we cotreated A10 cells with BSO to abolish D3T-induced GSH elevation. BSO cotreatment was found to greatly reverse the protective effects of D3T on ONOO(-)-elicited cytotoxicity. Taken together, our results demonstrate that upregulating GSH biosynthesis by D3T results in a marked protection against ONOO(-)-induced toxicity in vascular cells.